Control of Hazardous Air Pollutants From Mobile Sources, 8428-8570 [E7-2667]
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
ENVIRONMENTAL PROTECTION
AGENCY
40 CFR Parts 59, 80, 85, and 86
[EPA–HQ–OAR–2005–0036; FRL–8278–4]
RIN 2060–AK70
Control of Hazardous Air Pollutants
From Mobile Sources
Environmental Protection
Agency (EPA).
ACTION: Final rule.
AGENCY:
SUMMARY: EPA is adopting controls on
gasoline, passenger vehicles, and
portable fuel containers (primarily gas
cans) that will significantly reduce
emissions of benzene and other
hazardous air pollutants (‘‘mobile
source air toxics’’). Benzene is a known
human carcinogen, and mobile sources
are responsible for the majority of
benzene emissions. The other mobile
source air toxics are known or suspected
to cause cancer or other serious health
effects. We are limiting the benzene
content of gasoline to an annual refinery
average of 0.62% by volume, beginning
in 2011. In addition, for gasoline, we are
establishing a maximum average
standard for refineries of 1.3% by
volume beginning on July 1, 2012,
which acts as an upper limit on gasoline
benzene content when credits are used
to meet the 0.62 volume % standard. We
are also limiting exhaust emissions of
hydrocarbons from passenger vehicles
when they are operated at cold
temperatures. This standard will be
phased in from 2010 to 2015. For
passenger vehicles, we are also adopting
evaporative emissions standards that are
equivalent to those currently in effect in
California. Finally, we are adopting a
hydrocarbon emissions standard for
portable fuel containers beginning in
2009, which will reduce evaporation
and spillage of gasoline from these
containers. These controls will
significantly reduce emissions of
benzene and other mobile source air
toxics such as 1,3-butadiene,
formaldehyde, acetaldehyde, acrolein,
and naphthalene. There will be
additional substantial benefits to public
health and welfare because of
significant reductions in emissions of
particulate matter from passenger
vehicles.
DATES: This rule is effective on April 27,
2007.
ADDRESSES: EPA has established a
docket for this action under Docket ID
No. EPA–HQ–2005–0036. All
documents in the docket are listed on
the www.regulations.gov Web site.
Although listed in the index, some
information is not publicly available,
e.g., CBI or other information whose
disclosure is restricted by statute.
Certain other material, such as
copyrighted material, is not placed on
the Internet and will be publicly
available only in hard copy form.
Publicly available docket materials are
Category
NAICS
codes a
Industry .....................................................................................................
Industry .....................................................................................................
336111
335312
424720
811198
....................
811111
811112
811198
324110
326199
332431
Industry .....................................................................................................
Industry .....................................................................................................
Industry .....................................................................................................
a North
available either electronically through
https://www.regulations.gov or in hard
copy at the Air Docket, EPA/DC, EPA
West, Room 3334, 1301 Constitution
Ave., NW., Washington, DC. The Public
Reading Room is open from 8:30 a.m. to
4:30 p.m., Monday through Friday,
excluding legal holidays. The telephone
number for the Public Reading Room is
(202) 566–1744, and the telephone
number for the Air Docket is (202) 566–
1742.
FOR FURTHER INFORMATION CONTACT: Mr.
Chris Lieske, U.S. EPA, Office of
Transportation and Air Quality,
Assessment and Standards Division
(ASD), Environmental Protection
Agency, 2000 Traverwood Drive, Ann
Arbor, MI 48105; telephone number:
(734) 214–4584; fax number: (734) 214–
4816; e-mail address:
lieske.christopher@epa.gov, or
Assessment and Standards Division
Hotline; telephone number: (734) 214–
4636; e-mail address: asdinfo@epa.gov.
SUPPLEMENTARY INFORMATION:
Does This Action Apply to Me?
Entities potentially affected by this
action are those that produce new motor
vehicles, alter individual imported
motor vehicles to address U.S.
regulation, or convert motor vehicles to
use alternative fuels. It will also affect
you if you produce gasoline motor fuel
or manufacture portable gasoline
containers. Regulated categories
include:
SIC codes b
Examples of potentially affected entities
3711
3621
5172
7539
7549
7538
7533
7549
2911
3089
3411
Motor vehicle manufacturers.
Alternative fuel vehicle converters.
Independent commercial importers.
Gasoline fuel refiners.
Portable fuel container manufacturers.
American Industry Classification System (NAICS).
Industrial Classification (SIC) system code.
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b Standard
This table is not intended to be
exhaustive, but rather provides a guide
for readers regarding entities likely to be
regulated by this action. This table lists
the types of entities that EPA is now
aware could potentially be regulated by
this action. Other types of entities not
listed in the table could also be
regulated. To determine whether your
activities are regulated by this action,
you should carefully examine the
applicability criteria in 40 CFR parts 59,
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80, 85, and 86. If you have any
questions regarding the applicability of
this action to a particular entity, consult
the person listed in the preceding FOR
FURTHER INFORMATION CONTACT section.
Outline of This Preamble
I. Summary
II. Overview of Final Rule
A. Light-Duty Vehicle Emission Standards
B. Gasoline Fuel Standards
C. Portable Fuel Container (PFC) Controls
III. Why Is EPA Taking This Action?
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A. Statutory Requirements
1. Clean Air Act Section 202(l)
2. Clean Air Act Section 183(e)
3. Energy Policy Act
B. Public Health Impacts of Mobile Source
Air Toxics (MSATs)
1. What Are MSATs?
2. Health Risk Associated With MSATs
a. National Cancer Risk
b. National Risk of Noncancer Health
Effects
c. Exposure Near Roads
d. Exposure From Attached Garages
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3. What Are the Health Effects of Air
Toxics?
a. Overview of Potential Cancer and
Noncancer Health Effects
b. Health Effects of Key MSATs
i. Benzene
ii. 1,3-Butadiene
iii. Formaldehyde
iv. Acetaldehyde
v. Acrolein
vi. Polycyclic Organic Matter (POM)
vii. Naphthalene
viii. Diesel Exhaust
c. Gasoline PM
d. Near-Roadway Health Effects
C. Ozone
1. Background
2. Health Effects of Ozone
3. Plant and Ecosystem Effects of Ozone
4. Current and Projected 8-hour Ozone
Levels
D. Particulate Matter
1. Background
2. Health Effects of PM
3. Welfare Effects of PM
a. Visibility
i. Background
ii Current Visibility Impairment
iii. Future Visibility Impairment
b. Atmospheric Deposition
c. Materials Damage and Soiling
4. Current and Projected PM2.5 Levels
5. Current PM10 Levels
IV. What Are the Emissions, Air Quality, and
Public Health Impacts of This Rule?
A. Emissions Impacts of All Rule
Provisions Combined
1. How Will MSAT Emissions Be Reduced?
2. How Will VOC Emissions Be Reduced?
3. How Will PM Emissions Be Reduced?
B. Emission Impacts by Provision
1. Vehicle Controls
a. Volatile Organic Compounds (VOC)
b. Toxics
c. PM2.5
2. Fuel Benzene Standard
3. PFC Standards
a. VOC
b. Toxics
C. What Are the Air Quality, Exposure, and
Public Health Impacts of This Rule?
1. Mobile Source Air Toxics
2. Ozone
3. PM
D. What Other Mobile Source Emissions
Control Programs Reduce MSATs?
1. Fuels Programs
a. Gasoline Sulfur
b. Gasoline Volatility
c. Diesel Fuel
d. Phase-Out of Lead in Gasoline
2. Highway Vehicle and Engine Programs
3. Nonroad Engine Programs
4. Voluntary Programs
5. Additional Programs Under
Development That Will Reduce MSATs
a. On-Board Diagnostics for Heavy-Duty
Vehicles Over 14,000 Pounds
b. Standards for Small Nonroad SparkIgnition Engines
c. Standards for Locomotive and Marine
Diesel Engines
E. How Do These Mobile Source Programs
Satisfy the Requirements of Clean Air
Act Section 202(l)?
V. New Light-duty Vehicle Standards
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A. Introduction
B. What Cold Temperature Requirements
Are We Adopting?
1. Why Are We Adopting a New Cold
Temperature NMHC Standard?
2. What Are the New NMHC Exhaust
Emissions Standards?
3. Feasibility of the Cold Temperature
NMHC Standards
a. Currently Available Emission Control
Technologies
b. Feasibility Considering Current
Certification Levels, Deterioration and
Compliance Margin
c. Feasibility and Test Programs
4. Standards Timing and Phase-In
a. Phase-In Schedule
b. Alternative Phase-In Schedules
5. Certification Levels
6. Credit Program
a. How Credits Are Calculated
b. Credits Earned Prior to Primary PhaseIn Schedule
c. How Credits Can Be Used
d. Discounting and Unlimited Life
e. Deficits Can Be Carried Forward
f. Voluntary Heavy-Duty Vehicle Credit
Program
7. Additional Vehicle Cold Temperature
Standard Provisions
a. Applicability
b. Useful Life
c. High Altitude
d. In-Use Standards for Vehicles Produced
During Phase-In
8. Monitoring and Enforcement
C. What Evaporative Emissions Standards
Are We Finalizing?
1. Current Controls and Feasibility of the
New Standards
2. Evaporative Standards Timing
3. Timing for Flex Fuel Vehicles
4. In-Use Evaporative Emission Standards
5. Existing Differences Between California
and Federal Evaporative Emission Test
Procedures
D. Additional Exhaust Control Under
Normal Conditions
E. Vehicle Provisions for Small Volume
Manufacturers
1. Lead Time Transition Provisions
2. Hardship Provisions
3. Special Provisions for Independent
Commercial Importers (ICIs)
VI. Gasoline Benzene Control Program
A. Description of and Rationale for the
Gasoline Benzene Control Program
1. Gasoline Benzene Content Standard
a. Description of the Average Benzene
Content Standard
b. Why Are We Finalizing a Benzene
Content Standard?
i. Standards That Would Include Toxics
Other Than Benzene
ii. Control of Gasoline Sulfur and/or
Volatility for MSAT Reduction
iii. Diesel Fuel Changes
c. Why Are We Finalizing a Level of 0.62
vol% for the Average Benzene Standard?
i. General Technological Feasibility of
Benzene Control
ii. Appropriateness of the 0.62 vol%
Average Benzene Content Standard
iii. Timing of the Average Standard
d. Upper Limit Benzene Standard
2. Description of the Averaging, Banking,
and Trading (ABT) Program
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a. Overview
b. Credit Generation
i. Eligibility
ii. Early Credit Generation
iii. Standard Credit Generation
c. Credit Use
i. Early Credit Life
ii. Standard Credit Life
iii. Consideration of Unlimited Credit Life
iv. Credit Trading Provisions
3. Provisions for Small Refiners and
Refiners Facing Hardship Situations
a. Provisions for Small Refiners
i. Definition of Small Refiner for Purposes
of the MSAT2 Small Refiner Provisions
ii. Small Refiner Status Application
Requirements
iii. Small Refiner Provisions
iv. The Effect of Financial and Other
Transactions on Small Refiner Status and
Small Refiner Relief Provisions
b. Provisions for Refiners Facing Hardship
Situations
i. Temporary Waivers Based on Extreme
Hardship Circumstances
ii. Temporary Waivers Based on
Unforeseen Circumstances
c. Option for Early Compliance in Certain
Circumstances
B. How Will the Gasoline Benzene
Standard Be Implemented?
1. General Provisions
2. Small Refiner Status Application
Requirements
3. Administrative and Enforcement
Provisions
a. Sampling/Testing
b. Recordkeeping/Reporting
C. How Will the Program Relate to Other
Fuel-Related Toxics Programs?
D. How Does This Program Satisfy the
Statutory Requirements of Clean Air Act
Section 202(l)(2)?
VII. Portable Fuel Containers
A. What Are the New HC Emissions
Standards for PFCs?
1. Description of Emissions Standard
2. Determination of Best Available Control
3. Diesel, Kerosene and Utility Containers
4. Automatic Shut-Off
B. Timing of Standard
C. What Test Procedures Would Be Used?
1. Diurnal Test
2. Preconditioning To Ensure Durable InUse Control
a. Durability Cycles
b. Preconditioning Fuel Soak
c. Spout Actuation
D. What Certification and In-Use
Compliance Provisions Is EPA Adopting?
1. Certification
2. Emissions Warranty and In-Use
Compliance
3. Labeling
E. How Would State Programs Be Affected
by EPA Standards?
F. Provisions for Small PFC Manufacturers
1. First Type of Hardship Provision
2. Second Type of Hardship Provision
VIII. What Are the Estimated Impacts of the
Rule?
A. Refinery Costs of Gasoline Benzene
Reduction
1. Methodology
a. Overview of the Benzene Program Cost
Methodology
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b. Changes to the Cost Estimation
Methodology Used in the Proposed Rule
c. Linear Programming Cost Model
d. Refinery-by-Refinery Cost Model
e. Price of Chemical Grade Benzene
2. Summary of Costs
a. Nationwide Costs of the Final Benzene
Control Program
b. Regional Costs
c. Refining Industry Cost Study
B. What Are the Vehicle Cost Impacts?
C. What Are the PFC Cost Impacts?
D. Cost per Ton of Emissions Reduced
E. Benefits
1. Unquantified Health and Environmental
Benefits
2. Quantified Human Health and
Environmental Effects of the Final Cold
Temperature Vehicle Standard
3. Monetized Benefits
4. What Are the Significant Limitations of
the Benefit Analysis?
5. How Do the Benefits Compare to the
Costs of the Final Standards?
F. Economic Impact Analysis
1. What Is an Economic Impact Analysis?
2. What Is the Economic Impact Model?
3. What Economic Sectors Are Included in
This Economic Impact Analysis?
4. What Are the Key Features of the
Economic Impact Model?
5. What Are the Key Model Inputs?
6. What Are the Results of the Economic
Impact Modeling?
IX. Public Participation
X. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory
Planning and Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act (RFA), as
Amended by the Small Business
Regulatory Enforcement Fairness Act of
1996 (SBREFA), 5 U.S.C. 601 et seq.
1. Overview
2. The Need for and Objectives of This
Rule
3. Summary of the Significant Issues
Raised by the Public Comments
4. Summary of Regulated Small Entities
a. Highway Light-Duty Vehicles
b. Gasoline Refiners
c. Portable Fuel Container Manufacturers
5. Description of the Reporting,
Recordkeeping, and Other Compliance
Requirements of the Rule
6. Relevant Federal Rules
7. Steps Taken To Minimize the Significant
Economic Impact on Small Entities
a. Significant Panel Findings
b. Outreach With Small Entities (and the
Panel Process)
c. Small Business Flexibilities
i. Highway Light-Duty Vehicles
ii. Gasoline Refiners
iii. Portable Fuel Containers
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
G. Executive Order 13045: Protection of
Children From Environmental Health
and Safety Risks
H. Executive Order 13211: Actions That
Significantly Affect Energy Supply,
Distribution, or Use
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I. National Technology Transfer
Advancement Act
J. Executive Order 12898: Federal Actions
To Address Environmental Justice in
Minority Populations and Low-Income
Populations
K. Congressional Review Act
XI. Statutory Provisions and Legal Authority
I. Summary
Mobile sources emit air toxics (also
known as ‘‘hazardous air pollutants’’)
that can cause cancer and other serious
health effects. Mobile sources contribute
significantly to the nationwide risk from
breathing outdoor sources of air toxics.
Mobile sources were responsible for
about 44% of outdoor toxic emissions,
almost 50% of the cancer risk, and 74%
of the noncancer risk according to EPA’s
National-Scale Air Toxics Assessment
(NATA) for 1999. In addition, people
who live or work near major roads or
live in homes with attached garages are
likely to have higher exposures and risk,
which are not reflected in NATA.
According to NATA for 1999, there
are a few mobile source air toxics that
pose the greatest risk based on current
information about ambient levels and
exposure. These include benzene, 1,3butadiene, formaldehyde, acrolein,
naphthalene, and polycyclic organic
matter (POM). All of these compounds
are gas-phase hydrocarbons except
POM, which appears in the gas and
particle phases. Benzene is the most
significant contributor to cancer risk
from all outdoor air toxics, according to
NATA for 1999. NATA does not include
a quantitative estimate of cancer risk for
diesel exhaust, but it concludes that
diesel exhaust is a mixture of pollutants
that collectively poses one of the
greatest relative cancer risks when
compared with the other individual
pollutants assessed. Although we expect
significant reductions in mobile source
air toxics in the future, cancer and
noncancer health risks will remain a
public health concern, and exposure to
benzene will remain the largest
contributor to this risk.
In this rule, we are finalizing
standards for passenger vehicles,
gasoline, and portable fuel containers
(typically gas cans). Specifically, we are
finalizing standards for:
• exhaust hydrocarbon emissions
from passenger vehicles during cold
temperature operation;
• evaporative hydrocarbon emissions
from passenger vehicles;
• the benzene content of gasoline;
and
• hydrocarbon emissions from
portable fuel containers that would
reduce evaporation, permeation, and
spillage from these containers.
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These standards will significantly
reduce emissions of the many air toxics
that are hydrocarbons, including
benzene, 1,3-butadiene, formaldehyde,
acetaldehyde, acrolein, and
naphthalene. The fuel benzene
standards and hydrocarbon standards
for vehicles and portable fuel containers
will together reduce total emissions of
air toxics by 330,000 tons in 2030,
including 61,000 tons of benzene. As a
result of this final rule, in 2030
passenger vehicles will emit 45% less
benzene, gas cans will emit almost 80%
less benzene, and gasoline will have
38% less benzene overall. Mobile
sources were responsible for over 70%
of benzene emissions in 1999.
The reductions in mobile source air
toxics emissions will reduce exposure
and predicted risk of cancer and
noncancer health effects, including in
environments where exposure and risk
may be highest, such as near roads, in
vehicles, and in homes with attached
garages. Nationwide, the cancer risk
attributable to total MSATs emitted by
all mobile sources will be reduced by
30%, and the risk from mobile source
benzene will be reduced by 37%. At
2030 exposure levels, the highway
vehicle contribution to MSAT cancer
risk will be reduced on average 36%
across the U.S., and the highway vehicle
contribution to benzene cancer risk will
be reduced on average by 43% across
the U.S. Nationwide, the mobile source
contribution to the respiratory hazard
index will be reduced by 23%. In
addition, the hydrocarbon reductions
from the vehicle and gas can standards
will reduce VOC emissions (which are
precursors to ozone and PM2.5) by over
1.1 million tons in 2030. The vehicle
standards will reduce direct PM2.5
emissions by over 19,000 tons in 2030
and will also reduce secondary
formation of PM2.5. Although ozone and
PM2.5 are considered criteria pollutants
rather than ‘‘air toxics,’’ reductions in
ozone and PM2.5 are nevertheless
important co-benefits of this proposal.
Section I.B.2 of this preamble
provides more discussion of the public
health and environmental impacts of
mobile source air toxics, ozone, and PM.
Details on health effects, emissions,
exposure, and cancer risks are also
located in Chapters 1–3 of the
Regulatory Impact Analysis (RIA) for
this rule.
We estimate that the benefits of this
rule will be about $6 billion in 2030,
based on the direct PM2.5 reductions
from the vehicle standards, plus
unquantified benefits from reductions in
mobile source air toxics and VOC. We
estimate that the annual net social costs
of this rule will be about $400 million
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in 2030 (expressed in 2003 dollars).
These net social costs include the value
of fuel savings from the proposed gas
can standards, which will be worth
about $92 million in 2030.
The rule will have an average cost of
0.27 cents per gallon of gasoline, less
than $1 per vehicle, and less than $2 per
gas can. The reduced evaporation from
gas cans will result in fuel savings that
will more than offset the increased cost
for the gas can. In 2030, the long-term
cost per ton of the standards (in
combination, and including fuel
savings) will be $1,100 per ton of total
mobile source air toxics reduced; $5,900
per ton of benzene reduced; and no cost
for the hydrocarbon and PM reductions
(because we expect the vehicle
standards will have no cost in 2020 and
beyond). Section VIII of the preamble
and Chapters 8–13 of the RIA provide
more details on the costs, benefits, and
economic impacts of the standards. The
impacts on small entities and the
flexibilities we are finalizing are
discussed in section X of this preamble
and Chapter 14 of the RIA.
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II. Overview of Final Rule
A. Light-Duty Vehicle Emission
Standards
As described in more detail in section
V, we are adopting new standards for
both exhaust and evaporative emissions
from passenger vehicles. The new
exhaust emissions standards will
significantly reduce non-methane
hydrocarbon (NMHC) emissions from
passenger vehicles at cold temperatures.
These hydrocarbons include many
mobile source air toxics (including
benzene), as well as VOC.
As we discussed in the proposal,
current vehicle emission standards are
based on testing of NMHC that is
generally performed at 75 °F. Recent
research and analysis indicates that
these standards are not resulting in
robust control of NMHC at lower
temperatures. We believe that cold
temperature NMHC control can be
substantially improved using the same
technological approaches that are
generally already being used in the Tier
2 vehicle fleet to meet the stringent
standards at 75 °F. These coldtemperature NMHC controls will also
result in lower direct PM emissions at
cold temperatures.
Accordingly, consistent with the
proposal, we are adopting a new NMHC
exhaust emissions standard at 20 °F for
light-duty vehicles, light-duty trucks,
and medium-duty passenger vehicles.
Vehicles at or below 6,000 pounds gross
vehicle weight rating (GVWR) will be
subject to a sales-weighted fleet average
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NMHC level of 0.3 grams/mile. Vehicles
between 6,000 and 8,500 pounds GVWR
and medium-duty passenger vehicles
will be subject to a sales-weighted fleet
average NMHC level of 0.5 grams/mile.
For lighter vehicles, the standard will
phase in between 2010 and 2013. For
heavier vehicles, the new standards will
phase in between 2012 and 2015. The
standards include a credit program and
other provisions designed to provide
flexibility to manufacturers, especially
during the phase-in periods. These
provisions are designed to allow the
earliest possible phase-in of standards
and help minimize costs and ease the
transition to new standards. These
standards in combination are expected
to lead to emissions control over a wide
range of in-use temperatures, and not
just at 20 °F and 75 °F.
We are also establishing, as proposed,
a set of nominally more stringent
evaporative emission standards for all
light-duty vehicles, light-duty trucks,
and medium-duty passenger vehicles.
The standards are equivalent to
California’s Low Emission Vehicle II
(LEV II) standards, and they reflect the
evaporative emissions levels that are
already being achieved nationwide. The
standards codify the approach that most
manufacturers are already taking for 50state evaporative systems, and thus
prevent backsliding in the future. The
evaporative emission standards will
take effect in 2009 for lighter vehicles
and in 2010 for the heavier vehicles.
Section V of this preamble provides
details on the exhaust and evaporative
vehicle standards.
B. Gasoline Fuel Standards
As we proposed, we are limiting the
benzene content of all gasoline, both
reformulated and conventional.
Beginning January 1, 2011, refiners must
meet a refinery average gasoline
benzene content standard of 0.62% by
volume on all their gasoline. The
program is described in more detail in
section VI of this preamble. The
standard does not apply to gasoline
produced and/or sold for use in
California because such gasoline is
already covered under California’s
Phase 3 Reformulated Gasoline
(Ca3RFG) program.
The benzene content standard, in
combination with the existing gasoline
sulfur standard, will result in air toxics
emissions reductions that are greater
than required under all existing gasoline
toxics programs. As a result, upon full
implementation in 2011, the regulatory
provisions for the benzene control
program will become the regulatory
mechanism used to implement the
reformulated gasoline (RFG) and Anti-
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dumping annual average toxics
performance and benzene content
requirements. The current RFG and
Anti-dumping annual average
provisions thus will be replaced by this
benzene control program. This benzene
control program will also replace the
requirements of the 2001 MSAT rule
(‘‘MSAT1’’). In addition, the program
will satisfy certain fuel MSAT
conditions of the Energy Policy Act of
2005 and obviate the need to revise
toxics baselines for reformulated
gasoline otherwise required by that Act.
In all of these ways, the existing
national fuel-related MSAT regulatory
program will be significantly
consolidated and simplified.
We are finalizing a nationwide ABT
program that allows refiners and
importers to choose the most
economical compliance strategy
(investment in technology, credits, or
both) for meeting the 0.62 vol% annual
average standard. From 2007–2010,
refiners can generate ‘‘early credits’’ by
making qualifying benzene reductions
earlier than required. Beginning in 2011
and continuing indefinitely, refiners
and importers can generate ‘‘standard
credits’’ by producing/importing
gasoline with benzene levels below 0.62
volume percent (vol%) on an annual
average basis. Credits may be used
interchangeably towards company
compliance with the 0.62 vol%
standard, ‘‘banked’’ for future use, and/
or transferred nationwide to other
refiners/importers subject to the
standard. In addition to the 0.62 vol%
standard, refiners and importers must
also meet a 1.3 vol% maximum average
benzene standard beginning July 1,
2012. To comply with the maximum
average standard, gasoline produced by
a refinery or imported by an importer
may not exceed 1.3 vol% benzene on an
annual average basis.
The ABT program allows us to set a
numerically more stringent benzene
standard than would otherwise be
achievable (within the meaning of Clean
Air Act section 202(l)(2)). The ABT
program also allows implementation to
occur earlier. Under this benzene
content standard and ABT program,
gasoline in all areas of the country will
have lower benzene levels than they
have today. Overall benzene levels will
be 38% lower. This will reduce benzene
emissions and exposure nationwide.
The program includes special
provisions for refiners facing hardship.
Refiners approved as ‘‘small refiners’’
are eligible for certain temporary relief
provisions. In addition, any refiner
facing extreme unforeseen
circumstances or extreme hardship
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circumstances can apply for similar
temporary relief.
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C. Portable Fuel Container (PFC)
Controls
Portable fuel containers, such as gas
cans and diesel and kerosene
containers, are consumer products used
to refuel a wide variety of equipment,
including lawn and garden equipment,
recreational equipment, and passenger
vehicles that have run out of gas. As
described in section VII, we are
adopting standards for these containers
that would reduce hydrocarbon
emissions from evaporation,
permeation, and spillage. The program
we are finalizing is consistent with the
proposal, except that instead of
applying only to gasoline containers, it
will also apply to diesel and kerosene
containers. These standards will
significantly reduce emissions of
benzene and other gaseous toxics, as
well as VOC. VOC is an ozone
precursor, and certain aromatic species
are believed to contribute to secondary
organic PM 2.5.
We are finalizing a performance-based
standard of 0.3 grams per gallon per day
of hydrocarbons, determined based on
the emissions from the can over a
diurnal test cycle specified in the rule.
The standard applies to containers
manufactured on or after January 1,
2009. We are also establishing test
procedures and a certification and
compliance program, in order to ensure
that containers meet the emission
standard over a range of in-use
conditions. The standards are based on
the performance of best available
control technologies, such as durable
permeation barriers, automatically
closing spouts, and cans that are wellsealed, and the standards will result in
the use of these control technologies.
California implemented an emissions
control program for gas cans in 2001,
and since then, several other states have
adopted the program. Last year,
California adopted a revised program,
which will take effect July 1, 2007. The
revised California program is very
similar to the program we are finalizing.
Although a few aspects of the programs
are different, we believe manufacturers
will be able to meet both EPA and
California requirements with the same
container designs, resulting in
equivalent emission reductions.
III. Why Is EPA Taking This Action?
People experience elevated risk of
cancer and other noncancer health
effects from exposure to air toxics.
Mobile sources are responsible for a
significant portion of this risk. For
example, benzene is the most significant
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contributor to cancer risk from all
outdoor air toxics 1, and most of the
nation’s benzene emissions come from
mobile sources. These risks vary
depending on where people live and
work and the kinds of activities in
which they engage. People who live or
work near major roads, people that
spend a large amount of time in vehicles
or work with motorized equipment, and
people living in homes with attached
garages are likely to have higher
exposures and higher risks. Although
we expect significant reductions in
mobile source air toxics in the future,
predicted cancer and noncancer health
risks are likely to remain a public health
concern. Benzene will likely remain the
largest contributor to this risk. In
addition, some mobile source air toxics
contribute to the formation of ozone and
PM 2.5, which contribute to serious
public health problems. Section III.B of
this preamble discusses the risks posed
by outdoor toxics now and in the future.
Sections III.C and III.D discuss the
health and welfare effects of ozone and
PM, respectively. The controls in this
rule will significantly reduce exposure
to emissions of mobile source air toxics
(and reduce exposure to ozone and
PM 2.5 as well), thus reducing these
public health concerns.
A. Statutory Requirements
1. Clean Air Act Section 202(l)
Section 202(l)(2) of the Clean Air Act
requires EPA to set standards to control
hazardous air pollutants (‘‘air toxics’’)
from motor vehicles 2, motor vehicle
fuels, or both. These standards must
reflect the greatest degree of emission
reduction achievable through the
application of technology which will be
available, taking into consideration the
motor vehicle standards established
under section 202(a) of the Act, the
availability and cost of the technology,
and noise, energy and safety factors, and
lead time. The standards are to be set
under Clean Air Act sections 202(a)(1)
or 211(c)(1), and they are to apply, at a
minimum, to benzene and
formaldehyde emissions.
Section 202(a)(1) of the Clean Air Act
directs EPA to set standards for new
motor vehicles or new motor vehicle
engines which EPA judges to cause or
contribute to air pollution which may
reasonably be anticipated to endanger
public health or welfare. We are issuing
1 Based on quantitative estimates of risk, which
do not include risks associated with diesel
particulate matter and diesel exhaust organic gases.
2 ‘‘Motor vehicles’’ is a term of art, defined in
Clean Air Act section 216(2) as ‘‘any self-propelled
vehicle designed for transporting persons or
property on a street or highway.’’
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the vehicle emissions standards under
this authority in conjunction with
section 202(l)(2).
Section 211(c)(1)(A) of the Clean Air
Act authorizes EPA (among other
things) to control the manufacture of
fuel if any emission product of such fuel
causes or contributes to air pollution
which may reasonably be anticipated to
endanger public health or welfare. We
are issuing the benzene standard for
gasoline under this authority in
conjunction with section 202(l)(2).
Clean Air Act section 202(l)(2) also
requires EPA to revise its regulations
controlling hazardous air pollutants
from motor vehicles and fuels, ‘‘from
time to time.’’ EPA’s first rule under
Clean Air Act section 202(l) was
published on March 29, 2001, entitled,
‘‘Control of Emissions of Hazardous Air
Pollutants from Mobile Sources’’ (66 FR
17230). That rule committed to
additional rulemaking that would
evaluate the need for and feasibility of
additional controls. Today’s final rule
fulfills that commitment.
2. Clean Air Act Section 183(e)
Clean Air Act section 183(e)(3)
requires EPA to list categories of
consumer or commercial products that
the Administrator determines, based on
an EPA study of VOC emissions from
such products, contribute at least 80
percent of the VOC emissions from such
products in areas violating the national
ambient air quality standard for ozone.
EPA promulgated this list at 60 FR
15264 (March 23, 1995), but it did not
consider or list portable fuel containers.
After analyzing these containers’
emissions inventory impacts, we
recently published a Federal Register
notice that added portable fuel
containers to the list of consumer
products to be regulated.3 EPA is
required to develop rules reflecting
‘‘best available controls’’ to reduce VOC
emissions from the listed products.
‘‘Best available controls’’ are defined in
section 183(e)(1)(A) as follows:
The term ‘‘best available controls’’ means
the degree of emissions reduction that the
Administrator determines, on the basis of
technological and economic feasibility,
health, environmental, and energy impacts, is
achievable through the application of the
most effective equipment, measures,
processes, methods, systems, or techniques,
including chemical reformulation, product or
feedstock substitution, repackaging, and
directions for use, consumption, storage, or
disposal.
Section 183(e)(4) also allows these
standards to be implemented by means
3 71 FR 28320, May 16, 2006, ‘‘Consumer and
Commercial Products: Schedule for Regulation’’.
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of ‘‘any system or systems of regulation
as the Administrator may deem
appropriate, including requirements for
registration and labeling, selfmonitoring and reporting * * *
concerning the manufacture, processing,
distribution, use, consumption, or
disposal of the product.’’ We are issuing
a hydrocarbon standard for portable fuel
containers under the authority of
section 183(e).
3. Energy Policy Act
Section 1504(b) of the Energy Policy
Act of 2005 requires EPA to adjust the
toxics emissions baselines for
individual refineries for reformulated
gasoline to reflect 2001–2002 fuel
qualities. However, the Act provides
that this action becomes unnecessary if
EPA takes action which results in
greater overall reductions of toxics
emissions from vehicles in areas with
reformulated gasoline. As described in
section VI of this preamble, we believe
the benzene content standard we are
finalizing today will in fact result in
greater overall reductions than would be
achieved by adjusting the individual
baselines under the Energy Policy Act.
Accordingly, under the provisions of the
Energy Policy Act, this rule obviates the
need for readjusting emissions baselines
for reformulated gasoline.
B. Public Health Impacts of Mobile
Source Air Toxics (MSATs)
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1. What Are MSATs?
Section 202(l) refers to ‘‘hazardous air
pollutants from motor vehicles and
motor vehicle fuels.’’ We use the term
‘‘mobile source air toxics (MSATs)’’ to
refer to compounds that are emitted by
mobile sources and have the potential
for serious adverse health effects. Some
MSATs are known or suspected to cause
cancer. Some of these pollutants are also
known to have adverse health effects on
people’s respiratory, cardiovascular,
neurological, immune, reproductive, or
other organ systems, and they may also
have developmental effects. Some may
pose particular hazards to more
susceptible and sensitive populations,
such as pregnant women, children, the
elderly, or people with pre-existing
illnesses.
Some MSATs of particular concern
include benzene, 1,3-butadiene,
formaldehyde, acrolein, naphthalene,
polycyclic organic matter, and diesel
particulate matter and diesel exhaust
organic gases. These are compounds
that EPA’s National-Scale Air Toxics
Assessment (NATA) for 1999 4 identifies
as the most significant contributors to
4 https://www.epa.gov/ttn/atw/nata1999/.
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cancer and noncancer health risk from
breathing outdoor air toxics, and that
have a significant contribution from
mobile sources. Our understanding of
what compounds pose the greatest risk
will evolve over time, based on our
understanding of the ambient levels and
health effects associated with the
compounds.
EPA has compiled a Master List of
Compounds Emitted by Mobile Sources,
based on an extensive review of the
literature on exhaust and evaporative
emissions from onroad and nonroad
equipment. The list currently includes
approximately 1,000 compounds, and it
is available in the public docket for this
rule and on the Web (https://
www.epa.gov/otaq/toxics.htm). Chapter
1 of the RIA provides a detailed
discussion of information sources for
identifying those compounds that have
the potential for serious adverse health
effects (i.e., could be considered
‘‘MSATs’’). This discussion includes a
list of those compounds that are emitted
by mobile sources and listed in EPA’s
Integrated Risk Information System
(IRIS).
MSATs are emitted by motor vehicles,
nonroad engines (such as lawn and
garden equipment, farming and
construction equipment, locomotives,
and ships), aircraft, and their fuels.
MSATs are emitted as a result of various
processes. Some MSATs are present in
fuel or fuel additives and are emitted to
the air when the fuel evaporates or
passes through the engine. Some
MSATs are formed through engine
combustion processes. Some
compounds, like formaldehyde and
acetaldehyde, are also formed through a
secondary process when other mobile
source pollutants undergo chemical
reactions in the atmosphere. Finally,
some air toxics, such as metals, result
from engine wear or from impurities in
oil or fuel.
There are other sources of air toxics,
including stationary sources, such as
power plants, factories, oil refineries,
dry cleaners, gas stations, and small
manufacturers. They can also be
produced by combustion of wood and
other organic materials. There are also
indoor sources of air toxics, such as
solvent evaporation and outgassing from
furniture and building materials.
2. Health Risk Associated With MSATs
EPA’s National-Scale Air Toxics
Assessment (NATA) for 1999 provides
some perspective on the average risk of
cancer and noncancer health effects
associated with breathing air toxics from
outdoor sources, and the contribution of
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8433
mobile sources to these risks.5, 6 NATA
assessed 177 pollutants. It is worth
noting that NATA does not include
indoor sources of air toxics. Also, it
assumes uniform outdoor
concentrations within a census tract,
and therefore does not reflect elevated
concentrations and exposures near
roadways or other sources within a
census tract. Additional limitations and
uncertainties associated with NATA are
discussed in Section 3.2.1.3 of the RIA.
Nevertheless, its findings are useful in
providing a perspective on the
magnitude of risks posed by outdoor
sources of air toxics generally, and in
identifying what pollutants and sources
are important contributors to these
health risks. Some of NATA’s findings
are discussed in the paragraphs below.
For this rule, EPA also performed a
national-scale assessment for 1999 and
future years using the same modeling
tools and approach as the 1999 NATA,
but with updated emissions inventories
and an updated exposure model. The
exposure model accounts for higher
toxics concentrations near roads. This
updated national-scale analysis
examined only those toxics that are
emitted by mobile sources (i.e., a subset
of the 177 pollutants included in
NATA). However, the analysis includes
all sources of those pollutants,
including mobile, stationary, and area
sources. The analysis is discussed in
detail in Chapter 3 of the RIA, and some
highlights of the findings are discussed
immediately below.
In addition to national-scale analysis,
we have also evaluated more refined
local-scale modeling, measured ambient
concentrations, personal exposure
measurements, and other data. This
information is discussed in detail in
Chapter 3 of the RIA. These data
collectively show that while levels of air
toxics are decreasing, potential public
health risks remain a concern, and
ambient levels and personal exposure
vary significantly. These data indicate
that concentrations of benzene and
other air toxics can be higher near hightraffic roads, inside vehicles, and in
homes with attached garages.
a. National Cancer Risk
According to NATA, the average
national cancer risk in 1999 from all
outdoor sources of air toxics was
estimated to be 42 in a million. That is,
42 out of one million people would be
5 https://www.epa.gov/ttn/atw/nata1999/.
6 NATA does not include a quantitative estimate
of cancer risk for diesel particulate matter and
diesel exhaust organic gases. EPA has concluded
that while diesel exhaust is likely to be a human
carcinogen, available data are not sufficient to
develop a confident estimate of cancer unit risk.
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
expected to contract cancer from a
lifetime of breathing air toxics at 1999
levels. Mobile sources were responsible
for 44% of outdoor toxic emissions and
almost 50% of the cancer risk. Benzene
is the largest contributor to cancer risk
of all 133 pollutants quantitatively
assessed in the 1999 NATA, and mobile
sources are the single largest source of
ambient benzene.
According to the national-scale
analysis performed for this rule, the
national average cancer risk in 1999
from breathing outdoor sources of
MSATs was about 25 in a million.7 Over
224 million people in 1999 were
exposed to a risk level above 10 in a
million due to chronic inhalation
exposure to MSATs. About 130 million
people in 1999 were exposed to a risk
level above 10 in a million due to
chronic inhalation exposure to benzene
alone. Mobile sources were responsible
for over 70% of benzene emissions in
1999.
Although air toxics emissions are
projected to decline in the future as a
result of standards EPA has previously
adopted, cancer risk will continue to be
a public health concern. Without
additional controls, the predicted
national average cancer risk from
MSATs in 2030 is predicted to be above
20 in a million. In fact, in 2030 there
will be more people exposed to levels of
MSATs that result in the highest levels
of risk. For instance, the number of
Americans above the 10 in a million
cancer risk level from exposure to
MSATs is projected to increase from 223
million in 1999 to 272 million in 2030.
Mobile sources will continue to be a
significant contributor to risk in the
future, accounting for 43% of total air
toxic emissions in 2020, and 55% of
benzene emissions.
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b. National Risk of Noncancer Health
Effects
According to national-scale modeling
for 1999 done for this rule, nearly the
entire U.S. population was exposed to
an average level of air toxics that has the
potential for adverse respiratory health
effects (noncancer).8 We estimated this
will continue to be the case in 2030,
even though toxics levels will be lower.
Mobile sources were responsible for
74% of the noncancer (respiratory) risk
from outdoor air toxics in the 1999
NATA. The majority of this risk was
from acrolein, and formaldehyde also
7 This includes emissions from mobile and
stationary sources of these pollutants.
8 That is, the respiratory hazard index exceeded
1. See section III.B.3.a for more information.
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contributed to the risk of respiratory
health effects.9
Although not included in NATA’s
estimates of noncancer risk, PM from
gasoline and diesel mobile sources
contributes significantly to the health
effects associated with ambient PM, for
which EPA has established National
Ambient Air Quality Standards. There
are extensive human data showing a
wide spectrum of adverse health effects
associated with exposure to ambient
PM.10
c. Exposure Near Roads
A substantial number of modeling
assessment and air quality monitoring
studies show elevated concentrations of
multiple MSATs in close proximity to
major roads. Exposure studies also
indicate that populations spending time
near major roadways likely experience
elevated personal exposures to motor
vehicle-related pollutants. In addition,
these populations may experience
exposures to differing physical and
chemical compositions of certain air
toxic pollutants depending on the
amount of time spent in close proximity
to motor vehicle emissions. Chapter 3.1
of the RIA provides a detailed
discussion of air quality monitoring,
personal exposure monitoring, and
modeling assessments near major
roadways.
As part of the analyses underlying the
final rule, we employed a new version
of the Hazardous Air Pollutant Exposure
Model (HAPEM), the exposure model
used in NATA. HAPEM6 explicitly
accounts for the gradient in outdoor
concentrations that occurs near major
roads, and the fraction of the population
living near major roads.11 The HAPEM6
analysis highlights the fact that
residence near a major road is a
substantial contributor to overall
differences in exposure to directlyemitted MSATs. As an example, while
the average of within-tract median
annual census tract exposure
concentrations nationally is 1.4 µg/m3,
the average 90th percentile of within9 Acrolein was assigned an overall confidence
level of ‘‘lower’’ based on consideration of the
combined uncertainties from the modeling
estimates. In contrast, formaldehyde was assigned
an overall confidence level of ‘‘medium.’’
10 U.S. Environmental Protection Agency (2004)
Air Quality Criteria for Particulate Matter. Research
Triangle Park, NC: National Center for
Environmental Assessment—RTP Office; Report No.
EPA/600/P–99/002aF, p. 8–318.
11 U.S. EPA. 2007. The HAPEM6 User’s Guide.
Prepared for Ted Palma, Office of Air Quality
Planning and Standards, Research Triangle Park,
NC, by Arlene Rosenbaum and Michael Huang, ICF
International, January 2007. This document is
available in Docket EPA–HQ–OAR–2005–0036.
https://www.epa.gov/ttn/fera/human_hapem.html.
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tract exposure concentration nationally
is over 2 µg/m3.
The potential population exposed to
elevated concentrations near major
roadways is large. A study of the
populations nationally indicated that
more than half of the population lives
within 200 meters of a major road.12 It
should be noted that this analysis relied
on the Census Bureau definition of a
major road, which is not based on traffic
volume. Thus, some of the roads
designated as ‘‘major’’ may carry a low
volume of traffic. This estimate is
consistent with other studies that have
examined the proximity of population
to major roads. These studies are
discussed in Section 3.5 of the RIA. In
addition, analysis of data from the
Census Bureau’s American Housing
Survey suggests that approximately 37
million people live within 300 feet
(∼100 meters) of a 4-or-more lane
highway, railroad, or airport.13
American Housing Survey statistics, as
well as epidemiology studies, indicate
that those houses located near major
transportation sources are more likely to
be lower in income or have minority
residents than houses not located near
major transportation sources. These data
are also discussed in detail in Section
3.5 of the RIA.
Other population studies also indicate
that a significant fraction of the
population resides in locations near
major roads. At present, the available
studies use different indicators of
‘‘major road’’ and of ‘‘proximity,’’ but
the estimates range from 12.4% of
student enrollment in California
attending schools within 150 meters of
roads with 25,000 vehicles per day or
more, to 13% of Massachusetts veterans
living within 50 meters of a road with
at least 10,000 vehicles per day.14, 15
Using a more general definition of a
‘‘major road,’’ between 22% and 51% of
different study populations live near
such roads.
d. Exposure From Attached Garages
People living in homes with attached
garages are potentially exposed to
substantially higher overall
12 Major roads are defined as those roads defined
by the U.S. Census as one of the following: ‘‘limited
access highway,’’ ‘‘highway,’’ ‘‘major road (primary,
secondary and connecting roads ),’’ or ‘‘ramp.’’
13 United States Census Bureau. (2004) American
Housing Survey web page. [Online at https://
www.census.gov/hhes/www/housing/ahs/ahs03/
ahs03.html ] Table IA–6.
14 Green, R.S.; Smorodinsky, S.; Kim, J.J.;
McLaughlin, R.; Ostro, B. (2004) Proximity of
California public schools to busy roads. Environ.
Health Perspect. 112: 61–66.
15 Garshick, E.; Laden, F.; Hart, J.E.; Caron, A.
(2003) Residence near a major road and respiratory
symptoms in U.S. veterans. Epidemiol. 14: 728–736.
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concentrations of benzene, toluene, and
other VOCs from mobile source-related
emissions. EPA has conducted a
modeling analysis to examine the
influence of attached garages on
personal exposure to benzene (see
Appendix 3A of RIA). Compared to
national average exposure
concentrations modeled in 1999 NATA,
which does not account for emissions
originating in attached garages, average
exposure concentrations for people with
attached garages could more than
double. Other recent studies also
emphasize the substantial role of
attached garages in exposure to MSATs.
Chapter 3 of the RIA discusses
measurements of concentrations and
exposure associated with attached
garages and EPA’s modeling analysis.
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3. What Are the Health Effects of Air
Toxics?
a. Overview of Potential Cancer and
Noncancer Health Effects
Air toxics can cause of variety of
cancer and noncancer health effects.
Inhalation cancer risks are usually
estimated by EPA as ‘‘unit risks,’’ which
represent the excess lifetime cancer risk
estimated to result from continuous
exposure to an agent at a concentration
of 1 mu g/m3 in air. Some air toxics are
known to be carcinogenic in animals but
lack data in humans. Many of these
have been assumed to be human
carcinogens. Also, in the absence of
evidence of a nonlinear dose-response
curve, EPA assumes these relationships
between exposure and probability of
cancer are linear. These unit risks are
typically upper bound estimates. Upper
bound estimates are more likely to
overestimate than underestimate risk.
Where there are strong epidemiological
data, a maximum likelihood estimate
(MLE) may be developed. An MLE is a
best scientific estimate of risk. The
benzene unit risk is an MLE. A
discussion of the confidence in a
quantitative cancer risk estimate is
provided in the IRIS file for each
compound. The discussion of the
confidence in the cancer risk estimate
includes an assessment of the source of
the data (human or animal),
uncertainties in dose estimates, choice
of the model used to fit the exposure
and response data and how
uncertainties and potential confounders
are handled.
Potential noncancer chronic
inhalation health risks are quantified
using reference concentrations (RfCs)
and noncancer chronic ingestion and
dermal health risks are quantified using
reference doses (RfDs). The RfC is an
estimate (with uncertainty spanning
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perhaps an order of magnitude) of a
daily exposure to the human population
(including sensitive subgroups) that is
likely to be without appreciable risk of
deleterious effects during a lifetime.
Sources of uncertainty in the
development of the RfCs and RfDs
include interspecies extrapolation
(animal to human) and intraspecies
extrapolation (average human to
sensitive human). Additional sources of
uncertainty can include the use of a
lowest observed adverse effect level in
place of a no observed adverse effect
level, and other data deficiencies. A
statement regarding the confidence in
the RfC and/or RfD is developed to
reflect the confidence in the principal
study or studies on which the RfC or
RfD are based and the confidence in the
underlying database. Factors that affect
the confidence in the principal study
include how well the study was
designed, conducted and reported.
Factors that affect the confidence in the
database include an assessment of the
availability of information regarding
identification of the critical effect,
potentially susceptible populations and
exposure scenarios relevant to
assessment of risk.
The RfC may be used to estimate a
hazard quotient, which is the
environmental exposure to a substance
divided by its RfC. A hazard quotient
greater than one indicates adverse
health effects are possible. The hazard
quotient cannot be translated to a
probability that adverse health effects
will occur, and is unlikely to be
proportional to risk. It is especially
important to note that a hazard quotient
exceeding one does not necessarily
mean that adverse health effects will
occur. In NATA, hazard quotients for
different respiratory irritants were also
combined into a hazard index (HI). A
hazard index is the sum of hazard
quotients for substances that affect the
same target organ or organ system.
Because different pollutants may cause
similar adverse health effects, it is often
appropriate to combine hazard quotients
associated with different substances.
However, the HI is only an
approximation of a combined effect
because substances may affect a target
organ in different ways.
b. Health Effects of Key MSATs
i. Benzene
The EPA’s IRIS database lists
benzene, an aromatic hydrocarbon, as a
known human carcinogen (causing
leukemia) by all routes of exposure.16 A
16 U.S. EPA (2000). Integrated Risk Information
System File for Benzene. This material is available
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8435
number of adverse noncancer health
effects including blood disorders and
immunotoxicity have also been
associated with long-term occupational
exposure to benzene.17
Inhalation is the major source of
human exposure to benzene in
occupational and non-occupational
settings. Long-term occupational
inhalation exposure to benzene has been
shown to cause cancers of the
hematopoetic (blood cell) system in
adults.18 Among these are acute
nonlymphocytic leukemia 19 and
chronic lymphocytic leukemia.20, 21
Leukemias, lymphomas, and other
tumor types have been observed in
experimental animals exposed to
benzene by inhalation or oral
administration. Exposure to benzene
and/or its metabolites has also been
linked with chromosomal changes in
electronically at https://www.epa.gov/iris/subst/
0276.htm.
17 U.S. EPA (2002). Toxicological Review of
Benzene (Noncancer Effects). National Center for
Environmental Assessment, Washington, DC.
Report No. EPA/635/R–02/001F. https://
www.epa.gov/iris/toxreviews/0276-tr.pdf.
18 U.S. EPA (1998) Carcinogenic Effects of
Benzene: An Update, National Center for
Environmental Assessment, Washington, DC.
EPA600-P–97–001F. Enter report number at the
following search page, https://yosemite.epa.gov/
ncepihom/nsCatalog.nsf//SearchPubs?Openform.
19 Leukemia is a blood disease in which the white
blood cells are abnormal in type or number.
Leukemia may be divided into nonlymphocytic
(granulocytic) leukemias and lymphocytic
leukemias. Nonlymphocytic leukemia generally
involves the types of white blood cells (leukocytes)
that are involved in engulfing, killing, and digesting
bacteria and other parasites (phagocytosis) as well
as releasing chemicals involved in allergic and
immune responses. This type of leukemia may also
involve erythroblastic cell types (immature red
blood cells). Lymphocytic leukemia involves the
lymphocyte type of white blood cell that is
responsible for antibody and cell-mediated immune
responses. Both nonlymphocytic and lymphocytic
leukemia may, in turn, be separated into acute
(rapid and fatal) and chronic (lingering, lasting)
forms. For example in acute myeloid leukemia there
is diminished production of normal red blood cells
(erythrocytes), granulocytes, and platelets (control
clotting), which leads to death by anemia, infection,
or hemorrhage. These events can be rapid. In
chronic myeloid leukemia (CML) the leukemic cells
retain the ability to differentiate (i.e., be responsive
to stimulatory factors) and perform function; later
there is a loss of the ability to respond.
20 U.S. EPA (1985) Environmental Protection
Agency, Interim quantitative cancer unit risk
estimates due to inhalation of benzene, prepared by
the Office of Health and Environmental
Assessment, Carcinogen Assessment Group,
Washington, DC for the Office of Air Quality
Planning and Standards, Washington, DC, 1985.
21 U.S. EPA (1993) Motor Vehicle-Related Air
Toxics Study. Office of Mobile Sources, Ann Arbor,
MI. https://www.epa.gov/otaq/regs/toxics/
tox_archive.htm.
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humans and animals22, 23 and increased
proliferation of mouse bone marrow
cells.24, 25
The latest assessment by EPA
estimates the excess risk of developing
leukemia from inhalation exposure to
benzene at 2.2 × 10¥6 to 7.8 × 10¥6 per
µg/m3. In other words, there is an
estimated risk of about two to eight
excess leukemia cases in one million
people exposed to 1 µg/m3 of benzene
over a lifetime.26 This range of unit risks
reflects the MLEs calculated from
different exposure assumptions and
dose-response models that are linear at
low doses. At present, the true cancer
risk from exposure to benzene cannot be
ascertained, even though dose-response
data are used in the quantitative cancer
risk analysis, because of uncertainties in
the low-dose exposure scenarios and
lack of clear understanding of the mode
of action. A range of estimates of risk is
recommended, each having equal
scientific plausibility. There are
confidence intervals associated with the
MLE range that reflect variation of the
observed data used to develop doseresponse values. For the upper end of
the MLE range, the 5th and 95th
percentile values are about a factor of 5
lower and higher than the best fit value.
The upper end of the MLE range was
used in NATA.
It should be noted that not enough
information is known to determine the
slope of the dose-response curve at
22 International Agency for Research on Cancer
(IARC) (1982) IARC monographs on the evaluation
of carcinogenic risk of chemicals to humans,
Volume 29, Some industrial chemicals and
dyestuffs, International Agency for Research on
Cancer, World Health Organization, Lyon, France,
p. 345–389.
23 U.S. EPA (1998) Carcinogenic Effects of
Benzene: An Update, National Center for
Environmental Assessment, Washington, DC.
EPA600-P–97–001F. Enter report number at the
following search page, https://yosemite.epa.gov/
ncepihom/nsCatalog.nsf//SearchPubs?Openform.
24 Irons, R.D., W.S. Stillman, D.B. Colagiovanni,
and V.A. Henry (1992) Synergistic action of the
benzene metabolite hydroquinone on myelopoietic
stimulating activity of granulocyte/macrophage
colony-stimulating factor in vitro, Proc. Natl. Acad.
Sci. 89:3691–3695.
25 U.S. EPA (1998) Carcinogenic Effects of
Benzene: An Update, National Center for
Environmental Assessment, Washington, DC.
EPA600-P–97–001F. Enter report number at the
following search page, https://yosemite.epa.gov/
ncepihom/nsCatalog.nsf//SearchPubs?Openform.
26 U.S. EPA (1998) Carcinogenic Effects of
Benzene: An Update, National Center for
Environmental Assessment, Washington, DC.
EPA600-P–97–001F. Enter report number at the
following search page, https://yosemite.epa.gov/
ncepihom/nsCatalog.nsf//SearchPubs?Openform.
27 U.S. EPA (2005) Guidelines for Carcinogen Risk
Assessment. Report No. EPA/630/P–03/001F.
https://cfpub.epa.gov/ncea/raf/
recordisplay.cfm?deid=116283.
28 U.S. EPA (1998) Carcinogenic Effects of
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environmental levels of exposure and to
provide a sound scientific basis to
choose any particular extrapolation/
exposure model to estimate human
cancer risk at low doses. EPA risk
assessment guidelines suggest using an
assumption of linearity of dose response
when (1) there is an absence of
sufficient information on modes of
action or (2) the mode of action
information indicates that the doseresponse curve at low dose is or is
expected to be linear.27 Since the mode
of action for benzene carcinogenicity is
unknown, the current cancer unit risk
estimate assumes linearity of the lowdose response. Data that were
considered by EPA in its carcinogenic
update suggested that the dose-response
relationship at doses below those
examined in the studies reviewed in
EPA’s most recent benzene assessment
may be supralinear. Such a relationship
could support the inference that cancer
risks are as high or are higher than the
estimates provided in the existing EPA
assessment.28 Data discussed in the EPA
IRIS assessment suggest that genetic
abnormalities occur at low exposure in
humans, and the formation of toxic
metabolites plateaus above 25 ppm
(80,000 µ/m3).29 More recent data on
benzene adducts in humans, published
after the most recent IRIS assessment,
suggest that the enzymes involved in
benzene metabolism start to saturate at
exposure levels as low as 1 ppm.30, 31, 32
These data highlight the importance of
ambient exposure levels and their
contribution to benzene-related adducts.
Because there is a transition from linear
to saturable metabolism below 1 ppm,
the assumption of low-dose linearity
extrapolated from much higher
exposures could lead to substantial
27 U.S. EPA (2005) Guidelines for Carcinogen Risk
Assessment. Report No. EPA/630/P–03/001F.
https://cfpub.epa.gov/ncea/raf/
recordisplay.cfm?deid=116283.
28 U.S. EPA (1998) Carcinogenic Effects of
Benzene: An Update. EPA/600/P–97/001F.
29 Rothman, N; Li, GL; Dosemeci, M; et al. (1996)
Hematotoxicity among Chinese workers heavily
exposed to benzene. Am. J. Indust. Med. 29:236–
246.
30 Rappaport, S.M.; Waidyanatha, S.; Qu, Q.;
Shore, R.; Jin, X.; Cohen, B.; Chen, L.; Melikian, A.;
Li, G.; Yin, S.; Yan, H.; Xu, B.; Mu, R.; Li, Y.; Zhang,
X.; and Li, K. (2002) Albumin adducts of benzene
oxide and 1,4-benzoquinone as measures of human
benzene metabolism. Cancer Research 62:1330–
1337.
31 Rappaport, S.M.; Waidyanatha, S.; Qu, Q.;
Yeowell-O’Connell, K.; Rothman, N.; Smith M.T.;
Zhang, L.; Qu, Q.; Shore, R.; Li, G.; Yin, S. (2005)
Protein adducts as biomarkers of human enzene
metabolism. Chem Biol Interact. 153–154:103–109.
32 Lin, Y–S., Vermeulen, R., Tsai, C.H., Suramya,
W., Lan, Q., Rothman, N., Smith, M.T., Zhang, L.,
Shen, M., Songnian, Y., Kim, S., Rappaport, S.M.
(2006) Albumin adducts of electrophilic benzene
metabolites in benzene-exposed and control
workers. Environ Health Perspec.
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underestimation of leukemia risks. This
is consistent with recent
epidemiological data which also suggest
a supralinear exposure-response
relationship and which ‘‘[extend]
evidence for hematopoietic cancer risks
to levels substantially lower than had
previously been established.’’ 33, 34, 35
These data are from the largest cohort
studies done to date with individual
worker exposure estimates. However,
these data have not yet been formally
evaluated by EPA as part of the IRIS
review process, and it is not clear how
they might influence low-dose risk
estimates. A better understanding of the
biological mechanism of benzeneinduced leukemia is needed.
Children may represent a
subpopulation at increased risk from
benzene exposure, due to factors that
could increase their susceptibility.
Children may have a higher unit body
weight exposure because of their
heightened activity patterns which can
increase their exposures, as well as
different ventilation tidal volumes and
frequencies, factors that influence
uptake. This could entail a greater
lifetime risk of leukemia and other toxic
effects from exposures occurring during
childhood, if children are exposed to
benzene at similar levels as adults.
There is limited information from two
studies regarding an increased risk to
children whose parents have been
occupationally exposed to benzene.36, 37
Data from animal studies have shown
benzene exposures result in damage to
the hematopoietic (blood cell formation)
system during development.38, 39, 40
33 Hayes, R.B.; Yin, S.; Dosemeci, M.; Li, G.;
Wacholder, S.; Travis, L.B.; Li, C.; Rothman, N.;
Hoover, R.N.; and Linet, M.S. (1997) Benzene and
the dose-related incidence of hematologic
neoplasms in China. J. Nat. Cancer Inst. 89:1065–
1071.
34 Hayes, R.B.; Songnian, Y.; Dosemeci, M.; and
Linet, M. (2001) Benzene and lymphohematopoietic
malignancies in humans. Am. J. Indust. Med.
40:117–126.
35 Lan, Q.; Zhang, L., Li, G., Vermeulen, R., et al.
(2004). Hematotoxicity in Workers Exposed to Low
Levels of Benzene. Science 306: 1774–1776.
36 Shu, X.O.; Gao, Y.T.; Brinton, L.A.; et al. (1988)
A population-based case-control study of childhood
leukemia in Shanghai. Cancer 62:635–644.
37 McKinney P.A.; Alexander, F.E.; Cartwright,
R.A.; et al. (1991) Parental occupations of children
with leukemia in west Cumbria, north Humberside,
and Gateshead, Br. Med. J. 302:681–686.
38 Keller, KA; Snyder, CA. (1986) Mice exposed
in utero to low concentrations of benzene exhibit
enduring changes in their colony forming
hematopoietic cells. Toxicology 42:171–181.
39 Keller, KA; Snyder, CA. (1988) Mice exposed
in utero to 20 ppm benzene exhibit altered numbers
of recognizable hematopoietic cells up to seven
weeks after exposure. Fundam. Appl. Toxicol.
10:224–232.
40 Corti, M; Snyder, CA. (1996) Influences of
gender, development, pregnancy and ethanol
consumption on the hematotoxicity of inhaled 10
ppm benzene. Arch. Toxicol. 70:209–217.
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Also, key changes related to the
development of childhood leukemia
occur in the developing fetus.41 Several
studies have reported that genetic
changes related to eventual leukemia
development occur before birth. For
example, there is one study of genetic
changes in twins who developed T cell
leukemia at 9 years of age.42 An
association between traffic volume,
residential proximity to busy roads and
occurrence of childhood leukemia has
also been identified in some studies,
although some studies show no
association.
A number of adverse noncancer
health effects, including blood disorders
such as preleukemia and aplastic
anemia, have also been associated with
long-term exposure to benzene.43, 44
People with long-term occupational
exposure to benzene have experienced
harmful effects on the blood-forming
tissues, especially in the bone marrow.
These effects can disrupt normal blood
production and suppress the production
of important blood components, such as
red and white blood cells and blood
platelets, leading to anemia (a reduction
in the number of red blood cells),
leukopenia (a reduction in the number
of white blood cells), or
thrombocytopenia (a reduction in the
number of blood platelets, thus reducing
the ability of blood to clot). Chronic
inhalation exposure to benzene in
humans and animals results in
pancytopenia,45 a condition
characterized by decreased numbers of
circulating erythrocytes (red blood
cells), leukocytes (white blood cells),
41 U.S. EPA. (2002). Toxicological Review of
Benzene (Noncancer Effects). National Center for
Environmental Assessment, Washington, DC.
Report No. EPA/635/R–02/001F. https://
www.epa.gov/iris/toxreviews/0276-tr.pdf.
42 Ford, AM; Pombo-de-Oliveira, MS; McCarthy,
KP; MacLean, JM; Carrico, KC; Vincent, RF;
Greaves, M. (1997) Monoclonal origin of concordant
T-cell malignancy in identical twins. Blood 89:281–
285.
43 Aksoy, M. (1989) Hematotoxicity and
carcinogenicity of benzene. Environ. Health
Perspect. 82:193–197.
44 Goldstein, B.D. (1988) Benzene toxicity.
Occupational medicine. State of the Art Reviews 3:
541–554.
45 Pancytopenia is the reduction in the number of
all three major types of blood cells (erythrocytes, or
red blood cells, thrombocytes, or platelets, and
leukocytes, or white blood cells). In adults, all three
major types of blood cells are produced in the bone
marrow of the skeletal system. The bone marrow
contains immature cells, known as multipotent
myeloid stem cells, that later differentiate into the
various mature blood cells. Pancytopenia results
from a reduction in the ability of the red bone
marrow to produce adequate numbers of these
mature blood cells.
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and thrombocytes (blood platelets).46, 47
Individuals that develop pancytopenia
and have continued exposure to
benzene may develop aplastic anemia,
whereas others exhibit both
pancytopenia and bone marrow
hyperplasia (excessive cell formation), a
condition that may indicate a
preleukemic state.48, 49 The most
sensitive noncancer effect observed in
humans, based on current data, is the
depression of the absolute lymphocyte
count in blood.50, 51
EPA’s inhalation reference
concentration (RfC) for benzene is 30
µg/m3, based on suppressed absolute
lymphocyte counts as seen in humans
under occupational exposure
conditions. The overall confidence in
this RfC is medium. Since development
of this RfC, human reports of benzene’s
hematotoxic effects have been published
in the literature that provides data
suggesting a wide range of
hematological endpoints that are
affected at occupational exposures of
less than 5 ppm (about 16 mg/m3)52 and
at air levels of 1 ppm (about 3 mg/m3)
or less among genetically susceptible
populations.53 One recent study found
benzene metabolites in mouse liver and
bone marrow at environmental doses,
indicating that even concentrations in
urban air can elicit a biochemical
response in rodents that indicates
toxicity.54 EPA has not formally
46 Aksoy, M. (1991) Hematotoxicity,
leukemogenicity and carcinogenicity of chronic
exposure to benzene. In: Arinc, E.; Schenkman, J.B.;
Hodgson, E., Eds. Molecular Aspects of
Monooxygenases and Bioactivation of Toxic
Compounds. New York: Plenum Press, pp. 415–434.
47 Goldstein, B.D. (1988) Benzene toxicity.
Occupational medicine. State of the Art Reviews 3:
541–554.
48 Aksoy, M., S. Erdem, and G. Dincol. (1974)
Leukemia in shoe-workers exposed chronically to
benzene. Blood 44:837.
49 Aksoy, M. and K. Erdem. (1978) A follow-up
study on the mortality and the development of
leukemia in 44 pancytopenic patients associated
with long-term exposure to benzene. Blood 52: 285–
292.
50 Rothman, N., G.L. Li, M. Dosemeci, W.E.
Bechtold, G.E. Marti, Y.Z. Wang, M. Linet, L.Q. Xi,
W. Lu, M.T. Smith, N. Titenko-Holland, L.P. Zhang,
W. Blot, S.N. Yin, and R.B. Hayes (1996)
Hematotoxicity among Chinese workers heavily
exposed to benzene. Am. J. Ind. Med. 29: 236–246.
51 EPA 2005 ‘‘Full IRIS Summary for Benzene
(CASRN 71–43–2)’’ Environmental Protection
Agency, Integrated Risk Information System (IRIS),
Office of Health and Environmental Assessment,
Environmental Criteria and Assessment Office,
Cincinnati, OH, https://www.epa.gov/iris/subst/
0276.htm.
52 Qu, Q., R. Shore, G. Li, X. Jin, L.C. Chen, B.
Cohen, et al. (2002). Hematological changes among
Chinese workers with a broad range of benzene
exposures. Am. J. Industr. Med. 42: 275–285.
53 Lan, Q.; Zhang, L., Li, G., Vermeulen, R., et al.
(2004). Hematotoxicity in Workers Exposed to Low
Levels of Benzene. Science 306: 1774–1776.
54 Turtletaub, K.W. and Mani, C. (2003). Benzene
metabolism in rodents at doses relevant to human
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evaluated these recent studies as part of
the IRIS review process to determine
whether or not they will lead to a
change in the current RfC. EPA does not
currently have an acute reference
concentration for benzene. The Agency
for Toxic Substances and Disease
Registry Minimal Risk Level for acute
exposure to benzene is 160 µg/m3 for 1–
14 days exposure.
ii. 1,3-Butadiene
EPA has characterized 1,3-butadiene,
a hydrocarbon, as a leukemogen,
carcinogenic to humans by
inhalation.55 56 The specific mechanisms
of 1,3-butadiene-induced carcinogenesis
are unknown; however, it is virtually
certain that the carcinogenic effects are
mediated by genotoxic metabolites of
1,3-butadiene. Animal data suggest that
females may be more sensitive than
males for cancer effects; nevertheless,
there are insufficient data in humans
from which to draw any conclusions on
potentially sensitive subpopulations.
The upper bound cancer unit risk
estimate is 0.08 per ppm or 3 × 10 ¥5 per
µg/m3 (based primarily on linear
modeling and extrapolation of human
data). In other words, it is estimated that
approximately 30 persons in one
million exposed to 1 µg/m3 of 1,3butadiene continuously for their
lifetime would develop cancer as a
result of this exposure. The human
incremental lifetime unit cancer risk
estimate is based on extrapolation from
leukemias observed in an occupational
epidemiologic study.57 58 This estimate
includes a two-fold adjustment to the
epidemiologic-based unit cancer risk
applied to reflect evidence from the
rodent bioassays suggesting that the
epidemiologic-based estimate (from
males) may underestimate total cancer
exposure from Urban Air. Res Rep Health Effect Inst
113.
55 U.S. EPA. (2002). Health Assessment of 1,3Butadiene. Office of Research and Development,
National Center for Environmental Assessment,
Washington Office, Washington, DC. Report No.
EPA600–P–98–001F. https://cfpub.epa.gov/ncea/
cfm/recordisplay.cfm?deid=54499.
56 EPA 2005 ‘‘Full IRIS Summary for 1,3butadiene (CASRN 106–99–0)’’ Environmental
Protection Agency, Integrated Risk Information
System (IRIS), Office of Health and Environmental
Assessment, Environmental Criteria and
Assessment Office, Cincinnati, OH, https://
www.epa.gov/iris/subst/0139.htm.
57 Delzell, E, N. Sathiakumar, M. Macaluso, et al.
(1995). A follow-up study of synthetic rubber
workers. Submitted to the International Institute of
Synthetic Rubber Producers. University of Alabama
at Birmingham. October 2, 1995.
58 EPA 2005 ‘‘Full IRIS Summary for 1,3butadiene (CASRN 106–99–0)’’ Environmental
Protection Agency, Integrated Risk Information
System (IRIS), Office of Health and Environmental
Assessment, Environmental Criteria and
Assessment Office, Cincinnati, OH, https://
www.epa.gov/iris/subst/0139.htm.
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risk from 1,3-butadiene exposure in the
general population, particularly for
breast cancer in females. A recent study
extended the investigation of 1,3butadiene exposure and leukemia
among synthetic rubber industry
workers.59 The results of this study
strengthen the evidence for the
relationship between 1,3-butadiene
exposure and lymphohematopoietic
cancer. This relationship was found to
persist after controlling for exposure to
other toxics in this work environment.
1,3-Butadiene also causes a variety of
reproductive and developmental effects
in mice; no human data on these effects
are available. The most sensitive effect
was ovarian atrophy observed in a
lifetime bioassay of female mice.60
Based on this critical effect and the
benchmark concentration methodology,
an RfC was calculated. This RfC for
chronic health effects is 0.9 ppb, or
about 2 µg/m3. Confidence in the
inhalation RfC is medium.
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iii. Formaldehyde
Since 1987, EPA has classified
formaldehyde, a hydrocarbon, as a
probable human carcinogen based on
evidence in humans and in rats, mice,
hamsters, and monkeys.61 EPA’s current
IRIS summary provides an upper bound
cancer unit risk estimate of 1.3 × 10¥5
per µg/m3.62 In other words, there is an
estimated risk of about thirteen excess
leukemia cases in one million people
exposed to 1 µg/m3 of formaldehyde
over a lifetime.
EPA is currently reviewing recently
published epidemiological data. For
instance, research conducted by the
National Cancer Institute (NCI) found an
increased risk of nasopharyngeal cancer
and lymphohematopoietic malignancies
such as leukemia among workers
exposed to formaldehyde.63 64 NCI is
59 Delzell, E., Sathiakumar, N., Graff, J., Macaluso,
M., Maldonado, G., Matthews, R. (2006) An updated
study of mortality among North American synthetic
rubber industry workers. Health Effects Institute
Report Number 132.
60 Bevan, C.; Stadler, J.C.; Elliot, G.S.; et al. (1996)
Subchronic toxicity of 4-vinylcyclohexene in rats
and mice by inhalation. Fundam. Appl. Toxicol.
32:1–10.
61 U.S. EPA (1987). Assessment of Health Risks to
Garment Workers and Certain Home Residents
From Exposure to Formaldehyde, Office of
Pesticides and Toxic Substances, April 1987.
62 U.S. EPA (1989). Integrated Risk Information
System File for Formaldehyde. This material is
available electronically at https://www.epa.gov/iris/
subst/0419.htm.
63 Hauptmann, M.; Lubin, J. H.; Stewart, P. A.;
Hayes, R. B.; Blair, A. 2003. Mortality from
lymphohematopoietic malignancies among workers
in formaldehyde industries. Journal of the National
Cancer Institute 95: 1615–1623.
64 Hauptmann, M..; Lubin, J. H.; Stewart, P. A.;
Hayes, R. B.; Blair, A. 2004. Mortality from solid
cancers among workers in formaldehyde industries.
American Journal of Epidemiology 159: 1117–1130.
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currently performing an update of these
studies. A recent National Institute of
Occupational Safety and Health
(NIOSH) study of garment workers also
found increased risk of death due to
leukemia among workers exposed to
formaldehyde.65 Extended follow-up of
a cohort of British chemical workers did
not find evidence of an increase in
nasopharyngeal or
lymphohematopoeitic cancers, but a
continuing statistically significant
excess in lung cancers was reported.66
Based on the developments of the last
decade, in 2004, the working group of
the International Agency for Research
on Cancer concluded that formaldehyde
is carcinogenic to humans (Group 1
classification) on the basis of sufficient
evidence in humans and sufficient
evidence in experimental animals—a
higher classification than previous IARC
evaluations. In addition, the National
Institute of Environmental Health
Sciences recently nominated
formaldehyde for reconsideration as a
known human carcinogen under the
National Toxicology Program. Since
1981 it has been listed as a ‘‘reasonably
anticipated human carcinogen.’’
Recently the German Federal Institute
for Risk Assessment determined that
formaldehyde is a known human
carcinogen.67
In the past 15 years there has been
substantial research on the inhalation
dosimetry for formaldehyde in rodents
and primates by the CIIT Centers for
Health Research, with a focus on use of
rodent data for refinement of the
quantitative cancer dose-response
assessment.68 69 70 CIIT’s risk assessment
of formaldehyde incorporated
mechanistic and dosimetric information
65 Pinkerton, L. E. 2004. Mortality among a cohort
of garment workers exposed to formaldehyde: an
update. Occup. Environ. Med. 61: 193–200.
66 Coggon, D, EC Harris, J Poole, KT Palmer. 2003.
Extended follow-up of a cohort of British chemical
workers exposed to formaldehyde. J National
Cancer Inst. 95:1608–1615.
67 Bundesinstitut fur Risikobewertung (BfR)
¨
Toxicological Assessment of Formaldehyde.
Opinion of BfR No. 023/2006 of 30 March 2006.
www.bfr.bund.de/cm/290/
toxicological_assessment_of_formaldehyde.pdf.
68 Conolly, RB, JS Kimbell, D Janszen, PM
Schlosser, D Kalisak, J Preston, and FJ Miller. 2003.
Biologically motivated computational modeling of
formaldehyde carcinogenicity in the F344 rat. Tox.
Sci. 75: 432–447.
69 Conolly, RB, JS Kimbell, D Janszen, PM
Schlosser, D Kalisak, J Preston, and FJ Miller. 2004.
Human respiratory tract cancer risks of inhaled
formaldehyde: Dose-response predictions derived
from biologically-motivated computational
modeling of a combined rodent and human dataset.
Tox. Sci. 82: 279–296.
70 Chemical Industry Institute of Toxicology
(CIIT). 1999. Formaldehyde: Hazard
characterization and dose-response assessment for
carcinogenicity by the route of inhalation. CIIT,
September 28, 1999. Research Triangle Park, NC.
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on formaldehyde. The risk assessment
analyzed carcinogenic risk from inhaled
formaldehyde using approaches that
were consistent with EPA’s draft
guidelines for carcinogenic risk
assessment. In 2001, Environment
Canada relied on this cancer doseresponse assessment in their assessment
of formaldehyde.71 In 2004, EPA also
relied on this cancer unit risk estimate
during the development of the plywood
and composite wood products national
emissions standards for hazardous air
pollutants (NESHAPs).72 In these rules,
EPA concluded that the CIIT work
represented the best available
application of the available mechanistic
and dosimetric science on the doseresponse for portal of entry cancers due
to formaldehyde exposures. EPA is
reviewing the recent work cited above
from the NCI and NIOSH, as well as the
analysis by the CIIT Centers for Health
Research and other studies, as part of a
reassessment of the human hazard and
dose-response associated with
formaldehyde.
Noncancer effects of formaldehyde
have been observed in humans and
several animal species and include
irritation to eye, nose and throat tissues
in conjunction with increased mucous
secretions.
iv. Acetaldehyde
Acetaldehyde, a hydrocarbon, is
classified in EPA’s IRIS database as a
probable human carcinogen and is
considered toxic by inhalation.73 Based
on nasal tumors in rodents, the upper
confidence limit estimate of a lifetime
extra cancer risk from continuous
acetaldehyde exposure is about 2.2 ×
10¥6 per µg/m3. In other words, it is
estimated that about 2 persons in one
million exposed to 1 µg/m3
acetaldehyde continuously for their
lifetime (70 years) would develop
cancer as a result of their exposure,
although the risk could be as low as
zero. In short-term (4 week) rat studies,
compound-related histopathological
changes were observed only in the
respiratory system at various
concentration levels of exposure.74 75
71 Health Canada. 2001. Priority Substances List
Assessment Report. Formaldehyde. Environment
Canada, Health Canada, February 2001.
72 U.S. EPA. 2004. National Emission Standards
for Hazardous Air Pollutants for Plywood and
Composite Wood Products Manufacture: Final Rule.
(69 FR 45943, 7/30/04).
73 U.S. EPA. 1988. Integrated Risk Information
System File of Acetaldehyde. This material is
available electronically at https://www.epa.gov/iris/
subst/0290.htm.
74 Appleman, L. M., R. A. Woutersen, V. J. Feron,
R. N. Hooftman, and W. R. F. Notten. (1986). Effects
of the variable versus fixed exposure levels on the
toxicity of acetaldehyde in rats. J. Appl. Toxicol. 6:
331–336.
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Data from these studies showing
degeneration of the olfactory epithelium
were found to be sufficient for EPA to
develop an RfC for acetaldehyde of 9 µg/
m3. Confidence in the principal study is
medium and confidence in the database
is low, due to the lack of chronic data
establishing a no observed adverse effect
level and due to the lack of reproductive
and developmental toxicity data.
Therefore, there is low confidence in the
RfC. The agency is currently conducting
a reassessment of risk from inhalation
exposure to acetaldehyde.
The primary acute effect of exposure
to acetaldehyde vapors is irritation of
the eyes, skin, and respiratory tract.76
Some asthmatics have been shown to be
a sensitive subpopulation to decrements
in functional expiratory volume (FEV1
test) and bronchoconstriction upon
acetaldehyde inhalation.77
v. Acrolein
Acrolein, a hydrocarbon, is intensely
irritating to humans when inhaled, with
acute exposure resulting in upper
respiratory tract irritation and
congestion. The Agency has developed
an RfC for acrolein of 0.02 µg/m3.78 The
overall confidence in the RfC
assessment is judged to be medium. The
Agency is also currently in the process
of conducting an assessment of acute
health effects for acrolein. EPA
determined in 2003 using the 1999 draft
cancer guidelines that the human
carcinogenic potential of acrolein could
not be determined because the available
data were inadequate. No information
was available on the carcinogenic effects
of acrolein in humans and the animal
data provided inadequate evidence of
carcinogenicity.
vi. Polycyclic Organic Matter (POM)
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POM is generally defined as a large
class of organic compounds which have
multiple benzene rings and a boiling
point greater than 100 degrees Celsius.
Many of the compounds included in the
75 Appleman, L.M., R.A. Woutersen, and V.J.
Feron. (1982). Inhalation toxicity of acetaldehyde in
rats. I. Acute and subacute studies. Toxicology. 23:
293–297.
76 U.S. EPA (1988). Integrated Risk Information
System File of Acetaldehyde. This material is
available electronically at https://www.epa.gov/iris/
subst/0290.htm.
77 Myou, S.; Fujimura, M.; Nishi K.; Ohka, T.; and
Matsuda, T. (1993) Aerosolized acetaldehyde
induces histamine-mediated bronchoconstriction in
asthmatics. Am. Rev. Respir. Dis.148(4 Pt 1): 940–
3.
78 U.S. Environmental Protection Agency (2003)
Integrated Risk Information System (IRIS) on
Acrolein. National Center for Environmental
Assessment, Office of Research and Development,
Washington, D.C. 2003. This material is available
electronically at https://www.epa.gov/iris/subst/
0364.htm.
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class of compounds known as POM are
classified by EPA as probable human
carcinogens based on animal data. One
of these compounds, naphthalene, is
discussed separately below.
Polycyclic aromatic hydrocarbons
(PAHs) are a chemical subset of POM.
In particular, EPA frequently obtains
data on 16 of these POM compounds.
Recent studies have found that maternal
exposures to PAHs in a population of
pregnant women were associated with
several adverse birth outcomes,
including low birth weight and reduced
length at birth, as well as impaired
cognitive development at age three.79, 80
These studies are discussed in the
Regulatory Impact Analysis.
vii. Naphthalene
Naphthalene is a PAH compound
consisting of two benzene rings fused
together with two adjacent carbon atoms
common to both rings. In 2004, EPA
released an external review draft of a
reassessment of the inhalation
carcinogenicity of naphthalene.81 The
draft reassessment, External Review
Draft, IRIS Reassessment of the
Inhalation Carcinogenicity of
Naphthalene, U.S. EPA, completed
external peer review in 2004 by Oak
Ridge Institute for Science and
Education.82 Based on external
comments, additional analyses are being
considered. California EPA has released
a new risk assessment for naphthalene
with a cancer unit risk estimate of
3×10 ¥5 per µg/m3.83 The California EPA
value was used in the 1999 NATA and
in the analyses done for this rule. In
addition, IARC has reevaluated
naphthalene and re-classified it as
Group 2B: possibly carcinogenic to
79 Perera, F.P.; Rauh, V.; Tsai, W-Y.; et al. (2002)
Effect of transplacental exposure to environmental
pollutants on birth outcomes in a multiethnic
population. Environ Health Perspect. 111: 201–205.
80 Perera, F.P.; Rauh, V.; Whyatt, R.M.; Tsai, W.Y.;
Tang, D.; Diaz, D.; Hoepner, L.; Barr, D.; Tu, Y.H.;
Camann, D.; Kinney, P. (2006) Effect of prenatal
exposure to airborne polycyclic aromatic
hydrocarbons on neurodevelopment in the first 3
years of life among inner-city children. Environ
Health Perspect 114: 1287–1292.
81 U.S. EPA (1998) Integrated Risk Information
System (IRIS) summary on Naphthalene. National
Center for Environmental Assessment, Office of
Research and Development, Washington, D.C. 2003.
This material is available electronically at https://
www.epa.gov/iris/subst/0436.htm.
82 Oak Ridge Institute for Science and Education.
(2004) External Peer Review for the IRIS
Reassessment of the Inhalation Carcinogenicity of
Naphthalene. August 2004. https://cfpub2.epa.gov/
ncea/cfm/recordisplay.cfm?deid=86019.
83 California EPA. (2004) Long Term Health
Effects of Exposure to Naphthalene. Office of
Environmental Health Hazard Assessment. https://
www.oehha.ca.gov/air/toxic_contaminants/
draftnaphth.html.
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humans.84 Current risk estimates for
naphthalene are based on extrapolations
from rodent studies conducted at higher
doses. At present, human data are
inadequate for developing estimates.
The current EPA IRIS assessment
includes noncancer data on hyperplasia
and metaplasia in nasal tissue that form
the basis of an inhalation RfC of 3 µg/
m3.85 The principal study was given
medium confidence because adequate
numbers of animals were used, and the
severity of nasal effects increased at the
higher exposure concentration.
However, the study produced high
mortality and hematological evaluation
was not conducted beyond 14 days. The
database was given a low-to-medium
confidence rating because there are no
chronic or subchronic inhalation studies
in other animal species, and there are no
reproductive or developmental studies
for inhalation exposure. In the absence
of human or primate toxicity data, the
assumption is made that nasal responses
in mice to inhaled naphthalene are
relevant to humans; however, it cannot
be said with certainty that this RfC for
naphthalene based on nasal effects will
be protective for hemolytic anemia and
cataracts, the more well-known human
effects from naphthalene exposure. As a
result, we have medium confidence in
the RfC.
viii. Diesel Exhaust
In EPA’s Diesel Health Assessment
Document (HAD),86 diesel exhaust was
classified as likely to be carcinogenic to
humans by inhalation at environmental
exposures, in accordance with the
revised draft 1996/1999 EPA cancer
guidelines. A number of other agencies
(National Institute for Occupational
Safety and Health, the International
Agency for Research on Cancer, the
World Health Organization, California
EPA, and the U.S. Department of Health
and Human Services) have made similar
classifications. EPA concluded in the
Diesel HAD that it is not possible
currently to calculate a cancer unit risk
for diesel exhaust due to a variety of
factors that limit the current studies,
84 International Agency for Research on Cancer
(IARC). (2002) Monographs on the Evaluation of the
Carcinogenic Risk of Chemicals for Humans. Vol.
82. Lyon, France.
85 EPA 2005 ‘‘Full IRIS Summary for Naphthalene
(CASRN 91–20–3)’’ Environmental Protection
Agency, Integrated Risk Information System (IRIS),
Office of Health and Environmental Assessment,
Environmental Criteria and Assessment Office,
Cincinnati, OH https://www.epa.gov/iris/subst/
0436.htm.
86 U.S. EPA (2002) Health Assessment Document
for Diesel Engine Exhaust. EPA/600/8–90/057F
Office of Research and Development, Washington,
DC. This document is available electronically at
https://cfpub.epa.gov/ncea/cfm/
recordisplay.cfm?deid=29060.
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such as limited quantitative exposure
histories in occupational groups
investigated for lung cancer.
However, in the absence of a cancer
unit risk, the EPA Diesel HAD sought to
provide additional insight into the
significance of the cancer hazard by
estimating possible ranges of risk that
might be present in the population. An
exploratory analysis was used to
characterize a possible risk range by
comparing a typical environmental
exposure level for highway diesel
sources to a selected range of
occupational exposure levels. The
occupationally observed risks were then
proportionally scaled according to the
exposure ratios to obtain an estimate of
the possible environmental risk. A
number of calculations are needed to
accomplish this, and these can be seen
in the EPA Diesel HAD. The outcome
was that environmental risks from
diesel exhaust exposure could range
from a low of 10¥4 to 10¥5 to as high
as 10¥3, reflecting the range of
occupational exposures that could be
associated with the relative and absolute
risk levels observed in the occupational
studies. Because of uncertainties, the
analysis acknowledged that the risks
could be lower than 10¥4 or 10¥5, and
a zero risk from diesel exhaust exposure
was not ruled out.
Noncancer health effects of acute and
chronic exposure to diesel exhaust
emissions are also of concern to the
Agency. EPA derived an RfC from
consideration of four well-conducted
chronic rat inhalation studies showing
adverse pulmonary effects.87 88 89 90 The
RfC is 5 µg/m3 for diesel exhaust as
measured by diesel PM. This RfC does
not consider allergenic effects such as
those associated with asthma or
immunologic effects. There is growing
evidence, discussed in the Diesel HAD,
that diesel exhaust can exacerbate these
effects, but the exposure-response data
are presently lacking to derive an RfC.
The EPA Diesel HAD states, ‘‘With DPM
[diesel particulate matter] being a
87 Ishinishi, N; Kuwabara, N; Takaki, Y; et al.
(1988) Long-term inhalation experiments on diesel
exhaust. In: Diesel exhaust and health risks. Results
of the HERP studies. Ibaraki, Japan: Research
Committee for HERP Studies; pp. 11–84.
88 Heinrich, U; Fuhst, R; Rittinghausen, S; et al.
(1995) Chronic inhalation exposure of Wistar rats
and two different strains of mice to diesel engine
exhaust, carbon black, and titanium dioxide. Inhal.
Toxicol. 7:553–556.
89 Mauderly, JL; Jones, RK; Griffith, WC; et al.
(1987) Diesel exhaust is a pulmonary carcinogen in
rats exposed chronically by inhalation. Fundam.
Appl. Toxicol. 9:208–221.
90 Nikula, KJ; Snipes, MB; Barr, EB; et al. (1995)
Comparative pulmonary toxicities and
carcinogenicities of chronically inhaled diesel
exhaust and carbon black in F344 rats. Fundam.
Appl. Toxicol. 25:80–94.
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ubiquitous component of ambient PM,
there is an uncertainty about the
adequacy of the existing DE [diesel
exhaust] noncancer database to identify
all of the pertinent DE-caused
noncancer health hazards’’ (p. 9–19).
The Diesel HAD also briefly
summarizes health effects associated
with ambient PM and discusses the
EPA’s annual National Ambient Air
Quality Standard (NAAQS) of 15 µg/m3.
There is a much more extensive body of
human data showing a wide spectrum of
adverse health effects associated with
exposure to ambient PM, of which
diesel exhaust is an important
component. The PM2.5 NAAQS is
designed to provide protection from the
noncancer and premature mortality
effects of PM2.5 as a whole, of which
diesel PM is a constituent.
c. Gasoline PM
Beyond the specific areas of
quantifiable risk discussed above in
section III.C, EPA is also currently
investigating gasoline PM. Gasoline
exhaust is a complex mixture that has
not been evaluated in EPA’s IRIS.
Gasoline exhaust is a ubiquitous source
of particulate matter, contributing to the
health effects observed for ambient PM
which is discussed extensively in the
EPA Particulate Matter Criteria
Document.91 The PM Criteria Document
notes that the PM components of
gasoline and diesel engine exhaust are
hypothesized, important contributors to
the observed increases in lung cancer
incidence and mortality associated with
ambient PM2.5.92 Gasoline PM is also a
component of near-roadway emissions
that may be contributing to the health
effects observed in people who live near
roadways (see section III.F). There is
also emerging evidence for the
mutagenicity and cytotoxicity of
gasoline exhaust and gasoline PM.
Seagrave et al. investigated the
combined particulate and semivolatile
organic fractions of gasoline engine
emissions in various animal and
bioassay tests.93 The authors suggest
91 U.S. EPA (2004) Air Quality Criteria for
Particulate Matter: Volume 1. Research Triangle
Park, NC: National Center for Environmental
Assessment—RTP Office; Report No. EPA/600/P–
99/002aF. Enter report number at the following
search page, https://yosemite.epa.gov/ncepihom/
nsCatalog.nsf//SearchPubs?Openform.
92 U.S. EPA (2004) Air Quality Criteria for
Particulate Matter: Volume 1. Research Triangle
Park, NC: National Center for Environmental
Assessment—RTP Office; Report No. EPA/600/P–
99/002aF, p. 8–318. Enter report number at the
following search page, https://yosemite.epa.gov/
ncepihom/nsCatalog.nsf//SearchPubs?Openform.
93 Seagrave, J.; McDonald, J.D.; Gigliotti, A.P.;
Nikula, K.J.; Seilkop, S.K.; Gurevich, M. and
Mauderly, J.L. (2002) Mutagenicity and in Vivo
Toxicity of Combined Particulate and Semivolatile
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that emissions from gasoline engines are
mutagenic and can induce inflammation
and have cytotoxic effects.
EPA is working to improve the
understanding of PM emissions from
gasoline engines, including the potential
range of emissions and factors that
influence emissions. EPA led a
cooperative test program that recently
completed testing approximately 500
randomly procured vehicles in the
Kansas City metropolitan area. The
purpose of this study was to determine
the distribution of gasoline PM
emissions from the in-use light-duty
fleet. Results from this study are
expected to be available shortly.
Preliminary results from this work show
the influence of high emitters on overall
gasoline PM emissions and, also, that
gasoline PM emissions increase at lower
ambient temperatures in the in-use fleet.
Some source apportionment studies
show gasoline and diesel PM can result
in larger contributions to ambient PM
than predicted by EPA emission
inventories.94 95 These source
apportionment studies were one
impetus behind conducting the Kansas
City study.
Another issue related to gasoline PM
is the effect of gasoline vehicles and
engines on ambient PM, especially
secondary PM. Ambient PM is
composed of primary PM emitted
directly into the atmosphere and
secondary PM that is formed from
chemical reactions in the atmosphere.
The issue of secondary organic aerosol
formation from aromatic precursors
such as toluene is an important one to
which EPA and others are paying
significant attention. This is discussed
in more detail in section 1.4.1 of the
RIA.
d. Near-Roadway Health Effects
Another approach to investigating the
collective health effects of mobile
source contaminants is to examine
associations between living near major
roads and different adverse health
endpoints. These studies generally
examine people living near heavilytrafficked roadways, typically within
several hundred meters, where fresh
Organic Fractions of Gasoline and Diesel Engine
Emissions. Toxicological Sciences 70:212–226.
94 Fujita, E.; Watson, M.J.; Chow, M.C.; et al.
(1998) Northern Front Range Air Quality Study,
Volume C: Source apportionment and simulation
methods and evaluation. Prepared for Colorado
State University, Cooperative Institute for Research
in the Atmosphere, by Desert Research Institute,
Reno, NV.
95 Schauer, J.J.; Rogge, W.F.; Hildemann, L.M.; et
al. (1996) Source apportionment of airborne
particulate matter using organic compounds as
tracers. Atmos. Environ. 30(22):3837–3855.
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emissions from motor vehicles are not
yet fully diluted with background air.
Several studies have measured
elevated concentrations of pollutants
emitted directly by motor vehicles near
roadways as compared to overall urban
background levels. These elevated
concentrations generally occur within
approximately 200 meters of the road,
although the distance may vary
depending on traffic and environmental
conditions. Pollutants measured with
elevated concentrations include
benzene, polycyclic aromatic
hydrocarbons, carbon monoxide,
nitrogen dioxide, black carbon, and
coarse, fine, and ultrafine particulate
matter. In addition, concentrations of
road dust, and wear particles from tire
and brake use also show concentration
increases in proximity of major
roadways.
The near-roadway health studies
provide stronger evidence for some
health endpoints than others. Evidence
of adverse responses to traffic-related
pollution is strongest for non-allergic
respiratory symptoms, cardiovascular
effects, premature adult mortality, and
adverse birth outcomes, including low
birth weight and size. Some evidence
for new onset asthma is available, but
not all studies have significant
correlations. Lastly, among studies of
childhood cancer, in particular
childhood leukemia, evidence is
inconsistent. Several small studies
report positive associations, though
such effects have not been observed in
two larger studies. As described above,
benzene and 1,3-butadiene are both
known human leukemogens in adults.
As previously mentioned, there is
evidence of increased risk of leukemia
among children whose parents have
been occupationally exposed to
benzene. Though the near-roadway
studies are equivocal, taken together
with the laboratory studies and other
exposure environments, the data suggest
a potentially serious children’s health
concern could exist. Additional research
is needed to determine the significance
of this potential concern.
Significant scientific uncertainties
remain in our understanding of the
relationship between adverse health
effects and near-road exposure,
including the exposures of greatest
concern, the importance of chronic
versus acute exposures, the role of fuel
type (e.g. diesel or gasoline) and
composition (e.g., % aromatics),
relevant traffic patterns, the role of costressors including noise and
socioeconomic status, and the role of
differential susceptibility within the
‘‘exposed’’ populations. For a more
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detailed discussion, see Chapter 3 of the
Regulatory Impact Analysis.
These studies provide qualitative
evidence that reducing emissions from
on-road mobile sources will provide
public health benefits beyond those that
can be quantified using currently
available information.
C. Ozone
Many MSATs are part of a larger
category of mobile source emissions
known as volatile organic compounds
(VOCs), which contribute to the
formation of ozone. Mobile sources
contribute significantly to national
emissions of VOCs. In addition, PFCs
are a source of VOCs. The vehicle and
PFC standards in this final rule will
help reduce emissions of VOCs.
1. Background
Ground-level ozone pollution is
formed by the reaction of VOCs and
nitrogen oxides (NOX) in the lower
atmosphere in the presence of heat and
sunlight. These pollutants, often
referred to as ozone precursors, are
emitted by many types of pollution
sources, such as highway and nonroad
motor vehicles and engines, power
plants, chemical plants, refineries,
makers of consumer and commercial
products, industrial facilities, and
smaller area sources. The PFC controls
being finalized in this action will help
reduce VOC emissions by reducing
evaporation, permeation and spillage
from PFCs. The vehicle controls being
finalized will also reduce VOC
emissions; however, because these
reductions will occur at cold
temperatures the ozone benefits will be
limited.
The science of ozone formation,
transport, and accumulation is
complex.96 Ground-level ozone is
produced and destroyed in a cyclical set
of chemical reactions, many of which
are sensitive to temperature and
sunlight. When ambient temperatures
and sunlight levels remain high for
several days and the air is relatively
stagnant, ozone and its precursors can
build up and result in more ozone than
typically would occur on a single hightemperature day. Ozone also can be
transported into an area from pollution
sources found hundreds of miles
upwind, resulting in elevated ozone
levels even in areas with low VOC or
NOX emissions.
The current ozone National Ambient
Air Quality Standards (NAAQS)
96 U.S. EPA, Air Quality Criteria for Ozone and
Related Photochemical Oxidants (Final). U.S.
Environmental Protection Agency, Washington, DC,
EPA/600/R–05/004aF-cF, 2006. This document is
available in Docket EPA–HQ–OAR–2005–0036.
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established by EPA in 1997 has an 8hour averaging time.97 The 8-hour
ozone NAAQS is based on welldocumented science demonstrating that
more people were experiencing adverse
health effects at lower levels of exertion,
over longer periods, and at lower ozone
concentrations than addressed by the
previous one-hour ozone NAAQS. The
current ozone NAAQS addresses ozone
exposures of concern for the general
population and populations most at
risk, including children active outdoors,
outdoor workers, and individuals with
pre-existing respiratory disease, such as
asthma. The 8-hour ozone NAAQS is
met at an ambient air quality monitoring
site when the average of the annual
fourth-highest daily maximum 8-hour
average ozone concentration over three
years is less than or equal to 0.084 ppm.
2. Health Effects of Ozone
The health and welfare effects of
ozone are well documented and are
assessed in the EPA’s 2006 ozone Air
Quality Criteria Document (ozone
AQCD) and EPA staff papers.98 99 Ozone
can irritate the respiratory system,
causing coughing, throat irritation, and/
or uncomfortable sensation in the chest.
Ozone can reduce lung function and
make it more difficult to breathe deeply,
and breathing may become more rapid
and shallow than normal, thereby
limiting a person’s activity. Ozone can
also aggravate asthma, leading to more
asthma attacks that require a doctor’s
attention and/or the use of additional
medication. Animal toxicologic
evidence indicates that with repeated
exposure, ozone can inflame and
damage the lining of the lungs, which
may lead to permanent changes in lung
tissue and irreversible reductions in
lung function. People who are more
susceptible to effects associated with
exposure to ozone include children, the
elderly, and individuals with
respiratory disease such as asthma.
There is also suggestive evidence that
certain people may have greater genetic
susceptibility. Those with greater
exposures to ozone, for instance due to
time spent outdoors (e.g., outdoor
workers), are also of concern.
97 EPA’s review of the ozone NAAQS is underway
and a proposal is scheduled for June 2007 with a
final rule scheduled for March 2008.
98 U.S. EPA, Air Quality Criteria for Ozone and
Related Photochemical Oxidants (Final). U.S.
Environmental Protection Agency, Washington, DC,
EPA/600/R–05/004aF-cF, 2006. This document is
available in Docket EPA–HQ–OAR–2005–0036.
99 U.S. EPA (2007) Review of National Ambient
Air Quality Standards for Ozone, Assessment of
Scientific and Technical Information, OAQPS Staff
Paper, EPA–452/R–07–003. This document is
available in Docket EPA–HQ–OAR–2005–0036.
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The recent ozone AQCD also
examined relevant new scientific
information which has emerged in the
past decade, including the impact of
ozone exposure on such health effects as
changes in lung structure and
biochemistry, inflammation of the
lungs, exacerbation and causation of
asthma, respiratory illness-related
school absence, hospital admissions and
premature mortality. Animal toxicologic
studies have suggested potential
interactions between ozone and PM
with increased responses observed to
mixtures of the two pollutants
compared to either ozone or PM alone.
The respiratory morbidity observed in
animal studies along with the evidence
from epidemiologic studies supports a
causal relationship between acute
ambient ozone exposures and increased
respiratory-related emergency room
visits and hospitalizations in the warm
season. In addition, there is suggestive
evidence of a contribution of ozone to
cardiovascular-related morbidity and
non-accidental and cardiopulmonary
mortality.
3. Plant and Ecosystem Effects of Ozone
Ozone contributes to many
environmental effects, with impacts to
plants and ecosystems being of most
concern. Ozone can produce both acute
and chronic injury in sensitive species
depending on the concentration level
and the duration of the exposure. Ozone
effects also tend to accumulate over the
growing season of the plant, so that even
lower concentrations experienced for a
longer duration have the potential to
create chronic stress on vegetation.
Ozone damage to plants includes visible
injury to leaves and a reduction in food
production through impaired
photosynthesis, both of which can lead
to reduced crop yields, forestry
production, and use of sensitive
ornamentals in landscaping. In addition,
the reduced food production in plants
and subsequent reduced root growth
and storage below ground, can result in
other, more subtle plant and ecosystems
impacts. These include increased
susceptibility of plants to insect attack,
disease, harsh weather, interspecies
competition and overall decreased plant
vigor. The adverse effects of ozone on
forest and other natural vegetation can
potentially lead to species shifts and
loss from the affected ecosystems,
resulting in a loss or reduction in
associated ecosystem goods and
services. Lastly, visible ozone injury to
leaves can result in a loss of aesthetic
value in areas of special scenic
significance like national parks and
wilderness areas. The final 2006 ozone
AQCD presents more detailed
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information on ozone effects on
vegetation and ecosystems.
4. Current and Projected 8-hour Ozone
Levels
Currently, ozone concentrations
exceeding the level of the 8-hour ozone
NAAQS occur over wide geographic
areas, including most of the nation’s
major population centers.100 As of
October 2006 approximately 157 million
people live in the 116 areas that are
currently designated as not in
attainment with the 8-hour ozone
NAAQS. There are 461 full or partial
counties that make up the 116 8-hour
ozone nonattainment areas.
EPA has already adopted many
emission control programs that are
expected to reduce ambient ozone
levels. These control programs include
the Clean Air Interstate Rule (70 FR
25162, May 12, 2005), as well as many
mobile source rules (many of which are
described in section V.D). As a result of
these programs, the number of areas that
fail to meet the 8-hour ozone NAAQS is
expected to decrease.
Based on the recent ozone modeling
performed for the CAIR analysis,101
barring additional local ozone precursor
controls, we estimate 37 Eastern
counties (where 24 million people are
projected to live) will exceed the 8-hour
ozone NAAQS in 2010. An additional
148 Eastern counties (where 61 million
people are projected to live) are
expected to be within 10 percent of
violating the 8-hour ozone NAAQS in
2010.
States with 8-hour ozone
nonattainment areas will be required to
take action to bring these areas into
compliance in the future. Based on the
final rule designating and classifying 8hour ozone nonattainment areas (69 FR
23951, April 30, 2004), most 8-hour
ozone nonattainment areas will be
required to attain the 8-hour ozone
NAAQS in the 2007 to 2013 time frame
and then be required to maintain the 8hour ozone NAAQS thereafter.102 The
expected ozone inventory reductions
from the standards being finalized in
this action may be useful to states in
attaining or maintaining the 8-hour
ozone NAAQS.
EPA’s review of the ozone NAAQS is
currently underway and a proposed
decision in this review is scheduled for
100 A map of the 8-hour ozone nonattainment
areas is included in the RIA for this rule.
101 Technical Support Document for the Final
Clean Air Interstate Rule Air Quality Modeling.
This document is available in Docket EPA–HQ–
OAR–2005–0036.
102 The Los Angeles South Coast Air Basin 8-hour
ozone nonattainment area will have to attain before
June 15, 2021.
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June 2007 with a final rule scheduled
for March 2008. If the ozone NAAQS is
revised, then new nonattainment areas
could be designated. While EPA is not
relying on it for purposes of justifying
this rule, the emission reductions from
this rulemaking would also be helpful to
states if there is an ozone NAAQS
revision.
D. Particulate Matter
The cold temperature vehicle controls
being finalized here will result in
reductions of primary PM being emitted
by vehicles. In addition, both the
vehicle controls and the PFC controls
will reduce VOCs that react in the
atmosphere to form secondary PM2.5,
namely organic carbonaceous PM2.5.
1. Background
Particulate matter (PM) represents a
broad class of chemically and physically
diverse substances. It can be principally
characterized as discrete particles that
exist in the condensed (liquid or solid)
phase spanning several orders of
magnitude in size. PM is further
described by breaking it down into size
fractions. PM10 refers to particles
generally less than or equal to 10
micrometers (µm) in diameter. PM2.5
refers to fine particles, those particles
generally less than or equal to 2.5 µm in
diameter. Inhalable (or ‘‘thoracic’’)
coarse particles refer to those particles
generally greater than 2.5 µm but less
than or equal to 10 µm in diameter.
Ultrafine PM refers to particles with
diameters generally less than 100
nanometers (0.1 µm). Larger particles
(>10 µm) tend to be removed by the
respiratory clearance mechanisms,
whereas smaller particles are deposited
deeper in the lungs.
Fine particles are produced primarily
by combustion processes and by
transformations of gaseous emissions
(e.g., SOx, NOX and VOCs) in the
atmosphere. The chemical and physical
properties of PM2.5 may vary greatly
with time, region, meteorology and
source category. Thus, PM2.5 may
include a complex mixture of different
pollutants including sulfates, nitrates,
organic compounds, elemental carbon
and metal compounds. These particles
can remain in the atmosphere for days
to weeks and travel through the
atmosphere hundreds to thousands of
kilometers.
EPA has recently amended the PM
NAAQS (71 FR 61144, October 17,
2006). The final rule, signed on
September 21, 2006 and published on
October 17, 2006, addressed revisions to
the primary and secondary NAAQS for
PM to provide increased protection of
public health and welfare, respectively.
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The primary PM2.5 NAAQS include a
short-term (24-hour) and a long-term
(annual) standard. The level of the 24hour PM2.5 NAAQS has been revised
from 65 µg/m3 to 35 µg/m3 to provide
increased protection against health
effects associated with short-term
exposures to fine particles. The current
form of the 24-hour PM2.5 standard was
retained (e.g., based on the 98th
percentile concentration averaged over
three years). The level of the annual
PM2.5 NAAQS was retained at 15 µg/m3
continuing protection against health
effects associated with long-term
exposures. The current form of the
annual PM2.5 standard was retained as
an annual arithmetic mean averaged
over three years, however, the following
two aspects of the spatial averaging
criteria were narrowed: (1) The annual
mean concentration at each site shall be
within 10 percent of the spatially
averaged annual mean, and (2) the daily
values for each monitoring site pair
shall yield a correlation coefficient of at
least 0.9 for each calendar quarter. With
regard to the primary PM10 standards,
the 24-hour PM10 NAAQS was retained
at a level of 150 µg/m3 not to be
exceeded more than once per year on
average over a three-year period. Given
that the available evidence does not
suggest an association between longterm exposure to coarse particles at
current ambient levels and health
effects, EPA has revoked the annual
PM10 standard.
