National Emission Standards for Hazardous Air Pollutants: Primary Lead Smelting, 9410-9447 [2011-2866]
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Federal Register / Vol. 76, No. 33 / Thursday, February 17, 2011 / Proposed Rules
ENVIRONMENTAL PROTECTION
AGENCY
40 CFR Part 63
[EPA–HQ–OAR–2004–0305; FRL–9263–2]
RIN 2060–AQ43
National Emission Standards for
Hazardous Air Pollutants: Primary
Lead Smelting
Environmental Protection
Agency (EPA).
ACTION: Proposed rule.
AGENCY:
EPA is proposing
amendments to the national emission
standards for hazardous air pollutants
(NESHAP) for Primary Lead Smelting to
address the results of the residual risk
and technology reviews conducted as
required under sections 112(d)(6) and
(f)(2) of the Clean Air Act (CAA). These
proposed amendments include revisions
to the emission limits for lead, the
addition of a lead concentration in air
standard, and the modification and
addition of testing and monitoring and
related notification, recordkeeping, and
reporting requirements. We are also
proposing to revise provisions
addressing periods of startup,
shutdown, and malfunction to ensure
that they are consistent with a recent
court decision. Finally, we are
proposing revisions to the rule’s
applicability provision to make it
consistent with the definition of the
source category and proposing other
minor technical changes to the standard.
We are also responding to a petition for
rulemaking filed on the standard with
regard to lead as a surrogate and
regulation of volatile organic
compounds (VOC) and acid gases.
DATES: Comments must be received on
or before April 4, 2011. Under the
Paperwork Reduction Act, comments on
the information collection provisions
are best assured of having full effect if
the Office of Management and Budget
(OMB) receives a copy of your
comments on or before March 21, 2011.
Public Hearing. If anyone contacts
EPA requesting to speak at a public
hearing by February 28, 2011, a public
hearing will be held on March 4, 2011.
ADDRESSES: Submit your comments,
identified by Docket ID Number EPA–
HQ–OAR–2004–0305, by one of the
following methods:
• https://www.regulations.gov: Follow
the on-line instructions for submitting
comments.
• E-mail: a-and-r-docket@epa.gov,
Attention Docket ID Number EPA–HQ–
OAR–2004–0305.
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SUMMARY:
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• Fax: (202) 566–9744, Attention
Docket ID Number EPA–HQ–OAR–
2004–0305.
• Mail: U.S. Postal Service, send
comments to: EPA Docket Center, EPA
West (Air Docket), Attention Docket ID
Number EPA–HQ–OAR–2004–0305,
U.S. Environmental Protection Agency,
Mailcode: 2822T, 1200 Pennsylvania
Ave., NW., Washington, DC 20460.
Please include a total of two copies. In
addition, please mail a copy of your
comments on the information collection
provisions to the Office of Information
and Regulatory Affairs, Office of
Management and Budget (OMB), Attn:
Desk Officer for EPA, 725 17th Street,
NW., Washington, DC 20503.
• Hand Delivery: U.S. Environmental
Protection Agency, EPA West (Air
Docket), Room 3334, 1301 Constitution
Ave., NW., Washington, DC 20004,
Attention Docket ID Number EPA–HQ–
OAR–2004–0305. Such deliveries are
only accepted during the Docket’s
normal hours of operation, and special
arrangements should be made for
deliveries of boxed information.
Instructions. Direct your comments to
Docket ID Number EPA–HQ–OAR–
2004–0305. EPA’s policy is that all
comments received will be included in
the public docket without change and
may be made available on-line at https://
www.regulations.gov, including any
personal information provided, unless
the comment includes information
claimed to be confidential business
information (CBI) or other information
whose disclosure is restricted by statute.
Do not submit information that you
consider to be CBI or otherwise
protected through https://
www.regulations.gov or e-mail. The
https://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 https://
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. For additional information
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about EPA’s public docket, visit the EPA
Docket Center homepage at https://
www.epa.gov/epahome/dockets.htm.
Docket. The EPA has established a
docket for this rulemaking under Docket
ID Number EPA–HQ–OAR–2004–0305.
All documents in the docket are listed
in the https://www.regulations.gov index.
Although listed in the index, some
information is not publicly available,
e.g., CBI or other information whose
disclosure is restricted by statute.
Certain other material, such as
copyrighted material, is not placed on
the Internet and will be publicly
available only in hard copy. Publicly
available docket materials are available
either electronically in https://
www.regulations.gov or in hard copy at
the EPA Docket Center, EPA West,
Room 3334, 1301 Constitution Ave.,
NW., Washington, DC. The Public
Reading Room is open from 8:30 a.m. to
4:30 p.m., Monday through Friday,
excluding legal holidays. The telephone
number for the Public Reading Room is
(202) 566–1744, and the telephone
number for the EPA Docket Center is
(202) 566–1742.
Public Hearing. If a public hearing is
held, it will begin at 10 a.m. on March
4, 2011 and will be held at EPA’s
campus in Research Triangle Park,
North Carolina, or at an alternate facility
nearby. Persons interested in presenting
oral testimony or inquiring as to
whether a public hearing is to be held
should contact Ms. Virginia Hunt, Office
of Air Quality Planning and Standards,
Sector Policies and Programs Division,
Metals and Minerals Group (D243–02),
U.S. Environmental Protection Agency,
Research Triangle Park, North Carolina
27711; telephone number: (919) 541–
0832.
FOR FURTHER INFORMATION CONTACT: For
questions about this proposed action,
contact Ms. Sharon Nizich, Sector
Policies and Programs Division (D243–
02), Office of Air Quality Planning and
Standards, U.S. Environmental
Protection Agency, Research Triangle
Park, North Carolina 27711, telephone
(919) 541–2825; fax number: (919) 541–
5450; and e-mail address:
nizich.sharon@epa.gov. For specific
information regarding the risk modeling
methodology, contact Ms. Elaine
Manning, Health and Environmental
Impacts Division (C539–02), Office of
Air Quality Planning and Standards,
U.S. Environmental Protection Agency,
Research Triangle Park, North Carolina
27711; telephone number: (919) 541–
5499; fax number: (919) 541–0840; and
e-mail address:
manning.elaine@epa.gov. For
information about the applicability of
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the NESHAP to a particular entity,
contact the appropriate person listed in
Table 1 to this preamble.
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SUPPLEMENTARY INFORMATION:
TABLE 1—LIST OF EPA CONTACTS FOR THE NESHAP ADDRESSED IN THIS PROPOSED ACTION
NESHAP for:
OECA contact 1
OAQPS contact 2
Primary Lead Smelting ...
Maria Malave, (202) 564–7027, malave.maria@epa.gov ..
Sharon Nizich, (919) 541–2825, nizich.sharon@epa.gov.
1 EPA’s
2 EPA’s
Office of Enforcement and Compliance Assurance.
Office of Air Quality Planning and Standards.
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I. Preamble Acronyms and
Abbreviations
Several acronyms and terms used to
describe industrial processes, data
inventories, and risk modeling are
included in this preamble. While this
may not be an exhaustive list, to ease
the reading of this preamble and for
reference purposes, the following terms
and acronyms are defined here:
ADAF Age-dependent Adjustment Factors
AERMOD Air dispersion model used by the
HEM–3 model
AEGL Acute Exposure Guideline Levels
ANPRM Advance Notice of Proposed
Rulemaking
BACT Best Available Control Technology
CAA Clean Air Act
CBI Confidential Business Information
CEEL Community Emergency Exposure
Levels
CEMS Continuous Emissions Monitoring
System
CERMS Continuous Emission Rate
Monitoring System
CFR Code of Federal Regulations
EJ Environmental Justice
EPA Environmental Protection Agency
ERPG Emergency Response Planning
Guidelines
HAP Hazardous Air Pollutants
HI Hazard Index
HEM–3 Human Exposure Model version 3
HON Hazardous Organic National
Emissions Standards for Hazardous Air
Pollutants
HQ Hazard Quotient
IRIS Integrated Risk Information System
Km Kilometer
LAER Lowest Achievable Emission Rate
LOAEL Lowest Observed Adverse Effect
Level
MACT Maximum Achievable Control
Technology
MACT Code Code within the NEI used to
identify processes included in a source
category
MIR Maximum Individual Risk
NAAQS National Ambient Air Quality
Standard
NAC/AEGL Committee National Advisory
Committee for Acute Exposure Guideline
Levels for Hazardous Substances
NAICS North American Industry
Classification System
NAS National Academy of Sciences
NATA National Air Toxics Assessment
NESHAP National Emissions Standards for
Hazardous Air Pollutants
NEI National Emissions Inventory
NOAEL No Observed Adverse Effects Level
NRC National Research Council
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NTTAA National Technology Transfer and
Advancement Act
OAQPS EPA’s Office of Air Quality
Planning and Standards
OECA EPA’s Office of Enforcement and
Compliance Assurance
OMB Office of Management and Budget
PB-HAP Hazardous air pollutants known to
be persistent and bio-accumulative in the
environment
POM Polycyclic Organic Matter
RACT Reasonably Available Control
Technology
RBLC RACT/BACT/LAER Clearinghouse
RFA Regulatory Flexibility Act
RfC Reference Concentration
RfD Reference Dose
RTR Residual Risk and Technology Review
SAB Science Advisory Board
SBA Small Business Administration
SCC Source Classification Codes
SF3 2000 Census of Population and
Housing Summary File 3
SIP State Implementation Plan
SOP Standard Operating Procedures
SSM Startup, Shutdown, and Malfunction
TOSHI Target Organ-Specific Hazard Index
TPY Tons Per Year
TRIM Total Risk Integrated Modeling
System
TTN Technology Transfer Network
UF Uncertainty Factor
UMRA Unfunded Mandates Reform Act
URE Unit Risk Estimate
VOC Volatile Organic Compounds
VOHAP Volatile Organic Hazardous Air
Pollutants
WWW Worldwide Web
Organization of this Document. The
following outline is provided to aid in
the location of information in this
preamble.
I. Preamble Acronyms and Abbreviations
II. General Information
A. Does this action apply to me?
B. Where can I get a copy of this document
and other related information?
C. What should I consider as I prepare my
comments for EPA?
III. Background
A. What is the statutory authority for this
action?
B. How did we consider the risk results in
making decisions for this proposal?
C. What other actions are we addressing in
this proposal?
IV. Analyses Performed and Background for
the Source Category and MACT Standard
A. How did we estimate risks posed by the
source category?
B. How did we perform the technology
review?
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C. Overview of the source category and
MACT standards
V. Analyses Results and Proposed Decisions
A. What data were used in our risk
analyses?
B. What are the results of the risk
assessments and analyses?
C. What are our proposed decisions on risk
acceptability and ample margin of
safety?
D. What are the results and proposed
decisions from the technology review?
E. Variability
F. What other actions are we proposing?
VI. Proposed Action
A. What actions are we proposing as a
result of the residual risk reviews?
