Standards of Performance for New Stationary Sources and Emission Guidelines for Existing Sources: Hospital/Medical/Infectious Waste Incinerators, 5510-5550 [E7-1617]
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Federal Register / Vol. 72, No. 24 / Tuesday, February 6, 2007 / Proposed Rules
ENVIRONMENTAL PROTECTION
AGENCY
40 CFR Part 60
[EPA–HQ–OAR–2006–0534; FRL–8274–9]
RIN 2060–A004
Standards of Performance for New
Stationary Sources and Emission
Guidelines for Existing Sources:
Hospital/Medical/Infectious Waste
Incinerators
Environmental Protection
Agency (EPA).
ACTION: Proposed rule.
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AGENCY:
SUMMARY: On September 15, 1997, EPA
adopted new source performance
standards (NSPS) and emission
guidelines for hospital/medical/
infectious waste incinerators (HMIWI).
The NSPS and emission guidelines were
established under sections 111 and 129
of the Clean Air Act (CAA). On
November 14, 1997, the Sierra Club and
the Natural Resources Defense Council
(Sierra Club) filed suit in the U.S. Court
of Appeals for the District of Columbia
Circuit (the Court) challenging EPA’s
methodology for adopting the
regulations. On March 2, 1999, the
Court issued its opinion. The Court
remanded the rule to EPA for further
explanation of the Agency’s reasoning
in determining the minimum regulatory
‘‘floors’’ for new and existing HMIWI.
The Court did not vacate the
regulations, so the NSPS and emission
guidelines remained in effect during the
remand and were fully implemented by
September 2002. This action provides
EPA’s proposed response to the
questions raised in the Court’s remand.
Section 129(a)(5) of the CAA requires
EPA to review and, if appropriate, revise
the NSPS and emission guidelines every
5 years. In this action, EPA also is
proposing our response to this 5-year
review, which would revise the
emission limits in the NSPS and
emission guidelines to reflect the levels
of performance actually achieved by the
emission controls installed to meet the
emission limits set forth in the
September 15, 1997, NSPS and emission
guidelines.
DATES: Comments. Comments must be
received on or before April 9, 2007.
Under the Paperwork Reduction Act,
comments on the information collection
provisions must be received by the
Office of Management and Budget
(OMB) on or before March 8, 2007.
Because of the need to resolve the issues
raised in this action in a timely manner,
EPA will not grant requests for
extensions beyond these dates.
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Public Hearing. If anyone contacts
EPA by February 26, 2007 requesting to
speak at a public hearing, EPA will hold
a public hearing on March 8, 2007. If
you are interested in attending the
public hearing, contact Ms. Pamela
Garrett at (919) 541–7966 to verify that
a hearing will be held.
ADDRESSES: Submit your comments,
identified by Docket ID No. EPA–HQ–
OAR–2006–0534, by one of the
following methods:
www.regulations.gov: Follow the online instructions for submitting
comments.
E-mail: Send your comments via
electronic mail to
a-and-r-Docket@epa.gov, Attention
Docket ID No. EPA–HQ–OAR–2006–
0534.
Facsimile: Fax your comments to
(202) 566–1741, Attention Docket ID No.
EPA–HQ–OAR–2006–0534.
Mail: Send your comments to: EPA
Docket Center (EPA/DC), Environmental
Protection Agency, Mailcode 6102T,
1200 Pennsylvania Ave., NW.,
Washington, DC 20460, Attention
Docket ID No. EPA–HQ–OAR–2006–
0534.
Hand Delivery: Deliver your
comments to: EPA Docket Center (EPA/
DC), EPA West Building, Room 3334,
1301 Constitution Ave., NW.,
Washington, DC 20460, Attention
Docket ID No. EPA–HQ–OAR–2006–
0534. Such deliveries are accepted only
during the normal hours of operation
(8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays), and
special arrangements should be made
for deliveries of boxed information.
Instructions: Direct your comments to
Docket ID No. EPA–HQ–OAR–2006–
0534. The EPA’s policy is that all
comments received will be included in
the public docket and may be made
available online at 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
www.regulations.gov or e-mail. The
www.regulations.gov Web site is an
‘‘anonymous access’’ system, which
means EPA will not know your identity
or contact information unless you
provide it in the body of your comment.
If you send an e-mail comment directly
to EPA without going through
www.regulations.gov, your e-mail
address will be automatically captured
and included as part of the comment
that is placed in the public docket and
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made available on the Internet. If you
submit an electronic comment, 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 EPA
cannot read your comment due to
technical difficulties and cannot contact
you for clarification, 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.
Public Hearing: If a public hearing is
held, it will be held at EPA’s Campus
located at 109 T.W. Alexander Drive in
Research Triangle Park, NC, or an
alternate site nearby. Persons interested
in presenting oral testimony must
contact Ms. Pamela Garrett at (919) 541–
7966 at least 2 days in advance of the
hearing.
Docket: EPA has established a docket
for this action under Docket ID No.
EPA–HQ–OAR–2006–0534 and Legacy
Docket ID No. A–91–61. All documents
in the docket are listed in the
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,
will be publicly available only in hard
copy form. Publicly available docket
materials are available either
electronically at www.regulations.gov or
in hard copy at the EPA Docket Center
EPA/DC, EPA West, Room 3334, 1301
Constitution Ave., NW., Washington,
DC. The Public Reading Room is open
from 8:30 a.m. to 4:30 p.m., Monday
through Friday, excluding legal
holidays. The telephone number for the
Public Reading Room is (202) 566–1744,
and the telephone number for the EPA
Docket Center is (202) 566–1742.
FOR FURTHER INFORMATION CONTACT: Ms.
Mary Johnson, Energy Strategies Group,
Sector Policies and Programs Division
(D243–01), Environmental Protection
Agency, Research Triangle Park, North
Carolina 27711; telephone number:
(919) 541–5025; fax number: (919) 541–
5450; e-mail address:
johnson.mary@epa.gov.
SUPPLEMENTARY INFORMATION:
Organization of This Document. The
following outline is provided to aid in
locating information in this preamble.
I. General Information
A. Does the proposed action apply to me?
B. What should I consider as I prepare my
comments?
II. Background
III. Summary
A. Litigation and Proposed Remand
Response
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B. Proposed Amendments (CAA Section
129(a)(5) 5-Year Review)
IV. Rationale
A. Rationale for the Proposed Response to
the Remand
B. Rationale for the Proposed Amendments
(CAA Section 129(a)(5) 5-Year Review)
V. Impacts of the Proposed Action for
Existing Units
A. What are the primary air impacts?
B. What are the water and solid waste
impacts?
C. What are the energy impacts?
D. What are the secondary air impacts?
E. What are the cost and economic
impacts?
VI. Impacts of the Proposed Action for New
Units
VII. Relationship of the Proposed Action to
Section 112(c)(6) of the CAA
VIII. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory
Planning and 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 and
Safety Risks
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H. Executive Order 13211: Actions That
Significantly Affect Energy Supply,
Distribution or Use
I. National Technology Transfer
Advancement Act
I. General Information
A. Does the proposed action apply to
me?
Regulated Entities. Categories and
entities potentially affected by the
proposed action are those which operate
HMIWI. The NSPS and emission
guidelines for HMIWI affect the
following categories of sources:
Category
NAICS Code
Examples of potentially regulated entities
Industry ........................................
Federal Government ....................
622110,
622310,
325411,
325412, 562213, 611310.
622110, 541710, 928110 ............
State/local/Tribal Government .....
622110, 562213, 611310 ............
Private hospitals, other health care facilities, commercial research laboratories, commercial waste disposal companies, private universities.
Federal hospitals, other health care facilities, public health service,
armed services.
State/local hospitals, other health care facilities, State/local waste disposal services, State universities.
This table is not intended to be
exhaustive, but rather provides a guide
for readers regarding entities likely to be
affected by the proposed action. To
determine whether your facility would
be affected by the proposed action, you
should examine the applicability
criteria in 40 CFR 60.50c of subpart Ec
and 40 CFR 60.32e of subpart Ce. If you
have any questions regarding the
applicability of the proposed action to a
particular entity, contact the person
listed in the preceding FOR FURTHER
INFORMATION CONTACT section.
B. What should I consider as I prepare
my comments?
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1. Submitting CBI
Do not submit information that you
consider to be CBI electronically
through www.regulations.gov or e-mail.
Send or deliver information identified
as CBI to only the following address:
Ms. Mary Johnson, c/o OAQPS
Document Control Officer (Room C404–
02), U.S. EPA, Research Triangle Park,
NC 27711, Attention Docket ID No.
EPA–HQ–OAR–2006–0534. Clearly
mark the part or all of the information
that you claim to be CBI. For CBI
information in a disk or CD ROM that
you mail to 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. Information marked as
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CBI will not be disclosed except in
accordance with procedures set forth in
40 CFR part 2.
If you have any questions about CBI
or the procedures for claiming CBI,
please consult the person identified in
the FOR FURTHER INFORMATION CONTACT
section.
2. Tips for Preparing Your Comments
When submitting comments,
remember to:
a. Identify the rulemaking by docket
number and other identifying
information (subject heading, Federal
Register date and page number).
b. Follow directions. The EPA may
ask you to respond to specific questions
or organize comments by referencing a
Code of Federal Regulations (CFR) part
or section number.
c. Explain why you agree or disagree;
suggest alternatives and substitute
language for your requested changes.
d. Describe any assumptions and
provide any technical information and/
or data that you used.
e. If you estimate potential costs or
burdens, explain how you arrived at
your estimate in sufficient detail to
allow for it to be reproduced.
f. Provide specific examples to
illustrate your concerns, and suggest
alternatives.
g. Explain your views as clearly as
possible, avoiding the use of profanity
or personal threats.
h. Make sure to submit your
comments by the comment period
deadline identified in the preceding
section titled DATES.
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3. Docket
The docket number for the proposed
action regarding the HMIWI NSPS (40
CFR part 60, subpart Ec) and emission
guidelines (40 CFR part 60, subpart Ce)
is Docket ID No. EPA–HQ–OAR–2006–
0534.
4. Worldwide Web (WWW)
In addition to being available in the
docket, an electronic copy of this
proposed action is available on the
WWW through the Technology Transfer
Network Web site (TTN Web).
Following signature, EPA posted a copy
of the proposed action on the TTN’s
policy and guidance page for newly
proposed or promulgated rules at
https://www.epa.gov/ttn/oarpg. The TTN
provides information and technology
exchange in various areas of air
pollution control.
II. Background
Section 129 of the CAA, entitled
‘‘Solid Waste Combustion,’’ requires
EPA to develop and adopt NSPS and
emission guidelines for solid waste
incineration units pursuant to CAA
sections 111 and 129. Sections 111(b)
and 129(a) of the CAA (NSPS program)
address emissions from new HMIWI
units, and CAA sections 111(d) and
129(b) (emission guidelines program)
address emissions from existing HMIWI
units. The NSPS are directly enforceable
Federal regulations. The emission
guidelines are not directly enforceable
but, rather, are implemented by State air
pollution control agencies through
sections 111(d)/129 State plans.
An HMIWI is defined as any device
used to burn hospital waste or medical/
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infectious waste. Hospital waste means
discards generated at a hospital, and
medical/infectious waste means any
waste generated in the diagnosis,
treatment, or immunization of human
beings or animals, in research pertaining
thereto, or in the production or testing
of biologicals (e.g., vaccines, cultures,
blood or blood products, human
pathological waste, sharps). Hospital/
medical/infectious waste does not
include household waste, hazardous
waste, or human and animal remains
not generated as medical waste. An
HMIWI typically is a small, dualchamber incinerator that burns about
800 pounds per hour (lb/hr) of waste.
Smaller units burn as little as 13 lb/hr
while larger units burn as much as 3,700
lb/hr.
Incineration of hospital/medical/
infectious waste causes the release of a
wide array of air pollutants, some of
which exist in the waste feed material
and are released unchanged during
combustion, and some of which are
generated as a result of the combustion
process itself. These pollutants include
particulate matter (PM); heavy metals,
including lead (Pb), cadmium (Cd), and
mercury (Hg); toxic organics, including
chlorinated dibenzo-p-dioxins/
dibenzofurans (CDD/CDF); carbon
monoxide (CO); nitrogen oxides (NOX);
and acid gases, including hydrogen
chloride (HCl) and sulfur dioxide (SO2).
In addition to the use of good
combustion control practices, HMIWI
units are typically controlled by wet
scrubbers or dry sorbent injection fabric
filters (dry scrubbers).
Combustion control includes the
proper design, construction, operation,
and maintenance of HMIWI to destroy
or prevent the formation of air
pollutants prior to their release to the
atmosphere. Test data indicate that as
secondary chamber residence time and
temperature increase, emissions
decrease. Combustion control is most
effective in reducing CDD/CDF, PM, and
CO emissions. The 0.25-second
combustion level includes a minimum
secondary chamber temperature of
1700 °F and a 0.25-second secondary
chamber residence time. These
combustion conditions are typical of
older HMIWI. The 1-second combustion
level includes a minimum secondary
chamber temperature of 1700 °F and
residence time of 1 second. These
combustion conditions are typical of
newer HMIWI. Compared to 0.25second combustion, 1-second
combustion will achieve substantial
reductions in CDD/CDF and CO
emissions, and will provide some
control of PM, but will not reduce
emissions of acid gases (HCl and SO2),
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NOX, or metals (Pb, Cd, and Hg). The 2second combustion level includes a
minimum secondary chamber
temperature of 1800 °F and residence
time of 2 seconds. These combustion
conditions will provide additional
control of CDD/CDF, CO, and PM, but
will not reduce emissions of acid gases
(HCl and SO2), NOX, or metals (Pb, Cd,
and Hg). The 2-second combustion
conditions are considered to be the best
level of combustion control (i.e., good
combustion) that is applied to HMIWI.
Wet scrubbers and dry scrubbers
provide control of PM, CDD/CDF, HCl,
and metals, but do not influence CO,
SO2 (at the low concentrations emitted
by HMIWI units), or NOX; in fact, there
are no technologies currently used by
HMIWI that will consistently reduce
SO2 or NOX emissions. (See Legacy
Docket ID No. A–91–61, item II-A–111;
60 FR 10669, 10671–10677; and 61 FR
31742–31743.)
On September 15, 1997, EPA adopted
NSPS (40 CFR part 60, subpart Ec) and
emission guidelines (40 CFR part 60,
subpart Ce) for entities which operate
HMIWI. The NSPS and emission
guidelines are designed to reduce air
pollution emitted from new and existing
HMIWI, including HCl, CO, Pb, Cd, Hg,
PM, CDD/CDF (total, or 2,3,7,8tetrachlorinated dibenzo-p-dioxin toxic
equivalent (TEQ)), NOX, SO2, and
opacity. The NSPS apply to HMIWI for
which construction began after June 20,
1996, or for which modification began
after March 16, 1998. The NSPS became
effective on March 16, 1998, and its
requirements apply as of that date or at
start-up of a HMIWI unit, whichever is
later. The emission guidelines apply to
HMIWI for which construction began on
or before June 20, 1996, and required
compliance by September 2002.
CAA section 129 requires EPA to
establish technology-based emission
standards that reflect levels of control
EPA determines are achievable for new
and existing units, after considering
costs, non-air quality health and
environmental impacts, and energy
requirements associated with the
implementation of the standards.
In setting forth the methodology EPA
must use to establish the technologybased performance standards and
emissions guidelines, CAA section
129(a)(2) provides that standards
‘‘applicable to solid waste incineration
units promulgated under section 111
and this section shall reflect the
maximum degree of reduction in
emissions of [certain listed air
pollutants] that the Administrator,
taking into consideration the cost of
achieving such emission reduction, and
any non-air quality health and
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environmental impacts and energy
requirements, determines is achievable
for new and existing units in each
category.’’ This level of control is
referred to as a maximum achievable
control technology, or MACT standard.
In promulgating a MACT standard,
EPA must first calculate the minimum
stringency levels for new and existing
solid waste incineration units in a
category, generally based on levels of
emissions control achieved or required
to be achieved by the subject units. The
minimum level of stringency is called
the MACT floor, and CAA section
129(a)(2) provides that the ‘‘degree of
reduction in emissions that is deemed
achievable for new units in a category
shall not be less stringent than the
emissions control that is achieved in
practice by the best controlled similar
unit, as determined by the
Administrator. Emissions standards for
existing units in a category may be less
stringent than standards for new units
in the same category but shall not be
less stringent than the average emissions
limitation achieved by the best
performing 12 percent of units in the
category.’’
The minimum stringency
requirements form the first and least
stringent regulatory option EPA must
consider in the determination of MACT
for a source category. EPA must also
determine whether to control emissions
‘‘beyond the floor,’’ after considering the
costs, non-air quality health and
environmental impacts, and energy
requirements of such more stringent
control. These are the two steps EPA
took in the 1997 HMIWI rulemaking.
Finally, every 5 years after adopting a
MACT standard under section 129, CAA
section 129(a)(5) requires EPA to review
and, if appropriate, revise the
incinerator standards. In addition to
responding to the Court’s remand in
Sierra Club v. EPA, 167 F.3d 658 (D.C.
Cir. 1999), this proposed action includes
our first set of proposed revisions to the
HMIWI standards, also known as the 5year review.
III. Summary
A. Litigation and Proposed Remand
Response
1. What was EPA’s general methodology
for determining MACT?
The methodology used to determine
MACT is similar for source categories
under sections 112 and 129 of the CAA.
However, because each source category
is unique and the data available to
determine the performance capabilities
of technology can vary from one source
category to another, the basic
methodology must be adapted to fit the
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source category in question. As the
Court pointed out in the HMIWI
litigation, it ‘‘generally defer[s] 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.’ ’’ Sierra Club
v. EPA, 167 F.3d at 662.
In general, all MACT analyses involve
an assessment of the air pollution
control systems or technologies used by
the better performing units in a source
category. The technology assessment
can be based solely on actual emissions
data, on knowledge of the air pollution
control in place in combination with
actual emissions data, or on State
regulatory requirements, which give an
indication of the actual performance of
the regulated units. For each source
category, the assessment of the
technology involves a review of actual
emissions data with an appropriate
accounting for emissions variability.
Where there is more than one method or
technology to control emissions, the
analysis results in a series of potential
regulations (called regulatory options),
one of which is selected as MACT.
The first regulatory option considered
by EPA must be at least as stringent as
the CAA’s minimum stringency
requirements. However, MACT is not
necessarily the least stringent regulatory
option. EPA must examine more
stringent regulatory options to
determine MACT. Unlike the minimum
stringency requirements, EPA must
consider various impacts of the more
stringent regulatory options in
determining MACT. Only if the more
stringent regulatory options are
considered to have unreasonable
impacts does EPA select the first ‘‘floorbased’’ regulatory option as MACT.
As stated earlier, the CAA requires
that MACT for new sources be no less
stringent than the emissions control
achieved in practice by the best
controlled similar unit. After EPA’s
assessment of technology, EPA
determines the best control currently in
use for a given pollutant and establishes
one potential regulatory option at the
emission level achievable by that
control. More stringent potential
regulatory options might reflect controls
used on other sources that could be
applied to the source category in
question.
For existing sources, the CAA requires
that MACT be no less stringent than the
average emissions limitation achieved
by the best performing 12 percent of
units in a source category. EPA must
determine some measure of the average
emissions limitation achieved by the
best performing 12 percent of units to
form the least stringent regulatory
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option. Sometimes, a direct calculation
of the actual emissions values from the
best performing 12 percent of sources
provides the basis for this regulatory
option. More often, EPA determines the
technology used by the average source
in the best performing 12 percent of
sources and establishes the floor based
on the technology assessment for that
average source. More stringent
regulatory options reflect other
technologies capable of achieving better
performance.
2. What was EPA’s methodology in the
1997 HMIWI rulemaking?
On February 27, 1995, EPA published
a notice of proposed rulemaking
regarding emissions standards for
HMIWI units (60 FR 10654). The
proposal was the result of several years
of reviewing available information.
During the public comment period for
the proposal, EPA received over 700
letters, some of which contained new
information or indicated that the
commenters were in the process of
gathering more information for EPA to
consider. The new information led EPA
to consider the need for numerous
changes to the proposed rule, and on
June 20, 1996, the Agency published a
re-proposal (61 FR 31736). Following an
additional public comment period, EPA
published the final rule on September
15, 1997 (62 FR 48348).
During the data-gathering phase of
developing the 1995 proposal, EPA
found it difficult to obtain an accurate
count of the thousands of HMIWI units
nationwide, or to find HMIWI units
with add-on air pollution control
systems in place. A few HMIWI units
with combustion control were tested to
assess performance of combustion
control in reducing emissions. One unit
with a wet scrubber, and a few units
with dry scrubbing systems were tested
to determine performance capabilities of
add-on controls. (See 61 FR 31738.)
Altogether, data were available from
only 7 out of the estimated thenoperating 3,700 existing HMIWI units
(60 FR 10674). Because EPA was under
a court-ordered deadline to propose and
adopt standards for HMIWI that did not
provide sufficient time to collect more
actual emissions data (see consent
decree entered in Sierra Club v. EPA,
Nos. CV–92–2093 and CV–93–0284
(E.D.N.Y.)), EPA proceeded to develop
the regulations with the existing data, as
described below. However, EPA
specifically requested comment on
EPA’s MACT determinations and on
EPA’s conclusions about the
performance capabilities of air pollution
control technologies on HMIWI in light
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of the relatively small database (60 FR
10686).
a. EPA’s Methodology for New
HMIWI. In determining the least
stringent regulatory option allowed by
the CAA for new HMIWI, EPA first
examined the data available for various
air pollution control technologies
applied to HMIWI to determine the
performance capabilities of the
technologies (i.e., the achievable
emission limitations) (60 FR 10671–73,
61 FR 31741–43). To determine the
performance capabilities, EPA grouped
all of the test data by control technology
and established the numerical value for
the achievable emission limitations
somewhat higher than the highest test
data point for each particular control
technology. (See Legacy Docket ID No.
A–91–61, items IV–B–46, 47, 48, and
49.) Following the determination of
performance capability, EPA identified
the best control technology for each air
pollutant for each subcategory of
HMIWI, and established the numerical
values for the least stringent regulatory
option at the achievable emission
limitation associated with that
particular control technology. (See 60
FR 10673; Legacy Docket ID No. A–91–
61, item IV–B–38; 61 FR 31745–46.)
Other, more stringent, regulatory
options were developed reflecting the
actual performance of other, more
effective, control technologies (61 FR
31766–68).
As stated in the 1996 re-proposal, the
least stringent regulatory option for new
large HMIWI units (units with
maximum waste burning capacity of
more than 500 lb/hr) was based on good
combustion (i.e., 2-second combustion
level) and a combination of two control
technologies, high-efficiency wet
scrubbers and dry injection/fabric filter
dry scrubbers with carbon (61 FR
31746). New medium units (units with
maximum waste burning capacity of
more than 200 lb/hr but less than or
equal to 500 lb/hr) would need to use
good combustion and a combination of
two control technologies, highefficiency wet scrubbers and dry
injection/fabric filter dry scrubbers
without carbon, to meet the least
stringent regulatory option. Id. New
small units (units with maximum waste
burning capacity of less than or equal to
200 lb/hr) would need to use good
combustion and a moderate-efficiency
wet scrubber to meet the least stringent
regulatory option. Id.
In EPA’s final standards promulgated
in 1997, EPA selected an overall more
stringent regulatory option for new
HMIWI (62 FR 48365). The final
standards were based on emission limits
achievable with good combustion and a
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moderate-efficiency wet scrubber for
new small HMIWI, and good
combustion and a combined dry/wet
control system with carbon for new
medium and large HMIWI. Id. These
standards reflected the MACT floor
emissions levels for new small and large
HMIWI, but were more stringent than
the MACT floor for new medium
HMIWI. Id. EPA estimated that the
standards would reduce emissions from
these units of HCl by up to 98 percent,
PM and Pb by up to 92 percent, Cd by
up to 91 percent, CDD/CDF by up to 87
percent, Hg by up to 74 percent, and
CO, SO2, and NOX by up to 52 percent
(62 FR 48366).
b. EPA’s Methodology for Existing
HMIWI. For existing units, EPA did not
have sufficient emissions data to fully
characterize the actual emissions
performance of the best performing 12
percent of existing HMIWI, and, based
exclusively on such data, EPA did not
have a clear indication of the technology
used by the best 12 percent of units. As
a result, EPA used emission limits
included in State regulations and Stateissued permits (hereinafter referred to as
regulatory limits) as surrogate
information to determine emissions
limitations achieved by the best
performing 12 percent of units in each
subcategory (60 FR 10674). EPA
believed this information could be
expected to reliably reflect levels of
performance achieved on a continuous
basis by better-controlled units that
must meet these limits or risk violating
enforceable requirements. EPA assumed
that all HMIWI were achieving their
regulatory limits (60 FR 10674). Where
there were regulatory limits for more
than 12 percent of units in a
subcategory, the regulatory limits were
ranked from the most stringent to least
stringent, and the average of the
regulatory limits for the top 12 percent
of units in the subcategory was
calculated. Id.; 61 FR 31744–45. Where
the number of units subject to specific
emissions limitations did not comprise
12 percent of the population in a
subcategory, EPA assumed those units
with regulatory limits were the best
performing units, and the remaining
units in the top 12 percent were
assigned an emission value associated
with ‘‘combustion control.’’ (See 60 FR
10674; 61 FR 31745; Legacy Docket ID
No. A–91–61, item IV–B–24 at 2.) In
previous Federal Register notices
regarding HMIWI (60 FR 10654, 61 FR
31736, and 62 FR 48348), this level of
control was referred to as
‘‘uncontrolled,’’ which is misleading
because sources with combustion
control emit lesser amounts of CDD/
CDF, CO, and PM. In the latter situation
described above, the average of the
regulatory limits plus enough
combustion-controlled emission values
to account for 12 percent of units in the
subcategory was calculated. (See Legacy
Docket ID No. A–91–61, item IV–B–24
at 2–4.)
After calculating the averages of
regulatory limits and combustioncontrolled emission values, EPA
examined the resulting calculated
values to determine what level of air
pollution control would be needed to
meet the calculated average values. (See
60 FR 10675–78; 61 FR 31755–56.) For
many pollutants, the calculated averages
presented no clear indication of the type
of air pollution control used by the best
performing units. However, the
calculated values for three key
pollutants, PM, CO, and HCl, did
provide a good indication of the type of
air pollution control used on the best
performing 12 percent of units. The
level of air pollution control associated
with the calculated average values for
PM, CO, and HCl formed the technical
basis of the least stringent regulatory
option considered by EPA (61 FR 31756,
Table 13). The emission limitations
assigned to each pollutant reflected the
actual performance of the technology on
which they were based. Finally, EPA
developed a series of regulatory options
based on progressively more stringent
technologies and assigned emission
limitations to each regulatory option
based on the actual performance
capabilities of the technologies (61 FR
31757, Table 14).
As stated in the 1996 re-proposal,
large existing units would need to use
good combustion and a high-efficiency
wet scrubber to meet the least stringent
regulatory option, while medium
existing units would need to use good
combustion and a moderate-efficiency
wet scrubber, although dry scrubbers
could also be used with good
combustion at large and medium
existing units (61 FR 31745). EPA
further stated that its inclination was to
establish emission limitations for large
and medium existing units based on
regulatory options representing the
MACT floors (61 FR 31778). Small
existing units would need only to use
good combustion practices to meet the
regulatory option representing the
MACT floor (61 FR 31745). With respect
to small existing units, EPA stated that
it had no inclination with regard to
which regulatory option should be used
to establish emission limitations and
requested comment on requiring use of
good combustion and a low-efficiency
wet scrubber (61 FR 31778–79).
In EPA’s final standards promulgated
in 1997, EPA selected an overall more
stringent regulatory option for existing
HMIWI (62 FR 48371). The final
standards were based on emission limits
achievable with good combustion and a
low-efficiency wet scrubber for most
existing small HMIWI, good combustion
and a moderate-efficiency wet scrubber
for existing medium HMIWI, and good
combustion and a high-efficiency wet
scrubber for existing large HMIWI (62
FR 48371). The final standards allow
small HMIWI that meet certain rural
criteria to meet emissions limits
achievable with good combustion alone.
Id. These standards reflected the MACT
floor emissions levels for existing small
HMIWI meeting rural criteria, medium
HMIWI, and large HMIWI, but were
more stringent than the MACT floor for
most existing small HMIWI (i.e., nonrural) (62 FR 48371–72). The final
standards for existing medium and large
HMIWI were structured so that either a
dry scrubber or a wet scrubber could be
used to achieve the emission limits.
EPA estimated that the final emission
guidelines would reduce emissions of
CDD/CDF by up to 97 percent, Hg by up
to 95 percent, PM by up to 92 percent,
Pb by up to 87 percent, Cd by up to 84
percent, CO by up to 82 percent, HCl by
up to 98 percent, and SO2 and NOX by
up to 30 percent (62 FR 48372). Table
1 of this preamble summarizes the
emission limits for the NSPS and
emission guidelines promulgated in
1997.
TABLE 1.—SUMMARY OF PROMULGATED EMISSION LIMITS
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Pollutant (units)
Unit Size 1
Limit for existing HMIWI 2
HCl (parts per million by volume (ppmv)) ...........
L, M, S ........
SR ...............
L, M, S ........
SR ...............
L, M .............
100 or 93% reduction ..........................................
3,100 ...................................................................
40 ........................................................................
40 ........................................................................
1.2 or 70% reduction ...........................................
CO (ppmv) ...........................................................
Pb (milligrams per dry standard cubic meter
(mg/dscm)).
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Limit for new HMIWI 2
06FEP2
15 or 99% reduction.
N/A.3
40
N/A.
0.07 or 98% reduction.3
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TABLE 1.—SUMMARY OF PROMULGATED EMISSION LIMITS—Continued
Unit Size 1
Limit for existing HMIWI 2
S ..................
SR ...............
L, M .............
S ..................
SR ...............
L, M, S ........
SR ...............
L ..................
M .................
S ..................
SR ...............
L, M .............
1.2 or 70% reduction ...........................................
10 ........................................................................
0.16 or 65% reduction .........................................
0.16 or 65% reduction .........................................
4 ..........................................................................
0.55 or 85% reduction .........................................
7.5 .......................................................................
0.015 ...................................................................
0.03 .....................................................................
0.05. ....................................................................
0.086 ...................................................................
125 ......................................................................
1.2 or 70% reduction.
N/A.
0.04 or 90% reduction.
0.16 or 65% reduction.
N/A.
0.55 or 85% reduction.
N/A.
0.015
0.015
0.03.
N/A.
25
S ..................
SR ...............
L, M .............
S ..................
SR ...............
L, M, S ........
SR ...............
L, M, S ........
SR ...............
125 ......................................................................
800 ......................................................................
2.3 .......................................................................
2.3 .......................................................................
15 ........................................................................
250 ......................................................................
250 ......................................................................
55 ........................................................................
55 ........................................................................
125
N/A.
0.6
2.3
N/A.
250
N/A.
55
N/A.
Pollutant (units)
Cd (mg/dscm) ......................................................
Hg (mg/dscm) ......................................................
PM (grains per dry standard cubic foot (gr/dscf))
CDD/CDF, total (nanograms per dry standard
cubic meter (ng/dscm)).
CDD/CDF, TEQ (ng/dscm) ..................................
NOX (ppmv) .........................................................
SO2 (ppmv) ..........................................................
Limit for new HMIWI 2
1L
= Large; M = Medium; S = Small; SR = Small Rural
emission limits are measured at 7 percent oxygen.
3 Not applicable.
2 All
c. Compliance by HMIWI. At the time
of promulgation (September 1997), EPA
estimated that there were approximately
2,400 HMIWI operating in the United
States. Those units combusted
approximately 830 thousand tons of
hospital/medical/infectious waste
annually. Of those existing HMIWI,
about 48 percent were small units, 29
percent were medium units, and 20
percent were large units. About 3
percent of the HMIWI were commercial
units. EPA projected that no new small
or medium HMIWI would be
constructed, and that up to 60 new large
units and 10 new commercial units
would be constructed.
After shutdown of approximately 97
percent of the 2,400 HMIWI that were
operating in 1997, there are currently 72
existing HMIWI at 67 facilities.
Additionally, only 4 new HMIWI at 3
facilities began operation following the
1997 rulemaking. These 76 existing and
new units are estimated to combust
approximately 165 thousand tons of
waste annually. Of the 72 existing
HMIWI subject to the emission
guidelines, 44 are large units, 20 are
medium units, and 8 are small units (6
of which meet the rural criteria).
Twenty-one percent of the existing
HMIWI are commercially owned. Of the
four new HMIWI, three are large units,
and one is a medium unit. Two of the
new units are county-owned but accept
waste from other sources, similar to
commercial units. The actual emissions
reductions achieved as a result of
implementation of the standards
exceeded the 1997 projections for all
nine of the regulated pollutants. A
comparison of the estimated pollutant
reductions versus the actual reductions
is presented in Table 2 of this preamble.
TABLE 2.—COMPARISON OF ESTIMATED POLLUTANT REDUCTIONS VERSUS ACTUAL POLLUTANT REDUCTIONS
Pollutant
Estimated emissions reduction,
percent
HCl ..........................................................................................
CO ..........................................................................................
Pb ...........................................................................................
Cd ...........................................................................................
Hg ...........................................................................................
PM ..........................................................................................
CDD/CDF, total .......................................................................
CDD/CDF, TEQ ......................................................................
NOX ........................................................................................
SO2 .........................................................................................
98 ............................................................................................
75 to 82 ..................................................................................
80 to 87 ..................................................................................
75 to 84 ..................................................................................
93 to 95 ..................................................................................
88 to 92 ..................................................................................
96 to 97 ..................................................................................
95 to 97 ..................................................................................
0 to 30 ....................................................................................
0 to 30 ....................................................................................
1 Reflects
99.2
98.1
98.7
99.0
99.0
98.1
99.5
99.6
70.6
92.6
the effect of unit shutdowns as well as the effect of compliance with the promulgated standards.
3. What was the Sierra Club’s challenge?
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Actual emissions
reduction, percent 1
On November 14, 1997, the Sierra
Club and the Natural Resources Defense
Council (Sierra Club) filed suit in the
U.S. Court of Appeals for the District of
Columbia Circuit (the Court). The Sierra
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Club claimed that EPA had violated
CAA section 129 by setting emission
standards for HMIWI under CAA
sections 129 and 111 that are less
stringent than the statutory minimum
stringency required by section 129(a)(2);
that EPA had violated section 129 by
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not including mandatory pollution
prevention or waste minimization
requirements in the HMIWI standards;
and that EPA had not adequately
considered the non-air quality health
and environmental impacts of the
standards. For new units, the Sierra
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Club argued that to satisfy the statutory
phrase ‘‘best controlled similar unit’’ in
CAA section 129(a)(2), EPA should have
identified the single best performing
unit in each subcategory and based the
MACT floor for that subcategory on that
particular unit’s performance, rather
than consider the performance of other
units using the same technology. The
Sierra Club also argued that EPA
erroneously based the new unit floors
on the emissions of the worst
performing unit using a particular
technology. Regarding existing units,
the Sierra Club claimed that the plain
meaning of CAA section 129(a)(2)’s
words, ‘‘average emissions limitation
achieved by the best performing 12
percent of units,’’ precludes the use of
regulatory data, and claimed that the
legislative history of section 129(a)(2)
reflects congressional intent to prohibit
EPA from relying on regulatory data.
Moreover, the Sierra Club claimed that,
for HMIWI, using regulatory data was
impossible because such data existed for
fewer than 12 percent of units, and
because doing so would impermissibly
import an achievability requirement
into the unit floor determination.
