National Emissions Standards for Hazardous Air Pollutants: Primary Aluminum Reduction Plants, 76260-76291 [2011-29881]
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Federal Register / Vol. 76, No. 234 / Tuesday, December 6, 2011 / Proposed Rules
[EPA–HQ–OAR–2011–0797; FRL–9491–3]
Public Hearing. If anyone contacts the
EPA requesting to speak at a public
hearing by December 16, 2011, a public
hearing will be held on December 21,
2011.
RIN 2060–AQ92
ADDRESSES:
ENVIRONMENTAL PROTECTION
40 CFR Part 63
National Emissions Standards for
Hazardous Air Pollutants: Primary
Aluminum Reduction Plants
Environmental Protection
Agency (EPA).
ACTION: Proposed rule.
AGENCY:
The EPA is proposing
amendments to the national emissions
standards for hazardous air pollutants
for Primary Aluminum Reduction Plants
to address the results of the residual risk
and technology review that the EPA is
required to conduct by the Clean Air
Act. If finalized, these proposed
amendments would address previously
unregulated emissions (i.e., carbonyl
sulfide (COS) emissions from new and
existing potlines and polycyclic organic
matter (POM) emissions from new and
existing prebake potlines and existing
pitch storage tanks); remove the vertical
stud Soderberg one (VSS1) potline
subcategory; reduce the MACT limits for
POM emissions from horizontal stud
Soderberg (HSS) and VSS2 potlines;
eliminate the startup, shutdown and
malfunction exemption in accordance
with recent actions by the United States
Court of Appeals for the District of
Columbia Circuit; add provisions for
facilities to avail themselves of an
affirmative defense in the event of a
malfunction under certain conditions;
and make certain technical and editorial
changes. The proposed emissions limits
for POM and COS are based on
maximum achievable control
technology (MACT). While the proposed
modifications would result in some
reduction in actual emissions of POM
from existing pitch storage tanks, reduce
the potential emissions of POM from
Soderberg potlines, and prevent
increases in emissions of COS and
sulfur dioxide, the health risks posed by
actual emissions from this source
category are currently within the
acceptable range and would not be
reduced appreciably by the proposed
modifications.
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SUMMARY:
Comments must be received on
or before January 20, 2012. Under the
Paperwork Reduction Act, comments on
the information collection provisions
are best assured of receiving full
consideration if the Office of
Management and Budget (OMB)
receives a copy of your comments on or
before January 5, 2012.
DATES:
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Submit your comments,
identified by Docket ID Number EPA–
HQ–OAR–2011–0797, by one of the
following methods:
• https://www.regulations.gov: Follow
the on-line instructions for submitting
comments.
• Email: a-and-r-docket@epa.gov,
Attention Docket ID Number EPA–HQ–
OAR–2011–0797.
• Fax: (202) 566–9744, Attention
Docket ID Number EPA–HQ–OAR–
2011–0797.
• Mail: U.S. Postal Service, send
comments to: EPA Docket Center, EPA
West (Air Docket), Attention Docket ID
Number EPA–HQ–OAR–2011–0797,
U.S. Environmental Protection Agency,
Mail Code: 2822T, 1200 Pennsylvania
Ave. NW., Washington, DC 20460.
Please include a total of two copies. In
addition, please mail a copy of your
comments on the information collection
provisions to the Office of Information
and Regulatory Affairs, Office of
Management and Budget (OMB), Attn:
Desk Officer for EPA, 725 17th Street,
NW., Washington, DC 20503.
• Hand Delivery: U.S. Environmental
Protection Agency, EPA West (Air
Docket), Room 3334, 1301 Constitution
Ave. NW., Washington, DC 20004,
Attention Docket ID Number EPA–HQ–
OAR–2011–0797. Such deliveries are
only accepted during the Docket’s
normal hours of operation, and special
arrangements should be made for
deliveries of boxed information.
Instructions. Direct your comments to
Docket ID Number EPA–HQ–OAR–
2011–0797. The EPA’s policy is that all
comments received will be included in
the public docket without change and
may be made available on-line at https://
www.regulations.gov, including any
personal information provided, unless
the comment includes information
claimed to be confidential business
information (CBI) or other information
whose disclosure is restricted by statute.
Do not submit information that you
consider to be CBI or otherwise
protected through https://
www.regulations.gov or email. The
https://www.regulations.gov Web site is
an ‘‘anonymous access’’ system, which
means the EPA will not know your
identity or contact information unless
you provide it in the body of your
comment. If you send an email
comment directly to the EPA without
going through https://
www.regulations.gov, your email
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address will be automatically captured
and included as part of the comment
that is placed in the public docket and
made available on the Internet. If you
submit an electronic comment, the EPA
recommends that you include your
name and other contact information in
the body of your comment and with any
disk or CD–ROM you submit. If the EPA
cannot read your comment due to
technical difficulties and cannot contact
you for clarification, the EPA may not
be able to consider your comment.
Electronic files should avoid the use of
special characters, any form of
encryption, and be free of any defects or
viruses. For additional information
about the EPA’s public docket, visit the
EPA Docket Center homepage at https://
www.epa.gov/epahome/dockets.htm.
Docket. The EPA has established a
docket for this rulemaking under Docket
ID Number EPA–HQ–OAR–2011–0797.
All documents in the docket are listed
in the https://www.regulations.gov index.
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. Publicly
available docket materials are available
either electronically in https://
www.regulations.gov or in hard copy at
the EPA Docket Center, 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 EPA Docket Center is
(202) 566–1742.
Public Hearing. If a public hearing is
held, it will begin at 10 a.m. on
December 21, 2011 and will be held at
the EPA’s campus in Research Triangle
Park, North Carolina, or at an alternate
facility nearby. Persons interested in
presenting oral testimony or inquiring
as to whether a public hearing is to be
held should contact Ms. Virginia Hunt,
Office of Air Quality Planning and
Standards, Sector Policies and Programs
Division, (D243–02), U.S.
Environmental Protection Agency,
Research Triangle Park, North Carolina
27711; telephone number: (919) 541–
0832.
For
questions about this proposed action,
contact Mr. David Putney, Sector
Policies and Programs Division (D243–
02), Office of Air Quality Planning and
Standards, U.S. Environmental
FOR FURTHER INFORMATION CONTACT:
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Protection Agency, Research Triangle
Park, North Carolina 27711, telephone
(919) 541–2016; fax number: (919) 541–
3207; and email address:
putney.david@epa.gov. For specific
information regarding the risk modeling
methodology, contact Dr. Michael
Stewart, Office of Air Quality Planning
and Standards, Health and
Environmental Impacts Division, Air
Toxics Assessment Group (C504–06),
U.S. Environmental Protection Agency,
Research Triangle Park, NC 27711;
telephone number: (919) 541–7524; fax
number: (919) 541–0840; and email
address: stewart.michael@epa.gov. For
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information about the applicability of
the proposed or current national
emission standards for hazardous air
pollutants (NESHAP) for primary
aluminum reduction plants to a
particular entity, contact the appropriate
person listed in Table 1 of this
preamble.
TABLE 1—LIST OF EPA CONTACTS FOR THE NESHAP ADDRESSED IN THIS PROPOSED ACTION
OECA Contact 1
NESHAP for:
Primary Aluminum Reduction Plants ..................
1 EPA
2 EPA
Patrick Yellin,
(202) 564–2970, yellin.patrick@epa.gov
David Putney,
(919) 541–2016, putney.david@epa.gov
Office of Enforcement and Compliance Assurance.
Office of Air Quality Planning and Standards.
SUPPLEMENTARY INFORMATION:
Preamble Acronyms and Abbreviations
Several acronyms and terms used to
describe industrial processes, data
inventories, and risk modeling are
included in this preamble. While this
may not be an exhaustive list, the
following terms and acronyms are
defined here for reference:
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OAQPS Contact 2
ADAF age-dependent adjustment factors
AEGL acute exposure guideline levels
AERMOD air dispersion model used by the
HEM–3 model
AMOS ample margin of safety
ANPRM advance notice of proposed
rulemaking
ATSDR Agency for Toxic Substances and
Disease Registry
BACT best available control technology
BLDS bag leak detection system
CAA Clean Air Act
CBI Confidential Business Information
CEMS continuous emissions monitoring
system
CFR Code of Federal Regulations
COS carbonyl sulfide
CTE central tendency exposure
EJ environmental justice
EPA Environmental Protection Agency
ERPG Emergency Response Planning
Guidelines
ERT Electronic Reporting Tool
HAP hazardous air pollutants
HEM–3 Human Exposure Model, Version 3
HEPA high efficiency particulate air
HHRAP Human Health Risk Assessment
Protocols
HI Hazard Index
HQ Hazard Quotient
ICR information collection request
IRIS Integrated Risk Information System
Km kilometer
LAER lowest achievable emissions rate
lb/yr pounds per year
MACT maximum achievable control
technology
MACT Code Code within the NEI used to
identify processes included in a source
category
MDL method detection level
mg/acm milligrams per actual cubic meter
mg/dscm milligrams per dry standard cubic
meter
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mg/m3 milligrams per cubic meter
MIR maximum individual risk
MRL minimum risk level
NAC/AEGL Committee National Advisory
Committee for Acute Exposure Guideline
Levels for Hazardous Substances
NAICS North American Industry
Classification System
NAS National Academy of Sciences
NATA National Air Toxics Assessment
NEI National Emissions Inventory
NESHAP National Emissions Standards for
Hazardous Air Pollutants
NOAEL no observed adverse effects level
NRC National Research Council
NTTAA National Technology Transfer and
Advancement Act
O&M operation and maintenance
OAQPS Office of Air Quality Planning and
Standards
ODW Office of Drinking Water
OECA Office of Enforcement and
Compliance Assurance
OHEA Office of Health and Environmental
Assessment
OMB Office of Management and Budget
PB–HAP hazardous air pollutants known to
be persistent and bio-accumulative in the
environment
PM particulate matter
POM polycyclic organic matter
ppmv parts per million volume
RACT reasonably available control
technology
RBLC RACT/BACT/LAER Clearinghouse
REL reference exposure level
RFA Regulatory Flexibility Act
RfC reference concentration
RfD reference dose
RIA Regulatory Impact Analysis
RTR residual risk and technology review
SAB Science Advisory Board
SBA Small Business Administration
SCC Source Classification Codes
SOP standard operating procedures
SSM startup, shutdown, and malfunction
TEQ toxic equivalency quotient
TOSHI target organ-specific hazard index
TPY tons per year
TRIM Total Risk Integrated Modeling
System
TTN Technology Transfer Network
UF uncertainty factor
mg/m 3 microgram per cubic meter
UL upper limit
UMRA Unfunded Mandates Reform Act
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UPL upper predictive limit
URE unit risk estimate
WHO World Health Organization
WWW worldwide web
Organization of this Document. The
information in this preamble is
organized as follows:
I. General Information
A. What is the statutory authority for this
action?
B. Does this action apply to me?
C. Where can I get a copy of this document
and other related information?
D. What should I consider as I prepare my
comments for the EPA?
II. Background
A. What is this source category and how
did the MACT standard regulate its HAP
emissions?
B. What data collection activities were
conducted to support this action?
III. Analyses Performed
A. How did we address unregulated
emission sources?
B. How did we estimate risks posed by the
source category?
C. How did we consider the risk results in
making decisions for this proposal?
D. How did we perform the technology
review?
E. What other issues are we addressing in
this proposal?
IV. Analytical Results and Proposed
Decisions
A. What are the results of our analyses and
proposed decisions regarding
unregulated emissions sources?
B. What are the results of the risk
assessments?
C. What are our proposed decisions
regarding risk acceptability and ample
margin of safety?
D. What are the results and proposed
decisions based on our technology
review?
E. What other actions are we proposing?
F. Compliance dates
V. Summary of Cost, Environmental, and
Economic Impacts
A. What are the affected sources?
B. What are the air quality impacts?
C. What are the cost impacts?
D. What are the economic impacts?
E. What are the benefits?
VI. Request for Comments
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VII. Submitting Data Corrections
VIII. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory
Planning and Review and Executive
Order 13563: Improving Regulation and
Regulatory Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act
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
Risks and Safety Risks
H. Executive Order 13211: Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use
I. National Technology Transfer and
Advancement Act
J. Executive Order 12898: Federal Actions
To Address Environmental Justice in
Minority Populations and Low-Income
Populations
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I. General Information
A. What is the statutory authority for
this action?
Section 112 of the CAA establishes a
two-stage regulatory process to address
emissions of hazardous air pollutants
(HAP) from stationary sources. In the
first stage, after the EPA has identified
categories of sources emitting one or
more of the HAP listed in section 112(b)
of the CAA, section 112(d) of the CAA
calls for us to promulgate national
emission standards for hazardous air
pollutants (NESHAP) for those sources.
‘‘Major sources’’ are those that emit or
have the potential to emit (PTE) 10 tons
per year (tpy) or more of a single HAP
or 25 tpy or more of any combination of
HAP. For major sources, these
technology-based standards must reflect
the maximum degree of emission
reductions of HAP achievable (after
considering cost, energy requirements
and nonair quality health and
environmental impacts) and are
commonly referred to as maximum
achievable control technology (MACT)
standards.
MACT standards are to reflect
application of measures, processes,
methods, systems or techniques
including, but not limited to, measures
which (1) reduce the volume of or
eliminate emissions of pollutants
through process changes, substitution of
materials or other modifications, (2)
enclose systems or processes to
eliminate emissions, (3) capture or treat
pollutants when released from a
process, stack, storage or fugitive
emissions point, (4) are design,
equipment, work practice or operational
standards (including requirements for
operator training or certification) or (5)
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are a combination of the above. CAA
section 112(d)(2)(A)–(E). The MACT
standard may take the form of a design,
equipment, work practice or operational
standard where the EPA first determines
that either (1) a pollutant cannot be
emitted through a conveyance designed
and constructed to emit or capture the
pollutant or that any requirement for, or
use of, such a conveyance would be
inconsistent with law, or (2) the
application of measurement
methodology to a particular class of
sources is not practicable due to
technological and economic limitations.
CAA sections 112(h)(1)–(2).
The MACT ‘‘floor’’ is the minimum
control level allowed for MACT
standards promulgated under CAA
section 112(d)(3) and may not be based
on cost considerations. For new sources,
the MACT floor cannot be less stringent
than the emission control that is
achieved in practice by the bestcontrolled similar source. The MACT
floors for existing sources can be less
stringent than floors for new sources,
but they cannot be less stringent than
the average emission limitation
achieved by the best-performing
12 percent of existing sources in the
category or subcategory (or the bestperforming five sources for categories or
subcategories with fewer than 30
sources). In developing MACT
standards, we must also consider
control options that are more stringent
than the floor. We may establish
standards more stringent than the floor
(‘‘beyond the floor’’ standards) based on
the consideration of the cost of
achieving the emissions reductions and
any nonair quality health and
environmental impacts and energy
requirements. No beyond the floor
standards are proposed in this
rulemaking action.
The EPA is then required to review
these technology-based standards and to
revise them ‘‘as necessary (taking into
account developments in practices,
processes, and control technologies)’’ no
less frequently than every 8 years, under
CAA section 112(d)(6). In conducting
this review, the EPA is not obliged to
completely recalculate the prior MACT
determination. NRDC v. EPA, 529 F.3d
1077, 1084 (D.C. Cir. 2008).
The second stage in standard-setting
focuses on reducing any remaining
‘‘residual’’ risk according to CAA
section 112(f). This provision requires,
first, that the EPA prepare a Report to
Congress discussing (among other
things) methods of calculating risk
posed (or potentially posed) by sources
after implementation of the MACT
standards, the public health significance
of those risks, and the EPA’s
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recommendations as to legislation
regarding such remaining risk. The EPA
prepared and submitted this report
(Residual Risk Report to Congress, EPA–
453/R–99–001) in March 1999. Congress
did not act in response to the report,
thereby triggering the EPA’s obligation
under CAA section 112(f)(2) to analyze
and address residual risk.
CAA section 112(f)(2) requires us to
determine, for source categories subject
to MACT standards, whether the
emissions standards provide an ample
margin of safety to protect public health.
If the MACT standards for HAP
‘‘classified as a known, probable, or
possible human carcinogen do not
reduce lifetime excess cancer risks to
the individual most exposed to
emissions from a source in the category
or subcategory to less than 1-in-1
million,’’ the EPA must promulgate
residual risk standards for the source
category (or subcategory), as necessary,
to provide an ample margin of safety to
protect public health. In doing so, the
EPA may adopt standards equal to
existing MACT standards if the EPA
determines that the existing standards
are sufficiently protective. NRDC v.
EPA, 529 F.3d 1077, 1083 (D.C. Cir.
2008). (‘‘If EPA determines that the
existing technology-based standards
provide an ‘‘ample margin of safety,’’
then the agency is free to readopt those
standards during the residual risk
rulemaking.’’) The EPA must also adopt
more stringent standards, if necessary,
to prevent an adverse environmental
effect 1 but must consider cost, energy,
safety and other relevant factors in
doing so.
Section 112(f)(2) of the CAA expressly
preserves our use of a two-step process
for developing standards to address any
residual risk and our interpretation of
‘‘ample margin of safety’’ developed in
the National Emission Standards for
Hazardous Air Pollutants: Benzene
Emissions From Maleic Anhydride
Plants, Ethylbenzene/Styrene Plants,
Benzene Storage Vessels, Benzene
Equipment Leaks, and Coke By-Product
Recovery Plants (Benzene NESHAP)
(54 FR 38044, September 14, 1989). The
first step in this process is the
determination of acceptable risk. The
second step provides for an ample
margin of safety to protect public health,
which is the level at which the
standards are set (unless a more
1 ‘‘Adverse environmental effect’’ is defined in
CAA section 112(a)(7) as any significant and
widespread adverse effect, which may be
reasonably anticipated to wildlife, aquatic life or
natural resources, including adverse impacts on
populations of endangered or threatened species or
significant degradation of environmental qualities
over broad areas.
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stringent standard is required to
prevent, taking into consideration costs,
energy, safety, and other relevant
factors, an adverse environmental
effect).
The terms ‘‘individual most exposed,’’
‘‘acceptable level,’’ and ‘‘ample margin
of safety’’ are not specifically defined in
the CAA. However, CAA section
112(f)(2)(B) preserves the interpretation
set out in the Benzene NESHAP, and the
United States Court of Appeals for the
District of Columbia Circuit in NRDC v.
EPA, 529 F.3d 1077, concluded that the
EPA’s interpretation of subsection
112(f)(2) is a reasonable one. See NRDC
v. EPA, 529 F.3d at 1083 (‘‘[S]ubsection
112(f)(2)(B) expressly incorporates the
EPA’s interpretation of the Clean Air
Act from the Benzene standard,
complete with a citation to the Federal
Register’’). (D.C. Cir. 2008). See also, A
Legislative History of the Clean Air Act
Amendments of 1990, volume 1, p. 877
(Senate debate on Conference Report).
We notified Congress in the Residual
Risk Report to Congress that we
intended to use the Benzene NESHAP
approach in making CAA section 112(f)
residual risk determinations (EPA–453/
R–99–001, p. ES–11).
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In the Benzene NESHAP, we stated as an
overall objective:
* * * in protecting public health with an
ample margin of safety, we strive to provide
maximum feasible protection against risks to
health from hazardous air pollutants by, (1)
protecting the greatest number of persons
possible to an individual lifetime risk level
no higher than approximately 1-in-1 million;
and (2) limiting to no higher than
approximately 1-in-10 thousand [i.e., 100-in1 million] the estimated risk that a person
living near a facility would have if he or she
were exposed to the maximum pollutant
concentrations for 70 years.
The agency also stated that, ‘‘The EPA
also considers incidence (the number of
persons estimated to suffer cancer or
other serious health effects as a result of
exposure to a pollutant) to be an
important measure of the health risk to
the exposed population. Incidence
measures the extent of health risk to the
exposed population as a whole, by
providing an estimate of the occurrence
of cancer or other serious health effects
in the exposed population.’’ The agency
went on to conclude that ‘‘estimated
incidence would be weighed along with
other health risk information in judging
acceptability.’’ As explained more fully
in our Residual Risk Report to Congress,
the EPA does not define ‘‘rigid line[s] of
acceptability,’’ but considers rather
broad objectives to be weighed with a
series of other health measures and
factors (EPA–453/R–99–001, p. ES–11).
The determination of what represents an
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‘‘acceptable’’ risk is based on a
judgment of ‘‘what risks are acceptable
in the world in which we live’’
(Residual Risk Report to Congress, p.
178, quoting the Vinyl Chloride
decision at 824 F.2d 1165) recognizing
that our world is not risk-free.
In the Benzene NESHAP, we stated
that ‘‘EPA will generally presume that if
the risk to [the maximum exposed]
individual is no higher than
approximately 1-in-10 thousand, that
risk level is considered acceptable.’’
54 FR 38045. We discussed the
maximum individual lifetime cancer
risk (or maximum individual risk (MIR))
as being ‘‘the estimated risk that a
person living near a plant would have
if he or she were exposed to the
maximum pollutant concentrations for
70 years.’’ Id. We explained that this
measure of risk ‘‘is an estimate of the
upper bound of risk based on
conservative assumptions, such as
continuous exposure for 24 hours per
day for 70 years.’’ Id. We acknowledge
that maximum individual lifetime
cancer risk ‘‘does not necessarily reflect
the true risk, but displays a conservative
risk level which is an upper-bound that
is unlikely to be exceeded.’’ Id.
Understanding that there are both
benefits and limitations to using
maximum individual lifetime cancer
risk as a metric for determining
acceptability, we acknowledged in the
1989 Benzene NESHAP that
‘‘consideration of maximum individual
risk * * * must take into account the
strengths and weaknesses of this
measure of risk.’’ Id. Consequently, the
presumptive risk level of 100-in-1
million (1-in-10 thousand) provides a
benchmark for judging the acceptability
of maximum individual lifetime cancer
risk, but does not constitute a rigid line
for making that determination.
The agency also explained in the 1989
Benzene NESHAP the following: ‘‘In
establishing a presumption for MIR,
rather than a rigid line for acceptability,
the agency intends to weigh it with a
series of other health measures and
factors. These include the overall
incidence of cancer or other serious
health effects within the exposed
population, the numbers of persons
exposed within each individual lifetime
risk range and associated incidence
within, typically, a 50-kilometer (km)
exposure radius around facilities, the
science policy assumptions and
estimation uncertainties associated with
the risk measures, weight of the
scientific evidence for human health
effects, other quantified or unquantified
health effects, effects due to co-location
of facilities and co-emission of
pollutants.’’ Id.
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In some cases, these health measures
and factors taken together may provide
a more realistic description of the
magnitude of risk in the exposed
population than that provided by
maximum individual lifetime cancer
risk alone. As explained in the Benzene
NESHAP, ‘‘[e]ven though the risks
judged ‘acceptable’ by the EPA in the
first step of the Vinyl Chloride inquiry
are already low, the second step of the
inquiry, determining an ‘ample margin
of safety,’ again includes consideration
of all of the health factors, and whether
to reduce the risks even further.’’ In the
ample margin of safety decision process,
the agency again considers all of the
health risks and other health
information considered in the first step.
Beyond that information, additional
factors relating to the appropriate level
of control will also be considered,
including costs and economic impacts
of controls, technological feasibility,
uncertainties and any other relevant
factors. Considering all of these factors,
the agency will establish the standard at
a level that provides an ample margin of
safety to protect the public health, as
required by CAA section 112(f). 54 FR
38046.
As discussed in the previous section
of this preamble, we apply a two-step
process for developing standards to
address residual risk. In the first step,
the EPA determines whether risks are
acceptable. This determination
‘‘considers all health information,
including risk estimation uncertainty,
and includes a presumptive limit on
maximum individual lifetime [cancer]
risk (MIR) 2 of approximately 1-in-10
thousand [i.e., 100-in-1 million].’’ 54 FR
38045. In the second step of the process,
the EPA sets the standard at a level that
provides an ample margin of safety ‘‘in
consideration of all health information,
including the number of persons at risk
levels higher than approximately 1-in-1
million, as well as other relevant factors,
including costs and economic impacts,
technological feasibility, and other
factors relevant to each particular
decision.’’ Id.
In past residual risk determinations,
the EPA presented a number of human
health risk metrics associated with
emissions from the category under
review, including: The MIR; the
numbers of persons in various risk
ranges; cancer incidence; the maximum
noncancer hazard index (HI); and the
maximum acute noncancer hazard. In
estimating risks, the EPA considered
2 Although defined as ‘‘maximum individual
risk,’’ MIR refers only to cancer risk. MIR, one
metric for assessing cancer risk, is the estimated
risk were an individual exposed to the maximum
level of a pollutant for a lifetime.
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source categories under review that are
located near each other and that affect
the same population. The EPA provided
estimates of the expected difference in
actual emissions from the source
category under review and emissions
allowed pursuant to the source category
MACT standard. The EPA also
discussed and considered risk
estimation uncertainties. The EPA is
providing this same type of information
in support of these actions.
The agency acknowledges that the
Benzene NESHAP provides flexibility
regarding what factors the EPA might
consider in making our determinations
and how they might be weighed for each
source category. In responding to
comment on our policy under the
Benzene NESHAP, the EPA explained
that: ‘‘The policy chosen by the
Administrator permits consideration of
multiple measures of health risk. Not
only can the MIR figure be considered,
but also incidence, the presence of
noncancer health effects, and the
uncertainties of the risk estimates. In
this way, the effect on the most exposed
individuals can be reviewed as well as
the impact on the general public. These
factors can then be weighed in each
individual case. This approach complies
with the Vinyl Chloride mandate that
the Administrator ascertain an
acceptable level of risk to the public by
employing [her] expertise to assess
available data. It also complies with the
Congressional intent behind the CAA,
which did not exclude the use of any
particular measure of public health risk
from the EPA’s consideration with
respect to CAA section 112 regulations,
and, thereby, implicitly permits
consideration of any and all measures of
health risk which the Administrator, in
[her] judgment, believes are appropriate
to determining what will ‘protect the
public health.’ ’’
For example, the level of the MIR is
only one factor to be weighed in
determining acceptability of risks. The
Benzene NESHAP explains ‘‘an MIR of
approximately 1-in-10 thousand should
ordinarily be the upper end of the range
of acceptability. As risks increase above
this benchmark, they become
presumptively less acceptable under
CAA section 112, and would be
weighed with the other health risk
measures and information in making an
overall judgment on acceptability. Or,
the agency may find, in a particular
case, that a risk that includes MIR less
than the presumptively acceptable level
is unacceptable in the light of other
health risk factors.’’ Similarly, with
regard to the ample margin of safety
analysis, the Benzene NESHAP states
that: ‘‘EPA believes the relative weight
of the many factors that can be
considered in selecting an ample margin
of safety can only be determined for
each specific source category. This
occurs mainly because technological
and economic factors (along with the
health-related factors) vary from source
category to source category.’’
B. Does this action apply to me?
The regulated industrial source
category that is the subject of this
proposal is listed in Table 2 of this
preamble. Table 2 of this preamble is
not intended to be exhaustive, but rather
provides a guide for readers regarding
the entities likely to be affected by this
proposed action. These standards, once
finalized, will be directly applicable to
affected sources. Federal, State, local,
and Tribal government entities are not
affected by this proposed action. As
defined in the source category listing
report published by the EPA in 1992,
the Primary Aluminum Reduction Plant
source category is defined as any facility
which produced primary aluminum by
the electrolytic reduction process.
TABLE 2—NESHAP AND INDUSTRIAL SOURCE CATEGORIES AFFECTED BY THIS PROPOSED ACTION
NAICS code 1
Source category
NESHAP
Primary Aluminum Reduction Plants ........................
Primary Aluminum Reduction Plants ........................
1 North
331312
MACT code 2
0023
American Industry Classification System.
Achievable Control Technology.
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2 Maximum
C. Where can I get a copy of this
document and other related
information?
In addition to being available in the
docket, an electronic copy of this
proposal will also be available on the
World Wide Web (WWW) through the
EPA’s Technology Transfer Network
(TTN). Following signature by the EPA
Administrator, a copy of this proposed
action will be posted on the TTN’s
policy and guidance page for newly
proposed or promulgated rules at the
following address: https://www.epa.gov/
ttn/atw/rrisk/rtrpg.html. The TTN
provides information and technology
exchange in various areas of air
pollution control.
Additional information is available on
the residual risk and technology review
(RTR) Web page at: https://www.epa.gov/
ttn/atw/rrisk/rtrpg.html. This
information includes source category
descriptions and detailed emissions
estimates and other data that were used
as inputs to the risk assessments.
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D. What should I consider as I prepare
my comments for the EPA?
Submitting CBI. Do not submit
information containing CBI to the EPA
through https://www.regulations.gov or
email. Clearly mark the part or all of the
information that you claim to be CBI.
For CBI information on a disk or CD
ROM that you mail to the EPA, mark the
outside of the disk or CD ROM as CBI
and then identify electronically within
the disk or CD ROM the specific
information that is claimed as CBI. In
addition to one complete version of the
comment that includes information
claimed as CBI, a copy of the comment
that does not contain the information
claimed as CBI must be submitted for
inclusion in the public docket. If you
submit a CD ROM or disk that does not
contain CBI, mark the outside of the
disk or CD ROM clearly that it does not
contain CBI. Information not marked as
CBI will be included in the public
docket and the EPA’s electronic public
docket without prior notice. Information
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marked as CBI will not be disclosed
except in accordance with procedures
set forth in 40 CFR part 2. Send or
deliver information identified as CBI
only to the following address: Roberto
Morales, OAQPS Document Control
Officer (C404–02), Office of Air Quality
Planning and Standards, U.S.