With regard to the secondary PM
standards, EPA has revised these
standards to be identical in all respects
to the revised primary standards.
Specifically, EPA has revised the
current 24-hour PM2.5 secondary
standard by making it identical to the
revised 24-hour PM2.5 primary standard,
retained the annual PM2.5 and 24-hour
PM10 secondary standards, and revoked
the annual PM10 secondary standards.
This suite of secondary PM standards is
intended to provide protection against
PM-related public welfare effects,
including visibility impairment, effects
on vegetation and ecosystems, and
material damage and soiling.
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2. Health Effects of PM
Scientific studies show ambient PM is
associated with a series of adverse
health effects. These health effects are
discussed in detail in the 2004
Particulate Matter Air Quality Criteria
Document (PM AQCD) as well as the
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2005 PM Staff Paper.103, 104 Further
discussion of health effects associated
with PM can also be found in the RIA
for this final rule.
Health effects associated with shortterm exposures (e.g. hours to days) in
ambient PM2.5 include premature
mortality, increased hospital
admissions, heart and lung diseases,
increased cough, adverse lowerrespiratory symptoms, decrements in
lung function and changes in heart rate
rhythm and other cardiac effects.
Studies examining populations exposed
to different levels of air pollution over
a number of years, including the
Harvard Six Cities Study and the
American Cancer Society Study, show
associations between long-term
exposure to ambient PM2.5 and both
total and cardiorespiratory mortality. In
addition, the reanalysis of the American
Cancer Society cohort shows an
association between fine particle and
sulfate concentrations and lung cancer
mortality.
Recently, several studies have
highlighted the adverse effects of PM
specifically from mobile sources.105, 106
Studies have also focused on health
effects due to PM exposures on or near
roadways.107 Although these studies
include all air pollution sources,
including both spark-ignition (gasoline)
and diesel powered vehicles, they
indicate that exposure to PM emissions
near roadways, thus dominated by
mobile sources, are associated with
health effects. Additional information
on near-roadway health effects can be
found in section III.B.2.d of this
preamble.
103 U.S. EPA (2004) Air Quality Criteria for
Particulate Matter (Oct 2004), Volume I Document
No. EPA600/P–99/002aF and Volume II Document
No. EPA600/P–99/002bF. This document is
available in Docket EPA–HQ–OAR–2005–0036.
104 U.S. EPA (2005) Review of the National
Ambient Air Quality Standard for Particulate
Matter: Policy Assessment of Scientific and
Technical Information, OAQPS Staff Paper. EPA–
452/R–05–005. This document is available in
Docket EPA–HQ–OAR–2005–0036.
105 Laden, F.; Neas, L.M.; Dockery, D.W.;
Schwartz, J. (2000) Association of Fine Particulate
Matter from Different Sources with Daily Mortality
in Six U.S. Cities. Environmental Health
Perspectives 108: 941–947.
106 Janssen, N.A.H.; Schwartz, J.; Zanobetti, A.;
Suh, H.H. (2002) Air Conditioning and SourceSpecific Particles as Modifiers of the Effect of PM10
on Hospital Admissions for Heart and Lung Disease.
Environmental Health Perspectives 110: 43–49.
107 Riediker, M.; Cascio, W.E.; Griggs, T.R.;
Herbst, M.C.; Bromberg, P.A.; Neas, L.; Williams,
R.W.; Devlin, R.B. (2003) Particulate Matter
Exposures in Cars is Associated with
Cardiovascular Effects in Healthy Young Men. Am.
J. Respir. Crit. Care Med. 169: 934–940.
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8443
3. Welfare Effects of PM
a. Visibility
i. Background
Visibility can be defined as the degree
to which the atmosphere is transparent
to visible light.108 Visibility impairment
manifests in two principal ways: as
local visibility impairment and as
regional haze.109 Local visibility
impairment may take the form of a
localized plume, a band or layer of
discoloration appearing well above the
terrain as a result from complex local
meteorological conditions.
Alternatively, local visibility
impairment may manifest as an urban
haze, sometimes referred to as a ‘‘brown
cloud.’’ This urban haze is largely
caused by emissions from multiple
sources in the urban areas and is not
typically attributable to only one nearby
source or to long-range transport. The
second type of visibility impairment,
regional haze, usually results from
multiple pollution sources spread over
a large geographic region. Regional haze
can impair visibility over large regions
and across states.
Visibility is important because it has
direct significance to people’s
enjoyment of daily activities in all parts
of the country. Individuals value good
visibility for the well-being it provides
them directly, where they live and
work, and in places where they enjoy
recreational opportunities. Visibility is
also highly valued in significant natural
areas such as national parks and
wilderness areas, and special emphasis
is given to protecting visibility in these
areas. For more information on visibility
see the 2004 PM AQCD as well as the
2005 PM Staff Paper.110 111
Fine particles are the major cause of
reduced visibility in parts of the United
108 National Research Council, 1993. Protecting
Visibility in National Parks and Wilderness Areas.
National Academy of Sciences Committee on Haze
in National Parks and Wilderness Areas. National
Academy Press, Washington, DC. This document is
available in Docket EPA–HQ–OAR–2005–0036.
This book can be viewed on the National Academy
Press Web site at https://www.nap.edu/books/
0309048443/html/.
109 See discussion in U.S. EPA, National Ambient
Air Quality Standards for Particulate Matter;
Proposed Rule; January 17, 2006, Vol 71, p. 2676.
This information is available electronically at
https://epa.gov/fedrgstr/EPA-AIR/2006/January/Day17/a177.pdf.
110 U.S. EPA (2004) Air Quality Criteria for
Particulate Matter (Oct 2004), Volume I Document
No. EPA600/P–99/002aF and Volume II Document
No. EPA600/P–99/002bF. This document is
available in Docket EPA–HQ–OAR–2005–0036.
111 U.S. EPA (2005) Review of the National
Ambient Air Quality Standard for Particulate
Matter: Policy Assessment of Scientific and
Technical Information, OAQPS Staff Paper. EPA–
452/R–05–005. This document is available in
Docket EPA–HQ–OAR–2005–0036.
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States. To address the welfare effects of
PM on visibility, EPA set secondary
PM2.5 standards which would act in
conjunction with the establishment of a
regional haze program. In setting this
secondary standard, EPA concluded that
PM2.5 causes adverse effects on visibility
in various locations, depending on PM
concentrations and factors such as
chemical composition and average
relative humidity. The secondary
(welfare-based) PM2.5 NAAQS was
established as equal to the suite of
primary (health-based) NAAQS.
Furthermore, section 169 of the Act
provides additional authorities to
remedy existing visibility impairment
and prevent future visibility impairment
in the 156 national parks, forests and
wilderness areas categorized as
mandatory class I federal areas (62 FR
38680–81, July 18, 1997).112 In July
1999 the regional haze rule (64 FR
35714) was put in place to protect the
visibility in mandatory class I federal
areas. Visibility can be said to be
impaired in both PM2.5 nonattainment
areas and mandatory class I federal
areas.
ii. Current Visibility Impairment
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Recently designated PM2.5
nonattainment areas indicate that, as of
October 2006, almost 90 million people
live in nonattainment areas for the 1997
PM2.5 NAAQS. Thus, at least these
populations would likely be
experiencing visibility impairment, as
well as many thousands of individuals
who travel to these areas. In addition,
while visibility trends have improved in
mandatory class I federal areas, the most
recent data show that these areas
continue to suffer from visibility
impairment.113 In summary, visibility
impairment is experienced throughout
the U.S., in multi-state regions, urban
areas, and remote mandatory class I
federal areas.114 115 The mandatory class
I federal areas are listed in Chapter 3 of
the RIA for this action. The areas that
have design values above the 1997 PM2.5
NAAQS are also listed in Chapter 3 of
the RIA for this action.
112 These areas are defined in section 162 of the
Act as those national parks exceeding 6,000 acres,
wilderness areas and memorial parks exceeding
5,000 acres, and all international parks which were
in existence on August 7, 1977.
113 U.S. EPA, Regulatory Impact Analysis for the
Final Clean Air Interstate Rule. This document is
available in Docket EPA–HQ–OAR–2005–0036.
114 U.S. EPA, Air Quality Designations and
Classifications for the Fine Particles (PM2.5)
National Ambient Air Quality Standards, December
17, 2004. (70 FR 943, January 5, 2005) This
document is also available on the web at: https://
www.epa.gov/pmdesignations/.
115 U.S. EPA, Regional Haze Regulations, July 1,
1999. (64 FR 35714, July 1, 1999)
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iii. Future Visibility Impairment
Recent modeling for the Clean Air
Interstate Rule (CAIR) was used to
project visibility conditions in
mandatory class I federal areas across
the country in 2015. The results for the
mandatory class I federal areas suggest
that these areas are predicted to
continue to have annual average
deciview levels above background in the
future.116 Modeling done for the PM
NAAQS also projected PM2.5 levels in
2015. These projections include all
sources of PM2.5, including the engines
covered in this rule, and suggest that
PM2.5 levels above the NAAQS will
persist into the future.
The vehicles that will be subject to
the standards contribute to visibility
concerns in these areas through both
their primary PM emissions and their
VOC emissions, which contribute to the
formation of secondary PM2.5. The PFCs
that will be subject to the standards also
contribute to visibility concerns through
their VOC emissions. Reductions in
these direct PM and VOC emissions will
help to improve visibility across the
nation, including mandatory class I
federal areas.
b. Atmospheric Deposition
Wet and dry deposition of ambient
particulate matter delivers a complex
mixture of metals (e.g., mercury, zinc,
lead, nickel, aluminum, cadmium),
organic compounds (e.g., POM, dioxins,
furans) and inorganic compounds (e.g.,
nitrate, sulfate) to terrestrial and aquatic
ecosystems. EPA’s Great Waters
Program has identified 15 pollutants
whose deposition to water bodies has
contributed to the overall contamination
loadings to these Great Waters. These 15
compounds include several heavy
metals and a group known as polycyclic
organic matter (POM). Within POM are
the polycyclic aromatic hydrocarbons
(PAHs). PAHs in the environment may
be present in the gas or particle phase,
although the bulk will be adsorbed onto
airborne particulate matter. In most
cases, human-made sources of PAHs
account for the majority of PAHs
released to the environment. The PAHs
are usually the POMs of concern as
many PAHs are probable human
carcinogens.117 For some watersheds,
116 The deciview metric describes perceived
visual changes in a linear fashion over its entire
range, analogous to the decibel scale for sound. A
deciview of 0 represents pristine conditions. The
higher the deciview value, the worse the visibility,
and an improvement in visibility is a decrease in
deciview value.
117 Deposition of Air Pollutants to the Great
Waters—Third Report to Congress, Office of Air
Quality Planning and Standards, June 2000,
EPA453–R–00–005. This document is available in
Docket EPA–HQ–OAR–2005–0036.
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atmospheric deposition represents a
significant input to the total surface
water PAH burden.118 119 Emissions
from mobile sources have been found to
account for a percentage of the
atmospheric deposition of PAHs. For
instance, recent studies have reported
gasoline and diesel vehicles as major
contributors in the atmospheric
deposition of PAHs to Chesapeake Bay,
Massachusetts Bay and Casco Bay.120 121
The vehicle controls being finalized
may help to reduce deposition of heavy
metals and POM.
c. Materials Damage and Soiling
The deposition of airborne particles
can also reduce the aesthetic appeal of
buildings and culturally important
articles through soiling, and can
contribute directly (or in conjunction
with other pollutants) to structural
damage by means of corrosion or
erosion.122 Particles affect materials
principally by promoting and
accelerating the corrosion of metals, by
degrading paints, and by deteriorating
building materials such as concrete and
limestone. Particles contribute to these
effects because of their electrolytic,
hygroscopic, and acidic properties, and
their ability to sorb corrosive gases
(principally sulfur dioxide). The rate of
metal corrosion depends on a number of
factors, including the deposition rate
and nature of the pollutant; the
influence of the metal protective
corrosion film; the amount of moisture
present; variability in the
electrochemical reactions; the presence
and concentration of other surface
electrolytes; and the orientation of the
metal surface.
118 Simcik, M.F.; Eisenrich, S.J.; Golden, K.A.;
Liu, S.; Lipiatou, E.; Swackhamer, D.L.; and Long,
D.T. (1996) Atmospheric Loading of Polycyclic
Aromatic Hydrocarbons to Lake Michigan as
Recorded in the Sediments. Environ. Sci. Technol.
30:3039–3046.
119 Simcik, M.F.; Eisenrich, S.J.; and Lioy, P.J.
(1999) Source Apportionment and Source/Sink
Relationships of PAHs in the Coastal Atmosphere
of Chicago and Lake Michigan. Atmospheric
Environment 33: 5071–5079.
120 Dickhut, R.M.; Canuel, E.A.; Gustafson, K.E.;
Liu, K.; Arzayus, K.M.; Walker, S.E.; Edgecombe, G.;
Gaylor, M.O.; and McDonald, E.H. (2000)
Automotive Sources of Carcinogenic Polycyclic
Aromatic Hydrocarbons Associated with Particulate
Matter in the Chesapeake Bay Region. Environ. Sci.
Technol. 34: 4635–4640.
121 Golomb, D.; Barry, E.; Fisher, G.;
Varanusupakul, P.; Koleda, M.; and Rooney, T.
(2001) Atmospheric Deposition of Polycyclic
Aromatic Hydrocarbons near New England Coastal
Waters. Atmospheric Environment 35: 6245–6258.
122 U.S EPA (2005) Review of the National
Ambient Air Quality Standards for Particulate
Matter: Policy Assessment of Scientific and
Technical Information, OAQPS Staff Paper. This
document is available in Docket EPA–HQ–OAR–
2005–0036.
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4. Current and Projected PM2.5 Levels
In 2005 EPA designated 39
nonattainment areas for the 1997 PM2.5
NAAQS based on air quality design
values (using 2001–2003 or 2002–2004
measurements) and a number of other
factors.123 (See 70 FR 943, January 5,
2005; 70 FR 19844, April 14, 2005.)
These areas are comprised of 208 full or
partial counties with a total population
exceeding 88 million. As mentioned in
section III.D.1, the 1997 PM2.5 NAAQS
was recently revised and the 2006 PM2.5
NAAQS became effective on December
18, 2006. Table III.D–1 presents the
number of counties in areas currently
designated as nonattainment for the
1997 PM2.5 NAAQS as well as the
number of additional counties which
have monitored data that is violating the
2006 PM2.5 NAAQS. Nonattainment
areas will be designated with respect to
the new 2006 PM2.5 NAAQS in early
2010.
TABLE III.D–1.—PM2.5 STANDARDS: CURRENT NONATTAINMENT AREAS AND OTHER VIOLATING COUNTIES
Number of
counties
Population1
1997 PM2.5 Standards: 39 areas currently designated .............................................................................................
2006 PM2.5 Standards: Counties with violating monitors 2 ........................................................................................
208
49
88,394,000
18,198,676
Total ....................................................................................................................................................................
257
106,592,676
1 Population
numbers are from 2000 census data.
2 This table provides an estimate of the counties violating the 2006 PM
2.5 NAAQS based on 2003–05 air quality data. The areas designated as
nonattainment for the 2006 PM2.5 NAAQS will be based on 3 years of air quality data from later years. Also, the county numbers in the summary
table include only the counties with monitors violating the 2006 PM2.5 NAAQS. The monitored county violations may be an underestimate of the
number of counties and populations that will eventually be included in areas with multiple counties designated nonattainment.
Based on modeling performed for the
PM NAAQS analysis, we estimate that
52 counties (where 53 million people
are projected to live) will exceed the
2006 PM2.5 standard in 2015.124 125 In
addition, 54 counties (where 27 million
people are projected to live) are
expected to be within 10 percent of
violating the 2006 PM2.5 NAAQS in
2015.
Areas designated as not attaining the
1997 PM2.5 NAAQS will need to attain
these standards in the 2010 to 2015 time
frame, and then be required to maintain
the NAAQS thereafter. The attainment
dates associated with the potential
nonattainment areas based on the 2006
PM2.5 NAAQS would likely be in the
2015 to 2020 timeframe. The emissions
standards being finalized in this action
would become effective between 2009
and 2015, making the expected PM and
VOC inventory reductions useful to
states in attaining or maintaining the
PM2.5 NAAQS.
nonattainment areas and their
populations, as of October 2006. The
expected PM and VOC inventory
reductions from the standards being
finalized in this action could be useful
to states in maintaining the PM10
NAAQS.
IV. What Are the Emissions, Air
Quality, and Public Health Impacts of
This Rule?
Air quality monitoring data indicates
that as of October 2006 approximately
28.5 million people live in 46
designated PM10 nonattainment areas,
which include all or part of 46 counties.
The RIA for this rule lists the PM10
A. Emissions Impacts of All Rule
Provisions Combined
The emissions analysis presented in
section IV.A of this preamble is
described in more detail in Chapter
2.2.2. of the RIA. The emissions analysis
has been updated since the proposal,
largely to include the effects of the
recently proposed Renewable Fuels
Standard, which was required by the
Energy Policy Act. The emissions
analysis examines the 0.62 vol%
standard but does not include the 1.3%
maximum average, because of the lead
time necessary to conduct inventory
modeling. Thus, the emission
reductions from highway vehicles and
other sources attributable to the fuel
benzene standard are underestimated in
many areas of the country, particularly
in areas where fuel benzene levels were
highest without control, such as the
123 The full details involved in calculating a PM
2.5
design value are given in Appendix N of 40 CFR
Part 50.
124 Note that this analysis identifies only counties
projected to have a violating monitor; when
designated in the future, some areas may include
additional contributing counties. Thus, the total
number of counties designated in the future and the
associated population would likely exceed these
estimates.
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5. Current PM10 Levels
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Northwest. This issue is discussed in
more detail in the RIA.
1. How Will MSAT Emissions Be
Reduced?
Figure IV.A–1 depicts the estimated
reduction in total air toxic emissions
emitted by mobile sources between 1990
and 2030, with and without the
standards being finalized in this rule.
These estimates do not include diesel
PM. Trends in diesel PM emissions are
discussed in the regulatory impact
analysis for this rule. Without standards
being finalized in this rule, emissions of
air toxics from mobile sources will be
reduced by about 70% percent between
1990 and 2030, from about 3.3 million
tons to 1.3 million tons. This will occur
despite a projected increase in vehicle
miles traveled of over 100 percent, and
a projected 150% increase in nonroad
activity, based on units of work called
horsepower hours. Without additional
controls, air toxic emissions from
mobile sources would begin to increase
after 2015. Similar trends are observed
for benzene (see Figure IV.A–2), with a
reduction in emissions from about
380,000 tons in 1990 to less than
170,000 tons in 2030, but emissions
from mobile sources begin to increase
again after 2015.
125 Regulatory Impact Analysis for the final PM
NAAQS rule. This document is available in Docket
EPA–HQ–OAR–2005–0036.
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61,000 tons less than they would have
been without this rule (Figure IV.A–4).
Table IV.A–2 depicts reductions in
benzene by source sector from this rule.
In 2030, annual benzene emissions
from gasoline on-road mobile sources
will be 45% lower as a result of this rule
(Figure IV.A–5), and over 60% lower
than they were in 1999. In addition,
benzene emissions from gasoline
nonroad equipment will be 14% lower
in 2030, and over 45% lower than they
were in 1999. Benzene emissions from
PFCs will be reduced by almost 80% in
2030 (Figure IV.A–6), and benzene
emissions from gasoline distribution by
over 30% in 2030. For total MSAT
emissions from on-road mobile sources,
there will be a 38% reduction in MSAT
emissions in 2030 (Figure IV.A–7), and
a 65% reduction from 1999 levels.
Table IV.A–3 provides estimated
reductions in emissions from individual
MSATs in 2015, 2020 and 2030, from
gasoline vehicles, gasoline nonroad
engines, and PFCs as a result of the
controls being finalized in this rule.
126 Reduction in fuel benzene will reduce
emissions through the whole distribution chain.
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Total emissions of MSATs from
mobile and stationary sources in 2030
will be 330,000 tons less than they
would have been without this rule
(Figure IV.A–3). Of these 330,000 tons
of reductions, 310,000 will be from
mobile sources, with the rest from
portable fuel containers (PFCs) and
gasoline distribution.126 Table IV.A–1
summarizes MSAT reductions by source
sector in 2015, 2020, and 2030. In
addition, total benzene emissions from
mobile and stationary sources will be
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8449
TABLE IV.A–1.—ESTIMATED REDUCTIONS IN MSAT EMISSIONS FROM ALL CONTROL MEASURES BY SECTOR, 2015 TO
2030
2015
MSAT
1999
Gasoline Onroad Mobile
Sources ........................
Gasoline Nonroad Mobile
Sources ........................
PFCs ...............................
Gasoline Distribution .......
Total .........................
Without
rule
(tons)
With
rule
(tons)
2020
Reduction
(tons)
Without
rule
(tons)
With rule
(tons)
2030
Reduction
(tons)
Without
rule
(tons)
With rule
(tons)
Reduction
(tons)
1,452,739
675,781
558,666
117,115
693,189
507,782
185,408
808,141
505,074
303,067
806,725
37,166
57,765
449,422
27,355
62,870
443,973
9,893
62,059
5,449
17,462
811
406,196
29,338
64,942
400,816
10,672
64,092
5,380
18,666
850
412,617
33,430
64,942
406,856
12,264
64,092
5,761
21,166
850
2,354,395
1,215,428
1,074,591
140,837
1,193,665
983,362
210,303
1,319,130
988,286
330,844
TABLE IV.A–2.—ESTIMATED REDUCTIONS IN BENZENE EMISSIONS FROM ALL CONTROL MEASURES BY SECTOR, 2015 TO
2030
2015
1999
pwalker on PROD1PC71 with RULES_2
Gasoline Onroad Mobile
Sources ........................
Gasoline Nonroad Mobile
Sources ........................
PFCs ...............................
Gasoline Distribution .......
Total .........................
VerDate Aug<31>2005
Without
rule
(tons)
With
rule
(tons)
2020
Reduction
(tons)
Without
rule
(tons)
With rule
(tons)
2030
Reduction
(tons)
Without
rule
(tons)
With rule
(tons)
Reduction
(tons)
183,660
97,789
71,688
26,101
101,514
65,878
35,636
119,016
65,601
53,415
68,589
853
1,984
41,343
992
2,445
35,825
215
1,635
5,518
777
810
40,161
1,063
2,621
34,717
232
1,772
5,444
831
849
42,994
1,210
2,621
37,167
267
1,772
5,827
944
849
255,086
142,569
109,363
33,206
145,359
102,599
42,760
165,841
104,807
61,035
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
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TABLE IV.A–3.—ESTIMATED REDUCTIONS IN EMISSIONS FROM INDIVIDUAL MSATS IN 2015, 2020 AND 2030, FROM GASOLINE VEHICLES, GASOLINE NONROAD ENGINES, AND PORTABLE FUEL CONTAINERS, RESULTING FROM THE CUMULATIVE IMPACTS OF THE CONTROLS IN THIS RULE 127
2015
1999
(tons)
MSAT
Without
rule (tons)
With rule
(tons)
2020
Reductions
(tons)
Without
rule (tons)
With rule
(tons)
2030
Reductions
(tons)
Without
rule (tons)
With rule
(tons)
Reductions
(tons)
1,3-Butadiene ..................
2,2,4-Trimethylpentane ...
Acetaldehyde ...................
Acrolein ...........................
Benzene ..........................
Ethyl Benzene .................
Formaldehyde .................
Hexane ............................
MTBE ..............................
Propionaldehyde .............
Styrene ............................
Toluene ...........................
Xylenes ............................
31,234
296,310
27,800
3,835
250,227
120,150
74,053
106,464
143,350
4,142
16,352
729,908
487,768
14,771
166,270
21,223
1,650
140,124
61,300
32,341
57,852
0
2,195
8,212
390,688
252,993
13,259
149,178
18,154
1,457
107,728
54,805
28,096
52,042
0
1,965
6,985
347,363
228,561
1,512
17,091
3,069
193
32,396
6,495
4,245
5,810
0
231
1,227
43,325
24,432
15,037
159,892
22,156
1,665
142,737
59,963
33,350
54,673
0
2,249
8,423
380,420
245,180
12,535
133,578
17,011
1,347
100,827
49,968
26,371
46,926
0
1,869
6,405
312,542
206,913
2,501
26,314
5,145
317
41,911
9,995
6,979
7,747
0
380
2,018
67,878
38,267
17,054
174,824
25,754
1,889
163,221
66,823
38,472
59,152
0
2,565
9,731
420,534
270,775
12,834
132,763
17,213
1,360
103,035
50,830
26,946
48,029
0
1,932
6,365
310,654
208,839
4,220
42,061
8,541
529
60,186
15,992
11,526
11,124
0
633
3,366
109,880
61,936
Total MSATs ............
2,291,593
1,149,618
1,009,592
140,026
1,125,744
916,291
209,453
1,250,794
920,800
329,994
pwalker on PROD1PC71 with RULES_2
VOC emissions will be reduced by the
hydrocarbon emission standards for
both light-duty vehicles and PFCs. As
seen in the table and accompanying
figure below Table IV.A–4 and Figure
IV.A–8, annual VOC emission
reductions from both of these sources
will be 34% lower in 2030 because of
this rule, and 59% lower than in 1999.
127 Napthalene reductions from controls in this
rule are not quantified, due to limitations in
modeling tools.
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2. How Will VOC Emissions Be
Reduced?
Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
8453
TABLE IV.A–4. ESTIMATED REDUCTIONS IN VOC EMISSIONS FROM LIGHT-DUTY GASOLINE VEHICLES AND PFCS, 1999 TO
2030
1999
VOC Without Rule (tons) .................................................................................................
VOC With Vehicle and PFC Standards (tons) ................................................................
VOC Reduction (tons) .....................................................................................................
3. How Will PM Emissions Be Reduced?
EPA expects that the cold-temperature
vehicle standards will reduce exhaust
emissions of direct PM2.5 by over 19,000
tons in 2030 nationwide (see Table
IV.A–5 below). Our analysis of the data
from vehicles meeting Tier 2 emission
standards indicate that PM emissions
follow a monotonic relationship with
2015
5,224,921
....................
....................
temperature, with lower temperatures
corresponding to higher vehicle
emissions. Additionally, the analysis
shows the ratio of PM to total nonmethane hydrocarbons (NMHC) to be
independent of temperature.128 Our
testing indicates that strategies which
reduce NMHC start emissions at cold
temperatures also reduce direct PM
emissions. Based on these findings,
2020
2,944,491
2,420,860
523,631
2,892,134
2,146,476
745,658
2030
3,281,752
2,153,735
1,128,017
direct PM emissions at cold
temperatures were estimated using a
constant PM to NMHC ratio. PM
emission reductions were estimated by
assuming that NMHC reductions will
result in proportional reductions in PM.
This assumption is supported by test
data. For more detail, see Chapter 2.1 of
the RIA.
TABLE IV.A–5. ESTIMATED NATIONAL REDUCTIONS IN DIRECT PM2.5 EXHAUST EMISSIONS FROM LIGHT-DUTY GASOLINE
VEHICLES AND TRUCKS, 2015 TO 2030
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PM2.5 Reductions from Vehicle Standards (tons) ................................................................................................
128 U.S. EPA. 2005. Cold-temperature exhaust
particulate matter emissions. Memorandum from
Chad Bailey to docket EPA–HQ–OAR–2005–0036.
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7,068
2020
2030
11,646
19,421
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2015
8454
Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
B. Emission Impacts by Provision
1. Vehicle Controls
We are finalizing a hydrocarbon
standard for gasoline passenger vehicles
at cold temperatures. This standard will
reduce VOC at temperatures below 75
°F, including air toxics such as benzene,
1,3-butadiene, formaldehyde,
acetaldehyde, and acrolein, and will
also reduce emissions of direct and
secondary PM. We are also finalizing
new evaporative emissions standards for
Tier 2 vehicles starting in 2009. These
new evaporative standards reflect the
emissions levels already being achieved
by manufacturers.
result from the cold temperature
hydrocarbon standard alone. The
standards will reduce VOC emissions
from these vehicles in 2030 by 31%.
Overall VOC emissions from these
vehicles will be reduced by 82%
between 1999 and 2030 (including the
effects of these standards as well as
other standards in place, such as Tier 2).
a. Volatile Organic Compounds (VOC)
Table IV.B–1 shows the VOC exhaust
emission reductions from light-duty
gasoline vehicles and trucks that will
TABLE IV.B.–1. ESTIMATED NATIONAL REDUCTIONS IN EXHAUST VOC EMISSIONS FROM LIGHT-DUTY GASOLINE VEHICLES
AND TRUCKS, 1999 TO 2030.
1999
VOC Without Rule (tons) ...............................................................
VOC With Proposed Vehicle Standards (tons) .............................
VOC Reductions from Vehicle Standards (tons) ...........................
Percentage Reduction ...................................................................
b. Toxics
In 2030, we estimate that the vehicle
standards will result in a 38% reduction
2010
4,899,891
......................
......................
......................
2015
2020
2030
2,990,760
2,839,012
151,748
5
2,614,987
2,293,703
321,284
12
2,538,664
2,009,301
529,363
21
2,878,836
1,996,074
882,762
31
in total emissions of the MSATs and a
39% reduction in benzene emissions
from light-duty vehicles and trucks (see
Tables IV.B–1 and IV.B–2). Between
1999 and 2030, total MSATs from lightduty gasoline vehicles and trucks will
be reduced by 64%, and benzene by
59%.
TABLE IV.B.–1. ESTIMATED NATIONAL REDUCTIONS IN EXHAUST MSAT EMISSIONS FROM LIGHT-DUTY GASOLINE
VEHICLES AND TRUCKS, 1999 TO 2030
1999
MSATs Without Rule (tons) ...........................................................
MSATs With Vehicle Standards (tons) ..........................................
MSAT Reductions from Vehicle Standards (tons) .........................
Percentage Reduction ...................................................................
2010
1,376,002
......................
......................
......................
2015
695,408
644,312
51,987
7
2020
650,012
542,281
107,731
17
2030
669,707
492,700
177,007
26
783,648
488,824
294,824
38
TABLE IV.B–2.—ESTIMATED NATIONAL REDUCTIONS IN BENZENE EXHAUST EMISSIONS FROM LIGHT-DUTY GASOLINE
VEHICLES AND TRUCKS, 1999 TO 2030.
1999
Benzene Without Rule (tons) .............................................................................
Benzene With Vehicle Standards (tons) ............................................................
Benzene Reductions from Vehicle Standards (tons) ........................................
Percentage Reduction .......................................................................................
c. PM2.5
As discussed in Section IV.A.3, EPA
expects that the cold-temperature
vehicle standards will reduce exhaust
emissions of direct PM2.5 by over 19,000
tons in 2030 nationwide (see Table
IV.A–5).
pwalker on PROD1PC71 with RULES_2
2. Fuel Benzene Standard
The fuel benzene standard will reduce
benzene exhaust and evaporative
emissions from both on-road and
nonroad mobile sources that are fueled
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173,474
..................
..................
..................
by gasoline. In addition, the fuel
benzene standard will reduce
evaporative emissions from gasoline
distribution and PFCs. Impacts on 1,3butadiene, formaldehyde, and
acetaldehyde emissions are not
significant, but are presented in Chapter
2 of the RIA. We do not expect the fuel
benzene standard to have quantifiable
impacts on any other air toxics, total
VOCs, or direct PM.
Table IV.B–3 shows national
estimates of total benzene emissions
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2010
99,559
91,621
7,939
8
2015
95,234
78,664
16,570
17
2020
99,225
72,128
27,097
27
2030
116,742
71,704
45,037
39
from these source sectors with and
without the fuel benzene standard in
2015. These estimates do not include
effects of the vehicle or PFC standards
(see section IV.A.1 for the combined
effects of the controls). They also
assume that the fuel program is fully
phased in, which is a simplification of
the actual phase-in. The fuel benzene
standard will reduce total benzene
emissions from on-road and nonroad
gasoline mobile sources, PFCs, and
gasoline distribution by 12% in 2015.
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TABLE IV.B–3.—ESTIMATED REDUCTIONS IN BENZENE EMISSIONS FROM GASOLINE STANDARD BY SECTOR IN 2015
Gasoline
on-road
mobile
sources
Benzene Without Rule (tons) ...........................................................................
Benzene With Gasoline Standard (tons) .........................................................
Benzene Reductions from Gasoline Standard (tons) ......................................
Percentage Reduction .....................................................................................
3. PFC Standards
a. VOC
Table IV.B–4 shows the reductions in
VOC emissions that we expect from the
Gasoline
nonroad
mobile
sources
97,789
86,875
10,914
11
41,343
35,825
5,518
13
PFCs
Gasoline distribution
992
619
373
38
Total
2,445
1,635
810
33
142,569
124,954
17,615
12
PFC standard. In 2015, VOC emissions
From PFCs will be reduced by 61%
because of reduced permeation, spillage,
and evaporative losses.
TABLE IV.B–4.—ESTIMATED NATIONAL REDUCTIONS IN VOC EMISSIONS FROM PFCS, 1999 TO 2030
1999
VOC Without Rule (tons) ...................................................................................
VOC With PFC Standard (tons) ........................................................................
VOC Reductions from PFC Standard (tons) .....................................................
Percentage Reduction .......................................................................................
b. Toxics
The PFC standard will reduce
emissions of benzene, toluene, xylenes,
ethylbenzene, n-hexane, 2,2,4trimethylpentane, and MTBE. We
325,030
..................
..................
..................
estimate that benzene emissions from
PFCs will be reduced by 68% (see Table
IV.B–5) and, more broadly, air toxic
emissions by 63% (see Table IV.B–6) in
year 2015. These reductions do not
include effects of the fuel benzene
2010
2015
2020
2030
316,756
256,175
60,580
19
329,504
127,157
202,347
61
353,470
137,175
216,294
61
402,916
216,294
245,255
61
standard (see section IV.A–1 for the
combined effects of the controls).
Chapter 2 of the RIA provides details on
the emission reductions of the other
toxics.
TABLE IV.B–5.—ESTIMATED NATIONAL REDUCTIONS IN BENZENE EMISSIONS FROM PFCS, 1999 TO 2030
1999
Benzene Without Rule (tons) ...........................................................................................................
Benzene With PFC Standard (tons) ................................................................................................
Benzene Reductions from PFC Standard (tons) .............................................................................
Percentage Reduction .....................................................................................................................
853
............
............
............
2010
943
743
200
21
2015
992
320
672
68
2020
1063
345
718
68
2030
1210
396
814
67
TABLE IV.B–6.—ESTIMATED NATIONAL REDUCTIONS IN TOTAL MSAT EMISSIONS FROM PFCS, 1999 TO 2030
1999
MSATs Without Rule (tons) .............................................................................................................
MSATs With PFC Standard (tons) ..................................................................................................
MSAT Reductions from PFC Standard (tons) .................................................................................
Percentage Reduction .....................................................................................................................
C. What Are the Air Quality, Exposure,
and Public Health Impacts of This Rule?
pwalker on PROD1PC71 with RULES_2
1. Mobile Source Air Toxics
The controls being finalized in this
rule will reduce both evaporative and
exhaust emissions from motor vehicles
and nonroad equipment. They will also
reduce emissions from PFCs and
stationary source emissions associated
with gasoline distribution. Therefore,
they will reduce exposure to mobile
source air toxics for the general
population, and also for people near
roadways, in vehicles, in homes with
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attached garages, operating nonroad
equipment, and living or working near
sources of gasoline distribution
emissions (such as bulk terminals, bulk
plants, tankers, marine vessels, and
service stations). Section III.B of this
preamble and Chapter 3 of the RIA
provide more details on these types of
exposures.
We performed national-scale air
quality, exposure, and risk modeling in
order to quantitatively assess the
impacts of the standards being finalized.
The exposure modeling for the final rule
accounted for the spatial variability of
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2010
2015
2020
2030
37,167
............
............
............
26,189
21,010
5,179
20
27,355
9,998
17,357
63
29,338
10,785
18,553
63
33,430
12,394
21,036
63
outdoor concentrations of air toxics due
to higher concentrations near roadways.
This is a significant improvement over
exposure modeling done for the
proposal, and is discussed in more
detail in Chapter 3 of the RIA. However,
in addition to the limitations of the
national-scale modeling tools (discussed
in Chapter 3 of the RIA), this modeling
did not account for the impacts of the
recently proposed renewable fuel
standard, as this standard was proposed
subsequent to the development of
inventories for air quality modeling. In
addition, while the model includes the
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pwalker on PROD1PC71 with RULES_2
0.62 vol% fuel benzene standard, it does
not include the 1.3% maximum average.
The standards being finalized in this
rule will reduce both the number of
people above the 1 in 100,000 cancer
risk level, and the average population
cancer risk, by reducing exposures to
mobile source air toxics. The number of
people above the 1 in 100,000 cancer
risk level due to exposure to all mobile
source air toxics from all sources will
decrease by over 11 million in 2020 and
by almost 17 million in 2030. The
number of people above the 1 in
100,000 cancer risk level from exposure
to benzene from all sources will
decrease by about 30 million in 2020
and 46 million in 2030. It should be
noted that if it were possible to estimate
impacts of the standard on
‘‘background’’ concentrations 129, the
estimated overall risk reductions would
be even larger. The standards will also
reduce the number of people with a
respiratory hazard index (HI) greater
than one by about 10 million in 2020,
and 17 million in 2030. As previously
discussed, a value of the HI greater than
1.0 can be best described as indicating
that a potential may exist for adverse
health effects.
Figure IV.C–1 depicts the impact on
the mobile source contribution to
nationwide average population cancer
risk from total MSATs and benzene in
2030. Nationwide, the cancer risk
attributable to total MSATs will be
reduced by 30%, and the risk from
129 ‘‘Background represents the contribution to
ambient levels of air toxics from sources further
away than 50 kilometers, as well as the contribution
from uninventoried sources.
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mobile source benzene will be reduced
by 37%. In 2030, the highway vehicle
contribution to MSAT cancer risk will
be reduced on average 36% across the
U.S., and the highway vehicle
contribution to benzene cancer risk will
be reduced on average by 43% across
the U.S. The methods and assumptions
used to model the impact of the controls
are described in more detail in Chapter
3 of the RIA.
Figure IV.C–2 depicts the impact on
the mobile source contribution to
nationwide average respiratory hazard
index (HI) in 2030. Nationwide, the
mobile source contribution to the
respiratory hazard index will be
reduced by 23%.
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Table IV.C–1 summarizes the change
in median and 95th percentile
inhalation cancer risks from benzene
and all MSATs attributable to all
outdoor sources in 2015, 2020, and
2030, with the controls being finalized
in this rule. The reductions in risk
would be larger if the modeling fully
accounted for a number of factors,
including exposure to benzene
emissions from vehicles, equipment,
and PFCs in attached garages and the
impacts of the control program on
‘‘background’’ levels attributable to
8457
transport. Reductions are significantly
larger for individuals in the 95th
percentile than in the 50th percentile.
Thus, this rule is providing bigger
benefits to individuals experiencing the
highest levels of risk.
TABLE IV.C—1. CHANGE IN MEDIAN AND 95TH PERCENTILE INHALATION CANCER RISK FROM BENZENE AND ALL MSATS
ATTRIBUTABLE TO OUTDOOR SOURCES IN 2015, 2020, AND 2030 WITH THE CONTROLS BEING FINALIZED IN THIS RULE
2015
Median
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95th
Median
95th
4.75×10¥5
4.37×10¥5
8
1.53×10¥5
1.40×10¥5
8
4.93×10¥5
4.40×10¥5
11
1.61×10¥5
1.42×10¥5
12
5.28×10¥5
4.49×10¥5
15
6.86×10¥6
6.17×10¥6
10
1.82×10¥5
1.53×10¥5
16
6.93×10¥6
6.02×10¥6
13
1.86×10¥5
1.47×10¥5
21
7.37×10¥6
6.06×10¥6
18
2.06×10¥5
1.49×10¥5
28
The vehicle and PFC standards will
also reduce VOC emissions, which are
a precursor to ozone. We have modeled
the ozone impacts of the PFC standards.
As described in more detail in Chapter
3.3 of the RIA, a metamodeling tool
developed at EPA, the ozone response
surface metamodel, was used to
estimate the effects of the emission
18:54 Feb 23, 2007
Median
1.50×10¥5
1.41×10¥5
6
2. Ozone
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95th
2030
Jkt 211001
reductions. The ozone response surface
metamodel was created using multiple
runs of the Comprehensive Air Quality
Model with Extensions (CAMx). Base
and control CAMx metamodeling was
completed for two future years (2020,
2030) over a modeling domain that
includes all or part of 37 Eastern U.S.
states. For more information on the
response surface metamodel, please see
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the RIA for this final rule or the Air
Quality Modeling Technical Support
Document (TSD).
We have made estimates using the
ozone response surface metamodel to
illustrate the types of change in future
ozone levels that we would expect to
result from this rule, as described in
Chapter 3 of the RIA. The PFC controls
are projected to result in a very small
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All MSATs:
Without Controls ...................
With Controls ........................
Percent Change ....................
Benzene:
Without Controls ...................
With Controls ........................
Percent Change ....................
2020
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
net improvement in future ozone, after
weighting for population. Although the
net future ozone improvement is small,
some VOC-limited areas in the Eastern
U.S. are projected to have non-negligible
improvements in projected 8-hour
ozone design values due to the PFC
controls. We view these improvements
as useful in meeting the 8-hour ozone
NAAQS. These net ozone improvements
are in addition to reductions in levels of
benzene, a toxic ozone precursor, due to
the PFC controls.
3. PM
As described in section IV.A, the
vehicle standards will reduce emissions
of direct PM. The PM health benefits
that would be associated with these
reductions in PM emissions and
exposure are discussed in section VIII.E
of this preamble. The vehicle and PFC
standards will also reduce VOC
emissions, which contribute to the
secondary formation of PM. In this rule
we have not quantified the impact of the
VOC emission reductions on ambient
PM or associated health effects.
D. What Other Mobile Source Emissions
Control Programs Reduce MSATs?
As described in section IV.A, existing
mobile source control programs in
combination with this rule will reduce
MSAT emissions (not including diesel
PM) by 45% between 1999 and 2030.
The existing mobile source programs
include controls on fuels, highway
vehicles, and nonroad engines and
equipment. These programs are also
reducing hydrocarbons and PM more
generally, as well as oxides of nitrogen.
The sections immediately below
provide general descriptions of these
programs that will be providing MSAT
emission reductions, as well as
voluntary programs such as the National
Clean Diesel Campaign and Best
Workplaces for Commuters. We also
discuss some programs that are
currently being developed. A more
detailed description of mobile source
programs is provided in Chapter 2 of the
RIA.
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1. Fuels Programs
As described in section VI of this
preamble, this rule would supersede the
2001 MSAT rule and certain provisions
of the reformulated gasoline program
and anti-dumping programs. These
programs are described in Chapter 2 of
the RIA.
a. Gasoline Sulfur
EPA’s gasoline sulfur program 130
requires, beginning in 2006, that sulfur
130 65
FR 6822 (February 10, 2000).
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levels in gasoline could be no higher
than 80 ppm as a per-gallon cap, and
must average 30 ppm annually. When
fully effective, gasoline will have 90
percent less sulfur than before the
program. Reduced sulfur levels are
necessary to ensure that vehicle
emission control systems are not
impaired. These systems effectively
reduce non-methane organic gas
(NMOG) emissions, of which some are
air toxics, as well as emissions of NOX.
With lower sulfur levels, emission
control technologies can work longer
and more efficiently. Both new and
older vehicles benefit from reduced
gasoline sulfur levels.
b. Gasoline Volatility
A fuel’s volatility defines its
evaporation characteristics. A gasoline’s
volatility is commonly referred to as its
Reid vapor pressure, or RVP. Gasoline
summertime RVP ranges from about 6–
9 psi, and wintertime RVP ranges from
about 9–14 psi, when additional
volatility is required for starting in cold
temperatures. Gasoline vapors contain a
subset of the liquid gasoline
components, and thus can contain
toxics compounds such as benzene.
Since 1989, EPA has controlled
summertime gasoline RVP primarily as
a VOC and ozone precursor control,
resulting in additional toxics pollutant
reductions.
c. Diesel Fuel
In early 2001, EPA issued rules
requiring that diesel fuel for use in
highway vehicles contain no more than
15 ppm sulfur beginning June 1,
2006.131 This program contains
averaging, banking and trading
provisions during the transition to the
15 ppm level, as well as other
compliance flexibilities. In June 2004,
EPA issued rules governing the sulfur
content of diesel fuel used in nonroad
diesel engines.132 In the nonroad rule,
sulfur levels are limited to a maximum
of 500 ppm sulfur beginning in 2007
(current levels are approximately 3000
ppm). In 2010, nonroad diesel sulfur
levels must not exceed 15 ppm.
EPA’s diesel fuel requirements are
part of a comprehensive program to
combine engine and fuel controls to
achieve the greatest emission
reductions. The diesel fuel provisions
enable the use of advanced emissioncontrol technologies on diesel vehicles
and engines. The diesel fuel
requirements will also provide
immediate public health benefits by
131 66 FR 5002, January 18, 2001. See https://
www.epa.gov/otaq/highway-diesel/index.htm.
132 69 FR 38958, June 29, 2004.
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reducing PM emissions from current
diesel vehicles and engines.
d. Phase-Out of Lead in Gasoline
One of the first programs to control
toxic emissions from motor vehicles was
the removal of lead from gasoline.
Beginning in the mid-1970s, unleaded
gasoline was phased in to replace
leaded gasoline. The phase-out of
leaded gasoline was completed January
1, 1996, when lead was banned from
motor vehicle gasoline. The removal of
lead from gasoline has essentially
eliminated on-highway mobile source
emissions of this highly toxic substance.
2. Highway Vehicle and Engine
Programs
The 1990 Clean Air Act Amendments
set specific emission standards for
hydrocarbons and for PM. Air toxics are
present in both of these pollutant
categories. As vehicle manufacturers
develop technologies to comply with
the hydrocarbon (HC) and particulate
standards (e.g., more efficient catalytic
converters), air toxics are reduced as
well. Since 1990, we have developed a
number of programs to address exhaust
and evaporative hydrocarbon emissions
and PM emissions.
Two of our recent initiatives to
control emissions from motor vehicles
and their fuels are the Tier 2 control
program for light-duty vehicles and the
2007 heavy-duty engine rule. Together
these two initiatives define a set of
comprehensive standards for light-duty
and heavy-duty motor vehicles and their
fuels. In both of these initiatives, we
treat vehicles and fuels as a system. The
Tier 2 control program establishes
stringent tailpipe and evaporative
emission standards for light-duty
vehicles and a reduction in sulfur levels
in gasoline fuel beginning in 2004.133
The 2007 heavy-duty engine rule
establishes stringent exhaust emission
standards for new heavy-duty engines
and vehicles for the 2007 model year as
well as reductions in diesel fuel sulfur
levels starting in 2006.134 Both of these
programs will provide substantial
emissions reductions through the
application of advanced technologies.
We expect 90% reductions in PM from
new diesel engines compared to engines
under current standards.
Some of the key earlier programs
controlling highway vehicle and engine
emissions are the Tier 1 and NLEV
standards for light-duty vehicles and
trucks; enhanced evaporative emissions
standards; the supplemental federal test
procedures (SFTP); urban bus standards;
133 65
134 66
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FR 5001, January 18, 2001.
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and heavy-duty diesel and gasoline
standards for the 2004/2005 time frame.
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3. Nonroad Engine Programs
There are various categories of
nonroad engines, including land-based
diesel engines (e.g., farm and
construction equipment), small landbased spark-ignition (SI) engines (e.g.,
lawn and garden equipment, string
trimmers), large land-based SI engines
(e.g., forklifts, airport ground service
equipment), marine engines (including
diesel and SI, propulsion and auxiliary,
commercial and recreational),
locomotives, aircraft, and recreational
vehicles (off-road motorcycles, ‘‘all
terrain’’ vehicles and snowmobiles).
Chapter 2 of the RIA provides more
information about these programs.
As with highway vehicles, the VOC
standards we have established for
nonroad engines will also significantly
reduce VOC-based toxics from nonroad
engines. In addition, the standards for
diesel engines (in combination with the
stringent sulfur controls on nonroad
diesel fuel) will significantly reduce
diesel PM and exhaust organic gases,
which are mobile source air toxics.
In addition to the engine-based
emission control programs described
below, fuel controls will also reduce
emissions of air toxics from nonroad
engines. For example, restrictions on
gasoline formulation (the removal of
lead, limits on gasoline volatility and
RFG) are projected to reduce nonroad
MSAT emissions because most gasolinefueled nonroad vehicles are fueled with
the same gasoline used in on-highway
vehicles. An exception to this is lead in
aviation gasoline. Aviation gasoline,
used in general (as opposed to
commercial) aviation, is a high octane
fuel used in a relatively small number
of aircraft (those with piston engines).
Such aircraft are generally used for
personal transportation, sightseeing,
crop dusting, and similar activities.
4. Voluntary Programs
In addition to the fuel and engine
control programs described above, we
are actively promoting several voluntary
programs to reduce emissions from
mobile sources, such as the National
Clean Diesel Campaign, anti-idling
measures, and Best Workplaces for
Commuters SM. While the stringent
emissions standards described above
apply to new highway and nonroad
diesel engines, it is also important to
reduce emissions from the existing fleet
of about 11 million diesel engines. EPA
has launched a comprehensive initiative
called the National Clean Diesel
Campaign, one component of which is
to promote the reduction of emissions in
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the existing fleet of engines through a
variety of cost-effective and innovative
strategies. The goal of the Campaign is
to reduce emissions from the 11 million
existing engines by 2014. Emission
reduction strategies include switching
to cleaner fuels, retrofitting engines
through the addition of emission control
devices and engine replacement. For
example, installing a diesel particulate
filter achieves diesel particulate matter
reductions of approximately 90 percent
(when combined with the use of ultra
low sulfur diesel fuel). The Energy
Policy Act of 2005 includes grant
authorizations and other incentives to
help facilitate voluntary clean diesel
actions nationwide.
The National Clean Diesel Campaign
is focused on leveraging local, state, and
federal resources to retrofit or replace
diesel engines, adopt best practices and
track and report results. The Campaign
targets five key sectors: school buses,
ports, construction, freight and
agriculture. Almost 300 clean diesel
projects have been initiated through the
Campaign. These projects will reduce
more than 20,000 PM lifetime tons. PM
and NOX reductions from these
programs will provide nearly $5 billion
in health benefits.
Reducing vehicle idling provides
important environmental benefits. As a
part of their daily routine, truck drivers
often keep their vehicles running at idle
during stops to provide power, heat and
air conditioning. EPA’s SmartWay SM
Transport Partnership is helping the
freight industry to adopt innovative idle
reduction technologies and to take
advantage of proven systems that
provide drivers with basic necessities
without idling the main engine. To date,
there are 80 mobile and stationary idlereduction projects throughout the
country. Emission reductions, on an
annual basis, from these programs are in
excess of 157,000 tons of CO2, 2,000
tons of NOX and 60 tons of PM; over 14
million gallons of fuel are being saved
annually. The SmartWay Transport
Partnership also works with the freight
industry by promoting a wide range of
new technologies such as advanced
aerodynamics, single-wide tires, weight
reduction, speed control and intermodal
shipping.
Daily commuting represents another
significant source of emissions from
motor vehicles. EPA’s Best Workplaces
for Commuters SM program is working
with employers across the country to
reverse the trend of longer, singleoccupancy vehicle commuting. OTAQ
recognizes employers that have met the
National Standard of Excellence for
Commuter Benefits by adding them to
the List of Best Workplaces for
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8459
Commuters. These companies offer
superior commuter benefits such as
transit subsidies for rail, bus, and
vanpools and promote flexi-place and
telework. Emergency Ride Home
programs provide a safety net for
participants. More than 1,600 employers
representing 3.5 million U.S. workers
have been designated Best Workplaces
for Commuters.
Much of the growth in the Best
Workplaces for Commuters program has
been through metro area-wide
campaigns. Since 2002, EPA has worked
with coalitions in over 14 major
metropolitan areas to increase the
penetration of commuter benefits in the
marketplace and the visibility of the
companies that have received this
distinguished designation. Another
significant path by which the program
has grown is through Commuter
Districts including corporate and
industrial business parks, shopping
malls, business improvement districts
and downtown commercial areas. To
date EPA has granted the Best
Workplaces for Commuters ‘‘District’’
designation to over twenty locations
across the country including sites in
downtown Denver, Houston,
Minneapolis, Tampa and Boulder.
5. Additional Programs Under
Development That Will Reduce MSATs
a. On-Board Diagnostics for Heavy-Duty
Vehicles Over 14,000 Pounds
The Agency has proposed on-board
diagnostics (OBD) requirements for
heavy-duty vehicles over 14,000
pounds.135 In general, OBD systems
monitor the operation of key emissions
controls to detect any failure that would
lead to emissions above the standards
during the life of the vehicle. Given the
nature of the heavy-duty trucking
industry, 50-state harmonization of
emissions requirement is an important
consideration. Initially, the Agency
signed a Memorandum of Agreement in
2004 with the California Air Resources
Board which expressed both agencies’
interest in working towards a single,
nationwide program for heavy-duty
OBD. Since that time, California has
established their heavy-duty OBD
program, which will begin
implementation in 2010. EPA’s program
will also begin in 2010. These
requirements will help ensure that the
emission reductions we projected in the
2007 rulemaking for heavy-duty engines
occur in-use.
135 https://epa.gov/obd/regtech/heavy.htm.
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b. Standards for Small Nonroad SparkIgnition Engines
We are developing a proposal for
small nonroad spark-ignition engines,
those typically used in lawn and garden
equipment and in spark-ignition marine
engines. This proposal is being
developed in response to Section 428 of
the Omnibus Appropriations Bill for
2004, which requires EPA to propose
regulations under Clean Air Act section
213 for new nonroad spark-ignition
engines under 50 horsepower. We plan
to propose standards that would further
reduce engine and equipment emissions
for these nonroad categories. We
anticipate that any new standards
would provide significant additional
reductions in exhaust and evaporative
HC (and VOC-based toxics) emissions.
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c. Standards for Locomotive and Marine
Diesel Engines
We are planning to propose more
stringent standards for large diesel
engines used in locomotive and marine
applications, as discussed in a recent
Advance Notice of Proposed
Rulemaking.136 New standards for
marine diesel engines would apply to
engines less than 30 liters per cylinder
in displacement (all engines except for
Category 3). We are considering
standards modeled after our Tier 4
nonroad diesel engine program, which
achieve substantial reductions in PM,
HC, and NOX emissions. These
standards would be based on the use of
high efficiency catalyst aftertreatment
and would also require fuel sulfur
control.
E. How Do These Mobile Source
Programs Satisfy the Requirements of
Clean Air Act Section 202(l)?
The benzene and hydrocarbon
standards in this action will reduce
benzene, 1,3-butadiene, formaldehyde,
acrolein, polycyclic organic matter, and
naphthalene, as well as many other
hydrocarbon compounds that are
emitted by motor vehicles, including
those that are discussed in more detail
in Chapter 1 of the RIA. The emission
reductions expected from today’s
controls are set out in section IV.A and
B of this preamble and Chapter 2 of the
RIA.
EPA believes that the emission
reductions from the standards finalized
today for motor vehicles and their fuels,
combined with the standards currently
in place, represent the maximum
achievable reductions of emissions from
motor vehicles through the application
of technology that will be available,
considering costs and the other factors
136 69
FR 39276, June 29, 2004.
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listed in section 202(l)(2). This
conclusion applies whether one
considers just the compounds listed in
Table 1.1–1 of the RIA, or consider all
of the compounds on the Master List of
emissions, given the breadth of EPA’s
current control programs and the broad
groups of emissions that many of the
control technologies reduce. For
example, EPA has already taken
significant steps to reduce diesel
emissions from motor vehicles (as well
as other mobile sources). As explained
above, we have adopted stringent
standards for on-highway diesel trucks
and buses and these standards control
the air toxics emitted by these motor
vehicles to the extent feasible.
Emissions from motor vehicles can be
chemically categorized as hydrocarbons,
trace elements (including metals) and a
few additional compounds containing
carbon, nitrogen and/or halogens (e.g.,
chlorine). For the hydrocarbons, which
are the vast majority of these
compounds, we believe that with the
controls finalized today, we will control
the emissions of these compounds from
motor vehicles to the maximum amount
currently feasible or currently
identifiable with available information.
Section V of this preamble provides
more details about why the standards
represent maximum achievable
reduction of hydrocarbons from motor
vehicles. Motor vehicle controls do not
reduce individual hydrocarbons
selectively; instead, the maximum
emission reductions are achieved by
controls on hydrocarbons as a group.
There are fuel controls that could
selectively reduce individual air toxics
(e.g., formaldehyde, acetaldehyde, 1,3butadiene), as well as controls that
reduce hydrocarbons more generally.
Section VI of this preamble describes
why the standards we are finalizing
today represent the maximum emission
reductions achievable through fuel
controls, after considering the factors
enumerated in section 202(l)(2) of the
Clean Air Act.
Motor vehicle emissions also contain
trace elements, including metals, which
originate primarily from engine wear
and impurities in engine oil and
gasoline or diesel fuel. EPA does not
have authority to regulate engine oil,
and there are no feasible motor vehicle
controls to directly prevent engine wear.
Nevertheless, oil consumption and
engine wear have decreased over the
years, decreasing emission of metals
from these sources. Metals associated
with particulate matter will be captured
in emission control systems employing
a particulate matter trap, such as will be
used in heavy-duty vehicles meeting the
2007 standards. We believe that
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currently, particulate matter traps, in
combination with engine-out control,
represent the maximum feasible
reduction of both motor vehicle
particulate matter and toxic metals
present as a component of the
particulate matter.
The mobile source contribution to the
national inventory for metal compounds
is generally small. In fact, the emission
rate for most metals from motor vehicles
is small enough that quantitative
measurement requires state-of-the art
analytical techniques that are only
recently being applied to this source
category. We have efforts underway to
gather information regarding trace metal
emissions, including mercury
emissions, from motor vehicles (see
Chapter 1 of the RIA for more details).
A few metals and other elements are
used as fuel additives. These additives
are designed to reduce the emission of
regulated pollutants either in
combination with or without an
emission control device (e.g., a passive
particulate matter trap). Clean Air Act
section 211 (a) and (b) provide EPA with
various authorities to require the
registration of fuel additives by their
manufacturers before their introduction
into commerce. Registration involves
certain data requirements that enable
EPA to identify products whose
emissions may pose an unreasonable
risk to public health. In addition, this
section provides EPA with authority to
require health effects testing to fill any
gaps in the data that would prevent a
determination regarding the potential
for risk to the public. It is under the
section 211 registration program that
EPA is currently generating the
information needed to update an
assessment of the potential human
health risks related to having manganese
in the national fuel supply. Clean Air
Act section 211(c) provides the primary
mechanism by which EPA would take
actions necessary to minimize exposure
to emissions of metals or other additives
to diesel and gasoline.
Existing regulations limit sulfur in
gasoline and diesel fuel to the maximum
amount feasible and will reduce
emissions of all sulfur-containing
compounds (e.g., hydrogen sulfide,
carbon disulfide) to the greatest degree
achievable.137 138 139 For the remaining
compounds (e.g., chlorinated
137 65
FR 6697, February 10, 2000.
FR 5001, January 18, 2001.
139 69 FR 38958, June 29, 2004 (standards for nonroad diesel engines and fuels). Although non-road
vehicles are not ‘‘motor vehicles,’’ and so are not
subject to section 202(1)(2), EPA nevertheless has
adopted standards resulting in the greatest feasible
reductions of mobile source air toxics from these
engines.
138 66
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compounds), we currently have very
little information regarding emission
rates and conditions that impact
emissions. This information would be
necessary in order to evaluate potential
controls under section 202(l). Emissions
of hydrocarbons containing chlorine
(e.g., dioxins/furans) would likely be
reduced with control measures that
reduce total hydrocarbons, just as these
emissions were reduced with the use of
catalytic controls that lowered exhaust
hydrocarbons.
V. New Light-Duty Vehicle Standards
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A. Introduction
The program we are establishing for
vehicles will achieve the same
significant toxics reductions that we
projected for the proposed rule (see
generally 71 FR 15845–15848). The
program is very similar to that proposed
except for a few minor changes made in
response to comments we received.
These changes will improve the
implementation of the program without
significantly changing the program’s
overall emission reductions and
environmental benefits. As described in
this section, we are adopting stringent
new nonmethane hydrocarbon
standards for vehicles to reduce
hydrocarbon (HC) emissions during
vehicle cold temperature operation. As
discussed in the proposal, the current
HC emissions standards are measured
within a range of specified warm
temperatures, and the test procedure
does not include cold temperatures.
Data indicate that cold HC emissions
currently are very high for many
vehicles compared to emissions at
normal test temperatures. The new cold
temperature standards and program
requirements will be phased in starting
in 2010. When fully phased in, the new
standards will further reduce overall
vehicle HC emissions by about 31%, or
by about 883,000 tons in 2030.
By reducing overall HC emissions
from vehicles, we will be significantly
reducing several gaseous toxics
including benzene, formaldehyde, 1,3butadiene, and acetaldehyde. We also
project that the cold temperature
standard will provide concurrent
reductions in direct PM emissions from
vehicles, since the strategies
manufacturers are expected to employ
to reduce cold HC will reduce PM as
well. Although Clean Air Act section
202(l) deals with control of air toxics,
140 Most certification 20 °F hydrocarbon levels are
reported as total hydrocarbon (THC), but NMHC
accounts for approximately 95% of THC as seen in
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and not criteria pollutants like PM, this
co-benefit of cold temperature control is
significant.
We are finalizing the new cold
temperature standards and
implementation schedule essentially as
proposed. We are also adopting several
other related provisions and
requirements largely as proposed. Many
of these provisions will help the
manufacturers smoothly transition to
the new standards in the shortest lead
time possible. They include corporate
average emissions standards, emissions
credits, options for alternative phase-in
schedules, and special provisions for
small businesses. The program also
includes certification and compliance
provisions.
We are also adopting new evaporative
emissions standards, beginning in
model year 2009. The new standards are
essentially the same as those contained
in the California LEVII program.
Manufacturers have been selling 50state evaporative systems that meet both
the Tier 2 and LEVII requirements.
Today’s final rule will ensure that
industry continues this practice.
Sections V.B. and V.C. provide the
details of the new cold temperature and
evaporative emissions standards,
respectively, and briefly discuss some of
the comments we received on the
proposed vehicles program. We have
seriously considered all of the input
from stakeholders in developing the
final vehicles program and believe that
the final rule appropriately addresses
the concerns of all stakeholders. We
provide a full discussion of the
comments we received on vehicles in
Chapter 3 of the Summary and Analysis
of Comments for this rule.
B. What Cold Temperature
Requirements Are We Adopting?
1. Why Are We Adopting a New Cold
Temperature NMHC Standard?
As emissions standards have become
more stringent, manufacturers have
concentrated primarily on controlling
emissions performance just after the
start of the engine in order to further
reduce emissions. To comply with
stringent hydrocarbon emission
standards at 75 °F, manufacturers
developed new emission control
strategies and practices that resulted in
significant emissions reductions at that
start temperature. We expected that
proportional reductions in hydrocarbon
results with both THC and NMHC levels reported.
This relationship also is confirmed in EPA test
programs supporting this rulemaking.
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emissions would occur at other colder
start temperatures as a result of the more
stringent standards. We believe that
there is no engineering reason why
proportional control should not be
occurring on a widespread basis.
In some cases, certification data for
recent model year light-duty vehicles
indicate that individual vehicles did
demonstrate proportional improvements
in hydrocarbon emission results at 20 °F
relative to their 75 °F results, confirming
our belief that proportional control is
feasible and indeed is practiced at least
occasionally. One manufacturer’s
certification results reflected
proportional improvements across
almost its entire vehicle lines, further
supporting that proportional control is
feasible. However, for most vehicles,
certification reports show a sharp rise in
hydrocarbon 140 emissions at 20 ° F
when compared to the reported 75 ° F
hydrocarbon emission levels. Any rise
in hydrocarbon emissions, specifically
nonmethane hydrocarbons (NMHC),
will result in proportional rise in VOCbased air toxics.141 While some increase
in NMHC emissions can be expected
simply due to combustion limitations of
gasoline engines at colder temperatures,
the reported levels of hydrocarbon
emissions seem to indicate a
significantly diminished use of
hydrocarbon emissions controls
occurring at colder temperatures. Thus,
although all vehicle manufacturers have
been highly successful at reducing
emissions at the test start temperature
range, in general, they do not appear to
be capitalizing on NMHC emission
control strategies and technologies at
lower temperatures. This is likely
because compliance with hydrocarbon
standards is not required at 20 degree F
temperatures. (see 71 FR at 15845.)
Today’s rule remedies this by requiring
such compliance.
2. What Are the New NMHC Exhaust
Emissions Standards?
We are finalizing a set of standards
that will achieve proportional NMHC
control from the 75 °F Tier 2 standards
to the 20 °F test point. We expect that
by fully utilizing available Tier 2
hardware and software control
strategies, manufacturers will be able to
achieve this standard without major
changes to Tier 2 vehicle designs or the
use of additional technology. Table V.B–
1 contains the final standards.
141 ‘‘VOC/PM Cold Temperature Characterization
and Interior Climate Control Emissions/Fuel
Economy Impact,’’ Volume I and II, October 2005.
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TABLE V.B–1.—20 °F FTP EXHAUST EMISSION STANDARDS
NMHC sales-weighted fleet
average standard
(grams/mile)
Vehicle GVWR and category
≤6000 lbs: Light-duty vehicles (LDV) & Light light-duty trucks (LLDT) .........................................................................
>6000 lbs: Heavy light-duty trucks (HLDT) up to 8,500 lbs & Medium-duty passenger vehicles (MDPV) up to
10,000 lbs ...................................................................................................................................................................
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As shown in the table, we are
finalizing, as proposed, two separate
sales-weighted fleet average NMHC
standards: 0.3 grams/mile for vehicles at
or below 6,000 pounds (lbs) GVWR and
0.5 grams/mile for vehicles over 6,000
lbs, including MDPVs.142 NMHC
emissions will be measured during the
Cold Federal Test Procedure (FTP) test,
which already requires hydrocarbon
measurement.143 The new standard does
not require additional certification
testing beyond what is required today
with ‘‘worst case’’ model selection of a
durability test group.144
The separate fleet average standards
we are finalizing account for challenges
related to vehicle weight. We examined
certification data from Tier 2 and
interim non-Tier 2 vehicles (i.e.,
vehicles not yet phased into the final
Tier 2 program, but meeting interim
standards established by Tier 2), and
saw a general trend of increased
hydrocarbon levels with heavier GVWR
vehicles. Some comments suggested that
the standard for HLDT/MDPVs should
be the same standard as applies to LDVs
or contain a second future phase that
reduces emissions to those levels. At
this time, we continue to believe that
heavier vehicles have applicationspecific design limitations. Heavier
vehicles generally produce higher
emissions for several reasons. First,
added weight requires additional work
to accelerate the vehicle mass, generally
resulting in higher emissions,
particularly soon after engine start-up.
Second, the design of these emission
control systems may incorporate designs
for specific duty cycles (i.e., trailer
142 Tier 2 created the medium-duty passenger
vehicle (MDPV) category to include larger complete
passenger vehicles, such as SUVs and vans, with a
GVWR of 8,501–10,000 pounds GVWR. Large pickups above 8,500 pounds are not included in the
MDPV category but are included in the heavy-duty
vehicle category.
143 40 CFR Subpart C, § 86.244–94 requires the
measurement of all pollutants measured over the
FTP except NOX.
144 The existing cold FTP test procedures are
specified in 40 CFR Subpart C. In the final rule for
fuel economy labeling, (71 FR 77872, December 27,
2006), EPA revised the cold FTP test protocol to
require manufacturers to run the heater and/or
defroster while conducting the cold FTP test. This
had previously been an optional provision. We do
not believe this requirement will have a significant
impact on emissions.
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towing) that can negatively affect
emissions, particularly during 20° F
cold starts. For example, since the
catalyst may be located further away
from the engine for protection from high
exhaust temperatures during designspecific duty cycles, warm-up of the
catalyst is typically delayed, especially
at colder temperatures. Therefore, we
believe the 0.3 g/mile fleet average
standard for vehicles below 6,000 lbs
GVWR is not technically feasible at this
time for heavier vehicles. We are thus
finalizing a 0.5 g/mile standard for
vehicles over 6000 lbs GVWR, including
both HLDTs (6000 lbs to 8500 lbs) and
MDPVs.
We are finalizing the sales-weighted
fleet average approach as proposed, as
the way to achieve the greatest degree of
emission control for Tier 2 vehicles. At
the same time, this approach allows
manufacturers sufficient lead time and
flexibility to certify different vehicle
groups to different levels, thus lowering
the costs of the program. A fleet average
provides manufacturers with flexibility
to balance challenging vehicle families
with ones that more easily achieve the
standards. We believe this approach is
appropriate because the base Tier 2
program is also based on emissions
averaging, and will result in a mix of
emissions control strategies across the
fleet that have varying cold temperature
capabilities. While the Tier 2 program
continues to phase in, manufacturers are
concurrently developing emissions
control packages. The capabilities of
each Tier 2 package will not be fully
understood until manufacturers are able
to evaluate the potential of the
individual designs to control cold
temperature emissions.
We received several comments from
state and environmental groups
supporting the new cold temperature
standards. Manufacturers indicated
their support of the Agency’s initiative
to seek reductions in MSATs, and one
manufacturer commented that cold
temperature hydrocarbon control is both
effective and logical. Manufacturers
commented that the new standards
would be very challenging, but that the
flexibilities incorporated into the final
rule will significantly help
manufacturers achieve the new
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0.3
0.5
standards. One manufacturer with a
product line limited to vehicles below
6,000 lbs GVWR suggested that the 0.3
g/mile standard was too stringent and
unreasonable based on an assessment of
their current vehicle emission levels.
The manufacturer’s comments did not
provide data or further technical
analysis to substantiate this claim. We
know of no engineering basis for the
standards not being technically
achievable. Moreover, there are about
nine other manufacturers with similar
product lines exclusively below 6,000
lbs GVWR, and they did not provide
similar comments. We continue to
believe that with careful examination of
existing emission control opportunities
at colder temperatures on Tier 2
compliant vehicles, especially given the
lead time provided, manufacturers will
identify strategies to comply with the
new standards across their product
lines.
We are establishing a Family
Emissions Limit (FEL) structure in
which manufacturers will determine
individual FELs for each group of
vehicles certified. These FELs are the
standard for each individual group, and
are averaged on a sales-weighted basis
to demonstrate overall compliance with
the fleet average standards. We are using
the FEL-based approach for the new
cold temperature NMHC standards
because we believe it results in the same
level of environmental benefit but adds
flexibility and leads to cost-effective
compliance strategies. The FEL
approach is discussed further in section
V.B.4 below.
We are applying the new cold
temperature NMHC standards to lightduty gasoline-fueled vehicles. However,
diesel vehicles, alternative-fueled
vehicles, and heavy-duty vehicles will
not be subject to these standards, since
we lack data on which to base
standards. Section V.B.6.a provides a
detailed discussion of applicability and
comments received.
3. Feasibility of the Cold Temperature
NMHC Standards
We believe the new standards will be
challenging but are attainable and
provide the greatest emission reductions
using technology that will be available.
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The feasibility assessment described
below is based on our analysis of the
standard’s stringency given current
emission levels at certification
(considering deterioration, compliance
margin, and vehicle weight), available
emission control techniques, and our
own feasibility testing. In addition,
sections V.B.3–6 describe the lead time
and flexibility within the program
structure, which also contribute to the
achievability of the standards. There are
a number of technologies discussed
below that can be utilized to achieve
these standards. We expect that
manufacturers will employ these
technologies in various combinations,
which will likely vary from vehicle to
vehicle depending on a vehicle’s base
emission control package developed for
Tier 2 compliance. Moreover, as
discussed in section V.D, due to current
Tier 2 phase-in schedules, we are not
yet in a position to evaluate fully the
achievability of standards based on new
technologies that may result when Tier
2 is fully phased in in model year 2009.
Thus, we are not considering more
stringent cold temperature NMHC
standards that would require the
application of new technology to Tier 2
vehicles.
Chapter 8 of the RIA contains vehicle
and nationwide cost estimates,
including capital and development
costs. We believe the estimated costs are
reasonable and the rule is cost-effective,
as shown in section XIII, below. Given
the emission control strategies currently
available, we expect manufacturers to
implement these technologies
successfully without a significant
impact on vehicle noise, energy
consumption, or safety factors.
Although new emissions control
strategies are necessary at cold
temperatures, we do not expect
fundamental Tier 2 vehicle hardware to
change.
Manufacturers commented that the
standards will be extremely challenging
because the standards are based on full
useful life performance and
manufacturers must account for fuel
quality in the field to ensure adequate
performance. Manufacturers also noted
that they must account for a host of
requirements in addition to the new
cold temperature standards, including
Tier 2 and SFTP standards. In response,
we understand the challenges involved
in complying with the new cold
temperature standards and we are
providing the essential lead time for
manufacturers to identify and resolve
any related issues as part of overall
vehicle development. We are also
including several other provisions
discussed below, including an averaging
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program, phase-in, emissions credits,
deficit carry-forward, and in-use
standards that provide manufacturers
with flexibility in transitioning to the
new standards.
a. Currently Available Emission Control
Technologies
We believe that the cold temperature
NMHC standards for gasoline-fueled
vehicles being finalized today are
challenging but attainable with Tier 2
(i.e., existing) level emission control
technologies. Our determination of
feasibility is based on the emission
control hardware and calibration
strategies used today on Tier 2 vehicles.
These emission control technologies are
utilized to meet the stringent Tier 2
standards for HC at the FTP temperature
range of 68 °F to 86 °F, but are not
generally used or activated at colder
temperatures. As discussed in section
V.D, the standards we are finalizing
today will not force changes to Tier 2
compliance strategies. Many current
engine families already achieve
emissions levels at or below the
emission standards being adopted (see
RIA Chapter 5) and accomplish this
through software and calibration control
technologies. However, a significant
number of engine families emit more
than twice the level of the new
standards most likely because they fail
to use the Tier 2 control technologies at
colder temperatures. We believe the
new standards can be met by the
application of calibration and software
approaches similar to those currently
used at 75 °F. Although manufacturers
could use additional hardware to
facilitate compliance with the new
standard, we are not projecting that they
would choose to do so because the
standards can be achieved through
lower-cost calibration and software
strategies. As described in section
V.B.2.c, our own feasibility testing of a
vehicle over 6000 lbs GVWR achieved
NMHC reductions consistent with the
standard through calibration approaches
alone.
In 2002, the European Union (EU)
finalized a ¥7 °C (20 °F) cold HC
requirement.145 While the European
standard is based on a different drive
cycle, manufacturers have developed
individual strategies to comply with this
standard. When the EU implemented
the new cold HC standard in
conjunction with a new 75 °F standard
(Euro4), many manufacturers responded
by employing National Low Emission
145 European Union (EU) Type VI Test (¥7°C)
required for new vehicle models certified as of 1/
1/2002.
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8463
Vehicle (NLEV) 146 level hardware and
supplementing it with advanced cold
start emission control strategies. The EU
similarly determined that heavier
weight vehicles may have duty-cycle
based design limitations and also
adopted a separate unique emission
standard for these vehicles. Many
manufacturers offer common vehicle
models in both European and U.S.
markets. Such manufacturers can
leverage European models to transfer
emission control technologies
successfully used for 20 °F hydrocarbon
control in Europe to their U.S. model
counterparts.
There are several strategies used in
the vehicles that are achieving
proportional improvements in NMHC
emissions at 20 °F FTP. Calibration and
software strategies that can be used
include lean limit fuel strategies, fuel
injection timing,147 elevated idle
speeds, retarded spark timing,
redundant spark timing, and accelerated
closed loop times. These strategies are
consistently and successfully used at 75
°F to meet stringent Tier 2 standards.
We expect that software and/or
calibration changes will perform as well
or better than added hardware. This is
because some hardware such as the
improved catalyst system may not be
usable immediately following the cold
start because it must warm-up to operate
efficiently. Calibration and software
strategies that minimize emissions
produced by the engine during this
period while simultaneously
accelerating usage of the catalyst will be
more effective than most new hardware
options. See RIA Chapter 5 for further
discussion.
In addition to calibration strategies,
some manufacturers may comply with
the new standards by extending the use
of existing Tier 2 hardware to 20 °F. An
example of this is secondary air
systems. Several European models sold
in the U.S. market demonstrate
excellent cold HC performance and
utilize secondary air systems from 75 °F
to 20 °F start temperatures. The
secondary air systems reduce emissions
by injecting ambient air into the
exhaust, thus supplying oxygen for
more complete combustion. This also
supplies supplemental heat to the
catalyst. These systems have been used
extensively to reduce hydrocarbon
emissions at 75 °F starts. Currently, auto
146 NLEV voluntary program introduced
California low emission cars and light-duty trucks
(0–6000 lbs. GVW) into other states beginning in
1999.
147 Meyer, Robert and John B. Heywood, ‘‘Liquid
Fuel Transport Mechanisms into the Cylinder of a
Firing Port-Injected SI Engine During Start-up,’’
SAE 970865, 1997.
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makers are equipping a portion of the
Tier 2 fleet with secondary air systems
for compliance with Tier 2 standards.
Some manufacturers with vehicles
containing secondary air systems
claimed that they are not utilizing them
at temperatures below freezing simply
because of past engineering issues.
Those successfully using secondary air
at 20 °F (mainly European companies)
indicated that these challenges have
been addressed through design changes.
The robustness of these systems below
freezing has also been confirmed with
the manufacturers and with the
suppliers of the secondary air
components.148 While alternative
technologies are available and produce
comparable results, vehicles equipped
with secondary air technology should
meet the new 20 °F standard by utilizing
it at colder temperatures.
b. Feasibility Considering Current
Certification Levels, Deterioration and
Compliance Margin
The standards we are finalizing will
have a full useful life of 120,000 miles,
consistent with Tier 2 standards. We
believe the 0.3 g/mile FEL standard
leaves adequate flexibility for
compliance margins and any emissions
deterioration concerns. Of the vehicles
certified to Tier 2 with available cold
temperature certification data,
approximately 20% of vehicles below
6,000 lbs GVWR had HC levels in the
range of 0.18 to 0.27 g/mile, which is
two to three times the 75 °F Tier 2 bin
5 full useful life standard. These
reported HC levels are from Cold CO
test results for certification test vehicles
with typically only 4,000 mile aged
systems, without full useful life
deterioration applied. Rapid advances
in emission control hardware
technology have lowered deterioration
factors used by manufacturers to
demonstrate full useful life compliance,
usually indicating little or no
deterioration over a vehicle’s lifetime.
These deterioration factors are common
across all required test cycles including
cold temperature testing. Additionally,
manufacturers typically incorporate a
20% to 30% compliance margin to
account for in-use issues that may cause
emissions variability. See RIA Chapter 5
for further discussion and details
regarding current certification levels.
c. Feasibility and Test Programs
While a few of the heavier vehicles
achieved emission levels below the 0.5
g/mile level, there are only limited 20 °F
certification results for Tier 2 compliant
vehicles over 6000 lbs GVWR because
the Tier 2 standards are still phasing in
for these vehicles. Prior to proposal, we
conducted a feasibility study in 20 °F
conditions for Tier 2 vehicles over 6000
lbs GVWR. The test program further
investigated the feasibility of
compliance for heavier vehicles and
assessed their capabilities with typical
Tier 2 hardware. For one vehicle with
models above and below 6,000 lbs
GVWR, we reduced HC emissions by
60–70%, depending on the control
strategy. This vehicle had a baseline
level of about 1.0 g/mile. The results are
well within the 0.5 g/mile standard
including compliance margin, and
within a 0.3 g/mile level on some tests.
We achieved these reductions through
recalibration without the use of new
hardware.
Comments from the auto industry
suggested that the original single vehicle
feasibility test program and the
approach used to reduce emission levels
on the feasibility vehicle were too
simplistic and did not fully account for
competing requirements. The
commenter stated that that Tier 2 FTP
and SFTP requirements have affected
hardware decisions, such as catalyst
location, and make it more difficult to
simultaneously obtain optimal
performance at colder temperatures. For
the final rule, we completed a second
feasibility program to help address the
comments regarding the first feasibility
program. For the second feasibility test
program, we tested a vehicle with some
of the specific challenges listed by the
auto industry which represented a worst
case vehicle from the perspective of
cold temperature emissions control
including catalyst location and a large
displacement engine. The second
feasibility program utilized emission
control methods already practiced in the
production European version of the
vehicle tested, helping to demonstrate
that significant emission controls
through calibration are available to
manufacturers today. Simply utilizing
the European emission controls resulted
in a 32% reduction in NMHC emissions.
The findings from both studies are
provided in detail in the RIA.
While the auto industry did not
question the feasibility of the standards,
they expressed concerns that EPA was
not conveying the complexity of effort
required for full product line
manufacturers to meet the new
standards. We believe that the feasibility
program demonstrated that Tier 2
vehicles, including higher weight
vehicles, currently have existing
emission control capabilities to achieve
the new standards. The extensive
emission data from certification tests
detailed in RIA Chapter 5 provides
substantial support to the assessment
that Tier 2 vehicles generally possess
the necessary technology to achieve the
new standards. In most cases, the
technologies need to be activated and
optimized at colder temperatures
through calibration strategies. However,
we recognize that manufacturers,
particularly full line manufacturers, will
have to do significant development
work to bring their expansive Tier 2
product line into compliance with the
new standards over the vehicles’ full
useful life. This is why we have
included a phase-in of the standards
over 6 model years.
4. Standards Timing and Phase-In
a. Phase-In Schedule
As proposed, we will begin
implementing the standard in the 2010
model year (MY) for LDV/LLDTs and
2012 MY for HLDT/MDPVs. The
implementation schedule, in Table V.B–
2, begins three model years after the
Tier 2 phase-in is complete for each
vehicle class. Manufacturers will
demonstrate compliance with phase-in
requirements through sales projections,
similar to Tier 2, as discussed below in
Section V.B.7.
TABLE V.B–2.—PHASE-IN SCHEDULE FOR 20 °F NMHC STANDARD BY MODEL YEAR
2010
2011
≤6000 lbs (LDV/LLDT) .....................................................................................................
>6000 lbs HLDT and MDPV ............................................................................................
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Vehicle GVWR (category)
25%
............
50%
............
148 Memo to docket ‘‘Discussions Regarding
Secondary Air System Usage at 20°F with European
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2012
75%
25%
Automotive Manufacturers and Suppliers of
Secondary Air Systems,’’ December 2005.
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2013
100%
50%
2014
2015
............
75%
............
100%
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We requested comments on the
proposed start date and duration of the
phase-in schedule. Generally,
manufacturers supported the phase-in
schedule. Commenters indicated that
the stringency of the standards will
increase the development workload and
facility demands, but that the proposed
rule recognized these cost issues and
provided sufficient mechanisms for
phase-in flexibility to help
manufacturers transition to the new
program. One manufacturer with only
LDV and LLDT vehicles in their product
line commented that the required phasein percentage affects a larger portion of
their products compared with other
manufacturers with heavier vehicles,
and therefore the phase-in should be
extended to accommodate construction
of new facilities. Conversely, a nonprofit organization commented that EPA
should begin the program earlier than
we proposed. The organization cited our
assessment that manufacturers could
utilize primarily calibration and
software changes, and not hardware
changes, to achieve compliance.
However, as discussed below, we
believe that the finalized start date and
phase-in schedule will achieve the
greatest amount of emissions reductions
in the shortest feasible amount of time.
EPA must consider lead time in
determining the greatest degree of
emission reduction achievable under
section 202(l) of the Clean Air Act. Also,
for vehicles above 6,000 GVWR, section
202(a) of the Act requires that four years
of lead time be provided to
manufacturers. We believe that lead
time and phase-in schedule is needed to
allow manufacturers to develop
compliant vehicles without significant
disruptions in their product
development cycles. The three-year
period between completion of the Tier
2 phase-in and the start of the new cold
NMHC standard should provide vehicle
manufacturers sufficient lead time to
design their compliance strategies and
to determine the product development
plans necessary to meet the new
standards.
We recognize that the new cold
temperature standards we are finalizing
could represent a significant new
challenge for many manufacturers and
development time will be needed. The
issue of NMHC control at cold
temperatures was not anticipated by
many entities, and research and
development to address the issue is
consequently at a rudimentary stage for
some manufacturers. Lead time is
therefore necessary before compliance
can be demonstrated. While certification
will only require one vehicle model of
a durability group to be tested,
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manufacturers must do development on
all vehicle combinations to ensure full
compliance within the durability test
group. A phase-in is needed because
manufacturers must develop control
strategies for several vehicle lines. Since
manufacturers cannot be expected to
implement the standard over their entire
product line in 2010, we believe a
phase-in allows the program to begin
sooner than would otherwise be
feasible.
As noted at proposal, the lead time
and phase-in are also needed to address
test facility availability issues (see 71 FR
15849). Prior to proposal, manufacturers
raised concerns that a rapid phase-in
schedule would lead to a significant
increase in the demand for their cold
testing facilities, which could
necessitate substantial capital
investment in new cold test facilities to
meet development needs. This is
because manufacturers would need to
use their cold testing facilities not only
for certification but also for vehicle
development. Durability test groups
may be large and diverse and therefore
require significant development effort
and cold test facility usage for each
model. If vehicle development is
compressed into too narrow a time
window, significant numbers of new
facilities would be needed.
Manufacturers were also concerned that
investment in new test facilities would
be stranded at the completion of the
initial development and phase-in
period.
We took these concerns into
consideration when drafting our
proposed rule and are finalizing the
start date and phase-in as proposed
because we continue to believe they
address these issues adequately. Our
finalized phase-in period accommodates
test facilities and work load concerns by
distributing these fleet phase-in
percentage requirements over a fouryear period for each vehicle weight
category (six years total). The staggered
start dates for the phase-in schedule
between the two weight categories
should further alleviate manufacturers’
burden regarding construction of new
test facilities. We recognize that some
manufacturers may still determine that
upgrades to their current cold facility
are needed to handle increased
workload, or that additional shifts must
be added to their facility work
schedules that are not in place today.
The lead time provided and the fouryear phase-in period provides needed
time for vehicle manufacturers to
develop a compliance schedule that
does not significantly interfere with
their future product plans.
Manufacturers commented in support of
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8465
the lead time and phase in provided,
commenting that these program
elements are needed to avoid high test
facility costs.
b. Alternative Phase-In Schedules
We are finalizing provisions, as
proposed, that allow manufacturers to
introduce vehicles earlier than required
in exchange for flexibility to make
offsetting adjustments, on a one-for-one
basis, to the phase-in percentages in
later years. Alternative phase-in
schedules essentially credit the
manufacturer for its early or accelerated
efforts and allow the manufacturer
greater flexibility in subsequent years
during the phase-in. Under these
alternative schedules, manufacturers
would have to introduce vehicles that
meet or surpass the NHMC average
standards before they are required to do
so, or else introduce vehicles that meet
or surpass the standard in greater
quantities than required.
As proposed, we are finalizing
provisions allowing manufacturers to
apply for an alternative phase-in
schedule that would still result in 100%
phase-in by 2013 and 2015,
respectively, for the lighter and heavier
weight categories. As with the primary
phase-in, manufacturers would base an
alternative phase-in on their projected
sales estimates. An alternate phase-in
schedule submitted by a manufacturer
would be subject to EPA approval and
would need to provide the same
emissions reductions as the primary
phase-in schedule. The alternative
phase-in cannot be used to delay full
implementation past the last year of the
primary phase-in schedule (2013 for
LDVs/LDTs and 2015 for HLDTs/
MDPVs).
As proposed, this alternative phase-in
schedule will be acceptable if it passes
a specific mathematical test (see 71 FR
15849). We have designed the test to
provide manufacturers a benefit from
certifying to the standards early, while
ensuring that significant numbers of
vehicles are introduced during each
year of the alternative phase-in
schedule. Manufacturers will multiply
their percent phase-in by the number of
years the vehicles are phased in prior to
the second full phase-in year. The sum
of the calculation will need to be greater
than or equal to 500, which is the sum
from the primary phase-in schedule (4
× 25 + 3 × 50 + 2 × 75 + 1 × 100 = 500).
For example, the equation for LDVs/
LLDTs will be as follows:
(6 × API2008) + (5 × API2009) + (4 ×
API2010) + (3 ×API2011) + (2 ×
API2012) + (1 × API2013) ≥ 500%,
where ‘‘API’’ is the anticipated
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phase-in percentage for the
referenced model year
As described above, the final sum of
percentages for LDVs/LDTs must equal
or exceed 500 ¥ the sum that results
from a 25/50/75/100 percent phase-in.
For example, a 10/25/50/55/100 percent
phase-in for LDVs/LDTs that begins in
2009 will have a sum of 510 percent and
is acceptable. A 10/20/40/70/100
percent phase-in that begins the same
year has a sum of 490 percent and is not
acceptable.
To ensure that significant numbers of
compliant LDVs/LDTs are introduced in
the 2010 time frame (2012 for HLDT/
MDPVs), manufacturers would not be
allowed to use alternative phase-in
schedules that delay the
implementation of the requirements,
even if the sum of the phase-in
percentages ultimately meets or exceeds
500. Such a situation could occur if a
manufacturer delayed implementation
of its compliant production until 2011
and began an 80/85/100 percent phasein that year for LDVs/LDTs. To protect
against this possibility, we are
finalizing, as proposed, that for any
alternative phase-in schedule, the
manufacturer’s API × year factors for
LDV/LLDTs from the 2010 and earlier
model years (2012 and earlier for HLDT/
MDPVs) sum to at least 100. The early
phase-in also encourages the early
introduction of vehicles meeting the
new standard or the introduction of
such vehicles in greater quantity than
required, achieving early emissions
reductions.
One commenter recommended that
EPA carefully consider the added
complexity of allowing alternative
phase-in schedules before including
these provisions in the final rule. In
response, we allowed manufacturers the
option of using similar alternative
phase-ins for Tier 2 and these
provisions have not proven to be
detrimental in the implementation of
the Tier 2 program. We believe the
added flexibility provided to
manufacturers helps them to meet the
new requirements as soon as possible
while also helping to minimize
disruptions to their product plans.
These benefits offset the complexity
added by the alternative phase-in
option.
Manufacturers commented that EPA
should remove the requirement for 2010
to have a sum of 100 because it limits
flexibility and could cause
manufacturers to run a deficit early in
the program. We are retaining this
requirement as proposed, except for the
option discussed in the next paragraph.
In general, this requirement ensures that
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manufacturers introduce complying
vehicles early in the phase-in. The
alternative phase-in is not intended to
postpone introduction of compliant
vehicles; instead, it is to allow an
accelerated introduction of vehicles and
to allow manufacturers the flexibility of
aligning compliance with production
schedules. The commenter’s suggestion
of removing the sum of 100 provision
for MY 2010 and earlier vehicles would
essentially amount to delaying the
program by one year. Since all
manufacturers make LDV/LDTs, the
sum of 100 provision ensures that
environmental benefits are achieved as
soon as possible, while the alternative
phase-in provision as a whole provides
additional flexibility to manufacturers.
As described above, we proposed an
early-year requirement for alternative
phase-in schedules for HLDTs/MDPVs
(see 71 FR 15850). Similar to the LDV/
LDT requirement, we proposed that the
API × year factors from the 2012 and
earlier model years sum to at least 100.
We are finalizing the option of electing
an HLDT/MDPV alternative phase-in
that meets the 500% criteria, including
the 100% criteria for model years 2012
and earlier, as proposed. However,
based upon comments received, we are
revising this provision to allow
additional flexibilities. The comments
pointed out that such a requirement
would pose significant hardship for
limited-line manufacturers who produce
only a narrow range of HLDTs/MDPVs.
For example, a manufacturer who only
sells one configuration in the HLDT/
MDPV category would not have the
option of certifying only 25% of these
vehicles in 2012. To meet our proposed
criteria, that manufacturer would have
to ensure that the model is fully
compliant in 2012 (i.e., 100% of their
HLDTs/MDPVs), eliminating any
flexibility for these manufacturers. To
address this concern, we are allowing
HLDT/MDPV manufacturers the
additional option of employing a phasein not meeting the early year
requirement (sum of 100 in 2012) as
long as their full phase-in is accelerated.
Under this option, we are requiring only
that the full alternative phase-in
equation may meet or exceed 600% for
HLDTs/MDPVs. We believe this will
still yield environmental benefits as
quickly as possible, while not putting an
unreasonable burden on limited-line
manufacturers of HLDTs/MDPVs.
Manufacturers with limited HLDT/
MDPV product offerings will still
achieve 100 percent phase-in of the
HLDTs/MDPVs before the end of the
phase-in schedule in 2015. For example,
a manufacturer that only has one HLDT/
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MDPV family and achieves 100% phasein in 2013 would have a sum of 600%
in the equation:
(6 × 0) + (5 × 0) + (4 × 0) + (3 × 100%)
+ (2 × 100%) + (1 × 100%) = 600%
As noted above, phase-in schedules,
in general, add little flexibility for
manufacturers with limited product
offerings because a manufacturer with
only one or two test groups cannot take
full advantage of a 25/50/75/100 percent
or similar phase-in. Therefore,
consistent with our proposal which
reflected the recommendations of the
Small Advocacy Review Panel (SBAR
Panel), which we discuss in more detail
later in section V.E, manufacturers
meeting EPA’s definition of ‘‘small
volume manufacturer’’ will be exempt
from the phase-in schedules and will be
required simply to comply with the
final 100% compliance requirement.
This provision will only apply to small
volume manufacturers and not to small
test groups of larger manufacturers.
5. Certification Levels
Manufacturers typically certify
groupings of vehicles called durability
groups and test groups, and they have
some discretion on what vehicle models
are placed in each group. A durability
group is the basic classification used by
manufacturers to group vehicles to
demonstrate durability and to predict
deterioration. A test group is a basic
classification within a durability group
used to demonstrate compliance with
FTP 75 °F standards.149 For Cold CO,
manufacturers certify on a durability
group basis, whereas for 75 °F FTP
testing, manufacturers certify on a test
group basis. In keeping with the current
cold CO standards, we are requiring
testing on a durability group basis for
the cold temperature NMHC standard,
as proposed (see 71 FR 15850).
Manufacturers will have the option of
certifying on the smaller test group
basis, as is allowed under current cold
CO standards. Testing on a test group
basis will require more tests to be run
by manufacturers but may provide them
with more flexibility within the
averaging program. In either case, the
worst-case vehicle within the group
from an NMHC emissions standpoint
must be tested for certification.
For the new standard (and consistent
with certification for most section 202
standards), manufacturers will declare a
family emission limit (FEL) for each
group either at, above, or below the fleet
averaging standard. The FEL must be
based on the certification NMHC level,
including deterioration factor, plus the
149 40
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compliance margin manufacturers feel
is needed to ensure in-use compliance.
The FEL becomes the standard for each
group, and each group could have a
different FEL so long as the projected
sales-weighted average level met the
fleet average standard at time of
certification. Like the standard, the FEL
will be set at one significant digit to the
right of the decimal point.
Manufacturers will compute a salesweighted average for the NMHC
emissions at the end of the model year
and then determine credits generated or
needed based on how much the average
is above or below the standard.
One commenter questioned if the FEL
approach would interfere with the Tier
2 program, which uses bins rather than
FELs. We do not believe that the two
approaches create a conflict because
compliance with Tier 2 and the cold
temperature standards operate
independent of one another. Tier 2
standards and bins are not a factor when
manufacturers demonstrate compliance
with the cold temperature standards.
6. Credit Program
As described above, we are finalizing
proposed provisions allowing
manufacturers to average the FELs for
NMHC emissions by sales of their
vehicles and comply with a corporate
average NMHC standard (see 71 FR
15850). In addition, we are finalizing, as
proposed, banking and trading
provisions: when a manufacturer’s
average NMHC emissions from vehicles
certified and sold falls below the
corporate average standard, the
manufacturer may generate credits that
it could save for later use (banking) or
transfer to another manufacturer
(trading). Manufacturers must consume
any credits if their corporate average
NMHC emissions were above the
applicable standard for the weight class.
As proposed, credits may be
generated prior to, during, and after the
phase-in period. Manufacturers could
certify LDVs/LLDTs to standards as
early as the 2008 model year (2010 for
HLDTs/MDPVs) and receive early
NMHC credits for their efforts. They
could use credits generated under these
‘‘early banking’’ provisions after the
phase-in begins in 2010 (2012 for
HLDTs/MDPVs).
One organization opposed the use of
credits from one weight class to offset
debits in another weight class. However,
EPA views the averaging, banking, and
trading (ABT) provisions as an
important element in setting emission
standards reflecting the greatest degree
of emission reduction achievable,
considering factors including cost and
lead time. If there are vehicles that will
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be particularly costly or have a
particularly hard time coming into
compliance with the standard, the ABT
program allows a manufacturer to adjust
the compliance schedule accordingly,
without special delays or exceptions
having to be written into the rule. This
is an important flexibility especially
given the current uncertainty regarding
optimal technology strategies for any
given vehicle line. In these
circumstances, ABT allows us to
consider a more stringent emission
standard than might otherwise be
achievable under the Clean Air Act,
since ABT reduces the cost and
improves the technological feasibility of
achieving the standard. By enhancing
the technological feasibility and costeffectiveness of the new standard, ABT
allows the standard to be attainable
earlier than might otherwise be possible.
Also see, e.g., 69 FR 38996–97, (June 19,
2004), which discusses an ABT program
for nonroad diesel engines, which
allows for use of credits across engine
families. This type of credit use can be
important in enhancing standards’
overall technical feasibility, costeffectiveness, and pace of
implementation.
a. How Credits Are Calculated
As proposed, the corporate average for
each weight class will be calculated by
computing a sales-weighted average of
the FEL NMHC levels to which each
group was certified. As discussed above,
manufacturers will group vehicles into
durability groups or test groups and
establish an FEL for each group. This
FEL becomes the standard for that
group. Consistent with FEL practices in
other vehicle standards, manufacturers
may opt to select an FEL above the test
level. The FEL will be used in
calculating credits. The number of
credits or debits will then be
determined using the following
equation:
Credits or Debits = (Standard ¥ Salesweighted average of FELs to nearest
tenth) × Actual Sales
If a manufacturer’s average was below
the 0.3 g/mi corporate average standard
for LDVs/LDTs (below 0.5 g/mi for
HLDTs/MDPVs), credits would be
generated. These credits could then be
used in a future model year when its
average NMHC might exceed the 0.3 or
the 0.5 standard. Conversely, if the
manufacturer’s fleet average was above
the corporate average standard, banked
credits could offset the difference, or
credits could be purchased from another
manufacturer.
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b. Credits Earned Prior to Primary
Phase-In Schedule
As proposed, we are finalizing
provisions allowing manufacturers to
earn early emissions credits if they
introduce vehicles that comply with the
new standards early and the corporate
average of those vehicles is below the
applicable standard. Early credits could
be earned starting in model year 2008
for vehicles meeting the 0.3 g/mile
standard and in 2010 for vehicles
meeting the 0.5 g/mile standard. These
emissions credits generated before the
start of the phase-in could be used both
during and after the phase-in period and
have all the same properties as credits
generated by vehicles subject to the
primary phase-in schedule. As
mentioned in section V.B.4.b above, we
are also finalizing a provision that
allows manufacturers to apply for an
alternative phase-in schedule for
vehicles that are introduced early. The
alternative phase-in and early credits
provisions would operate independent
of one another.
c. How Credits Can Be Used
A manufacturer can use credits in any
future year when its corporate average is
above the standard, or it can trade
(transfer) the credits to other
manufacturers. Because of separate sets
of standards for the different weight
categories, we are finalizing as proposed
that manufacturers compute their
corporate NMHC averages separately for
LDV/LLDTs and HLDTs/MDPVs. Credit
exchanges between LDVs/LLDTs and
HLDTs/MDPVs will be allowed. This
will provide added flexibility for fullerline manufacturers who may have the
greatest challenge in meeting the new
standards due to their wide disparity of
vehicle types/weights and emissions
levels.
d. Discounting and Unlimited Life
Credits will allow manufacturers a
way to address unexpected shifts in
their sales mix. The NMHC emission
standards in this program are quite
stringent and do not present easy
opportunities to generate credits.
Therefore, we will not discount unused
credits. Further, the degree to which
manufacturers invest the resources to
achieve extra NMHC reductions
provides true value to the manufacturer
and to the environment. We do not want
to take measures to reduce the incentive
for manufacturers to bank credits, nor
do we want to take measures to
encourage unnecessary credit use.
Consequently, NMHC credits will not
have a credit life limit. However, credits
may only be used to offset deficits
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accrued with respect to the new 0.3/0.5
g/mile cold temperature standards, and
cannot be used in Tier 2 or other
programs.
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e. Deficits Can Be Carried Forward
When a manufacturer has an NMHC
deficit at the end of a model year—that
is, its corporate average NMHC level is
above the required corporate average
NMHC standard—the manufacturer will
be allowed to carry that deficit forward
into the next model year. To prevent
deficits from being carried forward
indefinitely, we are finalizing, as
proposed, that manufacturers will not
be permitted to run a deficit for two
years in a row. A deficit carry-forward
may only occur after the manufacturer
used any banked credits. If the deficit
still exists and the manufacturer
chooses not to, or is unable to, purchase
credits, the deficit will be carried over.
At the end of that next model year, the
deficit must be covered with an
appropriate number of credits that the
manufacturer generated or purchased.
Any remaining deficit means that the
manufacturer is not in compliance and
can be subject to an enforcement action.
We believe that it is reasonable to
provide this flexibility to carry a deficit
for one year given the uncertainties that
manufacturers face with changing
market forces and consumer
preferences, especially during the
introduction of new technologies. These
uncertainties can make it hard for
manufacturers to accurately predict
sales trends of different vehicle models.
f. Voluntary Heavy-Duty Vehicle Credit
Program
In addition to MDPV requirements in
Tier 2, we also currently have chassisbased emissions standards for other
complete heavy-duty vehicles (e.g., large
pick-ups and cargo vans) above 8,500
pound GVWR. However, these
standards do not include cold
temperature CO standards. As noted
below in section V.B.6.a, we did not
propose to apply cold temperature
NMHC standards to heavy-duty gasoline
vehicles due to a current lack of
emissions data on which to base such
standards. Accordingly, the final rule
does not contain any provisions for
heavy-duty vehicle standards or credit
program.
Our proposal discussed a few ideas
for voluntary approaches where
manufacturers could earn credits by
including heavy-duty gasoline vehicles
in the program. We only received one
comment regarding a voluntary credit
program for heavy-duty gasoline
vehicles. The organization that
submitted the comment opposed the
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creation of NMHC credits applicable to
other vehicle categories generated by
reductions from heavy-duty vehicles. In
light of this lack of support, as well as
insufficient data, we are not including a
heavy-duty standard or credit program
at this time. We plan to revisit the need
for and feasibility of standards as data
become available.
7. Additional Vehicle Cold Temperature
Standard Provisions
a. Applicability
As proposed, the new cold
temperature NMHC standards apply to
all gasoline-fueled light-duty vehicles
and MDPVs sold nationwide. The cold
NMHC standards do not apply to diesel
vehicles, alternative-fueled vehicles, or
to the non-gasoline portion of flex fuel
vehicles (FFVs).150 We are finalizing as
proposed that FFVs will still require
certification to the applicable cold
NMHC standard, though only when
operated on gasoline. FFVs operating on
ethanol are not subject to the cold
standard. When manufacturers submit
their application for certification for
FFVs (such as FFVs that can run on
gasoline or E85 151), the FFVs must have
been tested using gasoline. The
application must also include a
statement that either confirms the same
control strategies used with gasoline
will be used when operating on ethanol,
or that identifies any differences as an
Auxiliary Emission Control Device
(AECD). Again, dedicated alternativefueled vehicles are not covered.
We requested comment on standards
for vehicles operating on fuels other
than gasoline. Vehicle manufacturers
agreed that the cold NMHC standards
should not apply to diesels and
alternative fuel vehicles, stating that the
standard would capture all but a very
small percentage of air toxics emissions
from the light-duty onroad fleet. We also
received comments in support of a
standard for diesel vehicles. One
organization argued that the EPA must
exercise its authority to gather the
necessary data and establish a cold
temperature NMHC standard for diesel,
alternative fuel, and FFVs, or explain
why such standards are not needed.
A comprehensive assessment of
appropriate standards for diesel vehicles
will require a significant amount of
investigation and analysis of issues such
150 In this preamble, we use the term flex fuel
vehicle (FFV) to mean a vehicle capable of
operating on two or more different fuel types, either
separately or simultaneously. Most FFVs available
today run on gasoline and ethanol mixtures. EPA
regulations use the term ‘‘multi-fuel vehicle’’ when
referring to these vehicles.
151 E85 is a fuel mixture consisting of 85%
ethanol and 15% gasoline.
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as feasibility and costs. While we have
significant amounts of data on which to
base our final standards for light-duty
gasoline vehicles, we have very little
data for light-duty diesels. Currently,
diesel vehicles are not subject to the
cold CO standard, so, unlike the
situation for gasoline motor vehicles
where some certification data under
cold temperature conditions are
available, there is very limited data
available on diesel cold temperature
emissions. Also, many manufacturers
are currently in the process of
developing their diesel product
offerings and the cold temperature
performance of these vehicles cannot
yet be evaluated.
Therefore, at this time, the cold
NMHC standards will not apply to lightduty diesel vehicles. We will continue
to evaluate data for these vehicles as
they enter the fleet and will reconsider
the need for standards. We have
adopted cold temperature FTP testing
for diesels as part of the Fuel Economy
Labeling rulemaking, including NMHC
measurement.152 These testing data
would allow us to assess diesel NMHC
certification levels over time. There are
sound engineering reasons, however, to
expect cold NMHC emissions for diesel
vehicles to be as low as or even lower
than those required for gasoline vehicles
in the finalized standards. This is
because diesel engines operate with
leaner air-fuel mixtures compared to
gasoline engines. Therefore diesels have
fewer engine-out NMHC emissions due
to the abundance of oxygen and more
complete combustion. A very limited
amount of confidential manufacturerfurnished information is consistent with
this engineering hypothesis.