Finally, the Sierra Club argued that EPA
failed to require HMIWI units to
undertake programs to reduce the Hg
and chlorinated plastic in their waste
streams, in violation of CAA section
129(a)(3), and that EPA failed to
consider the fact that CDD/CDF and Hg
from HMIWI can contaminate water,
sediment, and soil, and can
bioaccumulate in food, in violation of
the CAA’s requirement that EPA
consider non-air quality impacts of
setting HMIWI emissions standards.
4. What was the Court’s ruling?
On March 2, 1999, the Court issued its
opinion in Sierra Club v. EPA, 167 F.3d
658 (D.C. Cir. 1999). While the Court
rejected the Sierra Club’s claims
regarding pollution prevention and nonair quality impacts, and rejected the
Sierra Club’s statutory arguments under
CAA section 129, the Court remanded
the rule to EPA for further explanation
regarding how EPA derived the MACT
floors for new and existing HMIWI
units. Furthermore, the Court did not
vacate the regulations, stating that ‘‘[i]t
is possible that EPA may be able to
explain [EPA’s basis for the standards]’’
in response to the concerns raised by
the Court. Id., at 664. The regulations
remain in effect during the remand.
a. The Court’s Ruling on New Units.
In response to the Sierra Club’s claims
regarding EPA’s treatment of new units,
the Court opined that ‘‘EPA would be
justified in setting the floors at a level
that is a reasonable estimate of the
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performance of the ‘best controlled
similar unit’ under the worst reasonably
foreseeable circumstances [* * *]. It is
reasonable to suppose that if an
emissions standard is as stringent as ‘the
emissions control that is achieved in
practice’ by a particular unit, then that
particular unit will not violate the
standard. This only results if ‘achieved
in practice’ is interpreted to mean
‘achieved under the worst foreseeable
circumstances.’ In National Lime Ass’n
v. EPA, 627 F.2d 416, 431 n. 46 (D.C.
Cir. 1980), we said that where a statute
requires that a standard be ‘achievable,’
it must be achievable ‘under most
adverse circumstances which can
reasonably be expected to recur.’ The
same principle should apply when a
standard is to be derived from the
operating characteristics of a particular
unit.’’ Sierra Club v. EPA, 167 F.3d at
665. Thus, the Court refused to embrace
the Sierra Club’s interpretation of CAA
section 129(a)(2) as requiring EPA to
base the MACT floor on only the lowest
emissions data points observed (i.e., the
level achieved by the best performing
unit for each pollutant).
Relating to the Sierra Club’s claim
that EPA erred in considering the
emissions of units other than the best
controlled unit, the Court refused to rule
that EPA’s approach was unlawful, and
posited that ‘‘[p]erhaps considering all
units with the same technology is
justifiable because the best way to
predict the worst reasonably foreseeable
performance of the best unit with the
available data is to look at other units’
performance. Or perhaps EPA
reasonably considered all units with the
same technology equally ‘wellcontrolled,’ so that each unit with the
best technology is a ‘best-controlled
unit’ even if such units vary widely in
performance.’’ Sierra Club v. EPA, 167
F.3d at 665.
However, the Court concluded that
the possible rationale for this treatment
of new units was not presented in the
rulemaking record with enough clarity
for the Court to determine that EPA’s
‘‘path may reasonably be discerned.’’ Id.
Moreover, the Court ruled that EPA had
‘‘not explained why the phrase best
controlled similar unit encompasses all
units using the same technology as the
unit with the best observed
performance, rather than just that unit
itself[. * * * W]e do not know what
interpretation the agency chose, and
thus cannot evaluate its choice.’’ Sierra
Club v. EPA, 167 F.3d at 665. The Court
further directed EPA to provide
additional explanation regarding how
the Agency had calculated the upper
bound of the best-controlled unit’s
performance through rounding. Id.
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b. The Court’s Ruling on Existing
Units. With respect to existing units, the
Court first rejected the Sierra Club’s
‘‘claim that EPA’s decision to base the
floors on regulatory data fails the first
step of the Chevron test. None of the
Sierra Club’s arguments establish that
Congress has ‘directly addressed’ and
rejected the use of regulatory data.’’ Id.,
at 661. After noting that the Sierra
Club’s statutory objections to EPA’s
methodology appeared to be premised
on ‘‘the counterintuitive proposition
that an ‘achieved’ level may not be
‘achievable,’ or, as Sierra Club puts it,
may be better than ‘EPA’s notions about
what is achievable,’ ’’ id. at 662, the
Court rejected the Sierra Club’s statutory
objections to using regulatory data and
uncontrolled (i.e., combustioncontrolled) emissions values. In other
words, the Court implicitly embraced
EPA’s view, under the principle of
National Lime, that the MACT floor is
premised on the fundamental concept
that it be ‘‘achievable,’’ and should not
be set at a level that happens to be
reflected by the lowest observed data
point without consideration of
variability in operating conditions.
Then, after analyzing and rejecting the
Sierra Club’s arguments that the plain
language of the CAA and its legislative
history forbid EPA’s methodology, the
Court further ruled that it found
‘‘nothing inherently impermissible
about construing the statute to permit
the use of regulatory data—if they allow
EPA to make a reasonable estimate of
the performance of the top 12 percent of
units. Indeed, the Sierra Club conceded
at oral argument that ‘a reasonable
sample’ may be used ‘to find out what
the best 12 percent are doing.’ Oral Arg.
Tr. at 11. To be sure, the Sierra Club did
not concede that permit data may be
used. But neither has it provided any
basis for believing that state and local
limitations are such weak indicators of
performance that using them is
necessarily an impossible stretch of the
statutory terms. [* * *] We therefore
reject the Sierra Club’s argument that
the CAA forbids the use of permit and
regulatory data, and hold that the use of
such information is permissible as long
as it allows a reasonable inference as to
the performance of the top 12 percent of
units. Similarly, as long as there is a
reasonable basis for believing that some
of the best performing 12 percent of
units are uncontrolled [i.e., combustion
controlled], EPA may include data
points giving a reasonable
representation of the performance of
those units in its averaging.’’ Sierra Club
v. EPA, 167 F.3d at 662, 663. Thus, the
Court rejected all of the Sierra Club’s
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arguments that the CAA prohibits EPA
from basing MACT floor determinations
on permit or regulatory data, or on
uncontrolled (i.e., combustioncontrolled) emissions values.
However, in addressing the manner in
which EPA had specifically relied upon
such data in the HMIWI rulemaking, the
Court concluded that ‘‘[a]lthough EPA
said that it believed the combination of
regulatory and uncontrolled [i.e.,
combustion-controlled] data gave an
accurate picture of the relevant
[HMIWI]s‘ performance, it never
adequately said why it believes this.
[* * *] First, EPA has said nothing
about the possibility that [HMIWI]s
might be substantially overachieving the
permit limits. If this were the case, the
permit limits would be of little value in
estimating the top 12 percent of
[HMIWI]s’ performance. [* * *]
Second, EPA never gave any reason for
its apparent belief that [HMIWI]s that
were not subject to permit requirements
did not deploy emission controls of any
sort. Unless there is some finding to this
effect, it is difficult to see the rationality
in using ‘uncontrolled’ [i.e.,
combustion-controlled] data for the
units that were not subject to regulatory
requirements.’’ Id., at 663–664. The
Court further questioned the rationality
of EPA using the highest of its test run
data in cases where the regulatory data
did not alone comprise the necessary 12
percent. Id., at 664.
c. Subsequent Court Rulings Relevant
to the Remand. Following the Court’s
remand of the HMIWI MACT floors in
Sierra Club v. EPA, the Court issued a
series of rulings in other cases
addressing MACT rules that bear on
EPA’s proposed response regarding
HMIWI. The first of these was Nat’l
Lime Ass’n v. EPA, 233 F.3d 625 (D.C.
Cir. 2000) (‘‘NLA II’’), which involved
challenges to EPA’s MACT standards
under CAA section 112(d) for portland
cement manufacturing facilities. In that
case, the Sierra Club argued that EPA
should have based its estimate of the top
performing 12 percent of sources on
actual emissions data, in order to
‘‘reasonably estimate’’ such
performance. But the Court determined
that EPA’s approach of selecting ‘‘the
median [performing] plant out of the
best twelve percent of the plants for
which it had information and set[ting]
the * * * floor at the level of the worst
performing plant in its databases using
th[e same] technology [as the median
plant]’’ had not been shown by the
Sierra Club to reflect a not reasonable
estimate. NLA II, 233 F.3d at 633.
In addition, the Court partially
clarified its position regarding EPA’s
approach of accounting for emissions
performance variability by setting floors
at a level that reasonably estimates ‘‘the
performance of the ‘best controlled
similar unit’ under the worst reasonably
foreseeable circumstances.’’ Sierra Club,
167 F.3d at 665. In NLA II, the Court
stressed that EPA should not simply set
floors at levels reflecting the worst
foreseeable circumstances faced by any
worst performing unit in a given source
category, and that while considering all
units with the same technology may be
justifiable because the best way to
predict the worst reasonably foreseeable
performance of the best unit with
available data is to look at other units’
performance, such an approach would
satisfy the CAA ‘‘if pollution control
technology were the only factor
determining emission levels of that
HAP.’’ NLA II, 233 F.3d at 633.
In Cement Kiln Recycling Coalition v.
EPA, 255 F.3d 855 (D.C. Cir. 2001)
(‘‘CKRC’’), the Court again refined its
view on when it is appropriate for EPA
to base MACT floors on the performance
of air pollution control technology. In
that case, the Sierra Club challenged
EPA’s MACT standards for hazardous
waste combustors (HWC), and argued
that factors other than MACT
technology influenced the emissions
performance of the best performing
sources.
The Court agreed that since EPA’s
record evidence in the HWC rulemaking
showed that factors besides MACT
controls significantly influenced HWC
emission rates, ’’emissions of the worstperforming MACT source may not
reflect what the best-performers actually
achieve.’’ CKRC, 255 F.3d at 864. EPA
had claimed that MACT floors must be
achievable by all sources using MACT
technology, and that to account for the
best-performing sources’’ operational
variability we had to base floors on the
worst performers’’ emissions. But the
Court stressed that ‘‘whether variability
in the MACT control accurately
estimates variability associated with the
5517
best performing sources depends on
whether factors other than MACT
control contribute to emissions[,]’’ id.,
and that ‘‘the relevant question here is
not whether control technologies
experience variability at all, but whether
the variability experienced by the bestperforming sources can be estimated by
relying on emissions data from the
worst-performing sources using the
MACT control.’’ Id., at 865.
In the specific case of the HWC rule,
the Court concluded that, since record
evidence showed that non-MACT
factors influenced emissions
performance, EPA could not base floors
simply on the worst-performing MACT
sources’ emissions. Id., at 866. However,
the Court also reiterated that ‘‘[i]f in the
case of a particular source category or
HAP, the Agency can demonstrate with
substantial evidence—not mere
assertions—that MACT technology
significantly controls emissions, or that
factors other than the control have a
negligible effect, the MACT approach
could be a reasonable means of
satisfying the statute’s requirements.’’
Id.
5. Are revisions to the emission limits
being proposed in response to the
remand?
Yes, the proposed response to the
remand would revise some of the
emission limits in both the NSPS and
emission guidelines. Relative to the
NSPS, the emission limits for CO, Pb,
Cd, Hg, PM, and CDD/CDF would be
revised. Relative to the emission
guidelines, the emission limits for HCl,
Pb, Cd, and CDD/CDF would be revised.
EPA believes that the revised emission
limits being proposed as a result of its
response to the remand can be achieved
with the same emission control
technology currently used by HMIWI.
The proposed emission limits for the
NSPS and emission guidelines
necessary to respond to the Court’s
remand are summarized in Table 3 of
this preamble. Note that in several
cases, further amendments to the
emission limits are being proposed as a
result of our 5-year review under CAA
section 129(a)(5). Those proposed
amendments are discussed in the
following section of this preamble.
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TABLE 3.—SUMMARY OF PROPOSED EMISSION LIMITS IN RESPONSE TO THE REMAND
Pollutant
(units)
Unit size 1
Proposed remand limit for
existing HMIWI 2
HCl (ppmv) ...................................................................................
L, M, S ........
SR ...............
L, M, S ........
SR ...............
78 or 93% reduction 3 .................
3,100 3 .........................................
40 3 ..............................................
40 3 ..............................................
CO (ppmv) ....................................................................................
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Proposed remand limit for
new HMIWI 2
153 or 99% reduction 3.
N/A 4.
32
N/A 4.
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TABLE 3.—SUMMARY OF PROPOSED EMISSION LIMITS IN RESPONSE TO THE REMAND—Continued
Pollutant
(units)
Unit size 1
Proposed remand limit for
existing HMIWI 2
Pb (mg/dscm) ...............................................................................
L, M .............
S ..................
SR ...............
L, M .............
S ..................
SR ...............
L, M .............
S ..................
SR ...............
L ..................
M .................
S ..................
SR ...............
L, M .............
S ..................
SR ...............
L, M .............
S ..................
SR ...............
L, M, S ........
SR ...............
L, M, S ........
SR ...............
0.78 or 71% reduction ................
0.78 or 71% reduction ................
8.9 ...............................................
0.11 or 66% reduction 3 ..............
0.11 or 66% reduction 3 ..............
4 3 ................................................
0.55 3 or 87% reduction ..............
0.55 3 or 87% reduction ..............
6.6 ...............................................
0.015 3 .........................................
0.030 3 .........................................
0.050 3 .........................................
0.086 3 .........................................
115 ..............................................
115 ..............................................
800 3 ............................................
2.2 ...............................................
2.2 ...............................................
15 3 ..............................................
250 3 ............................................
250 3 ............................................
55 3 ..............................................
55 3 ..............................................
Cd (mg/dscm) ...............................................................................
Hg (mg/dscm) ...............................................................................
PM (gr/dscf) .................................................................................
CDD/CDF, total (ng/dscm) ...........................................................
CDD/CDF, TEQ (ng/dscm) ..........................................................
NOX (ppmv) .................................................................................
SO2 (ppmv) ..................................................................................
Proposed remand limit for
new HMIWI 2
0.060 or 98% reduction 3.
0.78 or 71% reduction.
N/A 4.
0.030 or 93% reduction.
0.11 or 66% reduction 3.
N/A 4.
0.45 or 87% reduction.
0.47 or 87% reduction.
N/A 4.
0.009
0.009
0.018
N/A 4.
20
111
N/A 4.
0.53
2.1
N/A 4.
225
N/A 4
46
N/A 4.
1L
= Large; M = Medium; S = Small; SR = Small Rural
emission limits are measured at 7 percent oxygen.
change proposed.
4 Not applicable.
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3 No
B. Proposed Amendments (CAA Section
129(a)(5) 5-Year Review)
Section 129(a)(5) of the CAA requires
EPA to conduct a review of the NSPS
and emissions guidelines at 5 year
intervals and, if appropriate, revise the
NSPS and emission guidelines pursuant
to the requirements under sections 111
and 129 of the CAA. In conducting such
reviews, EPA attempts to assess the
performance of and variability
associated with the installed emissions
control equipment (and developments
in practices, processes and control
technologies) and to revise as necessary
and appropriate the NSPS and emission
guidelines. In these reviews, EPA takes
into account the currently installed
equipment and its performance and
operational variability. As appropriate,
we also consider new technologies that
have been demonstrated to reliably
control emissions from the source
category. In setting numerical emission
limits from single, ‘‘snap shot’’ stack test
data, EPA must exercise technical
judgment to ensure the achievability of
such limits over the course of
anticipated operating conditions. EPA
has completed the 5-year review, and
the proposed amendments discussed
below reflect the changes that EPA has
determined are appropriate in addition
to the amendments that are necessary to
respond to the Court’s remand. These
proposed amendments do not reflect
adoption of new control technologies or
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processes, but do reflect more efficient
practices in operation of the control
technologies that sources used in order
to meet the 1997 MACT standards.
Following year 2002 compliance with
the emission guidelines, EPA gathered
information on the performance levels
actually being achieved by HMIWI that
were operating under the guidelines.
After implementation of the guidelines
in 1997, approximately 94 percent of
HMIWI shut down, and 3 percent
demonstrated eligibility for exemptions
from the HMIWI regulation. Those
HMIWI that remained in operation
either continued operation with their
existing configuration or were retrofitted
with add-on air pollution control
devices in order to meet the standards.
The retrofits were completed on time,
and the controls installed to meet the
required emission limitations were
highly effective in reducing emissions of
all of the CAA section 129 pollutants
emitted by HMIWI. For those HMIWI,
relative to a 1995 baseline, the emission
guidelines reduced organic emissions
(CDD/CDF) by about 90 percent, metals
emissions (Pb, Cd, and Hg) by more than
80 percent, and acid gas emissions (HCl
and SO2) by more than 70 percent.
Including shutdowns and exemptions,
nationwide HMIWI emissions of
organics, metals, and acid gases each
decreased by about 99 percent or more
relative to a 1995 baseline. It should be
noted that the original HMIWI emission
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limits were based primarily on permit
information and other regulatory
requirements, and not on actual
performance or stack test data. To this
end, it was highly uncertain at
promulgation what the precise
performance efficiency and day-to-day
operational variability associated with
the promulgated regulatory
requirements would yield. Thus, the
2002 compliance test information
provided the first quantitative
assessment of the performance of the
installed control equipment’s ability to
attain the NSPS and emissions guideline
limits.
The goal of the current technology
review is to assess the performance
efficiency of the installed equipment
and to ensure that the emission limits
reflect the performance of the
technologies required by the MACT
standards. In addition, the review
addresses whether new technologies
and processes and improvements in
practices have been demonstrated at
sources subject to the emissions
limitations. EPA’s intent for future
technology reviews is to include similar
analyses that also assess risk along with
new technologies. For the current
review, while new technologies have
not yet been demonstrated to reliably
control emissions more efficiently at
reasonable cost at HMIWI units than
those used to meet MACT,
improvements in operational practices
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Federal Register / Vol. 72, No. 24 / Tuesday, February 6, 2007 / Proposed Rules
do support some additional revision of
the standards, in order to better reflect
the best operation of the MACT
controls.
These proposed amendments would
revise the NSPS and emission
guidelines, in some cases beyond the
point needed to respond to the Court’s
remand, based on the performance
levels currently being achieved by
HMIWI. The revisions discussed in the
following text apply to both the NSPS
and the emission guidelines, unless
otherwise specified.
1. Are revisions to the emission limits
being proposed?
Yes, the proposed amendments would
revise the emission limits in both the
5519
NSPS and emission guidelines. EPA’s
technology review demonstrates that the
proposed emission limits can be
achieved with the same emission
control technology currently used by
HMIWI. The proposed emission limits
for the NSPS and emission guidelines
are summarized in Tables 4 and 5 of this
preamble.
TABLE 4.—SUMMARY OF PROPOSED 5-YEAR REVIEW EMISSION LIMITS FOR NEW HMIWI
Unit Size 1
Pollutant (units)
HCl (ppmv) .......................................................................................................................................
CO (ppmv) .......................................................................................................................................
Pb (mg/dscm) ..................................................................................................................................
Cd (mg/dscm) ..................................................................................................................................
Hg (mg/dscm) ..................................................................................................................................
PM (gr/dscf) .....................................................................................................................................
CDD/CDF, total (ng/dscm) ...............................................................................................................
CDD/CDF, TEQ (ng/dscm) ..............................................................................................................
NOX (ppmv) .....................................................................................................................................
SO2 (ppmv) ......................................................................................................................................
L,
L,
L,
S
L,
S
L,
S
L,
S
L,
S
L,
S
L,
L,
S
M, S ..............
M, S ..............
M ..................
.......................
M ..................
.......................
M ..................
.......................
M ..................
.......................
M ..................
.......................
M ..................
.......................
M, S ..............
M ..................
.......................
Proposed Limit 2
15 3 or 99% reduction 3.
25
0.060 or 99% reduction.
0.64 or 71% reduction.
0.0050 or 99% reduction.
0.060 or 74% reduction.
0.19 or 96% reduction.
0.33 or 96% reduction.
0.0090.
0.018.
16
111
0.21
2.0
212
21
28
1L
= Large; M = Medium; S = Small
emission limits are measured at 7 percent oxygen.
3 No change proposed.
2 All
TABLE 5.—SUMMARY OF PROPOSED 5-YEAR REVIEW EMISSION LIMITS FOR EXISTING HMIWI
Pollutant (units)
Unit Size 1
HCl (ppm) ........................................................................................................................................
L, M, S ..............
SR .....................
All .....................
L, M, S ..............
SR .....................
L, M, S ..............
SR .....................
L, M, S ..............
SR .....................
L .......................
M ......................
S .......................
SR .....................
L, M, S ..............
SR .....................
L, M, S ..............
SR .....................
All .....................
All .....................
CO (ppm) .........................................................................................................................................
Pb (mg/dscm) ..................................................................................................................................
Cd (mg/dscm) ..................................................................................................................................
Hg (mg/dscm) ..................................................................................................................................
PM (gr/dscf) .....................................................................................................................................
CDD/CDF, total (ng/dscm) ...............................................................................................................
CDD/CDF, TEQ (ng/dscm) ..............................................................................................................
NOX (ppmv) .....................................................................................................................................
SO2 (ppmv) ......................................................................................................................................
1L
Proposed Limit 2
51 or 94% reduction.
398
25
0.64 or 71% reduction.
0.60
0.060 or 74% reduction.
0.050
0.33 or 96% reduction.
0.253
0.015
0.030 3
0.030
0.030
115
800 3
2.0
15 3
212
28
= Large; M = Medium; S = Small; SR = Small Rural
emission limits are measured at 7 percent oxygen.
change proposed.
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3 No
As indicated by Table 5 of this
preamble, the proposed emission limits
for Pb, Cd, and Hg for existing small
rural HMIWI are more stringent than
those being proposed for existing large,
medium, and small HMIWI. We believe
that this better emissions performance
by existing small rural HMIWI is a result
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of the waste stream of a small rural
hospital not including certain materials
that are in the waste stream of a nonrural hospital and that cause relatively
higher Pb, Cd and Hg emissions.
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2. Are other amendments being
proposed?
The proposed amendments would
also make the following changes based
on information received during
implementation of the HMIWI NSPS
and emission guidelines and would
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Federal Register / Vol. 72, No. 24 / Tuesday, February 6, 2007 / Proposed Rules
apply equally to the NSPS and emission
guidelines, unless otherwise specified.
a. Performance Testing and
Monitoring Amendments. The proposed
amendments would allow sources to use
the results of previous emissions tests to
demonstrate compliance with the
revised emission limits as long as the
sources certify that the previous test
results are representative of current
operations. Only those sources whose
previous emissions tests do not
demonstrate compliance with one or
more revised emission limits would be
required to conduct another emissions
test for those pollutants (note that
sources are already required to test for
HCl, CO, and PM on an annual basis).
The proposed amendments would
require, for existing HMIWI, annual
inspections of scrubbers and fabric
filters, and a one-time Method 22 visible
emissions test of the ash handling
operations to be conducted during the
next compliance test. For new HMIWI,
the proposed amendments would
require CO continuous emissions
monitoring systems (CEMS), bag leak
detection systems for fabric-filter
controlled units, annual inspections of
scrubbers and fabric filters, and Method
22 visible emissions testing of the ash
handling operations to be conducted
during each compliance test. For
existing HMIWI, use of CO CEMS would
be an approved alternative, and specific
language with requirements for CO
CEMS is included in the proposed
amendments. For new and existing
HMIWI, use of PM, HCl, multi-metals,
and Hg CEMS, and semi-continuous
dioxin monitoring (continuous sampling
with periodic sample analysis) also are
approved alternatives, and specific
language for these alternatives is
included in the proposed amendments.
b. Other Amendments. The proposed
amendments would revise the definition
of ‘‘Minimum secondary chamber
temperature’’ to read ‘‘Minimum
secondary chamber temperature means
90 percent of the highest 3-hour average
secondary chamber temperature (taken,
at a minimum, once every minute)
measured during the most recent
performance test demonstrating
compliance with the PM, CO, and
dioxin/furan emission limits.’’
The proposed amendments would
require sources to submit, along with
each test report, a description of how
operating parameters are established
during the initial performance test and
subsequent performance tests.
3. Is an implementation schedule being
proposed?
Yes; under the proposed amendments
to the emission guidelines, and
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consistent with CAA section 129,
revised State plans containing the
revised emission limits and other
requirements in the proposed
amendments would be due within 1
year after promulgation of the
amendments. That is, revised State
plans would have to be submitted to
EPA 1 year after the date on which EPA
promulgates revised standards.
The proposed amendments to the
emission guidelines then would allow
HMIWI units up to 3 years from the date
of approval of a State plan, but not later
than 5 years after promulgation of the
revised standards, to demonstrate
compliance with the amended
standards. Consistent with CAA section
129, EPA expects States to require
compliance as expeditiously as
practicable. HMIWI units have already
installed the emission control
equipment necessary to meet the
proposed revised limits, and EPA,
therefore, anticipates that most State
plans will include compliance dates
sooner than 5 years following
promulgation of the amendments. In
most cases, the only changes necessary
are to review the revisions and adjust
the emission monitoring and reporting
accordingly.
In revising the emission limits in a
State plan, a State has two options.
First, it could include both the current
and the new emission limits in its
revised State plan, which allows a
phased approach in applying the new
limits. That is, the State plan would
make it clear that the current emission
limits remain in force and apply until
the date the new emission limits are
effective (as defined in the State plan).
States whose HMIWI units do not find
it necessary to improve their
performance in order to meet the new
emission limits may want to consider a
second approach where the State would
insert the new emission limits in place
of the current emission limits, follow
procedures in 40 CFR part 60, subpart
B, and submit a revised State plan to
EPA for approval. If the revised State
plan contains only the new emission
limits (i.e., the current emission limits
are not retained), then the new emission
limits must become effective
immediately since the current limits
would be removed from the State plan.
4. Has EPA changed the applicability
date of the 1997 NSPS?
No; however, HMIWI may be treated
differently under the amended
standards than they were under the
1997 standards in terms of whether they
are ‘‘existing’’ or ‘‘new’’ sources, and
there will be new dates defining what
are ‘‘new’’ sources and imposing
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compliance deadlines regarding any
amended standards. The applicability
date for the NSPS units, with respect to
the standards as promulgated in 1997,
remains June 20, 1996; however, units
for which construction is commenced
after the date of this proposal, or
modification is commenced on or after
the date 6 months after promulgation of
the amended standards, would be
subject to more stringent NSPS emission
limits than units for which construction
or modification was completed prior to
those dates. Under the proposed
amendments, units that commenced
construction after June 20, 1996, and on
or before February 6, 2007, or that are
modified before the date 6 months after
the date of promulgation of any revised
final standards, would continue to be or
would become subject to the NSPS
emission limits that were promulgated
in 1997 and that remain in the 40 CFR
part 60, subpart Ec NSPS, except where
the revised emission guidelines would
be more stringent. In that case, HMIWI
that are NSPS units under the 1997 rule
would also need to comply with the
revised emission guidelines for existing
sources, by the applicable compliance
date for such existing sources. Similarly,
emission guidelines units under the
1997 rule would need to meet the
revised emission guidelines by the
applicable compliance date for the
revised guidelines. HMIWI that
commence construction after February
6, 2007 or that are modified 6 months
or more after the date of promulgation
of any revised standards would have to
meet the revised NSPS emission limits
being added to the subpart Ec NSPS and
any remaining NSPS limits from the
1997 rule, as applicable, within 6
months after the promulgation date of
the amendments or upon startup,
whichever is later.
IV. Rationale
A. Rationale for the Proposed Response
to the Remand
This action responds to the Court’s
remand by (1) further explaining the
reasoning processes by which EPA
determined the MACT floors and the
MACT standards for new and existing
HMIWI for the portions of those
processes that are being retained under
our remand response, and (2) explaining
revisions to the processes, the MACT
floors, and the MACT standards for new
and existing HMIWI that result from our
response to the remand.
1. New HMIWI
The Court raised three issues with
regard to EPA’s treatment of the MACT
floor for new units and the achievable
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emission limitations. First, the Court
asked EPA to explain why the floor was
based on the highest emissions levels of
the ‘‘worst-performing’’ unit employing
the MACT technology rather than on the
lowest observed emissions levels of the
best performing unit using the MACT
technology. (See Sierra Club v. EPA, 167
F.3d at 665.) Second, the Court
requested further explanation of why
EPA considered multiple units
employing the MACT technology, rather
than identify the single best-performing
unit and basing the floor on that
particular unit’s performance with that
technology. Id. Third, the Court
requested further explanation of EPA’s
procedure for determining the
achievable emission limitation from the
available data, where EPA selected a
numerical value somewhat higher than
the highest observed data point. The
Court stated that EPA’s procedure
‘‘[m]ay be justifiable as a means of
reasonably estimating the upper bound
of the best-controlled unit’s
performance, but in the absence of
agency explanation of both the decision
to increase the levels and the choice of
method for determining the increases,
we are in no position to decide.’’ Id.
As discussed in detail below, for the
first two issues, the Court described
potential rationale for EPA’s method.
However, because the Court concluded
that this rationale was not adequately
presented in the rulemaking record, the
Court asked for further clarification by
EPA. In subsequent cases the Court
further addressed these potential
rationales, and discussed under what
circumstances they would and would
not be persuasive. In fact, the Court’s
potential rationale for EPA’s method
reflects the principles used by EPA in
determining the MACT floor for new
units and the achievable emission
limitations for this source category, and
is the method that has been used by
EPA throughout most of the Agency’s
30-year history in developing achievable
technology-based emission limitations
for source categories in cases where the
application of control technology has
been the only means by which sources
have limited emissions, and the
variability of technology performance is
a critical factor in determining an
emission limitation’s achievability. (See,
e.g., American Iron and Steel Inst. v.
EPA, 115 F.3d 979, 1000 (D.C. Cir.
1997); BP Exploration & Oil, Inc., v.
EPA, 66 F.3d. 784, 794 (6th Cir. 1995);
NRDC v. EPA, 790 F.2d 289, 299 (3d Cir.
1986); National Ass’n of Metal Finishers
v. EPA, 719 F.2d 624, 659 (3d Cir. 1983);
rev’d on other grounds sub nom,
Chemical Mfrs. Ass’n v. NRDC, 470 U.S.
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116 (1985); American Petroleum Inst. v.
EPA, 661 F.2d 340, 347 n. 23 (5th Cir.
1981); Bunker Hill Co. v. EPA, 572 F.2d
1286, 1302 (9th Cir. 1977); Marathon Oil
Co. v. EPA, 564 F.2d 1253, 1266–67 (9th
Cir. 1977); FMC v. Train, 639 F.2d 973,
985–86 (4th Cir. 1976).) As discussed
elsewhere in this preamble, in CKRC the
Court stressed that where record
evidence suggests that factors other than
application of control technology
influence emissions, EPA will not be
able to demonstrate ‘‘that floors based
on the worst-performing MACT sources’
emissions represent ‘a reasonable
estimate of the performance of the [bestperforming] units.’ ’’ CKRC, 255 F.3d at
866, quoting Sierra Club, 167 F.3d at
662. However, the Court reiterated that
where EPA’s record demonstrates that
MACT technology significantly controls
emissions, or that factors other than the
control have a negligible effect, the
approach of accounting for variability
by basing the floor on the highest
emissions resulting from a source using
MACT technology ‘‘could be a
reasonable means of satisfying the
statute’s requirements.’’ CKRC, at 866.
a. Applicability of National Lime to
CAA Section 129. CAA section 129(a)(3)
states that ‘‘[s]tandards under section
111 and this section applicable to solid
waste incineration units shall be based
on methods and technologies for
removal or destruction of pollutants
before, during, or after combustion
[* * *].’’ This language requires that
such a standard be based on the degree
of reduction in air pollutant emissions
that can be achieved through
application of a particular method of
pollution control, and any other factors
that record evidence shows significantly
affect emissions performance. Much like
the language in CAA sections 111 and
129 governing the HMIWI standards,
Congress has used similar language in
other statutes to direct adoption of
technology-based standards. (See, e.g.,
CAA section 169(3) defining ‘‘best
available control technology’’; Clean
Water Act section 301(b)(2)(A), for ‘‘best
available technology economically
achievable’’ or ‘‘BAT’’ standards; Clean
Water Act section 304(b)(1) for ‘‘best
practicable technology’’ or ‘‘BPT’’
standards.)
As the Court has stated,
‘‘[t]echnology-based provisions [in the
CAA] require EPA to promulgate
standards only after finding that the
requisite technology exists or may be
feasibly developed. Absolute standards,
on the other hand, require compliance
with statutorily prescribed standards
and time tables, irrespective of present
technologies.’’ (See NRDC v. Reilly, 983
F.2d 259, 268 (D.C. Cir. 1993) (holding
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5521
that elimination of feasibility
requirements and specification of
particular control systems indicated that
congressional amendment of CAA
section 202(a)(6) resulted in an
‘‘absolute’’ standard).) MACT standards
under CAA sections 111 and 129 are
‘‘technology-based,’’ rather than
‘‘absolute’’ standards. The legislative
history to the 1990 CAA Amendments
clearly shows that Congress intended
the MACT standards to be technologybased. (See I A Legislative History, at
863 (Senator Durenberger referring to
‘‘the MACT technology-based
standards’’ in debates on the bill
reported by the Conference Committee);
id., at 1128 (Senator Dole explaining
that changes made to CAA section 129
in the Conference Committee ‘‘make the
technology test more closely
approximate the role of the NSPS’’); S.
Rep. No. 101–228, at 133–134 (1989)
(referring to CAA section 112 MACT
standards as ‘‘technology-based
standards’’ and noting that technologybased effluent standards under the
Clean Water Act served as a model for
the new MACT standards).)
CAA section 129 does not specify a
type of control technology for HMIWI,
but instead requires EPA to develop
floor levels already achieved in practice
by one or more units, and then issue
standards that EPA determines are
‘‘achievable’’ for units in that source
category. As the Court stated in National
Lime Ass’n v. EPA (627 F.2d 416, 431
n. 46 (D.C. Cir. 1980)) (‘‘NLA I’’), and
restated in Sierra Club, ‘‘where a statute
requires a standard to be achievable, it
must be achievable ‘under most adverse
circumstances which can reasonably be
expected to recur.’ ’’ (See Sierra Club,
167 F.3d at 665.) In other words, ‘‘EPA
would be justified in setting floors at a
level that is a reasonable estimate of the
performance of the ‘best controlled
similar unit’’ under the worst
reasonably foreseeable circumstances[.]’’
Id. This concept of ‘‘worst reasonably
foreseeable circumstances’’ is
fundamental in developing achievable
technology-based emission limitations,
since, once the standard is in force,
sources will be expected to comply with
it at all times by relying on the
technology that formed the basis for
EPA’s determination that the
promulgated emissions limitation is
achievable. As the Court stated in Sierra
Club, ‘[i]t is reasonable to suppose that
if an emissions standard is as stringent
as ‘the emissions control that is
achieved in practice’ by a particular
unit, then that particular unit will not
violate the standard. This only results if
‘achieved in practice’ is interpreted to
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mean ‘achieved under the worst
foreseeable circumstances.’ ’’ Id.
EPA agrees with the Court that, in
order to satisfy the requirements of NLA
I, ‘‘[t]he same principle should apply
when a standard is to be derived from
the operating characteristics of a
particular unit[,]’’ as is the case under
CAA section 129(a)(2). Id. CAA section
129(a)(2) requires that the new unit
MACT floor be ‘‘not less stringent than
the emissions control that is achieved in
practice by the best controlled similar
unit, as determined by the
Administrator.’’ It would have been
unreasonable for EPA to base the MACT
floors solely on the lowest levels of
emissions observed without an
assessment of whether those observed
levels could be met on a continuous
basis, and the CAA and its legislative
history provide no support in deviating
from the general practice EPA has
followed in the wake of NLA I. In a
report on H.R. 3030, the House
Committee on Energy and Commerce
explained that ‘‘MACT is not intended
to require unsafe control measures, or to
drive sources to the brink of shutdown.’’