Environmental Protection Agency,
Research Triangle Park, North Carolina
27711, Attention Docket ID Number
EPA–HQ–OAR–2011–0797.
II. Background
A. What is this source category and how
did the MACT standard regulate its HAP
emissions?
The NESHAP (or MACT rule) for the
Primary Aluminum Reduction Plants
was promulgated on October 7, 1997 (62
FR 52407) and amended on November
2, 2005 (70 FR 66285). The rule is
applicable to facilities with affected
sources associated with the production
of aluminum by electrolytic reduction.
Aluminum is produced from refined
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bauxite ore (also known as alumina),
using an electrolytic reduction process
in a series of cells called a ‘‘potline.’’
The raw materials include alumina,
coke, pitch and fluoride salts. According
to information available on the Web site
of The Aluminum Association, Inc.
(https://www.aluminum.org)
approximately 50 percent of the
aluminum produced in the U.S. comes
from primary aluminum facilities. The
two main potline types are prebake (a
newer, higher efficiency, lower-emitting
technology) and Soderberg (an older,
lower efficiency, higher-emitting
technology). There are currently 15
facilities located in the United States
that are subject to the requirements of
this NESHAP: 14 primary aluminum
production plants and one carbon-only
prebake anode production facility.
These 14 primary aluminum production
plants have approximately 53 potlines
that produce aluminum. Each plant has
a paste production operation, and 12 of
the 14 plants have anode bake furnaces.
Twelve of the 14 facilities utilize
prebake potlines; the other 2 utilize
Soderberg potlines. According to The
Aluminum Association, Inc., due to a
decrease in demand for aluminum, four
of the 14 facilities are currently idle
including 1 Soderberg facility. The
major HAPs emitted by these facilities
are carbonyl sulfide (COS), hydrogen
fluoride (HF), and polycyclic organic
matter (POM), specifically polycyclic
aromatic hydrocarbons (PAH).
The standards promulgated in 1997
and 2005 apply to emissions of HF,
measured using total fluorides (TF) as a
surrogate, from all potlines and anode
bake furnaces and POM (as measured by
methylene chloride extractables) from
Soderberg potlines, anode bake
furnaces, paste production plants and
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pitch storage tanks associated with
primary aluminum reduction. Affected
sources under the rules are each potline,
each anode bake furnace (except for one
that is located at a facility that only
produces anodes for use off-site), each
paste production plant, and each new
pitch storage tank.
The NESHAP designated seven
subcategories of existing potlines based
primarily on differences in the process
operation and configuration. The
control of primary emissions from the
reduction process is typically achieved
by the installation of a dry alumina
scrubber (with a baghouse to collect the
alumina and other particulate matter).
The MACT control technology typically
used for anode bake furnaces is a dry
alumina scrubber, and a capture system
vented to a dry coke scrubber is used for
control of paste production plants. See
Table 3 for the emission limits.
TABLE 3—SUMMARY OF CURRENT MACT EMISSION LIMITS FOR EXISTING SOURCES UNDER THE 1997 NESHAP, AND
THE 2005 AMENDMENTS
Source
Pollutant
Emission limit
Paste Production .........................................................................
TF .................
TF .................
TF .................
TF .................
TF .................
POM .............
TF .................
POM .............
TF .................
POM .............
POM .............
Anode Bake Furnace (collocated with a primary aluminum
plant).
TF .................
POM .............
0.95 kg/Mg (1.9 lb/ton) of aluminum produced.
1.5 kg/Mg (3.0 lb/ton) of aluminum produced.
1.25 kg/Mg (2.5 lb/ton) of aluminum produced.
0.8 kg/Mg (1.6 lb/ton) of aluminum produced.
1.1 kg/Mg (2.2 lb/ton) of aluminum produced.
1.2 kg/Mg (2.4 lb/ton) of aluminum produced.
1.35 kg/Mg (2.7 lb/ton) of aluminum produced.
2.85 kg/Mg (5.7 lb/ton) of aluminum produced.
1.35 kg/Mg (2.7 lb/ton) of aluminum produced.
2.35 kg/Mg (4.7 lb/ton) of aluminum produced.
Install, operate, and maintain equipment for capture of emissions and vent to a dry coke scrubber.
0.10 kg/Mg (0.20 lb/ton) of green anode.
0.09 kg/Mg (0.18 lb/ton) of green anode.
Potlines: 1
CWPB1 potlines ...................................................................
CWPB2 potlines ...................................................................
CWPB3 potlines ...................................................................
SWPB potlines .....................................................................
VSS1 potlines .......................................................................
VSS2 potlines .......................................................................
HSS potlines .........................................................................
1 CWPB1 = Center-worked prebake potline with the most modern reduction cells; includes all center-worked prebake potlines not specifically
identified as CWPB2 or CWPB3.
CWPB2 = Center-worked prebake potlines located at Alcoa in Rockdale, Texas; Kaiser Aluminum in Mead, Washington; Ormet Corporation in
Hannibal, Ohio; Ravenswood Aluminum in Ravenswood, West Virginia; Reynolds Metals in Troutdale, Oregon; and Vanalco Aluminum in Vancouver, Washington.
CWPB3 = Center-worked prebake potline that produces very high purity aluminum, has wet scrubbers as the primary control system, and is located at the primary aluminum plant operated by NSA in Hawesville, Kentucky.
HSS = Horizontal stud Soderberg potline.
SWPB = Side-worked prebake potline.
VSS1 = Vertical stud Soderberg potline at Northwest Aluminum in The Dalles, Oregon, or at Columbia Aluminum in Goldendale, Washington.
VSS2 = Vertical stud Soderberg potlines at Columbia Falls Aluminum in Columbia Falls, Montana.
TABLE 4—SUMMARY OF CURRENT MACT EMISSION LIMITS FOR NEW SOURCES UNDER THE 1997 NESHAP AND 2005
AMENDMENTS
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Source
Pollutant
Emission limit
All Potlines ...................................................................................
VSS1, VSS2, and HSS potlines ..................................................
Paste Production .........................................................................
TF .................
POM .............
POM .............
Anode Bake Furnace (collocated with a primary aluminum
plant).
Pitch storage tanks ......................................................................
TF .................
POM .............
POM .............
0.6 kg/Mg (1.2 lb/ton) of aluminum produced.
0.32 kg/Mg (0.63 lb/ton) of aluminum produced.
Install, operate, and maintain equipment for capture of emissions and vent to a dry coke scrubber.
0.01 kg/Mg (0.020 lb/ton) of green anode
0.025 kg/Mg (0.05 lb/ton) of green anode.
Emission control system designed and operated to reduce inlet
emissions by 95 percent or greater.
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The 1997 NESHAP for primary
aluminum reduction plants incorporates
new source performance standards for
potroom groups; these emission limits
are listed in Table 4. The limits for new
Soderberg facilities apply to any
Soderberg facility that adds a new
potroom group to an existing potline or
is associated with a potroom group that
meets the definition of a modified or
reconstructed potroom group. Since
these POM limits are very stringent,
they effectively preclude the operation
of any new Soderberg potlines.
Compliance with the emission limits
in the current rule is demonstrated by
performance testing which can be
addressed individually for each affected
source or according to emissions
averaging provisions. Monitoring
requirements include monthly
measurements of TF secondary
emissions, quarterly measurement of
POM secondary emissions and annual
measurement of primary emissions,
continuous parameter monitoring for
each emission control device, a
monitoring device to track daily weight
of aluminum produced, daily inspection
for visible emissions, and daily
inspection of wet roof scrubbers.
Recordkeeping for the rule is consistent
with the General Provisions
requirements with the addition of
recordkeeping for daily production of
aluminum, records supporting
emissions averaging and records
documenting the portion of TF
measured as particulate matter or
gaseous form.
B. What data collection activities were
conducted to support this action?
For the Primary Aluminum Reduction
Plant source category, we compiled a
preliminary dataset using available
information, reviewed the data, and
made changes where necessary. The
preliminary dataset was based on data
in the 2002 National Emissions
Inventory (NEI) Final Inventory, Version
1 (made publicly available on February
26, 2006), and the 2005 National
Emissions Inventory (NEI), version 2.0
(made publicly available in October
2008). The NEI is a database that
contains information about sources that
emit criteria air pollutants, their
precursors, and HAP. The NEI database
includes estimates of annual air
pollutant emissions from point and
volume sources, emission release
characteristic data such as height,
velocity, temperature and location
latitude/longitude coordinates.
We reviewed the NEI datasets,
corrected geographic coordinates and
stack parameters in consultation with
the facilities, and made changes based
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on available information. We also
reviewed the emissions and other data
to identify data anomalies that could
affect risk estimates. The 2005 NEI was
then updated to develop the 2005
National Air Toxics Assessment (NATA)
Inventory. Subsequently, in April 2011,
we received test data and other
information through an Information
Collection Request (ICR) from 11 of the
15 facilities in the source category.
These ICR data were then used along
with the 2005 NATA inventory data to
develop the emissions dataset for this
source category, which includes our
best estimates of actual emissions of
HAP for the facilities. This dataset was
then used in the risk modeling analyses
to estimate the risks due to actual
emissions for the source category.
POM emissions were allocated to
specific POM compounds on the basis
of the fractional contributions of these
compounds to the actual POM
emissions, as determined (as
appropriate) from an average of test data
for two prebake potlines and an average
of data from two Soderberg facilities.
Based on knowledge of the industry and
previous testing, we could reasonably
expect emissions of approximately 23
POM specific POM compounds from
primary aluminum production facilities.
The allocation incorporated POM
emissions at 50 percent of the detection
limit for those compounds ‘‘reported as
below detection limit.’’ The use of 50
percent of the detection limit is more
conservative than assuming that these
compounds were not present; an
assumption that the compounds were
present at the detection limit would be
an overestimation. The assumption that
these compounds were present at 50
percent of the detection limit
represented the midpoint of two
extreme options. For Soderberg potline
stacks, six out of 38 measurements were
below the detection limit. For Soderberg
potroom roof vents, 10 out of 38
measurements were below the detection
limit. For prebake potline stacks, 21 out
of 38 measurements were below the
detection limit. For prebake potroom
roof vents, 25 out of 38 measurements
were below the detection limit.
To estimate allowable emissions, we
analyzed the emissions data gathered
from the 2002 NEI, the 2005 NEI and
responses to the ICR described above.
Based on that analysis, we estimated
that allowable emissions were generally
about 1.5 times higher than actual
emissions. Therefore, to calculate
allowable emissions we assumed that
allowable emissions were 1.5 times
greater than actual emissions for all
facilities except for one idle Soderberg
facility (Columbia Falls). For Columbia
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Falls, which has the highest potential
for emissions of all the facilities, we
evaluated site-specific data and
estimated that allowable emissions were
about 1.9 times higher than actual
emissions.
Actual emissions of COS for the
industry are estimated to be about 4,400
tons per year (tpy), with an average of
about 330 tons per facility. Actual
emissions of HF are estimated to be
about 1,900 tpy with an average of about
160 tpy per facility. Estimated emissions
of speciated compounds of POM were
much lower. Estimated actual emissions
of identified POM species totaled
approximately 180 tpy for the industry.
Moreover, POM emissions are much
higher from Soderberg facilities
compared to prebake facilities. The
average POM emissions from prebake
facilities are about 4.5 tpy per facility,
and the average POM emissions for
Soderberg facilities are about 60 tpy per
facility. We estimate that approximately
one-third of the emissions of POM for
both types of potrooms come from the
control device stack, and the remainder
are secondary emissions emitted from
potroom vents. This estimate is based
on a summary of emissions derived
from reports of emission testing
conducted at two prebake facilities and
two Soderberg facilities (‘‘Industry
Review of Draft POM Speciation and
Emissions Data,’’ December 19, 2007).
The emissions data, calculations and
risk assessment inputs for the Primary
Aluminum Reduction Plant source
category are described further in Draft
Development of the RTR Emissions
Dataset for the Primary Aluminum
Production Source Category which is
available in the docket for this proposed
rulemaking.
III. Analyses Performed
In this section we describe the
analyses performed to support the
proposed decisions for the RTR for this
source category.
A. How did we address unregulated
emissions sources?
In the course of evaluating the
Primary Aluminum Reduction Plant
source category, we identified certain
HAP for which we failed to establish
emission standards in the original
MACT. See National Lime v. EPA, 233
F. 3d 625, 634 (DC Cir. 2000) (the EPA
has ‘‘clear statutory obligation to set
emissions standards for each listed
HAP’’).
We evaluated establishing emissions
limits for COS for the source category
and for POM for various emissions
points that had not been regulated in the
1997 MACT rule or in the 2005
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amendments. Section 112(d)(3)(B) of the
CAA requires that the MACT standards
for existing sources be at least as
stringent as the average emissions
limitation achieved by the best
performing five sources (for which the
Administrator has or could reasonably
obtain emissions information) in a
category with fewer than 30 sources.
The Primary Aluminum source category
consists of fewer than 30 sources.
The EPA must exercise its judgment,
based on an evaluation of the relevant
factors and available data, to determine
the level of emissions control that has
been achieved by the best performing
sources under variable conditions. It is
recognized in the case law that the EPA
may consider variability in estimating
the degree of emissions reduction
achieved by best-performing sources
and in setting MACT floors. See
Mossville Envt’l Action Now v. EPA, 370
F.3d 1232, 1241–42 (DC Cir 2004)
(holding that the EPA may consider
emissions variability in estimating
performance achieved by bestperforming sources and may set the
floor at a level that a best-performing
source can expect to meet ‘‘every day
and under all operating conditions’’).
More details on how we calculate
MACT floors and how we account for
variability are described in the Draft
MACT Floor Analysis for the Primary
Aluminum Source Category which is
available in the docket for this proposed
action.
Carbonyl sulfide (COS) was not
regulated in the 1997 NESHAP or in the
2005 amendments for Primary
Aluminum Reduction Plants. In this
action we analyzed the available data
and evaluated options for developing
MACT standards for this HAP. Based on
all our analyses, which are described in
section IV.A of this preamble, we
concluded that establishing a standard
based on a mass balance equation would
be the most appropriate approach.
Therefore, we are proposing MACT
standards for COS in today’s action
based on use of a mass balance equation
to derive COS emissions based on data
on anode coke sulfur content, anode
consumption and aluminum
production.
Polycyclic organic matter (POM)
emissions from prebake potlines were
also not regulated in the 1997 NESHAP
or in the 2005 amendments. We are
proposing MACT limits for new and
existing prebake potlines in today’s
action based on available data. Finally,
the 1997 NESHAP included MACT
standards for new pitch storage tanks,
which required a 95 percent reduction
in emissions. However, the rule had no
limits for existing storage tanks. We are
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proposing that existing tanks will be
subject to the same standard (i.e.,
minimum of 95 percent reduction of
POM emissions). At least three facilities
are currently achieving this level of
control on existing tanks.
Further details about the analyses, the
results and proposed decisions
regarding the proposed MACT limits
pursuant to CAA section 112(d)(2) and
112(d)(3) are presented in section IV.A
of this preamble.
B. How did we estimate risks posed by
the source category?
The EPA conducted risk assessments
that provided estimates of the MIR
posed by the HAP emissions for each
source in the category, the HI for
chronic exposures to HAP with the
potential to cause noncancer health
effects, and the hazard quotient (HQ) for
acute exposures to HAP with the
potential to cause noncancer health
effects. The assessments also provided
estimates of the distribution of cancer
risks within the exposed populations,
cancer incidence and an evaluation of
the potential for adverse environmental
effects for each source category. The risk
assessments consisted of seven primary
steps, as discussed below. The docket
for this rulemaking contains the
following document which provides
more information on the risk assessment
inputs and models: Draft Residual Risk
Assessment for the Primary Aluminum
Reduction Plant Source Category. The
methods used to assess risks (as
described in the seven primary steps
below) are consistent with those peerreviewed by a panel of the EPA’s
Science Advisory Board (SAB) in 2009
and described in their peer review
report issued in 2010 3; they are also
consistent with the key
recommendations contained in that
report.
1. Establishing the Nature and
Magnitude of Actual Emissions and
Identifying the Emissions Release
Characteristics
As discussed in section II.B of this
preamble, we used a dataset consisting
of the estimated actual and allowable
emissions as the basis for the risk
assessment. In addition to the quality
assurance (QA) of the emissions and
associated parameters contained in the
dataset, we also checked the coordinates
of every facility in the dataset through
visual observations using tools such as
Google Earth and ArcView. Where
3 U.S. EPA SAB. Risk and Technology Review
(RTR) Risk Assessment Methodologies: For Review
by the EPA’s Science Advisory Board with Case
Studies—MACT I Petroleum Refining Sources and
Portland Cement Manufacturing, May 2010.
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coordinates were found to be incorrect,
we identified and corrected them to the
extent possible. We also performed QA
of the emissions data and release
characteristics to ensure there were no
outliers.
2. Establishing the Relationship
Between Actual Emissions and MACTAllowable Emissions Levels
The available emissions data in the
MACT dataset include estimates of the
mass of HAP actually emitted during the
specified annual time period. These
‘‘actual’’ emission levels are often lower
than the emission levels that a facility
might be allowed to emit and still
comply with the MACT standards. The
emissions level allowed to be emitted by
the MACT standards is referred to as the
‘‘MACT-allowable’’ emissions level.
This represents the highest emissions
level that could be emitted by the
facility without violating the MACT
standards.
We discussed the use of both MACTallowable and actual emissions in the
final Coke Oven Batteries residual risk
rule (70 FR 19998–19999, April 15,
2005) and in the proposed and final
Hazardous Organic NESHAP residual
risk rules (71 FR 34428, June 14, 2006,
and 71 FR 76609, December 21, 2006,
respectively). In those previous actions,
we noted that assessing the risks at the
MACT-allowable level is inherently
reasonable since these risks reflect the
maximum level sources could emit and
still comply with national emission
standards. But we also explained that it
is reasonable to consider actual
emissions, where such data are
available, in both steps of the risk
analysis, in accordance with the
Benzene NESHAP. (54 FR 38044,
September 14, 1989.)
Further explanation is provided in the
document Draft Development of the
RTR Emissions Dataset for the Primary
Aluminum Production Source Category
which is available in the docket for this
proposed rulemaking.
3. Conducting Dispersion Modeling,
Determining Inhalation Exposures and
Estimating Individual and Population
Inhalation Risks
Both long-term and short-term
inhalation exposure concentrations and
health risks from each facility in the
source category addressed in this
proposal were estimated using the
Human Exposure Model (HEM)
(Community and Sector HEM–3 version
1.1.0). The HEM–3 performs three
primary risk assessment activities: (1)
Conducting dispersion modeling to
estimate the concentrations of HAP in
ambient air, (2) estimating long-term
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and short-term inhalation exposures to
individuals residing within 50 km of the
modeled sources and (3) estimating
individual and population-level
inhalation risks using the exposure
estimates and quantitative doseresponse information.
The dispersion model used by HEM–
3 is AERMOD, which is one of the
EPA’s preferred models for assessing
pollutant concentrations from industrial
facilities.4 To perform the dispersion
modeling and to develop the
preliminary risk estimates, HEM–3
draws on three data libraries. The first
is a library of meteorological data,
which is used for dispersion
calculations. This library includes 1
year (1991) of hourly surface and upper
air observations for more than 158
meteorological stations, selected to
provide coverage of the United States
and Puerto Rico. A second library of
United States Census Bureau census
block 5 internal point locations and
populations provides the basis of
human exposure calculations (Census,
2000). In addition, for each census
block, the census library includes the
elevation and controlling hill height,
which are also used in dispersion
calculations. A third library of pollutant
unit risk factors and other health
benchmarks is used to estimate health
risks. These risk factors and health
benchmarks are the latest values
recommended by the EPA for HAP and
other toxic air pollutants. These values
are available at https://www.epa.gov/ttn/
atw/toxsource/summary.html and are
discussed in more detail later in this
section.
In developing the risk assessment for
chronic exposures, we used the
estimated annual average ambient air
concentration of each of the HAP
emitted by each source for which we
have emissions data in the source
category. The air concentrations at each
nearby census block centroid were used
as a surrogate for the chronic inhalation
exposure concentration for all the
people who reside in that census block.
We calculated the MIR for each facility
as the cancer risk associated with a
continuous lifetime (24 hours per day,
7 days per week, and 52 weeks per year
for a 70-year period) exposure to the
maximum concentration at the centroid
of an inhabited census block. Individual
cancer risks were calculated by
4 U.S. EPA. Revision to the Guideline on Air
Quality Models: Adoption of a Preferred General
Purpose (Flat and Complex Terrain) Dispersion
Model and Other Revisions (70 FR 68218,
November 9, 2005).
5 A census block is generally the smallest
geographic area for which census statistics are
tabulated.
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multiplying the estimated lifetime
exposure to the ambient concentration
of each of the HAP (in micrograms per
cubic meter) by its unit risk estimate
(URE), which is an upper bound
estimate of an individual’s probability
of contracting cancer over a lifetime of
exposure to a concentration of 1
microgram of the pollutant per cubic
meter of air. For residual risk
assessments, we generally use URE
values from the EPA’s Integrated Risk
Information System (IRIS). For
carcinogenic pollutants without the EPA
IRIS values, we look to other reputable
sources of cancer dose-response values,
often using California EPA (CalEPA)
URE values, where available. In cases
where new, scientifically credible doseresponse values have been developed in
a manner consistent with the EPA
guidelines and have undergone a peer
review process similar to that used by
the EPA, we may use such doseresponse values in place of, or in
addition to, other values, if appropriate.
Polycyclic organic matter (POM), a
carcinogenic HAP with a mutagenic
mode of action, is emitted by the
facilities in this source category.6 For
this compound group,7 the agedependent adjustment factors (ADAF)
described in the EPA’s Supplemental
Guidance for Assessing Susceptibility
from Early-Life Exposure to
Carcinogens 8 were applied. This
adjustment has the effect of increasing
the estimated lifetime risks for POM by
a factor of 1.6. In addition, although
only a small fraction of the total POM
emissions were not reported as
individual compounds, the EPA
expresses carcinogenic potency for
compounds in this group in terms of
benzo[a]pyrene equivalence, based on
evidence that carcinogenic POM has the
same mutagenic mechanism of action as
benzo[a]pyrene. For this reason, the
EPA’s Science Policy Council 9
recommends applying the Supplemental
Guidance to all carcinogenic polycyclic
aromatic hydrocarbons for which risk
estimates are based on relative potency.
Accordingly, we have applied the ADAF
6 U.S. EPA. Performing risk assessments that
include carcinogens described in the Supplemental
Guidance as having a mutagenic mode of action.
Science Policy Council Cancer Guidelines
Implementation Work Group Communication II:
Memo from W.H. Farland, dated October 4, 2005.
7 See the Risk Assessment for Source Categories
document available in the docket for a list of HAP
with a mutagenic mode of action.
8 U.S. EPA. Supplemental Guidance for Assessing
Early-Life Exposure to Carcinogens. EPA/630/R–03/
003F, 2005. https://www.epa.gov/ttn/atw/
childrens_supplement_final.pdf.
9 U.S. EPA. Science Policy Council Cancer
Guidelines Implementation Workgroup
Communication II: Memo from W.H. Farland, dated
June 14, 2006.
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to the benzo[a]pyrene equivalent
portion of all POM mixtures.
Incremental individual lifetime
cancer risks associated with emissions
from the source category were estimated
as the sum of the risks for each of the
carcinogenic HAP (including those
classified as carcinogenic to humans,
likely to be carcinogenic to humans and
suggestive evidence of carcinogenic
potential 10) emitted by the modeled
source. Cancer incidence and the
distribution of individual cancer risks
for the population within 50 km of any
source were also estimated for the
source category as part of these
assessments by summing individual
risks. A distance of 50 km is consistent
with both the analysis supporting the
1989 Benzene NESHAP (54 FR 38044)
and the limitations of Gaussian
dispersion models, including AERMOD.
To assess risk of noncancer health
effects from chronic exposures, we
summed the HQ for each of the HAP
that affects a common target organ
system to obtain the HI for that target
organ system (or target organ-specific
HI, TOSHI). The HQ for chronic
exposures is the estimated chronic
exposure divided by the chronic
reference level, which is either the EPA
reference concentration (RfC), defined
as ‘‘an estimate (with uncertainty
spanning perhaps an order of
magnitude) of a continuous inhalation
exposure to the human population
(including sensitive subgroups) that is
likely to be without an appreciable risk
of deleterious effects during a lifetime,’’
or, in cases where an RfC from the
EPA’s IRIS database is not available, a
value from the following prioritized
sources: (1) The agency for Toxic
Substances and Disease Registry
Minimum Risk Level, which is defined
as ‘‘an estimate of daily human
exposure to a substance that is likely to
be without an appreciable risk of
adverse effects (other than cancer) over
a specified duration of exposure’’; (2)
the CalEPA Chronic Reference Exposure
Level (REL), which is defined as ‘‘the
concentration level at or below which
no adverse health effects are anticipated
for a specified exposure duration;’’ or
10 These classifications also coincide with the
terms ‘‘known carcinogen, probable carcinogen and
possible carcinogen,’’ respectively, which are the
terms advocated in the EPA’s previous Guidelines
for Carcinogen Risk Assessment, published in 1986
(51 FR 33992, September 24, 1986). Summing the
risks of these individual compounds to obtain the
cumulative cancer risks is an approach that was
recommended by the EPA’s SAB in their 2002 peer
review of EPA’s NATA entitled, NATA—Evaluating
the National-scale Air Toxics Assessment 1996
Data—an SAB Advisory, available at: https://
yosemite.epa.gov/sab/sabproduct.nsf/
214C6E915BB04E14852570CA007A682C/$File/
ecadv02001.pdf.
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(3) as noted above, a scientifically
credible dose-response value that has
been developed in a manner consistent
with the EPA guidelines and has
undergone a peer review process similar
to that used by the EPA, in place of or
in concert with other values.
Screening estimates of acute
exposures and risks were also evaluated
for each of the HAP at the point of
highest off-site exposure for each facility
(i.e., not just the census block
centroids), assuming that a person is
located at this spot at a time when both
the peak (hourly) emission rates from
each emission point at the facility and
worst-case dispersion conditions occur.
The acute HQ is the estimated acute
exposure divided by the acute doseresponse value. In each case, acute HQ
values were calculated using best
available, short-term dose-response
values. These acute dose-response
values, which are described below,
include the acute REL, acute exposure
guideline levels (AEGL) and emergency
response planning guidelines (ERPG) for
1-hour exposure durations. As
discussed below, we used conservative
assumptions for emission rates,
meteorology and exposure location for
our acute analysis.
As described in the CalEPA’s Air
Toxics Hot Spots Program Risk
Assessment Guidelines, Part I, The
Determination of Acute Reference
Exposure Levels for Airborne Toxicants,
an acute REL value (https://
www.oehha.ca.gov/air/pdf/acuterel.pdf)
is defined as ‘‘the concentration level at
or below which no adverse health
effects are anticipated for a specified
exposure duration.’’ Acute REL values
are based on the most sensitive,
relevant, adverse health effect reported
in the medical and toxicological
literature. Acute REL values are
designed to protect the most sensitive
sub-populations (e.g., asthmatics) by the
inclusion of margins of safety. Since
margins of safety are incorporated to
address data gaps and uncertainties,
exceeding the acute REL does not
automatically indicate an adverse health
impact.
AEGL values were derived in
response to recommendations from the
National Research Council (NRC). As
described in Standing Operating
Procedures (SOP) of the National
Advisory Committee on Acute Exposure
Guideline Levels for Hazardous
Substances (https://www.epa.gov/
opptintr/aegl/pubs/sop.pdf),11 ‘‘the
NRC’s previous name for acute exposure
11 NAS, 2001. Standing Operating Procedures for
Developing Acute Exposure Levels for Hazardous
Chemicals, page 2.
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levels—community emergency exposure
levels—was replaced by the term AEGL
to reflect the broad application of these
values to planning, response, and
prevention in the community, the
workplace, transportation, the military,
and the remediation of Superfund
sites.’’ This document also states that
AEGL values ‘‘represent threshold
exposure limits for the general public
and are applicable to emergency
exposures ranging from 10 minutes to
eight hours.’’ The document lays out the
purpose and objectives of AEGL by
stating (page 21) that ‘‘the primary
purpose of the AEGL program and the
National Advisory Committee for Acute
Exposure Guideline Levels for
Hazardous Substances is to develop
guideline levels for once-in-a-lifetime,
short-term exposures to airborne
concentrations of acutely toxic, highpriority chemicals.’’ In detailing the
intended application of AEGL values,
the document states (page 31) that ‘‘[i]t
is anticipated that the AEGL values will
be used for regulatory and
nonregulatory purposes by U.S. Federal
and state agencies and possibly the
international community in conjunction
with chemical emergency response,
planning, and prevention programs.
More specifically, the AEGL values will
be used for conducting various risk
assessments to aid in the development
of emergency preparedness and
prevention plans, as well as real-time
emergency response actions, for
accidental chemical releases at fixed
facilities and from transport carriers.’’
The AEGL–1 value is then specifically
defined as ‘‘the airborne concentration
of a substance above which it is
predicted that the general population,
including susceptible individuals, could
experience notable discomfort,
irritation, or certain asymptomatic
nonsensory effects. However, the effects
are not disabling and are transient and
reversible upon cessation of exposure.’’
The document also notes (page 3) that,
‘‘Airborne concentrations below AEGL–
1 represent exposure levels that can
produce mild and progressively
increasing but transient and
nondisabling odor, taste, and sensory
irritation or certain asymptomatic,
nonsensory effects.’’ Similarly, the
document defines AEGL–2 values as
‘‘the airborne concentration (expressed
as ppm or mg/m3) of a substance above
which it is predicted that the general
population, including susceptible
individuals, could experience
irreversible or other serious, long-lasting
adverse health effects or an impaired
ability to escape.’’