B. What actions are we proposing as a
result of the technology reviews?
C. What other actions are we proposing?
D. Compliance Dates
VII. Request for Comments
VIII.Submitting Data Corrections
IX. 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
Risks and Safety Risks
H. Executive Order 13211: Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use
I. National Technology Transfer and
Advancement Act
J. Executive Order 12898: Federal Actions
To Address Environmental Justice in
Minority Populations and Low-Income
Populations
II. General Information
A. Does this action apply to me?
The regulated industrial source
category that is the subject of this
proposal is listed in Table 2 to this
preamble. Table 2 is not intended to be
exhaustive, but rather provides a guide
for readers regarding entities likely to be
affected by this proposed action for the
source categories listed. This standard,
and any changes considered in this
rulemaking, would be directly
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applicable to sources as a Federal
program. Thus, Federal, State, local, and
tribal government entities are not
affected by this proposed action. As
defined in the source category listing
report published by EPA in 1992, the
Primary Lead Smelting source category
is defined as any facility engaged in
producing lead metal from ore
concentrates; including, but not limited
to, the following smelting processes:
sintering, reduction, preliminary
treatment, and refining operations.1 As
discussed in section III. (C)(3), to be
consistent with the 1992 listing, EPA is
proposing to change the applicability of
the Primary Lead Smelting NESHAP to
apply to any facility that produces lead
metal from lead ore concentrates.
Although the source category name in
the 1992 listing will remain Primary
Lead Smelting (as in 1992 listing) we are
proposing to change the title of the rule
to refer to Primary Lead Processing. For
clarification purposes, all references to
lead emissions in this preamble means
‘‘lead compounds’’ (which is a HAP) and
all reference to lead production means
elemental lead (which is not a HAP) as
provided under CAA 112(b)(7)).
TABLE 2—NESHAP AND INDUSTRIAL SOURCE CATEGORIES AFFECTED BY THIS PROPOSED ACTION
NAICS code 1
Source category
NESHAP
Primary Lead Smelting .................................................
Primary Lead Processing .............................................
1 North
331419
MACT code 2
0204
American Industry Classification System.
Achievable Control Technology.
2 Maximum
B. Where can I get a copy of this
document and other related
information?
In addition to being available in the
docket, an electronic copy of this
proposal will also be available on the
World Wide Web (WWW) through the
Technology Transfer Network (TTN).
Following signature by the EPA
Administrator, a copy of this proposed
action will be posted on the TTN’s
policy and guidance page for newly
proposed or promulgated rules at the
following address: https://www.epa.gov/
ttn/atw/rrisk/rtrpg.html. The TTN
provides information and technology
exchange in various areas of air
pollution control.
Additional information is available on
the residual risk and technology review
(RTR) Web page at https://www.epa.gov/
ttn/atw/rrisk/rtrpg.html. This
information includes source category
descriptions and detailed emissions and
other data that were used as inputs to
the risk assessments.
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C. What should I consider as I prepare
my comments for EPA?
Submitting CBI. Do not submit
information containing CBI to EPA
through https://www.regulations.gov or
e-mail. Clearly mark the part or all of
the information that you claim to be
CBI. For CBI information on a disk or
CD ROM that you mail to EPA, mark the
outside of the disk or CD ROM as CBI
and then identify electronically within
the disk or CD ROM the specific
information that is claimed as CBI. In
addition to one complete version of the
comment that includes information
claimed as CBI, a copy of the comment
that does not contain the information
claimed as CBI must be submitted for
inclusion in the public docket. If you
submit a CD ROM or disk that does not
contain CBI, mark the outside of the
disk or CD ROM clearly that it does not
contain CBI. Information not marked as
CBI will be included in the public
docket and EPA’s electronic public
docket without prior notice. Information
marked as CBI will not be disclosed
except in accordance with procedures
set forth in 40 CFR part 2. Send or
deliver information identified as CBI
only to the following address: Roberto
Morales, OAQPS Document Control
Officer (C404–02), Office of Air Quality
Planning and Standards, U.S.
Environmental Protection Agency,
Research Triangle Park, North Carolina
27711, Attention Docket ID Number
EPA–HQ–OAR–2004–0305.
III. Background
A. What is the statutory authority for
this action?
Section 112 of the Clean Air Act
(CAA) establishes a two-stage regulatory
process to address emissions of
hazardous air pollutants (HAP) from
stationary sources. In the first stage,
after EPA has identified categories of
sources emitting one or more of the HAP
listed in section 112(b) of the CAA,
section 112(d) of the CAA calls for us
to promulgate NESHAP for those
sources. ‘‘Major sources’’ are those that
emit or have the potential to emit 10
tons per year (TPY) or more of a single
HAP or 25 TPY or more of any
combination of HAP. For major sources,
these technology-based standards must
reflect the maximum degree of emission
reductions of HAP achievable (after
considering cost, energy requirements,
and non-air quality health and
environmental impacts) and are
commonly referred to as maximum
achievable control technology (MACT)
standards.
MACT standards must require the
maximum degree of emission reduction
through the application of measures,
processes, methods, systems, or
techniques, including, but not limited
to, measures which (A) Reduce the
volume of or eliminate pollutants
through process changes, substitution of
materials or other modifications;
(B) enclose systems or processes to
eliminate emissions; (C) capture or treat
pollutants when released from a
process, stack, storage, or fugitive
emissions point; (D) are design,
equipment, work practice, or
operational standards (including
requirements for operator training or
certification); or (E) are a combination of
the above. CAA section 112(d)(2)(A)–
(E). The MACT standards may take the
form of design, equipment, work
practice, or operational standards where
EPA first determines either that, (A) a
pollutant cannot be emitted through a
conveyance designed and constructed to
emit or capture the pollutants, or that
any requirement for, or use of, such a
conveyance would be inconsistent with
law; or (B) the application of
measurement methodology to a
particular class of sources is not
practicable due to technological and
economic limitations. CAA sections
112(h)(1)–(2).
The MACT ‘‘floor’’ is the minimum
control level allowed for MACT
standards promulgated under CAA
section 112(d)(3) and may not be based
on cost considerations. For new sources,
the MACT floor cannot be less stringent
than the emission control that is
achieved in practice by the best-
1 USEPA. Documentation for Developing the
Initial Source Category List—Final Report, USEPA/
OAQPS, EPA–450/3–91–030, July, 1992.
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controlled similar source. The MACT
floors for existing sources can be less
stringent than floors for new sources,
but they cannot be less stringent than
the average emissions limitation
achieved by the best-performing 12
percent of existing sources in the
category or subcategory (or the bestperforming 5 sources for categories or
subcategories with fewer than 30
sources). In developing MACT
standards, we must also consider
control options that are more stringent
than the floor. We may establish
standards more stringent than the floor
based on the consideration of the cost of
achieving the emissions reductions, any
non-air quality health and
environmental impacts, and energy
requirements.
The EPA is then required to review
these technology-based standards and to
revise them ‘‘as necessary (taking into
account developments in practices,
processes, and control technologies)’’ no
less frequently than every 8 years, under
CAA section 112(d)(6). In conducting
this review, EPA is not obliged to
completely recalculate the prior MACT
determination. NRDC v. EPA, 529 F.3d
1077, 1084 (D.C. Cir., 2008).
The second stage in standard-setting
focuses on reducing any remaining
‘‘residual’’ risk according to CAA section
112(f). This provision requires, first, that
EPA prepare a Report to Congress
discussing (among other things)
methods of calculating the risks posed
(or potentially posed) by sources after
implementation of the MACT standards,
the public health significance of those
risks, and the recommendations
regarding legislation of such remaining
risk. EPA prepared and submitted this
report (Residual Risk Report to
Congress, EPA–453/R–99–001) in March
1999. Congress did not act in response
to the report, thereby triggering EPA’s
obligation under CAA section 112(f)(2)
to analyze and address residual risk.
Section 112(f)(2) of the CAA requires
us to determine for source categories
subject to certain MACT standards,
whether the emissions standards
provide an ample margin of safety to
protect public health. If the MACT
standards that apply to a source
category emitting a HAP that is
‘‘classified as a known, probable, or
possible human carcinogen do not
reduce lifetime excess cancer risks to
the individual most exposed to
emissions from a source in the category
or subcategory to less than one-in-one
million,’’ EPA must promulgate residual
risk standards for the source category (or
subcategory) as necessary to provide an
ample margin of safety to protect public
health. CAA section 112(f)(2)(A). In
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doing so, EPA may adopt standards
equal to existing MACT standards if
EPA determines that the existing
standards are sufficiently protective. As
stated in NRDC v. EPA, 529 F.3d 1077,
1083 (D.C. Dir. 2008), ‘‘If EPA
determines that the existing technologybased standards provide an ‘ample
margin of safety,’ then the Agency is
free to readopt those standards during
the residual risk rulemaking.’’ Section
112(f)(2) of the Clean Air Act further
states that EPA must also adopt more
stringent standards, if necessary, to
‘‘prevent taking into consideration costs,
energy, safety, and other relevant
factors, an adverse environmental
effect.’’ 2
When Section 112(f)(2) of the CAA
was enacted in 1990, it expressly
preserved our use of the two-step
process for developing standards to
address any residual risk and our
interpretation of ‘‘ample margin of
safety’’ developed in the National
Emission Standards for Hazardous Air
Pollutants: Benzene Emissions from
Maleic Anhydride Plants, Ethylbenzene/
Styrene Plants, Benzene Storage Vessels,
Benzene Equipment Leaks, and Coke
By-Product Recovery Plants (Benzene
NESHAP) (54 FR 38044, September 14,
1989). The first step in this process is
the determination of acceptable risk.
The second step provides for an ample
margin of safety to protect public health,
which is the level at which the
standards are set (unless a more
stringent standard is required to
prevent, taking into consideration costs,
energy, safety, and other relevant
factors, an adverse environmental
effect).
The terms ‘‘individual most exposed,’’
‘‘acceptable level,’’ and ‘‘ample margin of
safety’’ are not specifically defined in
the CAA. However, CAA section
112(f)(2)(B) preserves the interpretation
set out in the Benzene NESHAP, and the
Court in NRDC v. EPA, concluded that
EPA’s interpretation of subsection
112(f)(2) is a reasonable one. See NRDC
v. EPA, 529 F.3d at 1083 (D.C. Cir.
2008), which says ‘‘[S]ubsection
112(f)(2)(B) expressly incorporates
EPA’s interpretation of the Clean Air
Act from the Benzene standard,
complete with a citation to the Federal
Register.’’ See also, A Legislative History
of the Clean Air Act Amendments of
1990, volume 1, p. 877 (Senate debate
2 ‘‘Adverse environmental effect’’ is defined in
CAA section 112(a)(7) as any significant and
widespread adverse effect, which may be
reasonably anticipated to wildlife, aquatic life, or
natural resources, including adverse impacts on
populations of endangered or threatened species or
significant degradation of environmental qualities
over broad areas.