With respect to FFVs, although FFVs
are currently required to certify to the
cold CO standards at 20 °F while
operating on gasoline, there is no cold
testing requirement for these vehicles
while operating on the alternative fuel
at 20 °F. There are little data upon
which to evaluate NMHC emissions
when operating on alternative fuels at
cold temperatures. For FFVs operating
on E85,153 it is difficult to develop a
reasonable standard due to a lack of fuel
specifications, testing protocols, and test
data for the 20 °F cold CO cycle.
Standards reflecting use of other fuels
such as methanol and natural gas pose
similar uncertainty. As in the case of
diesels, it will take time to gain an
152 ‘‘Fuel Economy Labeling of Motor Vehicles;
Revisions to Improve Calculations of Fuel Economy
Estimates,’’ Final Rule, 71 FR 77872, December 27,
2006.
153 E85 is a fuel mixture consisting of 85%
ethanol and 15% gasoline typical of a summer
blend of an ethanol based alternative fuel.
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understanding of these other
technologies in sufficient detail to
support a rulemaking. Therefore, as
proposed, we are not adopting a cold
NMHC testing requirement for FFVs
while operating on the non-gasoline fuel
or for alternative fuel vehicles under
this final rulemaking. However, for
FFVs, we are requiring confirmation
that emission controls used when
operating on gasoline are also used
when operating on the non-gasoline fuel
unless a reasonable exception why they
cannot be used is declared. We will
continue to investigate these other
technologies.
Between the proposed rule and
today’s final rule, we conducted an
initial emissions testing program on a
limited number of FFVs operated on
several blends of gasoline and ethanol at
normal test temperatures and 20 °F. 154
These vehicles were tested on summer
gasoline and E85 under normal test
temperatures and on winter gasoline
and E70 155 at 20 °F. At 20 °F, HC
emissions were significantly higher with
E70 fuel than with gasoline, with the HC
emissions largely consisting of
unburned ethanol generated during the
cold start. The reason for the elevated
HC emission levels is that during cold
starts, ethanol, which is an MSAT, does
not readily burn in the combustion
chamber due to its higher boiling point
(approximately 180 °F). FFVs must start
on the gasoline portion of the alternative
fuel, which can compose as little as
15% of the alternative fuel. Ethanol
emissions are further increased at colder
temperatures because the lower engine
start temperature will require an
increasing amount of the fuel mixture to
start the vehicle and subsequently more
unburned ethanol can escape the
combustion process. However, the
testing also indicates significantly lower
benzene emission levels for FFVs when
operating on the high ethanol blends.
Benzene was 30% to 90% lower on E85
and approximately 30% lower on E70
compared to the levels when run on
gasoline. Acetaldehyde emissions are
significantly higher with E85 relative to
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154 ‘‘Flex Fuel Vehicles (FFVs) VOC/PM Cold
Temperature Characterization When Operating on
Ethanol (E10, E70, E85)’’ February, 2007.
155 E70 is a fuel mixture consisting of 70%
ethanol and 30% gasoline typical of a winter blend
of an ethanol based alternative fuel.
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emissions from gasoline-fueled vehicles,
since it is a byproduct of partial (i.e.,
incomplete) ethanol combustion. In
addition, some other VOC-based toxics
emissions were generally lower with the
vehicles running on E85 and E70
compared with gasoline.
There are many issues that must be
resolved before we are able to establish
a cold temperature standard for FFVs
when run on E85 (and E70 at cold
temperatures). These include feasibility
(i.e., levels that are technically
achievable), cost, test procedures, test
fuel specifications and the appropriate
form of the standard. For example,
because much of the VOC emissions
from FFVs operating on the high ethanol
blends at cold temperatures is unburned
ethanol, we may need to consider
whether higher NMHC level would be
justified or whether an NMHC minus
ethanol standard would have merit. We
plan to address these issues as part of
a broader assessment of E85 emissions
regulatory issues in the future.
One organization commented that
EPA must establish cold temperature
standards for heavy-duty vehicles. Since
there is no 20 °F cold standard for
heavy-duty vehicles, we have no data
for heavy-duty gasoline-fueled vehicles,
but we would expect a range of
emissions performance similar to that of
lighter gasoline-fueled trucks. Due to the
lack of test data on which to base
feasibility and cost analyses, we did not
propose cold temperature NMHC
standards for these vehicles. As
mentioned previously, we plan to revisit
this issue when sufficient data become
available.
b. Useful Life
We are adopting the proposed
requirement that the new cold
temperature standards must be met over
the full useful life of the vehicle,
consistent with other emissions
standards for Tier 2 vehicles. The
‘‘useful life’’ of a vehicle means the
period of use or time during which an
emission standard applies to light-duty
vehicles and light-duty trucks.156 Given
that we expect that manufacturers will
make calibration or software changes to
existing Tier 2 technologies, it is
reasonable for the new cold temperature
156 40
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standards to have the same useful life as
the Tier 2 standards. For LDV/LLDT, the
full useful life values will be 120,000
miles or 10 years, whichever comes
first, and for HLDT/MDPV, full useful
life is 120,000 miles or 11 years,
whichever comes first.157 We did not
receive any comments regarding these
useful life provisions.
c. High Altitude
We do not expect emissions to be
significantly different at high altitude
due to the use of common emissions
control calibrations. Limited data
submitted by a manufacturer suggest
that FTP emissions performance at high
altitude generally follows sea level
performance. Furthermore, there are
very limited cold temperature testing
facilities at high altitudes. Therefore,
under normal circumstances,
manufacturers will not be required to
submit vehicle test data for high
altitude. Instead, manufacturers will be
required to submit an engineering
evaluation indicating that common
calibration approaches will be utilized
at high altitude. Any deviation from sea
level in emissions control practices
must be included in the auxiliary
emission control device (AECD)
descriptions submitted by
manufacturers at certification. In
addition, any AECD specific to high
altitude must include engineering
emission data for EPA evaluation to
quantify any emission impact and
validity of the AECD. We did not
receive any comments regarding these
provisions relating to altitude.
d. In-Use Standards for Vehicles
Produced During Phase-In
As proposed, we are finalizing
provisions for an in-use standard that is
0.1 g/mile higher than the certification
FEL for any given test group for a
limited number of model years. For
example, a test group with a 0.2 g/mile
FEL would have an in-use standard of
0.3 g/mile. This would not change the
FEL or averaging approaches and would
only apply in cases where EPA tests
vehicles in-use to ensure emissions
compliance. Tables V.B–3 and V.B–4
provide the finalized schedule for the
availability of the in-use standards.
157 40
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TABLE V.B–3.—SCHEDULE FOR IN-USE STANDARDS FOR LDVS/LLDTS
Model year of introduction
2008
Models years that the in-use standard is available for carry-over test groups ...............
2008
2009
2010
2011
2009
2009
2010
2011
2012
2010
2010
2011
2012
2013
2011
2011
2012
2013
2012
2012
2013
2014
2013
2013
2014
TABLE V.B–4.—SCHEDULE FOR IN-USE STANDARDS FOR HLDVS/MDPVS
Model year of introduction
2010
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Models years that the in-use standard is available for carry-over test groups ...............
2010
2011
2012
2013
not receive any data that supported the
manufacturer’s assertion, nor any
indication of an acceptable increase
beyond the 0.1 g/mi increment.
Furthermore, no other manufacturers
commented on this provision. We
believe the 0.1 g/mi increment is
sufficient and that anything greater may
result in a reduction of emission
control. Therefore, the interim in-use
standard is finalized as proposed.
This approach is similar to the one
adopted in the Tier 2 rulemaking.158 As
we have indicated, the standards we are
finalizing will be more challenging for
some vehicles than for others. With any
new technology, or even with new
calibrations of existing technology, there
are risks of in-use compliance problems
that may not appear in the certification
process. In-use compliance concerns
may discourage manufacturers from
applying new calibrations or
technologies. Thus, we believe it is
appropriate, for the first few years, for
those vehicles most likely to require the
greatest applications of effort to provide
assurance to the manufacturers that they
will not face recall if they exceed
standards in use by a specified amount.
The in-use standards will be available
for the first few model years of sales
after a test group meeting the new
standards is introduced, according to a
schedule that provides more years for
test groups introduced earlier in the
phase-in. This schedule provides
manufacturers with time to determine
the in-use performance of vehicles and
learn from the earliest years of the
program to help ensure that vehicles
introduced after the phase-in period
meet the final standards in-use. The inuse compliance margin only applies to
carry-over models. That is, once a test
group is certified to the new standards,
it will be carried over to future model
years.
We received one comment on the
provisions for an interim in-use
standard. A manufacturer commented
that the EPA should consider allowing
an interim in-use increment greater than
0.1 g/mi to account for known
variability in in-use conditions and
vehicle technologies. However, we did
8. Monitoring and Enforcement
As proposed, manufacturers must
either report that they met the relevant
corporate average standard in their
annual reports to the Agency, or show
via the use of credits that they have
offset any exceedance of the corporate
average standard. Manufacturers must
also report their credit balances or
deficits. EPA will monitor the program.
As in Tier 2, the averaging, banking
and trading program will be enforced
through the certificate of conformity
that manufacturers must obtain in order
to introduce any regulated vehicles into
commerce.159 The certificate for each
test group will require all vehicles to
meet the emissions level to which the
vehicles were certified, and will be
conditioned upon the manufacturer
meeting the corporate average standard
within the required time frame. If a
manufacturer fails to meet this
condition, the vehicles causing the
corporate average exceedance will be
considered to be not covered by the
certificate of conformity for that engine
family. A manufacturer will be subject
to penalties on an individual vehicle
basis for sale of vehicles not covered by
a certificate.
EPA will review the manufacturer’s
sales to designate the vehicles that
caused the exceedance of the corporate
158 ‘‘Control of Air Pollution from New Motor
Vehicles: Tier 2 Motor Vehicle Emissions Standards
and Gasoline Sulfur Control Requirements,’’ Final
Rule, 65 FR 6796, February 10, 2000.
159 ‘‘Control of Air Pollution from New Motor
Vehicles: Tier 2 Motor Vehicle Emissions Standards
and Gasoline Sulfur Control Requirements,’’ Final
Rule, 65 FR 6797, February 10, 2000.
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2011
2011
2012
2013
2014
2012
2012
2013
2014
2015
2013
2013
2014
2015
2014
2014
2015
2016
2015
2015
2016
average standard. We will designate as
nonconforming those vehicles in those
test groups with the highest certification
emission values first, continuing until
we reach a number of vehicles equal to
the calculated number of noncomplying
vehicles, as determined above. In a test
group where only a portion of vehicles
are deemed nonconforming, we will
determine the actual nonconforming
vehicles by counting backwards from
the last vehicle produced in that test
group number. Manufacturers will be
liable for penalties for each vehicle sold
that is not covered by a certificate.
As proposed, we will condition
certificates to enforce the requirements
that manufacturers not sell credits that
they have not generated. A
manufacturer that transfers credits it
does not have will create an equivalent
negative credit balance or deficit that
the manufacturer must make up by the
reporting deadline for the same model
year. A credit deficit in such cases at the
reporting deadline will be a violation of
the conditions under which EPA issued
the certificate of conformity. EPA will
identify the nonconforming vehicles in
the same manner described above and
nonconforming vehicles will not be
covered by the certificate.
In the case of a trade that resulted in
a negative credit balance that a
manufacturer could not cover by the
reporting deadline for the model year in
which the trade occurred, both the
buyer and the seller will be liable,
except in cases involving fraud. We
believe that holding both parties liable
will induce the buyer to exercise
diligence in assuring that the seller has
or will be able to generate appropriate
credits and will help to ensure that
inappropriate trades do not occur.
We did not propose any new
compliance monitoring activities or
programs for vehicles. These vehicles
will be subject to the certification
testing provisions of the CAP2000
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rule.160 We are not requiring
manufacturer in-use testing to verify
compliance. There is no cold CO
manufacturer in-use testing requirement
today (similarly, we do not require
manufacturer in-use testing for SCO3
standards under the Supplemental
Federal Test Procedures (SFTP) program
largely due to the limited availability of
the test facilities). As noted earlier,
manufacturers have limited cold
temperature testing capabilities and we
believe these facilities will be needed
for product development and
certification testing. However, we have
the authority to conduct our own in-use
testing program for exhaust emissions to
ensure that vehicles meet standards over
their full useful life. We will pursue
remedial actions when substantial
numbers of properly maintained and
used vehicles fail any standard in-use.
We also retain the right to conduct
Selective Enforcement Auditing of new
vehicles at manufacturers’ facilities.
The use of credits will not be
permitted to address Selective
Enforcement Auditing or in-use testing
failures. The enforcement of the
averaging standard will occur through
the vehicle’s certificate of conformity. A
manufacturer’s certificate of conformity
will be conditioned upon compliance
with the averaging provisions. If a
manufacturer failed to meet the
corporate average standard and did not
obtain appropriate credits to cover its
shortfalls in that model year or in the
subsequent model year (see deficit carry
forward provision in section V.B.5.e.),
then the certificate for the affected test
groups will be void for all past, present,
and future sales related to that
certificate. Manufacturers will need to
track their certification levels and sales
unless they produced only vehicles
certified to NMHC levels below the
standard and did not plan to bank
credits. We did not receive any
comments on the provisions regarding
Selective Enforcement Auditing or
conditions of certification.
C. What Evaporative Emissions
Standards Are We Finalizing?
We are finalizing as proposed a set of
numerically more stringent evaporative
emission standards for all light-duty
vehicles, light-duty trucks, and
medium-duty passenger vehicles. The
standards we are finalizing are
equivalent to California’s LEV II
standards, and these standards are
shown in Table V.C–1. The new
standards represent about a 20 to 50
percent reduction (depending on
vehicle weight class and type of test) in
the diurnal plus hot soak standards
currently in place for Tier 2 vehicles.161
As with the current Tier 2 evaporative
emission standards, the standards we
are finalizing vary by vehicle weight
class. The increasingly higher standards
for heavier weight class vehicles
account for larger vehicle sizes and fuel
tanks (non-fuel and fuel emissions).162
TABLE V.C–1.—FINAL EVAPORATIVE EMISSION STANDARDS
[Grams of hydrocarbons per test]
3-Day diurnal
plus hot soak
Vehicle class
LDVs ................................................................................................................................................................
LLDTs ..............................................................................................................................................................
HLDTs ..............................................................................................................................................................
MDPVs .............................................................................................................................................................
1. Current Controls and Feasibility of
the New Standards
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As described earlier, we are reducing
the numerical level of the evaporative
emission standards applicable to
diurnal and hot soak emissions from
light-duty vehicles and trucks by about
20 to 50 percent. These new standards
are meant to be effectively the same as
the evaporative emission standards in
the California LEV II program. Although
the new standards are numerically more
stringent, as we explained at proposal,
we believe they are essentially
equivalent to the current Tier 2
standards because of differences in
testing requirements (see 71 FR 15854;
also see section V.C.5 below for further
discussion of such test differences, e.g.,
test temperatures and fuel volatilies). As
discussed in the proposal, this view is
supported by manufacturers and by
160 71
FR 2810, January 17, 2006.
emissions (or diurnal breathing losses)
means evaporative emissions as a result of daily
temperature cycles or fluctuations for successive
days of parking in hot weather. Hot soak emissions
(or hot soak losses) are the evaporative emissions
from a parked vehicle immediately after turning off
161 Diurnal
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0.50
0.65
0.90
1.00
Supplemental
2-day diurnal
plus hot soak
0.65
0.85
1.15
1.25
current industry practices. Based on this
understanding, we do not project
additional VOC or air toxics reductions
from the evaporative standards we are
finalizing today.163 Also, we do not
expect additional costs since we expect
that manufacturers will continue to
produce 50-state evaporative systems.
Therefore, harmonizing the federal and
California LEV–II evaporative emission
standards will codify (i.e., lock in) the
approach manufacturers have already
indicated they are taking for 50-state
evaporative systems.
We believe this action is an important
step to ensure that the federal standards
reflect the lowest possible evaporative
emissions, and it also will provide states
with certainty that the emissions
reductions we project to occur due to
50-state compliance strategies will in
fact occur. In addition, the new
standards will assure that manufacturers
continue to use available fuel system
materials to minimize evaporative
emissions.
In the proposal, we considered but
did not propose more stringent
evaporative requirements contained in
the partial zero-emission vehicle (PZEV)
portion of California’s LEV II program.
The LEV II program includes PZEV
credits for vehicles that achieve near
zero emissions (e.g., LDV evaporative
emission standards for both the 2-day
and 3-day diurnal plus hot soak tests are
0.35 grams/test, which are more
stringent than the standards finalized
today). State and local air quality
organizations commented that EPA
should adopt the PZEV evaporative
standards. In addition, they indicated
that California Air Resources Board
estimates the additional per vehicle cost
the hot engine. For the evaporative emissions test
procedure, diurnal and hot soak emissions are
measured in an enclosure commonly called the
SHED (Sealed Housing for Evaporative
Determination).
162 Larger vehicles may have greater non-fuel
evaporative emissions, probably due to an increased
amount of interior trim, vehicle body surface area,
and larger tires.
163 U.S. EPA, Office of Air and Radiation, Update
to the Accounting for the Tier 2 and Heavy-Duty
2005/2007 Requirements in MOBILE6, EPA420–R–
03–012, September 2003.
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for a PZEV evaporative emission system
to be about $10.20. They commented
that EPA should consider the
introduction of a similar standard for
some vehicles. Moreover, they urged us
to commit in the final rule to pursue
actions to achieve further evaporative
emission reductions in the future.
However, auto manufacturers
supported the proposed evaporative
emission standards. They indicated that,
as EPA tentatively concluded in the
proposed rule, it would be
inappropriate for EPA to propose more
stringent standards. Manufacturers
noted that PZEVs have been limited to
a small fraction of the light-duty fleet,
mainly small 4-cylinder passenger cars,
and that the PZEV standard has not
proven feasible across the light-duty
fleet. Furthermore, it is significantly
more costly to comply with the PZEV
evaporative emission standard because
of significant modifications needed to
the evaporative emission control system
and fuel system. Also, the auto
manufacturers suggested that emission
benefits, if any, of the PZEV standard
would be minimal.
We have decided not to set more
stringent PZEV-equivalent evaporative
standards at this time. The limited
PZEV vehicles available today require
additional evaporative emissions
technology or hardware (e.g.,
modifications to fuel tank and
secondary canister) beyond what will be
needed for vehicles meeting the new
standards that we are adopting today.
As we described in the proposed rule,
at this time, we need to better
understand the evaporative system
modifications (i.e., technology, costs,
lead time, etc.) potentially needed
across the vehicle fleet to meet PZEVlevel standards before we can fully
evaluate whether it is feasible to
consider more stringent standards. For
example, at this point we cannot
determine whether the PZEV
technologies could be used fleetwide or
on only a limited set of vehicles. Thus,
in the near term, we lack any of the
information necessary to determine if
further reductions are feasible, and if
they could be achievable considering
cost, energy and safety issues. Moreover,
sufficient new information or data was
not provided from commenters on the
proposed rule to close these gaps in our
understanding. However, we intend to
consider more stringent evaporative
emission standards in the future.
2. Evaporative Standards Timing
As proposed, we will implement
today’s evaporative emission standards
in model year 2009 for LDVs/LLDTs and
model year 2010 for HLDTs/MDPVs.
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Many manufacturers already have begun
or completed model year 2008
certification. Thus, model year 2009 is
the earliest practical start date of new
standards for LDVs/LLDTs. For HLDTs/
MDPVs, the phase-in of the existing Tier
2 evaporative emission standards ends
in model year 2009. Thus, the model
year 2010 is the earliest start date
possible for HLDTs/MDPVs. As
discussed earlier, since we believe that
manufacturers already meet these
standards, there is no need for
additional lead time beyond the
implementation dates we are finalizing.
3. Timing for Flex Fuel Vehicles
For FFVs, the phase-in schedule we
are finalizing for the new evaporative
standards is somewhat different than
the phase-in schedule we proposed for
these vehicles. In the proposal, we
recognized that manufacturers will need
a few additional years of lead time to
adjust their evaporative systems to
comply with the new evaporative
emission standards for FFVs operating
on the non-gasoline fuel, typically E85
(see 71 FR 15855). The existing
regulations require that FFVs or E85
vehicles (vehicles designed to operate
on fuel that is 85 percent ethanol and 15
percent gasoline) certify on both
gasoline and E10 (E10 is a fuel
containing 10 percent ethanol and 90
percent gasoline) for the evaporative
emissions test procedure. E10 is
considered the ‘‘worst case’’ test fuel for
evaporative emissions, because it is the
ethanol blend that results in greater
evaporative emissions. Thus, E10 is the
evaporative certification test fuel for E85
vehicles. Thus far, only a few FFV
systems have been certified to California
LEV–II standards on E10 fuel. Vehicles
not certified with E10 in California are
sold as gasoline-fueled only vehicles
rather than FFVs. Some manufacturers
are still developing FFVs for future
introduction and the evaporative control
systems in some cases have not been
fully field tested and certified on the
E10 fuel. Therefore, certifying FFVs to
the new standards on the E10 fuel
(which is required by Tier 2) represents
a new requirement for manufacturers.
We proposed that FFVs would need to
meet the new evaporative emission
certification standards on the nongasoline fuel beginning in the fourth
year of the program—2012 for LDVs/
LLDTs and 2013 for HLDTs/MDPVs. We
proposed that the evaporative emission
standards would be implemented in
2009 for LDVs/LLDTs and 2010 for
HLDTs/MDPVs for the FFVs when run
on gasoline (along with gasoline
vehicles that are not flex fuel). At the
time of proposal, we believed this
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additional three years of lead time
would provide sufficient time for
manufacturers to make adjustments to
their new evaporative systems for FFVs,
which are limited product lines.
Auto manufacturers commented that
additional lead time and flexibility
beyond that proposed is needed for the
non-gasoline portion of FFVs.
Manufacturers requested the following
revisions to the proposed timing of the
new evaporative emission standards for
the non-gasoline portion of FFVs:
—combine the LDV/LLDT and HLDT/
MDPV fleets,
—implement the phase-in of this
combined fleet starting in 2013, and
—permit a three-year phase-in of 30
percent/60 percent/100 percent for
this combined fleet.
The auto industry indicated that for
many manufacturers of FFVs, the new
standards are considered new emission
requirements for their FFVs. This is
unlike the situation for gasoline
vehicles, where EPA intends to codify
what is already being done in practice
rather than imposing any new
requirements on gasoline vehicles. For
most manufacturers of FFVs, there is no
demonstrated capability at this time to
meet the new evaporative emission
standards from which to begin planning
compliance to the new standards. Also,
manufacturers expressed that there are
important enough differences between
fuels in the gasoline and FFVs (or the
non-gasoline portion of FFVs) that
independent evaluations of FFVs on
gasoline and the non-gasoline fuel are
warranted.
In addition, auto manufacturers stated
that as interest in alternative fuels has
increased due to energy supply
concerns, they are suddenly considering
widespread introduction of FFV models,
across entire product lines. What was at
first a limited offering of a few models
may become more offerings across a
manufacturer’s full line of products in
the timeframe of this rulemaking. The
auto industry argues that these new
developments justify lead time
provisions commensurate with those
when a new emission requirement
applies across a manufacturer’s lightduty product line.
They also indicated that model
renewals provide the most cost-effective
timing for the introduction of new
emissions capability to meet the new
standards. At this time, some
manufacturers plan model renewals for
multiple vehicle lines from model years
2013 to 2015. Allowing a three-year
phase-in for the non-gasoline portion of
FFVs provides more opportunities for
scheduled model renewals to coincide
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with implementation dates for the new
standards. Planning, engineering, and
development activities needed to meet
these new standards can be
incorporated into the model redesign
activities.
We believe that many of the concerns
presented by manufacturers supporting
additional lead time are valid. Most
manufacturers have less experience
meeting the new standards on the nongasoline portion of FFVs compared to
gasoline vehicles. The new standards
will apply beginning in model year 2012
with a three-year phase-in, 30/60/100
percent, for LDVs/LLDTs and HLDTs/
MDPVs grouped together (see Table
V.C–2). Although auto manufacturers
requested a start date of 2013 for a
combined fleet, we believe the
additional flexibilities we are providing
(three-year phase-in and grouping
LDVs/LLDTs and HLDTs/MDPVs
together) is sufficient flexibility for the
8473
production of FFVs. There is enough
time between now and the
implementation dates or phase-in
schedule (2012 through 2014) for
manufacturers to coordinate model
renewals with the introduction of
broader product offerings of FFVs. See
the Summary and Analysis of
Comments of this rulemaking for further
discussion of comments and our
responses to comments.
TABLE V.C–2.—PHASE-IN SCHEDULE FOR NON-GASOLINE PORTION OF FFVS: EVAPORATIVE EMISSION STANDARDS*
Vehicle GVWR (Category)
2012
≤6000 lbs (LDVs/LLDTs) and > 6000 lbs (HLDTs and MDPVs) ................................................
2013
30%
2014
60%
100%
*Phase-in schedules are grouped together for LDVs/LLDTs and HLDTs/MDPVs.
Provisions for in-use evaporative
emission standards similar to those
described below in section V.C.4 do not
apply to the non-gasoline portion of
FFVs. We believe that three to five
additional years to prepare vehicles (or
evaporative families) to meet the
certification standards, and to
simultaneously make vehicle
adjustments from the federal in-use
experience of other vehicles (including
those that are not FFVs) is sufficient to
resolve any issues for FFVs. Also, we
did not receive comments requesting
additional flexibility beyond the phasein schedule for certification vehicles
discussed earlier. Therefore, we are
finalizing our proposal not to provide
additional in-use compliance margin to
FFVs. According to the phase-in
schedule for a combined fleet in Table
V.C–2, the evaporative emission
standards will apply both for
certification and in-use beginning in
2012 for LDVs/LLDTs and HLDTs/
MDPVs.
4. In-Use Evaporative Emission
Standards
As described earlier in this section,
we are adopting evaporative emission
standards that are equivalent to
California’s LEV II standards. Currently,
the Tier 2 evaporative emission
standards are the same for certification
and in-use vehicles. However, the
California LEV II program permits
manufacturers to meet less stringent
standards in-use for a short time in
order to account for potential variability
in-use during the initial years of the
program when technical issues are most
likely to arise.164 The LEV II program
specifies that in-use evaporative
emission standards of 1.75 times the
certification standards will apply for the
first three model years after an
evaporative family is first certified to
the LEV II standards (only for vehicles
introduced prior to model year 2007, the
year after 100 percent phase-in).165 166
An interim three-year period was
considered sufficient to accommodate
any technical issues that may arise.
Federal in-use conditions may raise
unique issues (e.g., salt/ice exposure) for
evaporative systems certified to the new
standards (which are equivalent to the
LEV II standards), and thus, we will
adopt a similar, interim in-use
compliance provision for vehicles
subject to these new federal standards.
As with the LEV II program, this
provision will enable manufacturers to
make adjustments for unforeseen
problems that may occur in-use during
the first three years of a new evaporative
family. We believe that a three-year
period is enough time to resolve these
problems, because it allows
manufacturers to gain real world
experience and to make adjustments to
a vehicle within a typical product cycle.
Depending on the vehicle weight class
and type of test, the Tier 2 certification
standards are 1.3 to 1.9 times the LEV
II certification standards. On average the
Tier 2 standards are 1.51 times the LEV
II certification standards. Thus, to
maintain the same level of stringency
for the in-use evaporative emission
standards provided by the Tier 2
program, we will apply the Tier 2
standards in-use for only the first three
model years after an evaporative family
is first certified under today’s new
standards, instead of using the LEV II
1.75 multiplier approach described
above. Since the new evaporative
emission certification standards
(equivalent to LEV II standards) will be
implemented in model year 2009 for
LDVs/LLDTs and model year 2010 for
HLDTs/MDPVs, these same certification
standards will apply in-use beginning in
model year 2012 for LDVs/LLDTs and
model year 2013 for HLDTs/MDPVs.167
The schedule for in-use evaporative
emissions standards are shown in
Tables V.C.–3 and V.C.–4 below.
TABLE V.C–3.—SCHEDULE FOR IN-USE EVAPORATIVE EMISSION STANDARDS FOR LDVS/LLDTS
Model year of introduction
2009
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Models Years That Tier 2
2009
164 California Air Resources Board, ‘‘LEV II’’ and
‘‘CAP 2000’’ Amendments to the California Exhaust
and Evaporative Emission Standards and Test
Procedures for Passenger Cars, Light-Duty Trucks
and Medium-Duty Vehicles, and to the Evaporative
Emission Requirements for Heavy-Duty Vehicles,
Final Statement of Reasons, September 1999.
165 1.75 times the 3-day diurnal plus hot soak and
2-day diurnal plus hot soak standards.
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166 For example, evaporative families first
certified to LEV II standards in the 2005 model year
shall meet in-use standards of 1.75 times the
evaporative certification standards for 2005, 2006,
and 2007 model year vehicles.
167 For example, evaporative families first
certified to the new LDV/LLDT evaporative
emission standards in the 2011 model year will be
required to meet the Tier 2 LDV/LLDT evaporative
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2011
2010
2011
emission standards in-use for 2011, 2012, and 2013
model year vehicles (applying Tier 2 standards inuse will be limited to the first three years after
introduction of a vehicle), and 2014 and later model
year vehicles of such evaporative families will be
required to meet the new LDV/LLDT evaporative
emission standards in-use.
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TABLE V.C–3.—SCHEDULE FOR IN-USE EVAPORATIVE EMISSION STANDARDS FOR LDVS/LLDTS—Continued
Model year of introduction
2009
Standards Apply to In-use Vehicles ............................................................................................
2010
2010
2011
2011
2011
2012
2012
2013
TABLE V.C–4.—SCHEDULE FOR IN-USE EVAPORATIVE EMISSION STANDARDS FOR HLDTS/MDPVS
Model year of introduction
2010
Models Years That Tier 2 Standards Apply to In-use Vehicles ..................................................
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5. Existing Differences Between
California and Federal Evaporative
Emission Test Procedures
As described above, the levels of the
California LEV II evaporative emission
standards are seemingly more stringent
than EPA’s Tier 2 standards, but due to
differences in California and EPA
evaporative test requirements, EPA and
most manufacturers view the programs
as similar in stringency. The Tier 2
evaporative program requires
manufacturers to certify the durability
of their evaporative emission systems
using a fuel containing the maximum
allowable concentration of alcohols
(highest alcohol level allowed by EPA in
the fuel on which the vehicle is
intended to operate, i.e., a ‘‘worst case’’
test fuel). Under current requirements,
this fuel would be about 10 percent
ethanol by volume.168 We are retaining
these Tier 2 durability requirements for
the new evaporative emissions program.
California does not require this
provision. To compensate for the
increased vulnerability of system
components to alcohol fuel,
manufacturers have indicated that they
will produce a more durable evaporative
emission system than the Tier 2
numerical standards would imply, using
the same low permeability hoses and
low loss connections and seals planned
for California LEV II vehicles.
As shown in Table V.C–3, in addition
to the maximum alcohol fuel content for
durability testing, the other key
differences between the federal and
California test requirements are fuel
volatilities, diurnal temperature cycles,
and running loss test temperatures.169
The EPA fuel volatility requirement is 2
psi greater than that of California. The
168 Manufacturers are required to develop
deterioration factors using a fuel that contains the
highest legal quantity of ethanol available in the
U.S.
169 Running loss emissions means evaporative
emissions as a result of sustained vehicle operation
(average trip in an urban area) on a hot day. The
running loss test requirement is part of the 3-day
diurnal plus hot soak test sequence.
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high end of EPA’s diurnal temperature
range is 9° F lower than that of
California. Also, EPA’s running loss
temperature is 10° F lower than
California’s.
2011
2010
2011
2012
2012
2011
2012
2013
2012
2013
2014
California results. Thus, we are
finalizing provisions that would allow
certification to the new evaporative
emission standards in accordance with
California test conditions and test
procedures without pre-approval from
EPA.
TABLE V.C–3.—DIFFERENCES IN TIER
2 AND LEV II EVAPORATIVE EMIS- D. Additional Exhaust Control Under
SION TEST REQUIREMENTS
Normal Conditions
We received comments
recommending that EPA harmonize
exhaust emissions standards with the
Fuel volatility (Reid
California LEV II program. We also
Vapor Pressure in
received comments from manufacturers
psi): .......................
9
7 stating that more stringent tailpipe
Diurnal temperature
standards beyond Tier 2 were not
cycle (degrees F):
72–96
65–105
warranted and that the difference
Running loss test
between Tier 2 and LEV II would not be
temperature (degrees F): ................
95
105 meaningful. As discussed in the
proposal (71 FR 15856), we did not
propose to further align the federal
Currently, California accepts
light-duty exhaust emissions control
evaporative emission results generated
program with that of California. We
on the federal test procedure (using
federal test fuel), because available data continue to believe, for reasons
discussed below, that it would not be
indicates the federal procedure to be a
appropriate to adopt more stringent
‘‘worst case’’ procedure. In addition,
tailpipe standards under normal test
manufacturers can currently obtain
conditions beyond those contained in
federal evaporative certification based
Tier 2. It is possible that a future
upon California results (meeting LEV II
standards under California fuels and test evaluation could result in EPA
reconsidering the option of harmonizing
conditions), if they obtain advance
the Tier 2 program with California’s
approval from EPA.170
Auto manufacturers commented that
LEV-II program or otherwise seeking
meeting the new standards can be
emission reductions beyond those of the
achieved more effectively if they are
Tier 2 program and those being finalized
today.171 A full analysis of the
provided greater flexibility in the
comments is available in the Summary
certification process. They
and Analysis of Comments document
recommended that EPA allow federal
for this final rule.
evaporative certification to the new
As explained earlier, section 202(l)(2)
standards, which are equivalent to
requires EPA to adopt regulations that
California’s LEV II standards, through
contain standards which reflect the
California evaporative testing results
greatest degree of emissions reductions
without obtaining advance approval.
achievable through the application of
Since we are harmonizing federal
technology that will be available, taking
evaporative standards with the LEV II
into consideration existing motor
evaporative emission standards in
today’s rule, we believe that for the new
171 See Sierra Club v. EPA, 325 F. 3d at 480 (EPA
standards it is unnecessary to continue
can reasonably determine that no further reductions
to require this advance approval for
in MSATs are presently achievable due to
Test Requirement
EPA
Tier 2
170 Currently,
California
LEV II
EPA may require comparative data
from both federal and California tests.
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uncertainties created by other recently promulgated
regulatory provisions applicable to the same
vehicles).
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vehicle standards, the availability and
costs of the technology, and noise,
energy and safety factors. The cold
temperature NMHC program finalized
today is appropriate under section
202(l)(2) as a near-term control: that is,
a control that can be implemented
relatively soon and without disruption
to the existing vehicle emissions control
program. We did not propose additional
long-term controls (i.e., controls that
require longer lead time to implement)
because we lack the information
necessary to assess their
appropriateness. We believe it will be
important to address the
appropriateness of further MSAT
controls in the context of compliance
with other significant vehicle emissions
regulations (discussed below).
In the late 1990’s both the EPA and
the California Air Resources Board
finalized new and technologically
challenging light-duty vehicle/truck
emission control programs. The EPA
Tier 2 program focuses on reducing NOX
emissions from the light-duty fleet. In
contrast, the California LEV–II program
focuses primarily on reducing
hydrocarbons by tightening the lightduty nonmethane organic gas (NMOG)
standards.172 Both programs will require
the use of hardware and emission
control strategies not used in the fleet
under previously existing programs.
Both programs will achieve significant
reductions in emissions. Taken as a
whole, the Tier 2 program presents the
manufacturers with significant
engineering challenges in the coming
years. Manufacturers must bring
essentially all passenger vehicles under
the same emission control program
regardless of their size, weight, and
application. The Tier 2 program
represents a comprehensive, integrated
package of exhaust, evaporative, and
fuel quality standards which will
achieve significant reductions in
NMHC, NOX, and PM emissions from all
light-duty vehicles in the program.
These reductions will include
significant reductions in MSATs.
Emission control in the Tier 2 program
will be based on the widespread
implementation of advanced catalyst
and related control system technology.
The standards are very stringent and
will require manufacturers to make full
use of nearly all available emission
control technologies.
Today, the Tier 2 program remains in
its phase-in. Cars and lighter trucks will
172 NMOG includes emissions of nonmethane
hydrocarbons plus all other nonmethane organic air
pollutants (for example, aldehydes), which are
ozone precursors. For gasoline and diesel vehicles,
NMHC and NMOG emissions levels are very
similar.
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be fully phased into the program with
the 2007 model year, and the heavier
trucks won’t be fully entered into the
program until the 2009 model year.
Even though the lighter vehicles will be
fully phased in by 2007, we expect the
characteristics of this segment of the
fleet to remain in a state of transition at
least through 2009, because
manufacturers will be making
adjustments to their fleets as the larger
trucks phase in. The Tier 2 program is
designed to enable vehicles certified to
the LEV–II program to cross over to the
federal Tier 2 program. At this point in
time, however, it is difficult to predict
the degree to which this will occur. The
fleetwide NMOG levels of the Tier 2
program will ultimately be affected by
the manner in which LEV–II vehicles
are certified within the Tier 2 bin
structure, and vice versa. We intend to
carefully assess these two programs as
they evolve and periodically evaluate
the relative emission reductions and the
integration of the two programs.
Today’s final rule addresses toxics
emissions from vehicles operating at
cold temperatures. The technology to
achieve this is already available and we
project that compliance will not be
costly. However, we do not believe that
we could reasonably propose further
controls at this time. There is enough
uncertainty regarding the interaction of
the Tier 2 and LEV–II programs to make
it difficult to evaluate today what might
be achievable in the future. Depending
on the assumptions one makes, the
LEV–II and Tier 2 programs may or may
not achieve very similar NMOG
emission levels. Therefore, the eventual
Tier 2 baseline technologies and
emissions upon which new standards
would necessarily be based are not
known today. Additionally, we believe
it is important for manufacturers to
focus in the near term on developing
and implementing robust technological
responses to the Tier 2 program without
the distraction or disruption that could
result from changing the program in the
midst of its phase-in. We believe that it
may be feasible in the longer term to
seek additional emission reductions
from the base Tier 2 program, and the
next several years will allow an
evaluation based on facts rather than
assumptions. For these reasons, we are
deferring a decision on seeking
additional NMOG reductions from the
base Tier 2 program.
E. Vehicle Provisions for Small Volume
Manufacturers
Before issuing a proposal for this
rulemaking, we analyzed the potential
impacts of these regulations on small
entities. As a part of this analysis, we
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8475
convened a Small Business Advocacy
Review Panel (SBAR Panel, or ‘‘the
Panel’’). During the Panel process, we
gathered information and
recommendations from Small Entity
Representatives (SERs) on how to
reduce the impact of the rule on small
entities, and those comments are
detailed in the Final Panel Report which
is located in the public record for this
rulemaking (Docket EPA–HQ–OAR–
2005–0036). Based on these comments,
we proposed lead time transition and
hardship provisions that will be
applicable to small volume
manufacturers as described below in
section V.E.1 and V.E.2. For further
discussion of the Panel process, see
section XII.C of this rule and/or the
Final Panel Report. We received no
comments on this section in response to
the proposed rulemaking.
As discussed in more detail in section
XII.C, in addition to the major vehicle
manufacturers, three distinct categories
of businesses relating to highway lightduty vehicles would be covered by the
new vehicle standards: small volume
manufacturers (SVMs), independent
commercial importers (ICIs),173 and
alternative fuel vehicle converters.174
We define small volume manufacturers
as those with total U.S. sales less than
15,000 vehicles per year, and this status
allows vehicle models to be certified
under a slightly simpler certification
process. For certification purposes,
SVMs include ICIs and alternative fuel
vehicle converters since they sell less
than 15,000 vehicles per year.
About 34 out of 50 entities that certify
vehicles are SVMs, and the Panel
identified 21 of these 34 SVMs that are
small businesses as defined by the
Small Business Administration criteria
(5 manufacturers, 10 ICIs, and 6
converters). Since a majority of the
SVMs are small businesses and all
SVMs have similar characteristics as
described below in section V.E.1, the
Panel recommended that we apply the
lead time transition and hardship
provisions to all SVMs. These
manufacturers represent just a fraction
of one percent of the light-duty vehicle
and light-duty truck sales. Our final rule
today is consistent with the Panel’s
recommendation.
173 ICIs are companies that hold a Certificate (or
certificates) of Conformity permitting them to
import nonconforming vehicles and to modify these
vehicles to meet U.S. emission standards.
174 Alternative fuel vehicle converters are
businesses that convert gasoline or diesel vehicles
to operate on alternative fuel (e.g., compressed
natural gas), and converters must seek a certificate
for all of their vehicle models.
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1. Lead Time Transition Provisions
In these types of vehicle businesses,
predicting sales is difficult and it is
often necessary to rely on other entities
for technology (see earlier discussions
in section V on technology needed to
meet the new standards).175 176
Moreover, percentage phase-in
requirements pose a dilemma for an
entity such as an SVM that has a limited
product line. For example, it is
challenging for an SVM to address
percentage phase-in requirements if the
manufacturer makes vehicles in only
one or two test groups. Because of its
very limited product lines, a SVM could
be required to certify all their vehicles
to the new standards in the first year of
the phase-in period, whereas a full-line
manufacturer (or major manufacturer)
could utilize all four years of the phasein. Thus, similar to the flexibility
provisions implemented in the Tier 2
rule, the Panel recommended that we
allow SVMs (includes all vehicle small
entities that would be affected by this
rule, which are the majority of SVMs)
the following options for meeting cold
temperature NMHC standards and
evaporative emission standards as an
element of determining appropriate lead
time for these entities to comply with
the standards.
For cold NMHC standards, the Panel
recommended that SVMs simply
comply with the standards with 100
percent of their vehicles during the last
year of the four-year phase-in period.
Since these entities could need
additional lead time and the new
standards for LDVs and LLDTs would
begin in model year 2010 and would
end in model year 2013 (25%, 50%,
75%, 100% phase-in over four years),
we are finalizing, as proposed, a
provision requiring only that SVMs
certify 100 percent of their LDVs and
LLDTs in model year 2013. Also, since
the new standard for HLDTs and
MDPVs would start in 2012 (25%, 50%,
75%, 100% phase-in over four years),
we are finalizing, again as proposed, a
provision requiring that the SVMs
certify 100 percent of their HLDTs and
MDPVs in model year 2015.
In regard to evaporative emission
standards, the Panel recommended that
175 For example, as described later in section
V.E.3, ICIs may not be able to predict their sales
because they are dependent upon vehicles brought
to them by individuals attempting to import
uncertified vehicles.
176 SMVs (those with sales less than 15,000
vehicles per year) include ICIs, alternative fuel
vehicle converters, companies that produce
specialty vehicles by modifying vehicles produced
by others, and companies that produce small
quantities of their own vehicles, but rely on major
manufacturers for engines and other vital emission
related components.
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since the new evaporative emissions
standards would not have phase-in
years, we allow SVMs to simply comply
with standards during the third year of
the program. We have implemented
similar provisions in past rulemakings.
Given the additional challenges that
SVMs face, as noted above, we believe
that this recommendation is reasonable.
Therefore, for a 2009 model year start
date for LDVs and LLDTs, we are
finalizing, as proposed, a provision
requiring that SVMs meet the
evaporative emission standards in
model year 2011. For a model year 2010
implementation date for HLDTs and
MDPVs, we are finalizing the proposed
provision requiring that SVMs comply
in model year 2012.
2. Hardship Provisions
In addition, the Panel recommended
that case-by-case hardship provisions be
extended to SVMs for the cold
temperature NMHC and evaporative
emission standards as an aspect of
determining the greatest emission
reductions feasible. These entities
could, on a case-by-case basis, face
hardship more than major
manufacturers (manufacturers with
sales of 15,000 vehicles or more per
year), and we are finalizing as proposed
this provision to provide what could
prove to be a needed safety valve for
these entities. SVMs will be allowed to
apply for up to an additional 2 years to
meet the 100 percent phase-in
requirements for cold NMHC and the
delayed requirement for evaporative
emissions. As with hardship provisions
for the Tier 2 rule, we are finalizing, as
proposed, a provision providing that
applications for such hardship relief
must be made in writing, must be
submitted before the earliest date of
noncompliance, must include evidence
that the noncompliance will occur
despite the manufacturer’s best efforts to
comply, and must include evidence that
severe economic hardship will be faced
by the company if the relief is not
granted.
We will work with the applicant to
ensure that all other remedies available
under this rule are exhausted before
granting additional relief. To avoid any
perception that the existence of the
hardship provision could prompt SVMs
to delay development, acquisition and
application of new technology, we want
to make clear that we expect this
provision to be rarely invoked, and that
relief would rarely be granted. Today’s
rule contains numerous flexibilities for
all manufacturers and it delays
implementation dates for SVMs. We
would expect SVMs to prepare for the
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applicable implementation dates in
today’s rule.
3. Special Provisions for Independent
Commercial Importers (ICIs)
Although the SBAR panel did not
specifically recommend it, we are
finalizing as proposed provisions
allowing ICIs to participate in the
averaging, banking, and trading program
for cold temperature NMHC fleet
average standards (as described in Table
IV.B.–1), but with appropriate
constraints to ensure that fleet averages
will be met. The existing regulations for
ICIs specifically prohibit ICIs from
participating in emission-related
averaging, banking, and trading
programs unless specific exceptions are
provided (see 40 CFR 85.1515(d)). The
concern is that they may not be able to
predict their sales and control their fleet
average emissions because they are
dependent upon vehicles brought to
them by individuals attempting to
import uncertified vehicles. However,
an exception for ICIs to participate in an
averaging, banking, and trading program
was made for the Tier 2 NOX fleet
average standards (65 FR 6794, February
10, 2000), and today we are finalizing,
as proposed, a similar exception for the
cold temperature NMHC fleet average
standards.
If an ICI is able to purchase credits or
to certify a test group to a family
emission level (FEL) below the
applicable cold temperature NMHC fleet
average standard, the rule allows the ICI
to bank credits for future use. Where an
ICI desires to certify a test group to a
FEL above the applicable fleet average
standard, the rule allows them to do so
if they have adequate and appropriate
credits. Where an ICI desires to certify
to an FEL above the fleet average
standard and does not have adequate or
appropriate credits to offset the
vehicles, we will permit the
manufacturer to obtain a certificate for
vehicles using such a FEL, but will
condition the certificate such that the
manufacturer can only produce vehicles
if it first obtains credits from other
manufacturers or from other vehicles
certified to a FEL lower than the fleet
average standard during that model
year.
Our experience over the years through
certification indicates that the nature of
the ICI business is such that these
companies cannot predict or estimate
their sales of various vehicles well.
Therefore, we do not have confidence in
their ability to certify compliance under
a program that will allow them leeway
to produce some vehicles to a higher
FEL now but sell vehicles with lower
FELs later, such that they were able to
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comply with the fleet average standard.
We also cannot reasonably assume that
an ICI that certifies and produces
vehicles one year, will certify or even be
in business the next. Consequently, we
are finalizing the proposed provision
barring ICIs from utilizing the deficit
carry forward provisions of the ABT
program.
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VI. Gasoline Benzene Control Program
A. Description of and Rationale for the
Gasoline Benzene Control Program
We received comments on a wide
range of issues regarding our proposal of
a gasoline benzene control program. We
have considered these comments
carefully. This notice finalizes a
gasoline benzene control program that is
very similar to the proposed program,
with the inclusion of an upper limit
benzene standard on which we sought
comment.
The gasoline benzene control program
has three main components, each of
which is discussed in this section:
—A gasoline benzene content standard.
In general, refiners and importers will
be subject to an annual average
gasoline benzene standard of 0.62
volume percent (vol%), beginning
January 1, 2011. This single standard
will apply to all gasoline, both
reformulated gasoline (RFG) and
conventional gasoline (CG)
nationwide (except for gasoline sold
in California, which is already
covered by a similar state program).
—An upper limit benzene standard. In
general, this ‘‘maximum average
standard’’ will require that the annual
average of actual benzene levels that
each refinery produces be less than or
equal to 1.3 vol% without the use of
credits, beginning July 1, 2012.177
—An averaging, banking, and trading
(ABT) program. The ABT program
allows refiners and importers to
choose the most economical
compliance strategy (investment in
technology, credits, or both) for
meeting the 0.62 vol% annual average
benzene standard. The program
allows refiners to generate ‘‘early
credits’’ for making qualifying
benzene reductions earlier than
required and allows refiners and
importers to generate ‘‘standard
credits’’ for overcomplying with the
0.62 vol% benzene standard in 2011
and beyond. Credits may be used
interchangeably towards compliance
with the 0.62 vol% standard,
‘‘banked’’ for future use, and/or
transferred nationwide to other
refiners/importers subject to the
177 The per-gallon benzene cap (1.3 vol%) in the
RFG program will continue to apply separately.
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standard. While credits may not be
used to demonstrate compliance with
the 1.3 vol% maximum average
standard, the ABT program in its
entirety provides the refining industry
with significant compliance
flexibility. To achieve compliance
with the 0.62 vol% average standard
in 2011 and beyond, refiners and
importers may use credits generated
and/or obtained under the ABT
program, reduce their gasoline
benzene levels, or any combination of
these.
—Provisions for refiners facing
economic hardship. Refiners
approved as ‘‘small refiners’’ will
have access to special temporary relief
provisions. In addition, any refiner
facing extreme unforeseen
circumstances or extreme hardship
circumstances can apply for
temporary relief.
1. Gasoline Benzene Content Standard
a. Description of the Average Benzene
Content Standard
The program finalized in this rule
requires significant reductions in the
average levels of benzene in gasoline
sold in the U.S. Beginning in 2011, the
average benzene level of all batches of
gasoline produced during a calendar
year at each refinery will need to be at
or below a standard of 0.62 vol%
benzene. Approved small refiners must
comply with this requirement by 2015.
Each gasoline importer will need to
meet the 0.62 vol% standard on average
for its imported gasoline during each
year. The 0.62 vol% average standard
may be met through actual production/
importation of fuel with a benzene
content of 0.62 vol% or less, on average,
and/or by using benzene credits. A
deficit is created when compliance is
not achieved in a given year. This
deficit may be carried forward without
regulatory approval but must be made
up the next year. (See VI.B
(Implementation), below.) While this
subsection focuses on the 0.62 vol%
average standard, refiners and importers
will also be subject to a ‘‘maximum
average benzene standard’’ of 1.3 vol%,
which is discussed below in section
VI.A.1.d.
The 0.62 vol% average benzene
standard applies to all gasoline, both
RFG and CG. Gasoline sold nationwide
is covered by the standard, with the
exception of gasoline sold in California.
California gasoline is covered by
existing State of California benzene
requirements that result in benzene
reductions similar to the federal
program finalized here.
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The 0.62 vol% average benzene
standard and the 1.3 vol% maximum
average standard result in air toxics
emissions reductions that are greater
than required under all existing
gasoline-related MSAT programs. As a
result, upon implementation in 2011,
the regulatory provisions for this
gasoline benzene control program will
become the regulatory mechanism used
to implement the RFG and CG (AntiDumping) annual average toxics
performance requirements and the
annual average benzene content
requirement for RFG. The current RFG
and Anti-Dumping annual average
toxics provisions thus will be replaced
by this benzene control program. This
final benzene control program will also
replace the requirements of the 2001
MSAT rule (‘‘MSAT1’’). In addition, the
program will satisfy certain conditions
of the Energy Policy Act of 2005 (EPAct)
and thus remove the need to revise
individual MSAT1 toxics baselines for
RFG otherwise required by the EPAct. In
all of these ways, this program will
significantly consolidate and simplify
the existing national fuel-related MSAT
regulatory program while achieving
greater overall emission reductions.178
See Section VI.C below for additional
discussion of this issue.
b. Why Are We Finalizing a Benzene
Content Standard?
As discussed in the proposal, we
believe a benzene content standard is
the most cost-effective and most certain
way to reduce gasoline benzene
emissions from vehicles. Fuel benzene
reductions directly and demonstrably
result in benzene emissions reductions
which also results in overall MSAT
emission reductions. Focusing MSAT
control on benzene alone means that the
effectiveness of the control will not be
affected by changes in fuel composition
or vehicle technology. Because benzene
is a small component of gasoline
(around 1 vol%), gasoline octane is not
significantly affected by a reduction in
benzene content. Other fuel changes
that could be undertaken to reduce
MSATs would significantly impact
octane, and replacing that octane would
be costly and could increase emissions
of MSATs other than benzene.
Nonetheless, in addition to proposing to
control fuel-related MSAT emissions by
means of a gasoline benzene content
standard, we sought comment on a
178 Although this program will supersede several
compliance requirements from other programs, we
are retaining certain recordkeeping and reporting
requirements from these programs. For example,
refiners will need to continue to provide gasoline
fuel property data for more than just benzene. This
is discussed in more detail in VI.B below.
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number of alternative approaches,
including control of toxics in addition
to benzene and more stringent limits on
gasoline sulfur and volatility. A number
of commenters expressed support for
some of these alternatives and others
opposed them. In reaching our decision
to finalize a benzene content standard,
we evaluated the comments on each of
the alternative approaches, and we
discuss these next.
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i. Standards That Would Include Toxics
Other Than Benzene
We considered separate standards for
each of the key fuel-related toxics (we
discuss control of aromatic compounds
separately) as well as a total toxics
performance standard.
A Standard for Total Toxics
Performance
Several commenters advocated a
standard in the form of a toxics
emissions performance standard,
analogous to the current MSAT1 and
RFG standards. Some commenters
requested an air toxics standard in
addition to the fuel benzene content
standard we are finalizing. In general,
these commenters expressed concern
that if toxics other than benzene are not
also controlled simultaneously, refiners
may allow the emissions of these other
compounds to increase, even while
benzene is being reduced. Other
commenters requested a toxics standard
instead of fuel benzene control (or as an
alternative compliance option). These
commenters felt that a toxics
performance standard offered more
compliance flexibility. Other
commenters supported our proposed
benzene-only standard, stating that a
total toxics standard would add
complexity without additional benefit.
For several reasons, we continue to
believe that a benzene-only standard is
superior to a toxics emissions
performance standard. First, because
controlling benzene is much more costeffective than controlling emissions of
other MSATs, refiners historically have
preferentially reduced benzene under
the MSAT1 and other air toxics control
programs. This is despite the theoretical
flexibility that refiners have under a
toxics performance standard to change
other fuel parameters instead of
benzene. Thus, even if we were to
express the proposed standard as an air
toxics performance standard, we would
expect the outcome to be the same—
refiners would reduce benzene content
and leave unchanged the levels of other
MSATs.
Even with, or as a result of, this fuel
benzene control, we do not expect
refiners to actively modify their refinery
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operations such that increases will
occur in emissions of the other MSATs
currently controlled under the toxics
performance standards. These other
MSATs are acetaldehyde, formaldehyde,
POM, and 1,3-butadiene, and they are
all affected to varying degrees by VOC
emissions control. VOC emissions are
generally decreasing due to the gasoline
sulfur controls recently phased in along
with tighter vehicle controls under the
Tier 2 program, as well as the vehicle
controls being finalized under this
program (see section V above). In
combination, these changes are
expected to decrease VOC-based MSAT
emissions substantially.
In addition to reductions because of
declining VOC emissions, formaldehyde
emissions are currently, and for the
foreseeable future, declining as MTBE
use ends. See 71 FR 15860.
According to the Complex Model, the
Agency’s current gasoline emissions
compliance model, POM emissions
correlate directly with VOC emissions
(see 40 CFR 80.45(e)(8). Therefore, we
expect significant POM emission
reductions as VOC emissions decline.
For 1,3-butadiene, the fuel parameter
of interest is olefins. Increasing olefins
increases 1,3-butadiene emissions.
However, olefins are expected to
decrease as a result of the
implementation of the gasoline sulfur
program because they are reduced along
with sulfur during the desulfurization
process. Olefins are also often used for
their octane value, but because of
increased ethanol use, this need should
be reduced. As a result, we do not
expect refiners to take actions to
increase olefins, and thus 1,3-butadiene
emissions should not increase. Also,
1,3-butadiene, like other MSATs, is
reduced when VOC is reduced due to
fuel and vehicles standards being
implemented (see 71 FR 15860).
The one MSAT likely to increase in
the future is acetaldehyde. Current
market forces, along with state and
federal policies and requirements such
as the proposed Renewable Fuels
Standard (RFS) Program,179 ensure that
ethanol use will increase, and thus
acetaldehyde as well, since that MSAT
is directly and substantially affected by
ethanol use. Acetaldehyde emissions are
currently about one-seventh the
magnitude of benzene emissions from
motor vehicles, but are increasing
(while formaldehyde emissions are
decreasing) due to the substitution of
ethanol for MTBE in RFG as a result of
state MTBE bans. Any action that
refiners could take to offset the total
toxics increase as a result of
179 71
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acetaldehyde increasing would be
through benzene control, which we are
already requiring to be controlled to the
maximum extent possible. The EPAct,
which charged EPA with developing the
RFS program, also requires an
evaluation of that Act’s impacts on air
quality. Any future control of
acetaldehyde emissions will be based
primarily on the results of that study.
EPA thus believes it premature to act
until we determine a course of future
action reflecting the EPAct study, a draft
of which is due to Congress in 2009.
As described above, with the
exception of acetaldehyde, the benzene
control program will ensure the
certainty of additional MSAT
reductions. Other MSAT emissions are
thus unlikely to increase under this
program. Because an air toxics standard
would not provide any additional
emission reductions, we believe that the
regulatory controls, and the associated
paperwork and the other administrative
costs that would result if standards
explicitly including these other MSATs
were adopted, are not necessary. The
benzene control program will thus
ensure the certainty of additional MSAT
reductions. A toxics emissions
performance standard that would
effectively achieve the same level of
MSAT reduction would be more costly
and complex. For all of these reasons,
we believe a standard in the form of a
benzene content standard will produce
more certain environmental results with
less complexity than a toxics emissions
performance standard, and we are
therefore finalizing only a benzene
content standard.
A Standard for Aromatic Compounds in
Addition to Benzene
In the proposal, we considered MSAT
control through the reduction of the
content of aromatics in addition to
benzene in gasoline. For a number of
reasons, we did not propose such
control (see 71 FR 15860 and 15864).
During the comment period, we
received comments urging EPA to
impose controls on non-benzene
gasoline aromatic compounds, in
addition to controlling benzene. These
commenters believe aromatics control
would provide more toxics emissions
reductions than a benzene-only control
program, and they also believe it would
improve air quality by significantly
reducing fine particulate matter.
Expanded use of E85 and flexible-fuel
vehicles and ETBE were suggested as
ways to replace the octane value which
would be lost if aromatics were reduced.
They also cited other benefits such as
energy independence and reduction of
trade deficits, and stated that costs to
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the refining industry would not be
significant. A significant rebuttal to this
request for aromatics control was
presented by the refining industry.
We note first that regardless of
specific regulatory action to control
aromatics, the increased use of ethanol
in response to current market forces and
state and federal policies (including the
RFS program) will contribute to lower
aromatics levels. This will occur for two
reasons. First, ethanol has historically
been blended downstream of refineries,
either as a ‘‘splash blend’’ or as a
‘‘match blend.’’ In a splash blend, the
ethanol is mixed with finished gasoline.
In a match blend, refiners prepare a
special subgrade of gasoline that, when
blended with ethanol, becomes finished
gasoline. In recent years, match
blending has increased as refiners have
been producing RFG with ethanol, and
it is expected to increase even more as
ethanol use expands. A splash blend
will reduce aromatics by about 3 vol%
by simple dilution.180 A match blend
will reduce aromatics by about 5
vol%.181 With ethanol use expected to
more than double, we expect a
significant reduction in aromatics
levels. Second, with all of this ethanol
there will be excess octane in the
gasoline pool. Thus, not only will
increased ethanol use decrease
aromatics concentrations through
dilution, but refiners will make the
economic decision to use ethanol to
reduce or avoid producing aromatics for
the purpose of increasing octane.
Because of differences in how refiners
will respond to the rapid increase in
ethanol use, it would be difficult to
determine an appropriate level for an
aromatics standard at this time. The
gasoline market is going through an
historic transition now due to the
removal of MTBE, conversion of some
portion of the MTBE production volume
to other high octane blendstock
production, growth of ethanol use, and
the rise in crude oil prices.
Consequently, it is difficult to reliably
project a baseline level of aromatics for
the gasoline pool with any confidence.
This is compounded by a great deal of
uncertainty in knowing how much of
the market ethanol will capture.
Projections by EIA are significantly
higher now than just a few months ago,
and Presidential and Congressional
proposals could easily result in 100% of
gasoline being blended with ethanol.
180 If the aromatics content of a gallon of gasoline
is 30 vol%, adding 10% ethanol dilutes the
aromatic content to about 27 vol%.
181 Section 2.2 ‘‘Effects of Ethanol and MTBE on
Gasoline Fuel Properties’’ in the Renewable Fuel
Standard Program: Draft Regulatory Impact
Analysis, September, 2006.
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Second, aromatics levels vary
dramatically across refineries based on
a number of factors, including refinery
configuration and complexity, access to
other high octane feedstocks, access to
the chemicals market, crude sources,
and premium grade versus regular grade
production volumes. Third, without
knowing with some certainty the range
of aromatics contents of refineries’
gasoline, we cannot determine the
greatest degree of emission reduction
achievable, and also cannot make
reasonable estimates regarding cost, lead
time, safety, energy impacts, etc. As a
result, at this time we would not be able
to determine an appropriate or
meaningful aromatics standard.
For the purpose of reducing total
toxics emissions, fuel benzene control is
far more cost-effective than control of
total aromatics, for a number of reasons.
As we explained in the proposal,
reducing the content of other aromatics
in gasoline is much less effective at
reducing benzene emissions than
reducing fuel benzene content. Based on
the Complex Model,182 roughly 20 times
greater reduction in total aromatics
content is needed to achieve the same
benzene emission reduction as is
achieved by fuel benzene reductions. At
the same time, to broaden the program
to control other aromatics would result
in a significant octane loss. While we
have not yet conducted a thorough
refinery modeling evaluation, based on
existing refinery and market information
the alternative sources of octane (other
than ethanol) appear to be of limited
supply and would be of limited
effectiveness in replacing the octane lost
from any fuel aromatics reductions.
Furthermore, as noted above, the
uncertainty in the extent to which
ethanol will penetrate the market makes
it difficult to project the potential
replacement of aromatics with ethanol.
Any significant reduction in aromatics
would also affect the gasoline and diesel
sulfur reduction programs because
hydrogen, which is used in the
desulfurization process, is produced
when aromatics are produced. If refiners
were required to reduce their aromatics
levels, costs would increase further
because some would have to expand or
182 Total toxics emissions are as calculated by the
Complex Model. This model is the tool used to
determine compliance with the toxics emissions
controls in the RFG, Anti-dumping, and MSAT1
programs. Cost estimates for aromatics control and
analysis of relative benzene emissions with control
of aromatics and benzene are found in Regulation
of Fuels and Fuel Additives; Standards for
Reformulated and Conventional Gasoline; Final
rule, Table VI–A6 of the Regulatory Impact
Analysis, February 16, 1994.
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build new hydrogen production
facilities.
Reducing aromatics would also raise
other environmental concerns that
would need to be addressed in any
regulation. Actions available to
refineries for replacing octane,
including adding ethanol, can increase
other MSATs, as mentioned above. In
addition, some commenters encouraged
the use of the ether derived from
ethanol, ETBE, to make up octane. Any
regulatory action that required or was
based on the use of ETBE would likely
raise issues of potential groundwater
contamination given the groundwater
contamination caused by the use of the
chemically similar MTBE.
There may be compelling reasons to
consider aromatics control in the future,
especially regarding reduction in
secondary PM2.5 emissions, to the extent
that evidence supports a role for
aromatics in secondary PM2.5
formation.183 Unfortunately, there are
limitations in both primary and
secondary PM science and modeling
tools that limit our present ability to
quantitatively predict what would
happen for a given fuel control. Thus, at
this point, we do not feel that the
existing body of information and
analytical tools provide a sufficient
basis to determine if further fuel
aromatics control is warranted.
However, we do feel that additional
research is very important. Test
programs and analyses are planned to
address primary PM issues, including
those examining the role of aromatics.
Also, more work is underway on how
fuel aromatics, including toluene, affect
secondary PM formation, and how
aromatics control should be
incorporated into air quality predictive
models.184
In summary, we believe that
aromatics levels will be falling even
without an aromatics standard, and
aromatics control will need to be
evaluated in the context of what might
be possible beyond what will occur
through the expanded use of ethanol.
Furthermore, any additional control
would be costly and raise a number of
other issues which need further
investigation before EPA could
responsibly initiate such a control effort.
Thus, we have concluded that
additional aromatics control for MSAT
purposes is not warranted at this time.
183 See Chapter 1 in the RIA for more on current
studies on this subject.
184 See Chapter 1 in the RIA for more on current
studies on this subject.
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ii. Control of Gasoline Sulfur and/or
Volatility for MSAT Reduction
In the proposal, we outlined a number
of issues related to further control of
gasoline sulfur content and volatility
(usually described as Reid vapor
pressure, or RVP) as a means of MSAT
emissions reduction.185 (See 71 FR
15861–62.) In both cases, there was
insufficient data on newest technology
vehicles at that time to evaluate their
effectiveness as MSAT controls.
Therefore, we did not propose changes
to existing standards.
We received several comments related
to sulfur and RVP control, but there was
general agreement in the comments
from auto manufacturers and refiners
that sufficient data does not yet exist for
EPA to take action as a part of this rule.
Consequently, we are not taking action
to adopt additional control of gasoline
sulfur or RVP. However, since the
proposal, we have completed a small
fuel effects test program in cooperation
with several automakers to help
evaluate the impact of fuel property
changes on emissions from Tier 2
vehicles. These data suggest that
reducing gasoline sulfur below 30 ppm
could bring significant reductions in
VOC and NOX, but the data relating to
air toxics reductions were not
statistically significant. Unlike past
programs on older technology vehicles,
these data suggest that reducing gasoline
volatility from 9 to 7 psi RVP under
normal testing conditions (75° F) may
actually increase exhaust toxics
emissions. The program did not
examine the impacts of fuel volatility on
evaporative emissions. These data
indicate that there may be benefits to
future fuel control but that more testing
is warranted. More details on the test
program and its results are available in
Chapter 6 of the RIA.
said that we were unaware of other
changes to diesel fuel that could have a
significant effect on MSAT emissions,
and requested comment about limiting
this action to gasoline benzene.
One group of commenters stated in
joint comments that they believe that
EPA needs to do more to protect human
health and the environment from the
effects of diesel exhaust emissions.
While they specifically mention actions
to accelerate the introduction of cleaner
diesel engines, they do not suggest any
additional changes to diesel fuel.
Another commenter, a refiner, believes
that further diesel fuel controls are not
warranted.
Some commenters support control of
the polyaromatic hydrocarbon (PAH)
content of diesel fuel. The actions
refiners are taking to produce ultra-low
sulfur diesel fuel (15 ppm sulfur) are
expected to reduce the PAH content in
diesel fuel.186 In addition, available data
indicate that the advent of exhaust
emission controls on diesel engines
under the recent diesel programs will
reduce exhaust PAH, regardless of any
changes to diesel fuel.
We continue to believe that existing
regulations will achieve the greatest
currently achievable reductions in
MSAT emissions from diesel engines.
EPA will continue to monitor MSAT
issues related to diesel fuel. For
example, there are active programs
underway to measure PAH exhaust
emissions from diesel engines meeting
the 2007 PM engine standards.187
However, at this time, we are not aware
of diesel fuel controls that could
significantly affect MSAT emissions and
commenters did not offer specific
information to the contrary.
Consequently, we have focused our fuelrelated MSAT action on gasoline
benzene, as proposed.
iii. Diesel Fuel Changes
In the proposal, EPA did not propose
additional controls on diesel fuel for
MSAT control. We continue to believe
that the recent highway and nonroad
diesel programs (see section IV. D. 1. c
above) will achieve the greatest
currently achievable reductions in
diesel-related MSAT control (i.e.,
reductions in emissions of diesel
particulate matter and exhaust organic
gases). These emission reductions will
result from the deep cuts in diesel fuel
sulfur that will be implemented in the
same time frame as this gasoline
benzene rule, along with the associated
diesel engine emission control
requirements of the diesel programs. We
c. Why Are We Finalizing a Level of
0.62 vol% for the Average Benzene
Standard?
We considered a range of average
benzene standards, taking into account
technological feasibility as well as cost
and the other enumerated statutory
factors. We received comments from a
variety of parties supporting standards
more stringent than the proposed level
of 0.62 vol%. In general, the refining
industry did not express strong
opposition to a standard of 0.62 vol%.
However, several small refiners opposed
a benzene standard and argued for relief
185 For
further discussion of the impact of these
fuel properties on emissions, see RIA Chapter 7.
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186 Control of Emissions of Air Pollution from
Nonroad Diesel Engines and Fuel—Final Rule,
Section 5.9.4 of the Regulatory Impact Analysis,
June 29, 2004.
187 Health Effects Institute’s Advanced
Collaborative Emissions Study.
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for small refiners if EPA went forward
with such a program. One commenter,
an importer, proposed a standard of 1.0
vol%. None of the commenters
opposing the 0.62 vol% standard
provided analytical support for a less
stringent standard, or addressed how a
less stringent standard might reflect the
greatest emission reductions achievable
based on the statutory factors. We have
considered all of these comments and
reassessed the level of the standard in
light of the key factors we are required
to consider, and have concluded that, as
proposed, 0.62 vol% is the appropriate
level for the average standard, because
it achieves the greatest achievable
emission reductions through the
application of technology that will be
available, considering cost, energy,
safety, and lead time.188 As discussed in
section VI.A.1.d below, we have drawn
this conclusion in the context of the 1.3
vol% maximum average benzene
standard. We summarize our assessment
of technological and economic factors
next.
i. General Technological Feasibility of
Benzene Control
Benzene Control Technologies
We have identified several
technologies that can cost-effectively
reduce gasoline benzene levels and we
assessed their feasibility. These benzene
control technologies function primarily
by controlling the benzene in the
feedstock to and the product stream
from the reformer. They primarily focus
on the reformer because refiners rely on
the reformer to produce aromatic
compounds for their octane content, and
benzene is one of the aromatic
compounds produced. For refiners who
are not actively reducing the benzene in
their gasoline today, we estimate that
the reformer is responsible for about one
half to three quarters of the benzene in
gasoline.
Since the proposal, we learned of a
change in how a particular gasoline
blending stream is being routed in the
refinery which affects its treatability for
reducing benzene. After speaking to
several refiners, we learned that natural
gasoline is being blended differently
into gasoline today because of the need
to address the sulfur in this stream for
compliance with Tier 2. Specifically,
natural gasoline is being blended with
the crude oil before the crude oil is
refined in the refinery. Therefore the
benzene in natural gasoline would be
treated along with the naturally
occurring benzene in crude oil using the
188 EPA does not believe that there are any noise
issues associated with these standards, and no
comments suggested any such issues exist.
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benzene control technologies described
below. We reflected this change in our
refinery modeling.
One approach to reducing gasoline
benzene levels is to reroute around the
reformer the intermediate refiner
streams that have the greatest tendency
to form benzene in the reformer. This
technology is usually termed light
naphtha splitting. Assuming that a
refinery applying this technology is not
applying any sort of benzene control
today, we estimate that this method
reduces the benzene levels of reformate
(the stream leaving the reformer) by 60
percent. This approach requires little or
no capital investments in refineries to
realize the results, but its effectiveness
is limited because it does not address
any of the naturally-occurring benzene
found in crude oil and from natural
gasoline and the other benzene which is
formed in the reformer. Although this
benzene control technology normally
will not achieve the most substantial
benzene control, refiners choosing it
will achieve some measure of benzene
control and then would likely need to
purchase credits to comply with the
0.62 benzene standard.
To achieve deeper benzene control,
refiners with an isomerization unit can
send the rerouted intermediate refinery
stream to their isomerization unit. The
isomerization unit would saturate the
naturally-occurring benzene from crude
oil and natural gasoline in the rerouted
refinery intermediate stream mentioned
above, thus achieving additional
benzene reduction. Using these two
technologies together, refiners will be
able to reduce reformer benzene levels
by an estimated 80 percent. However,
the benzene formed in the reformer
would still not be treated using these
two technologies together.
For even deeper benzene reductions
than benzene precursor rerouting by
itself or in combination with
isomerization, refiners could choose
between benzene saturation and
benzene extraction. Each of these
technologies work by reducing the
benzene levels in the reformate,
achieving an estimated 96 percent
reduction in benzene, assuming that the
refinery is not already taking steps to
control its benzene levels. Benzene
saturation involves using hydrogen to
saturate the benzene into cyclohexane,
which is a compound usually found in
gasoline. Benzene extraction units
chemically extract the benzene from the
rest of the hydrocarbon compounds in
reformate and concentrate it to a high
purity using distillation such that it is
suitable for sale into the chemicals
market. Either of these technologies is
capable of achieving the deepest levels
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of gasoline benzene reductions,
allowing virtually all refiners to meet or
exceed the 0.62 vol% gasoline benzene
standard.
The actual impact of these benzene
control technologies on an individual
refinery’s finished gasoline benzene
content, however, will be a function of
many different refinery-specific factors.
These factors include the types of
refining units in each refinery and the
benzene levels produced by them, and
the extent to which they are already
utilizing one or more of these benzene
control technologies.
Each of the benzene control
technologies associated with the
reformer has been commercially
demonstrated by at least half a dozen
units in U.S. refineries today operating
for at least two years. Also, we did not
receive any comments questioning the
viability of these technologies for
achieving the benzene reduction
attributed to these technologies in the
proposed rule. We therefore conclude
that these technologies can feasibly
achieve the benzene reductions that we
attribute to them. We discuss the
economics for each of these approaches
to benzene reduction in more detail in
section VIII.A. of this preamble, and we
discuss their feasibility and cost in
detail in Chapters 6 and 9 of the RIA.
We evaluated the benzene control
level achievable without the use of
credits by each refinery using either
benzene saturation or extraction, since
this would represent the maximum
technologically feasible level of benzene
control by each refinery. Our refinery
cost model shows that based on the
application of one or the other of these
two benzene technologies, eight
refineries would still not be able to
achieve the final 0.62 vol% benzene
average standard. We believe that these
refineries would, however, be able to
achieve the 1.3 vol% maximum average
standard (which, as explained in section
VI.A.1.d below, must be achieved
without the use of credits) through the
use of one of these technologies.
These eight refineries would be able
to further reduce their gasoline benzene
levels by treating the benzene contained
in other gasoline blendstocks,
particularly light straight run, light
coker naphtha and light hydrocrackate.
We believe that refiners could merge
these streams with their reformate
gasoline stream, so that these other
sources of benzene would be treated
along with the benzene in the reformate
using either benzene saturation or
benzene extraction. The results of this
additional analysis summarized in the
RIA show that these eight refineries
would be able to meet the 0.62 vol%
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average standard if they were to apply
one or more of these additional benzene
control steps, though in some cases it
may be at a considerably higher cost
than through the purchase of credits.
The cost and ultimate feasibility for
controlling the benzene in light straight
run, light coker naphtha and light
hydrocrackate is very difficult to
determine without detailed and
comprehensive knowledge about how
refineries are configured and operated
today. It might be possible for a refinery
to adjust existing distillation units,
either operationally or with minor
capital investments, to change the
cutpoints for these streams. They might
then route the benzene in these streams
to the reformer, where a benzene control
technology would be applied. On the
other hand, changing the cutpoints to
reroute the benzene might require the
addition of a whole new distillation
column, similar in function to a
reformate splitter. Adding such
grassroots distillation columns to make
these splits would be much more costly.
Finally we have not found any
commercially demonstrated benzene
control technologies that can reduce the
benzene of FCC naphtha, the second
largest contributor of benzene to the
gasoline pool.
Impacts on Octane and Strategies for
Recovering Octane Loss
All these benzene reduction
technologies tend to cause a small
reduction in the octane value of the
final gasoline, since benzene is high in
octane (about 101 octane number
((R+M)/2). Understanding how lost
octane will be recovered is critical to
determining the feasibility and cost of
benzene control. Regular grade gasoline
must comply with a minimum 87 octane
number (or a sub-octane rating of 86 for
driving in altitude), while premium
grade gasoline must comply with an
octane rating which ranges from 91 to
93 octane numbers. Gasoline must meet
these octane ratings to be sold at retail.
Routing the benzene precursors around
the reformer reduces the octane of the
six-carbon compound stream (by
foregoing the formation of benzene)
which normally exits the reformer with
the rest of the reformate. Without these
compounds in the reformate, our
refinery model shows that a loss of
octane in the gasoline pool of about 0.14
octane numbers will typically occur. If
this rerouted stream can be sent to an
isomerization unit additional octane
loss will occur due to the saturation of
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benzene 189; however, as described
below, the isomerization unit offsets a
part of the octane loss caused by this
combination of saturation and rerouting.
Benzene saturation and benzene
extraction both affect the octane of
reformate and therefore of the gasoline
pool. Our refinery model estimates that
benzene saturation typically reduces the
octane of gasoline by 0.24 octane
numbers, and benzene extraction
typically reduces the octane of gasoline
by 0.14 octane numbers.
Refiners have several choices
available to them for recovering the lost
octane. One is to blend in ethanol.
Ethanol has a very high octane number
rating of 115. Thus, only a small amount
of ethanol (one percent of the gasoline
pool or less) would be necessary to
offset the octane loss associated with
benzene reductions. Moreover, ethanol
blending will occur for reasons
independent of the benzene control
requirements (and attendant octane loss)
of the present rule. As explained in the
discussion of potential aromatics
controls above, current market forces
and state and federal policies (including
the RFS program) will increase the
volume of renewable fuels, including
ethanol, which is to be blended into
gasoline. The volume of renewable fuels
must increase from around 4 billion
gallons in 2004 to 7.5 billion gallons in
2012 when the renewable fuels
provisions of the RFS are fully
implemented. However, as part of the
Annual Energy Outlook for 2006, the
Energy Information Administration
projects that the economics driven by
higher crude oil prices will result in
more like 9.6 billion gallons of ethanol
use by 2012.
Octane may also be increased by
increasing the severity of the reformer
(which determines the final octane of
the reformate). However, if the refiner is
reducing benzene through precursor
rerouting or saturation, this strategy can
be somewhat counterproductive. This is
because increased severity increases the
amount of benzene in the reformate and
thus increases the cost of saturation and
offsets some of the benzene reduction of
precursor rerouting. Increasing reformer
severity also decreases the operating
cycle life of the reformer, requiring more
frequent regeneration. However, where
benzene extraction is used, increased
reformer severity can improve the
economics of extraction because not
only is lost octane replaced by other
189 The chemical process of benzene saturation in
the isomerization unit is the same as the process
that occurs in a benzene saturation unit, as
described above.
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aromatic compounds, but more benzene
is extracted and sold.
Refiners can also recover lost octane
by increased use of isomerization and
alkylate units. As discussed above,
saturating benzene in the isomerization
unit results in an octane loss, but the
octane loss is partially offset by the
simultaneous formation of branch-chain
compounds in the isomerization unit.
The isomerization unit would only
offset a portion of the octane loss caused
by saturating the benzene if the unit has
sufficient capacity to treat both the fivecarbon hydrocarbons normally sent to
the unit as well as the newly rerouted
six-carbon hydrocarbons. Also, many
refineries produce a high-octane
blendstock called alkylate. Refiners can
alter their refineries to produce more
alkylate or they may be able to purchase
alkylate on the open market. Not only is
alkylate moderately high in octane (93
or 94 octane numbers), but it converts
four-carbon (i.e., butane) compounds
that are too volatile to be blended in
large amounts into the gasoline pool
into heavier compounds that can be
readily blended into gasoline, thus
increasing gasoline volume.
All these means available to refiners
for recovering the octane loss associated
with gasoline benzene reductions are
commercially demonstrated, and we did
not receive any comments questioning
our reliance on them at proposal for
maintaining the octane of the gasoline
pool in the proposal. Therefore, we
conclude that it is feasible for refiners
to recover the octane loss associated
with benzene control.
ii. Appropriateness of the 0.62 vol%
Average Benzene Content Standard
As discussed above, we received
many comments about the proposed
level of the benzene standard. Many
commenters advocated a more stringent
standard, generally pointing to
refineries currently producing gasoline
with benzene levels below the proposed
0.62 vol% standard and stating that the
average standard should be sufficiently
stringent that all refineries, especially
those with higher benzene levels, would
be required to use similar technologies
and achieve similarly low levels. We
also received broad support for the 0.62
vol% standard in the comments from
the refining industry, although several
small refiners opposed imposing a
benzene standard and argued for relief
for small refiners if EPA implemented
the proposed standard. One importer
was concerned that the standard of 0.62
vol% could make it more difficult for
importers to find compliant gasoline
shipments and proposed a standard of
1.0 vol%. None of the commenters
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opposing the 0.62 vol% standard
provided analytical support for a less
stringent standard or addressed how a
less stringent standard might reflect the
greatest emission reductions achievable
based on the statutory factors.
In the proposal, EPA described in
detail what we believe would be the
consequences of average standards of
different stringencies to the overall goals
of the program (see 71 FR 15866–67).
These anticipated consequences relate
in large part to how we believe refiners
would respond to the benzene averaging
and benzene credit trading provisions
that were integral to the proposed
program. For the final rule, we have
reassessed how we believe refiners
would respond to different average
standards. We continue to believe that
increasing the stringency of the average
benzene standard would have the effect
of reducing the number of benzene
credits generated, since fewer refineries
are likely or able to take actions to
significantly reduce benzene further
than required by the standard. This
would reduce the liquidity of the credit
trading market. As discussed in section
VI.A.2, a well functioning averaging,
banking, and trading program is integral
to the achievability of the benzene
standard. With fewer credits available
that are affordable as an alternative to
immediate capital investment,
investment in relatively expensive
benzene saturation equipment would be
necessary for a greater number of
refiners. We specifically considered a
level of 0.50 vol% for the average
standard, which we expected would
require all refineries to install the most
expensive benzene control technologies.
We concluded that this level would
clearly not be achievable, considering
cost. In a related analysis, we also
showed that if, contrary to our
expectations, credits were not easily
available as a compliance option, there
are several refineries for which it may
be technologically feasible to reach
benzene levels below 0.62 vol%, but
only at costs far greater than for most
other refiners.
Decreasing the stringency of the
standard would fail to meet our
obligation under 202(l)(2) to set the
most stringent standard achievable
considering costs and other statutory
factors. First, over the last several years
RFG benzene levels have already been
averaging around 0.62 vol%, and we
have no information to suggest that this
level is not technologically feasible for
the rest of the gasoline pool as well. In
fact, our analysis shows that this level
is feasible for the pool of gasoline as a
whole. Commenters did not provide any
analysis that a standard of 0.62 vol%
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was not the greatest achievable after
considering cost and the other statutory
factors. Second, a standard less stringent
than 0.62 vol% would not achieve a
number of important programmatic
objectives. As shown in Table VI.C–1
below, a 0.62 vol% standard is
necessary to satisfy the conditions on
overall RFG toxics performance
established by EPAct and thus to avoid
the requirement for updated individual
refinery baselines. We believe that any
level for the standard above 0.62 vol%
would require EPA to promulgate
regulations requiring RFG refiners to
continue to maintain individual
refinery-specific baselines, adjusted to
2001–2 as required by EPAct. The
refining industry believes that this
would continue to penalize the cleanest
refineries, constrain their flexibility, and
cause market inefficiencies that increase
costs. They have been strongly
supportive of a program that eliminates
the need for individual refinery
baselines. EPA agrees with these
concerns, and believes that the
nationwide ABT program allowed under
this program will remove these impacts.
Another of EPA’s policy objectives that
has been strongly supported by the
refining industry was establishing the
same standard nationwide for the
combined pool of RFG and CG. The
level of 0.62 vol% allows us to establish
a single combined program for RFG and
CG. In addition, the level of 0.62 vol%
for the standard allows us to streamline
with confidence our toxics regulations
for RFG and CG, so that this benzene
program (along with the gasoline sulfur
program) will become the regulatory
mechanism used to implement the RFG
and CG annual average toxics
performance requirements and the
annual average benzene content
requirement for RFG. Further, we
believe that with such a stringent
benzene standard, refiners should have
the certainty they need for their
investment and planning decisions.
Many comments that supported a
more stringent standard pointed to
average costs projected in the proposal
that are higher than for the proposed
standard, but are not large on a pergallon basis compared to other EPA fuel
programs. However, these commenters
did not address the wide range of
compliance costs for individual
refineries that we discuss in the
proposal (see Chapter 9 of the proposed
and final RIA documents). It is critical
to recognize that as more stringent
average standards are considered, the
costs for many refineries begin to rise
significantly, especially for some
individual technologically-challenged
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refineries. This potential for high costs
at more stringent average standards
exists if, as we expect, the ABT program
functions as it is designed to. If the ABT
program operates less efficiently than
projected, the costs for some individual
refineries could be higher still. (We
discuss issues related to the 1.3 vol%
maximum average standard, which
cannot be met through the use of
credits, in section VI.A.1.d, ‘‘Upper
Limit Benzene Standard,’’ below.)
Based on our analysis of the projected
response of the refining industry to an
average benzene standard, we are
finalizing the 0.62 vol% standard as
proposed. We believe that this average
benzene standard of 0.62, in the context
of the associated ABT program and the
1.3 vol% maximum average standard,
results in the greatest reductions
achievable, taking into account cost and
the other statutory factors in CAA
202(l)(2).
iii. Timing of the Average Standard
Section 202(l)(2) requires that we
consider lead time in adopting any fuel
control for MSATs. We proposed that
refiners and importers meet the 0.62
vol% average benzene standard
beginning January 1, 2011 (January 1,
2015 for small refiners). This date was
based on the industry experience that
most of the technological approaches
that we believe refiners will apply—
rerouting of benzene precursors around
the reformer and use of an existing
isomerization unit—will take less than
two years. The more capital intensive
approaches—saturation and
extraction—generally take two to three
years to complete. The January 1, 2011
date provides nearly four years of lead
time. We believe this is an appropriate
amount of lead time, even taking into
account that other fuel control programs
(notably the Nonroad Diesel program)
will be implemented in the same time
frame.
Some commenters supported earlier
start dates, referring in some cases to the
experience of Canada in regulating
gasoline benzene. However, these
comments failed to acknowledge the
less stringent Canadian standard (0.95
vol%) which naturally takes less lead
time to implement. No commenter
provided information that challenged
our assessments of the technical lead
time for the range of benzene control
approaches that will be implemented.
Other commenters, mostly from the
refining industry, supported a start date
that would be at least four years after
the date of the final rule. For the reasons
described above, we do not believe this
additional time is necessary for this
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program. We are finalizing a start date
of January 1, 2011, as proposed.
We discuss the lead time for the 1.3
vol% maximum average standard,
which takes effect July 1, 2012 for nonsmall refiners and importers, and July 1,
2016 for small refiners, in the next
section.
d. Upper Limit Benzene Standard
In the proposal, we discussed the
potential concern that without an upper
limit, some refiners may choose to allow
their benzene levels to increase, or to
remain unchanged indefinitely.
However, we also said that once an
average standard is in place, any
increase in benzene levels will
necessarily come at the cost of
purchasing additional credits. We
tentatively concluded that this
downward pressure on benzene levels
meant there would likely be no
increases in benzene from any refinery,
whether or not there was an upper limit.
In fact, we concluded that this pressure
would result in actual reductions at
almost all refineries, especially into the
future as refiners try to limit their
reliance on credits as much as and
whenever it is economical to do so (see
71 FR 15867–68).
We nonetheless considered the
implications of an upper limit on the
actual level of benzene in the gasoline
that refiners produce (as opposed to the
level achieved using credits). (See 71 FR
15678–79.) We considered an upper
limit both in the form of a per-gallon
benzene cap and a limit on the average
of actual benzene in gasoline produced
by a refinery (‘‘maximum average
standard’’). Of these two approaches, we
recognized that a per-gallon cap would
be the more rigid. If every batch needed
to meet the cap, there would be no
opportunity to offset benzene spikes
with lower-benzene production at other
times. Even during times of normal
operation, our review of refinery batch
data indicated that unavoidable wide
swings commonly occur in the benzene
content of gasoline batches, even for
refineries that have relatively low
benzene levels on average. A per-gallon
cap could result in refiners halting
gasoline production during short-term
shut-downs of benzene control
equipment or in other temporary
excursions in benzene levels. Unless a
per-gallon limit were generous enough
or included case-by-case exceptions
(eroding the possible benefit of the cap),
many refiners would likely need to
implement much deeper and more
costly reductions in benzene than
would otherwise be necessary, simply to
protect against such fluctuations. For
some refiners, we concluded, a cap
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could make complying with the
program prohibitively expensive.
The other option on which we
solicited comment, a maximum average
standard, would be more flexible. A
maximum average standard would limit
the average benzene content of the
actual production at each refinery over
the course of the year, regardless of the
extent to which credits may have been
used to comply with the 0.62 vol%
average standard. Thus, a maximum
average standard would allow for shortterm benzene fluctuations as long as the
annual average benzene level of actual
production was less than that upper
limit.
Several commenters stated that an
upper limit would add costs without
resulting in additional benefits, and
supported a program without upper
limits. Other commenters, however,
expressed serious concerns about the
potential consequences of a program
without upper limits. Several
commenters were concerned that under
the program as proposed, it would be
possible for refiners to maintain
benzene levels well above the standard
indefinitely while complying through
the use of credits, thus potentially
reducing the benefits of the program
where this gasoline is used. Some
commenters noted that under the
proposed program, gasoline in some
areas could still have significantly
higher benzene levels than in other
parts of the country. These commenters
believe that these projected disparities
raise issues of fairness. While our
modeling of the proposed average
standard suggested that all refineries
were likely to reduce their benzene
levels to some extent and that there
would be significant reductions in
gasoline benzene levels in each PADD,
the commenters noted that an upper
limit would provide a guarantee of
reduction to at least the level of the
upper limit.
After evaluating the results of our
updated refinery analysis and
considering all of the comments, we
have reconsidered the appropriateness
of an upper limit standard. For the
reasons discussed above, we continue to
believe that a per-gallon cap for CG
would be inappropriate for a benzene
control program due to actions
refineries would need to take to protect
against common fluctuations in benzene
content, and the related adverse cost
and energy implications if refineries
invest in deeper benzene reductions or
need to temporarily shut down. In
contrast, the per-gallon cap for RFG of
1.3 vol%, which is currently in place,
functions differently than would a pergallon cap that applied to both the RFG
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and CG pools. The per-gallon cap for
RFG alone is appropriate because the
CG pool provides an outlet for batches
of higher benzene RFG. However, if
such a cap were applied to CG as well,
refiners would be left without an outlet.
As we said in the proposal, any
meaningful level for a per-gallon cap
applying to CG would thus overly
restrict the normal fluctuations in
gasoline benzene (see 71 FR 15869).
On the other hand, we now believe
that the program should include a
maximum average benzene standard, set
at an appropriate level. The maximum
average standard has the strong
advantage of ensuring that the benzene
content of gasoline produced by each
refinery (or imported by each importer)
will average no higher than this
standard, regardless of the use of
credits, providing greater assurance that
actual in-use benzene reductions more
clearly reflect our modeled projections
which form the basis for this rule. At the
same time, the maximum average
standard avoids the serious drawbacks
of a per-gallon cap.
Our refinery modeling is state of the
art, but it cannot predict with high
confidence each refinery’s actions and
how benzene trading will occur in each
instance. We have done a refinery-byrefinery assessment of the most
economical decisions we believe the
industry will make to comply with the
standard. However, in developing the
model, we did not have access to
specific information on many refineries,
much of which is confidential business
information. To fill these gaps, we used
broader industry average information for
a number of key model input parameters
(including benzene levels in crude oil
and in gasoline blendstocks, individual
refinery unit throughput and operating
conditions, distillation ‘‘cut points,’’
and future refinery expansions). Since
there is wide variation in these
important parameters among different
refineries that impacts their baseline
benzene levels and their opportunities
for control, our model’s assumptions
inherently vary from actual refinery
circumstances. Furthermore, by
necessity, our model assumes that all
refineries will, in effect, work
collectively to make the most
economical investment decisions on a
nationwide basis, as though each knew
in advance the investment decisions of
the others. In reality, each individual
refinery will be making its decisions
independently of each other, based on
very limited information about other
refineries’ actions. In addition, our
model assumes that refiners will limit
their actions to only treat the principal
benzene-containing stream (reformate).
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There are individual circumstances
where it may be economical to also treat
other refinery streams. If the benzene in
these other streams is indeed treated by
some refineries, it is possible that
sufficient credits might be generated to
allow more refineries to avoid benzene
reductions altogether by simply
purchasing credits. Consequently,
although our refinery-by-refinery
modeling predicts significant benzene
reductions in all areas nationwide,
individual refineries might continue to
have gasoline with higher benzene
levels than the model predicts. This
may also result in higher regional
variation in gasoline benzene levels
than the model predicts. Thus, we
cannot dismiss this possibility with a
high degree of confidence.
For these reasons, we believe that the
addition of a maximum average
standard to the 0.62 average standard
provides far greater assurance that
refineries will control benzene in the
future as projected—and certainly will
not increase benzene levels to be greater
than the level of the maximum average
standard. Furthermore, through
selection of an appropriate level for the
maximum average standard, we believe
that we are achieving this goal with a
minimal impact on the overall costs of
the program.
We did not originally propose a
maximum average standard, largely
because of our interpretation of our
modeling done for the proposal. That
modeling indicated that adding a
maximum average standard would
result in significantly more benzene
reduction in some areas, but that these
increases would cause other areas to
experience slightly smaller benzene
reductions (see 71 FR 15903). Our
updated modeling results are similar. In
the proposal, we considered this
potential for smaller benzene reductions
in some areas to be a reason not to
propose a maximum average standard.
However, upon further evaluation of
these modeling results, given the level
of uncertainty in the model to predict
individual refinery and regional
benzene levels (as discussed above), we
do not have confidence in the size of
any offsetting increases in benzene
levels in other areas, or even whether
they would occur. In addition, we
recognize that some of the refiners that
the model predicts would reduce
benzene slightly less (creating the
apparent offsetting regional effects) may
in fact decide to overcomply with the
standard in order to maintain a
compliance ‘‘safety margin,’’ regardless
of the presence of a maximum average
standard, and regardless of the strength
of the market for the generated credits.
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In light of this, we do not think it
warrants giving up the benefits resulting
from the inclusion of the maximum
average standard.
Absent concern about any measurable
offsetting effects from a maximum
average standard, we believe that the
major benefit of such a standard can and
should be pursued. That is, the program
can achieve increased certainty that the
significant gasoline benzene reductions
across all parts of the nation that our
modeling projects will indeed occur,
and thus that regional variations in
gasoline benzene levels will indeed be
minimized as we project.
We believe that setting the maximum
average standard at a level of 1.3 vol%
accomplishes the goal of reasonably
assuring lower benzene levels for all
refineries while balancing the negative
aspects of more- and less-stringent
benzene standards. Virtually all the
commenters who supported a maximum
average standard agreed that 1.3 vol%
would be a reasonable level for such a
standard. EPA agrees. Implementing a
maximum average standard lower than
1.3 vol% would begin to significantly
increase the number of refineries that
would need to install the more
expensive benzene reduction
equipment. This would quickly
diminish the value of the flexibility
provided by the ABT program and thus
force an increasing number of refineries
to make expenditures in benzene
control that could otherwise be smaller
or avoided entirely, significantly
increasing the overall cost of the
program. Conversely, a maximum
average standard greater than 1.3 vol%
would require progressively fewer
refineries to take action to reduce their
benzene levels. This would in turn
provide less assurance that actual
benzene levels would be broadly
achieved. As shown in detail in Chapter
9 of the RIA, the addition of the 1.3
vol% standard has minimal impact on
the overall costs of the program. It is for
this reason that we find that the 0.62
vol% annual average standard, in
tandem with the 1.3 vol% maximum
average standard, represents the greatest
benzene reductions achievable
considering cost, energy supply, and
other enumerated statutory factors.
We believe that it is very important to
monitor levels of benzene as refiners
and importers begin to respond to the
average and maximum average
standards. EPA currently collects
information on benzene and several
other gasoline parameters for every
batch of gasoline produced in or
imported into the U.S., and publishes it
in aggregate form on the EPA Web site.
By January 1, 2011, we plan to begin
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publishing a more detailed annual
report on gasoline quality. We will
present this data on a PADD-by-PADD
basis (to the extent that protection of
confidential business information
allows). We expect that these reports
will be a valuable tool to stakeholders
and members of the public who are
interested in following the real-world
progress of this rule’s gasoline benzene
reductions.
Among other changes discussed in
section VIII below, our updated
refinery-by-refinery model uses yearround 2004 gasoline production data as
a starting point (replacing 2003 summer
production data used in the proposal)
and incorporates updated crude oil and
benzene prices. The model thus
generates updated predictions of the
responses of refineries to the benzene
standards. Our updated analysis shows
that with the 0.62 vol% average
standard and the maximum average
benzene standard of 1.3 vol%, benzene
levels will be reduced very significantly
in all parts of the country. However, a
degree of variation will continue to
exist, due to the wide variety of refinery
configurations, crude oil supplies, and
approaches to benzene control, among
other factors. This remaining variation
is clearly legally permissible,
notwithstanding the reasonable
objective of assuring that reductions
occur both regionally and nationally,
because we do not read CAA section
202(l)(2) as requiring uniform gasoline
benzene levels in each area of the
country, since the standard is to be
technology-based considering costs and
other factors which vary considerably
by region and by refinery. On the other
hand, the maximum average standard
will have the appropriate effect of
directionally providing a greater degree
of geographic uniformity of gasoline
benzene levels and these levels remain
achievable considering cost and the
other enumerated factors. Reducing
gasoline benzene levels on both a
national and regional basis is within the
discretion of the Administrator, since
section 202(l)(2) does not specify
whether the maximum degree of
emission reductions are to be achieved
nationally, regionally, or both.
The 1.3 vol% maximum average
standard will become effective 18
months after the 0.62 vol% average
standard, on July 1, 2012, and on July
1, 2016 for small refiners. While there
is ample lead time for non-small refiners
to meet the 0.62 vol% standard by
January 1, 2011, we believe that
staggering the implementation dates
will ensure that the implementation of
the programs by the refining industry is
as smooth and efficient as possible. An
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8485
important aspect of the design of this
program as proposed is the recognition
that not all of the benzene reduction
would occur at once. As discussed in
detail in section VI.A.2.b below, we
expect that individual refiners will use
the ABT program to schedule their
benzene control expenditures in the
most efficient way, using the early
credit and standard credit provisions.
This will essentially create a gradual
phasing-in of the reductions in gasoline
benzene content, beginning well before
the initial compliance date of January 1,
2011 and spreading out industry-wide
compliance activities over several years.
Since the 1.3 vol% standard may not be
met using credits, we have set the
implementation dates for this standard
such that the credit program can
continue to be fully utilized for an
additional 18 months after the effective
date of the 0.62 vol% average standard
to allow the intended phasing-in of the
program to occur (i.e., there will be 18
additional months during which the
0.62 vol% average standard may be
achieved exclusively by using credits).
We acknowledge that by
incorporating the 1.3 vol% maximum
average standard into the program, we
are creating additional compliance
challenges for a small number of
refineries that might have relied on
credits but will now need to install
capital equipment to meet the 1.3 vol%
maximum average standard. Most
refiners will need to take these steps by
July 1, 2012. Small refiners will need to
take these steps four years later, by July
1, 2016. Although we believe that most
(possibly all) refiners will be able to
install appropriate benzene control
equipment by these future dates, there
may be a small number of refiners that
continue to face significant financial
hurdles as these dates approach. We
have considered this concern, and we
believe that the leadtime provided,
including the longer leadtime for small
refiners, and the hardship relief
provisions discussed below, are
sufficient to address any circumstances
of severe economic impacts on
individual refineries. We are making
clear that serious economic difficulties
in meeting the 1.3 vol% maximum
average standard may be a basis for
granting relief under the ‘‘extreme
hardship’’ provision discussed in
sectionVI.A.3. below.
2. Description of the Averaging,
Banking, and Trading (ABT) Program
a. Overview
We are finalizing a nationwide
averaging, banking, and trading (ABT)
program that allows us to set a more
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stringent annual average gasoline
benzene standard than would otherwise
be justifiable. The ABT program allows
refiners and importers to choose the
most economical compliance strategy
(investment in technology, credits, or
both) for meeting the 0.62 vol% annual
average benzene standard. The
flexibility afforded by the program is
especially significant and needed given
the considerable variation in existing
gasoline benzene levels, which reflects
important differences in crude oil
composition and individual refinery
design.
From 2007–2010, refiners can
generate ‘‘early credits’’ by making
qualifying benzene reductions earlier
than required. In 2011 and beyond,
refiners and importers can generate
‘‘standard credits’’ by producing/
importing gasoline with benzene levels
below 0.62 volume percent (vol%) on an
annual average basis. Credits may be
used interchangeably towards
compliance with the 0.62 vol%
standard, ‘‘banked’’ for future use, and/
or transferred nationwide to other
refiners/importers subject to the
standard. In addition to the 0.62 vol%
standard, refiners and importers must
also meet a 1.3 vol% maximum average
benzene standard beginning July 1,
2012. To comply with the maximum
average standard, gasoline produced by
a refinery or imported by an importer
may not exceed 1.3 vol% on an annual
average basis. While the 1.3 vol%
maximum average standard places a
limitation on credit use, we believe that
the ABT program still provides the
refining industry with significant
compliance flexibility as described
below.
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b. Credit Generation
i. Eligibility
Under the ABT program, U.S. refiners
(including ‘‘small refiners’’190) who
produce gasoline by processing crude
oil and/or intermediate feedstocks
through refinery processing units (see
§ 80.1270) are eligible to generate both
early and standard benzene credits.
Foreign refiners with individual refinery
baselines established under § 80.910(d)
who imported gasoline into the U.S. in
2004–2005 are also eligible to generate
early credits. Importers, on the other
hand, are only eligible to generate
standard credits under the ABT
program. As explained in the proposal,
importers are precluded from generating
early credits because, unlike refineries,
they do not need additional lead time to
comply with the standard since they are
190 Refiners approved as small refiners under
§ 80.1340.
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not investing in benzene control
technology. Additionally, due to their
variable operations, importers could
potentially redistribute the importation
of foreign gasoline to generate
‘‘windfall’’ early credits with no
associated benzene emission reduction
value (see 71 FR 15874).
Benzene credits may only be
generated on gasoline which is subject
to the benzene requirements as
described at § 80.1235. This excludes
California gasoline (gasoline produced
or imported for use in California) but
includes gasoline produced by
California refineries for use outside of
California. Despite the fact that
California gasoline is not covered by
this program, EPA sought comment on
whether and how credits could be
generated based on California gasoline
benzene reductions and applied towards
non-California gasoline compliance (see
71 FR 15873). We did not receive any
substantive comments on this matter but
nonetheless considered the feasibility of
such a program (described in more
detail in the Summary and Analysis of
Comments). We concluded that such a
program could be very problematic to
implement and, based on the apparent
lack of interest by California gasoline
refineries, it is likely that there would
be very few participants. As a result, we
have decided to maintain the proposed
ABT provision which excludes
California gasoline from generating
credits.
ii. Early Credit Generation
To encourage early innovation in
gasoline benzene control technology,
refiners are eligible to generate early
credits for making qualifying benzene
reductions prior to the start of the
program. Refiners must first establish
individual benzene baselines for each
refinery planning on generating early
credits (discussed further in section
VI.B.1). Benzene baselines are defined
as the annualized volume-weighted
benzene content of gasoline produced at
a refinery from January 1, 2004 through
December 31, 2005. To qualify to
generate early credits, refineries must
make operational changes and/or
improvements in benzene control
technology to reduce gasoline benzene
levels in accordance with § 80.1275.
Additionally, a refinery must produce
gasoline with at least ten percent less
benzene (on a volume-weighted annual
average basis) than its 2004–2005
baseline. The first early credit
generation period is from June 1, 2007
through December 31, 2007, and
subsequent early credit generation
periods are the 2008, 2009, and 2010
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calendar years (2008 through 2014
calendar years for small refiners).
We are setting a ten percent reduction
trigger point for early credits to ensure
that changes in gasoline benzene levels
result from real refinery process
improvements. Without a substantial
trigger point, refiners could earn credits
for the normal year-to-year fluctuations
in benzene level at a given refinery
allowed under MSAT1. These windfall
credits could negatively impact the ABT
program because—as reflections of
normal variability—they would have no
associated benzene emission reduction
value. As described in the proposal, we
believe that a percent reduction trigger
point, as opposed to an absolute level or
fixed reduction trigger point, is the most
appropriate early credit validation tool
considering the wide range in starting
benzene levels. In addition, we believe
that ten percent is an appropriate value
for the trigger point because it prevents
most windfall credit generation, yet is
not so restrictive as to discourage
refineries from making early benzene
reductions (see 71 FR 15875).
Once the ten percent reduction trigger
point is met, refineries can generate
credits based on the entire gasoline
benzene reduction. For example, if in
2008 a refinery reduced its annual
average benzene level from a baseline of
2.00 vol% to 1.50 vol% (below the
trigger point of 0.90 × 2.00 = 1.80 vol%),
its early benzene credits would be
determined based on the difference in
annual benzene content (2.00 ¥ 1.50 =
0.50 vol%) divided by 100 and
multiplied by the gallons of gasoline
produced in 2008 (expressed in gallons
of benzene).
We proposed that refiners be
prohibited from moving gasoline or
gasoline blendstock streams from one
refinery to another in order to generate
early credits (see 71 FR 15875). We
received comments indicating that
many refiners trade blending
components between refineries to
maximize gasoline production while
minimizing cost, and that such
companies should not be prohibited
from generating early credits. In fact, we
are not prohibiting these types of
normal refinery activities, nor are we
prohibiting such refineries from
participating in the early credit
program. We are simply requiring that
all refineries make real operational
changes and/or improvements in
benzene control technology to reduce
gasoline benzene levels in order to be
eligible to generate early credits. In most
cases, moving gasoline blendstocks from
one refinery to another does not result
in a net benzene reduction (one refinery
gets cleaner at the expense of another
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getting dirtier). Accordingly, refineries
that lower their benzene levels
exclusively through blendstock trading
(no additional qualifying reductions) are
not eligible to generate early credits
under the ABT program. An exception
exists for refineries that transfer
benzene-rich reformate streams for
processing at other refineries with
qualifying post-treatment capabilities,
e.g., extraction or benzene saturation
units. Under this scenario, the
transferring refinery would be eligible to
generate early credits because a real
operational change to reduce gasoline
benzene levels has been made. The
regulations at § 80.1275 have been
modified to more clearly reflect our
intended early credit eligibility
provisions, and specifically address
blendstock trading.
iii. Standard Credit Generation
Refiners and importers may generate
standard credits for overcomplying with
the 0.62 vol% gasoline benzene
standard on a volume-weighted annual
average basis in 2011 and beyond (2015
and beyond for small refiners).191 For
example, if in 2011 a refinery’s annual
average benzene level is 0.52, its
standard benzene credits would be
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191 Standard credit generation begins in 2011, or
2015 for small refiners, regardless of whether a
refinery pursues early compliance with the 0.62
vol% standard under § 80.1334.