ERPG values are derived for use in
emergency response, as described in the
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American Industrial Hygiene
Association’s document entitled,
Emergency Response Planning
Guidelines (ERPG) Procedures and
Responsibilities (https://www.aiha.org/
1documents/committees/
ERPSOPs2006.pdf) which states that,
‘‘Emergency Response Planning
Guidelines were developed for
emergency planning and are intended as
health based guideline concentrations
for single exposures to chemicals.’’ 12
The ERPG–1 value is defined as ‘‘the
maximum airborne concentration below
which it is believed that nearly all
individuals could be exposed for up to
1 hour without experiencing other than
mild transient adverse health effects or
without perceiving a clearly defined,
objectionable odor.’’ Similarly, the
ERPG–2 value is defined as ‘‘the
maximum airborne concentration below
which it is believed that nearly all
individuals could be exposed for up to
1 hour without experiencing or
developing irreversible or other serious
health effects or symptoms which could
impair an individual’s ability to take
protective action.’’
As can be seen from the definitions
above, the AEGL and ERPG values
include the similarly defined severity
levels 1 and 2. For many chemicals, a
severity level 1 value AEGL or ERPG has
not been developed; in these instances,
higher severity level AEGL–2 or ERPG–
2 values are compared to our modeled
exposure levels to assess potential for
acute concerns.
Acute REL values for 1-hour exposure
durations are typically lower than their
corresponding AEGL–1 and ERPG–1
values. Even though their definitions are
slightly different, AEGL–1 values are
often similar to the corresponding
ERPG–1 values, and AEGL–2 values are
often similar to ERPG–2 values.
Maximum HQ values from our acute
screening risk assessments typically
result when basing them on the acute
REL value for a particular pollutant. In
cases where our maximum acute HQ
value exceeds 1, we also report the HQ
value based on the next highest acute
dose-response value (usually the AEGL–
1 and/or the ERPG–1 value).
To develop screening estimates of
acute exposures, we developed
estimates of maximum hourly emission
rates by multiplying the average actual
annual hourly emission rates by a factor
to cover routinely variable emissions.
Acute risk modeling is conducted under
the assumption that peak emissions are
ten times greater than long term average
12 ERP Committee Procedures and
Responsibilities. November 1, 2006. American
Industrial Hygiene Association.
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emissions, in the absence of information
regarding the variability of the
emissions.
With respect to routine variable
emissions, primary aluminum potlines
have a more consistent emissions profile
than many other sources because these
emissions actually reflect the average of
the emissions from approximately 100
individual pots which operate in cycles
that are not in phase with each other.
Thus any variability associated with
aluminum levels or electrode
replacement for a particular pot may be
damped out by the other pots at
different stages. Alcoa provided to EPA
a series of hourly hydrogen fluoride
concentration data for two potlines at
their Wenatchee facility. Approximately
2,075 consecutive hourly readings were
provided based on Fourier Transform
Infrared measurements at the roof vents.
Alcoa found that the ratio of the
maximum HAP emission rate to the
average HAP emission rate for these two
potlines were 2.7 and 5.6. Only one
value out 2,075 consecutive hour
samples (0.05 percent) was more than 5
times the average (i.e., 99.95 percent of
values were less than 5 times the
average).
This dataset was then combined and
subjected to two statistical analysis
techniques: The upper prediction limit
(UPL) calculated assuming a log-normal
distribution after adjusting for temporal
correction and extreme value theory.
The average of the concentration values
is 514 mg/m3. The 99 percent UPL was
calculated at 2,215 mg/m, which
corresponds to 4.3 times the mean.
Using the extreme value theory, the
99.9 percentile estimate of the
generalized extreme value distribution
(corresponding to 1 observation in 1000)
was 2,306 mg/m3, which corresponds to
4.5 times the mean. Based on these data,
a source category factor of 5 times the
average hourly emissions rate, rather
than the default factor of 10, was used
in the acute screening assessment.
When worst-case HQ values from the
initial acute screen step were less than
1, acute impacts were deemed negligible
and no further analysis was performed.
In cases where an acute HQ value from
the screening step indicated the
potential for acute risk, we further
analyzed these values by considering
additional site-specific data to develop
a relatively more refined estimate of the
potential for acute impacts of concern.
This site-specific data includes the
facility layout that was used to
distinguish facility property from an
area where the public could be exposed.
These refinements are discussed in the
Draft Residual Risk Assessment for the
Primary Aluminum Production Source
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Category document, which is available
in the docket for this proposed
rulemaking.
Ideally, we would prefer to have
continuous measurements over time to
see how the emissions vary by each
hour over an entire year. Having a
frequency distribution of hourly
emission rates over a year would allow
us to perform a probabilistic analysis to
estimate potential threshold
exceedances and their frequency of
occurrence. Such an evaluation could
include a more complete statistical
treatment of the key parameters and
elements adopted in this screening
analysis. However, we recognize that
having this level of data is rare, hence
our use of the multiplier approach.
To better characterize the potential
health risks associated with estimated
acute exposures to HAP, and in
response to a key recommendation from
the SAB’s peer review of the EPA’s RTR
risk assessment methodologies,13 we
generally examine a wider range of
available acute health metrics than we
do for our chronic risk assessments.
This is in response to the SAB’s
acknowledgement that there are
generally more data gaps and
inconsistencies in acute reference
values than there are in chronic
reference values. Comparisons of the
estimated maximum off-site 1-hour
exposure levels are not typically made
to occupational levels for the purpose of
characterizing public health risks in
RTR assessments. This is because they
are developed for working-age adults
and are not generally considered
protective for the general public. We
note that occupational ceiling values
are, for most chemicals, set at levels
higher than a 1-hour AEGL–1.
4. Conducting Multi-Pathway Exposure
and Risk Screening
The potential for significant human
health risks due to exposures via routes
other than inhalation (i.e., multipathway exposures) and the potential
for adverse environmental impacts were
evaluated in a three-step process. In the
first step, we determined whether any
facilities emitted any PB–HAP (HAP
known to be persistent and bioaccumulative in the environment).
There are 14 PB–HAP compounds or
compound classes identified for this
screening in the EPA’s Air Toxics Risk
Assessment Library (available at https://
www.epa.gov/ttn/fera/
risk_atra_vol1.html). They are cadmium
13 The SAB peer review of RTR Risk Assessment
Methodologies is available at: https://
yosemite.epa.gov/sab/sabproduct.nsf/
4AB3966E263D943A8525771F00668381/$File/EPASAB-10-007-unsigned.pdf.
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compounds, chlordane, chlorinated
dibenzodioxins and furans,
dichlorodiphenyldichloroethylene,
heptachlor, hexachlorobenzene,
hexachlorocyclohexane, lead
compounds, mercury compounds,
methoxychlor, polychlorinated
biphenyls, POM, toxaphene and
trifluralin.
Since POM is a PB–HAP and is
emitted by all facilities in this source
category, we proceeded to the second
step of the evaluation to screen for
potentially significant multi-pathway
risks due to POM emissions. In this
step, we determined whether the
facility-specific emission rates of POM
were large enough to create the potential
for significant non-inhalation human or
environmental risks under reasonable
worst-case conditions. To facilitate this
step, we have developed emission rate
thresholds for each PB–HAP using a
hypothetical worst-case screening
exposure scenario developed for use in
conjunction with the EPA’s TRIM.FaTE
model. The hypothetical screening
scenario was subjected to a sensitivity
analysis to ensure that its key design
parameters were established such that
environmental media concentrations
were not underestimated (i.e., to
minimize the occurrence of false
negatives or results that suggest that
risks might be acceptable when, in fact,
actual risks are high) and to also
minimize the occurrence of false
positives for human health endpoints.
We call this application of the
TRIM.FaTE model TRIM-Screen. The
facility-specific emission rates of POM
were compared to the TRIM-Screen
emission threshold values for POM to
assess the potential for significant
human health risks or environmental
risks via non-inhalation pathways.
5. Assessing Risks Considering
Emissions Control Options
In addition to assessing baseline
inhalation risks and screening for
potential multi-pathway risks, where
appropriate, we also estimated risks
considering the potential emission
reductions that would be achieved by
the particular control options under
consideration. In these cases, the
expected emissions reductions were
applied to the specific HAP and
emissions sources in the source category
dataset to develop corresponding
estimates of risk reductions.
6. Conducting Other Risk-Related
Analyses: Facility Wide Assessments
To put the source category risks in
context, for our residual risk reviews,
we also typically examine the risks from
the entire ‘‘facility,’’ where the facility
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includes all HAP-emitting operations
within a contiguous area and under
common control. In these facility wide
assessments we examine the HAP
emissions not only from the source
category of interest, but also emissions
of HAP from all other emissions sources
at the facility. Eleven of the primary
aluminum reduction plants are
collocated with secondary aluminum
production operations. Based on a
general knowledge of these facilities, we
believe that the Primary Aluminum
sources are the largest sources of HAP
emissions at each of them. Moreover, we
plan to do a facility wide assessment for
each of these eleven facilities in an
upcoming RTR rulemaking for the
Secondary Aluminum source category.
Therefore, we did not perform a facility
wide risk assessment for these eleven
facilities as part of today’s action. For
the four primary aluminum facilities
that are not collocated with secondary
aluminum production operations, the
risk assessment performed as part of
today’s action is a facility wide risk
assessment.
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7. Considering Uncertainties in Risk
Assessment
Uncertainty and the potential for bias
are inherent in all risk assessments,
including those performed for the
Primary Aluminum source category
addressed in this proposal. Although
uncertainty exists, we believe that our
approach, which used conservative
tools and assumptions, ensures that our
decisions are health-protective. A brief
discussion of the uncertainties in the
emissions datasets, dispersion
modeling, inhalation exposure estimates
and dose-response relationships follows
below. A more thorough discussion of
these uncertainties is included in the
risk assessment documentation
(referenced earlier) available in the
docket for this action.
a. Uncertainties in the Emissions
Datasets
Although the development of the
MACT dataset involved QA/quality
control processes, the accuracy of
emissions values will vary depending
on the source of the data, the degree to
which data are incomplete or missing,
the degree to which assumptions made
to complete the datasets are inaccurate,
errors in estimating emissions values
and other factors. The emission
estimates considered in this analysis
generally are annual totals for certain
years that do not reflect short-term
fluctuations during the course of a year
or variations from year to year.
The estimates of peak hourly emission
rates for the acute effects screening
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assessment were based on a
multiplication factor of 5 applied to the
average annual hourly emission rate,
which is intended to account for
emission fluctuations due to normal
facility operations.
b. Uncertainties in Dispersion Modeling
While the analysis employed the
EPA’s recommended regulatory
dispersion model, AERMOD, we
recognize that there is uncertainty in
ambient concentration estimates
associated with any model, including
AERMOD. In circumstances where we
had to choose between various model
options, where possible, model options
(e.g., rural/urban, plume depletion,
chemistry) were selected to provide an
overestimate of ambient air
concentrations of the HAP rather than
underestimates. However, because of
practicality and data limitation reasons,
some factors (e.g., meteorology, building
downwash) have the potential in some
situations to overestimate or
underestimate ambient impacts. For
example, meteorological data were
taken from a single year (1991), and
facility locations can be a significant
distance from the sites where these data
were taken. Despite these uncertainties,
we believe that at off-site locations and
census block centroids, the approach
considered in the dispersion modeling
analysis should generally yield
overestimates of ambient HAP
concentrations.
c. Uncertainties in Inhalation Exposure
The effects of human mobility on
exposures were not included in the
assessment. Specifically, short-term
mobility and long-term mobility
between census blocks in the modeling
domain were not considered.14 The
assumption of not considering short or
long-term population mobility does not
bias the estimate of the theoretical MIR,
nor does it affect the estimate of cancer
incidence since the total population
number remains the same. It does,
however, affect the shape of the
distribution of individual risks across
the affected population, shifting it
toward higher estimated individual
risks at the upper end and reducing the
number of people estimated to be at
lower risks, thereby increasing the
estimated number of people at specific
risk levels.
In addition, the assessment predicted
the chronic exposures at the centroid of
each populated census block as
14 Short-term mobility is movement from one
micro-environment to another over the course of
hours or days. Long-term mobility is movement
from one residence to another over the course of a
lifetime.
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surrogates for the exposure
concentrations for all people living in
that block. Using the census block
centroid to predict chronic exposures
tends to over-predict exposures for
people in the census block who live
further from the facility, and underpredict exposures for people in the
census block who live closer to the
facility. Thus, using the census block
centroid to predict chronic exposures
may lead to a potential understatement
or overstatement of the true maximum
impact, but it is an unbiased estimate of
average risk and incidence.
The assessments evaluate the cancer
inhalation risks associated with
continuous pollutant exposures over a
70-year period, which is the assumed
lifetime of an individual. In reality, both
the length of time that modeled
emissions sources at facilities actually
operate (i.e., more or less than 70 years)
and the domestic growth or decline of
the modeled industry (i.e., the increase
or decrease in the number or size of
United States facilities) will influence
the risks posed by a given source
category. Depending on the
characteristics of the industry, these
factors will, in most cases, result in an
overestimate both in individual risk
levels and in the total estimated number
of cancer cases. However, in rare cases,
where a facility maintains or increases
its emission levels beyond 70 years,
residents live beyond 70 years at the
same location, and the residents spend
most of their days at that location, then
the risks could potentially be
underestimated. Annual cancer
incidence estimates from exposures to
emissions from these sources would not
be affected by uncertainty in the length
of time emissions sources operate.
The exposure estimates used in these
analyses assume chronic exposures to
ambient levels of pollutants. Because
most people spend the majority of their
time indoors, actual exposures may not
be as high, depending on the
characteristics of the pollutants
modeled. For many of the HAP, indoor
levels are roughly equivalent to ambient
levels, but for very reactive pollutants or
larger particles, these levels are
typically lower. This factor has the
potential to result in an overstatement of
25 to 30 percent of exposures.15
In addition to the uncertainties
highlighted above, there are several
other factors specific to the acute
exposure assessment. The accuracy of
an acute inhalation exposure assessment
depends on the simultaneous
15 U.S. EPA. National-Scale Air Toxics
Assessment for 1996. (EPA 453/R–01–003; January
2001; page 85.)
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occurrence of independent factors that
may vary greatly, such as hourly
emissions rates, meteorology, and
human activity patterns. In this
assessment, we assume that individuals
remain for 1 hour at the point of
maximum ambient concentration as
determined by the co-occurrence of
peak emissions and worst-case
meteorological conditions. These
assumptions would tend to overestimate
actual exposures since it is unlikely that
a person would be located at the point
of maximum exposure during the time
of worst-case impact.
d. Uncertainties in Dose-Response
Relationships
There are uncertainties inherent in
the development of the dose-response
values used in our risk assessments for
cancer effects from chronic exposures
and noncancer effects from both chronic
and acute exposures. Some
uncertainties may be considered
quantitatively, and others generally are
expressed in qualitative terms. We note
as a preface to this discussion a point on
dose-response uncertainty that is
brought out in the EPA 2005 Cancer
Guidelines; namely, that ‘‘the primary
goal of the EPA actions is protection of
human health; accordingly, as an agency
policy, risk assessment procedures,
including default options that are used
in the absence of scientific data to the
contrary, should be health protective.’’
(EPA 2005 Cancer Guidelines, pages 1–
7.) This is the approach followed here
as summarized in the next several
paragraphs. A complete detailed
discussion of uncertainties and
variability in dose-response
relationships is given in the residual
risk documentation, which is available
in the docket for this action.
Cancer URE values used in our risk
assessments are those that have been
developed to generally provide an upper
bound estimate of risk. That is, they
represent a ‘‘plausible upper limit to the
true value of a quantity’’ (although this
is usually not a true statistical
confidence limit).16 In some
circumstances, the true risk could be as
low as zero; however, in other
circumstances, the risk could also be
greater.17 When developing an upper
bound estimate of risk and to provide
risk values that do not underestimate
risk, health-protective default
approaches are generally used. To err on
16 IRIS glossary (https://www.epa.gov/NCEA/iris/
help_gloss.htm).
17 An exception to this is the URE for benzene,
which is considered to cover a range of values, each
end of which is considered to be equally plausible
and which is based on maximum likelihood
estimates.
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the side of ensuring adequate healthprotection, the EPA typically uses the
upper bound estimates rather than
lower bound or central tendency
estimates in our risk assessments, an
approach that may have limitations for
other uses (e.g., priority-setting or
expected benefits analysis).
Chronic noncancer reference (RfC and
reference dose (RfD)) values represent
chronic exposure levels that are
intended to be health-protective levels.
Specifically, these values provide an
estimate (with uncertainty spanning
perhaps an order of magnitude) of daily
oral exposure (RfD) or of a continuous
inhalation exposure (RfC) to the human
population (including sensitive
subgroups) that is likely to be without
an appreciable risk of deleterious effects
during a lifetime. To derive values that
are intended to be ‘‘without appreciable
risk,’’ the methodology relies upon an
uncertainty factor (UF) approach (U.S.
EPA, 1993, 1994) which includes
consideration of both uncertainty and
variability. When there are gaps in the
available information, UF are applied to
derive reference values that are
intended to protect against appreciable
risk of deleterious effects. The UF are
commonly default values,18 e.g., factors
of 10 or 3, used in the absence of
compound-specific data; where data are
available, UF may also be developed
using compound-specific information.
When data are limited, more
assumptions are needed and more UF
are used. Thus, there may be a greater
tendency to overestimate risk in the
sense that further study might support
development of reference values that are
higher (i.e., less potent) because fewer
default assumptions are needed.
However, for some pollutants, it is
possible that risks may be
underestimated. While collectively
termed ‘‘uncertainty factor,’’ these
18 According to the NRC report, Science and
Judgment in Risk Assessment (NRC, 1994)
‘‘[Default] options are generic approaches, based on
general scientific knowledge and policy judgment,
that are applied to various elements of the risk
assessment process when the correct scientific
model is unknown or uncertain.’’ The 1983 NRC
report, Risk Assessment in the Federal Government:
Managing the Process, defined default option as
‘‘the option chosen on the basis of risk assessment
policy that appears to be the best choice in the
absence of data to the contrary’’ (NRC, 1983a, p. 63).
Therefore, default options are not rules that bind
the Agency; rather, the Agency may depart from
them in evaluating the risks posed by a specific
substance when it believes this to be appropriate.
In keeping with EPA’s goal of protecting public
health and the environment, default assumptions
are used to ensure that risk to chemicals is not
underestimated (although defaults are not intended
to overtly overestimate risk). See EPA, 2004, An
Examination of EPA Risk Assessment Principles
and Practices, EPA/100/B–04/001 available at:
https://www.epa.gov/osa/pdfs/ratf-final.pdf.
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factors account for a number of different
quantitative considerations when using
observed animal (usually rodent) or
human toxicity data in the development
of the RfC. The UF are intended to
account for: (1) Variation in
susceptibility among the members of the
human population (i.e., inter-individual
variability); (2) uncertainty in
extrapolating from experimental animal
data to humans (i.e., interspecies
differences); (3) uncertainty in
extrapolating from data obtained in a
study with less-than-lifetime exposure
(i.e., extrapolating from sub-chronic to
chronic exposure); (4) uncertainty in
extrapolating the observed data to
obtain an estimate of the exposure
associated with no adverse effects; and
(5) uncertainty when the database is
incomplete or there are problems with
the applicability of available studies.
Many of the UF used to account for
variability and uncertainty in the
development of acute reference values
are quite similar to those developed for
chronic durations, but they more often
use individual UF values that may be
less than 10. UF are applied based on
chemical-specific or health effectspecific information (e.g., simple
irritation effects do not vary appreciably
between human individuals, hence a
value of 3 is typically used), or based on
the purpose for the reference value (see
the following paragraph). The UF
applied in acute reference value
derivation include: (1) Heterogeneity
among humans; (2) uncertainty in
extrapolating from animals to humans;
(3) uncertainty in lowest observed
adverse effect (exposure) level to no
observed adverse effect (exposure) level
adjustments; and (4) uncertainty in
accounting for an incomplete database
on toxic effects of potential concern.
Additional adjustments are often
applied to account for uncertainty in
extrapolation from observations at one
exposure duration (e.g., 4 hours) to
derive an acute reference value at
another exposure duration (e.g., 1 hour).
Not all acute reference values are
developed for the same purpose, and
care must be taken when interpreting
the results of an acute assessment of
human health effects relative to the
reference value or values being
exceeded. Where relevant to the
estimated exposures, the lack of shortterm dose-response values at different
levels of severity should be factored into
the risk characterization as potential
uncertainties.
Although every effort is made to
identify peer-reviewed reference values
for cancer and noncancer effects for all
pollutants emitted by the sources
included in this assessment, some HAP
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continue to have no reference values for
cancer or chronic noncancer or acute
effects. Since exposures to these
pollutants cannot be included in a
quantitative risk estimate, an
understatement of risk for these
pollutants at environmental exposure
levels is possible. For a group of
compounds that are either unspeciated
or do not have reference values for every
individual compound (e.g., glycol
ethers), we conservatively use the most
protective reference value to estimate
risk from individual compounds in the
group of compounds.
Additionally, chronic reference values
for several of the compounds included
in this assessment are currently under
the EPA IRIS review, and revised
assessments may determine that these
pollutants are more or less potent than
the current value. We may re-evaluate
residual risks for the final rulemaking if
these reviews are completed prior to our
taking final action for this source
category and a dose-response metric
changes enough to indicate that the risk
assessment supporting this notice may
significantly understate human health
risk.
jlentini on DSK4TPTVN1PROD with PROPOSALS3
e. Uncertainties in the Multi-Pathway
and Environmental Effects Screening
Assessment
We generally assume that when
exposure levels are not anticipated to
adversely affect human health, they also
are not anticipated to adversely affect
the environment. For each source
category, we generally rely on the sitespecific levels of PB–HAP emissions to
determine whether a full assessment of
the multi-pathway and environmental
effects is necessary. For this source
category, we only performed a multipathway screening assessment for PB–
HAP. Thus, it is important to note that
potential PB–HAP multi-pathway risks
are biased high.
C. How did we consider the risk results
in making decisions for this proposal?
In evaluating and developing
standards under section 112(f)(2), as
discussed in section I.A of this
preamble, we apply a two-step process
to address residual risk. In the first step,
the EPA determines whether risks are
acceptable. This determination
‘‘considers all health information,
including risk estimation uncertainty,
and includes a presumptive limit on
maximum individual lifetime [cancer]
risk (MIR) 19 of approximately 1-in-10
19 Although defined as ‘‘maximum individual
risk,’’ MIR refers only to cancer risk. MIR, one
metric for assessing cancer risk, is the estimated
risk were an individual exposed to the maximum
level of a pollutant for a lifetime.
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thousand [i.e., 100-in-1 million]’’ (54 FR
38045). In the second step of the
process, the EPA sets the standard at a
level that provides an ample margin of
safety ‘‘in consideration of all health
information, including the number of
persons at risk levels higher than
approximately 1-in-1 million, as well as
other relevant factors, including costs
and economic impacts, technological
feasibility, and other factors relevant to
each particular decision’’ (Id.)
In past residual risk actions, the EPA
has presented and considered a number
of human health risk metrics associated
with emissions from the category under
review, including: The MIR; the
numbers of persons in various risk
ranges; cancer incidence; the maximum
non-cancer hazard index (HI); and the
maximum acute non-cancer hazard (72
FR 25138, May 3, 2007; 71 FR 42724,
July 27, 2006). In more recent proposals
(75 FR 65068, October 21, 2010, and 75
FR 80220, December 21, 2010), the EPA
also presented and considered
additional measures of health
information, such as estimates of the
risks associated with the maximum
level of emissions which might be
allowed by the current MACT standards
(see, e.g., 75 FR 65068, October 21,
2010, and 75 FR 80220, December 21,
2010). The EPA also discussed and
considered risk estimation
uncertainties. The EPA is providing this
same type of information in support of
the proposed actions described in this
Federal Register notice.
The agency is considering all
available health information to inform
our determinations of risk acceptability
and ample margin of safety under CAA
section 112(f). Specifically, as explained
in the Benzene NESHAP, ‘‘the first step
judgment on acceptability cannot be
reduced to any single factor’’ and thus
‘‘[t]he Administrator believes that the
acceptability of risk under [previous]
section 112 is best judged on the basis
of a broad set of health risk measures
and information’’ (54 FR 38046).
Similarly, with regard to making the
ample margin of safety determination,
as stated in the Benzene NESHAP ‘‘[in
the ample margin decision, the agency
again considers all of the health risk and
other health information considered in
the first step. Beyond that information,
additional factors relating to the
appropriate level of control will also be
considered, including cost and
economic impacts of controls,
technological feasibility, uncertainties,
and any other relevant factors.’’ Id.
The agency acknowledges that the
Benzene NESHAP provides flexibility
regarding what factors the EPA might
consider in making determinations and
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76273
how these factors might be weighed for
each source category. In responding to
comment on our policy under the
Benzene NESHAP, the EPA explained
that: ‘‘The policy chosen by the
Administrator permits consideration of
multiple measures of health risk. Not
only can the MIR figure be considered,
but also incidence, the presence of noncancer health effects, and the
uncertainties of the risk estimates. In
this way, the effect on the most exposed
individuals can be reviewed as well as
the impact on the general public. These
factors can then be weighed in each
individual case. This approach complies
with the Vinyl Chloride mandate that
the Administrator ascertain an
acceptable level of risk to the public by
employing [her] expertise to assess
available data. It also complies with the
Congressional intent behind the CAA,
which did not exclude the use of any
particular measure of public health risk
from the EPA’s consideration with
respect to CAA section 112 regulations,
and, thereby, implicitly permits
consideration of any and all measures of
health risk which the Administrator, in
[her] judgment, believes are appropriate
to determining what will ‘protect the
public health’ ’’ (54 FR 38057).
Thus, the level of the MIR is only one
factor to be weighed in determining
acceptability of risks. The Benzene
NESHAP explained that ‘‘an MIR of
approximately 1-in-10 thousand should
ordinarily be the upper end of the range
of acceptability. As risks increase above
this benchmark, they become
presumptively less acceptable under
CAA section 112, and would be
weighed with the other health risk
measures and information in making an
overall judgment on acceptability. Or,
the agency may find, in a particular
case, that a risk that includes MIR less
than the presumptively acceptable level
is unacceptable in the light of other
health risk factors’’ (Id. at 38045).
Similarly, with regard to the ample
margin of safety analysis, the EPA stated
in the Benzene NESHAP that: ‘‘* * *
the EPA believes the relative weight of
the many factors that can be considered
in selecting an ample margin of safety
can only be determined for each specific
source category. This occurs mainly
because technological and economic
factors (along with the health-related
factors) vary from source category to
source category’’ (Id. at 38061).
D. How did we perform the technology
review?
Our technology review focused on the
identification and evaluation of
developments in practices, processes,
and control technologies that have
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occurred since the Primary Aluminum
Reduction Plant NESHAP was
promulgated.
Based on our analyses of the data and
information collected from industry and
the trade organization representing all
facilities subject to the NESHAP, our
general understanding of the industry,
and other available information in the
literature on potential controls for this
industry, we identified no new
developments in practices, processes,
and control technologies. For the
purpose of this exercise, we considered
any of the following to be a
‘‘development’’:
• Any add-on control technology or
other equipment that was not identified
and considered during development of
the 1997 Primary Aluminum Reduction
Plant NESHAP.
• Any improvements in add-on
control technology or other equipment
(that were identified and considered
during development of the 1997 Primary
Aluminum Reduction Plant NESHAP)
that could result in significant
additional emissions reduction.
• Any work practice or operational
procedure that was not identified or
considered during development of the
1997 Primary Aluminum Reduction
Plant NESHAP.
• Any process change or pollution
prevention alternative that could be
broadly applied to the industry and that
was not identified or considered during
development of the 1997 Primary
Aluminum Reduction Plant NESHAP.
We also consulted the EPA’s RACT/
BACT/LAER Clearinghouse (RBLC) to
identify potential technology advances.
Control technologies classified as RACT
(Reasonably Available Control
Technology), BACT (Best Available
Control Technology), or LAER (Lowest
Achievable Emissions Rate) apply to
stationary sources depending on
whether the sources exist or new and on
the size, age, and location of the facility.
BACT and LAER (and sometimes RACT)
are determined on a case-by-case basis,
usually by State or local permitting
agencies. The EPA established the RBLC
to provide a central database of air
pollution technology information
(including technologies required in
source-specific permits) to promote the
sharing of information among
permitting agencies and to aid in
identifying future possible control
technology options that might apply
broadly to numerous sources within a
category or apply only on a source-bysource basis. The RBLC contains over
5,000 air pollution control permit
determinations that can help identify
appropriate technologies to mitigate
many air pollutant emissions streams.
We searched this database to determine
whether it contained any practices,
processes, or control technologies for
the types of processes covered by the
Primary Aluminum Reduction Plant
NESHAP. No such practices, processes,
or control technologies were identified
in this database.
E. What other issues are we addressing
in this proposal?
In addition to the analyses described
above, we also reviewed other aspects of
the MACT standards for possible
revision as appropriate and necessary.
Based on this review we have identified
aspects of the MACT standards that we
believe need revision.
This includes proposing revisions to
the startup, shutdown and malfunction
(SSM) provisions of the MACT rule in
order to ensure that they are consistent
with a recent court decision in Sierra
Club v. EPA, 551 F. 3d 1019 (DC Cir.