(See H.R. Rep. No. 101–490, pt. 1, at 328
(1990).) This view is consistent with
NLA I, which involved challenges to
standards EPA promulgated under
section 111 of the CAA and is
particularly applicable to the HMIWI
rulemaking under CAA section 129,
since this rule has its basis in authority
in both section 129 and section 111.
(See CAA section 129(a)(1)(A) and (C).)
Moreover, interpreting CAA section
129 as subject to the principles of NLA
I appropriately notes the critical
distinction between a level of emissions
that has been continuously achieved
through performance using control
technology, and one that has been
observed at a single point in time. A
level that has been continuously
achieved is capable of being met under
most conditions which can reasonably
be expected to recur because variability
in operating conditions is taken into
account. Such a level best effectuates
Congress’ intent because it ensures that
the MACT floor will result in reduced
emissions without forcing sources to
shut down. A lowest observed emission
level, however, is not representative of
a unit’s performance under most
conditions which can reasonably be
expected, and may be impossible to
achieve on a regular, let alone
continuous, basis. While an observed
lowest emissions level may be
appropriate for use in determining
whether a source is in compliance with
an emission standard that must be
continuously met, it is not an
appropriate level upon which to base
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the minimum stringency level of such a
standard.
In addition, Congress’ use of the
phrases ‘‘as determined by the
Administrator’’ and ‘‘achieved in
practice’’ in CAA section 129(a)(2) in
the directive to establish MACT floors
shows that Congress expected EPA to
consider variability in operating
conditions and other relevant factors in
the Agency’s determinations. The term
‘‘practice’’ is defined as ‘‘[r]epeated or
customary action; habitual performance;
a succession of acts of a similar kind;
custom; usage.’’ (See Black’s Law
Dictionary 1172 (6th ed. 1990).) Thus,
achieved in ‘‘practice’’ means achieved
on a repeated, customary, or habitual
basis. Under the statutory mandate that
the level ‘‘achieved in practice’’ be
‘‘determined by the Administrator,’’
EPA must exercise its judgment, based
on an evaluation of the relevant factors
and available data, to determine the
level of emissions control that can be
customarily achieved using the reliedupon technology under variable
conditions. Merely locating the lowest
emissions data point and setting the
MACT standard at that level would not
constitute a considered ‘‘determination
by the Administrator’’ as to what has
been ‘‘achieved in practice.’’ (See, e.g.,
Senate Debate on Conference Report,
10–26–90, reprinted in I A Legislative
History of CAA Amendments of 1990,
103d Cong., 1st Sess. at 1128–1129
(Comm. Print 1993) (exchange between
Senators Dole and Durenberger
confirming that the phrase ‘‘achieved in
practice’’ accounts for the distinction
between research-type pollution control
systems and systems that are
‘‘economically viable for widespread
use,’’ and stressing that MACT floors
should rely upon technologies that can
‘‘stand the rigors of day to day
operations’’).)
Ultimately, NLA I is controlling
because the case addressed how
standards must be set in the face of
variable operating conditions, and
involved one of the same provisions of
the CAA, section 111, under which the
HMIWI rule was promulgated. NLA I
held that EPA is required to use data
that is representative of emissions that
could be achieved in the industry as a
whole. (See 627 F.2d at 433.) In
developing the standards at issue in that
case, EPA relied upon tests of the
emissions from particular units to
determine the level of emissions control
that was achievable across the entire
industry. The Court directed EPA to
identify ‘‘variable conditions that may
contribute substantially to the amount
of emissions, or otherwise affect the
efficiency of the emissions control
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systems.’’ Id. The Court then stated that
‘‘where test results are relied upon, it
should involve the selection or use of
test results in a manner which provides
some assurance of the achievability of
the standard for the industry as a whole,
given the range of variable factors found
relevant to the standards’ achievability.’’
Id. This does not mean that EPA must
test every plant, but it does mean that
‘‘due consideration must be given to the
possible impact on emissions of
recognized variations in operations and
some rationale offered for the
achievability of the promulgated
standards given the tests conducted and
the relevant variables identified.’’ Id., at
434. Thus, applying NLA I to the HMIWI
rule adopted under CAA sections 111
and 129, it is really a misnomer to
characterize EPA as basing the MACT
floor on the emissions of the ‘‘worst
performing’’ unit using the technology
in question, since that unit’s level of
emissions necessarily more closely
represents the level ‘‘achieved in
practice’’ by the given technology than
would the lowest emissions level
observed at a source using that ‘‘best’’
technology.
b. Variability Between Facilities or
Units. In remanding the NSPS at issue
in NLA I, the Court noted that its
decisions under CAA section 111
‘‘evince a concern that variables be
accounted for, that the
representativeness of test conditions be
[sic] ascertained, that the validity of
tests be assured and the statistical
significance of results be determined.’’
(See NLA I, 627 F.2d at 452–53.) (See,
also, Portland Cement Ass’n v.
Ruckelshaus, 486 F.2d 375, 396 (D.C.
Cir. 1973), cert. denied, 417 U.S. 921
(1974).) When floors and standards are
developed based on emissions data,
EPA accounts for several types of
variability to avoid adopting
unachievable standards. The first type
of variability is that concerning
operational distinctions between
facilities or units. As the Sierra Club
Court stated in reviewing the HMIWI
rule, ‘‘[p]erhaps considering all units
with the same technology is justifiable
because the best way to predict the
worst reasonably foreseeable
performance of the best unit with the
available data is to look at other units’
performance. Or perhaps EPA
reasonably considered all units with the
same technology equally ‘wellcontrolled,’ so that each unit with the
best technology is a ‘best-controlled
unit’ even if such units vary widely in
performance.’’ (See 167 F.3d at 665.)
These are two ways of saying essentially
the same thing, and these concepts have
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been used by EPA throughout most of
the Agency’s history in determining
achievable technology-based emission
limitations, in cases where application
of control technology significantly
controls emissions and no record
evidence indicates that factors other
than the control have more than a
negligible effect. Examining multiple
units using the same technology gives
the best picture of the performance
capability of that particular technology,
since it provides EPA with a more
complete set of data by which to
evaluate what levels of emissions
control a technology can achieve as it is
applied to varying sources. Such an
analysis is necessary especially when
adopting standards that all sources in a
category will have to be able to meet by
using the identified technology. Since
MACT floors and standards are
generally expressed as numerical
emissions limits, it is necessary to
account for this variability in order to
adopt a regulation that is ‘achievable’ by
the industry as a whole.’’ (See NLA I,
627 F.2d at 437.)
Section 129(a)(2) of the CAA requires
that EPA determine the emissions
control achieved by the ‘‘best controlled
similar unit’’ when establishing the
MACT floors for new units. A solid
waste incineration ‘‘unit’’ is defined as
‘‘a distinct operating unit of any facility
which combusts any solid waste
material’’ (CAA section 129(g)(1)). To
achieve the best level of pollution
control, that unit will utilize a particular
method of pollution control (and
possibly use other means that affect its
emissions performance). The emissions
control achieved by that method (and by
any additional means) is the emissions
control achieved by the ‘‘best controlled
similar unit.’’ Thus, the MACT floor for
new units is based on the ‘‘emissions
control’’ that is attained by the specific
method of pollution control and any
other means used to limit emissions at
the best similar unit, rather than merely
on the emissions measured at a
particular unit.
In this way, by basing the MACT floor
on the capability of a particular method
of pollution control used at ‘‘similar’’
‘‘best’’ ‘‘units,’’ instead of on the
emissions measured at a single unit,
EPA ensures that the floors would not
only be achievable by the single best
performing unit, but are also achievable
by other units using the same
technology and/or emissions limiting
means as the best similar unit, and that
it is reasonable to require the best
similar unit and all future new units to
meet this floor on a continuous basis. In
contrast, identifying the ‘‘emissions
control’’ of the ‘‘best controlled similar
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unit’’ as being a single data point from
a single source provides merely a
snapshot of emissions performance that
may not be replicable by either that
single source or by other sources using
the same control technology, and,
therefore, does not provide a basis for
enforceably requiring all sources to
perform to that level.
Thus, the most reasonable way to
interpret the statutory phrase ‘‘best
controlled similar unit’’ in CAA section
129 is as encompassing all units using
the same technology and emissions
limiting means as the single unit with
the best observed performance, rather
than just that single best performing
unit itself. A contrary interpretation
would seem to directly conflict with the
Court’s directive in NLA I, and is not
compelled by the Court rulings in Sierra
Club, NLA II, and CKRC. Applying this
approach to evaluating ‘‘best
technologies’’ at ‘‘best controlled similar
units,’’ where different design
characteristics are identified (e.g., lowefficiency versus moderate-efficiency
versus high-efficiency wet scrubbers),
the data are grouped such that each data
set reflects the performance of an
‘‘identical’’ control device, providing
the best indication of the true
performance of each control device and
enabling the Agency to adopt a
numerical standard that can be met with
the subject technology at all units
employing this technology, and can be
enforced. Again, where the record
evidence indicates that the only means
of control of emissions at units is
application of control technology, and
there is no record evidence showing that
other means of emissions limitation
significantly affect emissions
performance, basing the MACT floor on
this approach is fully consistent with
the Court’s rulings in the MACT cases.
c. Variability Between and Within
Tests at Facilities. Another type of
variability that EPA accounts for in
order to ensure the achievability of
technology-based standards that rely
upon application of pollution controls
concerns operational distinctions
between and within tests at the same
unit. Regarding ‘‘between-test
variability,’’ even where conditions
appear to be the same when two or more
tests are conducted, variations in
emissions are often caused by different
settings for emissions testing equipment
and differences in sample handling.
Varying results may also be caused by
use of different field teams to conduct
the testing, or different laboratories to
analyze the results. All these variations
are typical.
An achievable standard needs to
account for these differences between
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tests, in order for ‘‘a uniform standard
[to] be capable of being met under most
adverse conditions which can
reasonably be expected to recur[.]’’ (See
NLA I, 627 F.2d at 431, n. 46.) (See also
Portland Cement Ass’n, 486 F.2d at 396
(noting industry point that ‘‘a single test
offered a weak basis’’ for inferring that
plants could meet the standards).)
Without accounting for variation among
different emissions tests, it can be
determined with a significant degree of
statistical confidence that even a single
unit will not be able to meet the
standard over a reasonable period of
time, when one can expect adverse
conditions to recur. The Courts have
recognized this basic principle in
reviewing technology-based effluent
standards under the Clean Water Act.
As the U.S. Court of Appeals for the 5th
Circuit stressed regarding ‘‘best
practicable technology’’ or ‘‘BPT’’
standards under section 304(b)(1) of the
Clean Water Act, ‘‘[t]he same plant
using the same treatment method to
remove the same toxic does not always
achieve the same result. Tests
conducted one day may show a different
concentration of the same toxic than are
shown by the same test on the next day.
This variability may be due to the
inherent inaccuracy of analytical
testing, i.e., ‘analytical variability,’ or to
routine fluctuations in a plant’s
treatment performance.’’ (See Chemical
Mf’rs Ass’n v. EPA, 870 F.2d 177, 228
(5th Cir. 1989).) (See also American
Petroleum Institute v. EPA, 540 F.2d
1023, 1035–36 (10th Cir. 1976) (‘‘Even
in the best treatment systems, changes
occur in ability to treat wastes. [* * *]
[V]ariability factors present[] a practical
effort to accommodate for variations in
plant operations’’); FMC Corp. v. Train,
539 F.2d 973, 985 (4th Cir. 1976)
(variability factors account for ‘‘the fact
that even in the best treatment systems
changes continually occur in the
treatability of wastes’’).)
The same types of differences leading
to between-test variability also cause
variations in results between various
runs comprising a single test, or
‘‘within-test variability.’’ A single test at
a unit usually includes at least three
separate test runs. (See 40 CFR
63.7(e)(3) (for MACT standards under
section 112 of the CAA), and 40 CFR
60.8(f) (for NSPS under CAA section
111).) (See also Portland Cement Ass’n,
486 F.2d at 397 (noting differences in
conditions among several test runs).)
d. Application of NLA I, Sierra Club,
NLA II, and CKRC Principles in HMIWI
Rulemaking. Based on the record for the
1997 rulemaking, the best way to
determine the worst reasonably
foreseeable circumstances for the
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particular technologies used to control
emissions at HMIWI was to first
examine the highest data point actually
observed from HMIWI equipped with
each particular technology. If an
emission value has been observed and
there is no reason to believe it
represents poor performance (i.e., there
is nothing that can be done to prevent
its recurring), it is likely to occur again
in the future and, therefore, reflects a
foreseeable circumstance. It is incorrect
to characterize the highest data point as
the ‘‘worst performance’’ of the best
performing unit, or to characterize one
control device’s performance as ‘‘better’’
than another’s based solely on the
results of a single emission test. This is
because such focuses relate to
essentially random single data
occurrences, rather than to estimating
what a particular technology can be
expected to continuously achieve.
Rather, each data point, whether from
one unit or from several identical units
using the same technology, should be
viewed as a snapshot of the actual
performance of the technology in use.
Along with an understanding of the
factors affecting the performance of the
technology, each of these snapshots
gives information about the normal, and
unavoidable, variation in emissions that
would be expected to recur over time
when using the identified technology.
Conversely, when there is evidence that
an emission data point reflects poor
performance (design, operation, or
both), such a data point should not be
considered in determining the
achievable emission limitation
associated with the technology.
Furthermore, a distinction must be
made between an emission level that
has been ‘‘observed’’ and an emission
limitation that can be continuously
‘‘achieved.’’ The purpose of the MACT
program is to compel sources to
replicate emission reduction strategies
used by the best-performing sources.
Thus, MACT floors are based on the
control strategies used by the bestperforming sources to reduce emissions,
not based on a snapshot level of
emissions from sources without regard
to whether this level reflects application
of any replicable emission control
strategies. CAA section 129(a)(2) does
not direct EPA to assess relative
emission ‘‘levels’’ in determining MACT
floors; it directs EPA to assess the
degree of emissions ‘‘control’’ or
‘‘reduction’’ or ‘‘limitation’’ ‘‘achieved’’
by the best-controlled or bestperforming sources. The plain meaning
of these words implies that a source is
utilizing some method or technique to
reduce emissions that is within a source
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operator’s power to adopt. The reference
to a ‘‘degree of reduction’’ supports the
view that the words ‘‘control’’ and
‘‘limitation’’ appearing in section
129(a)(2) require a source to have
reduced emissions from uncontrolled
levels through some control technique.
See NLA II, 233 F.3d at 631–32
(rejecting position that EPA is required
to set new source floors at the lowest
recorded emission level for which it has
data and to set existing source floors at
the average of the lowest 12 percent or
recorded emission level data points).
The Court has recognized that EPA
may consider variability in estimating
the degree of emission 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 (D.C. Cir 2004)
(holding EPA may consider emission
variability in estimating performance
achieved by best-performing sources
and may set floor at level that bestperforming source can expect to meet
‘‘every day and under all operating
conditions’’). Since an emission
limitation must be complied with at all
times, for it to be achievable it must be
set at a level that will not force sources
to violate it when operating conditions
are not ideal and higher emissions
levels might be observed. For example,
a car which has been observed to
consume 0.02 gallons of gasoline in a
one-mile downhill stretch of highway
cannot be said to have ‘‘achieved’’ a
minimum 50 miles per gallon fuel
efficiency rate when that same car is
later certain to consume 0.04 gallons of
gasoline in a one-mile uphill stretch of
highway (25 miles per gallon). Rather,
the minimum fuel efficiency of the car
will be that which the car can meet in
adverse circumstances, the uphill
stretch. So it is with emissions
limitations, which cannot reasonably be
set at levels which would force sources
to operate in violation even when
properly employing the control
technology upon which the standards
are based.
The emission data used to develop the
emission limitations in the HMIWI
regulations reflect properly designed
and operated air pollution control
technology on properly designed and
operated HMIWI, and emission data that
reflected poor operation of the HMIWI
unit or the air pollution control
technology were excluded. (See Legacy
Docket ID No. A–91–61, items II–A–111
and IV–B–14.) The incinerators selected
by EPA for testing represented a range
of incinerator designs and air pollution
control systems in use on this source
category. (See Legacy Docket ID No. A–
91–61, item IV–B–46.) The incinerators
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and air pollution controls were
inspected thoroughly, and maintenance
was performed where necessary to
ensure that the incinerators and
pollution controls were functioning
properly. (See Legacy Docket ID No. A–
91–61, items II–A–93, II–A–94, and II–
A–85.) During testing, most test runs
were conducted under representative
conditions to minimize emissions. (See
Legacy Docket ID No. A–91–61, items
II–A–111, IV–B–46, and IV–B–47.)
However, some test runs were purposely
conducted under conditions that would
represent poor operation (e.g.,
overcharging waste to the incinerator) to
determine the effect of improper
operation on emissions. (See Legacy
Docket ID No. A–91–61, items II–A–111
and IV–B–46.) These test runs
demonstrated that improper operation
results in higher emissions. (See Legacy
Docket ID No. A–91–61, items II–A–111,
IV–B–46, and II–A–81.) Of course, the
test runs reflecting poor operation were
not used in developing the achievable
emission limitations. Id. It is important
to note that such poor operation is
precluded by the good combustion
requirements and the parametric
monitoring requirements in the 1997
final rule. In addition to data gathered
by EPA directly, vendors of air pollution
control systems submitted test reports to
EPA. (See Legacy Docket ID No. A–91–
61, items II–I–230 through 237, II–I–243
and 244, II–I–248, IV–B–48 and 49, IV–
J–11, IV–J–15 and 16, IV–J–20, IV–J–24,
IV–J–27, IV–J–29 through 31, IV–J–33
and 34, IV–J–39 and 40, and IV–J–47.)
The test reports were submitted
primarily by wet scrubber vendors to
demonstrate to EPA that wet scrubbers
could achieve lower emissions than
EPA had concluded from the EPAcollected data. (EPA had conducted
testing on only one wet scrubber
system.) (See 61 FR 31742; Legacy
Docket ID No. A–91–61, item IV–B–48.)
The test reports and the data collected
by EPA reflect the best performance of
the air pollution controls that can
reasonably be expected when
continuously applied on HMIWI.
MACT and other technology-based
standards are necessarily derived from
short-term emissions test data, but such
data are not representative of the range
of operating conditions that facilities
face on a day-to-day basis. In statistical
terms, each test produces a limited data
sample, not a complete enumeration of
the available data for performance of the
unit over a long period of time. (See
Natrella, Experimental Statistics,
National Bureau of Standards Handbook
91, chapter 1 (revised ed., 1966).) EPA,
therefore, often needs to adjust the
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short-term data to account for these
varying conditions, so facilities properly
employing optimal controls can remain
in compliance with the standards on a
continuous basis.
With the relatively small data sets
EPA had to work with in the 1997
HMIWI rulemaking, it is possible that
EPA has not recorded the highest
emissions levels that would occur under
the worst reasonably foreseeable
circumstances. As the Court noted, it
would ‘‘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 Sierra Club,
167 F.3d at 662.) ‘‘[S]ince EPA had data
on only one percent of about 3,000
[HMIWI], the data gathering costs of any
non-sampling method may well have
been daunting.’’ Id., at 663. In fact, the
‘‘perfect study’’ cannot be conducted,
regardless of the resources expended to
conduct it. Every study ends with some
uncertainty in the results. There is no
‘‘cookbook’’ methodology for
determining achievable emission
limitations from data. In every case, but
especially in cases where data are
limited as with the 1997 HMIWI
rulemaking, EPA must make judgments
about what constitutes the worst
reasonably foreseeable circumstance
and put those judgments out for public
comment. In the case of the HMIWI
rulemaking, the ‘‘high’’ data points
simply reflected the normal, and
unavoidable, variation in emissions that
would be expected to recur over time
when properly using the best control
technologies and strategies we
determined were being used at HMIWI
units. In fact, while the highest observed
value is a ‘‘foreseeable circumstance,’’ it
may not reflect the worst reasonably
foreseeable circumstance. In
determining the 1997 final MACT
standards, EPA chose to account for the
‘‘worst reasonably foreseeable
circumstance’’ by adding 10 percent to
the highest observed emissions levels in
the data, and then rounding up those
figures. Upon review of this approach in
responding to the Court’s remand, we
have determined that although the
highest observed data point may not
reflect the ‘‘worst reasonably foreseeable
circumstance,’’ we do not have
information to support accounting for
the ‘‘worst reasonably foreseeable
circumstance’’ by adding 10 percent to
the highest observed emissions levels,
and then rounding up those figures. We,
therefore, propose to base revised
MACT standards for new HMIWI units
on the highest observed data points
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associated with employed control
strategies.
In the CKRC case, the Court left open
the possibility that the approach of
basing floors on the ‘‘worst-performing
MACT sources’’ emissions represent ‘a
reasonable estimate of the performance
of the [best-performing] units,’ ’’ CKRC
at 866, quoting Sierra Club at 662,
provided that ‘‘in the case of a particular
source category or HAP, the Agency can
demonstrate with substantial
evidence—not mere assertions—that
MACT technology significantly controls
emissions, or that factors other than the
control have a negligible effect[.] CKRC
at 866, citing NLA II at 633. The Court
in Sierra Club essentially already found
this to be the situation for the HMIWI
rulemaking, and it was, therefore,
appropriate for EPA to base its MACT
floor review in the 1997 rule strictly on
the emissions reductions achieved by
use of control technologies. The Sierra
Club had claimed that EPA wrongly
failed to require HMIWI units to
undertake programs to reduce the Hg
and chlorinated plastics in HMIWI
waste streams. Sierra Club, at 666.
While the petitioner raised this
objection in its challenge to the
promulgated standards, rather than its
objection to the floor methodology, the
Court’s response to the Sierra Club’s
claim shows that in the case of the 1997
HMIWI rulemaking, EPA appropriately
focused on the control technologies
used at HMIWI units, and that,
therefore, under the CKRC ruling it was
appropriate, in this instance, to base
floors on the highest emissions levels
achieved by units employing the MACT
technologies.
The Court observed that ‘‘EPA does
not deny that the waste stream
reductions the Sierra Club calls for
would reduce pollution. The less
mercury in, the less mercury out, and
the less chlorinated plastic in, the less
HCl out. But the EPA has consistently
argued in its response to comments and
here that it does not have evidence that
allows quantification of the relevant
output reduction. For mercury, the only
quantitative evidence before EPA was
that a pollution prevention program
aimed at mercury could reduce mercury
emissions from very high levels to
typical levels. See RTC at 7–14 to 7–15.
For chlorinated plastics, there was no
quantitative evidence before the agency.
See RTC at 7–16, 7–18. The Sierra Club
does not contest the adequacy of EPA’s
data-gathering with respect to these
measures.’’ Id. (Note that the emission
guidelines and NSPS require HMIWI to
prepare a waste management plan under
§§ 60.35e and 60.55c that would
segregate from the health care waste
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stream certain solid waste components
contributing to toxic emissions from the
incinerator (62 FR 48380, 48387).)
e. Development of the Proposed
Revised Emission Limits. While we are
proposing to respond to the Court’s
remand regarding new units by basing
floors and standards on the same control
technologies that formed the basis for
the 1997 standards, in some cases it is
necessary to adjust the emission limits
in order to correct for the concerns
regarding our 1997 methodology that
the Court raised. As at promulgation of
the 1997 rule, EPA examined the data
available for various air pollution
control technologies applied to HMIWI
to determine the performance
capabilities of the technologies;
identified the best control technology
for each air pollutant for each
subcategory of HMIWI (i.e., MACT
floor); considered control technologies
more stringent than the MACT floor;
made a determination regarding the
achievable emissions levels from using
control technologies upon which the
emission standards would be based; and
then established numerical emission
limits achievable with those
technologies. The proposed revised
standards are based on the same
technologies upon which the 1997 final
standards were based—good
combustion and a moderate-efficiency
wet scrubber for new small HMIWI, and
good combustion and a combined dry/
wet control system with carbon for new
medium and large HMIWI—and reflect
the MACT floor emissions levels for
new small and large HMIWI, but are
more stringent than the MACT floor for
new medium HMIWI. The rationale for
these determinations regarding
identification of MACT can be found at
62 FR 48365.
As explained earlier in this preamble,
we are proposing emission limits for
each air pollutant for each subcategory
of new HMIWI based on the highest
observed data points associated with the
control technologies upon which the
emission standards are based, since we
identified the ‘‘best controlled similar
unit’’ as one using the relevant control
technologies for each subcategory of
new units. The proposed percent
reduction limits for HCl, Pb, Cd, and Hg
were established based on average
combustion-controlled emissions
estimates and highest observed data
points associated with the control
technologies upon which the emission
standards for each of these pollutants
for each subcategory are based. This is
the same approach used at the time of
promulgation with two exceptions—the
proposed percent reduction limits do
not include the addition of 10 percent
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to the highest observed emissions levels,
nor does it include the rounding up of
those figures. A summary of the control
technologies upon which the proposed
standards for new HMIWI are based, the
highest observed data points associated
with those control technologies, and the
proposed emission limits for new
HMIWI in response to the remand are
presented in Table 6 of this preamble.
Note that MACT for NOX and SO2 are
‘‘combustion control,’’ although
combustion control results in no
emission reductions for those pollutants
because NOX emissions are not reduced
by combustion control, and NOX add-on
controls have not been demonstrated on
HMIWI; and SO2 emissions are not
reduced by combustion control, and
acid gas controls are not effective in
reducing SO2 emissions from HMIWI at
the low SO2 levels associated with
HMIWI.
TABLE 6.—SUMMARY OF REMAND RESPONSE FOR NEW HMIWI
Highest observed
data point 2
Pollutant
(units)
Unit Size 1
MACT
HCl (ppmv) ...........................................
CO (ppmv) ...........................................
Pb (mg/dscm) ......................................
L, M, S ........
L, M, S ........
L, M .............
S ..................
L, M .............
S ..................
L, M .............
S ..................
L, M .............
S ..................
L, M .............
S ..................
L, M .............
S ..................
L, M, S ........
L, M, S ........
Wet scrubber .......................................
Good combustion ................................
Dry scrubber w/carbon ........................
Wet scrubber .......................................
Dry scrubber w/carbon ........................
Wet scrubber .......................................
Dry scrubber w/carbon ........................
Wet scrubber .......................................
Dry scrubber w/carbon ........................
Moderate-efficiency wet scrubber .......
Dry scrubber w/carbon ........................
Wet scrubber .......................................
Dry scrubber w/carbon ........................
Wet scrubber .......................................
Combustion Control 5 ..........................
Combustion Control 5 ..........................
Cd (mg/dscm) ......................................
Hg (mg/dscm) ......................................
PM (gr/dscf) .........................................
CDD/CDF, total (ng/dscm) ...................
CDD/CDF, TEQ (ng/dscm) ..................
NOX (ppmv) .........................................
SO2 (ppmv) ..........................................
9.3
32
0.06
1.1
0.03
0.14
0.45
0.47
0.009
0.018
20
111
0.53
2.1
225
46
Proposed emission limit 2
15 3 or 99% reduction 3.
32.
0.060 or 98% reduction 3.
0.78 4 or 71% reduction.
0.030 or 93% reduction.
0.11 4 or 66% reduction 3.
0.45 or 87% reduction.
0.47 or 87% reduction.
0.0090.
0.018.
20.
111.
0.53.
2.1.
225.
46.
1L
= Large; M = Medium; S = Small.
values are measured at 7 percent oxygen.
change proposed.
4 Remand standards for existing small non-rural HMIWI are proposed.
5 Combustion control results in no emissions reduction.
2 All
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3 No
Note that no change is proposed for
the emission limit for HCl for new large,
medium, and small HMIWI. In this
situation, the highest observed emission
point (i.e., 9.3 ppmv) is not used as a
basis for the proposed emission limits.
Public comments concerning use of EPA
Method 26A when testing for HCl
emissions at sources with wet scrubbers
were submitted with respect to the
recently promulgated standards for
other solid waste incineration units (70
FR 74870, December 16, 2005). The
commenter asserted that EPA Method
26A is not adequate for demonstrating
compliance with an HCl standard below
20 ppmv when sampling sources with
wet scrubbers. Although EPA did not
concede that there is an outright
problem, we acknowledged that a tester
may need to take certain precautions to
ensure that there is no bias when
sampling streams with low HCl
concentrations in certain environments
and promulgated an HCl emission limit
of 15 ppmv (versus the proposed limit
of 3.7 ppmv). Method 26A also notes
that there is a possible measurable
negative bias below 20 ppmv HCl
perhaps due to reaction with small
amounts of moisture in the probe and
filter (40 CFR part 60, appendix A).
Accordingly, because many of the wetscrubber controlled HMIWI used
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Method 26A to measure HCl emissions
below 20 ppmv and did not take
precautions to ensure no negative bias,
in this action we are proposing to retain
the emission limit of 15 ppmv and also
are including provisions that require
sources to condition the filter before
testing, and use a cyclone and post test
purge if water droplets may be present.
In the cases of Pb and Cd for new small
HMIWI, using the highest observed data
points would result in emission limits
less stringent (i.e., higher) than the
proposed emission limits for existing
small non-rural HMIWI. Because the
existing source analysis provides limits
that can be achieved by existing HMIWI,
there is no reason to believe that new
HMIWI could not also meet the more
stringent limits. This unanticipated
result may be due to the small amount
of Pb and Cd emissions data available
for wet scrubbers at promulgation.
Regardless, we are proposing emission
limits for Pb and Cd for new small
HMIWI that are the same as those
proposed for existing small non-rural
HMIWI.
2. Existing Units
The Court raised three specific
concerns regarding EPA’s approach for
existing units in concluding that EPA
had not adequately explained why the
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combination of regulatory and
uncontrolled (i.e., combustioncontrolled) data provided a ‘‘reasonable
estimate’’ of HMIWI performance:
‘‘First, EPA has said nothing about the
possibility that [HMIWI] might be
substantially overachieving the
[regulatory] limits. [Footnote:] Although
the agency conceded in its response to
comments that ‘actual emission data
routinely fall below the State permit
emission limits,’ [* * *] the context
makes reasonably clear that the EPA
was referring to data on ‘actual
emissions’ during tests; EPA implied
that ‘these levels are not routinely
achieved in practice.’ [* * *] [End
Footnote] If this were the case, the
permit limits would be of little value in
estimating the top 12 percent of
[HMIWI]s’ performance’’ (167 F.3d at
663, and at n. 3). According to the
Court, ‘‘[d]ata in the record suggest that
the regulatory limits are in fact much
higher than emissions that units achieve
in practice.’’ Id., at 663.
‘‘Second, EPA never gave any reason
for its apparent belief that [HMIWI]s
that were not subject to [regulatory
limits] did not employ emission
controls of any sort. Unless there is
some finding to this effect, it is difficult
to see the rationality in using
‘uncontrolled’ data for the units that
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were not subject to regulatory
requirements’’ (167 F.3d at 664). The
Court pointed out that ‘‘[d]ata submitted
by the American Hospital Association
[AHA] in 1995 indicate that over 55%
of [HMIWI]s in each category were
controlled by wet scrubbers.’’ Id.,
footnote omitted. As a result, the Court
found it ‘‘difficult to see how it was
rational to include any uncontrolled
[i.e., combustion-controlled] units in the
top 12 percent, at least with respect to
pollutants that wet scrubbing controls.’’
Id.
Third, the Court held that ‘‘assuming
the regulatory data was a good proxy for
the better controlled units and that there
were shortfalls in reaching the necessary
12 percent, EPA has never explained
why it made sense to use the highest of
its test run data to make up the gap.’’ Id.
Subsequent court decisions also
addressed the type of information EPA
may use to estimate emissions
performance and establish MACT floors
for existing units. In NLA II, the Court
rejected the Sierra Club’s claim that it
was unreasonable for EPA to select ‘‘the
median [performing] plant out of the
best twelve percent of the plants for
which it had information and set the
* * * floor at the level of the worst
performing plant in its databases using
th[e same] technology [as the median
plant].’’ 233 F.3d at 630. As long as
EPA’s estimate of the performance of the
top 12 percent was reasonable, the Court
held, EPA was not required to use actual
emissions data. Id. While in CKRC the
Court held that EPA had not justified in
the HWC rulemaking basing the floor on
emissions levels of the worst performing
plant utilizing MACT control
technology, when record evidence
indicated other factors beyond MACT
technology affected emissions
performance, the Court reiterated that
EPA could use estimates, as long as they
reflected a ‘‘reasonable[] estimate [of]
the performance of the * * * bestperforming plants.’’ 255 F.3d at 862.
Specifically regarding the use of State
permits to determine MACT floors, the
Court in Northeast Maryland Waste
Disposal Authority v. EPA, 358 F.3d 936
(D.C. Cir. 2004) (‘‘NMWDA’’), rejected
EPA’s approach for small municipal
waste combustion units because ‘‘as in
Sierra Club, EPA stated only that it
‘believes’ state permit limits reasonably
reflect the actual performance of the
best performing units without
explaining why this is so.’’ 358 F.3d at
954. There, EPA had asserted that the
inherent variability of emission levels
made other data inaccurate, but the
Court concluded that EPA gave ‘‘no
evidence that the [State] permit levels
reflect the emission levels of the best-
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performing’’ units, and that EPA’s stated
‘‘belief’’ did not rise to the level of a
‘‘reasonable estimate.’’ Id. However, in
Mossville Envt’l Action Now v. EPA (370
F.3d 1232 (D.C. Cir. 2004)), the Court
concluded that ‘‘instead of simply
claiming that it believes its [relied upon]
standards estimate what the best five
plants actually achieve, EPA points to
some evidence. In its response to
comments, EPA cited its analysis of
three years of data, and * * * met its
burden of establishing that its standards
reasonably estimate the performance of
the best five performing sources. Having
cited the great variability of emission
levels, even within the same plants, and
the inherent difficulty in other
standards it considered, the EPA’s
selection of the [relevant] standards as
the MACT floor is reasonable because it
has supported its decision with record
data that shows the connection between
its MACT floor and the top performing
plants.’’ 370 F.3d at 1242.
a. The Possibility that HMIWI Sources
are Substantially Overachieving their
Regulatory Limits. With regard to the
Sierra Club Court’s first concern, the
Court itself noted early in its opinion
that ‘‘the necessary relationship [of
regulatory data serving as a reasonable
proxy to indicate HMIWI performance]
seems quite reasonable here. Indeed, it
seems likely that any jurisdiction
bothering to impose limits would not
knowingly set them below what it found
firms to be achieving in practice. And
there seems no reason to think that
underachieving firms would be
overrepresented in jurisdictions making
this effort.’’ 167 F.3d at 662. The Court
also expressed support for the notion
that, when faced with limited actual
emissions information, a substitute
‘‘ ‘reasonable sample’ may be used ‘to
find out what the best 12 percent are
doing[,]’ ’’ (id., citing Oral Arg. Tr. at
11), and that ‘‘EPA typically has wide
latitude in determining the extent of
data-gathering necessary to solve a
problem.’’ Id. Specifically, the Court
noted ‘‘that since EPA had data on only
one percent of about 3000 [HMIWI]s,
[* * *] the data-gathering costs of any
non-sampling method may well have
been daunting.’’ Id., at 663.
There are three reasons why EPA
chose to use the regulatory limits at
their face value in calculating the
existing source MACT floor for the 1997
rule. First, regulatory data were used
because there was very little actual
emissions data available and very little
data available indicating the type of air
pollution control used by the best
performing units. (See 61 FR at 31738.)
None of the available information
indicated that the regulated entities
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5527
were substantially overachieving or
underachieving their regulatory limits.
Second, there was no information before
the Agency suggesting that the State
regulatory agencies erred in establishing
the regulatory limits or that the States’
regulatory limits were outdated. It was
thus reasonable for EPA to expect that
the State regulatory limits provided a
reasonable estimate of the actual
performance of HMIWI units. Third, it
was reasonable for EPA to expect that
regulated entities take their regulatory
limits into account when designing their
control equipment. To some extent,
control equipment can be designed to
meet various levels of emissions, and
regulated entities do not normally spend
more money than necessary to meet a
regulatory limit. As noted above, the
Court observed that ‘‘there seems no
reason to think that underachieving
firms would be overrepresented’’ by
regulatory limits (167 F.3d at 662).