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determined based on the margin of
overcompliance with the standard
(0.62¥0.52 = 0.10 vol%) divided by 100
and multiplied by the gallons of
gasoline produced during the 2011
calendar year (expressed in gallons of
benzene). Likewise, if in 2012 the same
refinery were to produce the same
amount of gasoline with the same
average benzene content, they would
earn the same number of credits. The
standard credit generation opportunities
for overcomplying with the standard
continue indefinitely (see 71 FR 15872).
c. Credit Use
As proposed, we are finalizing a
program where refiners and importers
can use benzene credits generated or
obtained under the ABT program to
meet the 0.62 vol% annual average
standard in 2011 and beyond (2015 and
beyond for small refiners). We are also
finalizing a 1.3 vol% maximum average
standard which takes effect in July 2012
(July 2016 for small refiners). The
maximum average standard must be met
based on actual refinery benzene levels,
essentially placing a cap on total credit
use. As discussed above in section
VI.A.1.d, we believe this is an
appropriate strategy for addressing the
current disparity in gasoline benzene
levels throughout the country.
Overall, the ABT program will allow
for a more gradual phase-in of the 0.62
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8487
vol% benzene standard and a more costeffective program. The early credit
program gives refiners an incentive to
make initial gasoline benzene
reductions sooner than required. The
early credits generated can be used to
provide refiners with additional lead
time to make their final (more
expensive) investments in benzene
control technology. As a result, some
benzene reductions will occur prior to
the start of the program while others
will lag (within the realms of the credit
life provisions described below). We
anticipate that there will be enough
early credits generated to allow refiners
to postpone their final investments by
up to three years, which coincides with
the maximum time afforded by the early
credit life provisions. In addition, we
predict that standard credits generated
during the early credit lag period will
allow for an additional 16 months of
lead time. The result is a gradual phasein of the 0.62 vol% benzene standard
beginning in June 2007 and ending in
July 2016, as shown below in Figure
VI.A–1. Without early credits, refineries
would be immediately constrained by
the 0.62 vol% standard and likely
forced to make their final investments
sooner (including those necessary to
meet the 1.3 vol% maximum average
standard).
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In addition to earlier benzene
reductions and a more gradual phase-in
of the 0.62/1.3 vol% standards (as
shown above), the ABT program results
in a more cost-effective program for the
refining industry. Our modeling shows
that allowing refiners to average
benzene levels nationwide to meet the
0.62 vol% standard reduces ongoing
compliance costs by about 50% from
0.51 to 0.27 cents per gallon (refer to
RIA Section 9.6.2). Our modeling
further shows that the early credit
program we are finalizing results in the
lowest possible compliance costs during
the phase-in period. Without an early
credit program, the total amortized
capital and operating costs incurred by
the refining industry during the phasein period is estimated to be $905 million
(2003 dollars).192 With an early credit
program, the total cost incurred during
the same phase-in period is reduced to
192 ABT program cost calculations consider future
gasoline growth and the time value of money. The
gasoline growth rate from 2004–2012 was estimated
by the refinery cost model and future growth rates
were obtained from EIA’s AEO 2006. The costs and
resulting cost savings estimated for the phase-in
period were calculated based on compliance costs
presented in RIA Section 9.6.2 and adjusted back
to 2007 to account for the time-value of money
based on a 7% average rate of return.
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$608 million, providing about $300
million in savings. In the absence of an
ABT program altogether, the total cost
incurred during the phase-in period
would be $1.7 billion. As a result, the
ABT program in its entirety could save
the refining industry up to $1.1 billion
in compliance costs from 2007–2015.
For a more detailed discussion on
compliance costs, refer to section VIII.A.
For more information on how the cost
savings associated with the ABT
program were derived, refer to RIA
Section 6.5.5.12.
Under the ABT program, early and
standard benzene credits can be used
interchangeably towards compliance
with the 0.62 vol% standard (within the
realms of the credit life provisions
described below). Each credit
(expressed in gallons of benzene) can be
used on a one-for-one basis to offset the
same volume of benzene produced/
imported in gasoline above the
standard. For example, if in 2011 a
refinery’s annual average benzene level
was 0.72, the number of benzene credits
needed to comply would be determined
based on the margin of
undercompliance with the standard
(0.72¥0.62 = 0.10 vol%) divided by 100
and multiplied by the gallons of
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gasoline produced during the 2011
calendar year. The credits needed
would be expressed in gallons of
benzene.
To enable enforcement of the
program, the ABT program we are
finalizing includes a limit on credit life
(for both early and standard credits), a
limit on the number of times credits
may be traded, and a prohibition on
outside parties taking ownership of
credits. We believe that these provisions
are necessary to ensure that the full
benzene reduction potential of the
program is realized and that the credit
trading program is equitably
administered among all participants. In
the proposal, we acknowledged
concerns that credit use limitations
might in some circumstances
unnecessarily hamper the credit market.
Specifically, we requested comment on
ways that some of the provisions might
be reduced or eliminated while still
maintaining an enforceable program (see
71 FR 15872). Although we received
many comments on the proposed ABT
program, we did not receive any
substantive comments indicating that
the proposed credit provisions would be
a significant burden on refiners or
importers. Likewise, we did not receive
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any substantive comments suggesting
that the removal of such restrictions
would greatly improve the efficiency of
the ABT program. For these reasons, we
are finalizing such provisions for credit
use (described in more detail below).
i. Early Credit Life
Early credits must be used towards
compliance within three years of the
start of the program; otherwise they will
expire and become invalid. In other
words, early credits generated or
obtained under the ABT program must
be applied to the 2011, 2012, or 2013
compliance years. Similarly, early
credits generated/obtained and
ultimately used by small refiners must
be applied to the 2015, 2016, or 2017
compliance years. The result is that no
early credits may be used toward
compliance with the 2014 year. This
break in the early credit application
period may help funnel surplus early
credits facing expiration to small
refiners in need.
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ii. Standard Credit Life
Standard credits must be used within
five years from the year they were
generated (regardless of when/if they are
traded). For example, standard credits
generated in 2011 would have to be
applied towards the 2012 through 2016
compliance year(s); otherwise they
would expire and become invalid. To
encourage trading to small refiners,
there is a credit life extension for
standard credits traded to and
ultimately used by small refiners. These
credits may be used towards compliance
for an additional two years, giving
standard credits a maximum seven-year
life. For example, the same abovementioned standard credits generated in
2011, if traded and used by a small
refiner, would have until 2018 to be
applied towards compliance before they
would expire.
iii. Consideration of Unlimited Credit
Life
Since compliance with the gasoline
benzene standards is determined at the
refinery or importer level, there are no
enforceable downstream standards
associated with this rulemaking. Thus,
it is critical that EPA be able to conduct
enforcement at the refinery or importer
level. Additionally, since EPA
enforcement activities are limited by the
five-year statute of limitations in the
Clean Air Act, allowing credit life
beyond five years poses serious
enforcement issues. As a result, we are
finalizing three-year early credit life and
five-year standard credit life provisions
(as just described above). We believe
that these credit life provisions are
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limited enough to satisfy enforcement
and trading concerns yet sufficiently
long to provide necessary program
flexibility. However, we recognize that
extending credit life might result in
increased program flexibility.
Accordingly, in the proposal, EPA
sought comment on different ways to
structure the program that would allow
for unlimited credit life. Specifically,
we asked for comment on how
unlimited credit life could be beneficial
to the program and/or how the
associated increase in recordkeeping
and enforcement issues could be
mitigated (see 71 FR 15872). Comments
received provided no support for why
unlimited credit life would improve
program flexibility or how enforcement
issues could be addressed. Furthermore,
we did not receive any comments
suggesting that the proposed credit life
provisions would significantly hamper
trading. As such, we are finalizing the
credit life provisions as proposed.
iv. Credit Trading Provisions
It is possible that benzene credits
could be generated by one party,
subsequently transferred or used in
good faith by another, and later found
to have been calculated or created
improperly or otherwise determined to
be invalid. If this occurs, as in past
programs, both the seller and purchaser
will have to adjust their benzene
calculations to reflect the proper credits
and either party (or both) could be
determined to be in violation of the
standards and other requirements if the
adjusted calculations demonstrate
noncompliance with the 0.62 vol%
standard.
Credits must be transferred directly
from the refiner or importer generating
them to the party using them for
compliance purposes. This ensures that
the parties purchasing them are better
able to assess the likelihood that the
credits are valid. An exception exists
where a credit generator transfers
credits to a refiner or importer who
inadvertently cannot use all the credits.
In this case, the credits can be
transferred a second time to another
refiner or importer. After the second
trade, the credits must be used or
terminated. In the proposal, we
requested comment on whether more
than two trades should be allowed—
specifically, whether three or four trades
were more appropriate and/or more
beneficial to the program (see 71 FR
15876). We did not receive any
comments providing analytical support
for an additional number of trades. We
are finalizing a maximum of two trades,
consistent with other recent
rulemakings, in order to provide
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8489
flexibility while still maintaining
enforceability as discussed in the
proposal.
There are no prohibitions against
brokers facilitating the transfer of credits
from one party to another. Any person
can act as a credit broker, regardless of
whether such person is a refiner or
importer, as long as the title to the
credits is transferred directly from the
generator to the user. This prohibition
on outside parties taking ownership of
credits was promulgated in response to
problems encountered during the
unleaded gasoline program and has
since appeared in subsequent fuels
rulemakings. To reevaluate potential
stakeholder interest in removing this
prohibition, EPA sought comment on
this provision in the proposal—
specifically, whether there were
potential benefits to allowing other
parties to take ownership of credits and
how such a program would be enforced
(see 71 FR 15876). We did not receive
any comments on this issue and
continue to believe that our proposal is
appropriate. Therefore, to maintain
maximum program enforceability and
consistency with all of our other ABT
programs for mobile sources and their
fuels, we are maintaining our existing
prohibition on outside parties taking
ownership of credits.
We are not imposing any geographic
restrictions on credit trading. Credits
may be traded nationwide between
refiners or importers as well as within
companies to meet the 0.62 vol%
national average benzene standard. We
believe that restricting credit trading
could reduce refiners’ incentive to
generate credits and hinder trading
essential to this program. In addition,
since there are no fuel-availability
issues associated with this rule (as
opposed to the case of the ultra-low
sulfur diesel program), there is no need
to impose a geographic restriction.
3. Provisions for Small Refiners and
Refiners Facing Hardship Situations
In developing the MSAT2 program,
we evaluated the need for and the
ability of refiners to meet the proposed
benzene standards as expeditiously as
possible. We continue to believe that it
is feasible and necessary for the vast
majority of the program to be
implemented in the time frame stated
above to achieve the air quality benefits
as soon as possible. Further, we believe
that refineries owned by small
businesses generally face unique
hardship circumstances as compared to
larger refiners. We are also finalizing
provisions for other refiners to allow
them to seek limited relief from
hardship situations on a case-by-case
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basis. These provisions are discussed in
detail below.
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a. Provisions for Small Refiners
We proposed several special
provisions for refiners that are approved
as small refiners (see VI.A.3.a.ii below).
This is due to the fact that small refiners
generally have greater difficulty than
larger companies (including those large
companies that own small-capacity
refineries) in raising capital for
investing in benzene control equipment.
Small refiners are also likely to have
more difficulty in competing for
engineering resources and in completing
construction of the needed benzene
control (and any necessary octane
recovery) equipment in time to meet the
required standards (see also the more
detailed discussion at 71 FR 15877).
As explained in the discussion of our
compliance with the Regulatory
Flexibility Act below in section XII.C
and in the Final Regulatory Flexibility
Analysis in Chapter 14 of the RIA, we
carefully considered the impacts of the
regulations on small businesses. Most of
our analysis of small business impacts
was performed as a part of the work of
the Small Business Advocacy Review
Panel (‘‘SBAR Panel’’, or ‘‘the Panel’’)
convened prior to the proposed rule,
pursuant to the Regulatory Flexibility
Act as amended by the Small Business
Regulatory Enforcement Fairness Act of
1996 (SBREFA). (The final report of the
Panel is available in the docket.)
For the SBREFA process, EPA
conducted outreach, fact-finding, and
analysis of the potential impacts of our
regulations on small businesses. Based
on these factors and analyses by all
Panel members, the Panel concluded
that small refiners in general would
likely experience a significant and
disproportionate financial hardship in
reaching the objectives of the MSAT2
program. We proposed many of the
provisions recommended by the Panel
and we are finalizing these provisions in
this action.
i. Definition of Small Refiner for
Purposes of the MSAT2 Small Refiner
Provisions
The criteria to qualify for small refiner
status for this program are in most ways
the same as those required in the
Gasoline Sulfur and the Highway and
Nonroad Diesel rules. However, there
are some differences; as stated in our
more recent fuels programs, we believe
that it is necessary to limit relief to
those small entities most likely to
experience adverse economic impacts
from fuel regulations. We are finalizing
the following provisions for determining
small refiner status.
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To qualify as a small refiner, a refiner
must demonstrate that it meets all of the
following criteria: (1) Produced gasoline
from crude during calendar year 2005;
(2) had no more than 1,500 employees,
based on the average number of
employees for all pay periods from
January 1, 2005 to January 1, 2006; and,
(3) had an average crude oil capacity
less than or equal to 155,000 barrels per
calendar day (bpcd) for 2005. We are
likewise finalizing the provision
requiring refiners to apply for, and for
EPA to approve, a refiner’s status as a
‘‘small refiner’’.
Small refiner provisions are limited to
refiners of gasoline from crude because
they are the entities that bear the
investment burden and the consequent
economic hardship. Therefore, blenders,
importers, and additive component
producers are not eligible. For these
same reasons, small refiner status is
limited to those refiners that owned and
operated the refinery during the period
from January 1, 2005 through December
31, 2005. This is consistent with the
approach taken in the Nonroad Diesel
rule, but we are revising the text to be
more clear on this issue.
In determining its crude oil capacity
and total number of employees, a refiner
must include the crude oil capacity and
number of employees of any subsidiary
companies, any parent companies, any
subsidiaries of the parent companies,
and any joint venture partners. As stated
in the proposal, there was confusion in
past rules regarding ownership. Thus,
we proposed defining a parent company
as any company (or companies) with
controlling ownership interest, and a
subsidiary of a company as any
company in which the refiner or its
parent(s) has a controlling ownership
interest (see 71 FR 15878). We requested
comment on these clarifications in the
proposal, but did not receive any
comments on these aspects of the small
refiner definition. Therefore, we are
finalizing the definition of parent
company and related clarifying
provisions such that the employees and
crude capacity of all parent companies,
and all subsidiaries of all parent
companies, must be taken into
consideration when evaluating
compliance with these criteria.
We received comments regarding the
small refiner employee count and crude
capacity criteria. These commenters
stated that they believed that EPA’s
criteria fail to provide relief to a small
number of refiners whom they believe
are similar in many respects to those
refiners that will qualify as small under
our criteria. The commenters pointed to
recent Congressionally enacted
programs, specifically the Energy Policy
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Act of 2005 (EPAct) and the American
Jobs Creation Act of 2004 (Jobs Act),
which use definitions that are different
from the SBA definition, and from the
criteria EPA is adopting in this rule. The
EPAct focuses on refinery size rather
than company size, and the Jobs Act
focuses on refinery-only employees
rather than employees company-wide.
EPA has established the criteria for
qualifying for small refiner relief based
on the Small Business Administration’s
(SBA) small business definition (per 13
CFR 121.201).
We do not believe that it would be
appropriate to change the proposed
small refiner employee count or crude
capacity limit criteria to fit the
definitions used in either of the two
recent statutes. While Congress is able
to establish special provisions for
subsets of the industry in programs like
those mentioned above, EPA
appropriately focuses, under SBREFA
and in this rulemaking, on
consideration of relief on those refining
companies that we believe are likely to
face serious economic hardship as a
result of compliance with the rule.
Under programs subject to the EPAct
and Jobs Act definitions, relief would be
granted to refineries that are owned by
larger companies, or companies that
have additional sources of revenue
(indicated by more employees and/or
refining capacity), and also refineries
owned by foreign governments. These
definitions do not focus as directly on
refiners which, due to their size, could
incur serious adverse economic impact
from fuel regulations; and EPA
consequently is not adopting either of
them in this rule. Further, SBA
established its small business definition
to set apart those companies which are
most likely to be at an inherent
economic disadvantage relative to larger
businesses. We agree with the
assessment that refiners of this size may
be afforded special consideration under
regulatory programs that have a
significant economic impact on them
(insofar as is consistent with Clean Air
Act requirements). We continue to
believe that it is most appropriate to
remain consistent with our previous
fuels programs and retain the criteria to
qualify for small refiner status that have
been used in the past (with some minor
clarifications to avoid confusion), since
these criteria best identify the class of
small refiner which may incur
disproportionate regulatory impact
under the rule. We are therefore
finalizing the small refiner qualification
criteria that were proposed.
As previously stated, our intent has
been, and continues to be, limiting the
small refiner relief provisions to the
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small subset of refiners that are likely to
be seriously economically challenged as
a result of the new regulations. We
assume that new owners that purchase
a refinery after December 31, 2005 do so
with full knowledge of the proposed
regulation. Given that they have the
resources available to purchase the
refinery assets, they are not in an
economic hardship situation. Therefore,
they should include compliance
planning as part of their purchase
decision. Similar to earlier fuel rules,
we are finalizing a provision that a
refiner that restarts a refinery in the
future is eligible for small refiner status.
In such cases, we will judge eligibility
under the employment and crude oil
capacity criteria based on the most
recent 12 consecutive months before the
application, unless we conclude from
data provided by the refiner that another
period of time is more appropriate.
However, unlike past fuel rules, this
will be limited to a company that owned
the refinery at the time that it was shut
down. New purchasers will not be
eligible for small refiner status for the
reasons described above. Companies
with refineries built after January 1,
2005 will also not be eligible for the
small refiner hardship provisions, again
for the reasons given above.
Similar to previous fuel sulfur
programs, we also proposed that refiners
owned and controlled by an Alaska
Regional or Village Corporation
organized under the Alaska Native
Claims Settlement Act are also eligible
for small refiner status, based only on
the refiner’s employee count and crude
oil capacity (see 71 FR 15878). We did
not receive any comments on this
provision, and we are finalizing it in
this action.
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ii. Small Refiner Status Application
Requirements
A refiner applying for status as a
small refiner under this program is
required to apply and provide EPA with
several types of information by
December 31, 2007. (The application
requirements are summarized in section
VI.B.2, below.) A refiner seeking small
refiner status under this program must
apply for small refiner status, regardless
of whether the refiner had been
approved or rejected for small refiner
status under another fuel program. As
with applications for relief under other
rules, applications for small refiner
status under this rule that are later
found to contain false or inaccurate
information will be void ab initio.
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iii. Small Refiner Provisions
Delay in the Effective Date of the
Standards
We proposed that small refiners be
allowed to postpone compliance with
the 0.62 vol% benzene standard until
January 1, 2015, four years after the
general program would begin (see 71 FR
15878). At such time, approved small
refiners would be required to meet the
0.62 vol% benzene standard. As stated
in the proposal, this additional lead
time is justified because small refiners
face disproportionate challenges, which
the additional lead time will help to
mitigate. We requested comment on this
proposed provision, and we received
many comments supporting it and none
opposing it.
Normally a period of two to three
years of lead time is required for a
refiner to secure necessary financing
and to carry out capital improvements
for benzene control (see VI.A.1.c.i.
above). Commenters specifically noted
that additional lead time would allow
small refiners to more efficiently obtain
financing and contracts to carry out
necessary capital projects (or to obtain
credits) with less direct competition
with non-small refiners for financing
and for contractors to carry out capital
improvements. Some commenters noted
that they generally supported the
proposed program of a 0.62 vol%
benzene standard with no upper limit
and the proposed small refiner relief.
While we did not propose an upper
limit, as discussed above in section
VI.A.1, we have chosen to finalize a 1.3
vol% refinery maximum average.
The additional lead time also allows
EPA to make programmatic adjustments,
if necessary, before small refiners are
required to comply with the benzene
standards. As discussed below, we are
finalizing a requirement that EPA
review the program in 2012, leaving a
number of years to adjust the program
before small refiners are required to
meet the benzene standards. The
additional lead time for small refiners
will also provide these refiners with
three years of lead time following the
review to take the review results into
account in completing capital projects if
necessary or desirable to meet the
benzene standards. Based on these
assessments, we are therefore finalizing
a four-year period of additional lead
time for small refiners for compliance
with the 0.62 vol% benzene standard,
until January 1, 2015 (and small refiners
would continue to meet the
requirements of MSAT1 until January 1,
2015). Further, we are finalizing an
additional 4 years of lead time for small
refiners to comply with the 1.3 vol%
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maximum average benzene standard,
until July 1, 2016.
Early ABT Credit Generation
Opportunities
During the development of the
proposal, we anticipated that many
small refiners would likely find it more
economical to purchase credits for
compliance than to comply by making
capital investments to reduce gasoline
benzene. However, some small refiners
indicated that they would make
reductions to their gasoline benzene
levels to fully or partially meet the
proposed 0.62 vol% benzene standard.
Therefore, we proposed that small
refiners that take steps to meet the
benzene requirement before January 1,
2015 would be eligible to generate early
credits (see 71 FR 15879). Current and
previous fuels programs allow for credit
generation opportunities to encourage
early compliance, and extending this
opportunity to small refiners, based on
the small refiner effective date, is
consistent with this objective. Small
refiners generally supported this
provision and we did not receive any
adverse comments on it.
Early credit generation opportunities
will provide more credits for the
MSAT2 ABT program and will help to
achieve the air quality goals of the
MSAT2 program earlier than otherwise
required. We are therefore finalizing an
early credit generation provision for
small refiners. This is similar to the
general early credit generation provision
that is provided to all refiners, except
that small refiners may generate early
credits until January 1, 2015. As
discussed in section VI.A.2.b.ii above,
refineries must reduce their 2004–2005
benzene levels by at least ten percent to
generate early credits. This ten percent
threshold is being set to ensure that
changes in gasoline benzene levels
result from real refinery process
improvements, not just normal
fluctuations in benzene levels at a given
refinery (allowed under MSAT1). The
small refiner early credit generation
period will be from June 1, 2007 to
December 31, 2014, after which
standard credits may be generated
indefinitely for those that overcomply
with the 0.62 vol% annual average
standard.
Extended Credit Life
During the SBREFA process, many
small refiners expressed interest in
relying upon credits as an ongoing
compliance strategy for meeting the 0.62
vol% gasoline benzene standard.
However, several small refiners voiced
concerns surrounding the idea of relying
on the credit market to avoid large
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capital costs for benzene control. One of
their primary concerns was that credits
might not be available and/or traded to
small refiners in need. To increase the
certainty that credits would be
available, we proposed a two-year credit
life extension for credits generated by or
traded to small refiners (see 71 FR
15879). Not only does this provision
encourage trading to small refiners, it
creates a viable outlet for credits facing
expiration. Most small refiners
supported the proposed credit life
provision. However, one refiner
suggested that we finalize unlimited
credit life for credits traded to small
refiners. Although unlimited credit life
could have some perceived benefits,
overall it poses serious enforcement
problems. Therefore, for the reasons
described above in VI.A.2.c.iii, we are
not finalizing unlimited credit life for
credits traded to small refiners. Further,
we are finalizing a slightly modified
version of the proposed small refiner
extended credit life provision to better
reflect its intended purpose. First, the
two-year credit life extension pertains
only to standard credits. The extension
does not apply to early credits because
refiners already have an incentive to
trade early credits to small refiners.
Based on the nature of the early credit
life program (three-year life based on the
start of the program) and small refiners’
delayed program start date (2015 as
opposed to 2011), early credits traded to
small refiners are already valid for an
additional four years. Second, the twoyear credit life extension applies only to
standard credits traded to small refiners.
There is no need to extend credit life for
credits generated by small refiners,
because in this event, the small refiner
would already have the utmost certainty
that the credits would be available for
use.
ABT Program Review
We proposed that we would perform
a review of the ABT program (and thus,
the small refiner flexibility options) by
2012, one year after the general program
begins (see 71 FR 15879). Coupled with
the small refiner four-year additional
lead time provision, the ABT program
review after the first year of the overall
program will provide small refiners
with roughly three years, after learning
the results of the review, to obtain
financing and perform engineering and
construction. We are committing to this
provision today. The review will take
into account the number of early credits
generated industry-wide each year prior
to the start of the MSAT2 program, as
well as the number of credits generated
and transferred during the first year of
the overall benzene control program. In
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part to support this review, we are
requiring that refiners submit precompliance reports, similar to those
required under the highway and
nonroad diesel programs. In addition,
the first compliance report that refiners
submit (for the 2011 compliance period)
will provide important information on
how many credits are actually being
generated or utilized during the first
year of the program.
The ABT pre-compliance reports will
be due annually on June 1 from 2008
through 2011. The reports must include
projections of how many credits will be
generated and how many credits will
need to be used at each refinery. The
reports must also contain information
on a refiner’s plans (for each refinery)
for compliance with the benzene
standard, including whether or not the
refiner will utilize credits alone to
comply with the standard. Refiners
must also report any early credits that
may have been transferred to another
entity prior to January 1, 2011 and the
sale price of those credits.
In addition, ABT compliance reports
will be due annually beginning
February 28, 2012. For any refiner
expecting to participate in the credit
trading program (under § 80.1275 and/or
§ 80.1290, the report must include
information on actual credit generation
and usage. Refiners must also provide
any updated information regarding
plans for compliance. EPA will publish
the results of these refinery compliance
reports and the results of our review as
soon as possible to provide small
refiners with information on the ABT
program roughly three years prior to the
small refiner compliance date. EPA will
maintain the confidentiality of
information from individual refiners
submitted in the reports. We will
present generalized summaries of the
reports annually.
If, following the review, EPA finds
that the credit market is not adequate to
support the small refiner provisions, we
will revisit the provisions to determine
whether or not they should be altered or
whether EPA can assist the credit
market (and small refiners’ access to
credits). For example, the Panel
suggested that EPA could consider
actions such as: (1) The ‘‘creation’’ of
credits by EPA that would be
introduced into the credit market to
ensure that there are additional credits
available for small refiners; (2) a
requirement that a percentage of all
credits to be sold be set aside and only
made available for small refiners; and
(3) a requirement that credits sold, or a
certain percentage of credits sold, be
made available to small refiners before
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they are allowed to be sold to any other
refiners.
Further, we are finalizing an
additional hardship provision to assist
small refiners. This hardship provision
would be for the case of a small refiner
for which compliance with the 0.62
vol% benzene standard would be
feasible only through the purchase of
credits, but for whom purchase of
credits is not economically feasible.
This hardship provision will only be
available following the ABT program
review, since EPA wishes to use the
most accurate information to assess
credit availability and the working of
the credit market. The provision will
only be afforded to a small refiner on a
case-by-case basis, and must be based
on a showing by the refiner of the
practical or economic difficulty in
acquiring credits for compliance with
the 0.62 vol% benzene standard (or
some other type of similar situation that
would render its compliance with the
standard not economically feasible). The
relief offered under this hardship
provision is a further delay, on an
individual refinery basis, for up to two
years. Applications for relief under this
provision must meet the requirements
set out in § 80.1343. Following the two
years, a small refiner will be allowed to
request one or more extensions of the
hardship until the refinery’s material
situation has changed. Finally, if a small
refiner is unable to comply with the 1.3
vol% refinery maximum average, it may
apply for relief from this standard under
the general hardship provisions
discussed below in section VI.A.3.b.
Applications for relief from the 1.3
vol% refinery maximum average must
be received by January 1, 2013 and must
meet the requirements set out in
§ 80.1335.
iv. The Effect of Financial and Other
Transactions on Small Refiner Status
and Small Refiner Relief Provisions
We believe that the effects of financial
(and other) transactions are also relevant
to this action. We proposed these
provisions (see 71 FR 15880) and did
not receive any comments on them. We
continue to believe that these provisions
are appropriate and are finalizing the
provisions discussed below.
Large Refiner Purchasing a Small
Refiner’s Refinery
One situation involves a ‘‘non-small’’
refiner that wishes to purchase a
refinery owned by an approved small
refiner. The small refiner may not have
completed or even begun any necessary
planning to meet the MSAT2 standards,
since it would likely have planned to
make use of the special small refiner
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relief provisions. We assume that the
refiner would have incorporated
financial planning for compliance into
its purchase decision. However, we
recognize that a limited amount of time
would be required for the physical
completion of the refinery upgrades for
compliance. (This situation would be
similar to that addressed in the Nonroad
Diesel program (96 FR 39051).)
We therefore believe that an
appropriate period of lead time for
compliance with the MSAT2
requirements is warranted where a
refiner purchases any refinery owned by
a small refiner, whether by purchase of
a refinery or purchase of the small
refiner entity. A refiner that acquires a
refinery from an approved small refiner
will be provided with 30 additional
months from the date of the completion
of the purchase transaction (or until the
end of the applicable small refiner relief
interim period if it is within 30 months).
During this 30-month period,
production at the newly-acquired
refinery may remain at the benzene
levels that applied to that refinery for
the previous small refiner owner, and
all existing small refiner provisions and
restrictions will also remain in place for
that refinery. At the end of this period,
the refiner must comply with the ‘‘nonsmall refiner’’ standards. There will not
be an adverse environmental impact of
this provision, since the small refiner
would already have been provided relief
prior to the purchase and this provision
would be no more generous.
We expect that in most (if not all)
cases, the 30 months of additional lead
time will be sufficient for the new
refiner-owner to accomplish the
necessary planning and any needed
refinery upgrades. If a refiner
nonetheless believes that the technical
characteristics of its plans would
require additional lead time, the refiner
may apply for additional time and EPA
will consider such requests on a caseby-case basis. Based on information
provided in such an application and
other relevant information, EPA will
decide whether additional time is
technically necessary and, if so, how
much additional time would be
appropriate. As discussed above, in no
case will compliance dates be extended
beyond the time frame of the applicable
small refiner relief.
Small Refiner Losing Its Small Refiner
Status Due To Merger or Acquisition
Another type of potential transaction
involves a refiner with approved small
refiner status that later loses its small
refiner status because it no longer meets
the small refiner criteria. An approved
small refiner that exceeds the small
refiner employee or crude capacity limit
due to merger or acquisition will lose its
small refiner status. This includes
exceedances of the employee or crude
capacity criteria caused by acquisitions
of assets such as plants and equipment,
as well as acquisitions of business
entities.
Our intent has been, and continues to
be, to limit the small refiner relief
provisions to a small subset of refiners
that are most likely to be significantly
economically challenged, as discussed
above. At the same time, it is also our
intent to avoid stifling normal business
growth. Therefore, under this program,
a refiner will be disqualified from small
refiner status if it exceeds the small
refiner criteria through its involvement
in transactions such as being acquired
by or merging with another entity,
through the small refiner itself
purchasing another entity or assets from
another entity, or when it ceases to
process crude oil. However, if a small
refiner grows through normal business
practices, and exceeds the employee or
crude capacity criteria without merger
or acquisition, it will retain its small
refiner status for this program.
In the sole case of a merger between
two approved MSAT2 small refiners,
both small refiners will be allowed to
retain their small refiner status under
this program. As in past fuel
rulemakings, we believe the justification
for continued small refiner relief for
each of the merged entities remains
valid. Small refiner status for the two
entities of the merger will not be
affected, and hence the original
compliance plans of the two refiners
should not be impacted. Moreover, no
environmental detriment will result
from the two small refiners maintaining
their small refiner status within the
merged entity as they would have likely
maintained their small refiner status
had the merger not occurred. We did not
receive any comments on this provision.
We recognize that a small refiner that
loses its small refiner status because of
a merger with, or acquisition of, a nonsmall refiner would face the same type
of technical lead time concerns
discussed above for a non-small refiner
acquiring a small refiner’s refinery.
Therefore, we are also providing the 30
months of additional lead time
described above for non-small refiners
purchasing a small refiner’s refinery.
b. Provisions for Refiners Facing
Hardship Situations
The MSAT2 program includes a
nationwide credit trading program of
indefinite duration for the 0.62 vol%
annual average benzene standard, and
we expect that credits will be available
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at a reasonable cost industry-wide.
However, as explained in the proposal
(71 FR 15880–15881), there could be
circumstances when refiners would
need hardship relief. We reiterate this
conclusion here, especially given the 1.3
vol% refinery maximum average
benzene standard in the final rule.
These hardship provisions are available
to all refiners, small and non-small,
with relief being available on a case-bycase basis following a showing of
certain requirements (as described in
the regulations at sections 80.1335 and
80.1336). We believe that the inclusion
of hardship provisions for refiners is a
necessary part of adopting the benzene
requirements as the maximum reduction
achievable considering costs. Without a
mechanism to consider economic
hardship to particular refineries, the
overall level of the standards would
need to be higher to reflect the potential
increased costs. Note, however, that we
do not intend for these hardship waiver
provisions to encourage refiners to delay
planning and investments they would
otherwise make.
We are finalizing two forms of
hardship relief: the first applies to
situations of extreme and unusual
hardship, and the second applies to
situations where unforeseen
circumstances prevent the refiner from
meeting the benzene standards. These
provisions are similar to the hardship
provisions that were proposed, but with
some modification because this final
rule includes a 1.3 vol% refinery
maximum average benzene standard,
which cannot be satisfied through the
use of credits. While we sought
comment in the proposal on such a
standard, we did not propose it, and
therefore also did not propose any
hardship relief specific to it.
As discussed further below, the
application requirements and potential
relief available differ somewhat
depending upon whether a refiner
applies for hardship relief for the 0.62
vol% benzene standard, the 1.3 vol%
refinery maximum average, or both (a
refiner may apply for relief from both
standards, but EPA will address them
independently). This is partly due to the
fact that a refiner may use credits to
meet the 0.62 vol% benzene standard,
but credits cannot be used for
compliance with the 1.3 vol% refinery
maximum average standard. EPA can
impose appropriate conditions on any
hardship relief. Note also that any
hardship relief granted under this rule
will be separate and apart from EPA’s
authority under the Energy Policy Act to
issue temporary waivers for extreme and
unusual supply circumstances, under
amended section 211(c)(4). In general,
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commenters stated that they supported
the inclusion of hardship provisions,
but they did not provide any specific
comments regarding these provisions.
i. Temporary Waivers Based on Extreme
Hardship Circumstances
We are finalizing the proposed
hardship relief provisions based on a
showing of extreme hardship
circumstances, with some slight
modifications from the proposed
extreme hardship relief provision (see
71 FR 15881). We did not receive
comment on the proposed hardship
provision.
Extreme hardship circumstances
could exist based on severe economic or
physical lead time limitations of the
refinery to comply with the benzene
standards required by the program.
Such extreme hardship may be due to
an inability to physically comply in the
time available, an inability to secure
sufficient financing to comply in the
time available, or an inability to comply
in the time available in a manner that
would not place the refiner at an
extreme competitive disadvantage
sufficient to cause extreme economic
hardship. A refiner seeking such
hardship relief under this provision will
have to demonstrate that these criteria
were met. In addition to showing that
unusual circumstances exist that impose
extreme hardship in meeting the
benzene standards, the refiner must
show: (1) Circumstances exist that
impose extreme hardship and
significantly affect the ability to comply
with the gasoline benzene standards by
the applicable date(s); and (2) that it has
made best efforts to comply with the
requirements. Refiners seeking
additional time must apply for hardship
relief, and the hardship applications
must contain the information required
under § 80.1335.
For relief from the 0.62 vol% benzene
standard in extreme hardship
circumstances, an aspect of the
demonstration of best efforts to comply
is that severe economic or physical lead
time limitations exist and that the
refinery has attempted, but was unable,
to procure sufficient credits. EPA will
determine an appropriate extended
deficit carry-forward time period based
on the nature and degree of the
hardship, as presented by the refiner in
its hardship application, and on our
assessment of the credit market at that
time. Moreover, because we expect the
credit program to be operating and
robust, we believe that circumstances
under which we would grant relief from
the 0.62 vol% benzene standard will be
rare, and should we grant relief, it
would likely be for less than three years.
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Further, we may impose additional
conditions to ensure that the refiner was
making best efforts to comply with the
benzene standards while offsetting any
loss of emission control from the
program (due to extended deficit carryforward).
For relief from the 1.3 vol% refinery
maximum average benzene standard in
extreme hardship circumstances, a
refiner must show that it could not meet
the 1.3 vol% standard, despite its best
efforts, in the timeframe required due to
extreme economic or technical
problems. Extreme hardship relief from
the 1.3 vol% refinery maximum average
standard is available for both non-small
and small refiners. This provision is
intended to address unusual
circumstances that should be apparent
now, or well before the standard takes
effect. Thus, refiners must apply for
such relief by January 1, 2008, or
January 1, 2013 for small refiners. If
granted, such hardship relief would
consist of additional time to comply
with the 1.3 vol% refinery maximum
average. The length of such relief and
any conditions on that relief will be
granted on a case-by-case basis,
following an assessment of the refiner’s
hardship application, but could be for a
longer period than for relief from the
0.62 vol% standard since credits cannot
be used for compliance with the 1.3
vol% refinery maximum average.
ii. Temporary Waivers Based on
Unforeseen Circumstances
We are also finalizing the proposed
temporary hardship provision based on
unforeseen circumstances, which, at our
discretion, will permit any refiner or
importer to seek temporary relief from
the benzene standards under certain
rare circumstances (see 71 FR 15880).
This waiver provision is similar to
provisions in prior fuel regulations. It is
intended to provide refiners and
importers relief in unanticipated
circumstances—such as a refinery fire or
a natural disaster—that cannot be
reasonably foreseen now or in the near
future. We did not receive comments on
this proposed hardship provision.
To receive hardship relief based on
unforeseen circumstances, a refiner or
importer will be required to show that:
(1) The waiver is in the public interest;
(2) the refiner/importer was not able to
avoid the noncompliance; (3) the
refiner/importer will meet the benzene
standard as expeditiously as possible;
(4) the refiner/importer will make up
the air quality detriment associated with
the nonconforming gasoline, where
practicable; and (5) the refiner/importer
will pay to the U.S. Treasury an amount
equal to the economic benefit of the
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noncompliance less the amount
expended to make up the air quality
detriment. These conditions are similar
to those in the RFG, Tier 2 gasoline
sulfur, and the highway and nonroad
diesel regulations, and are necessary
and appropriate to ensure that any
waivers that are granted will be limited
in scope. Such a request must be based
on the refiner or importer’s inability to
produce compliant gasoline at the
affected facility due to extreme and
unusual circumstances outside the
refiner or importer’s control that could
not have been avoided through the
exercise of due diligence.
For relief from the 0.62 vol% benzene
standard based on unforeseen
circumstances, the hardship request
must also show that other avenues for
mitigating the problem, such as the
purchase of credits toward compliance
under the credit provisions, had been
pursued and yet were insufficient or
unavailable. Hardship relief from that
standard will allow a deficit to be
carried forward for an extended, but
limited, time period (more than the one
year allowed by the rule). The refiner or
importer must demonstrate that the
magnitude of the impact was so severe
as to require such an extension. EPA
will determine an appropriate extended
deficit carry-forward time period based
on the nature and degree of the
hardship, as presented by the refiner or
importer in its hardship application,
and on our assessment of the credit
market at that time.
For relief from the 1.3 vol% refinery
maximum average benzene standard
based on unforeseen circumstances, the
hardship request must show that,
despite its best efforts, the refiner or
importer cannot meet the standard in
the timeframe required. Relief will be
granted on a case-by-case basis,
following an assessment of the refiner’s
hardship application.
c. Option for Early Compliance in
Certain Circumstances
We are finalizing an option that
would allow a refinery to begin
compliance with the MSAT2 benzene
standards earlier than 2011 instead of
maintaining compliance with its
MSAT1 baseline. See 71 FR 15881 for
the proposal’s discussion of this
option.193 We are providing this option
because refineries that meet the criteria
discussed below are already providing
the market with very clean gasoline
from a mobile source air toxics
193 The 1.3 vol% maximum average standard was
not discussed in the proposal vis-a-vis this early
compliance option. However, any refinery approved
for this option should easily meet the 1.3 vol%
standard.
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perspective. In the proposal, we took
comment on such an option, stating that
eligibility for this option would be
limited to those that have historically
better than average toxics performance,
lower than average benzene and sulfur
levels, and a significant volume of
gasoline impacted by the phase-out of
MTBE use. However, in order to qualify
for this option, a refinery must produce
gasoline by processing crude and other
intermediate feedstocks and not merely
be a blender or importer of gasoline, as
discussed later.
A refinery that is approved for this
option would comply with the 0.62
vol% annual average and 1.3 vol%
maximum average benzene standards
and would not be required to continue
to comply with its applicable toxics
performance requirements, i.e., its
MSAT1 baseline and its anti-dumping
or RFG toxics performance standards.
We believe this option is appropriate
because if qualifying refineries had to
continue to comply with MSAT1 194
until 2011, they would likely be forced
to reduce gasoline output in order to
comply, while other refineries or
importers, most likely with less clean
MSAT1 baselines, would provide the
replacement gasoline. The result would
be less supply of these refineries’
cleaner gasoline and more supply of fuel
with higher toxics emissions, leading to
a net detrimental effect on overall
MSAT emissions in the surrounding
region.
We chose 2003 as the period for
determining eligibility for this option
because State MTBE bans began taking
effect in 2004. Refiners who had used
MTBE generally now use ethanol as the
replacement source for oxygen.
Although RFG no longer has an oxygen
requirement 195, MSAT1 baselines were
established when that requirement was
still in place. Even some CG producers
used significant amounts of MTBE as
reflected in their MSAT1 baselines.
Ethanol provides less toxics reduction
benefits than MTBE, and so the refinery
must take other actions in order to
continue to meet its MSAT1 standard.
Consequently, while MSAT1 baseline
adjustments in the past were limited to
RFG, it may be possible for a refinery to
also qualify to adopt MSAT2 early for
its CG pool. Both qualification and the
ability to adopt MSAT2 are allowed
separately for RFG and CG. For
194 While refineries are subject to MSAT1 and
anti-dumping or RFG toxics performance
requirements depending on the gasoline type (CG
and/or RFG) they produce, in almost all cases, the
MSAT1 standard is more stringent than the
corresponding anti-dumping or RFG toxics
standard.
195 71 FR 26691, May 8, 2006.
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example, a refinery that qualifies to
adopt MSAT2 early for RFG will be
permitted to do so for RFG alone while
maintaining its MSAT1 baseline for its
CG, or vice versa.
As mentioned in the proposal, the
criteria for eligibility for early
compliance are similar in concept to
those EPA has used in granting refineryspecific adjustments to MSAT1
baselines, that is, significantly cleaner
than the national average for toxics,
benzene, and sulfur, and relatively high
MTBE use. We re-evaluated those
criteria to determine the numerical
criteria that a refinery would have to
meet in order to qualify for this option.
Specifically, a refinery must at
minimum meet the following criteria:
—2003 annual average benzene level
less than or equal to 0.62 vol%
—2003 annual average MTBE use
greater than 6.0 vol%
—2003 annual average sulfur level less
than 140 ppm
—MSAT1 RFG baseline greater than
30.0% reduction or CG less than 80
mg/mile
Many refineries can reduce benzene
and sulfur levels to reduce toxics
emissions. However, those that used a
significant amount of MTBE and already
have low benzene and sulfur levels also
have fairly stringent toxics emissions
performance standards. As a result, they
may have little ability to further reduce
sulfur or benzene or make other refinery
changes to offset the impact of
switching from MTBE to ethanol.
Refineries that are not in this situation
are not so constrained. We believe that
the criteria above are an appropriate
screening to delineate between these
two groups.
To qualify for this provision we
believe it is appropriate for a refinery to
have used at least 6.0 vol% MTBE in
their gasoline in their 2003 baseline;
when the oxygen provided by this
amount of MTBE is provided instead by
ethanol, a substantial loss in toxics
performance results. A benzene average
of less than or equal to the 0.62 vol%
standard is appropriate because if a
refinery’s average benzene is higher,
they would have to further reduce
benzene to comply with the MSAT2
standard early. However, to qualify for
this provision to switch to MSAT2
early, a refinery should have no viable
options for reducing benzene further to
continue to meet their MSAT1 baseline.
We chose the 140 ppm sulfur level
because we found that even for
refineries with significant MTBE use (in
the 6–13 vol% range), the sulfur
reductions brought about by the Tier 2
gasoline sulfur standard provided
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sufficient benefit to offset much of the
increase in toxics emissions that results
from eliminating MTBE and replacing it
with ethanol. Finally, refineries should
have had MSAT1 baseline toxics
performance significantly cleaner than
the average in order to qualify. The
MSAT1 baseline toxics performance
thresholds listed above were set based
on past experience with baseline
adjustments where we found that only
those with significantly clean baselines
(in addition to low benzene, low sulfur,
and high MTBE use) would have to
reduce production in order to comply
with their MSAT1 standard in the face
of MTBE bans. Thus, we are limiting
this provision to those with relatively
clean baselines as our goal is preventing
the perverse outcome that refineries
with cleaner gasoline may be forced to
reduce their production volume only to
have it be made up by refineries with
dirtier baselines. The threshold helps
ensure that only those refineries in
situations where such an outcome could
realistically have otherwise occurred are
permitted to exercise this option.
Refineries that do not fulfill all of the
threshold requirements may have to
take further refinery processing-related
actions to meet their MSAT1 baseline,
but are unlikely to have to reduce
production and/or have that production
replaced by someone with a less clean
standard.
In addition to meeting the screening
criteria mentioned, a refinery would
still have to apply to EPA to use this
compliance option and would need to
demonstrate that it cannot further
reduce its benzene or sulfur levels, nor
make other refinery processing changes
in order to maintain compliance with its
MSAT1 baseline due to the impact of
switching from MTBE to ethanol.
Details of the application requirements
and approval process are provided in
section 80.1334 of the regulations. We
estimate that less than 10 refineries may
meet the screening criteria and thus
potentially qualify for this option based
on our analysis of their 2003 data and
MSAT1 baselines. Note that this early
compliance option will apply only to
the type of gasoline that qualifies—RFG
or CG—not to the refinery’s total pool.
In 2011, the MSAT2 benzene standards
will apply to the refinery’s total
applicable gasoline pool.
We are limiting this compliance
option to refineries that produce
gasoline by processing crude and
intermediate feedstocks through refinery
processing equipment. Thus, this option
is not available to gasoline blenders and
importers. While gasoline blenders and
importers may have gasoline with
significantly cleaner than average toxics
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performance, benzene and sulfur levels,
and may have used large amounts of
MTBE, they have more options in the
marketplace for obtaining qualifying
gasoline and gasoline blending
components. Refineries have
comparatively less ability to adjust their
refining operations, without
significantly reducing volume, in order
to accommodate the change from MTBE
to ethanol.
Few comments were received
regarding this provision. All
commenters supported the provision.
Many of those suggested that it be
available to any refinery. We continue to
believe that this provision should apply
only to those entities that meet the
criteria above. Those that do not meet
the criteria have the ability to further
adjust their benzene and sulfur content
values to be able to comply with their
MSAT1 baselines. If this provision was
available to all refineries, it could result
in an overall nationwide backsliding on
MSAT1. The intent of this provision is
to provide appropriate relief to a limited
number of entities that have unique
challenges, while at the same time
ensuring that the net result is cleaner
gasoline in the marketplace than would
otherwise be there.
EPA also took comment on when
entities that are approved for this option
should be allowed to begin compliance
with the MSAT2 benzene standards. We
received comment supporting allowing
such compliance for the entire calendar
year 2007, even though the rule will not
be final until partway into that year.
Other suggested options include the
next calendar year, and partial year
compliance for 2007. This latter option
would likely be unworkable under
MSAT1 due to differences between
summer and winter MSAT performance.
Thus, we decided that refineries that are
approved for this option will be allowed
to comply with the MSAT2 benzene
standard for the entire 2007 period. We
have also decided against requiring
approved refineries to wait until the
2008 compliance period because we
want to ensure that gasoline production
from these refineries is maximized, and
waiting until 2008 would not achieve
that goal. Because this is an optional
program for those that qualify, approved
refiners may choose to comply with
MSAT2 beginning in 2007, or beginning
in 2008.
As a final note on this subject, we also
proposed that refineries that meet the
criteria and are approved for early
compliance with the MSAT2 benzene
standards would not be allowed to
generate early benzene credits (see 71
FR 15881). A few commenters thought
that such refineries should be allowed
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to generate early credits. However, the
criteria for generating early credits
require that the refinery reduce benzene
by 10% below its 2004–2005 baseline
benzene level. The early compliance
provision is predicated on the fact that
an approved refinery has almost no
ability to reduce benzene in order to
maintain compliance with its MSAT1
baseline. If such a refinery were able to
further reduce benzene, it would negate
its need for early compliance with the
MSAT2 benzene standard. Therefore,
we are finalizing this early compliance
option with this limitation as proposed.
B. How Will the Gasoline Benzene
Standard Be Implemented?
This section summarizes the main
implementation provisions in the
regulations and provides additional
clarification in a few cases.
1. General Provisions
Compliance with the 0.62 vol%
annual average and 1.3 vol% maximum
average benzene standards is
determined over a refiner’s or importer’s
total gasoline pool, RFG and
conventional gasoline (CG) combined.
For the 0.62 vol% standard, the first
annual compliance period for non-small
refiners and for importers is 2011. For
the 1.3 vol% standard, the first
compliance period for these entities is
July 1, 2012 through December 31, 2013.
Thereafter, compliance is determined
annually. Small refiners will comply
with the 0.62 vol% on an annual basis
beginning in 2015. Compliance with the
1.3 vol% maximum average standard
commences for small refiners on July 1,
2016. For small refiners, the first
compliance period for the 1.3 vol%
standard is July 1, 2016 through
December 31, 2017. Thereafter,
compliance is determined annually.
Compliance with the benzene
standards is achieved separately for
each refinery of a refiner.196 For an
importer, compliance is achieved over
its total volume of imports, regardless of
point of entry. As discussed in the
proposal, gasoline produced by a foreign
refiner is included in the compliance
calculation of the importer of that
gasoline, with certain exceptions for
early credit generation and small foreign
refiners.
Finished gasoline and gasoline
blendstock that becomes finished
gasoline solely upon the addition of
oxygenate are included in the
196 Aggregation of facilities for compliance is not
allowed under this benzene control program.
However, as pointed out in the proposal, the ABT
program’s credit generation and transfer provisions
provide compliance flexibility similar to that
provided by aggregation.
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compliance determination. Gasoline
produced for use in California is not
included. Gasoline produced for use in
the American territories—Guam,
Northern Mariana Islands, American
Samoa—is not subject to the benzene
standard. Gasoline produced for use in
these areas is currently exempt from the
MSAT1 standards, and for the same
reasons we discussed in the MSAT1
final rule 197, including distance from
gasoline producers, low gasoline use,
and distinct environmental conditions,
we are exempting gasoline produced for
these areas from this rule.
Oxygenate and butane blenders are
not subject to the benzene standard
unless they add other gasoline blending
components beyond oxygenates and
butane. Similarly, transmix processors
are not subject to the benzene standard.
We proposed that transmix processors
would be subject to the benzene
standard if they add gasoline blending
components to the gasoline produced
from transmix (see 71 FR 15891). One
commenter suggested that only the
blending component added to the
gasoline produced from transmix should
be subject to the standard because the
transmix processor has no control over
the benzene level in the gasoline
produced from transmix, and the
benzene in the gasoline produced from
transmix would have already been
accounted for by another entity. We
agree with this comment, and have
modified the final rule accordingly.
As discussed earlier, this benzene
program has both an early credit
generation period and a standard credit
generation period that begins when the
program takes effect. Early credits may
be generated from January 1, 2007
through December 31, 2010 by refineries
with approved benzene baselines. For
small refiners, early credit generation
extends through December 31, 2014 for
their refineries with approved benzene
baselines. Benzene baselines are based
on a refinery’s 2004–2005 average
benzene content, and refiners can begin
applying for benzene baselines as early
as March 1, 2007. Although there is no
single cut-off date for applying for a
baseline, refiners planning to generate
early credits must submit individual
refinery baseline applications at least 60
days prior to beginning credit
generation at that refinery.
As explained earlier, in order to
generate early credits, a refinery’s
annual average benzene level must be at
least 10 percent lower than its baseline
benzene level, and the refinery must
show that its low benzene levels result,
in part, from operational changes and/
197 66
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or improvements in benzene control
technology since the baseline period.
Foreign refiners who sent gasoline to the
U.S. during 2004–2005 under their
foreign refiner baseline may generate
early credits if they are able to establish
a benzene baseline and agree to comply
with other requirements that help to
ensure enforcement of the regulation at
the foreign refinery. Early credits
generated or obtained under the ABT
program must be used towards
compliance within three years of the
start of the program; otherwise they will
expire and become invalid. In other
words, early credits must be applied to
the 2011, 2012, or 2013 compliance
years. In the case of small refiners, early
credits must be applied to the 2015,
2016, or 2017 compliance years.
Standard credits may be generated by
refiners and importers beginning with
the 2011 compliance period. Standard
credits may be generated by small
refiners beginning with the 2015
compliance period. For refiners, credits
are generated on a refinery-by-refinery
basis for each facility. For importers,
credits are generated over the total
volume imported, regardless of point of
entry. Foreign refiners are not allowed
to generate standard credits because
compliance for their gasoline is the
responsibility of the importer. In order
to generate standard credits, a refinery’s
or importer’s annual average benzene
level must be less than 0.62 vol%.
Standard credits are valid for five years
from the year they were generated. A
credit life extension exists for standard
credits traded to and ultimately used by
small refiners. These credits may be
used towards compliance for an
additional two years, giving standard
credits a maximum seven-year life.
Compliance with the 0.62 vol%
standard is based on the annual average
benzene content of the refinery’s or
importer’s gasoline production or
importation, any credits used, and any
compliance deficit carried forward from
the previous year. Credits may be used
in any quantity and combination (i.e.,
early or standard credits) to achieve
compliance with the 0.62 vol% benzene
standard beginning with the first
compliance period in 2011, or 2015 for
approved small refiners. For the 2011
and 2012 compliance periods, credits
may be used in any amount, and from
any starting average benzene level. For
example, if the refinery’s annual average
benzene level at the end of 2011 is 1.89
vol%, it may use credits to meet the
0.62 vol% standard for that compliance
period. If its average benzene level at
the end of 2012 is 1.45 vol%, it may
likewise use credits to meet the 0.62
vol% standard for that period.
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The first averaging period for the 1.3
vol% standard for non-small refiners
and importers begins July 1, 2012 and
ends December 31, 2013, an 18-month
period. Similarly, the first averaging
period for the 1.3 vol% standard for
small refiners begins July 1, 2016 and
ends December 31, 2017. Credits may
not be used to achieve compliance with
the 1.3 vol% standard at any time. A
refinery must make capital
improvements and/or operational or
blending practice changes such that it
achieves an actual average benzene level
of no greater than 1.3 vol% for the
initial (18-month) compliance period,
and each annual compliance period
thereafter. (An importer must bring in
gasoline with benzene levels that will
average to 1.3 vol% or less during these
same compliance periods.) Continuing
from our previous example, if at the end
of 2012, the refinery’s average benzene
level is 1.45 vol%, no further action is
yet needed to meet the 1.3 vol%
standard. However, the refinery must
make capital improvements and/or
operational or blending practice changes
such that it achieves an actual average
benzene level of no greater than 1.3
vol% for the 18-month period July 1,
2012-December 31, 2013. We will
assume for this example that the
refinery has a 1.0 vol% average benzene
level at the end of 2013. The refinery
can then use credits to meet the 0.62
vol% standard.
Lack of compliance with the 0.62
vol% standard creates a deficit that may
be carried over to the next year’s
compliance determination. Lack of
compliance with the 0.62 vol% standard
could occur for a number of reasons, for
example, a refinery or importer may
choose not to use (buy) sufficient
offsetting credits. However, in the next
year, the refinery or importer must make
up the deficit (through credit use and/
or refining or import improvements) and
be in compliance with the 0.62 vol%
standard.198 There is no deficit carryforward provision associated with the
1.3 vol% standard. If a refinery or
importer is out of compliance with the
1.3 vol% standard, it is subject to
enforcement action immediately.
2. Small Refiner Status Application
Requirements
A refiner applying for status as a
small refiner under this program is
required to apply to and to provide EPA
with several types of information by
December 31, 2007. The application
requirements are summarized below. A
198 An extension of the period of deficit carryover
may be allowed in certain hardship situations, as
discussed in section A.3.
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8497
refiner seeking small refiner status
under this program would need to apply
to EPA for that status, regardless of
whether or not the refiner had been
approved for small refiner status under
another fuel program. As with
applications for relief under other rules,
applications for small refiner status
under this rule that are later found to
contain false or inaccurate information
would be void ab initio. Requirements
for small refiner status applications
include:
—The total crude oil capacity as
reported to the Energy Information
Administration (EIA) of the U.S.
Department of Energy (DOE) for the
most recent 12 months of operation.
This would include the capacity of all
refineries controlled by a refiner and
by all subsidiaries and parent
companies and their subsidiaries. We
will presume that the information
submitted to EIA is correct. In cases
where a company disagreed with this
information, the company could
petition EPA with appropriate data to
correct the record when the company
submitted its application for small
refiner status. EPA could accept such
alternate data at its discretion.
—The name and address of each
location where employees worked
from January 1, 2005 through
December 31, 2005; and the average
number of employees at each location
during this time period. This must
include the employees of the refiner
and all subsidiaries and parent
companies and their subsidiaries.
—In the case of a refiner who
reactivated a refinery that was
shutdown or non-operational between
January 1, 2005, and January 1, 2006,
the name and address of each location
where employees worked since the
refiner reactivated the refinery and
the average number of employees at
each location for each calendar year
since the refiner reactivated the
refinery.
—The type of business activities carried
out at each location.
—The small refiner option(s) the refiner
intends to use for each refinery.
—Contact information for a corporate
contact person, including: name,
mailing address, phone and fax
numbers, e-mail address.
—A letter signed by the president, chief
operating officer, or chief executive
officer of the company (or a designee)
stating that the information contained
in the application was true to the best
of his/her knowledge and that the
company owned the refinery as of
January 1, 2007.
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3. Administrative and Enforcement
Provisions
Most of the administrative and
enforcement provisions are similar to
those in effect for other gasoline
programs, as discussed in the proposal.
The discussion below highlights those
areas that we wish to clarify and those
that received significant comment.
a. Sampling/Testing
Because compliance with this
program and with the gasoline sulfur
program will become the compliance
mechanism for certain RFG and antidumping requirements, some reporting
simplifications will occur, as described
below. However, sampling, testing, and
reporting of all of the current fuel
parameters will continue to be required.
It is important to continue to monitor
how refiners continue to achieve the
toxics control required of RFG and CG
through fuel composition changes, and
how other toxics emissions may be
affected by this MSAT2 benzene rule.
Continued collection of all of the fuel
parameters will facilitate future toxics
evaluation activities.
We proposed to require every-batch
sampling for CG under this program, but
indicated that results would not have to
be available before the batch leaves the
refinery (see 71 FR 15893). RFG already
is every-batch tested, and the results
must be available before the batch
leaves the refinery because of RFG’s 1.3
vol% per gallon cap. Several
commenters stated that every-batch
testing for CG was unnecessary because
the benzene standard is an average
standard, and that it would be costly,
especially for small refiners. These
commenters requested that continued
composite sampling be allowed for
conventional gasoline.199 Nevertheless,
we are concerned about potential
downstream benzene addition.
Requiring every-batch testing for CG
will allow for closer monitoring of the
movement of high benzene streams. In
this program, we are relying on there
being no significant incentive to dump
benzene-rich streams into gasoline
downstream of the refinery where the
benzene levels are originally measured.
With every-batch benzene testing of all
gasoline, we will be able to better
discern if high benzene batches
originated at the refinery, or
downstream. With composite testing, it
would be significantly more difficult to
determine the source of the high
benzene streams. Thus, we are finalizing
every-batch benzene testing for all
gasoline.
b. Recordkeeping/Reporting
This program will require some new
records to be kept, such as the benzene
baseline, credits generated, and credit
transactions, and new reports to be filed
(e.g., benzene pre-compliance reports).
However, because the current
regulations for RFG and anti-dumping
toxics controls and MSAT1 controls are
being removed, certain recordkeeping
and reporting requirements will be
reduced or eliminated, as detailed in the
regulations. Because the program will
not be fully implemented until small
refiners are also subject to both the 0.62
vol% and the 1.3 vol% benzene
standards, the process of streamlining
the reporting forms will not be complete
until that time.
As mentioned above, in order to
provide an early indication of the credit
market for refiners and importers
planning on relying upon benzene
credits as a compliance strategy in 2011
and beyond, we are requiring refiners to
submit pre-compliance reports to us in
the years leading up to start of the
program. Pre-compliance reporting has
proven to be an indispensable
mechanism in implementing the
gasoline and diesel sulfur programs, and
we expect this to be the case in this
program as well. Refiners are required to
submit annual pre-compliance reports
on June 1st of every year beginning in
2008 and continuing through 2011
(2015 for small refiners). The precompliance reports must contain
engineering and construction plans as
well as actual/projected gasoline
production levels, actual/projected
gasoline benzene levels, and actual/
projected credit generation and use.
Several commenters suggested that
the RFG NOX retail survey be
discontinued after 2006, and that the
RFG toxics retail survey be discontinued
after 2010. The surveys use fuel
parameters of RFG sampled from retail
stations to estimate VOC, NOX, and
toxics emissions. There are also fuel
benzene and oxygen content surveys. If
a survey is ‘‘failed’’, gasoline sent to the
area must meet a more stringent
standard. Because we are finalizing, as
proposed, provisions that make the
gasoline sulfur program the sole
regulatory mechanism used to
implement gasoline NOX requirements,
and the benzene control program the
sole regulatory mechanism used to
implement the toxics requirements of
RFG 200 and anti-dumping, we agree that
the NOX and toxics surveys are no
longer needed. A discussion of the
origin of the survey program, and how
the toxics and NOX requirements for CG
and RFG will be met under the MSAT2
program is provided in Chapter 6.13 of
the RIA for this rulemaking.
C. How Will the Program Relate to Other
Fuel-Related Toxics Programs?
In the proposal we presented an
analysis that examined quantitatively
how the fuel performance under the
new gasoline content standard and
vehicle emissions standard as proposed
would compare to current toxics
performance requirements and to
performance as modified by the Energy
Policy Act of 2005. This analysis
suggested that the fuel standard alone
would exceed previous performance for
RFG, and significantly exceed it for CG.
We have updated the results of this
analysis, using better estimates of future
ethanol use developed for the RFS final
rulemaking, as well as the updated
benzene projections from the refineryby-refinery analysis done for this final
rulemaking. As shown in Table VI.C–1,
these updated analyses continue to
support the conclusion that the MSAT2
fuel program will provide greater toxics
reductions for both CG and RFG.
TABLE VI.C–1.—ESTIMATED ANNUAL AVERAGE TOTAL TOXICS PERFORMANCE OF LIGHT DUTY VEHICLES IN MG/MI UNDER
CURRENT AND PROJECTED SCENARIOS.a
Fleet
year
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Regulatory scenario
MSAT1 Baseline b (1998–2000) .......................................
EPAct Baseline b (RFG: 2001–2002) ...............................
EPAct Baseline, 2011 c ....................................................
MSAT2 program, 2011 c (Fuel standard only) .................
199 Section
80.101(i).
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18:54 Feb 23, 2007
RFG by PADD
I
II
112
104
67
66
129
121
78
76
2002
2002
2011
2011
CG by PADD
III
I
97
87
52
52
II
114
114
62
60
145
145
83
77
200 The 1.3 vol% per gallon cap on RFG benzene
remains.
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26FER2
III
107
107
54
52
IV
145
145
82
74
V
156
156
88
81
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TABLE VI.C–1.—ESTIMATED ANNUAL AVERAGE TOTAL TOXICS PERFORMANCE OF LIGHT DUTY VEHICLES IN MG/MI UNDER
CURRENT AND PROJECTED SCENARIOS.a—Continued
Fleet
year
Regulatory scenario
MSAT2 program, 2011 c (Fuel + vehicle standards) .......
MSAT2 program, 2025 c (Fuel + vehicle standards) .......
RFG by PADD
I
2011
2025
II
64
39
CG by PADD
III
72
45
I
48
31
II
56
36
III
74
45
IV
47
31
V
70
44
78
48
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a Total toxics performance for this analysis includes overall emissions of 1,3-butadiene, acetaldehyde, acrolein, benzene and formaldehyde as
calculated by MOBILE6.2. Although POM appears in the Complex Model, it is not included here. However, it contributes a small and relatively
constant mass to the total toxics figure (∼4%), and therefore doesn’t make a significant difference in the comparisons. Toxics performance figures here are for representative cities in each PADD, and therefore some geographical variation is not captured here.
b Baseline figures generated in this analysis were calculated differently from the regulatory baselines determined as part of the MSAT1 program, and are only intended to be a point of comparison for future year cases.
c Future year scenarios include (in addition to the MSAT2 standards, where stated) effects of the Tier 2 vehicle and gasoline sulfur standards,
and vehicle fleet turnover with time, as well as estimated effects of the renewable fuels standard and the phase-out of ether blending as developed in the RFS rulemaking.
D. How Does This Program Satisfy the
Statutory Requirements of Clean Air Act
Section 202(l)(2)?
As discussed earlier in this section,
we have concluded that the most
effective and appropriate program for
MSAT emission reduction from gasoline
is a benzene control program. We are
finalizing, as proposed, an average
benzene content standard of 0.62 vol%
along with a specially-designed ABT
program, as well as a maximum average
annual standard of 1.3 vol%. In sections
VI.A.1.c and d above, we summarize our
evaluation of the feasibility of the
program, and in section VIII.A we
summarize our evaluation of the costs of
the program. The analyses supporting
our conclusions in these sections are
discussed in detail in Chapters 6 and 9
of the RIA.
Taking all of this information into
account, we believe that a more
stringent program would not be
achievable, taking costs into
consideration. As we have discussed,
making the 0.62 vol% standard more
stringent would require more refiners to
install the more expensive benzene
control equipment, with very little
incremental decrease in benzene
emissions. Also, we have shown that
refinery costs increase very rapidly as
the level of the average standard is made
more stringent, especially for certain
individual technologically-challenged
refineries. We discuss the costs of this
program in detail in section VIII.A of
this preamble and in Chapter 9 of the
RIA. Moreover, the 0.62 vol% standard
achieves significant reductions in
benzene levels nationwide, and
achieves significant reductions in each
PADD. The 1.3 vol% annual average
standard makes it more certain that the
predicted emission reductions will in
fact occur.
Conversely, we believe that a less
stringent national average standard than
0.62 vol% would not satisfy our
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statutory obligation to promulgate the
most stringent standard achievable
considering cost and other factors along
with technological feasibility.
Furthermore, as discussed in section
VI.A, less stringent standards would not
accomplish several important
programmatic objectives, such as
avoiding the triggering of the provisions
in the 2005 EPAct to adjust the MSAT1
baseline for RFG. We have also
considered energy implications of the
proposed program, as well as noise and
safety, and we believe that the MSAT2
program will have very little impact on
any of these factors (although, as
explained in section VI.A above, some
of the alternative toxic control strategies
urged by commenters could have
adverse energy supply implications).
Analyses supporting these conclusions
are also found in Chapter 9 of the RIA.
We carefully considered lead time in
establishing the stringency and timing
of the proposed program (see section
VI.A above).
We have carefully reviewed the
technological feasibility (see section
VI.A.1.c.i above and chapter 6 of the
RIA) and costs of this program. Based on
the considerations outlined in this
section VI, we conclude that this
program meets the requirements of
section 202(l)(2) of the Clean Air Act,
reflecting ‘‘the greatest degree of
emission reduction achievable through
the application of technology which is
available, taking into consideration
* * * the availability and costs of the
technology, and noise, energy, and
safety factors, and lead time.’’
VII. Portable Fuel Containers
As described in this section, we are
adopting new HC emissions standards
for portable gasoline containers (gas
cans) essentially as proposed. We are
also finalizing the same requirements
for portable diesel and kerosene
containers, containers which could
easily be used for gasoline.
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Manufacturers must begin meeting the
new requirements on January 1, 2009.
These new emissions control
requirements will reduce HC emissions
from uncontrolled gasoline containers
by about 75%, including reducing
spillage losses. The final rule also
includes new certification and
compliance requirements that will help
ensure that the containers achieve
emissions control in use over the life of
the container. The standards and
program requirements we are finalizing
are very similar to those adopted by
California in 2005, so that
manufacturers will be able to sell 50state products. Overall, commenters
were very supportive of the proposed
new emissions control program for
portable fuel containers.
We are establishing the portable fuel
container (PFC) standards and
emissions control requirements under
section 183(e) of the Clean Air Act,
which directs EPA to study, list, and
regulate consumer and commercial
products that are significant sources of
VOC emissions. In 1995, after
conducting a study and submitting a
Report to Congress on VOC emissions
from consumer and commercial
products, EPA published an initial list
of product categories to be regulated
under section 183(e). Based on criteria
that we established pursuant to section
183(e)(2)(B), we listed for regulation
those consumer and commercial
products that we considered at the time
to be significant contributors to the
ozone nonattainment problem, but we
did not include PFC emissions.201 After
analyzing the emissions inventory
impacts of these containers, we
published a Federal Register notice that
added PFCs to the list of consumer
201 60 FR 15264 ‘‘Consumer and Commercial
Products: Schedule for Regulation,’’ March 23,
1995.
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products to be regulated.202 We
requested comment on the data
underlying the listing but did not
receive any comments.203 We continue
to believe that the standards we
proposed and are finalizing for fuel
containers represent ‘‘best available
controls’’ as required by section
183(e)(3)(A). Determination of the ‘‘best
available controls’’ requires EPA to
determine the degree of reduction
achievable through use of the most
effective control measures (which
includes chemical reformulation, and
other measures) after considering
technological and economic feasibility,
as well as health, energy, and
environmental impacts.204
A. What Are the New HC Emissions
Standards for PFCs?
1. Description of Emissions Standard
We are finalizing as proposed a
performance-based standard of 0.3
grams per gallon per day (g/gal/day) of
HC to control evaporative and
permeation losses. The standard will be
measured based on the emissions from
the container over a diurnal test cycle.
The cans will be tested as a system with
their spouts attached. Manufacturers
will test the containers by placing them
in an environmental chamber which
simulates summertime ambient
temperature conditions and cycling the
containers through the 24-hour
temperature profile (72–96 °F), as
discussed below. The test procedures,
which are described in more detail
below, ensure that containers meet the
emissions standard over a range of inuse conditions such as different
temperatures, different fuels, and taking
into consideration factors affecting
durability. EPA received only
supportive comments on the proposed
emissions standards.
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2. Determination of Best Available
Control
We continue to believe that the 0.3 g/
gal/day emissions standard and
associated test procedures reflect the
performance of the best available
control technologies including durable
permeation barriers, auto-closing
spouts, and a can that is well-sealed to
reduce evaporative losses. The standard
202 71 FR 28320 ‘‘Consumer and Commercial
Products: Schedule for Regulation,’’ May 16, 2006.
203 See not only the notice cited in the previous
note, but also 71 FR 15894 (‘‘EPA will afford
interested persons the opportunity to comment on
the data underlying the listing before taking final
action on today’s proposal’’).
204 See section 183(e)(1); see also section 183(e)(4)
providing broad authority to include ‘‘systems of
regulation’’ in controlling VOC emissions from
consumer products.
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18:54 Feb 23, 2007
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is both economically and
technologically feasible. To comply
with California’s program, gas can
manufacturers have developed gas cans
with low VOC emissions at a reasonable
cost (see section XIII. for costs). Testing
of cans designed to meet CARB
standards has shown the new standards
to be technologically feasible. When
tested over cycles very similar to those
we are adopting, emissions from these
cans have been in the range of 0.2–0.3
g/gal/day.205 These cans have been
produced with permeation barriers
representing a high level of control (over
90 percent reductions) and with autoclosing spouts, which are technologies
that represent best available controls for
gas cans. Establishing the standard at
0.3 g/gal/day will require the use of best
available technologies. As discussed in
the proposal, we are finalizing a level at
the upper end of the tested performance
range to account for product
performance variability (see 71 FR
15896). In addition, we believe that
current best designs can achieve these
levels, so we do not believe that the
standard forecloses use of any of the
existing performing product designs.
Our detailed feasibility analysis is
provided in the Regulatory Impact
Analysis. We did not receive any
comments on our feasibility analysis.
In addition to considering
technological and economic feasibility,
section 183(e)(1)(A) requires us to
consider ‘‘health, environmental, and
energy impacts’’ in assessing best
available controls. Environmental and
health impacts are discussed in section
III. Moreover, control of spillage from
containers may reduce fire hazards as
well because cans would stay tightly
closed if tipped over. We expect the
energy impacts of gas can control to be
positive, because the standards will
reduce evaporative fuel losses.
3. Diesel, Kerosene and Utility
Containers
Diesel and kerosene containers are
manufactured by the same
manufacturers as are gasoline containers
and are identical to gasoline containers
except for color (diesel containers are
yellow and kerosene containers are
blue). In the proposal, we requested
comment on applying the emissions
control requirements being proposed for
gasoline containers to diesel and
kerosene containers (see 71 FR 15897).
California included diesel and kerosene
cans in their regulations largely due to
205 ‘‘Quantification of Permeation and
Evaporative Emissions From Portable Fuel
Container’’, California Air Resources Board, June
2004.
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the concern that they would be
purchased as substitutes for gasoline
containers. We received only supportive
comments for including these
containers in the program. Several states
and state organizations urged EPA to
include these containers in the EPA
program, viewing their omission as a
significant difference between the
California program and EPA’s proposed
program.
We recognize that using uncontrolled
diesel and kerosene containers as a
substitute for gasoline containers would
result in a loss of emissions reductions.
California collected limited survey data
which indicated that about 60 percent of
kerosene containers were being used for
gasoline. In addition, keeping gasoline
in containers marked for other fuels
could lead to misfueling of equipment
and possible safety issues. Finally, not
including these containers would likely
be viewed as a gap in EPA’s program,
resulting in states adopting or retaining
their own emissions control program for
PFCs. This would hamper the ability of
manufacturers to have a 50-state
product line. For these reasons, we are
including diesel and kerosene
containers in the program.
We are also clarifying that utility jugs
are considered portable gasoline
containers and therefore are subject to
the program. They are designed and
marketed for use with gasoline, often to
fuel recreational equipment such as allterrain vehicles and personal watercraft.
This interpretation is consistent with
the scope of the California program.
California recently issued a clarification
that these containers are covered by
their program, after some utility jug
manufacturers failed to meet the
existing California requirements.
4. Automatic Shut-Off
We received a few comments
encouraging EPA to consider or evaluate
spillage control requirements.
California’s original program which
began in 2001 required automatic shutoff as a way to reduce spillage.
However, for reasons discussed in the
proposal, we did not propose and are
not finalizing automatic shut-off
requirements (see 71 FR 15896).
Automatic shut-off is supposed to stop
the flow of fuel when the fuel reaches
the top of the receiving tank in order to
prevent over-filling. However, due to a
wide variety of receiving fuel tank
designs, the auto shut-off spouts do not
work well with a variety of equipment
types. In California, this problem led to
spillage and consumer dissatisfaction,
and California has removed automatic
shut-off requirements from their
program.
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We continue to believe that including
an automatic shut-off requirement
would be counterproductive at this
time. We believe that the automatic
closing cans, even without automatic
shut-off requirements, will lead to
reduced spillage. Consumers will be
able to watch the fuel rise in the
receiving tank and stop fuel flow using
the automatic close features prior to
overfill. As discussed in the proposal,
automatic closure keeps the cans closed
when they are not in use and provides
more control to the consumer during
use. We believe consumers will
appreciate this feature and see it as an
improvement over existing cans,
whereas an automatic shut-off that
worked with only some equipment
types would not be acceptable.
B. Timing of Standard
We are finalizing as proposed a start
date for the new PFC standards of
January 1, 2009. We received comments
from state organizations recommending
that the program start on January 1,
2008. In the proposal we recognized that
adequate lead time is a key aspect of the
standard’s technological feasibility.
Manufacturers have developed the
primary technologies to reduce
emissions from gas cans but will need
a few years of lead time to certify
products and ramp up production to a
national scale. The certification process
will take at least six months due to the
required durability demonstrations
described below, and manufacturers
will need time to procure and install the
tooling needed to produce gas cans with
permeation barriers for nationwide
sales. Commenters did not provide any
new information to counter these points
and we continue to believe for these
reasons that the January 1, 2009 start
date is appropriate.
The standards apply to containers
manufactured on or after the start date
of the program and do not affect cans
produced before the start date. As
proposed, as of July 1, 2009,
manufacturers and importers must not
enter into U.S. commerce any products
not meeting the emissions standards.
This provides manufacturers with a 6month period to clear any stocks of
containers manufactured prior to the
January 1, 2009 start of the program,
allowing the normal sell-through of
these cans to the retail level. Retailers
may sell their stocks of containers
through the course of normal business
without restriction. Containers are
required by this rule to be stamped with
their production date (consistent with
current industry practices), which will
allow EPA to determine which cans are
required to meet the new standards. We
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did not receive any comments on these
aspects of the proposal or comments
suggesting that the proposed lead times
would not be adequate.
C. What Test Procedures Would Be
Used?
As proposed, we are finalizing a
system of regulations for containers that
includes test conditions designed to
assure that the intended emission
reductions occur over a range of in-use
conditions such as operating at different
temperatures, with different fuels, and
considering factors affecting durability.
These test procedures are authorized
under section 183(e)(4) as part of a
system of regulations to achieve the
appropriate level of emissions
reductions. Emission testing on all
containers that manufacturers produce
is not feasible due to the high annual
production volumes and the cost and
time involved with emissions testing.
Instead, before the containers are
introduced into commerce, the
manufacturer will need to receive a
certificate of conformity from EPA that
the containers conform to the emissions
standards, based on manufacturers’
applications for certification.
Manufacturers must submit test data on
a sample of containers that are
prototypes of the products the
manufacturer intends to produce. The
certificate issued by EPA will cover the
range of production containers
represented by the prototype container.
As part of the application for
certification, manufacturers also need to
declare that their production cans will
not deviate in materials or design from
the prototype cans that are tested. If the
production containers do deviate, then
they will not be coved by the certificate
and it will be a violation of the
regulations to introduce such
uncertified containers into commerce.
Manufacturers must obtain their
certification from EPA prior to
introducing their products into
commerce. The test procedures and
certification requirements are described
in detail below. Unless otherwise noted
below, we did not receive comments on
these test procedures.
We are requiring that manufacturers
test cans in their most likely storage
configuration. The key to reducing
evaporative losses from gasoline
containers is to ensure that there are no
openings on the cans that could be left
open by the consumer. Traditional cans
have vent caps and spout caps that are
easily lost or left off cans, which leads
to very high evaporative emissions. We
expect manufacturers to meet the
evaporative standards by using
automatic closing spouts and by
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removing other openings that
consumers could leave open. However,
if manufacturers choose to design cans
with an opening that does not close
automatically, we are requiring that
containers be tested in their open
condition. If the containers have any
openings that consumers could leave
open (for example, vents with caps),
these openings thus would need to be
left open during testing. This applies to
any opening other than where the spout
attaches to the can. We believe it is
important to take this approach because
these openings could be a significant
source of in-use emissions and there is
a realistic possibility that these
openings would be inadvertently left
open in use.
Except for pressure cycling, discussed
below, spouts would be in place during
testing because this would be the most
likely storage configuration for the
emissions compliant cans. Spouts
would still be removable so that
consumers would be able to refill the
cans, but we would expect the
containers to be resealed by consumers
after being refilled in order to prevent
spillage during transport. We do not
believe that consumers would routinely
leave spouts off cans because spouts are
integral to the cans’ use and it is
obvious that they need to be sealed.
1. Diurnal Test
We are finalizing as proposed a test
procedure for diurnal emissions testing
where the containers are placed in an
environmental chamber or a Sealed
Housing for Evaporative Determination
(SHED), the temperature is varied over
a prescribed temperature and time
profile, and the hydrocarbons escaping
from the can are measured. Containers
are to be tested over the same 72–96 °F
(22.2–35.6 °C) temperature profile used
for automotive applications. This
temperature profile represents a hot
summer day when ground level ozone
emissions would be highest. Three
containers must be tested, each over a
three-day test. Testing three cans for
certification will help address
variability in products or test
measurements. All three cans must
individually meet the standard. As
noted above, cans must be tested in
their most likely storage configuration.
The final results are to be reported in
grams per gallon, where the grams are
the mass of hydrocarbons escaping from
the container over 24 hours and the
gallons are the nominal can capacity.
The daily emissions will then be
averaged for each can to demonstrate
compliance with the standard. This test
captures hydrocarbons lost through
permeation and any other evaporative
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losses from the container as a whole.
The grams of hydrocarbons lost may be
determined by either weighing the gas
can before and after the diurnal test
cycle or measuring emissions directly
using the SHED instrumentation.
Consistent with the automotive test
procedures, we are requiring that the
testing take place using 9 pounds per
square inch (psi) Reid Vapor Pressure
(RVP) certification gasoline, which is
the same fuel required by EPA to be
used in its other evaporative test
programs. We are requiring testing be
done using E10 fuel (10% ethanol
blended with the gasoline described
above) to help ensure in-use emission
reductions on ethanol-gasoline blends,
which tend to have increased
evaporative emissions with certain
permeation barrier materials. We
continue to believe that including
ethanol in the test fuel will lead to the
selection of materials by manufacturers
that are consistent with ‘‘best available
control’’ requirements for all likely
contained gasolines, and is clearly
appropriate given the expected increase
over time of the use of ethanol blends
of gasoline under the renewable fuel
provisions of the Energy Policy Act of
2005.
Diurnal emissions are not only a
function of temperature and fuel
volatility, but of the size of the vapor
space in the container as well. We are
finalizing as proposed that the fill level
at the start of the test be 50% of the
nominal capacity of the can. This would
likely be the average fuel level of the gas
can in-use. Nominal capacity of the cans
is defined as the volume of fuel,
specified by the manufacturer, to which
the can could be filled when sitting on
level ground. The vapor space that
normally occurs in a container, even
when ‘‘full,’’ would not be considered
in the nominal capacity of the can. All
of these test requirements are meant to
represent typical in-use storage
conditions for containers, on which EPA
can base its emissions standards. The
above provisions for diurnal testing are
included as a way to implement the
standards effectively, which, in
conjunction with the new emissions
standard, will lead to the use of best
available technology at a reasonable
cost. We did not receive comment on
these test procedures.
Before testing for certification, the
container must be run through the
durability tests described below. Within
8 hours of the end of the soak period
contained in the durability cycle, the
cans are to be drained and refilled to 50
percent nominal capacity with fresh
fuel, and then the spouts re-attached.
When the can is drained, it must be
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immediately refilled to prevent it from
drying out. The timing of these steps is
needed to ensure that the stabilized
permeation emissions levels are
retained. The can will then be weighed
and placed in the environmental
chamber for the diurnal test. After each
diurnal, the can must be re-weighed. In
lieu of weighing the container,
manufacturers may opt to measure
emissions from the SHED directly. For
any in-use testing of containers, the
durability procedures will not be run
prior to testing.
California’s test procedures are very
similar to those described above.
However, the California procedure
contains a more severe temperature
profile of 65–105 °F. As proposed, we
will allow manufacturers to use this
temperature profile to test cans as long
as other parts of the EPA test procedures
are followed, including the durability
provisions below.
2. Preconditioning to Ensure Durable InUse Control
a. Durability Cycles
As proposed, we are specifying three
durability aging cycles to help ensure
durable permeation barriers: slosh,
pressure-vacuum cycling, and
ultraviolet (UV) exposure. They
represent conditions that are likely to
occur in-use for gas cans, especially for
those cans used for commercial
purposes and carried on truck beds or
trailers. The purpose of these
deterioration cycles is to help ensure
that the technology chosen by
manufacturers is durable in-use,
representing best available control, and
the measured emissions are
representative of in-use permeation
rates. Fuel slosh, pressure cycling, and
ultraviolet (UV) exposure each impact
the durability of certain permeation
barriers, and we believe these cycles are
needed to ensure long-term emissions
control. Without these durability cycles,
manufacturers could choose to use
materials that meet the standard when
they are new but have degraded
performance in-use, leading to higher
emissions. We do not expect these
procedures to adversely impact the
feasibility of the standards, because
there are permeation barriers available
at a reasonable cost that do not
deteriorate significantly under these
conditions (these permeation barriers
are examples of best available controls).
For slosh and pressure cycling, we are
finalizing durability tests that are based
on draft recommended SAE practice for
evaluating permeation barriers.206 For
206 Draft SAE Information Report J1769, ‘‘Test
Protocol for Evaluation of Long Term Permeation
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slosh testing, the container is to be filled
to 40 percent capacity with E10 fuel and
rocked for 1 million cycles. The
pressure-vacuum testing contains
10,000 cycles from ¥0.5 to 2.0 psi. This
pressure may be applied through the
opening where the spout attaches, in
order to avoid the need to drill a hole
in the container. The third durability
test is intended to assess potential
impacts of ultraviolet (UV) sunlight (0.2
µm–0.4 µm) on the durability of a
surface treatment. In this test, the
container must be exposed to a UV light
of at least 0.40 Watt-hour/meter 2
/minute on the container surface for 15
hours per day for 30 days. Alternatively,
containers may be exposed to direct
natural sunlight for an equivalent period
of time. We have also established these
same durability requirements as part of
our program to control permeation
emissions from recreational vehicle fuel
tanks.207 While there are obvious
differences in the use of gas cans
compared to the use of recreational
vehicle fuel tanks, we believe the test
procedures offer assurance that
permeation controls used by
manufacturers will be robust and will
continue to perform as intended when
in use.
Manufacturers may also do an
engineering evaluation, based on data
from testing on their permeation barrier,
to demonstrate that one or more of these
factors (slosh, UV exposure, and
pressure cycle) do not impact the
permeation rates of their fuel containers
and therefore that the durability cycles
are not needed. Manufacturers may use
data collected previously on gas cans or
other similar containers made with the
same materials and processes to
demonstrate that the emissions
performance of the materials does not
degrade when exposed to slosh, UV,
and/or pressure cycling. The test data
must be collected under equivalent or
more severe conditions as those noted
above. EPA must approve an alternative
demonstration method prior to its use
for certification.
b. Preconditioning Fuel Soak
It takes time for fuel to permeate
through the walls of containers.
Permeation emissions will increase over
time as fuel slowly permeates through
the container wall, until the permeation
finally stabilizes when the saturation
point is reached. We want to evaluate
emissions performance once permeation
Barrier Durability on Non-Metallic Fuel Tanks,’’
(Docket A–2000–01, document IV–A–24).
207 Final Rule, ‘‘Control of Emissions from
Nonroad Large Spark-ignition engines, and
Recreational Engines (Marine and Land-based)’’, 67
FR 68287, November 8, 2002.
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emissions have stabilized, to ensure that
the emissions standard is met in-use.
Therefore, as proposed, prior to testing
the containers, the cans need to be
preconditioned by allowing the cans to
sit with fuel in them until the
hydrocarbon permeation rate has
stabilized. Under this step, the container
is filled with a 10-percent ethanol blend
in gasoline (E10), sealed, and soaked for
20 weeks at a temperature of 28 ± 5 °C.
As an alternative, the fuel soak may be
performed, for example, for 10 weeks at
43 ± 5 °C to shorten the test time, if the
certifier can demonstrate that the
hydrocarbon permeation rate has
stabilized. During this fuel soak, the
container must be sealed with the spout
attached. This is representative of how
the gas cans would be stored in-use. We
have established these soak
temperatures and durations based on
protocols EPA has established to
measure permeation from fuel tanks
made of HDPE.208 These soak times
should be sufficient to achieve
stabilized permeation emission rates.
However, if a longer time period is
necessary to achieve a stabilized rate for
a given container, the manufacturer
must use a longer soak period (and/or
higher temperature) consistent with
good engineering judgment.
Durability testing that is performed
with fuel in the container may be
considered part of the fuel soak
provided that the container
continuously has fuel in it. This
approach would shorten the total test
time. For example, the length of the UV
and slosh tests may be considered as
part of the fuel soak provided that the
container is not drained between these
tests and the beginning of the fuel soak.
In such cases, manufacturers must use
the 40 percent fill level for the soak
period. The reduced fill level will not
affect the permeation rate of the
container because the vapor space in the
container will be saturated with fuel
vapor.
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c. Spout Actuation
In its recently revised program for
PFCs, California included a durability
demonstration for spouts. We are
finalizing as proposed a durability
demonstration consistent with
California’s procedures. Automatically
closing spouts are a key part of the
emissions controls expected to be used
to meet the new standards. If these
spouts stick or deteriorate, in-use
emissions could remain very high, at
208 Final Rule, ‘‘Control of Emissions from
Nonroad Large Spark-ignition engines, and
Recreational Engines (Marine and Land-based)’’, 67
FR 68287, November 8, 2002.
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essentially uncontrolled levels.
California requires manufacturers to
actuate the spouts 200 times prior to the
soak period and 200 times near the
conclusion of the soak period to
simulate spout use. The spouts’ internal
components would be required to be
exposed to fuel by tipping the can
between each cycle. Spouts that stick
open or leak during these cycles would
be considered failed. The total of 400
spout actuations represents about 1.5
actuations per week on average over the
average container life of 5 years. In the
absence of data, we believe this number
of actuations appears to reasonably
replicate the number that can occur inuse for high-end usage and will help
ensure quality spout designs that do not
fail in-use. We also believe that
finalizing requirements consistent with
California will help manufacturers to
avoid duplicate testing.
One commenter stated that 400
actuations over a short period of time is
not representative of real life and that
many containers will last 15–25 years.
In response, we understand that 5 years
is an estimate of the average life and
that some containers will be used longer
than 5 years. However, we continue to
believe that the approach we are
finalizing is reasonable. This provision
is meant to help ensure that spouts are
made of quality materials so that the
emissions performance will not
deteriorate readily during normal use.
The provision also helps to ensure that
spouts will not break easily or stick
open during normal use, and helps to
identify issues during the certification
process prior to sale. In addition, this
approach balances the need to ensure
quality designs with the manufacturers’
need to be able to conduct certification
testing in a reasonable amount of time.
This type of ‘‘accelerated aging’’ of
components is a necessary part of many
of EPA’s mobile source emissions
control programs.
D. What Certification and In-Use
Compliance Provisions Is EPA
Adopting?
1. Certification
Section 183(e)(4) authorizes EPA to
adopt appropriate systems of regulations
to implement the program, including
requirements ranging from registration
and self-monitoring of products, to
prohibitions, limitations, economic
incentives and restrictions on product
use. We are finalizing as proposed a
certification mechanism pursuant to
these authorities. Manufacturers are
required to apply for and receive an
EPA certificate of conformity, using the
certification process specified in the
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regulations, before entering their
containers into U.S. commerce. To have
their products certified, manufacturers
must first define their emission families.
This is generally based on selecting
groups of products that have similar
emissions. For example, co-extruded
containers of various geometries could
be grouped together. The manufacturer
must select a worst-case configuration
for testing, such as the thinnest-walled
container. Manufacturers may group
gasoline, diesel, and kerosene
containers together as long as the
containers do not differ materially in a
way that could be anticipated to cause
differences in emissions performance.
These determinations must be made
using good engineering judgment and
are subject to EPA review. Testing with
those products, as specified above, must
show compliance with emission
standards. The manufacturers must then
send us an application for certification.
As proposed, we define the
manufacturer as the entity that is in dayto-day control of the manufacturing
process (either directly or through
contracts with component suppliers)
and responsible for ensuring that
components meet emissions-related
specifications. Importers are not
considered a manufacturer under this
program, and thus would not receive
certificates. The manufacturers of the
PFCs they import would have to certify
the cans. Importers will only be able to
import PFCs that are certified.
After reviewing the information in the
application, if all the required
information is provided and it
demonstrates compliance with the
standards, then we will issue a
certificate of conformity allowing
manufacturers to introduce into
commerce the containers from the
certified emission family. We expect
EPA review to typically take about 90
days or less, but could be longer if we
have questions regarding the
application. The certificate of
conformity will be for a production
period of up to 5 years. Manufacturers
are allowed to carry over certification
test data if no changes are made to their
products that would affect emissions
performance. We may revoke or void a
certificate if we find that data and
information on which it is based is false
or inaccurate. We will notify the
manufacturer in writing and the
manufacturer may request a hearing.
Changes to the certified products that
affect emissions require reapplication
for certification. Manufacturers wanting
to make changes without doing testing
are required to present an engineering
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evaluation demonstrating that emissions
are not affected by the change.
The manufacturer is responsible for
meeting applicable emission standards.
Importers are also responsible for the
product meeting the standards. While
we are not including requirements for
manufacturers to conduct productionline testing, we may pursue EPA in-use
testing of certified products to evaluate
compliance with emission standards. If
we find that containers do not meet
emissions standards in use, we would
consider the new information during
future product certification. Also, we
may require certification prior to the
end of the 5-year production period
otherwise allowed between
certifications. The details of the
certification process are provided in the
regulatory text. We did not receive any
comments on the certification
procedures described above.
EPA is authorized under the
Independent Offices Appropriation Act
of 1952 to establish fees for Government
services and things of value that it
provides. This provision encourages
Federal regulatory agencies to recover,
to the fullest extent possible, costs
provided to identifiable recipients. The
agency currently collects fees for
compliance programs administered by
EPA including those for certification of
motor vehicles and motor vehicle
engines. At this time, we are not
finalizing a fee program for PFC
certification. However, we may establish
a certification fee for PFCs in a future
rulemaking.
2. Emissions Warranty and In-Use
Compliance
We are finalizing as proposed an
emissions warranty period of one year
to be provided by the manufacturer of
the PFC to the consumer. The warranty
covers emissions-related materials
defects and breakage under normal use.
For example, the warranty covers
failures related to the proper operation
of the auto-closing spout or defects with
the permeation barriers. We are also
requiring that manufacturers submit a
warranty and defect report documenting
successful warranty claims and the
reason for the claim to EPA annually so
that EPA may monitor the program.
Unsuccessful claims will not need to be
submitted. We believe that this warranty
will encourage designs that work well
for consumers and are durable.
Although it does not fully cover the
average life of the product, it is not
typical for very long consumer
warranties to be offered with such
products and therefore we believe a oneyear warranty is reasonable. Also, the
warranty period is more similar to the
expected life of gas cans when used in
commercial operations, which would
need to be considered by the
manufacturers in their designs. We did
not receive any comments on these
warranty provisions.
EPA views this aspect of the final rule
as another part of the ‘‘system of
regulation’’ it is finalizing to control
VOC emissions from PFCs. A warranty
will promote the objective of the rule by
providing consumers with an
opportunity to replace containers that
have failed in use. The warranty
provides an obvious remedy to
consumers if issues arise. The provision
also helps to ensure that manufacturers
will ‘‘stand behind’’ their product if
they fail in use, thus improving product
design and performance. Similarly, the
defect reporting requirement will
promote product integrity by allowing
EPA to readily monitor in-use
performance by tracking successful
warranty claims.
Gas cans have a typical life of about
5 years on average before they are
scrapped. We are including durability
provisions as part of certification testing
to help ensure containers perform well
in use. Under this final rule, we could
test containers within their five-year
useful life period to monitor in-use
performance and take steps to correct
in-use failures, including denying
certification, for container designs that
are consistently failing to meet
emissions standards. (This provision
thus would work in tandem with the
warranty claim reporting provision
contained in the preceding paragraph.)
3. Labeling
Since the requirements will be
effective based on the date of
manufacture of the container, we are
requiring as proposed that the date of
manufacture must be indelibly marked
on the can. This is consistent with
current industry practices. This is
needed so that we and others can
recognize whether a unit is regulated or
not. In addition, we are requiring a label
providing the manufacturer name and
contact information, a statement that the
can is EPA certified, citation of EPA
regulations, and a statement that it is
warranted for one year from the date of
purchase. The manufacturer name and
contact information is necessary to
verify certification. Indicating that a
one-year warranty applies will ensure
that consumers have knowledge of the
warranty and a way to contact the
manufacturer. Enforcement of the
warranty is critical to the defect
reporting system. In finalizing this
labeling requirement, we further
believe, pursuant to CAA section
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183(e)(8), that these labeling
requirements will be useful in meeting
the NAAQS for ozone. They provide
necessary means of implementing the
various measures described above
which help ensure that VOC emission
reductions from the proposed standard
will in fact occur in use. We did not
receive any comments on these labeling
requirements.
E. How Would State Programs Be
Affected By EPA Standards?
Several states have adopted emissions
control programs for PFCs. California
implemented an emissions control
program for PFCs in 2001. Fifteen other
states, mostly in the northeast, have
adopted or are considering adopting the
California program.209 In 2005,
California adopted a revised program,
which will go into effect on July 1, 2007.
The revised California program is very
similar to the program we are finalizing.
We believe that although a few aspects
of the program we are finalizing are
different, manufacturers will be able to
meet both EPA and CARB requirements
with the same container designs and
therefore sell a single product in all 50
states. In most cases, we believe
manufacturers will take this approach.
By closely aligning with California
where possible, we will allow
manufacturers to minimize research and
development (R&D) and emissions
testing, while potentially achieving
better economies of scale. It may also
reduce administrative burdens and
market logistics from having to track the
sale of multiple can designs. We
consider these to be important factors
under CAA section 183(e) which
requires us to consider economic
feasibility of controls.
States that have adopted the original
California program will likely choose to
either adopt the new California program
or eliminate their state program in favor
of the federal program. Because the
programs are similar, we expect that
most states will eventually choose to
rely on implementation of the EPA
program rather than continue their own
program. Including diesel and kerosene
containers in our final program further
aligns the two programs and several
states commented in support of this
approach. We expect very little
difference in the emissions reductions
provided by the EPA and California
programs in the long term.
209 Delaware, Maine, Maryland, Pennsylvania,
New York, Connecticut, Massachusetts, New Jersey,
Rhode Island, Vermont, Virginia, Washington DC,
Texas, Ohio, and New Hampshire.
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2. Second Type of Hardship Provision
F. Provisions for Small PFC
Manufacturers
As discussed in previous sections,
prior to issuing our proposal for this
rulemaking, we analyzed the potential
impacts of these regulations on small
entities. As a part of this analysis, we
convened a Small Business Advocacy
Review Panel (SBAR Panel, or ‘‘the
Panel’’). During the Panel process, we
gathered information and
recommendations from Small Entity
Representatives (SERs) on how to
reduce the impact of the rule on small
entities, and those comments are
detailed in the Final Panel Report which
is located in the public record for this
rulemaking (Docket EPA–HQ–OAR–
2005–0036). Based upon these
comments, we proposed to include
flexibility and hardship provisions for
container manufacturers. Since nearly
all manufacturers are small entities and
they account for about 60 percent of
sales, the Panel recommended that we
extend the flexibility options and
hardship provisions to all
manufacturers. Our proposal was
consistent with that recommendation.
We did not receive any comments on
our proposed flexibilities and are
finalizing them as proposed. The
flexibility provisions are incorporated
into the program requirements
described earlier in sections VII.B
through VII.D. The hardship provisions
are described below. For further
discussion of the Panel process, see
section X.C of this rule and/or the Final
Panel Report.
The Panel recommended and we are
finalizing two types of hardship
provisions for container manufacturers.
These entities could, on a case-by-case
basis, face hardship, and we are
finalizing these provisions to provide
what could prove to be needed safety
valves for these entities. Thus, the
hardship provisions are as follows:
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1. First Type of Hardship Provision
Container manufacturers may petition
EPA for limited additional lead-time to
comply with the standards. A
manufacturer would have to
demonstrate that it has taken all
possible business, technical, and
economic steps to comply but the
burden of compliance costs prevents it
from meeting the requirements of this
subpart by the required compliance date
and not having an extension would
jeopardize the company’s solvency.
Hardship relief may include
requirements for interim emission
reductions.
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Container manufacturers are
permitted to apply for hardship relief if
circumstances outside their control
cause the failure to comply (i.e., an ‘‘Act
of God,’’ a fire at the manufacturing
plant, or the unforeseen shut down of a
supplier with no alternative available),
and if failure to sell the subject
containers would jeopardize the
company’s solvency. The terms and
timeframe of the relief will depend on
the specific circumstances of the
company and the situation involved.
For both types of hardship provisions,
the length of the hardship relief will be
established, during the initial review,
for not more than one year and will be
reviewed annually thereafter as needed.
As part of its application, a company is
required to provide a compliance plan
detailing when and how it will achieve
compliance with the standards.
VIII. What Are the Estimated Impacts
of the Rule?
A. Refinery Costs of Gasoline Benzene
Reduction
The benzene control program we are
finalizing today is expected to result in
many refiners investing in benzene
control hardware and changing the
operations in their refineries to reduce
their gasoline benzene levels. The
finalized benzene control program
requires refiners and importers to
reduce their gasoline benzene levels on
average down to 0.62 vol% benzene.
The averaging, banking and trading
(ABT) provisions being finalized along
with the 0.62 vol% average benzene
control standard allows refineries that
reduce their gasoline benzene levels
below 0.62 vol% to earn credits and
transfer those credits to other refineries
which would find it more expensive to
reduce their benzene levels down to the
average standard. The ABT program will
allow refiners to optimize their
investments, which we believe will
result in achieving the average benzene
control standard nationwide at much
lower costs. The final benzene control
program also puts into place a 1.3 vol%
benzene maximum average standard
which requires each refinery to reduce
its gasoline benzene levels to or below
this standard and will increase the
benzene control costs only slightly
compared to a benzene control program
which does not contain a maximum
average standard. We estimate that the
national average refinery costs incurred
to comply with the fully phased-in
benzene control program will be 0.27
cents per gallon, averaged over all
gasoline. This estimate includes the
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8505
capital costs, which are amortized over
the volume of gasoline produced.
In this section we summarize the
methodology used to estimate the costs
of benzene control (including changes
we have made since the proposal) and
our estimated costs for the program. In
addition we evaluate the cost estimate
provided by the American Petroleum
Institute. A detailed discussion of all of
these analyses is found in Chapter 9 of
the RIA.
1. Methodology
a. Overview of the Benzene Program
Cost Methodology
The basic methodology we used to
estimate the cost of benzene control for
the final rule is the same as that used
for the proposed rule. Using a refineryby-refinery cost model that we
developed for this rulemaking, we
projected which refineries implement
what benzene control technology, and
the cost of each refinery’s benzene
control step, to estimate compliance
with the final benzene control program.
We aggregated the individual refinery
costs to develop a national average cost
estimate for the final benzene control
program. Based on the flexibilities
offered by the ABT program, refiners are
expected to come very close to
achieving the 0.62 vol% average
benzene standard on average with little
overcompliance. For this reason, we
modeled refiners achieving the average
standard without any overcompliance.
To the extent that any overcompliance
does occur the costs and benefits of the
benzene program will increase.
b. Changes to the Cost Estimation
Methodology Used in the Proposed Rule
In deriving the cost estimate for the
final rule, we identified and made a
number of changes to the refinery
modeling methodology used for the
proposed rule. One of the primary
changes was to base the future year fuel
prices on the Annual Energy Outlook
(AEO) 2006 instead of AEO 2005, which
increased the crude oil price used in the
analysis from $27 per barrel to $47 per
barrel. Other changes included: (1)
Updating the refinery modeling base
year to 2004 (used for calibrating each
refinery’s gasoline benzene levels); (2)
modeling the baseline benzene levels
and reductions on an annual basis
instead of on a summer-only basis; (3)
increasing the tax-hurdle rate of return
to 15 percent from the 10 percent hurdle
used in the proposed rule, and (4)
including the treatment of the benzene
in natural gasoline, which was assumed
to be left untreated in the proposed rule
analysis.
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In addition, we also made some
adjustments that were based on
comments we received on the cost
analysis that we conducted for the
proposal, as well as the peer review
process that we undertook for the
proposal’s refinery cost model. One of
the peer reviewers for the refinery-byrefinery cost model, and API in its
comments on the proposed rule,
provided capital cost estimates for the
benzene control technologies.210 We
reviewed these capital cost estimates
and made some adjustments to
somewhat increase the capital cost
figures used in the final rule analysis.
These changes were partially
responsible for the higher costs reported
here compared to those reported in the
proposed rule. More complete
descriptions of these and other changes
made to the refinery cost model are
contained in Chapter 9 the RIA.
c. Linear Programming Cost Model
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We considered performing our cost
assessments using a linear programming
(LP) cost model. LP cost models are
based on a set of complex mathematical
representations of refineries which, for
national analyses, are usually conducted
on a regional basis. This type of refining
cost model has been used by the
government and the refining industry
for many years for estimating the cost
and other implications of changes to
fuel quality.
The design of LP models lends itself
to modeling situations where every
refinery in a region is expected to use
the same control strategy and/or has the
same process capabilities. As we began
to develop a gasoline benzene control
program with an ABT program, it
became clear that LP modeling was not
well suited for evaluating such a
program. Because refiners will be
choosing a variety of technologies for
controlling benzene, and because the
program will be national and will
include an ABT program, we initiated
development of a more appropriate cost
model, as described below. However,
the LP model remained important for
providing many of the inputs into the
cost model developed for this
rulemaking.
210 An important reason for the discrepancy
between our capital cost estimate and that by API
(which was about three times higher) was that we
only estimated the capital costs related to the
benzene control technologies, not those related to
octane recovery and increased hydrogen production
needed for saturation or to replace the octane lost
due to reduced benzene production by the reformer.
For the final rule, we estimated these additional
capital costs and included them in our capital cost
estimates.
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d. Refinery-by-Refinery Cost Model
In contrast to LP models, refinery-byrefinery cost models are useful when
individual refineries are expected to
respond to program requirements in
different ways and/or have significantly
different process capabilities. Thus, in
the case of modeling gasoline benzene
control programs, we needed a model
that could accurately simulate the
variety of decisions refiners will make at
different refineries, especially in the
context of a nationwide ABT program.