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on Conference Report). We notified
Congress in the Residual Risk Report to
Congress that we intended to use the
Benzene NESHAP approach in making
CAA section 112(f) residual risk
determinations (EPA–453/R–99–001, p.
ES–11).
In the Benzene NESHAP, we stated as
an overall objective:
* * * in protecting public health with an
ample margin of safety, we strive to provide
maximum feasible protection against risks to
health from hazardous air pollutants by (1)
protecting the greatest number of persons
possible to an individual lifetime risk level
no higher than approximately 1-in-1 million;
and (2) limiting to no higher than
approximately 1-in-10 thousand [i.e., 100-in1 million] the estimated risk that a person
living near a facility would have if he or she
were exposed to the maximum pollutant
concentrations for 70 years.
The Agency also stated that, ‘‘The EPA
also considers incidence (the number of
persons estimated to suffer cancer or
other serious health effects as a result of
exposure to a pollutant) to be an
important measure of the health risk to
the exposed population. Incidence
measures the extent of health risks to
the exposed population as a whole, by
providing an estimate of the occurrence
of cancer or other serious health effects
in the exposed population.’’ The Agency
went on to conclude that ‘‘estimated
incidence would be weighed along with
other health risk information in judging
acceptability.’’ As explained more fully
in our Residual Risk Report to Congress,
EPA does not define ‘‘rigid line[s] of
acceptability,’’ but considers rather
broad objectives to be weighed with a
series of other health measures and
factors (EPA–453/R–99–001, p. ES–11).
The determination of what represents an
‘‘acceptable’’ risk is based on a judgment
of ‘‘what risks are acceptable in the
world in which we live’’ (Residual Risk
Report to Congress, p. 178, quoting the
Vinyl Chloride decision at 824 F.2d
1165) recognizing that our world is not
risk-free.
In the Benzene NESHAP, we stated
that ‘‘EPA will generally presume that if
the risk to [the maximum exposed]
individual is no higher than
approximately 1-in-10 thousand, that
risk level is considered acceptable.’’ 54
FR 38045. We discussed the maximum
individual lifetime cancer risk as being
‘‘the estimated risk that a person living
near a plant would have if he or she
were exposed to the maximum pollutant
concentrations for 70 years.’’ Id. We
explained that this measure of risk ‘‘is
an estimate of the upper bound of risk
based on conservative assumptions,
such as continuous exposure for 24
hours per day for 70 years.’’ Id. We
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acknowledge that maximum individual
lifetime cancer risk ‘‘does not
necessarily reflect the true risk, but
displays a conservative risk level which
is an upper-bound that is unlikely to be
exceeded.’’ Id.
Understanding that there are both
benefits and limitations to using
maximum individual lifetime cancer
risk as a metric for determining
acceptability, we acknowledged in the
1989 Benzene NESHAP that
‘‘consideration of maximum individual
risk * * * must take into account the
strengths and weaknesses of this
measure of risk.’’ Id. Consequently, the
presumptive risk level of 100-in-1
million (1-in-10 thousand) provides a
benchmark for judging the acceptability
of maximum individual lifetime cancer
risk, but does not constitute a rigid line
for making that determination.
The Agency also explained in the
1989 Benzene NESHAP the following:
‘‘In establishing a presumption for MIR
[maximum individual cancer risk],
rather than a rigid line for acceptability,
the Agency intends to weigh it with a
series of other health measures and
factors. These include the overall
incidence of cancer or other serious
health effects within the exposed
population, the numbers of persons
exposed within each individual lifetime
risk range and associated incidence
within, typically, a 50-kilometer (km)
exposure radius around facilities, the
science policy assumptions and
estimation uncertainties associated with
the risk measures, weight of the
scientific evidence for human health
effects, other quantified or unquantified
health effects, effects due to co-location
of facilities, and co-emission of
pollutants.’’ Id.
In some cases, these health measures
and factors taken together may provide
a more realistic description of the
magnitude of risk in the exposed
population than that provided by
maximum individual lifetime cancer
risk alone. As explained in the Benzene
NESHAP, ‘‘[e]ven though the risks
judged ‘‘acceptable’’ by EPA in the first
step of the Vinyl Chloride inquiry are
already low, the second step of the
inquiry, determining an ‘‘ample margin
of safety,’’ again includes consideration
of all of the health factors, and whether
to reduce the risks even further.’’ In the
ample margin of safety decision process,
the Agency again considers all of the
health risks and other health
information considered in the first step.
Beyond that information, additional
factors relating to the appropriate level
of control will also be considered,
including costs and economic impacts
of controls, technological feasibility,
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uncertainties, and any other relevant
factors. Considering all of these factors,
the Agency will establish the standard
at a level that provides an ample margin
of safety to protect the public health, as
required by CAA section 112(f). 54 FR
38046.
B. How did we consider the risk results
in making decisions for this proposal?
As discussed in section III.A of this
preamble, we apply a two-step process
for developing standards to address
residual risk. In the first step, EPA
determines if risks are acceptable. This
determination ‘‘considers all health
information, including risk estimation
uncertainty, and includes a presumptive
limit on maximum individual lifetime
[cancer] risk (MIR) 3 of approximately 1in-10 thousand [i.e., 100-in-1 million].’’
54 FR 38045. In the second step of the
process, EPA sets the standard at a level
that provides an ample margin of safety
‘‘in consideration of all health
information, including the number of
persons at risk levels higher than
approximately 1-in-1 million, as well as
other relevant factors, including costs
and economic impacts, technological
feasibility, and other factors relevant to
each particular decision.’’ Id.
In past residual risk actions, EPA has
presented and considered a number of
human health risk metrics associated
with emissions from the category under
review, including: the MIR; the numbers
of persons in various risk ranges; cancer
incidence; the maximum non-cancer
hazard index (HI); and the maximum
acute non-cancer hazard (72 FR 25138,
May 3, 2007; 71 FR 42724, July 27,
2006). In our most recent proposals (75
FR 65068, October 21, 2010 and 75 FR
80220, December 21, 2010), EPA also
presented and considered additional
measures of health information,
including: estimates of ‘‘facility-wide’’
risks (risks from all HAP emissions from
the facility at which the source category
is located); 4 demographic analyses
(analyses of the distributions of HAPrelated risks across different social,
demographic, and economic groups
living near the facilities); and estimates
of the risks associated with the
maximum level of emissions which
might be allowed by the current MACT
standards (see, e.g., 75 FR 65068,
October 21, 2010 and 75 FR 80220,
December 21, 2010). EPA also discussed
3 Although defined as ‘‘maximum individual
risk,’’ MIR refers only to cancer risk. MIR, one
metric for assessing cancer risk, is the estimated
risk were an individual exposed to the maximum
level of a pollutant for a lifetime.
4 EPA previously provided estimates of total
facility risk in a residual risk proposal for coke oven
batteries (69 FR 48338, August 9, 2004).
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and considered risk estimation
uncertainties. EPA is providing this
same type of information in support of
the proposed actions described in this
Federal Register notice.
The Agency is considering all
available health information to inform
our determinations of risk acceptability
and ample margin of safety under CAA
section 112(f). Specifically, as explained
in the Benzene NESHAP, ‘‘the first step
judgment on acceptability cannot be
reduced to any single factor’’ and thus
‘‘[t]he Administrator believes that the
acceptability of risk under section 112 is
best judged on the basis of a broad set
of health risk measures and
information.’’ 54 FR at 38046. Similarly,
with regard to making the ample margin
of safety determination, as stated in the
Benzene NESHAP ‘‘[I]n the ample
margin decision, the Agency again
considers all of the health risk and other
health information considered in the
first step. Beyond that information,
additional factors relating to the
appropriate level of control will also be
considered, including cost and
economic impacts of controls,
technological feasibility, uncertainties,
and any other relevant factors.’’ Id.
The Agency acknowledges that
flexibility is provided by the Benzene
NESHAP regarding what factors EPA
might consider in making
determinations and how they might be
weighed for each source category. In
responding to comment on our policy
under the Benzene NESHAP, EPA
explained that: ‘‘The policy chosen by
the Administrator permits consideration
of multiple measures of health risk. Not
only can the MIR figure be considered,
but also incidence, the presence of noncancer health effects, and the
uncertainties of the risk estimates. In
this way, the effect on the most exposed
individuals can be reviewed as well as
the impact on the general public. These
factors can then be weighed in each
individual case. This approach complies
with the Vinyl Chloride mandate that
the Administrator ascertain an
acceptable level of risk to the public by
employing [her] expertise to assess
available data. It also complies with the
Congressional intent behind the CAA,
which did not exclude the use of any
particular measure of public health risk
from the EPA’s consideration with
respect to CAA section 112 regulations,
and, thereby, implicitly permits
consideration of any and all measures of
health risk which the Administrator, in
[her] judgment, believes are appropriate
to determining what will ‘protect the
public health.’ ’’ 54 FR at 38057.
For example, the level of the MIR is
only one factor to be weighed in
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determining acceptability of risks. It is
explained in the Benzene NESHAP that
‘‘an MIR of approximately 1-in-10
thousand should ordinarily be the upper
end of the range of acceptability. As
risks increase above this benchmark,
they become presumptively less
acceptable under CAA section 112, and
would be weighed with the other health
risk measures and information in
making an overall judgment on
acceptability. Or, the Agency may find,
in a particular case, that a risk that
includes MIR less than the
presumptively acceptable level is
unacceptable in the light of other health
risk factors.’’ Id. at 38045. Similarly,
with regard to the ample margin of
safety analysis, EPA stated in the
Benzene NESHAP that: ‘‘* * * EPA
believes the relative weight of the many
factors that can be considered in
selecting an ample margin of safety can
only be determined for each specific
source category. This occurs mainly
because technological and economic
factors (along with the health-related
factors) vary from source category to
source category.’’ Id. at 38061.
EPA wishes to point out that certain
health information has not been
considered to date in making residual
risk determinations. In assessing risks to
populations in the vicinity of the
facilities in each category, we present
estimates of risk associated with HAP
emissions from the source category
alone (source category risk estimates)
and HAP emissions from the entire
facility at which the covered source
category is located (facility-wide risk
estimates). We do not attempt to
characterize the risks associated with all
HAP emissions impacting the
populations living near the sources in
these categories. That is, at this time, we
do not attempt to quantify those HAP
risks that may be associated with mobile
source emissions, natural source
emissions, persistent environmental
pollution, or atmospheric
transformation in the vicinity of the
sources in these categories.