2008). In addition, we are proposing
other changes to the rule which are not
based on residual risk. These include
establishing MACT floor-based
standards for POM emissions from
prebake potlines, COS emissions from
all potlines, and design standards for
control of POM emissions from existing
pitch storage tanks. We are also
proposing changes to the rule related to
affirmative defense for exceedance of an
emission limit during a malfunction.
The analyses and proposed decisions for
these actions are presented in section IV
of this preamble.
IV. Analytical Results and Proposed
Decisions
This section of the preamble provides
the results of our RTR for the Primary
Aluminum Reduction Plant source
category and our proposed decisions
concerning changes to the Primary
Aluminum Reduction Plant NESHAP.
A. What are the results of our analyses
and proposed decisions regarding
unregulated emissions sources?
The current MACT rule has no
standards for POM from prebake
potlines. Prebake facilities have
significantly lower POM emissions
compared to Soderberg facilities.
Nevertheless, these emissions are not
negligible. We are proposing to establish
MACT emission limits for POM from
prebake potlines in this action. The
typical controls used on these prebake
potlines to limit the primary (i.e., stack)
emissions, and which reflect the MACT
floor level of control, are dry alumina
scrubbers (with a baghouse). We
calculated MACT floor limits for these
potlines based on the limited available
data. We also considered possible
controls beyond the MACT floor, such
as wet roof scrubbers, but we estimated
that these beyond-the-floor controls
would only achieve approximately an
additional 30 percent reduction in
secondary (i.e., roof vent) emissions and
that the costs of these additional
controls would be quite high (e.g., well
over $100 million in capital costs for the
industry). We estimate that the cost of
controlling POM from prebake potroom
secondary emissions would be
approximately $800,000 per ton.
Therefore, we are proposing emission
limits for POM from prebake potlines,
after considering variability in
emissions using a 99% upper prediction
level approach, based on the MACT
floor. We are proposing a POM emission
limit for new prebake potlines equal to
the lowest limit for existing prebake
potlines (developed from data obtained
from the best performing sources
(center-worked prebake one) facilities).
More details about the data and analyses
used to derive the MACT limits, and
explanation of the beyond-the-floor
analyses, are provided in the technical
document Draft MACT Floor Analysis
for the Primary Aluminum Production
Source Category which is available in
the docket for this proposed action. The
proposed limits for prebake potlines are
shown in Table 5.
jlentini on DSK4TPTVN1PROD with PROPOSALS3
TABLE 5—PROPOSED EMISSION LIMITS FOR NEW AND EXISTING PREBAKE POTLINES
Source
Pollutant
Existing Prebake:
CWPB1 potlines ...................................................................
CWPB2 potlines ...................................................................
CWPB3 potlines ...................................................................
SWPB potlines: ....................................................................
New Prebake:
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POM
POM
POM
POM
.............
.............
.............
.............
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Emission limit
0.31
0.65
0.63
0.33
Sfmt 4702
kg/Mg
kg/Mg
kg/Mg
kg/Mg
(0.62 lb/ton) of aluminum produced.
(1.3 lb/ton) of aluminum produced.
(1.26 lb/ton) of aluminum produced.
(0.65 lb/ton) of aluminum produced.
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TABLE 5—PROPOSED EMISSION LIMITS FOR NEW AND EXISTING PREBAKE POTLINES—Continued
Pollutant
All prebake potline types ......................................................
jlentini on DSK4TPTVN1PROD with PROPOSALS3
As mentioned above, the current
MACT rule has no standards for COS. It
is very difficult and quite expensive to
measure total COS emissions because
the concentrations of secondary
emissions are below the detection limit
of the EPA reference method. However,
stack tests are feasible and have been
completed. Moreover, emissions studies
have been completed using an
experimental test method to estimate
COS emissions from these secondary
emissions sources (Determination of
COS to SO2 Ratio in Smelting Process
Emissions at the Alcoa Warrick
Operations, 4 August 1995). We have
been able to use the experimental test
results along with stack test data and
data on sulfur content of input materials
to estimate total COS emissions. We
have determined that there is a direct
relationship between the COS emissions
and the sulfur content of raw materials.
The results of these studies indicate that
an estimated 8 percent of the sulfur
present in the coke (used to make
anodes) is converted to COS emissions.
Given the technical difficulties of
measuring secondary COS emissions
directly, and given that there is a direct
relationship between sulfur content of
input materials and COS emissions, we
developed a mass balance equation for
calculating COS emissions. Using this
approach, we developed a proposed
MACT standard for COS using the mass
balance equation. The equation derives
monthly COS emission rates based on
anode coke sulfur content, anode
consumption and aluminum
production, as follows:
Where:
ECOS = the facility wide emission rate of COS
during the calendar month in pounds per
ton of aluminum produced;
K = factor accounting for molecular weights
and conversion of sulfur to carbonyl
sulfide = 234;
Y = the tons of anode used at the facility
during the calendar month;
Z = the tons of aluminum produced at the
facility during the calendar month; and
%S = the weighted average sulfur content of
the anode coke utilized in the
production of aluminum during the
calendar month (e.g., if the weighted
average sulfur content of the anode coke
utilized during the calendar month was
2.5%, then %S = 0.025).
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POM .............
Emission limit
0.31 kg/Mg (0.62 lb/ton) of aluminum produced.
Using this method, we are proposing
a MACT floor limit for COS for existing
facilities at 3.9 pounds of COS per ton
of aluminum produced (lb/ton Al),
based on data obtained from the five
facilities with the lowest calculated COS
emissions and adjustment to account for
variability using a 99% upper
prediction limit approach. With regard
to costs for this standard, we estimate
that all facilities will be able to meet
this limit with minimal additional costs
(e.g., calculating COS emissions and the
associated monitoring, recordkeeping
and reporting). With regard to new
sources, the MACT floor limit for COS
for new facilities is proposed at 3.1 lb
COS/ton Al, based on data obtained
from the facility with the lowest
calculated COS emissions and
adjustment to account for variability.
We also considered beyond-the-floor
options for COS. For example, we
assessed the feasibility and costs of
proposing that all existing facilities
meet a limit of 3.1 lb COS/ton Al. We
estimate that a limit at this level would
impact 5 facilities, result in 220 tpy
reductions of COS emissions, at a total
cost of $13,000,000 (or $2.6 million per
facility) per year. However, there are
significant uncertainties regarding the
future availability and costs of the
associated lower-sulfur anode coke. The
Primary Aluminum industry obtains
most of their coke as a by-product from
the gas and oil refinery industry. It is
our understanding that currently
available coke with low sulfur contents
could be very hard to obtain in the
future and will likely be much more
expensive. This situation is expected
due to the following: (1) The type of
crude oil input at refineries in the future
is generally expected to be heavier and,
therefore, less likely to result in ‘‘anode
grade coke’’ that has the structure
necessary for use in anode production;
(2) the type of crude oil input at
refineries in the future is generally
expected to have higher sulfur content
because the per barrel cost of heavy sour
(i.e., high-sulfur) crude oil is so much
lower than light sweet (i.e., low-sulfur)
crude oil; (3) refineries initially
designed to process light sweet crude oil
are being converted to process heavy
sour crude oil at a rapid pace worldwide
due to refinery economics; (4) refineries
are designed to desulfurize the product
streams (gasoline, diesel, etc.), not the
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Sfmt 4702
crude oil input, and the sulfur in the
crude oil tends to concentrate in the
petroleum coke (i.e., the ‘‘bottoms’’); (5)
unwillingness of refineries to
preferentially process light sweet crude
oil in place of heavy sour crude oil due
to unfavorable economics (i.e., refineries
will not modify their operations to
change the quality of a by-product such
as petroleum coke); and (6) the lack of
leverage that primary aluminum
companies have over the quality of this
by-product, as coke is a very low profit
item for refineries and anode grade coke
represents less than 20% of all the
petroleum coke produced worldwide.
Thus, based on future availability of
low-sulfur coke, the true long term costs
could exceed the present estimated cost
of $13,000,000 per year.
We also evaluated the feasibility and
costs of another beyond-the-floor option
of requiring that all existing facilities
meet a limit of 3.5 lb COS/ton Al. We
estimate that a limit at this level would
impact 2 facilities, result in 52 tpy
reductions of COS emissions, at a total
cost of $2,000,000 (or $1 million per
facility) per year. Once again, these
estimated costs could be significant
underestimates of the true long-term
costs. The uncertainties and concerns
about the future availability and costs of
the required low-sulfur content coke
that are described above for the 3.1 lb
COS/ton Al option are also a concern for
this 3.5 lb COS/ton Al option.
We also considered control options
including incineration and scrubbing of
COS. The cost of incineration would be
quite high due to the volume (typically
millions of cubic feet per minute) and
the relatively low temperature of the
exhaust stream (typically less than 200
°F). Incineration also involves the
disadvantage of the generation of sulfur
dioxide and other pollutants. Similarly,
the cost of scrubbers would be quite
high and involve the disadvantage of
generating a waste sludge stream.
Given the analyses and conclusions
described above, we are proposing a
MACT standard for COS for existing
facilities based on the MACT floor
analysis, which is a limit of 3.9 lb COS/
ton Al. With regard to new sources, we
are proposing a MACT standard for COS
based on the MACT floor analysis,
which is a limit of 3.1 lb COS/ton Al.
With regard to POM emissions from
pitch storage tanks, the 1997 NESHAP
included MACT standards for new pitch
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storage tanks, which required a 95
percent reduction in POM emissions.
However, the 1997 NESHAP had no
limits for existing storage tanks. We are
proposing in today’s action that existing
tanks will be subject to the same
standard (i.e., minimum of 95 percent
reduction of POM emissions). At least
three facilities are currently achieving
this level of control. We estimate that
eight facilities would be affected by this
standard and would need to add
controls, at a total annualized cost of
about $21,000 per facility. We also
estimate that this would achieve 1.6
tons reductions in POM emissions per
year.
A non-contact single stage,
refrigerated, water cooled condenser
system was considered as a beyond the
floor option for POM from pitch storage
tanks. However, we believe the
associated cost (estimated at $184,000
per year, per facility) is not justified by
the incremental control of HAP
(estimated at 0.081 tons per year for the
industry).
B. What are the results of the risk
assessments?
For the Primary Aluminum source
category, we conducted an inhalation
risk assessment for all HAP emitted. We
also conducted multi-pathway screening
analyses for PB–HAP emitted (i.e.,
POM). Results of the risk assessment are
presented briefly below and in more
detail in the residual risk
documentation referenced in section III
of this preamble, which is available in
the docket for this action.
Table 6 of this preamble provides an
overall summary of the results of the
inhalation risk assessment.
TABLE 6—PRIMARY ALUMINUM REDUCTION PLANT INHALATION RISK ASSESSMENT RESULTS
Maximum individual cancer risk
(in 1 million) 1
Based on actual emissions level
Based on
allowable
emissions
level 4 5
Estimated
population
at increased
risk of
cancer
≥1-in-1
million
Estimated
annual
cancer
incidence
(cases per
year)
30 ...........................................................................
100
41,000
0.005
Maximum chronic non-cancer TOSHI 2
Based on
actual
emissions
level
Based on
allowable
emissions
level
0.4
0.6
Worst-case
maximum refined
screening acute
non-cancer HQ 3
HQREL 10 (HF)
HQAEGL-1
4 (HF)
1 Estimated
maximum individual excess lifetime cancer risk due to HAP emissions from the source category.
TOSHI. The target organ with the highest TOSHI for the primary aluminum source category is the skeletal system.
3 See section III.B of this preamble for explanations of acute dose-response values.
4 The facility with the highest MIR based on allowable emissions is the Columbia Falls facility. Notably, this facility has not operated in approximately 2 years and therefore, the EPA did not generate risk estimates (i.e., MIR, TOSHI, and acute screening values) based on actual emissions
for this facility.
5 The highest MIR based on allowable emissions from an operating facility is estimated to be up to 50 in one million, for the operating
Soderberg facility.
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2 Maximum
The results of the chronic inhalation
cancer risk assessment indicate that,
based on estimates of current actual
emissions, the maximum individual
lifetime cancer risk (MIR) could be up
to 30 in one million, with emissions of
POM 20 primarily from potline roof
vents (secondary emissions) and anode
bake furnaces driving these risks. The
highest MIR of up to 30 in one million
based on actual emissions is due to
POM emissions from the one currently
operating Soderberg facility. The highest
MIR due to actual emissions from
prebake facilities was estimated to be up
to 20 in one million; the next highest
MIR for an operating prebake facility is
estimated to be up to 6 in one million.
The total estimated cancer incidence
from this source category based on
actual emission levels is 0.005 excess
cancer cases per year or one case in
every 200 years, with emissions of POM
contributing approximately 99 percent
to this cancer incidence. In addition, we
note that approximately 41,000 people
are estimated to have cancer risks
greater than 1 in one million, and
20 Most all POM emitted by this source category
are PAHs.
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approximately 900 people are estimated
to have risks greater than 10 in one
million. When considering the risks
associated with MACT-allowable
emissions, the MIR could be up to 100
in one million if the Columbia Falls
facility (a Soderberg type facility) were
to resume its primary aluminum
operations (see note 4 on Table 6). The
MIR based on allowable emissions from
the one currently operating Soderberg
facility (Massena East facility) was up to
50 in one million. The highest MIR
based on allowable emissions from any
of the prebake facilities was up to 30 in
one million.
The maximum modeled chronic noncancer TOSHI value is 0.4 based on
actual emissions, driven primarily by
HF emissions. When considering MACT
allowable emissions, the maximum
chronic non-cancer TOSHI value could
be up to 0.6. For this source category,
there were two HAP that had relevant
acute health effect screening values:
Carbonyl sulfide (COS) and hydrofluoric
acid (HF). Acute health effect screening
is performed using actual emissions
data. The Columbia Falls facility has not
operated in about 2 years and has not
operated at capacity since about 1999.
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Therefore, suitable actual emission data
was not available for this facility and its
acute health effects are not included in
this discussion. Further, the carbon-only
prebake anode production facility does
not emit COS or HF. Therefore, this
discussion addresses the acute health
effects of only the 13 remaining
facilities subject to this NESHAP. With
respect to COS, we did not find any
potential for acute health concerns for
the 13 facilities based on their actual
emissions. However, HF emissions did
not screen out with respect to potential
acute health effects. The highest refined
worst-case HQ for HF based on a REL
is 10, based on an AEGL-1 is 4, and
based on an ERPG-1 is 2. Moreover, 8
of the 13 facilities show the potential for
worst-case acute HQ values greater than
1 based on the REL, 4 of the 13 facilities
show the potential for worst-case acute
HQ values greater than 1 based on the
AEGL-1 and 4 of the 13 facilities show
the potential for worst-case acute HQ
values greater than or equal to 1 based
on the ERPG-1.21 Nevertheless, it is
21 Individual facility acute HQ values for all
facilities can be found in Appendix 5, Table 4, of
the risk assessment document that is included in
the docket for this proposed rulemaking. Acute HQ
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important to note that all the worst-case
acute HQs are based on conservative
assumptions (e.g., worst-case
meteorology coinciding with peak shortterm one-hour emissions from each
emission point, with a person located at
the point of maximum concentration
during that hour).
In addition to the analyses presented
above, to screen for potential multipathway effects from emissions of POM,
we compared the estimated actual PAH
emission rates from 14 facilities in this
source category to the multi-pathway
screening rate for PAHs described in
section III.B. Results of this worst-case
screen estimate that actual PAH
emissions from all 14 facilities exceed
the PAH multi-pathway screening rate.
With respect to these exceedances of the
worst-case multi-pathway screening rate
for PAHs, we note that this only
indicates the potential for multipathway-related cancer risks of concern
from PAHs. Moreover, due to data
limitations, we were not able to refine
our multi-pathway analysis beyond the
screening assessment. Thus, we note
that these results are biased high for
purposes of screening and are subject to
significant uncertainties. As such, they
do not necessarily indicate that multipathway risks from POM are significant,
only that we cannot rule out the
possibility that they might be
significant.
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C. What are our proposed decisions
regarding risk acceptability and ample
margin of safety?
1. Risk Acceptability
As noted in section III.C of this
preamble, we weigh all health risk
factors in our risk acceptability
determination, including the MIR, the
numbers of persons in various risk
ranges, cancer incidence, the maximum
noncancer HI, the maximum acute
noncancer hazard, the extent of
noncancer risks, the potential for
adverse environmental effects,
distribution of risks in the exposed
population, and risk estimation
uncertainties (54 FR 38044, September
14, 1989).
For the Primary Aluminum Reduction
source category, the risk analysis we
performed indicates that the cancer risk
to the individual most exposed due to
actual emissions is well below 100 in
one million, and the cancer incidence is
low (1 case in every 200 years). The
values exceeding a value of 1 based on the REL
were as follows: 10, 10, 9, 9, 5, 3, 2 and 2. Acute
HQ values greater than a value of 1 based on the
AEGL-1 were as follows: 4, 4, 3 and 3. Acute HQ
values greater than or equal to a value of 1 based
on the ERPG-1 were as follows: 2, 2, 1 and 1.
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potential risks due to allowable
emissions are higher with an estimated
MIR of up to 100 in one million which
is the presumptive upper limit of
acceptable risk.
With regard to noncancer risks, the
analysis indicates that chronic
noncancer health risks are negligible
due to both actual and allowable
emissions. The assessment of potential
acute noncancer effects (described in
the previous section) suggests that there
may be potential for some acute risks
due to HF emissions with worst-case
HQs up to 10 (based on the REL). In
characterizing the potential for acute
noncancer impacts of concern, it is
important to remember the upward bias
of these worst-case exposure estimates
and to consider the results along with
the rather large uncertainties related to
the emissions estimates and screening
methodology.
With regard to multi-pathway
exposures and risks, results of the
screening analysis indicate that actual
PAH emissions from all the facilities
exceed the worst-case multi-pathway
screening rate for PAHs, indicating the
potential for possible multi-pathwayrelated cancer risks of concern from
PAHs. We note that these screening
results do not necessarily indicate that
significant multi-pathway risks actually
exist at primary aluminum facilities,
only that we cannot rule them out as a
possibility.
Overall, in determining whether risk
is acceptable, we considered all the
available health risk information, as
described above. In this case, because
the MIRs due to actual emissions are
well below 100-in-1 million risk, and
since the one facility that could pose
possible risks due to allowable
emissions of up to 100 in one million
is not operating, and because a number
of other factors indicate relatively low
risk concern (e.g., low cancer incidence
and low potential for chronic noncancer
risks), and given the conservative,
worst-case screening level
characteristics of the acute and multipathway assessments, and various
uncertainties, we are proposing to
determine that the risks due to HAP
emissions from this source category are
acceptable.
2. Ample Margin of Safety Analysis
We next considered whether the
existing MACT standard provides an
ample margin of safety (AMOS). Under
the ample margin of safety analysis, we
evaluate the cost and feasibility of
available control technologies and other
measures (including the controls,
measures and costs reviewed under the
technology review) that could be
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applied in this source category to
further reduce the risks (or potential
risks) due to emissions of HAP
identified in our risk assessment, along
with all of the health risks and other
health information considered in the
risk acceptability determination
described above.
First, we evaluated the feasibility to
reduce the potential risks due to
allowable POM emissions from
Soderberg facilities. As described above,
the potential cancer MIR from Soderberg
facilities is estimated to be up to 100 in
one million due to allowable emissions.
These risks are driven by POM
emissions from a Soderberg facility
within the vertical stud Soderberg
(VSS2) subcategory. The current
emissions limit (from the 2005 NESHAP
amendments) for POM from potlines in
this VSS2 subcategory is 2.85 kg of POM
per Mg of Aluminum produced (2.85 kg/
Mg, or 5.7 lbs/ton). Based on sitespecific emissions data submitted by the
company in early 2008 for this facility,
the estimated actual emissions from this
facility were about 2 lbs/ton during the
most recent years of operation (see
Document EPA–HQ–OAR–2002–0031–
0029, which is available in the docket
for this rulemaking).
After considering variability in
emissions, which is appropriate for
establishing MACT limits (as described
in section III.A above), we calculated,
using a 99% upper prediction level
approach, that an emissions limit of 3.8
lbs/ton could be achieved by this
facility without any additional controls
and therefore no additional costs. This
would result in a reduction of
approximately 33 percent for the
allowable emissions from VSS2
potlines, and would reduce the
potential cancer MIR due to allowable
emissions to about 70 in one million.
We also evaluated potential controls to
reduce these risks further (such as
requiring wet roof scrubbers). We
determined that these controls would be
quite costly (approximately $4 million
per ton of organic HAP), with estimated
capital costs of about $40 million for
this facility, and would only achieve
about an additional 9.6 tons of HAP per
year (30 percent) reduction in POM
emissions. These controls and costs are
described in more detail below.
We also evaluated the POM emissions
from the one operating Soderberg
facility (which is in the HSS
subcategory) as part of our AMOS
analyses. Based on the risk assessment,
we estimated that this facility posed a
cancer MIR of up to 30 in one million
based on actual emissions and an MIR
of up to 50 in one million based on
allowable emissions. The current
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emissions limit for POM from potlines
for this HSS subcategory is 2.35 kg/Mg
(or 4.7 lbs/ton). Based on site specific
emissions data for this facility, the
actual emissions from this facility are
estimated to be about 1.5 lbs/ton. After
considering variability in emissions, we
determined that an emissions limit of
3.0 lbs/ton could be achieved by this
facility with no additional controls and,
therefore, no additional costs. This
would result in a reduction of
approximately 36 percent for the
allowable emissions from these HSS
potlines, and would reduce the
potential cancer MIR due to allowable
emissions from this facility to about 30
in one million.
We identified wet roof scrubbers as
one possible control technology that
could be applied to further reduce
allowable and actual emissions of POM
from potlines, to reduce the cancer risks
due to actual and allowable POM
emissions, and to reduce the potential
risks due to multi-pathway exposures to
POM. One facility in the source category
currently has this type of scrubber.
These controls can also be used to
reduce HF emissions and, thus, would
reduce the potential for acute noncancer
risks. However, the costs for these
controls are high. For example, we
estimate that the capital costs for the
typical facility would be more than $40
million, with annualized costs of $13
million. Industry wide this would result
in total capital costs of over $400
million, with estimated annualized
costs of over $150 million. These
controls would achieve reductions of
secondary emissions of about 30 to 50
percent. Given the high costs (estimated
at approximately $140,000 per ton of
HAP) and relatively low emissions and
risk reductions, we propose that it is not
appropriate or necessary to establish
these additional controls under
112(f)(2). Therefore, based our AMOS
analysis, we are proposing under
section 112(f)(2) of the CAA to lower the
POM emissions limit for VSS2 potlines
from 5.7 to 3.8 lbs/ton and to lower the
POM limit for HSS potlines from 4.7 to
3.0 lbs/ton. Pursuant to CAA section
112(f)(4), we are proposing that these
changes apply 90 days after the effective
date of this rulemaking. We did not
identify any other cost-effective controls
to further reduce HAP emissions for this
source category under the AMOS
analyses.
In accordance with the approach
established in the Benzene NESHAP,
the EPA weighed all health risk
measures and information considered in
the risk acceptability determination,
along with the costs and economic
impacts of emissions controls,
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technological feasibility, uncertainties
and other relevant factors in proposing
our ample margin of safety
determination. Considering the health
risk information and the costs of the
options identified, we propose that the
existing MACT standards, along with
the proposed lower POM limits for
potlines at Soderberg facilities (VSS2
and HSS subcategories) described
above, will provide an ample margin of
safety to protect public health.
Pursuant to CAA section 112(f)(4), we
are proposing that these changes (i.e.,
lower emission limits for potlines at
Soderberg facilities) apply 90 days after
the effective date of this rulemaking. See
CAA section 112(f)(4)(A).
Nevertheless, we solicit comment and
information on the feasibility, costs and
appropriateness of any additional
controls or options to further reduce the
potential risks due to emissions of HAP,
especially POM and HF.
D. What are the results and proposed
decisions based on our technology
review?
As described above, dry alumina
scrubbers (with baghouses) are the
typical controls used to minimize
primary emissions of HF and POM from
the potlines. However, some facilities
use wet scrubbers and ESPs to control
these emissions. The MACT control
technology typically used for anode
bake furnaces is also a dry alumina
scrubber, and a capture system vented
to a dry coke scrubber is used for
control of paste production plants.
These facilities further reduce HAP
emissions from anode bake furnaces by
implementation of certain practices
during periods of startup (e.g.,
development of an anode bake furnace
startup schedule, operation of the
associated control system(s) within
normal parametric limits prior to the
startup of the anode bake furnace). To
further control potline secondary
emissions, one facility has wet roof
scrubbers to get additional control of HF
and POM. As described in the AMOS
section above, it would be quite costly
to require wet roof scrubbers on other
facilities.
Overall, based on our technology
review, we determined that there have
been no developments in practices,
processes, and control technologies that
would be considered feasible and costeffective to apply to this source category
since promulgation of the Primary
Aluminum Reduction Plant NESHAP,
other than the anode bake furnace
startup practices mentioned above. We
propose to modify the MACT
requirements for anode bake furnaces to
include implementation of the startup
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practices mentioned above. Further,
based on an analysis of recent emissions
data, we believe that the practices,
processes and control technologies
currently in use by this source category
allow for a reduction in the POM
emission limits for Soderberg potlines
(please refer to the ample margin of
safety analysis in section IV.C.2 of this
preamble).
Additional details regarding these
analyses can be found in the following
technical document for this action
which is available in the docket: Draft
Technology Review for the Primary
Aluminum Reduction Plant Source
Category.
E. What other actions are we proposing?
1. Startup, Shutdown and Malfunctions
The United States Court of Appeals
for the District of Columbia Circuit
vacated portions of two provisions in
the EPA’s CAA section 112 regulations
governing the emissions of HAP during
periods of startup, shutdown and
malfunction (SSM). Sierra Club v. EPA,
551 F.3d 1019 (DC Cir. 2008), cert.
denied, 130 S. Ct. 1735 (U.S. 2010).
Specifically, the Court vacated the SSM
exemption contained in 40 CFR
63.6(f)(1) and 40 CFR 63.6(h)(1), that are
part of a regulation, commonly referred
to as the ‘‘General Provisions Rule,’’ that
the EPA promulgated under CAA
section 112. When incorporated into
CAA section 112(d) regulations for
specific source categories, these two
provisions exempt sources from the
requirement to comply with the
otherwise applicable CAA section
112(d) emissions standard during
periods of SSM.
We are proposing the elimination of
the SSM exemption in this rule.
Consistent with Sierra Club v. EPA, the
EPA is proposing standards in this rule
that apply at all times. We are also
proposing several revisions to Appendix
A to subpart LL of part 63 (the General
Provisions Applicability table). For
example, we are proposing to eliminate
the incorporation of the General
Provisions’ requirement that the source
develop an SSM plan. We also are
proposing to eliminate or revise certain
recordkeeping and reporting
requirements related to the SSM
exemption. The EPA has attempted to
ensure that we have not included in the
proposed regulatory language any
provisions that are inappropriate,
unnecessary, or redundant in the
absence of the SSM exemption. We are
specifically seeking comment on
whether there are any such provisions
that we have inadvertently incorporated
or overlooked.
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In proposing the standards in this
rule, the EPA has taken into account
startup and shutdown periods and, for
the reasons explained below, the EPA is
proposing in some cases different
standards for startup periods.
The 1997 MACT rule allowed for
periods of up to six months for startup
of existing potlines that had been
previously shutdown. These long
startup periods for potlines are
recognized as part of the normal
operations during which emissions
testing is not feasible. The current
MACT emission limits are not
applicable during these startup periods.
Thus, we are proposing MACT
standards for these periods in today’s
action. Given that it is economically and
technically infeasible to measure
emissions during these startup periods,
we are proposing detailed work practice
standards that will minimize HAP
emissions and ensure proper operation
of the processes and control equipment
during startup periods. The proposed
work practices include bringing the
potline scrubbers and exhaust fans on
line prior to energizing the first cell
being restarted, ensuring that the
primary capture and control system is
operating at all times during startup,
and keeping pots covered during startup
as much as practicable to include, but
not limited to, minimizing the removal
of covers or panels of the pots on which
work is being performed. Moreover,
facilities must inspect potlines daily
during startup and perform additional
work practices, including resealing pot
crust as often and as soon as practicable,
reducing cell temperatures to as low as
practicable, and adjusting pot
parameters to their optimum levels to
include, but not limited to, the
following parameters: Alumina addition
rate, exhaust air flow, cell voltage,
feeding level, anode current, and liquid
and solid bath levels.
The 1997 MACT rule allowed for
startup periods for new or reconstructed
anode bake furnaces and pitch storage
tanks and for anode bake furnaces that
had been previously shutdown. Based
on information received from industry,
we believe that these sources can
comply with their MACT standards
during startup periods. Therefore, we
are removing the provisions for startup
of anode bake furnaces and pitch storage
tanks. However, we have added startup
practices for anode bake furnace startup
periods to help ensure that the
standards will be met. These startup
practices will minimize HAP emissions
and ensure proper operation of the
processes and control equipment during
startup periods (please refer to the
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discussion of the technology review in
section IV.D of this preamble).
Shutdown emissions are not expected
to be different from those during normal
operation; therefore, no separate
standard or work practice is warranted.
We propose that the numerical MACT
limits described in previous sections of
this preamble (established for normal
operations) will apply during shutdown
periods. We also propose that the MACT
limits for all other affected units besides
potlines (bake furnaces, pitch tanks, and
paste production plants) apply at all
times, including during startups and
shutdowns.