Conversely, there is no reason to
generally assume that substantially
overachieving firms would be
overrepresented in jurisdictions
imposing regulatory limits. Rather, what
is most likely is that sources in
regulated jurisdictions will have
assessed whether steps to control
emissions are needed to comply with
the regulatory limits, and that, in order
to account for emissions variability
when applying control technologies,
they will be targeting their emissions
levels at some safe point below the
regulatory limits. Hence, with no
information in the 1997 rulemaking
record to indicate otherwise, EPA
generally expected that regulatory limits
were being achieved, through
application of emissions control
methods, at emissions levels that
sources deem necessary in order to
minimize the risk of violating the
relevant limit, and were neither
substantially overachieving the limits
nor underachieving them.
The Court noted that the
administrative record indicated that, in
some cases, sources were overachieving
their regulatory limits, where the floors
based on the weighted average of the
regulatory limits and the ‘‘uncontrolled’’
(i.e., combustion-controlled) data were
significantly higher than the values used
for combustion-controlled data. (See 167
F.3d at 663, citing A–91–61, IV–B–024
at 2–3). Here, the Court was referring to
some regulatory limits that, in fact,
reflected higher emissions levels than
did EPA’s uncontrolled (i.e.,
combustion-controlled) emission
estimates, and suggested that in these
cases it would be unreasonable for EPA
to view the best performing 12 percent
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of sources as actually polluting at levels
so much higher than the test units for
which EPA assumed no emissions
controls were in place. Id., at 663–664.
EPA agrees that a regulatory limit
does not reflect ‘‘actual performance’’
when that limit is higher than the level
attributed to the worst reasonably
foreseeable performance of an
uncontrolled (i.e., combustioncontrolled) source. Since the data
forming the basis for the existing source
MACT floor must provide a reasonable
estimation of the ‘‘actual performance’’
of the best performing 12 percent of
HMIWI, such high regulatory limits
should not have been included in the
best-performing 12 percent. Therefore,
in our re-visiting the MACT floor for
existing HMIWI based on the 1997
record, in situations for which there is
no information in the 1997 record
indicating the presence of an add-on
pollution control device (‘‘APCD’’) or
other use of air pollution control
methods but there are regulatory limits,
we propose the substitution of
combustion-controlled data for
regulatory limits where those data
reflect lower emissions levels than do
regulatory limits that appear to be
unrelated to actual controls. We propose
to continue to use combustioncontrolled data in situations for which
there is no information indicating air
pollution controls are in use and there
are no regulatory limits.
b. Emission Control on HMIWI Not
Subject to Regulatory Limits. The
Court’s second concern was that EPA
had not made a finding that HMIWI that
were not subject to regulatory
requirements did not use emissions
controls of any kind. The Court viewed
such a finding as a necessary
prerequisite to using uncontrolled (i.e.,
combustion-controlled) data for units
not subject to regulatory requirements.
This issue can be partly resolved by
correcting a misunderstanding that may
have resulted from our 1997
administrative record. The Court
focused on information submitted in
1995 by the AHA suggesting that ‘‘over
55% of [HMIWI]s in each category were
controlled by wet scrubbers.’’ (See 167
F.3d at 664, citing AHA Comments,
Exhibit 3.) Based on its review of the
AHA comments, the Court assumed that
under EPA’s estimation of the HMIWI
population, more than 12 percent in
each category ‘‘would as a matter of
mathematical necessity have to be
controlled.’’ Id., at 664, n. 8. The Court
then observed that ‘‘it is difficult to see
how it was rational to include any
uncontrolled [i.e., combustioncontrolled] units in the top 12 percent,
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at least with respect to pollutants that
wet scrubbing controls.’’ Id., at 664.
With regard to the AHA ‘‘data’’
identified by the Court as indicating 55
percent of HMIWI use wet scrubbers,
EPA believes that the Court was led by
this information into assuming that
unregulated HMIWI were in fact
applying add-on emissions controls,
when the record does not actually
substantiate such an assumption,
especially for small HMIWI. The AHA
asserts ‘‘almost all properly designed,
operated, and controlled [HMIWI] can
readily meet a particulate emission limit
of 0.10 gr/dscf without an [add-on air
pollution control] system’’ (IV–D–637,
Exhibit 2, emphasis added). The AHA
then concludes ‘‘[t]herefore, it is
reasonable that as many as 50 percent of
those [HMIWI] having such an emission
limit would be uncontrolled.’’ Id. The
AHA goes on to assume that 50 percent
of all HMIWI with particulate emission
limits of 0.10 gr/dscf or higher are
controlled with wet scrubbers, while an
even higher percentage of units with
more stringent particulate emission
limits are assumed to be controlled. Id.
This is akin to saying that, because
homeowners are generally not required
to install wet scrubbers on fireplaces, it
is reasonable to assume that as many as
50 percent of homes with fireplaces do
not have wet scrubbers, while the other
50 percent of home fireplaces are
equipped with wet scrubbers. The AHA
makes a basic assumption that at least
50 percent of all HMIWI have wet
scrubbers, no matter what requirements
they are subject to. With no other
information to support its assumption,
AHA’s ‘‘data’’ indicating 55 percent of
HMIWI are equipped with wet scrubbers
is altogether unreliable. In addition,
EPA’s documented difficulty in
identifying sources with add-on controls
during the development of the HMIWI
emission testing program is in direct
conflict with the large number of
controlled sources suggested by the
AHA ‘‘data.’’
Based on information from various
sources in the docket from the 1997
rulemaking, including an AHA HMIWI
inventory, we now estimate that about
32 percent of large, 4 percent of
medium, and 1 percent of small HMIWI
at the time of the 1997 rulemaking were
equipped with add-on control systems.
Other sources in the 1997 record that
provided an indication of whether or
not HMIWI were equipped with add-on
air pollution control and upon which
these estimates are based include a
survey of HMIWI in California and New
York, air permits from State regulatory
agencies, responses to information
collection requests, telephone contact
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summaries, HMIWI emissions test
reports, and various inventories. (See
Legacy Docket ID No. A–91–61, items
IV–J–82, IV–B–07, II–B–94, II–D–175
through 178, II–I–151, IV–J–89, IV–E–
65, IV–E–74, IV–E–86, and II–B–61;
Docket EPA–HQ–OAR–2006–0534,
document titled ‘‘List of Test Reports
Used to Identify HMIWI Control
Devices’’). Our assessment that few
HMIWI were equipped with add-on
controls is also supported by economics
in that it would not have made sense for
an HMIWI to be voluntarily equipped
with an air pollution control device that
costs one to three or more times as
much as the entire HMIWI. Further
supporting our assessment is the fact
that the expected outcome of the
regulation (which was not refuted by
any commenters), that 50 to 80 percent
of existing incinerators (including 100
percent of the small units) would shut
down rather than meet the regulations
because those that chose to meet the
regulations would have to install air
pollution control to comply, was, in
fact, more than realized. (See 60 FR
10665, 61 FR 31768, and 62 FR 48372.)
In fact, all but 8 small units, 6 of which
meet the rural criteria and did not have
to install air pollution control to
comply, 20 medium units, and 44 large
units have shut down, rather than meet
the standards that would have been
achieved by use of the very controls
AHA appeared to assume were in place.
Consequently, EPA concludes that the
1997 record, as confirmed by recent data
showing the vast reduction in sources
(as opposed to sources installing
controls), shows that most HMIWI were
not equipped with add-on air pollution
control and that the use of uncontrolled
(i.e., combustion-controlled) emission
estimates where there was no indication
of air pollution control (and where any
applicable regulatory limits allowed
higher levels of emissions than our
combustion-controlled emissions values
reflected) was warranted. Based on the
number of HMIWI shutdowns, it
appears very likely that there were even
fewer HMIWI with air pollution controls
than we estimated based on the
information discussed above (i.e., that
about 32 percent of large, 4 percent of
medium, and 1 percent of small HMIWI
were equipped with add-on control
systems).
c. EPA’s Use of the Highest Emissions
Data to Reflect Uncontrolled (i.e.,
Combustion-Controlled) Emissions. The
Court’s third concern regarded our use
of the highest of the test run data to
reflect uncontrolled (i.e., combustioncontrolled) emissions in cases where
regulatory data did not comprise the
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necessary 12 percent of best performing
sources. Our reason for this approach is
the same as the reason described earlier
regarding new units for using the
highest data point from MACTparticular technology to reflect the
performance of that technology and
identify the ‘‘best controlled similar
unit.’’ As the Court stated in NLA I,
‘‘where test results are relied upon, it
should involve the selection or use of
test results in a manner which provides
some assurance of the achievability of
the standard for the industry as a whole,
given the range of variable factors found
relevant to the standard’s achievability.’’
(See 627 F.2d at 433). EPA reads the
Court’s opinion in Sierra Club as at least
endorsing the principles of NLA I with
respect to existing units, as the Court
described as ‘‘counterintuitive’’ the
Sierra Club’s ‘‘proposition that an
‘achieved’ level may not be
‘achievable[.]’ ’’ (See 167 F.3d at 662). In
addition, we also read CKRC as allowing
this approach, where no evidence in the
record contradicts the assumption that
‘‘factors other than the control have a
negligible effect [on emissions
performance],’’ 255 F.3d at 866, and,
therefore, the presence or absence of
known effective MACT controls is the
prime determinant of emissions
performance.
Where regulatory data indicating use
of emissions control was absent in the
1997 rulemaking record, EPA needed to
find a surrogate emission limitation that
reflected uncontrolled (i.e., combustioncontrolled) emissions, expecting, when
not faced with data indicating
otherwise, that facilities with no
regulatory limits would not be
controlling their emissions with add-on
controls or other control methods
(beyond combustion control). In this
situation, EPA used the highest test data
point from a well-operated HMIWI as a
surrogate for the worst reasonably
foreseeable circumstances. The highest
test data points reflect the normal, and
unavoidable, variation in emissions that
would be expected to recur over time.
Table 7 of this preamble summarizes the
performance values used for units for
which there is no information indicating
an APCD is present and there are no
regulatory limits, or where regulatory
limits do exist but reflect emissions
levels that are higher than the values for
uncontrolled (i.e., combustioncontrolled) units.
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TABLE 7.—UNCONTROLLED (I.E., COM- size category. Actual test data, where
BUSTION-CONTROLLED)
PERFORM- available in the 1997 record, were the
initial type of pollutant-specific values
ANCE VALUES
considered. Next, where the 1997 record
has information indicating that a source
employed some type of add-on control
but there are no test data or regulatory
HCl (ppmv) ...........................
2,770
limits for that source, an average of the
1 584.9
CO (ppmv) - ..........................
maximum dry and wet control system
Pb (micrograms per dry
performance was determined for each
standard cubic meter µg/
pollutant, and those values were added
dscm) ................................
8,629
to the data set towards comprising the
Cd (µg/dscm) ........................
3,520
best performing 12 percent. We believe
Hg (µg/dscm) ........................
6,543.4
2 0.278
that use of these averages is an
PM (gr/dscf) ..........................
2 8,102
CDD/CDF, total (ng/dscm) ...
appropriate method of estimating the
2 236
CDD/CDF, TEQ (ng/dscm) ...
performance of HMIWI (1) where the
NOX (ppmv) ..........................
224.5
1997 record has limited information
SO2 (ppmv) ...........................
46.39
indicating the presence of some type of
1 All performance values are measured at 7
add-on control but no test data for the
percent oxygen.
unit, and (2) where we are unsure if the
2 Based on 1-second combustion level
control is similar to, or is as efficient as,
those for which we have data, or if the
d. Determining the MACT Floor and
unit even employed a true control
MACT for Existing Units. As discussed
device. As previously stated, we believe
above, the Sierra Club Court identified
it very likely that there were fewer
some potential errors in EPA’s
HMIWI with air pollution controls than
methodology for determining the
existing source MACT floors for HMIWI. we estimated in 1997, and to which we
After reviewing the 1997 HMIWI record have assigned pollutant-specific average
control device values. If, in fact, those
in the context of the Court’s opinion,
sources were employing true control
EPA agrees that, in determining the
devices, common sense dictates that
MACT floor, the Agency should not
there wouldn’t have been the large
have used regulatory limits that
number of unit shut downs that
reflected higher emissions levels (and
occurred in response to the promulgated
that did not appear to be related to any
standards. However, because we had
air pollution controls) than those
some indication that an add-on control
corresponding to EPA’s combustiondevice was in place on those sources,
controlled emission estimates.
we recognize that the use of
Furthermore, as we examined the 1997
uncontrolled (i.e., combustionrecord and our estimates of the
controlled) emission estimates (at
performance of HMIWI where we had
promulgation) did not provide a
some indication that add-on controls
reasonable estimate of their
may have been used, we determined
performance. Similarly, use of
that we should not have used
performance values associated with a
combustion-controlled emission
specific type of add-on control device
estimates in the floor calculations to
seems inappropriate when no details are
represent the performance of those
available on the control device and
sources. Additionally, for this
there is, in fact, some doubt as to the
rulemaking we propose that where
presence of a true control device at all.
actual emissions test data reflecting
emissions performance was available in Despite the doubts of the presence of a
true control device, the approach we
the 1997 record for use in determining
have selected assumes that the 1997
the MACT floor, that data should take
precedence over other types of data (i.e., record is correct and assigns ‘‘default’’
performance values to the units that are
regulatory limits or performance
based on the expected performance of
values).
the types of control devices used in the
EPA’s reassessment of the 1997
industry in 1997. These default
MACT floors and MACT decisions,
performance values, based on the
based on an adjusted methodology that
average of the maximum dry and wet
addresses the Court’s issues discussed
control system performance, also are
above, results in proposed emission
used where regulatory limits exist but
limits that in many cases are more
stringent than the limits promulgated in are higher than the default performance
values.
1997. EPA’s first step in redoing the
MACT analysis based on the 1997
Table 8 of this preamble summarizes
record for existing HMIWI was to
the performance values for HCl, Pb, Cd,
determine the pollutant-specific values
Hg, CDD/CDF, and PM for units for
that make up the best performing 12
which the 1997 record has information
percent of existing units within each
indicating that they employed some
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type of add-on control but has no test
data or regulatory limits corresponding
to specific controls, or where regulatory
limits exist but are higher than the
values based on an average of the
maximum dry and wet control system
performance.
(46.39 ppmv) are the same as those
presented in Table 7 of this preamble.
The next step in the MACT analysis
for existing HMIWI was to determine
the average emission limitation
achieved by the best-performing 12
percent of existing sources where there
are 30 or more sources in the category
TABLE 8.—PERFORMANCE VALUES
or subcategory. Our general approach to
BASED ON AVERAGE OF MAXIMUM identifying the average emission
DRY AND WET CONTROL SYSTEM limitation has been to use a measure of
central tendency, such as the arithmetic
PERFORMANCE
mean or the median. If the median is
Pollutant
Performance
used when there are at least 30 sources,
1
(units)
value
then the emission level that is at the
bottom of the best performing 6 percent
HCl (ppmv) ...........................
53.165
of sources (i.e., the 94th percentile)
Pb (µg/dscm) ........................
568.5
represents the MACT floor control level.
Cd (µg/dscm) ........................
83.65
We based our MACT floors for each
Hg (µg/dscm) ........................
459.5
PM (gr/dscf) ..........................
0.0195 pollutant within each size category on
CDD/CDF, total (ng/dscm) ...
65.35
this approach. We then determined the
CDD/CDF, TEQ (ng/dscm) ...
1.296
technology associated with each
1 All performance values are measured at 7
‘‘average of the best-performing 12
percent oxygen.
percent’’ value by comparing the
average values to average performance
The values for CO, NOX and SO2 are
data for wet scrubbers, dry injection
based on the performance of
combustion-controlled HMIWI because, fabric filters (also known as dry
scrubbers), and combustion controls (no
as stated at proposal and promulgation
of the 1997 HMIWI standards, as well as add-on air pollution controls). Those
pollutants with average values that were
earlier in this preamble, CO emission
higher than the relevant combustionlevels are affected by combustion
practices rather than the control systems controlled emission estimate were
identified as having a ‘‘combustion
used by HMIWI; NOX control had not
control’’ floor, even if the pollutant is
been demonstrated on HMIWI; and the
not reduced by combustion control. The
acid gas controls used by HMIWI were
technology needed to meet the
not effective in reducing SO2 emissions
remaining average values reflects the
from HMIWI due to the low inlet levels
technology used by the average unit in
of SO2 associated with hospital/
medical/infectious waste. Therefore, for the top 12 percent and serves as the
units (1) where the 1997 record contains basis for the MACT floor. EPA then
considered, on a pollutant-specific
information indicating that they
basis, technologies that were more
employed some type of add-on control
stringent than the MACT floor
but for which there was no test data or
regulatory limits, or (2) where regulatory technologies.
limits existed but were higher than the
Add-on control technology-based
values for CO, NOX, or SO2 based on
MACT floors were identified for large
combustion-controlled HMIWI, the
HMIWI for HCl, Pb, Cd, Hg, PM, and
performance values for CO (584.9
CDD/CDF. The MACT floor technology
ppmv), NOX (224.5 ppmv), and SO2
for all size units for NOX and SO2 is
‘‘combustion control’’ although, as
previously explained in this preamble,
combustion control results in no
emission reductions for those
pollutants. ‘‘Good combustion’’ (i.e., 2second combustion) was identified as
the MACT floor technology for all size
units for CO. ‘‘Combustion control’’
floors were identified for medium
HMIWI for Pb, Cd, Hg, and CDD/CDF
and for small HMIWI for HCl, Pb, Cd,
Hg, and CDD/CDF. However, for these
pollutants for all medium and most
small HMIWI, we have decided to
propose limits that are more stringent
than the ‘‘combustion control’’ floors
and are consistent with the control
technology-based MACT floors that
were identified for large HMIWI for
these pollutants (i.e., Pb, Cd, Hg, and
CDD/CDF for medium HMIWI and HCl,
Pb, Cd, Hg, and CDD/CDF for small
HMIWI). The control technologies
identified as the MACT floors for HCl
and PM for medium HMIWI, and for PM
for small HMIWI, provide an indication
of the level of control of the other
pollutants—a level of technology that is
consistent with those technologies
identified for large HMIWI. The
rationale for not basing the proposed
emission limits on other technologies
that would result in even more stringent
limits can be found at 62 FR 48371–72.
As at the 1997 promulgation, MACT for
small HMIWI that meet certain ‘‘rural
criteria’’ was determined to be at the
MACT floor level for each pollutant
(i.e., no ‘‘beyond-the-floor’’-based
emission limits).
Table 9 of this preamble shows the
average emission value, based on the
ranking of emissions data, regulatory
data, and performance data, of each
pollutant for the top 12 percent of
HMIWI in each subcategory. The values
in Table 9 allow EPA to identify the
technology associated with the average
unit in the top 12 percent of HMIWI.
TABLE 9.— AVERAGE EMISSION VALUES FOR TOP 12 PERCENT OF HMIWI 1
HMIWI size
Pollutant (units)
jlentini on PROD1PC65 with PROPOSAL2
Small
HCl (ppmv) .....................................................................................................................................................
CO (ppmv) .....................................................................................................................................................
Pb (mg/dscm) ................................................................................................................................................
Cd (mg/dscm) ................................................................................................................................................
Hg (mg/dscm) ................................................................................................................................................
PM (gr/dscf) ...................................................................................................................................................
CDD/CDF, total (ng/dscm) .............................................................................................................................
CDD/CDF, TEQ (ng/dscm) ............................................................................................................................
NOX (ppmv) ...................................................................................................................................................
SO2 (ppmv) ....................................................................................................................................................
1 All
Medium
Large
2,770
100
8.63
3.52
6.54
0.080
8,102
236
225
46.4
53
100
8.63
3.52
4.27
0.030
8,102
236
225
46.4
50
100
0.569
0.084
0.460
0.020
65.4
1.30
225
46.4
emission values are measured at 7 percent oxygen.
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Table 10 of this preamble shows the
technology associated with each average
emission value.
TABLE 10.—MACT FLOOR TECHNOLOGY
HMIWI Size
Pollutant (units)
Small
HCl (ppmv) .....................................
CO (ppmv) .....................................
Pb (mg/dscm) ................................
Cd (mg/dscm) ................................
Hg (mg/dscm) ................................
PM (gr/dscf) ...................................
CDD/CDF, total (ng/dscm) .............
CDD/CDF, TEQ (ng/dscm) ............
NOX (ppmv) ...................................
SO2 (ppmv) ....................................
Medium
Large
combustion control .......................
good combustion ..........................
combustion control .......................
combustion control .......................
combustion control .......................
low-efficiency wet scrubbber ........
combustion control .......................
combustion control .......................
combustion control .......................
combustion control .......................
dry scrubber ..................................
good combustion ..........................
combustion control .......................
combustion control .......................
combustion control .......................
moderate-efficiency wet scrubber
combustion control .......................
combustion control .......................
combustion control .......................
combustion control .......................
dry scrubber.
good combustion.
wet scrubber.
wet scrubber.
dry scrubber.
moderate-efficiency wet scrubber.
wet scrubber.
wet scrubber.
combustion control.
combustion control.
For small units, the CO and PM
values indicate that good combustion
control (i.e., 2-second combustion) and
a low-efficiency wet scrubber reflect the
CO and PM MACT floors. For medium
units, as well as large units, the CO,
HCl, and PM values indicate that good
combustion control used in conjunction
with either a dry scrubber or moderateefficiency wet scrubber reflects the CO,
HCl, and PM MACT floors. As
previously stated, EPA concluded that
emission limits for small units that meet
the rural criteria should reflect the
MACT floor level of control for all
pollutants. The average emission value
and MACT floor level of control for PM
vary by unit size, and we are proposing
emission limits based on those levels of
control. The average emission values,
and associated MACT floor levels of
control, for CO, NOX, and SO2 are the
same for all size units. For most small
units and all medium units, however,
we concluded that emission limits for
HCl, Pb, Cd, Hg, and CDD/CDF should
reflect the MACT floor level of control
for large units for those pollutants.
The resulting numerical emission
limits were determined by combining
the appropriate average emission value
for each pollutant for each size HMIWI
with a variability factor. We believe it is
necessary to account for variability
given the limited amount of actual data
available in the 1997 record and the
resulting need for use of various, and
often presumptive, types of information
to formulate the best performing 12
percent of HMIWI. At promulgation, we
recognized the need to account for
variability and did so as described
earlier in this preamble. Although we
maintain that the methodology we used
was not unreasonable given the
available information at promulgation,
we now have additional information
(the 2002 compliance test data for all of
the currently operating units) for use in
calculating pollutant-specific variability
factors. While these data were not
available at promulgation, they are the
only data available for providing a
quantitative assessment of variability of
emissions from well-controlled HMIWI.
To determine the pollutant-specific
variability factors, a statistical analysis
was conducted. Specifically, the
emission limit achievable for each
pollutant was determined based on the
combination of actual emissions test
data, regulatory data, and estimated
performance levels (as described earlier)
and a statistics-based variability factor
calculated for each pollutant. To
calculate the variability factors, we used
the general equation: variability factor =
t * standard deviation. This general
equation has been used by EPA in
similar analyses. (See, e.g., 68 FR 27650;
69 FR 55235–7; 70 FR 28615.) We
selected the 90th percentile confidence
level for this one-sided t-statistics test.
The 90th percentile provides a
variability factor appropriate for wellcontrolled sources that is based on data
from well-controlled sources (i.e., the
only sources that are still in operation).
Table 11 of this preamble presents the
values determined by adding the
variability factors to the average
emission values for each pollutant for
existing large and medium HMIWI. The
table also presents the proposed revised
emission limits for existing large and
medium HMIWI necessary to respond to
the Court’s remand and the percent
reduction limits for HCl, Pb, Cd, and Hg.
The percent reduction limits are based
on average combustion-controlled
emissions estimates and maximum
performance values for the MACT
identified for each pollutant for each
subcategory. This is the same approach
used at the time of promulgation of the
1997 rule, except that the proposed
percent reduction limits do not include
the addition of 10 percent to the
maximum performance values or the
rounding up of those figures.
TABLE 11.—AVERAGE EMISSION VALUES, CONSIDERING VARIABILITY, AND EMISSION LIMITS 1—EXISTING LARGE AND
MEDIUM HMIWI
Large
jlentini on PROD1PC65 with PROPOSAL2
Pollutant
(units)
Average +
variability
HCl (ppmv) .......................................
CO (ppmv) .......................................
Pb (mg/dscm) ..................................
Cd (mg/dscm) ..................................
Hg (mg/dscm) ..................................
PM (gr/dscf) .....................................
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78
110
0.78
0.11
0.64
0.025
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Medium
Emission
limit
Average +
variability
78 or 93% reduction 2 ......................
40 2 ..................................................
0.78 or 71% reduction .....................
0.11 or 66% reduction .....................
0.55 2 or 87% reduction ...................
0.015 2 .............................................
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limit
57.9
113
9.02
3.56
4.34
0.043
E:\FR\FM\06FEP2.SGM
78 3 or 93% reduction 2.
40 2
0.78 3 or 71% reduction 3.
0.11 3 or 66% reduction 2.
0.55 2 or 87% reduction 3.
0.030 2
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TABLE 11.—AVERAGE EMISSION VALUES, CONSIDERING VARIABILITY, AND EMISSION LIMITS 1—EXISTING LARGE AND
MEDIUM HMIWI—Continued
Large
Pollutant
(units)
Average +
variability
CDD/CDF, total (ng/dscm) ...............
CDD/CDF, TEQ (ng/dscm) ..............
NOX (ppmv) .....................................
SO2 (ppmv) ......................................
1 All
2 No
Medium
Emission
limit
115 ...................................................
2.2 ....................................................
250 2 ................................................
55 2 ..................................................
115
2.16
284
61
Average +
variability
8,150
237
273
51.8
Emission
limit
115 3
2.2 3
250 2
55 2
emission values are measured at 7 percent oxygen.
change from current emission limit.
limit is the same as that for large HMIWI.
3 Emission
Table 12 of this preamble presents the
same information for existing small non-
rural HMIWI and for existing small
HMIWI meeting the rural criteria.
TABLE 12.— AVERAGE EMISSION VALUES, CONSIDERING VARIABILITY, AND EMISSION LIMITS 1—EXISTING SMALL AND
SMALL RURAL HMIWI
Large
Pollutant
(units)
Average +
variability
HCl (ppmv) .........................................................
CO (ppmv) .........................................................
Pb (mg/dscm) ....................................................
Cd (mg/dscm) ....................................................
Hg (mg/dscm) ....................................................
PM (gr/dscf) .......................................................
CDD/CDF, total (ng/dscm) .................................
CDD/CDF, TEQ (ng/dscm) ................................
NOX (ppmv) .......................................................
SO2 (ppmv) ........................................................
2,772
103
8.85
3.54
6.55
0.095
8,335
239
225
46.4
Medium
Average +
variability
Emission limit
78 3 or 93% reduction 2. ....................................
40 2 ....................................................................
0.78 3 or 71% reduction 3 ..................................
0.11 3 or 66% reduction 2 ..................................
0.55 2 or 87% reduction 3 ..................................
0.050 2 ...............................................................
115 3 ..................................................................
2.2 3 ...................................................................
250 2 ..................................................................
55 2 ....................................................................
3,125
109
8.88
3.54
6.56
0.089
8,518
244
273
51.8
Emission limit
2 3,100
2 40
8.9
4
6.6
2 0.086
2 800
2 15
2 250
2 55
1 All
emission values are measured at 7 percent oxygen.
change from current emission limit.
3 Emission limit is the same as that for large HMIWI.
jlentini on PROD1PC65 with PROPOSAL2
2 No
For pollutants where this remand
analysis (based on the average of the
best performing 12 percent of HMIWI
plus the variability factor) resulted in
emission limits less stringent (i.e.,
higher) than the current emission limits,
we retained the current emission limits.
This is because we see no reason to
upwardly revise standards that the
regulated industry has already
demonstrated are achievable based on
compliance data. In fact, now that we
have received the 2002 compliance data
for HMIWI units, it is apparent that
EPA’s estimate of the achievable
emissions performance levels from use
of the identified MACT technology was
reasonably accurate. While we are not in
this proposal attempting to justify our
prior existing unit MACT floor
decisions post hoc based on new data
that we could not have relied upon in
the 1997 rulemaking itself, we note that,
similar to the Mossville case, we
currently find ourselves in a situation
where actual emissions data fairly
confirms our prior estimates of what the
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best controlled HMIWI units could
achieve when using MACT controls.
The resulting emission limits being
proposed for medium HMIWI for HCl
and SO2; for small HMIWI for NOX and
SO2; and for small rural HMIWI for SO2
are the same as those being proposed for
large HMIWI because, in these
instances, the medium, small, and small
rural HMIWI are expected to achieve
reductions similar to large HMIWI.
B. Rationale for the Proposed
Amendments (CAA Section 129(a)(5) 5Year Review)
In recent rulemakings (see, e.g., 71 FR
34422, 34436–38 (June 14, 2006)
(proposed amendments to the NESHAP
for Hazardous Air Pollutants for Organic
Hazardous Air Pollutants from the
Synthetic Organic Chemical
manufacturing Industry)) EPA has
addressed the similar technology review
requirement under CAA section
112(d)(6). EPA stated that the statute
provides the Agency with broad
discretion to revise MACT standards as
we determine necessary, and to account
for a wide range of relevant factors,
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including risk. EPA does not interpret
such technology review requirements to
require another analysis of MACT floors
for existing and new units, but rather
requires us to consider developments in
pollution control in the industry and
assess the costs of potentially stricter
standards reflecting those
developments. (See, id., at 34436–47.)
Moreover, as a general matter, EPA has
stated that where we determine that
existing standards are adequate to
protect public health with an ample
margin of safety and prevent adverse
environmental effects, it is unlikely that
EPA would revise MACT standards
merely to reflect advances in air
pollution control technology. Id., at
34437–38.
Under CAA section 112(d)(6), the first
round of technology review for MACT
standards is subject to the same
statutory timeframe as EPA’s residual
risk review under CAA section 112(f)(2),
with both reviews occurring 8 years
following initial promulgation of
MACT. We interpret CAA section
129(a)(5)’s technology review
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requirement as providing us the same
degree of discretion in terms of whether
to revise MACT standards, for the
reasons discussed in those prior
rulemakings. (See, id., at 34436–38.)
However, the deadline for the first
round of technology review under
section 129(a)(5) (5 years following
MACT promulgation) does not coincide
with the deadline for residual risk
review under section 112(f)(2) (9 years,
in the case of HMIWI standards).
Therefore, this first section 129(a)(5)
technology review for HMIWI does not
account for or reflect our residual risk
analysis. In future rounds of review
under section 129(a)(5) for the HMIWI
standards, we intend to follow our
general policy, and for our technology
reviews and conclusions to be informed
by our residual risk analysis, which we
will have performed by that point.
In exercising its discretion under CAA
section 129(a)(5), EPA is proposing in
this technology review to adopt
emission limits based on the 2002 data
because it believes that these limits
represent the cost-effective operation of
the MACT control technology. EPA is
aware of the possibility that regulated
units are likely to operate at a level
somewhat below emission standards in
order to account for operational
variability. It is not our intent to
preclude this practice through
successive rounds of the section
129(a)(5) technology review. EPA
requests comment on its proposal (as
outlined below) to adopt more stringent
emission limits in this instance through
its section 129(a)(5) technology review.
1. How were the proposed emission
limits developed?
The proposed revised emission limits
resulting from our 5-year review of the
HMIWI standards under section
129(a)(5) of the CAA are based on the
performance of units within the
industry that currently are subject to the
MACT standards. One set of emission
limits is proposed for existing HMIWI
regulated under CAA section 111(d)/
129(b) emission guidelines, and another
set of emission limits is proposed for
new HMIWI (units commencing
construction after February 6, 2007)
regulated under CAA section 111(b)/
129(a) NSPS. Units that were subject to
the 1997 NSPS as new units (referred to
as ‘‘1997 NSPS units’’ for the remainder
of this preamble) will remain subject to
the 1997 NSPS (including revisions
resulting from EPA’s response to the
Court remand), but will also be subject
to any requirements of the revised
emission guidelines that are more
stringent than the 1997 NSPS
requirements. The proposed emission
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limits for existing units, 1997 NSPS
units, and new units were developed
following the procedures discussed
below.
As background, with one exception
resulting from the analyses associated
with our response to the Court remand,
the proposed emission limits for new
and existing units are based on the
application of the same control
technologies upon which the 1997
MACT standards were based. For new
large and medium units, both the
current and proposed emission limits
are based upon good combustion and
the application of combined control
systems that include both dry scrubbers
(i.e., dry injection fabric filters or spray
dryer fabric filters) with carbon
injection and wet scrubbers. The current
and proposed emission limits for new
small units are based on good
combustion and the application of a
moderate-efficiency wet scrubber. For
large, medium, and most small existing
units, the current and proposed
emission limits are based on good
combustion control for CO; combustion
controls (i.e., no add-on controls) for
NOX and SO2; and the application of
either dry scrubbers or wet scrubbers
(with various ‘‘efficiencies’’ depending
on the size of the unit) for the remaining
pollutants. The current emission limits
for one additional subcategory, existing
small rural units, are based solely on
good combustion (i.e., the MACT floor
identified in the 1997 analysis was not
based on add-on control technology).
With the exception of PM, the proposed
emission limits for existing small rural
units also are based solely on good
combustion. In our remand analysis, we
identified a low-efficiency wet scrubber
as being the MACT floor for PM for
these units. Although all small rural
units currently use only good
combustion, to address this difference
in the MACT floors (i.e., 1997 analysis
versus remand analysis), we are
proposing a PM emission limit for
existing small rural units based on the
application of low-efficiency wet
scrubbers to existing small non-rural
units (i.e., MACT floor for small nonrural units in the 1997 analysis as well
as the remand analysis). While this
performance level is associated with the
expected performance of a lowefficiency wet scrubber, the combustion
controls in place on these six existing
small rural units achieve this
performance level, based on the initial
compliance tests for these units.
In performing this 5-year review, we
have not recalculated new MACT floors,
but have proposed to revise the
emission limits to reflect the actual
performance of the MACT technologies.
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5533
We believe this approach reflects the
most reasonable interpretation of the
review requirement of CAA section
129(a)(5), and is consistent with how we
have interpreted the similar review
requirement of CAA section 112(d)(6)
regarding MACT standards promulgated
under section 112. (See 71 FR 27327–28;
69 FR 48350–51; and 70 FR 20008.) The
language of section 129(a)(5) directs
EPA to ‘‘review’’ our promulgated
standards under CAA section 111/129,
and to ‘‘revise such standards and
requirements’’ ‘‘in accordance with this
section and section 111.’’ It does not,
however, direct EPA to conduct, at 5year-intervals, new MACT floor and
beyond-floor analyses based on each 5years’ changing information as to what
might comprise the top 12 percent of
sources or constitute the best controlled
similar unit. There is no indication that
Congress intended for section 129(a)(5)
to inexorably force existing source
standards progressively lower and lower
in each successive review cycle, the
likely result of requiring successive
floor determinations.
Following MACT compliance in
September 2002, EPA obtained
compliance test reports from all
operating HMIWI (76 units at 70
facilities) and used those data to
evaluate MACT performance. When the
HMIWI regulations were first proposed
in 1995, re-proposed in 1996, and
promulgated in 1997, only limited
information was available about HMIWI
emission controls, and significant
engineering judgment was necessary in
selecting the emission limits. The year
2002 compliance data show that the
control technologies that were installed
and the practices that were
implemented to meet the 1997 NSPS
and emission guidelines achieved
reductions somewhat superior to what
we expected under the 1997 limits for
many of the pollutants. EPA used the
compliance test data to develop the
emission limits contained in the
amendments we are proposing under
the 5-year review. EPA believes that the
proposed emission limits more
accurately reflect actual real-world
HMIWI MACT performance than what
we had estimated in 1997 and what we
re-estimated based on the 1997 record in
response to the Court’s remand
(discussed previously in this preamble).