For this and other related reasons, we
developed a refinery-by-refinery cost
model specifically to evaluate the
benzene control program.
Our refinery-by-refinery benzene cost
model incorporates the capacities of all
the major units in each refinery in the
country, as reported by the Energy
Information Administration and in the
Oil and Gas Journal. Regarding
operational information, we know less
about how specific refineries use the
various units to produce gasoline and
about such factors as octane and
hydrogen costs for individual refineries.
We used the LP model to estimate these
factors on a regional basis, and we
applied the average regional result to
each refinery in that region (PADD). We
calibrated the model for each individual
refinery based on 2004 gasoline volumes
and benzene levels (from the RFG data
base), which was the most recent year
for which data was available. After
calibration, each refinery’s gasoline
volume and benzene level closely
matched their actual gasoline volumes
and benzene levels. We also compared
cost estimates of similar benzene control
cases from both the refinery-by-refinery
model and the LP model, and the results
were in close agreement.211
Refinery-by-refinery cost models have
been used in the past by both EPA and
the oil industry for such programs as the
highway and nonroad diesel fuel sulfur
standards, and they are a proven means
for estimating the cost of compliance for
fuel control programs. For this refineryby-refinery benzene cost model, we
conducted a peer review process, and
have received some comments on the
design of our model. We summarize
211 Despite our commitment to accurately model
the baseline operations of each refinery, we
recognize that without detailed refinery-specific
operations information at our disposal, that our
modeling may not be accurate in some specific
cases. Particular refineries may choose a different
benzene control path than that estimated by our
analysis for a number of reasons, including
differences in the baseline and our lack of
knowledge for investment and ABT program use
preferences for each refiner. We believe, though,
that overall our refinery cost model captures the
strategies and costs for complying with the benzene
control program.
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some of these comments here, and they
are summarized and addressed in detail
in the RIA. (See Chapter 9 of the RIA for
our responses to these peer-review
comments.) The oil industry has also
conducted similar analyses using a
refinery-by-refinery modeling
technique, including the oil industry’s
cost analysis carried out for this
rulemaking.
Based on our understanding of the
primary benzene control technologies
(see section VI.A.1.c.i. above), the cost
model assumes that four technologies
will be used, as appropriate, for
reducing benzene levels. All of these
technologies focus on addressing
benzene in the reformate stream. They
are (1) routing the benzene precursors
around the reformer (also called light
naphtha splitting and reformer feed
fractionation); (2) routing benzene
precursors to an existing isomerization
unit, if available; (3) benzene extraction
(extractive distillation); and (4) benzene
saturation. For the proposed rulemaking
we assumed that only the usual feed or
the product stream of the reformer will
be processed by these benzene control
technologies. However, since the
proposal, we learned that another
refinery stream—natural gasoline—
contains some benzene and will likely
be treated by the saturation and
extraction processes in refineries if they
have or install these units. For the
proposal, we assumed that natural
gasoline would be blended directly into
gasoline and not be treated by refiners
if faced with a benzene control
standard. However, most refiners have
been combining natural gasoline with
their crude oil to enable treating the
sulfur in natural gasoline to help
comply with the Tier 2 gasoline sulfur
standard. Because the natural gasoline
will be refined along with crude oil, the
benzene in natural gasoline can and will
be treated along with the benzene in
crude oil.
The nationwide ABT program is
intended to optimize benzene reduction
by allowing each refinery to
individually choose the most costeffective means of complying with the
program. To model this phenomenon,
we first established an estimated cost for
the array of technologies that could be
employed by each refinery to reduce its
gasoline benzene levels. We then
deployed these technologies to
refineries with baseline benzene levels
above the 1.3 vol% benzene maximum
average standard to bring them into
compliance with this standard. Next we
ranked the refineries in order from
lowest to highest benzene control cost
per gallon of gasoline and estimated the
impact of their projected benzene
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control strategies on refinery benzene
levels. The model then follows this
ranking, starting with the lowest-cost
refineries, and adds refineries and their
associated control technologies one-byone until the projected national average
benzene level reaches 0.62 vol%
benzene. This modeling strategy
projects the benzene control technology
that will be used by each refinery, as
well as identifies those refineries that
are expected to generate credits and
those that are expected to use credits in
lieu of investing in benzene control. The
sum of the costs of the refineries
expected to invest in benzene control
provides the projected overall cost of
the program.
Finally, we projected how the ABT
program will affect the program cost and
benzene levels starting in 2007, when
early credits can be generated. We
assumed that refiners will use
operational changes (benzene precursor
rerouting, with isomerization if
available) to the maximum extent
possible in mid-2007, when they are
able to start to generate credits. We also
assumed that refiners will choose to
accumulate additional early credits by
making their initial lowest-cost capital
investments for reducing their gasoline
benzene levels, and that these changes
will take effect in 2010. We modeled
compliance by nonsmall and small
refiners with the maximum average
standard taking effect in mid-2012 and
the beginning of 2015, respectively, as
well as the final benzene control step to
meet the 0.62 vol% standard—the
phase-in of which depends on the
aggregate amount of credits
generated.212
e. Price of Chemical Grade Benzene
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The price of chemical grade benzene
is critical to the benzene control
program because it defines the
opportunity cost for benzene removed
using benzene extraction and sold into
the chemicals market. According to
2004 World Benzene Analysis authored
by Chemical Market Associates
Incorporated (CMAI), during the
consecutive five-year period ending
with 2004, the price of benzene
averaged 24 dollars per barrel higher
than regular grade gasoline. During the
three consecutive year period ending
with 2004, the price of benzene
212 The ABT analysis assumed that small refiners
would comply with the 1.3 vol% maximum average
standard in January 2015 at the same time as the
0.62 vol% annual average standard. We are
finalizing a later maximum average standard
implementation date (July 2016), which will have
very little effect on the overall program and
therefore has not been incorporated into this
analysis.
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averaged 28 dollars per barrel higher
than regular grade gasoline. However,
during the first part of 2004, the price
of benzene relative to gasoline rose
steeply, primarily because of high
energy prices adding to the cost of
extracting benzene. The 2004 benzene
price averaged 78 dollars per barrel
higher than regular grade gasoline.
Since early 2006, CMAI has been
projecting that the future price of
benzene relative to gasoline will return
to more historic levels, in the range of
30 dollars per barrel higher than regular
grade gasoline (in 2005, CMAI was
projecting that the benzene price would
be 20 dollars per barrel higher than
gasoline). We have based our modeling
for the final rule on the 30 dollar per
barrel value.
2. Summary of Costs
a. Nationwide Costs of the Final
Benzene Control Program
We have used the refinery-by-refinery
cost model to estimate the costs of the
benzene control program being finalized
today. In general, the cost model
indicates that among the four primary
reformate-based technologies, benzene
precursor rerouting will be the most
cost-effective. The next most costeffective technologies are isomerization
of the rerouted light straight run
material, revamped extraction units and
new installations of large extraction
units. The model indicates that benzene
saturation and small installations of
new extraction units will be the least
cost-effective.
Based on the results of our analysis
using the refinery-by-refinery model, we
estimate that when the benzene control
program is fully phased in, 78 refineries
of the total 104 gasoline-producing
refineries in the U.S. (outside of
California) will have to put in new
capital equipment or change their
refining operations to reduce the
benzene levels in their gasoline. Of
these refineries, we estimate that 17 will
use benzene precursor removal, 28
refineries will use benzene precursor
removal coupled with isomerization, 16
will use extraction, and 17 will use
benzene saturation. We project that 52
refineries will continue to produce
gasoline with benzene levels greater
than the average standard and will need
to purchase credits to comply. Including
the refineries with benzene levels
currently below 0.62, we project that
there will be a total of 50 refineries that
will produce gasoline with benzene
levels at 0.62 or lower and will generate
credits for sale to other refineries.
Finally, the model projects that 26
refineries will take no steps to reduce
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their gasoline benzene levels, which
includes those which remain above the
average benzene standard as well as
those already below the average
standard.
Based on the results of our cost
analysis, we estimate that the final
benzene control program will cost 0.27
cents per gallon when it is fully phased
in, assuming that capital investments
are amortized at a 7 percent return on
investment before taxes and expressed
in 2003 dollars. Our cost analysis
projects that the ABT program will
result in a phase-in of the benzene
control standard from mid-2007 to early
in 2015. Starting in mid-2007 we believe
that refiners will take the opportunity to
achieve modest benzene reductions to
generate early credits using simple
operational changes. We project that
these actions taken in mid-2007 will
result in a reduction of the average U.S.
gasoline benzene level from 0.99 to 0.81
vol% at an average cost of 0.04 cents per
gallon.
To take full advantage of the
flexibility provided to refiners by the
ABT program to delay more expensive
capital investments, refiners are
expected to make additional early
benzene reductions to generate more
early credits, requiring modest
investments in capital. Because of the
time it takes to assess, design and install
the capital equipment, we project that
these additional early benzene
reductions will not occur until the
beginning of 2010, although in reality
these investments and associated
benzene reductions would likely occur
before and after the beginning of 2010.
These benzene reductions are expected
to further reduce the average benzene
level of U.S. gasoline to 0.74 vol% and
cost 0.05 cents per gallon averaged over
all U.S. gasoline. Refiners are expected
to make $324 million of capital
investments to achieve this benzene
reduction. In 2011 when the 0.62 vol%
benzene control standard takes effect,
we do not anticipate any further
reduction in benzene because we project
that the refining industry will be able to
comply using early credits.
In mid-2012, when refineries with
high benzene levels need to comply
with the 1.3 vol% maximum average
standard, we anticipate that U.S.
gasoline benzene levels will decline
further, to 0.73 vol% benzene, and cost
an additional 0.04 cents per gallon
averaged over all U.S. gasoline. Refiners
are expected to make another $153
million in capital investments.
Although the early credit use period
terminates at the end of 2013, refiners
will again have flexibility in scheduling
their most expensive capital
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investments by using standard credits
(which will have been accruing since
the start of 2011). Because we expect
that refiners will first use their early
credits, the standard credits will be
banked and will start to be used in 2014
to show compliance with the 0.62 vol%
benzene standard. Our analysis suggests
that the U.S. refining industry will be
able to delay their highest capital
investments until May 2015, when the
standard credits accumulated since the
beginning of 2011 run out. Small
refiners must meet the 1.3 vol%
maximum average standard which was
assumed to occur at the beginning of
2015 so they also will be reducing their
gasoline benzene levels to that standard
or below.213 Taken together, these
reductions in 2015 will bring the U.S.
gasoline pool down to the 0.62 vol%
benzene standard at an average cost of
0.14 cents per gallon averaged over all
U.S. gasoline, based on the addition of
$634 million in capital investments.
To comply with the fully phased-in
final benzene control program, refiners
are expected to have made a total of
$1110 million in capital investments.
This will amount to an average of $14
million in capital investment in each
refinery that adds such equipment.
We also estimated annual aggregate
costs, including the amortized capital
costs, associated with the new fuel
standard. As shown in Table VIII.A–1,
these costs are projected to begin at $28
million in 2007 and increase to $363
million in 2015 when the benzene
program is fully phased in. These
aggregated costs continue to increase
over time as fuel demand increases.
TABLE VIII.A–1.—PER-GALLON AND
ANNUAL AGGREGATE FUEL COSTS
FOR THE FINAL BENZENE CONTROL
PROGRAM
(7% ROI before taxes and 2003 dollars)
Per-gallon
cost
(c/gal)
Year
2007
2008
2009
2010
2011
2012
2013
2014
2015
2020
2025
2030
2035
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
..................
Aggregate
cost
($million)
0.02
0.04
0.04
0.09
0.09
0.11
0.13
0.13
0.27
0.27
0.27
0.27
0.27
28
49
50
101
104
133
164
166
363
388
412
437
464
Several observations can be made
from these results of our nationwide
cost analysis. First, significantly
reducing gasoline benzene levels to low
levels, coupled with the flexibility of an
ABT program, will incur fairly modest
aggregate program costs. This is
primarily because we expect that
refiners will optimize their benzene
control strategies, resulting in large
benzene reductions at a relatively low
overall program cost. With higher
benzene prices relative to those of
gasoline projected to continue (even if
they drop from the recent very high
levels), extraction is expected to be a
very low-cost technology—the primary
reason why the cost of the overall
program is very low. Also, precursor
rerouting, either with or without
isomerization in an existing unit, is a
low-cost technology requiring little or
no capital to realize. The model
concludes that even the higher-cost
benzene saturation technology will be
fairly cost-effective overall because
larger refineries that install this
technology will take advantage of their
economies of scale.
b. Regional Costs
The benzene reductions estimated by
the cost model and associated costs vary
significantly by region. Table VIII.A–2
summarizes the estimated per-gallon
costs for complying with the benzene
control standard by PADD region.
TABLE VIII.A–2.—PROJECTED BENZENE CONTROL COSTS BY PADD FOR THE FINAL BENZENE CONTROL PROGRAM
(2003 dollars, 7% ROI before taxes)
PADD
1
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Cost (c/gal) .......................................................................................................................
2
3
4
0.14
0.35
0.15
0.55
5 (w/o
CA)
1.21
U.S.
0.268
Table VIII.A–2 shows that the PADDaverage costs are highest in PADD 5
followed next by PADD 4. In PADDs 1,
2 and 3, where reformulated gasoline
programs have already forced gasoline
benzene levels lower, the benzene
control costs are lower. Extraction is the
technology most used in PADDs 1 and
3, resulting in lower benzene control
cost in these regions. Individual
refineries show a wider range of control
costs than the PADD-average costs.
There are 20 refineries for which we
estimate benzene control costs lower
than 0.20 cents per gallon. Also, there
are 11 refineries, all of which are very
small refineries, with costs in the range
of 3 to 7 cents per gallon range.
c. Refining Industry Cost Study
The American Petroleum Institute
(API) conducted its own refinery
modeling study to evaluate the cost of
benzene control. The API study
analyzed the cost of three different
benzene control programs. Two of the
benzene control programs analyzed by
API were very different than our final
benzene control program and we will
not discuss them here (see Chapter 9 of
the RIA). The third program analyzed by
API was nearly identical to the final
benzene control standard, and we have
carefully compared API’s cost analysis
to ours.
API analyzed a benzene control
program with a nationwide 0.60 vol%
benzene standard and with an ABT
program and with no upper benzene
limit. API also assumed that credits will
not be traded freely, but instead that
refining companies would hold onto 10
percent of their credits in case they have
a future problem with their benzene
control unit. Including the compliance
margin and the 10 percent credit
margin, the API study estimated that
under its modeled benzene control
program and associated assumptions
that U.S. gasoline would average 0.56
vol% benzene. The API study estimates
the cost of complying with its modeled
benzene control program to be 1.00 cent
213 The ABT analysis assumed that small refiners
would comply with the 1.3 vol% maximum average
standard in January 2015 at the same time as the
0.62 vol% annual average standard. We are
finalizing a later maximum average standard
implementation date (July 2016), which will have
very little effect on the overall program and
therefore has not been incorporated into this
analysis.
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per gallon.214 This estimated benzene
control cost is substantially higher than
our estimated 0.27 cents per gallon cost
for our nearly identical program. After
comparing their methodology to ours we
identified three primary differences
which explain the large difference in
costs.
The first difference is that API
modeled a somewhat lower benzene
control standard and assumed a credit
generation margin which resulted in
refiners achieving a much lower
benzene level than the 0.62 vol%
benzene control standard. A primary
reason why the refining industry study
modeled overcompliance with the
benzene standard is due to an
assumption that refiners will want to
hold onto a substantial quantity of
credits, yet the API cost study did not
provide a justification for the
accumulation of credits. EPA does not
believe that refiners will significantly
overcomply with the average benzene
standard. This is because the 0.62 vol%
benzene standard is an averaging
standard which is met across the entire
industry, not a cap standard, and can be
met by the accumulation of gasoline
batches with benzene levels higher or
lower than the standard. Thus, if a
refinery produced gasoline with lower
or higher gasoline benzene levels over
the first part of the year, the operations
could be adjusted to balance out the
gasoline benzene levels for the rest of
the year. Also, our program includes
several provisions which give refiners
significant flexibility for compliance.
For example, refiners could overcomply
slightly with the standard early on in
the program’s implementation and hold
onto the credits for up to five years
before they expire. If a refinery’s
benzene control unit goes down, the
refiner would be able to use those
accumulated credits, the refiner could
purchase credits from other refineries,
or the refiner could create a benzene
reduction deficit at that refinery and
make it up the following year. With this
degree of flexibility, any significant
overcompliance with the 0.62 vol%
average benzene standard is
unnecessary.
The second reason why the API costs
are much higher than ours is because
API used a more restrictive assumption
with respect to benzene extraction—a
more cost-effective benzene control
technology than benzene saturation, as
discussed above. API assumed that no
214 This cost estimate includes an adjustment we
made to convert the API capital cost amortization
from the after-tax 10 percent rate of return that was
the basis for the estimated costs in their report to
a before-tax 7 percent rate of return, which is how
our rules are estimated.
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new grassroots benzene extraction
capacity will be installed in the future,
but that existing extraction units could
be expanded. We agree that existing
units will likely be expanded. However,
we also believe that several refineries
will install new grassroots extraction
units. Our premise is supported by
CMAI projections of a robust benzene
market in the future with benzene
priced higher than its historical margin
above gasoline. Higher benzene price
margins will provide an incentive to
refiners to add grassroots benzene
extraction units, even in areas where
benzene markets are smaller. For
example, one refiner has indicated to us
that if the proposed gasoline benzene
standard was to be finalized, it would
install a grassroots benzene extraction
unit at one of its refineries in the
Midwest, where the benzene market is
small with less room for increased
supply (although this benzene could be
shipped down to the Gulf Coast). This
is a strong indicator that new grassroots
benzene extraction units will also be
installed on the Gulf and East Coasts,
where benzene markets are much larger
with much more room to absorb
increased supply.
The third reason why the API benzene
control costs are much higher than ours
is their very high octane control costs.
For both studies, the octane loss that
occurs due to the modeled application
of the various benzene control
technologies is accounted for by
assigning a dollar per octane-barrel cost
to the octane loss. However, API’s costs
for restoring octane are higher than the
future octane recovery costs that we are
projecting. The octane costs used by API
are higher because API used the rack
price differential between premium and
regular grade gasolines as summarized
by the Energy Information
Administration. However, the rack price
differential between premium and
regular grade gasolines reflects a
significant amount of profit. For
example, the cost difference to produce
premium gasoline is usually only a few
cents per gallon more than for
producing regular grade gasoline, yet
refiners and marketers usually charge 20
to 30 cents more per gallon for premium
gasoline at retail. Some of this inflated
price appears at the rack price
differential between regular and
premium grades of gasoline. In addition,
future octane control costs, when the
benzene control standard takes effect,
are expected to be much lower due to
the very large volume of ethanol that is
expected to enter the gasoline market by
then.
Overall, we have carefully evaluated
the differences between our cost
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analysis and that provided by API.
Except for the differences described
above, the assumptions used and the
conclusions reached were very similar.
We believe our revised analysis
provides a more accurate assessment of
the costs of the benzene control
program.
B. What Are the Vehicle Cost Impacts?
In assessing the economic impact of
setting cold temperature emission
standards, we have made a best estimate
of the necessary vehicle modifications
and their associated costs. In making
our estimates we have relied on our own
technology assessment, which includes
information supplied by individual
manufacturers and our own in-house
testing. Estimated costs typically
include variable costs (for hardware and
assembly time) and fixed costs (for
research and development, retooling,
and certification). All costs are
presented in 2003 dollars. Full details of
our cost analysis can be found in
Chapter 8 of the RIA.
As described in section V, we are not
expecting hardware changes to Tier 2
vehicles in response to new cold
temperature standards. Tier 2 vehicles
are already being equipped with very
sophisticated emissions control systems.
We expect manufacturers to use these
systems to minimize emissions at cold
temperatures. We were able to
demonstrate significant emissions
reductions from a Tier 2 vehicle through
recalibration alone. In addition, the
standard we are finalizing is based on
averaging which allows some vehicles
to be above the numeric standard as
long as those excess emissions are offset
by vehicles below the standard.
Averaging will help manufacturers in
cases where they are not able to achieve
the numeric standard for a particular
vehicle group, thus helping
manufacturers avoid costly hardware
changes. The phase-in of standards and
emissions credits provisions also help
manufacturers avoid situations where
expensive vehicle modifications will be
needed to meet the new cold
temperature NMHC standard. Therefore,
we are not projecting hardware costs or
additional assembly costs associated
with meeting new cold temperature
NMHC emissions standards.
Manufacturers will incur research and
development (R&D) costs associated
with a new cold temperature standard,
and some likely will need to upgrade
testing facilities to handle an increased
number of cold tests during vehicle
development. We have estimated the
fixed costs associated with R&D and test
facilities. We project that manufacturers
will recover R&D costs over a five-year
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period and their facilities costs over a
ten-year period. Long-term impacts on
engine costs are expected to decrease as
manufacturers fully amortize their fixed
costs. Because manufacturers recoup
fixed costs over a large volume of
vehicles, average per vehicle costs due
to the new cold temperature NMHC
standards are expected to be low. We
project that the average incremental
costs associated with the new cold
temperature standards will be less than
$1 per vehicle.
We did not receive comments on the
methodology we used to derive average
cost estimates. However, we did receive
comments from one manufacturer with
a limited product line who believes new
hardware will be needed on its vehicles
to meet the new cold temperature
standards. Other manufacturers did not
comment that hardware changes would
be needed, and they generally supported
our lead-time, phase-in, and other
transitional provisions as providing the
flexibility needed to meet the standards.
We continue to believe that
manufacturers will be able to meet the
standards through vehicle development
without additional hardware. However,
we conducted a sensitivity analysis in
response to this comment, assuming the
commenter would use new hardware to
meet the cold temperature standard. If
one percent of new vehicles required
additional hardware costing $100–$200
per vehicle, the average cost would
increase from less than $1 to the range
of $1.60–$2.60 per vehicle. The
commenter did not provide cost
information in their comments and we
believe that the costs used in our
sensitivity analysis are conservatively
high, given the lead time provided for
vehicle development and market
pressures to keep costs in line with
those of competitors. In any event, we
believe the costs associated with the
program are reasonable. Additional
discussion of the comments received on
the vehicle cold temperature standard is
provided in Chapter 3 of the Summary
and Analysis of Comments for this rule.
We are not anticipating additional
costs for the new evaporative emissions
standard. As discussed in section V, we
expect that manufacturers will continue
to produce 50-state evaporative systems
that meet LEV II standards. Therefore,
harmonizing with California’s LEV–II
evaporative emission standards will
streamline certification and be an ‘‘antibacksliding’’ measure. It also codifies
the approach manufacturers have
already indicated they are taking for 50state evaporative systems.
We also estimated annual aggregate
costs associated with the new cold
temperature emissions standards. These
costs are projected to increase with the
phase-in of standards and peak in 2014
at about $13.4 million per year, then
decrease as the fixed costs are fully
amortized. The projected aggregate costs
are summarized below, with annual
estimates provided in Chapter 8 of the
RIA.
TABLE VIII.B–1.—ANNUAL AGGREGATE COSTS
2010
2012
$11,119,000 .........................................................................
C. What Are the PFC Cost Impacts?
For PFCs, we have made a best
estimate of the necessary technologies
and their associated costs. Estimated
costs include variable costs (for
hardware and assembly time) and fixed
costs (for research and development,
retooling, and certification). The
analysis also considers fuels savings
associated with low emission PFCs. Cost
estimates based on the projected
technologies represent an expected
change in the cost of PFCs as they begin
to comply with new emission standards.
All costs are presented in 2003 dollars.
We did not receive comments on
estimated costs for PFCs controls. Full
details of our cost analysis, including
fuel savings, can be found in Chapter 10
of the RIA.
Table VIII.C–1 summarizes the
projected near-term and long-term per
unit average costs to meet the new
emission standards. Long-term impacts
2014
$12,535,000
2016
$13,406,000
on PFCs are expected to decrease as
manufacturers fully amortize their fixed
costs. We project that manufacturers
will generally recover their fixed costs
over a five-year period, so these costs
disappear from the analysis after the
fifth year of production. These estimates
are based on the manufacturing cost
rather than predicted price increases.215
The table also shows our projections of
average fuel savings over the life of the
PFC when used with gasoline. Fuel
savings can be estimated based on the
VOC emissions reductions due to
controls.
TABLE VIII.C–1.—ESTIMATED AVERAGE PER UNIT PFC COSTS AND
LIFETIME FUEL SAVINGS
2018
$12,207,000
2020
$10,682,000
$0
With current and projected estimates
of PFC sales, we translate these costs
into projected direct costs to the nation
for the new emission standards in any
year. A summary of the annual aggregate
costs to manufacturers is presented in
Table VIII.C–2. The annual cost savings
due to fuel savings start slowly, then
increase as greater numbers of
compliant PFCs enter the market. Table
VIII.C–2 also presents a summary of the
estimated annual fuel savings. Aggregate
costs are projected to peak in 2013 at
about $61 million and then drop to
about $34 million once fixed costs are
recovered. The change in numbers
beyond 2015 occurs due to projected
growth in sales and population.
Cost
Near-Term Costs ..........................
Long-Term Costs ..........................
Fuel Savings (NPV) ......................
$2.69
1.52
4.24
TABLE VIII.C–2.—TOTAL ANNUALIZED COSTS AND FUEL SAVINGS
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2009
Costs ................................................................................................................
215 These costs numbers may not necessarily
reflect actual price increases as manufacturer
production costs, perceived product enhancements,
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$58,070,000
2013
2015
$60,559,000
and other market impacts will affect actual prices
to consumers.
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$34,004,000
2020
$37,543,000
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TABLE VIII.C–2.—TOTAL ANNUALIZED COSTS AND FUEL SAVINGS—Continued
2009
Fuel Savings ....................................................................................................
D. Cost per Ton of Emissions Reduced
We have calculated the cost per ton of
HC, benzene, total MSATs, and PM
emissions reductions associated with
the fuel, vehicle, and PFC programs
using the costs described above and the
emissions reductions described in
section IV. More detail on the costs,
emissions reductions, and cost per ton
estimates can be found in the RIA. We
have calculated the costs per ton using
the net present value of the annualized
costs of the program, including PFC
gasoline fuel savings, from 2009 through
2030 and the net present value of the
annual emission reductions through
2030. We have also calculated the cost
per ton of emissions reduced in the year
2030 using the annual costs and
emissions reductions in that year alone.
This number represents the long-term
cost per ton of emissions reduced. For
fuels, the cost per ton estimates include
costs and emission reductions that will
occur from all motor vehicles and
15,347,000
nonroad engines fueled with
gasoline.216
For vehicles and PFCs, we are
establishing NMHC and HC standards,
respectively, which will also reduce
benzene and other VOC-based toxics.
For vehicles, we are also expecting
direct PM reductions due to the NMHC
standard.217 Section IV above provides
an overview of how we are estimating
benzene and PM reductions resulting
from the NMHC standards for vehicles
and benzene reductions resulting from
the HC standard for PFCs. We have not
attempted to apportion costs across
these various pollutants for purposes of
the cost per ton calculations since there
is no distinction in the technologies, or
associated costs, used to control the
pollutants. Instead, we have calculated
costs per ton by assigning all costs to
each individual pollutant. If we
apportioned costs among the pollutants,
the costs per ton presented here would
be proportionally lowered depending on
what portion of costs were assigned to
the various pollutants.
2013
2015
83,506,000
2020
102,523,000
109,589,000
The results for HC for vehicles and
PFCs are provided in Table VIII.D–1
using both a three percent and a seven
percent social discount rate. Again, this
analysis assumes that all costs are
assigned to HC control. The discounted
cost per ton of HC reduced for the final
rule as a whole would be $0 because the
gasoline fuel savings from PFCs offsets
the costs of PFC and vehicle controls.
The table presents these as $0 per ton,
rather than calculating a negative value
that has no clear meaning. For vehicles
in 2030, the cost per ton is $0 because
by 2030 all fixed costs have been
recovered and there are no variable
costs estimated for the new vehicle
program.218
The cost per ton estimates for each
individual program are presented
separately in the tables below, and are
part of the justification for each of the
programs. For informational purposes,
we also present the cost per ton for the
three programs combined.
TABLE VIII.D–1.—HC AGGREGATE COST PER TON AND LONG-TERM ANNUAL COST PER TON
[$2003]
Discounted
lifetime cost
per ton at 3%
Discounted
lifetime cost
per ton at 7%
Long-Term
cost per ton in
2030
$14
240
0
0
$18
270
0
0
$0
190
0
0
Vehicles .......................................................................................................................................
PFCs (without fuel savings) .........................................................................................................
PFCs (with fuel savings) ..............................................................................................................
Combined (with fuel savings) ......................................................................................................
The cost per ton of benzene
reductions for fuels, vehicles, and PFCs
are shown in Table VIII.D–2 using the
same methodology as noted above for
HC. The results are calculated by
assigning all costs to benzene control.
TABLE VIII.D–2.—BENZENE AGGREGATE COST PER TON AND LONG-TERM ANNUAL COST PER TON
[$2003]
Discounted
lifetime cost
per ton at 3%
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Fuels ............................................................................................................................................
Vehicles .......................................................................................................................................
PFCs (without fuels savings) .......................................................................................................
PFCs (with fuel savings) ..............................................................................................................
216 The proposed standards do not apply to
nonroad engines, since section 202(l) authorizes
controls only for ‘‘motor vehicles,’’ which term does
not include nonroad vehicles (CAA section 216(2)).
However, we are reducing benzene in all gasoline,
including that used in nonroad equipment.
Therefore, we are including both the costs and the
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benzene emissions reductions associated with the
fuel used in nonroad equipment.
217 Again, although gasoline PM is not a mobile
source air toxic, the rule will result in emission
reductions of gasoline PM, which reductions are
accounted for in our analysis.
218 We note that in determining whether the new
vehicle controls represent the greatest emissions
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Discounted
lifetime cost
per ton at 7%
Long-term cost
per ton in
2030
$22,400
270
74,500
0
$23,100
360
82,900
0
$22,500
0
56,200
0
reductions achievable considering costs, we have
considered the new cold-start standards separately
from any other new control program. Similarly, in
considering whether the new controls for PFCs
represent the best available control considering
economic feasibility, we considered the PFC
standards separately from any other new control
program.
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TABLE VIII.D–2.—BENZENE AGGREGATE COST PER TON AND LONG-TERM ANNUAL COST PER TON—Continued
[$2003]
Discounted
lifetime cost
per ton at 3%
Discounted
lifetime cost
per ton at 7%
Long-term cost
per ton in
2030
8,200
8,600
5,900
Combined (with fuel savings) ......................................................................................................
The cost per ton of reductions of all
MSAT reductions for fuels, vehicles,
and PFCs are shown in Table VIII.D–3
using the same methodology as noted
above for HC and benzene. The results
are calculated by assigning all costs to
MSAT control.
TABLE VIII.D–3.—MSAT AGGREGATE COST PER TON AND LONG-TERM ANNUAL COST PER TON
[$2003]
Discounted
lifetime cost
per ton at 3%
Fuels ............................................................................................................................................
Vehicles .......................................................................................................................................
PFCs (without fuel savings) .........................................................................................................
PFCs (with fuel savings) ..............................................................................................................
Combined (with fuel savings) ......................................................................................................
We have also calculated a cost per ton
for direct PM reductions for vehicles.
Discounted
lifetime cost
per ton at 7%
Long-term cost
per ton in
2030
$22,400
42
2,800
0
1,700
$23,100
54
3,100
0
1,800
$22,500
0
2,200
0
1,100
Again, this analysis assigns all related
costs to direct PM reductions.
TABLE VIII.D–4.—DIRECT PM AGGREGATE COST PER TON AND LONG-TERM ANNUAL COST PER TON
[$2003]
Discounted
lifetime cost
per ton at 3%
Discounted
lifetime cost
per ton at 7%
Long-term cost
per ton in
2030
$650
$870
$0
Vehicles .......................................................................................................................................
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E. Benefits
This section presents our analysis of
the health and environmental benefits
that will occur as a result of the final
standards throughout the period from
initial implementation through 2030. In
terms of emission benefits, we expect to
see significant reductions in mobile
source air toxics (MSATs) from the
vehicle, fuel and PFC standards;
reductions in VOCs (an ozone and PM2.5
precursor) from the cold temperature
vehicle and PFC standards; and
reductions in direct PM2.5 from the cold
temperature vehicle standards. When
translating emission benefits to health
effects and monetized values, however,
we quantify only the PM-related
benefits associated with the cold
temperature vehicle standards.
The reductions in PM2.5 from the cold
temperature vehicle standards will
result in significant reductions in
premature deaths and other serious
human health effects, as well as other
important public health and welfare
effects. We estimate that in 2030, the
benefits we are able to monetize will be
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approximately $6.3 billion using a 3
percent discount rate and $5.7 billion
using a 7 percent discount rate. Total
social costs of the entire rule for the
same year (2030) are $400 million.
Details on the costs of the final
standards are in section VIII.F. These
estimates, and all monetized benefits
presented in this section, are in year
2003 dollars.
The PM2.5 benefits are scaled based on
relative changes in direct PM2.5
emissions between this rule and the
proposed Clean Air Nonroad Diesel
(CAND) rule.219 As explained in Section
12.2.1 of the RIA for this rule, the PM2.5
benefits scaling approach is limited to
those studies, health impacts, and
assumptions that were used in the
proposed CAND analysis. As a result,
PM-related premature mortality is based
on the updated analysis of the American
Cancer Society cohort (ACS; Pope et al.,
219 Due to time and resource constraints, EPA
scaled the final CAND benefits estimates from the
benefits estimated for the CAND proposal. The
scaling approach used in that analysis, and applied
here, is described in the RIA for the final CAND
rule.
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2002). However, it is important to note
that since the CAND rule, EPA’s Office
of Air and Radiation (OAR) has adopted
a different format for its benefits
analyses in which characterization of
the uncertainty in the concentrationresponse function is integrated into the
main benefits analysis. This new
approach follows the recommendation
of NRC’s 2002 report ‘‘Estimating the
Public Health Benefits of Proposed Air
Pollution Regulations’’ to begin moving
the assessment of uncertainties from its
ancillary analyses into its main benefits
presentation through the conduct of
probabilistic analyses. Within this
context, additional data sources are
available, including a recent expert
elicitation and updated analysis of the
Six-Cities Study cohort (Laden et al.,
2006). Please see the PM NAAQS RIA
for an indication of the sensitivity of our
results to use of alternative
concentration-response functions.
We also demonstrate that the final
standards will reduce cancer and
noncancer risk from reduced exposure
to MSATs (as described in Section IV of
this preamble). However, we do not
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translate this risk reduction into
benefits. We also do not quantify the
benefits related to ambient reductions in
ozone and PM2.5 due to the VOC
emission reductions associated with the
final standards. The following section
describes in more detail why these
benefits are not quantified.
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1. Unquantified Health and
Environmental Benefits
This benefit analysis estimates
improvements in health and human
welfare that are expected as a result of
the final standards, and monetizes those
benefits. The benefits will come from
reductions in emissions of air toxics
(including benzene, 1,3-butadiene,
formaldehyde, acetaldehyde, acrolein,
naphthalene, and other air toxic
pollutants discussed in section III),
ambient ozone (as a result of VOC
controls), and direct PM2.5 emissions.
While there will be benefits
associated with air toxic pollutant
reductions, notably with regard to
reductions in exposure and risk (see
section IV), we do not attempt to
monetize those benefits. This is
primarily because available tools and
methods to assess air toxics risk from
mobile sources at the national scale are
not adequate for extrapolation to
incidence estimations or benefits
assessment. The best suite of tools and
methods currently available for
assessment at the national scale are
those used in the National-Scale Air
Toxics Assessment (NATA; these tools
are discussed in Chapter 3 of the RIA).
The EPA Science Advisory Board
specifically commented in their review
of the 1996 NATA that these tools were
not yet ready for use in a national-scale
benefits analysis, because they did not
consider the full distribution of
exposure and risk, or address subchronic health effects.220 While EPA has
since improved the tools, there remain
critical limitations for estimating
incidence and assessing benefits of
reducing mobile source air toxics. We
continue to work to address these
limitations, and we are exploring the
feasibility of a quantitative benefits
assessment for air toxics through a
benzene case study as part of the revised
study of ‘‘The Benefits and Costs of the
Clean Air Act’’ (also known as the
‘‘Section 812’’ report).221 In this case
study, we are attempting to monetize
the benefits of reduced cancer
220 Science Advisory Board. 2001. NATA—
Evaluating the National-Scale Air Toxics
Assessment for 1996—an SAB Advisory. https://
www.epa.gov/ttn/atw/sab/sabrev.html.
221 The analytic blueprint for the Section 812
benzene case study can be found at https://
www.epa.gov/air/sect812/appendixi51203.pdf.
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incidence, specifically leukemia, and
are not addressing other cancer or
noncancer endpoints.
We also do not estimate the
monetized benefits of VOC controls in
this benefits analysis. Though VOCs
will be demonstrably reduced as a result
of the cold temperature vehicle
standards, we assume that these
emissions will not have a measurable
impact on ozone formation since the
standards will reduce VOC emissions at
cold ambient temperatures and ozone
formation is primarily a warm ambient
temperature issue. The PFC controls
will likely result in ozone benefits,
though we do not attempt to monetize
those benefits. This is primarily due to
the magnitude of, and uncertainty
associated with, the estimated changes
in ambient ozone associated with the
final standards. In Section IV.C., we
discuss that the ozone modeling
conducted for the final PFC standards
results in a net reduction in ambient
ozone concentrations within the
modeled domain (37 Eastern states and
the District of Columbia). The net
improvement is very small, however,
and will likely lead to negligible
monetized benefits. Instead, we
acknowledge that this analysis may
underestimate the benefits associated
with reductions in ozone precursor
emissions achieved by the various
standards. We discuss these benefits
qualitatively within the RIA.
The VOC reductions resulting from
the cold temperature vehicle standards
and PFC standards will also likely
reduce secondary PM2.5 formation.
However, we did not quantify the
impacts of these reductions on ambient
PM2.5 or estimate any resulting benefits.
As described further below, we
estimated PM benefits by scaling from a
previous analysis, and this analysis did
not examine the relationship between
VOC reductions and ambient PM. As a
result, we did not quantify PM benefits
associated with this rule’s VOC
reductions, and we acknowledge that
this analysis may therefore
underestimate benefits.
Table VIII.E–1 lists each of the MSAT
and ozone health and welfare effects
that remain unquantified because of
current limitations in the methods or
available data. This table also includes
the PM-related health and welfare
effects that also remain unquantified
due to current method and data
limitations. Chapter 12 of the RIA for
the final standards provides a
qualitative description of the health and
welfare effects not quantified in this
analysis.
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TABLE VIII.E–1.—UNQUANTIFIED AND
NON-MONETIZED EFFECTS
Pollutant/effects
Effects not included in primary estimates—changes in:
Ozone Health a
Premature mortality: shortterm exposures b.
Hospital admissions: respiratory.
Emergency room visits for
asthma.
Minor restricted-activity days.
School loss days.
Asthma attacks.
Cardiovascular emergency
room visits.
Acute respiratory symptoms.
Chronic respiratory damage.
Premature aging of the
lungs.
Non-asthma respiratory
emergency room visits.
Exposure to UVb (+/-) e.
Decreased outdoor worker
productivity.
Agricultural yields for
—commercial forests.
—some fruits and vegetables.
—non-commercial crops.
Damage to urban ornamental plants.
Impacts on recreational demand from damaged forest aesthetics.
Ecosystem functions.
Exposure to UVb (+/-) e.
Premature mortality—shortterm exposures d.
Low birth weight.
Pulmonary function.
Chronic respiratory diseases
other than chronic bronchitis.
Non-asthma respiratory
emergency room visits.
Exposure to UVb (+/-) e.
Visibility in many Class I
areas.
Residential and recreational
visibility in non-Class I
areas.
Soiling and materials damage.
Damage to ecosystem functions.
Exposure to UVb (+/-) e.
Cancer (benzene, 1,3-butadiene, formaldehyde, acetaldehyde, naphthalene).
Anemia (benzene).
Disruption of production of
blood components (benzene).
Reduction in the number of
blood platelets (benzene).
Excessive bone marrow formation (benzene).
Depression of lymphocyte
counts (benzene).
Reproductive and developmental effects (1,3-butadiene).
Ozone Welfare
PM Health c ....
PM Welfare ....
MSAT Health f
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TABLE VIII.E–1.—UNQUANTIFIED AND
NON-MONETIZED EFFECTS—Continued
Pollutant/effects
Effects not included in primary estimates—changes in:
Irritation of eyes and mucus
membranes (formaldehyde).
Respiratory irritation (formaldehyde).
Asthma attacks in
asthmatics (formaldehyde).
Asthma-like symptoms in
non-asthmatics (formaldehyde).
Irritation of the eyes, skin,
and respiratory tract (acetaldehyde).
Upper respiratory tract irritation and congestion (acrolein).
Neurotoxicity (n-hexane, toluene, xylenes).
Direct toxic effects to animals.
Bioaccumulation in the food
chain.
Damage to ecosystem function.
Odor.
c In addition to primary economic endpoints,
there are a number of biological responses
that have been associated with PM health effects including morphological changes and altered host defense mechanisms. The public
health impact of these biological responses
may be partly represented by our quantified
endpoints.
d While some of the effects of short-term exposures are likely to be captured in the estimates, there may be premature mortality due
to short-term exposure to PM not captured in
the cohort study upon which the primary analysis is based. However, the PM mortality results derived from the expert elicitation do take
into account premature mortality effects of
short-term exposures.
e May result in benefits or disbenefits.
f The categorization of unquantified toxic
health and welfare effects is not exhaustive.
2. Quantified Human Health and
Environmental Effects of the Final Cold
Temperature Vehicle Standard
In this section we discuss the benefits
of the final cold temperature vehicle
standard related to reductions in
directly emitted PM2.5. To estimate
PM2.5 benefits, we rely on a benefits
MSAT Weltransfer technique. The benefits transfer
f.
fare
approach uses as its foundation the
relationship between emission
reductions and ambient PM2.5
concentrations modeled across the
contiguous 48 states (and DC) for the
Clean Air Nonroad Diesel (CAND)
a In addition to primary economic endpoints,
proposal.222 For a given future year, we
there are a number of biological responses
that have been associated with ozone health first calculate the ratio between CAND
effects including increased airway responsive- direct PM2.5 emission reductions and
ness to stimuli, inflammation in the lung, acute direct PM2.5 emission reductions
inflammation and respiratory cell damage, and associated with the final cold
increased susceptibility to respiratory infection.
temperature vehicle control standard
b Recent analyses provide evidence that
short-term ozone exposure is associated with (cold temperature vehicle emission
increased premature mortality. As a result, reductions/CAND emission reductions).
EPA is considering how to incorporate ozone We multiply this ratio by the percent
mortality benefits into its benefits analyses as
a separate estimate of the number of pre- that direct PM2.5 contributes towards
mature deaths that would be avoided due to population-weighted reductions in total
reductions in ozone levels.
PM2.5 due to the CAND standards. This
calculation results in a ‘‘benefits
apportionment factor’’ for the
relationship between direct PM
emissions and primary PM2.5, which is
then applied to the BenMAP-based
incidence and monetized benefits from
the CAND proposal. In this way, we
apportion the results of the proposed
CAND analysis to its underlying direct
PM emission reductions and scale the
apportioned benefits to reflect
differences in emission reductions
between the two rules.223 This benefits
transfer method is consistent with the
approach used in other recent mobile
and stationary source rules.224
Table VIII.E–2 presents the estimates
of reduced incidence of PM2.5-related
health effects for the years 2020 and
2030 for the final cold temperature
vehicle control strategies. In 2030, we
estimate that PM2.5-related annual
benefits will result in approximately
880 fewer premature fatalities, 600
fewer cases of chronic bronchitis, 1,600
fewer non-fatal heart attacks, and 900
fewer hospitalizations (for respiratory
and cardiovascular disease combined).
In addition, we estimate that the
emission controls will reduce days of
restricted activity due to respiratory
illness by about 600,000 days and
reduce work-loss days by about 100,000
days. We also estimate substantial
health improvements for children from
reduced upper and lower respiratory
illness, acute bronchitis, and asthma
attacks.
It is important to note that since the
CAND rule, EPA’s Office of Air and
Radiation (OAR) has adopted a different
format for its benefits analysis in which
characterization of the uncertainty in
the concentration-response function is
integrated into the main benefits
analysis. Within this context, additional
data sources are available, including a
recent PM-related premature mortality
expert elicitation and updated analysis
of the Six-Cities Study cohort (Laden et
al., 2006). Please see the PM NAAQS
RIA for an indication of the sensitivity
of our results to use of alternative
concentration-response functions.
TABLE VIII.E–2.—ESTIMATED ANNUAL REDUCTIONS IN INCIDENCE OF HEALTH EFFECTS RELATED TO THE FINAL COLD
TEMPERATURE VEHICLE STANDARD A
2020 Annual incidence reduction
Health effect
PM-Related Endpoints:
Premature Mortality b Adult, age 30+ and Infant, age <1 year ................................................................................
222 See
68 FR 28327, May 23, 2003.
that while the final regulations also
control VOCs, which contribute to PM formation,
the benefits transfer scaling approach only scales
benefits based on NOX, SO2, and direct PM
emission reductions. PM benefits will likely be
underestimated as a result, though we are unable
to estimate the magnitude of the underestimation.
224 See: Clean Air Nonroad Diesel final rule (69
FR 38958, June 29, 2004); Nonroad Large Spark-
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223 Note
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Ignition Engines and Recreational Engines
standards (67 FR 68241, November 8, 2002); Final
Industrial Boilers and Process Heaters NESHAP (69
FR 55217, September 13, 2004); Final Reciprocating
Internal Combustion Engines NESHAP (69 FR
33473, June 15, 2004); Final Clean Air Visibility
Rule (EPA–452/R–05–004, June 15, 2005); Ozone
Implementation Rule (documentation forthcoming).
225 Pope, C.A., III, R.T. Burnett, M.J. Thun, E.E.
Calle, D. Krewski, K. Ito, and G.D. Thurston. 2002.
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480
2030 Annual incidence reduction
880
‘‘Lung Cancer, Cardiopulmonary Mortality, and
Long-term Exposure to Fine Particulate Air
Pollution.’’ Journal of American Medical
Association 287:1132–1141.
226 Woodruff, T.J., J. Grillo, and K.C. Schoendorf.
1997. ‘‘The Relationship Between Selected Causes
of Postneonatal Infant Mortality and Particulate
Infant Mortality and Particulate Air Pollution in the
United States.’’ Environmental Health Perspectives
105(6):608–612.
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TABLE VIII.E–2.—ESTIMATED ANNUAL REDUCTIONS IN INCIDENCE OF HEALTH EFFECTS RELATED TO THE FINAL COLD
TEMPERATURE VEHICLE STANDARD A—Continued
2020 Annual incidence reduction
Health effect
Chronic bronchitis (adult, age 26 and over) .............................................................................................................
Non-fatal myocardial infarction (adult, age 18 and over) .........................................................................................
Hospital admissions—respiratory (all ages) c ...........................................................................................................
Hospital admissions—cardiovascular (adults, age >18) d ........................................................................................
Emergency room visits for asthma (age 18 years and younger) ............................................................................
Acute bronchitis, (children, age 8–12) .....................................................................................................................
Lower respiratory symptoms (children, age 7–14) ...................................................................................................
Upper respiratory symptoms (asthmatic children, age 9–18) ..................................................................................
Asthma exacerbation (asthmatic children, age 6–18) ..............................................................................................
Work loss days .........................................................................................................................................................
Minor restricted activity days (adults age 18–65) ....................................................................................................
2030 Annual incidence reduction
330
810
260
210
350
780
9,300
7,000
12,000
62,000
370,000
570
1,600
530
390
610
1,400
16,000
12,000
20,000
100,000
600,000
a Incidence
is rounded to two significant digits. Estimates represent benefits from the final rule nationwide, excluding Alaska and Hawaii.
adult mortality based upon the ACS cohort study (Pope et al., 2002).225 PM-related infant mortality based upon studies by Woodruff, Grillo, and Schoendorf, 1997.226 Due to analytical constraints associated with the PM benefits scaling approach, we are unable to present
the premature mortality impacts associated with the recent Six-Cities study (Laden et al., 2006) or the impacts associated with the recent PM-related premature mortality expert elicitation (IEc, 2006). Chapter 12.6 of the RIA discusses the implications these new studies have on the benefits estimated for the final rule.
c Respiratory hospital admissions for PM include admissions for chronic obstructive pulmonary disease (COPD), pneumonia and asthma.
d Cardiovascular hospital admissions for PM include total cardiovascular and subcategories for ischemic heart disease, dysrhythmias, and
heart failure.
b PM-related
PM2.5 also has numerous documented
effects on environmental quality that
affect human welfare. These welfare
effects include direct damages to
property, either through impacts on
material structures or by soiling of
surfaces, and indirect economic
damages through the loss in value of
recreational visibility or the existence
value of important resources. Additional
information about these welfare effects
can be found in Chapter 12 of the
Regulatory Impact Analysis.
3. Monetized Benefits
Table VIII.E–3 presents the estimated
monetary value of reductions in the
incidence of those health effects we are
able to monetize for the final cold
temperature vehicle standard. Total
annual PM-related health benefits are
estimated to be approximately $6.3 or
$5.7 billion in 2030 (3 percent and 7
percent discount rate, respectively).
These estimates account for growth in
real gross domestic product (GDP) per
capita between the present and 2030.
Table VIII.E–3 indicates with a ‘‘B’’
those additional health and
environmental benefits of the rule that
we are unable to quantify or monetize.
These effects are additive to the estimate
of total benefits, and are related to the
following sources:
• There are many human health and
welfare effects associated with PM,
ozone, and toxic air pollutant
reductions that remain unquantified
because of current limitations in the
methods or available data. A listing of
the benefit categories that could not be
quantified or monetized in our benefit
estimates are provided in Table VIII.E–
1.
• The PM2.5 benefits scaled transfer
approach, derived from the Clean Air
Nonroad Diesel rule, does not account
for VOCs as precursors to ambient PM2.5
formation. To the extent that VOC
emission reductions associated with the
final regulations contribute to
reductions in ambient PM2.5, this
analysis does not capture the related
health and environmental benefits of
those changes.
• The PM air quality model only
captures the benefits of air quality
improvements in the 48 states and DC;
PM benefits for Alaska and Hawaii are
not reflected in the estimate of benefits.
TABLE VIII.E–3.—ESTIMATED ANNUAL MONETARY VALUE OF REDUCTIONS IN INCIDENCE OF HEALTH AND WELFARE
EFFECTS RELATED TO THE FINAL COLD TEMPERATURE VEHICLE STANDARD
(Millions of 2003$) a,b
2020 estimated value of
reductions
2030 estimated value of
reductions
PM2.5 ................................................
..........................................................
PM2.5 ................................................
$3,100
2,800
150
$5,800
5,200
260
..........................................................
PM2.5 ................................................
PM2.5 ................................................
PM2.5 ................................................
PM2.5 ................................................
PM2.5 ................................................
PM2.5 ................................................
PM2.5 ................................................
PM2.5 ................................................
79
76
4.7
5.0
0.11
0.32
0.16
0.20
0.56
150
140
10
9.1
0.20
0.56
0.29
0.35
1.0
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Health effect
Pollutant
PM-Related Premature mortality c,d Adult, 30+ years and Infant, <1 year:
3 percent discount rate .......................................................................
7 percent discount rate .......................................................................
Chronic bronchitis (adults, 26 and over) ...................................................
Non-fatal acute myocardial infarctions:
3 percent discount rate .......................................................................
7 percent discount rate .......................................................................
Hospital admissions for respiratory causes ...............................................
Hospital admissions for cardiovascular causes ........................................
Emergency room visits for asthma ............................................................
Acute bronchitis (children, age 8–12) ........................................................
Lower respiratory symptoms (children, age 7–14) ....................................
Upper respiratory symptoms (asthma, age 9–11) .....................................
Asthma exacerbations ...............................................................................
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TABLE VIII.E–3.—ESTIMATED ANNUAL MONETARY VALUE OF REDUCTIONS IN INCIDENCE OF HEALTH AND WELFARE
EFFECTS RELATED TO THE FINAL COLD TEMPERATURE VEHICLE STANDARD—Continued
(Millions of 2003$) a,b
2020 estimated value of
reductions
2030 estimated value of
reductions
PM2.5 ................................................
PM2.5 ................................................
9.1
21
14
35
PM2.5 ................................................
..........................................................
3,300+ B
3,000+ B
6,300+ B
5,700+ B
Health effect
Pollutant
Work loss days ..........................................................................................
Minor restricted activity days (MRADs) .....................................................
Monetized Totale
Base estimate:
3 percent discount rate .......................................................................
7 percent discount rate .......................................................................
a Dollars
are rounded to two significant digits. The PM estimates represent benefits from the final rule across the contiguous United States.
benefits adjusted to account for growth in real GDP per capita between 1990 and the analysis year (2020 or 2030).
c Valuation of premature mortality based on long-term PM exposure assumes discounting over the SAB recommended 20-year segmented lag
structure described in the Regulatory Impact Analysis for the Final Clean Air Interstate Rule (March 2005). Results show 3 percent and 7 percent
discount rates consistent with EPA and OMB guidelines for preparing economic analyses (US EPA, 2000 and OMB, 2003).227,228
d Adult mortality based upon the ACS cohort study (Pope et al., 2002). Infant mortality based upon studies by Woodruff, Grillo, and
Schoendorf, 1997. Due to analytical constraints associated with the PM benefits scaling approach, we are unable to present the premature mortality impacts associated with the recent Six-Cities study (Laden et al., 2006) study or the impacts associated with the recent PM-related premature mortality expert elicitation (IEc, 2006). Chapter 12.6 of the RIA discusses the implications these new studies have on the benefits estimated for the final rule.
e B represents the monetary value of health and welfare benefits not monetized. A detailed listing is provided in Table VIII.E–1.
b Monetary
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4. What Are the Significant Limitations
of the Benefit Analysis?
The most significant limitation of this
analysis is our inability to quantify a
number of potentially significant benefit
categories associated with
improvements in air quality that would
result from the final standards. Most
notably, we are unable to estimate the
benefits from reduced air toxics
exposures because the available tools
and methods to assess mobile source air
toxics risk at the national scale are not
adequate for extrapolation to incidence
estimations or benefits assessment. We
also do not quantify ozone benefits
associated with the final PFC standards,
despite the fact that there are net
benefits, when population-weighted, in
the ozone design value metric across the
modeled domain (see section IV.C). We
do not quantify these benefits because of
their magnitude and the uncertainty
associated with them.
More generally, every benefit-cost
analysis examining the potential effects
of a change in environmental protection
requirements is limited to some extent
by data gaps, limitations in model
capabilities (such as geographic
coverage), and uncertainties in the
underlying scientific and economic
studies used to configure the benefit and
cost models. Deficiencies in the
scientific literature often result in the
inability to estimate quantitative
changes in health and environmental
227 U.S. Environmental Protection Agency, 2000,
Guidelines for Preparing Economic Analyses.
https://yosemite.epa.gov/ee/epa/eed.nsf/webpages/
Guidelines.html.
228 Office of Management and Budget, The
Executive Office of the President, 2003. Circular A–
4. https://www.whitehouse.gov/omb/circlars.
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effects. Deficiencies in the economics
literature often result in the inability to
assign economic values even to those
health and environmental outcomes
which can be quantified. These general
uncertainties in the underlying
scientific and economics literature,
which can cause the valuations to be
higher or lower, are discussed in detail
in the RIA and its supporting references.
Key uncertainties that have a bearing on
the results of the benefit-cost analysis of
the final standards include the
following:
• The exclusion of potentially
significant and unquantified benefit
categories (such as health, odor, and
ecological benefits of reduction in air
toxics, ozone, and PM);
• Errors in measurement and
projection for variables such as
population growth;
• Uncertainties in the estimation of
future year emissions inventories and
air quality;
• Uncertainties associated with the
scaling of the PM results of the modeled
benefits analysis to the final standards,
especially regarding the assumption of
similarity in geographic distribution
between emissions and human
populations and years of analysis;
• Uncertainty in the estimated
relationships of health and welfare
effects to changes in pollutant
concentrations including the shape of
the C–R function, the size of the effect
estimates, and the relative toxicity of the
many components of the PM mixture;
• Uncertainties in exposure
estimation; and
• Uncertainties associated with the
effect of potential future actions to limit
emissions.
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As Table VIII.E–3 indicates, total
benefits are driven primarily by the
reduction in premature fatalities each
year. Elaborating on the list of
uncertainties above, some key
assumptions underlying the primary
estimate for the premature mortality
category include the following:
1. Inhalation of fine particles is
causally associated with premature
death at concentrations near those
experienced by most Americans on a
daily basis. Although biological
mechanisms for this effect have not yet
been completely established, the weight
of the available epidemiological,
toxicological, and experimental
evidence supports an assumption of
causality. The impacts of including a
probabilistic representation of causality
were explored in the expert elicitationbased results of the recently published
PM NAAQS RIA. Because the analysis
of the final cold temperature vehicle
standard is constrained to the studies
included in the CAND PM benefits
scaling approach, we are unable to
conduct the same analysis of expert
elicitation-based mortality incidence for
the final standards.229 However, we
qualitatively describe the expert
elicitation-based mortality results
associated with the final PM NAAQS to
provide an indication of the sensitivity
of our PM-related premature mortality
results to use of alternative
229 The scaling approach relies on the incidence
and valuation estimates derived from the studies
available at the time of the CAND analysis.
Incidence estimates and monetized benefits derived
from new information, including mortality derived
from the full expert elicitation, are not available for
scaling. Please refer to section 2 of this preamble
and Chapter 12 of the RIA for more information
about the benefits scaling approach.
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concentration-response functions. We
present this discussion in the RIA.
2. Since the publication of CAIR and
CAND, a follow up to the Harvard SixCities study on premature mortality was
published (Laden et al., 2006 based on
Dockery et al., 1993),230, 231 which both
confirmed the effect size from the first
study and provided additional evidence
that reductions in PM2.5 directly result
in reductions in the risk of premature
death. The impacts of including this
study in the primary analysis were
explored in the results of the recently
published PM NAAQS RIA. Because the
analysis of the final cold temperature
vehicle standard is constrained to the
studies included in the CAND PM
benefits scaling approach, we are unable
to characterize PM-related mortality
based on Laden et al. However, we
discuss the implications of these results
in the RIA for the final standards.
3. All fine particles, regardless of their
chemical composition, are equally
potent in causing premature mortality.
This is an important assumption,
because PM produced via transported
precursors emitted from vehicles at cold
temperatures may differ significantly
from PM precursors released from
electric generating units and other
industrial sources. However, no clear
scientific grounds exist for supporting
differential effects estimates by particle
type.
4. The concentration-response
function for fine particles is
approximately linear within the range of
ambient concentrations under
consideration. Thus, the estimates
include health benefits from reducing
fine particles in areas with varied
concentrations of PM, including both
regions that may be in attainment with
PM2.5 standards and those that are at
risk of not meeting the standards.
Taking into account these
uncertainties, we believe this benefitcost analysis provides a conservative
estimate of the expected economic
benefits of the final standards for cold
temperature vehicle control in future
years because of the exclusion of
potentially significant benefit categories.
Acknowledging benefits omissions and
uncertainties, we present a best estimate
of the total benefits based on our
interpretation of the best available
230 Laden, F., J. Schwartz, F.E. Speizer, and D.W.
Dockery. 2006. Reduction in Fine Particulate Air
Pollution and Mortality. American Journal of
Respiratory and Critical Care Medicine. 173: 667–
672.
231 Dockery, D.W., C.A. Pope, X.P. Xu, J.D.
Spengler, J.H. Ware, M.E. Fay, B.G. Ferris, and F.E.
Speizer. 1993. ‘‘An Association between Air
Pollution and Mortality in Six U.S. Cities.’’ New
England Journal of Medicine 329(24):1753–1759.
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scientific literature and methods.
Furthermore, our analysis reflects many
methodological improvements that were
incorporated into the analysis of the
final Clean Air Interstate Rule (CAIR),
including a revised value of a statistical
life, a revised baseline rate of future
mortality, and a revised mortality lag
assumption. Details of these
improvements can be found in the RIA
for this rule and in the final CAIR rule
RIA.232 Once again, however, it should
be noted that since the CAIR rule, EPA’s
Office of Air and Radiation (OAR) has
adopted a different format for its
benefits analysis in which
characterization of uncertainty is
integrated into the main benefits
analysis. Please see the PM NAAQS RIA
for an indication of the uncertainty
present in the base estimate of benefits
and the sensitivity of our results to the
use of alternative concentrationresponse functions.
In contrast to the additional benefits
of the final standards discussed above,
it is also possible that this rule will
result in disbenefits in some areas of the
United States. The effects of ozone and
PM on radiative transfer in the
atmosphere can lead to effects of
uncertain magnitude and direction on
the penetration of ultraviolet light and
climate. Ground level ozone makes up
a small percentage of total atmospheric
ozone (including the stratospheric layer)
that attenuates penetration of
ultraviolet—b (UVb) radiation to the
ground. EPA’s past evaluation of the
information indicates that potential
disbenefits would be small, variable,
and with too many uncertainties to
attempt quantification of relatively
small changes in average ozone levels
over the course of a year.233 EPA’s most
recent provisional assessment of the
currently available information
indicates that potential but
unquantifiable benefits may also arise
from ozone-related attenuation of UVb
radiation.234 In addition, EPA believes
that we are unable to quantify any net
climate-related disbenefit or benefit
associated with the combined ozone and
PM reductions in this rule.
232 See Chapter 4 of the Final Clean Air Interstate
Rule RIA (https://www.epa.gov/cair) for a discussion
of EPA’s ongoing efforts to address the NAS
recommendations in its regulatory analyses.
233 EPA, 2005. Air Quality Criteria for Ozone and
Related Photochemical Oxidants (First External
Review Draft). January. https://cfpub.epa.gov/ncea/
cfm/recordisplay.cfm?deid=114523.
234 EPA, 2005. Air Quality Criteria for Ozone and
Related Photochemical Oxidants (Second External
Review Draft). August. https://cfpub.epa.gov/ncea/
cfm/recordisplay.cfm?deid=137307.
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5. How Do the Benefits Compare to the
Costs of The Final Standards?
The final rule provides three separate
provisions that reduce air toxics
emissions from mobile sources: cold
temperature vehicle controls, a PFC
emissions control program, and a
control program limiting benzene in
gasoline. A full appreciation of the
overall economic consequences of these
provisions requires consideration of the
benefits and costs expected to result
from each standard, not just those that
could be expressed here in dollar terms.
As noted above, due to limitations in
data availability and analytical methods,
our benefits analysis only monetizes the
PM2.5 benefits from direct PM emission
reductions associated with the cold
temperature standards. There are a
number of health and environmental
effects associated with the final
standards that we were unable to
quantify or monetize (see Table VIII.E–
1).
Table VIII.E–4 contains the estimates
of monetized benefits of the final cold
temperature vehicle standards only and
estimated social welfare costs for all of
the final control programs.235 The
annual social welfare costs of all
provisions of the final rule are described
more fully in Section VIII.F. It should be
noted that the estimated social welfare
costs for the vehicle program contained
in this table are for 2019. The 2019
vehicle program costs are included for
comparison purposes only and are
therefore not included in the total 2020
social costs. There are no compliance
costs associated with the vehicle
program after 2019; as explained
elsewhere in this preamble, the vehicle
compliance costs are primarily R&D and
facilities costs that are expected to be
recovered by manufacturers over the
first ten years of the program.
The results in Table VIII.E–4 suggest
that the 2020 monetized benefits of the
cold temperature vehicle standards are
greater than the expected social welfare
costs of that program in 2019.
Specifically, the annual benefits of the
program will be approximately $3,300 +
B million or $3,000 + B million
annually in 2020 (using a 3 percent and
7 percent discount rate in the benefits
analysis, respectively), compared to
estimated social welfare costs of
approximately $10.6 million in the last
year of the program (2019). These
benefits are expected to increase to
$6,300 + B million or $5,700 + B million
annually in 2030 (using a 3 percent and
235 Social costs represent the welfare costs of the
rule to society. These social costs do not consider
transfer payments (such as taxes) that are simply
redistributions of wealth.
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7 percent discount rate in the benefits
analysis, respectively), even as the
social welfare costs of that program fall
to zero. Table VIII.E–4 also presents the
costs of the other rule provisions: a PFC
emissions control program and a control
program limiting benzene in gasoline.
Though we are unable to present the
benefits associated with these two
programs, the benefits associated with
the final cold temperature vehicle
standards alone outweigh the costs of all
three rule provisions combined.
TABLE VIII.E–4.—SUMMARY OF ANNUAL BENEFITS OF THE FINAL COLD TEMPERATURE VEHICLE STANDARDS AND COSTS
OF ALL PROVISIONS OF THE FINAL STANDARDS a
[Millions of 2003 dollars]
Description
2020 (Millions of 2003 dollars)
2030 (Millions of 2003 dollars)
Estimated Social Welfare Costs b
Cold Temperature Vehicle Standards ..............................................
PFC Standards .................................................................................
Fuel Standards d ...............................................................................
Total .................................................................................................
Fuel Savings ....................................................................................
Net Social Welfare Costs
$10.6 c ............................................
$37.5 ..............................................
$402.6 ............................................
$440.1 ............................................
¥$80.7 ..........................................
$359.4 ............................................
$0
$45.7
$445.8
$491.5
¥$91.5
$400.0
Total PM2.5-Related Health Benefits of the
Cold Temperature Vehicle Standards e
3 percent discount rate ....................................................................
7 percent discount rate ....................................................................
$3,300 + B f ...................................
$3,000 + B f ...................................
$6,300 + B f
$5,700 + B f
a All estimates are rounded to two significant digits and represent annualized benefits and costs anticipated for the years 2020 and 2030, except where noted. Totals may not sum due to rounding.
b Note that costs are the annual costs of reducing all pollutants associated with each provision of the final MSAT control package in 2020 and
2030 (unless otherwise noted). To estimate fixed costs associated with the vehicle standards, we use a 7 percent average before-tax rate of return over 5 years to amortize the capital fixed costs. For the fuel standards, we use a 7 percent before-tax rate of return over 15 years to amortize the capital costs. Note that by 2020, PFC container standard costs are only variable and do not use a rate of return assumption. See Chapters 8 and 9 for discussion of the vehicle and fuel standard costs, respectively. In Chapter 13, however, we do use both a 3 percent and 7 percent social discount rate to calculate the net present value of total social costs consistent with EPA and OMB guidelines for preparing economic
analyses (US EPA, 2000 and OMB, 2003).236, 237
c These costs are for 2019; the vehicle program compliance costs terminate after 2019 and are included for illustrative purposes. They are not
included in the total social welfare cost sum for 2020.
d Our modeling for the total costs of the proposed gasoline benzene program included participation by California refineries (achieving benzene
reductions below the 0.62 proposed benzene standard—thus generating credits), since it was completed before we decided that California gasoline would not be covered by the program. For the final rule, we exclude California refineries from the analysis. By excluding California refineries,
other higher cost refineries will have to comply in their place, slightly increasing the costs for the program.
e Annual benefits reflect only direct PM reductions associated with the cold temperature vehicle standards. Annual benefits analysis results reflect the use of a 3 percent and 7 percent discount rate in the valuation of premature mortality and nonfatal myocardial infarctions, consistent
with EPA and OMB guidelines for preparing economic analyses (US EPA, 2000 and OMB, 2003). Valuation of premature mortality based on
long-term PM exposure assumes discounting over the SAB recommended 20-year segmented lag structure described in the Regulatory Impact
Analysis for the Final Clean Air Interstate Rule (March 2005). Valuation of nonfatal myocardial infarctions (MI) assumes discounting over a 5-year
period, reflecting lost earnings and direct medical costs following a nonfatal MI. Note that we do not calculate a net present value of benefits associated with the cold temperature vehicle standards.
f Not all possible benefits or disbenefits are quantified and monetized in this analysis. B is the sum of all unquantified benefits and disbenefits.
Potential benefit categories that have not been quantified and monetized are listed in Table VIII.E–1.
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F. Economic Impact Analysis
We prepared an Economic Impact
Analysis (EIA) to estimate the economic
impacts of this rule on the portable fuel
container (PFC), gasoline fuel, and lightduty vehicle markets. In this section we
briefly describe the Economic Impact
Model (EIM) we developed to estimate
both the market-level changes in price
and outputs for affected markets and the
social costs of the program and their
distribution across affected
stakeholders. We also present the results
of our analysis.
We estimate the net social costs of the
program to be about $359.4 million in
2020. This estimate reflects the
236 U.S. Environmental Protection Agency, 2000.
Guidelines for Preparing Economic Analyses.
https://yosemite.epa.gov/ee/epa/eed.nsf/webpages/
Guidelines.html.
237 Office of Management and Budget, The
Executive Office of the President, 2003. Circular A–
4. https://www.whitehouse.gov/omb/circulars.
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estimated costs associated with
compliance with the gasoline, PFC, and
vehicle controls and the expected
gasoline fuel savings from better
evaporative controls on PFCs. The
results of the economic impact
modeling performed for the gasoline
fuel and PFC control programs suggest
that the social costs of those two
programs are expected to be about
$440.1 million in 2020, with consumers
of these products expected to bear about
58.4 percent of these costs. We estimate
gasoline fuel savings of about $80.7
million in 2020, which will accrue to
consumers. There are no social costs
associated with the vehicle program in
2020 (these accrue only in the 10-year
period from 2010 through 2019). These
estimates, and all costs presented in this
section, are in year 2003 dollars.
With regard to market-level impacts
in 2020, the maximum price increase for
gasoline fuel is expected to be about 0.3
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percent (0.5 cents per gallon), for PADD
5. The price of PFCs is expected to
increase by about 1.9 percent ($0.20 per
can) in areas that already have PFC
requirements and 32.5 percent ($1.52
per can) in areas that do not.
Detailed descriptions of the EIM, the
model inputs, modeling results, and
several sensitivity analyses can be found
in Chapter 13 of the Regulatory Impact
Analysis prepared for this rule.
1. What Is an Economic Impact
Analysis?
An Economic Impact Analysis (EIA) is
prepared to inform decision makers
about the potential economic
consequences of a regulatory action. The
analysis consists of estimating the social
costs of a regulatory program and the
distribution of these costs across
stakeholders. These estimated social
costs can then be compared with
estimated social benefits (as presented
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in Section VIII.E). As defined in EPA’s
Guidelines for Preparing Economic
Analyses, social costs are the value of
the goods and services lost by society
resulting from a) the use of resources to
comply with and implement a
regulation and b) reductions in
output.238 In this analysis, social costs
are explored in two steps. In the market
analysis, we estimate how prices and
quantities of goods affected by the
emission control program can be
expected to change once the program
goes into effect. In the economic welfare
analysis, we look at the total social costs
associated with the program and their
distribution across stakeholders.
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2. What Is the Economic Impact Model?
The Economic Impact Model (EIM) is
a behavioral model developed to
estimate price and quantity changes and
total social costs associated with the
emission controls set out in this rule.
The EIM simulates how producers and
consumers of affected products can be
expected to respond to an increase in
production costs associated with
compliance with the emission control
program. In this EIM, compliance costs
are directly borne by producers of
affected goods. Depending on the
producers’ and consumers’ sensitivity to
price changes, producers may be able to
pass some or all of these compliance
costs on to the consumers of these goods
in the form of higher prices. Consumers
adjust their consumption of affected
goods in response to these price
changes. This information is passed
back to the producers in the form of
purchasing decisions. The EIM takes
these behavioral responses into account
to estimate new market equilibrium
quantities and prices for all modeled
sectors and the resulting distribution of
social costs across these stakeholders
(producers and consumers).
3. What Economic Sectors Are Included
in this Economic Impact Analysis?
There are three economic sectors
affected by the control programs
described in this rule: PFCs, gasoline
fuel, and light-duty vehicles. In this
Economic Impact Analysis we model
only the impacts on the PFC and
gasoline fuel markets. We did not model
the impacts on the light-duty vehicle
market. This is because the compliance
costs for the vehicle program are
expected to be very small, less than $1
per vehicle and, even if passed on
entirely, are unlikely to affect producer
238 EPA
Guidelines for Preparing Economic
Analyses, EPA 240–R–00–003, September 2000, p
113. A copy of this document can be found at
https://yosemite.epa.gov/ee/epa/eed.nsf/webpages/
Guidelines.html#download.
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or consumer behavior. Therefore, we do
not expect these controls to affect the
quantity of vehicles produced or their
prices. At the same time, however, the
light-duty vehicle compliance costs are
a cost to society and should be included
in the economic welfare analysis. We do
this by adding the vehicle program
engineering compliance cost estimates
to the estimated social costs of the
gasoline and PFC programs.
With regard to the gasoline fuel and
PFC markets, we model the impacts on
residential users of these products. This
means that we focus the analysis on the
use of these products for personal
transportation (gasoline fuel) or
residential lawns and garden care or
recreational uses (PFCs) and do not
separately model how the costs of
complying with the standards may
affect the production of goods and
services that use gasoline fuel or PFCs
as production inputs. We believe this
approach is reasonable because the
commercial share of the end-user
markets for both gasoline fuel and PFCs
is relatively small.239, 240 In addition, for
most commercial users the share of the
cost of these products to total
production costs is also small (e.g., the
cost of a PFC is only a very small part
of the total production costs for an
agricultural or construction firm).
Therefore, a price increase of the
magnitude anticipated for this control
program is not expected to have a
noticeable impact on prices or
quantities of goods produced using
these inputs (e.g., agricultural product
or buildings).
With regard to the gasoline fuel
analysis, it should be noted that this EIA
does not include California fuels in the
market analysis. California currently has
state-level controls that address air
toxics from gasoline. Also, consistent
with the cost analysis, the economic
impact analysis does not distinguish
239 The U.S Department of Energy estimates that
about 92 percent of gasoline used in the United
States for transportation is used in light-duty
vehicles. About 6 percent is used for commercial or
industrial transportation, and the remaining 2
percent is used in recreational marine vessels. See
U.S Department of Energy, Energy Information
Administration, 2004. ‘‘Annual Energy Outlook
2004 with projections to 2025.’’ Last updated June
2, 2004. Table A–2 and Supplemental Table 34.
https://www.eia.doe.gov/oiaf/aeoref_tab.html.
240 A recent study by CARB (1999) found that 94
percent of portable fuel containers in California
were used by residential households California
Environmental Protection Agency, Air Resources
Board (CARB) 1999. See ‘‘Hearing Notice and Staff
Report, Initial Statement of Reasons for Proposed
Rule Making Public Hearing to Consider the
Adoption of Portable Fuel Container Spillage
Control Regulation.’’ Sacrament, CA: California
Environmental Protection Agency, Air Resources
Board (CARB). A copy of this document is available
at https://www.arb.ca.gov/regact/spillcon/isor.pdf.
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8519
between reformulated and conventional
gasoline fuels.
The EIM models the economic
impacts on two PFC markets (states that
currently have requirements for PFCs
and those that do not), and four gasoline
fuel markets (PADDs 1+3, PADD 2,
PADD 4, PADD 5). The markets
included in this EIA are described in
more detail in Chapter 13 of the RIA for
this rule.
In the EIM, the gasoline fuel and PFC
markets are not linked (there is no
feedback mechanism between the PFC
and gasoline fuel model segments). This
is because these two sectors represent
different aspects of fuel consumption
(fuel storage and fuel production) and
production and consumption of PFCs is
not expected to have an impact on the
production and supply of gasoline, and
vice versa. Production and consumption
of each of these products are the result
of other factors that have little crossover impacts (the need for fuel storage;
the need for personal transportation).
4. What Are the Key Features of the
Economic Impact Model?
A detailed description of the features
of the EIM and the data used in the
analysis is provided in Chapter 13 of the
RIA prepared for this rule. The model
methodology is firmly rooted in applied
microeconomic theory and was
developed following the methodology
set out in the OAQPS’s Economic
Analysis Resource Document.241
The EIM is a computer model
comprised of a series of spreadsheet
modules that simulate the supply and
demand characteristics of the affected
markets. The initial market equilibrium
conditions are shocked by applying the
compliance costs for the control
program to the supply side of the
markets (this is done by shifting the
relevant supply curves by the amount of
the compliance costs). The model
equations can be analytically solved for
equilibrium prices and quantities for the
markets with the regulatory program
and these new prices and quantities are
used to estimate the social costs of the
model and how those costs are shared
among affected markets.
The EIM is a partial equilibrium,
intermediate-run model that assumes
perfect competition in the relevant
markets. As explained in EPA’s
Guidelines for Preparing Economic
Analyses, ‘‘partial equilibrium’’ means
that the model considers markets in
241 U.S. Environmental Protection Agency, Office
of Air Quality Planning and Standards, Innovative
Strategies and Economics Group, OAQPS Economic
Analysis Resource Document, April 1999. A copy
of this document can be found at https://
www.epa.gov/ttn/ecas/econdata/Rmanual2/.
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isolation and that conditions in other
markets are assumed either to be
unaffected by a policy or unimportant
for social cost estimation.242 The use of
the intermediate run means that some
factors of production are fixed and some
are variable. In very short analyses, all
factors of production would be assumed
to be fixed, leaving the producers with
no means to respond to the increased
production costs associated with the
regulation (e.g., they cannot adjust labor
or capital inputs). Under this time
horizon, the costs of the regulation fall
entirely on the producer. In the long
run, all factors of production are
variable and producers can adjust
production in response to cost changes
imposed by the regulation (e.g., using a
different labor/capital mix). In the
intermediate run there is some resource
immobility which may cause producers
to suffer producer surplus losses, but
they can also pass some of the
compliance costs to consumers.
The perfect competition assumption
is widely accepted economic practice
for this type of analysis, and only in rare
cases are other approaches used.243 It
should be noted that the perfect
competition assumption is not primarily
about the number of firms in a market.
It is about how the market operates: the
nature of the competition among firms.
Indicators that allow us to assume
perfect competition include absence of
barriers to entry, absence of strategic
behavior among firms in the market, and
product differentiation.
With regard to the fuel market, the
Federal Trade Commission (FTC) has
developed an approach to ensure
competitiveness in gasoline fuel
markets. It reviews oil company mergers
and frequently requires divestiture of
refineries, terminals, and gas stations to
maintain a minimum level of
competition. This is discussed in more
detail in the industry profile prepared
for this rule.244
With regard to the PFC market, the
small number of firms in the market is
offset by several features of this market.
Because PFCs are compact and
lightweight, they are easy to transport
far from their place of manufacture. This
means that production is not limited to
local producers. Although they vary by
size and material, consumers are likely
to view all PFCs designed for storing a
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242 EPA
Guidelines for Preparing Economic
Analyses, EPA 240–R–00–003, September 2000, p.
125–6.
243 See, for example, EPA Guidelines for
Preparing Economic Analyses, EPA 240–R–00–003,
September 2000, p 126.
244 Section 3 Industry Organization,
‘‘Characterizing Gasoline Markets: a Profile,’’ Final
Report, prepared for EPA by RTI, August 2005.
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particular fuel (gasoline, diesel fuel,
kerosene) as good substitutes for the
storage of that particular fuel. Because
the products are similar enough to be
considered homogeneous (e.g., perfectly
substitutable), consumers can shift their
purchases from one manufacturer to
another. There are only minimal
technical barriers to entry that would
prevent new firms from freely entering
the market, since manufacturing is
based on well-known plastic processing
methods. In addition, there is significant
excess capacity, enabling competitors to
respond quickly to changes in price.
Excess production capacity in the
general container manufacturing market
also means that manufacturers could
potentially switch their product lines to
compete in this segment of the market,
often without a significant investment.
In addition, there is no evidence of high
levels of strategic behavior in the price
and quantity decisions of the firms.
Finally, it should be noted that
contestable market theory asserts that
oligopolies and even monopolies will
behave very much like firms in a
competitive market if manufacturers
have extra production capacity and this
capacity could allow them to enter the
market costlessly (i.e., there are no sunk
costs associated with this kind of market
entry or exit).245 As a result of all of
these conditions, producers and
consumers in the PFC market are
expected to take the market price as
given when making their production
and consumption choices and the
market can be modeled as a competitive
market even though the number of
producers is small.
5. What Are the Key Model Inputs?
Key model inputs for the EIM are the
behavioral parameters, compliance costs
estimates, and market equilibrium
quantities and prices.
The EIM is a behavioral model. The
estimated social costs of this emission
control program are a function of the
ways in which producers and
consumers of the PFC and gasoline fuel
affected by the standards change their
behavior in response to the costs
incurred in complying with the
standards. These behavioral responses
are incorporated in the EIM through the
price elasticity of supply and demand
245 A monopoly or firms in oligopoly may not
behave as neoclassical economic theories of the
firm predict because they may be concerned about
new entrants to the market. If super-normal profits
are earned, potential competitors may enter the
market. To respond to this threat, existing firm(s)
in the market will keep prices and output at a level
where only normal profits are made, setting price
and output levels at or close to the competitive
price and output. See Chapter 13 of the RIA for
more information, Section 13.2.3.
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(reflected in the slope of the supply and
demand curves), which measure the
price sensitivity of consumers and
producers. The price elasticities used in
this analysis are described in Chapter 13
of the RIA. The gasoline elasticities
were obtained from the literature and
are ¥0.2 for demand and 0.2 for supply.
This means that both the quantity
supplied and demanded are expected to
be fairly insensitive to price changes
and that increases in prices are not
expected to cause sales to fall or
production to increase by very much.
Because we were unable to find
published supply and demand
elasticities for the PFC market, we
estimated these parameters using the
procedures described in Chapter 13 of
the RIA. This approach yielded a
demand elasticity of ¥0.01 and a
supply elasticity of 1.5. The estimated
demand elasticity is nearly perfectly
inelastic (equal to zero), which means
that changes in price are expected to
have very little effect on the quantity of
PFCs demanded. However, supply is
fairly elastic, meaning producers are
expected to respond to a change in
price. Therefore, consumers are
expected to bear more of the burden of
PFC regulatory control costs than
producers.
Initial market equilibrium conditions
are simulated using the same current
year sales quantities and growth rates
used in the engineering cost analysis.
The initial equilibrium prices for PFCs
and gasoline fuel were obtained from
industry sources and published
government data. The initial
equilibrium market conditions are
shocked by applying the engineering
compliance cost estimates described
earlier in this section. Although both the
PFC and gasoline fuel markets are
competitive markets, the model is
shocked by applying the sum of variable
and fixed costs. Two sets of compliance
costs are used in the PFC market
analysis, reflecting states with existing
controls and states without existing
controls. The compliance costs used to
shock the gasoline fuel market are based
on an average total cost (variable +
fixed) analysis. An explanation for this
approach can be found in Section
13.2.4.1 of the RIA prepared for this
rule. These gasoline fuel compliance
costs differ across PADDs but are the
same across years. Because California
already has existing gasoline fuel
controls, fuel volumes for that state are
not included in the market analysis.
Additional costs that need to be
considered in the EIM are the gasoline
fuel savings associated with the PFC
controls and the costs of the light-duty
vehicle controls. The PFC controls are
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expected to reduce gasoline evaporative
emissions from fuel storage, leading to
gasoline fuel savings for users of these
containers. These gasoline fuel savings
are not included in the market analysis
for this economic impact analysis
because these savings are not expected
to affect consumer decisions with
respect to the purchase of new
containers. Gasoline fuel savings are
included in the social cost analysis,
however, because they are a savings that
accrues to society. The estimated
gasoline fuel savings are added to the
estimated social costs as a separate line
item. As noted above, the economic
impacts of the light-duty vehicle
controls are not modeled in the EIM.
Instead, the estimated engineering
compliance costs are used as a proxy,
and are also added into the estimated
social costs as a separate line item.
The EIM relies on the estimated
compliance costs for the PFC and
gasoline fuel programs described
elsewhere in this preamble. Thus, the
EIM reflects cost savings associated with
ABT or other flexibility programs to the
extent they are included in the
estimated compliance costs.
6. What Are the Results of the Economic
Impact Modeling?
Using the model and data described
above, we estimated the economic
impacts of the rule. The results of our
modeling for selected years are
summarized in this section. The year
2009 is presented because that is the
production processes or marketing
strategies in response to the control
program.
The market analysis results for 2009,
2012, 2015, and 2020 are presented in
Table VIII.F–1. With regard to the
gasoline fuel program, the market
impacts are expected to be small, on
average. The price of gasoline fuel is
expected to increase by less than 0.5
percent, depending on PADD, with
smaller increases during the program
phase-in. The expected reduction in
quantity of fuel produced is expected to
be less than 0.1 percent.
The market impacts for the PFC
program are expected to be more
significant. In 2009, the first year of the
PFC program, the model predicts a price
increase of about seven percent for PFCs
in states that currently have regulations
for PFCs and about 57 percent for those
that do not. Even with these large price
increases, however, the quantity
produced is not expected to decrease by
very much: less than 0.6 percent. These
percent price increases and quantity
decreases are much smaller after the
first five years. In 2015, the estimated
PFC price increase is expected to be less
than two percent for states that
currently regulate PFCs and about 32.5
percent for states without such
regulations. The quantity produced is
expected to decrease by less than 0.4
percent. The results for 2020 are
substantially the same as 2015, with a
larger decrease in the number of PFCs
produced.
first year in which both the PFC and the
gasoline programs are in effect (the PFC
program begins in 2009; the gasoline
fuel program goes into effect January 1,
2011 but the compliance cost analysis
includes a phase-in starting in 2007 that
ends May 2015). The year 2012 is
presented because it is a high cost year
due to the way the fuel program
compliance costs were estimated.246
The year 2015 is presented because
beginning with that year compliance
costs are stabilized for future years for
both the gasoline and PFC programs (the
vehicle program compliance costs
continue for five more years). Detailed
results for all years are included in the
appendices to Chapter 13 of the RIA.
Also included as an appendix to that
chapter are sensitivity analyses for
several key inputs.
Market Impact Analysis. In the market
analysis, we estimate how prices and
quantities of goods affected by the
emission control program can be
expected to change once the program
goes into effect. As explained above, we
estimated market impacts for only the
gasoline fuel and PFC markets. The
analysis relies on the baseline
equilibrium prices and quantities for
each market and the price elasticity of
supply and demand. It predicts market
reactions to the increase in production
costs due to the new compliance costs.
It should be noted that this analysis
does not allow any other factors to vary.
In other words, it does not consider that
manufacturers may adjust their
TABLE VIII.F–1.—SUMMARY OF MARKET IMPACTS (2009, 2012, 2015, AND 2020; 2003$)
Engineering cost
per unit
Market
Change in price
Absolute
Change in quantity
Percent
Absolute
Percent
2009
¢/gallon
Gasoline Fuel:
PADD 1 & 3 ....................................
PADD 2 ...........................................
PADD 4 ...........................................
PADD 5 (w/out CA) ........................
¢/gallon
0.016
0.091
0.033
0.007
Million gallons
0.009
0.050
0.018
0.004
¥0.9
¥2.7
¥0.1
¥0.0
0.006
0.033
0.011
0.002
$/can
Portable Fuel Containers:
States with existing programs ........
States without existing programs ...
¥0.001
¥0.007
¥0.002
0.000
Thousand cans
0.77
2.70
0.76
2.68
¥8.0
¥104.7
6.9
57.5
¥0.07
¥0.57
2012
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¢/gallon
Gasoline Fuel:
PADD 1 & 3 ....................................
PADD 2 ...........................................
0.058
0.308
0.032
0.168
Million gallons
¥3.3
¥9.7
0.021
0.111
246 Actual fuel program compliance costs are
expected to be spread more evenly across years.
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¥0.022
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TABLE VIII.F–1.—SUMMARY OF MARKET IMPACTS (2009, 2012, 2015, AND 2020; 2003$)—Continued
Engineering cost
per unit
Market
PADD 4 ...........................................
PADD 5 (w/out CA) ........................
Change in price
Absolute
0.213
0.140
Change in quantity
Percent
0.116
0.768
Absolute
¥0.8
¥0.8
0.074
0.046
$/can
Portable Fuel Containers:
States with existing programs ........
States without existing programs ...
Percent
¥0.015
¥0.009
Thousand cans
0.77
2.70
0.76
2.68
¥8.5
¥111.1
6.9
57.5
¥0.07
¥0.57
2015
¢/gallon
Gasoline Fuel:
PADD 1 & 3 ....................................
PADD 2 ...........................................
PADD 4 ...........................................
PADD 5 (w/out CA) ........................
0.149
0.307
0.501
0.997
Million gallons
0.081
0.167
0.273
0.544
¥8.9
¥10.4
¥1.8
¥6.1
0.055
0.111
0.174
0.327
$/can
Portable Fuel Containers:
States with existing programs ........
States without existing programs ...
¥0.011
¥0.022
¥0.035
¥0.065
Thousand cans
0.21
1.53
0.20
1.52
¥2.4
¥66.7
1.9
32.5
¥0.02
¥0.32
2020
¢/gallon
Gasoline Fuel:
PADD 1 & 3 ....................................
PADD 2 ...........................................
PADD 4 ...........................................
PADD 5 (w/out CA) ........................
0.149
0.307
0.501
0.997
Million gallons
0.081
0.167
0.273
0.544
¥9.5
¥10.7
¥2.0
¥6.4
0.055
0.111
0.174
0.327
$/can
pwalker on PROD1PC71 with RULES_2
Portable Fuel Containers:
States with existing programs ........
States without existing programs ...
0.21
1.53
Economic Welfare Analysis. In the
economic welfare analysis, we look at
the costs to society of the emission
control program in terms of losses to key
stakeholder groups that are the
producers and consumers in the
gasoline and PFC markets. These
surplus losses are combined with
estimated vehicle compliance costs,
gasoline fuel savings, and government
revenue losses to estimate the net
economic welfare impacts of the
program. Detailed economic welfare
results for the rule are presented in
Appendix C and are summarized below.
The estimated annual net social costs
(total social costs less gasoline fuel
savings) for all years are presented in
Table VIII.F–2. These social costs follow
the trend of the fuel program
compliance costs. Initially, the
estimated social costs of the program are
relatively small as the gasoline program
begins to phase in. The net social costs
increase to 2012, fall somewhat for 2013
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Thousand cans
0.20
1.52
TABLE VIII.F–2.—ESTIMATED ENGINEERING COMPLIANCE AND SOCIAL
COSTS THROUGH 2035
[Including fuel savings; $million; 2003$]
Engineering
compliance
costs
2007 ..........
2008 ..........
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$29.5
51.3
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Sfmt 4700
¥2.7
¥73.6
1.9
32.5
and 2014 due to changes in the fuel
program compliance costs, and then
increase again in 2015, after which time
the per-gallon costs are expected to be
stable. Some of the decrease in social
costs in 2014 is also due to a decrease
in costs associated with the PFC
program, since fixed costs are fully
amortized by 2014. The slight decrease
in 2020 is due to the end of the vehicle
compliance costs, which are incurred in
the 10-year period from 2010 through
2019.
Year
¥0.011
¥0.022
¥0.035
¥0.065
Social costs
$29.5
51.3
¥0.02
¥0.32
TABLE VIII.F–2.—ESTIMATED ENGINEERING COMPLIANCE AND SOCIAL
COSTS THROUGH 2035—Continued
[Including fuel savings; $million; 2003$]
Year
2009
2010
2011
2012
2013
2014
2015
2016
2017
2018
2019
2020
2021
2022
2023
2024
2025
2026
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..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
..........
26FER2
Engineering
compliance
costs
99.0
161.9
152.6
228.7
190.9
150.8
350.8
354.5
358.0
361.9
366.1
359.5
363.5
367.1
370.7
374.7
378.7
383.1
Social costs
98.9
161.7
152.4
228.5
190.8
150.7
350.7
354.4
357.9
361.8
366.0
359.4
363.4
367.0
370.6
374.6
378.6
383.0
Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
the PFC program. This reflects the
inelastic price elasticity on the demand
side of the market and the elastic price
elasticity on the supply side. The
burden of the gasoline fuel program is
expected to be shared more evenly, with
Engineering
Social costs
about 54.5 percent expected to be borne
Year
compliance
Social costs
costs
by consumers and about 45.5 percent
expected to be borne by producers. In
387.4 7% NPV
all years, the estimated loss to consumer
391.4
(2006–
395.9
2035) .....
2,901.0
2,899.7 welfare will be offset somewhat by the
gasoline fuel savings associated with
400.0
404.5
PFCs. Beginning at about $11 million
Table VIII.F–3 shows how the social
409.1 costs are expected to be shared across
per year, these savings increase to about
413.7
$76 million by 2015 as compliant PFCs
stakeholders, for selected years.
418.4
Information for all years can be found in are phased in. These savings continue
423.2
Appendix C. According to these results, for the life of the PFCs; total annual
consumers are expected to bear
savings increase as the number of cans
5,354.6 approximately 99 percent of the cost of
increases.
TABLE VIII.F–2.—ESTIMATED ENGINEERING COMPLIANCE AND SOCIAL
COSTS THROUGH 2035—Continued
[Including fuel savings; $million; 2003$]
Engineering
compliance
costs
Year
2027 ..........
2028 ..........
2029 ..........
2030 ..........
2031 ..........
2032 ..........
2033 ..........
2034 ..........
2035 ..........
3% NPV
(2006–
2035) .....
387.5
391.6
396.0
400.1
404.6
409.2
413.9
418.6
423.4
5,356.8
8523
TABLE VIII.F–2.—ESTIMATED ENGINEERING COMPLIANCE AND SOCIAL
COSTS THROUGH 2035—Continued
[Including fuel savings; $million; 2003$]
TABLE VIII.F–3.—SUMMARY OF ESTIMATED SOCIAL COSTS, 2009, 2012, 2015, AND 2020
[$million; 2003$]
Change in
consumer
surplus
Market
Change in
producer
surplus
Total
2009
¥$28.5
(54.6%)
¥$6.7
¥$20.6
¥$0.9
¥$0.3
¥$57.5
(99.3%)
¥$8.9
¥$48.7
¥$23.8
(45.4%)
¥$5.6
¥$17.2
¥$0.7
¥$0.3
¥$0.4
(0.7%)
¥$0.1
¥$0.3
¥$52.3
........................
¥$12.2
¥$37.8
¥$1.6
¥$0.6
¥$57.9
........................
¥$8.9
¥$49.0
Subtotal .........................................................................................................................
¥$86.1
(78.1%)
¥$24.1
(22%)
¥$110.2
........................
Fuel Savings ................................................................................................................................
Vehicle Program ..........................................................................................................................
........................
........................
........................
........................
$11.3
$0
Total ...............................................................................................................................
........................
........................
¥$98.9
¥$110.7
(54.5%)
¥$24.8
¥$73.2
¥$5.9
¥$6.8
¥$61.1
(99.3%)
¥$9.4
¥$51.7
¥$92.3
(45.5%)
¥$20.7
¥$61.0
¥$4.9
¥$4.7
¥$0.4
(0.7%)
¥$0.1
¥$0.4
¥$203.0
........................
¥$45.5
¥$134.2
¥$10.9
¥$12.4
¥$61.5
........................
¥$9.5
¥$52.1
Subtotal .........................................................................................................................
¥$171.8
(65.0%)
¥$92.7
(35.0%)
¥$264.5
........................
Fuel Savings ................................................................................................................................
Vehicle Program ..........................................................................................................................
Total ...............................................................................................................................
........................
........................
........................
........................
........................
........................
$48.5
¥$12.5
¥$228.5
¥$207.0
(54.5%)
¥$66.3
¥$75.9
¥$172.5
(45.5%)
¥$55.3
¥$63.2
¥$379.4
........................
¥$121.6
¥$139.1
Gasoline U.S. ...............................................................................................................................
PADD 1 & 3 ..........................................................................................................................
PADD 2 .................................................................................................................................
PADD 4 .................................................................................................................................
PADD 5 (w/out CA) ..............................................................................................................
Portable Fuel Containers U.S. .....................................................................................................
States with existing programs ..............................................................................................
States without existing programs .........................................................................................
2012
Gasoline U.S. ...............................................................................................................................
PADD 1 & 3 ..........................................................................................................................
PADD 2 .................................................................................................................................
PADD 4 .................................................................................................................................
PADD 5 (w/out CA) ..............................................................................................................
Portable Fuel Containers U.S. .....................................................................................................
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States with existing programs ..............................................................................................
States without existing programs .........................................................................................
2015
Gasoline U.S. ...............................................................................................................................
PADD 1 & 3 ..........................................................................................................................
PADD 2 .................................................................................................................................
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
TABLE VIII.F–3.—SUMMARY OF ESTIMATED SOCIAL COSTS, 2009, 2012, 2015, AND 2020—Continued
[$million; 2003$]
Change in
consumer
surplus
Market
Change in
producer
surplus
Total
¥$14.5
¥$50.3
¥$33.7
(99.3%)
¥$2.7
¥$31.0
¥$12.1
¥$41.9
¥$0.2
(0.7%)
$0.0
¥$0.2
¥$26.6
¥$92.2
¥$34.0
........................
¥$2.7
¥$31.3
Subtotal .........................................................................................................................
¥$240.7
(58.2%)
¥$172.7
(41.8%)
¥$413.4
........................
Fuel Savings ................................................................................................................................
Vehicle Program ..........................................................................................................................
Total ...............................................................................................................................
........................
........................
........................
........................
........................
........................
$75.5
¥$12.9
¥$350.7
¥$219.6
(54.5%)
¥$70.4
¥$80.5
¥$15.4
¥$53.4
¥$37.2
(99.3%)
¥$3.0
¥$34.3
¥$183.0
(45.5%)
¥$58.6
¥$67.1
¥$12.8
¥$44.5
¥$0.2
(0.7%)
$0.0
¥$0.2
¥$402.6
........................
¥$129.0
¥$147.6
¥$28.2
¥$97.8
¥$37.5
........................
¥$3.0
¥$34.5
Subtotal .........................................................................................................................
¥$256.8
(58.4%)
¥$183.3
(41.6%)
¥$440.1
........................
Fuel Savings ................................................................................................................................
Vehicle Program ..........................................................................................................................
........................
........................
........................
........................
$80.7
¥$0
Total ...............................................................................................................................
........................
........................
¥$359.4
PADD 4 .................................................................................................................................
PADD 5 (w/out CA) ..............................................................................................................
Portable Fuel Containers U.S. .....................................................................................................
States with existing programs ..............................................................................................
States without existing programs .........................................................................................
2020
Gasoline U.S. ...............................................................................................................................
PADD 1 & 3 ..........................................................................................................................
PADD 2 .................................................................................................................................
PADD 4 .................................................................................................................................
PADD 5 (w/out CA) ..............................................................................................................
Portable Fuel Containers U.S. .....................................................................................................
States with existing programs ..............................................................................................
States without existing programs .........................................................................................
The present value of net social costs
(discounted back to 2006) of the
standards through 2035, contained in
Table VIII.F–2, is estimated to be about
$5.4 billion (2003$). This present value
is calculated using a social discount rate
of three percent and the stream of
economic welfare costs through 2035.
We also performed an analysis using a
seven percent social discount rate.247
Using that discount rate, the present
value of the net social costs through
2035 is estimated to be about $2.9
billion (2003$).
TABLE VIII.F–4.—NET PRESENT OF ESTIMATED SOCIAL COSTS 2007 THROUGH 2035, DISCOUNTED TO 2006
[$million; 2003$]
Change in
consumer surplus
Market
Gasoline, U.S. ..............................................................................................................................
PADD
PADD
PADD
PADD
1
2
4
5
& 3 ..........................................................................................................................
.................................................................................................................................
.................................................................................................................................
(w/out CA) ..............................................................................................................
Portable Fuel Containers US .......................................................................................................
pwalker on PROD1PC71 with RULES_2
States with existing programs ..............................................................................................
States without existing programs .........................................................................................
247 EPA presents the present value of cost and
benefits estimates using both a three percent and a
seven percent social discount rate. According to
OMB Circular A–4, ‘‘the 3 percent discount rate
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represents the ‘social rate of time preference’ * * *
[which] means the rate at which ‘society’ discounts
future consumption flows to their present value’’;
‘‘the seven percent rate is an estimate of the average
PO 00000
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Sfmt 4700
Change in producer surplus
¥$3,115.4
(54.5%)
¥$959.7
¥$1,260.4
¥$210.8
¥$229.5
¥$684.5
¥$754.9
(99.3%)
¥$78.7
¥$676.2
¥$2,596.2
(45.5%)
¥$799.8
¥$1,050.4
¥$175.6
¥$570.4
........................
¥$5.0
(0.7%)
¥$0.5
¥$4.5
Total
¥$5,711.6
¥$1,759.5
¥$2,310.8
¥$386.4
¥$1,254.8
........................
¥$759.9
¥$79.3
¥$680.7
before-tax rate of return to private capital in the
U.S. economy * * * [that] approximates the
opportunity cost of capital.’’
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8525
TABLE VIII.F–4.—NET PRESENT OF ESTIMATED SOCIAL COSTS 2007 THROUGH 2035, DISCOUNTED TO 2006—Continued
[$million; 2003$]
Change in
consumer surplus
Change in producer surplus
Subtotal .........................................................................................................................
¥$3870.3
59.8%
¥$2,601.2
40.2%
¥$6,471.6
Fuel Savings ................................................................................................................................
Vehicle Program ..........................................................................................................................
$1,208.0
........................
........................
¥$91.1
$1,208.0
¥$91.1
Total ......................................................................................................................................
¥$2,662.3
¥$2,692.3
¥$5,354.6
Market
Table VIII.F–4 shows the distribution
of total surplus losses for the cumulative
net social costs of the rule. This analysis
includes the estimated social costs from
2007 through 2035, discounted to 2006
at a 3 percent discount rate. These
results suggest that consumers will bear
about 60 percent of the total social costs
associated with the PFC and gasoline
fuel programs for that period. The
consumer share of the NPV social costs
is about $3,870 million, or about 60
percent of the total. Of that loss of
consumer surplus, about $3,115 million
(about 80 percent) is from the gasoline
fuel program. When the total costs of the
program are taken into account,
including the fuel savings and the
vehicle program costs, the loss of
consumer surplus decreases to about
$2,662.3 million (about 50 percent of
the social costs of the program).
pwalker on PROD1PC71 with RULES_2
IX. Public Participation
Many interested parties participated
in the rulemaking process that
culminates with this final rule. This
process provided opportunity for
submitting written public comments
following the proposal that we
published on March 29, 2006 (71 FR
15804). We considered these comments
in developing the final rule. In addition,
we held a public hearing on the
proposed rulemaking on April 12, 2006,
and we have considered comments
presented at the hearing.
Throughout the rulemaking process,
EPA met with stakeholders including
representatives from the fuel refining
and distribution industry, automobile
industry, emission control
manufacturing industry, gas can
industry, environmental organizations,
states, interests, and others.
We have prepared a detailed
Summary and Analysis of Comments
document, which describes comments
we received on the proposal and our
response to each of these comments.
The Summary and Analysis of
Comments is available in the docket for
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18:54 Feb 23, 2007
Jkt 211001
this rule at the internet address listed
under ADDRESSES, as well as on the
Office of Transportation and Air Quality
Web site (https://www.epa.gov/otaq/
toxics.htm#mobile). In addition,
comments and responses for key issues
are included throughout this preamble.
X. Statutory and Executive Order
Reviews
A. Executive Order 12866: Regulatory
Planning and Review
Under section 3(f)(1) of Executive
Order (EO) 12866 (58 FR 51735, October
4, 1993), this action is an ‘‘economically
significant regulatory action’’ because it
is likely to ‘‘have an annual effect on the
economy of $100 million or more’’ and
‘‘raise novel legal and policy issues.’’
Accordingly, EPA submitted this action
to the Office of Management and Budget
(OMB) for review under EO 12866, and
any changes made in response to OMB
recommendations have been
documented in the docket for this
action.
A final Regulatory Impact Analysis
has been prepared and is available in
the docket for this rulemaking and at the
docket internet address listed under
ADDRESSES.
B. Paperwork Reduction Act
The information collection
requirements in this rule have been
submitted for approval to the Office of
Management and Budget (OMB) under
the Paperwork Reduction Act, 44 U.S.C.
3501 et seq. The information collection
requirements are not enforceable until
OMB approves them.
The Agency will collect information
to ensure compliance with the
provisions in this rule. This includes a
variety of requirements, both for vehicle
manufacturers, fuel producers, and
portable fuel container manufacturers.
Information-collection requirements
related to vehicle manufacturers are in
EPA ICR #0783.52 (OMB Control
Number 2060–0104); requirements
related to fuel producers are in EPA ICR
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Sfmt 4700
Total
#1591.22 (OMB Control Number 2060–
0277); requirements related to portable
fuel container manufacturers are in EPA
ICR #2213.02. For vehicle and fuel
standards, section 208(a) of the Clean
Air Act requires that manufacturers
provide information the Administrator
may reasonably require to determine
compliance with the regulations;
submission of the information is
therefore mandatory. We will consider
confidential all information meeting the
requirements of section 208(c) of the
Clean Air Act. For portable fuel
container standards, recordkeeping and
reporting requirements for
manufacturers would be pursuant to the
authority of sections 183(e) and 111 of
the Clean Air Act.
As shown in Table X.B–1, the total
annual burden associated with this rule
is about 28,000 hours and $1,993,723,
based on a projection of 521
respondents. The estimated burden for
vehicle manufacturers and fuel
producers is a total estimate for both
new and existing reporting
requirements. The portable fuel
container requirements represent our
first regulation of these containers, so
those burden estimates reflect only new
reporting requirements. Burden means
the total time, effort, or financial
resources expended by persons to
generate, maintain, retain, or disclose or
provide information to or for a Federal
agency. This includes the time needed
to review instructions; develop, acquire,
install, and utilize technology and
systems for the purposes of collecting,
validating, and verifying information,
processing and maintaining
information, and disclosing and
providing information; adjust the
existing ways to comply with any
previously applicable instructions and
requirements; train personnel to be able
to respond to a collection of
information; search data sources;
complete and review the collection of
information; and transmit or otherwise
disclose the information.
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
TABLE X.B–1.—ESTIMATED BURDEN FOR REPORTING AND RECORDKEEPING REQUIREMENTS
Number of
respondents
Industry sector
Annual burden
hours
Annual costs
Vehicles .......................................................................................................................................
Fuels ............................................................................................................................................
Portable fuel containers ...............................................................................................................
35
476
10
770
26,592
638
$80,900
*1,888,032
24,791
Total ......................................................................................................................................