Information on periods of startup and
shutdown received from the industry
indicate that emissions during startup
(except for potlines) and shutdown
periods are no greater than emissions
during normal operations. Therefore,
the continued operation of the existing
control devices and emission capture
systems will, in conjunction with the
detailed proposed startup practices and
work practices described above, be
consistent with maximum achievable
control technology and will be
adequate, along with all the other
standards described above, to ensure
that risks will be acceptable and the rule
will provide an ample margin of safety.
Periods of startup, normal operations,
and shutdown are all predictable and
routine aspects of a source’s operations.
However, by contrast, malfunction is
defined as a ‘‘sudden, infrequent, and
not reasonably preventable failure of air
pollution control and monitoring
equipment, process equipment or a
process to operate in a normal or usual
manner * * *’’ (40 CFR 63.2). The EPA
has determined that CAA section 112
does not require that emissions that
occur during periods of malfunction be
factored into development of CAA
section 112 standards. Under CAA
section 112, emissions standards for
new sources must be no less stringent
than the level ‘‘achieved’’ by the best
controlled similar source and for
existing sources generally must be no
less stringent than the average emissions
limitation ‘‘achieved’’ by the best
performing 12 percent of sources in the
category. There is nothing in CAA
section 112 that directs the agency to
consider malfunctions in determining
the level ‘‘achieved’’ by the best
performing or best controlled sources
when setting emissions standards.
Moreover, while the EPA accounts for
variability in setting emissions
standards consistent with the CAA
section 112 case law, nothing in that
case law requires the agency to consider
malfunctions as part of that analysis.
Section 112 of the CAA uses the concept
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of ‘‘best controlled’’ and ‘‘best
performing’’ unit in defining the level of
stringency that CAA section 112
performance standards must meet.
Applying the concept of ‘‘best
controlled’’ or ‘‘best performing’’ to a
unit that is malfunctioning presents
significant difficulties, as malfunctions
are sudden and unexpected events.
Further, accounting for malfunctions
would be difficult, if not impossible,
given the myriad different types of
malfunctions that can occur across all
sources in the category and given the
difficulties associated with predicting or
accounting for the frequency, degree,
and duration of various malfunctions
that might occur. As such, the
performance of units that are
malfunctioning is not ‘‘reasonably’’
foreseeable. See, e.g., Sierra Club v.
EPA, 167 F.3d 658, 662 (DC Cir. 1999)
(EPA typically has wide latitude in
determining the extent of data-gathering
necessary to solve a problem. We
generally defer to an agency’s decision
to proceed on the basis of imperfect
scientific information, rather than to
‘‘invest the resources to conduct the
perfect study.’’). See also, Weyerhaeuser
v. Costle, 590 F.2d 1011, 1058 (DC Cir.
1978) (‘‘In the nature of things, no
general limit, individual permit, or even
any upset provision can anticipate all
upset situations. After a certain point,
the transgression of regulatory limits
caused by ‘uncontrollable acts of third
parties,’ such as strikes, sabotage,
operator intoxication or insanity, and a
variety of other eventualities, must be a
matter for the administrative exercise of
case-by-case enforcement discretion, not
for specification in advance by
regulation’’). In addition, the goal of a
best controlled or best performing
source is to operate in such a way as to
avoid malfunctions of the source, and
accounting for malfunctions could lead
to standards that are significantly less
stringent than levels that are achieved
by a well-performing nonmalfunctioning source. The EPA’s
approach to malfunctions is consistent
with CAA section 112 and is a
reasonable interpretation of the statute.
In the event that a source fails to
comply with the applicable CAA section
112(d) standards as a result of a
malfunction event, the EPA would
determine an appropriate response
based on, among other things, the good
faith efforts of the source to minimize
emissions during malfunction periods,
including preventative and corrective
actions, as well as root cause analyses
to ascertain and rectify excess
emissions. The EPA would also
consider whether the source’s failure to
comply with the CAA section 112(d)
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standard was, in fact, ‘‘sudden,
infrequent, not reasonably preventable’’
and was not instead ‘‘caused in part by
poor maintenance or careless operation’’
40 CFR 63.2 (definition of malfunction).
Finally, the EPA recognizes that even
equipment that is properly designed and
maintained can sometimes fail and that
such failure can sometimes cause an
exceedance of the relevant emissions
standard. (See, e.g., State
Implementation Plans: Policy Regarding
Excessive Emissions During
Malfunctions, Startup, and Shutdown
(Sept. 20, 1999); Policy on Excess
Emissions During Startup, Shutdown,
Maintenance, and Malfunctions (Feb.
15, 1983).). The EPA is therefore
proposing to add to the final rule an
affirmative defense to civil penalties for
exceedances of emissions limits that are
caused by malfunctions. See 40 CFR
63.842 (defining ‘‘affirmative defense’’
to mean, in the context of an
enforcement proceeding, a response or
defense put forward by a defendant,
regarding which the defendant has the
burden of proof, and the merits of which
are independently and objectively
evaluated in a judicial or administrative
proceeding). We also are proposing
other regulatory provisions to specify
the elements that are necessary to
establish this affirmative defense; the
source must prove by a preponderance
of the evidence that it has met all of the
elements set forth in 40 CFR 63.855 (see
also 40 CFR 22.24). The criteria ensure
that the affirmative defense is available
only where the event that causes an
exceedance of the emissions limit meets
the narrow definition of malfunction in
40 CFR 63.2 (sudden, infrequent, not
reasonably preventable and not caused
by poor maintenance and or careless
operation). For example, to successfully
assert the affirmative defense, the source
must prove by a preponderance of the
evidence that excess emissions ‘‘[w]ere
caused by a sudden, infrequent, and
unavoidable failure of air pollution
control and monitoring equipment,
process equipment, or a process to
operate in a normal or usual manner
* * *.’’ The criteria also are designed to
ensure that steps are taken to correct the
malfunction, to minimize emissions in
accordance with 40 CFR sections
63.843(f) and 63.844(f) to prevent future
malfunctions. For example, the source
must prove by a preponderance of the
evidence that ‘‘[r]epairs were made as
expeditiously as possible when the
applicable emissions limitations were
being exceeded * * *’’ and that ‘‘[a]ll
possible steps were taken to minimize
the impact of the excess emissions on
ambient air quality, the environment
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and human health * * *.’’ In any
judicial or administrative proceeding,
the Administrator may challenge the
assertion of the affirmative defense and,
if the respondent has not met its burden
of proving all of the requirements in the
affirmative defense, appropriate
penalties may be assessed in accordance
with CAA section 113 (see also 40 CFR
22.27).
The EPA included an affirmative
defense in the proposed rule in an
attempt to balance a tension, inherent in
many types of air regulation, to ensure
adequate compliance while
simultaneously recognizing that despite
the most diligent of efforts, emission
limits may be exceeded under
circumstances beyond the control of the
source. The EPA must establish
emission standards that ‘‘limit the
quantity, rate, or concentration of
emissions of air pollutants on a
continuous basis.’’ 42 U.S.C. 7602(k)
(defining ‘‘emission limitation and
emission standard’’). See generally
Sierra Club v. EPA, 551 F.3d 1019, 1021
(DC Cir. 2008). Thus, the EPA is
required to ensure that section 112
emissions limitations are continuous.
The affirmative defense for malfunction
events meets this requirement by
ensuring that even where there is a
malfunction, the emission limitation is
still enforceable through injunctive
relief. While ‘‘continuous’’ limitations,
on the one hand, are required, there is
also case law indicating that in many
situations it is appropriate for EPA to
account for the practical realities of
technology. For example, in Essex
Chemical v. Ruckelshaus, 486 F.2d 427,
433 (DC Cir. 1973), the DC Circuit
acknowledged that in setting standards
under CAA section 111 ‘‘variant
provisions’’ such as provisions allowing
for upsets during startup, shutdown and
equipment malfunction ‘‘appear
necessary to preserve the reasonableness
of the standards as a whole and that the
record does not support the ‘never to be
exceeded’ standard currently in force.’’
See also, Portland Cement Association
v. Ruckelshaus, 486 F.2d 375 (DC Cir.
1973). Though intervening case law
such as Sierra Club v. EPA and the CAA
1977 amendments undermine the
relevance of these cases today, they
support the EPA’s view that a system
that incorporates some level of
flexibility is reasonable. The affirmative
defense simply provides for a defense to
civil penalties for excess emissions that
are proven to be beyond the control of
the source. By incorporating an
affirmative defense, the EPA has
formalized its approach to upset events.
In a Clean Water Act setting, the Ninth
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Circuit required this type of formalized
approach when regulating ‘‘upsets
beyond the control of the permit
holder.’’ Marathon Oil Co. v. EPA, 564
F.2d 1253, 1272–73 (9th Cir. 1977). But
see, Weyerhaeuser Co. v. Costle, 590
F.2d 1011, 1057–58 (DC Cir. 1978)
(holding that an informal approach is
adequate). The affirmative defense
provisions give the EPA the flexibility to
both ensure that its emission limitations
are ‘‘continuous’’ as required by 42
U.S.C. 7602(k), and account for
unplanned upsets and thus support the
reasonableness of the standard as a
whole.
Specifically, we are proposing the
following rule changes:
• Add general duty requirements in
40 CFR sections 63.843 and 63.844 to
replace General Provision requirements
that reference vacated SSM provisions.
• Add replacement language that
eliminates the reference to SSM
exemptions applicable to performance
tests in 40 CFR section 63.847(d).
• Add paragraphs in 40 CFR section
63.850(d) requiring the reporting of
malfunctions as part of the affirmative
defense provisions.
• Add paragraphs in 40 CFR section
63.850(e) requiring the keeping of
certain records during malfunctions as
part of the affirmative defense
provisions.
• Revise Appendix A to subpart LL of
part 63 to reflect changes in the
applicability of the General Provisions
to this subpart resulting from a court
vacatur of certain SSM requirements in
the General Provisions.
2. Electronic Reporting
The EPA must have performance test
data to conduct effective reviews of
CAA sections 112 and 129 standards, as
well as for many other purposes
including compliance determinations,
emissions factor development, and
annual emissions rate determinations.
In conducting these required reviews,
the EPA has found it ineffective and
time consuming, not only for us, but
also for regulatory agencies and source
owners and operators, to locate, collect,
and submit performance test data
because of varied locations for data
storage and varied data storage methods.
In recent years, though, stack testing
firms have typically collected
performance test data in electronic
format, making it possible to move to an
electronic data submittal system that
would increase the ease and efficiency
of data submittal and improve data
accessibility.
Through this proposal the EPA is
presenting a step to increase the ease
and efficiency of data submittal and
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improve data accessibility. Specifically,
the EPA is proposing that owners and
operators of Primary Aluminum
Reduction Plant facilities submit
electronic copies of required
performance test reports to the EPA’s
WebFIRE database. The WebFIRE
database was constructed to store
performance test data for use in
developing emissions factors. A
description of the WebFIRE database is
available at https://cfpub.epa.gov/
oarweb/index.cfm?action=fire.main.
As proposed above, data entry would
be through an electronic emissions test
report structure called the Electronic
Reporting Tool. The ERT would be able
to transmit the electronic report through
the EPA’s Central Data Exchange
network for storage in the WebFIRE
database making submittal of data very
straightforward and easy. A description
of the ERT can be found at https://
www.epa.gov/ttn/chief/ert/ert_tool.html.
The proposal to submit performance
test data electronically to the EPA
would apply only to those performance
tests conducted using test methods that
will be supported by the ERT. The ERT
contains a specific electronic data entry
form for most of the commonly used
EPA reference methods. A listing of the
pollutants and test methods supported
by the ERT is available at https://
www.epa.gov/ttn/chief/ert/ert_tool.html.
We believe that industry would benefit
from this proposed approach to
electronic data submittal. Having these
data, the EPA would be able to develop
improved emissions factors, make fewer
information requests, and promulgate
better informed regulations.
One major advantage of the proposed
submittal of performance test data
through the ERT is a standardized
method to compile and store much of
the documentation required to be
reported by this rule. Another advantage
is that the ERT clearly states what
testing information would be required.
Another important proposed benefit of
submitting these data to the EPA at the
time the source test is conducted is that
it should substantially reduce the effort
involved in data collection activities in
the future. When the EPA has
performance test data in hand, there
will likely be fewer or less substantial
data collection requests in conjunction
with prospective required residual risk
assessments or technology reviews. This
would result in a reduced burden on
both affected facilities (in terms of
reduced manpower to respond to data
collection requests) and the EPA (in
terms of preparing and distributing data
collection requests and assessing the
results).
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State, local, and Tribal agencies could
also benefit from more streamlined and
accurate review of electronic data
submitted to them. The ERT would
allow for an electronic review process
rather than a manual data assessment
making review and evaluation of the
source provided data and calculations
easier and more efficient. Finally,
another benefit of the proposed data
submittal to WebFIRE electronically is
that these data would greatly improve
the overall quality of existing and new
emissions factors by supplementing the
pool of emissions test data for
establishing emissions factors and by
ensuring that the factors are more
representative of current industry
operational procedures. A common
complaint heard from industry and
regulators is that emissions factors are
outdated or not representative of a
particular source category. With timely
receipt and incorporation of data from
most performance tests, the EPA would
be able to ensure that emissions factors,
when updated, represent the most
current range of operational practices. In
summary, in addition to supporting
regulation development, control strategy
development, and other air pollution
control activities, having an electronic
database populated with performance
test data would save industry, state,
local, Tribal agencies, and the EPA
significant time, money, and effort
while also improving the quality of
emissions inventories and, as a result,
air quality regulations.
Records must be maintained in a form
suitable and readily available for
expeditious review, according to
63.10(b)(1). Electronic recordkeeping
and reporting is available for many
records, and is the form considered
most suitable for expeditious review if
available. Electronic recordkeeping and
reporting is encouraged in this proposal
and some records and reports are
required to be kept in electronic format.
F. Compliance Dates
We are proposing that existing
facilities must comply with the
proposed revised emissions limits for
Soderberg potlines (which are being
proposed under CAA sections 112(f)(2)
for all affected sources), no later than 90
days after the date of publication of the
final rule. We are proposing that
existing facilities must comply with all
other changes proposed in this action
(other than affirmative defense
provisions and electronic reporting
which are effective upon promulgation
of the final rule) no later than 3 years
after the date of publication of the final
rule. All new or reconstructed facilities
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must comply with all requirements in
this rule upon startup.
V. Summary of Cost, Environmental,
and Economic Impacts
A. What are the affected sources?
The affected sources are new and
existing potlines, new and existing pitch
storage tanks, new and existing anode
bake furnaces (except for one that is
located at a facility that only produces
anodes for use off-site), and new and
existing paste production plants.
B. What are the air quality impacts?
The proposed rule will require the
POM emissions from existing
uncontrolled pitch storage tanks to be
reduced by a minimum of 95 percent.
This is estimated to result in a reduction
of 1.6 tons per year (tpy) of POM. In
addition, the proposed lower Soderberg
potline POM limits would reduce POM
emissions from the two Soderberg
facilities, assuming production at plant
capacity, by approximately 300 tpy,
combined.
C. What are the cost impacts?
Under the proposed amendments, 8
facilities would be required to install or
upgrade, and operate emissions control
systems (such as activated carbon
adsorbers or condensers) to control
emissions of HAP from pitch storage
tanks at total estimated cost of $167,832
per year, or $20,979 per facility. In
addition, 12 facilities will have to
conduct periodic performance tests for
POM emissions from 45 prebake
potlines at an estimated total cost of
$90,000 per year for the source category,
or $7,500 per year per facility. The total
estimated cost of the rule is $258,000
per year.
D. What are the economic impacts?
We performed an economic impact
analysis for the proposed modifications
in this rulemaking. That analysis
estimates total annualized costs of
approximately $257,832 at 13 facilities
and cost to revenue of less than 0.02%
for the Primary Aluminum Production
source category. For more information,
please refer to the Draft Economic
Impact Analysis for this proposed
rulemaking that is available in the
public docket for this proposed
rulemaking.
E. What are the benefits?
This proposed rule will achieve about
1.6 tons per year reductions in POM
emissions, which may result in a slight
health benefit. The proposed limits of
3.9 pounds of COS per ton of aluminum
produced (lb COS/ton Al) for existing
facilities and 3.1 lb COS/ton Al for new
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facilities will prevent increases in COS
emissions and prevent increases in SO2
emissions as a co-benefit. The proposed
COS standard will likely result in the
use of lower sulfur content coke in the
anode production processes. This
reduction in anode coke sulfur content
would result in decreases in emissions
of both COS and sulfur dioxide (SO2).
We estimate that SO2 emissions will
decrease by 12 tons for each ton of COS
reduction.
VI. Request for Comments
We are soliciting comments on all
aspects of this proposed action. In
addition to general comments on this
proposed action, we are also interested
in any additional data that may help to
reduce the uncertainties inherent in the
risk assessments and other analyses. We
are specifically interested in receiving
corrections to the site-specific emissions
profiles used for risk modeling. Such
data should include supporting
documentation in sufficient detail to
allow characterization of the quality and
representativeness of the data or
information. Section VII of this
preamble provides more information on
submitting data.
VII. Submitting Data Corrections
The site-specific emissions profiles
used in the source category risk and
demographic analyses are available for
download on the RTR Web page at:
https://www.epa.gov/ttn/atw/rrisk/
rtrpg.html. The data files include
detailed information for each HAP
emissions release point for the facility
included in the source category.
If you believe that the data are not
representative or are inaccurate, please
identify the data in question, provide
your reason for concern, and provide
any ‘‘improved’’ data that you have, if
available. When you submit data, we
request that you provide documentation
of the basis for the revised values to
support your suggested changes. To
submit comments on the data
downloaded from the RTR Web page,
complete the following steps:
1. Within this downloaded file, enter
suggested revisions to the data fields
appropriate for that information. The
data fields that may be revised include
the following:
Data element
Definition
Control Measure .................................................................
Control Measure Comment ................................................
Delete .................................................................................
Delete Comment ................................................................
Emissions Calculation Method Code for Revised Emissions.
Emissions Process Group ..................................................
Are control measures in place? (yes or no)
Select control measure from list provided, and briefly describe the control measure.
Indicate here if the facility or record should be deleted.
Describes the reason for deletion.
Code description of the method used to derive emissions. For example, CEM, material balance, stack test, etc.
Enter the general type of emissions process associated with the specified emissions
point.
Enter release angle (clockwise from true North); orientation of the y-dimension relative to true North, measured positive for clockwise starting at 0 degrees (maximum 89 degrees).
Enter dimension of the source in the east-west (x-) direction, commonly referred to
as length (ft).
Enter dimension of the source in the north-south (y-) direction, commonly referred to
as width (ft).
Enter total annual emissions due to malfunctions (tpy).
Enter maximum hourly malfunction emissions here (lb/hr).
Enter datum for latitude/longitude coordinates (NAD27 or NAD83); if left blank,
NAD83 is assumed.
Enter general comments about process sources of emissions.
Enter revised physical street address for MACT facility here.
Enter revised city name here.
Enter revised county name here.
Enter revised Emissions Release Point Type here.
Enter revised End Date here.
Enter revised Exit Gas Flowrate here (ft3/sec).
Enter revised Exit Gas Temperature here (F).
Enter revised Exit Gas Velocity here (ft/sec).
Enter revised Facility Category Code here, which indicates whether facility is a major
or area source.
Enter revised Facility Name here.
Enter revised Facility Registry Identifier here, which is an ID assigned by the EPA
Facility Registry System.
Enter revised HAP Emissions Performance Level here.
Enter revised Latitude here (decimal degrees).
Enter revised Longitude here (decimal degrees).
Enter revised MACT Code here.
Enter revised Pollutant Code here.
Enter revised routine emissions value here (tpy).
Enter revised SCC Code here.
Enter revised Stack Diameter here (ft).
Enter revised Stack Height here (ft).
Enter revised Start Date here.
Enter revised State here.
Enter revised Tribal Code here.
Enter revised Zip Code here.
Enter total annual emissions due to shutdown events (tpy).
Enter maximum hourly shutdown emissions here (lb/hr).
Enter general comments about emissions release points.
Enter total annual emissions due to startup events (tpy).
Enter maximum hourly startup emissions here (lb/hr).
Fugitive Angle ....................................................................
Fugitive Length ...................................................................
Fugitive Width ....................................................................
Malfunction Emissions .......................................................
Malfunction Emissions Max Hourly ....................................
North American Datum ......................................................
Process Comment ..............................................................
REVISED Address .............................................................
REVISED City ....................................................................
REVISED County Name ....................................................
REVISED Emissions Release Point Type .........................
REVISED End Date ...........................................................
REVISED Exit Gas Flow Rate ...........................................
REVISED Exit Gas Temperature .......................................
REVISED Exit Gas Velocity ...............................................
REVISED Facility Category Code ......................................
jlentini on DSK4TPTVN1PROD with PROPOSALS3
REVISED Facility Name ....................................................
REVISED Facility Registry Identifier ..................................
REVISED HAP Emissions Performance Level Code ........
REVISED Latitude ..............................................................
REVISED Longitude ...........................................................
REVISED MACT Code ......................................................
REVISED Pollutant Code ...................................................
REVISED Routine Emissions ............................................
REVISED SCC Code .........................................................
REVISED Stack Diameter ..................................................
REVISED Stack Height ......................................................
REVISED Start Date ..........................................................
REVISED State ..................................................................
REVISED Tribal Code ........................................................
REVISED Zip Code ............................................................
Shutdown Emissions ..........................................................
Shutdown Emissions Max Hourly ......................................
Stack Comment ..................................................................
Startup Emissions ..............................................................
Startup Emissions Max Hourly ...........................................
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Data element
Definition
Year Closed .......................................................................
2. Fill in the commenter information
fields for each suggested revision (i.e.,
commenter name, commenter
organization, commenter email address,
commenter phone number, and revision
comments).
3. Gather documentation for any
suggested emissions revisions (e.g.,
performance test reports, material
balance calculations).
4. Send the entire downloaded file
with suggested revisions in Microsoft®
Access format and all accompanying
documentation to Docket ID Number
EPA–HQ–OAR–2011–0797 (through one
of the methods described in the
ADDRESSES section of this preamble). To
expedite review of the revisions, it
would also be helpful if you submitted
a copy of your revisions to the EPA
directly at RTR@epa.gov in addition to
submitting them to the docket.
5. If you are providing comments on
a facility, you need only submit one file
for that facility, which should contain
all suggested changes for all sources at
that facility. We request that all data
revision comments be submitted in the
form of updated Microsoft® Access files,
which are provided on the RTR Web
Page at: https://www.epa.gov/ttn/atw/
rrisk/rtrpg.html.
VIII. Statutory and Executive Order
Reviews
jlentini on DSK4TPTVN1PROD with PROPOSALS3
A. Executive Order 12866: Regulatory
Planning and Review and Executive
Order 13563: Improving Regulation and
Regulatory Review
Under Executive Order 12866 (58 FR
51735, October 4, 1993), this action is a
significant regulatory action because it
raises novel legal and policy issues.
Accordingly, the EPA submitted this
action to the Office of Management and
Budget (OMB) for review under
Executive Orders 12866 and 13563 (76
FR 3821, January 21, 2011) and any
changes made in response to OMB
recommendations have been
documented in the docket for this
action.
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
Request (ICR) document prepared by the
EPA has been assigned the EPA ICR
number 2447.01. The information
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Enter date facility stopped operations.
collection requirements are not
enforceable until OMB approves them.
The information requirements are based
on notification, recordkeeping, and
reporting requirements in the NESHAP
General Provisions (40 CFR part 63,
subpart A), which are mandatory for all
operators subject to national emissions
standards. These recordkeeping and
reporting requirements are specifically
authorized by CAA section 114 (42
U.S.C. 7414). All information submitted
to the EPA pursuant to the
recordkeeping and reporting
requirements for which a claim of
confidentiality is made is safeguarded
according to agency policies set forth in
40 CFR part 2, subpart B.
We are proposing new paperwork
requirements for the Primary Aluminum
Reduction Plant source category in the
form of a one-time requirement to
prepare design specifications for
existing pitch storage tank controls, and
submissions of test reports and
calculations for demonstration of
compliance with prebake potline POM
limits.
For this proposed rule, the EPA is
adding affirmative defense to the
estimate of burden in the ICR. To
provide the public with an estimate of
the relative magnitude of the burden
associated with an assertion of the
affirmative defense position adopted by
a source, the EPA has provided
administrative adjustments to this ICR
to show what the notification,
recordkeeping and reporting
requirements associated with the
assertion of the affirmative defense
might entail. The EPA’s estimate for the
required notification, reports and
records for any individual incident,
including the root cause analysis, totals
$3,141 and is based on the time and
effort required of a source to review
relevant data, interview plant
employees, and document the events
surrounding a malfunction that has
caused an exceedance of an emissions
limit. The estimate also includes time to
produce and retain the record and
reports for submission to the EPA. The
EPA provides this illustrative estimate
of this burden because these costs are
only incurred if there has been a
violation and a source chooses to take
advantage of the affirmative defense.
Given the variety of circumstances
under which malfunctions could occur,
as well as differences among sources’
operation and maintenance practices,
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we cannot reliably predict the severity
and frequency of malfunction-related
excess emissions events for a particular
source. It is important to note that the
EPA has no basis currently for
estimating the number of malfunctions
that would qualify for an affirmative
defense. Current historical records
would be an inappropriate basis, as
source owners or operators previously
operated their facilities in recognition
that they were exempt from the
requirement to comply with emissions
standards during malfunctions. Of the
number of excess emissions events
reported by source operators, only a
small number would be expected to
result from a malfunction (based on the
definition above), and only a subset of
excess emissions caused by
malfunctions would result in the source
choosing to assert the affirmative
defense. Thus we believe the number of
instances in which source operators
might be expected to avail themselves of
the affirmative defense will be
extremely small.
With respect to the Primary
Aluminum Production source category,
the emissions controls are operational
before the associated emission source(s)
commence operation and remain
operational until after the associated
emission source(s) cease operation.
Also, production operations would not
proceed or continue if there is a
malfunction of a control device and the
time required to shut down production
operations (i.e., on the order of a day)
is small compared to the averaging time
of the emission standards (i.e., monthly,
quarterly and annual averages). Thus,
we believe it is unlikely that a control
device malfunction would cause an
exceedance of any emission limit.
Therefore, sources within this source
category are not expected to have any
need or use for the affirmative defense
and we believe that there is no burden
to the industry for the affirmative
defense provisions in the proposed rule.
We expect to gather information on
such events in the future and will revise
this estimate as better information
becomes available. We estimate 15
regulated entities are currently subject
to subpart LL and will be subject to all
proposed standards. The annual
monitoring, reporting, and
recordkeeping burden for this collection
(averaged over the first 3 years after the
effective date of the standards) for these
amendments to subpart LL is estimated
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to be $148,000 per year. This includes
1,558 labor hours per year at a total
labor cost of $148,000 per year, and total
non-labor capital and operation and
maintenance (O&M) costs of $500 per
year. This estimate includes
performance tests, notifications,
reporting, and recordkeeping associated
with the new requirements for existing
pitch storage tanks and new and
existing potlines. The total burden for
the Federal government (averaged over
the first 3 years after the effective date
of the standard) is estimated to be 120
hours per year at a total labor cost of
$11,400 per year. Burden is defined at
5 CFR 1320.3(b).
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 the EPA’s regulations in 40
CFR are listed in 40 CFR part 9. When
these ICRs are approved by OMB, the
agency will publish a technical
amendment to 40 CFR part 9 in the
Federal Register to display the OMB
control numbers for the approved
information collection requirements
contained in the final rules.
To comment on the agency’s need for
this information, the accuracy of the
provided burden estimates, and any
suggested methods for minimizing
respondent burden, the EPA has
established a public docket for this rule,
which includes this ICR, under Docket
ID number EPA–HQ–OAR–2011–0797.
Submit any comments related to the ICR
to the EPA and OMB. See the ADDRESSES
section at the beginning of this notice
for where to submit comments to the
EPA. Send comments to OMB at the
Office of Information and Regulatory
Affairs, Office of Management and
Budget, 725 17th Street, NW.,
Washington, DC 20503, Attention: Desk
Office for the EPA. Since OMB is
required to make a decision concerning
the ICR between 30 and 60 days after
December 6, 2011, a comment to OMB
is best assured of having its full effect
if OMB receives it by January 5, 2012.
The final rule will respond to any OMB
or public comments on the information
collection requirements contained in
this proposal.
C. Regulatory Flexibility Act
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
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number of small entities. Small entities
include small businesses, small
organizations, and small governmental
jurisdictions.
For purposes of assessing the impacts
of this proposed 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; (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 that is independently
owned and operated and is not
dominant in its field. For this source
category, which has the NAICS code
331312, the SBA small business size
standard is 1,000 employees according
to the SBA small business standards
definitions. There are no small entities
subject to subpart LL.
After considering the economic
impacts of today’s proposed rule on
small entities, I certify that this action
will not have a significant economic
impact on a substantial number of small
entities. This proposed rule will not
impose any requirements on small
entities. We continue to be interested in
the potential impacts of the proposed
rule on small entities and welcome
comment on issues related to such
impacts.
D. Unfunded Mandates Reform Act
This proposed rule does not contain
a Federal mandate under the provisions
of Title II of the Unfunded Mandates
Reform Act of 1995 (UMRA), 2 U.S.C.
1531–1538 for State, local, or Tribal
governments or the private sector. The
proposed rule would not result in
expenditures of $100 million or more
for State, local, and Tribal governments,
in aggregate, or the private sector in any
1 year. The proposed rule imposes no
enforceable duties on any State, local or
Tribal governments or the private sector.