The Agency understands the potential
importance of considering an
individual’s total exposure to HAP in
addition to considering exposure to
HAP emissions from the source category
and facility. This is particularly
important when assessing non-cancer
risks, where pollutant-specific exposure
levels (e.g., Reference Concentration
(RfC)) are based on the assumption that
thresholds exist for adverse health
effects. For example, the Agency
recognizes that, although exposures
attributable to emissions from a source
category or facility alone may not
indicate the potential for increased risk
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of adverse non-cancer health effects in
a population, the exposures resulting
from emissions from the facility in
combination with emissions from all of
the other sources (e.g., other facilities) to
which an individual is exposed may be
sufficient to result in increased risk of
adverse non-cancer health effects. In
May 2010, the Science Advisory Board
(SAB) advised us ‘‘* * * that RTR
assessments will be most useful to
decision makers and communities if
results are presented in the broader
context of aggregate and cumulative
risks, including background
concentrations and contributions from
other sources in the area.’’ 5
While we are interested in placing
source category and facility-wide HAP
risks in the context of total HAP risks
from all sources combined in the
vicinity of each source, we are
concerned about the uncertainties of
doing so. At this point, we believe that
such estimates of total HAP risks will
have significantly greater associated
uncertainties than for the source
category or facility-wide estimates, and
hence compounding the uncertainty in
any such comparison. This is because
we have not conducted a detailed
technical review of HAP emissions data
for source categories and facilities that
have not previously undergone an RTR
review or are not currently undergoing
such review. We are requesting
comment on whether and how best to
estimate and evaluate total HAP
exposure in our assessments, and, in
particular, on whether and how it might
be appropriate to use information from
EPA’s National Air Toxics Assessment
(NATA) to support such estimates. We
are also seeking comment on how best
to consider various types and scales of
risk estimates when making our
acceptability and ample margin of safety
determinations under CAA section
112(f). Additionally, we are seeking
comments and recommendations for
any other comparative measures that
may be useful in the assessment of the
distribution of HAP risks across
potentially affected demographic
groups.
5 EPA’s responses to this and all other key
recommendations of the SAB’s advisory on RTR
risk assessment methodologies (which is available
at: https://yosemite.epa.gov/sab/sabproduct.nsf/
4AB3966E263D943A8525771F00668381/$File/EPASAB-10-007-unsigned.pdf) are outlined in a memo
to this rulemaking docket from David Guinnup
entitled, EPA’s Actions in Response to the Key
Recommendations of the SAB Review of RTR Risk
Assessment Methodologies.
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C. What other actions are we addressing
in this proposal?
1. Startup, Shutdown and Malfunction
This proposed action would amend
the provisions of the existing NESHAP
that apply to periods of startup,
shutdown, and malfunction (SSM). The
proposed revisions of these provisions
result from a Court decision that vacated
portions of two provisions in EPA’s
‘‘General Provisions’’ regulation under
CAA section 112, governing the
emissions of HAP during periods of
SSM. The current Primary Lead
Smelting MACT includes references to
the vacated provisions in the General
Provisions rule.
We are proposing to revise the
Primary Lead Smelting MACT standard
to require affected sources to comply
with the emission limitations at all
times and during periods of SSM.
Specifically, we are proposing several
revisions to subpart TTT including
revising Table 1 to indicate that the
requirements of the General Provisions
pertaining to SSM do not apply and to
revise language in § 63.1547 (g)(1) and
(2) to remove the exemption for bag leak
detection alarm time attributable to SSM
from total allowed alarm time. For
reasons discussed below, we are also
proposing to promulgate an affirmative
defense to civil penalties for
exceedances of emission standards
caused by malfunctions, as well as
criteria for establishing the affirmative
defense. These changes would go into
effect upon the effective date of
promulgation of the final rule.
The United States Court of Appeals
for the District of Columbia Circuit
vacated portions of two provisions in
EPA’s CAA Section 112 regulations
governing the emissions of HAP during
periods of SSM. Sierra Club v. EPA, 551
F.3d 1019 (D.C. Cir. 2008), cert. denied,
130 S. Ct. 1735 (U.S. 2010). Specifically,
the Court vacated the SSM exemptions
contained in 40 CFR 63.6(f)(1) and 40
CFR 63.6(h)(1), that are part of a
regulation commonly known as the
‘‘General Provisions Rule,’’ that EPA had
promulgated under section 112 of the
CAA. When incorporated into CAA
section 112(d) regulations for specific
source categories, these two provisions
exempt sources from the requirement to
comply with the otherwise applicable
CAA section 112(d) emission standard
during periods of SSM.
We are proposing the elimination of
the SSM exemption in this rule.
Consistent with Sierra Club v. EPA, EPA
is proposing standards in this rule that
apply at all times. We are also proposing
several revisions to Table 1 (the General
Provisions Applicability table). For
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example, we are proposing to eliminate
the incorporation of the General
Provisions’ requirement that the source
develop an SSM plan. We also are
proposing to eliminate or revise certain
recordkeeping and reporting that relate
to the SSM exemption. EPA has
attempted to ensure that we have not
included in the proposed regulatory
language any provisions that are
inappropriate, unnecessary, or
redundant in the absence of the SSM
exemption. We are specifically seeking
comment on whether there are any such
provisions that we have inadvertently
incorporated or overlooked.
In proposing standards in this rule,
EPA has taken into account startup and
shutdown periods and, for the reasons
explained below, has not proposed
different standards for those periods.
Information on periods of startup and
shutdown in the industry indicate that
emissions during these periods do not
increase. Furthermore, all processes are
controlled by either control devices or
work practices and these controls would
not typically be affected by an SSM
event. Also, compliance with the
standard already requires averaging of
emissions over a three month period,
which accounts for the variability of
emissions that may result during
periods of startup and shutdown.
Therefore, separate standards for
periods of startup and shutdown are not
being proposed.
Periods of startup, normal operations,
and shutdown are all predictable and
routine aspects of a source’s operations.
However, by contrast, malfunction is
defined as a ‘‘sudden, infrequent, and
not reasonably preventable failure of air
pollution control and monitoring
equipment, process equipment, or a
process to operate in a normal or useful
manner * * *’’ (40 CFR 63.2). EPA has
determined that malfunctions should
not be viewed as a distinct operating
mode and, therefore, any emissions that
occur at such times do not need to be
factored into development of CAA
section 112(d) standards, which, once
promulgated, apply at all times. In
Mossville Environmental Action Now v.
EPA, 370 F.3d 1232, 1242 (D.C. Cir.
2004), the court upheld as reasonable
standards that had factored in
variability of emissions under all
operating conditions. However, nothing
in section 112(d) or in case law requires
that EPA anticipate and account for the
innumerable types of potential
malfunction events in setting emission
standards. See, Weyerhaeuser v. Costle,
590 F.2d 1011, 1058 (D.C. Cir. 1978)(‘‘In
the nature of things, no general limit,
individual permit, or even any upset
provision can anticipate all upset
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situations. After a certain point, the
transgression of regulatory limits caused
by ‘uncontrollable acts of third parties,’
such as strikes, sabotage, operator
intoxication or insanity, and a variety of
other eventualities, must be a matter for
the administrative exercise of case-bycase enforcement discretion, not for
specification in advance by
regulation.’’).
Further, it is reasonable to interpret
section 112(d) as not requiring EPA to
account for malfunctions in setting
emission standards. For example, we
note that CAA section 112 uses the
concept of ‘‘best performing’’ sources in
defining MACT, the level of stringency
that major source standards must meet.
Applying the concept of ‘‘best
performing’’ to a source that is
malfunctioning presents significant
difficulties. The goal of best performing
sources is to operate in such a way as
to avoid malfunctions of their units.
Moreover, even if malfunctions were
considered a distinct operating mode,
we believe it would be impracticable to
take malfunctions into account in
setting CAA section 112(d) standards for
Primary Lead Smelting. As noted above,
by definition, malfunctions are sudden
and unexpected events and it would be
difficult to set a standard that takes into
account the myriad different types of
malfunctions that can occur across all
sources in the category. Moreover,
malfunctions can vary in frequency,
degree, and duration, further
complicating standard setting.
In the unlikely event that a source
fails to comply with the applicable CAA
section 112(d) standards as a result of a
malfunction event, EPA would
determine an appropriate response
based on, among other things, the good
faith efforts of the source to minimize
emissions during malfunction periods,
including preventative and corrective
actions, as well as root cause analyses
to ascertain and rectify excess
emissions. EPA would also consider
whether the source’s failure to comply
with the CAA section 112(d) standard
was, in fact, ‘‘sudden, infrequent, not
reasonably preventable’’ and was not
instead ‘‘caused in part by poor
maintenance or careless operation.’’ 40
CFR 63.2 (definition of malfunction).
Finally, EPA recognizes that even
equipment that is properly designed and
maintained can sometimes fail and that
such failure can sometimes cause or
contribute to an exceedance of the
relevant emission standard. (See, e.g.,
State Implementation Plans: Policy
Regarding Excessive Emissions During
Malfunctions, Startup, and Shutdown
(Sept. 20, 1999); Policy on Excess
Emissions During Startup, Shutdown,
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Maintenance, and Malfunctions (Feb.
15, 1983).) EPA is therefore proposing to
add to the final rule an affirmative
defense to civil penalties for
exceedances of emission limits that are
caused by malfunctions. See 40 CFR
63.1542 (defining ‘‘affirmative defense’’
to mean, in the context of an
enforcement proceeding, a response or
defense put forward by a defendant,
regarding which the defendant has the
burden of proof, and the merits of which
are independently and objectively
evaluated in a judicial or administrative
proceeding). We also are proposing
other regulatory provisions to specify
the elements that are necessary to
establish this affirmative defense; the
source must prove by a preponderance
of the evidence that it has met all of the
elements set forth in § 63.1551. (See 40
CFR 22.24.) The criteria ensure that the
affirmative defense is available only
where the event that causes an
exceedance of the emission limit meets
the narrow definition of malfunction in
40 CFR 63.2 (sudden, infrequent, not
reasonably preventable and not caused
by poor maintenance and/or careless
operation). For example, to successfully
assert the affirmative defense, the source
must prove by a preponderance of the
evidence that excess emissions ‘‘[w]ere
caused by a sudden, short, infrequent,
and unavoidable failure of air pollution
control and monitoring equipment,
process equipment, or a process to
operate in a normal or usual manner
* * *’’ The criteria also are designed to
ensure that steps are taken to correct the
malfunction, to minimize emissions in
accordance with §§ 63.1543(i) and
63.1544(e) and to prevent future
malfunctions. For example, the source
must prove by a preponderance of the
evidence that ‘‘[r]epairs were made as
expeditiously as possible when the
applicable emission limitations were
being exceeded * * *’’ and that ‘‘[a]ll
possible steps were taken to minimize
the impact of the excess emissions on
ambient air quality, the environment
and human health * * *.’’ In any
judicial or administrative proceeding,
the Administrator may challenge the
assertion of the affirmative defense and,
if the respondent has not met its burden
of proving all of the requirements in the
affirmative defense, appropriate
penalties may be assessed in accordance
with section 113 of the Clean Air Act
(see also 40 CFR part 22.77).
Specifically, we are proposing the
following changes to the rule.
• Added general duty requirements in
§§ 63.1543 and 63.1544 to replace
General Provision requirements that
reference vacated SSM provisions.