521
28,000
1,993,723
*Does not include non-postage purchased services of approximately $1,988,000.
An agency may not conduct or
sponsor, and a person is not required to
respond to, a collection of information
unless it displays a currently valid OMB
control number. The OMB control
numbers for EPA’s regulations are listed
in 40 CFR part 9 and 48 CFR chapter 15.
When this ICR is approved by OMB,
the Agency will publish a technical
amendment to 40 CFR part 9 and 48
CFR chapter 15 in the Federal Register
to display the OMB control number for
the approved information collection
requirements contained in this final
rule. EPA received various comments on
the rulemaking provisions covered by
the ICRs, but no comments on the
paperwork burden or other information
in the ICRs. All comments that were
submitted to EPA are considered in the
relevant Summary and Analysis of
Comments, which can be found in the
docket.
C. Regulatory Flexibility Act (RFA), as
Amended by the Small Business
Regulatory Enforcement Fairness Act of
1996 (SBREFA), 5 U.S.C. 601 et seq.
1. Overview
The Regulatory Flexibility Act (RFA)
generally requires an agency to prepare
a regulatory flexibility analysis of any
rule subject to notice and comment
rulemaking requirements under the
Administrative Procedure Act or any
other statute unless the agency certifies
that the rule will not have a significant
economic impact on a substantial
number of small entities. Small entities
include small businesses, small
organizations, and small governmental
jurisdictions.
For purposes of assessing the impacts
of today’s rule on small entities, small
entity is defined as: (1) A small business
as defined by the Small Business
Administration’s (SBA) regulations at 13
CFR 121.201 (see table below); (2) a
small governmental jurisdiction that is a
government of a city, county, town,
school district or special district with a
population of less than 50,000; and (3)
a small organization that is any not-forprofit enterprise which is independently
owned and operated and is not
dominant in its field. The following
table provides an overview of the
primary SBA small business categories
potentially affected by this regulation:
Industry
Defined as small entity by SBA if less
than or equal to:
Light-duty vehicles:
—vehicle manufacturers (including small volume manufacturers) .......................
—independent commercial importers ...................................................................
1,000 employees ......................................
$6 million annual sales .............................
—alternative fuel vehicle converters .....................................................................
Gasoline fuel refiners ...................................................................................................
Portable fuel container manufacturers:
—plastic container manufacturers ........................................................................
—metal gas can manufacturers ............................................................................
NAICS
Codes a
100 employees .........................................
1,000 employees ......................................
$6 million annual sales .............................
1500 employees b .....................................
336111
811111
811112
811198
424720
335312
811198
324110
500 employees .........................................
1,000 employees ......................................
326199
332431
pwalker on PROD1PC71 with RULES_2
Notes:
a North American Industrial Classification System
b EPA has included in past fuels rulemakings a provision that, in order to qualify for EPA’s small refiner flexibilities, a refiner must also produce
no greater than 155,000 bpcd crude capacity.
Pursuant to section 603 of the RFA,
EPA prepared an initial regulatory
flexibility analysis (IRFA) for the
proposed rule and convened a Small
Business Advocacy Review Panel
(SBAR Panel, or the ‘Panel’) to obtain
advice and recommendations of
representatives of the regulated small
entities. A detailed discussion of the
Panel’s advice and recommendations is
found in the Panel Report (see Docket
EPA–HQ–OAR–2005–0036). A summary
of the Panel’s recommendations is
presented at 71 FR 15922 (March 29,
2006).
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As required by section 604 of the
RFA, we also prepared a final regulatory
flexibility analysis (FRFA) for today’s
final rule. The FRFA addresses the
issues raised by public comments on the
IRFA, which was part of the proposal of
this rule. The FRFA is available for
review in Chapter 14 of the RIA and is
summarized below.
Key elements of our FRFA include:
• A description of the reasons the
Agency is considering this action, and
the need for, and objectives of, the rule;
• A summary of the significant issues
raised by the public comments on the
IRFA, a summary of the Agency’s
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assessment of those issues, and any
changes made to the proposed rule as a
result of those comments;
• A description of the types and
number of small entities to which the
rule will apply;
• A description of the reporting,
recordkeeping, and other compliance
requirements of the rule;
• An identification, to the extent
practicable, of all relevant Federal rules
that may duplicate, overlap, or conflict
with the rule; and
• A description of the steps taken to
minimize the significant economic
impact on small entities consistent with
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the stated objectives of the applicable
statutes.
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2. The Need for and Objectives of This
Rule
Mobile sources emit air toxics that
can cause cancer and other serious
health effects (Section III of this
preamble and Chapter 1 of the
Regulatory Impact Analysis for this rule
describe these compounds and their
health effects). Mobile sources
contribute significantly to the
nationwide risk from breathing outdoor
sources of air toxics. In this action we
are finalizing: Standards to limit the
exhaust hydrocarbons from passenger
vehicles during cold temperature
operation; evaporative hydrocarbon
emissions standards for passenger
vehicles; limiting the average annual
benzene content of gasoline; and
hydrocarbon emissions standards for gas
cans that would reduce evaporation,
permeation, and spillage from these
containers. (Detailed discussions of each
of these programs are in sections V, VI,
and VII of the preamble and Chapters 5,
6, and 7 of the RIA). Standards for
vehicles and gasoline benzene control
are being pursued under section
202(l)(2) of the Clean Air Act (CAA),
which directs EPA to establish
requirements to control emissions of
mobile source air toxics from new motor
vehicles and fuels. Controls for gas cans
are being pursued under CAA section
183(e), the provisions applying to
consumer and commercial products.
3. Summary of the Significant Issues
Raised by the Public Comments
We did not receive comments on the
proposed flexibilities and hardships for
small volume vehicle manufacturers or
gas can manufacturers. We received
comments from small refiners
supporting the inclusion of flexibility
provisions and hardships for small
gasoline refiners. These comments
generally supported additional leadtime, credit generation provisions (early
credit generation and extra credit life for
credits generated by or transferred to
small refiners), and a review of the
credit program.
Small refiners also indicated that they
could incur significant economic impact
in complying with the 1.3 vol% refinery
maximum average benzene standard.
Our economic analysis indicates that
most small refiners will be able to
comply with this standard without
incurring significant adverse economic
impact. We also believe that allowing
additional lead time (until July 1, 2016)
to meet this standard ameliorates
potential economic impact. In addition,
we believe that any other refiners that
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still demonstrate instances of severe
economic impact can be accommodated
through the hardship relief provision set
out in the regulations at § 80.1335. This
issue is discussed in more detail in
section VI.A.3, in chapter 14 of the final
RIA, and in individual comment
responses.
We also received comments regarding
the fact that two recent statutes use
definitions that are not the same as the
small refiner criteria that we proposed.
The commenters generally stated that
EPA should use one of the definitions
from those statutes. However, we do not
believe that it would be appropriate to
change the small refiner employee count
or crude capacity limit criteria to fit
either of those programs’ definitions;
rather, we believe that it is prudent to
continue using criteria similar to our
current and previous fuel programs.
(Please see section VI.A.3.a.i above for
a more detailed discussion of this
comment and our response.)
4. Summary of Regulated Small Entities
The following section discusses the
small entities directly regulated by this
action.
a. Highway Light-Duty Vehicles
In addition to the major vehicle
manufacturers, three distinct categories
of businesses relating to highway lightduty vehicles will be covered by the
new vehicle standards: small volume
manufacturers (SVMs), independent
commercial importers (ICIs), and
alternative fuel vehicle converters.
SVMs are companies that sell less than
15,000 vehicles per year, as defined in
past EPA regulations, and this status
allows vehicle models to be certified
under a slightly simpler certification
process. Independent commercial
importers are companies that hold a
Certificate (or certificates) of Conformity
permitting them to alter imported
vehicles to meet U.S. emission
standards. Alternative fuel vehicle
converters are businesses that convert
gasoline or diesel vehicles to operate on
alternative fuel, and converters must
seek a certificate for all of their vehicle
models. From an assessment performed
for our SBREFA Panel process, we
continue to believe that there are about
14 SVMs, 10 alternative fuel vehicle
converters, and 10 ICIs. Of these, EPA
believes 5 SVMs, 6 converters, and all
10 ICIs would meet the small-entity
criteria as defined by SBA (no major
vehicle manufacturers meet the smallentity criteria). It is believed that these
small entities comprise about 0.02
percent of the total light-duty vehicle
sales in the U.S. for the year 2004.
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b. Gasoline Refiners
EPA’s current assessment is that 14
refiners (owning 16 refineries) meet
SBA’s criterion of having 1,500
employees or less and our criterion of
having a crude capacity of less than or
equal to 155,000 bpcd. It should be
noted that because of the dynamics in
the refining industry (i.e., mergers and
acquisitions) and decisions by some
refiners to enter or leave the gasoline
market, the actual number of refiners
that ultimately qualify for small refiner
status under an MSAT program could be
different than these estimates. Current
data further indicates that these refiners
produce about 2.5 percent of the total
gasoline pool.
c. Portable Fuel Container
Manufacturers
EPA conducted an industry profile to
identify the manufacturers of portable
fuel containers—98 percent are plastic
containers and 2 percent are metal gas
cans. Using this industry profile, EPA
identified 9 domestic manufacturers and
1 foreign manufacturer. Of these 9 U.S.
manufacturers, 8 meet the SBA
definition of a small entity. One small
business accounted for over 50 percent
of the U.S. sales in 2002, and the other
small entities comprised about 10
percent of U.S. sales.
5. Description of the Reporting,
Recordkeeping, and Other Compliance
Requirements of the Rule
For highway light-duty vehicles, the
reporting, recordkeeping, and
compliance requirements prescribed for
this category in 40 CFR 86 will be
continued. Key among these
requirements are certification
requirements and provisions related to
reporting of production, emissions
information, flexibility use, etc.
For any fuel control program, EPA
must have assurance that fuel produced
by refiners meets the applicable
standard, and that the fuel continues to
meet the standard as it passes
downstream through the distribution
system to the ultimate end user. As
stated in section VI above, the
recordkeeping, reporting and
compliance provisions of the MSAT
program will be consistent with those
currently in place for existing fuel
programs. These provisions include:
The submission of refinery precompliance reports (similar to those
required under the highway and
nonroad diesel fuel programs), the
submission of refinery batch reports,
small refiner status and small refiner
baseline applications, and retention of
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all records for this program for five
years.
For portable fuel containers,
requirements similar to those in the
California program (such as submitting
emissions testing information, reporting
of certification families, and use of
transition provisions) were proposed
and are being finalized today.
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6. Relevant Federal Rules
We are aware of a few other current
or proposed Federal rules that are
related to this rule. The primary related
federal rules are the first MSAT rule (66
FR 17230, March 29, 2001), the Tier 2
Vehicle/Gasoline Sulfur rulemaking (65
FR 6698, February 10, 2000), the fuel
sulfur rules for highway diesel (66 FR
5002, January 18, 2001) and nonroad
diesel (69 FR 38958, June 29, 2004), the
Reformulated Gasoline and Antidumping rule (59 FR 7813 and 59 FR
7860, February 16, 1994), and the Cold
Temperature Carbon Monoxide
Rulemaking (57 FR 31888, July 17,
1992).
In addition, the Evaporative
Emissions Streamlining Direct Final
Rulemaking was issued on December 8,
2005 (70 FR 72917). For portable fuel
containers, the Occupational Safety and
Health Administration (OSHA) has
safety regulations for containers used in
workplace settings. Containers that meet
OSHA’s requirements, commonly called
safety cans, are exempt from the
California program, and we are thus
exempting them from the EPA program.
Section 1501 of the Energy Policy Act
of 2005 requires the Agency to
implement a Renewable Fuels Standard
(RFS) program. Beginning in 2006, this
program will require increasing volumes
of renewable fuel to be used in gasoline,
until a total of 7.5 billion gallons is
required in 2012. The most prevalent
renewable fuel is expected to be
ethanol. There are a wide variety of
potential impacts of ethanol blending on
MSAT emissions that will be evaluated
as part of the RFS rulemaking process.
In general, as ethanol use increases,
other sources of octane in gasoline can
decrease. Depending on these changes,
the impact on benzene emissions will
vary. The specific effects of ethanol on
benzene are addressed in the Regulatory
Impact Analysis (RIA) to this rule and
in other fuels rulemakings, such as the
RFS rule (71 FR 55552, September 22,
2006).
7. Steps Taken To Minimize the
Significant Economic Impact on Small
Entities
a. Significant Panel Findings
The SBAR Panel considered many
regulatory options and flexibilities that
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would help mitigate potential adverse
effects on small businesses as a result of
this rule. During the SBREFA Panel
process, the Panel sought out and
received comments on the regulatory
options and flexibilities that were
presented to Small Entity
Representatives (SERs) and Panel
members. The major flexibilities and
hardship relief provisions that were
recommended by the Panel were
proposed and are generally being
finalized today (for more information
regarding the Panel process, see Section
9 of the SBREFA Final Panel Report,
which is available in the public docket
for this rule).
b. Outreach With Small Entities (and the
Panel Process)
As required by section 609(b) of the
RFA as amended by SBREFA, EPA
conducted outreach to small entities
and convened a SBAR Panel prior to
proposing the MSAT rule to obtain
advice and recommendations of
representatives of the small entities that
potentially would be subject to the
rule’s requirements.
As part of the SBAR Panel process, we
conducted outreach with
representatives from the various small
entities that would be affected by the
rule. We met with these SERs to discuss
the potential rulemaking approaches
and potential options to decrease the
impact of the rulemaking on their
industries. The Panel received written
comments from the SERs, specifically
on regulatory alternatives that could
help to minimize the rule’s impact on
small businesses.
In general, SERs representing the
portable fuel container industry raised
concerns on how the MSAT rule’s
requirements would be coordinated
with the California program and other
requirements, and that there should be
adequate opportunity for sell through at
the start of the program. The small
volume manufacturer, ICI, and vehicle
converter SERs that participated had
questions about the form of the new
standards for light-duty vehicles,
specifically testing and certification
requirements. The gasoline refiner SERs
generally stated that they believed that
small refiners would face challenges in
meeting a new standard. More
specifically, they raised the concern that
the rule could be very costly and
dependence on credits may not be a
comfortable situation; they were also
concerned about the timing of the
standards for this rule, given other
upcoming fuel standards.
The Panel agreed that EPA should
consider the issues raised by the SERs
(and discussions had by the Panel itself)
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and that EPA should consider
comments on flexibility alternatives that
would help to mitigate any negative
impacts on small businesses.
Alternatives discussed throughout the
Panel process included those offered in
previous or current EPA rulemakings, as
well as alternatives suggested by SERs
and Panel members, and the Panel
recommended that all be considered in
the development of the rule.
A summary of the Panel’s
recommendations, what the Agency
proposed, and what is being finalized
today is discussed below. A detailed
discussion of the regulatory alternatives
and hardship provisions discussed and
recommended by the Panel can be
found in the SBREFA Final Panel
Report. A complete discussion of the
transition and hardship provisions that
are being finalized today can be found
in Sections V, VI, and VII (vehicle, fuels,
and portable fuel container sections) of
this preamble.
c. Small Business Flexibilities
i. Highway Light-Duty Vehicles
(a) Highway Light-Duty Vehicle
Flexibilities
For certification purposes (and for the
sake of simplicity for Panel discussions
regarding flexibility options), SVMs
include ICIs and alternative fuel vehicle
converters since they sell less than
15,000 vehicles per year. Similar to the
flexibility provisions implemented in
the Tier 2 rule, the Panel recommended
that we allow SVMs (includes all
vehicle small entities that would be
affected by this rule, which are the
majority of SVMs) the following
flexibility options for meeting cold
temperature NMHC standards and
evaporative emission standards:
Cold NMHC Standards—The Panel
recommended that SVMs simply
comply with the standards with 100
percent of their vehicles during the last
year of the four-year phase-in period.
For example, if the standard for lightduty vehicles and light light-duty trucks
(0 to 6,000 pounds GVWR) were to
begin in 2010 and end in 2013 (25%,
50%, 75%, 100% phase-in over four
years), the SVM provision would be 100
percent in 2013. If the standard for
heavy light-duty trucks and mediumduty passenger vehicles (greater than
6,000 pounds GVWR) were to start in
2012 (25%, 50%, 75%, 100% phase-in
over four years), the SVM provision
would be 100 percent in 2015.
Evaporative Emission Standards—
The Panel recommended that since the
evaporative emissions standards will
not have phase-in years, we allow SVMs
to simply comply with standards during
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the third year of the program (we have
implemented similar provisions in past
rulemakings). For a 2009 start date for
light-duty vehicles and light light-duty
trucks, SVMs would need to meet the
evaporative emission standards in 2011.
For a 2010 implementation date for
heavy light-duty trucks and mediumduty passenger vehicles, SVMs would
need to comply in 2012.
We proposed the recommendations
given by the Panel for these small
business entities. We agree that SVMs
may need additional lead time
flexibility and the new cold NMHC
standards for LDVs and LLDTs will
begin in model year 2010 and end in
model year 2013, therefore we are
finalizing (as proposed) that the SVM
provision would be 100 percent in
model year 2013. Also, since the new
cold NMHC standard for HLDTs and
MDPVs will begin in 2012, we are
finalizing as proposed that the SVM
provision will be 100 percent in model
year 2015. We believe that the Panel’s
recommendation for flexibilities with
regard to the evaporative emission
standards is reasonable. Therefore, for a
2009 model year start date for LDVs and
LLDTs we proposed, and are finalizing,
that SVMs meet the evaporative
emission standards in model year 2011.
For a model year 2010 implementation
date for HLDTs and MDPVs, we
proposed and are finalizing that SVMs
comply in model year 2012. (Please see
section V.E.1 for a greater discussion on
flexibility provisions for small volume
manufacturers.)
(b) Highway Light-Duty Vehicle
Hardships
In addition, the Panel recommended
that hardship flexibility provisions be
extended to SVMs for the cold
temperature VOC and evaporative
emission standards. The provisions that
the Panel recommended are:
SVMs would be allowed to apply
(EPA would need to review and approve
application) for up to an additional 2
years to meet the 100 percent phase-in
requirements for cold VOC and the
delayed requirement for evaporative
emissions. Appeals for such hardship
relief must be made in writing, must be
submitted before the earliest date of
noncompliance, must include evidence
that the noncompliance will occur
despite the manufacturer’s best efforts to
comply, and must include evidence that
severe economic hardship will be faced
by the company if the relief is not
granted.
We proposed the Panel-recommended
flexibility and hardship provisions
described above, and we are finalizing
these provisions in this action. (Please
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see section V.E.2 for a greater discussion
on the hardship provisions for small
volume manufacturers.)
(c) Special Provisions for Independent
Commercial Importers (ICIs)
Although the SBAR panel did not
specifically recommend it, we proposed,
and are finalizing, that ICIs may
participate in the averaging, banking,
and trading (ABT) program for cold
temperature NMHC fleet average
standards, but with appropriate
constraints to ensure that fleet averages
will be met. The existing regulations for
ICIs specifically prohibit ICIs from
participating in emission-related
averaging, banking, and trading
programs unless specific exceptions are
provided. However, an exception for
ICIs to participate in an averaging,
banking, and trading program was made
for the Tier 2 NOX fleet average
standards, and today we are finalizing
as proposed to apply a similar exception
for the cold temperature NMHC fleet
average standards. We also proposed,
and are finalizing, that ICIs not be
allowed to utilize the deficit carryforward provisions of the ABT program.
(Please see section V.E.3 for a greater
discussion on the hardship provisions
for small volume manufacturers.)
ii. Gasoline Refiners
(a) Gasoline Refiner Flexibilities
The Panel recommended that EPA
propose certain provisions to encourage
early compliance with lower benzene
standards. The Panel recommended that
EPA propose that small refiners be
afforded the following flexibility
options to help mitigate the impacts on
small refiners:
Delay in Standards—The Panel
recommended that a four-year delay
period be proposed for small refiners (in
order to allow for a review of the ABT
program, as discussed below, to occur
one year after implementation but still
roughly three years prior to the small
refiner compliance deadline). It was
noted by the small refiners that three
years are generally needed for small
refiners to obtain financing and perform
engineering and construction. The Panel
was also in support of allowing for
refinery expansion within the delay
option, and recommended that refinery
expansion be provided for in the rule.
Early ABT Credits—The Panel
recommended that small refiners be
eligible to generate early credits if they
take some steps to meet the 0.62 vol%
benzene requirement prior to the
effective date of the standard.
Depending on the start date of the
program, and coupled with the four-year
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delay option for small refiners, a small
refiner could have a total credit
generation period of five to seven years.
The Panel was also in support of
allowing refiners (small, as well as nonsmall, refiners) to generate credits for
reductions to their benzene emissions
levels, rather than credits only for
meeting the 0.62 vol% benzene standard
that is set by the rule.
ABT Program Review—The Panel
recommended a review of the credit
trading program and small refiner
flexibility options one year after the
general program starts. The Panel
further recommended that the review
could take into account the number of
early credits generated, as well as the
number of credits generated and sold
during the first year of the program. The
Panel recommended that if the review
were to conclude that changes to either
the program or the small refiner
provisions were necessary, EPA should
also consider some of the suggestions
provided by the small refiners (their
comments are located in Appendix E of
the Final Panel Report), such as:
• The general MSAT program should
require pre-compliance reporting
(similar to EPA’s highway and nonroad
diesel rules);
• Following the review, EPA should
revisit the small refiner provisions if it
is found that the credit trading market
does not exist, or if credits are only
available at a cost that would not allow
small refiners to purchase credits for
compliance;
• The review should offer ways either
to help the credit market, or help small
refiners gain access to credits (e.g., EPA
could ‘create’ credits to introduce to the
market, EPA could impose additional
requirements to encourage trading with
small refiners, etc.).
• In addition, the Panel
recommended that EPA consider in this
rulemaking establishing an additional
hardship provision to assist those small
refiners that cannot comply with the
MSAT with a viable credit market. (This
suggested hardship provision was also
suggested by the small refiners in their
comments, located in Appendix E of the
Final Panel Report). This hardship
provision would address concerns that,
for some small refineries, compliance
may be technically feasible only through
the purchase of credits and it may not
be economically feasible to purchase
those credits. This flexibility would be
provided to a small refiner on a case-bycase basis following the review and
based on a summary, by the refiner, of
technical or financial infeasibility (or
some other type of similar situation that
would render its compliance with the
standard difficult). This hardship
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provision might include further delays
and/or a slightly relaxed standard on an
individual refinery basis for a duration
of two years; in addition, this provision
might allow the refinery to request, and
EPA grant, multiple extensions of the
flexibility until the refinery’s material
situation changes. The Panel also stated
that it understood that EPA may need to
modify or rescind this provision, should
it be implemented, based on the results
of the program review.
We proposed and are finalizing the
recommended four-year period of
additional lead time (until January 1,
2015, four years after the general
program start date) for compliance with
the 0.62 vol% benzene standard. With
respect to the 0.62 vol% standard, we
agreed that a four-year period of
additional lead time for small refiners
would provide these refiners with
roughly three years of lead time
following the review of the credit
program to complete capital projects if
necessary or desirable to meet the 0.62
vol% benzene standard rather than to
rely on credits. Further, we are
finalizing an additional 18 months of
lead time for small refiners to comply
with the 1.3 vol% maximum average
benzene standard (similar to 18-month
lead-time afforded under the general
program), until July 1, 2016. We
likewise believe that this additional
lead-time will provide small refiners
with appropriate additional opportunity
to raise capital and complete projects
necessary to comply with the maximum
average benzene standard.
With regard to credits, we proposed
the Panel’s recommendation that small
refiners that take steps to meet the 0.62
vol% benzene requirement prior to
January 1, 2015 would be eligible to
generate early credits, and that credits
remain available for small refiners for an
additional amount of time. Early credit
generation opportunities will provide
more credits for the MSAT ABT
program and will help to achieve the air
quality goals of the MSAT program
earlier than otherwise required.
Therefore, we are finalizing an early
credit generation provision for small
refiners. Further, we believe that some
incentive to trade credits with small
refiners is warranted to help ensure that
sufficient credits are available.
Therefore, as stated above in section
VI.A.3, we are finalizing the proposed
provision that standard credits that are
traded to, and ultimately used by, small
refiners have an additional credit life of
two years beyond the limit that is
otherwise allowed.
We proposed that we would perform
a review of the ABT program (and thus,
the small refiner flexibility options) by
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2012, one year after the general program
begins. We are finalizing this provision
today. In part to support this review, we
are also requiring that refiners submit
pre-compliance reports. If, following the
review, EPA finds that the credit market
is not adequate to support the small
refiner provisions, we will revisit the
provisions to determine whether or not
they should be altered or whether EPA
can assist the credit market (and small
refiners’ access to credits) to enable a
successful ABT program. We are
finalizing an additional hardship
provision to assist small refiners if it is
found that some small refiners still
cannot comply with the 0.62 vol%
benzene standard even with a viable
credit market. The provision will only
be available following the ABT program
review and will only be afforded to
small refiners on a case-by-case basis,
and is in addition to the general refiner
hardship provisions that are available to
all refiners. Please see section
VI.A.3.a.iii of this preamble for a more
detailed discussion of this hardship
provision.
(b) Gasoline Refiner Hardships
During the Panel process, we stated
that we intended to propose the extreme
unforeseen circumstances hardship and
extreme hardship provisions (for all
gasoline refiners and importers), similar
to those in prior fuels programs. A
hardship based on extreme unforeseen
circumstances is intended to provide
short-term relief due to unanticipated
circumstances beyond the control of the
refiner, such as a natural disaster or a
refinery fire; an extreme hardship is
intended to provide short-term relief
based on extreme circumstances (e.g.,
extreme financial problems, extreme
operational or technical problems, etc.)
that impose extreme hardship and thus
significantly affect a refiner’s ability to
comply with the program requirements
by the applicable dates. The Panel
agreed with the proposal of such
provisions and recommended that we
include them in the MSAT rulemaking;
thus, we proposed these provisions.
We are finalizing the extreme
hardship provision and the extreme
unforeseen circumstances hardship
provision with some modifications, as
this final rule includes a 1.3 vol%
refinery maximum average benzene
standard. As discussed in more detail in
section VI.A.3.b, relief will be granted
on a case-by-case basis; however, it may
differ somewhat depending upon
whether a refiner applies for hardship
relief for the 0.62 vol% benzene
standard or for the 1.3 vol% refinery
maximum average standard (while a
refiner may apply for relief from both
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standards, hardship relief will be
addressed independently for each
standard). This is partly due to the fact
that a refiner may use credits to meet
the 0.62 vol% benzene standard, but
credits cannot be used for compliance
with the 1.3 vol% refinery maximum
average.
Extreme hardship circumstances
could exist based on severe economic or
physical lead time limitations of the
refinery to comply with the required
benzene standards at the start of the
program. For relief from the 0.62 vol%
benzene standard in extreme hardship
circumstances, relief will likely be in
the form of an extension of the one-year
deficit carry-forward allowed by the
rule. Relief from the 1.3 vol% refinery
maximum average benzene standard in
extreme hardship circumstances would
consist of additional time to comply
with the 1.3 vol% refinery maximum
average. Refiners must apply by
January 1, 2008 (or, January 1, 2013 for
approved small refiners) for extreme
hardship relief from the 1.3 vol%
refinery maximum average standard, as
this provision is intended to address
unusual circumstances that should be
apparent now, or well before the
standard takes effect.
The extreme unforeseen
circumstances hardship is available to
both refiners and importers, and is
intended to provide relief in extreme
and unusual circumstances outside a
refiner or importer’s control that could
not have been avoided through the
exercise of due diligence. Hardship
relief for the 0.62 vol% benzene
standard will allow a deficit to be
carried forward for an extended, but
limited, time period (more than the one
year allowed by the rule). Relief from
the 1.3 vol% refinery maximum average
benzene standard based on unforeseen
circumstances will be granted on a caseby-case basis, following an assessment
of the hardship application, and would
generally be in the form of an extension
of time to comply with the standard.
iii. Portable Fuel Containers
(a) Portable Fuel Container Flexibilities
Since nearly all portable fuel
container manufacturers are small
entities and they account for about 60
percent of sales, the Panel planned to
extend the flexibility options to all
portable fuel container manufacturers.
Moreover, implementation of the
program would be much simpler by
doing so. The recommended flexibilities
are the following:
Design Certification—The Panel
recommended that we propose to permit
portable fuel container manufacturers to
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use design certification in lieu of
running any or all of the durability
aging cycles. Manufacturers could
demonstrate the durability of their gas
cans based in part on emissions test data
from designs using the same permeation
barriers and materials. Under a designbased certification program, a
manufacturer would provide evidence
in the application for certification that
their container would meet the
applicable standards based on its design
(e.g., use of a particular permeation
barrier). The manufacturer would
submit adequate engineering and other
information about its individual design
such that EPA could determine that the
emissions performance of their
individual design would not be
negatively impacted by slosh, UV
exposure, and/or pressure cycling
(whichever tests the manufacturer is
proposing to not run prior to emissions
testing).
Broaden Certification Families—This
approach would relax the criteria used
to determine what constitutes a
certification family. It would allow
small businesses to limit their
certification families (and therefore their
certification testing burden), rather than
testing all of the various size containers
in a manufacturer’s product line. Some
small entities may be able to put all of
their various size containers into a
single certification family.
Manufacturers would then certify their
containers using the ‘‘worst case’’
configuration within the family. To be
grouped together, containers would
need to be manufactured using the same
materials and processes even though
they are of different sizes.
Additional Lead-time—Since it may
take additional time for the portable fuel
container SERs to gather information to
fully evaluate whether or not additional
lead-time is needed beyond the 2009
start date, the Panel recommended that
we discuss lead-time in the proposal
and request comments on the need for
additional lead-time to allow
manufacturers to ramp up to a
nationwide program.
Product Sell-through—As with past
rulemakings for other source sectors, the
Panel recommended that EPA propose
to allow normal sell through of portable
fuel containers as long as manufacturers
do not create stockpiles of
noncomplying portable fuel containers
prior to the start of the program.
We proposed these Panelrecommended flexibilities for all
portable fuel container manufacturers.
As stated above, we did not receive any
comments on the proposed flexibilities,
and are therefore finalizing them as
proposed (the flexibility provisions are
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incorporated into the program
requirements described earlier in
sections VII.B through VII.D).
(b) Portable Fuel Container Hardships
The Panel recommended that EPA
propose two types of hardship programs
for small portable fuel container
manufacturers.
The first would allow small
manufacturers to petition EPA for
limited additional lead-time to comply
with the standards. A manufacturer
would have to demonstrate that it has
taken all possible business, technical,
and economic steps to comply, but the
burden of compliance costs would have
a significant adverse effect on the
company’s solvency. Hardship relief
may include requirements for interim
emission reductions.
The second hardship provision would
permit small manufacturers to apply for
hardship relief if circumstances outside
their control cause the failure to comply
(i.e., supply contract broken by parts
supplier) and if failure to sell the subject
containers would have a major impact
on the company’s solvency. The terms
and timeframe of the relief would
depend on the specific circumstances of
the company and the situation involved.
We proposed, and are finalizing, the
above hardship provisions for portable
fuel container manufacturers. These
entities could, on a case-by-case basis,
face hardship, and we are finalizing
these provisions to provide what could
prove to be needed safety valves for
these entities. For both types of
hardship provisions, the length of the
hardship relief will be established,
during the initial review, for not more
than one year and will be reviewed
annually thereafter as needed. (Please
see section VII.F for a more detailed
discussion of these hardship
provisions.)
As required by section 212 of
SBREFA, EPA also is preparing a Small
Entity Compliance Guide to help small
entities comply with this rule. The
compliance guide will be available on
the Web at: https://www.epa.gov/otaq/
toxics.htm.
D. Unfunded Mandates Reform Act
Title II of the Unfunded Mandates
Reform Act of 1995 (UMRA), Public
Law 104–4, establishes requirements for
Federal agencies to assess the effects of
their regulatory actions on State, local,
and tribal governments and the private
sector. Under section 202 of the UMRA,
EPA generally must prepare a written
statement, including a cost-benefit
analysis, for proposed and final rules
with ‘‘Federal mandates’’ that may
result in expenditures to State, local,
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8531
and tribal governments, in the aggregate,
or to the private sector, of $100 million
or more in any one year. Before
promulgating an EPA rule for which a
written statement is needed, section 205
of the UMRA generally requires EPA to
identify and consider a reasonable
number of regulatory alternatives and
adopt the least costly, most costeffective, or least burdensome
alternative that achieves the objectives
of the rule. The provisions of section
205 do not apply when they are
inconsistent with applicable law.
Moreover, section 205 allows EPA to
adopt an alternative other than the least
costly, most cost-effective, or least
burdensome alternative if the
Administrator publishes with the final
rule an explanation of why that
alternative was not adopted.
Before EPA establishes any regulatory
requirements that may significantly or
uniquely affect small governments,
including tribal governments, it must
have developed under section 203 of the
UMRA a small government agency plan.
The plan must provide for notifying
potentially affected small governments,
enabling officials of affected small
governments to have meaningful and
timely input in the development of EPA
regulatory proposals with significant
federal intergovernmental mandates,
and informing, educating, and advising
small governments on compliance with
the regulatory requirements.
This rule contains no federal
mandates for state, local, or tribal
governments as defined by the
provisions of Title II of the UMRA. The
rule imposes no enforceable duties on
any of these governmental entities.
Nothing in the rule would significantly
or uniquely affect small governments.
EPA has determined that this rule
contains federal mandates that may
result in expenditures of more than
$100 million to the private sector in any
single year. EPA believes that the final
rule represents the least costly, most
cost-effective approach to achieve the
statutory requirements of the rule. The
costs and benefits associated with the
final rule are discussed above and in the
Regulatory Impact Analysis, as required
by the UMRA.
E. Executive Order 13132: Federalism
Executive Order 13132, entitled
‘‘Federalism’’ (64 FR 43255, August 10,
1999), requires EPA to develop an
accountable process to ensure
‘‘meaningful and timely input by State
and local officials in the development of
regulatory policies that have federalism
implications.’’ ‘‘Policies that have
federalism implications’’ is defined in
the Executive Order to include
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regulations that have ‘‘substantial direct
effects on the States, on the relationship
between the national government and
the States, or on the distribution of
power and responsibilities among the
various levels of government.’’
This final rule does not have
federalism implications. It will not have
substantial direct effects on the States,
on the relationship between the national
government and the States, or on the
distribution of power and
responsibilities among the various
levels of government, as specified in
Executive Order 13132.
Although section 6 of Executive Order
13132 does not apply to this rule, EPA
did consult with representatives of
various State and local governments in
developing this rule. EPA has also
consulted representatives from
STAPPA/ALAPCO, which represents
state and local air pollution officials.
In the spirit of Executive Order 13132,
and consistent with EPA policy to
promote communications between EPA
and State and local governments, EPA
specifically solicited comment on the
proposed rule from State and local
officials.
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F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
Executive Order 13175, entitled
‘‘Consultation and Coordination with
Indian Tribal Governments’’ (65 FR
67249, November 9, 2000), requires EPA
to develop an accountable process to
ensure ‘‘meaningful and timely input by
tribal officials in the development of
regulatory policies that have tribal
implications.’’
This final rule does not have tribal
implications as specified in Executive
Order 13175. This rule will be
implemented at the Federal level and
impose compliance costs only on
vehicle manufacturers (includes
alternative fuel vehicle converters and
ICIs), fuel producers, and portable
gasoline container manufacturers. Tribal
governments will be affected only to the
extent they purchase and use regulated
vehicles, fuels, and portable gasoline
containers. Thus, Executive Order
13175 does not apply to this rule.
G. Executive Order 13045: Protection of
Children From Environmental Health
and Safety Risks
Executive Order 13045, ‘‘Protection of
Children from Environmental Health
Risks and Safety Risks’’ (62 FR 19885,
April 23, 1997) applies to any rule that
(1) is determined to be ‘‘economically
significant’’ as defined under Executive
Order 12866, and (2) concerns an
environmental health or safety risk that
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EPA has reason to believe may have a
disproportionate effect on children. If
the regulatory action meets both criteria,
section 5–501 of the Order directs the
Agency to evaluate the environmental
health or safety effects of the planned
rule on children, and explain why the
planned regulation is preferable to other
potentially effective and reasonably
feasible alternatives considered by the
Agency.
This final rule is subject to the
Executive Order because it is an
economically significant regulatory
action as defined by Executive Order
12866, and we believe that by
addressing the environmental health or
safety risk this action may have a
disproportionate beneficial effect on
children. Accordingly, we have
evaluated the potential environmental
health or safety effects of VOC and
toxics emissions from gasoline-fueled
mobile sources and gas cans on
children. The results of this evaluation
are described below and contained in
sections III and IV.
Exposure to a number of the
compounds addressed in this rule may
have a disproportionate effect on
children. First, exposure to carcinogens
that cause cancer through a mutagenic
mode of action during childhood
development may have an
incrementally disproportionate impact.
Because of their small size, increased
activity, and increased ventilation rates
compared to adults, children may have
greater exposure to these compounds in
the ambient air, on a unit body weight
basis. Moreover, for PM, because
children’s breathing rates are higher,
their exposures may be higher and
because their respiratory systems are
still developing, children may be more
susceptible to problems from exposure
to respiratory irritants.
H. Executive Order 13211: Actions That
Significantly Affect Energy Supply,
Distribution, or Use
This rule is not a ‘‘significant energy
action’’ as defined in Executive Order
13211, ‘‘Actions Concerning Regulations
That Significantly Affect Energy Supply,
Distribution, or Use’’ (66 FR 28355 (May
22, 2001)) because it is not likely to
have a significant adverse effect on the
supply, distribution, or use of energy.
The gasoline benzene provisions of the
final rule will shift about 12,500 barrels
per day of benzene from the gasoline
market to the petrochemical market.
This volume represents about 0.1
percent of nationwide gasoline
production. The actual impact of the
rule on the gasoline market, however, is
likely to be less due to offsetting
changes in the production of
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petrochemicals, as well as expected
growth in the petrochemical market
absent this rule. The major sources of
benzene for the petrochemical market
other than reformate from gasoline
production are also derived from
gasoline components or gasoline
feedstocks. Consequently, the expected
shift toward more benzene production
from reformate due to this final rule will
be offset by less benzene produced from
other gasoline feedstocks.
The rule will require refiners to use a
small additional amount of energy in
processing gasoline to reduce benzene
levels, primarily due to the increased
energy used for benzene extraction. Our
modeling of increased energy use
indicates that the process energy used
by refiners to produce gasoline would
increase by about 0.6 percent (or, sixtenths of a percent). Overall, we believe
that the final rule will result in no
significant adverse energy impacts.
The gasoline benzene provisions will
not affect the current gasoline
distribution practices.
We discuss our analysis of the energy
and supply effects of the gasoline
benzene standard further in section VIII
of this preamble and in Chapter 9 of the
Regulatory Impact Analysis.
The fuel supply and energy effects
described above will be offset
substantially by the positive effects on
gasoline supply and energy use of the
gas can standards also promulgated in
today’s action. These provisions will
greatly reduce the gasoline lost to
evaporation from gas cans. This will in
turn reduce the demand for gasoline,
increasing the gasoline supply and
reducing the energy used in producing
gasoline.
I. National Technology Transfer
Advancement Act
As noted in the proposed rule,
Section 12(d) of the National
Technology Transfer and Advancement
Act of 1995 (‘‘NTTAA’’), Public Law
104–113, 12(d) (15 U.S.C. 272 note)
directs EPA to use voluntary consensus
standards in its regulatory activities
unless to do so would be inconsistent
with applicable law or otherwise
impractical. Voluntary consensus
standards are technical standards (e.g.,
materials specifications, test methods,
sampling procedures, and business
practices) that are developed or adopted
by voluntary consensus standards
bodies. The NTTAA directs EPA to
provide Congress, through OMB,
explanations when the Agency decides
not to use available and applicable
voluntary consensus standards.
This rulemaking involves technical
standards. Therefore, the Agency
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conducted a search to identify
potentially applicable voluntary
consensus standards. However, we
identified no such standards. Therefore,
for the cold temperature NMHC
standards, EPA will use the existing
EPA cold temperature CO test
procedures (manufacturers currently
measure hydrocarbon emissions with
current cold CO test procedures), which
were adopted in a previous EPA
rulemaking (1992). The fuel standards
referenced in today’s rule involve the
measurement of gasoline fuel
parameters. The measurement standards
for gasoline fuel parameters referenced
in today’s rulemaking are governmentunique standards that were developed
by the Agency through previous
rulemakings. Both the cold temperature
CO test procedures and the
measurement standards for gasoline fuel
parameters have served the Agency’s
emissions control goals well since their
implementation and have been well
accepted by industry. For gas cans, EPA
is promulgating new procedures for
measuring hydrocarbon emissions.
J. Executive Order 12898: Federal
Actions To Address Environmental
Justice in Minority Populations and
Low-Income Populations
Executive Order (EO) 12898 (59 FR
7629 (Feb. 16, 1994)) establishes federal
executive policy on environmental
justice. Its main provision directs
federal agencies, to the greatest extent
practicable and permitted by law, to
make environmental justice part of their
mission by identifying and addressing,
as appropriate, disproportionately high
and adverse human health or
environmental effects of their programs,
policies, and activities on minority
populations and low-income
populations in the United States.
EPA has determined that this final
rule will not have disproportionately
high and adverse human health or
environmental effects on minority or
low-income populations because it does
not affect the level of protection
provided to human health or the
environment.
The final rule will reduce VOC and
toxic emissions from gasoline-fueled
mobile sources (particularly highway
light-duty vehicles) and gas cans, and
thus, it will decrease the amount of air
pollution to which the entire population
is exposed. The rule will also reduce
PM emissions from highway light-duty
vehicles. EPA evaluated the population
residing close to high traffic density
(near roadways), and we found that this
population has demographic differences
from the general population, including
a greater fraction of lower income and
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minority residents. The rule will reduce
emissions from roadways. Since those
living near roadways are more likely to
be lower income and minority residents,
this population will have a
disproportionate benefit from the rule.
Thus, this rule does not have a
disproportionately high adverse human
health or environmental effect on
minority populations.
K. Congressional Review Act
The Congressional Review Act, 5
U.S.C. 801 et seq., as added by the Small
Business Regulatory Enforcement
Fairness Act of 1996, generally provides
that before a rule may take effect, the
agency promulgating the rule must
submit a rule report, which includes a
copy of the rule, to each House of the
Congress and to the Comptroller General
of the United States. EPA will submit a
report containing this rule and other
required information to the U.S. Senate,
the U.S. House of Representatives, and
the Comptroller General of the United
States before the rule is published in the
Federal Register. This rule is a ‘‘major
rule’’ as defined by 5 U.S.C. 804(2).
XI. Statutory Provisions and Legal
Authority
Statutory authority for the fuels
controls in this final rule can be found
in sections 202 and 211(c) of the Clean
Air Act (CAA), as amended, 42 U.S.C.
7521 and 7545(c). Additional support
for the procedural and enforcementrelated aspects of the fuel controls in
this final rule, including the
recordkeeping requirements, come from
sections 114(a) and 301(a) of the CAA,
42 U.S.C. 7414(a) and 7601(a).
Statutory authority for the vehicle
controls in this final rule can be found
in sections 202, 206, 207, 208, and 301
of the CAA, 42 U.S.C. 7521, 7525, 7541,
7542 and 7601.
Statutory authority for the portable
fuel container controls in this final rule
can be found in sections 183(e) and 111
of the CAA, 42 U.S.C. sections 7511b(e)
and 7411.
List of Subjects
40 CFR Part 59
Environmental protection,
Administrative practice and procedure,
Confidential business information,
Incorporation by reference, Labeling,
Consumer or Commercial Products
pollution, Penalties, Reporting and
recordkeeping requirements.
40 CFR Part 80
Environmental protection, Air
pollution control, Fuel additives,
Gasoline, Imports, Incorporation by
reference, Labeling, Motor vehicle
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pollution, Penalties, Reporting and
recordkeeping requirements.
40 CFR Part 85
Environmental protection,
Administrative practice and procedure,
Confidential business information,
Imports, Labeling, Motor vehicle
pollution, Penalties, Reporting and
recordkeeping requirements, Research,
Warranties.
40 CFR Part 86
Environmental protection,
Administrative practice and procedure,
Confidential business information,
Incorporation by reference, Labeling,
Motor vehicle pollution, Penalties,
Reporting and recordkeeping
requirements.
Dated: February 9, 2007.
Stephen L. Johnson,
Administrator.
For the reasons set forth in the
preamble, parts 59, 80, 85 and 86 of title
40 of the Code of Federal Regulations
are amended as follows:
I
PART 59—NATIONAL VOLATILE
ORGANIC COMPOUND EMISSION
STANDARDS FOR CONSUMER AND
COMMERCIAL PRODUCTS
1. The authority citation for part 59 is
revised to read as follows:
I
Authority: 42 U.S.C. 7414 and 7511b(e).
Subpart E—[Added and Reserved]
2a. Add and reserve Subpart E.
2b. A new Subpart F is added to part
59 to read as follows:
I
I
Subpart F—Control of Evaporative
Emissions From New and In-Use Portable
Fuel Containers
Overview and Applicability
Sec.
59.600 Does this subpart apply for my
products?
59.601 Do the requirements of this subpart
apply to me?
59.602 What are the general prohibitions
and requirements of this subpart?
59.603 How must manufacturers apply
good engineering judgment?
59.605 What portable fuel containers are
excluded from this subpart’s
requirements?
59.607 Submission of information.
Emission Standards and Related
Requirements
59.611 What evaporative emission
requirements apply under this subpart?
59.612 What emission-related warranty
requirements apply to me?
59.613 What operation and maintenance
instructions must I give to buyers?
59.615 How must I label and identify the
portable fuel containers I produce?
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Certifying Emission Families
59.621 Who may apply for a certificate of
conformity?
59.622 What are the general requirements
for obtaining a certificate of conformity
and producing portable fuel containers
under it?
59.623 What must I include in my
application?
59.624 How do I amend my application for
certification?
59.625 How do I select emission families?
59.626 What emission testing must I
perform for my application for a
certificate of conformity?
59.627 How do I demonstrate that my
emission family complies with
evaporative emission standards?
59.628 What records must I keep and what
reports must I send to EPA?
59.629 What decisions may EPA make
regarding my certificate of conformity?
59.630 EPA testing.
59.650 General testing provisions.
59.652 Other procedures.
59.653 How do I test portable fuel
containers?
Special Compliance Provisions
59.660 Exemption from the standards.
59.662 What temporary provisions address
hardship due to unusual circumstances?
59.663 What are the provisions for
extending compliance deadlines for
manufacturers under hardship?
59.664 What are the requirements for
importing portable fuel containers into
the United States?
Definitions and Other Reference Information
59.680 What definitions apply to this
subpart?
59.685 What symbols, acronyms, and
abbreviations does this subpart use?
59.695 What provisions apply to
confidential information?
59.697 State actions.
59.698 May EPA enter my facilities for
inspections?
59.699 How do I request a hearing?
Subpart F—Control of Evaporative
Emissions From New and In-Use
Portable Fuel Containers
Overview and Applicability
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§ 59.600 Does this subpart apply for my
products?
(a) Except as provided in § 59.605 and
paragraph (b) of this section, the
regulations in this subpart F apply for
all portable fuel containers (defined in
§ 59.680) that are manufactured on or
after January 1, 2009.
(b) See § 59.602 (a) and (b) to
determine how to apply the provisions
of this subpart for containers that were
manufactured before January 1, 2009.
§ 59.601 Do the requirements of this
subpart apply to me?
(a) Unless specified otherwise in this
subpart, the requirements and
prohibitions of this subpart apply to all
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manufacturers and importers of portable
fuel containers. Certain prohibitions in
§ 59.602 apply to all other persons.
(b) New portable fuel containers that
are subject to the emissions standards of
this part must be covered by a certificate
of conformity that is issued to the
manufacturer of the container. If more
than one person meets the definition of
manufacturer for a portable fuel
container, see § 59.621 to determine if
you are the manufacturer who may
apply for and receive a certificate of
conformity.
(c) Unless specifically noted
otherwise, the term ‘‘you’’ means
manufacturers, as defined in § 59.680.
§ 59.602 What are the general prohibitions
and requirements of this subpart?
(a) General prohibition for
manufacturers and importers. No
manufacturer or importer may sell, offer
for sale, introduce or deliver for
introduction into commerce in the
United States, or import any new
portable fuel container that is subject to
the emissions standards of this subpart
and is manufactured after December 31,
2008 unless it is covered by a valid
certificate of conformity, it is labeled as
required, and it complies with all of the
applicable requirements of this subpart,
including compliance with the
emissions standards for its useful life.
After June 30, 2009, no manufacturer or
importer may sell, offer for sale,
introduce or deliver into commerce in
the United States, or import any new
portable fuel container that was
manufactured prior to January 1, 2009
unless it meets the requirements of this
subpart.
(b) General prohibition for wholesale
distributors. No wholesale distributor
may sell, offer for sale, or distribute any
portable fuel container in the United
States that is subject to the emissions
standards of this subpart and is
manufactured after December 31, 2008
unless it is covered by a valid certificate
of conformity and is labeled as required.
After December 31, 2009, no wholesale
distributor may sell, offer for sale, or
distribute in the United States any
portable fuel container that was
manufactured prior to January 1, 2009
unless it meets the requirements of this
subpart. After December 31, 2009, all
new portable fuel containers shall be
deemed to be manufactured after
December 31, 2008 unless they are in
retail inventory.
(c) Reporting and recordkeeping. (1)
You must keep the records and submit
the reports specified in § 59.628.
Records must be retained for at least 5
years from the date of manufacture or
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importation and must be supplied to
EPA upon request.
(2) No person may alter, destroy, or
falsify any record or report required by
this subpart.
(d) Testing and access to facilities.
You may not keep us from entering your
facility to observe tests or inspect
facilities if we are authorized to do so.
Also, you must perform the tests we
require (or have the tests done for you).
Failure to perform this testing is
prohibited.
(e) Warranty. You may not fail to
offer, provide notice of, or honor the
emissions warranty required under this
subpart.
(f) Replacement components. No
person may sell, offer for sale, introduce
or deliver for introduction into
commerce in the United States, import,
or install any replacement component
for portable fuel containers subject to
the standards of this subpart where the
component has the effect of disabling,
bypassing, or rendering inoperative the
emissions controls of the containers.
(g) Violations. If a person violates any
prohibition or requirement of this
subpart or the Act concerning portable
fuel containers, it shall be considered a
separate violation for each portable fuel
container.
(h) Assessment of penalties and
injunctions. We may assess
administrative penalties, bring a civil
action to assess and recover civil
penalties, bring a civil action to enjoin
and restrain violations, or bring criminal
action as provided by the Clean Air Act.
§ 59.603 How must manufacturers apply
good engineering judgment?
(a) In addition to other requirements
and prohibitions set forth in this
subpart, you must use good engineering
judgment for decisions related to any
requirements under this subpart. This
includes your applications for
certification, any testing you do to show
that your portable fuel containers
comply with requirements that apply to
them, and how you select, categorize,
determine, and apply these
requirements.
(b) Upon request, you must provide
EPA a written description of the
engineering judgment in question. Such
information must be provided within 15
working days unless EPA specifies a
different period of time to respond.
(c) We may reject your decision if it
is not based on good engineering
judgment or is otherwise inconsistent
with the requirements that apply, and
we may—
(1) Suspend, revoke, or void a
certificate of conformity if we determine
you used incorrect or incomplete
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information or failed to consider
relevant information, or that your
decision was not based on good
engineering judgment; or
(2) Notify you that we believe any
aspect of your application or other
information submission may be
incorrect or invalid due to lack of good
engineering judgment or other cause.
Unless a different period is specified,
you will have 30 days to respond to our
notice and specifically address our
concerns. After considering your
information, we will notify you
regarding our finding, which may
include the actions provided in
paragraph (c)(1) of this section.
(d) If you disagree with our
conclusions under paragraph (c) of this
section, you may file a request for a
hearing with the Designated Compliance
Officer as described in § 59.699. In your
request, you must specifically state your
objections, and include relevant data or
supporting analysis. The request must
be signed by your authorized
representative. If we agree that your
request raises a substantial factual issue,
we will hold the hearing according to
§ 59.699.
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§ 59.605 What portable fuel containers are
excluded from this subpart’s requirements?
This section describes exclusions that
apply to certain portable fuel containers.
The prohibitions and requirements of
this subpart do not apply for containers
excluded under this section. Exclusions
under this section are based on inherent
characteristics of the containers. See
§ 59.660 for exemptions that apply
based on special circumstances.
(a) Containers approved as safety cans
consistent with the requirements of 29
CFR 1926.150 through 1926.152 are
excluded. Such cans generally have a
flash-arresting screens, spring-closing
lids and spout covers and have been
approved by a nationally recognized
testing laboratory such as Factory
Mutual Engineering Corp. or
Underwriters Laboratories, Inc., or
Federal agencies such as Bureau of
Mines, or U.S. Coast Guard.
(b) Containers with a nominal
capacity of less than 0.25 gallons or
more than 10.0 gallons are excluded.
(c) Containers designed and marketed
solely to deliver fuel directly to nonroad
engines during engine operation, such
as containers with a connection for a
fuel line and a reserve fuel area, are
considered to be nonroad fuel tanks,
and are thus excluded.
§ 59.607
Submission of information.
(a) You are responsible for all
statements you make to us related to
this subpart F, including information
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not required during certification. You
are required to provide truthful and
complete information. This subpart
describes the consequences of failing to
meet this obligation. The consequences
also may include prosecution under 18
U.S.C. 1001 and 42 U.S.C. 7431(c)(2).
(b) We may require an officer or
authorized representative of your
company with knowledge of the
information contained in the submittal
to approve and sign any submission of
information to us, and to certify that all
the information submitted is accurate
and complete.
Emission Standards and Related
Requirements
§ 59.611 What evaporative emission
requirements apply under this subpart?
(a) Hydrocarbon emissions from
portable fuel containers may not exceed
0.3 grams per gallon per day when
measured with the test procedures in
§§ 59.650 through 59.653. This
procedure measures diurnal venting
emissions and permeation emissions.
(b) For the purpose of this section,
portable fuel containers include spouts,
caps, gaskets, and other parts provided
with the container.
(c) The following general
requirements also apply for all portable
fuel containers subject to the standards
of this subpart:
(1) Prohibited controls. The following
controls are prohibited:
(i) For anyone to design, manufacture,
or install emission control systems so
they cause or contribute to an
unreasonable risk to public health,
welfare, or safety while operating.
(ii) For anyone to design,
manufacture, or install emission control
systems with features that disable,
deactivate, reduce effectiveness, or
bypass the emission controls, either
actively or passively. For example, you
may not include a manual vent that the
operator can open to bypass emission
controls. You may ask us to allow such
features if needed for safety reasons or
if the features operate during emission
tests described in subpart F of this part.
(2) Leaks. You must design and
manufacture your containers to be free
of leaks. This requirement applies when
your container is upright, partially
inverted, or completely inverted.
(3) Refueling. You are required to
design your portable fuel containers to
minimize spillage during refueling to
the extent practical. This requires that
you use good engineering judgment to
avoid designs that will make it difficult
to refuel typical vehicle and equipment
designs without spillage.
(d) Portable fuel containers must meet
the standards and requirements
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8535
specified in this subpart throughout the
useful life of the container. The useful
life of the container is five years
beginning on the date of sale to the
ultimate purchaser.
§ 59.612 What emission-related warranty
requirements apply to me?
(a) General requirements. You must
warrant to the ultimate purchaser that
the new portable fuel container,
including all parts of its evaporative
emission-control system, is:
(1) Designed, built, and equipped so
it conforms at the time of sale to the
ultimate purchaser with the
requirements of this subpart.
(2) Is free from defects in materials
and workmanship that may keep it from
meeting these requirements.
(b) Warranty notice and period. Your
emission-related warranty must be valid
for a minimum of one year from the date
of sale to the ultimate purchaser.
(c) Notice. You must provide a
warranty notice with each container.
§ 59.613 What operation and maintenance
instructions must I give to buyers?
You must provide the ultimate
purchaser of the new portable fuel
container written instructions for
properly maintaining and using the
emission-control system.
§ 59.615 How must I label and identify the
portable fuel containers I produce?
This section describes how you must
label your portable fuel containers.
(a) At the time of manufacture,
indelibly mark the month and year of
manufacture on each container.
(b) Mold into or affix a legible label
identifying each portable fuel container.
The label must be:
(1) Attached so it is not easily
removable.
(2) Secured to a part of the container
that can be easily viewed when the can
is in use, not on the bottom of the
container.
(3) Written in English.
(c) The label must include:
(1) The heading ‘‘EMISSION
CONTROL INFORMATION’’.
(2) Your full corporate name,
trademark and warranty contact
information.
(3) A standardized identifier such as
EPA’s standardized designation for the
emission families, the model number, or
the part number.
(4) This statement: ‘‘THIS
CONTAINER COMPLIES WITH U.S.
EPA EMISSION REGULATIONS FOR
PORTABLE FUEL CONTAINERS (40
CFR Part 59).’’.
(5) This statement: ‘‘THE EMISSIONS
WARRANTY IS VALID FOR A
MINIMUM OF ONE YEAR FROM DATE
OF PURCHASE.’’.
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(d) You may add information to the
emission control information label to
identify other emission standards that
the container meets or does not meet
(such as California standards). You may
also add other information to ensure
that the portable fuel container will be
properly maintained and used.
(e) You may request that we approve
modified labeling requirements in this
subpart F if you show that it is
necessary or appropriate. We will
approve your request if your alternate
label is consistent with the requirements
of this subpart.
(f) You may identify the name and
trademark of another company instead
of their own on your emission control
information label, subject to the
following provisions:
(1) You must have a contractual
agreement with the other company that
obligates that company to take the
following steps:
(i) Meet the emission warranty
requirements that apply under § 59.612.
This may involve a separate agreement
involving reimbursement of warrantyrelated expenses.
(ii) Report all warranty-related
information to the certificate holder.
(2) In your application for
certification, identify the company
whose trademark you will use and
describe the arrangements you have
made to meet your requirements under
this section.
(3) You remain responsible for
meeting all the requirements of this
subpart.
Certifying Emission Families
§ 59.621 Who may apply for a certificate of
conformity?
A certificate of conformity may be
issued only to the manufacturer that
completes the construction of the
portable fuel container. In unusual
circumstances, upon a petition by a
manufacturer, we may allow another
manufacturer of the container to hold
the certificate of conformity. However,
in order to hold the certificate, the
manufacturer must demonstrate day-today ability to ensure that containers
produced under the certificate will
comply with the requirements of this
subpart.
pwalker on PROD1PC71 with RULES_2
§ 59.622 What are the general
requirements for obtaining a certificate of
conformity and producing portable fuel
containers under it?
(a) You must send us a separate
application for a certificate of
conformity for each emission family. A
certificate of conformity for containers
is valid from the indicated effective date
until the end of the production period
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for which it is issued. We may require
new certification prior to the end of the
production period if we finds that
containers are not meeting the standards
in use during their useful life.
(b) The application must be written in
English and contain all the information
required by this subpart and must not
include false or incomplete statements
or information (see §§ 59.607 and
59.629).
(c) We may ask you to include less
information than we specify in this
subpart, as long as you maintain all the
information required by § 59.628.
(d) You must use good engineering
judgment for all decisions related to
your application (see § 59.603).
(e) An authorized representative of
your company must approve and sign
the application.
(f) See § 59.629 for provisions
describing how we will process your
application.
(g) If we approve your application, we
will issue a certificate that will allow
you to produce the containers that you
described in your application for a
specified production period. Certificates
do not allow you to produce containers
that were not described in your
application, unless we approve the
additional containers under § 59.624.
§ 59.623 What must I include in my
application?
This section specifies the information
that must be in your application, unless
we ask you to include less information
under § 59.622(c). We may require you
to provide additional information to
evaluate your application.
(a) Describe the emission family’s
specifications and other basic
parameters of the emission controls. List
each distinguishable configuration in
the emission family. Include
descriptions and part numbers for all
detachable components such as spouts
and caps.
(b) Describe and explain the method
of emission control.
(c) Describe the products you selected
for testing and the reasons for selecting
them.
(d) Describe the test equipment and
procedures that you used, including any
special or alternate test procedures you
used (see § 59.650).
(e) List the specifications of the test
fuel to show that it falls within the
required ranges specified in § 59.650.
(f) Include the maintenance and use
instructions and warranty information
you will give to the ultimate purchaser
of each new portable fuel container (see
§ 59.613).
(g) Describe your emission control
information label (see § 59.615).
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(h) State that your product was tested
as described in the application
(including the test procedures, test
parameters, and test fuels) to show you
meet the requirements of this subpart.
(i) Present emission data to show your
products meet the applicable emission
standards. Where applicable, §§ 59.626
and 59.627 may allow you to submit an
application in certain cases without new
emission data.
(j) Report all test results, including
those from invalid tests or from any
other tests, whether or not they were
conducted according to the test
procedures of §§ 59.650 through 59.653.
We may ask you to send other
information to confirm that your tests
were valid under the requirements of
this subpart.
(k) Unconditionally certify that all the
products in the emission family comply
with the requirements of this subpart,
other referenced parts of the CFR, and
the Clean Air Act.
(l) Include estimates of U.S.-directed
production volumes.
(m) Include the information required
by other sections of this subpart.
(n) Include other relevant
information, including any additional
information requested by EPA.
(o) Name an agent for service located
in the United States. Service on this
agent constitutes service on you or any
of your officers or employees for any
action by EPA or otherwise by the
United States related to the
requirements of this subpart.
§ 59.624 How do I amend my application
for certification?
Before we issue you a certificate of
conformity, you may amend your
application to include new or modified
configurations, subject to the provisions
of this section. After we have issued
your certificate of conformity, you may
send us an amended application
requesting that we include new or
modified configurations within the
scope of the certificate, subject to the
provisions of this section. You must
amend your application if any changes
occur with respect to any information
included in your application.
(a) You must amend your application
before you take either of the following
actions:
(1) Add a configuration to an emission
family. In this case, the configuration
added must be consistent with other
configurations in the emission family
with respect to the criteria listed in
§ 59.625.
(2) Change a configuration already
included in an emission family in a way
that may affect emissions, or change any
of the components you described in
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your application for certification. This
includes production and design changes
that may affect emissions any time
during the portable fuel containers’
lifetime.
(b) To amend your application for
certification, send the Designated
Compliance Officer the following
information:
(1) Describe in detail the addition or
change in the configuration you intend
to make.
(2) Include engineering evaluations or
data showing that the amended
emission family complies with all
applicable requirements. You may do
this by showing that the original
emission data are still appropriate with
respect to showing compliance of the
amended family with all applicable
requirements.
(3) If the original emission data for the
emission family are not appropriate to
show compliance for the new or
modified configuration, include new
test data showing that the new or
modified configuration meets the
requirements of this subpart.
(c) We may ask for more test data or
engineering evaluations. You must give
us these within 30 days after we request
them.
(d) For emission families already
covered by a certificate of conformity,
we will determine whether the existing
certificate of conformity covers your
new or modified configuration. You
may ask for a hearing if we deny your
request (see § 59.699).
(e) For emission families already
covered by a certificate of conformity
and you send us a request to amend
your application, you may sell and
distribute the new or modified
configuration before we make a decision
under paragraph (d) of this section,
subject to the provisions of this
paragraph. If we determine that the
affected configurations do not meet
applicable requirements, we will notify
you to cease production of the
configurations and any containers from
the new or modified configuration will
not be considered covered by the
certificate. In addition, we may require
you to recall any affected containers that
you have already distributed, including
those sold to the ultimate purchasers.
Choosing to produce containers under
this paragraph (e) is deemed to be
consent to recall all containers that we
determine do not meet applicable
emission standards or other
requirements and to remedy the
nonconformity at no expense to the
owner. If you do not provide
information required under paragraph
(c) of this section within 30 days, you
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18:54 Feb 23, 2007
Jkt 211001
must stop producing the new or
modified containers.
§ 59.625 How do I select emission
families?
(a) Divide your product line into
families of portable fuel containers that
are expected to have similar emission
characteristics throughout the useful
life.
(b) Group containers in the same
emission family if they are the same in
all the following aspects:
(1) Type of material (including
pigments, plasticizers, UV inhibitors, or
other additives that may affect control of
emissions).
(2) Production method.
(3) Spout and cap design.
(4) Gasket material and design.
(5) Emission control strategy.
(c) You may subdivide a group of
containers that is identical under
paragraph (b) of this section into
different emission families if you show
the expected emission characteristics
are different.
(d) You may group containers that are
not identical with respect to the things
listed in paragraph (b) of this section in
the same emission family if you show
that their emission characteristics will
be similar throughout their useful life.
§ 59.626 What emission testing must I
perform for my application for a certificate
of conformity?
This section describes the emission
testing you must perform to show
compliance with the emission standards
in § 59.611.
(a) Test your products using the
procedures and equipment specified in
§§ 59.650 through 59.653.
(b) Select an emission-data unit from
each emission family for testing. You
must test a production sample or a
preproduction product that will
represent actual production. Select the
configuration that is most likely to
exceed (or have emissions nearest to)
the applicable emission standard. For
example, for a family of multilayer
portable fuel containers, test the
container with the thinnest barrier layer.
Test three identical containers.
(c) We may measure emissions from
any of your products from the emission
family. You must supply your products
to us if we choose to perform
confirmatory testing.
(d) You may ask to use emission data
from a previous production period
(carryover) instead of doing new tests,
but only if the emission-data from the
previous production period remains the
appropriate emission-data unit under
paragraph (b) of this section. For
example, you may not carryover
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8537
emission data for your family of
containers if you have added a thinnerwalled container than was tested
previously.
(e) We may require you to test a
second unit of the same or different
configuration in addition to the unit
tested under paragraph (b) of this
section.
(f) If you use an alternate test
procedure under § 59.652 and later
testing shows that such testing does not
produce results that are equivalent to
the procedures specified in this subpart,
we may reject data you generated using
the alternate procedure and base our
compliance determination on the later
testing.
§ 59.627 How do I demonstrate that my
emission family complies with evaporative
emission standards?
(a) For purposes of certification, your
emission family is considered in
compliance with an evaporative
emission standard in § 59.611(a) if the
test results from all portable fuel
containers in the family that have been
tested show measured emissions levels
that are at or below the applicable
standard.
(b) Your emissions family is deemed
not to comply if any container
representing that family has test results
showing an official emission level above
the standard.
(c) Round the measured emission
level to the same number of decimal
places as the emission standard.
Compare the rounded emission levels to
the emission standard.
§ 59.628 What records must I keep and
what reports must I send to EPA?
(a) Organize and maintain the
following records:
(1) A copy of all applications and any
other information you send us.
(2) Any of the information we specify
in § 59.623 that you were not required
to include in your application.
(3) A detailed history of each
emission-data unit. For each emissiondata unit, include all of the following:
(i) The emission-data unit’s
construction, including its origin and
buildup, steps you took to ensure that
it represents production containers, any
components you built specially for it,
and all the components you include in
your application for certification.
(ii) All your emission tests, including
documentation on routine and standard
tests, as specified in §§ 59.650 through
59.653, and the date and purpose of
each test.
(iii) All tests to diagnose emissioncontrol performance, giving the date and
time of each and the reasons for the test.
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(iv) Any other relevant events or
information.
(4) Production figures for each
emission family divided by assembly
plant.
(5) If you identify your portable fuel
containers by lot number or other
identification numbers, keep a record of
these numbers for all the containers you
produce under each certificate of
conformity.
(b) Keep data from routine emission
tests (such as test cell temperatures and
relative humidity readings) for one year
after we issue the associated certificate
of conformity. Keep all other
information specified in paragraph (a) of
this section for five years after we issue
your certificate.
(c) Store these records in any format
and on any media, as long as you can
promptly send us organized, written
records in English if we ask for them.
You must keep these records readily
available. We may review them at any
time.
(d) Send us copies of any
maintenance instructions or
explanations if we ask for them.
(e) Send us an annual warranty report
summarizing successful warranty claims
by emission family under § 59.612,
including the reason for the claim. You
must submit the report by July 1 for the
preceding calendar year.
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§ 59.629 What decisions may EPA make
regarding my certificate of conformity?
(a) If we determine your application is
complete and shows that the emission
family meets all the requirements of this
subpart and the Act, we will issue a
certificate of conformity for your
emission family for the specified
production period. We may make the
approval subject to additional
conditions.
(b) We may deny your application for
certification if we determine that your
emission family fails to comply with
emission standards or other
requirements of this subpart or the Act.
Our decision may be based on a review
of all information available to us. If we
deny your application, we will explain
why in writing.
(c) In addition, we may deny your
application or suspend, revoke, or void
your certificate if you do any of the
following:
(1) Refuse to comply with any testing
or reporting requirements.
(2) Submit false or incomplete
information.
(3) Render inaccurate any test data.
(4) Deny us from completing
authorized activities (see § 59.698). This
includes a failure to provide reasonable
assistance.
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(5) Produce portable fuel containers
for importation into the United States at
a location where local law prohibits us
from carrying out authorized activities.
(6) Fail to supply requested
information or amend your application
to include all portable fuel containers
being produced.
(7) Take any action that otherwise
circumvents the intent of the Act or this
subpart.
(d) If we deny your application or
suspend, revoke, or void your
certificate, you may ask for a hearing
(see § 59.699).
§ 59.630
EPA testing.
We may test any portable fuel
container subject to the standards of this
subpart.
(a) Certification and production
sample testing. Upon our request, a
manufacturer must supply a prototype
container or a reasonable number of
production samples to us for
verification testing. These samples will
generally be tested using the full test
procedure of § 59.653.
(b) In-use testing. We may test in-use
containers using the test procedure of
§ 59.653 without preconditioning.
§ 59.650
General testing provisions.
(a) The test procedures of this subpart
are addressed to you as a manufacturer,
but they apply equally to anyone who
does testing for you.
(b) Unless we specify otherwise, the
terms ‘‘procedures’’ and ‘‘test
procedures’’ in this subpart include all
aspects of testing, including the
equipment specifications, calibrations,
calculations, and other protocols and
procedural specifications needed to
measure emissions.
(c) The specification for gasoline to be
used for testing is given in 40 CFR
1065.710. Use the grade of gasoline
specified for general testing. Blend this
grade of gasoline with reagent grade
ethanol in a volumetric ratio of 90.0
percent gasoline to 10.0 percent ethanol.
You may use ethanol that is less pure if
you can demonstrate that it will not
affect your ability to demonstrate
compliance with the applicable
emission standards.
(d) Accuracy and precision of all
temperature measurements must be
±2.2° C or better.
(e) Accuracy and precision of mass
balances must be sufficient to ensure
accuracy and precision of two percent
or better for emission measurements for
products at the maximum level allowed
by the standard. The readability of the
display may not be coarser than half of
the required accuracy and precision.
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§ 59.652
Other procedures.
(a) Your testing. The procedures in
this subpart apply for all testing you do
to show compliance with emission
standards, with certain exceptions listed
in this section.
(b) Our testing. These procedures
generally apply for testing that we do to
determine if your portable fuel
containers complies with applicable
emission standards. We may perform
other testing as allowed by the Act.
(c) Exceptions. We may allow or
require you to use procedures other than
those specified in this subpart as
follows:
(1) You may request to use special
procedures if your portable fuel
containers cannot be tested using the
specified procedures. We will approve
your request if we determine that it
would produce emission measurements
that represent in-use operation and we
determine that it can be used to show
compliance with the requirements of
§ 59.611.
(2) You may ask to use emission data
collected using other procedures, such
as those of the California Air Resources
Board. We will approve this only if you
show us that using these other
procedures do not affect your ability to
show compliance with the applicable
emission standards. This generally
requires emission levels to be far
enough below the applicable emission
standards so that any test differences do
not affect your ability to state
unconditionally that your containers
will meet all applicable emission
standards when tested using the
specified test procedures.
(3) You may request to use alternate
procedures that are equivalent to
allowed procedures, or more accurate or
more precise than allowed procedures.
(4) You may not use other procedures
under this paragraph (c) until we
approve your request.
§ 59.653 How do I test portable fuel
containers?
You must test the portable fuel
container as described in your
application, with the applicable spout
attached except as otherwise noted.
Tighten fittings in a manner
representative of how they would be
tightened by a typical user.
(a) Preconditioning for durability.
Complete the following steps before an
emissions test, in any order, unless we
determine that omission of one or more
of these durability steps will not affect
the emissions from your container.
(1) Pressure cycling. Perform a
pressure test by sealing the container
and cycling it between +13.8 and ¥1.7
kPa (+2.0 and ¥0.5 psig) for 10,000
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cycles at a rate of 60 seconds per cycle.
For this test, the spout may be removed
and the pressure applied through the
opening where the spout attaches. The
purpose of this test is to represent
environmental wall stresses caused by
pressure changes and other factors (such
as vibration or thermal expansion). If
your container cannot be tested using
the pressure cycles specified by this
paragraph (a)(1), you may ask to use
special test procedures under
§ 59.652(c).
(2) UV exposure. Perform a sunlightexposure test by exposing the container
to an ultraviolet light of at least 24 W/
m2 (0.40 W-hr/m2/min) on the container
surface for at least 450 hours.
Alternatively, the container may be
exposed to direct natural sunlight for an
equivalent period of time, as long as you
ensure that the container is exposed to
at least 450 daylight hours.
(3) Slosh testing. Perform a slosh test
by filling the portable fuel container to
40 percent of its capacity with the fuel
specified in paragraph (e) of this section
and rocking it at a rate of 15 cycles per
minute until you reach one million total
cycles. Use an angle deviation of +15°
to ¥15° from level.
(4) Spout actuation. Perform the
following spout actuation and inversion
steps at the end on the slosh testing, and
at the end of the preconditioning soak.
(i) Perform one complete actuation/
inversion cycle per day for ten days.
(ii) One actuation/inversion cycle
consists of the following steps:
(A) Remove and replace the spout to
simulate filling the container.
(B) Slowly invert the container and
keep it inverted for at least 5 seconds to
ensure that the spout and mechanisms
become saturated with fuel. Any fuel
leaking from any part of the container
will denote a leak and must be reported
as part of certification. Once completed,
place the container on a flat surface in
the upright position.
(C) Actuate the spout by fully opening
and closing without dispensing fuel.
The spout must return to the closed
position without the aid of the operator
(e.g., pushing or pulling the spout
closed). Repeat for a total of 10
actuations. If at any point the spout fails
to return to the closed position, the
container fails the test.
(D) Repeat the step contained in
paragraph (a)(4)(ii)(B) of this section
(i.e., the inversion step).
(E) Repeat the steps contained in
paragraph (a)(4)(ii)(C) of this section
(i.e., ten actuations).
(b) Preconditioning fuel soak.
Complete the following steps before a
diurnal emission test:
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(1) Fill the portable fuel container
with the specified fuel to its nominal
capacity, seal it using the spout, and
allow it to soak at 28 ±5° C for 20 weeks.
Alternatively, the container may be
soaked for 10 weeks at 43 ±5° C. You
may count the time of the
preconditioning steps in paragraph (a)
of this section as part of the
preconditioning fuel soak, as long as the
ambient temperature remains within the
specified temperature range and the fuel
tank is at least 40 percent full; you may
add or replace fuel as needed to conduct
the specified durability procedures.
(2) Pour the fuel out of the container
and immediately refill to 50 percent of
nominal capacity. Be careful to not spill
any fuel on the container. Wipe the
outside of the container as needed to
remove any liquid fuel that may have
spilled on it.
(3) Install the spout assembly that will
be used in the production containers.
The spout and other openings (such as
vents) on the container must be tested
in their open condition unless they
close automatically and are unlikely to
be left open by the user during typical
storage. All manual closures such as
caps must be left off the container and
spout during testing.
(c) Reference container. A reference
container is required to correct for
buoyancy effects that may occur during
testing. Prepare the reference tank as
follows:
(1) Obtain a second container of the
same model as the test tank. You may
not use a container that has previously
contained fuel or any other contents that
might affect the stability of its mass.
(2) Fill the reference container with
enough dry sand (or other inert
material) so that the mass of the
reference container is approximately the
same as the test container when filled
with fuel. Use good engineering
judgment to determine how similar the
mass of the reference container needs to
be to the mass of the test container
considering the performance
characteristics of your balance.
(3) Ensure that the sand (or other inert
material) is dry. This may require
heating the container or applying a
vacuum to it.
(4) Seal the container.
(d) Diurnal test run. To run the test,
take the following steps for a portable
fuel container that was preconditioned
as specified in paragraph (a) of this
section.
(1) Stabilize the fuel temperature
within the portable fuel container at
22.2 °C. Vent the container at this point
to relieve any positive or negative
pressure that may have developed
during stabilization.
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8539
(2) Weigh the sealed reference
container and record the weight. Place
the reference on the balance and tare it
so that it reads zero. Place the sealed
test container on the balance and record
the difference between the test container
and the reference container. This value
is Minitial Take this measurement within
8 hours of filling the test container with
fuel as specified in paragraph (b)(2) of
this section.
(3) Immediately place the portable
fuel container within a well ventilated,
temperature-controlled room or
enclosure. Do not spill or add any fuel.
(4) Close the room or enclosure.
(5) Follow the temperature profile in
the following table for all portable fuel
containers. Use good engineering
judgment to follow this profile as
closely as possible. You may use
linearly interpolated temperatures or a
spline fit for temperatures between the
hourly setpoints.
TABLE 1 OF § 59.653—DIURNAL TEMPERATURE PROFILE FOR PORTABLE
FUEL CONTAINERS
Time
(hours)
0 ................................................
1 ................................................
2 ................................................
3 ................................................
4 ................................................
5 ................................................
6 ................................................
7 ................................................
8 ................................................
9 ................................................
10 ..............................................
11 ..............................................
12 ..............................................
13 ..............................................
14 ..............................................
15 ..............................................
16 ..............................................
17 ..............................................
18 ..............................................
19 ..............................................
20 ..............................................
21 ..............................................
22 ..............................................
23 ..............................................
24 ..............................................
Ambient
Temperature
(°C)
Profile
22.2
22.5
24.2
26.8
29.6
31.9
33.9
35.1
35.4
35.6
35.3
34.5
33.2
31.4
29.7
28.2
27.2
26.1
25.1
24.3
23.7
23.3
22.9
22.6
22.2
(6) At the end of the diurnal period,
retare the balance using the reference
container and weigh the portable fuel
container. Record the difference in mass
between the reference container and the
test. This value is Mfinal.
(7) Subtract Mfinal from Minitial and
divide the difference by the nominal
capacity of the container (using at least
three significant figures) to calculate the
g/gallon/day emission rate as follows:
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Emission rate = (Minitial—Mfinal)/
(nominal capacity)/(one day)
(8) Round your result to the same
number of decimal places as the
emission standard.
(9) Instead of determining emissions
by weighing the container before and
after the diurnal temperature cycle, you
may place the container in a SHED
meeting the specifications of 40 CFR
86.107–96(a)(1) and measure emissions
directly. Immediately following the
stabilization in paragraph (d)(1) of this
section, purge the SHED and follow the
temperature profile from paragraph
(d)(4) of this section. Start measuring
emissions when you start the
temperature profile and stop measuring
emissions when the temperature profile
concludes.
(e) For metal containers, you may
demonstrate for certification that your
portable fuel containers comply with
the evaporative emission standards
without performing the pre-soak or
container durability cycles (i.e., the
pressure cycling, UV exposure, and
slosh testing) specified in this section.
For other containers, you may
demonstrate compliance without
performing the durability cycles
specified in this section only if we
approve it after you have presented data
clearly demonstrating that the cycle or
cycles do not negatively impact the
permeation rate of the materials used in
the containers.
Special Compliance Provisions
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§ 59.660
Exemption from the standards.
In certain circumstances, we may
exempt portable fuel containers from
the evaporative emission standards and
requirements of § 59.611 and the
prohibitions and requirements of
§ 59.602. You do not need an exemption
for any containers that you own but do
not sell, offer for sale, introduce or
deliver for introduction into U.S.
commerce, or import into the United
States. Submit your request for an
exemption to the Designated
Compliance Officer.
(a) Portable fuel containers that are
intended for export only and are in fact
exported are exempt provided they are
clearly labeled as being for export only.
Keep records for five years of all
portable fuel containers that you
manufacture for export. Any
introduction into U.S. commerce of
such portable fuel containers for any
purpose other than export is considered
to be a violation of § 59.602 by the
manufacturer. You do not need to
request this exemption.
(b) You may ask us to exempt portable
fuel containers that you will purchase,
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sell, or distribute for the sole purpose of
testing them.
(c) You may ask us to exempt portable
fuel containers for the purpose of
national security, as long as your
request is endorsed by an agency of the
federal government responsible for
national defense. In your request,
explain why you need the exemption.
(d) You may ask us to exempt
containers that are designed and
marketed solely for rapidly refueling
racing applications which are designed
to create a leak proof seal with the target
tank or are designed to connect with a
receiver installed on the target tank.
This exemption is generally intended
for containers used to rapidly refuel a
race car during a pit stop and similar
containers. In your request, explain how
why these containers are unlikely to be
used for nonracing applications. We
may limit these exemptions to those
applications that are allowed to use
gasoline exempted under 40 CFR
80.200(a).
(e) EPA may impose reasonable
conditions on any exemption, including
a limit on the number of containers that
are covered by an exemption.
§ 59.662 What temporary provisions
address hardship due to unusual
circumstances?
(a) After considering the
circumstances, we may exempt you
from the evaporative emission standards
and requirements of § 59.611 of this
subpart and the prohibitions and
requirements of § 59.602 for specified
portable fuel containers that do not
comply with emission standards if all
the following conditions apply:
(1) Unusual circumstances that are
clearly outside your control and that
could not have been avoided with
reasonable discretion prevent you from
meeting requirements from this subpart.
(2) You exercised prudent planning
and were not able to avoid the violation;
you have taken all reasonable steps to
minimize the extent of the
nonconformity.
(3) Not having the exemption will
jeopardize the solvency of your
company.
(4) No other allowances are available
under the regulations in this chapter to
avoid the impending violation,
including the provisions of § 59.663.
(b) To apply for an exemption, you
must send the Designated Compliance
Officer a written request as soon as
possible before you are in violation. In
your request, show that you meet all the
conditions and requirements in
paragraph (a) of this section.
(c) Include in your request a plan
showing how you will meet all the
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applicable requirements as quickly as
possible.
(d) You must give us other relevant
information if we ask for it.
(e) We may include reasonable
additional conditions on an approval
granted under this section, including
provisions to recover or otherwise
address the lost environmental benefit
or paying fees to offset any economic
gain resulting from the exemption.
(f) We may approve renewable
extensions of up to one year. We may
review and revise an extension as
reasonable under the circumstances.
(g) Add a legible label, written in
English, to a readily visible part of each
container exempted under this section.
This label must prominently include at
least the following items:
(1) Your corporate name and
trademark.
(2) The statement ‘‘EXEMPT UNDER
40 CFR 59.662.’’.
§ 59.663 What are the provisions for
extending compliance deadlines for
manufacturers under hardship?
(a) After considering the
circumstances, we may extend the
compliance deadline for you to meet
new emission standards, as long as you
meet all the conditions and
requirements in this section.
(b) To apply for an extension, you
must send the Designated Compliance
Officer a written request. In your
request, show that all the following
conditions and requirements apply:
(1) You have taken all possible
business, technical, and economic steps
to comply.
(2) Show that the burden of
compliance costs prevents you from
meeting the requirements of this subpart
by the required compliance date.
(3) Not having the exemption will
jeopardize the solvency of your
company.
(4) No other allowances are available
under the regulations in this subpart to
avoid the impending violation.
(c) In describing the steps you have
taken to comply under paragraph (b)(1)
of this section, include at least the
following information:
(1) Describe your business plan,
showing the range of projects active or
under consideration.
(2) Describe your current and
projected financial standing, with and
without the burden of complying in full
with the applicable regulations in this
subpart by the required compliance
date.
(3) Describe your efforts to raise
capital to comply with regulations in
this subpart.
(4) Identify the engineering and
technical steps you have taken or plan
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to take to comply with regulations in
this subpart.
(5) Identify the level of compliance
you can achieve. For example, you may
be able to produce containers that meet
a somewhat less stringent emission
standard than the regulations in this
subpart require.
(d) Include in your request a plan
showing how you will meet all the
applicable requirements as quickly as
possible.
(e) You must give us other relevant
information if we ask for it.
(f) An authorized representative of
your company must sign the request and
include the statement: ‘‘All the
information in this request is true and
accurate, to the best of my knowledge.’’.
(g) Send your request for this
extension at least nine months before
the relevant deadline.
(h) We may include reasonable
requirements on an approval granted
under this section, including provisions
to recover or otherwise address the lost
environmental benefit. For example, we
may require that you meet a less
stringent emission standard.
(i) We may approve renewable
extensions of up to one year. We may
review and revise an extension as
reasonable under the circumstances.
(j) Add a permanent, legible label,
written in English, to a readily visible
part of each container exempted under
this section. This label must
prominently include at least the
following items:
(1) Your corporate name and
trademark.
(2) The statement ‘‘EXEMPT UNDER
40 CFR 59.663.’’.
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§ 59.664 What are the requirements for
importing portable fuel containers into the
United States?
As specified in this section, we may
require you to post a bond if you import
into the United States containers that
are subject to the standards of this
subpart. See paragraph (f) of this section
for the requirements related to
importing containers that have been
certified by someone else.
(a) Prior to importing containers into
the U.S., we may require you to post a
bond to cover any potential compliance
or enforcement actions under the Clean
Air Act if you cannot demonstrate to us
that you have assets of an appropriate
liquidity readily available in the United
States with a value equal to the retail
value of the containers that you will
import during the calendar year.
(b) We may set the value of the bond
up to five dollars per container.
(c) You may meet the bond
requirements of this section by
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obtaining a bond from a third-party
surety that is cited in the U.S.
Department of Treasury Circular 570,
‘‘Companies Holding Certificates of
Authority as Acceptable Sureties on
Federal Bonds and as Acceptable
Reinsuring Companies’’ (https://
www.fms.treas.gov/c570/
c570.html#certified).
(d) If you forfeit some or all of your
bond in an enforcement action, you
must post any appropriate bond for
continuing importation within 90 days
after you forfeit the bond amount.
(e) You will forfeit the proceeds of the
bond posted under this section if you
need to satisfy any United States
administrative final order or judicial
judgment against you arising from your
conduct in violation of this subpart.
(f) This paragraph (f) applies if you
import for resale containers that have
been certified by someone else. You and
the certificate holder are each
responsible for compliance with the
requirements of this subpart and the
Clean Air Act. No bond is required
under this section if either you or the
certificate holder meet the conditions in
paragraph (a) of this section. Otherwise,
the importer must comply with the
bond requirements of this section.
Definitions and Other Reference
Information
§ 59.680 What definitions apply to this
subpart?
The following definitions apply to
this subpart. The definitions apply to all
subparts unless we note otherwise. All
undefined terms have the meaning the
Act gives to them. The definitions
follow:
Act means the Clean Air Act, as
amended, 42 U.S.C. 7401–7671q.
Adjustable parameter means any
device, system, or element of design that
someone can adjust and that, if
adjusted, may affect emissions. You may
ask us to exclude a parameter if you
show us that it will not be adjusted in
use in a way that affects emissions.
Certification means relating to the
process of obtaining a certificate of
conformity for an emission family that
complies with the emission standards
and requirements in this subpart.
Configuration means a unique
combination of hardware (material,
geometry, and size) and calibration
within an emission family. Units within
a single configuration differ only with
respect to normal production variability.
Container means portable fuel
container.
Designated Compliance Officer means
the Manager, Engine Programs Group
(6403–J), U.S. Environmental Protection
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8541
Agency, 1200 Pennsylvania Ave., NW.,
Washington, DC 20460.
Designated Enforcement Officer
means the Director, Air Enforcement
Division (2242A), U.S. Environmental
Protection Agency, 1200 Pennsylvania
Ave., NW.,Washington, DC 20460.
Emission-control system means any
device, system, or element of design that
controls or reduces the regulated
evaporative emissions from.
Emission-data unit means a portable
fuel container that is tested for
certification. This includes components
tested by EPA.
Emission-related maintenance means
maintenance that substantially affects
emissions or is likely to substantially
affect emission deterioration.
Emission family has the meaning
given in § 59.625.
Evaporative means relating to fuel
emissions that result from permeation of
fuel through the portable fuel container
materials and from ventilation of the
container.
Good engineering judgment means
judgments made consistent with
generally accepted scientific and
engineering principles and all available
relevant information. See § 59.603 for
the administrative process we use to
evaluate good engineering judgment.
Hydrocarbon (HC) means total
hydrocarbon (THC).
Manufacture means the physical and
engineering process of designing and/or
constructing a portable fuel container.
Manufacturer means any person who
manufactures a portable fuel container
for sale in the United States.
Nominal capacity means the expected
volumetric working capacity of a
container.
Official emission result means the
measured emission rate for an emissiondata unit.
Portable fuel container means any
reusable container designed and
marketed (or otherwise intended) for
use by consumers for receiving,
transporting, storing, and dispensing
gasoline, diesel fuel, or kerosene. For
the purpose of this subpart, all utility
jugs that are red, yellow or blue in color
are deemed to be portable fuel
containers, regardless of how they are
labeled or marketed.
Production period means the period
in which a portable fuel container will
be produced under a certificate of
conformity. The maximum production
period is five years.
Revoke means to terminate the
certificate or an exemption for an
emission family. If we revoke a
certificate or exemption, you must apply
for a new certificate or exemption before
continuing to introduce the affected
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containers into commerce. This does not
apply to containers you no longer
possess.
Round has the meaning given in 40
CFR 1065.1001.
Suspend means to temporarily
discontinue the certificate or an
exemption for an emission family. If we
suspend a certificate, you may not
introduce into commerce portable fuel
containers from that emission family
unless we reinstate the certificate or
approve a new one. If we suspend an
exemption, you may not introduce into
commerce containers that were
previously covered by the exemption
unless we reinstate the exemption.
Total hydrocarbon means the
combined mass of organic compounds
measured by the specified procedure for
measuring total hydrocarbon, expressed
as a hydrocarbon with a hydrogen-tocarbon mass ratio of 1.85:1.
Ultimate purchaser means, with
respect to any portable fuel container,
the first person who in good faith
purchases such a container for purposes
other than resale.
Ultraviolet light means
electromagnetic radiation with a
wavelength between 300 and 400
nanometers.
United States means the States, the
District of Columbia, the
Commonwealth of Puerto Rico, the
Commonwealth of the Northern Mariana
Islands, Guam, American Samoa, and
the U.S. Virgin Islands.
U.S.-directed production volume
means the amount of portable fuel
containers, subject to the requirements
of this subpart, produced by a
manufacturer for which the
manufacturer has a reasonable
assurance that sale was or will be made
to ultimate purchasers in the United
States.
Useful life means the period during
which a portable fuel container is
required to comply with all applicable
emission standards. See § 59.611.
Void means to invalidate a certificate
or an exemption ab initio (i.e.
retroactively). Portable fuel containers
introduced into U.S. commerce under
the voided certificate or exemption is a
violation of this subpart, whether or not
they were introduced before the
certificate or exemption was voided.
We (us, our) means the Administrator
of the Environmental Protection Agency
and any authorized representatives.
§ 59.685 What symbols, acronyms, and
abbreviations does this subpart use?
The following symbols, acronyms,
and abbreviations apply to this subpart:
CFR Code of Federal Regulations
EPA Environmental Protection Agency
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18:54 Feb 23, 2007
Jkt 211001
HC hydrocarbon
NIST National Institute of Standards
and Technology
THC total hydrocarbon
U.S.C. United States Code
§ 59.695 What provisions apply to
confidential information?
(a) Clearly show what you consider
confidential by marking, circling,
bracketing, stamping, or some other
method.
(b) We will store your confidential
information as described in 40 CFR part
2. Also, we will disclose it only as
specified in 40 CFR part 2. This applies
both to any information you send us and
to any information we collect from
inspections, audits, or other site visits.
(c) If you send us a second copy
without the confidential information,
we will assume it contains nothing
confidential whenever we need to
release information from it.
(d) If you send us information without
claiming it is confidential, we may make
it available to the public without further
notice to you, as described in 40 CFR
2.204.
§ 59.697
State actions.
The provisions in this subpart do not
preclude any State or any political
subdivision of a State from:
(a) Adopting and enforcing any
emission standard or limitation
applicable to anyone subject to the
provisions of this part; or
(b) Requiring the regulated entity to
obtain permits, licenses, or approvals
prior to initiating construction,
modification, or operation of a facility
for manufacturing a consumer product.
§ 59.698 May EPA enter my facilities for
inspections?
(a) We may inspect your portable fuel
containers, testing, manufacturing
processes, storage facilities (including
port facilities for imported containers or
other relevant facilities), or records, as
authorized by the Act, to enforce the
provisions of this subpart. Inspectors
will have authorizing credentials and
will limit inspections to reasonable
times—usually, normal operating hours.
(b) If we come to inspect, we may or
may not have a warrant or court order.
(1) If we do not have a warrant or
court order, you may deny us entry.
(2) If we have a warrant or court
order, you must allow us to enter the
facility and carry out the activities it
describes.
(c) We may seek a warrant or court
order authorizing an inspection
described in this section, whether or not
we first tried to get your permission to
inspect.
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(d) We may select any facility to do
any of the following:
(1) Inspect and monitor any aspect of
portable fuel container manufacturing,
assembly, storage, or other procedures,
and any facilities where you do them.
(2) Inspect and monitor any aspect of
test procedures or test-related activities,
including test container selection,
preparation, durability cycles, and
maintenance and verification of your
test equipment’s calibration.
(3) Inspect and copy records or
documents related to assembling,
storing, selecting, and testing a
container.
(4) Inspect and photograph any part or
aspect of containers or components use
for assembly.
(e) You must give us reasonable help
without charge during an inspection
authorized by the Act. For example, you
may need to help us arrange an
inspection with the facility’s managers,
including clerical support, copying, and
translation. You may also need to show
us how the facility operates and answer
other questions. If we ask in writing to
see a particular employee at the
inspection, you must ensure that he or
she is present (legal counsel may
accompany the employee).
(f) If you have facilities in other
countries, we expect you to locate them
in places where local law does not keep
us from inspecting as described in this
section. We will not try to inspect if we
learn that local law prohibits it, but we
may suspend your certificate if we are
not allowed to inspect.
§ 59.699
How do I request a hearing?
(a) You may request a hearing under
certain circumstances, as described
elsewhere in this subpart. To do this,
you must file a written request with the
Designated Compliance Officer,
including a description of your
objection and any supporting data,
within 30 days after we make a
decision.
(b) For a hearing you request under
the provisions of this subpart, we will
approve your request if we find that
your request raises a substantial factual
issue.
(c) If we agree to hold a hearing, we
will use the procedures specified in 40
CFR part 1068, subpart G.
PART 80—REGULATION OF FUELS
AND FUEL ADDITIVES
3. The authority citation for part 80 is
revised to read as follows:
I
Authority: 42 U.S.C. 7414, 7521(1), 7545
and 7601(a).
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Subpart D—[Amended]
4. Section 80.41 is amended as
follows:
I a. By redesignating paragraph (e) as
paragraph (e)(1).
I b. By adding paragraphs (e)(2) and
(e)(3).
I c. By redesignating paragraph (f) as
paragraph (f)(1).
I d. By adding paragraphs (f)(2) and
(f)(3).
I
§ 80.41 Standards and requirements for
compliance.
pwalker on PROD1PC71 with RULES_2
*
*
*
*
*
(e) * * *
(2)(i) The NOX emissions performance
reduction specified in paragraph (e)(1)
of this section shall no longer apply
beginning January 1, 2007, except as
provided in paragraph (e)(2)(ii) of this
section.
(ii) For a refiner subject to the small
refiner gasoline sulfur standards at
§ 80.240, the NOX emissions
performance reduction specified in
paragraph (e)(1) of this section shall no
longer apply beginning January 1, 2008.
For a refiner subject to the gasoline
sulfur standards at § 80.240 that has
received an extension of its small refiner
gasoline sulfur standards under
§ 80.553, the NOX emissions
performance reduction specified in
paragraph (e)(1) of this section shall no
longer apply beginning January 1, 2011.
(3)(i) Beginning January 1, 2011, or
January 1, 2015 for small refiners
approved under § 80.1340, the toxic air
pollutants emissions performance
reduction and benzene content specified
in paragraph (e)(1) of this section shall
apply to reformulated gasoline that is
not subject to the benzene standard of
§ 80.1230, pursuant to the provisions of
§ 80.1235.
(ii) The toxic air pollutants emissions
performance reduction and benzene
content specified in paragraph (e)(1) of
this section shall not apply to
reformulated gasoline produced by a
refinery approved under § 80.1334,
pursuant to § 80.1334(c).
(f) * * *
(2)(i) The NOX emissions performance
reduction specified in paragraph (f)(1) of
this section shall no longer apply
beginning January 1, 2007, except as
provided in paragraph (f)(2)(ii) of this
section.
(ii) For a refiner subject to the small
refiner gasoline sulfur standards at
§ 80.240, the NOX emissions
performance reduction specified in
paragraph (f)(1) of this section shall no
longer apply beginning January 1, 2008.
For a refiner subject to the gasoline
sulfur standards at § 80.240 that has
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received an extension of its small refiner
gasoline sulfur standards under
§ 80.553, the NOX emissions
performance reduction specified in
paragraph (f)(1) of this section shall no
longer apply beginning January 1, 2011.
(3)(i) Beginning January 1, 2011, or
January 1, 2015 for small refiners
approved under § 80.1340, the toxic air
pollutants emissions performance
reduction and benzene content specified
in paragraph (f)(1) of this section shall
apply only to reformulated gasoline that
is not subject to the benzene standard of
§ 80.1230, pursuant to the provisions of
§ 80.1235.
(ii) The toxic air pollutants emissions
performance reduction and benzene
content specified in paragraph (f)(1) of
this section shall not apply to
reformulated gasoline produced by a
refinery approved under § 80.1334,
pursuant to § 80.1334(c).
*
*
*
*
*
I 5. Section 80.68 is amended as
follows:
I a. By redesignating paragraphs (a)
through (c) as paragraphs (b) through
(d), respectively.
I b. By adding new paragraph (a).
I c. In newly designated paragraph
(b)(2) revise the reference ‘‘(c)’’ to read
‘‘(d)’’.
I d. In newly designated paragraph (c)
introductory text revise the reference
‘‘(a)’’ to read ‘‘(b)’’.
I e. In newly designated paragraph
(c)(2)(i) revise the reference ‘‘(b)(1)’’ to
read ‘‘(c)(1)’’.
I f. In newly designated paragraph
(c)(2)(ii) revise the reference ‘‘(c)’’ to
read ‘‘(d)’’, revise all references ‘‘(b)(1)’’
to read ‘‘(c)(1)’’, and revise all references
‘‘(b)(2)(i)’’ to read ‘‘(c)(2)(i)’’.
I g. In newly designated paragraph
(c)(3) revise the reference ‘‘(c)’’ to read
‘‘(d)’’.
I h. In newly designated paragraph
(c)(4)(i) revise the reference ‘‘(a)’’ to read
‘‘(b)’’.
I i. In newly designated paragraph
(d)(1)(ii)(A) revise the reference ‘‘(c)(6)’’
to read ‘‘(d)(6)’’.
I j. In newly designated paragraph
(d)(1)(ii)(B) revise the reference ‘‘(c)(6)’’
to read ‘‘(d)(6)’’.
I k. In newly designated paragraph
(d)(2)(i) revise the reference ‘‘(c)(6)’’ to
read ‘‘(d)(6)’’.
I l. In newly designated paragraph
(d)(8)(i)(C) revise the reference
‘‘(c)(8)(i)(B)’’ to read ‘‘(d)(8)(i)(B)’’.
I m. In newly designated paragraph
(d)(9)(ii)(B) revise the reference
‘‘(c)(9)(i)(B)’’ to read ‘‘(d)(9)(i)(B)’’.
I n. In newly designated paragraph
(d)(10)(v) revise the reference
‘‘(c)(10)(iv)’’ to read ‘‘(d)(10)(iv)’’.
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8543
o. In newly designated paragraph
(d)(11)(ii) revise the reference
‘‘(c)(11)(i)’’ to read ‘‘(d)(11)(i)’’.
I p. In newly designated paragraph
(d)(13)(v)(G) revise the reference
‘‘(c)(8)(i)’’ to read ‘‘(d)(8)(i)’’.
I
§ 80.68
Compliance surveys.
(a)(1) Beginning January 1, 2007, the
compliance surveys for NOX emissions
performance under this section shall
cease to be required.
(2) Beginning January 1, 2011, the
compliance surveys for toxics emissions
performance under this section shall
cease to be required.
*
*
*
*
*
Subpart E—[Amended]
6. Section 80.101 is amended by
adding paragraphs (c)(3) and (c)(4) to
read as follows:
I
§ 80.101 Standards applicable to refiners
and importers.
*
*
*
*
*
(c) * * *
(3)(i) The NOX emissions standard
specified in paragraph (b)(3)(i) of this
section shall no longer apply beginning
January 1, 2007, except as provided in
paragraph (c)(3)(ii) of this section.
(ii) For a refiner subject to the small
refiner gasoline sulfur standards at
§ 80.240, the NOX emissions standard
specified in paragraph (b)(3)(i) of this
section shall no longer apply beginning
January 1, 2008. For a refiner subject to
the gasoline sulfur standards at § 80.240
that has received an extension of its
small refiner gasoline sulfur standards
under § 80.553, the NOX emissions
standard specified in paragraph (b)(3)(i)
of this section shall no longer apply
beginning January 1, 2011.
(4)(i) Beginning January 1, 2011, or
January 1, 2015 for small refiners
approved under § 80.1340, the exhaust
toxics emissions standard specified in
paragraph (b)(3)(i) of this section shall
apply only to conventional gasoline that
is not subject to the benzene standard of
§ 80.1230, pursuant to the provisions of
§ 80.1235.
(ii) The exhaust toxic emissions
standard specified in paragraph (b)(3)(i)
of this section shall not apply to
conventional gasoline produced by a
refinery approved under § 80.1334,
pursuant to § 80.1334(c).
*
*
*
*
*
Subpart F—[Amended]
7. Section 80.128 is amended by
revising paragraph (a) to read as follows:
I
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
§ 80.128 Alternative agreed upon
procedures for refiners and importers.
*
*
*
*
*
(a) Read the refiner’s or importer’s
reports filed with EPA for the previous
year as required by §§ 80.75, 80.83(g),
80.105, 80.990 and 80.1354.
*
*
*
*
*
Subpart J—[Amended]
8. Section 80.815 is amended by
redesignating paragraph (d)(1) as
paragraph (d)(1)(i) and adding
paragraph (d)(1)(ii) to read as follows:
I
§ 80.815 What are the gasoline toxics
performance requirements for refiners and
importers?
*
*
*
*
*
(d) * * *
(1) * * *
(ii)(A) Beginning January 1, 2011, or
January 1, 2015 for small refiners
approved under § 80.1340, the gasoline
toxics performance requirements of this
subpart shall apply only to gasoline that
is not subject to the benzene standard of
§ 80.1230, pursuant to the provisions of
§ 80.1235.
(B) The gasoline toxics performance
requirements of this subpart shall not
apply to gasoline produced by a refinery
approved under § 80.1334, pursuant to
§ 80.1334(c).
*
*
*
*
*
I 9. Section 80.1035 is amended by
adding paragraph (h) to read as follows:
§ 80.1035 What are the attest engagement
requirements for gasoline toxics
compliance applicable to refiners and
importers?
*
*
*
*
*
(h) Beginning January 1, 2011, or
January 1, 2015 for small refiners
approved per § 80.1340, the
requirements of this section shall apply
only to gasoline that is not subject to the
benzene standard of § 80.1230, pursuant
to the provisions of § 80.1235.
I 10. Subpart L is added to read as
follows:
Subpart L—Gasoline Benzene
Sec.
80.1200–80.1219 [Reserved]
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General Information
80.1220 What are the implementation dates
for the gasoline benzene program?
80.1225 Who must register with EPA under
the gasoline benzene program?
Gasoline Benzene Requirements
80.1230 What are the gasoline benzene
requirements for refiners and importers?
80.1235 What gasoline is subject to the
benzene requirements of this subpart?
80.1236 What requirements apply to
California gasoline?
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80.1238 How is a refinery’s or importer’s
average benzene concentration
determined?
80.1240 How is a refinery’s or importer’s
compliance with the gasoline benzene
requirements of this subpart determined?
subpart and liability for violations of this
subpart?
80.1360 Who is liable for violations under
the gasoline benzene program?
80.1361 What penalties apply under the
gasoline benzene program?
Averaging, Banking and Trading (ABT)
Program
80.1270 Who may generate benzene credits
under the ABT program?
80.1275 How are early benzene credits
generated?
80.1280 How are refinery benzene baselines
calculated?
80.1285 How does a refiner apply for a
benzene baseline?
80.1290 How are standard benzene credits
generated?
80.1295 How are gasoline benzene credits
used?
Foreign Refiners
80.1363 What are the additional
requirements under this subpart for
gasoline produced at foreign refineries?
Hardship Provisions
80.1334 What are the requirements for early
compliance with the gasoline benzene
program?
80.1335 Can a refiner seek relief from the
requirements of this subpart?
80.1336 What if a refiner or importer cannot
produce gasoline conforming to the
requirements of this subpart?
Small Refiner Provisions
80.1338 What criteria must be met to
qualify as a small refiner for the gasoline
benzene requirements of this subpart?
80.1339 Who is not eligible for the
provisions for small refiners?
80.1340 How does a refiner obtain approval
as a small refiner?
80.1342 What compliance options are
available to small refiners under this
subpart?
80.1343 What hardship relief provisions are
available only to small refiners?
80.1344 What provisions are available to a
non-small refiner that acquires one or
more of a small refiner’s refineries?
Sampling, Testing and Retention
Requirements
80.1347 What are the sampling and testing
requirements for refiners and importers?
80.1348 What gasoline sample retention
requirements apply to refiners and
importers?
Recordkeeping and Reporting Requirements
80.1350 What records must be kept?
80.1352 What are the pre-compliance
reporting requirements for the gasoline
benzene program?
80.1354 What are the reporting
requirements for the gasoline benzene
program?
Attest Engagements
80.1356 What are the attest engagement
requirements for gasoline benzene
compliance?
Violations and Penalties
80.1358 What acts are prohibited under the
gasoline benzene program?