We believe that it is necessary, as well
as appropriate, to update the 1997
promulgated standards based on the
actual performance of MACT
technologies in situations where
compliance test data indicate that the
technologies achieve better performance
levels than those we previously
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estimated based on the information
available at the time of promulgation.
a. Existing Units. The first step in the
analysis was to assess the performance
of the HMIWI currently subject to the
emission guidelines with respect to each
regulated pollutant. We first examined
the data separately for each unit size,
and the data showed, for all pollutants
except PM, that the performance of
units with add-on controls, regardless of
size, (excluding small rural units, which
do not employ add-on controls), is
similar. Therefore, we combined the
data, regardless of unit size, for all of the
pollutants except PM, and conducted
analyses on the combined data sets. In
addition, for the pollutants with
emission limits based on good
combustion and combustion control
(i.e., no add-on controls), namely CO,
NOX, and SO2, the data for small rural
units also were combined with the data
for all of the other subcategories of
units. Analyses were performed on each
data set, and we calculated the 99
percent upper tolerance limit (UTL),
which is the emission level that 99
percent of the HMIWI would be
expected to achieve. A similar
methodology was used for stack testbased emission limits in the 5-year
review recently conducted for large
municipal waste combustors (MWC). In
the preamble to that final action, EPA
indicated that analysis of data to
estimate emission limits to be enforced
by stack test methods must be done
using a different approach (i.e., lower
percent UTL) than where enforcement is
to be based on CEMS and that the
percentile must also reflect a reasonable
consideration of emissions variability
and compliance limitations of stack
testing (See 71 FR 27329). EPA further
indicated that for this type of
technology review, the 99 percent UTL
was appropriate to use as a tool for
estimating achievable emission levels
for emission limits enforced by stack
testing. Id. In this proposed rulemaking,
the 99 percent UTL was used as the
starting point for selecting the revised
emission limits. We compared the 99
percent UTL values to several other
values, including the 1997 promulgated
emission limits and the revised limits
that we are proposing in response to the
Court’s remand (‘‘remand limits’’). For
several pollutants, the value associated
with the 99 percent UTL was higher
than the remand limit. In these cases,
we selected the remand limit, rather
than the 99 percent UTL value, as the
proposed emission limit. We also
graphically compared the 99 percent
values and remand limits, where
applicable, to all of the data that were
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used to calculate the percentile values.
In many cases, this visual comparison
revealed that the 99 percent UTL value
or remand limit fell within a break in
the data that indicated a level of
performance that the technologies,
considering variability, could readily
achieve but that the ‘‘worst performing’’
units were not achieving during their
compliance tests. Thus, our analyses
indicate that the emission limits that we
selected reflect the actual performance
of the MACT control technologies while
also serving to require modest
improvements in performance from
units that are not achieving the
performance levels demonstrated in
practice by the control technologies
currently being used in the industry.
For small non-rural HMIWI, we used
a different methodology for assessing
PM performance because there are only
two units and, therefore, statistics are
not a useful tool. Both of the small nonrural units are equipped with wet
scrubbers. Because existing medium
units are predominantly equipped with
wet scrubbers, the PM emission limit
developed using the 99 percent UTL
value of the data set for existing
medium units also is being proposed for
small non-rural units.
A different methodology also was
used for assessing performance of the
six small rural HMIWI. To determine
the actual performance of these small
combustion-controlled units while
considering the inherent variability in
emissions, we obtained test data for all
six units (although, as allowed in the
emission guidelines, not all of the
pollutants were tested at every unit) and
selected as the emission limit the
highest individual test run from the
compliance testing for HCl, Pb, Cd, Hg,
and CDD/CDF. This methodology uses
actual test data to provide a reasonable
estimate of the performance of the small
rural units for these pollutants, where
statistics are not a useful tool, while
accounting for variability. There are
exceptions to this methodology for CO,
NOX, and SO2. As previously mentioned
in this preamble, the CO, NOX, and SO2
data for small rural units were
combined with the CO, NOX, and SO2
data for the other subcategories of units.
The 99 percent UTL methodology was
then used as the starting point, as
previously described in this preamble,
to determine proposed emission limits
that would apply to all of the
subcategories of existing HMIWI.
Another exception to this methodology
is the proposed emission limit for PM.
As previously explained in this
preamble, we are proposing a PM
emission limit for existing small rural
units based on the application of low-
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efficiency wet scrubbers to existing
small non-rural units (i.e., we are
proposing the same PM emission limit
for small rural and non-rural units).
While many of the resulting proposed
emission limits for small rural units are
significantly more stringent than the
1997 promulgated limits, the proposed
limits more accurately reflect the actual
performance of these units.
Finally, we examined the available
data for calculating percent reduction
requirements for HCl, Pb, Cd, and Hg.
Percent reduction standards were
included in the 1997 promulgated
standards for these pollutants, and we
are proposing to update these
requirements to reflect the now-known
actual performance of HMIWI utilizing
MACT controls. For HCl, we obtained
percent reduction data from five large
HMIWI using dry scrubbers (i.e., the
control technology upon which the
emission limits for existing large,
medium, and small non-rural units are
based), and these data showed percent
reductions from 94.2 percent to greater
than 99 percent. To account for
variability, we based the proposed
percent reduction requirement of 94
percent on the lowest percent reduction
recorded during the individual test runs
(i.e., 94.2 percent). The three-run test
that included the 94.2 percent value
showed significant variability and
demonstrates the need to account for
variability. The percent reduction
values for the three runs ranged from
94.2 percent to 97.8 percent while there
was no identifiable change in the
operation of the unit or the dry
scrubber. For Pb and Cd from existing
large, medium, and small non-rural
HMIWI, we used the same methodology
as for HCl, and the data sets showed
even greater variability. For Hg, we used
the only available estimate of percent
reduction. The proposed percent
reduction standards are 71 percent for
Pb, 74 percent for Cd, and 96 percent for
Hg. The 5-year review methodology
used to assess performance of existing
HMIWI resulted in no change to the PM
standards for existing large and medium
units, and CDD/CDF standards for
existing small rural units. All of the
other standards for existing HMIWI
were adjusted based on either the 5-year
review or the remand analyses.
Table 13 of this preamble summarizes
the emission limits promulgated in
1997, the emission limits resulting from
the proposed response to the Court
remand, and the emission limits being
proposed as a result of the 5-year review
for existing HMIWI. Note that these
proposed limits for existing HMIWI only
apply to units for which construction
was commenced on or before June 20,
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5535
1996, or for which modification was
commenced before March 16, 1998.
TABLE 13.—SUMMARY OF 1997 PROMULGATED EMISSION LIMITS, PROPOSED REMAND RESPONSE EMISSION LIMITS, AND
PROPOSED 5-YEAR REVIEW LIMITS FOR EXISTING HMIWI
Pollutant
(units)
Unit
size1
Promulgated
limit2
Proposed remand response
limit2
HCl (ppmv) ...............................
L, M, S ........
SR ...............
All ................
L, M, S ........
SR ...............
L, M, S ........
SR ...............
L, M, S ........
SR ...............
L ..................
M .................
S ..................
SR ...............
L, M, S ........
SR ...............
L, M, S ........
SR ...............
All ................
All ................
100 or 93% reduction ..............
3,100 ........................................
40 .............................................
1.2 or 70% reduction ...............
10 .............................................
0.16 or 65% reduction .............
4 ...............................................
0.55 or 85% reduction .............
7.5 ............................................
0.015 ........................................
0.03 ..........................................
0.05 ..........................................
0.086 ........................................
125 ...........................................
800 ...........................................
2.3 ............................................
15 .............................................
250 ...........................................
55 .............................................
78 or 93% reduction ................
3,100 ........................................
40 .............................................
0.78 or 71% reduction .............
8.9 ............................................
0.11 or 66% reduction .............
4 ...............................................
0.55 or 87% reduction .............
6.6 ............................................
0.015 ........................................
0.030 ........................................
0.050 ........................................
0.086 ........................................
115 ...........................................
800 ...........................................
2.2 ............................................
15 .............................................
250 ...........................................
55 .............................................
CO (ppmv) ................................
Pb (mg/dscm) ...........................
Cd (mg/dscm) ...........................
Hg (mg/dscm) ...........................
PM (gr/dscf) ..............................
CDD/CDF, total (ng/dscm) .......
CDD/CDF, TEQ (ng/dscm) .......
NOX (ppmv) ..............................
SO2 (ppmv) ...............................
1L
Proposed 5-year review
limit2
51 or 94% reduction.
398
25
0.64 or 71% reduction.
0.60
0.060 or 74% reduction.
0.050
0.33 or 96% reduction.
0.25
0.015
0.030
0.030
0.030
115
800
2.0
15
212
28
= Large; M = Medium; S = Small; SR = Small Rural
emission limits are measured at 7 percent oxygen.
2 All
Table 14 of this preamble summarizes
the emission limits promulgated in 1997
and the emission limits being proposed
as a result of EPA’s response to the
Court remand for the 1997 NSPS
HMIWI. Note that these proposed limits
for 1997 NSPS HMIWI only apply to
units for which construction was
commenced after June 20, 1996, and on
or before the date of this proposal, or for
which modification is commenced
before the date 6 months after
promulgation of the proposed limits.
Also note that where the proposed 5year review limits for existing HMIWI
are more stringent than those resulting
from the remand response for 1997
NSPS HMIWI, the more stringent limits
for existing HMIWI are included in the
table as the limits being proposed.
HMIWI subject to the 1997 NSPS,
however, will not find these proposed
limits, as presented in Table 14 of this
preamble, in subparts Ec or Ce of 40
CFR part 60. Instead, they must consider
the proposed revisions to subpart Ec of
40 CFR part 60 regarding existing
HMIWI, as well as in the proposed
revisions to subpart Ce of 40 CFR part
60 regarding 1997 NSPS HMIWI, and
comply with the more stringent
emission limit.
TABLE 14.—SUMMARY OF 1997 PROMULGATED EMISSION LIMITS AND PROPOSED LIMITS IN RESPONSE TO THE REMAND
FOR 1997 NSPS HMIWI
Pollutant
(units)
Unit size1
HCl (ppmv) ........................................................
CO (ppmv) ........................................................
Pb (mg/dscm) ...................................................
Cd (mg/dscm) ...................................................
Hg (mg/dscm) ...................................................
PM (gr/dscf) ......................................................
CDD/CDF, total (ng/dscm) ................................
CDD/CDF, TEQ (ng/dscm) ...............................
NOX (ppmv) ......................................................
SO2 (ppmv) .......................................................
L,
L,
L,
S
L,
S
L,
L,
S
L,
S
L,
S
L,
L,
Proposed remand response
limit2
Promulgated limit2
M, S ..............
M, S ..............
M ..................
.......................
M ..................
.......................
M, S ..............
M ..................
.......................
M ..................
.......................
M ..................
.......................
M, S ..............
M, S ..............
15 or 99% reduction .........................................
40 ......................................................................
0.07 or 98% reduction ......................................
1.2 or 70% reduction ........................................
0.04 or 90% reduction ......................................
0.16 or 65% reduction ......................................
0.55 or 85% reduction ......................................
0.015 .................................................................
0.03 ...................................................................
25 ......................................................................
125 ....................................................................
0.6 .....................................................................
2.3 .....................................................................
250 ....................................................................
55 ......................................................................
15 or 99% reduction.
25 3.
0.060 or 98% reduction.
0.64 3 or 71% reduction.
0.030 or 93% reduction.
0.0603 or 74% reduction 3.
0.333 or 96% reduction 3.
0.0090
0.018
20
111
0.53
2.0 3.
212 3.
28 3.
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1L
= Large; M = Medium; S = Small
emission limits are measured at 7 percent oxygen.
3 Because the proposed 5-year review limit for existing HMIWI is more stringent than the one resulting from the remand response for 1997
NSPS HMIWI, the more stringent limit for existing HMIWI is being proposed.
2 All
b. New Units. The first step in the
analysis for new large and medium
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HMIWI was to assess the performance of
the units currently operating a
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combined dry/wet control system,
which is the control technology upon
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which the 1997 NSPS for large and
medium HMIWI was based. Four units
currently are operating such controls,
and we obtained compliance test data
for each unit for use in assessing
performance. We selected as the
proposed emission limit the highest
individual test run from the compliance
testing for each pollutant. This
methodology uses actual test data from
the best-controlled sources in the
industry to provide a reasonable
estimate of the performance of these
units, while accounting for variability.
In several instances, the emission limit
suggested by the highest run from the
four combined-control sources was
higher than either the emission limit for
new sources that we are proposing in
response to the Court remand or the 5year review emission limit that we are
proposing for existing sources. This was
likely a result of the small amount of
data that we used to establish the limits,
and, in these instances, we are
proposing the most stringent among
these three limits for new sources.
Although there are no small HMIWI
subject to the current NSPS, we are
proposing emission limits based on the
performance of moderate-efficiency wet
scrubbers, which is the control
technology upon which the 1997 limits
for new small units was based. As an
initial step in selection of these
emission limits, we used the
performance values representative of
control with a moderate-efficiency wet
scrubber as determined for the existing
medium HMIWI. We then compared
these values to the values for new small
units developed in response to the
remand and, in each case, we selected
the more stringent value as the proposed
emission limit.
To determine proposed percent
reduction requirements for new units
for HCl, Pb, Cd, and Hg, we followed a
methodology similar to that used for
existing units. For HCl, we obtained
percent reduction data from two units
controlled with the MACT control
technology for HCl for new large and
medium units (wet scrubbers), and these
data showed percent reductions greater
than 99 percent. To account for
variability, we based the percent
reduction requirement of 99 percent on
the lowest percent reduction recorded
during the individual test runs (i.e., 99.1
percent). We used the same
methodology for each of the three
metals for new large and medium units,
and the corresponding percent
reduction standards based on the MACT
control technology (dry scrubbers) are
99 percent for Pb, 99 percent for Cd, and
96 percent for Hg. For HCl from new
small HMIWI, we used the same
methodology as for new large and
medium units because the MACT
control technology upon which the
reductions are based is the same (wet
scrubbers). For Pb and Cd from new
small HMIWI, we used the same
methodology as for new large and
medium units, except that the MACT
control technology upon which the
reductions are based is a wet scrubber.
For Hg, we used the only available
estimate of percent reduction. The
proposed percent reduction standards
for new small units are 99 percent for
HCl, 71 percent for Pb, 74 percent for
Cd, and 96 percent for Hg. The 5-year
review methodology used to assess
performance of new units resulted in no
change to the HCl standards for all new
units. All of the other standards for new
units were adjusted based on either the
5-year review or the remand analyses.
Table 15 of this preamble summarizes
the emission limits promulgated in 1997
and the emission limits being proposed
as a result of the 5-year review for new
HMIWI. Note that these proposed limits
for new HMIWI only apply to units for
which construction is commenced after
the date of this proposal, or for which
modification is commenced on or after
the date 6 months after promulgation of
the proposed limits.
TABLE 15.—SUMMARY OF 1997 PROMULGATED EMISSION LIMITS AND PROPOSED 5-YEAR REVIEW LIMITS FOR NEW
HMIWI
Pollutant
(units)
Unit size 1
HCl (ppmv) ........................................................
CO (ppmv) ........................................................
Pb (mg/dscm) ...................................................
Cd (mg/dscm) ...................................................
Hg (mg/dscm) ...................................................
PM (gr/dscf) ......................................................
CDD/CDF, total (ng/dscm) ................................
CDD/CDF, TEQ (ng/dscm) ...............................
NOX (ppmv) ......................................................
SO2 (ppmv) .......................................................
1L
L,
L,
L,
S
L,
S
L,
S
L,
S
L,
S
L,
S
L,
L,
S
Proposed 5-year review
limit 2
Promulgated limit 2
M, S ..............
M, S ..............
M ..................
.......................
M ..................
.......................
M ..................
.......................
M ..................
.......................
M ..................
.......................
M ..................
.......................
M, S ..............
M ..................
.......................
15 or 99% reduction .........................................
40 ......................................................................
0.07 or 98% reduction ......................................
1.2 or 70% reduction ........................................
0.04 or 90% reduction ......................................
0.16 or 65% reduction ......................................
0.55 or 85% reduction ......................................
0.55 or 85% reduction ......................................
0.015 .................................................................
0.03 ...................................................................
25 ......................................................................
125 ....................................................................
0.6 .....................................................................
2.3 .....................................................................
250 ....................................................................
55 ......................................................................
55 ......................................................................
15 or 99% reduction.
25
0.060 or 99% reduction.
0.64 or 71% reduction.
0.0050 or 99% reduction.
0.060 or 74% reduction.
0.19 or 96% reduction.
0.33 or 96% reduction.
0.0090
0.018
16
111
0.21
2.0
212
21
28
= Large; M = Medium; S = Small.
emission limits are measured at 7 percent oxygen.
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2 All
2. How did EPA determine the proposed
performance testing and monitoring
requirements?
We are proposing minor adjustments
to the performance testing and
monitoring requirements that were
promulgated in 1997. For existing
HMIWI and 1997 NSPS HMIWI, we are
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proposing retaining the current
requirements of the rule and adding the
following requirements: Annual
inspections of scrubbers and fabric
filters; and one-time testing of the ash
handling operations at the time of the
next compliance test using EPA Method
22 of appendix A of 40 CFR part 60.
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These proposed requirements were
selected to provide additional assurance
that sources continue to operate at the
levels established during their initial
performance test. The proposed
amendments would allow sources to use
the results of previous emissions tests to
demonstrate compliance with the
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revised emission limits as long as the
sources certify that the previous test
results are representative of current
operations. Only those sources whose
previous emissions tests do not
demonstrate compliance with one or
more revised emission limits would be
required to conduct another emissions
test for those pollutants (note that
sources are already required to test for
HCl, CO, and PM on an annual basis).
Additional requirements also are
proposed for new HMIWI. For new
sources, we are proposing retaining the
current requirements and adding the
following requirements: Use of CO
CEMS; annual inspections of scrubbers
and fabric filters; use of bag leak
detection systems on fabric filter-based
control systems; and annual testing of
the ash handling operations using EPA
Method 22 of appendix A of 40 CFR part
60. For existing sources, in addition to
the proposed changes in monitoring
requirements, we also are proposing to
allow for the optional use of bag leak
detection systems. We also are clarifying
that the rule allows for the following
optional CEMS use: CO CEMS for
existing sources and 1997 NSPS
sources; and PM CEMS, HCl CEMS,
multi-metals CEMS, Hg CEMS, and
semi-continuous dioxin monitoring for
existing, 1997 NSPS, and new sources.
The optional use of HCl CEMS, multimetals CEMS, and semi-continuous
dioxin monitoring will be available on
the date a final performance
specification for these monitoring
systems is published in the Federal
Register or the date of approval of a sitespecific monitoring plan. The proposed
testing and monitoring provisions are
discussed below.
a. Bag Leak Detection Systems. The
proposed amendments would provide,
as an alternative PM monitoring
technique for existing sources and 1997
NSPS sources and a requirement for
new sources, the use of bag leak
detection systems on HMIWI controlled
with fabric filters. Bag leak detection
systems have been applied successfully
at many industrial sources. EPA is
proposing to drop the opacity testing
requirements for HMIWI that use bag
leak detection systems.
b. CO CEMS. The proposed
amendments would require the use of
CO CEMS for new sources, and allow
the use of CO CEMS on existing sources
and 1997 NSPS sources. Owners and
operators that use CO CEMS would be
able to discontinue their annual CO
compliance test as well as their
monitoring of the secondary chamber
temperature. The continuous
monitoring of CO emissions is an
effective way of ensuring that the
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combustion unit is operating properly.
The proposed amendments incorporate
the use of performance specification
(PS)–4B (Specifications and Test
Procedures for Carbon Monoxide and
Oxygen Continuous Monitoring Systems
in Stationary Sources) of appendix B of
40 CFR part 60.
The proposed CO emission limits are
based on data from infrequent (normally
annual) stack tests and compliance
would be demonstrated by stack tests.
The change to use of CO CEMS for
measurement and enforcement of the
same emission limits must be carefully
considered in relation to an appropriate
averaging period for data reduction.
EPA considered this issue and
concluded the use of a 24-hour block
average was appropriate to address CO
emissions variability, and EPA has
included the use of a 24-hour block
average in the proposed rule. The 24hour block average would be calculated
following procedures in EPA Method 19
of appendix A of 40 CFR part 60.
Facilities electing to use CO CEMS as an
optional method would be required to
notify EPA 1 month before starting use
of CO CEMS and 1 month before
stopping use of the CO CEMS. In
addition, EPA specifically requests
comment on whether continuous
monitoring of CO emissions should be
required for all existing HMIWI and all
1997 NSPS HMIWI.
c. PM CEMS. The proposed
amendments would allow the use of PM
CEMS as an alternative testing and
monitoring method. Owners or
operators who choose to rely on PM
CEMS would be able to discontinue
their annual PM compliance test. In
addition, because units that demonstrate
compliance with the PM emission limits
with a PM CEMS would clearly be
meeting the opacity standard,
compliance demonstration with PM
CEMS would be considered a substitute
for opacity testing. Owners and
operators that use PM CEMS also would
be able to discontinue their monitoring
of minimum wet scrubber pressure
drop, horsepower, or amperage. The
proposed amendments incorporate the
use of PS–11 (Specifications and Test
Procedures for Particulate Matter
Continuous Emission Monitoring
Systems at Stationary Sources) of
appendix B of 40 CFR part 60 for PM
CEMS, and PS–11 QA Procedure 2 to
ensure that PM CEMS are installed and
operated properly and produce good
quality monitoring data.
The proposed PM emission limits are
based on data from infrequent (normally
annual) stack tests and compliance
would be demonstrated by stack tests.
The use of PM CEMS for measurement
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5537
and enforcement of the same emission
limits must be carefully considered in
relation to an appropriate averaging
period for data reduction. EPA
considered this issue and concluded the
use of a 24-hour block average was
appropriate to address PM emissions
variability, and EPA has included the
use of a 24-hour block average in the
proposed rule. The 24-hour block
average would be calculated following
procedures in EPA Method 19 of
appendix A of 40 CFR part 60. An
owner or operator of an HMIWI unit
who wishes to use PM CEMS would be
required to notify EPA 1 month before
starting use of PM CEMS and 1 month
before stopping use of the PM CEMS.
d. Other CEMS and Monitoring
Systems. EPA also is proposing the
optional use of HCl CEMS, multi-metals
CEMS, Hg CEMS, and semi-continuous
dioxin monitoring as alternatives to the
existing methods for demonstrating
compliance with the HCl, metals (Pb,
Cd, and Hg), and CDD/CDF emissions
limits. For the reasons explained above
for CO CEMS and PM CEMS, EPA has
concluded that the use of 24-hour block
averages would be appropriate to
address emissions variability, and EPA
has included the use of 24-hour block
averages in the proposed rule. The 24hour block averages would be calculated
following procedures in EPA Method 19
of appendix A of 40 CFR part 60.
Although final performance
specifications are not yet available for
HCl CEMS and multi-metals CEMS, EPA
is considering development of
performance specifications. The
proposed rule specifies that these
options will be available to a facility on
the date a final performance
specification is published in the Federal
Register or the date of approval of a sitespecific monitoring plan.
The use of HCl CEMS would allow
the discontinuation of HCl sorbent flow
rate monitoring, scrubber liquor pH
monitoring, and the annual testing
requirements for HCl. EPA has proposed
PS–13 (Specifications and Test
Procedures for Hydrochloric Acid
Continuous Monitoring Systems in
Stationary Sources) of appendix B of 40
CFR part 60 and believes that
performance specification can serve as
the basis for a performance specification
for HCl CEMS use at HMIWI. In
addition to the procedures used in
proposed PS–13 for initial accuracy
determination using the relative
accuracy test, a comparison against a
reference method, EPA is taking
comment on an alternate initial
accuracy determination procedure,
similar to the one in section 11 of PS–
15 (Performance Specification for
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Extractive FTIR Continuous Emissions
Monitor Systems in Stationary Sources)
of appendix B of 40 CFR part 60 using
the dynamic or analyte spiking
procedure.
EPA believes multi-metals CEMS can
be used in many applications, including
HMIWI. EPA has monitored side-by-side
evaluations of multi-metals CEMS with
EPA Method 29 of appendix A of 40
CFR part 60 at industrial waste
incinerators and found good correlation.
EPA also approved the use of multimetals CEMS as an alternative
monitoring method at a hazardous waste
combustor. EPA believes it is possible to
adapt proposed PS–10 (Specifications
and Test Procedures for Multi-metals
Continuous Monitoring Systems in
Stationary Sources) of appendix B of 40
CFR part 60 or other EPA performance
specifications to allow the use of multimetals CEMS at HMIWI. In addition to
the procedures used in proposed PS–10
for initial accuracy determination using
the relative accuracy test, a comparison
against a reference method, EPA is
taking comment on an alternate initial
accuracy determination procedure,
similar to the one in section 11 of PS–
15 using the dynamic or analyte spiking
procedure.
Relative to the use of Hg CEMS, EPA
believes that PS–12A (Specifications
and Test Procedures for Total Vapor
Phase Mercury Continuous Emission
Monitoring Systems in Stationary
Sources) of appendix B of 40 CFR part
60 can provide the basis for using Hg
CEMS at HMIWI. An owner or operator
of an HMIWI unit who wishes to use Hg
CEMS would be required to notify EPA
1 month before starting use of Hg CEMS
and 1 month before stopping use of the
Hg CEMS. The use of multi-metals
CEMS or Hg CEMS would allow the
discontinuation of wet scrubber outlet
flue gas temperature monitoring.
Mercury sorbent flow rate monitoring
could not be eliminated in favor of a
multi-metals CEMS or Hg CEMS
because it also is an indicator of CDD/
CDF control. Additionally, there is no
annual metals test that could be
eliminated.
The semi-continuous monitoring of
dioxin would entail use of a continuous
automated sampling system and
analysis of the sample using EPA
Reference Method 23 of appendix A of
40 CFR part 60. The option to use a
continuous automated sampling system
would take effect on the date a final
performance specification is published
in the Federal Register or the date of
approval of a site-specific monitoring
plan. Semi-continuous monitoring of
dioxin would allow the discontinuation
of fabric filter inlet temperature
monitoring. Dioxin/furan sorbent flow
rate monitoring could not be eliminated
in favor of semi-continuous monitoring
of dioxin because it also is an indicator
of Hg control. Additionally, there is no
annual CDD/CDF test that could be
eliminated. If semi-continuous
monitoring of dioxin as well as multimetals CEMS or Hg CEMS are used, Hg
sorbent flow rate monitoring and CDD/
CDF sorbent flow rate monitoring (in
both cases activated carbon is the
sorbent) could be eliminated. EPA
requests comment on other parameter
monitoring requirements that could be
eliminated upon use of any or all of the
optional CEMS discussed above. Table
16 of this preamble presents a summary
of the HMIWI operating parameters, the
pollutants influenced by each
parameter, and alternative monitoring
options for each parameter.
TABLE 16.—SUMMARY OF HMIWI OPERATING PARAMETERS, POLLUTANTS INFLUENCED BY EACH PARAMETER, AND
ALTERNATIVE MONITORING OPTIONS FOR EACH PARAMETER
Pollutants Influenced by Operating Parameter (by Control Device Type)
Operating parameter/monitoring requirement
Alternative monitoring options
Dry scrubber
Wet scrubber
Combined system
Maximum fabric filter inlet temperature .....
All 1 ...................
PM, CO, CDD/
CDF.
CDD/CDF .........
All 1 ...................
PM, CO, CDD/
CDF.
...........................
All 1 ...................
PM, CO, CDD/
CDF.
CDD/CDF .........
Minimum CDD/CDF sorbent flow rate .......
CDD/CDF .........
...........................
CDD/CDF .........
Semi-continuous dioxin monitoring system
(SCDMS).
SCDMS and multi-metals CEMS or Hg
CEMS.
Minimum Hg sorbent flow rate ...................
Minimum HCl sorbent flow rate .................
Minimum scrubber pressure drop/ horsepower amperage.
Minimum scrubber liquor flow rate .............
Hg .....................
HCl ...................
...........................
...........................
...........................
PM ....................
Hg.
HCl ....................
PM ....................
HCl CEMS.
PM CEMS.
...........................
...........................
...........................
HCl, PM, Cd,
Pb, Hg, CDD/
CDF.
HCl ....................
...........................
HCl CEMS, PM CEMS,
CEMS, and SCDMS.
Minimum scrubber liquor pH ......................
Maximum flue gas temperature (wet
scrubber outlet).
Do not use bypass stack (except during
startup, shutdown, and malfunction).
Air pollution control device inspections ......
HCl, PM, Cd,
Pb, Hg, CDD/
CDF.
HCl ...................
Hg .....................
All 1 ...................
All 1 ...................
All 1 ...................
None.
All 1 ...................
All 1 ...................
All 1 ...................
None.
Maximum charge rate ................................
Minimum secondary chamber temperature
None.
CO CEMS 2.
multi-metals
HCl CEMS.
Hg CEMS or multi-metals CEMS.
1 ‘‘All’’
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pollutants designation does not include SO2 and NOX, which are regulated at combustion-controlled levels (no add-on controls) and
have no associated parameter monitoring.
2 Optional method for existing and 1997 NSPS sources; required for new sources.
Table 17 of this preamble presents a
summary of the HMIWI test methods
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and approved alternative compliance
methods.
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TABLE 17.—SUMMARY OF HMIWI TEST METHODS AND APPROVED ALTERNATIVE METHODS
Pollutant/parameter
Test method(s) 1
Approved alternative method(s)
Comments
PM .........................................................
Method 5, Method
29.
Method 10 .............
PM CEMS .............................................
HCl CEMS ............................................
Cd ..........................................................
Pb ..........................................................
Hg ..........................................................
Method 26 or
Method 26A.
Method 29 .............
Method 29 .............
Method 29 .............
PM CEMS are optional for all sources
in lieu of annual PM test.
CO CEMS are optional for existing and
1997 NSPS sources in lieu of annual
CO test; CO CEMS are required for
new sources.
HCl CEMS are optional for all sources
in lieu of annual HCl test.
CDD/CDF ..............................................
Method 23 .............
Opacity ..................................................
Method 22 .............
Flue and exhaust gas analysis .............
Method 3, 3A, or
3B.
Method 22 .............
CO .........................................................
HCl .........................................................
Opacity from ash handling ....................
1 EPA
Multi-metals CEMS.
Multi-metals CEMS.
ASTM D6784–02, multi-metals CEMS
or Hg CEMS.
Semi-continuous dioxin monitoring system.
Bag leak detection system or PM
CEMS.
Bag leak detection systems are optional for existing and 1997 NSPS
sources; and are required for new
sources.
ASME PTC 19–10–1981 Part 10.
None.
Reference Methods in appendix A of 40 CFR part 60.
V. Impacts of the Proposed Action for
Existing Units
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CO CEMS .............................................
The emission limits for existing
HMIWI that we are proposing as part of
this action are based on the actual
performance of the MACT control
technologies. This proposed action is
expected to result in modest
improvements in performance being
required by HMIWI that are not
achieving the performance levels
demonstrated in practice by the control
technologies currently being used in the
industry. Based on compliance test
reports from all existing operating
HMIWI (72 units at 67 facilities)
following MACT compliance in
September 2002, 18 existing large
HMIWI and 4 existing medium HMIWI
are likely to find it necessary to improve
performance of their units in order to
achieve the proposed emission limits
which their compliance test data
indicates they would not meet. The
modest improvements anticipated
include adding lime (for SO2),
increasing lime use (for HCl and SO2),
increasing natural gas use (for CO and
CDD/CDF), and increasing scrubber
horsepower (for Pb, Cd, and Hg).
Facilities may resubmit previous
compliance test data that indicates that
their HMIWI meets the proposed
emission limits if the facility certifies
that the test results are representative of
current operations. Those facilities
would then not be required to test for
those pollutants to prove compliance
with the emission limits.
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A. What are the primary air impacts?
As a result of the modest
improvements estimated to be required
at 22 HMIWI such that they would
achieve the proposed emission limits,
EPA estimates that a total of
approximately 24,700 pounds per year
(lb/yr) of the regulated pollutants would
be reduced. Approximate reductions by
pollutant follow:
• HCl—20,600 lb/yr
• CO—400 lb/yr
• Pb—35 lb/yr
• Cd—3 lb/yr
• Hg—30 lb/yr
• PM—2,700 lb/yr
• CDD/CDF—0.0007 lb/yr
• NOX—200 lb/yr
• SO2—700 lb/yr
B. What are the water and solid waste
impacts?
EPA estimates that approximately 80
tpy of additional solid waste and
267,000 gallons per year of additional
wastewater would be generated as a
result of the increase of lime use by
some facilities.
C. What are the energy impacts?
EPA estimates that approximately
3,600 megawatt-hours per year of
additional electricity would be required
to support the increase in scrubber
horsepower that we estimate would be
required to enable some facilities to
achieve the proposed emission limits.
D. What are the secondary air impacts?
Secondary air impacts associated with
this proposed action are direct impacts
that result from the increase in natural
gas use and/or wet scrubber horsepower
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that we estimate may be required to
enable some facilities to achieve the
proposed emission limits. We estimate
that the adjustments could result in
emissions of 211 lb/yr of PM; 1,880 lb/
yr of CO; 1,230 lb/yr of NOX; and 1,450
lb/yr of SO2 from the increased
electricity and natural gas usage.
E. What are the cost and economic
impacts?
EPA estimates that the national total
costs for the 72 existing HMIWI and 4
1997 NSPS HMIWI to comply with this
proposed action would be
approximately $488,000 in the first year
of compliance. This estimate includes
the costs that would be incurred by the
22 HMIWI that we anticipate needing to
improve performance (i.e., costs of
improvements in emissions control and
emissions tests for pollutants for which
the improvements are made), and the
additional monitoring (i.e., annual
control device inspections), testing (i.e.
initial Method 22 test), and
recordkeeping and reporting costs that
would be incurred by all 76 HMIWI as
a result of this proposed action.
Approximately 50 percent of the
estimated total cost in the first year is
for emissions control, 11 percent is for
monitoring, 32 percent is for testing,
and 7 percent is for recordkeeping and
reporting. National total costs for
subsequent years are estimated to be
approximately $308,000 per year, with
approximately 78 percent of the total
cost for emissions control, 18 percent
for monitoring, and 3 percent for testing.
Economic impact analyses focus on
changes in market prices and output
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levels. If changes in market prices and
output levels in the primary markets are
significant enough, impacts on other
markets are also examined. EPA’s
economic impact analysis for this
proposed action assessed the magnitude
of the cost of market changes resulting
from the proposed amendments by
comparing annualized costs to annual
sales. We were able to assess the cost of
market changes for 70 HMIWI (sales
information was unavailable for the
other 6 units). For purposes of assessing
economic impacts of the proposed
action, the total annualized cost of this
proposed action is estimated to be
$328,000 and was determined by first
annualizing at 7 percent over 15 years
the difference between the first year
costs and subsequent year costs for each
of the 76 HMIWI, and adding to that
value the subsequent year costs for each
HMIWI; followed by then combining the
annualized costs for the 76 HMIWI. The
$328,000 was distributed among the 76
HMIWI, resulting in cost-to-sales ratios
ranging from 0.0006 percent to 0.06
percent, with an average cost-to-sales
ratio of 0.003 percent. Because of the
small size of these regulatory costs and
estimated impacts, no additional market
analysis is needed. Neither the modest
national costs nor the facility level costs
are anticipated to significantly impact
any market.