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• Added replacement language that
eliminates the reference to SSM
exemptions applicable to performance
tests in § 63.1546.
• Added paragraphs in § 63.1549(e)
requiring the reporting of malfunctions
as part of the affirmative defense
provisions.
• Added paragraphs in § 63.1549(b)
requiring the keeping of certain records
during malfunctions as part of the
affirmative defense provisions.
• Revised Table 1 to reflect changes
in the applicability of the General
Provisions to this subpart resulting from
a court vacatur of certain SSM
requirements in the General Provisions.
2. Lead as a Surrogate and Regulation of
Volatile Organic Compounds (VOC) and
Acid Gas Emissions
In a January 14, 2009, petition for
rulemaking filed by the Natural
Resources Defense Council and Sierra
Club, the petitioners claim that for the
Primary Lead Smelting MACT, EPA
relied on lead as a surrogate for all HAP
and they claim that it was inappropriate
for EPA to do so in absence of a showing
that lead is an appropriate surrogate for
all other HAP (such as mercury, acid
gases, and volatile organic compounds
(VOC)). The petitioners asserted that
EPA should set standards for other HAP
absent a showing that lead is an
appropriate surrogate for these HAP.
They also assert that EPA’s PM standard
does not reflect the emission level
achieved by the best performing sources
and that EPA must re-open the rule to
set floors for PM in accordance with
CAA section 112(d)(3). A copy of the
petition is included in the docket.
As part of this rulemaking, EPA is
responding to the claims made by the
petitioners regarding the Primary Lead
Smelting MACT.
As an initial matter, the petitioners
are incorrect in their claim that EPA
considers lead as a surrogate for all
HAP. Rather, EPA used lead as a
surrogate only for other metal HAP
compounds in establishing the
emissions limit in the current MACT
standard for this source category (63 FR
19206 and 64 FR 30195). EPA
determined in the 1999 rule that lead,
a nonvolatile metal HAP, is an
appropriate surrogate for other
nonvolatile metal HAP including
antimony, arsenic, chromium, nickel,
manganese, and cadmium. In the
proposed rule for the Primary Lead
Smelting MACT (63 FR 19206), EPA
discussed the use of lead as a surrogate
for metal HAP emissions and explained
that strong correlations exist between
emissions of lead and other metal HAP
and that the technologies identified for
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the control of metal HAP are the same
as those used to control lead emissions.
Therefore, EPA expected that the
standards requiring control of lead
would achieve similar control of the
other metal HAP emitted from primary
lead smelters. No adverse comments
were received regarding EPA’s proposed
rationale for relying on lead as a
surrogate for other metal HAP emitted
by these sources and EPA adopted that
rationale in the final rule promulgating
the Primary Lead Smelting MACT. The
petitioners do not have any substantive
basis as to why EPA’s rationale is not
supported. Nor do they claim that there
is any new information that would
support re-opening this issue. Thus they
fail to present a basis for re-opening this
issue.
The petitioners also insist that EPA
should have set standards for VOC and
acid gases that are HAP because lead
would not be a surrogate for these
pollutants. EPA noted in the original
proposal that due to small amounts of
coke fed to the blast furnace, organic
HAP (VOC) was emitted at a rate so low
as to be infeasible to reduce. Again, no
adverse comments were received on
EPA’s proposed conclusions, which
were adopted in the final rule, and the
petitioners do not now provide
substantive support for their claim. Nor
do they explain why any such claim
could not have been raised during the
initial rulemaking. Thus, they fail to
present a basis for re-opening the rule
on this issue.
Finally, petitioners claim that the ‘‘PM
standard does not reflect the emission
level achieved by the best performing
sources.’’ This claim is unclear as there
is no PM standard in the Primary Lead
Smelting MACT. The monitoring
provisions provide that PM should be
measured in relation to a predetermined
PM level as one test for indicating
baghouse performance. However, the
PM levels are not enforceable emission
limits, but merely an indication that the
baghouse may not be operating
properly. Again, these provisions were
clearly explained in the proposed and
final Primary Lead Smelting MACT
rulemakings. Any claims concerning the
appropriateness of these monitoring
requirements should have been raised
during the initial rulemaking process.
Petitioners do not claim any new
grounds for raising this issue now.
Thus, the petition fails to provide a
basis for re-opening the MACT.
3. Modification of the Applicability
Provision
EPA is proposing to amend the
applicability section to apply to any
facility processing lead ore concentrate
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to produce lead metal. Under the
current applicability provisions, the
affected sources include any sinter
machine, blast furnace, dross furnace,
process fugitive source, and fugitive
dust source located at a primary lead
smelter and excludes secondary lead
smelters, lead refiners, or lead remelters.
Combined with the current definition
for ‘‘primary lead smelter,’’ the current
rule effectively only applies to facilities
that produce lead metal from lead
sulfide ore concentrates using
pyrometallurgical techniques. While the
only processes available for the
production of lead from lead ore
concentrate at the time the MACT rule
was developed were pyrometallurgical
techniques, that applicability language
is narrower than the primary lead
smelting source category description
EPA identified in its source category
listing issued pursuant to CAA section
112(c)(1), Documentation for
Developing the Initial Source Category
List (EPA–450/3–91–030, July 1992). In
the source category listing, EPA defined
the primary lead smelting source
category as follows: ‘‘The Primary Lead
Smelting source category includes any
facility engaged in producing lead metal
from ore concentrates. The category
includes, but is not limited to, the
following smelting processes: sintering
reduction, preliminary treatment, and
refining operations. The sintering
process includes an updraft or
downdraft sintering machine. The
reduction process includes the blast
furnace, electric smelting furnace with a
converter or reverberatory furnace, and
slag fuming furnace process units. The
preliminary treatment process includes
the drossing kettles and dross
reverberatory furnace process units. The
refining process includes the refinery
process unit.’’ The definition is clear
that the primary intent was to cover
sources that produce lead metal from
ore concentrates, which would
‘‘include’’ the use of a pyrometallurgical
process, but would not be limited to
such. As noted previously, at the time
we promulgated the MACT standard,
the only method of producing lead
metal from ore concentrates was
through use of pyrometallurgical
techniques and we adopted an
applicability provision that focused on
that process.
However, information provided by the
sole operating primary lead smelting
facility indicates that lead production is
likely to continue at the current Doe
Run facility, although using a process
other than a pyrometallurgical
technique. The new lead facility would
continue to process lead ore concentrate
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in order to produce lead metal. Based on
the current applicability section and
definitions, it could be interpreted that
the future lead producing process, using
techniques other than
pyrometallurgical, would not be subject
to the NESHAP for primary lead
smelters. Such a limited interpretation
is not consistent with EPA’s intent as
evidenced by the broader definition in
the source category list. Therefore, EPA
is proposing to amend the applicability
section to specify that the MACT
applies to any lead processing facility
that produces lead metal from lead ore
concentrate. Consistent with the
proposed revision to the applicability
section, we are proposing to remove the
definition of ‘‘primary lead smelter’’ and
add a definition of ‘‘primary lead
processor’’ which means any facility
engaged in the production of lead metal
from lead sulfide ore concentrates
through the use of pyrometallurgical or
other techniques. In addition, we are
proposing to replace ‘‘primary lead
smelter’’ with ‘‘primary lead processor’’
throughout 40 CFR subpart TTT.
(§ 63.1541 through § 63.1545, § 63.1547
through § 63.1549). We are specifically
asking for comment on this proposed
change in the definition.
Because there is only one primary
lead processing facility in the U.S., there
will be no impact of this change on the
number of existing facilities covered by
the MACT.
We note, however, that although we
are changing the applicability section to
clarify that the MACT applies to all
processes for producing lead metal from
ore concentrates, we are not today
proposing a specific MACT standard
that would apply to the as-yet
undemonstrated hydrometallurgical
process which Doe Run has indicated
that it plans to build at the current Doe
Run facility. If and when that process
begins operation, we will consider
whether to revise the MACT standard to
specifically address that process or any
other new processes. However, the
limits applicable to specific emission
sources currently in operation as
specified in the MACT and as revised
under CAA sections 112(d)(6) and (f)(2)
in this rulemaking would continue to
apply to any emission source at the
facility that continues in operation, such
as the refinery. In addition, to the extent
that we establish a final air lead
concentration limit as proposed in
§ 63.1544, those limits would also
continue to apply to the facility. We also
are proposing that the plant-wide
emission limit we are proposing today
should continue to apply to any facility
that meets the revised applicability
definition, but we are specifically
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soliciting comment on whether it
should apply.
We are also taking this opportunity to
clarify the reference to ‘‘lead refiners’’ in
the second sentence of the applicability
section, which provides that the MACT
standard does not apply to ‘‘secondary
lead smelters, lead refiners, or lead
remelters.’’ The intent of this provision
was to make clear that secondary lead
smelters would not be subject to the rule
because secondary lead smelters were
listed as a separate source category and
addressed in a separate MACT standard.
With regard to lead refiners and lead
remelters, the intent was to provide that
these activities, to the extent that they
are not located at facilities that produce
lead from lead ore concentrate, would
not be subject to the Primary Lead
Smelting MACT. However, it was not
the intention of the rule to exempt kettle
refining operations included as part of
a primary lead processing facility.
Therefore, EPA is proposing to add
definitions for secondary lead smelters,
lead refiners, and lead remelters in the
definitions section of this NESHAP in
order to further clarify the exemption in
the applicability provisions with regard
to these types of facilities. As this
change only clarifies an existing
provision in the rule, there will be no
impact to the number of facilities
covered by the rule.
4. Other Changes
The following lists additional minor
changes we are proposing. This list
includes rule changes that address
editorial errors and plain language
revisions.
• As part of EPA’s effort to
incorporate plain language into its
regulations, replaced the word ‘‘shall’’
with ‘‘must.’’ (§ 63.1543 through
§ 63.1550)
• Correction to the original rule
(‘‘thru’’ replaced with ‘‘through’’ in the
definition of ‘‘tapping location’’).
(§ 63.1542)
• Minor wording change to definition
of ‘‘fugitive dust source’’ to clarify
meaning. (§ 63.1542)
IV. Analyses Performed and
Background of the Source Category and
MACT Standard
As discussed above, in this proposed
rule we are proposing action to address
the RTR requirements of CAA sections
112(d)(6) and (f)(2) for the Primary Lead
Smelting MACT standard. In this
section, we describe the analyses
performed to support the proposed
decisions for the RTR for this source
category and we also include
background information on the source
category and the MACT standard.
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A. How did we estimate risks posed by
the source category?
The EPA conducted a risk assessment
that provided estimates of the MIR
posed by the HAP emissions from the
one source in the source category, the
distribution of cancer risks within the
exposed populations, cancer incidence,
HI for chronic exposures to HAP with
the potential to cause non-cancer health
effects, hazard quotients (HQ) for acute
exposures to HAP with the potential to
cause non-cancer health effects, and an
evaluation of the potential for adverse
environmental effects. The risk
assessments consisted of seven primary
steps, as discussed below.