Thus, this proposed rule is not subject
to the requirements of sections 202 or
205 of the UMRA.
This proposed rule is also not subject
to the requirements of section 203 of
UMRA because it contains no regulatory
requirements that might significantly or
uniquely affect small governments
because it contains no requirements that
apply to such governments nor does it
impose obligations upon them.
E. Executive Order 13132: Federalism
This proposed 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
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distribution of power and
responsibilities among the various
levels of government, as specified in
Executive Order 13132. None of the
facilities subject to this action are
owned or operated by State
governments, and, because no new
requirements are being promulgated,
nothing in this proposed rule will
supersede State regulations. Thus,
Executive Order 13132 does not apply
to this proposed rule.
In the spirit of Executive Order 13132,
and consistent with the EPA policy to
promote communications between the
EPA and State and local governments,
the EPA specifically solicits comment
on this proposed rule from State and
local officials.
F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
This proposed rule does not have
Tribal implications, as specified in
Executive Order 13175 (65 FR 67249,
November 9, 2000). None of the
provisions of this proposed rule will
result in increased emissions of any
hazardous air pollutant from any
facility. The more stringent limitations
of POM emissions from horizontal stud
Soderberg potlines may result in
decreased risk to Indian Tribal
populations. Thus, Executive Order
13175 does not apply to this action.
The EPA specifically solicits
additional comment on this proposed
action from Tribal officials.
G. Executive Order 13045: Protection of
Children From Environmental Health
Risks and Safety Risks
This proposed rule is not subject to
Executive Order 13045 (62 FR 19885,
April 23, 1997) because it is not
economically significant as defined in
Executive Order 12866. Moreover, the
agency does not believe the
environmental health risks or safety
risks addressed by this action present a
disproportionate risk to children.
Nevertheless, the public is invited to
submit comments or identify studies
and data that assess effects of early life
exposure to HAP from Primary
Aluminum sources. The EPA will
typically accord greater weight to
studies and data that have been peer
reviewed.
H. Executive Order 13211: Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use
This action is not a ‘‘significant
energy action’’ as defined under
Executive Order 13211, ‘‘Actions
Concerning Regulations That
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Significantly Affect Energy Supply,
Distribution, or Use’’ (66 FR 28355, May
22, 2001), because it is not likely to have
significant adverse effect on the supply,
distribution, or use of energy. This
action will not create any new
requirements and therefore no
additional costs for sources in the
energy supply, distribution, or use
sectors.
jlentini on DSK4TPTVN1PROD with PROPOSALS3
I. National Technology Transfer and
Advancement Act
Section 12(d) of the National
Technology Transfer and Advancement
Act of 1995 (‘‘NTTAA’’), Public Law
104–113 (15 U.S.C. 272 note), directs
the EPA to use voluntary consensus
standards (VCS) in its regulatory
activities unless to do so would be
inconsistent with applicable law or
otherwise impractical. VCS are
technical standards (e.g., materials
specifications, test methods, sampling
procedures, and business practices) that
are developed or adopted by voluntary
consensus standards bodies. NTTAA
directs the EPA to provide Congress,
through OMB, explanations when the
agency decides not to use available and
applicable VCS.
This proposed rulemaking involves
technical standards. The EPA proposes
to use ASTM D3177–02 (2007) Standard
Test Methods for Total Sulfur in the
Analysis Sample of Coal and Coke. This
is a voluntary consensus method. This
method can be obtained from the
American Society for Testing and
Materials, 100 Bar Harbor Drive, West
Conshohocken, Pennsylvania 19428
(telephone number (610) 832–9500).
This method was proposed because it is
commonly used by primary aluminum
reduction facilities to demonstrate
compliance with sulfur dioxide
emission limitations imposed in their
current Title V permits. The EPA
welcomes comments on this aspect of
this proposed rulemaking and,
specifically, invites the public to
identify potentially-applicable
voluntary consensus standards and to
explain why such standards should be
used in this regulation.
J. Executive Order 12898: Federal
Actions To Address Environmental
Justice in Minority Populations and
Low-Income Populations
Executive Order 12898 (59 FR 7629,
February 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
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and adverse human health or
environmental effects of their programs,
policies, and activities on minority
populations and low-income
populations in the United States.
For the primary aluminum source
category, EPA has determined that the
current health risks posed to anyone by
actual emissions from this source
category are within the acceptable
range, and that the proposed rulemaking
will not appreciably reduce these risks
further. As a result, this proposed rule
will not have disproportionately high
and adverse human health or
environmental effects on minority or
low-income populations.
To examine the potential for any
environmental justice issues that might
be associated with each source category,
we evaluated the distributions of HAPrelated cancer and non-cancer risks
across different social, demographic,
and economic groups within the
populations living near the facilities
where this source category is located.
The methods used to conduct
demographic analyses for this rule are
described in the document Draft
Residual Risk Assessment for the
Primary Aluminum Reduction Plant
Source Category which may be found in
the docket for this rulemaking. The
development of demographic analyses
to inform the consideration of
environmental justice issues in the EPA
rulemakings is an evolving science. The
EPA offers the demographic analyses in
today’s proposed rulemaking as
examples of how such analyses might be
developed to inform such consideration,
and invites public comment on the
approaches used and the interpretations
made from the results, with the hope
that this will support the refinement
and improve utility of such analyses.
In the demographics analysis, we
focused on populations within 50 km of
the facilities in this source category with
emissions sources subject to the MACT
standard. More specifically, for these
populations we evaluated exposures to
HAP that could result in cancer risks of
1 in one million or greater. We
compared the percentages of particular
demographic groups within the focused
populations to the total percentages of
those demographic groups nationwide.
The results of this analysis are
documented in the document Draft
Residual Risk Assessment for the
Primary Aluminum Reduction Plant
Source Category in the docket for this
proposed rulemaking.
List of Subjects in 40 CFR Part 63
Environmental protection, Air
pollution control, Hazardous
substances, Incorporation by reference,
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76285
Reporting and recordkeeping
requirements.
Dated: November 4, 2011.
Lisa P. Jackson,
Administrator.
For the reasons stated in the
preamble, part 63 of title 40, chapter I,
of the Code of Federal Regulations is
proposed to be amended as follows:
PART 63—[AMENDED]
1. The authority citation for part 63
continues to read as follows:
Authority: 42 U.S.C. 7401, et seq.
Subpart LL—[AMENDED]
2. Section 63.840 is amended by
revising paragraph (a) to read as follows:
§ 63.840
Applicability.
(a) Except as provided in paragraph
(b) of this section, the requirements of
this subpart apply to the owner or
operator of each new or existing pitch
storage tank, potline, paste production
plant and anode bake furnace associated
with primary aluminum production and
located at a major source as defined in
§ 63.2.
*
*
*
*
*
3. Section 63.841 is amended by
adding paragraph (a)(3) to read as
follows:
§ 63.841
Incorporation by reference.
(a) * * *
(3) ASTM D3177–02 (2007) Standard
Test Methods for Total Sulfur in the
Analysis Sample of Coal and Coke.
*
*
*
*
*
4. Section 63.842 is amended to read
as follows:
a. Removing the definition for
‘‘Vertical stud Soderberg one (VSS1)’’
and
b. Adding, in alphabetical order,
definitions for ‘‘Affirmative defense’’
and ‘‘Startup of an anode bake furnace’’
§ 63.842
Definitions.
*
*
*
*
*
Affirmative defense means, in the
context of an enforcement proceeding, a
response or defense put forward by a
defendant, regarding which the
defendant has the burden of proof, and
the merits of which are independently
and objectively evaluated in a judicial
or administrative proceeding.
*
*
*
*
*
Startup of an anode bake furnace
means the process of initiating heating
to the anode baking furnace where all
sections of the furnace have previously
been at ambient temperature. The
startup or re-start of the furnace begins
when the heating begins. The startup or
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re-start concludes at the start of the
second anode bake cycle.
*
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*
5. Section 63.843 is amended to read
as follows:
a. Revising paragraph
(a)(1)introductory text;
b. Removing and reserving paragraph
(a)(1)(v);
c. Revising paragraph
(a)(2)introductory text, and (a)(2)(i);
d. Removing and reserving paragraph
(a)(2)(ii);
e. Revising paragraph (a)(2)(iii); and
f. Adding paragraphs (a)(2)(iv)
through (a)(2)(vii), (d), (e), and (f)
jlentini on DSK4TPTVN1PROD with PROPOSALS3
§ 63.843 Emission limits for existing
sources.
(a) * * *
(1) Emissions of TF must not exceed:
*
*
*
*
*
(v) [Reserved]
*
*
*
*
*
(2) Emissions of POM must not
exceed:
(i) 1.5 kg/Mg (3.0 lb/ton) of aluminum
produced for each HSS potline;
(ii) [Reserved;]
(iii) 1.9 kg/Mg (3.8 lb/ton) of
aluminum produced for each VSS2
potline;
(iv) 0.31 kg/Mg (0.62 lb/ton) of
aluminum produced for each existing
CWPB1 prebake potline;
(v) 0.65 kg/Mg (1.3 lb/ton) of
aluminum produced for each existing
CWPB2 prebake potline;
(vi) 0.63 kg/Mg (1.26 lb/ton) of
aluminum produced for each existing
CWPB3 prebake potline;
(vii) 0.33 kg/Mg (0.65 lb/ton) of
aluminum produced for each existing
SWPB prebake potline;
*
*
*
*
*
(d) Pitch storage tanks. Each pitch
storage tank shall be equipped with an
emission control system designed and
operated to reduce inlet emissions of
POM by 95 percent or greater.
(e) COS limit. Emissions of COS must
not exceed 3.9 lb/ton of aluminum
produced.
(f) At all times, the owner or operator
must operate and maintain any affected
source, including associated air
pollution control equipment and
monitoring equipment, in a manner
consistent with safety and good air
pollution control practices for
minimizing emissions. Determination of
whether such operation and
maintenance procedures are being used
will be based on information available
to the Administrator which may
include, but is not limited to,
monitoring results, review of operation
and maintenance procedures, review of
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operation and maintenance records, and
inspection of the source.
6. Section 63.844 is amended to read
as follows:
a. Adding paragraph (a)(3);
b. Adding paragraph (e); and
c. Adding paragraph (f)
§ 63.844 Emission limits for new or
reconstructed sources.
(a) * * *
(3) POM limit. Emissions of POM from
prebake potlines must not exceed 0.31
kg/Mg (0.62 lb/ton) of aluminum
produced.
*
*
*
*
*
(e) COS limit. Emissions of COS must
not exceed 3.1 lb/ton of aluminum
produced.
(f) At all times, the owner or operator
must operate and maintain any affected
source, including associated air
pollution control equipment and
monitoring equipment, in a manner
consistent with safety and good air
pollution control practices for
minimizing emissions. Determination of
whether such operation and
maintenance procedures are being used
will be based on information available
to the Administrator which may
include, but is not limited to,
monitoring results, review of operation
and maintenance procedures, review of
operation and maintenance records, and
inspection of the source.
7. Section 63.846 is amended to read
as follows:
a. Revising paragraph (b);
b. Revising paragraph (d)(2)(iv);
c. Revising paragraphs (d)(4)(ii) and
(iii);
d. Removing and reserving paragraph
(d)(4)(iv); and
e. Adding paragraphs (e) and (f)
§ 63.846
Emission averaging.
*
*
*
*
*
(b) Soderberg Potlines. The owner or
operator may average TF emissions from
potlines and demonstrate compliance
with the limits in Table 1 of this subpart
using the procedures in paragraphs
(b)(1) and (b)(2) of this section. The
owner or operator also may average
POM emissions from potlines and
demonstrate compliance with the limits
in Table 2 of this subpart using the
procedures in paragraphs (b)(1) and
(b)(3) of this section.
*
*
*
*
*
(d) * * *
(2) * * *
(iv) The test plan for the measurement
of TF or POM emissions in accordance
with the requirements in §§ 63.847(b)
and (k);
*
*
*
*
*
(4) * * *
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(ii) The inclusion of any emission
source other than an existing potline or
existing anode bake furnace subject to
the same operating permit; or
(iii) The inclusion of any potline or
anode bake furnace while it is shut
down, in the emission calculations.
(iv) [Reserved]
*
*
*
*
*
(e) TF emissions from Prebake
Potlines. The owner or operator may
average TF emissions from potlines and
demonstrate compliance with the limits
in Table 1 of this subpart using the
procedures in paragraphs (e)(1) and
(e)(2) of this section.
(1) Monthly average emissions of TF
must not exceed the applicable emission
limit in Table 1 of this subpart. The
emission rate must be calculated based
on the total emissions from all potlines
over the period divided by the quantity
of aluminum produced during the
period, from all potlines comprising the
averaging group.
(2) To determine compliance with the
applicable emission limit in Table 1 of
this subpart for TF emissions, the owner
or operator must determine the monthly
average emissions (in lb/ton) from each
potline from at least three runs per
potline each month for TF secondary
emissions using the procedures and
methods in §§ 63.847 and 63.849. The
owner or operator must combine the
results of secondary TF monthly average
emissions with the TF results for the
primary control system and divide total
emissions by total aluminum
production.
(f) POM Emissions from Prebake
Potlines. The owner or operator also
may average POM emissions from
potlines and demonstrate compliance
with the limits in Table 2 of this subpart
using the procedures in paragraphs (f)(1)
and (f)(2) of this section.
(1) Average emissions of POM for
each compliance demonstration period,
must not exceed the applicable emission
limit in Table 2 of this subpart. The
emission rate must be calculated based
on the total emissions from all potlines
divided by the quantity of aluminum
produced during the period, from all
potlines comprising the averaging
group.
(2) To determine compliance with the
applicable emission limit in Table 2 of
this subpart for POM emissions, the
owner or operator must determine the
emissions (in lb/ton) from each potline
using the procedures and methods in
§§ 63.847 and 63.849. The owner or
operator must combine the results of
measured or calculated secondary POM
emissions with the POM emissions from
the primary control system and divide
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total emissions by total aluminum
production.
8. Section 63.847 is amended to read
as follows:
a. Revising paragraph (a)
b. Removing and reserving paragraph
(a)(3);
c. Revising paragraph (b) introductory
text;
d. Removing and reserving paragraph
(b)(6);
e. Revising paragraphs (c)(1); (c)(2);
and (c)(3);
f. Removing paragraphs (c)(2)(i)
through (iii);
g. Revising paragraph (c)(3);
h. Revising paragraphs (d)
introductory text and (d)(2);
i. Adding paragraph (d)(5);
j. Revising paragraph (e)(2);
k. Adding paragraph (e)(8);
l. Revising paragraph (g) introductory
text;
m. Adding and reserving paragraph
(i); and
n. Adding paragraphs (j), (k), (l), and
(m).
The revisions and additions read as
follows:
jlentini on DSK4TPTVN1PROD with PROPOSALS3
§ 63.847
Compliance Provisions.
(a) Compliance dates. The owner
operator of a primary aluminum
reduction plant must comply with the
requirements of this subpart by the
applicable compliance date in
paragraph (a)(1), (a)(2) or (a)(3) of this
section:
(1) Except as noted in paragraph (a)(2)
of this section, the compliance date for
an owner or operator of an existing
plant or source subject to the provisions
of this subpart is October 7, 1999.
(2) The compliance dates for existing
plants and sources are:
(i) [Date 90 days after date of
publication of final rule] for Soderberg
potlines subject to emission limits in
§§ 63.843(a)(2)(i) and (iii) which became
effective [Date of publication of final
rule].
(ii) [Date 3 years after date of
publication of final rule] for prebake
potlines subject to emission limits in
§§ 63.843(a)(2)(iv) through (vii) and
§ 63.848(n) which became effective
[Date of publication of final rule].
(iii) [Date 3 years after date of
publication of final rule] for potlines
subject to the work practice standards in
§ 63.854 which became effective [insert
date of publication of final rule].
(iv) [Date 3 years after date of
publication of final rule] for anode bake
furnaces subject to the startup practices
in § 63.847(m) which became effective
[insert date of publication of final rule].
(v) [Date 3 years after date of
publication of final rule] for compliance
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with the pitch storage tank POM limit
provisions of § 63.843(d) and the COS
emission limit provisions of §§ 63.843(e)
and 63.844(e).
(vi) [Date of publication of final rule]
for the malfunction provisions of
§§ 63.850(d)(2) and (e)(4)(xvi) and (xvii),
the affirmative defense provisions of
§ 63.855, and the electronic reporting
provisions of §§ 63.850(c) and (f).
(3) [Reserved]
*
*
*
*
*
(b) Test plan for TF from all anode
bake furnaces and potlines and POM
from Soderberg potlines. The owner or
operator shall prepare a site-specific test
plan prior to the initial performance test
according to the requirements of
§ 63.7(c) of this part. The test plan must
include procedures for conducting the
initial performance test and for
subsequent performance tests required
in § 63.848 for emission monitoring. In
addition to the information required by
§ 63.7, the test plan shall include:
*
*
*
*
*
(6) [Reserved]
*
*
*
*
*
(c) * * *
(1) During the first month following
the compliance date for an existing
potline (or potroom group), anode bake
furnace or pitch storage tank;
(2) By the 180th day following startup
for a potline or potroom group for which
the owner or operator elects to conduct
an initial performance test. The 180-day
period starts when the first pot in a
potline or potroom group is energized.
(3) By the 180th day following startup
for a potline or potroom group that was
shut down at the time compliance
would have otherwise been required
and is subsequently restarted. The 180day period starts when the first pot in
a potline or potroom group is energized.
(d) Performance test requirements.
The initial performance test and all
subsequent performance tests must be
conducted in accordance with the
requirements of the general provisions
in subpart A of this part, the approved
test plan, and the procedures in this
section. Performance tests must be
conducted under such conditions as the
Administrator specifies to the owner or
operator based on representative
performance of the affected source for
the period being tested. Upon request,
the owner or operator must make
available to the Administrator such
records as may be necessary to
determine the conditions of
performance tests.
*
*
*
*
*
(2) POM emissions from Soderberg
potlines. For each Soderberg (HSS and
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76287
VSS2) potline, the owner or operator
must measure and record the emission
rate of POM exiting the primary
emission control system and the rate of
secondary emissions exiting through
each roof monitor, or for a plant with
roof scrubbers, exiting through the
scrubbers. Using the equation in
paragraph (e)(2) of this section, the
owner or operator must compute and
record the average of at least three runs
each quarter (one run per month) for
secondary emissions and at least three
runs each year for the primary control
system to determine compliance with
the applicable emission limit.
Compliance is demonstrated when the
emission rate of POM is equal to or less
than the applicable emission limit in
§§ 63.843, 63.844 or 63.846.
*
*
*
*
*
(5) POM emissions from prebake
potlines. For each prebake potline, the
owner or operator shall measure and
record the emission rate of POM exiting
the primary emission control system.
The owner or operator shall compute
and record the average of at least three
runs every five years. For each prebake
potline for which the owner or operator
chooses to demonstrate compliance
using the provisions of § 63.847(e)(2),
the owner or operator shall measure and
record the emission rate of secondary
emissions exiting through each roof
monitor, or for a plant with roof
scrubbers, exiting through the scrubbers.
The owner or operator shall compute
and record the average of at least three
runs every five years for secondary
emissions. The owner or operator shall
calculate POM emissions in accordance
with §§ 63.847(e)(2) or (8). Compliance
is demonstrated when the emission rate
of POM is equal to or less than the
applicable emission limit in §§ 63.843,
63.844 or 63.846.
(e) * * *
(2) Compute the emission rate of POM
from each Soderberg potline, and from
those prebake potlines for which the
owner or operator chooses to measure
secondary emissions, using Equation 1,
Where:
Ep = emission rate of POM from the potline,
kg/mg (lb/ton); and
Cs = concentration of POM, mg/dscm (mg/
dscf). POM emission data collected during
the installation and startup of a cathode
must not be included in Cs.
*
*
*
*
*
(8) Compute the rate of POM from
each prebake potline for which the
owner or operator does not choose to
determine the measure the secondary
emissions using Equation 3:
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*
*
*
*
(g) Pitch storage tanks. The owner or
operator must demonstrate initial
compliance with the standard for pitch
storage tanks in §§ 63.843(d) and
63.844(d) by preparing a design
evaluation or by conducting a
performance test. The owner or operator
shall submit for approval by the
regulatory authority the information
specified in paragraph (g)(1) of this
section, along with the information
specified in paragraph (g)(2) of this
section where a design evaluation is
performed or the information specified
in paragraph (g)(3) of this section where
a performance test is conducted.
*
*
*
*
*
(i) [Reserved]
(j) COS Emissions. The owner
operator of each plant must calculate
the facility wide emission rate of COS
for each calendar month of operation
using the following equation:
jlentini on DSK4TPTVN1PROD with PROPOSALS3
*
Where:
ECOS = the facility wide emission rate of COS
during the calendar month in pounds per
ton of aluminum produced;
K = factor accounting for molecular weights
and conversion of sulfur to carbonyl
sulfide = 234;
Y = the tons of anode used at the facility
during the calendar month;
Z = the tons of aluminum produced at the
facility during the calendar month; and
%S = the weighted average sulfur content of
the anode coke utilized in the
production of aluminum during the
calendar month (e.g., if the weighted
average sulfur content of the anode coke
utilized during the calendar month was
2.5%, then %S = 0.025).
Compliance is demonstrated if the
calculated value of ECOS is less than the
applicable standard for COS emissions
in §§ 63.843(e) and 63.844(e).
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(k) Test plan POM from prebake
potlines. The owner or operator must
prepare a site-specific test plan prior to
the initial performance test according to
the requirements of § 63.7(c) of this part.
The test plan must include procedures
for conducting the initial performance
test and for subsequent performance
tests required in § 63.848 for emission
monitoring. In addition to the
information required by § 63.7 the test
plan shall include:
(1) Procedures to ensure a minimum
of three runs are performed for the
primary control system for each source;
(2) For a source with a single control
device exhausted through multiple
stacks, procedures to ensure that at least
three runs are performed by a
representative sample of the stacks
satisfactory to the applicable regulatory
authority;
(3) For multiple control devices on a
single source, procedures to ensure that
at least one run is performed for each
control device by a representative
sample of the stacks satisfactory to the
applicable regulatory authority;
(4) For plants with roof scrubbers,
procedures for rotating sampling among
the scrubbers or other procedures to
obtain representative samples as
approved by the applicable regulatory
authority.
(l) Potlines. The owner or operator
shall develop a written startup plan as
described in § 63.854 that contains
specific procedures to be followed
during startup periods of potline(s).
Compliance with the applicable
standards in § 63.854 will be
demonstrated through site inspection(s)
and review of site records by the
applicable regulatory authority.
(m) Anode bake furnaces. If you own
or operate a new or existing primary
aluminum reduction affected source,
you must develop a written startup plan
as described in paragraphs (m)(1)
through (4) of this section. Compliance
with the startup plan will be
demonstrated through site inspection(s)
and review of site records by the
applicable regulatory authority. The
written startup plan must contain
specific procedures to be followed
during startup periods of anode bake
furnaces, including the following:
(1) A requirement to develop an
anode bake furnace startup schedule
prior to startup of the first anode bake
furnace.
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(2) Records of time, date, duration and
any nonroutine actions taken during
startup of the furnaces.
(3) A requirement that the associated
emission control system should be
operating within normal parametric
limits prior to startup of the first anode
bake furnace.
(4) A requirement to shut down the
anode bake furnaces immediately if the
associated emission control system is off
line at any time during startup.
9. Section 63.848 is amended by
revising paragraph (b) and adding
paragraph (n) to read as follows:
§ 63.848 Emission monitoring
requirements.
*
*
*
*
*
(b) POM emissions from Soderberg
potlines. Using the procedures in
§ 63.847 and in the approved test plan,
the owner or operator shall monitor
emissions of POM from each Soderberg
(HSS and VSS2) potline every three
months. The owner or operator shall
compute and record the quarterly (3month) average from at least one run per
month for secondary emissions and the
previous 12-month average of all runs
for the primary control systems to
determine compliance with the
applicable emission limit. The owner or
operator must include all valid runs in
the quarterly (3-month) average. The
duration of each run for secondary
emissions must represent a complete
operating cycle. The primary control
system must be sampled over an 8-hour
period, unless site-specific factors
dictate an alternative sampling time
subject to the approval of the regulatory
authority.
*
*
*
*
*
(n) POM emissions from prebake
potlines. Using the procedures in
§ 63.847 and in the approved test plan,
the owner or operator must monitor
emissions of POM from each prebake
potline every five years. The owner or
operator must compute and record the
sum of the average primary and
secondary emissions using the
procedures of §§ 63.847(e)(2) or (e)(8).
10. Section 63.849 is amended by
adding paragraph (f) to read as follows:
§ 63.849
Test methods and procedures.
*
*
*
*
*
(f) The owner or operator must use
ASTM Method D3177—02 (2007) for
determination of the sulfur content in
anode coke shipments to determine
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EP06DE11.007</GPH>
Where:
Epp = emission rate of POM from a potline,
kg/Mg (lb/ton);
Cpp1 = concentration of POM from the
primary control system, mg/dscm (mg/
dscf);
Q1 = volumetric flow rate of effluent gas from
the primary control system dscm/hr
(dscf/hr);
CpF2 = concentration of TF from the
secondary control system or roof
monitor, mg/dscm (mg/dscf);
CpF1 = concentration of TF from the primary
control system, mg/dscm (mg/dscf); and
Q2 = volumetric flow rate of effluent gas from
the secondary control system or roof
monitor, dscm/hr (dscf/hr).
EP06DE11.006</GPH>
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Federal Register / Vol. 76, No. 234 / Tuesday, December 6, 2011 / Proposed Rules
compliance with the applicable facility
wide emission limit for COS emissions.
11. Section 63.850 is amended to read
as follows:
a. Revising paragraphs (c) and (d);
b. Removing and reserving paragraph
(e)(4)(iii); and
c. Adding paragraphs (e)(4)(xvi),
(e)(4)(xvii) and (f).
The revisions and additions read as
follows:
§ 63.850 Notification, reporting and
recordkeeping requirements.
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*
*
*
*
*
(c) As of January 1, 2012, and within
60 days after the date of completing
each performance test, as defined in
§ 63.2, and as required in this subpart,
the owner or operator must submit
performance test data, except opacity
data, electronically to the EPA’s Central
Data Exchange by using the ERT (see
https://www.epa.gov/ttn/chief/ert/
erttool.html/) or other compatible
electronic spreadsheet. Only data
collected using test methods compatible
with ERT are subject to this requirement
to be submitted electronically into the
EPA’s WebFIRE database.
(d) Reporting. In addition to the
information required under § 63.10 of
the General Provisions, the owner or
operator must provide semi-annual
reports containing the information
specified in paragraphs (d)(1) through
(d)(2) of this section to the
Administrator or designated authority.
(1) Excess emissions report. As
required by § 63.10(e)(3), the owner or
operator must submit a report (or a
summary report) if measured emissions
are in excess of the applicable standard.
The report must contain the information
specified in § 63.10(e)(3)(v) and be
submitted semiannually unless
quarterly reports are required as a result
of excess emissions.
(2) If there was a malfunction during
the reporting period, the owner or
operator must submit a report that
includes the number, duration, and a
brief description for each type of
malfunction which occurred during the
reporting period and which caused or
may have caused any applicable
emission limitation to be exceeded. The
report must also include a description of
actions taken by an owner or operator
during a malfunction of an affected
source to minimize emissions in
accordance with §§ 63.843(f) and
63.844(f), including actions taken to
correct a malfunction.
(e) * * *
(4) * * *
(iii) [Reserved]
*
*
*
*
*
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(xvi) Records of the occurrence and
duration of each malfunction of
operation (i.e., process equipment) or
the air pollution control equipment and
monitoring equipment.
(xvii) Records of actions taken during
periods of malfunction to minimize
emissions in accordance with §§ 63.843
and 63.844, including corrective actions
to restore malfunctioning process and
air pollution control and monitoring
equipment to its normal or usual
manner of operation.
(f) All reports required by this subpart
not subject to the requirements in
paragraph (b) of this section must be
sent to the Administrator at the
appropriate address listed in § 63.13. If
acceptable to both the Administrator
and the owner or operator of a source,
these reports may be submitted on
electronic media. The Administrator
retains the right to require submittal of
reports subject to paragraph (b) of this
section in paper format.
12. Section 63.854 is added to read as
follows:
§ 63.854 Work Practice Standards for
Periods of Startup.
(a) Startup of potlines. If you own or
operate a new or existing primary
aluminum reduction affected source,
you must comply with the requirements
of paragraphs (a)(1) through (7) of this
section during startup for each affected
potline.
(1) Develop a potline startup schedule
before starting up the potline.
(2) Keep records of number of pots
started per day.
(3) Bring the potline scrubbers and
exhaust fans on line prior to energizing
the first cell being restarted.
(4) Ensure that the primary capture
and control system is operating at all
times during startup.
(5) Keep pots covered during startup
as much as practicable to include but
not limited to minimizing the removal
of covers or panels of the pots on which
work is being performed.
(6) Inspect potlines daily during
startup and perform the following work
practices as specified in paragraphs
(a)(6)(i) through (iv) of this section.
(i) Identify unstable pots as soon as
practicable but in no case more than
12 hours from the time the pot became
unstable;
(ii) Reduce cell temperatures to as low
as practicable, but no higher than the
maximum temperature specified in the
operating plan described in paragraph
(a)(7) of this section;
(iii) Reseal pot crusts that have been
broken as often and as soon as
practicable but in no case more than
24 hours from the time the crust was
broken; and
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76289
(iv) Adjust pot parameters to their
optimum levels, as specified in the
operating plan described in paragraph
(a)(7) of this section, including, but not
limited to, the following parameters:
Alumina addition rate, exhaust air flow,
cell voltage, feeding level, anode current
and liquid and solid bath levels.