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VI. Impacts of the Proposed Action for
New Units
The current NSPS apply to HMIWI for
which construction began after June 20,
1996, or for which modification began
after March 16, 1998. There are three
new HMIWI and one modified HMIWI
that are subject to the current NSPS. No
additional units have become subject to
the NSPS since 2002. Considering this
information, EPA does not anticipate
any new HMIWI, and, therefore, no
impacts of the proposed standards for
new units. However, in the unlikely
event that a new HMIWI is constructed,
we are proposing new emission limits
for those units based on performance of
the control technology upon which
current NSPS limits are based, as well
as additional monitoring requirements,
including use of CO CEMS and use of
bag leak detection systems for fabric
filters. Because EPA does not anticipate
any new HMIWI, we, therefore, do not
expect there to be any air impacts, water
or solid waste impacts, energy impacts,
or cost or economic impacts associated
with the proposed standards for new
sources.
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VII. Relationship of the Proposed
Action to Section 112(c)(6) of the CAA
Section 112(c)(6) of the CAA requires
EPA to identify categories of sources of
seven specified pollutants to assure that
sources accounting for not less than 90
percent of the aggregate emissions of
each such pollutant are subject to
standards under CAA section 112(d)(2)
or 112(d)(4). EPA has identified medical
waste incinerators as a source category
that emits five of the seven CAA section
112(c)(6) pollutants: Polycyclic organic
matter (POM), dioxins, furans, Hg, and
polychlorinated biphenyls (PCBs). (The
POM emitted by HMIWI is composed of
16 polyaromatic hydrocarbons (PAH)
and extractable organic matter (EOM).)
In the Federal Register notice Source
Category Listing for Section 112(d)(2)
Rulemaking Pursuant to Section
112(c)(6) Requirements, 63 FR 17838,
17849, Table 2 (1998), EPA identified
medical waste incinerators (now
referred to as HMIWI) as a source
category ‘‘subject to regulation’’ for
purposes of CAA section 112(c)(6) with
respect to the CAA section 112(c)(6)
pollutants that HMIWI emit. HMIWI are
solid waste incineration units currently
regulated under CAA section 129. For
purposes of CAA section 112(c)(6), EPA
has determined that standards
promulgated under CAA section 129 are
substantively equivalent to those
promulgated under CAA section 112(d).
(See Id. at 17845; see also 62 FR 33625,
33632 (1997).) As discussed in more
detail below, the CAA section 129
standards effectively control emissions
of the five identified CAA section
112(c)(6) pollutants. Further, since CAA
section 129(h)(2) precludes EPA from
regulating these substantial sources of
the five identified CAA section 112(c)(6)
pollutants under CAA section 112(d),
EPA cannot further regulate these
emissions under that CAA section. As a
result, EPA considers emissions of these
five pollutants from HMIWI units
‘‘subject to standards’’ for purposes of
CAA section 112(c)(6).
As required by the statute, the CAA
section 129 HMIWI standards include
numeric emission limitations for the
nine pollutants specified in that section.
The combination of good combustion
practices and add-on air pollution
control equipment (dry sorbent injection
fabric filters, wet scrubbers, or
combined fabric filter and wet scrubber
systems) effectively reduces emissions
of the pollutants for which emission
limits are required under CAA section
129: Hg, CDD/CDF, Cd, Pb, PM, SO2,
HCl, CO, and NOX. Thus, the NSPS and
emissions guidelines specifically
require reduction in emissions of three
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of the CAA section 112(c)(6) pollutants:
Dioxins, furans, and Hg. As explained
below, the air pollution controls
necessary to comply with the
requirements of the HMIWI NSPS and
emission guidelines also effectively
reduce emissions of the following CAA
section 112(c)(6) pollutants that are
emitted from HMIWI units: POM and
PCBs. Although the CAA section 129
HMIWI standards do not have separate,
specific emissions standards for PCBs
and POM, emissions of these two CAA
section 112(c)(6) pollutants are
effectively controlled by the same
control measures used to comply with
the numerical emissions limits for the
enumerated CAA section 129 pollutants.
Specifically, as byproducts of
combustion, the formation of PCBs and
POM is effectively reduced by the
combustion and post-combustion
practices required to comply with the
CAA section 129 standards. Any PCBs
and POM that do form during
combustion are further controlled by the
various post-combustion HMIWI
controls. The add-on PM control
systems (either fabric filter or wet
scrubber) and activated carbon injection
in the fabric filter-based systems further
reduce emissions of these organic
pollutants, as well as reducing Hg
emissions. The post-MACT compliance
tests at currently operating HMIWI show
that the HMIWI MACT regulations
reduced Hg emissions by greater than 80
percent and CDD/CDF emissions by
about 90 percent from pre-MACT levels.
In light of the fact that similar controls
have been demonstrated to effectively
reduce emissions of POM and PCBs
from another incineration source
category (municipal solid waste
combustors), it is, therefore, reasonable
to conclude that POM and PCB
emissions are substantially reduced at
all 76 HMIWI. Thus, while the proposed
rule does not identify specific limits for
POM and PCB, they are, for the reasons
noted above, nonetheless ‘‘subject to
regulation’’ for purposes of section
112(c)(6) of the CAA.
VIII. Statutory and Executive Order
Reviews
A. Executive Order 12866: Regulatory
Planning and Review
Under Executive Order 12866 (58 FR
51735; October 4, 1993), this proposed
action is a ‘‘significant regulatory
action’’ because it is likely to raise novel
legal or policy issues arising out of legal
mandates, the President’s priorities, or
the principles set forth in the Executive
Order. Accordingly, EPA submitted this
proposed action to the Office of
Management and Budget (OMB) for
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jlentini on PROD1PC65 with PROPOSAL2
review under Executive Order 12866,
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 associated with this
proposed action are included in the
information collection requirements
addressing the HMIWI standards in
their entirety, which have been
submitted for approval to the OMB
under the Paperwork Reduction Act, 44
U.S.C. 3501 et seq. The Information
Collection Request (ICR) documents
prepared by EPA have been assigned
EPA ICR number 1899.04 for subpart Ce
and 1730.05 for subpart Ec.
The requirements in this proposed
action result in industry recordkeeping
and reporting burden associated with
review of the amendments for all
HMIWI, initial EPA Method 22 testing
for all HMIWI, annual inspections of
scrubbers and fabric filters for all
HMIWI, and stack testing and
development of new parameter limits
for HMIWI that need to make
performance improvements. The total
nationwide recordkeeping and reporting
burden of this proposed action is
estimated at 722 hours at a cost of
approximately $32,800. This burden
and cost would only be applicable once.
After that, the total nationwide
recordkeeping and reporting burden and
costs would be $0 (above and beyond
current burden and costs).
The annual average burden associated
with the emission guidelines over the
first 3 years following promulgation of
this proposed action is estimated to be
49,878 hours at a total annual labor cost
of $2,433,045. The total annualized
capital/startup costs and operation and
maintenance (O&M) costs associated
with the monitoring requirements, EPA
Method 22 testing, storage of data and
reports, and photocopying and postage
over the 3-year period of the ICR are
estimated at $407,953 and $333,258 per
year, respectively. (The annual
inspection costs are included under the
recordkeeping and reporting labor
costs.) The annual average burden
associated with the NSPS over the first
3 years following promulgation of this
proposed action is estimated to be 2,004
hours at a total annual labor cost of
$91,011. The total annualized capital/
startup costs are estimated at $13,046,
with total operation and maintenance
costs of $36,310 per year.
Burden means the total time, effort, or
financial resources expended by persons
to generate, maintain, retain, or disclose
or provide information to or for a
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Federal agency. This includes the time
needed to review instructions; develop,
acquire, install, and utilize technology
and systems for the purposes of
collecting, validating, and verifying
information, processing and
maintaining information, and disclosing
and providing information; adjust the
existing ways to comply with any
previously applicable instructions and
requirements; train personnel to be able
to respond to a collection of
information; search data sources;
complete and review the collection of
information; and transmit or otherwise
disclose the information.
An Agency may not conduct or
sponsor, and a person is not required to
respond to a collection of information
unless it displays a currently valid OMB
control number. The OMB control
numbers for EPA’s regulations are listed
in 40 CFR part 9.
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, including the use of
automated collection techniques, EPA
has established a public docket for this
action, which includes these ICR
documents, under Docket ID No. EPA–
HQ–OAR–2006–0534. Submit any
comments related to the ICR documents
for this proposed action to EPA and
OMB. See ADDRESSES section at the
beginning of this notice for where to
submit comments to 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 EPA.
Since OMB is required to make a
decision concerning the ICR between 30
and 60 days after February 6, 2007, a
comment to OMB is best assured of
having its full effect if OMB receives it
by March 8, 2007. The final action 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 Procedures Act or any
other statute unless the agency certifies
that the proposed action will not have
a significant economic impact on a
substantial number of small entities.
Small entities include small businesses,
small government organizations, and
small government jurisdictions.
For purposes of assessing the impacts
of this proposed action on small
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5541
entities, small entity is defined as
follows: (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; or (3) a
small organization that is any not-forprofit enterprise that is independently
owned and operated and is not
dominant in its field.
After considering the economic
impacts of this proposed action on small
entities, I certify that this action will not
have a significant economic impact on
a substantial number of small entities.
Because none of the HMIWI facilities
are expected to be significantly
impacted by this proposed action, that
also means that none of the four small
entity-owned facilities would be
expected to be significantly impacted.
None of the 22 HMIWI that we estimate
would need to make improvements in
order to meet the proposed emission
limits are owned by small entities. The
only estimated economic impacts on
small entities would result from the
additional monitoring requirements
(annual control device inspections),
testing requirements (one-time EPA
Method 22 testing), and associated
recordkeeping and reporting
requirements of this proposed action.
We continue to be interested in the
potential impacts of this proposed
action on small entities and welcome
comments on issues related to such
impacts.
D. Unfunded Mandates Reform Act
Title II of the Unfunded Mandates
Reform Act (UMRA) of 1995, Public
Law 104–4, establishes requirements for
Federal agencies to assess the effects of
their regulatory actions on State, local,
and Tribal governments and the private
sector. Under section 202 of the UMRA,
EPA generally must prepare a written
statement, including a cost-benefit
analysis, for proposed and final rules
with ‘‘Federal mandates’’ that may
result in expenditures by State, local,
and Tribal governments, in the
aggregate, or by the private sector, of
$100 million or more in any 1 year.
Before promulgating an EPA rule for
which a written statement is needed,
section 205 of the UMRA generally
requires EPA to identify and consider a
reasonable number of regulatory
alternatives and adopt the least costly,
most cost-effective, or least burdensome
alternative that achieves the objectives
of the proposed rule. The provisions of
section 205 do not apply when they are
inconsistent with applicable law.
Moreover, section 205 allows EPA to
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adopt an alternative other than the least
costly, most cost-effective, or least
burdensome alternative if EPA
publishes with the final rule an
explanation why that alternative was
not adopted.
Before EPA establishes any regulatory
requirements that may significantly or
uniquely affect small governments,
including Tribal governments, EPA
must develop a small government
agency plan under section 203 of the
UMRA. The plan must provide for
notifying potentially affected small
governments, enabling officials of
affected small governments to have
meaningful and timely input in the
development of EPA’s regulatory
proposals with significant Federal
intergovernmental mandates, and
informing, educating, and advising
small governments on compliance with
the regulatory requirements.
EPA has determined that this
proposed action does not contain a
Federal mandate that may result in
expenditures of $100 million or more
for State, local, and Tribal governments,
in the aggregate, or the private sector in
any 1 year. Thus, this proposed action
is not subject to the requirements of
section 202 and 205 of the UMRA. In
addition, EPA has determined that this
proposed action contains no regulatory
requirements that might significantly or
uniquely affect small governments.
Therefore, this proposed action is not
subject to the requirements of section
203 of the UMRA.
E. Executive Order 13132: Federalism
Executive Order 13132 (64 FR 43255;
August 10, 1999), requires EPA to
develop an accountable process to
ensure ‘‘meaningful and timely input by
State and local officials in the
development of regulatory policies that
have federalism implications.’’ ‘‘Policies
that have federalism implications’’ are
defined in the Executive Order to
include regulations that have
‘‘substantial direct effects on the States,
on the relationship between the national
government and the States, or on the
distribution of power and
responsibilities among the various
levels of government.’’ This proposed
action does not have federalism
implications. It will not have substantial
direct effects on the States, on the
relationship between the national
government and the States, or on the
distribution of power and
responsibilities among the various
levels of government, as specified in
Executive Order 13132. This proposed
action will not impose substantial direct
compliance costs on State or local
governments, and will not preempt
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State law. Thus, Executive Order 13132
does not apply to this proposed action.
In the spirit of Executive Order 13132,
and consistent with EPA policy to
promote communications between EPA
and State and local governments, EPA
specifically solicits comment on this
proposed action from State and local
officials.
F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
Executive Order 13175, (65 FR 67249;
November 9, 2000), requires EPA to
develop an accountable process to
ensure ‘‘meaningful and timely input by
Tribal officials in the development of
regulatory policies that have Tribal
implications.’’
This proposed action does not have
Tribal implications, as specified in
Executive Order 13175. It will not have
substantial direct effects on Tribal
governments, on the relationship
between the Federal government and
Indian tribes, or on the distribution of
power and responsibilities between the
Federal government and Indian tribes,
as specified in Executive Order 13175.
EPA is not aware of any HMIWI owned
or operated by Indian Tribal
governments. Thus, Executive Order
13175 does not apply to this proposed
action.
G. Executive Order 13045: Protection of
Children From Environmental Health
and Safety Risks
Executive Order 13045 (62 FR 19885;
April 23, 1997), applies to any rule that:
(1) Is determined to be ‘‘economically
significant’’ as defined under Executive
Order 12866, and (2) concerns an
environmental health or safety risk that
EPA has reason to believe may have a
disproportionate effect on children. If
the regulatory action meets both criteria,
EPA must evaluate the environmental
health or safety effects of the planned
rule on children, and explain why the
planned regulation is preferable to other
potentially effective and reasonably
feasible alternatives EPA considered.
EPA interprets Executive Order 13045
as applying only to those regulatory
actions that are based on health or safety
risks, such that the analysis required
under section 5–501 of the Executive
Order has the potential to influence the
regulation. This proposed action is not
subject to Executive Order 13045
because it is based on technology
performance and not on health and
safety risks.
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H. Executive Order 13211: Actions That
Significantly Affect Energy Supply,
Distribution or Use
This proposed action is not a
‘‘significant energy action’’ as defined in
Executive Order 13211, ‘‘Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use’’ (66 FR 28355; May
22, 2001) because it is not likely to have
a significant adverse effect on the
supply, distribution, or use of energy.
EPA estimates that the requirements in
this proposed action would cause some
HMIWI to increase the horsepower of
their wet scrubbers, resulting in
approximately 3,600 megawatt-hours
per year of additional electricity being
used.
Given the negligible change in energy
consumption resulting from this
proposed action, EPA does not expect
any price increase for any energy type.
The cost of energy distribution should
not be affected by this proposed action
at all since the action would not affect
energy distribution facilities. We also
expect that there would be no impact on
the import of foreign energy supplies,
and no other adverse outcomes are
expected to occur with regard to energy
supplies.
I. National Technology Transfer
Advancement Act
Section 12(d) of the National
Technology Transfer and Advancement
Act (NTTAA) of 1995 (Pub. L. 104–113,
Section 12(d), 15 U.S.C. 272 note)
directs EPA to use voluntary consensus
standards (VCS) in its regulatory
activities, unless to do so would be
inconsistent with applicable law or
otherwise impractical. The VCS are
technical standards (e.g., materials
specifications, test methods, sampling
procedures, and business practices) that
are developed or adopted by VCS
bodies. The NTTAA directs EPA to
provide Congress, through OMB,
explanations when the Agency does not
use available and applicable VCS.
This proposed action involves
technical standards. EPA cites the
following standards: EPA Methods 1, 3,
3A, 3B, 5, 9, 10, 10B, 22, 23, 26, 26A,
and 29 in 40 CFR part 60, appendix A.
Consistent with the NTTAA, EPA
conducted searches to identify
voluntary consensus standards in
addition to these EPA methods. No
applicable voluntary consensus
standards were identified for EPA
Methods 9 and 22. The search and
review results are in the docket for this
proposed action.
Two voluntary consensus standards
were identified as acceptable
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alternatives to EPA test methods for the
purposes of this proposed action. The
voluntary consensus standard ASME
PTC 19–10–1981–Part 10, ‘‘Flue and
Exhaust Gas Analyses,’’ is cited in the
proposed action for its manual method
for measuring the oxygen content of
exhaust gas. This part of ASME PTC 19–
10–1981–Part 10 is an acceptable
alternative to EPA Method 3B.
The voluntary consensus standard
ASTM D6784–02, ‘‘Standard Test
Method for Elemental, Oxidized,
Particle-Bound and Total Mercury Gas
Generated from Coal-Fired Stationary
Sources (Ontario Hydro Method),’’ is an
acceptable alternative to EPA Method 29
(portion for mercury only) as a method
for measuring Hg.
The search for emissions
measurement procedures identified 16
other voluntary consensus standards.
EPA determined that these 16 standards
identified for measuring emissions of
the pollutants subject to emission
standards in this proposed action were
impractical alternatives to EPA test
methods for the purposes of this action.
Therefore, EPA does not intend to adopt
these standards for this purpose. A
document that discusses the
determinations for these 16 methods is
located in the docket to this proposed
action.
Section 60.56c of subpart Ec of 40
CFR part 60 and § 60.37e of subpart Ce
of 40 CFR part 60 list the testing
methods included in the proposed
action. Under 40 CFR 60.8(b) and
60.13(i) of subpart A (General
Provisions), a source may apply to EPA
for permission to use alternative test
methods or alternative monitoring
requirements in place of any required
testing methods, performance
specifications, or procedures.
List of Subjects in 40 CFR Part 60
Environmental protection,
Administrative practice and procedure,
Air pollution control, Intergovernmental
relations, Reporting and recordkeeping
requirements.
jlentini on PROD1PC65 with PROPOSAL2
Dated: January 26, 2007.
Stephen L. Johnson,
Administrator.
For the reasons stated in the
preamble, title 40, chapter I, part 60 of
the Code of Federal Regulations is
proposed to be amended as follows:
PART 60—[AMENDED]
1. The authority citation for part 60
continues to read as follows:
Authority: 42 U.S.C. 7401, et seq.
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Subpart Ce—[Amended]
2. Section 60.32e is amended by
revising paragraphs (a) and (i) to read as
follows:
§ 60.32e
Designated facilities.
(a) Except as provided in paragraphs
(b) through (h) of this section, the
designated facility to which the
guidelines apply is each individual
HMIWI for which construction was
commenced on or before June 20, 1996
and each individual HMIWI currently
subject to subpart Ec as promulgated in
1997 (for which construction was
commenced after June 20, 1996 but no
later than February 6, 2007 or for which
modification commenced after March
16, 1998 but no later than 6 months after
the date of promulgation of this
subpart).
*
*
*
*
*
(i) Beginning 3 years after the date of
promulgation of this subpart, or on the
effective date of an EPA approved
operating permit program under Clean
Air Act title V and the implementing
regulations under 40 CFR part 70 in the
State in which the unit is located,
whichever date is later, designated
facilities subject to this subpart shall
operate pursuant to a permit issued
under the EPA-approved operating
permit program.
3. Section 60.33e is amended by
revising paragraph (b) to read as follows:
§ 60.33e
Emission guidelines.
*
*
*
*
*
(b) For approval, a State plan shall
include the requirements for emission
limits at least as protective as those
requirements listed in Table 2 of this
subpart for any small HMIWI
constructed on or before June 20, 1996
which is located more than 50 miles
from the boundary of the nearest
Standard Metropolitan Statistical Area
(defined in § 60.31e) and which burns
less than 2,000 pounds per week of
hospital waste and medical/infectious
waste. The 2,000 lb/week limitation
does not apply during performance
tests.
*
*
*
*
*
4. Section 60.36e is amended by
adding paragraphs (c) and (d) to read as
follows:
§ 60.36e
Inspection guidelines.
*
*
*
*
*
(c) For approval, a State plan shall
require that each HMIWI subject to the
emission limits under § 60.33e(a)
undergo an initial air pollution control
device inspection that is at least as
protective as the following within 1 year
following approval of the State plan:
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5543
(1) At a minimum, an inspection shall
include the following:
(i) Inspect air pollution control
device(s) for proper operation, if
applicable;
(ii) Ensure proper calibration of
thermocouples, sorbent feed systems,
and any other monitoring equipment;
and
(iii) Generally observe that the
equipment is maintained in good
operating condition.
(2) Within 10 operating days
following an air pollution control device
inspection, all necessary repairs shall be
completed unless the owner or operator
obtains written approval from the State
agency establishing a date whereby all
necessary repairs of the designated
facility shall be completed.
(d) For approval, a State plan shall
require that each HMIWI subject to the
emission limits under § 60.33e(a)
undergo an air pollution control device
inspection annually (no more than 12
months following the previous annual
air pollution control device inspection),
as outlined in paragraphs (c)(1) and (2)
of this section.
5. Section 60.37e is amended by
revising paragraphs (a) and (b)(1) and
adding paragraph (e) to read as follows:
§ 60.37e Compliance, performance testing,
and monitoring guidelines.
(a) Except as provided in paragraph
(b) of this section, for approval, a State
plan shall include the requirements for
compliance and performance testing
listed in § 60.56c of subpart Ec of this
part, excluding the fugitive emissions
annual testing requirement under
§ 60.56c(c)(3), the CO CEMS
requirements under § 60.56c(c)(5), and
the bag leak detection system
requirements under § 60.57c(g). Sources
may, however, elect to use CO CEMS as
specified under § 60.56c(c)(5) or bag
leak detection systems as specified
under § 60.57c(g).
(b) * * *
(1) Conduct the performance testing
requirements in § 60.56c(a), (b)(1)
through (b)(9), (b)(11) (Hg only), (b)(12),
and (c)(1) of subpart Ec of this part. The
2,000 lb/week limitation under
§ 60.33e(b) does not apply during
performance tests.
*
*
*
*
*
(e) The owner or operator of a
designated facility may use the results
of previous emissions tests to
demonstrate compliance with the
emission limits, provided that the
conditions in paragraphs (e)(1) through
(e)(3) of this section are met:
(1) The previous emissions tests must
have been conducted using the
applicable procedures and test methods
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listed in § 60.56c(b)(1) through (b)(9),
(b)(11) (Hg only), and (b)(12). Previous
emissions test results obtained using
EPA-accepted voluntary consensus
standards are also acceptable.
(2) The HMIWI at the affected facility
shall be operated in a manner (e.g., with
charge rate, secondary chamber
temperature, etc.) that would be
expected to result in the same or lower
emissions than observed during the
previous emissions test(s), and the
HMIWI may not have been modified
such that emissions would be expected
to exceed (notwithstanding normal testto-test variability) the results from
previous emissions test(s).
(3) The previous emissions test(s)
must have been conducted in 1997 or
later.
6. Section 60.38e is amended by
revising paragraph (a) and adding
paragraph (c) to read as follows:
§ 60.38e Reporting and recordkeeping
guidelines.
(a) For approval, a State plan shall
include the reporting and recordkeeping
requirements listed in § 60.58c(b), (c),
(d), (e), and (f) of subpart Ec of this part,
excluding § 60.58c(b)(7) (siting).
*
*
*
*
*
(c) For approval, a State plan shall
require the owner or operator of each
HMIWI subject to the emission limits
under § 60.33e(a) to:
(1) Maintain records of the annual air
pollution control device inspections,
any required maintenance, and any
repairs not completed within 10 days of
an inspection or the timeframe
established by the State regulatory
agency; and
(2) Submit an annual report
containing information recorded under
paragraph (c)(1) of this section no later
than 60 days following the year in
which data were collected. Subsequent
reports shall be sent no later than 12
calendar months following the previous
report (once the unit is subject to
permitting requirements under title V of
the Act, the owner or operator shall
submit these reports semiannually). The
report shall be signed by the facilities
manager.
7. Section 60.39e is amended as
follows:
a. By revising paragraph (a);
b. By revising paragraph (c)
introductory text;
c. By revising paragraph (d)(3); and
d. By revising paragraph (f).
§ 60.39e
Compliance times.
(a) Not later than 1 year after the date
of promulgation of this subpart, each
State in which a designated facility is
operating shall submit to the
Administrator a plan to implement and
enforce the emission guidelines.
*
*
*
*
*
(c) State plans that specify measurable
and enforceable incremental steps of
progress towards compliance for
designated facilities planning to install
the necessary air pollution control
equipment may allow compliance on or
before the date 3 years after EPA
approval of the State plan (but not later
than 5 years after the date of
promulgation of this subpart). Suggested
measurable and enforceable activities to
be included in State plans are:
*
*
*
*
*
(d) * * *
(3) If an extension is granted, require
compliance with the emission
guidelines on or before the date 3 years
after EPA approval of the State plan (but
not later than 5 years after the date of
promulgation of this subpart).
*
*
*
*
*
(f) The Administrator shall develop,
implement, and enforce a plan for
existing HMIWI located in any State that
has not submitted an approvable plan
within 2 years after the date of
promulgation of this subpart. Such
plans shall ensure that each designated
facility is in compliance with the
provisions of this subpart no later than
5 years after the date of promulgation of
this subpart.
8. Table 1 to subpart Ce is revised to
read as follows:
TABLE 1 TO SUBPART CE.—EMISSION LIMITS FOR SMALL, MEDIUM, AND LARGE HMIWI
Emission limits
HMIWI size
Units
(7 percent oxygen, dry basis)
Pollutant
Small
Particulate matter .......
Carbon monoxide ......
Dioxins/furans ............
Hydrogen chloride ......
Sulfur dioxide .............
Nitrogen oxides ..........
Lead ...........................
Cadmium ....................
Mercury ......................
Milligrams per dry standard cubic meter (mg/
dscm) (grains per dry standard cubic foot
(gr/dscf)).
Parts per million by volume (ppmv) ...............
Nanograms per dry standard cubic meter
total dioxins/furans (ng/dscm) (grains per
billion dry standard cubic feet (gr/109
dscf)) or ng/dscm TEQ (gr/109 dscf).
ppmv or percent reduction .............................
Ppmv ................................................................
Ppmv ................................................................
mg/dscm (grains per thousand dry standard
cubic feet (gr/103 dscf)) or percent reduction.
mg/dscm (gr/103 dscf) or percent reduction ..
mg/dscm (gr/103 dscf) or percent reduction ..
Medium
Large
69 (0.030) ..................
69 (0.030) ..................
34 (0.015).
25 ...............................
115 (50) or 2.0 (0.87)
25 ...............................
115 (50) or 2.0 (0.87)
25.
115 (50) or 2.0 (0.87).
51 or 94% ..................
28 ...............................
212 .............................
0.64 (0.28) or 71% .....
51 or 94% ..................
28 ...............................
212 .............................
0.64 (0.28) or 71% .....
51 or 94%
28.
212.
0.64 (0.28) or 71%.
0.060 (0.026) or 74%
0.33 (0.14) or 96% .....
0.060 (0.026) or 74%
0.33 (0.14) or 96% .....
0.060 (0.026) or 74%.
0.33 (0.14) or 96%.
jlentini on PROD1PC65 with PROPOSAL2
9. Table 2 of subpart Ce is revised to
read as follows:
TABLE 2 TO SUBPART CE.—EMISSION LIMITS FOR SMALL HMIWI WHICH MEET THE CRITERIA UNDER § 60.33E(B)
Pollutant
Units
(7 percent oxygen, dry basis)
Particulate matter ................................
Carbon monoxide ................................
mg/dscm (gr/dscf) .............................................................................................
Ppmv ..................................................................................................................
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69 (0.030).
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5545
TABLE 2 TO SUBPART CE.—EMISSION LIMITS FOR SMALL HMIWI WHICH MEET THE CRITERIA UNDER § 60.33E(B)—
Continued
Pollutant
Units
(7 percent oxygen, dry basis)
Dioxins/furans ......................................
Hydrogen chloride ...............................
Sulfur dioxide ......................................
Nitrogen oxides ...................................
Lead ....................................................
Cadmium .............................................
Mercury ...............................................
ng/dscm total dioxins/furans (gr/109 dscf) or ng/dscm TEQ (gr/109 dscf) .......
ppmv or percent reduction ...............................................................................
Ppmv ..................................................................................................................
Ppmv ..................................................................................................................
mg/dscm (gr/103 dscf) or percent reduction ....................................................
mg/dscm (gr/103 dscf) or percent reduction ....................................................
mg/dscm (gr/103 dscf) or percent reduction ....................................................
Subpart Ec—[Amended]
10. Section 60.50c is amended by
revising paragraphs (a), (k) and (l) to
read as follows:
§ 60.50c Applicability and delegation of
authority.
jlentini on PROD1PC65 with PROPOSAL2
(a) Except as provided in paragraphs
(b) through (h) of this section, the
affected facility to which this subpart
applies is each individual hospital/
medical/infectious waste incinerator
(HMIWI):
(1) For which construction is
commenced after June 20, 1996 but no
later than February 6, 2007;
(2) For which modification is
commenced after March 16, 1998 but no
later than 6 months after the date of
promulgation of this subpart;
(3) For which construction is
commenced after February 6, 2007; or
(4) For which modification is
commenced after 6 months after the
date of promulgation of this subpart.
*
*
*
*
*
(k) The requirements of this subpart
shall become effective 6 months after
the date of promulgation of this subpart.
(l) Beginning 3 years after the date of
promulgation of this subpart, or on the
effective date of an EPA-approved
operating permit program under Clean
Air Act title V and the implementing
regulations under 40 CFR part 70 in the
State in which the unit is located,
whichever date is later, affected
facilities subject to this subpart shall
operate pursuant to a permit issued
under the EPA approved State operating
permit program.
11. Section 60.51c is amended by
adding a definition for ‘‘Bag leak
detection system’’ in alphabetical order
and revising the definition for
‘‘Minimum secondary chamber
temperature’’ to read as follows:
§ 60.51c
Definitions.
Bag leak detection system means an
instrument that is capable of monitoring
PM loadings in the exhaust of a fabric
filter in order to detect bag failures. A
bag leak detection system includes, but
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is not limited to, an instrument that
operates on triboelectric, lightscattering, light-transmittance, or other
effects to monitor relative PM loadings.
*
*
*
*
*
Minimum secondary chamber
temperature means 90 percent of the
highest 3-hour average secondary
chamber temperature (taken, at a
minimum, once every minute) measured
during the most recent performance test
demonstrating compliance with the PM,
CO, and dioxin/furan emission limits.
*
*
*
*
*
12. Section 60.52c is amended by
revising paragraph (c) to read as follows:
§ 60.52c
Emission limits.
*
*
*
*
*
(c) On and after the date on which the
initial performance test is completed or
is required to be completed under
§ 60.8, whichever date comes first, no
owner or operator of an affected facility
shall cause to be discharged into the
atmosphere visible emissions of
combustion ash from an ash conveying
system (including conveyor transfer
points) in excess of 5 percent of the
observation period (i.e., 9 minutes per 3hour period), as determined by EPA
Reference Method 22 of appendix A of
this part, except as provided in
paragraphs (d) and (e) of this section.
*
*
*
*
*
13. Section 60.56c is amended as
follows:
a. By revising paragraph (b)
introductory text;
b. By revising paragraphs (b)(4) and
(b)(6) through (b)(8), (b)(9) introductory
text, and (b)(10);
c. By revising paragraph (b)(11);
d. By revising paragraphs (c)(2)
through (4);
e. By adding paragraphs (c)(5), and
(c)(6);
f. By revising paragraph (d)
introductory text;
g. By adding paragraphs (e)(6) and (7);
h. By adding paragraphs (f)(7) through
(9);
i. By adding paragraphs (g)(6) through
(9); and
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HMIWI emission limits
800 (350) or 15 (6.6).
398.
28.
212.
0.60 (0.26).
0.050 (0.022).
0.25 (0.11).
j. By adding paragraph (k).
§ 60.56c
testing.
Compliance and performance
*
*
*
*
*
(b) Except as provided in paragraph
(k) of this section, the owner or operator
of an affected facility shall conduct an
initial performance test as required
under § 60.8 to determine compliance
with the emission limits using the
procedures and test methods listed in
paragraphs (b)(1) through (b)(12) of this
section. The use of the bypass stack
during a performance test shall
invalidate the performance test.
*
*
*
*
*
(4) EPA Reference Method 3, 3A, or
3B of appendix A of this part shall be
used for gas composition analysis,
including measurement of oxygen
concentration. EPA Reference Method 3,
3A, or 3B of appendix A of this part
shall be used simultaneously with each
of the other EPA reference methods. As
an alternative, ASME PTC–19–10–1981Part 10 may be used.
*
*
*
*
*
(6) EPA Reference Method 5 or 29 of
appendix A of this part shall be used to
measure the particulate matter
emissions. As an alternative, PM CEMS
may be used as specified in paragraph
(c)(4) of this section.
(7) EPA Reference Method 9 of
appendix A of this part shall be used to
measure stack opacity. As an
alternative, demonstration of
compliance with the PM standards
using bag leak detection systems as
specified in § 60.57c(g) or PM CEMS as
specified in paragraph (c)(4) of this
section is considered demonstrative of
compliance with the opacity
requirements.
(8) For affected facilities under
§ 60.50c(a)(1) and (a)(2), EPA Reference
Method 10 or 10B of appendix A of this
part shall be used to measure the CO
emissions. As an alternative, CO CEMS
may be used as specified in paragraph
(c)(4) of this section.
(9) EPA Reference Method 23 of
appendix A of this part shall be used to
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measure total dioxin/furan emissions.
As an alternative, an owner or operator
may elect to sample dioxins/furans by
installing, calibrating, maintaining, and
operating a continuous automated
sampling system for monitoring dioxin/
furan emissions as specified in
paragraph (c)(6) of this section. For
Method 23 sampling, the minimum
sample time shall be 4 hours per test
run. If the affected facility has selected
the toxic equivalency standards for
dioxins/furans, under § 60.52c, the
following procedures shall be used to
determine compliance:
*
*
*
*
*
(10) EPA Reference Method 26 or 26A
of appendix A of this part shall be used
to measure HCl emissions, with the
additional requirements for Method 26A
specified in paragraphs (b)(10)(i)
through (iii) of this section. As an
alternative, HCl CEMS may be used as
specified in paragraph (c)(4) of this
section. If the affected facility has
selected the percentage reduction
standards for HCl under § 60.52c, the
percentage reduction in HCl emission
(%RHCl) is computed using the
following formula:
(%RHCl) = (Ei¥Eo)/Ei × 100
jlentini on PROD1PC65 with PROPOSAL2
Where:
%RHCl=percentage reduction of HCl
emissions achieved;
Ei=HCl emission concentration measured at
the control device inlet, corrected to 7
percent oxygen (dry basis); and
Eo=HCl emission concentration measured at
the control device outlet, corrected to 7
percent oxygen (dry basis).
(i) The probe and filter shall be
conditioned prior to sampling using the
procedure described in paragraphs
(b)(10)(i)(A) through (C) of this section.
(A) Assemble the sampling train(s)
and conduct a conditioning run by
collecting between 14 liters per minute
(L/min)_(0.5 cubic feet per minute (ft 3/
min)) and 30 L/min (1.0 ft 3/min) of gas
over a 1-hour period. Follow the
sampling procedures outlined in section
8.1.5 of Method 26A of appendix A of
this part. For the conditioning run,
water may be used as the impinger
solution.
(B) Remove the impingers from the
sampling train and replace with a fresh
impinger train for the sampling run,
leaving the probe and filter (and
cyclone, if used) in position. Do not
recover the filter or rinse the probe
before the first run. Thoroughly rinse
the impingers used in the
preconditioning run with deionized
water and discard these rinses.
(C) The probe and filter assembly
shall be conditioned by the stack gas
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and shall not be recovered or cleaned
until the end of testing.