The docket for this rulemaking
contains the following document which
provides more information on the risk
assessment inputs and models: Draft
Residual Risk Assessment for the
Primary Lead Smelting Source Category.
1. Establishing the Nature and
Magnitude of Actual Emissions and
Identifying the Emissions Release
Characteristics
For the Primary Lead Smelting source
category, we compiled a preliminary
dataset using readily available
information, reviewed the data, and
made changes where necessary. The
preliminary dataset was based on data
in the 2002 National Emissions
Inventory (NEI) Final Inventory, Version
1 (made publicly available on February
26, 2006). The NEI is a database that
contains information about sources that
emit criteria air pollutants, their
precursors, and HAP. The NEI database
includes estimates of annual air
pollutant emissions from point, nonpoint, and mobile sources in the 50
States, the District of Columbia, Puerto
Rico, and the Virgin Islands. The EPA
collects this information and releases an
updated version of the NEI database
every 3 years.
On December 4, 2009, a CAA Section
114 Information Collection Request
(ICR) was issued requesting information
from the one facility in this source
category. An updated dataset was
created through incorporation of
changes to the dataset from the ICR data
review process and additional
information gathered by EPA. The
updated dataset contains information
for the one facility in the source
category and was used to conduct the
risk assessment and other analyses that
form the basis for the proposed risk and
technology reviews. A copy of the
dataset used and documentation of the
risk assessment can be found in the
docket.
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2. Establishing the Relationship
Between Actual Emissions and MACT–
Allowable Emissions Levels
The available emissions data in the
NEI and from other sources typically
represent the estimates of mass of
emissions actually emitted during the
specified annual time period. These
‘‘actual’’ emission levels are often lower
than the emission levels that a facility
might be allowed to emit and still
comply with the MACT standards. The
emissions level allowed to be emitted by
the MACT standards is referred to as the
‘‘MACT-allowable’’ emissions level. This
represents the highest emissions level
that could be emitted by the facility
without violating the MACT standards.
We discussed the use of both MACTallowable and actual emissions in the
final Coke Oven Batteries residual risk
rule (70 FR 19998–19999, April 15,
2005) and in the proposed and final
Hazardous Organic NESHAP (HON)
residual risk rules (71 FR 34428, June
14, 2006, and 71 FR 76609, December
21, 2006, respectively). In those
previous actions, we noted that
assessing the risks at the MACTallowable level is inherently reasonable
since these risks reflect the maximum
level sources could emit and still
comply with national emission
standards. But we also explained that it
is reasonable to consider actual
emissions, where such data are
available, in both steps of the risk
analysis, in accordance with the
Benzene NESHAP. (54 FR 38044,
September 14, 1989.) It is reasonable to
consider actual emissions because
sources typically seek to perform better
than required by emission standards to
provide an operational cushion to
accommodate the variability in
manufacturing processes and control
device performance.
As described above, the actual
emissions data were compiled based on
the NEI, information gathered from the
facility and State, and information
received in response to the ICR. To
estimate emissions at the MACTallowable level, we developed a ratio of
MACT-allowable to actual emissions for
each source type (i.e., the individual
stacks and the aggregate fugitive
emissions) for the one facility in the
source category. This ratio is based on
the level of control required by the
MACT standards compared to the level
of reported actual emissions and
available information on the level of
control achieved by the emissions
controls in use. For example, if there
was information to suggest that an
emission point type was being
controlled by 98 percent while the
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MACT standards required only 92
percent control, we would estimate that
MACT-allowable emissions from that
emission point type could be as much
as 4 times higher (8 percent allowable
emissions compared with 2 percent
actually emitted), and the ratio of
MACT-allowable to actual would be 4:1
for this emission point type. After
developing these ratios for each
emission point type at the one facility
in this source category, we next applied
these ratios to the maximum chronic
risk estimates from the inhalation risk
assessment to obtain maximum risk
estimates based on MACT-allowable
emissions. The estimate of MACTallowable emissions for the Primary
Lead Smelting source category is
described in section V of this preamble.
3. Conducting Dispersion Modeling,
Determining Inhalation Exposures, and
Estimating Individual and Population
Inhalation Risks
Both long-term and short-term
inhalation exposure concentrations and
health risks from the source category
addressed in this proposal were
estimated using the Human Exposure
Model (Community and Sector HEM–3
version 1.1.0). The HEM–3 performs
three of the primary risk assessment
activities listed above: (1) Conducting
dispersion modeling to estimate the
concentrations of HAP in ambient air,
(2) estimating long-term and short-term
inhalation exposures to individuals
residing within 50 km of the modeled
sources, and (3) estimating individual
and population-level inhalation risks
using the exposure estimates and
quantitative dose-response information.
The dispersion model used by HEM–
3 is AERMOD, which is one of EPA’s
preferred models for assessing pollutant
concentrations from industrial
facilities.6 To perform the dispersion
modeling and to develop the
preliminary risk estimates, HEM–3
draws on three data libraries. The first
is a library of meteorological data,
which is used for dispersion
calculations. This library includes 1
year of hourly surface and upper air
observations for 130 meteorological
stations, selected to provide coverage of
the United States and Puerto Rico.
However, in this instance, site-specific
meteorological data for the one facility
in this source category were supplied by
the state of Missouri and used for the
modeling. The data provided by the
state of Missouri were for eight quarters
6 U.S. EPA. Revision to the Guideline on Air
Quality Models: Adoption of a Preferred General
Purpose (Flat and Complex Terrain) Dispersion
Model and Other Revisions (70 FR 68218,
November 9, 2005).
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(i.e., eight three-month periods) from
April 1997 through June 1999. To obtain
one year of meteorological data, we used
the middle portion of these data, the
year 1998, in our modeling. A second
library of United States Census Bureau
census block 7 internal point locations
and populations provides the basis of
human exposure calculations (Census,
2000). In addition, for each census
block, the census library includes the
elevation and controlling hill height,
which are also used in dispersion
calculations. A third library of pollutant
unit risk factors and other health
benchmarks is used to estimate health
risks. These risk factors and health
benchmarks are the latest values
recommended by EPA for HAP and
other toxic air pollutants. These values
are available at https://www.epa.gov/ttn/
atw/toxsource/summary.html and are
discussed in more detail later in this
section.
In developing the risk assessment for
chronic exposures, we used the
estimated annual average ambient air
concentration of each of the HAP
emitted by each source for which we
have emissions data in the source
category. The air concentrations at each
nearby census block centroid were used
as a surrogate for the chronic inhalation
exposure concentration for all the
people who reside in that census block.
We calculated the MIR for the one
facility as the cancer risk associated
with a lifetime (70-year period) of
exposure to the maximum concentration
at the centroid of an inhabited census
block. Individual cancer risks were
calculated by multiplying the estimated
lifetime exposure to the ambient
concentration of each of the HAP (in
micrograms per cubic meter) by its Unit
Risk Estimate (URE), which is an upper
bound estimate of an individual’s
probability of contracting cancer over a
lifetime of exposure to a concentration
of 1 microgram of the pollutant per
cubic meter of air. In general, for
residual risk assessments, we use URE
values from EPA’s Integrated Risk
Information System (IRIS). For
carcinogenic pollutants without EPA
IRIS values, we look to other reputable
sources of cancer dose-response values,
often using California Environmental
Protection Agency (CalEPA) URE
values, where available. In cases where
new, scientifically credible doseresponse values have been developed in
a manner consistent with EPA
guidelines and have undergone a peer
review process similar to that used by
7 A census block is generally the smallest
geographic area for which census statistics are
tabulated.
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EPA, we may use such dose response
values in place of, or in addition to,
other values, if appropriate. In this
review, IRIS values were available for
both carcinogenic pollutants (cadmium
and arsenic) emitted by the facility in
this source category, and therefore IRIS
values were used in the assessment.
Incremental individual lifetime
cancer risks associated with emissions
from the one source in the source
category were estimated as the sum of
the risks for each of the carcinogenic
HAP (including those classified as
carcinogenic to humans, likely to be
carcinogenic to humans, and suggestive
evidence of carcinogenic potential 8)
emitted by the modeled source. Cancer
incidence and the distribution of
individual cancer risks for the
population within 50 km of the source
were also estimated for the source
category as part of these assessments by
summing individual risks. A distance of
50 km is consistent with both the
analysis supporting the 1989 Benzene
NESHAP (54 FR 38044) and the
limitations of Gaussian dispersion
models, including AERMOD.
To assess risk of non-cancer health
effects from chronic exposures, we
summed the HQ for each of the HAP
that affects a common target organ
system to obtain the HI for that target
organ system (or target organ-specific
HI, TOSHI). The HQ is the estimated
exposure divided by the chronic
reference value, which is either the EPA
RfC, defined as ‘‘an estimate (with
uncertainty spanning perhaps an order
of magnitude) of a continuous
inhalation exposure to the human
population (including sensitive
subgroups) that is likely to be without
an appreciable risk of deleterious effects
during a lifetime,’’ or, in cases where an
RfC is not available, the Agency for
Toxic Substances and Disease Registry
(ATSDR) chronic Minimal Risk Level
(MRL) or the CalEPA Chronic Reference
Exposure Level (REL). The REL is
defined as ‘‘the concentration level at or
below which no adverse health effects
are anticipated for a specified exposure
duration.’’
8 These classifications also coincide with the
terms ‘‘known carcinogen, probable carcinogen, and
possible carcinogen,’’ respectively, which are the
terms advocated in the EPA’s previous Guidelines
for Carcinogen Risk Assessment, published in 1986
(51 FR 33992, September 24, 1986). Summing the
risks of these individual compounds to obtain the
cumulative cancer risks is an approach that was
recommended by the EPA’s SAB in their 2002 peer
review of EPA’s NATA entitled, NATA—Evaluating
the National-scale Air Toxics Assessment 1996
Data—an SAB Advisory, available at: https://
yosemite.epa.gov/sab/sabproduct.nsf/214C6E915BB
04E14852570CA007A682C/$File/ecadv02001.pdf.
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Screening estimates of acute
exposures and risks were also evaluated
for each of the HAP at the point of
highest off-site exposure for each facility
(i.e., not just the census block centroids)
assuming that a person was located at
this spot at a time when both the peak
(hourly) emission rate and hourly
dispersion conditions occurred. In
general, acute HQ values were
calculated using best available, shortterm dose-response value. These acute
dose-response values include REL,
Acute Exposure Guideline Levels
(AEGL), and Emergency Response
Planning Guidelines (ERPG) for 1-hour
exposure durations. Notably, for HAP
emitted from this source category, REL
values were the only such doseresponse values available. As discussed
below, we used conservative
assumptions for emission rates,
meteorology, and exposure location for
our acute analysis.