80.1359 What evidence may be used to
determine compliance with the
prohibitions and requirements of this
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Subpart L—Gasoline Benzene
§§ 80.1200–80.1219
[Reserved]
General Information
§ 80.1220 What are the implementation
dates for the gasoline benzene program?
(a) Benzene standard. (1) For the
annual averaging period beginning
January 1, 2011, and for each annual
averaging period thereafter, gasoline
produced at each refinery of a refiner or
imported by an importer, must meet the
benzene standard specified in
§ 80.1230(a), except as otherwise
specifically provided for in this subpart.
(2) For the period July 1, 2012 through
December 31, 2013, and for each annual
averaging period thereafter, gasoline
produced at each refinery of a refiner or
imported by an importer, must meet the
maximum average benzene standard
specified in § 80.1230(b), except as
otherwise specifically provided for in
this subpart.
(3) Small refiners approved under
§ 80.1340 may defer meeting the
benzene standard specified in
§ 80.1230(a) until the annual averaging
period beginning January 1, 2015 and
may defer meeting the benzene standard
specified in § 80.1230(b) until the
averaging period beginning July 1, 2016,
as described in § 80.1342.
(b) Early credit generation. (1)
Effective with the averaging period
beginning June 1, 2007, a refiner for
each of its refineries that has an
approved benzene baseline per
§ 80.1285 may generate early benzene
credits in accordance with the
provisions of § 80.1275.
(2) Early benzene credits may be
generated through the end of the
averaging period ending December 31,
2010, or through the end of the
averaging period ending December 31,
2014 for small refiners approved under
§ 80.1340.
(c) Standard credit generation. (1)
Effective with the annual averaging
period beginning January 1, 2011, a
refiner for any of its refineries or an
importer for its imported gasoline, may
generate standard benzene credits in
accordance with the provisions of
§ 80.1290.
(2) Effective with the annual
averaging period beginning January 1,
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2015, a small refiner approved under
§ 80.1340, for any of its refineries, may
generate standard benzene credits in
accordance with the provisions of
§ 80.1290.
§ 80.1225 Who must register with EPA
under the gasoline benzene program?
(a) Refiners and importers that are
registered by EPA under § 80.76,
§ 80.103, § 80.190, or § 80.810 are
deemed to be registered for purposes of
this subpart.
(b) Refiners and importers subject to
the requirements in § 80.1230 that are
not registered by EPA under §§ 80.76,
80.103, 80.190 or 80.810 shall provide
to EPA the information required in
§ 80.76 by September 30, 2010, or not
later than three months in advance of
the first date that such person produces
or imports gasoline, whichever is later.
(c) Refiners that plan to generate early
credits under § 80.1275 and that are not
registered by EPA under §§ 80.76,
80.103, 80.190, or 80.810 must provide
to EPA the information required in
§ 80.76 not later than 60 days prior to
the end of the first year of credit
generation.
Gasoline Benzene Requirements
pwalker on PROD1PC71 with RULES_2
§ 80.1230 What are the gasoline benzene
requirements for refiners and importers?
(a) Annual average benzene standard.
(1) Except as specified in paragraph (c)
of this section, a refinery’s or importer’s
average gasoline benzene concentration
in any annual averaging period shall not
exceed 0.62 volume percent.
(2) Compliance with the standard
specified in paragraph (a)(1) of this
section, or creation of a deficit in
accordance with paragraph (c) of this
section, is determined in accordance
with § 80.1240(a).
(3) The annual averaging period for
achieving compliance with the
requirement of paragraph (a)(1) of this
section is January 1 through December
31 of each calendar year beginning
January 1, 2011, or beginning January 1,
2015 for small refiners approved under
§ 80.1340.
(4) Refinery grouping per § 80.101(h)
does not apply to compliance with the
gasoline benzene requirement specified
in this paragraph (a).
(5) Gasoline produced at foreign
refineries that is subject to the gasoline
benzene requirements per § 80.1235
shall be included in the importer’s
compliance determination beginning
January 1, 2011, or beginning January 1,
2015 for small foreign refiners approved
under § 80.1340.
(b) Maximum average benzene
standard. (1) A refinery’s or importer’s
maximum average gasoline benzene
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Jkt 211001
concentration in any averaging period
shall not exceed 1.30 volume percent.
(2) Compliance with the standard
specified in paragraph (b)(1) of this
section is determined in accordance
with § 80.1240(b).
(3) The averaging period for achieving
compliance with the requirement of
paragraph (b)(1) of this section is July 1,
2012 through December 31, 2013 and
each calendar year thereafter, or July 1,
2016 through December 31, 2017, and
each calendar year thereafter for small
refiners approved under § 80.1340.
(c) Deficit carry-forward. (1) A
refinery or importer creates a benzene
deficit for a given averaging period
when its compliance benzene value, per
§ 80.1240(a), is greater than the benzene
standard specified in paragraph (a) of
this section.
(2) A refinery or importer may carry
the benzene deficit forward to the
calendar year following the year the
benzene deficit is created but only if no
deficit had been previously carried
forward to the year the deficit is created.
If a refinery or importer carries forward
a deficit, the following provisions apply
in the second year:
(i) The refinery or importer must
achieve compliance with the benzene
standard specified in paragraph (a) of
this section.
(ii) The refinery or importer must
achieve further reductions in its
gasoline benzene concentrations
sufficient to offset the benzene deficit of
the previous year.
(iii) Benzene credits may be used, per
§ 80.1295, to meet the requirements of
paragraphs (c)(2)(i) and (ii) of this
section.
(iv) A refinery that has banked credits
per § 80.1295(a)(3) must use all of its
banked credits to achieve compliance
with the benzene standard specified in
paragraph (a) of this section before
creating a deficit.
(3) EPA may allow an extended
period of deficit carry-forward if it
grants hardship relief under §§ 80.1335
or 80.1336 from the annual average
standard specified in paragraph (a) of
this section.
§ 80.1235 What gasoline is subject to the
benzene requirements of this subpart?
(a) For the purposes of determining
compliance with the requirements of
§ 80.1230, all of the following products
that are produced or imported for use in
the United States during a refinery’s or
importer’s applicable compliance period
are collectively ‘‘gasoline’’ and are to be
included in a refinery’s or importer’s
compliance determination under
§ 80.1240, except as provided in
paragraph (b) of this section:
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8545
(1) Reformulated gasoline.
(2) Conventional gasoline.
(3) Reformulated gasoline blendstock
for oxygenate blending (‘‘RBOB’’).
(4) Conventional gasoline blendstock
that becomes finished conventional
gasoline upon the addition of oxygenate
(‘‘CBOB’’).
(5) Blendstock that has been
combined with finished gasoline, other
blendstock, transmix, or gasoline
produced from transmix to produce
gasoline.
(6) Blendstock that has been
combined with previously certified
gasoline (‘‘PCG’’) to produce gasoline.
Such blendstock must be sampled in
accordance with the provisions at
§ 80.1347(a)(5).
(b) The following products are not to
be included in a refinery’s or importer’s
compliance determination under
§ 80.1240:
(1) Blendstock that has not been
combined with other blendstock or
finished gasoline to produce gasoline.
(2) Oxygenate added to finished
gasoline, RBOB, or CBOB downstream
of the refinery that produced the
gasoline or import facility where the
gasoline was imported.
(3) Butane added to finished gasoline,
RBOB, CBOB downstream of the
refinery that produced the gasoline or
import facility where the gasoline was
imported.
(4) Gasoline produced by separating
gasoline from transmix.
(5) PCG.
(6) Gasoline produced or imported for
use in Guam, American Samoa, and the
Commonwealth of the Northern Mariana
Islands.
(7) Gasoline exported for use outside
the United States.
(8) Gasoline produced by a small
refiner approved under § 80.1340 prior
to January 1, 2015, or prior to the small
refiner’s first compliance period
pursuant to § 80.1342(a), whichever is
earlier.
(9) Gasoline that is used to fuel
aircraft, racing vehicles or racing boats
that are used only in sanctioned racing
events, provided that —
(i) Product transfer documents
associated with such gasoline, and any
pump stand from which such gasoline
is dispensed, identify the gasoline either
as gasoline that is restricted for use in
aircraft, or as gasoline that is restricted
for use in racing motor vehicles or
racing boats that are used only in
sanctioned events;
(ii) The gasoline is completely
segregated from all other gasoline
throughout production, distribution and
sale to the ultimate consumer; and
(iii) The gasoline is not made
available for use as motor vehicle
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(a) Definition. For purposes of this
subpart, ‘‘California gasoline’’ means
any gasoline designated by the refiner or
importer as for use only in California
and that is actually used in California.
(b) California gasoline exemption.
California gasoline that complies with
all the requirements of this section is
exempt from the requirements in
§ 80.1230.
(c) Requirements for California
gasoline. The following requirements
apply to California gasoline:
(1) Each batch of California gasoline
must be designated as such by its refiner
or importer.
(2) Designated California gasoline
must be kept segregated from gasoline
that is not California gasoline at all
points in the distribution system.
(3) Designated California gasoline
must ultimately be used in the State of
California and not used elsewhere in the
United States.
(4) In the case of California gasoline
produced outside the State of California,
the transferors and transferees must
meet the product transfer document
requirements under § 80.81(g).
(5) Gasoline that is ultimately used in
any part of the United States outside of
the State of California must comply with
the requirements specified in § 80.1230,
regardless of any designation as
California gasoline.
§ 80.1238 How is a refinery’s or importer’s
average benzene concentration
determined?
(a) The average benzene concentration
of gasoline produced at a refinery or
imported by an importer for an
applicable averaging period is
calculated according to the following
equation:
n
∑(V × B )
i
Bavg =
i
i =1
n
∑V
i
pwalker on PROD1PC71 with RULES_2
i =1
Where:
Bavg = Average benzene concentration for the
applicable averaging period (volume
percent benzene).
i = Individual batch of gasoline produced at
the refinery or imported during the
applicable averaging period.
n = Total number of batches of gasoline
produced at the refinery or imported
during the applicable annual averaging
period.
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18:54 Feb 23, 2007
Jkt 211001
(b) A refiner or importer may include
the volume of oxygenate added
downstream from the refinery or import
facility in the calculation specified in
paragraph (a) of this section, provided
the following requirements are met:
(1) For oxygenate added to
conventional gasoline, the refiner or
importer must comply with the
requirements of § 80.101(d)(4)(ii) and
the calculation methodologies of
§ 80.101(g)(3).
(2) For oxygenate added to RBOB, the
refiner or importer must comply with
the requirements of § 80.69(a).
(c) Refiners and importers must
exclude from the calculation specified
in paragraph (a) of this section all of the
following:
(1) Gasoline that was not produced at
the refinery or imported by the
importer.
(2) Except as provided in paragraph
(b) of this section, any blendstocks or
unfinished gasoline transferred to
others.
(3) Gasoline that has been included in
the compliance calculations for another
refinery or importer.
(4) Gasoline exempted from the
standards under § 80.1235(b).
§ 80.1240 How is a refinery’s or importer’s
compliance with the gasoline benzene
requirements of this subpart determined?
(a) A refinery’s or importer’s
compliance with the annual average
benzene standard at § 80.1230(a) is
determined as follows:
(1)(i) The compliance benzene value
for a refinery or importer is:
Bavg , y
CBVy = Vy ×
+ D y −1 − BC − OC
100
Where:
CBVy = Compliance benzene value (gallons
benzene) for year y.
Vy = Gasoline volume produced or imported
in year y (gallons).
Bavg,y = Average benzene concentration in
year y (volume percent benzene),
calculated in accordance with § 80.1238.
Dy-1 = Benzene deficit from the previous
reporting period, per § 80.1230(c)
(gallons benzene).
BC = Banked benzene credits used to show
compliance (gallons benzene).
OC = Benzene credits obtained by the
refinery or importer used to show
compliance (gallons benzene).
(ii) Benzene credits used in the
calculation specified in paragraph
(a)(1)(i) of this section must be used in
accordance with the requirements at
§ 80.1295.
(2)(i) If CBVy ≤ Vy × (0.62)/100, then
compliance with the benzene
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requirement at § 80.1230(a) is achieved
for calendar year y.
(ii) If CBVy > Vy × (0.62)/100, then
compliance with the benzene
requirement at § 80.1230(a) is not
achieved for calendar year y, and a
deficit is created per § 80.1230(c). The
deficit value to be included in the
following year’s compliance calculation
per paragraph (a) of this section is
calculated as follows:
0.62
D y = CBVy − Vy ×
100
Where:
Dy = Benzene deficit created in compliance
period y (gallons benzene).
(b) Compliance with the maximum
average benzene standard at
§ 80.1230(b) is achieved by a refinery or
importer if the value of Bavg calculated
in accordance with § 80.1238(a) is no
greater 1.30 volume percent for an
applicable averaging period per
§ 80.1230(b)(3).
Averaging, Banking and Trading (ABT)
Program
§ 80.1270 Who may generate benzene
credits under the ABT program?
(a) Early benzene credits. Early
benzene credits are credits generated
prior to 2011, or prior to 2015 if
generated by a small refiner approved
under § 80.1340.
(1)(i) Early credits may be generated
under § 80.1275 by a refiner for any
refinery it owns that has an approved
benzene baseline under § 80.1285,
including a refinery of a foreign refiner
that is subject to the provisions of
§ 80.1363.
(ii) The refinery specified in
paragraph (a)(1)(i) of this section must
process crude oil and/or intermediate
feedstocks through refinery processing
units.
(iii) Early benzene credits shall be
calculated separately for each refinery of
a refiner.
(iv) A refinery that is approved for
early compliance under § 80.1334 may
not generate early credits for the
gasoline subject to the early compliance
provisions.
(2)(i) A refinery that was shut down
during the entire 2004–2005 benzene
baseline period is not eligible to
generate early credits under § 80.1275.
(ii) A refinery not in full production,
excluding normal refinery downtime, or
not showing consistent or regular
gasoline production activity during
2004–2005 may be eligible to generate
early benzene credits under § 80.1275
upon petition to and approval by EPA,
pursuant to § 80.1285(d).
E:\FR\FM\26FER2.SGM
26FER2
ER26FE07.014</MATH>
§ 80.1236 What requirements apply to
California gasoline?
Vi = Volume of gasoline in batch i (gallons).
Bi = Benzene concentration of batch i
(volume percent benzene), per § 80.46(e).
ER26FE07.013</MATH>
gasoline, or dispensed for use in motor
vehicles, except for motor vehicles used
only in sanctioned racing events.
(10) California gasoline, as defined in
§ 80.1236.
ER26FE07.012</MATH>
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Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 / Rules and Regulations
(a) For each averaging period per
paragraph (b) of this section in which a
refinery plans to generate early credits,
its average gasoline benzene
concentration calculated according to
§ 80.1238(a) must be at least 10% lower
than its benzene baseline concentration
approved under § 80.1280.
(b) The early credit averaging periods
are as follows:
(1) For 2007, the seven-month period
from June 1, 2007 through December 31,
2007.
(2) For 2008, 2009 and 2010, the 12month calendar year.
(3) For small refiners approved under
§ 80.1340, the 12-month calendar years
2011, 2012, 2013, and 2014 in addition
to the periods specified in paragraphs
(b)(1) and (b)(2) of this section.
(c) The number of early benzene
credits generated shall be calculated for
each applicable averaging period as
follows:
pwalker on PROD1PC71 with RULES_2
BBase − Bavg , y
EC y =
× Ve , y
100
Where:
ECy = Early credits generated in averaging
period y (gallons benzene).
BBase = Baseline benzene concentration of the
refinery (volume percent benzene), per
§ 80.1280(a).
Bavg,y = Average benzene concentration of
gasoline produced at the refinery during
averaging period y (volume percent
benzene), per § 80.1238.
Ve,y = Total volume of gasoline produced at
the refinery during averaging period y
(gallons).
(d) A refinery that plans to generate
early credits must also show that it has
met all of the following requirements
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§ 80.1280 How are refinery benzene
baselines calculated?
(a) A refinery’s benzene baseline is
based on the refinery’s 2004–2005
average gasoline benzene concentration,
calculated according to the following
equation:
n
∑(V × B )
i
BBase =
i
i =1
n
∑V
i
i =1
Where:
BBase = Benzene baseline concentration
(volume percent benzene).
i = Individual batch of gasoline produced at
the refinery from January 1, 2004
through December 31, 2005.
n = Total number of batches of gasoline
produced at the refinery from January 1,
2004 through December 31, 2005 (or the
total number of batches of gasoline
pursuant to § 80.1285(d)).
Vi = Volume of gasoline in batch i (gallons).
Bi = Benzene content of batch i (volume
percent benzene).
(b) A refiner for a refinery that
included oxygenate blended
downstream of the refinery in
compliance calculations for RFG or
conventional gasoline for calendar years
2004 or 2005 under § 80.69 or
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§ 80.101(d)(4) must include the volume
and benzene concentration of this
oxygenate in the benzene baseline
calculation for that refinery under
paragraph (a) of this section.
§ 80.1285 How does a refiner apply for a
benzene baseline?
(a) A benzene baseline application
must be submitted for each refinery that
plans to generate early credits under
§ 80.1275. The application must include
the information specified in paragraph
(c) of this section and must be submitted
to EPA at least 60 days before the first
averaging period in which the refinery
plans to generate early credits.
(b) For U.S. Postal delivery, the
benzene baseline application shall be
sent to: Attn: MSAT2 Benzene, Mail
Stop 6406J, U.S. Environmental
Protection Agency, 1200 Pennsylvania
Ave., NW., Washington, DC 20460. For
commercial delivery: MSAT2 Benzene,
202–343–9038, U.S. Environmental
Protection Agency, 1310 L Street, NW.,
Washington, DC 20005.
(c) The benzene baseline application
must include the following information:
(1) A listing of the names and
addresses of all refineries owned by the
company.
(2) The benzene baseline for gasoline
produced in 2004–2005 at the refinery,
calculated in accordance with § 80.1280.
(3) Copies of the annual reports
required under § 80.75 for RFG and
§ 80.105 for conventional gasoline.
(4) A letter signed by the president,
chief operating officer, or chief
executive officer, of the company, or
his/her designee, stating that the
information contained in the benzene
baseline determination is true to the
best of his/her knowledge.
(5) Name, address, phone number,
facsimile number and e-mail address of
a corporate contact person.
(d) For a refinery that may be eligible
to generate early credits under
§ 80.1270(a)(2)(ii), a refiner may submit
to EPA a benzene baseline application
per the requirements of this section. The
refiner must also submit information
regarding the nature and cause of the
refinery’s production activity that
resulted in irregular or less than full
production, how it affected the baseline
benzene concentration, and whether
and how an alternative calculation to
the calculation specified in § 80.1280
produces a more representative benzene
baseline value. Upon consideration of
the submitted information, EPA may
approve a benzene baseline for such a
refinery.
(e) EPA will notify the refiner of
approval of the refinery’s benzene
baseline or any deficiencies in the
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§ 80.1275 How are early benzene credits
generated?
prior to or during the first early credit
averaging period, per paragraph (b) of
this section, in which it generates early
credits:
(1) Since 2005, has made operational
changes and/or improvements in
benzene control technology to reduce
gasoline benzene levels, including at
least one of the following:
(i) Treating the heavy straight run
naphtha entering the reformer using
light naphtha splitting and/or
isomerization.
(ii) Treating the reformate stream
exiting the reformer using benzene
extraction or benzene saturation.
(iii) Directing additional refinery
streams to the reformer for treatment
described paragraphs (d)(1)(i) and (ii) of
this section.
(iv) Directing reformate streams to
other refineries with treatment
capabilities described in paragraph
(d)(1)(ii) of this section.
(2) Has not included gasoline
blendstock streams transferred to, from,
or between refineries, except as noted in
paragraph (d)(1)(iv) of this section.
(e) Early benzene credits calculated in
accordance with paragraph (c) of this
section shall be expressed to the nearest
gallon. Fractional values shall be
rounded down if less than 0.50, and
rounded up if greater than or equal to
0.50.
ER26FE07.015</MATH>
(3) Importers may not generate early
credits.
(b) Standard benzene credits.
Standard benzene credits are credits
generated after 2010, or after 2014 if
generated by a small refiner approved
under § 80.1340.
(1) Unless otherwise provided for
elsewhere in this subpart, standard
credits may be generated under
§ 80.1290 as follows:
(i) A refiner may generate standard
credits separately for each of its
refineries.
(ii) An importer may generate
standard credits for all of its imported
gasoline.
(2) Oxygenate blenders, butane
blenders, and transmix producers may
not generate standard credits.
(3) Foreign refiners may not generate
standard credits.
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§ 80.1290 How are standard benzene
credits generated?
(a) The standard credit averaging
periods are the calendar years beginning
January 1, 2011, or beginning January 1,
2015 for small refiners approved under
§ 80.1340.
(b) [Reserved]
(c)(1) The number of standard
benzene credits generated shall be
calculated annually for each applicable
averaging period according to the
following equation:
0.62 − Bavg , y
SC y =
× Vy
100
Where:
SCy = Standard credits generated in year y
(gallons benzene).
Bavg,y = Annual average benzene
concentration for year y (volume percent
benzene), per § 80.1238.
Vy = Total volume of gasoline produced or
imported in year y (gallons).
(2) No credits shall be generated
unless the value SCy is positive.
(d) Standard benzene credits
calculated in accordance with paragraph
(c) of this section shall be expressed to
the nearest gallon. Fractional values
shall be rounded down if less than 0.50,
and rounded up if greater than or equal
to 0.50.
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§ 80.1295 How are gasoline benzene
credits used?
(a) Credit use. (1) Gasoline benzene
credits may be used to comply with the
gasoline benzene standard of
§ 80.1230(a) provided that—
(i) The gasoline benzene credits were
generated according to §§ 80.1275 or
80.1290.
(ii) The recordkeeping requirements
for gasoline benzene credits under
§ 80.1350 are met.
(iii) The gasoline benzene credits are
correctly reported according to
§§ 80.1352 and 80.1354.
(iv) The conditions of this section are
met.
(2) Gasoline benzene credits generated
under §§ 80.1275 and 80.1290 may be
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used interchangeably in all credit use
scenarios, subject to the credit life
provisions specified in paragraph (c) of
this section.
(3) Gasoline benzene credits may be
used by a refiner or importer to comply
with the gasoline benzene content
standard of § 80.1230(a), may be banked
by a refiner or importer for future use
or transfer, may be transferred to
another refinery or importer within a
company (intracompany trading), or
may be transferred to another refiner or
importer outside of the company.
(b) Credit transfers. (1) Gasoline
benzene credits obtained from another
refinery or importer may be used to
comply with the gasoline benzene
content requirement of § 80.1230(a)
provided the following conditions are
met:
(i) The credits are generated and
reported according to the requirements
of this subpart, and the transferred
credits have not expired, per paragraph
(c) of this section.
(ii) Any credit transfer takes place no
later than the last day of February
following the calendar year averaging
period when the credits are used.
(iii) The credit has not been
transferred more than twice. The first
transfer by the refinery or importer that
generated the credit may only be made
to a refiner or importer that intends to
use the credit; if the transferee cannot
use the credit, it may make the second,
and final, transfer only to a refiner or
importer that intends to use or to
terminate the credit. In no case may a
credit be transferred more than twice
before being used or terminated.
(iv) The credit transferor has applied
any gasoline benzene credits necessary
to meet its own annual compliance
requirements (including any deficit
carried forward, pursuant to
§ 80.1230(c), if applicable) before
transferring any gasoline benzene
credits to any other refiner or importer.
(v) The credit transferor does not
create a deficit as a result of a credit
transfer.
(vi) The transferor supplies records to
the transferee indicating the year the
gasoline benzene credits were
generated, the identity of the refiner
(and refinery) or importer that generated
the gasoline benzene credits, and the
identity of the transferring entity if it is
not the same entity that generated the
gasoline benzene credits.
(2) In the case of gasoline benzene
credits that have been calculated or
created improperly, or that EPA has
otherwise determined to be invalid, the
following provisions apply:
(i) Invalid gasoline benzene credits
cannot be used to achieve compliance
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with the gasoline benzene content
requirement of § 80.1230(a), regardless
of the transferee’s good-faith belief that
the gasoline benzene credits were valid.
(ii) The refiner or importer that used
the gasoline benzene credits and any
transferor of the gasoline benzene
credits must adjust their credit records,
reports, and compliance calculations as
necessary to reflect the proper gasoline
benzene credits.
(iii) Any properly created gasoline
benzene credits existing in the
transferor’s credit balance following the
corrections and adjustments specified in
paragraph (b)(2)(ii) of this section must
first be applied to correct the invalid
transfers to the transferee, before the
transferor uses, trades or banks the
gasoline benzene credits.
(c) Credit life. (1)(i) Early credits, per
§ 80.1275, may be used for compliance
purposes under § 80.1240(a) for any of
the following annual averaging periods:
2011, 2102, 2013.
(ii) Early credits, per § 80.1275, may
be used for compliance purposes under
§ 80.1240(a) by small refiners approved
under § 80.1340 for any of the following
averaging periods: 2015, 2016, 2017.
(2)(i) Standard credits, per § 80.1290,
may be used for compliance purposes
under § 80.1240(a) within five years
from the year they were generated,
except as noted under paragraph
(c)(2)(ii) of this section. Example:
Standard credits generated during 2011
may be used to achieve compliance
under § 80.1240(a) for any calendar year
averaging period prior to the 2017
averaging period.
(ii) Standard credits, per § 80.1290,
may be used for compliance purposes
under § 80.1240(a) within seven years
from the year they were generated if
traded to and ultimately used by a small
refiner approved under § 80.1340.
Example: Standard credits generated in
2011 may be used to achieve
compliance under § 80.1240(a) for any
calendar year averaging period prior to
the 2019 averaging period if traded to
and ultimately used by a small refiner
approved under § 80.1340.
(d) Deficit provision limitation. A
refiner or importer possessing gasoline
benzene credits must use all gasoline
benzene credits in its possession before
applying the benzene deficit provisions
of § 80.1230(c).
Hardship Provisions
§ 80.1334 What are the requirements for
early compliance with the gasoline benzene
program?
(a)(1) A refinery may comply with the
benzene requirements at § 80.1230 for
its RFG and/or conventional gasoline
(CG) prior to the 2011 compliance
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application. However, except for
applications submitted in accordance
with paragraph (d) of this section, the
refinery’s benzene baseline application
may be considered approved 60 days
after EPA’s receipt of the baseline
application, subject to paragraph (f) of
this section.
(f) If at any time the baseline
submitted in accordance with the
requirements of this section is
determined to be incorrect, EPA will
notify the refiner of the corrected
baseline.
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period if it applies for this early
compliance option as specified in
paragraph (b) of this section, and is
approved by EPA.
(2) Only refineries that produce
gasoline by processing crude and/or
intermediate feedstocks through refinery
processing units may apply for this
early compliance option.
(b) Refiners must submit an
application in order to be considered for
early compliance as described in this
section.
(1) Applications for early compliance
as described in this section must be
submitted to EPA by December 31,
2007.
(2) Applications must be sent to: U.S.
EPA, NVFEL–ASD, Attn: MSAT2 Early
Compliance, 2000 Traverwood Dr., Ann
Arbor, MI 48105.
(3) Application must be made
separately for a refinery’s RFG and CG
pools.
(4) The early compliance application
must show that all the following criteria
are met:
(i) For an RFG early compliance
application—
(A) The refinery’s RFG baseline value
under § 80.915 is greater than or equal
to 30 percent reduction.
(B) The refinery’s 2003 RFG annual
average benzene concentration was less
than or equal to 0.62 vol%.
(C) The refinery’s 2003 RFG annual
average sulfur concentration was less
than or equal to 140 ppm.
(D) The refinery’s 2003 RFG annual
average MTBE concentration was greater
than or equal to 6 vol%.
(ii) For a CG early compliance
application—
(A) The refinery’s CG baseline under
§ 80.915 is less than or equal to 80 mg/
mile.
(B) The refinery’s 2003 CG annual
average benzene concentration was less
than or equal to 0.62 vol%.
(C) The refinery’s 2003 CG annual
average sulfur concentration was less
than or equal to 140 ppm.
(D) The refinery’s 2003 CG annual
average MTBE concentration was greater
than or equal to 6 vol%.
(5) In addition, the application must
demonstrate that the refinery has
extremely limited ability to adjust its
operations in order to comply with its
applicable RFG or CG toxics
performance requirements under
§ 80.815.
(6) The refiner must provide
additional information as requested by
EPA.
(c)(1) If approved for early compliance
with the provisions of this subpart, the
refinery may comply with the
provisions of § 80.1230 as follows:
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18:54 Feb 23, 2007
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(i) For the compliance period
beginning January 1, 2007, and each
annual compliance period through
2010; or
(ii) For the compliance period
beginning January 1, 2008, and each
annual compliance period through
2010.
(2) The refinery must notify EPA
under which compliance period
specified in paragraph (c)(1) of this
section it will begin compliance.
(3) Beginning with the compliance
period chosen pursuant to paragraph
(c)(2) of this section—
(i) For early compliance approved for
a refinery’s RFG pool, the toxics air
pollutants emissions performance
requirements specified in §§ 80.41(e)(1)
and (f)(1) and 80.815 shall not apply to
the reformulated gasoline produced by
the refinery.
(ii) For early compliance approved for
a refinery’s CG pool, the annual average
exhaust toxics emissions requirements
specified in §§ 80.101(c)(2) and 80.815
shall not apply to conventional gasoline
produced by the refinery.
(4) Refineries approved for early
compliance under this section may not
generate early credits under § 80.1275.
(d) If EPA finds that a refiner
provided false or inaccurate information
in its application for early compliance,
the early compliance approval will be
void ab initio.
§ 80.1335 Can a refiner seek relief from the
requirements of this subpart?
(a) A refiner may apply for relief from
the requirements specified in
§ 80.1230(a) or (b) for a refinery, if it can
show that—
(1) Unusual circumstances exist that
impose extreme hardship and
significantly affect the ability to comply
with the gasoline benzene standards at
§ 80.1230(a) or (b) by the applicable
date(s); and
(2) It has made best efforts to comply
with the requirements of this subpart.
(b) A refiner must apply for and be
approved for relief under this section.
(1) An application must include the
following information:
(i) A plan demonstrating how the
refiner will comply with the
requirements of § 80.1230(a) or (b), as
applicable, as expeditiously as possible.
The plan shall include a showing that
contracts are or will be in place for
engineering and construction of benzene
reduction technology, a plan for
applying for and obtaining any permits
necessary for construction, a description
of plans to obtain necessary capital, and
a detailed estimate of when the
requirements of § 80.1230(a) or (b), as
applicable, will be met.
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8549
(ii) A detailed description of the
refinery configuration and operations
including, at minimum, the following
information:
(A) The refinery’s total reformer unit
throughput capacity;
(B) The refinery’s total crude capacity;
(C) Total crude capacity of any other
refineries owned by the same entity;
(D) Total volume of gasoline
production at the refinery;
(E) Total volume of other refinery
products;
(F) Geographic location(s) where the
refinery’s gasoline will be sold;
(G) Detailed descriptions of efforts to
obtain capital for refinery investments;
(H) Bond rating of entity that owns
the refinery; and
(I) Estimated capital investment
needed to comply with the requirements
of this subpart.
(iii) For a hardship related to
complying with the requirement at
§ 80.1230(a), detailed descriptions of
efforts to obtain credits, including the
prices of credits available, but deemed
uneconomical by the refiner.
(2) Applicants must also provide any
other relevant information requested by
EPA.
(3) An application for relief from the
requirements specified in § 80.1230(b)
must be submitted to EPA by January 1,
2008, or by January 1, 2013 for small
refiners approved under § 80.1340.
(c)(1) Approval of a hardship
application under this section for relief
from the annual average benzene
standard at § 80.1230(a) shall be in the
form of an extended period of deficit
carry-forward, per § 80.1230(c), for such
period of time as EPA determines is
appropriate.
(2) Approval of a hardship application
under this section for relief from the
maximum average benzene standard at
§ 80.1230(b) shall be in the form of a
waiver of the standard for such period
of time as EPA determines is
appropriate.
(3) EPA may deny any application for
appropriate reasons, including
unacceptable environmental impact.
(d) EPA may impose any other
reasonable conditions on relief provided
under this section, including rescinding,
or reducing the length of, the extended
deficit carry-forward period if
conditions or situations change between
approval of the hardship application
and the end of the approved relief
period.
§ 80.1336 What if a refiner or importer
cannot produce gasoline conforming to the
requirements of this subpart?
In extreme, unusual, and unforeseen
circumstances (for example, a natural
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disaster or a refinery fire) that are
clearly outside the control of the refiner
or importer and that could not have
been avoided by the exercise of
prudence, diligence, and due care, EPA
may permit a refinery or importer to
exceed the allowable average benzene
levels specified in § 80.1230(a) or (b), as
applicable, if—
(a) It is in the public interest to do so;
(b) The refiner or importer exercised
prudent planning and was not able to
avoid the violation and has taken all
reasonable steps to minimize the extent
of the nonconformity;
(c) The refiner or importer can show
how the requirements at § 80.1230(a) or
(b), as applicable, will be achieved as
expeditiously as possible;
(d) The refiner or importer agrees to
make up any air quality detriment
associated with the nonconformity,
where practicable; and
(e) The refiner or importer pays to the
U.S. Treasury an amount equal to the
economic benefit of the nonconformity
minus the amount expended making up
the air quality detriment pursuant to
paragraph (d) of this section.
Small Refiner Provisions
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§ 80.1338 What criteria must be met to
qualify as a small refiner for the gasoline
benzene requirements of this subpart?
(a) A small refiner is any person that
demonstrates that it—
(1) Produced gasoline at a refinery by
processing crude oil through refinery
processing units from January 1, 2005
through December 31, 2005.
(2) Employed an average of no more
than 1,500 people, based on the average
number of employees for all pay periods
from January 1, 2005 through December
31, 2005.
(3) Had a corporate average crude oil
capacity less than or equal to 155,000
barrels per calendar day (bpcd) for 2005.
(4) Following the submission of a
small refiner application, pursuant to
§ 80.1340, has been approved as a small
refiner for this subpart.
(b) For the purpose of determining the
number of employees and the crude oil
capacity under paragraph (a) of this
section, the following determinations
shall be observed:
(1) The refiner shall include the
employees and crude oil capacity of any
subsidiary companies, any parent
company, subsidiaries of the parent
company in which the parent has a
controlling interest, and any joint
venture partners.
(2) For any refiner owned by a
governmental entity, the number of
employees and total crude oil capacity
as specified in paragraph (a) of this
section shall include all employees and
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18:54 Feb 23, 2007
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crude oil production of the government
to which the governmental entity is a
part.
(3) Any refiner owned and controlled
by an Alaska Regional or Village
Corporation organized pursuant to the
Alaska Native Claims Settlement Act (43
U.S.C. 1601) is not considered an
affiliate of such entity, or with other
concerns owned by such entity, solely
because of their common ownership.
(c) Notwithstanding the provisions of
paragraph (a) of this section, a refiner
that reactivates a refinery that it had
previously operated, and that was shut
down or non-operational for the entire
period between January 1, 2005 and
December 31, 2005, may apply for small
refiner status in accordance with the
provisions of § 80.1340.
§ 80.1339 Who is not eligible for the
provisions for small refiners?
The following are not eligible for the
hardship provisions for small refiners:
(a) A refiner with one or more
refineries built after December 31, 2005.
(b) A refiner that exceeds the
employee or crude oil capacity criteria
under § 80.1338 but that meets these
criteria after December 31, 2005,
regardless of whether the reduction in
employees or crude capacity is due to
operational changes at the refinery or a
company sale or reorganization.
(c) Importers.
(d) A refiner that produce gasoline
other than by processing crude oil
through refinery processing units.
(e)(1) A small refiner approved under
§ 80.1340 that subsequently ceases
production of gasoline from processing
crude oil through refinery processing
units, employs more than 1,500 people,
or exceeds the 155,000 bpcd crude oil
capacity limit after December 31, 2005
as a result of merger with or acquisition
of or by another entity, is disqualified as
a small refiner, except that this shall not
apply in the case of a merger between
two previously approved small refiners.
If disqualification occurs, the refiner
shall notify EPA in writing no later than
20 days following this disqualifying
event.
(2) Except as provided under
paragraph (e)(3) of this section, any
refiner whose status changes as
specified in paragraph (e)(1) under this
paragraph (b) shall meet the applicable
standards of § 80.1230 within 30 months
of the disqualifying event for all its
refineries. However, such period shall
not extend beyond December 31, 2014.
(3) A refiner may apply to EPA for an
additional six months to comply with
the standards of § 80.1230 if it believes
that more than 30 months will be
required for the necessary engineering,
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permitting, construction, and start-up
work to be completed. Such
applications must include detailed
technical information supporting the
need for additional time. EPA will base
its decision to approve additional time
on the information provided by the
refiner and on other relevant
information. In no case will EPA extend
the compliance date beyond December
31, 2014.
(4) During the period provided under
paragraph (e)(2) of this section, and any
extension provided under paragraph
(e)(3) of this section, the refiner may not
generate gasoline benzene credits under
§ 80.1275 or § 80.1290.
(f) A small refiner approved under
§ 80.1340 which notifies EPA that it
wishes to withdraw its small refiner
status pursuant to § 80.1340(g).
§ 80.1340 How does a refiner obtain
approval as a small refiner?
(a) Applications for small refiner
status must be submitted to EPA by
December 31, 2007.
(b) For U.S. Postal delivery,
applications for small refiner status
must be sent to: Attn: MSAT2 Benzene,
Mail Stop 6406J, U.S. Environmental
Protection Agency, 1200 Pennsylvania
Ave., NW., Washington, DC 20460. For
commercial delivery: MSAT2 Benzene,
202–343–9038, U.S. Environmental
Protection Agency, 1310 L Street, NW.,
Washington, DC 20005.
(c) The small refiner status
application must contain the following
information for the company seeking
small refiner status, and for all
subsidiary companies, all parent
companies, all subsidiaries of the parent
companies, and all joint venture
partners:
(1) Employees. For joint ventures, the
total number of employees includes the
combined employee count of all
corporate entities in the venture. For
government-owned refiners, the total
employee count includes all
government employees.
(i) Pursuant to paragraph (c) of this
section, a listing of each company
facility and each facility’s address
where any employee, as specified in
paragraph (a)(1) of this section, worked
during the 12 months preceding January
1, 2006.
(ii) The average number of employees
at each facility based upon the number
of employees for each pay period for the
12 months preceding January 1, 2006.
(iii) The type of business activities
carried out at each location.
(iv) In the case of a refiner that
reactivates a refinery that it previously
owned and operated and that was shut
down or non-operational between
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January 1, 2005 and January 1, 2006,
include the following:
(A) Pursuant to paragraph (c) of this
section, a listing of each company
refinery each refinery’s address where
any employee, as specified in paragraph
(a)(1) of this section, worked since the
refiner acquired or reactivated the
refinery.
(B) The average number of employees
at any such reactivated refinery during
each calendar year since the refiner
reactivated the refinery.
(C) The type of business activities
carried out at each location.
(2) Crude oil capacity.
(i) The total corporate crude oil
capacity of each refinery as reported to
the Energy Information Administration
(EIA) of the U.S. Department of Energy
(DOE), for the period January 1, 2005
through December 31, 2005.
(ii) The information submitted to EIA
is presumed to be correct. In cases
where a company disagrees with this
information, the company may petition
EPA with appropriate data to correct the
record when the company submits its
application for small refiner status.
(3) The type of business activity
carried out at each location.
(4) For each refinery, an indication of
the small refiner option(s), pursuant to
§ 80.1342, intended to be utilized at the
refinery.
(5) A letter signed by the president,
chief operating officer or chief executive
officer of the company, or his/her
designee, stating that the information
contained in the application is true to
the best of his/her knowledge, and that
the company owned the refinery as of
January 1, 2006.
(6) Name, address, phone number,
facsimile number, and e-mail address of
a corporate contact person.
(d) Approval of a small refiner status
application will be based on the
information submitted under paragraph
(c) of this section and any other relevant
information.
(e) EPA will notify a refiner of
approval or disapproval of small refiner
status by letter.
(1) If approved, all refineries of the
refiner may defer meeting the standard
specified in § 80.1230(a) until the
annual averaging period beginning
January 1, 2015, and the standard
specified in § 80.1230(b) until the
averaging period beginning July 1, 2016.
(2) If disapproved, all refineries of the
refiner must meet the standard specified
in § 80.1230(a) beginning with the
annual averaging period beginning
January 1, 2011, and must meet the
standard specified in § 80.1230(b)
beginning with the averaging period
beginning July 1, 2012.
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(f) If EPA finds that a refiner provided
false or inaccurate information on its
application for small refiner status, the
refiner’s small refiner status will be void
ab initio.
(g) Prior to January 1, 2014, and upon
notification to EPA, a small refiner
approved per this section may withdraw
its status as a small refiner. Effective on
January 1 of the year following such
notification, the small refiner will
become subject to the standards at
§ 80.1230.
§ 80.1342 What compliance options are
available to small refiners under this
subpart?
(a) A refiner that has been approved
as a small refiner under § 80.1340 may—
(1)(i) Defer meeting the standard
specified in § 80.1230(a) until the
annual averaging period beginning
January 1, 2015; or
(ii) Meet the standard specified in
§ 80.1230(a) in any annual averaging
period from 2011 through 2014,
inclusive, provided it notifies EPA in
writing no later than November 15 prior
to the year in which it will produce
compliant gasoline.
(2)(i) Defer meeting the standard
specified in § 80.1230(b) until the
averaging period beginning July 1, 2016;
or
(ii) Meet the standard specified in
§ 80.1230(b) in any averaging period
specified in § 80.1230(b)(3) prior to the
averaging period beginning July 1, 2016
provided it notifies EPA in writing no
later than November 15 prior to the year
in which it will produce compliant
gasoline.
(b) Any refiner that makes an election
under paragraphs (a)(1) or (a)(2) of this
section must comply with the
applicable benzene standards at
§ 80.1230 beginning with the first
averaging period subsequent to the
status change.
(c) The provisions of paragraph (a) of
this section shall apply separately for
each of an approved small refiner’s
refineries.
§ 80.1343 What hardship relief provisions
are available only to small refiners?
(a)(1) In the case of a small refiner
approved under § 80.1340 for which
compliance with the requirement at
§ 80.1230(a) would be feasible only
through the purchase of credits, but for
whom purchase of credits is not
practically or economically feasible,
EPA may approve a delay of the
requirements applicable to the first
compliance period for that refiner for up
to two years.
(2) No delay in accordance with
paragraph (a) of this section will be
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granted to any small refiner prior to the
EPA issuing a review of the credit
program.
(3) A small refiner may request one or
more extensions of an approved delay if
it can continue to demonstrate extreme
difficulty in achieving compliance,
through the use of credits, with the
annual average benzene standard at
§ 80.1230(a).
(b) In the case of a small refiner
approved under § 80.1340 for which
compliance with the maximum average
benzene requirement at § 80.1230(b) is
not feasible, the refiner may apply for
hardship relief under § 80.1335.
§ 80.1344 What provisions are available to
a non-small refiner that acquires one or
more of a small refiner’s refineries?
(a) In the case of a refiner that is not
an approved small refiner under
§ 80.1340 and that acquires a refinery
from a small refiner approved under
§ 80.1340, the small refiner provisions
of the gasoline benzene program of this
subpart continue to apply to the
acquired refinery for a period of up to
30 months from the date of acquisition
of the refinery. In no case shall this
period extend beyond December 31,
2014.
(b) A refiner may apply to EPA for up
to an additional six months to comply
with the standards of § 80.1230 for the
acquired refinery if it believes that more
than 30 months would be required for
the necessary engineering, permitting,
construction, and start-up work to be
completed. Such applications must
include detailed technical information
supporting the need for additional time.
EPA will base a decision to approve
additional time on information provided
by the refiner and on other relevant
information. In no case shall this period
extend beyond December 31, 2014.
(c) A refiner that acquires a refinery
from a small refiner approved per
§ 80.1340 shall notify EPA in writing no
later than 20 days following the
acquisition.
Sampling, Testing and Retention
Requirements
§ 80.1347 What are the sampling and
testing requirements for refiners and
importers?
(a) Sample and test each batch of
gasoline. (1) The sampling and testing
requirements specified in subpart D for
reformulated gasoline shall continue to
apply to reformulated gasoline and shall
be extended to conventional gasoline
(CG) for the purpose of complying with
the benzene requirements of this
subpart, except as modified by
paragraphs (a)(2), (a)(3) and (a)(4) of this
section.
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(2) Refiners and importers shall
collect a representative sample from
each batch of gasoline produced or
imported, according to the earliest
applicable date in the following
schedule:
(i) Beginning January 1, 2011;
(ii) Beginning January 1, 2015 for
small refiners approved under
§ 80.1340;
(iii) Beginning January 1 of the year
prior to 2015 in which a small refiner
approved under § 80.1340 has opted,
per § 80.1342(a), to begin meeting the
standards at § 80.1230;
(iv) Beginning June 1, 2007, for any
refinery planning to generate early
credits for the averaging period
specified at § 80.1275(b)(1);
(v) Beginning January 1 of each
averaging period specified at
§ 80.1275(b)(2) or (b)(3) for which the
refinery plans to generate early credits;
(vi) Beginning January 1 of the year,
per § 80.1334(c)(1), in which a refinery
approved for early compliance under
§ 80.1334 opts to begin early
compliance. The provisions shall only
apply to the type of gasoline, RFG or
CG, for which early compliance was
approved.
(3)(i) Each sample shall be tested in
accordance with the methodology
specified at § 80.46(e) to determine its
benzene concentration for compliance
with the requirements of this subpart.
(ii) Independent sample analysis,
under § 80.65(f), is not required for
conventional gasoline.
(4) Any refiner or importer may
release CG prior to obtaining the test
results for benzene required under
paragraph (a)(1) of this section.
(5) Exclusion of previously certified
gasoline.
(i) Any refiner who uses previously
certified reformulated or conventional
gasoline or RBOB to produce
conventional gasoline at a refinery, must
exclude the previously certified gasoline
(‘‘PCG’’) for purposes of demonstrating
compliance with the benzene standards
at § 80.1230.
(ii) To accomplish the exclusion
required in paragraph (a)(5)(i) of this
section, the refiner must determine the
volume and benzene content of the
previously certified gasoline used at the
refinery and the volume and benzene
content of gasoline produced at the
refinery, and use the compliance
calculation procedures in paragraphs
(a)(5)(iii) and (a)(5)(iv) of this section.
(iii) For each batch of previously
certified gasoline that is used to produce
conventional gasoline the refiner must
include the volume and benzene
content of the previously certified
gasoline as a negative volume and a
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negative benzene content in the refiner’s
compliance calculations in accordance
with the requirements at § 80.1238.
(iv) For each batch of conventional
gasoline produced at the refinery using
previously certified gasoline, the refiner
must determine the volume and
benzene content and include each batch
in the refinery’s compliance
calculations at § 80.1240 without regard
to the presence of previously certified
gasoline in the batch.
(v) The refiner must use any
previously certified gasoline that it
includes as a negative batch in its
compliance calculations pursuant to
§ 80.1240 as a component in gasoline
production during the annual averaging
period in which the previously certified
gasoline was included as a negative
batch in the refiner’s compliance
calculations.
(b) Batch numbering. The batch
numbering convention of § 80.365(b)
shall apply to batches of conventional
gasoline beginning with earliest
applicable date specified in paragraph
(a)(2) of this section.
§ 80.1348 What gasoline sample retention
requirements apply to refiners and
importers?
Beginning with earliest applicable
date specified in § 80.1347(a)(2), the
gasoline sample retention requirements
specified in subpart H of this part for
the gasoline sulfur provisions apply for
the purpose of complying with the
requirements of this subpart, except that
in addition to including the sulfur test
result as provided by § 80.335(a)(4)(ii),
the refiner, importer, or independent
laboratory shall also include with the
retained sample the test result for
benzene as conducted pursuant to
§ 80.46(e).
Recordkeeping and Reporting
Requirements
§ 80.1350
What records must be kept?
(a) General requirements. The
recordkeeping requirements specified in
§§ 80.74 and 80.104, as applicable,
apply for the purpose of complying with
the requirements of this subpart;
however, duplicate records are not
required.
(b) Additional records that refiners
and importers shall keep. (1) Beginning
with earliest applicable date specified in
§ 80.1347(a)(2), any refiner for each of
its refineries, and any importer for the
gasoline it imports, shall keep records
that include the following information,
as applicable:
(i) Its compliance benzene value per
§ 80.1240, and the calculations used to
obtain that value.
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(ii) Its benzene baseline value, per
§ 80.1280, if the refinery or importer
submitted a benzene baseline
application to EPA per § 80.1285.
(iii) The number of early benzene
credits generated under § 80.1275,
separately by year of generation.
(iv) The number of early benzene
credits obtained, separately by
generating refinery and year of
generation.
(v) The number of valid credits in
possession of the refinery or importer at
the beginning of each averaging period,
separately by generating facility and
year of generation.
(vi) The number of standard credits
generated by the refinery or importer
under § 80.1290, separately by transferor
(if applicable), by facility and by year of
generation.
(vii) The number of credits used,
separately by generating facility and
year of generation.
(viii) If any credits were obtained
from, or transferred to, other parties, for
each other party, its name, its EPA
refinery or importer registration
number, and the number of credits
obtained from, or transferred to, the
other party, and the price per credit.
(ix) The number of credits that
expired at the end of each averaging
period, separately by generating facility
and year of generation.
(x) The number of credits that will be
carried over into a subsequent averaging
period, separately by generating facility
and year of generation.
(xi) Contracts or other commercial
documents that establish each transfer
of credits from the transferor to the
transferee.
(xii) A copy of all reports submitted
to EPA under §§ 80.1352 and 80.1354;
however, duplicate records are not
required.
(2)(i) Beginning July 1, 2012, any
refiner for each of its refineries, and any
importer for the gasoline it imports,
shall include, in the records required by
paragraph (b)(1) of this section, its
maximum average benzene value for the
period July 1, 2012 through December
31, 2013, and for each annual
compliance period thereafter.
(ii) Notwithstanding the requirements
specified in paragraph (b)(2)(i) of this
section, beginning July 1, 2016, a small
refiner approved under § 80.1340, for
each of its refineries, shall include, in
the records required by paragraph (b)(1)
of this section, its maximum average
benzene value for the period July 1,
2016 through December 31, 2017, and
for each annual compliance period
thereafter.
(3) Records of all supporting
calculations pursuant to paragraphs
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(b)(1) or (b)(2) of this section shall also
be kept.
(c) Length of time records shall be
kept. Records required in this section
shall be kept for five years from the date
they were created, except that records
relating to credit transfers shall be kept
by the transferor for five years from the
date the credits were transferred, and
shall be kept by the transferee for five
years from the date the credits were
transferred, used or terminated,
whichever is later.
(d) Make records available to EPA. On
request by EPA, the records specified in
this section shall be provided to the
Administrator. For records that are
electronically generated or maintained,
the equipment and software necessary
to read the records shall be made
available, or upon approval by EPA,
electronic records shall be converted to
paper documents which shall be
provided to the Administrator.
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§ 80.1352 What are the pre-compliance
reporting requirements for the gasoline
benzene program?
(a) Except as provided in paragraph
(c) of this section, a refiner for each of
its refineries shall submit the following
information, as applicable, to EPA by
June 1, 2008 and annually thereafter
through June 1, 2011, or through June 1,
2015 for small refiners approved under
§ 80.1340:
(1) Changes to the information
submitted in the company’s registration;
(2) Changes to the information
submitted for any refinery or import
facility registration;
(3) Gasoline production.
(i) An estimate of the average daily
volume (in gallons) of gasoline
produced at each refinery. This estimate
shall include RFG, RBOB, conventional
gasoline and conventional gasoline
blendstock that becomes finished
gasoline solely upon the addition of
oxygenate but shall exclude gasoline
exempted pursuant to § 80.1235.
(ii) The volume estimates specified in
paragraph (a)(3)(i) of this section must
be provided for the periods of June 1,
2007 through December 31, 2007, and
calendar years 2008 through 2015.
(4) Benzene concentration. An
estimate of the average gasoline benzene
concentration corresponding to the time
periods specified in paragraph (a)(3)(ii)
of this section.
(5) ABT participation. For each year
through 2015, the following information
related to crdits shall be provided to
EPA, if applicable:
(i) If the refinery is expecting to
generate benzene credits per § 80.1275
and/or § 80.1290, the actual or
estimated, as applicable, numbers of
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early credits and standard credits
expected to be generated.
(ii) If the refinery is expecting to use
benzene credits per § 80.1295, the actual
or estimated, as applicable, numbers of
early credits and standard credits
expected to be banked, transferred or
used to achieve compliance in
accordance with § 80.1240.
(6) Information on any project
schedule by quarter of known or
projected completion date, by the stage
of the project. See, for example, the five
project phases described in EPA’s June
2002 Highway Diesel Progress Review
report (EPA420–R–02–016, https://
www.epa.gov/otaq/regs/hd2007/
420r02016.pdf): Strategic planning,
Planning and front-end engineering,
Detailed engineering and permitting,
Procurement and Construction, and
Commissioning and startup.
(7) Basic information regarding the
selected technology pathway for
compliance (e.g., precursor re-routing or
other technologies, revamp vs.
grassroots, etc.).
(8) Whether capital commitments
have been made or are projected to be
made.
(b) The pre-compliance reports due in
2008 and succeeding years must provide
an update of the progress in each of
these areas and include actual values
where available.
(c) The pre-compliance reporting
requirements of this section do not
apply to refineries that only produce
products exempt from the requirements
of this subpart per § 80.1235(b).
§ 80.1354 What are the reporting
requirements for the gasoline benzene
program?
(a) Beginning with earliest applicable
date specified in § 80.1347(a)(2), any
refiner for each of its refineries, and any
importer for the gasoline it imports,
shall submit to EPA an Annual Gasoline
Benzene Report that contains the
information required in this section, and
such other information as EPA may
require for each applicable averaging
period.
(b) The Annual Gasoline Benzene
Report shall contain the following
information:
(1) Benzene volume percent and
volume of any RFG, RBOB, and
conventional gasoline, separately by
batch, produced by the refinery or
imported, and the sum of the volumes
and the volume-weighted benzene
concentration, in volume percent.
(2)(i) The annual average benzene
concentration, per § 80.1238.
(ii) The maximum average benzene
concentration per § 80.1240(b).
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(3) Any benzene deficit from the
previous reporting period, per
§ 80.1230(b).
(4) The number of banked benzene
credits from the previous reporting
period.
(5) The number of benzene credits
generated under § 80.1275, if applicable.
(6) The number of benzene credits
generated under § 80.1290, if applicable.
(7) The number of benzene credits
transferred to the refinery or importer,
per § 80.1295(c), and the cost of the
credits, if applicable.
(8) The number of benzene credits
transferred from the refinery or
importer, per § 80.1295(c), and the price
of the credits, if applicable.
(9) The number of benzene credits
terminated or expired.
(10) The compliance benzene value
per § 80.1240.
(11) The number of banked benzene
credits.
(12) Projected credit generation
through compliance year 2015.
(13) Projected credit use through
compliance year 2015.
(c) EPA may require submission of
additional information to verify
compliance with the requirements of
this subpart.
(d) The report required by paragraph
(a) of this section shall be—
(1) Submitted on forms and following
procedures specified by the
Administrator.
(2) Submitted to EPA by the last day
of February each year for the prior
calendar year averaging period.
(3) Signed and certified as correct by
the owner or a responsible corporate
officer of the refiner or importer.
Attest Engagements
§ 80.1356 What are the attest engagement
requirements for gasoline benzene
compliance?
In addition to the requirements for
attest engagements that apply to refiners
and importers under §§ 80.125 through
80.130, 80.410, and 80.1030, the attest
engagements for refiners and importers
must include the following:
(a) EPA Early Credit Generation
Baseline Years’ Reports. (1) Obtain and
read a copy of the refinery’s or
importer’s annual reports and batch
reports filed with EPA for 2004 and
2005 that contain gasoline benzene and
gasoline volume information.
(2) Agree the yearly volumes of
gasoline and benzene concentration, in
volume percent and benzene gallons,
reported to EPA in the reports specified
in paragraph (a)(1) of this section with
the inventory reconciliation analysis
under § 80.128.
(3) Verify that the information in the
refinery’s or importer’s batch reports
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filed with EPA under §§ 80.75 and
80.105, and any laboratory test results,
agree with the information contained in
the reports specified in paragraph (a)(1)
of this section.
(4) Calculate the average benzene
concentration for all of the refinery’s or
importer’s gasoline volume over 2004
and 2005 and verify that those values
agree with the values reported to EPA
per § 80.1285.
(b) Baseline for Early Credit
Generation. Take the following steps for
the first attest reporting period
following approval of a benzene
baseline:
(1) Obtain the EPA benzene baseline
approval letter for the refinery to
determine the refinery’s applicable
benzene baseline under § 80.1285.
(2) Obtain a written statement from
the company representative identifying
the benzene value used as the refinery’s
baseline and agree that number to
paragraph (b)(1) of this section and to
the reports to EPA.
(c) Early Credit Generation. The
following procedures shall be
completed for a refinery or importer that
generates early benzene credits per
§ 80.1275:
(1) Obtain the baseline benzene
concentration and gasoline volume from
paragraph (a)(4) of this section.
(2) Obtain the annual benzene report
per § 80.1354.
(3) If the benzene value under
paragraph (c)(2) of this section is at least
10 percent less than the value in
paragraph (c)(1) of this section, compute
and report as a finding the difference
according to § 80.1275.
(4) Compute and report as a finding
the total number of benzene credits
generated by multiplying the value
calculated in paragraph (c)(3) of this
section by the volume of gasoline listed
in the report specified in paragraph
(c)(2) of this section, and agree this
number with the number reported to
EPA.
(d) Standard Credit Generation. The
following procedures shall be
completed for a refinery or importer that
generates benzene credits per § 80.1290:
(1) Obtain the annual average benzene
value from the annual benzene report
per § 80.1285.
(2) If the annual average benzene
value under paragraph (d)(1) of this
section is less than 0.62 percent by
volume, compute and report as a finding
the difference according to § 80.1290.
(3) Compute and report as a finding
the total number of benzene credits
generated by multiplying the value
calculated in paragraph (d)(2) of this
section by the volume of gasoline listed
in the report specified in paragraph
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(d)(1) of this section, and agree this
number with the number reported to
EPA.
(e) Credits Required. The following
attest procedures shall be completed for
refineries and importers:
(1) Obtain the annual average benzene
concentration and volume from the
annual benzene report per § 80.1285.
(2) If the value in paragraph (e)(1) of
this section is greater than 0.62 percent
by volume, compute and report as a
finding the difference between 0.62
percent by volume and the value in
paragraph (e)(1) of this section.
(3) Compute and report as a finding
the total benzene credits required by
multiplying the value in paragraph
(e)(2) of this section times the volume of
gasoline in paragraph (e)(1) of this
section, and agree this number with the
report to EPA.
(4) Obtain a statement from the refiner
or importer as to the portion of the
deficit under paragraph (e)(3) of this
section that was resolved with credits,
or that was carried forward as a deficit
under § 80.1230(b), and agree these
figures with the report to EPA.
(f) Credit Purchases and Sales. The
following attest procedures shall be
completed for a refinery or importer that
is a transferor or transferee of credits
during an averaging period:
(1) Obtain contracts or other
documents for all credits transferred to
another refinery or importer during the
year being reviewed; compute and
report as a finding the number and year
of creation of credits represented in
these documents as being transferred;
and agree these figures with the report
to EPA.
(2) Obtain contracts or other
documents for all credits received
during the year being reviewed;
compute and report as a finding the
number and year of creation of credits
represented in these documents as being
received; and agree with the report to
EPA.
(g) Credit Reconciliation. The
following attest procedures shall be
completed each year credits were in the
refiner’s or importer’s possession at any
time during the year:
(1) Obtain the credits remaining or the
credit deficit from the previous year
from the refiner’s or importer’s report to
EPA for the previous year.
(2) Compute and report as a finding
the net credits remaining at the
conclusion of the year being reviewed
by totaling credits as follows:
(i) Credits remaining from the
previous year; plus
(ii) Credits generated under
paragraphs (c) and (d) of this section;
plus
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(iii) Credits purchased under
paragraph (f) of this section; minus
(iv) Credits sold under paragraph (f) of
this section; minus
(v) Credits used under paragraphs (e)
of this section; minus
(vi) Credits expired; minus
(vii) Credit deficit from the previous
year.
(3) Agree the credits remaining or the
credit deficit at the conclusion of the
year being reviewed with the report to
EPA.
(4) If the refinery or importer had a
credit deficit for both the previous year
and the year being reviewed, report this
fact as a finding.
Violations and Penalties
§ 80.1358 What acts are prohibited under
the gasoline benzene program?
No person shall—
(a)(1) Produce or import gasoline
subject to this subpart that does not
comply with the applicable benzene
standards under § 80.1230.
(2) Fail to meet any other
requirements of this subpart.
(b) Cause another person to commit
an act in violation of paragraph (a) of
this section.
§ 80.1359 What evidence may be used to
determine compliance with the prohibitions
and requirements of this subpart and
liability for violations of this subpart?
(a) Compliance with the benzene
standards of this subpart shall be
determined based on the benzene
concentration of the gasoline, measured
using the methodologies specified in
§ 80.46(e), and other allowable
adjustments. Any evidence or
information, including the exclusive use
of such evidence or information, may be
used to establish the benzene
concentration of the gasoline if the
evidence or information is relevant to
whether the benzene concentration of
the gasoline would have been in
compliance with the standard if the
appropriate sampling and testing
methodologies had been correctly
performed. Such evidence may be
obtained from any source or location
and may include, but is not limited to,
test results using methods other than
those specified in § 80.46(e), business
records, and commercial documents.
(b) Determinations of compliance
with the requirements of this subpart
other than the benzene standards, and
determinations of liability for any
violation of this subpart, may be based
on information from any source or
location. Such information may include,
but is not limited to, business records
and commercial documents.
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§ 80.1360 Who is liable for violations
under the gasoline benzene program?
(a) The following persons are liable
for violations of prohibited acts:
(1) Any refiner or importer that
violates § 80.1358(a) is liable for the
violation.
(2) Any person that causes another
party to violate § 80.1358(a) is liable for
a violation of § 80.1358(b).
(3) Any parent corporation is liable
for any violations of this subpart that are
committed by any of its wholly-owned
subsidiaries.
(4) Each partner to a joint venture, or
each owner of a facility owned by two
or more owners, is jointly and severally
liable for any violation of this subpart
that occurs at the joint venture facility
or a facility that is owned by the joint
owners, or a facility that is committed
by the joint venture operation or any of
the joint owners of the facility.
(b) Any person who violates § 80.1358
is liable for the violation.
§ 80.1361 What penalties apply under the
gasoline benzene program?
(a) Any person liable for a violation
under § 80.1360 is subject to civil
penalties as specified in sections 205
and 211(d) of the Clean Air Act for
every day of each such violation and the
amount of economic benefit or savings
resulting from each violation.
(b) Any person liable under
§ 80.1358(a) and (b) for a violation of the
applicable benzene standards or causing
another person to violate the
requirements during any averaging
period, is subject to a separate day of
violation for each and every day in the
averaging period. Any person liable
under § 80.1360(b) for a failure to fulfill
any requirement of credit generation,
transfer, use, banking, or deficit carryforward correction is subject to a
separate violation for each and every
day in the averaging period in which
invalid credits are generated, banked,
transferred or used.
(c) Any person liable under
§ 80.1360(b) for failure to meet, or
causing a failure to meet, a provision of
this subpart is liable for a separate day
of violation for each and every day such
provision remains unfulfilled.
Foreign Refiners
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§ 80.1363 What are the additional
requirements under this subpart for
gasoline produced at foreign refineries?
(a) Definitions.
(1) A foreign refinery is a refinery that
is located outside the United States, the
Commonwealth of Puerto Rico, the
Virgin Islands, Guam, American Samoa,
and the Commonwealth of the Northern
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Mariana Islands (collectively referred to
in this section as ‘‘the United States’’).
(2) A foreign refiner is a person that
meets the definition of refiner under
§ 80.2(i) for a foreign refinery.
(3) Benzene-FRGAS means gasoline
produced at a foreign refinery that has
been assigned an individual refinery
benzene baseline under § 80.1285, has
been approved as a small refiner under
§ 80.1340, or has been granted
temporary relief under § 80.1335, and
that is imported into the United States.
(4) Non-Benzene-FRGAS means
(i) Gasoline meeting any of the
conditions specified in paragraph (a)(3)
of this section that is not imported into
the United States.
(ii) Gasoline meeting any of the
conditions specified in paragraph (a)(3)
of this section during a year when the
foreign refiner has opted to not
participate in the Benzene-FRGAS
program under paragraph (c)(3) of this
section.
(iii) Gasoline produced at a foreign
refinery that has not been assigned an
individual refinery benzene baseline
under § 80.1285, or that has not been
approved as a small refiner under
§ 80.1340, or that has not been granted
temporary relief under § 80.1335.
(5) Certified Benzene-FRGAS means
Benzene-FRGAS the foreign refiner
intends to include in the foreign
refinery’s benzene compliance
calculations under § 80.1240 or credit
calculations under § 80.1275 and does
include in these calculations when
reported to EPA.
(6) Non-Certified Benzene-FRGAS
means Benzene-FRGAS that is not
Certified Benzene-FRGAS.
(b) Baseline for Early Credits. For any
foreign refiner to obtain approval under
the benzene foreign refiner program of
this subpart for any refinery in order to
generate early credits under § 80.1275, it
must apply for approval under the
applicable provisions of this subpart.
(1) The refiner shall follow the
procedures specified in §§ 80.1280 and
80.1285 to establish a baseline of the
volume of gasoline that was produced at
the refinery and imported into the
United States during the applicable
years.
(2) In making determinations for
foreign refinery baselines EPA will
consider all information supplied by a
foreign refiner, and in addition may rely
on any and all appropriate assumptions
necessary to make such determinations.
(3) Where a foreign refiner submits a
petition that is incomplete or
inadequate to establish an accurate
baseline, and the refiner fails to correct
this deficiency after a request for more
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8555
information, EPA will not assign an
individual refinery baseline.
(c) General requirements for BenzeneFRGAS foreign refiners. A foreign
refiner of a refinery that is approved
under the benzene foreign refiner
program of this subpart must designate
each batch of gasoline produced at the
foreign refinery that is exported to the
United States as either Certified
Benzene-FRGAS or as Non-Certified
Benzene-FRGAS, except as provided in
paragraph (c)(3) of this section.
(1) In the case of Certified BenzeneFRGAS, the foreign refiner must meet
all requirements that apply to refiners
under this subpart.
(2) In the case of Non-Certified
Benzene-FRGAS, the foreign refiner
shall meet all the following
requirements:
(i) The designation requirements in
this section;
(ii) The recordkeeping requirements
in this section and in § 80.1350;
(iii) The reporting requirements in
this section and in §§ 80.1352 and
80.1354;
(iv) The product transfer document
requirements in this section;
(v) The prohibitions in this section
and in § 80.1358; and
(vi) The independent audit
requirements in this section and in
§ 80.1356.
(3)(i) Any foreign refiner that
generates early benzene credits under
§ 80.1275 shall designate all BenzeneFRGAS as Certified Benzene-FRGAS for
any year that such credits are generated.
(ii) Any foreign refiner that has been
approved to produce gasoline subject to
the benzene foreign refiner program for
a foreign refinery under this subpart
may elect to classify no gasoline
imported into the United States as
Benzene-FRGAS provided the foreign
refiner notifies EPA of the election no
later than November 1 preceding the
beginning of the next compliance
period.
(iii) An election under paragraph
(c)(3)(ii) of this section shall be for a 12
month compliance period and apply to
all gasoline that is produced by the
foreign refinery that is imported into the
United States, and shall remain in effect
for each succeeding year unless and
until the foreign refiner notifies EPA of
the termination of the election. The
change in election shall take effect at the
beginning of the next annual
compliance period.
(d) Designation, product transfer
documents, and foreign refiner
certification. (1) Any foreign refiner of a
foreign refinery that has been approved
by EPA to produce gasoline subject to
the benzene foreign refiner program
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must designate each batch of BenzeneFRGAS as such at the time the gasoline
is produced, unless the refiner has
elected to classify no gasoline exported
to the United States as Benzene-FRGAS
under paragraph (c)(3) of this section.
(2) On each occasion when any
person transfers custody or title to any
Benzene-FRGAS prior to its being
imported into the United States, it must
include the following information as
part of the product transfer document
information:
(i) Designation of the gasoline as
Certified Benzene-FRGAS or as NonCertified Benzene-FRGAS; and
(ii) The name and EPA refinery
registration number of the refinery
where the Benzene-FRGAS was
produced.
(3) On each occasion when BenzeneFRGAS is loaded onto a vessel or other
transportation mode for transport to the
United States, the foreign refiner shall
prepare a certification for each batch of
the Benzene-FRGAS that meets the
following requirements.
(i) The certification shall include the
report of the independent third party
under paragraph (f) of this section, and
the following additional information:
(A) The name and EPA registration
number of the refinery that produced
the Benzene-FRGAS;
(B) The identification of the gasoline
as Certified Benzene-FRGAS or NonCertified Benzene-FRGAS;
(C) The volume of Benzene-FRGAS
being transported, in gallons;
(D) In the case of Certified BenzeneFRGAS:
(1) The benzene content as
determined under paragraph (f) of this
section, and the applicable designations
stated in paragraph (d)(2)(i) of this
section; and
(2) A declaration that the BenzeneFRGAS is being included in the
applicable compliance calculations
required by EPA under this subpart.
(ii) The certification shall be made
part of the product transfer documents
for the Benzene-FRGAS.
(e) Transfers of Benzene-FRGAS to
non-United States markets. The foreign
refiner is responsible to ensure that all
gasoline classified as Benzene-FRGAS is
imported into the United States. A
foreign refiner may remove the BenzeneFRGAS classification, and the gasoline
need not be imported into the United
States, but only if:
(1) The foreign refiner excludes:
(i) The volume of gasoline from the
refinery’s compliance report under
§ 80.1354; and
(ii) In the case of Certified BenzeneFRGAS, the volume of the gasoline from
the compliance report under § 80.1354.
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(2) The foreign refiner obtains
sufficient evidence in the form of
documentation that the gasoline was not
imported into the United States.
(f) Load port independent sampling,
testing and refinery identification.
(1) On each occasion that BenzeneFRGAS is loaded onto a vessel for
transport to the United States a foreign
refiner shall have an independent third
party:
(i) Inspect the vessel prior to loading
and determine the volume of any tank
bottoms;
(ii) Determine the volume of BenzeneFRGAS loaded onto the vessel
(exclusive of any tank bottoms before
loading);
(iii) Obtain the EPA-assigned
registration number of the foreign
refinery;
(iv) Determine the name and country
of registration of the vessel used to
transport the Benzene-FRGAS to the
United States; and
(v) Determine the date and time the
vessel departs the port serving the
foreign refinery.
(2) On each occasion that Certified
Benzene-FRGAS is loaded onto a vessel
for transport to the United States a
foreign refiner shall have an
independent third party:
(i) Collect a representative sample of
the Certified Benzene-FRGAS from each
vessel compartment subsequent to
loading on the vessel and prior to
departure of the vessel from the port
serving the foreign refinery;
(ii) Determine the benzene content
value for each compartment using the
methodology as specified in § 80.46(e)
by one of the following:
(A) The third party analyzing each
sample; or
(B) The third party observing the
foreign refiner analyze the sample;
(iii) Review original documents that
reflect movement and storage of the
Certified Benzene-FRGAS from the
refinery to the load port, and from this
review determine:
(A) The refinery at which the
Benzene-FRGAS was produced; and
(B) That the Benzene-FRGAS
remained segregated from:
(1) Non-Benzene-FRGAS and NonCertified Benzene-FRGAS; and
(2) Other Certified Benzene-FRGAS
produced at a different refinery.
(3) The independent third party shall
submit a report:
(i) To the foreign refiner containing
the information required under
paragraphs (f)(1) and (f)(2) of this
section, to accompany the product
transfer documents for the vessel; and
(ii) To the Administrator containing
the information required under
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paragraphs (f)(1) and (f)(2) of this
section, within thirty days following the
date of the independent third party’s
inspection. This report shall include a
description of the method used to
determine the identity of the refinery at
which the gasoline was produced,
assurance that the gasoline remained
segregated as specified in paragraph
(n)(1) of this section, and a description
of the gasoline’s movement and storage
between production at the source
refinery and vessel loading.
(4) The independent third party must:
(i) Be approved in advance by EPA,
based on a demonstration of ability to
perform the procedures required in this
paragraph (f);
(ii) Be independent under the criteria
specified in § 80.65(f)(2)(iii); and
(iii) Sign a commitment that contains
the provisions specified in paragraph (i)
of this section with regard to activities,
facilities and documents relevant to
compliance with the requirements of
this paragraph (f).
(g) Comparison of load port and port
of entry testing. (1)(i) Any foreign refiner
and any United States importer of
Certified Benzene-FRGAS shall compare
the results from the load port testing
under paragraph (f) of this section, with
the port of entry testing as reported
under paragraph (o) of this section, for
the volume of gasoline and the benzene
content value; except as specified in
paragraph (g)(1)(ii) of this section.
(ii) Where a vessel transporting
Certified Benzene-FRGAS off loads this
gasoline at more than one United States
port of entry, and the conditions of
paragraph (g)(2)(i) of this section are met
at the first United States port of entry,
the requirements of paragraph (g)(2) of
this section do not apply at subsequent
ports of entry if the United States
importer obtains a certification from the
vessel owner that meets the
requirements of paragraph (s) of this
section, that the vessel has not loaded
any gasoline or blendstock between the
first United States port of entry and the
subsequent port of entry.
(2)(i) The requirements of this
paragraph (g)(2) apply if—
(A) The temperature-corrected
volumes determined at the port of entry
and at the load port differ by more than
one percent; or
(B) The benzene content value
determined at the port of entry is higher
than the benzene content value
determined at the load port, and the
amount of this difference is greater than
the reproducibility amount specified for
the port of entry test result by the
American Society of Testing and
Materials (ASTM) for the test method
specified at § 80.46(e).
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(ii) The United States importer and
the foreign refiner shall treat the
gasoline as Non-Certified BenzeneFRGAS, and the foreign refiner shall
exclude the gasoline volume from its
gasoline volumes calculations and
benzene standard designations under
this subpart.
(h) Attest requirements. Refiners, for
each annual compliance period, must
arrange to have an attest engagement
performed of the underlying
documentation that forms the basis of
any report required under this subpart.
The attest engagement must comply
with the procedures and requirements
that apply to refiners under §§ 80.125
through 80.130, § 80.1356, and other
applicable attest engagement provisions,
and must be submitted to the
Administrator of EPA for the prior
annual compliance period within the
time period required under § 80.130.
The following additional procedures
shall be carried out for any foreign
refiner of Benzene-FRGAS.
(1) The inventory reconciliation
analysis under § 80.128(b) and the
tender analysis under § 80.128(c) shall
include Non-Benzene-FRGAS.
(2) Obtain separate listings of all
tenders of Certified Benzene-FRGAS
and of Non-Certified Benzene-FRGAS,
and obtain separate listings of Certified
Benzene-FRGAS based on whether it is
small refiner gasoline, gasoline
produced through the use of credits, or
other applicable designation under this
subpart. Agree the total volume of
tenders from the listings to the gasoline
inventory reconciliation analysis in
§ 80.128(b), and to the volumes
determined by the third party under
paragraph (f)(1) of this section.
(3) For each tender under paragraph
(h)(2) of this section, where the gasoline
is loaded onto a marine vessel, report as
a finding the name and country of
registration of each vessel, and the
volumes of Benzene-FRGAS loaded onto
each vessel.
(4) Select a sample from the list of
vessels identified in paragraph (h)(3) of
this section used to transport Certified
Benzene-FRGAS, in accordance with the
guidelines in § 80.127, and for each
vessel selected perform the following:
(i) Obtain the report of the
independent third party, under
paragraph (f) of this section, and of the
United States importer under paragraph
(o) of this section.
(A) Agree the information in these
reports with regard to vessel
identification, gasoline volumes and
benzene content test results.
(B) Identify, and report as a finding,
each occasion the load port and port of
entry benzene content and volume
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results differ by more than the amounts
allowed in paragraph (g) of this section,
and determine whether the foreign
refiner adjusted its refinery calculations
as required in paragraph (g) of this
section.
(ii) Obtain the documents used by the
independent third party to determine
transportation and storage of the
Certified Benzene-FRGAS from the
refinery to the load port, under
paragraph (f) of this section. Obtain tank
activity records for any storage tank
where the Certified Benzene-FRGAS is
stored, and pipeline activity records for
any pipeline used to transport the
Certified Benzene-FRGAS, prior to being
loaded onto the vessel. Use these
records to determine whether the
Certified Benzene-FRGAS was produced
at the refinery that is the subject of the
attest engagement, and whether the
Certified Benzene-FRGAS was mixed
with any Non-Certified BenzeneFRGAS, Non-Benzene-FRGAS, or any
Certified Benzene-FRGAS produced at a
different refinery.
(5) Select a sample from the list of
vessels identified in paragraph (h)(3) of
this section used to transport Certified
and Non-Certified Benzene-FRGAS, in
accordance with the guidelines in
§ 80.127, and for each vessel selected
perform the following:
(i) Obtain a commercial document of
general circulation that lists vessel
arrivals and departures, and that
includes the port and date of departure
of the vessel, and the port of entry and
date of arrival of the vessel.
(ii) Agree the vessel’s departure and
arrival locations and dates from the
independent third party and United
States importer reports to the
information contained in the
commercial document.
(6) Obtain separate listings of all
tenders of Non-Benzene-FRGAS, and
perform the following:
(i) Agree the total volume and
benzene content of tenders from the
listings to the gasoline inventory
reconciliation analysis in § 80.128(b).
(ii) Obtain a separate listing of the
tenders under this paragraph (h)(6)
where the gasoline is loaded onto a
marine vessel. Select a sample from this
listing in accordance with the
guidelines in § 80.127, and obtain a
commercial document of general
circulation that lists vessel arrivals and
departures, and that includes the port
and date of departure and the ports and
dates where the gasoline was off loaded
for the selected vessels. Determine and
report as a finding the country where
the gasoline was off loaded for each
vessel selected.
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8557
(7) In order to complete the
requirements of this paragraph (h) an
auditor shall:
(i) Be independent of the foreign
refiner;
(ii) Be licensed as a Certified Public
Accountant in the United States and a
citizen of the United States, or be
approved in advance by EPA based on
a demonstration of ability to perform the
procedures required in §§ 80.125
through 80.130 and this paragraph (h);
and
(iii) Sign a commitment that contains
the provisions specified in paragraph (i)
of this section with regard to activities
and documents relevant to compliance
with the requirements of §§ 80.125
through 80.130 and this paragraph (h).
(i) Foreign refiner commitments. Any
foreign refiner shall commit to and
comply with the provisions contained
in this paragraph (i) as a condition to
being approved as a foreign refiner
under this subpart.
(1) Any United States Environmental
Protection Agency inspector or auditor
must be given full, complete and
immediate access to conduct
inspections and audits of the foreign
refinery.
(i) Inspections and audits may be
either announced in advance by EPA, or
unannounced.
(ii) Access will be provided to any
location where:
(A) Gasoline is produced;
(B) Documents related to refinery
operations are kept;
(C) Gasoline or blendstock samples
are tested or stored; and
(D) Benzene-FRGAS is stored or
transported between the foreign refinery
and the United States, including storage
tanks, vessels and pipelines.
(iii) Inspections and audits may be by
EPA employees or contractors to EPA.
(iv) Any documents requested that are
related to matters covered by
inspections and audits must be
provided to an EPA inspector or auditor
on request.
(v) Inspections and audits by EPA
may include review and copying of any
documents related to:
(A) Refinery baseline establishment, if
applicable, including the volume and
benzene content of gasoline; transfers of
title or custody of any gasoline or
blendstocks whether Benzene-FRGAS or
Non-Benzene-FRGAS, produced at the
foreign refinery during the period
January 1, 2004 through December 31,
2005, and any work papers related to
refinery baseline establishment;
(B) The volume and benzene content
of Benzene-FRGAS;
(C) The proper classification of
gasoline as being Benzene-FRGAS or as
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not being Benzene-FRGAS, or as
Certified Benzene-FRGAS or as NonCertified Benzene-FRGAS, and all other
relevant designations under this
subpart;
(D) Transfers of title or custody to
Benzene-FRGAS;
(E) Sampling and testing of BenzeneFRGAS;
(F) Work performed and reports
prepared by independent third parties
and by independent auditors under the
requirements of this section, including
work papers; and
(G) Reports prepared for submission
to EPA, and any work papers related to
such reports.
(vi) Inspections and audits by EPA
may include taking samples of gasoline,
gasoline additives or blendstock, and
interviewing employees.
(vii) Any employee of the foreign
refiner must be made available for
interview by the EPA inspector or
auditor, on request, within a reasonable
time period.
(viii) English language translations of
any documents must be provided to an
EPA inspector or auditor, on request,
within 10 working days.
(ix) English language interpreters
must be provided to accompany EPA
inspectors and auditors, on request.
(2) An agent for service of process
located in the District of Columbia shall
be named, and service on this agent
constitutes service on the foreign refiner
or any employee of the foreign refiner
for any action by EPA or otherwise by
the United States related to the
requirements of this subpart.
(3) The forum for any civil or criminal
enforcement action related to the
provisions of this section for violations
of the Clean Air Act or regulations
promulgated thereunder shall be
governed by the Clean Air Act,
including the EPA administrative forum
where allowed under the Clean Air Act.
(4) United States substantive and
procedural laws shall apply to any civil
or criminal enforcement action against
the foreign refiner or any employee of
the foreign refiner related to the
provisions of this section.
(5) Submitting a petition for
participation in the benzene foreign
refiner program or producing and
exporting gasoline under any such
program, and all other actions to comply
with the requirements of this subpart
relating to participation in any benzene
foreign refiner program, or to establish
an individual refinery gasoline benzene
baseline under this subpart constitute
actions or activities covered by and
within the meaning of the provisions of
28 U.S.C. 1605(a)(2), but solely with
respect to actions instituted against the
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foreign refiner, its agents and employees
in any court or other tribunal in the
United States for conduct that violates
the requirements applicable to the
foreign refiner under this subpart,
including conduct that violates the
False Statements Accountability Act of
1996 (18 U.S.C. 1001) and section
113(c)(2) of the Clean Air Act (42 U.S.C.
7413).
(6) The foreign refiner, or its agents or
employees, will not seek to detain or to
impose civil or criminal remedies
against EPA inspectors or auditors,
whether EPA employees or EPA
contractors, for actions performed
within the scope of EPA employment
related to the provisions of this section.
(7) The commitment required by this
paragraph (i) shall be signed by the
owner or president of the foreign refiner
business.
(8) In any case where Benzene-FRGAS
produced at a foreign refinery is stored
or transported by another company
between the refinery and the vessel that
transports the Benzene-FRGAS to the
United States, the foreign refiner shall
obtain from each such other company a
commitment that meets the
requirements specified in paragraphs
(i)(1) through (7) of this section, and
these commitments shall be included in
the foreign refiner’s petition to
participate in any benzene foreign
refiner program.
(j) Sovereign immunity. By submitting
a petition for participation in any
benzene foreign refiner program under
this subpart (and baseline, if applicable)
under this section, or by producing and
exporting gasoline to the United States
under any such program, the foreign
refiner, and its agents and employees,
without exception, become subject to
the full operation of the administrative
and judicial enforcement powers and
provisions of the United States without
limitation based on sovereign immunity,
with respect to actions instituted against
the foreign refiner, its agents and
employees in any court or other tribunal
in the United States for conduct that
violates the requirements applicable to
the foreign refiner under this subpart,
including conduct that violates the
False Statements Accountability Act of
1996 (18 U.S.C. 1001) and section
113(c)(2) of the Clean Air Act (42 U.S.C.
7413).
(k) Bond posting. Any foreign refiner
shall meet the requirements of this
paragraph (k) as a condition to approval
as benzene foreign refiner under this
subpart.
(1) The foreign refiner shall post a
bond of the amount calculated using the
following equation:
Bond = G × $0.01
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Where:
Bond = amount of the bond in U.S. dollars
G = the largest volume of gasoline produced
at the foreign refinery and exported to
the United States, in gallons, during a
single calendar year among the most
recent of the following calendar years,
up to a maximum of five calendar years:
the calendar year immediately preceding
the date the refinery’s baseline petition
is submitted, the calendar year the
baseline petition is submitted, and each
succeeding calendar year.
(2) Bonds shall be posted by:
(i) Paying the amount of the bond to
the Treasurer of the United States;
(ii) Obtaining a bond in the proper
amount from a third party surety agent
that is payable to satisfy United States
administrative or judicial judgments
against the foreign refiner, provided
EPA agrees in advance as to the third
party and the nature of the surety
agreement; or
(iii) An alternative commitment that
results in assets of an appropriate
liquidity and value being readily
available to the United States, provided
EPA agrees in advance as to the
alternative commitment.
(3) Bonds posted under this paragraph
(k) shall—
(i) Be used to satisfy any judicial
judgment that results from an
administrative or judicial enforcement
action for conduct in violation of this
subpart, including where such conduct
violates the False Statements
Accountability Act of 1996 (18 U.S.C.
1001) and section 113(c)(2) of the Clean
Air Act (42 U.S.C. 7413);
(ii) Be provided by a corporate surety
that is listed in the United States
Department of Treasury Circular 570
‘‘Companies Holding Certificates of
Authority as Acceptable Sureties on
Federal Bonds’’; and
(iii) Include a commitment that the
bond will remain in effect for at least
five years following the end of latest
annual reporting period that the foreign
refiner produces gasoline pursuant to
the requirements of this subpart.
(4) On any occasion a foreign refiner
bond is used to satisfy any judgment,
the foreign refiner shall increase the
bond to cover the amount used within
90 days of the date the bond is used.
(5) If the bond amount for a foreign
refiner increases, the foreign refiner
shall increase the bond to cover the
shortfall within 90 days of the date the
bond amount changes. If the bond
amount decreases, the foreign refiner
may reduce the amount of the bond
beginning 90 days after the date the
bond amount changes.
(l) [Reserved]
(m) English language reports. Any
report or other document submitted to
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EPA by a foreign refiner shall be in
English language, or shall include an
English language translation.
(n) Prohibitions. (1) No person may
combine Certified Benzene-FRGAS with
any Non-Certified Benzene-FRGAS or
Non-Benzene-FRGAS, and no person
may combine Certified Benzene-FRGAS
with any Certified Benzene-FRGAS
produced at a different refinery, until
the importer has met all the
requirements of paragraph (o) of this
section, except as provided in paragraph
(e) of this section.
(2) No foreign refiner or other person
may cause another person to commit an
action prohibited in paragraph (n)(1) of
this section, or that otherwise violates
the requirements of this section.
(o) United States importer
requirements. Any United States
importer shall meet the following
requirements:
(1) Each batch of imported gasoline
shall be classified by the importer as
being Benzene-FRGAS or as NonBenzene-FRGAS, and each batch
classified as Benzene-FRGAS shall be
further classified as Certified BenzeneFRGAS or as Non-Certified BenzeneFRGAS.
(2) Gasoline shall be classified as
Certified Benzene-FRGAS or as NonCertified Benzene-FRGAS according to
the designation by the foreign refiner if
this designation is supported by product
transfer documents prepared by the
foreign refiner as required in paragraph
(d) of this section, unless the gasoline is
classified as Non-Certified BenzeneFRGAS under paragraph (g) of this
section. Additionally, the importer shall
comply with all requirements of this
subpart applicable to importers.
(3) For each gasoline batch classified
as Benzene-FRGAS, any United States
importer shall perform the following
procedures.
(i) In the case of both Certified and
Non-Certified Benzene-FRGAS, have an
independent third party:
(A) Determine the volume of gasoline
in the vessel;
(B) Use the foreign refiner’s BenzeneFRGAS certification to determine the
name and EPA-assigned registration
number of the foreign refinery that
produced the Benzene-FRGAS;
(C) Determine the name and country
of registration of the vessel used to
transport the Benzene-FRGAS to the
United States; and
(D) Determine the date and time the
vessel arrives at the United States port
of entry.
(ii) In the case of Certified BenzeneFRGAS, have an independent third
party:
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(A) Collect a representative sample
from each vessel compartment
subsequent to the vessel’s arrival at the
United States port of entry and prior to
off loading any gasoline from the vessel;
(B) Obtain the compartment samples;
and
(C) Determine the benzene content
value of each compartment sample
using the methodology specified at
§ 80.46(e) by the third party analyzing
the sample or by the third party
observing the importer analyze the
sample.
(4) Any importer shall submit reports
within 30 days following the date any
vessel transporting Benzene-FRGAS
arrives at the United States port of entry:
(i) To the Administrator containing
the information determined under
paragraph (o)(3) of this section; and
(ii) To the foreign refiner containing
the information determined under
paragraph (o)(3)(ii) of this section, and
including identification of the port at
which the product was offloaded.
(5) Any United States importer shall
meet all other requirements of this
subpart for any imported gasoline that is
not classified as Certified BenzeneFRGAS under paragraph (o)(2) of this
section.
(p) Truck imports of Certified
Benzene-FRGAS produced at a foreign
refinery.
(1) Any refiner whose Certified
Benzene-FRGAS is transported into the
United States by truck may petition EPA
to use alternative procedures to meet the
following requirements:
(i) Certification under paragraph (d)(5)
of this section;
(ii) Load port and port of entry
sampling and testing under paragraphs
(f) and (g) of this section;
(iii) Attest under paragraph (h) of this
section; and
(iv) Importer testing under paragraph
(o)(3) of this section.
(2) These alternative procedures must
ensure Certified Benzene-FRGAS
remains segregated from Non-Certified
Benzene-FRGAS and from NonBenzene-FRGAS until it is imported
into the United States. The petition will
be evaluated based on whether it
adequately addresses the following:
(i) Provisions for monitoring pipeline
shipments, if applicable, from the
refinery, that ensure segregation of
Certified Benzene-FRGAS from that
refinery from all other gasoline;
(ii) Contracts with any terminals and/
or pipelines that receive and/or
transport Certified Benzene-FRGAS, that
prohibit the commingling of Certified
Benzene-FRGAS with any of the
following:
(A) Other Certified Benzene-FRGAS
from other refineries.
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(B) All Non-Certified BenzeneFRGAS.
(C) All Non-Benzene-FRGAS;
(iii) Procedures for obtaining and
reviewing truck loading records and
United States import documents for
Certified Benzene-FRGAS to ensure that
such gasoline is only loaded into trucks
making deliveries to the United States;
(iv) Attest procedures to be conducted
annually by an independent third party
that review loading records and import
documents based on volume
reconciliation, or other criteria, to
confirm that all Certified BenzeneFRGAS remains segregated throughout
the distribution system and is only
loaded into trucks for import into the
United States.
(3) The petition required by this
section must be submitted to EPA along
with the application for temporary
refiner relief individual refinery
benzene standard under this subpart.
(q) Withdrawal or suspension of
foreign refiner status. EPA may
withdraw or suspend a foreign refiner’s
benzene baseline or standard approval
for a foreign refinery where—
(1) A foreign refiner fails to meet any
requirement of this section;
(2) A foreign government fails to
allow EPA inspections as provided in
paragraph (i)(1) of this section;
(3) A foreign refiner asserts a claim of,
or a right to claim, sovereign immunity
in an action to enforce the requirements
in this subpart; or
(4) A foreign refiner fails to pay a civil
or criminal penalty that is not satisfied
using the foreign refiner bond specified
in paragraph (k) of this section.
(r) Early use of a foreign refiner
benzene baseline.
(1) A foreign refiner may begin using
an individual refinery benzene baseline
under this subpart before EPA has
approved the baseline, provided that:
(i) A baseline petition has been
submitted as required in paragraph (b)
of this section;
(ii) EPA has made a provisional
finding that the baseline petition is
complete;
(iii) The foreign refiner has made the
commitments required in paragraph (i)
of this section;
(iv) The persons that will meet the
independent third party and
independent attest requirements for the
foreign refinery have made the
commitments required in paragraphs
(f)(3)(iii) and (h)(7)(iii) of this section;
and
(v) The foreign refiner has met the
bond requirements of paragraph (k) of
this section.
(2) In any case where a foreign refiner
uses an individual refinery baseline
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before final approval under paragraph
(r)(1) of this section, and the foreign
refinery baseline values that ultimately
are approved by EPA are more stringent
than the early baseline values used by
the foreign refiner, the foreign refiner
shall recalculate its compliance, ab
initio, using the baseline values
approved by the EPA, and the foreign
refiner shall be liable for any resulting
violation of the requirements of this
subpart.
(s) Additional requirements for
petitions, reports and certificates. Any
petition for approval to produce
gasoline subject to the benzene foreign
refiner program, any alternative
procedures under paragraph (p) of this
section, any report or other submission
required by paragraph (c), (f)(2), or (i) of
this section, and any certification under
paragraph (d)(3) of this section shall
be—
(1) Submitted in accordance with
procedures specified by the
Administrator, including use of any
forms that may be specified by the
Administrator.
(2) Be signed by the president or
owner of the foreign refiner company, or
by that person’s immediate designee,
and shall contain the following
declaration:
I hereby certify: (1) That I have actual
authority to sign on behalf of and to bind
[insert name of foreign refiner] with regard to
all statements contained herein; (2) that I am
aware that the information contained herein
is being Certified, or submitted to the United
States Environmental Protection Agency,
under the requirements of 40 CFR part 80,
subpart L, and that the information is
material for determining compliance under
these regulations; and (3) that I have read and
understand the information being Certified or
submitted, and this information is true,
complete and correct to the best of my
knowledge and belief after I have taken
reasonable and appropriate steps to verify the
accuracy thereof. I affirm that I have read and
understand the provisions of 40 CFR part 80,
subpart L, including 40 CFR 80.1363 apply
to [insert name of foreign refiner]. Pursuant
to Clean Air Act section 113(c) and 18 U.S.C.
1001, the penalty for furnishing false,
incomplete or misleading information in this
certification or submission is a fine of up to
$10,000 U.S., and/or imprisonment for up to
five years.
PART 85—CONTROL OF AIR
POLLUTION FROM MOBILE SOURCES
11a. The authority citation for part 85
continues to read as follows:
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I
Authority: 42 U.S.C. 7401–7671q.
Subpart P—[Amended]
11b. Section 85.1515 is amended by
adding paragraphs (c)(2)(vii), (c)(2)(viii),
and (c)(8) to read as follows.
I
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§ 85.1515 Emission standards and test
procedures applicable to imported
nonconforming motor vehicles and motor
vehicle engines.
*
*
*
*
*
(c) * * *
(2) * * *
(vii) Nonconforming LDV/LLDTs
originally manufactured in OP years
2009 and later must meet the
evaporative emission standards in Table
S09–1 in 40 CFR 86.1811–09(e).
However, LDV/LLDTs originally
manufactured in OP years 2009 and
2010 and imported by ICIs who qualify
as small volume manufacturers as
defined in 40 CFR 86.1838–01 are
exempt from the LDV/LLDT evaporative
emission standards in Table S09–1 in 40
CFR 86.1811–09(e), but must comply
with the Tier 2 evaporative emission
standards in Table S04–3 in 40 CFR
86.1811–04(e).
(viii) Nonconforming HLDTs and
MDPVs originally manufactured in OP
years 2010 and later must meet the
evaporative emission standards in Table
S09–1 in 40 CFR 86.1811–09(e).
However, HLDTs and MDPVs originally
manufactured in OP years 2010 and
2011 and imported by ICIs, who qualify
as small volume manufacturers as
defined in 40 CFR 86.1838–01, are
exempt from the HLDTs and MDPVs
evaporative emission standards in Table
S09–1 in 40 CFR 86.1811–09(e), but
must comply with the Tier 2
evaporative emission standards in Table
S04–3 in 40 CFR 86.1811–04(e).
*
*
*
*
*
(8)(i) Nonconforming LDV/LLDTs
originally manufactured in OP years
2010 and later must meet the cold
temperature NHMC emission standards
in Table S10–1 in 40 CFR 86.1811–
10(g).
(ii) Nonconforming HLDTs and
MDPVs originally manufactured in OP
years 2012 and later must meet the cold
temperature NHMC emission standards
in Table S10–1 in 40 CFR 86.1811–
10(g).
(iii) ICIs, which qualify as small
volume manufacturers, are exempt from
the cold temperature NMHC phase-in
intermediate percentage requirements
described in 40 CFR 86.1811–10(g)(3).
See 40 CFR 86.1811–04(k)(5)(vi) and
(vii).
(iv) As an alternative to the
requirements of paragraphs (c)(8)(i) and
(ii) of this section, ICIs may elect to
meet a cold temperature NMHC family
emission level below the cold
temperature NMHC fleet average
standards specified in Table S10–1 of 40
CFR 86.1811–10 and bank or sell credits
as permitted in 40 CFR 86.1864–10. An
ICI may not meet a higher cold
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temperature NMHC family emission
level than the fleet average standards in
Table S10–1 of 40 CFR 86.1811–10 as
specified in paragraphs (c)(8)(i) and (ii)
of this section, unless it demonstrates to
the Administrator at the time of
certification that it has obtained
appropriate and sufficient NMHC
credits from another manufacturer, or
has generated them in a previous model
year or in the current model year and
not traded them to another
manufacturer or used them to address
other vehicles as permitted in 40 CFR
86.1864–10.
(v) Where an ICI desires to obtain a
certificate of conformity using a higher
cold temperature NMHC family
emission level than specified in
paragraphs (c)(8)(i) and (ii) of this
section, but does not have sufficient
credits to cover vehicles imported under
such certificate, the Administrator may
issue such certificate if the ICI has also
obtained a certificate of conformity for
vehicles certified using a cold
temperature NMHC family emission
level lower than that required under
paragraphs (c)(8)(i) and (ii) of this
section. The ICI may then import
vehicles to the higher cold temperature
NMHC family emission level only to the
extent that it has generated sufficient
credits from vehicles certified to a
family emission level lower than the
cold temperature NMHC fleet average
standard during the same model year.
(vi) ICIs using cold temperature
NMHC family emission levels higher
than the cold temperature NMHC fleet
average standards specified in
paragraphs (c)(8)(i) and (ii) of this
section must monitor their imports so
that they do not import more vehicles
certified to such family emission levels
than their available credits can cover.
ICIs must not have a credit deficit at the
end of a model year and are not
permitted to use the deficit carryforward
provisions provided in 40 CFR 86.1864–
10.
(vii) The Administrator may condition
the certificates of conformity issued to
ICIs as necessary to ensure that vehicles
subject to this paragraph (c)(8) comply
with the applicable cold temperature
NMHC fleet average standard for each
model year.
*
*
*
*
*
PART 86—CONTROL OF EMISSIONS
FROM NEW AND IN-USE HIGHWAY
VEHICLES AND ENGINES
12. The authority citation for part 86
continues to read as follows:
I
Authority: 42 U.S.C. 7401–7671q.
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Subpart H—[Amended]
13. Section 86.701–94 is amended by
revising paragraph (a) to read as follows:
I
§ 86.701–94
General applicability.
(a) The provisions of this subpart
apply to: 1994 through 2003 model year
Otto-cycle and diesel light-duty
vehicles; 1994 through 2003 model year
Otto-cycle and diesel light-duty trucks;
and 1994 and later model year Ottocycle and diesel heavy-duty engines;
and 2001 and later model year Ottocycle heavy-duty vehicles and engines
certified under the provisions of subpart
S of this part. The provisions of subpart
B of this part apply to this subpart. The
provisions of § 86.1811–04(a)(5) and (p)
apply to 2004 and later model year
light-duty vehicles, light-duty trucks,
and medium duty passenger vehicles.
*
*
*
*
*
Subpart S—[Amended]
14. Section 86.1803–01 is amended by
revising the definition of ‘‘Banking’’ and
adding the definition for ‘‘Fleet average
cold temperature NMHC standard’’ in
alphabetical order to read as follows:
I
§ 86.1803–01
Definitions.
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*
*
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*
Banking means one of the following:
(1) The retention of NOX emission
credits for complete heavy-duty vehicles
by the manufacturer generating the
emission credits, for use in future model
year certification programs as permitted
by regulation.
(2) The retention of cold temperature
non-methane hydrocarbon (NMHC)
emission credits for light-duty vehicles,
light-duty trucks, and medium-duty
passenger vehicles by the manufacturer
generating the emission credits, for use
in future model year certification
programs as permitted by regulation.
*
*
*
*
*
Fleet average cold temperature NMHC
standard means, for light-duty vehicles,
light-duty trucks and medium-duty
passenger vehicles, an NMHC cold
temperature standard imposed over an
individual manufacturer’s total 50-State
U.S. sales (or a fraction of total U.S.
sales during phase-in years), as ‘‘U.S.
sales’’ is defined to include all national
sales, including points-of-first sale in
California, of a given model year.
Manufacturers determine their
compliance with such a standard by
averaging, on a sales-weighted basis, the
individual NMHC ‘‘Family Emission
Limits’’ (FEL—as defined in this
subpart) to which light-duty vehicles,
light-duty trucks and medium-duty
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passenger vehicles were certified and
sold for that model year.
*
*
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*
I 15. Section 86.1805–04 is amended by
adding paragraph (g) to read as follows:
§ 86.1805–04
Useful life.
*
*
*
*
*
(g) Where cold temperature NMHC
standards are applicable, the useful life
requirement for compliance with the
cold temperature NMHC standard only
is as follows:
(1) For LDV/LLDTs, 10 years or
120,000 miles, whichever occurs first.
(2) For HLDT/MDPVs, 11 years or
120,000 miles, whichever occurs first.
I 16. A new § 86.1809–10 is added to
Subpart S to read as follows:
§ 86.1809–10
Prohibition of defeat devices.
(a) No new light-duty vehicle, lightduty truck, medium-duty passenger
vehicle, or complete heavy-duty vehicle
shall be equipped with a defeat device.
(b) The Administrator may test or
require testing on any vehicle at a
designated location, using driving
cycles and conditions that may
reasonably be expected to be
encountered in normal operation and
use, for the purposes of investigating a
potential defeat device.
(c) For cold temperature CO and cold
temperature NMHC emission control,
the Administrator will use a guideline
to determine the appropriateness of the
CO and NMHC emission control at
ambient temperatures between 25 °F
(the upper bound of the temperatue test
range) and 68 °F (the lower bound of the
FTP range). The guideline for CO
emission congruity across the
intermediate temperature range is the
linear interpolation between the CO
standard applicable at 25 °F and the CO
standard applicable at 68 °F. The
guideline for NMHC emission congruity
across the intermediate temperature
range is the linear interpolation between
the NMHC FEL pass limit (e.g. 0.3499
g/mi for a 0.3 g/mi FEL) applicable at
20 °F and the Tier 2 NMOG standard to
which the vehicle was certified at 68 °F,
where the intermediate temperature
NMHC level is rounded to the nearest
hundredth for comparison to the
interpolated line. For vehicles that
exceed this CO emissions guideline or
this NMHC emissions guideline upon
intermediate temperature cold testing:
(1) If the CO emission level is greater
than the 20 °F emission standard, the
vehicle will automatically be considered
to be equipped with a defeat device
without further investigation. If the
intermediate temperature NMHC
emission level, rounded to the nearest
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8561
hundredth, is greater than the 20 °F FEL
pass limit, the vehicle will be presumed
to have a defeat device unless the
manufacturer provides evidence to
EPA’s satisfaction that the cause of the
test result in question is not due to a
defeat device.
(2) If the CO emission level does not
exceed the 20 °F emission standard, the
Administrator may investigate the
vehicle design for the presence of a
defeat device under paragraph (d) of this
section. If the intermediate temperature
NMHC emission level, rounded to the
nearest hundredth, does not exceed the
20 °F FEL pass limit the Administrator
may investigate the vehicle design for
the presence of a defeat device under
paragraph (d) of this section.
(d) The following provisions apply for
vehicle designs designated by the
Administrator to be investigated for
possible defeat devices:
(1) The manufacturer must show to
the satisfaction of the Administrator that
the vehicle design does not incorporate
strategies that unnecessarily reduce
emission control effectiveness exhibited
during the Federal Test Procedure or
Supplemental Federal Test Procedure
(FTP or SFTP) when the vehicle is
operated under conditions that may
reasonably be expected to be
encountered in normal operation and
use.
(2) The following information
requirements apply:
(i) Upon request by the Administrator,
the manufacturer must provide an
explanation containing detailed
information regarding test programs,
engineering evaluations, design
specifications, calibrations, on-board
computer algorithms, and design
strategies incorporated for operation
both during and outside of the Federal
emission test procedure.
(ii) For purposes of investigations of
possible cold temperature CO or cold
temperature NMHC defeat devices
under this paragraph (d), the
manufacturer must provide an
explanation to show, to the satisfaction
of the Administrator, that CO emissions
and NMHC emissions are reasonably
controlled in reference to the linear
guideline across the intermediate
temperature range.
(e) For each test group of Tier 2 LDV/
LLDTs and HLDT/MDPVs and interim
non-Tier 2 LDV/LLDTs and HLDT/
MDPVs the manufacturer must submit,
with the Part II certification application,
an engineering evaluation
demonstrating to the satisfaction of the
Administrator that a discontinuity in
emissions of non-methane organic gases,
carbon monoxide, oxides of nitrogen
and formaldehyde measured on the
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Federal Test Procedure (subpart B of
this part) does not occur in the
temperature range of 20 to 86 °F. For
diesel vehicles, the engineering
evaluation must also include particulate
emissions.
I 17. A new § 86.1810–09 is added to
Subpart S to read as follows:
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§ 86.1810–09 General standards; increase
in emissions; unsafe condition; waivers.
Section 86.1810–09 includes text that
specifies requirements that differ from
§ 86.1810–01. Where a paragraph in
§ 86.1810–01 is identical and applicable
to § 86.1810–09, this may be indicated
by specifying the corresponding
paragraph and the statement
‘‘[Reserved]. For guidance see
§ 86.1810–01.’’ Where a corresponding
paragraph of § 86.1810–01 is not
applicable, this is indicated by the
statement ‘‘[Reserved].’’ This section
applies to model year 2009 and later
light-duty vehicles and light-duty trucks
fueled by gasoline, diesel, methanol,
ethanol, natural gas and liquefied
petroleum gas fuels. This section also
applies to MDPVs and complete heavyduty vehicles certified according to the
provisions of this subpart. Multi-fueled
vehicles (including dual-fueled and
flexible-fueled vehicles) must comply
with all requirements established for
each consumed fuel (or blend of fuels in
the case of flexible fueled vehicles). The
standards of this subpart apply to both
certification and in-use vehicles unless
otherwise indicated. This section also
applies to hybrid electric vehicles and
zero emission vehicles. Unless
otherwise specified, requirements and
provisions of this subpart applicable to
methanol fueled vehicles are also
applicable to Tier 2 and interim nonTier 2 ethanol fueled vehicles.