(ii) For the duration of sampling, a
temperature around the probe and filter
(and cyclone, if used) between 120 °C
(248 °F) and 134 °C (273 °F) shall be
maintained.
(iii) If water droplets are present in
the sample gas stream, the requirements
specified in paragraphs (b)(10)(iii)(A)
and (B) of this section shall be met.
(A) The cyclone described in section
6.1.4 of EPA Reference Method 26A of
appendix A of this part shall be used.
(B) The post-test moisture removal
procedure described in section 8.1.6 of
EPA Reference Method 26A of appendix
A of this part shall be used.
(11) EPA Reference Method 29 of
appendix A of this part shall be used to
measure Pb, Cd, and Hg emissions. As
an alternative, Hg emissions may be
measured using ASTM D6784–02. As an
alternative for Pb, Cd, and Hg, multimetals CEMS, or Hg CEMS, may be used
as specified in paragraph (c)(4) of this
section. If the affected facility has
selected the percentage reduction
standards for metals under § 60.52c, the
percentage reduction in emissions
(%Rmetal) is computed using the
following formula:
(%Rmetal) = (Ei¥Eo)/Ei × 100
Where:
%Rmetal=percentage reduction of metal
emission (Pb, Cd, or Hg) achieved;
Ei=metal emission concentration (Pb, Cd, or
Hg) measured at the control device inlet,
corrected to 7 percent oxygen (dry basis);
and
Eo=metal emission concentration (Pb, Cd, or
Hg) measured at the control device
outlet, corrected to 7 percent oxygen (dry
basis).
*
*
*
*
*
(c) * * *
(2) Except as provided in paragraphs
(c)(4) and (c)(5) of this section,
determine compliance with the PM, CO,
and HCl emission limits by conducting
an annual performance test (no more
than 12 months following the previous
performance test) using the applicable
procedures and test methods listed in
paragraph (b) of this section. If all three
performance tests over a 3-year period
indicate compliance with the emission
limit for a pollutant (PM, CO, or HCl),
the owner or operator may forego a
performance test for that pollutant for
the subsequent 2 years. At a minimum,
a performance test for PM, CO, and HCl
shall be conducted every third year (no
more than 36 months following the
previous performance test). If a
performance test conducted every third
year indicates compliance with the
emission limit for a pollutant (PM, CO,
or HCl), the owner or operator may
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forego a performance test for that
pollutant for an additional 2 years. If
any performance test indicates
noncompliance with the respective
emission limit, a performance test for
that pollutant shall be conducted
annually until all annual performance
tests over a 3-year period indicate
compliance with the emission limit. The
use of the bypass stack during a
performance test shall invalidate the
performance test.
(3) For large HMIWI under
§ 60.50c(a)(1) and (a)(2) and for all
HMIWI under § 60.50c(a)(3) and (a)(4),
determine compliance with the visible
emission limits for fugitive emissions
from flyash/bottom ash storage and
handling by conducting a performance
test using EPA Reference Method 22 on
an annual basis (no more than 12
months following the previous
performance test).
(4) Facilities using optional CEMS to
demonstrate compliance with the PM,
CO, HCl, Pb, Cd, and/or Hg emission
limits under § 60.52c shall:
(i) Determine compliance with the
appropriate emission limit(s) using a 24hour block average, calculated as
specified in section 12.4.1 of EPA
Reference Method 19 of appendix A of
this part.
(ii) Operate all CEMS in accordance
with the applicable procedures under
appendices B and F of this part. For
those CEMS for which performance
specifications have not yet been
promulgated (HCl, multi-metals), this
option takes effect on the date a final
performance specification is published
in the Federal Register or the date of
approval of a site-specific monitoring
plan.
(iii) Be allowed to substitute use of an
HCl CEMS for the HCl annual
performance test, minimum HCl sorbent
flow rate, and minimum scrubber liquor
pH to demonstrate compliance with the
HCl emission limit.
(iv) Be allowed to substitute use of a
PM CEMS for the PM annual
performance test and minimum pressure
drop across the wet scrubber, if
applicable, to demonstrate compliance
with the PM emission limit.
(v) Be allowed to substitute use of a
CO CEMS for the CO annual
performance test and minimum
secondary chamber temperature to
demonstrate compliance with the CO
emission limit.
(5) For affected facilities under
§ 60.50c(a)(3) and (a)(4), determine
compliance with the CO emission limit
using a CO CEMS according to
paragraphs (c)(5)(i) and (c)(5)(ii) of this
section:
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(i) Determine compliance with the CO
emission limit using a 24-hour block
average, calculated as specified in
section 12.4.1 of EPA Reference Method
19 of appendix A of this part.
(ii) Operate the CO CEMS in
accordance with the applicable
procedures under appendices B and F of
this part.
(iii) Use of a CO CEMS may be
substituted for the CO annual
performance test and minimum
secondary chamber temperature to
demonstrate compliance with the CO
emission limit.
(6) Facilities using a continuous
automated sampling system to
demonstrate compliance with the
dioxin/furan emission limits under
§ 60.52c shall record the output of the
system and analyze the sample using
EPA Reference Method 23 of appendix
A of this part. This option to use a
continuous automated sampling system
takes effect on the date a final
performance specification applicable to
dioxin/furan from monitors is published
in the Federal Register or the date of
approval of a site-specific monitoring
plan. The owner or operator of an
affected facility who elects to
continuously sample dioxin/furan
emissions instead of sampling and
testing using EPA Reference Method 23
shall install, calibrate, maintain, and
operate a continuous automated
sampling system and shall comply with
the requirements specified in
§ 60.58b(p) and (q) of subpart Eb of this
part.
(d) Except as provided in paragraphs
(c)(4), (c)(5), and (c)(6) of this section,
the owner or operator of an affected
facility equipped with a dry scrubber
followed by a fabric filter, a wet
scrubber, or a dry scrubber followed by
a fabric filter and wet scrubber shall:
*
*
*
*
*
(e) * * *
(6) For HMIWI under § 60.50c(a)(3)
and (a)(4), operation of the affected
facility above the CO emission limit as
measured by the CO CEMS shall
constitute a violation of the CO
emission limit.
(7) For HMIWI under § 60.50c(a)(3)
and (a)(4), failure to initiate corrective
action within 1 hour of a bag leak
detection system alarm; or failure to
operate and maintain the fabric filter
such that the alarm is not engaged for
more than 5 percent of the total
operating time in a 6-month block
reporting period shall constitute a
violation of the PM emission limit. If
inspection of the fabric filter
demonstrates that no corrective action is
required, no alarm time is counted. If
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corrective action is required, each alarm
is counted as a minimum of 1 hour. If
it takes longer than 1 hour to initiate
corrective action, the alarm time is
counted as the actual amount of time
taken to initiate corrective action. If the
bag leak detection system is used to
demonstrate compliance with the
opacity limit, this would also constitute
a violation of the opacity emission limit.
(f) * * *
(7) For HMIWI under § 60.50c(a)(3)
and (a)(4), operation of the affected
facility above the CO emission limit as
measured by the CO CEMS shall
constitute a violation of the CO
emission limit.
(8) For all HMIWI, operation of the
affected facility above the PM, CO, HCl,
Pb, Cd, and/or Hg emission limit as
measured by the CEMS specified in
paragraph (c)(4) of this section shall
constitute a violation of the applicable
emission limit.
(9) For all HMIWI, operation of the
affected facility above the CDD/CDF
emission limit as measured by the
continuous automated sampling system
specified in paragraph (c)(6) of this
section shall constitute a violation of the
CDD/CDF emission limit.
(g) * * *
(6) For HMIWI under § 60.50c(a)(3)
and (a)(4), operation of the affected
facility above the CO emission limit as
measured by the CO CEMS shall
constitute a violation of the CO
emission limit.
(7) For HMIWI under § 60.50c(a)(3)
and (a)(4), failure to initiate corrective
action within 1 hour of a bag leak
detection system alarm; or failure to
operate and maintain the fabric filter
such that the alarm is not engaged for
more than 5 percent of the total
operating time in a 6-month block
reporting period shall constitute a
violation of the PM emission limit. If
inspection of the fabric filter
demonstrates that no corrective action is
required, no alarm time is counted. If
corrective action is required, each alarm
is counted as a minimum of 1 hour. If
it takes longer than 1 hour to initiate
corrective action, the alarm time is
counted as the actual amount of time
taken to initiate corrective action. If the
bag leak detection system is used to
demonstrate compliance with the
opacity limit, this would also constitute
a violation of the opacity emission limit.
(8) For all HMIWI, operation of the
affected facility above the PM, CO, HCl,
Pb, Cd, and/or Hg emission limit as
measured by the CEMS specified in
paragraph (c)(4) of this section shall
constitute a violation of the applicable
emission limit.
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5547
(9) For all HMIWI, operation of the
affected facility above the CDD/CDF
emission limit as measured by the
continuous automated sampling system
specified in paragraph (c)(6) of this
section shall constitute a violation of the
CDD/CDF emission limit.
*
*
*
*
*
(k) The owner or operator of an
affected facility may use the results of
previous emissions tests to demonstrate
compliance with the emission limits,
provided that the conditions in
paragraphs (k)(1) through (k)(3) of this
section are met:
(1) The previous emissions tests shall
have been conducted using the
applicable procedures and test methods
listed in paragraph (b) of this section.
Previous emissions test results obtained
using EPA-accepted voluntary
consensus standards are also acceptable.
(2) The HMIWI at the affected facility
shall be operated in a manner (e.g., with
charge rate, secondary chamber
temperature, etc.) that would be
expected to result in the same or lower
emissions than observed during the
previous emissions test(s) and the
HMIWI may not have been modified
such that emissions would be expected
to exceed (notwithstanding normal testto-test variability) the results from
previous emissions test(s).
(3) The previous emissions test(s)
shall have been conducted in 1997 or
later.
14. Section 60.57c is amended as
follows:
a. By revising paragraph (a);
b. By adding paragraph (e);
c. By adding paragraph (f); and
d. By adding paragraph (g).
§ 60.57c
Monitoring requirements
(a) Except as provided in
§ 60.56c(c)(4) through (c)(6), the owner
or operator of an affected facility shall
install, calibrate (to manufacturers’
specifications), maintain, and operate
devices (or establish methods) for
monitoring the applicable maximum
and minimum operating parameters
listed in Table 3 to this subpart (unless
optional CEMS are used as a substitute
for certain parameters as specified) such
that these devices (or methods) measure
and record values for these operating
parameters at the frequencies indicated
in Table 3 at all times except during
periods of startup and shutdown.
*
*
*
*
*
(e) The owner or operator of an
affected facility shall ensure that each
HMIWI subject to the emission limits in
§ 60.52c undergoes an initial air
pollution control device inspection that
is at least as protective as the following:
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(1) At a minimum, an inspection shall
include the following:
(i) Inspect air pollution control
device(s) for proper operation, if
applicable;
(ii) Ensure proper calibration of
thermocouples, sorbent feed systems,
and any other monitoring equipment;
and
(iii) Generally observe that the
equipment is maintained in good
operating condition.
(2) Within 10 operating days
following an air pollution control device
inspection, all necessary repairs shall be
completed unless the owner or operator
obtains written approval from the
Administrator establishing a date
whereby all necessary repairs of the
designated facility shall be completed.
(f) The owner or operator of an
affected facility shall ensure that each
HMIWI subject to the emission limits
under § 60.52c undergoes an air
pollution control device inspection
annually (no more than 12 months
following the previous annual air
pollution control device inspection), as
outlined in paragraphs (e)(1) and (e)(2)
of this section.
(g) For affected facilities under
§ 60.50c(a)(3) and (a)(4) using an air
pollution control device that includes a
fabric filter and not using PM CEMS,
determine compliance with the PM
emission limit using a bag leak
detection system and meet the
requirements in paragraphs (g)(1)
through (g)(12) of this section for each
bag leak detection system. Affected
facilities under § 60.50c(a)(1) and (a)(2)
may elect to demonstrate continuous
compliance with the PM emission limit
using a bag leak detection system and
meet the requirements in paragraphs
(g)(1) through (g)(12) of this section.
(1) Each triboelectric bag leak
detection system shall be installed,
calibrated, operated, and maintained
according to the ‘‘Fabric Filter Bag Leak
Detection Guidance,’’ (EPA 454/R–98–
015, September 1997). This document is
available from the U.S. Environmental
Protection Agency (U.S. EPA); Office of
Air Quality Planning and Standards;
Sector Policies and Programs Division;
Measurement Policy Group (D–243–02),
Research Triangle Park, NC 27711. This
document is also available on the
Technology Transfer Network (TTN)
under Emission Measurement Center
Continuous Emission Monitoring. Other
types of bag leak detection systems shall
be installed, operated, calibrated, and
maintained in a manner consistent with
the manufacturer’s written
specifications and recommendations.
(2) The bag leak detection system
shall be certified by the manufacturer to
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be capable of detecting PM emissions at
concentrations of 10 milligrams per
actual cubic meter (0.0044 grains per
actual cubic foot) or less.
(3) The bag leak detection system
sensor shall provide an output of
relative PM loadings.
(4) The bag leak detection system
shall be equipped with a device to
continuously record the output signal
from the sensor.
(5) The bag leak detection system
shall be equipped with an audible alarm
system that will sound automatically
when an increase in relative PM
emissions over a preset level is detected.
The alarm shall be located where it is
easily heard by plant operating
personnel.
(6) For positive pressure fabric filter
systems, a bag leak detector shall be
installed in each baghouse compartment
or cell.
(7) For negative pressure or induced
air fabric filters, the bag leak detector
shall be installed downstream of the
fabric filter.
(8) Where multiple detectors are
required, the system’s instrumentation
and alarm may be shared among
detectors.
(9) The baseline output shall be
established by adjusting the range and
the averaging period of the device and
establishing the alarm set points and the
alarm delay time according to section
5.0 of the ‘‘Fabric Filter Bag Leak
Detection Guidance.’’
(10) Following initial adjustment of
the system, the sensitivity or range,
averaging period, alarm set points, or
alarm delay time may not be adjusted.
In no case may the sensitivity be
increased by more than 100 percent or
decreased more than 50 percent over a
365-day period unless such adjustment
follows a complete fabric filter
inspection that demonstrates that the
fabric filter is in good operating
condition. Each adjustment shall be
recorded.
(11) Record the results of each
inspection, calibration, and validation
check.
(12) Initiate corrective action within 1
hour of a bag leak detection system
alarm; operate and maintain the fabric
filter such that the alarm is not engaged
for more than 5 percent of the total
operating time in a 6-month block
reporting period. If inspection of the
fabric filter demonstrates that no
corrective action is required, no alarm
time is counted. If corrective action is
required, each alarm is counted as a
minimum of 1 hour. If it takes longer
than 1 hour to initiate corrective action,
the alarm time is counted as the actual
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amount of time taken to initiate
corrective action.
15. Section 60.58c is amended as
follows:
a. By adding paragraphs (b)(2)(xvi)
through (xviii);
b. By revising paragraph (b)(6);
c. By revising paragraph (c)
introductory text;
d. By revising paragraph (c)(2);
e. By adding paragraph (c)(4);
f. By revising paragraph (d)
introductory text;
g. By adding paragraphs (d)(9)
through (11); and
h. By adding paragraph (g).
§ 60.58c Reporting and recordkeeping
requirements.
*
*
*
*
*
(b) * * *
(2) * * *
(xvi) Records of the annual air
pollution control device inspections,
any required maintenance, and any
repairs not completed within 10 days of
an inspection or the timeframe
established by the Administrator.
(xvii) For affected facilities using a
bag leak detection system, records of
each alarm, the time of the alarm, the
time corrective action was initiated and
completed, and a brief description of the
cause of the alarm and the corrective
action taken.
(xviii) For affected facilities under
§ 60.50c(a)(3) and (a)(4), concentrations
of CO as determined by the continuous
emission monitoring system.
*
*
*
*
*
(6) The results of the initial, annual,
and any subsequent performance tests
conducted to determine compliance
with the emission limits and/or to
establish or re-establish operating
parameters, as applicable, and a
description of how the operating
parameters were established or reestablished, if applicable.
*
*
*
*
*
(c) The owner or operator of an
affected facility shall submit the
information specified in paragraphs
(c)(1) through (c)(4) of this section no
later than 60 days following the initial
performance test. All reports shall be
signed by the facilities manager.
*
*
*
*
*
(2) The values for the site-specific
operating parameters established
pursuant to § 60.56c(d) or § 60.56c(i), as
applicable, and a description of how the
operating parameters were established
during the initial performance test.
*
*
*
*
*
(4) For each affected facility that uses
a bag leak detection system, analysis
and supporting documentation
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demonstrating conformance with EPA
guidance and specifications for bag leak
detection systems in § 60.57c(g).
(d) An annual report shall be
submitted 1 year following the
submission of the information in
paragraph (c) of this section and
subsequent reports shall be submitted
no more than 12 months following the
previous report (once the unit is subject
to permitting requirements under title V
of the Clean Air Act, the owner or
operator of an affected facility must
submit these reports semiannually). The
annual report shall include the
information specified in paragraphs
(d)(1) through (9) of this section. All
reports shall be signed by the facilities
manager.
*
*
*
*
*
(9) Records of the annual air pollution
control device inspection, any required
maintenance, and any repairs not
completed within 10 days of an
inspection or the timeframe established
by the Administrator.
(10) For affected facilities using a bag
leak detection system, records of each
alarm, the time of the alarm, the time
corrective action was initiated and
completed, and a brief description of the
cause of the alarm and the corrective
action taken.
(11) For affected facilities under
§ 60.50c(a)(3) and (a)(4), concentrations
of CO as determined by the continuous
emission monitoring system.
*
*
*
*
*
(g) The owner or operator of an
affected facility that uses the results of
previous emissions tests to demonstrate
compliance with the emission limits
shall submit the information specified
in paragraphs (g)(1) through (g)(4) of this
section no later than [DATE 30 DAYS
AFTER DATE OF PUBLICATION OF
FINAL RULE]. All reports shall have
been signed by the facility’s manager.
(1) The previous emissions test results
as recorded using the methods and
procedures in § 60.56c(b)(1) through
(12), as applicable. Previous emissions
test results recorded using EPAaccepted voluntary consensus standards
are also acceptable.
(2) Certification that the test results
are representative of current operations.
(3) The values for the site-specific
operating parameters established
pursuant to § 60.56c(d) or (i), as
applicable.
(4) The waste management plan as
specified in § 60.55c.
16. Table 1 to subpart Ec is revised to
read as follows:
TABLE 1 TO SUBPART EC OF PART 60.—EMISSION LIMITS FOR SMALL, MEDIUM, AND LARGE HMIWI
Emission limits
HMIWI size
Units
(7 percent oxygen dry basis)
Pollutant
Small
Medium
Large
1. Units for which construction is commenced after June 20, 1996 but no later than February 6, 2007 or for which modification is commenced on
or after March 16, 1998 but no later than [THE DATE 6 MONTHS AFTER PROMULGATION OF THE FINAL RULE]
Particulate matter .......
Carbon monoxide ......
Dioxins/furans ............
Hydrogen chloride ......
Sulfur dioxide .............
Nitrogen oxides ..........
Lead ...........................
Cadmium ....................
Mercury ......................
Milligrams per dry standard cubic meter
(grains per dry standard cubic foot).
Parts per million by volume ...........................
Nanograms per dry standard cubic meter
total dioxins/furans (grains per billion dry
standard cubic feet) or nanograms per dry
standard cubic meter TEQ (grains per billion dry standard cubic feet).
Parts per million by volume or percent reduction.
Parts per million by volume ...........................
Parts per million by volume ...........................
Milligrams per dry standard cubic meter
(grains per thousand dry standard cubic
feet) or percent reduction.
Milligrams per dry standard cubic meter
(grains per thousand dry standard cubic
feet) or percent reduction.
Milligrams per dry standard cubic meter
(grains per thousand dry standard cubic
feet) or percent reduction.
41 (0.018) ..................
21 (0.0090) ................
21 (0.0090).
32 1 .............................
111 (49) or 2.1 (0.92)
32 1 .............................
20 (8.7) or 0.53 (0.23)
32 1.
20 (8.7) or 0.53
(0.23).
15 or 99% ..................
15 or 99% ..................
15 or 99%.
46 1 .............................
225 1 ...........................
0.78 1 (0.34) or 71% ..
46 1 .............................
225 1 ...........................
0.060 (0.026) or 98%
46 1.
225 1.
0.060 (0.026) or 98%.
0.11 1 (0.048) or 66%
0.030 (0.013) or 93%
0.030 (0.013) or 93%.
0.47 1 (0.21) or 87% ..
0.45 1 (0.20) or 87% ..
0.45 1 (0.20) or 87%.
2. Units for which construction is commenced after February 6, 2007 or for which modification is commenced after [THE DATE 6 MONTHS
AFTER PROMULGATION OF THE FINAL RULE]
Particulate matter .......
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Carbon monoxide ......
Dioxins/furans ............
Hydrogen chloride ......
Sulfur dioxide .............
Nitrogen oxides ..........
Lead ...........................
VerDate Aug<31>2005
Milligrams per dry standard cubic meter
(grains per dry standard cubic foot).
Parts per million by volume ...........................
Nanograms per dry standard cubic meter
total dioxins/furans (grains per billion dry
standard cubic feet) or nanograms per dry
standard cubic meter TEQ (grains per billion dry standard cubic feet).
Parts per million by volume or percent reduction.
Parts per million by volume ...........................
Parts per million by volume ...........................
Milligrams per dry standard cubic meter
(grains per thousand dry standard cubic
feet) or percent reduction.
18:17 Feb 05, 2007
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41 (0.018) ..................
21 (0.0090) ................
21 (0.0090).
25 ...............................
111 (49) or 2.0 (0.87)
25 ...............................
16 (7.0) or 0.21
(0.092).
25.
16 (7.0) or 0.21
(0.092).
15 or 99% ..................
15 or 99% ..................
15 or 99%.
28 ...............................
212 .............................
0.64 (0.28) or 71% .....
21 ...............................
212 .............................
0.060 (0.026) or 99%
21.
212.
0.060 (0.026) or 99%.
Sfmt 4702
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TABLE 1 TO SUBPART EC OF PART 60.—EMISSION LIMITS FOR SMALL, MEDIUM, AND LARGE HMIWI—Continued
Emission limits
HMIWI size
Units
(7 percent oxygen dry basis)
Pollutant
Small
Cadmium ....................
Mercury ......................
Milligrams per dry standard cubic
(grains per thousand dry standard
feet) or percent reduction.
Milligrams per dry standard cubic
(grains per thousand dry standard
feet) or percent reduction.
Medium
Large
meter
cubic
0.060 (0.026) or 74%
0.0050 (0.0022) or
99%.
0.0050 (0.0022) or
99%.
meter
cubic
0.33 (0.14) or 96% .....
0.19 (0.083) or 96% ...
0.19 (0.083) or 96%.
1 Emission limit is less stringent than the corresponding limit for existing sources contained in subpart Ce. Sources that would be subject to the
emission limits in this table also would be subject to regulation under State plans or Federal plans that would implement subpart Ce and would
be subject to limits at least as stringent as those in subpart Ce.
[FR Doc. E7–1617 Filed 2–5–07; 8:45 am]
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[Federal Register Volume 72, Number 24 (Tuesday, February 6, 2007)]
[Proposed Rules]
[Pages 5510-5550]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: E7-1617]
[[Page 5509]]
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Part II
Environmental Protection Agency
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40 CFR Part 60
Standards of Performance for New Stationary Sources and Emission
Guidelines for Existing Sources: Hospital/Medical/Infectious Waste
Incinerators; Proposed Rule
��Federal Register / Vol. 72, No. 24 / Tuesday, February 6, 2007 /
Proposed Rules��
[[Page 5510]]
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ENVIRONMENTAL PROTECTION AGENCY
40 CFR Part 60
[EPA-HQ-OAR-2006-0534; FRL-8274-9]
RIN 2060-A004
Standards of Performance for New Stationary Sources and Emission
Guidelines for Existing Sources: Hospital/Medical/Infectious Waste
Incinerators
AGENCY: Environmental Protection Agency (EPA).
ACTION: Proposed rule.
-----------------------------------------------------------------------
SUMMARY: On September 15, 1997, EPA adopted new source performance
standards (NSPS) and emission guidelines for hospital/medical/
infectious waste incinerators (HMIWI). The NSPS and emission guidelines
were established under sections 111 and 129 of the Clean Air Act (CAA).
On November 14, 1997, the Sierra Club and the Natural Resources Defense
Council (Sierra Club) filed suit in the U.S. Court of Appeals for the
District of Columbia Circuit (the Court) challenging EPA's methodology
for adopting the regulations. On March 2, 1999, the Court issued its
opinion. The Court remanded the rule to EPA for further explanation of
the Agency's reasoning in determining the minimum regulatory ``floors''
for new and existing HMIWI. The Court did not vacate the regulations,
so the NSPS and emission guidelines remained in effect during the
remand and were fully implemented by September 2002. This action
provides EPA's proposed response to the questions raised in the Court's
remand.
Section 129(a)(5) of the CAA requires EPA to review and, if
appropriate, revise the NSPS and emission guidelines every 5 years. In
this action, EPA also is proposing our response to this 5-year review,
which would revise the emission limits in the NSPS and emission
guidelines to reflect the levels of performance actually achieved by
the emission controls installed to meet the emission limits set forth
in the September 15, 1997, NSPS and emission guidelines.
DATES: Comments. Comments must be received on or before April 9, 2007.
Under the Paperwork Reduction Act, comments on the information
collection provisions must be received by the Office of Management and
Budget (OMB) on or before March 8, 2007. Because of the need to resolve
the issues raised in this action in a timely manner, EPA will not grant
requests for extensions beyond these dates.
Public Hearing. If anyone contacts EPA by February 26, 2007
requesting to speak at a public hearing, EPA will hold a public hearing
on March 8, 2007. If you are interested in attending the public
hearing, contact Ms. Pamela Garrett at (919) 541-7966 to verify that a
hearing will be held.
ADDRESSES: Submit your comments, identified by Docket ID No. EPA-HQ-
OAR-2006-0534, by one of the following methods:
www.regulations.gov: Follow the on-line instructions for submitting
comments.
E-mail: Send your comments via electronic mail to a-and-r-
Docket@epa.gov, Attention Docket ID No. EPA-HQ-OAR-2006-0534.
Facsimile: Fax your comments to (202) 566-1741, Attention Docket ID
No. EPA-HQ-OAR-2006-0534.
Mail: Send your comments to: EPA Docket Center (EPA/DC),
Environmental Protection Agency, Mailcode 6102T, 1200 Pennsylvania
Ave., NW., Washington, DC 20460, Attention Docket ID No. EPA-HQ-OAR-
2006-0534.
Hand Delivery: Deliver your comments to: EPA Docket Center (EPA/
DC), EPA West Building, Room 3334, 1301 Constitution Ave., NW.,
Washington, DC 20460, Attention Docket ID No. EPA-HQ-OAR-2006-0534.
Such deliveries are accepted only during the normal hours of operation
(8:30 a.m. to 4:30 p.m., Monday through Friday, excluding legal
holidays), and special arrangements should be made for deliveries of
boxed information.
Instructions: Direct your comments to Docket ID No. EPA-HQ-OAR-
2006-0534. The EPA's policy is that all comments received will be
included in the public docket and may be made available online at
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 www.regulations.gov or e-mail.
The www.regulations.gov Web site is an ``anonymous access'' system,
which means EPA will not know your identity or contact information
unless you provide it in the body of your comment. If you send an e-
mail comment directly to EPA without going through www.regulations.gov,
your e-mail 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, 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 EPA cannot read
your comment due to technical difficulties and cannot contact you for
clarification, 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.
Public Hearing: If a public hearing is held, it will be held at
EPA's Campus located at 109 T.W. Alexander Drive in Research Triangle
Park, NC, or an alternate site nearby. Persons interested in presenting
oral testimony must contact Ms. Pamela Garrett at (919) 541-7966 at
least 2 days in advance of the hearing.
Docket: EPA has established a docket for this action under Docket
ID No. EPA-HQ-OAR-2006-0534 and Legacy Docket ID No. A-91-61. All
documents in the docket are listed in the 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, will be publicly available only in hard copy form. Publicly
available docket materials are available either electronically at
www.regulations.gov or in hard copy at the EPA Docket Center EPA/DC,
EPA West, Room 3334, 1301 Constitution Ave., NW., Washington, DC. The
Public Reading Room is open from 8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays. The telephone number for the Public
Reading Room is (202) 566-1744, and the telephone number for the EPA
Docket Center is (202) 566-1742.
FOR FURTHER INFORMATION CONTACT: Ms. Mary Johnson, Energy Strategies
Group, Sector Policies and Programs Division (D243-01), Environmental
Protection Agency, Research Triangle Park, North Carolina 27711;
telephone number: (919) 541-5025; fax number: (919) 541-5450; e-mail
address: johnson.mary@epa.gov.
SUPPLEMENTARY INFORMATION: Organization of This Document. The following
outline is provided to aid in locating information in this preamble.
I. General Information
A. Does the proposed action apply to me?
B. What should I consider as I prepare my comments?
II. Background
III. Summary
A. Litigation and Proposed Remand Response
[[Page 5511]]
B. Proposed Amendments (CAA Section 129(a)(5) 5-Year Review)
IV. Rationale
A. Rationale for the Proposed Response to the Remand
B. Rationale for the Proposed Amendments (CAA Section 129(a)(5)
5-Year Review)
V. Impacts of the Proposed Action for Existing Units
A. What are the primary air impacts?
B. What are the water and solid waste impacts?
C. What are the energy impacts?
D. What are the secondary air impacts?
E. What are the cost and economic impacts?
VI. Impacts of the Proposed Action for New Units
VII. Relationship of the Proposed Action to Section 112(c)(6) of the
CAA
VIII. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and 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 and Safety Risks
H. Executive Order 13211: Actions That Significantly Affect
Energy Supply, Distribution or Use
I. National Technology Transfer Advancement Act
I. General Information
A. Does the proposed action apply to me?
Regulated Entities. Categories and entities potentially affected by
the proposed action are those which operate HMIWI. The NSPS and
emission guidelines for HMIWI affect the following categories of
sources:
----------------------------------------------------------------------------------------------------------------
Examples of
Category NAICS Code potentially
regulated entities
----------------------------------------------------------------------------------------------------------------
Industry..................................... 622110, 622310, 325411, 325412, 562213, Private hospitals,
611310. other health care
facilities,
commercial
research
laboratories,
commercial waste
disposal
companies, private
universities.
Federal Government........................... 622110, 541710, 928110...................... Federal hospitals,
other health care
facilities, public
health service,
armed services.
State/local/Tribal Government................ 622110, 562213, 611310...................... State/local
hospitals, other
health care
facilities, State/
local waste
disposal services,
State
universities.
----------------------------------------------------------------------------------------------------------------
This table is not intended to be exhaustive, but rather provides a
guide for readers regarding entities likely to be affected by the
proposed action. To determine whether your facility would be affected
by the proposed action, you should examine the applicability criteria
in 40 CFR 60.50c of subpart Ec and 40 CFR 60.32e of subpart Ce. If you
have any questions regarding the applicability of the proposed action
to a particular entity, contact the person listed in the preceding FOR
FURTHER INFORMATION CONTACT section.
B. What should I consider as I prepare my comments?
1. Submitting CBI
Do not submit information that you consider to be CBI
electronically through www.regulations.gov or e-mail. Send or deliver
information identified as CBI to only the following address: Ms. Mary
Johnson, c/o OAQPS Document Control Officer (Room C404-02), U.S. EPA,
Research Triangle Park, NC 27711, Attention Docket ID No. EPA-HQ-OAR-
2006-0534. Clearly mark the part or all of the information that you
claim to be CBI. For CBI information in a disk or CD ROM that you mail
to 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. Information marked as CBI will not be
disclosed except in accordance with procedures set forth in 40 CFR part
2.
If you have any questions about CBI or the procedures for claiming
CBI, please consult the person identified in the FOR FURTHER
INFORMATION CONTACT section.
2. Tips for Preparing Your Comments
When submitting comments, remember to:
a. Identify the rulemaking by docket number and other identifying
information (subject heading, Federal Register date and page number).
b. Follow directions. The EPA may ask you to respond to specific
questions or organize comments by referencing a Code of Federal
Regulations (CFR) part or section number.
c. Explain why you agree or disagree; suggest alternatives and
substitute language for your requested changes.
d. Describe any assumptions and provide any technical information
and/or data that you used.
e. If you estimate potential costs or burdens, explain how you
arrived at your estimate in sufficient detail to allow for it to be
reproduced.
f. Provide specific examples to illustrate your concerns, and
suggest alternatives.
g. Explain your views as clearly as possible, avoiding the use of
profanity or personal threats.
h. Make sure to submit your comments by the comment period deadline
identified in the preceding section titled DATES.
3. Docket
The docket number for the proposed action regarding the HMIWI NSPS
(40 CFR part 60, subpart Ec) and emission guidelines (40 CFR part 60,
subpart Ce) is Docket ID No. EPA-HQ-OAR-2006-0534.
4. Worldwide Web (WWW)
In addition to being available in the docket, an electronic copy of
this proposed action is available on the WWW through the Technology
Transfer Network Web site (TTN Web). Following signature, EPA posted a
copy of the proposed action on the TTN's policy and guidance page for
newly proposed or promulgated rules at https://www.epa.gov/ttn/oarpg.
The TTN provides information and technology exchange in various areas
of air pollution control.
II. Background
Section 129 of the CAA, entitled ``Solid Waste Combustion,''
requires EPA to develop and adopt NSPS and emission guidelines for
solid waste incineration units pursuant to CAA sections 111 and 129.
Sections 111(b) and 129(a) of the CAA (NSPS program) address emissions
from new HMIWI units, and CAA sections 111(d) and 129(b) (emission
guidelines program) address emissions from existing HMIWI units. The
NSPS are directly enforceable Federal regulations. The emission
guidelines are not directly enforceable but, rather, are implemented by
State air pollution control agencies through sections 111(d)/129 State
plans.
An HMIWI is defined as any device used to burn hospital waste or
medical/
[[Page 5512]]
infectious waste. Hospital waste means discards generated at a
hospital, and medical/infectious waste means any waste generated in the
diagnosis, treatment, or immunization of human beings or animals, in
research pertaining thereto, or in the production or testing of
biologicals (e.g., vaccines, cultures, blood or blood products, human
pathological waste, sharps). Hospital/medical/infectious waste does not
include household waste, hazardous waste, or human and animal remains
not generated as medical waste. An HMIWI typically is a small, dual-
chamber incinerator that burns about 800 pounds per hour (lb/hr) of
waste. Smaller units burn as little as 13 lb/hr while larger units burn
as much as 3,700 lb/hr.
Incineration of hospital/medical/infectious waste causes the
release of a wide array of air pollutants, some of which exist in the
waste feed material and are released unchanged during combustion, and
some of which are generated as a result of the combustion process
itself. These pollutants include particulate matter (PM); heavy metals,
including lead (Pb), cadmium (Cd), and mercury (Hg); toxic organics,
including chlorinated dibenzo-p-dioxins/dibenzofurans (CDD/CDF); carbon
monoxide (CO); nitrogen oxides (NOX); and acid gases,
including hydrogen chloride (HCl) and sulfur dioxide (SO2).
In addition to the use of good combustion control practices, HMIWI
units are typically controlled by wet scrubbers or dry sorbent
injection fabric filters (dry scrubbers).