As described in the CalEPA’s Air
Toxics Hot Spots Program Risk
Assessment Guidelines, Part I, The
Determination of Acute Reference
Exposure Levels for Airborne Toxicants,
an acute REL value (https://
www.oehha.ca.gov/air/pdf/acuterel.pdf)
is defined as ‘‘the concentration level at
or below which no adverse health
effects are anticipated for a specified
exposure duration is termed the REL.
REL values are based on the most
sensitive, relevant, adverse health effect
reported in the medical and
toxicological literature. REL values are
designed to protect the most sensitive
individuals in the population by the
inclusion of margins of safety. Since
margins of safety are incorporated to
address data gaps and uncertainties,
exceeding the REL does not
automatically indicate an adverse health
impact.
To develop screening estimates of
acute exposures, we first developed
estimates of maximum hourly emission
rates by multiplying the average actual
annual hourly emission rates by a factor
to cover routinely variable emissions.
We chose the factor to use based on
process knowledge and engineering
judgment and with awareness of a Texas
study of short-term emissions
variability, which showed that most
peak emission events, in a heavilyindustrialized 4-county area (Harris,
Galveston, Chambers, and Brazoria
Counties, Texas) were less than twice
the annual average hourly emission rate.
The highest peak emission event was 74
times the annual average hourly
emission rate, and the 99th percentile
ratio of peak hourly emission rate to the
annual average hourly emission rate was
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9.9 This analysis is provided in
Appendix 4 of the Draft Residual Risk
Assessment for Primary Lead Smelting
which is available in the docket for this
action. Considering this analysis, unless
specific process knowledge or data are
available to provide an alternate value,
to account for more than 99 percent of
the peak hourly emissions, we apply a
conservative screening multiplication
factor of 10 to the average annual hourly
emission rate in these acute exposure
screening assessments. For the Primary
Lead Smelting source category, this
factor of 10 was applied.
In cases where all acute HQ values
from the screening step were less than
or equal to 1, acute impacts were
deemed negligible and no further
analysis was performed. In the cases
where an acute HQ from the screening
step was greater than 1, additional sitespecific data were considered to
develop a more refined estimate of the
potential for acute impacts of concern.
Ideally, we would prefer to have
continuous measurements over time to
see how the emissions vary by each
hour over an entire year. Having a
frequency distribution of hourly
emission rates over a year would allow
us to perform a probabilistic analysis to
estimate potential threshold
exceedances and their frequency of
occurrence. Such an evaluation could
include a more complete statistical
treatment of the key parameters and
elements adopted in this screening
analysis. However, we recognize that
having this level of data is rare, hence
our use of the multiplier (i.e., factor of
10) approach in our screening analysis.
4. Conducting Multipathway Exposure
and Risk Modeling
The potential for significant human
health risks due to exposures via routes
other than inhalation (i.e.,
multipathway exposures) and the
potential for adverse environmental
impacts were evaluated in a three-step
process. In the first step, we determined
whether any facilities emitted any HAP
known to be persistent and bioaccumulative in the environment (PB–
HAP). There are 14 PB–HAP
compounds or compound classes
identified for this screening in EPA’s Air
Toxics Risk Assessment Library
(available at https://www.epa.gov/ttn/
fera/risk_atra_vol1.html). They are
cadmium compounds, chlordane,
chlorinated dibenzodioxins and furans,
dichlorodiphenyldichloroethylene,
heptachlor, hexachlorobenzene,
9 See https://www.tceq.state.tx.us/compliance/
field_ops/eer/ or docket to access the
source of these data.
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hexachlorocyclohexane, lead
compounds, mercury compounds,
methoxychlor, polychlorinated
biphenyls, POM, toxaphene, and
trifluralin. Emissions of two PB HAP
were identified in the emissions
inventory for the Primary Lead Smelting
source category: Lead compounds and
cadmium compounds.
Cadmium emissions were evaluated
for potential non-inhalation risks and
adverse environmental impacts using
our recently developed screening
scenario that was developed for use
with the TRIM.FaTE model. This
screening scenario uses environmental
media outputs from the peer-reviewed
TRIM.FaTE to estimate the maximum
potential ingestion risks for any
specified emission scenario by using a
generic farming/fishing exposure
scenario that simulates a subsistence
environment. The screening scenario
retains many of the ingestion and
scenario inputs developed for EPA’s
Human Health Risk Assessment
Protocols (HHRAP) for hazardous waste
combustion facilities. In the
development of the screening scenario a
sensitivity analysis was conducted to
ensure that its key design parameters
were established such that
environmental media concentrations
were not underestimated, and to also
minimize the occurrence of false
positives for human health endpoints.
See Appendix 3 of the risk assessment
document for a complete discussion of
the development and testing of the
screening scenario, as well as for the
values of facility-level de minimis
emission rates developed for screening
potentially significant multi-pathway
impacts. For the purpose of developing
de minimis emission rates for our
cadmium multi-pathway screening, we
derived emission levels for cadmium at
which the maximum human health risk
would be 1-in-1 million for lifetime
cancer risk.
In evaluating the potential air-related
multi-pathway risks from the emissions
of lead compounds from the one facility
in this source category, rather than
developing a de minimis emission rate,
we compared its maximum modeled 3month average atmospheric lead
concentration at any off-site location
with the current primary National
Ambient Air Quality Standard (NAAQS)
for lead (promulgated in 2008), which is
set to a level of 0.15 micro-grams per
cubic meter (μg/m3) based on a rolling
3-month period with a not-to-beexceeded form, and which will require
attainment by 2016. 73 FR 66964.
Notably, in making these comparisons,
we estimated maximum rolling 3-month
ambient lead concentrations taking into
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account all of the elements of the
NAAQS for lead. That is, our estimated
3-month lead concentrations are
calculated in a manner that is consistent
with the indicator, averaging time, and
form of the NAAQS for lead, and those
estimates are compared to the actual
level of the lead NAAQS (0.15 μg/m3).
The NAAQS value, a public health
policy judgment, incorporated the
Agency’s most recent health evaluation
of air effects of lead exposure for the
purposes of setting a national standard.
In setting this value, the Administrator
promulgated a standard that was
requisite to protect public health with
an adequate margin of safety. We
consider values below the level of the
primary NAAQS to protect against
multi-pathway risks because, as
mentioned above, the primary NAAQS
is set as to protect public health with an
adequate margin of safety. However,
ambient air lead concentrations above
the NAAQS are considered to pose the
potential for increased risk to public
health. We consider this NAAQS
assessment to be a refined analysis
given the numerous health studies,
detailed risk and exposure analyses, and
level of external peer and public review
that went into the development of the
primary NAAQS for lead, combined
with the site-specific dispersion
modeling analysis performed to develop
the ambient concentration estimates due
to emissions from the one Primary Lead
Processing facility being addressed in
this RTR. It should be noted, however,
that this comparison does not account
for possible population exposures to
lead from sources other than the one
being modeled; for example, via
consumption of water from untreated
local sources or ingestion of locally
grown food. Nevertheless, the
Administrator judged that such a
standard, would protect, with an
adequate margin of safety, the health of
children and other at-risk populations
against an array of adverse health
effects, most notably including
neurological effects, particularly
neurobehavioral and neurocognitive
effects, in children. 73 FR 67007. The
Administrator, in setting the standard,
also recognized that no evidence-or risk
based bright line indicated a single
appropriate level. Instead a collection of
scientific evidence and other
information was used to select the
standard from a range of reasonable
values. 73 FR 67006.
We further note that comparing
ambient lead concentrations to the
NAAQS for lead, considering the level,
averaging time, form and indicator, also
informs whether there is the potential
for adverse environmental effects. This
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is because the secondary lead NAAQS,
which has the same averaging time,
form, and level as the primary standard,
was set to protect the public welfare
which includes among other things
soils, water, crops, vegetation and
wildlife. CAA section 302(h). Thus,
ambient lead concentrations above the
NAAQS for lead also indicate the
potential for adverse environmental
effects.
For additional information on the
multi-pathway analysis approach, see
the residual risk documentation as
referenced in section IV.A of this
preamble. The EPA solicits comment
generally on the modeling approach
used herein to assess air-related lead
risks, and specifically on the use of the
lead NAAQS in this analytical
construct.
5. Assessing Risks Considering
Emissions Control Options
In addition to assessing baseline
inhalation risks and screening for
potential multi-pathway risks, we also
estimated risks considering the potential
emission reductions that would be
achieved by the particular control
options under consideration. The
expected emissions reductions were
applied to the specific HAP and
emissions points in the source category
dataset to develop corresponding
estimates of risk reductions.
6. Conducting Other Risk-Related
Analyses, Including Facility-Wide
Assessments and Demographic Analyses
a. Facility-Wide Risk
To put the source category risks in
context, for our residual risk review, we
also examine the risks from the entire
‘‘facility,’’ where the facility includes all
HAP-emitting operations within a
contiguous area and under common
control. In other words, we examine the
HAP emissions not only from the source
category of interest, but also emissions
of HAP from all other emission sources
at the facility. In this rulemaking, for the
sole facility in the Primary Lead
Smelting source category, there are no
other significant HAP emission sources
present. With the exception of organic
HAP sources determined to present
insignificant risk, all HAP sources have
been included in the risk analysis.
Therefore, the facility-wide risks are the
same as the source category risk and no
separate facility-wide analysis was
necessary.
b. Demographic Analysis
To examine the potential for any
environmental justice issues that might
be associated with HAP emissions with
this source category, we evaluated the
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distributions of HAP-related cancer and
non-cancer risks across different social,
demographic, and economic groups
within the populations living near the
one facility in this source category. The
development of demographic analyses
to inform the consideration of
environmental justice issues in EPA
rulemakings is evolving. EPA offers the
demographic analyses in this
rulemaking to inform the consideration
of potential environmental justice
issues, and invites public comment on
the approaches used and the
interpretations made from the results,
with the hope that this will support the
refinement and improve the utility of
such analyses for future rulemakings.
For the demographic analyses, we
focus on the populations within 50 km
of any facility with emission sources
subject to the MACT standard (identical
to the risk assessment). Based on the
emissions for the source category or the
facility, we then identified the
populations that are estimated to have
exposures to HAP which result in: (1)
Cancer risks of 1-in-1 million or greater,
(2) non-cancer HI of 1 or greater, and/
or (3) ambient lead concentrations above
the level of the NAAQS for lead. We
compare the percentages of particular
demographic groups within the focused
populations to the total percentages of
those demographic groups nationwide.
The results, including other risk
metrics, such as average risks for the
exposed populations, are documented
in a technical report in the docket for
the source category covered in this
proposal.10
The basis for the risk values used in
the demographic analyses for the one
facility subject to the Primary Lead
Smelting MACT was the modeling
results based on actual emissions levels
obtained from the HEM–3 model
described above. The risk values for
each census block were linked to a
database of information from the 2000
decennial census that includes data on
race and ethnicity, age distributions,
poverty status, household incomes, and
education level. The Census Department
Landview® database was the source of
the data on race and ethnicity, and the
data on age distributions, poverty status,
household incomes, and education level
were obtained from the 2000 Census of
Population and Housing Summary File
3 (SF3) Long Form. While race and
ethnicity census data are available at the
census block level, the age and income
census data are only available at the
census block group level (which
10 Risk and Technology Review—Analysis of
Socio-Economic Factors for Populations Living Near
Primary Lead Smelting Operations.