(7) Prepare a written operating plan to
minimize emissions during startup to
include, but not limited to, the
requirements in (a)(1) through (6) of this
section.
13. Section 63.855 is added to read as
follows:
§ 63.855 Affirmative defense for
exceedance of emission limit during
malfunction.
In response to an action to enforce the
standards set forth in this subpart, you
may assert an affirmative defense to a
claim for civil penalties for exceedances
of such standards that are caused by
malfunction, as defined at § 63.2.
Appropriate penalties may be assessed,
however, if you fail to meet your burden
of proving all of the requirements in the
affirmative defense. The affirmative
defense shall not be available for claims
for injunctive relief.
(a) To establish the affirmative
defense in any action to enforce such a
limit, you must timely meet the
notification requirements in § 63.850,
and must prove by a preponderance of
evidence that:
(1) The excess emissions:
(i) Were caused by a sudden,
infrequent, and unavoidable failure of
air pollution control and monitoring
equipment, process equipment, or a
process to operate in a normal or usual
manner; and
(ii) Could not have been prevented
through careful planning, proper design
or better operation and maintenance
practices; and
(iii) Did not stem from any activity or
event that could have been foreseen and
avoided, or planned for.
(iv) Were not part of a recurring
pattern indicative of inadequate design,
operation, or maintenance; and
(2) Repairs were made as
expeditiously as possible when the
applicable emissions limitations were
being exceeded. Off-shift and overtime
labor were used, to the extent
practicable to make these repairs; and
(3) The frequency, amount and
duration of the excess emissions
(including any bypass) were minimized
to the maximum extent practicable
during periods of such emissions; and
(4) If the excess emissions resulted
from a bypass of control equipment or
a process, then the bypass was
unavoidable to prevent loss of life,
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Federal Register / Vol. 76, No. 234 / Tuesday, December 6, 2011 / Proposed Rules
personal injury, or severe property
damage; and
(5) All possible steps were taken to
minimize the impact of the excess
emissions on ambient air quality, the
environment and human health; and
(6) All emissions monitoring and
control systems were kept in operation
if at all possible, consistent with safety
and good air pollution control practices;
and
(7) All of the actions in response to
the excess emissions were documented
by properly signed, contemporaneous
operating logs; and
(8) At all times, the affected source
was operated in a manner consistent
with good practices for minimizing
emissions; and
(9) A written root cause analysis has
been prepared, the purpose of which is
to determine, correct, and eliminate the
primary causes of the malfunction and
the excess emissions resulting from the
malfunction event at issue. The analysis
shall also specify, using best monitoring
methods and engineering judgment, the
amount of excess emissions that were
the result of the malfunction.
(b) Notification. The owner or
operator of the affected source
experiencing an exceedance of its
emissions limit(s) during a malfunction,
shall notify the Administrator by
telephone or facsimile transmission as
soon as possible, but no later than two
business days after the initial
occurrence of the malfunction, if it
wishes to avail itself of an affirmative
defense to civil penalties for that
malfunction. The owner or operator
seeking to assert an affirmative defense,
shall also submit a written report to the
Administrator within 45 days of the
initial occurrence of the exceedance of
the standards in this subpart to
demonstrate, with all necessary
supporting documentation, that it has
met the requirements set forth in
paragraph (e) of this section. The owner
or operator may seek an extension of
this deadline for up to 30 additional
days by submitting a written request to
the Administrator before the expiration
of the 45 day period. Until a request for
an extension has been approved by the
Administrator, the owner or operator is
subject to the requirement to submit
such report within 45 days of the initial
occurrence of the exceedance.
14. Table 1 to Subpart LL of Part 63
is revised to read as follows:
TABLE 1 TO SUBPART LL OF PART 63—POTLINE TF LIMITS FOR EMISSION AVERAGING
Monthly TF limit (1b/ton)
(for given number of potlines)
Type
2 lines
CWPB1
CWPB2
CWPB3
VSS2
HSS
SWPB
3 lines
1.7
2.9
2.3
2.6
2.5
1.4
4 lines
1.6
2.8
2.2
2.5
2.4
1.3
5 lines
1.5
2.7
2.2
2.5
2.4
1.3
6 lines
1.5
2.7
2.1
2.4
2.3
1.2
7 lines
1.4
2.6
2.1
2.4
2.3
1.2
8 lines
1.4
2.6
2.1
2.4
2.3
1.2
1.4
2.6
2.1
2.4
2.3
1.2
15. Table 2 to Subpart LL of Part 63
is revised to read as follows:
TABLE 2 TO SUBPART LL OF PART 63—POTLINE POM LIMITS FOR EMISSION AVERAGING
POM limit (lb/ton)
(for given number of potlines)
Type
2 lines
HSS
VSS2
CWPB1
CWBP2
CWBP3
SWPB
3 lines
3.5
3.5
0.63
1.4
1.33
0.63
4 lines
3.2
3.3
0.56
1.35
1.28
0.56
16. Appendix A to Subpart LL of Part
63 is revised to read as follows:
5 lines
3.1
3.2
0.52
1.31
1.28
0.52
3.0
3.1
0.52
1.31
1.26
0.52
Applies to
subpart LL
63.1 ............................................................................................
63.2 ............................................................................................
63.3 ............................................................................................
63.4 ............................................................................................
63.5 ............................................................................................
63.6(a), (b), (c) ...........................................................................
63.6(d) ........................................................................................
63.6(e)(1)(i) ................................................................................
63.6(e)(1)(ii) ...............................................................................
63.6(e)(1)(iii) ..............................................................................
Yes.
Yes.
Yes.
Yes.
Yes.
Yes.
No .....................
No .....................
No.
Yes.
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7 lines
3.0
3.0
0.48
1.26
1.26
0.48
8 lines
2.9
2.9
0.48
1.26
1.26
0.48
2.8
2.9
0.48
1.26
1.26
0.48
Appendix A to Subpart LL of Part 63—
Applicability of General Provisions (40
CFR Part 63, Subpart A)
Reference Section(s) * * *
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6 lines
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Comment
Section reserved.
See §§ 63.843(f) and 63.844(f) for general duty requirement.
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Reference Section(s) * * *
Applies to
subpart LL
63.6(e)(2) ...................................................................................
63.6(e)(3) ...................................................................................
63.6(f)(1) ....................................................................................
63.6(g) ........................................................................................
63.6(h) ........................................................................................
63.6(i) .........................................................................................
63.6(j) .........................................................................................
63.7(a) through (d) .....................................................................
63.7(e)(1) ...................................................................................
63.7(e)(2) through (e)(4) ............................................................
63.7(f), (g), (h) ...........................................................................
63.8(a) and (b) ...........................................................................
63.8(c)(1)(i) ................................................................................
63.8(c)(1)(ii) ...............................................................................
63.8(c)(1)(iii) ...............................................................................
63.8(c)(2) through (d)(2) ............................................................
63.8(d)(3) ...................................................................................
No .....................
No.
No.
Yes.
No .....................
Yes.
Yes.
Yes.
No .....................
Yes.
Yes.
Yes.
No .....................
Yes.
No.
Yes.
Yes, except for
last sentence.
Yes.
Yes.
Comment
Section reserved.
No opacity limits in rule.
See § 63.847(d).
See §§ 63.843(f) and 63.844(f) for general duty requirement.
63.8(e) through (g) .....................................................................
63.9(a), (b), (c), (e), (g), (h)(1) through (3), (h)(5) and (6), (i)
and (j).
63.9(f) .........................................................................................
63.9(h)(4) ...................................................................................
63.10(a) ......................................................................................
63.10(b)(1) .................................................................................
63.10(b)(2)(i) ..............................................................................
63.10(b)(2)(ii) .............................................................................
No.
No .....................
Yes.
Yes.
No.
No .....................
63.10(b)(2)(iii) ............................................................................
63.10(b)(2)(iv) and (b)(2)(v) .......................................................
63.10(b)(2)(vi) through (b)(2)(xiv) ..............................................
63.(10)(b)(3) ...............................................................................
63.10(c)(1) through (9) ..............................................................
63.10(c)(10) and (11) .................................................................
Yes.
No.
Yes.
Yes.
Yes.
No .....................
63.10(c)(12) through (c)(14) ......................................................
63.10(c)(15) ...............................................................................
63.10(d)(1) through (4) ..............................................................
63.10(d)(5) .................................................................................
63.10(e) and (f) ..........................................................................
63.11 ..........................................................................................
63.12 through 63.15 ..................................................................
Yes.
No.
Yes.
No .....................
Yes.
No .....................
Yes.
See § 63.850(d)(2) for reporting of malfunctions.
Fmt 4701
E:\FR\FM\06DEP3.SGM
Section reserved.
See §§ 63.850(e)(4)(xvi) and (xvii) for recordkeeping of occurrence and duration of malfunctions and recordkeeping
of actions taken during malfunction.
See §§ 63.850(e)(4)(xvi) and (xvii) for recordkeeping of malfunctions.
Flares will not be used to comply with the emission limits.
[FR Doc. 2011–29881 Filed 12–5–11; 8:45 am]
BILLING CODE 6560–50–P
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06DEP3
]]>Agencies
[Federal Register Volume 76, Number 234 (Tuesday, December 6, 2011)]
[Proposed Rules]
[Pages 76260-76291]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 2011-29881]
[[Page 76259]]
Vol. 76
Tuesday,
No. 234
December 6, 2011
Part III
Environmental Protection Agency
-----------------------------------------------------------------------
40 CFR Part 63
National Emissions Standards for Hazardous Air Pollutants: Primary
Aluminum Reduction Plants; Proposed Rule
��Federal Register / Vol. 76 , No. 234 / Tuesday, December 6, 2011 /
Proposed Rules��
[[Page 76260]]
-----------------------------------------------------------------------
ENVIRONMENTAL PROTECTION
40 CFR Part 63
[EPA-HQ-OAR-2011-0797; FRL-9491-3]
RIN 2060-AQ92
National Emissions Standards for Hazardous Air Pollutants:
Primary Aluminum Reduction Plants
AGENCY: Environmental Protection Agency (EPA).
ACTION: Proposed rule.
-----------------------------------------------------------------------
SUMMARY: The EPA is proposing amendments to the national emissions
standards for hazardous air pollutants for Primary Aluminum Reduction
Plants to address the results of the residual risk and technology
review that the EPA is required to conduct by the Clean Air Act. If
finalized, these proposed amendments would address previously
unregulated emissions (i.e., carbonyl sulfide (COS) emissions from new
and existing potlines and polycyclic organic matter (POM) emissions
from new and existing prebake potlines and existing pitch storage
tanks); remove the vertical stud Soderberg one (VSS1) potline
subcategory; reduce the MACT limits for POM emissions from horizontal
stud Soderberg (HSS) and VSS2 potlines; eliminate the startup, shutdown
and malfunction exemption in accordance with recent actions by the
United States Court of Appeals for the District of Columbia Circuit;
add provisions for facilities to avail themselves of an affirmative
defense in the event of a malfunction under certain conditions; and
make certain technical and editorial changes. The proposed emissions
limits for POM and COS are based on maximum achievable control
technology (MACT). While the proposed modifications would result in
some reduction in actual emissions of POM from existing pitch storage
tanks, reduce the potential emissions of POM from Soderberg potlines,
and prevent increases in emissions of COS and sulfur dioxide, the
health risks posed by actual emissions from this source category are
currently within the acceptable range and would not be reduced
appreciably by the proposed modifications.
DATES: Comments must be received on or before January 20, 2012. Under
the Paperwork Reduction Act, comments on the information collection
provisions are best assured of receiving full consideration if the
Office of Management and Budget (OMB) receives a copy of your comments
on or before January 5, 2012.
Public Hearing. If anyone contacts the EPA requesting to speak at a
public hearing by December 16, 2011, a public hearing will be held on
December 21, 2011.
ADDRESSES: Submit your comments, identified by Docket ID Number EPA-HQ-
OAR-2011-0797, by one of the following methods:
https://www.regulations.gov: Follow the on-line
instructions for submitting comments.
Email: a-and-r-docket@epa.gov, Attention Docket ID Number
EPA-HQ-OAR-2011-0797.
Fax: (202) 566-9744, Attention Docket ID Number EPA-HQ-
OAR-2011-0797.
Mail: U.S. Postal Service, send comments to: EPA Docket
Center, EPA West (Air Docket), Attention Docket ID Number EPA-HQ-OAR-
2011-0797, U.S. Environmental Protection Agency, Mail Code: 2822T, 1200
Pennsylvania Ave. NW., Washington, DC 20460. Please include a total of
two copies. In addition, please mail a copy of your comments on the
information collection provisions to the Office of Information and
Regulatory Affairs, Office of Management and Budget (OMB), Attn: Desk
Officer for EPA, 725 17th Street, NW., Washington, DC 20503.
Hand Delivery: U.S. Environmental Protection Agency, EPA
West (Air Docket), Room 3334, 1301 Constitution Ave. NW., Washington,
DC 20004, Attention Docket ID Number EPA-HQ-OAR-2011-0797. Such
deliveries are only accepted during the Docket's normal hours of
operation, and special arrangements should be made for deliveries of
boxed information.
Instructions. Direct your comments to Docket ID Number EPA-HQ-OAR-
2011-0797. The EPA's policy is that all comments received will be
included in the public docket without change and may be made available
on-line at https://www.regulations.gov, including any personal
information provided, unless the comment includes information claimed
to be confidential business information (CBI) or other information
whose disclosure is restricted by statute. Do not submit information
that you consider to be CBI or otherwise protected through https://www.regulations.gov or email. The https://www.regulations.gov Web site
is an ``anonymous access'' system, which means the EPA will not know
your identity or contact information unless you provide it in the body
of your comment. If you send an email comment directly to the EPA
without going through https://www.regulations.gov, your email address
will be automatically captured and included as part of the comment that
is placed in the public docket and made available on the Internet. If
you submit an electronic comment, the EPA recommends that you include
your name and other contact information in the body of your comment and
with any disk or CD-ROM you submit. If the EPA cannot read your comment
due to technical difficulties and cannot contact you for clarification,
the EPA may not be able to consider your comment. Electronic files
should avoid the use of special characters, any form of encryption, and
be free of any defects or viruses. For additional information about the
EPA's public docket, visit the EPA Docket Center homepage at https://www.epa.gov/epahome/dockets.htm.
Docket. The EPA has established a docket for this rulemaking under
Docket ID Number EPA-HQ-OAR-2011-0797. All documents in the docket are
listed in the https://www.regulations.gov index. 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. Publicly available
docket materials are available either electronically in https://www.regulations.gov or in hard copy at the EPA Docket Center, 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 EPA
Docket Center is (202) 566-1742.
Public Hearing. If a public hearing is held, it will begin at 10
a.m. on December 21, 2011 and will be held at the EPA's campus in
Research Triangle Park, North Carolina, or at an alternate facility
nearby. Persons interested in presenting oral testimony or inquiring as
to whether a public hearing is to be held should contact Ms. Virginia
Hunt, Office of Air Quality Planning and Standards, Sector Policies and
Programs Division, (D243-02), U.S. Environmental Protection Agency,
Research Triangle Park, North Carolina 27711; telephone number: (919)
541-0832.
FOR FURTHER INFORMATION CONTACT: For questions about this proposed
action, contact Mr. David Putney, Sector Policies and Programs Division
(D243-02), Office of Air Quality Planning and Standards, U.S.
Environmental
[[Page 76261]]
Protection Agency, Research Triangle Park, North Carolina 27711,
telephone (919) 541-2016; fax number: (919) 541-3207; and email
address: putney.david@epa.gov. For specific information regarding the
risk modeling methodology, contact Dr. Michael Stewart, Office of Air
Quality Planning and Standards, Health and Environmental Impacts
Division, Air Toxics Assessment Group (C504-06), U.S. Environmental
Protection Agency, Research Triangle Park, NC 27711; telephone number:
(919) 541-7524; fax number: (919) 541-0840; and email address:
stewart.michael@epa.gov. For information about the applicability of the
proposed or current national emission standards for hazardous air
pollutants (NESHAP) for primary aluminum reduction plants to a
particular entity, contact the appropriate person listed in Table 1 of
this preamble.
Table 1--List of EPA Contacts for the NESHAP Addressed in This Proposed
Action
------------------------------------------------------------------------
NESHAP for: OECA Contact \1\ OAQPS Contact \2\
------------------------------------------------------------------------
Primary Aluminum Reduction Patrick Yellin, David Putney,
Plants. (202) 564-2970, (919) 541-2016,
yellin.patrick@epa. putney.david@epa.go
gov. v
------------------------------------------------------------------------
\1\ EPA Office of Enforcement and Compliance Assurance.
\2\ EPA Office of Air Quality Planning and Standards.
SUPPLEMENTARY INFORMATION:
Preamble Acronyms and Abbreviations
Several acronyms and terms used to describe industrial processes,
data inventories, and risk modeling are included in this preamble.
While this may not be an exhaustive list, the following terms and
acronyms are defined here for reference:
ADAF age-dependent adjustment factors
AEGL acute exposure guideline levels
AERMOD air dispersion model used by the HEM-3 model
AMOS ample margin of safety
ANPRM advance notice of proposed rulemaking
ATSDR Agency for Toxic Substances and Disease Registry
BACT best available control technology
BLDS bag leak detection system
CAA Clean Air Act
CBI Confidential Business Information
CEMS continuous emissions monitoring system
CFR Code of Federal Regulations
COS carbonyl sulfide
CTE central tendency exposure
EJ environmental justice
EPA Environmental Protection Agency
ERPG Emergency Response Planning Guidelines
ERT Electronic Reporting Tool
HAP hazardous air pollutants
HEM-3 Human Exposure Model, Version 3
HEPA high efficiency particulate air
HHRAP Human Health Risk Assessment Protocols
HI Hazard Index
HQ Hazard Quotient
ICR information collection request
IRIS Integrated Risk Information System
Km kilometer
LAER lowest achievable emissions rate
lb/yr pounds per year
MACT maximum achievable control technology
MACT Code Code within the NEI used to identify processes included in
a source category
MDL method detection level
mg/acm milligrams per actual cubic meter
mg/dscm milligrams per dry standard cubic meter
mg/m\3\ milligrams per cubic meter
MIR maximum individual risk
MRL minimum risk level
NAC/AEGL Committee National Advisory Committee for Acute Exposure
Guideline Levels for Hazardous Substances
NAICS North American Industry Classification System
NAS National Academy of Sciences
NATA National Air Toxics Assessment
NEI National Emissions Inventory
NESHAP National Emissions Standards for Hazardous Air Pollutants
NOAEL no observed adverse effects level
NRC National Research Council
NTTAA National Technology Transfer and Advancement Act
O&M operation and maintenance
OAQPS Office of Air Quality Planning and Standards
ODW Office of Drinking Water
OECA Office of Enforcement and Compliance Assurance
OHEA Office of Health and Environmental Assessment
OMB Office of Management and Budget
PB-HAP hazardous air pollutants known to be persistent and bio-
accumulative in the environment
PM particulate matter
POM polycyclic organic matter
ppmv parts per million volume
RACT reasonably available control technology
RBLC RACT/BACT/LAER Clearinghouse
REL reference exposure level
RFA Regulatory Flexibility Act
RfC reference concentration
RfD reference dose
RIA Regulatory Impact Analysis
RTR residual risk and technology review
SAB Science Advisory Board
SBA Small Business Administration
SCC Source Classification Codes
SOP standard operating procedures
SSM startup, shutdown, and malfunction
TEQ toxic equivalency quotient
TOSHI target organ-specific hazard index
TPY tons per year
TRIM Total Risk Integrated Modeling System
TTN Technology Transfer Network
UF uncertainty factor
[micro]g/m \3\ microgram per cubic meter
UL upper limit
UMRA Unfunded Mandates Reform Act
UPL upper predictive limit
URE unit risk estimate
WHO World Health Organization
WWW worldwide web
Organization of this Document. The information in this preamble is
organized as follows:
I. General Information
A. What is the statutory authority for this action?
B. Does this action apply to me?
C. Where can I get a copy of this document and other related
information?
D. What should I consider as I prepare my comments for the EPA?
II. Background
A. What is this source category and how did the MACT standard
regulate its HAP emissions?
B. What data collection activities were conducted to support
this action?
III. Analyses Performed
A. How did we address unregulated emission sources?
B. How did we estimate risks posed by the source category?
C. How did we consider the risk results in making decisions for
this proposal?
D. How did we perform the technology review?
E. What other issues are we addressing in this proposal?
IV. Analytical Results and Proposed Decisions
A. What are the results of our analyses and proposed decisions
regarding unregulated emissions sources?
B. What are the results of the risk assessments?
C. What are our proposed decisions regarding risk acceptability
and ample margin of safety?
D. What are the results and proposed decisions based on our
technology review?
E. What other actions are we proposing?
F. Compliance dates
V. Summary of Cost, Environmental, and Economic Impacts
A. What are the affected sources?
B. What are the air quality impacts?
C. What are the cost impacts?
D. What are the economic impacts?
E. What are the benefits?
VI. Request for Comments
[[Page 76262]]
VII. Submitting Data Corrections
VIII. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review and
Executive Order 13563: Improving Regulation and Regulatory Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act
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 Risks and Safety Risks
H. Executive Order 13211: Actions Concerning Regulations That
Significantly Affect Energy Supply, Distribution, or Use
I. National Technology Transfer and Advancement Act
J. Executive Order 12898: Federal Actions To Address
Environmental Justice in Minority Populations and Low-Income
Populations
I. General Information
A. What is the statutory authority for this action?
Section 112 of the CAA establishes a two-stage regulatory process
to address emissions of hazardous air pollutants (HAP) from stationary
sources. In the first stage, after the EPA has identified categories of
sources emitting one or more of the HAP listed in section 112(b) of the
CAA, section 112(d) of the CAA calls for us to promulgate national
emission standards for hazardous air pollutants (NESHAP) for those
sources. ``Major sources'' are those that emit or have the potential to
emit (PTE) 10 tons per year (tpy) or more of a single HAP or 25 tpy or
more of any combination of HAP. For major sources, these technology-
based standards must reflect the maximum degree of emission reductions
of HAP achievable (after considering cost, energy requirements and
nonair quality health and environmental impacts) and are commonly
referred to as maximum achievable control technology (MACT) standards.
MACT standards are to reflect application of measures, processes,
methods, systems or techniques including, but not limited to, measures
which (1) reduce the volume of or eliminate emissions of pollutants
through process changes, substitution of materials or other
modifications, (2) enclose systems or processes to eliminate emissions,
(3) capture or treat pollutants when released from a process, stack,
storage or fugitive emissions point, (4) are design, equipment, work
practice or operational standards (including requirements for operator
training or certification) or (5) are a combination of the above. CAA
section 112(d)(2)(A)-(E). The MACT standard may take the form of a
design, equipment, work practice or operational standard where the EPA
first determines that either (1) a pollutant cannot be emitted through
a conveyance designed and constructed to emit or capture the pollutant
or that any requirement for, or use of, such a conveyance would be
inconsistent with law, or (2) the application of measurement
methodology to a particular class of sources is not practicable due to
technological and economic limitations. CAA sections 112(h)(1)-(2).
The MACT ``floor'' is the minimum control level allowed for MACT
standards promulgated under CAA section 112(d)(3) and may not be based
on cost considerations. For new sources, the MACT floor cannot be less
stringent than the emission control that is achieved in practice by the
best-controlled similar source. The MACT floors for existing sources
can be less stringent than floors for new sources, but they cannot be
less stringent than the average emission limitation achieved by the
best-performing 12 percent of existing sources in the category or
subcategory (or the best-performing five sources for categories or
subcategories with fewer than 30 sources). In developing MACT
standards, we must also consider control options that are more
stringent than the floor. We may establish standards more stringent
than the floor (``beyond the floor'' standards) based on the
consideration of the cost of achieving the emissions reductions and any
nonair quality health and environmental impacts and energy
requirements. No beyond the floor standards are proposed in this
rulemaking action.
The EPA is then required to review these technology-based standards
and to revise them ``as necessary (taking into account developments in
practices, processes, and control technologies)'' no less frequently
than every 8 years, under CAA section 112(d)(6). In conducting this
review, the EPA is not obliged to completely recalculate the prior MACT
determination. NRDC v. EPA, 529 F.3d 1077, 1084 (D.C. Cir. 2008).
The second stage in standard-setting focuses on reducing any
remaining ``residual'' risk according to CAA section 112(f). This
provision requires, first, that the EPA prepare a Report to Congress
discussing (among other things) methods of calculating risk posed (or
potentially posed) by sources after implementation of the MACT
standards, the public health significance of those risks, and the EPA's
recommendations as to legislation regarding such remaining risk. The
EPA prepared and submitted this report (Residual Risk Report to
Congress, EPA-453/R-99-001) in March 1999. Congress did not act in
response to the report, thereby triggering the EPA's obligation under
CAA section 112(f)(2) to analyze and address residual risk.
CAA section 112(f)(2) requires us to determine, for source
categories subject to MACT standards, whether the emissions standards
provide an ample margin of safety to protect public health. If the MACT
standards for HAP ``classified as a known, probable, or possible human
carcinogen do not reduce lifetime excess cancer risks to the individual
most exposed to emissions from a source in the category or subcategory
to less than 1-in-1 million,'' the EPA must promulgate residual risk
standards for the source category (or subcategory), as necessary, to
provide an ample margin of safety to protect public health. In doing
so, the EPA may adopt standards equal to existing MACT standards if the
EPA determines that the existing standards are sufficiently protective.
NRDC v. EPA, 529 F.3d 1077, 1083 (D.C. Cir. 2008). (``If EPA determines
that the existing technology-based standards provide an ``ample margin
of safety,'' then the agency is free to readopt those standards during
the residual risk rulemaking.'') The EPA must also adopt more stringent
standards, if necessary, to prevent an adverse environmental effect \1\
but must consider cost, energy, safety and other relevant factors in
doing so.
---------------------------------------------------------------------------
\1\ ``Adverse environmental effect'' is defined in CAA section
112(a)(7) as any significant and widespread adverse effect, which
may be reasonably anticipated to wildlife, aquatic life or natural
resources, including adverse impacts on populations of endangered or
threatened species or significant degradation of environmental
qualities over broad areas.
---------------------------------------------------------------------------
Section 112(f)(2) of the CAA expressly preserves our use of a two-
step process for developing standards to address any residual risk and
our interpretation of ``ample margin of safety'' developed in the
National Emission Standards for Hazardous Air Pollutants: Benzene
Emissions From Maleic Anhydride Plants, Ethylbenzene/Styrene Plants,
Benzene Storage Vessels, Benzene Equipment Leaks, and Coke By-Product
Recovery Plants (Benzene NESHAP) (54 FR 38044, September 14, 1989). The
first step in this process is the determination of acceptable risk. The
second step provides for an ample margin of safety to protect public
health, which is the level at which the standards are set (unless a
more
[[Page 76263]]
stringent standard is required to prevent, taking into consideration
costs, energy, safety, and other relevant factors, an adverse
environmental effect).
The terms ``individual most exposed,'' ``acceptable level,'' and
``ample margin of safety'' are not specifically defined in the CAA.
However, CAA section 112(f)(2)(B) preserves the interpretation set out
in the Benzene NESHAP, and the United States Court of Appeals for the
District of Columbia Circuit in NRDC v. EPA, 529 F.3d 1077, concluded
that the EPA's interpretation of subsection 112(f)(2) is a reasonable
one. See NRDC v. EPA, 529 F.3d at 1083 (``[S]ubsection 112(f)(2)(B)
expressly incorporates the EPA's interpretation of the Clean Air Act
from the Benzene standard, complete with a citation to the Federal
Register''). (D.C. Cir. 2008). See also, A Legislative History of the
Clean Air Act Amendments of 1990, volume 1, p. 877 (Senate debate on
Conference Report). We notified Congress in the Residual Risk Report to
Congress that we intended to use the Benzene NESHAP approach in making
CAA section 112(f) residual risk determinations (EPA-453/R-99-001, p.
ES-11).
In the Benzene NESHAP, we stated as an overall objective:
* * * in protecting public health with an ample margin of
safety, we strive to provide maximum feasible protection against
risks to health from hazardous air pollutants by, (1) protecting the
greatest number of persons possible to an individual lifetime risk
level no higher than approximately 1-in-1 million; and (2) limiting
to no higher than approximately 1-in-10 thousand [i.e., 100-in-1
million] the estimated risk that a person living near a facility
would have if he or she were exposed to the maximum pollutant
concentrations for 70 years.
The agency also stated that, ``The EPA also considers incidence
(the number of persons estimated to suffer cancer or other serious
health effects as a result of exposure to a pollutant) to be an
important measure of the health risk to the exposed population.
Incidence measures the extent of health risk to the exposed population
as a whole, by providing an estimate of the occurrence of cancer or
other serious health effects in the exposed population.'' The agency
went on to conclude that ``estimated incidence would be weighed along
with other health risk information in judging acceptability.'' As
explained more fully in our Residual Risk Report to Congress, the EPA
does not define ``rigid line[s] of acceptability,'' but considers
rather broad objectives to be weighed with a series of other health
measures and factors (EPA-453/R-99-001, p. ES-11). The determination of
what represents an ``acceptable'' risk is based on a judgment of ``what
risks are acceptable in the world in which we live'' (Residual Risk
Report to Congress, p. 178, quoting the Vinyl Chloride decision at 824
F.2d 1165) recognizing that our world is not risk-free.