Combustion control includes the proper design, construction,
operation, and maintenance of HMIWI to destroy or prevent the formation
of air pollutants prior to their release to the atmosphere. Test data
indicate that as secondary chamber residence time and temperature
increase, emissions decrease. Combustion control is most effective in
reducing CDD/CDF, PM, and CO emissions. The 0.25-second combustion
level includes a minimum secondary chamber temperature of 1700 [deg]F
and a 0.25-second secondary chamber residence time. These combustion
conditions are typical of older HMIWI. The 1-second combustion level
includes a minimum secondary chamber temperature of 1700 [deg]F and
residence time of 1 second. These combustion conditions are typical of
newer HMIWI. Compared to 0.25-second combustion, 1-second combustion
will achieve substantial reductions in CDD/CDF and CO emissions, and
will provide some control of PM, but will not reduce emissions of acid
gases (HCl and SO2), NOX, or metals (Pb, Cd, and
Hg). The 2-second combustion level includes a minimum secondary chamber
temperature of 1800 [deg]F and residence time of 2 seconds. These
combustion conditions will provide additional control of CDD/CDF, CO,
and PM, but will not reduce emissions of acid gases (HCl and
SO2), NOX, or metals (Pb, Cd, and Hg). The 2-
second combustion conditions are considered to be the best level of
combustion control (i.e., good combustion) that is applied to HMIWI.
Wet scrubbers and dry scrubbers provide control of PM, CDD/CDF, HCl,
and metals, but do not influence CO, SO2 (at the low
concentrations emitted by HMIWI units), or NOX; in fact,
there are no technologies currently used by HMIWI that will
consistently reduce SO2 or NOX emissions. (See
Legacy Docket ID No. A-91-61, item II-A-111; 60 FR 10669, 10671-10677;
and 61 FR 31742-31743.)
On September 15, 1997, EPA adopted NSPS (40 CFR part 60, subpart
Ec) and emission guidelines (40 CFR part 60, subpart Ce) for entities
which operate HMIWI. The NSPS and emission guidelines are designed to
reduce air pollution emitted from new and existing HMIWI, including
HCl, CO, Pb, Cd, Hg, PM, CDD/CDF (total, or 2,3,7,8-tetrachlorinated
dibenzo-p-dioxin toxic equivalent (TEQ)), NOX, SO2, and
opacity. The NSPS apply to HMIWI for which construction began after
June 20, 1996, or for which modification began after March 16, 1998.
The NSPS became effective on March 16, 1998, and its requirements apply
as of that date or at start-up of a HMIWI unit, whichever is later. The
emission guidelines apply to HMIWI for which construction began on or
before June 20, 1996, and required compliance by September 2002.
CAA section 129 requires EPA to establish technology-based emission
standards that reflect levels of control EPA determines are achievable
for new and existing units, after considering costs, non-air quality
health and environmental impacts, and energy requirements associated
with the implementation of the standards.
In setting forth the methodology EPA must use to establish the
technology-based performance standards and emissions guidelines, CAA
section 129(a)(2) provides that standards ``applicable to solid waste
incineration units promulgated under section 111 and this section shall
reflect the maximum degree of reduction in emissions of [certain listed
air pollutants] that the Administrator, taking into consideration the
cost of achieving such emission reduction, and any non-air quality
health and environmental impacts and energy requirements, determines is
achievable for new and existing units in each category.'' This level of
control is referred to as a maximum achievable control technology, or
MACT standard.
In promulgating a MACT standard, EPA must first calculate the
minimum stringency levels for new and existing solid waste incineration
units in a category, generally based on levels of emissions control
achieved or required to be achieved by the subject units. The minimum
level of stringency is called the MACT floor, and CAA section 129(a)(2)
provides that the ``degree of reduction in emissions that is deemed
achievable for new units in a category shall not be less stringent than
the emissions control that is achieved in practice by the best
controlled similar unit, as determined by the Administrator. Emissions
standards for existing units in a category may be less stringent than
standards for new units in the same category but shall not be less
stringent than the average emissions limitation achieved by the best
performing 12 percent of units in the category.''
The minimum stringency requirements form the first and least
stringent regulatory option EPA must consider in the determination of
MACT for a source category. EPA must also determine whether to control
emissions ``beyond the floor,'' after considering the costs, non-air
quality health and environmental impacts, and energy requirements of
such more stringent control. These are the two steps EPA took in the
1997 HMIWI rulemaking. Finally, every 5 years after adopting a MACT
standard under section 129, CAA section 129(a)(5) requires EPA to
review and, if appropriate, revise the incinerator standards. In
addition to responding to the Court's remand in Sierra Club v. EPA, 167
F.3d 658 (D.C. Cir. 1999), this proposed action includes our first set
of proposed revisions to the HMIWI standards, also known as the 5-year
review.
III. Summary
A. Litigation and Proposed Remand Response
1. What was EPA's general methodology for determining MACT?
The methodology used to determine MACT is similar for source
categories under sections 112 and 129 of the CAA. However, because each
source category is unique and the data available to determine the
performance capabilities of technology can vary from one source
category to another, the basic methodology must be adapted to fit the
[[Page 5513]]
source category in question. As the Court pointed out in the HMIWI
litigation, it ``generally defer[s] 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.' '' Sierra Club v.
EPA, 167 F.3d at 662.
In general, all MACT analyses involve an assessment of the air
pollution control systems or technologies used by the better performing
units in a source category. The technology assessment can be based
solely on actual emissions data, on knowledge of the air pollution
control in place in combination with actual emissions data, or on State
regulatory requirements, which give an indication of the actual
performance of the regulated units. For each source category, the
assessment of the technology involves a review of actual emissions data
with an appropriate accounting for emissions variability. Where there
is more than one method or technology to control emissions, the
analysis results in a series of potential regulations (called
regulatory options), one of which is selected as MACT.
The first regulatory option considered by EPA must be at least as
stringent as the CAA's minimum stringency requirements. However, MACT
is not necessarily the least stringent regulatory option. EPA must
examine more stringent regulatory options to determine MACT. Unlike the
minimum stringency requirements, EPA must consider various impacts of
the more stringent regulatory options in determining MACT. Only if the
more stringent regulatory options are considered to have unreasonable
impacts does EPA select the first ``floor-based'' regulatory option as
MACT.
As stated earlier, the CAA requires that MACT for new sources be no
less stringent than the emissions control achieved in practice by the
best controlled similar unit. After EPA's assessment of technology, EPA
determines the best control currently in use for a given pollutant and
establishes one potential regulatory option at the emission level
achievable by that control. More stringent potential regulatory options
might reflect controls used on other sources that could be applied to
the source category in question.
For existing sources, the CAA requires that MACT be no less
stringent than the average emissions limitation achieved by the best
performing 12 percent of units in a source category. EPA must determine
some measure of the average emissions limitation achieved by the best
performing 12 percent of units to form the least stringent regulatory
option. Sometimes, a direct calculation of the actual emissions values
from the best performing 12 percent of sources provides the basis for
this regulatory option. More often, EPA determines the technology used
by the average source in the best performing 12 percent of sources and
establishes the floor based on the technology assessment for that
average source. More stringent regulatory options reflect other
technologies capable of achieving better performance.
2. What was EPA's methodology in the 1997 HMIWI rulemaking?
On February 27, 1995, EPA published a notice of proposed rulemaking
regarding emissions standards for HMIWI units (60 FR 10654). The
proposal was the result of several years of reviewing available
information. During the public comment period for the proposal, EPA
received over 700 letters, some of which contained new information or
indicated that the commenters were in the process of gathering more
information for EPA to consider. The new information led EPA to
consider the need for numerous changes to the proposed rule, and on
June 20, 1996, the Agency published a re-proposal (61 FR 31736).
Following an additional public comment period, EPA published the final
rule on September 15, 1997 (62 FR 48348).
During the data-gathering phase of developing the 1995 proposal,
EPA found it difficult to obtain an accurate count of the thousands of
HMIWI units nationwide, or to find HMIWI units with add-on air
pollution control systems in place. A few HMIWI units with combustion
control were tested to assess performance of combustion control in
reducing emissions. One unit with a wet scrubber, and a few units with
dry scrubbing systems were tested to determine performance capabilities
of add-on controls. (See 61 FR 31738.)
Altogether, data were available from only 7 out of the estimated
then-operating 3,700 existing HMIWI units (60 FR 10674). Because EPA
was under a court-ordered deadline to propose and adopt standards for
HMIWI that did not provide sufficient time to collect more actual
emissions data (see consent decree entered in Sierra Club v. EPA, Nos.
CV-92-2093 and CV-93-0284 (E.D.N.Y.)), EPA proceeded to develop the
regulations with the existing data, as described below. However, EPA
specifically requested comment on EPA's MACT determinations and on
EPA's conclusions about the performance capabilities of air pollution
control technologies on HMIWI in light of the relatively small database
(60 FR 10686).
a. EPA's Methodology for New HMIWI. In determining the least
stringent regulatory option allowed by the CAA for new HMIWI, EPA first
examined the data available for various air pollution control
technologies applied to HMIWI to determine the performance capabilities
of the technologies (i.e., the achievable emission limitations) (60 FR
10671-73, 61 FR 31741-43). To determine the performance capabilities,
EPA grouped all of the test data by control technology and established
the numerical value for the achievable emission limitations somewhat
higher than the highest test data point for each particular control
technology. (See Legacy Docket ID No. A-91-61, items IV-B-46, 47, 48,
and 49.) Following the determination of performance capability, EPA
identified the best control technology for each air pollutant for each
subcategory of HMIWI, and established the numerical values for the
least stringent regulatory option at the achievable emission limitation
associated with that particular control technology. (See 60 FR 10673;
Legacy Docket ID No. A-91-61, item IV-B-38; 61 FR 31745-46.) Other,
more stringent, regulatory options were developed reflecting the actual
performance of other, more effective, control technologies (61 FR
31766-68).
As stated in the 1996 re-proposal, the least stringent regulatory
option for new large HMIWI units (units with maximum waste burning
capacity of more than 500 lb/hr) was based on good combustion (i.e., 2-
second combustion level) and a combination of two control technologies,
high-efficiency wet scrubbers and dry injection/fabric filter dry
scrubbers with carbon (61 FR 31746). New medium units (units with
maximum waste burning capacity of more than 200 lb/hr but less than or
equal to 500 lb/hr) would need to use good combustion and a combination
of two control technologies, high-efficiency wet scrubbers and dry
injection/fabric filter dry scrubbers without carbon, to meet the least
stringent regulatory option. Id. New small units (units with maximum
waste burning capacity of less than or equal to 200 lb/hr) would need
to use good combustion and a moderate-efficiency wet scrubber to meet
the least stringent regulatory option. Id.
In EPA's final standards promulgated in 1997, EPA selected an
overall more stringent regulatory option for new HMIWI (62 FR 48365).
The final standards were based on emission limits achievable with good
combustion and a
[[Page 5514]]
moderate-efficiency wet scrubber for new small HMIWI, and good
combustion and a combined dry/wet control system with carbon for new
medium and large HMIWI. Id. These standards reflected the MACT floor
emissions levels for new small and large HMIWI, but were more stringent
than the MACT floor for new medium HMIWI. Id. EPA estimated that the
standards would reduce emissions from these units of HCl by up to 98
percent, PM and Pb by up to 92 percent, Cd by up to 91 percent, CDD/CDF
by up to 87 percent, Hg by up to 74 percent, and CO, SO2,
and NOX by up to 52 percent (62 FR 48366).
b. EPA's Methodology for Existing HMIWI. For existing units, EPA
did not have sufficient emissions data to fully characterize the actual
emissions performance of the best performing 12 percent of existing
HMIWI, and, based exclusively on such data, EPA did not have a clear
indication of the technology used by the best 12 percent of units. As a
result, EPA used emission limits included in State regulations and
State-issued permits (hereinafter referred to as regulatory limits) as
surrogate information to determine emissions limitations achieved by
the best performing 12 percent of units in each subcategory (60 FR
10674). EPA believed this information could be expected to reliably
reflect levels of performance achieved on a continuous basis by better-
controlled units that must meet these limits or risk violating
enforceable requirements. EPA assumed that all HMIWI were achieving
their regulatory limits (60 FR 10674). Where there were regulatory
limits for more than 12 percent of units in a subcategory, the
regulatory limits were ranked from the most stringent to least
stringent, and the average of the regulatory limits for the top 12
percent of units in the subcategory was calculated. Id.; 61 FR 31744-
45. Where the number of units subject to specific emissions limitations
did not comprise 12 percent of the population in a subcategory, EPA
assumed those units with regulatory limits were the best performing
units, and the remaining units in the top 12 percent were assigned an
emission value associated with ``combustion control.'' (See 60 FR
10674; 61 FR 31745; Legacy Docket ID No. A-91-61, item IV-B-24 at 2.)
In previous Federal Register notices regarding HMIWI (60 FR 10654, 61
FR 31736, and 62 FR 48348), this level of control was referred to as
``uncontrolled,'' which is misleading because sources with combustion
control emit lesser amounts of CDD/CDF, CO, and PM. In the latter
situation described above, the average of the regulatory limits plus
enough combustion-controlled emission values to account for 12 percent
of units in the subcategory was calculated. (See Legacy Docket ID No.
A-91-61, item IV-B-24 at 2-4.)
After calculating the averages of regulatory limits and combustion-
controlled emission values, EPA examined the resulting calculated
values to determine what level of air pollution control would be needed
to meet the calculated average values. (See 60 FR 10675-78; 61 FR
31755-56.) For many pollutants, the calculated averages presented no
clear indication of the type of air pollution control used by the best
performing units. However, the calculated values for three key
pollutants, PM, CO, and HCl, did provide a good indication of the type
of air pollution control used on the best performing 12 percent of
units. The level of air pollution control associated with the
calculated average values for PM, CO, and HCl formed the technical
basis of the least stringent regulatory option considered by EPA (61 FR
31756, Table 13). The emission limitations assigned to each pollutant
reflected the actual performance of the technology on which they were
based. Finally, EPA developed a series of regulatory options based on
progressively more stringent technologies and assigned emission
limitations to each regulatory option based on the actual performance
capabilities of the technologies (61 FR 31757, Table 14).
As stated in the 1996 re-proposal, large existing units would need
to use good combustion and a high-efficiency wet scrubber to meet the
least stringent regulatory option, while medium existing units would
need to use good combustion and a moderate-efficiency wet scrubber,
although dry scrubbers could also be used with good combustion at large
and medium existing units (61 FR 31745). EPA further stated that its
inclination was to establish emission limitations for large and medium
existing units based on regulatory options representing the MACT floors
(61 FR 31778). Small existing units would need only to use good
combustion practices to meet the regulatory option representing the
MACT floor (61 FR 31745). With respect to small existing units, EPA
stated that it had no inclination with regard to which regulatory
option should be used to establish emission limitations and requested
comment on requiring use of good combustion and a low-efficiency wet
scrubber (61 FR 31778-79).
In EPA's final standards promulgated in 1997, EPA selected an
overall more stringent regulatory option for existing HMIWI (62 FR
48371). The final standards were based on emission limits achievable
with good combustion and a low-efficiency wet scrubber for most
existing small HMIWI, good combustion and a moderate-efficiency wet
scrubber for existing medium HMIWI, and good combustion and a high-
efficiency wet scrubber for existing large HMIWI (62 FR 48371). The
final standards allow small HMIWI that meet certain rural criteria to
meet emissions limits achievable with good combustion alone. Id. These
standards reflected the MACT floor emissions levels for existing small
HMIWI meeting rural criteria, medium HMIWI, and large HMIWI, but were
more stringent than the MACT floor for most existing small HMIWI (i.e.,
non-rural) (62 FR 48371-72). The final standards for existing medium
and large HMIWI were structured so that either a dry scrubber or a wet
scrubber could be used to achieve the emission limits. EPA estimated
that the final emission guidelines would reduce emissions of CDD/CDF by
up to 97 percent, Hg by up to 95 percent, PM by up to 92 percent, Pb by
up to 87 percent, Cd by up to 84 percent, CO by up to 82 percent, HCl
by up to 98 percent, and SO2 and NOX by up to 30
percent (62 FR 48372). Table 1 of this preamble summarizes the emission
limits for the NSPS and emission guidelines promulgated in 1997.
Table 1.--Summary of Promulgated Emission Limits
----------------------------------------------------------------------------------------------------------------
Limit for existing
Pollutant (units) Unit Size \1\ HMIWI \2\ Limit for new HMIWI \2\
----------------------------------------------------------------------------------------------------------------
HCl (parts per million by volume L, M, S............. 100 or 93% 15 or 99% reduction.
(ppmv)). reduction.
SR.................. 3,100............. N/A.\3\
CO (ppmv)....................... L, M, S............. 40................ 40
SR.................. 40................ N/A.
Pb (milligrams per dry standard L, M................ 1.2 or 70% 0.07 or 98% reduction.\3\
cubic meter (mg/dscm)). reduction.
[[Page 5515]]
S................... 1.2 or 70% 1.2 or 70% reduction.
reduction.
SR.................. 10................ N/A.
Cd (mg/dscm).................... L, M................ 0.16 or 65% 0.04 or 90% reduction.
reduction.
S................... 0.16 or 65% 0.16 or 65% reduction.
reduction.
SR.................. 4................. N/A.
Hg (mg/dscm).................... L, M, S............. 0.55 or 85% 0.55 or 85% reduction.
reduction.
SR.................. 7.5............... N/A.
PM (grains per dry standard L................... 0.015............. 0.015
cubic foot (gr/dscf)).
M................... 0.03.............. 0.015
S................... 0.05.............. 0.03.
SR.................. 0.086............. N/A.
CDD/CDF, total (nanograms per L, M................ 125............... 25
dry standard cubic meter (ng/
dscm)).
S................... 125............... 125
SR.................. 800............... N/A.
CDD/CDF, TEQ (ng/dscm).......... L, M................ 2.3............... 0.6
S................... 2.3............... 2.3
SR.................. 15................ N/A.
NOX (ppmv)...................... L, M, S............. 250............... 250
SR.................. 250............... N/A.
SO2 (ppmv)...................... L, M, S............. 55................ 55
SR.................. 55................ N/A.
----------------------------------------------------------------------------------------------------------------
\1\ L = Large; M = Medium; S = Small; SR = Small Rural
\2\ All emission limits are measured at 7 percent oxygen.
\3\ Not applicable.
c. Compliance by HMIWI. At the time of promulgation (September
1997), EPA estimated that there were approximately 2,400 HMIWI
operating in the United States. Those units combusted approximately 830
thousand tons of hospital/medical/infectious waste annually. Of those
existing HMIWI, about 48 percent were small units, 29 percent were
medium units, and 20 percent were large units. About 3 percent of the
HMIWI were commercial units. EPA projected that no new small or medium
HMIWI would be constructed, and that up to 60 new large units and 10
new commercial units would be constructed.
After shutdown of approximately 97 percent of the 2,400 HMIWI that
were operating in 1997, there are currently 72 existing HMIWI at 67
facilities. Additionally, only 4 new HMIWI at 3 facilities began
operation following the 1997 rulemaking. These 76 existing and new
units are estimated to combust approximately 165 thousand tons of waste
annually. Of the 72 existing HMIWI subject to the emission guidelines,
44 are large units, 20 are medium units, and 8 are small units (6 of
which meet the rural criteria). Twenty-one percent of the existing
HMIWI are commercially owned. Of the four new HMIWI, three are large
units, and one is a medium unit. Two of the new units are county-owned
but accept waste from other sources, similar to commercial units. The
actual emissions reductions achieved as a result of implementation of
the standards exceeded the 1997 projections for all nine of the
regulated pollutants. A comparison of the estimated pollutant
reductions versus the actual reductions is presented in Table 2 of this
preamble.
Table 2.--Comparison of Estimated Pollutant Reductions Versus Actual
Pollutant Reductions
------------------------------------------------------------------------
Estimated
emissions Actual emissions
Pollutant reduction, reduction, percent
percent \1\
------------------------------------------------------------------------
HCl............................. 98................ 99.2
CO.............................. 75 to 82.......... 98.1
Pb.............................. 80 to 87.......... 98.7
Cd.............................. 75 to 84.......... 99.0
Hg.............................. 93 to 95.......... 99.0
PM.............................. 88 to 92.......... 98.1
CDD/CDF, total.................. 96 to 97.......... 99.5
CDD/CDF, TEQ.................... 95 to 97.......... 99.6
NOX............................. 0 to 30........... 70.6
SO2............................. 0 to 30........... 92.6
------------------------------------------------------------------------
\1\ Reflects the effect of unit shutdowns as well as the effect of
compliance with the promulgated standards.
3. What was the Sierra Club's challenge?
On November 14, 1997, the Sierra Club and the Natural Resources
Defense Council (Sierra Club) filed suit in the U.S. Court of Appeals
for the District of Columbia Circuit (the Court). The Sierra Club
claimed that EPA had violated CAA section 129 by setting emission
standards for HMIWI under CAA sections 129 and 111 that are less
stringent than the statutory minimum stringency required by section
129(a)(2); that EPA had violated section 129 by not including mandatory
pollution prevention or waste minimization requirements in the HMIWI
standards; and that EPA had not adequately considered the non-air
quality health and environmental impacts of the standards. For new
units, the Sierra
[[Page 5516]]
Club argued that to satisfy the statutory phrase ``best controlled
similar unit'' in CAA section 129(a)(2), EPA should have identified the
single best performing unit in each subcategory and based the MACT
floor for that subcategory on that particular unit's performance,
rather than consider the performance of other units using the same
technology. The Sierra Club also argued that EPA erroneously based the
new unit floors on the emissions of the worst performing unit using a
particular technology. Regarding existing units, the Sierra Club
claimed that the plain meaning of CAA section 129(a)(2)'s words,
``average emissions limitation achieved by the best performing 12
percent of units,'' precludes the use of regulatory data, and claimed
that the legislative history of section 129(a)(2) reflects
congressional intent to prohibit EPA from relying on regulatory data.
Moreover, the Sierra Club claimed that, for HMIWI, using regulatory
data was impossible because such data existed for fewer than 12 percent
of units, and because doing so would impermissibly import an
achievability requirement into the unit floor determination. Finally,
the Sierra Club argued that EPA failed to require HMIWI units to
undertake programs to reduce the Hg and chlorinated plastic in their
waste streams, in violation of CAA section 129(a)(3), and that EPA
failed to consider the fact that CDD/CDF and Hg from HMIWI can
contaminate water, sediment, and soil, and can bioaccumulate in food,
in violation of the CAA's requirement that EPA consider non-air quality
impacts of setting HMIWI emissions standards.
4. What was the Court's ruling?
On March 2, 1999, the Court issued its opinion in Sierra Club v.
EPA, 167 F.3d 658 (D.C. Cir. 1999). While the Court rejected the Sierra
Club's claims regarding pollution prevention and non-air quality
impacts, and rejected the Sierra Club's statutory arguments under CAA
section 129, the Court remanded the rule to EPA for further explanation
regarding how EPA derived the MACT floors for new and existing HMIWI
units. Furthermore, the Court did not vacate the regulations, stating
that ``[i]t is possible that EPA may be able to explain [EPA's basis
for the standards]'' in response to the concerns raised by the Court.
Id., at 664. The regulations remain in effect during the remand.
a. The Court's Ruling on New Units. In response to the Sierra
Club's claims regarding EPA's treatment of new units, the Court opined
that ``EPA would be justified in setting the floors at a level that is
a reasonable estimate of the performance of the `best controlled
similar unit' under the worst reasonably foreseeable circumstances [* *
*]. It is reasonable to suppose that if an emissions standard is as
stringent as `the emissions control that is achieved in practice' by a
particular unit, then that particular unit will not violate the
standard. This only results if `achieved in practice' is interpreted to
mean `achieved under the worst foreseeable circumstances.' In National
Lime Ass'n v. EPA, 627 F.2d 416, 431 n. 46 (D.C. Cir. 1980), we said
that where a statute requires that a standard be `achievable,' it must
be achievable `under most adverse circumstances which can reasonably be
expected to recur.' The same principle should apply when a standard is
to be derived from the operating characteristics of a particular
unit.'' Sierra Club v. EPA, 167 F.3d at 665. Thus, the Court refused to
embrace the Sierra Club's interpretation of CAA section 129(a)(2) as
requiring EPA to base the MACT floor on only the lowest emissions data
points observed (i.e., the level achieved by the best performing unit
for each pollutant).
Relating to the Sierra Club's claim that EPA erred in considering
the emissions of units other than the best controlled unit, the Court
refused to rule that EPA's approach was unlawful, and posited that
``[p]erhaps considering all units with the same technology is
justifiable because the best way to predict the worst reasonably
foreseeable performance of the best unit with the available data is to
look at other units' performance. Or perhaps EPA reasonably considered
all units with the same technology equally `well-controlled,' so that
each unit with the best technology is a `best-controlled unit' even if
such units vary widely in performance.'' Sierra Club v. EPA, 167 F.3d
at 665.
However, the Court concluded that the possible rationale for this
treatment of new units was not presented in the rulemaking record with
enough clarity for the Court to determine that EPA's ``path may
reasonably be discerned.'' Id. Moreover, the Court ruled that EPA had
``not explained why the phrase best controlled similar unit encompasses
all units using the same technology as the unit with the best observed
performance, rather than just that unit itself[. * * * W]e do not know
what interpretation the agency chose, and thus cannot evaluate its
choice.'' Sierra Club v. EPA, 167 F.3d at 665. The Court further
directed EPA to provide additional explanation regarding how the Agency
had calculated the upper bound of the best-controlled unit's
performance through rounding. Id.
b. The Court's Ruling on Existing Units. With respect to existing
units, the Court first rejected the Sierra Club's ``claim that EPA's
decision to base the floors on regulatory data fails the first step of
the Chevron test. None of the Sierra Club's arguments establish that
Congress has `directly addressed' and rejected the use of regulatory
data.'' Id., at 661. After noting that the Sierra Club's statutory
objections to EPA's methodology appeared to be premised on ``the
counterintuitive proposition that an `achieved' level may not be
`achievable,' or, as Sierra Club puts it, may be better than `EPA's
notions about what is achievable,' '' id. at 662, the Court rejected
the Sierra Club's statutory objections to using regulatory data and
uncontrolled (i.e., combustion-controlled) emissions values. In other
words, the Court implicitly embraced EPA's view, under the principle of
National Lime, that the MACT floor is premised on the fundamental
concept that it be ``achievable,'' and should not be set at a level
that happens to be reflected by the lowest observed data point without
consideration of variability in operating conditions. Then, after
analyzing and rejecting the Sierra Club's arguments that the plain
language of the CAA and its legislative history forbid EPA's
methodology, the Court further ruled that it found ``nothing inherently
impermissible about construing the statute to permit the use of
regulatory data--if they allow EPA to make a reasonable estimate of the
performance of the top 12 percent of units. Indeed, the Sierra Club
conceded at oral argument that `a reasonable sample' may be used `to
find out what the best 12 percent are doing.' Oral Arg. Tr. at 11. To
be sure, the Sierra Club did not concede that permit data may be used.
But neither has it provided any basis for believing that state and
local limitations are such weak indicators of performance that using
them is necessarily an impossible stretch of the statutory terms. [* *
*] We therefore reject the Sierra Club's argument that the CAA forbids
the use of permit and regulatory data, and hold that the use of such
information is permissible as long as it allows a reasonable inference
as to the performance of the top 12 percent of units. Similarly, as
long as there is a reasonable basis for believing that some of the best
performing 12 percent of units are uncontrolled [i.e., combustion
controlled], EPA may include data points giving a reasonable
representation of the performance of those units in its averaging.''
Sierra Club v. EPA, 167 F.3d at 662, 663. Thus, the Court rejected all
of the Sierra Club's
[[Page 5517]]
arguments that the CAA prohibits EPA from basing MACT floor
determinations on permit or regulatory data, or on uncontrolled (i.e.,
combustion-controlled) emissions values.
However, in addressing the manner in which EPA had specifically
relied upon such data in the HMIWI rulemaking, the Court concluded that
``[a]lthough EPA said that it believed the combination of regulatory
and uncontrolled [i.e., combustion-controlled] data gave an accurate
picture of the relevant [HMIWI]s` performance, it never adequately said
why it believes this. [* * *] First, EPA has said nothing about the
possibility that [HMIWI]s might be substantially overachieving the
permit limits. If this were the case, the permit limits would be of
little value in estimating the top 12 percent of [HMIWI]s' performance.
[* * *] Second, EPA never gave any reason for its apparent belief that
[HMIWI]s that were not subject to permit requirements did not deploy
emission controls of any sort. Unless there is some finding to this
effect, it is difficult to see the rationality in using `uncontrolled'
[i.e., combustion-controlled] data for the units that were not subject
to regulatory requirements.'' Id., at 663-664. The Court further
questioned the rationality of EPA using the highest of its test run
data in cases where the regulatory data did not alone comprise the
necessary 12 percent. Id., at 664.
c. Subsequent Court Rulings Relevant to the Remand. Following the
Court's remand of the HMIWI MACT floors in Sierra Club v. EPA, the
Court issued a series of rulings in other cases addressing MACT rules
that bear on EPA's proposed response regarding HMIWI. The first of
these was Nat'l Lime Ass'n v. EPA, 233 F.3d 625 (D.C. Cir. 2000) (``NLA
II''), which involved challenges to EPA's MACT standards under CAA
section 112(d) for portland cement manufacturing facilities. In that
case, the Sierra Club argued that EPA should have based its estimate of
the top performing 12 percent of sources on actual emissions data, in
order to ``reasonably estimate'' such performance. But the Court
determined that EPA's approach of selecting ``the median [performing]
plant out of the best twelve percent of the plants for which it had
information and set[ting] the * * * floor at the level of the worst
performing plant in its databases using th[e same] technology [as the
median plant]'' had not been shown by the Sierra Club to reflect a not
reasonable estimate. NLA II, 233 F.3d at 633.
In addition, the Court partially clarified its position regarding
EPA's approach of accounting for emissions performance variability by
setting floors at a level that reasonably estimates ``the performance
of the `best controlled similar unit' under the worst reasonably
foreseeable circumstances.'' Sierra Club, 167 F.3d at 665. In NLA II,
the Court stressed that EPA should not simply set floors at levels
reflecting the worst foreseeable circumstances faced by any worst
performing unit in a given source category, and that while considering
all units with the same technology may be justifiable because the best
way to predict the worst reasonably foreseeable performance of the best
unit with available data is to look at other units' performance, such
an approach would satisfy the CAA ``if pollution control technology
were the only factor determining emission levels of that HAP.'' NLA II,
233 F.3d at 633.
In Cement Kiln Recycling Coalition v. EPA, 255 F.3d 855 (D.C. Cir.
2001) (``CKRC''), the Court again refined its view on when it is
appropriate for EPA to base MACT floors on the performance of air
pollution control technology. In that case, the Sierra Club challenged
EPA's MACT standards for hazardous waste combustors (HWC), and argued
that factors other than MACT technology influenced the emissions
performance of the best performing sources.
The Court agreed that since EPA's record evidence in the HWC
rulemaking showed that factors besides MACT controls significantly
influenced HWC emission rates, ''emissions of the worst-performing MACT
source may not reflect what the best-performers actually achieve.''
CKRC, 255 F.3d at 864. EPA had claimed that MACT floors must be
achievable by all sources using MACT technology, and that to account
for the best-performing sources'' operational variability we had to
base floors on the worst performers'' emissions. But the Court stressed
that ``whether variability in the MACT control accurately estimates
variability associated with the best performing sources depends on
whether factors other than MACT control contribute to emissions[,]''
id., and that ``the relevant question here is not whether control
technologies experience variability at all, but whether the variability
experienced by the best-performing sources can be estimated by relying
on emissions data from the worst-performing sources using the MACT
control.'' Id., at 865.
In the specific case of the HWC rule, the Court concluded that,
since record evidence showed that non-MACT factors influenced emissions
performance, EPA could not base floors simply on the worst-performing
MACT sources' emissions. Id., at 866. However, the Court also
reiterated that ``[i]f in the case of a particular source category or
HAP, the Agency can demonstrate with substantial evidence--not mere
assertions--that MACT technology significantly controls emissions, or
that factors other than the control have a negligible effect, the MACT
approach could be a reasonable means of satisfying the statute's
requirements.'' Id.
5. Are revisions to the emission limits being proposed in response to
the remand?
Yes, the proposed response to the remand would revise some of the
emission limits in both the NSPS and emission guidelines. Relative to
the NSPS, the emission limits for CO, Pb, Cd, Hg, PM, and CDD/CDF would
be revised. Relative to the emission guidelines, the emission limits
for HCl, Pb, Cd, and CDD/CDF would be revised. EPA believes that the
revised emission limits being proposed as a result of its response to
the remand can be achieved with the same emission control technology
currently used by HMIWI. The proposed emission limits for the NSPS and
emission guidelines necessary to respond to the Court's remand are
summarized in Table 3 of this preamble. Note that in several cases,
further amendments to the emission limits are being proposed as a
result of our 5-year review under CAA section 129(a)(5). Those proposed
amendments are discussed in the following section of this preamble.
Table 3.--Summary of Proposed Emission Limits in Response to the Remand
----------------------------------------------------------------------------------------------------------------
Proposed remand
Pollutant (units) Unit size \1\ limit for Proposed remand limit for new HMIWI
existing HMIWI \2\ \2\
----------------------------------------------------------------------------------------------------------------
HCl (ppmv)...................... L, M, S............. 78 or 93% 15\3\ or 99% reduction \3\.
reduction \3\.
SR.................. 3,100 \3\......... N/A \4\.
CO (ppmv)....................... L, M, S............. 40 \3\............ 32
SR.................. 40 \3\............ N/A \4\.
[[Page 5518]]
Pb (mg/dscm).................... L, M................ 0.78 or 71% 0.060 or 98% reduction \3\.
reduction.
S................... 0.78 or 71% 0.78 or 71% reduction.
reduction.
SR.................. 8.9............... N/A \4\.
Cd (mg/dscm).................... L, M................ 0.11 or 66% 0.030 or 93% reduction.
reduction \3\.
S................... 0.11 or 66% 0.11 or 66% reduction \3\.
reduction \3\.
SR.................. 4 \3\............. N/A \4\.
Hg (mg/dscm).................... L, M................ 0.55 \3\ or 87% 0.45 or 87% reduction.
reduction.
S................... 0.55 \3\ or 87% 0.47 or 87% reduction.
reduction.
SR.................. 6.6............... N/A \4\.
PM (gr/dscf).................... L................... 0.015 \3\......... 0.009
M................... 0.030 \3\......... 0.009
S................... 0.050 \3\......... 0.018
SR.................. 0.086 \3\......... N/A \4\.
CDD/CDF, total (ng/dscm)........ L, M................ 115............... 20
S................... 115............... 111
SR.................. 800 \3\........... N/A \4\.
CDD/CDF, TEQ (ng/dscm).......... L, M................ 2.2............... 0.53
S................... 2.2............... 2.1
SR.................. 15 \3\............ N/A \4\.
NOX (ppmv)...................... L, M, S............. 250 \3\........... 225
SR.................. 250 \3\........... N/A \4\
SO2 (ppmv)...................... L, M, S............. 55 \3\............ 46
SR.................. 55 \3\............ N/A \4\.
----------------------------------------------------------------------------------------------------------------
\1\ L = Large; M = Medium; S = Small; SR = Small Rural
\2\ All emission limits are measured at 7 percent oxygen.
\3\ No change proposed.
\4\ Not applicable.
B. Proposed Amendments (CAA Section 129(a)(5) 5-Year Review)
Section 129(a)(5) of the CAA requires EPA to conduct a review of
the NSPS and emissions guidelines at 5 year intervals and, if
appropriate, revise the NSPS and emission guidelines pursuant to the
requirements under sections 111 and 129 of the CAA. In conducting such
reviews, EPA attempts to assess the performance of and variability
associated with the installed emissions control equipment (and
developments in practices, processes and control technologies) and to
revise as necessary and appropriate the NSPS and emission guidelines.
In these reviews, EPA takes into account the currently installed
equipment and its performance and operational variability. As
appropriate, we also consider new technologies that have been
demonstrated to reliably control emissions from the source category. In
setting numerical emission limits from single, ``snap shot'' stack test
data, EPA must exercise technical judgment to ensure the achievability
of such limits over the course of anticipated operating conditions. EPA
has