(a) through (e) [Reserved]. For
guidance see § 86.1810–01.
(f) Altitude requirements. (1) All
emission standards apply at low altitude
conditions and at high altitude
conditions, except for supplemental
exhaust emission standards, cold
temperature NMHC emission standards,
and the evaporative emission standards
as described in § 86.1811–09(e).
Supplemental exhaust emission
standards, as described in § 86.1811–
04(f), apply only at low altitude
conditions. Cold temperature NMHC
emission standards, as described in
§ 86.1811–10(g), apply only at low
altitude conditions. Tier 2 evaporative
emission standards apply at high
altitude conditions as specified in
§ 86.1810–01(f) and (j), and § 86.1811–
04(e).
(2) For vehicles that comply with the
cold temperature NMHC standards,
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manufacturers must submit an
engineering evaluation indicating that
common calibration approaches are
utilized at high altitudes. Any deviation
from low altitude emission control
practices must be included in the
auxiliary emission control device
(AECD) descriptions submitted at
certification. Any AECD specific to high
altitude must require engineering
emission data for EPA evaluation to
quantify any emission impact and
validity of the AECD.
(g) through (p) [Reserved]. For
guidance see § 86.1810–01.
I 18. Section 86.1811–04 is amended by
adding paragraphs (k)(5)(iv) through
(vii) and (q)(1)(vi) through (ix) to read as
follows:
§ 86.1811–04 Emission standards for lightduty vehicles, light-duty trucks and
medium-duty passenger vehicles.
*
*
*
*
*
(k) * * *
(5) * * *
(iv) Vehicles produced by small
volume manufacturers, as defined in
§ 86.1838–01, are exempt from the LDV/
LLDT evaporative emissions standards
in Table S09–1 of § 86.1811–09(e) for
model years 2009 and 2010, but must
comply with the Tier 2 evaporative
emission standards in Table S04–3 in
paragraph (e)(1) of this section for
model years 2009 and 2010.
(v) Vehicles produced by small
volume manufacturers, as defined in
§ 86.1838–01, are exempt from the
HLDT/MDPV evaporative emissions
standards in Table S09–1 of § 86.1811–
09(e) for model years 2010 and 2011,
but must comply with the Tier 2
evaporative emission standards in Table
S04–3 in paragraph (e)(1) of this section
for model years 2010 and 2011.
(vi) Small volume manufacturers, as
defined in § 86.1838–01, are exempt
from the LDV/LLDT cold temperature
NMHC phase-in requirements in Table
S10–1 of § 86.1811–10(g) for model
years 2010, 2011, and 2012, but must
comply with the 100% requirement for
2013 and later model years for cold
temperature NMHC standards.
(vii) Small volume manufacturers, as
defined in § 86.1838–01, are exempt
from the HLDT/MDPV cold temperature
NMHC phase-in requirements in Table
S10–1 of § 86.1811–10(g) for model
years 2012, 2013, and 2014, but must
comply with the 100% requirement for
2015 and later model years for cold
temperature NMHC standards.
*
*
*
*
*
(q) * * *
(1) * * *
(vi) Defer compliance with the LDV/
LLDT evaporative emissions standards
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in Table S09–1 of § 86.1811–09(e) until
2013, and defer 100% compliance with
the LDV/LLDT evaporative emissions
standards in Table S09–2 of § 86.1811–
09(e) until 2016. (The hardship relief
may be extended one additional model
year—two model years total.)
(vii) Defer compliance with the
HLDT/MDPV evaporative emissions
standards in Table S09–1 of § 86.1811–
09(e) until 2014, and defer 100%
compliance with the HLDT/MDPV
evaporative emissions standards in
Table S09–2 of § 86.1811–09(e) until
2016. (The hardship relief may be
extended one additional model year—
two model years total.)
(viii) Defer 100% compliance with the
LDV/LLDT cold temperature NMHC
standards in Table S10–X of § 86.1811–
10(g) until 2015. (The hardship relief
may be extended one additional model
year—two model years total.)
(ix) Defer 100% compliance with the
HLDT/MDPV cold temperature NMHC
standards in Table S10–X of § 86.1811–
10(g) until 2017. (The hardship relief
may be extended one additional model
year—two model years total.)
*
*
*
*
*
I 19. A new § 86.1811–09 is added to
Subpart S to read as follows:
§ 86.1811–09 Emission standards for lightduty vehicles, light-duty trucks and
medium-duty passenger vehicles.
Section 86.1811–09 includes text that
specifies requirements that differ from
§ 86.1811–04. Where a paragraph in
§ 86.1811–04 is identical and applicable
to § 86.1811–09, this may be indicated
by specifying the corresponding
paragraph and the statement
‘‘[Reserved]. For guidance see
§ 86.1811–04.’’ Where a corresponding
paragraph of § 86.1811–04 is not
applicable, this is indicated by the
statement ‘‘[Reserved].’’
(a) Applicability. (1) This section
contains regulations implementing
emission standards for all LDVs, LDTs
and MDPVs. This section applies to
2009 and later model year LDVs, LDTs
and MDPVs fueled by gasoline, diesel,
methanol, ethanol, natural gas and
liquefied petroleum gas fuels, except as
noted. Additionally, this section applies
to hybrid electric vehicles (HEVs) and
zero emission vehicles (ZEVs). Unless
otherwise specified, multi-fueled
vehicles must comply with all
requirements established for each
consumed fuel.
(2) through (4) [Reserved]. For
guidance see § 86.1811–04.
(5) The exhaust emission standards
and evaporative emission standards of
this section apply equally to
certification and in-use LDVs, LDTs and
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MDPVs, unless otherwise specified. See
paragraph (t) of this section for interim
evaporative emission in-use standards
that are different than the certification
evaporative emission standards
specified in paragraph (e) of this
section.
(b) through (d) [Reserved]. For
guidance see § 86.1811–04.
(e) Evaporative emission standards.
Evaporative emissions from gasolinefueled, natural gas-fueled, liquefied
petroleum gas-fueled, ethanol-fueled
and methanol-fueled vehicles must not
exceed the standards in this paragraph
(e). The standards apply equally to
certification and in-use vehicles.
(1) Diurnal-plus-hot soak evaporative
hydrocarbon standards. (i)
Hydrocarbons for LDV/LLDTs, HLDTs
and MDPVs that are gasoline-fueled,
dedicated natural gas-fueled, dedicated
liquefied petroleum gas-fueled,
dedicated ethanol-fueled, dedicated
8563
methanol-fueled and multi-fueled
vehicles when operating on gasoline
must not exceed the diurnal plus hot
soak standards shown in Table S09–1
for the full three diurnal test sequence
and for the supplemental two diurnal
test sequence. The standards apply
equally to certification and in-use
vehicles, except as otherwise specified
in paragraph (t) of this section. Table
S09–1 follows:
TABLE S09–1.—LIGHT-DUTY DIURNAL PLUS HOT SOAK EVAPORATIVE EMISSION STANDARDS
[grams per test]
Vehicle category
Model year
LDVs ............................................................................................................................................
LLDTs ..........................................................................................................................................
HLDTs ..........................................................................................................................................
MDPVs .........................................................................................................................................
(ii) Hydrocarbons for LDV/LLDTs,
HLDTs and MDPVs that are multi-fueled
vehicles operating on non-gasoline fuel
must not exceed the diurnal plus hot
soak standards shown in Table S09–2
for the full three diurnal test sequence
and for the supplemental two diurnal
test sequence. The standards apply
2009
2009
2010
2010
3 day
diurnal+hot
soak
0.50
0.65
0.90
1.00
Supplemental
2 day
diurnal+hot
soak
0.65
0.85
1.15
1.25
equally to certification and in-use
vehicles except as otherwise specified
in paragraph (t) of this section. Table
S09–2 follows:
TABLE S09–2.—LIGHT-DUTY DIURNAL PLUS HOT SOAK EVAPORATIVE EMISSION STANDARDS: NON-GASOLINE PORTION
OF MULTI-FUELED VEHICLES
[grams per test]
3 day
diurnal+hot
soak
Vehicle category
LDVs ........................................................................................................................................................................
LLDTs ......................................................................................................................................................................
HLDTs ......................................................................................................................................................................
MDPVs .....................................................................................................................................................................
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(iii) For multi-fueled vehicles
operating on non-gasoline fuel,
manufacturers must comply with the
phase-in requirements in Table S09–3 of
this paragraph for the evaporative
emission requirements specified in
Table S09–2 of this section. Phase-in
schedules are grouped together for LDV/
LLDTs and HLDT/MDPVs. These
requirements specify the minimum
percentage of the manufacturer’s LDV/
LLDT/HLDT/MDPV 50-State sales, by
model year, that must meet the
requirements for their full useful lives.
Table S09–3 follows:
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0.50
0.65
0.90
1.00
Supplemental
2 day
diurnal+hot
soak
0.65
0.85
1.15
1.25
low altitude testing in accordance with
California test conditions and test
procedures (in lieu of the evaporative
emission test condition and test
procedure requirements of subpart B of
this part).
HICLES
(f) through (s) [Reserved]. For
guidance see § 86.1811–04.
Percentage of
(t) Evaporative emission in-use
vehicles that
Model year
must meet evap- standards. (1) For LDVs and LLDTs
orative emission certified prior to the 2012 model year,
requirements
the Tier 2 LDV/LLDT evaporative
2012 ..................................
30 emissions standards in Table S04–3 of
2013 ..................................
60 § 86.1811–04(e) shall apply to in-use
2014 and subsequent .......
100 vehicles for only the first three model
years after an evaporative family is first
(2) through (6) [Reserved]. For
certified to the LDV/LLDT evaporative
guidance see § 86.1811–04.
emission standards in Table S09–1 of
(7) In cases where vehicles are
paragraph (e) of this section, as shown
certified to evaporative emission
in Table S09–4. For example,
standards in Tables S09–1 and S09–2 of evaporative families first certified to the
this section, the Administrator may
LDV/LLDT standards in Table S09–1 in
accept evaporative emissions data for
the 2011 model year must meet the Tier
TABLE S09–3.—PHASE-IN PERCENTAGES FOR LIGHT-DUTY DIURNAL
PLUS HOT SOAK EVAPORATIVE
EMISSION STANDARDS: NON-GASOLINE PORTION OF MULTI-FUELED VE-
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2 LDV/LLDT evaporative emission
standards (Table S04–3) in-use for 2011,
2012, and 2013 model year vehicles
(applying Tier 2 standards in-use is
limited to the first three years after
introduction of a vehicle).
(2) For HLDTs and MDPVs certified
prior to the 2013 model year, the Tier
2 HLDT/MDPV evaporative emissions
standards in Table S04–3 of § 86.1811–
04(e) shall apply to in-use vehicles for
only the first three model years after an
evaporative family is first certified to
the HLDT/MDPV evaporative emission
standards in Table S09–1 of paragraph
(e) of this section, as shown in Table
S09–5. For example, evaporative
families first certified to the HLDT/
MDPV standards in Table S09–1 in the
2012 model year must meet the Tier 2
HLDT/MDPV evaporative emission
standards (Table S04–3) in-use for 2012,
2013, and 2014 model year vehicles
(applying Tier 2 standards in-use is
limited to the first three years after
introduction of a vehicle).
(f) [Reserved]. For guidance see
TABLE S09–5—SCHEDULE FOR INUSE HLDT/MDPV DIURNAL PLUS § 86.1811–04.
(g) Cold temperature exhaust
HOT SOAK EVAPORATIVE EMISSION
emission standards. (1) Cold
STANDARDS
temperature CO standards. These cold
temperature CO standards are
2010
2011
2012 applicable only to gasoline fueled LDV/
Ts and MDPVs. Cold temperature CO
Models Years That
exhaust emission standards apply over
Tier 2 Standards
a useful life of 50,000 miles or 5 years
Apply to In-use
(whichever occurs first) as follows:
Vehicles ...............
2010
2011
2012
(i) For LDVs and LDT1s, the standard
2011
2012
2013
2012
2013
2014 is 10.0 grams per mile CO.
(ii) For LDT2s, LDT3s and LDT4s, and
MDPVs, the standard is 12.5 grams per
I 20. A new § 86.1811–10 is added to
mile CO.
Subpart S to read as follows:
(iii) These standards do not apply to
§ 86.1811–10 Emission standards for light- interim non-Tier 2 MDPVs.
(2) Cold temperature NMHC
duty vehicles, light-duty trucks and
standards. Full useful life fleet average
medium-duty passenger vehicles.
Section 86.1811–10 includes text that cold temperature NMHC standards are
applicable only to gasoline fueled LDV/
specifies requirements that differ from
§ 86.1811–04 and § 86.1811–09. Where a LLDTs and HLDT/MDPVs, and apply
paragraph in § 86.1811–04 or § 86.1811– equally to certification and in-use
except as otherwise specified in
09 is identical and applicable to
paragraph (u) of this section for in-use
§ 86.1811–10, this may be indicated by
specifying the corresponding paragraph standards for applicable phase-in
models. Testing with other fuels such as
TABLE S09–4.—SCHEDULE FOR INand the statement ‘‘[Reserved]. For
E85, or testing on diesel vehicles, is not
USE LDV/LLDT DIURNAL PLUS HOT guidance see § 86.1811–04’’ or
required. Multi-fuel, bi-fuel or dual-fuel
SOAK
EVAPORATIVE
EMISSION ‘‘[Reserved]. For guidance see
vehicles must comply with
§ 86.1811–09.’’ Where a corresponding
STANDARDS
paragraph of § 86.1811–04 or § 86.1811– requirements using gasoline only. For
LDV/LLDTs, the useful life is 120,000
Model Year of Intro2009
2010
2011 09 is not applicable, this is indicated by
miles or 10 years, whichever comes
duction
the statement ‘‘[Reserved].’’
first. For HLDT/MDPVs, the useful life
(a) [Reserved]. For guidance see
Models Years That
is 120,000 miles or 11 years, whichever
§ 86.1811–09.
Tier 2 Standards
comes first. There is not an intermediate
Apply to In-use
(b) through (d) [Reserved]. For
useful life standard for cold temperature
Vehicles ...............
2009
2010
2011 guidance see § 86.1811–04.
NMHC standards.
2010
2011
2012
(e) [Reserved]. For guidance see
(i) The standards are shown in the
2011
2012
2013
§ 86.1811–09.
following table:
Model Year of Introduction 2010
TABLE S10–1—FLEET AVERAGE COLD TEMPERATURE NMHC FULL USEFUL LIFE EXHAUST EMISSION STANDARDS
Cold temperature
NMHC salesweighted fleet
average standard
(grams/mile)
Vehicle weight category
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LDVs & LLDTs (≤6,000 lbs GVWR) ................................................................................................................................................
HLDTs (>6,000–8,500 lbs GVWR) & MDPVs (>8,500–10,000 lbs GVWR) ...................................................................................
(ii) The manufacturer must calculate
its fleet average cold temperature NMHC
emission level(s) as described in
§ 86.1864–10(m).
(iii) During a phase-in year, the
manufacturer must comply with the
fleet average standards for the required
phase-in percentage for that year as
specified in paragraph (g)(3) of this
section, or for the alternate phase-in
percentage as permitted under
paragraph (g)(4) of this section.
(iv) For model years prior to 2010
(LDV/LLDTs) and 2012 (HLDT/MDPVs),
where the manufacturer desires to bank
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19:58 Feb 23, 2007
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early NMHC credits as permitted under
§ 86.1864–10(o)(5), the manufacturer
must achieve a fleet average standard
below the applicable standard.
Manufacturers must determine
compliance with the cold temperature
NMHC fleet average standard according
to § 86.1864–10(o).
(3) Phase-in of the cold temperature
NMHC standards. Except as permitted
in § 86.1811–04(k)(5)(vi) and (vii)
regarding small volume manufacturers,
manufacturers must comply with the
phase-in requirements in Tables S10–2
and S10–3. Separate phase-in schedules
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0.3
0.5
are provided for LDV/LLDTs and for
HLDT/MDPVs. These requirements
specify the minimum percentage of the
manufacturer’s LDV/LLDT and HLDT/
MDPV 50-State sales, by model year,
that must meet the fleet average cold
temperature NMHC standard for their
full useful lives. LDVs and LLDTs must
be grouped together to determine
compliance with these phase-in
requirements, and HLDTs and MDPVs
must also be grouped together to
determine compliance with these phasein requirements. Tables S10–2 and S10–
3 follow:
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TABLE S10–2—PHASE-IN PERCENT- acceptable, except as prohibited in
AGES FOR LDV/LLDT COLD TEM- paragraphs (g)(4)(i) and (iii) of this
section. In addition, manufacturers
PERATURE NMHC REQUIREMENTS
electing to use an alternate phase-in
schedule for compliance with the cold
temperature NMHC exhaust emission
Model year
standards must ensure that the sum of
products is at least 100% for model
years 2010 and earlier for LDV/LLDTs.
2010 ......................................
25
2011 ......................................
50 For example, a phase-in schedule for
2012 ......................................
75 LDV/LLDTs of 5/10/10/45/80/100 that
2013 and subsequent ...........
100 begins in 2008 would calculate as
(6×5%) + (5×10%) + (4×10%) = 120%
and would be acceptable for 2008–2010.
TABLE S10–3—PHASE-IN PERCENT- The full phase-in would calculate as
AGES FOR HLDT/MDPV COLD TEM- (6×5%) + (5×10%) + (4×10%) + (3×45%)
PERATURE NMHC REQUIREMENTS
+ (2×80%) + (1×100%) = 515% and
would be acceptable for 2008–2013.
Percentage of
(B) For HLDT/MDPVs, if the sum of
HLDT/MDPVs products in paragraph (g)(4)(i) of this
Model year
that must meet
section is greater than or equal to 500%,
requirement
which is the sum of products from the
2012 ......................................
25 primary phase-in schedule (4×25% +
2013 ......................................
50 3×50% + 2×75% + 1×100% = 500%),
2014 ......................................
75 then the alternate phase-in schedule is
2015 and subsequent ...........
100 acceptable, except as prohibited in
paragraphs (g)(4)(i) and (iii) of this
(4) Alternate phase-in schedules for
section. In addition, manufacturers
cold temperature NMHC standards. (i)
electing to use an alternate phase-in
Manufacturers may apply for alternate
schedule for compliance with the cold
phase-in schedules that would still
temperature NMHC exhaust emission
result in 100% phase-in by 2013 and
standards must ensure that the sum of
2015, respectively, for LDV/LLDTs and
products is at least 100% for model
HLDT/MDPVs. An alternate phase-in
years 2012 and earlier for HLDT/
schedule submitted by a manufacturer is MDPVs. Alternately, if the sum of
subject to EPA approval. The alternate
products is greater than or equal to
phase-in will not be used to delay full
600%, then the alternate phase-in
implementation past the last year of the schedule is acceptable, except as
primary phase-in schedule (2013 for
prohibited in paragraphs (g)(4)(i) and
LDV/LLDTs, 2015 for HLDT/MDPVs).
(iii) of this section. If the sum of
An alternate phase-in schedule will be
products is greater than or equal to
acceptable if it satisfies the following
600%, then there are no requirements
conditions (where API = Anticipated
on the sum of products for model years
Phase-In percentage for the referenced
2012 and earlier.
model year):
(iii) Under an alternate phase-in
LDV/LLDTs:
schedule, the projected phase-in
(6×API2008) + (5×API2009) + (4×API2010) + percentage is not binding for a given
model year, provided the sums of the
(3×API2011) + (2×API2012) +
(1×API2013) ≥ 500%, and (6×API2008) actual phase-in percentages that occur
meet the appropriate total sums as
+ (5×API2009) + (4×API2010) ≥ 100%
required in the equations of paragraph
HLDT/MDPVs:
(6×API2010) + (5×API2011) + (4×API2012) + (g)(4)(i) of this section, and provided
that 100% actual compliance is reached
(3×API2013) + (2×API2014) +
(1×API2015) ≥ 500%, and (6×API2010) for the appropriate model year, either
+ (5×API2011) + (4×API2012) ≥ 100%, 2013 for LDV/LLDTs or 2015 for HLDT/
MDPVs.
or
(5) Manufacturers must determine
(6×API2010) + (5×API2011) + (4×API2012) + compliance with required phase-in
(3×API2013) + (2×API2014) +
schedules as follows:
(1×API2015) ≥ 600%
(i) Manufacturers must submit
(ii)(A) For LDV/LLDTs, if the sum of
information showing compliance with
products in paragraph (g)(4)(i) of this
all phase-in requirements of this section
section is greater than or equal to 500%, with their Part I applications as required
which is the sum of products from the
by § 86.1844(d)(13).
primary phase-in schedule (4×25% +
(ii) A manufacturer electing to use any
3×50% + 2×75% + 1×100% = 500%),
alternate phase-in schedule permitted
then the alternate phase-in schedule is
under this section must provide in its
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Percentage of
LDV/LLDTs
that must meet
requirement
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8565
Application for Certification for the first
year in which it intends to use such a
schedule, and in each succeeding year
during the phase-in, the intended phasein percentages for that model year and
the remaining phase-in years along with
the intended final sum of those
percentages as described in paragraph
(g)(4)(i) of this section. This information
may be included with the information
required under § 86.1844–01(d)(13). In
its year end annual reports, as required
under § 86.1844–01(e)(4), the
manufacturer must include sufficient
information so that the Administrator
can verify compliance with the alternate
phase-in schedule established under
paragraph (g)(4)(i) of this section.
(6)(i) Sales percentages for the
purpose of determining compliance
with the phase-in of the cold
temperature NMHC requirements must
be based upon projected 50-State sales
of LDV/LLDTs and HLDT/MDPVs of the
applicable model year by the
manufacturer to the point of first sale.
Such sales percentages must be rounded
to the nearest 0.1 percent.
(ii) Alternatively, the manufacturer
may petition the Administrator to allow
actual volume produced for U.S. sales to
be used in lieu of projected U.S. sales
for purposes of determining compliance
with the phase-in percentage
requirements under this section. The
manufacturer must submit its petition
within 30 days of the end of the model
year. For EPA to approve the use of
actual volume produced for U.S. sales,
the manufacturer must establish to the
satisfaction of the Administrator, that
actual production volume is
functionally equivalent to actual sales
volume of LDV/LLDTs and HLDT/
MDPVs sold in all 50 U.S. States.
(h) through (s) [Reserved]. For
guidance see § 86.1811–04.
(t) [Reserved]. For guidance see
§ 86.1811–09.
(u) Cold temperature NMHC exhaust
emission in-use standards for applicable
phase-in models. An interim full useful
life in-use compliance standard is
calculated by adding 0.1 g/mi to the FEL
to which each test group is newly
certified, and applies to that test group
only for the model years shown in
Tables S10–4 and S10–5. Otherwise, the
in-use standard is the certification
standard from paragraph (g)(2) of this
section. The standards apply for
purposes of in-use testing only and does
not apply to certification or Selective
Enforcement Auditing. Tables S10–4
and S10–5 follow:
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TABLE S10–4.—IN-USE STANDARDS FOR APPLICABLE PHASE-IN LDV/LLDTS
Model Year of Introduction
2008
2009
2010
2011
2012
2013
Models years that the interim in-use standard is available .........................................................
2008
2009
2010
2011
2009
2010
2011
2012
2010
2011
2012
2013
2011
2012
2013
2012
2013
2014
2013
2014
TABLE S10–5.—IN-USE STANDARDS FOR APPLICABLE PHASE-IN HLDT/MDPVS
Model Year of Introduction
2010
2011
2012
2013
2014
2015
Models years that the interim in-use standard is available .........................................................
2010
2011
2012
2013
2011
2012
2013
2014
2012
2013
2014
2015
2013
2014
2015
2014
2015
2016
2015
2016
21. Section 86.1823–01 is amended by
revising paragraph (a)(3)(i)(C) to read as
follows:
I
§ 86.1823–01 Durability demonstration
procedures for exhaust emissions.
pwalker on PROD1PC71 with RULES_2
*
*
*
*
*
(a) * * *
(3) * * *
(i) * * *
(C) The DF calculated by these
procedures will be used for determining
compliance with FTP exhaust emission
standards, SFTP exhaust emission
standards, cold temperature NMHC
emission standards, and cold
temperature CO emission standards. At
the manufacturer’s option and using
procedures approved by the
Administrator, a separate DF may be
calculated exclusively using cold
temperature CO test data to determine
compliance with cold temperature CO
emission standards. Similarly, at the
manufacturer’s option and using
procedures approved by the
Administrator, a separate DF may be
calculated exclusively using cold
temperature NMHC test data to
determine compliance with cold
temperature NMHC emission standards.
For determining compliance with full
useful life cold temperature NMHC
emission standards, the 68–86 °F
120,000 mile full useful life NMOG DF
may be used. Also at the manufacturer’s
option and using procedures approved
by the Administrator, a separate DF may
be calculated exclusively using US06
and/or air conditioning (SC03) test data
to determine compliance with the SFTP
emission standards.
*
*
*
*
*
I 22. Section 86.1827–01 is amended by
revising paragraph (a)(5) to read as
follows:
§ 86.1827–01
*
*
*
(a) * * *
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*
*
18:54 Feb 23, 2007
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(5) Subject to the same emission
standards (or FEL in the case of cold
temperature NMHC standards), except
that a manufacturer may request to
group vehicles into the same test group
as vehicles subject to more stringent
standards, so long as all the vehicles
within the test group are certified to the
most stringent standards applicable to
any vehicle within that test group.
Light-duty trucks subject to the same
emission standards as light-duty
vehicles, with the exception of the lightduty truck idle CO standard and/or total
HC standard, may be included in the
same test group.
*
*
*
*
*
I 23. A new § 86.1828–10 is added to
Subpart S to read as follows:
§ 86.1828–10
selection.
Emission data vehicle
Section 86.1828–10 includes text that
specifies requirements that differ from
§ 86.1828–01. Where a paragraph in
§ 86.1828–01 is identical and applicable
to § 86.1828–10, this may be indicated
by specifying the corresponding
paragraph and the statement
‘‘[Reserved]. For guidance see
§ 86.1828–01.’’ Where a corresponding
paragraph of § 86.1828–01 is not
applicable, this is indicated by the
statement ‘‘[Reserved].’’
(a) through (f) [Reserved]. For
guidance see § 86.1828–01.
(g) Cold temperature NMHC testing.
For cold temperature NMHC exhaust
emission compliance for each durability
group, the manufacturer must select the
vehicle expected to emit the highest
NMHC emissions at 20 °F on candidate
in-use vehicles from the test vehicles
specified in § 86.1828–01(a). When the
expected worst-case cold temperature
NMHC vehicle is also the expected
worst-case cold temperature CO vehicle
as selected in paragraph (c) of this
section, then cold testing is required
only for that vehicle; otherwise, testing
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is required for both the worst-case cold
temperature CO vehicle and the worstcase cold temperature NMHC vehicle.
I 24. Section 86.1829–01 is amended by
revising paragraph (b)(3) to read as
follows:
§ 86.1829–01 Durability and emission
testing requirements; waivers.
*
*
*
*
*
(b) * * *
(3) Cold temperature CO and cold
temperature NMHC Testing. The
manufacturer must test one EDV in each
durability group for cold temperature
CO and cold temperature NMHC
exhaust emission compliance in
accordance with the test procedures in
subpart C of this part or with alternative
procedures approved in advance by the
Administrator. The selection of which
EDV and test group within the
durability group will be tested for cold
temperature CO and cold temperature
NMHC compliance will be determined
under the provisions of § 86.1828–10(c)
and (g).
*
*
*
*
*
I 25. Section 86.1844–01 is amended by
revising paragraph (d)(11) to read as
follows:
§ 86.1844–01 Information requirements:
application for certification and submittal of
information upon request.
*
*
*
*
*
(d) * * *
(11) A list of all auxiliary emission
control devices (AECD) installed on any
applicable vehicles, including a
justification for each AECD, the
parameters they sense and control, a
detailed justification of each AECD
which results in a reduction in
effectiveness of the emission control
system, and rationale for why the AECD
is not a defeat device as defined under
§§ 86.1809–01 and 86.1809–10. For any
AECD uniquely used at high altitudes,
EPA may request engineering emission
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data to quantify any emission impact
and validity of the AECD. For any AECD
uniquely used on multi-fuel vehicles
when operated on fuels other than
gasoline, EPA may request engineering
emission data to quantify any emission
impact and validity of the AECD.
*
*
*
*
*
I 26. A new § 86.1848–10 is added to
Subpart S to read as follows:
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§ 86.1848–10
Certification.
Section 86.1848–10 includes text that
specifies requirements that differ from
§ 86.1848–01. Where a paragraph in
§ 86.1848–01 is identical and applicable
to § 86.1848–10, this may be indicated
by specifying the corresponding
paragraph and the statement
‘‘[Reserved]. For guidance see
§ 86.1848–01.’’ Where a corresponding
paragraph of § 86.1848–01 is not
applicable, this is indicated by the
statement ‘‘[Reserved].’’
(a) through (b) [Reserved]. For
guidance see § 86.1848–01.
(c) The following conditions apply to
all certificates:
(1) The manufacturer must supply all
required information according to the
provisions of §§ 86.1843–01 and
86.1844–01.
(2) The manufacturer must comply
with all certification and in-use
emission standards contained in
subparts S and H of this part both
during and after model year production.
(3) The manufacturer must comply
with all implementation schedules sales
percentages as required in § 86.1810 or
elsewhere in this part. Failure to meet
a required implementation schedule
sales percentage will be considered to
be a failure to satisfy a condition upon
which the certificate was issued and any
vehicles or trucks sold in violation of
the implementation schedule are not to
be covered by the certificate.
(4) For incomplete light-duty trucks
and incomplete heavy-duty vehicles, a
certificate covers only those new motor
vehicles that, when completed by
having the primary load-carrying device
or container attached, conform to the
maximum curb weight and frontal area
limitations described in the application
for certification as required in
§ 86.1844–01.
(5) The manufacturer must meet the
in-use testing and reporting
requirements contained in §§ 86.1845–
01, 86.1846–01, and 86.1847–01, as
applicable. Failure to meet the in-use
testing or reporting requirements shall
be considered a failure to satisfy a
condition upon which the certificate
was issued. A vehicle or truck is
considered to be covered by the
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certificate only if the manufacturer
fulfills this condition upon which the
certificate was issued.
(6) Vehicles are covered by a
certificate of conformity only if they are
in all material respects as described in
the manufacturer’s application for
certification (Part I and Part II).
(7) For Tier 2 and interim non-Tier 2
vehicles, all certificates of conformity
issued are conditional upon compliance
with all provisions of §§ 86.1811–04,
86.1860–04, 86.1861–04 and 86.1862–04
both during and after model year
production. The manufacturer must bear
the burden of establishing to the
satisfaction of the Administrator that the
terms and conditions upon which the
certificate(s) was (were) issued were
satisfied. For recall and warranty
purposes, vehicles not covered by a
certificate of conformity will continue to
be held to the standards stated or
referenced in the certificate that
otherwise would have applied to the
vehicles.
(i) Failure to meet the fleet average
NOX requirements of 0.07g/mi, 0.3 g/mi
or 0.2 g/mi, as applicable, will be
considered to be a failure to satisfy the
terms and conditions upon which the
certificate(s) was (were) issued and the
vehicles sold in violation of the fleet
average NOX standard will not be
covered by the certificate(s).
(ii) Failure to comply fully with the
prohibition against selling credits that it
has not generated or that are not
available, as specified in § 86.1861–04,
will be considered to be a failure to
satisfy the terms and conditions upon
which the certificate(s) was (were)
issued and the vehicles sold in violation
of this prohibition will not be covered
by the certificate(s).
(iii) Failure to comply fully with the
phase-in requirements of § 86.1811–04,
will be considered to be a failure to
satisfy the terms and conditions upon
which the certificate(s) was (were)
issued and the vehicles sold which do
not comply with Tier 2 or interim nonTier 2 requirements, up to the number
needed to comply, will not be covered
by the certificate(s).
(8) For LDV/LLDTs and HLDT/
MDPVs, all certificates of conformity
issued are conditional upon compliance
with all provisions of §§ 86.1811–10 and
86.1864–10 both during and after model
year production. The manufacturer
bears the burden of establishing to the
satisfaction of the Administrator that the
terms and conditions upon which the
certificate(s) was (were) issued were
satisfied. For recall and warranty
purposes, vehicles not covered by a
certificate of conformity will continue to
be held to the standards stated or
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referenced in the certificate that
otherwise would have applied to the
vehicles.
(i) Failure to meet the fleet average
cold temperature NMHC requirements
will be considered a failure to satisfy the
terms and conditions upon which the
certificate(s) was (were) issued and the
vehicles sold in violation of the fleet
average NMHC standard will not be
covered by the certificate(s).
(ii) Failure to comply fully with the
prohibition against selling credits that
are not generated or that are not
available, as specified in § 86.1864–10,
will be considered a failure to satisfy the
terms and conditions upon which the
certificate(s) was (were) issued and the
vehicles sold in violation of this
prohibition will not be covered by the
certificate(s).
(iii) Failure to comply fully with the
phase-in requirements of § 86.1811–10
will be considered a failure to satisfy the
terms and conditions upon which the
certificate(s) was (were) issued and the
vehicles sold that do not comply with
cold temperature NMHC requirements,
up to the number needed to comply,
will not be covered by the certificate(s).
(d) through (i) [Reserved]. For
guidance see § 86.1848–01.
I 27. A new § 86.1864–10 is added to
Subpart S to read as follows:
§ 86.1864–10 How to comply with the fleet
average cold temperature NMHC standards.
(a) Applicability. Cold temperature
NMHC exhaust emission standards
apply to the following vehicles, subject
to the phase-in requirements in
§ 86.1811–10(g)(3) and (4):
(1) 2010 and later model year LDV/
LLDTs.
(2) 2012 and later model year HLDT/
MDPVs.
(3) Aftermarket conversion systems as
defined in 40 CFR 85.502, including
conversion of MDPVs.
(4) Vehicles imported by ICIs as
defined in 40 CFR 85.1502.
(b) Useful life requirements. Full
useful life requirements for cold
temperature NMHC standards are
defined in § 86.1805–04(g). There is not
an intermediate useful life standard for
cold temperature NMHC standards.
(c) Altitude. Altitude requirements for
cold temperature NMHC standards are
provided in § 86.1810–09(f).
(d) Small volume manufacturer
certification procedures. Certification
procedures for small volume
manufacturers are provided in
§ 86.1838–01.
(e) Cold temperature NMHC
standards. Fleet average cold
temperature NMHC standards are
provided in § 86.1811–10(g)(2).
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(f) Phase-in. Phase-in of the cold
temperature NMHC standards are
provided in § 86.1811–10(g)(3) and (4).
(g) Phase-in flexibilities for small
volume manufacturers. Phase-in
flexibilities for small volume
manufacturer compliance with the cold
temperature NMHC standards are
provided in § 86.1811–04(k)(5).
(h) Hardship provisions for small
volume manufacturers. Hardship
provisions for small volume
manufacturers related to the cold
temperature NMHC standards are
provided in § 86.1811–04(q)(1).
(i) In-use standards for applicable
phase-in models. In-use cold
temperature NMHC standards for
applicable phase-in models are
provided in § 86.1811–10(u).
(j) Durability procedures and method
of determining deterioration factors
(DFs). The durability data vehicle
selection procedures of § 86.1822–01
and the durability demonstration
procedures of § 86.1823–06 apply for
cold temperature NMHC standards. For
determining compliance with full useful
life cold temperature NMHC emission
standards, the 68–86 °F, 120,000 mile
full useful life NMOG DF may be used.
(k) Vehicle test procedure. (1) The test
procedure for demonstrating
compliance with cold temperature
NMHC standards is contained in
subpart C of this part. With prior EPA
approval, alternative testing procedures
may be used, as specified in § 86.106–
96(a), provided cold temperature NMHC
emissions test results are equivalent or
superior.
(2) Testing of all LDVs, LDTs and
MDPVs to determine compliance with
cold temperature NMHC exhaust
emission standards set forth in this
section must be on a loaded vehicle
weight (LVW) basis, as defined in
§ 86.1803–01.
(3) Testing for the purpose of
providing certification data is required
only at low altitude conditions and only
for vehicles that can operate on
gasoline, except as requested in
§§ 86.1810–09(f) and 86.1844–01(d)(11).
If hardware and software emission
control strategies used during low
altitude condition testing are not used
similarly across all altitudes for in-use
operation, the manufacturer must
include a statement in the application
for certification, in accordance with
§§ 86.1844–01(d)(11) and 86.1810–09(f),
stating what the different strategies are
and why they are used. If hardware and
software emission control strategies
used during testing with gasoline are
not used similarly with all fuels that can
be used in multi-fuel vehicles, the
manufacturer will include a statement
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in the application for certification, in
accordance with §§ 86.1844–01(d)(11)
and 86.1810–09(f), stating what the
different strategies are and why they are
used. For example, unless a
manufacturer states otherwise, air
pumps used to control emissions on
dedicated gasoline vehicles or multifuel vehicles during low altitude
conditions must also be used to control
emissions at high altitude conditions,
and software used to control emissions
or closed loop operation must also
operate similarly at low and high
altitude conditions and similarly when
multi-fueled vehicles are operated on
gasoline and alternate fuels. These
examples are for illustrative purposes
only; similar strategies would apply to
other currently used emission control
technologies and/or emerging or future
technologies.
(l) Emission data vehicle (EDV)
selection. Provisions for selecting the
appropriate EDV for the cold
temperature NMHC standards are
provided in §§ 86.1828–10(g) and
86.1829–01(b)(3).
(m) Calculating the fleet average cold
temperature NMHC standard.
Manufacturers must compute separate
sales-weighted fleet average cold
temperature NMHC emissions at the end
of the model year for LDV/LLDTs and
HLDT/MDPVs, using actual sales, and
certifying test groups to FELs, as defined
in § 86.1803–01. The FEL becomes the
standard for each test group, and every
test group can have a different FEL. The
certification resolution for the FEL will
be 0.1 grams/mile. LDVs and LLDTs
must be grouped together when
calculating the fleet average, and HLDTs
and MDPVs must also be grouped
together to determine the fleet average.
Manufacturers must compute the salesweighted cold temperature NMHC fleet
averages using the following equation,
rounded to the nearest 0.1 grams/mile:
Fleet average cold temperature NMHC
exhaust emissions (grams/mile) =
S(N × FEL) ÷ Total number of
vehicles sold of the applicable
weight category (i.e., either LDV +
LLDTs, or HLDT + MDPVs)
Where:
N = The number of LDVs and LLDTs, or
HLDTs and MDPVs, sold within the
applicable FEL, based on vehicles
counted to the point of first sale.
FEL = Family Emission Limit (grams/mile).
(n) Certification compliance and
enforcement requirements for cold
temperature NMHC standards. (1)
Compliance and enforcement
requirements are provided in § 86.1864–
10 and § 86.1848–10(c)(8).
(2) The certificate issued for each test
group requires all vehicles within that
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test group to meet the emission standard
or FEL to which the vehicles were
certified.
(3) Each manufacturer must comply
with the applicable cold temperature
NMHC fleet average standard on a salesweighted average basis, at the end of
each model year, using the procedure
described in paragraph (m) of this
section.
(4) During a phase-in year, the
manufacturer must comply with the
applicable cold temperature NMHC fleet
average standard for the required phasein percentage for that year as specified
in § 86.1811–10(g)(3) or (4).
(5) Manufacturers must compute
separate cold temperature NMHC fleet
averages for LDV/LLDTs and HLDT/
MDPVs. The sales-weighted cold
temperature NMHC fleet averages must
be compared with the applicable fleet
average standard.
(6) Each manufacturer must comply
on an annual basis with the fleet average
standards as follows:
(i) Manufacturers must report in their
annual reports to the Agency that they
met the relevant corporate average
standard by showing that their salesweighted average cold temperature
NMHC emissions of LDV/LLDTs and
HLDT/MDPVs, as applicable, are at or
below the applicable fleet average
standard;
(ii) If the sales-weighted average is
above the applicable fleet average
standard, manufacturers must obtain
and apply sufficient NMHC credits as
permitted under paragraph (o)(8) of this
section. A manufacturer must show via
the use of credits that they have offset
any exceedence of the corporate average
standard. Manufacturers must also
include their credit balances or deficits.
(iii) If a manufacturer fails to meet the
corporate average cold temperature
NMHC standard for two consecutive
years, the vehicles causing the corporate
average exceedence will be considered
not covered by the certificate of
conformity (see paragraph (o)(8) of this
section). A manufacturer will be subject
to penalties on an individual-vehicle
basis for sale of vehicles not covered by
a certificate.
(iv) EPA will review each
manufacturer’s sales to designate the
vehicles that caused the exceedence of
the corporate average standard. EPA
will designate as nonconforming those
vehicles in test groups with the highest
certification emission values first,
continuing until reaching a number of
vehicles equal to the calculated number
of noncomplying vehicles as determined
above. In a group where only a portion
of vehicles would be deemed
nonconforming, EPA will determine the
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actual nonconforming vehicles by
counting backwards from the last
vehicle produced in that test group.
Manufacturers will be liable for
penalties for each vehicle sold that is
not covered by a certificate.
(o) Requirements for the cold
temperature NMHC averaging, banking
and trading (ABT) program. (1)
Manufacturers must average the cold
temperature NMHC emissions of their
vehicles and comply with the cold
temperature NMHC fleet average
corporate standard. Manufacturers may
generate credits during and after the
phase-in period. Manufacturers may
generate credits prior to the phase-in
periods as described in paragraph (o)(5)
of this section. A manufacturer whose
cold temperature NMHC fleet average
emissions exceed the applicable
standard must complete the calculation
in paragraph (o)(4) of this section to
determine the size of its NMHC credit
deficit. A manufacturer whose cold
temperature NMHC fleet average
emissions are less than the applicable
standard must complete the calculation
in paragraph (o)(4) of this section to
generate NMHC credits.
(2) There are no property rights
associated with NMHC credits generated
under this subpart. Credits are a limited
authorization to emit the designated
amount of emissions. Nothing in this
part or any other provision of law
should be construed to limit EPA’s
authority to terminate or limit this
authorization through a rulemaking.
(3) Each manufacturer must comply
with the reporting and recordkeeping
requirements of paragraph (p) of this
section for NMHC credits, including
early credits. The averaging, banking
and trading program is enforceable
through the certificate of conformity
that allows the manufacturer to
introduce any regulated vehicles into
commerce.
(4) Credits are earned on the last day
of the model year. Manufacturers must
calculate, for a given model year, the
number of credits or debits it has
generated according to the following
equation, rounded to the nearest 0.1
grams/mile:
NMHC Credits or Debits = (Cold
Temperature NMHC Standard—
Manufacturer’s Sales-Weighted
Fleet Average Cold Temperature
NMHC Emissions) × (Total Number
of Vehicles Sold)
Where:
Cold Temperature NMHC Standard = 0.3
grams/mile for LDV/LLDTs or 0.5 grams/
mile for HLDT/MDPV, per § 86.1811–
10(g)(2).
Manufacturer’s Sales-Weighted Fleet Average
Cold Temperature NMHC Emissions =
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average calculated according to
paragraph (m) of this section.
Total Number of Vehicles Sold = Total 50State sales based on the point of first
sale.
(5) The following provisions apply for
early banking:
(i) Manufacturers may certify LDV/
LLDTs to the cold temperature NMHC
exhaust standards in § 86.1811–10(g)(2)
for model years 2008–2009 to bank
credits for use in the 2010 and later
model years. Manufacturers may certify
HLDT/MDPVs to the cold temperature
NMHC exhaust standards in § 86.1811–
10(g)(2) for model years 2010–2011 to
bank credits for use in the 2012 and
later model years.
(ii) This process is referred to as
‘‘early banking’’ and the resultant
credits are referred to as ‘‘early credits.’’
To bank early credits, a manufacturer
must comply with all exhaust emission
standards and requirements applicable
to LDV/LLDTs and/or HLDT/MDPVs. To
generate early credits, a manufacturer
must separately compute the salesweighted cold temperature NMHC
average of the LDV/LLDTs and HLDT/
MDPVs it certifies to the exhaust
requirements and separately compute
credits using the calculations in
paragraph (o)(4) of this section. Early
HLDT/MDPV credits may not be applied
to LDV/LLDTs before the 2010 model
year. Early LDV/LLDT credits may not
be applied to HLDT/ MDPV before the
2012 model year.
(6) NMHC credits are not subject to
any discount or expiration date except
as required under the deficit
carryforward provisions of paragraph
(o)(8) of this section. There is no
discounting of unused credits. NMHC
credits have unlimited lives, subject to
the limitations of paragraph (o)(2) of this
section.
(7) Credits may be used as follows:
(i) Credits generated and calculated
according to the method in paragraph
(o)(4) of this section may be used only
to offset deficits accrued with respect to
the standard in § 86.1811–10(g)(2).
Credits may be banked and used in a
future model year in which a
manufacturer’s average cold
temperature NMHC level exceeds the
applicable standard. Credits may be
exchanged between the LDT/LLDT and
HLDT/MDPV fleets of a given
manufacturer. Credits may also be
traded to another manufacturer
according to the provisions in paragraph
(o)(9) of this section. Before trading or
carrying over credits to the next model
year, a manufacturer must apply
available credits to offset any credit
deficit, where the deadline to offset that
credit deficit has not yet passed.
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(ii) The use of credits shall not be
permitted to address Selective
Enforcement Auditing or in-use testing
failures. The enforcement of the
averaging standard occurs through the
vehicle’s certificate of conformity. A
manufacturer’s certificate of conformity
is conditioned upon compliance with
the averaging provisions. The certificate
will be void ab initio if a manufacturer
fails to meet the corporate average
standard and does not obtain
appropriate credits to cover its shortfalls
in that model year or in the subsequent
model year (see deficit carryforward
provision in paragraph (o)(8) of this
section). Manufacturers must track their
certification levels and sales unless they
produce only vehicles certified to cold
temperature NMHC levels below the
standard and do not plan to bank
credits.
(8) The following provisions apply if
debits are accrued:
(i) If a manufacturer calculates that it
has negative credits (also called
‘‘debits’’ or a ‘‘credit deficit’’) for a given
model year, it may carry that deficit
forward into the next model year. Such
a carry-forward may only occur after the
manufacturer exhausts any supply of
banked credits. At the end of that next
model year, the deficit must be covered
with an appropriate number of credits
that the manufacturer generates or
purchases. Any remaining deficit is
subject to an enforcement action, as
described in this paragraph (o)(8).
Manufacturers are not permitted to have
a credit deficit for two consecutive
years.
(ii) If debits are not offset within the
specified time period, the number of
vehicles not meeting the fleet average
cold temperature NMHC standards (and
therefore not covered by the certificate)
must be calculated by dividing the total
amount of debits for the model year by
the fleet average cold temperature
NMHC standard applicable for the
model year in which the debits were
first incurred.
(iii) EPA will determine the number
of vehicles for which the condition on
the certificate was not satisfied by
designating vehicles in those test groups
with the highest certification cold
temperature NMHC emission values
first and continuing until reaching a
number of vehicles equal to the
calculated number of noncomplying
vehicles as determined above. If this
calculation determines that only a
portion of vehicles in a test group
contribute to the debit situation, then
EPA will designate actual vehicles in
that test group as not covered by the
certificate, starting with the last vehicle
produced and counting backwards.
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(iv)(A) If a manufacturer ceases
production of LDV/LLDTs and HLDT/
MDPVs, the manufacturer continues to
be responsible for offsetting any debits
outstanding within the required time
period. Any failure to offset the debits
will be considered a violation of
paragraph (o)(8)(i) of this section and
may subject the manufacturer to an
enforcement action for sale of vehicles
not covered by a certificate, pursuant to
paragraphs (o)(8)(ii) and (iii) of this
section.
(B) If a manufacturer is purchased by,
merges with, or otherwise combines
with another manufacturer, the
controlling entity is responsible for
offsetting any debits outstanding within
the required time period. Any failure to
offset the debits will be considered a
violation of paragraph (o)(8)(i) of this
section and may subject the
manufacturer to an enforcement action
for sale of vehicles not covered by a
certificate, pursuant to paragraphs
(o)(8)(ii) and (iii) of this section.
(v) For purposes of calculating the
statute of limitations, a violation of the
requirements of paragraph (o)(8)(i) of
this section, a failure to satisfy the
conditions upon which a certificate(s)
was issued and hence a sale of vehicles
not covered by the certificate, all occur
upon the expiration of the deadline for
offsetting debits specified in paragraph
(o)(8)(i) of this section.
(9) The following provisions apply to
NMHC credit trading:
(i) EPA may reject NMHC credit
trades if the involved manufacturers fail
to submit the credit trade notification in
the annual report. A manufacturer may
not sell credits that are not available for
sale pursuant to the provisions in
paragraphs (o)(7)(i) of this section.
(ii) In the event of a negative credit
balance resulting from a transaction that
a manufacturer could not cover by the
reporting deadline for the model year in
which the trade occurred, both the
buyer and seller are liable, except in
cases involving fraud. EPA may void ab
initio the certificates of conformity of all
engine families participating in such a
trade.
(iii) A manufacturer may only trade
credits that it has generated pursuant to
paragraph (o)(4) of this section or
acquired from another party.
(p) Maintenance of records and
submittal of information relevant to
compliance with fleet average cold
temperature NMHC standards. (1)
Maintenance of records. (i)
Manufacturers producing any light-duty
vehicles, light-duty trucks, or mediumduty passenger vehicles subject to the
provisions in this subpart must
establish, maintain, and retain all the
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following information in adequately
organized records for each model year:
(A) Model year.
(B) Applicable fleet average cold
temperature NMHC standards.
(C) Fleet average cold temperature
NMHC value.
(D) All values used in calculating the
fleet average cold temperature NMHC
value.
(ii) Manufacturers producing any
light-duty vehicles, light-duty trucks, or
medium-duty passenger vehicles subject
to the provisions in this subpart must
establish, maintain, and retain all the
following information in adequately
organized records for each LDV/T or
MDPV subject to this subpart:
(A) Model year.
(B) Applicable fleet average cold
temperature NMHC standard.
(C) EPA test group.
(D) Assembly plant.
(E) Vehicle identification number.
(F) Cold temperature NMHC FEL to
which the LDV, LDT, or MDPV is
certified.
(G) Information on the point of first
sale, including the purchaser, city, and
state.
(iii) Manufacturers must retain all
required records for a period of eight
years from the due date for the annual
report. Records may be stored in any
format and on any media, as long as
manufacturers can promptly send EPA
organized, written records in English if
we ask for them. Manufacturers must
keep records readily available as EPA
may review them at any time.
(iv) The Administrator may require
the manufacturer to retain additional
records or submit information not
specifically required by this section.
(v) Pursuant to a request made by the
Administrator, the manufacturer must
submit to the Administrator the
information that the manufacturer is
required to retain.
(vi) EPA may void ab initio a
certificate of conformity for vehicles
certified to emission standards as set
forth or otherwise referenced in this
subpart for which the manufacturer fails
to retain the records required in this
section or to provide such information
to the Administrator upon request.
(2) Reporting. (i) Each covered
manufacturer must submit an annual
report. The annual report must contain
for each applicable cold temperature
NMHC standard, the calculated fleet
average cold temperature NMHC value,
all values required to calculate the cold
temperature NMHC emissions value, the
number of credits generated or debits
incurred, all the values required to
calculate the credits or debits, the
resulting balance of credits or debits,
PO 00000
Frm 00144
Fmt 4701
Sfmt 4700
and sufficient information to show
compliance with all phase-in or
alternate phase-in requirements.
(ii) For each applicable fleet average
cold temperature NMHC standard, the
annual report must also include
documentation on all credit transactions
the manufacturer has engaged in since
those included in the last report.
Information for each transaction must
include all of the following:
(A) Name of credit provider.
(B) Name of credit recipient.
(C) Date the trade occurred.
(D) Quantity of credits traded.
(E) Model year in which the credits
were earned.
(iii) Unless a manufacturer reports the
data required by this section in the
annual production report required
under § 86.1844–01(e), a manufacturer
must submit an annual report for each
model year after production ends for all
affected vehicles produced by the
manufacturer subject to the provisions
of this subpart and no later than May 1
of the calendar year following the given
model year. Annual reports must be
submitted to: Director, Compliance and
Innovative Strategies Division, U.S.
Environmental Protection Agency, 2000
Traverwood, Ann Arbor, Michigan
48105.
(iv) Failure by a manufacturer to
submit the annual report in the
specified time period for all vehicles
subject to the provisions in this section
is a violation of section 203(a)(1) of the
Clean Air Act (42 U.S.C. 7522 (a)(1)) for
each applicable vehicle produced by
that manufacturer.
(v) If EPA or the manufacturer
determines that a reporting error
occurred on an annual report previously
submitted to EPA, the manufacturer’s
credit or debit calculations will be
recalculated. EPA may void erroneous
credits, unless traded, and will adjust
erroneous debits. In the case of traded
erroneous credits, EPA must adjust the
selling manufacturer’s credit balance to
reflect the sale of such credits and any
resulting credit deficit.
(3) Notice of opportunity for hearing.
Any revoking of the certificate under
paragraph (p)(1)(vi) of this section will
be made only after EPA has offered the
affected manufacturer an opportunity
for a hearing conducted in accordance
with § 86.614–84 for light-duty vehicles
or § 86.1014–84 for light-duty trucks
and, if a manufacturer requests such a
hearing, will be made only after an
initial decision by the Presiding Officer.
[FR Doc. E7–2667 Filed 2–23–07; 8:45 am]
BILLING CODE 6560–50–P
E:\FR\FM\26FER2.SGM
26FER2
]]>Agencies
[Federal Register Volume 72, Number 37 (Monday, February 26, 2007)]
[Rules and Regulations]
[Pages 8428-8570]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: E7-2667]
[[Page 8427]]
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Part II
Environmental Protection Agency
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40 CFR Parts 59, 80, 85, and 86
Control of Hazardous Air Pollutants From Mobile Sources; Final Rule
��Federal Register / Vol. 72, No. 37 / Monday, February 26, 2007 /
Rules and Regulations��
[[Page 8428]]
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ENVIRONMENTAL PROTECTION AGENCY
40 CFR Parts 59, 80, 85, and 86
[EPA-HQ-OAR-2005-0036; FRL-8278-4]
RIN 2060-AK70
Control of Hazardous Air Pollutants From Mobile Sources
AGENCY: Environmental Protection Agency (EPA).
ACTION: Final rule.
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SUMMARY: EPA is adopting controls on gasoline, passenger vehicles, and
portable fuel containers (primarily gas cans) that will significantly
reduce emissions of benzene and other hazardous air pollutants
(``mobile source air toxics''). Benzene is a known human carcinogen,
and mobile sources are responsible for the majority of benzene
emissions. The other mobile source air toxics are known or suspected to
cause cancer or other serious health effects. We are limiting the
benzene content of gasoline to an annual refinery average of 0.62% by
volume, beginning in 2011. In addition, for gasoline, we are
establishing a maximum average standard for refineries of 1.3% by
volume beginning on July 1, 2012, which acts as an upper limit on
gasoline benzene content when credits are used to meet the 0.62 volume
% standard. We are also limiting exhaust emissions of hydrocarbons from
passenger vehicles when they are operated at cold temperatures. This
standard will be phased in from 2010 to 2015. For passenger vehicles,
we are also adopting evaporative emissions standards that are
equivalent to those currently in effect in California. Finally, we are
adopting a hydrocarbon emissions standard for portable fuel containers
beginning in 2009, which will reduce evaporation and spillage of
gasoline from these containers. These controls will significantly
reduce emissions of benzene and other mobile source air toxics such as
1,3-butadiene, formaldehyde, acetaldehyde, acrolein, and naphthalene.
There will be additional substantial benefits to public health and
welfare because of significant reductions in emissions of particulate
matter from passenger vehicles.
DATES: This rule is effective on April 27, 2007.
ADDRESSES: EPA has established a docket for this action under Docket ID
No. EPA-HQ-2005-0036. All documents in the docket are listed on the
www.regulations.gov Web site. Although listed in the index, some
information is not publicly available, e.g., CBI or other information
whose disclosure is restricted by statute. Certain other material, such
as copyrighted material, is not placed on the Internet and will be
publicly available only in hard copy form. Publicly available docket
materials are available either electronically through https://
www.regulations.gov or in hard copy at the Air Docket, EPA/DC, EPA
West, Room 3334, 1301 Constitution Ave., NW., Washington, DC. The
Public Reading Room is open from 8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays. The telephone number for the Public
Reading Room is (202) 566-1744, and the telephone number for the Air
Docket is (202) 566-1742.
FOR FURTHER INFORMATION CONTACT: Mr. Chris Lieske, U.S. EPA, Office of
Transportation and Air Quality, Assessment and Standards Division
(ASD), Environmental Protection Agency, 2000 Traverwood Drive, Ann
Arbor, MI 48105; telephone number: (734) 214-4584; fax number: (734)
214-4816; e-mail address: lieske.christopher@epa.gov, or Assessment and
Standards Division Hotline; telephone number: (734) 214-4636; e-mail
address: asdinfo@epa.gov.
SUPPLEMENTARY INFORMATION:
Does This Action Apply to Me?
Entities potentially affected by this action are those that produce
new motor vehicles, alter individual imported motor vehicles to address
U.S. regulation, or convert motor vehicles to use alternative fuels. It
will also affect you if you produce gasoline motor fuel or manufacture
portable gasoline containers. Regulated categories include:
----------------------------------------------------------------------------------------------------------------
NAICS codes SIC codes
Category \a\ \b\ Examples of potentially affected entities
----------------------------------------------------------------------------------------------------------------
Industry....................... 336111 3711 Motor vehicle manufacturers.
Industry....................... 335312 3621 Alternative fuel vehicle converters.
424720 5172
811198 7539
........... 7549
Industry....................... 811111 7538 Independent commercial importers.
811112 7533
811198 7549
Industry....................... 324110 2911 Gasoline fuel refiners.
Industry....................... 326199 3089 Portable fuel container manufacturers.
332431 3411
----------------------------------------------------------------------------------------------------------------
\a\ North American Industry Classification System (NAICS).
\b\ Standard Industrial Classification (SIC) system code.
This table is not intended to be exhaustive, but rather provides a
guide for readers regarding entities likely to be regulated by this
action. This table lists the types of entities that EPA is now aware
could potentially be regulated by this action. Other types of entities
not listed in the table could also be regulated. To determine whether
your activities are regulated by this action, you should carefully
examine the applicability criteria in 40 CFR parts 59, 80, 85, and 86.
If you have any questions regarding the applicability of this action to
a particular entity, consult the person listed in the preceding FOR
FURTHER INFORMATION CONTACT section.
Outline of This Preamble
I. Summary
II. Overview of Final Rule
A. Light-Duty Vehicle Emission Standards
B. Gasoline Fuel Standards
C. Portable Fuel Container (PFC) Controls
III. Why Is EPA Taking This Action?
A. Statutory Requirements
1. Clean Air Act Section 202(l)
2. Clean Air Act Section 183(e)
3. Energy Policy Act
B. Public Health Impacts of Mobile Source Air Toxics (MSATs)
1. What Are MSATs?
2. Health Risk Associated With MSATs
a. National Cancer Risk
b. National Risk of Noncancer Health Effects
c. Exposure Near Roads
d. Exposure From Attached Garages
[[Page 8429]]
3. What Are the Health Effects of Air Toxics?
a. Overview of Potential Cancer and Noncancer Health Effects
b. Health Effects of Key MSATs
i. Benzene
ii. 1,3-Butadiene
iii. Formaldehyde
iv. Acetaldehyde
v. Acrolein
vi. Polycyclic Organic Matter (POM)
vii. Naphthalene
viii. Diesel Exhaust
c. Gasoline PM
d. Near-Roadway Health Effects
C. Ozone
1. Background
2. Health Effects of Ozone
3. Plant and Ecosystem Effects of Ozone
4. Current and Projected 8-hour Ozone Levels
D. Particulate Matter
1. Background
2. Health Effects of PM
3. Welfare Effects of PM
a. Visibility
i. Background
ii Current Visibility Impairment
iii. Future Visibility Impairment
b. Atmospheric Deposition
c. Materials Damage and Soiling
4. Current and Projected PM2.5 Levels
5. Current PM10 Levels
IV. What Are the Emissions, Air Quality, and Public Health Impacts
of This Rule?
A. Emissions Impacts of All Rule Provisions Combined
1. How Will MSAT Emissions Be Reduced?
2. How Will VOC Emissions Be Reduced?
3. How Will PM Emissions Be Reduced?
B. Emission Impacts by Provision
1. Vehicle Controls
a. Volatile Organic Compounds (VOC)
b. Toxics
c. PM2.5
2. Fuel Benzene Standard
3. PFC Standards
a. VOC
b. Toxics
C. What Are the Air Quality, Exposure, and Public Health Impacts
of This Rule?
1. Mobile Source Air Toxics
2. Ozone
3. PM
D. What Other Mobile Source Emissions Control Programs Reduce
MSATs?
1. Fuels Programs
a. Gasoline Sulfur
b. Gasoline Volatility
c. Diesel Fuel
d. Phase-Out of Lead in Gasoline
2. Highway Vehicle and Engine Programs
3. Nonroad Engine Programs
4. Voluntary Programs
5. Additional Programs Under Development That Will Reduce MSATs
a. On-Board Diagnostics for Heavy-Duty Vehicles Over 14,000
Pounds
b. Standards for Small Nonroad Spark-Ignition Engines
c. Standards for Locomotive and Marine Diesel Engines
E. How Do These Mobile Source Programs Satisfy the Requirements
of Clean Air Act Section 202(l)?
V. New Light-duty Vehicle Standards
A. Introduction
B. What Cold Temperature Requirements Are We Adopting?
1. Why Are We Adopting a New Cold Temperature NMHC Standard?
2. What Are the New NMHC Exhaust Emissions Standards?
3. Feasibility of the Cold Temperature NMHC Standards
a. Currently Available Emission Control Technologies
b. Feasibility Considering Current Certification Levels,
Deterioration and Compliance Margin
c. Feasibility and Test Programs
4. Standards Timing and Phase-In
a. Phase-In Schedule
b. Alternative Phase-In Schedules
5. Certification Levels
6. Credit Program
a. How Credits Are Calculated
b. Credits Earned Prior to Primary Phase-In Schedule
c. How Credits Can Be Used
d. Discounting and Unlimited Life
e. Deficits Can Be Carried Forward
f. Voluntary Heavy-Duty Vehicle Credit Program
7. Additional Vehicle Cold Temperature Standard Provisions
a. Applicability
b. Useful Life
c. High Altitude
d. In-Use Standards for Vehicles Produced During Phase-In
8. Monitoring and Enforcement
C. What Evaporative Emissions Standards Are We Finalizing?
1. Current Controls and Feasibility of the New Standards
2. Evaporative Standards Timing
3. Timing for Flex Fuel Vehicles
4. In-Use Evaporative Emission Standards
5. Existing Differences Between California and Federal
Evaporative Emission Test Procedures
D. Additional Exhaust Control Under Normal Conditions
E. Vehicle Provisions for Small Volume Manufacturers
1. Lead Time Transition Provisions
2. Hardship Provisions
3. Special Provisions for Independent Commercial Importers
(ICIs)
VI. Gasoline Benzene Control Program
A. Description of and Rationale for the Gasoline Benzene Control
Program
1. Gasoline Benzene Content Standard
a. Description of the Average Benzene Content Standard
b. Why Are We Finalizing a Benzene Content Standard?
i. Standards That Would Include Toxics Other Than Benzene
ii. Control of Gasoline Sulfur and/or Volatility for MSAT
Reduction
iii. Diesel Fuel Changes
c. Why Are We Finalizing a Level of 0.62 vol% for the Average
Benzene Standard?
i. General Technological Feasibility of Benzene Control
ii. Appropriateness of the 0.62 vol% Average Benzene Content
Standard
iii. Timing of the Average Standard
d. Upper Limit Benzene Standard
2. Description of the Averaging, Banking, and Trading (ABT)
Program
a. Overview
b. Credit Generation
i. Eligibility
ii. Early Credit Generation
iii. Standard Credit Generation
c. Credit Use
i. Early Credit Life
ii. Standard Credit Life
iii. Consideration of Unlimited Credit Life
iv. Credit Trading Provisions
3. Provisions for Small Refiners and Refiners Facing Hardship
Situations
a. Provisions for Small Refiners
i. Definition of Small Refiner for Purposes of the MSAT2 Small
Refiner Provisions
ii. Small Refiner Status Application Requirements
iii. Small Refiner Provisions
iv. The Effect of Financial and Other Transactions on Small
Refiner Status and Small Refiner Relief Provisions
b. Provisions for Refiners Facing Hardship Situations
i. Temporary Waivers Based on Extreme Hardship Circumstances
ii. Temporary Waivers Based on Unforeseen Circumstances
c. Option for Early Compliance in Certain Circumstances
B. How Will the Gasoline Benzene Standard Be Implemented?
1. General Provisions
2. Small Refiner Status Application Requirements
3. Administrative and Enforcement Provisions
a. Sampling/Testing
b. Recordkeeping/Reporting
C. How Will the Program Relate to Other Fuel-Related Toxics
Programs?
D. How Does This Program Satisfy the Statutory Requirements of
Clean Air Act Section 202(l)(2)?
VII. Portable Fuel Containers
A. What Are the New HC Emissions Standards for PFCs?
1. Description of Emissions Standard
2. Determination of Best Available Control
3. Diesel, Kerosene and Utility Containers
4. Automatic Shut-Off
B. Timing of Standard
C. What Test Procedures Would Be Used?
1. Diurnal Test
2. Preconditioning To Ensure Durable In-Use Control
a. Durability Cycles
b. Preconditioning Fuel Soak
c. Spout Actuation
D. What Certification and In-Use Compliance Provisions Is EPA
Adopting?
1. Certification
2. Emissions Warranty and In-Use Compliance
3. Labeling
E. How Would State Programs Be Affected by EPA Standards?
F. Provisions for Small PFC Manufacturers
1. First Type of Hardship Provision
2. Second Type of Hardship Provision
VIII. What Are the Estimated Impacts of the Rule?
A. Refinery Costs of Gasoline Benzene Reduction
1. Methodology
a. Overview of the Benzene Program Cost Methodology
[[Page 8430]]
b. Changes to the Cost Estimation Methodology Used in the
Proposed Rule
c. Linear Programming Cost Model
d. Refinery-by-Refinery Cost Model
e. Price of Chemical Grade Benzene
2. Summary of Costs
a. Nationwide Costs of the Final Benzene Control Program
b. Regional Costs
c. Refining Industry Cost Study
B. What Are the Vehicle Cost Impacts?
C. What Are the PFC Cost Impacts?
D. Cost per Ton of Emissions Reduced
E. Benefits
1. Unquantified Health and Environmental Benefits
2. Quantified Human Health and Environmental Effects of the
Final Cold Temperature Vehicle Standard
3. Monetized Benefits
4. What Are the Significant Limitations of the Benefit Analysis?
5. How Do the Benefits Compare to the Costs of the Final
Standards?
F. Economic Impact Analysis
1. What Is an Economic Impact Analysis?
2. What Is the Economic Impact Model?
3. What Economic Sectors Are Included in This Economic Impact
Analysis?
4. What Are the Key Features of the Economic Impact Model?
5. What Are the Key Model Inputs?
6. What Are the Results of the Economic Impact Modeling?
IX. Public Participation
X. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act (RFA), as Amended by the Small
Business Regulatory Enforcement Fairness Act of 1996 (SBREFA), 5
U.S.C. 601 et seq.
1. Overview
2. The Need for and Objectives of This Rule
3. Summary of the Significant Issues Raised by the Public
Comments
4. Summary of Regulated Small Entities
a. Highway Light-Duty Vehicles
b. Gasoline Refiners
c. Portable Fuel Container Manufacturers
5. Description of the Reporting, Recordkeeping, and Other
Compliance Requirements of the Rule
6. Relevant Federal Rules
7. Steps Taken To Minimize the Significant Economic Impact on
Small Entities
a. Significant Panel Findings
b. Outreach With Small Entities (and the Panel Process)
c. Small Business Flexibilities
i. Highway Light-Duty Vehicles
ii. Gasoline Refiners
iii. Portable Fuel Containers
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
F. Executive Order 13175: Consultation and Coordination With
Indian Tribal Governments
G. Executive Order 13045: Protection of Children From
Environmental Health and Safety Risks
H. Executive Order 13211: Actions That Significantly Affect
Energy Supply, Distribution, or Use
I. National Technology Transfer Advancement Act
J. Executive Order 12898: Federal Actions To Address
Environmental Justice in Minority Populations and Low-Income
Populations
K. Congressional Review Act
XI. Statutory Provisions and Legal Authority
I. Summary
Mobile sources emit air toxics (also known as ``hazardous air
pollutants'') that can cause cancer and other serious health effects.
Mobile sources contribute significantly to the nationwide risk from
breathing outdoor sources of air toxics. Mobile sources were
responsible for about 44% of outdoor toxic emissions, almost 50% of the
cancer risk, and 74% of the noncancer risk according to EPA's National-
Scale Air Toxics Assessment (NATA) for 1999. In addition, people who
live or work near major roads or live in homes with attached garages
are likely to have higher exposures and risk, which are not reflected
in NATA.
According to NATA for 1999, there are a few mobile source air
toxics that pose the greatest risk based on current information about
ambient levels and exposure. These include benzene, 1,3-butadiene,
formaldehyde, acrolein, naphthalene, and polycyclic organic matter
(POM). All of these compounds are gas-phase hydrocarbons except POM,
which appears in the gas and particle phases. Benzene is the most
significant contributor to cancer risk from all outdoor air toxics,
according to NATA for 1999. NATA does not include a quantitative
estimate of cancer risk for diesel exhaust, but it concludes that
diesel exhaust is a mixture of pollutants that collectively poses one
of the greatest relative cancer risks when compared with the other
individual pollutants assessed. Although we expect significant
reductions in mobile source air toxics in the future, cancer and
noncancer health risks will remain a public health concern, and
exposure to benzene will remain the largest contributor to this risk.
In this rule, we are finalizing standards for passenger vehicles,
gasoline, and portable fuel containers (typically gas cans).
Specifically, we are finalizing standards for:
exhaust hydrocarbon emissions from passenger vehicles
during cold temperature operation;
evaporative hydrocarbon emissions from passenger vehicles;
the benzene content of gasoline; and
hydrocarbon emissions from portable fuel containers that
would reduce evaporation, permeation, and spillage from these
containers.
These standards will significantly reduce emissions of the many air
toxics that are hydrocarbons, including benzene, 1,3-butadiene,
formaldehyde, acetaldehyde, acrolein, and naphthalene. The fuel benzene
standards and hydrocarbon standards for vehicles and portable fuel
containers will together reduce total emissions of air toxics by
330,000 tons in 2030, including 61,000 tons of benzene. As a result of
this final rule, in 2030 passenger vehicles will emit 45% less benzene,
gas cans will emit almost 80% less benzene, and gasoline will have 38%
less benzene overall. Mobile sources were responsible for over 70% of
benzene emissions in 1999.
The reductions in mobile source air toxics emissions will reduce
exposure and predicted risk of cancer and noncancer health effects,
including in environments where exposure and risk may be highest, such
as near roads, in vehicles, and in homes with attached garages.
Nationwide, the cancer risk attributable to total MSATs emitted by all
mobile sources will be reduced by 30%, and the risk from mobile source
benzene will be reduced by 37%. At 2030 exposure levels, the highway
vehicle contribution to MSAT cancer risk will be reduced on average 36%
across the U.S., and the highway vehicle contribution to benzene cancer
risk will be reduced on average by 43% across the U.S. Nationwide, the
mobile source contribution to the respiratory hazard index will be
reduced by 23%. In addition, the hydrocarbon reductions from the
vehicle and gas can standards will reduce VOC emissions (which are
precursors to ozone and PM2.5) by over 1.1 million tons in
2030. The vehicle standards will reduce direct PM2.5
emissions by over 19,000 tons in 2030 and will also reduce secondary
formation of PM2.5. Although ozone and PM2.5 are
considered criteria pollutants rather than ``air toxics,'' reductions
in ozone and PM2.5 are nevertheless important co-benefits of
this proposal.
Section I.B.2 of this preamble provides more discussion of the
public health and environmental impacts of mobile source air toxics,
ozone, and PM. Details on health effects, emissions, exposure, and
cancer risks are also located in Chapters 1-3 of the Regulatory Impact
Analysis (RIA) for this rule.
We estimate that the benefits of this rule will be about $6 billion
in 2030, based on the direct PM2.5 reductions from the
vehicle standards, plus unquantified benefits from reductions in mobile
source air toxics and VOC. We estimate that the annual net social costs
of this rule will be about $400 million
[[Page 8431]]
in 2030 (expressed in 2003 dollars). These net social costs include the
value of fuel savings from the proposed gas can standards, which will
be worth about $92 million in 2030.
The rule will have an average cost of 0.27 cents per gallon of
gasoline, less than $1 per vehicle, and less than $2 per gas can. The
reduced evaporation from gas cans will result in fuel savings that will
more than offset the increased cost for the gas can. In 2030, the long-
term cost per ton of the standards (in combination, and including fuel
savings) will be $1,100 per ton of total mobile source air toxics
reduced; $5,900 per ton of benzene reduced; and no cost for the
hydrocarbon and PM reductions (because we expect the vehicle standards
will have no cost in 2020 and beyond). Section VIII of the preamble and
Chapters 8-13 of the RIA provide more details on the costs, benefits,
and economic impacts of the standards. The impacts on small entities
and the flexibilities we are finalizing are discussed in section X of
this preamble and Chapter 14 of the RIA.
II. Overview of Final Rule
A. Light-Duty Vehicle Emission Standards
As described in more detail in section V, we are adopting new
standards for both exhaust and evaporative emissions from passenger
vehicles. The new exhaust emissions standards will significantly reduce
non-methane hydrocarbon (NMHC) emissions from passenger vehicles at
cold temperatures. These hydrocarbons include many mobile source air
toxics (including benzene), as well as VOC.
As we discussed in the proposal, current vehicle emission standards
are based on testing of NMHC that is generally performed at 75 [deg]F.
Recent research and analysis indicates that these standards are not
resulting in robust control of NMHC at lower temperatures. We believe
that cold temperature NMHC control can be substantially improved using
the same technological approaches that are generally already being used
in the Tier 2 vehicle fleet to meet the stringent standards at 75
[deg]F. These cold-temperature NMHC controls will also result in lower
direct PM emissions at cold temperatures.
Accordingly, consistent with the proposal, we are adopting a new
NMHC exhaust emissions standard at 20 [deg]F for light-duty vehicles,
light-duty trucks, and medium-duty passenger vehicles. Vehicles at or
below 6,000 pounds gross vehicle weight rating (GVWR) will be subject
to a sales-weighted fleet average NMHC level of 0.3 grams/mile.
Vehicles between 6,000 and 8,500 pounds GVWR and medium-duty passenger
vehicles will be subject to a sales-weighted fleet average NMHC level
of 0.5 grams/mile. For lighter vehicles, the standard will phase in
between 2010 and 2013. For heavier vehicles, the new standards will
phase in between 2012 and 2015. The standards include a credit program
and other provisions designed to provide flexibility to manufacturers,
especially during the phase-in periods. These provisions are designed
to allow the earliest possible phase-in of standards and help minimize
costs and ease the transition to new standards. These standards in
combination are expected to lead to emissions control over a wide range
of in-use temperatures, and not just at 20 [deg]F and 75 [deg]F.
We are also establishing, as proposed, a set of nominally more
stringent evaporative emission standards for all light-duty vehicles,
light-duty trucks, and medium-duty passenger vehicles. The standards
are equivalent to California's Low Emission Vehicle II (LEV II)
standards, and they reflect the evaporative emissions levels that are
already being achieved nationwide. The standards codify the approach
that most manufacturers are already taking for 50-state evaporative
systems, and thus prevent backsliding in the future. The evaporative
emission standards will take effect in 2009 for lighter vehicles and in
2010 for the heavier vehicles.
Section V of this preamble provides details on the exhaust and
evaporative vehicle standards.
B. Gasoline Fuel Standards
As we proposed, we are limiting the benzene content of all
gasoline, both reformulated and conventional. Beginning January 1,
2011, refiners must meet a refinery average gasoline benzene content
standard of 0.62% by volume on all their gasoline. The program is
described in more detail in section VI of this preamble. The standard
does not apply to gasoline produced and/or sold for use in California
because such gasoline is already covered under California's Phase 3
Reformulated Gasoline (Ca3RFG) program.
The benzene content standard, in combination with the existing
gasoline sulfur standard, will result in air toxics emissions
reductions that are greater than required under all existing gasoline
toxics programs. As a result, upon full implementation in 2011, the
regulatory provisions for the benzene control program will become the
regulatory mechanism used to implement the reformulated gasoline (RFG)
and Anti-dumping annual average toxics performance and benzene content
requirements. The current RFG and Anti-dumping annual average
provisions thus will be replaced by this benzene control program. This
benzene control program will also replace the requirements of the 2001
MSAT rule (``MSAT1''). In addition, the program will satisfy certain
fuel MSAT conditions of the Energy Policy Act of 2005 and obviate the
need to revise toxics baselines for reformulated gasoline otherwise
required by that Act. In all of these ways, the existing national fuel-
related MSAT regulatory program will be significantly consolidated and
simplified.
We are finalizing a nationwide ABT program that allows refiners and
importers to choose the most economical compliance strategy (investment
in technology, credits, or both) for meeting the 0.62 vol% annual
average standard. From 2007-2010, refiners can generate ``early
credits'' by making qualifying benzene reductions earlier than
required. Beginning in 2011 and continuing indefinitely, refiners and
importers can generate ``standard credits'' by producing/importing
gasoline with benzene levels below 0.62 volume percent (vol%) on an
annual average basis. Credits may be used interchangeably towards
company compliance with the 0.62 vol% standard, ``banked'' for future
use, and/or transferred nationwide to other refiners/importers subject
to the standard. In addition to the 0.62 vol% standard, refiners and
importers must also meet a 1.3 vol% maximum average benzene standard
beginning July 1, 2012. To comply with the maximum average standard,
gasoline produced by a refinery or imported by an importer may not
exceed 1.3 vol% benzene on an annual average basis.
The ABT program allows us to set a numerically more stringent
benzene standard than would otherwise be achievable (within the meaning
of Clean Air Act section 202(l)(2)). The ABT program also allows
implementation to occur earlier. Under this benzene content standard
and ABT program, gasoline in all areas of the country will have lower
benzene levels than they have today. Overall benzene levels will be 38%
lower. This will reduce benzene emissions and exposure nationwide.
The program includes special provisions for refiners facing
hardship. Refiners approved as ``small refiners'' are eligible for
certain temporary relief provisions. In addition, any refiner facing
extreme unforeseen circumstances or extreme hardship
[[Page 8432]]
circumstances can apply for similar temporary relief.
C. Portable Fuel Container (PFC) Controls
Portable fuel containers, such as gas cans and diesel and kerosene
containers, are consumer products used to refuel a wide variety of
equipment, including lawn and garden equipment, recreational equipment,
and passenger vehicles that have run out of gas. As described in
section VII, we are adopting standards for these containers that would
reduce hydrocarbon emissions from evaporation, permeation, and
spillage. The program we are finalizing is consistent with the
proposal, except that instead of applying only to gasoline containers,
it will also apply to diesel and kerosene containers. These standards
will significantly reduce emissions of benzene and other gaseous
toxics, as well as VOC. VOC is an ozone precursor, and certain aromatic
species are believed to contribute to secondary organic PM
2.5.
We are finalizing a performance-based standard of 0.3 grams per
gallon per day of hydrocarbons, determined based on the emissions from
the can over a diurnal test cycle specified in the rule. The standard
applies to containers manufactured on or after January 1, 2009. We are
also establishing test procedures and a certification and compliance
program, in order to ensure that containers meet the emission standard
over a range of in-use conditions. The standards are based on the
performance of best available control technologies, such as durable
permeation barriers, automatically closing spouts, and cans that are
well-sealed, and the standards will result in the use of these control
technologies.
California implemented an emissions control program for gas cans in
2001, and since then, several other states have adopted the program.
Last year, California adopted a revised program, which will take effect
July 1, 2007. The revised California program is very similar to the
program we are finalizing. Although a few aspects of the programs are
different, we believe manufacturers will be able to meet both EPA and
California requirements with the same container designs, resulting in
equivalent emission reductions.
III. Why Is EPA Taking This Action?
People experience elevated risk of cancer and other noncancer
health effects from exposure to air toxics. Mobile sources are
responsible for a significant portion of this risk. For example,
benzene is the most significant contributor to cancer risk from all
outdoor air toxics \1\, and most of the nation's benzene emissions come
from mobile sources. These risks vary depending on where people live
and work and the kinds of activities in which they engage. People who
live or work near major roads, people that spend a large amount of time
in vehicles or work with motorized equipment, and people living in
homes with attached garages are likely to have higher exposures and
higher risks. Although we expect significant reductions in mobile
source air toxics in the future, predicted cancer and noncancer health
risks are likely to remain a public health concern. Benzene will likely
remain the largest contributor to this risk. In addition, some mobile
source air toxics contribute to the formation of ozone and PM
2.5, which contribute to serious public health problems.
Section III.B of this preamble discusses the risks posed by outdoor
toxics now and in the future. Sections III.C and III.D discuss the
health and welfare effects of ozone and PM, respectively. The controls
in this rule will significantly reduce exposure to emissions of mobile
source air toxics (and reduce exposure to ozone and PM 2.5
as well), thus reducing these public health concerns.
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\1\ Based on quantitative estimates of risk, which do not
include risks associated with diesel particulate matter and diesel
exhaust organic gases.
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A. Statutory Requirements
1. Clean Air Act Section 202(l)
Section 202(l)(2) of the Clean Air Act requires EPA to set
standards to control hazardous air pollutants (``air toxics'') from
motor vehicles \2\, motor vehicle fuels, or both. These standards must
reflect the greatest degree of emission reduction achievable through
the application of technology which will be available, taking into
consideration the motor vehicle standards established under section
202(a) of the Act, the availability and cost of the technology, and
noise, energy and safety factors, and lead time. The standards are to
be set under Clean Air Act sections 202(a)(1) or 211(c)(1), and they
are to apply, at a minimum, to benzene and formaldehyde emissions.
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\2\ ``Motor vehicles'' is a term of art, defined in Clean Air
Act section 216(2) as ``any self-propelled vehicle designed for
transporting persons or property on a street or highway.''
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Section 202(a)(1) of the Clean Air Act directs EPA to set standards
for new motor vehicles or new motor vehicle engines which EPA judges to
cause or contribute to air pollution which may reasonably be
anticipated to endanger public health or welfare. We are issuing the
vehicle emissions standards under this authority in conjunction with
section 202(l)(2).
Section 211(c)(1)(A) of the Clean Air Act authorizes EPA (among
other things) to control the manufacture of fuel if any emission
product of such fuel causes or contributes to air pollution which may
reasonably be anticipated to endanger public health or welfare. We are
issuing the benzene standard for gasoline under this authority in
conjunction with section 202(l)(2).
Clean Air Act section 202(l)(2) also requires EPA to revise its
regulations controlling hazardous air pollutants from motor vehicles
and fuels, ``from time to time.'' EPA's first rule under Clean Air Act
section 202(l) was published on March 29, 2001, entitled, ``Control of
Emissions of Hazardous Air Pollutants from Mobile Sources'' (66 FR
17230). That rule committed to additional rulemaking that would
evaluate the need for and feasibility of additional controls. Today's
final rule fulfills that commitment.
2. Clean Air Act Section 183(e)
Clean Air Act section 183(e)(3) requires EPA to list categories of
consumer or commercial products that the Administrator determines,
based on an EPA study of VOC emissions from such products, contribute
at least 80 percent of the VOC emissions from such products in areas
violating the national ambient air quality standard for ozone. EPA
promulgated this list at 60 FR 15264 (March 23, 1995), but it did not
consider or list portable fuel containers. After analyzing these
containers' emissions inventory impacts, we recently published a
Federal Register notice that added portable fuel containers to the list
of consumer products to be regulated.\3\ EPA is required to develop
rules reflecting ``best available controls'' to reduce VOC emissions
from the listed products. ``Best available controls'' are defined in
section 183(e)(1)(A) as follows:
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\3\ 71 FR 28320, May 16, 2006, ``Consumer and Commercial
Products: Schedule for Regulation''.
The term ``best available controls'' means the degree of
emissions reduction that the Administrator determines, on the basis
of technological and economic feasibility, health, environmental,
and energy impacts, is achievable through the application of the
most effective equipment, measures, processes, methods, systems, or
techniques, including chemical reformulation, product or feedstock
substitution, repackaging, and directions for use, consumption,
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storage, or disposal.
Section 183(e)(4) also allows these standards to be implemented by
means
[[Page 8433]]
of ``any system or systems of regulation as the Administrator may deem
appropriate, including requirements for registration and labeling,
self-monitoring and reporting * * * concerning the manufacture,
processing, distribution, use, consumption, or disposal of the
product.'' We are issuing a hydrocarbon standard for portable fuel
containers under the authority of section 183(e).
3. Energy Policy Act
Section 1504(b) of the Energy Policy Act of 2005 requires EPA to
adjust the toxics emissions baselines for individual refineries for
reformulated gasoline to reflect 2001-2002 fuel qualities. However, the
Act provides that this action becomes unnecessary if EPA takes action
which results in greater overall reductions of toxics emissions from
vehicles in areas with reformulated gasoline. As described in section
VI of this preamble, we believe the benzene content standard we are
finalizing today will in fact result in greater overall reductions than
would be achieved by adjusting the individual baselines under the
Energy Policy Act. Accordingly, under the provisions of the Energy
Policy Act, this rule obviates the need for readjusting emissions
baselines for reformulated gasoline.
B. Public Health Impacts of Mobile Source Air Toxics (MSATs)
1. What Are MSATs?
Section 202(l) refers to ``hazardous air pollutants from motor
vehicles and motor vehicle fuels.'' We use the term ``mobile source air
toxics (MSATs)'' to refer to compounds that are emitted by mobile
sources and have the potential for serious adverse health effects. Some
MSATs are known or suspected to cause cancer. Some of these pollutants
are also known to have adverse health effects on people's respiratory,
cardiovascular, neurological, immune, reproductive, or other organ
systems, and they may also have developmental effects. Some may pose
particular hazards to more susceptible and sensitive populations, such
as pregnant women, children, the elderly, or people with pre-existing
illnesses.
Some MSATs of particular concern include benzene, 1,3-butadiene,
formaldehyde, acrolein, naphthalene, polycyclic organic matter, and
diesel particulate matter and diesel exhaust organic gases. These are
compounds that EPA's National-Scale Air Toxics Assessment (NATA) for
1999 \4\ identifies as the most significant contributors to cancer and
noncancer health risk from breathing outdoor air toxics, and that have
a significant contribution from mobile sources. Our understanding of
what compounds pose the greatest risk will evolve over time, based on
our understanding of the ambient levels and health effects associated
with the compounds.
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\4\ https://www.epa.gov/ttn/atw/nata1999/.
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EPA has compiled a Master List of Compounds Emitted by Mobile
Sources, based on an extensive review of the literature on exhaust and
evaporative emissions from onroad and nonroad equipment. The list
currently includes approximately 1,000 compounds, and it is available
in the public docket for this rule and on the Web (https://www.epa.gov/
otaq/toxics.htm). Chapter 1 of the RIA provides a detailed discussion
of information sources for identifying those compounds that have the
potential for serious adverse health effects (i.e., could be considered
``MSATs''). This discussion includes a list of those compounds that are
emitted by mobile sources and listed in EPA's Integrated Risk
Information System (IRIS).
MSATs are emitted by motor vehicles, nonroad engines (such as lawn
and garden equipment, farming and construction equipment, locomotives,
and ships), aircraft, and their fuels. MSATs are emitted as a result of
various processes. Some MSATs are present in fuel or fuel additives and
are emitted to the air when the fuel evaporates or passes through the
engine. Some MSATs are formed through engine combustion processes. Some
compounds, like formaldehyde and acetaldehyde, are also formed through
a secondary process when other mobile source pollutants undergo
chemical reactions in the atmosphere. Finally, some air toxics, such as
metals, result from engine wear or from impurities in oil or fuel.
There are other sources of air toxics, including stationary
sources, such as power plants, factories, oil refineries, dry cleaners,
gas stations, and small manufacturers. They can also be produced by
combustion of wood and other organic materials. There are also indoor
sources of air toxics, such as solvent evaporation and outgassing from
furniture and building materials.
2. Health Risk Associated With MSATs
EPA's National-Scale Air Toxics Assessment (NATA) for 1999 provides
some perspective on the average risk of cancer and noncancer health
effects associated with breathing air toxics from outdoor sources, and
the contribution of mobile sources to these risks.5, 6 NATA
assessed 177 pollutants. It is worth noting that NATA does not include
indoor sources of air toxics. Also, it assumes uniform outdoor
concentrations within a census tract, and therefore does not reflect
elevated concentrations and exposures near roadways or other sources
within a census tract. Additional limitations and uncertainties
associated with NATA are discussed in Section 3.2.1.3 of the RIA.
Nevertheless, its findings are useful in providing a perspective on the
magnitude of risks posed by outdoor sources of air toxics generally,
and in identifying what pollutants and sources are important
contributors to these health risks. Some of NATA's findings are
discussed in the paragraphs below.
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\5\ https://www.epa.gov/ttn/atw/nata1999/.
\6\ NATA does not include a quantitative estimate of cancer risk
for diesel particulate matter and diesel exhaust organic gases. EPA
has concluded that while diesel exhaust is likely to be a human
carcinogen, available data are not sufficient to develop a confident
estimate of cancer unit risk.
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For this rule, EPA also performed a national-scale assessment for
1999 and future years using the same modeling tools and approach as the
1999 NATA, but with updated emissions inventories and an updated
exposure model. The exposure model accounts for higher toxics
concentrations near roads. This updated national-scale analysis
examined only those toxics that are emitted by mobile sources (i.e., a
subset of the 177 pollutants included in NATA). However, the analysis
includes all sources of those pollutants, including mobile, stationary,
and area sources. The analysis is discussed in detail in Chapter 3 of
the RIA, and some highlights of the findings are discussed immediately
below.
In addition to national-scale analysis, we have also evaluated more
refined local-scale modeling, measured ambient concentrations, personal
exposure measurements, and other data. This information is discussed in
detail in Chapter 3 of the RIA. These data collectively show that while
levels of air toxics are decreasing, potential public health risks
remain a concern, and ambient levels and personal exposure vary
significantly. These data indicate that concentrations of benzene and
other air toxics can be higher near high-traffic roads, inside
vehicles, and in homes with attached garages.
a. National Cancer Risk
According to NATA, the average national cancer risk in 1999 from
all outdoor sources of air toxics was estimated to be 42 in a million.
That is, 42 out of one million people would be
[[Page 8434]]
expected to contract cancer from a lifetime of breathing air toxics at
1999 levels. Mobile sources were responsible for 44% of outdoor toxic
emissions and almost 50% of the cancer risk. Benzene is the largest
contributor to cancer risk of all 133 pollutants quantitatively
assessed in the 1999 NATA, and mobile sources are the single largest
source of ambient benzene.
According to the national-scale analysis performed for this rule,
the national average cancer risk in 1999 from breathing outdoor sources
of MSATs was about 25 in a million.\7\ Over 224 million people in 1999
were exposed to a risk level above 10 in a million due to chronic
inhalation exposure to MSATs. About 130 million people in 1999 were
exposed to a risk level above 10 in a million due to chronic inhalation
exposure to benzene alone. Mobile sources were responsible for over 70%
of benzene emissions in 1999.
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\7\ This includes emissions from mobile and stationary sources
of these pollutants.
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Although air toxics emissions are projected to decline in the
future as a result of standards EPA has previously adopted, cancer risk
will continue to be a public health concern. Without additional
controls, the predicted national average cancer risk from MSATs in 2030
is predicted to be above 20 in a million. In fact, in 2030 there will
be more people exposed to levels of MSATs that result in the highest
levels of risk. For instance, the number of Americans above the 10 in a
million cancer risk level from exposure to MSATs is projected to
increase from 223 million in 1999 to 272 million in 2030. Mobile
sources will continue to be a significant contributor to risk in the
future, accounting for 43% of total air toxic emissions in 2020, and
55% of benzene emissions.
b. National Risk of Noncancer Health Effects
According to national-scale modeling for 1999 done for this rule,
nearly the entire U.S. population was exposed to an average level of
air toxics that has the potential for adverse respiratory health
effects (noncancer).\8\ We estimated this will continue to be the case
in 2030, even though toxics levels will be lower.
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\8\ That is, the respiratory hazard index exceeded 1. See
section III.B.3.a for more information.
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Mobile sources were responsible for 74% of the noncancer
(respiratory) risk from outdoor air toxics in the 1999 NATA. The
majority of this risk was from acrolein, and formaldehyde also
contributed to the risk of respiratory health effects.\9\
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\9\ Acrolein was assigned an overall confidence level of
``lower'' based on consideration of the combined uncertainties from
the modeling estimates. In contrast, formaldehyde was assigned an
overall confidence level of ``medium.''
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Although not included in NATA's estimates of noncancer risk, PM
from gasoline and diesel mobile sources contributes significantly to
the health effects associated with ambient PM, for which EPA has
established National Ambient Air Quality Standards. There are extensive
human data showing a wide spectrum of adverse health effects associated
with exposure to ambient PM.\10\
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\10\ U.S. Environmental Protection Agency (2004) Air Quality
Criteria for Particulate Matter. Research Triangle Park, NC:
National Center for Environmental Assessment--RTP Office; Report No.
EPA/600/P-99/002aF, p. 8-318.
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c. Exposure Near Roads
A substantial number of modeling assessment and air quality
monitoring studies show elevated concentrations of multiple MSATs in
close proximity to major roads. Exposure studies also indicate that
populations spending time near major roadways likely experience
elevated personal exposures to motor vehicle-related pollutants. In
addition, these populations may experience exposures to differing
physical and chemical compositions of certain air toxic pollutants
depending on the amount of time spent in close proximity to motor
vehicle emissions. Chapter 3.1 of the RIA provides a detailed
discussion of air quality monitoring, personal exposure monitoring, and
modeling assessments near major roadways.
As part of the analyses underlying the final rule, we employed a
new version of the Hazardous Air Pollutant Exposure Model (HAPEM), the
exposure model used in NATA. HAPEM6 explicitly accounts for the
gradient in outdoor concentrations that occurs near major roads, and
the fraction of the population living near major roads.\11\ The HAPEM6
analysis highlights the fact that residence near a major road is a
substantial contributor to overall differences in exposure to directly-
emitted MSATs. As an example, while the average of within-tract median
annual census tract exposure concentrations nationally is 1.4 [mu]g/
m3, the average 90th percentile of within-tract exposure
concentration nationally is over 2 [mu]g/m3.
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\11\ U.S. EPA. 2007. The HAPEM6 User's Guide. Prepared for Ted
Palma, Office of Air Quality Planning and Standards, Research
Triangle Park, NC, by Arlene Rosenbaum and Michael Huang, ICF
International, January 2007. This document is available in Docket
EPA-HQ-OAR-2005-0036. https://www.epa.gov/ttn/fera/human_hapem.html.
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The potential population exposed to elevated concentrations near
major roadways is large. A study of the populations nationally
indicated that more than half of the population lives within 200 meters
of a major road.\12\ It should be noted that this analysis relied on
the Census Bureau definition of a major road, which is not based on
traffic volume. Thus, some of the roads designated as ``major'' may
carry a low volume of traffic. This estimate is consistent with other
studies that have examined the proximity of population to major roads.
These studies are discussed in Section 3.5 of the RIA. In addition,
analysis of data from the Census Bureau's American Housing Survey
suggests that approximately 37 million people live within 300 feet
(~100 meters) of a 4-or-more lane highway, railroad, or airport.\13\
American Housing Survey statistics, as well as epidemiology studies,
indicate that those houses located near major transportation sources
are more likely to be lower in income or have minority residents than
houses not located near major transportation sources. These data are
also discussed in detail in Section 3.5 of the RIA.
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\12\ Major roads are defined as those roads defined by the U.S.
Census as one of the following: ``limited access highway,''
``highway,'' ``major road (primary, secondary and connecting roads
),'' or ``ramp.''
\13\ United States Census Bureau. (2004) American Housing Survey
web page. [Online at https://www.census.gov/hhes/www/housing/ahs/
ahs03/ahs03.html ] Table IA-6.
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Other population studies also indicate that a significant fraction
of the population resides in locations near major roads. At present,
the available studies use different indicators of ``major road'' and of
``proximity,'' but the estimates range from 12.4% of student enrollment
in California attending schools within 150 meters of roads with 25,000
vehicles per day or more, to 13% of Massachusetts veterans living
within 50 meters of a road with at least 10,000 vehicles per
day.14, 15 Using a more general definition of a ``major
road,'' between 22% and 51% of different study populations live near
such roads.
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\14\ Green, R.S.; Smorodinsky, S.; Kim, J.J.; McLaughlin, R.;
Ostro, B. (2004) Proximity of California public schools to busy
roads. Environ. Health Perspect. 112: 61-66.
\15\ Garshick, E.; Laden, F.; Hart, J.E.; Caron, A. (2003)
Residence near a major road and respiratory symptoms in U.S.
veterans. Epidemiol. 14: 728-736.
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d. Exposure From Attached Garages
People living in homes with attached garages are potentially
exposed to substantially higher overall
[[Page 8435]]
concentrations of benzene, toluene, and other VOCs from mobile source-
related emissions. EPA has conducted a modeling analysis to examine the
influence of attached garages on personal exposure to benzene (see
Appendix 3A of RIA). Compared to national average exposure
concentrations modeled in 1999 NATA, which does not account for
emissions originating in attached garages, average exposure
concentrations for people with attached garages could more than double.
Other recent studies also emphasize the substantial role of attached
garages in exposure to MSATs. Chapter 3 of the RIA discusses
measurements of concentrations and exposure associated with attached
garages and EPA's modeling analysis.
3. What Are the Health Effects of Air Toxics?
a. Overview of Potential Cancer and Noncancer Health Effects
Air toxics can cause of variety of cancer and noncancer health
effects. Inhalation cancer risks are usually estimated by EPA as ``unit
risks,'' which represent the excess lifetime cancer risk estimated to
result from continuous exposure to an agent at a concentration of 1 mu
g/m\3\ in air. Some air toxics are known to be carcinogenic in animals
but lack data in humans. Many of these have been assumed to be human
carcinogens. Also, in the absence of evidence of a nonlinear dose-
response curve, EPA assumes these relationships between exposure and
probability of cancer are linear. These unit risks are typically upper
bound estimates. Upper bound estimates are more likely to overestimate
than underestimate risk. Where there are strong epidemiological data, a
maximum likelihood estimate (MLE) may be developed. An MLE is a best
scientific estimate of risk. The benzene unit risk is an MLE. A
discussion of the confidence in a quantitative cancer risk estimate is
provided in the IRIS file for each compound. The discussion of the
confidence in the cancer risk estimate includes an assessment of the
source of the data (human or animal), uncertainties in dose estimates,
choice of the model used to fit the exposure and response data and how
uncertainties and potential confounders are handled.
Potential noncancer chronic inhalation health risks are quantified
using reference concentrations (RfCs) and noncancer chronic ingestion
and dermal health risks are quantified using reference doses (RfDs).
The RfC is an estimate (with uncertainty spanning perhaps an order of
magnitude) of a daily exposure to the human population (including
sensitive subgroups) that is likely to be without appreciable risk of
deleterious effects during a lifetime. Sources of uncertainty in the
development of the RfCs and RfDs include interspecies extrapolation
(animal to human) and intraspecies extrapolation (average human to
sensitive human). Additional sources of uncertainty can include the use
of a lowest observed adverse effect level in place of a no observed
adverse effect level, and other data deficiencies. A statement
regarding the confidence in the RfC and/or RfD is developed to reflect
the confidence in the principal study or studies on which the RfC or
RfD are based and the confidence in the underlying database. Factors
that affect the confidence in the principal study include how well the
study was designed, conducted and reported. Factors that affect the
confidence in the database include an assessment of the availability of
information regarding identification of the critical effect,
potentially susceptible populations and exposure scenarios relevant to
assessment of risk.
The RfC may be used to estimate a hazard quotient, which is the
environmental exposure to a substance divided by its RfC. A hazard
quotient greater than one indicates adverse health effects are
possible. The hazard quotient cannot be translated to a probability
that adverse health effects will occur, and is unlikely to be
proportional to risk. It is especially important to note that a hazard
quotient exceeding one does not necessarily mean that adverse health
effects will occur. In NATA, hazard quotients for different respiratory
irritants were also combined into a hazard index (HI). A hazard index
is the sum of hazard quotients for substances that affect the same
target organ or organ system. Because different pollutants may cause
similar adverse health effects, it is often appropriate to combine
hazard quotients associated with different substances. However, the HI
is only an approximation of a combined effect because substances may
affect a target organ in different ways.
b. Health Effects of Key MSATs
i. Benzene
The EPA's IRIS database lists benzene, an aromatic hydrocarbon, as
a known human carcinogen (causing leukemia) by all routes of
exposure.\16\ A number of adverse noncancer health effects including
blood disorders and immunotoxicity have also been associated with long-
term occupational exposure to benzene.\17\
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\16\ U.S. EPA (2000). Integrated Risk Information System File
for Benzene. This material is available electronically at https://
www.epa.gov/iris/subst/0276.htm.
\17\ U.S. EPA (2002). Toxicological Review of Benzene (Noncancer
Effects). National Center for Environmental Assessment, Washington,
DC. Report No. EPA/635/R-02/001F. https://www.epa.gov/iris/
toxreviews/0276-tr.pdf.
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Inhalation is the major source of human exposure to benzene in
occupational and non-occupational settings. Long-term occupational
inhalation exposure to benzene has been shown to cause cancers of the
hematopoetic (blood cell) system in adults.\18\ Among these are acute
nonlymphocytic leukemia \19\ and chronic lymphocytic
leukemia.20, 21 Leukemias, lymphomas, and other tumor types
have been observed in experimental animals exposed to benzene by
inhalation or oral administration. Exposure to benzene and/or its
metabolites has also been linked with chromosomal changes in
[[Page 8436]]
humans and animals22, 23 and increased proliferation of
mouse bone marrow cells.24, 25
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\18\ U.S. EPA (1998) Carcinogenic Effects of Benzene: An Update,
National Center for Environmental Assessment, Washington, DC.
EPA600-P-97-001F. Enter report number at the following search page,
https://yosemite.epa.gov/ncepihom/nsCatalog.nsf//SearchPubs?Openform.
\19\ Leukemia is a blood disease in which the white blood cells
are abnormal in type or number. Leukemia may be divided into
nonlymphocytic (granulocytic) leukemias and lymphocytic leukemias.
Nonlymphocytic leukemia generally involves the types of white blood
cells (leukocytes) that are involved in engulfing, killing, and
digesting bacteria and other parasites (phagocytosis) as well as
releasing chemicals involved in allergic and immune responses. This
type of leukemia may also involve erythroblastic cell types
(immature red blood cells). Lymphocytic leukemia involves the
lymphocyte type of white blood cell that is responsible for antibody
and cell-mediated immune responses. Both nonlymphocytic and
lymphocytic leukemia may, in turn, be separated into acute (rapid
and fatal) and chronic (lingering, lasting) forms. For example in
acute myeloid leukemia there is diminished production of normal red
blood cells (erythrocytes), granulocytes, and platelets (control
clotting), which leads to death by anemia, infection, or hemorrhage.
These events can be rapid. In chronic myeloid leukemia (CML) the
leukemic cells retain the ability to differentiate (i.e., be
responsive to stimulatory factors) and perform function; later there
is a loss of the ability to respond.
\20\ U.S. EPA (1985) Environmental Protection Agency, Interim
quantitative cancer unit risk estimates due to inhalation of
benzene, prepared by the Office of Health and Environmental
Assessment, Carcinogen Assessment Group, Washington, DC for the
Office of Air Quality Planning and Standards, Washington, DC, 1985.
\21\ U.S. EPA (1993) Motor Vehicle-Related Air Toxics Study.
Office of Mobile Sources, Ann Arbor, MI. https://www.epa.gov/otaq/
regs/toxics/tox_archive.htm.
\22\ International Agency for Research on Cancer (IARC) (1982)
IARC monographs on the evaluation of carcinogenic risk of chemicals
to humans, Volume 29, Some industrial chemicals and dyestuffs,
International Agency for Research on Cancer, World Health
Organization, Lyon, France, p. 345-389.
\23\ U.S. EPA (1998) Carcinogenic Effects of Benzene: An Update,
National Center for Environmental Assessment, Washington, DC.
EPA600-P-97-001F. Enter report number at the following search page,
https://yosemite.epa.gov/ncepihom/nsCatalog.nsf//SearchPubs?Openform.
\24\ Irons, R.D., W.S. Stillman, D.B. Colagiovanni, and V.A.
Henry (1992) Synergistic action of the benzene metabolite
hydroquinone on myelopoietic stimulating activity of granulocyte/
macrophage colony-stimulating factor in vitro, Proc. Natl. Acad.
Sci. 89:3691-3695.
\25\ U.S. EPA (1998) Carcinogenic Effects of Benzene: An Update,
National Center for Environmental Assessment, Washington, DC.
EPA600-P-97-001F. Enter report number at the following search page,
https://yosemite.epa.gov/ncepihom/nsCatalog.nsf//SearchPubs?Openform.
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The latest assessment by EPA estimates the excess risk of
developing leukemia from inhalation exposure to benzene at 2.2 x
10-6 to 7.8 x 10-6 per [mu]g/m3. In
other words, there is an estimated risk of about two to eight excess
leukemia cases in one million people exposed to 1 [mu]g/m3
of benzene over a lifetime.\26\ This range of unit risks reflects the
MLEs calculated from different exposure assumptions and dose-response
models that are linear at low doses. At present, the true cancer risk
from exposure to benzene cannot be ascertained, even though dose-
response data are used in the quantitative cancer risk analysis,
beca