In the Benzene NESHAP, we stated that ``EPA will generally presume
that if the risk to [the maximum exposed] individual is no higher than
approximately 1-in-10 thousand, that risk level is considered
acceptable.'' 54 FR 38045. We discussed the maximum individual lifetime
cancer risk (or maximum individual risk (MIR)) as being ``the estimated
risk that a person living near a plant would have if he or she were
exposed to the maximum pollutant concentrations for 70 years.'' Id. We
explained that this measure of risk ``is an estimate of the upper bound
of risk based on conservative assumptions, such as continuous exposure
for 24 hours per day for 70 years.'' Id. We acknowledge that maximum
individual lifetime cancer risk ``does not necessarily reflect the true
risk, but displays a conservative risk level which is an upper-bound
that is unlikely to be exceeded.'' Id.
Understanding that there are both benefits and limitations to using
maximum individual lifetime cancer risk as a metric for determining
acceptability, we acknowledged in the 1989 Benzene NESHAP that
``consideration of maximum individual risk * * * must take into account
the strengths and weaknesses of this measure of risk.'' Id.
Consequently, the presumptive risk level of 100-in-1 million (1-in-10
thousand) provides a benchmark for judging the acceptability of maximum
individual lifetime cancer risk, but does not constitute a rigid line
for making that determination.
The agency also explained in the 1989 Benzene NESHAP the following:
``In establishing a presumption for MIR, rather than a rigid line for
acceptability, the agency intends to weigh it with a series of other
health measures and factors. These include the overall incidence of
cancer or other serious health effects within the exposed population,
the numbers of persons exposed within each individual lifetime risk
range and associated incidence within, typically, a 50-kilometer (km)
exposure radius around facilities, the science policy assumptions and
estimation uncertainties associated with the risk measures, weight of
the scientific evidence for human health effects, other quantified or
unquantified health effects, effects due to co-location of facilities
and co-emission of pollutants.'' Id.
In some cases, these health measures and factors taken together may
provide a more realistic description of the magnitude of risk in the
exposed population than that provided by maximum individual lifetime
cancer risk alone. As explained in the Benzene NESHAP, ``[e]ven though
the risks judged `acceptable' by the EPA in the first step of the Vinyl
Chloride inquiry are already low, the second step of the inquiry,
determining an `ample margin of safety,' again includes consideration
of all of the health factors, and whether to reduce the risks even
further.'' In the ample margin of safety decision process, the agency
again considers all of the health risks and other health information
considered in the first step. Beyond that information, additional
factors relating to the appropriate level of control will also be
considered, including costs and economic impacts of controls,
technological feasibility, uncertainties and any other relevant
factors. Considering all of these factors, the agency will establish
the standard at a level that provides an ample margin of safety to
protect the public health, as required by CAA section 112(f). 54 FR
38046.
As discussed in the previous section of this preamble, we apply a
two-step process for developing standards to address residual risk. In
the first step, the EPA determines whether risks are acceptable. This
determination ``considers all health information, including risk
estimation uncertainty, and includes a presumptive limit on maximum
individual lifetime [cancer] risk (MIR) \2\ of approximately 1-in-10
thousand [i.e., 100-in-1 million].'' 54 FR 38045. In the second step of
the process, the EPA sets the standard at a level that provides an
ample margin of safety ``in consideration of all health information,
including the number of persons at risk levels higher than
approximately 1-in-1 million, as well as other relevant factors,
including costs and economic impacts, technological feasibility, and
other factors relevant to each particular decision.'' Id.
---------------------------------------------------------------------------
\2\ Although defined as ``maximum individual risk,'' MIR refers
only to cancer risk. MIR, one metric for assessing cancer risk, is
the estimated risk were an individual exposed to the maximum level
of a pollutant for a lifetime.
---------------------------------------------------------------------------
In past residual risk determinations, the EPA presented a number of
human health risk metrics associated with emissions from the category
under review, including: The MIR; the numbers of persons in various
risk ranges; cancer incidence; the maximum noncancer hazard index (HI);
and the maximum acute noncancer hazard. In estimating risks, the EPA
considered
[[Page 76264]]
source categories under review that are located near each other and
that affect the same population. The EPA provided estimates of the
expected difference in actual emissions from the source category under
review and emissions allowed pursuant to the source category MACT
standard. The EPA also discussed and considered risk estimation
uncertainties. The EPA is providing this same type of information in
support of these actions.
The agency acknowledges that the Benzene NESHAP provides
flexibility regarding what factors the EPA might consider in making our
determinations and how they might be weighed for each source category.
In responding to comment on our policy under the Benzene NESHAP, the
EPA explained that: ``The policy chosen by the Administrator permits
consideration of multiple measures of health risk. Not only can the MIR
figure be considered, but also incidence, the presence of noncancer
health effects, and the uncertainties of the risk estimates. In this
way, the effect on the most exposed individuals can be reviewed as well
as the impact on the general public. These factors can then be weighed
in each individual case. This approach complies with the Vinyl Chloride
mandate that the Administrator ascertain an acceptable level of risk to
the public by employing [her] expertise to assess available data. It
also complies with the Congressional intent behind the CAA, which did
not exclude the use of any particular measure of public health risk
from the EPA's consideration with respect to CAA section 112
regulations, and, thereby, implicitly permits consideration of any and
all measures of health risk which the Administrator, in [her] judgment,
believes are appropriate to determining what will `protect the public
health.' ''
For example, the level of the MIR is only one factor to be weighed
in determining acceptability of risks. The Benzene NESHAP explains ``an
MIR of approximately 1-in-10 thousand should ordinarily be the upper
end of the range of acceptability. As risks increase above this
benchmark, they become presumptively less acceptable under CAA section
112, and would be weighed with the other health risk measures and
information in making an overall judgment on acceptability. Or, the
agency may find, in a particular case, that a risk that includes MIR
less than the presumptively acceptable level is unacceptable in the
light of other health risk factors.'' Similarly, with regard to the
ample margin of safety analysis, the Benzene NESHAP states that: ``EPA
believes the relative weight of the many factors that can be considered
in selecting an ample margin of safety can only be determined for each
specific source category. This occurs mainly because technological and
economic factors (along with the health-related factors) vary from
source category to source category.''
B. Does this action apply to me?
The regulated industrial source category that is the subject of
this proposal is listed in Table 2 of this preamble. Table 2 of this
preamble is not intended to be exhaustive, but rather provides a guide
for readers regarding the entities likely to be affected by this
proposed action. These standards, once finalized, will be directly
applicable to affected sources. Federal, State, local, and Tribal
government entities are not affected by this proposed action. As
defined in the source category listing report published by the EPA in
1992, the Primary Aluminum Reduction Plant source category is defined
as any facility which produced primary aluminum by the electrolytic
reduction process.
Table 2--NESHAP and Industrial Source Categories Affected by This Proposed Action
----------------------------------------------------------------------------------------------------------------
Source category NESHAP NAICS code \1\ MACT code \2\
----------------------------------------------------------------------------------------------------------------
Primary Aluminum Reduction Plants........... Primary Aluminum Reduction 331312 0023
Plants.
----------------------------------------------------------------------------------------------------------------
\1\ North American Industry Classification System.
\2\ Maximum Achievable Control Technology.
C. Where can I get a copy of this document and other related
information?
In addition to being available in the docket, an electronic copy of
this proposal will also be available on the World Wide Web (WWW)
through the EPA's Technology Transfer Network (TTN). Following
signature by the EPA Administrator, a copy of this proposed action will
be posted on the TTN's policy and guidance page for newly proposed or
promulgated rules at the following address: https://www.epa.gov/ttn/atw/rrisk/rtrpg.html. The TTN provides information and technology exchange
in various areas of air pollution control.
Additional information is available on the residual risk and
technology review (RTR) Web page at: https://www.epa.gov/ttn/atw/rrisk/rtrpg.html. This information includes source category descriptions and
detailed emissions estimates and other data that were used as inputs to
the risk assessments.
D. What should I consider as I prepare my comments for the EPA?
Submitting CBI. Do not submit information containing CBI to the EPA
through https://www.regulations.gov or email. Clearly mark the part or
all of the information that you claim to be CBI. For CBI information on
a disk or CD ROM that you mail to the EPA, mark the outside of the disk
or CD ROM as CBI and then identify electronically within the disk or CD
ROM the specific information that is claimed as CBI. In addition to one
complete version of the comment that includes information claimed as
CBI, a copy of the comment that does not contain the information
claimed as CBI must be submitted for inclusion in the public docket. If
you submit a CD ROM or disk that does not contain CBI, mark the outside
of the disk or CD ROM clearly that it does not contain CBI. Information
not marked as CBI will be included in the public docket and the EPA's
electronic public docket without prior notice. Information marked as
CBI will not be disclosed except in accordance with procedures set
forth in 40 CFR part 2. Send or deliver information identified as CBI
only to the following address: Roberto Morales, OAQPS Document Control
Officer (C404-02), Office of Air Quality Planning and Standards, U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina
27711, Attention Docket ID Number EPA-HQ-OAR-2011-0797.
II. Background
A. What is this source category and how did the MACT standard regulate
its HAP emissions?
The NESHAP (or MACT rule) for the Primary Aluminum Reduction Plants
was promulgated on October 7, 1997 (62 FR 52407) and amended on
November 2, 2005 (70 FR 66285). The rule is applicable to facilities
with affected sources associated with the production of aluminum by
electrolytic reduction. Aluminum is produced from refined
[[Page 76265]]
bauxite ore (also known as alumina), using an electrolytic reduction
process in a series of cells called a ``potline.'' The raw materials
include alumina, coke, pitch and fluoride salts. According to
information available on the Web site of The Aluminum Association, Inc.
(https://www.aluminum.org) approximately 50 percent of the aluminum
produced in the U.S. comes from primary aluminum facilities. The two
main potline types are prebake (a newer, higher efficiency, lower-
emitting technology) and Soderberg (an older, lower efficiency, higher-
emitting technology). There are currently 15 facilities located in the
United States that are subject to the requirements of this NESHAP: 14
primary aluminum production plants and one carbon-only prebake anode
production facility. These 14 primary aluminum production plants have
approximately 53 potlines that produce aluminum. Each plant has a paste
production operation, and 12 of the 14 plants have anode bake furnaces.
Twelve of the 14 facilities utilize prebake potlines; the other 2
utilize Soderberg potlines. According to The Aluminum Association,
Inc., due to a decrease in demand for aluminum, four of the 14
facilities are currently idle including 1 Soderberg facility. The major
HAPs emitted by these facilities are carbonyl sulfide (COS), hydrogen
fluoride (HF), and polycyclic organic matter (POM), specifically
polycyclic aromatic hydrocarbons (PAH).
The standards promulgated in 1997 and 2005 apply to emissions of
HF, measured using total fluorides (TF) as a surrogate, from all
potlines and anode bake furnaces and POM (as measured by methylene
chloride extractables) from Soderberg potlines, anode bake furnaces,
paste production plants and pitch storage tanks associated with primary
aluminum reduction. Affected sources under the rules are each potline,
each anode bake furnace (except for one that is located at a facility
that only produces anodes for use off-site), each paste production
plant, and each new pitch storage tank.
The NESHAP designated seven subcategories of existing potlines
based primarily on differences in the process operation and
configuration. The control of primary emissions from the reduction
process is typically achieved by the installation of a dry alumina
scrubber (with a baghouse to collect the alumina and other particulate
matter). The MACT control technology typically used for anode bake
furnaces is a dry alumina scrubber, and a capture system vented to a
dry coke scrubber is used for control of paste production plants. See
Table 3 for the emission limits.
Table 3--Summary of Current MACT Emission Limits for Existing Sources
Under the 1997 NESHAP, and the 2005 Amendments
------------------------------------------------------------------------
Source Pollutant Emission limit
------------------------------------------------------------------------
Potlines: \1\
CWPB1 potlines............ TF............... 0.95 kg/Mg (1.9 lb/
ton) of aluminum
produced.
CWPB2 potlines............ TF............... 1.5 kg/Mg (3.0 lb/
ton) of aluminum
produced.
CWPB3 potlines............ TF............... 1.25 kg/Mg (2.5 lb/
ton) of aluminum
produced.
SWPB potlines............. TF............... 0.8 kg/Mg (1.6 lb/
ton) of aluminum
produced.
VSS1 potlines............. TF............... 1.1 kg/Mg (2.2 lb/
ton) of aluminum
produced.
POM.............. 1.2 kg/Mg (2.4 lb/
ton) of aluminum
produced.
VSS2 potlines............. TF............... 1.35 kg/Mg (2.7 lb/
ton) of aluminum
produced.
POM.............. 2.85 kg/Mg (5.7 lb/
ton) of aluminum
produced.
HSS potlines.............. TF............... 1.35 kg/Mg (2.7 lb/
ton) of aluminum
produced.
POM.............. 2.35 kg/Mg (4.7 lb/
ton) of aluminum
produced.
Paste Production.............. POM.............. Install, operate, and
maintain equipment
for capture of
emissions and vent
to a dry coke
scrubber.
Anode Bake Furnace (collocated TF............... 0.10 kg/Mg (0.20 lb/
with a primary aluminum POM.............. ton) of green anode.
plant). 0.09 kg/Mg (0.18 lb/
ton) of green anode.
------------------------------------------------------------------------
\1\ CWPB1 = Center-worked prebake potline with the most modern reduction
cells; includes all center-worked prebake potlines not specifically
identified as CWPB2 or CWPB3.
CWPB2 = Center-worked prebake potlines located at Alcoa in Rockdale,
Texas; Kaiser Aluminum in Mead, Washington; Ormet Corporation in
Hannibal, Ohio; Ravenswood Aluminum in Ravenswood, West Virginia;
Reynolds Metals in Troutdale, Oregon; and Vanalco Aluminum in
Vancouver, Washington.
CWPB3 = Center-worked prebake potline that produces very high purity
aluminum, has wet scrubbers as the primary control system, and is
located at the primary aluminum plant operated by NSA in Hawesville,
Kentucky.
HSS = Horizontal stud Soderberg potline.
SWPB = Side-worked prebake potline.
VSS1 = Vertical stud Soderberg potline at Northwest Aluminum in The
Dalles, Oregon, or at Columbia Aluminum in Goldendale, Washington.
VSS2 = Vertical stud Soderberg potlines at Columbia Falls Aluminum in
Columbia Falls, Montana.
Table 4--Summary of Current MACT Emission Limits for New Sources Under
the 1997 NESHAP and 2005 Amendments
------------------------------------------------------------------------
Source Pollutant Emission limit
------------------------------------------------------------------------
All Potlines.................. TF............... 0.6 kg/Mg (1.2 lb/
ton) of aluminum
produced.
VSS1, VSS2, and HSS potlines.. POM.............. 0.32 kg/Mg (0.63 lb/
ton) of aluminum
produced.
Paste Production.............. POM.............. Install, operate, and
maintain equipment
for capture of
emissions and vent
to a dry coke
scrubber.
Anode Bake Furnace (collocated TF............... 0.01 kg/Mg (0.020 lb/
with a primary aluminum POM.............. ton) of green anode
plant). 0.025 kg/Mg (0.05 lb/
ton) of green anode.
Pitch storage tanks........... POM.............. Emission control
system designed and
operated to reduce
inlet emissions by
95 percent or
greater.
------------------------------------------------------------------------
[[Page 76266]]
The 1997 NESHAP for primary aluminum reduction plants incorporates
new source performance standards for potroom groups; these emission
limits are listed in Table 4. The limits for new Soderberg facilities
apply to any Soderberg facility that adds a new potroom group to an
existing potline or is associated with a potroom group that meets the
definition of a modified or reconstructed potroom group. Since these
POM limits are very stringent, they effectively preclude the operation
of any new Soderberg potlines.
Compliance with the emission limits in the current rule is
demonstrated by performance testing which can be addressed individually
for each affected source or according to emissions averaging
provisions. Monitoring requirements include monthly measurements of TF
secondary emissions, quarterly measurement of POM secondary emissions
and annual measurement of primary emissions, continuous parameter
monitoring for each emission control device, a monitoring device to
track daily weight of aluminum produced, daily inspection for visible
emissions, and daily inspection of wet roof scrubbers. Recordkeeping
for the rule is consistent with the General Provisions requirements
with the addition of recordkeeping for daily production of aluminum,
records supporting emissions averaging and records documenting the
portion of TF measured as particulate matter or gaseous form.
B. What data collection activities were conducted to support this
action?
For the Primary Aluminum Reduction Plant source category, we
compiled a preliminary dataset using available information, reviewed
the data, and made changes where necessary. The preliminary dataset was
based on data in the 2002 National Emissions Inventory (NEI) Final
Inventory, Version 1 (made publicly available on February 26, 2006),
and the 2005 National Emissions Inventory (NEI), version 2.0 (made
publicly available in October 2008). The NEI is a database that
contains information about sources that emit criteria air pollutants,
their precursors, and HAP. The NEI database includes estimates of
annual air pollutant emissions from point and volume sources, emission
release characteristic data such as height, velocity, temperature and
location latitude/longitude coordinates.
We reviewed the NEI datasets, corrected geographic coordinates and
stack parameters in consultation with the facilities, and made changes
based on available information. We also reviewed the emissions and
other data to identify data anomalies that could affect risk estimates.
The 2005 NEI was then updated to develop the 2005 National Air Toxics
Assessment (NATA) Inventory. Subsequently, in April 2011, we received
test data and other information through an Information Collection
Request (ICR) from 11 of the 15 facilities in the source category.
These ICR data were then used along with the 2005 NATA inventory data
to develop the emissions dataset for this source category, which
includes our best estimates of actual emissions of HAP for the
facilities. This dataset was then used in the risk modeling analyses to
estimate the risks due to actual emissions for the source category.
POM emissions were allocated to specific POM compounds on the basis
of the fractional contributions of these compounds to the actual POM
emissions, as determined (as appropriate) from an average of test data
for two prebake potlines and an average of data from two Soderberg
facilities. Based on knowledge of the industry and previous testing, we
could reasonably expect emissions of approximately 23 POM specific POM
compounds from primary aluminum production facilities. The allocation
incorporated POM emissions at 50 percent of the detection limit for
those compounds ``reported as below detection limit.'' The use of 50
percent of the detection limit is more conservative than assuming that
these compounds were not present; an assumption that the compounds were
present at the detection limit would be an overestimation. The
assumption that these compounds were present at 50 percent of the
detection limit represented the midpoint of two extreme options. For
Soderberg potline stacks, six out of 38 measurements were below the
detection limit. For Soderberg potroom roof vents, 10 out of 38
measurements were below the detection limit. For prebake potline
stacks, 21 out of 38 measurements were below the detection limit. For
prebake potroom roof vents, 25 out of 38 measurements were below the
detection limit.
To estimate allowable emissions, we analyzed the emissions data
gathered from the 2002 NEI, the 2005 NEI and responses to the ICR
described above. Based on that analysis, we estimated that allowable
emissions were generally about 1.5 times higher than actual emissions.
Therefore, to calculate allowable emissions we assumed that allowable
emissions were 1.5 times greater than actual emissions for all
facilities except for one idle Soderberg facility (Columbia Falls). For
Columbia Falls, which has the highest potential for emissions of all
the facilities, we evaluated site-specific data and estimated that
allowable emissions were about 1.9 times higher than actual emissions.
Actual emissions of COS for the industry are estimated to be about
4,400 tons per year (tpy), with an average of about 330 tons per
facility. Actual emissions of HF are estimated to be about 1,900 tpy
with an average of about 160 tpy per facility. Estimated emissions of
speciated compounds of POM were much lower. Estimated actual emissions
of identified POM species totaled approximately 180 tpy for the
industry. Moreover, POM emissions are much higher from Soderberg
facilities compared to prebake facilities. The average POM emissions
from prebake facilities are about 4.5 tpy per facility, and the average
POM emissions for Soderberg facilities are about 60 tpy per facility.
We estimate that approximately one-third of the emissions of POM for
both types of potrooms come from the control device stack, and the
remainder are secondary emissions emitted from potroom vents. This
estimate is based on a summary of emissions derived from reports of
emission testing conducted at two prebake facilities and two Soderberg
facilities (``Industry Review of Draft POM Speciation and Emissions
Data,'' December 19, 2007).
The emissions data, calculations and risk assessment inputs for the
Primary Aluminum Reduction Plant source category are described further
in Draft Development of the RTR Emissions Dataset for the Primary
Aluminum Production Source Category which is available in the docket
for this proposed rulemaking.
III. Analyses Performed
In this section we describe the analyses performed to support the
proposed decisions for the RTR for this source category.
A. How did we address unregulated emissions sources?
In the course of evaluating the Primary Aluminum Reduction Plant
source category, we identified certain HAP for which we failed to
establish emission standards in the original MACT. See National Lime v.
EPA, 233 F. 3d 625, 634 (DC Cir. 2000) (the EPA has ``clear statutory
obligation to set emissions standards for each listed HAP'').
We evaluated establishing emissions limits for COS for the source
category and for POM for various emissions points that had not been
regulated in the 1997 MACT rule or in the 2005
[[Page 76267]]
amendments. Section 112(d)(3)(B) of the CAA requires that the MACT
standards for existing sources be at least as stringent as the average
emissions limitation achieved by the best performing five sources (for
which the Administrator has or could reasonably obtain emissions
information) in a category with fewer than 30 sources. The Primary
Aluminum source category consists of fewer than 30 sources.
The EPA must exercise its judgment, based on an evaluation of the
relevant factors and available data, to determine the level of
emissions control that has been achieved by the best performing sources
under variable conditions. It is recognized in the case law that the
EPA may consider variability in estimating the degree of emissions
reduction achieved by best-performing sources and in setting MACT
floors. See Mossville Envt'l Action Now v. EPA, 370 F.3d 1232, 1241-42
(DC Cir 2004) (holding that the EPA may consider emissions variability
in estimating performance achieved by best-performing sources and may
set the floor at a level that a best-performing source can expect to
meet ``every day and under all operating conditions''). More details on
how we calculate MACT floors and how we account for variability are
described in the Draft MACT Floor Analysis for the Primary Aluminum
Source Category which is available in the docket for this proposed
action.
Carbonyl sulfide (COS) was not regulated in the 1997 NESHAP or in
the 2005 amendments for Primary Aluminum Reduction Plants. In this
action we analyzed the available data and evaluated options for
developing MACT standards for this HAP. Based on all our analyses,
which are described in section IV.A of this preamble, we concluded that
establishing a standard based on a mass balance equation would be the
most appropriate approach. Therefore, we are proposing MACT standards
for COS in today's action based on use of a mass balance equation to
derive COS emissions based on data on anode coke sulfur content, anode
consumption and aluminum production.
Polycyclic organic matter (POM) emissions from prebake potlines
were also not regulated in the 1997 NESHAP or in the 2005 amendments.
We are proposing MACT limits for new and existing prebake potlines in
today's action based on available data. Finally, the 1997 NESHAP
included MACT standards for new pitch storage tanks, which required a
95 percent reduction in emissions. However, the rule had no limits for
existing storage tanks. We are proposing that existing tanks will be
subject to the same standard (i.e., minimum of 95 percent reduction of
POM emissions). At least three facilities are currently achieving this
level of control on existing tanks.
Further details about the analyses, the results and proposed
decisions regarding the proposed MACT limits pursuant to CAA section
112(d)(2) and 112(d)(3) are presented in section IV.A of this preamble.
B. How did we estimate risks posed by the source category?
The EPA conducted risk assessments that provided estimates of the
MIR posed by the HAP emissions for each source in the category, the HI
for chronic exposures to HAP with the potential to cause noncancer
health effects, and the hazard quotient (HQ) for acute exposures to HAP
with the potential to cause noncancer health effects. The assessments
also provided estimates of the distribution of cancer risks within the
exposed populations, cancer incidence and an evaluation of the
potential for adverse environmental effects for each source category.
The risk assessments consisted of seven primary steps, as discussed
below. The docket for this rulemaking contains the following document
which provides more information on the risk assessment inputs and
models: Draft Residual Risk Assessment for the Primary Aluminum
Reduction Plant Source Category. The methods used to assess risks (as
described in the seven primary steps below) are consistent with those
peer-reviewed by a panel of the EPA's Science Advisory Board (SAB) in
2009 and described in their peer review report issued in 2010 \3\; they
are also consistent with the key recommendations contained in that
report.
---------------------------------------------------------------------------
\3\ U.S. EPA SAB. Risk and Technology Review (RTR) Risk
Assessment Methodologies: For Review by the EPA's Science Advisory
Board with Case Studies--MACT I Petroleum Refining Sources and
Portland Cement Manufacturing, May 2010.
---------------------------------------------------------------------------
1. Establishing the Nature and Magnitude of Actual Emissions and
Identifying the Emissions Release Characteristics
As discussed in section II.B of this preamble, we used a dataset
consisting of the estimated actual and allowable emissions as the basis
for the risk assessment. In addition to the quality assurance (QA) of
the emissions and associated parameters contained in the dataset, we
also checked the coordinates of every facility in the dataset through
visual observations using tools such as Google Earth and ArcView. Where
coordinates were found to be incorrect, we identified and corrected
them to the extent possible. We also performed QA of the emissions data
and release characteristics to ensure there were no outliers.
2. Establishing the Relationship Between Actual Emissions and MACT-
Allowable Emissions Levels
The available emissions data in the MACT dataset include estimates
of the mass of HAP actually emitted during the specified annual time
period. These ``actual'' emission levels are often lower than the
emission levels that a facility might be allowed to emit and still
comply with the MACT standards. The emissions level allowed to be
emitted by the MACT standards is referred to as the ``MACT-allowable''
emissions level. This represents the highest emissions level that could
be emitted by the facility without violating the MACT standards.
We discussed the use of both MACT-allowable and actual emissions in
the final Coke Oven Batteries residual risk rule (70 FR 19998-19999,
April 15, 2005) and in the proposed and final Hazardous Organic NESHAP
residual risk rules (71 FR 34428, June 14, 2006, and 71 FR 76609,
December 21, 2006, respectively). In those previous actions, we noted
that assessing the risks at the MACT-allowable level is inherently
reasonable since these risks reflect the maximum level sources could
emit and still comply with national emission standards. But we also
explained that it is reasonable to consider actual emissions, where
such data are available, in both steps of the risk analysis, in
accordance with the Benzene NESHAP. (54 FR 38044, September 14, 1989.)
Further explanation is provided in the document Draft Development
of the RTR Emissions Dataset for the Primary Aluminum Production Source
Category which is available in the docket for this proposed rulemaking.
3. Conducting Dispersion Modeling, Determining Inhalation Exposures and
Estimating Individual and Population Inhalation Risks
Both long-term and short-term inhalation exposure concentrations
and health risks from each facility in the source category addressed in
this proposal were estimated using the Human Exposure Model (HEM)
(Community and Sector HEM-3 version 1.1.0). The HEM-3 performs three
primary risk assessment activities: (1) Conducting dispersion modeling
to estimate the concentrations of HAP in ambient air, (2) estimating
long-term
[[Page 76268]]
and short-term inhalation exposures to individuals residing within 50
km of the modeled sources and (3) estimating individual and population-
level inhalation risks using the exposure estimates and quantitative
dose-response information.
The dispersion model used by HEM-3 is AERMOD, which is one of the
EPA's preferred models for assessing pollutant concentrations from
industrial facilities.\4\ To perform the dispersion modeling and to
develop the preliminary risk estimates, HEM-3 draws on three data
libraries. The first is a library of meteorological data, which is used
for dispersion calculations. This library includes 1 year (1991) of
hourly surface and upper air observations for more than 158
meteorological stations, selected to provide coverage of the United
States and Puerto Rico. A second library of United States Census Bureau
census block \5\ internal point locations and populations provides the
basis of human exposure calculations (Census, 2000). In addition, for
each census block, the census library includes the elevation and
controlling hill height, which are also used in dispersion
calculations. A third library of pollutant unit risk factors and other
health benchmarks is used to estimate health risks. These risk factors
and health benchmarks are the latest values recommended by the EPA for
HAP and other toxic air pollutants. These values are available at
https://www.epa.gov/ttn/atw/toxsource/summary.html and are discussed in
more detail later in this section.
---------------------------------------------------------------------------
\4\ U.S. EPA. Revision to the Guideline on Air Quality Models:
Adoption of a Preferred General Purpose (Flat and Complex Terrain)
Dispersion Model and Other Revisions (70 FR 68218, November 9,
2005).
\5\ A census block is generally the smallest geographic area for
which census statistics are tabulated.
---------------------------------------------------------------------------
In developing the risk assessment for chronic exposures, we used
the estimated annual average ambient air concentration of each of the
HAP emitted by each source for which we have emissions data in the
source category. The air concentrations at each nearby census block
centroid were used as a surrogate for the chronic inhalation exposure
concentration for all the people who reside in that census block. We
calculated the MIR for each facility as the cancer risk associated with
a continuous lifetime (24 hours per day, 7 days per week, and 52 weeks
per year for a 70-year period) exposure to the maximum concentration at
the centroid of an inhabited census block. Individual cancer risks were
calculated by multiplying the estimated lifetime exposure to the
ambient concentration of each of the HAP (in micrograms per cubic
meter) by its unit risk estimate (URE), which is an upper bound
estimate of an individual's probability of contracting cancer over a
lifetime of exposure to a concentration of 1 microgram of the pollutant
per cubic meter of air. For residual risk assessments, we generally use
URE values from the EPA's Integrated Risk Information System (IRIS).
For carcinogenic pollutants without the EPA IRIS values, we look to
other reputable sources of cancer dose-response values, often using
California EPA (CalEPA) URE values, where available. In cases where
new, scientifically credible dose-response values have been developed
in a manner consistent with the EPA guidelines and have und