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includes an average of 26 blocks or an
average of 1,350 people). Where census
data are available at the block group
level but not the block level, we
assumed that all census blocks within
the block group have the same
distribution of ages and incomes as the
block group.
We focused the analysis on those
census blocks where source category
risk results show either estimated
lifetime inhalation cancer risks above 1in-1 million or chronic non-cancer
indices above 1. In addition, in this case
we also focused on those census blocks
where estimated ambient lead
concentrations were above the level of
the lead NAAQS. For each of these
cases, we determined the relative
percentage of different racial and ethnic
groups, different age groups, adults with
and without a high school diploma,
people living in households below the
national median income, and for people
living below the poverty line within
those census blocks. The specific census
population categories included:
• Total population;
• White;
• African American (or Black);
• Native Americans;
• Other races and multiracial;
• Hispanic or Latino;
• People living below the poverty
line;
• Children 18 years of age and under;
• Adults 19 to 64 years of age;
• Adults 65 years of age and over;
• Adults without a high school
diploma.
It should be noted that these
categories overlap in some instances,
resulting in some populations being
counted in more than one category (e.g.,
other races and multiracial and
Hispanic). In addition, while not a
specific census population category, we
also examined risks to ‘‘Minorities,’’ a
classification which is defined for these
purposes as all race population
categories except white.
The methodology and the results of
the demographic analyses for this
source category are included in the
technical report available in the docket
for this action. (Risk and Technology
Review—Analysis of Socio-Economic
Factors for Populations Living Near
Primary Lead Smelting Operations).
7. Considering Uncertainties in Risk
Assessment
Uncertainty and the potential for bias
are inherent in all risk assessments,
including that performed for the source
category addressed in this proposal.
Although uncertainty exists, we believe
the approach that we took, which used
conservative tools and assumptions,
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ensures that our decisions are healthprotective. A brief discussion of the
uncertainties in the emissions dataset,
dispersion modeling, inhalation
exposure estimates, and dose-response
relationships follows below. A more
thorough discussion of these
uncertainties is included in the risk
assessment documentation (Draft
Residual Risk Assessment for Primary
Lead Smelting) available in the docket
for this action.
a. Uncertainties in the Emissions
Dataset
Although the development of the RTR
dataset involved quality assurance/
quality control processes, the accuracy
of emissions values will vary depending
on the source of the data, the degree to
which data are incomplete or missing,
the degree to which assumptions made
to complete the datasets are accurate,
whether and to what extent errors were
made in estimating emissions values,
and other factors. The emission
estimates considered in this analysis are
annual totals provided by the facility
that do not reflect short-term
fluctuations during the course of a year
or variations from year to year. In
contrast, the estimates of peak hourly
emission rates for the acute effects
screening assessment were based on
multiplication factors applied to the
average annual hourly emission rates
(the default factor of 10 was used for
Primary Lead Smelting), which is
intended to account for emission
fluctuations due to normal facility
operations.
b. Uncertainties in Dispersion Modeling
While the analysis employed EPA’s
recommended regulatory dispersion
model, AERMOD, we recognize that
there is uncertainty in ambient
concentration estimates associated with
any model, including AERMOD. In
circumstances where we had to choose
between various model options, where
possible, we selected model options
(e.g., rural/urban, plume depletion,
chemistry) that provided an
overestimate of ambient concentrations
of the HAP rather than an
underestimate. However, because of
practicality and data limitation reasons,
some factors (e.g., building downwash)
have the potential in some situations to
overestimate or underestimate ambient
impacts. Despite these uncertainties, we
believe that at off-site locations and
census block centroids, the approach
considered in the dispersion modeling
analysis should generally yield
overestimates of ambient HAP
concentrations.
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c. Uncertainties in Inhalation Exposure
The effects of human mobility on
exposures were not included in the
assessment. Specifically, short-term
mobility and long-term mobility
between census blocks in the modeling
domain were not considered.11 As a
result, this simplification will likely
bias the assessment toward
overestimating the highest exposures. In
addition, the assessment predicted the
chronic exposures at the centroid of
each populated census block as
surrogates for the exposure
concentrations for all people living in
that block. Using the census block
centroid to predict chronic exposures
tends to over-predict exposures for
people in the census block who live
farther from the facility, and underpredict exposures for people in the
census block who live closer to the
facility. Thus, using the census block
centroid to predict chronic exposures
may lead to a potential understatement
or overstatement of the true maximum
impact for any one individual, but is an
unbiased estimate of average risk and
incidence.
The assessments evaluate the
projected cancer inhalation risks
associated with pollutant exposures
over a 70-year period, which is the
assumed lifetime of an individual. In
reality, both the length of time that
modeled emissions sources at facilities
actually operate (i.e., more or less than
70 years), and the domestic growth or
decline of the modeled industry (i.e., the
increase or decrease in the number or
size of United States facilities), will
influence the future risks posed by a
given source or source category.
Depending on the characteristics of the
industry, these factors will, in most
cases, result in an overestimate both in
individual risk levels and in the total
estimated number of cancer cases.
However, in rare cases, where a facility
maintains or increases its emission
levels beyond 70 years, residents live
beyond 70 years at the same location,
and the residents spend most of their
days at that location, then the risks
could potentially be underestimated.
Annual cancer incidence estimates from
exposures to emissions from these
sources would not be affected by
uncertainty in the length of time
emissions sources operate. For the
specific source in this source category
we anticipate significant reduction in
activities and emissions in the relatively
11 Short-term mobility is movement from one
microenvironment to another over the course of
hours or days. Long-term mobility is movement
from one residence to another over the course of a
lifetime.
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near future. If this happens, chronic
risks based on the continuation of
current emission levels will be over
estimated.
The exposure estimates used in these
analyses assume chronic exposures to
ambient levels of pollutants. Because
most people spend the majority of their
time indoors, actual exposures may not
be as high, depending on the
characteristics of the pollutants
modeled. For many of the HAP, indoor
levels are roughly equivalent to ambient
levels, but for very reactive pollutants or
larger particles, these levels are
typically lower. This factor has the
potential to result in an overstatement of
25 to 30 percent of exposures.12
In addition to the uncertainties
highlighted above, there are several
factors specific to the acute exposure
assessment that should be highlighted.
The accuracy of an acute inhalation
exposure assessment depends on the
simultaneous occurrence of
independent factors that may vary
greatly, such as hourly emissions rates,
meteorology, and human activity
patterns. In this assessment, we assume
that individuals remain for 1 hour at the
point of maximum ambient
concentration as determined by the cooccurrence of peak emissions and worstcase meteorological conditions. These
assumptions would tend to overestimate
actual exposures since it is unlikely that
a person would be located at the point
of maximum exposure during the time
of worst-case impact.
d. Uncertainties in Dose-Response
Relationships
There are uncertainties inherent in
the development of the dose-response
values used in our risk assessments for
cancer effects from chronic exposures
and non-cancer effects from both
chronic and acute exposures. Some
uncertainties may be considered
quantitatively, and others generally are
expressed in qualitative terms. We note
as a preface to this discussion a point on
dose-response uncertainty that is
brought out in EPA’s 2005 Cancer
Guidelines; namely, that ‘‘the primary
goal of EPA actions is protection of
human health; accordingly, as an
Agency policy, risk assessment
procedures, including default options
that are used in the absence of scientific
data to the contrary, should be health
protective.’’ (EPA 2005 Cancer
Guidelines, pages 1–7.) This is the
approach followed here as summarized
in the next several paragraphs. A
12 U.S. EPA. National-Scale Air Toxics
Assessment for 1996. (EPA 453/R–01–003; January
2001; page 85.)
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complete detailed discussion of
uncertainties and variabilities in doseresponse relationships is given in the
residual risk documentation which is
available in the docket for this action.
Cancer URE values used in our risk
assessments are those that have been
developed to generally provide an upper
bound estimate of risk. That is, they
represent a ‘‘plausible upper limit to the
true value of a quantity’’ (although this
is usually not a true statistical
confidence limit).13 In some
circumstances, the true risk could be as
low as zero; however, in other
circumstances the risk could be
greater.14 When developing an upper
bound estimate of risk and to provide
risk values that do not underestimate
risk, health-protective default
approaches are generally used. To err on
the side of ensuring adequate healthprotection, EPA typically uses the upper
bound estimates rather than lower
bound or central tendency estimates in
our risk assessments, an approach that
may have limitations for other uses (e.g.,
priority-setting or expected benefits
analysis).
Chronic non-cancer reference (RfC
and RfD) values represent chronic
exposure levels that are intended to be
health-protective levels. Specifically,
these values provide an estimate (with
uncertainty spanning perhaps an order
of magnitude) of a continuous
inhalation exposure (RfC) or a daily oral
exposure (RfD) to the human population
(including sensitive subgroups) that is
likely to be without an appreciable risk
of deleterious effects during a lifetime.
To derive values that are intended to be
‘‘without appreciable risk,’’ the
methodology relies upon an uncertainty
factor (UF) approach (U.S. EPA, 1993,
1994) which includes consideration of
both uncertainty and variability. When
there are gaps in the available
information, UF are applied to derive
reference values that are intended to
protect against appreciable risk of
deleterious effects. The UF are
commonly default values,15 e.g., factors
13 IRIS glossary (https://www.epa.gov/NCEA/iris/
help_gloss.htm).
14 An exception to this is the URE for benzene,
which is considered to cover a range of values, each
end of which is considered to be equally plausible,
and which is based on maximum likelihood
estimates.
15 According to the NRC report, Science and
Judgment in Risk Assessment (NRC, 1994) ‘‘[Default]
options are generic approaches, based on general
scientific knowledge and policy judgment, that are
applied to various elements of the risk assessment
process when the correct scientific model is
unknown or uncertain.’’ The 1983 NRC report, Risk
Assessment in the Federal Government: Managing
the Process, defined default option as ‘‘the option
chosen on the basis of risk assessment policy that
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of 10 or 3, used in the absence of
compound-specific data; where data are
available, UF may also be developed
using compound-specific information.
When data are limited, more
assumptions are needed and more UF
are used. Thus, there may be a greater
tendency to overestimate risk in the
sense that further study might support
development of reference values that are
higher (i.e., less potent) because fewer
default assumptions are needed.
However, for some pollutants, it is
possible that risks may be
underestimated.
While collectively termed ‘‘UF,’’ these
factors account for a number of different
quantitative considerations when using
observed animal (usually rodent) or
human toxicity data in the development
of the RfC. The UF are intended to
account for: (1) Variation in
susceptibility among the members of the
human population (i.e., inter-individual
variability); (2) uncertainty in
extrapolating from experimental animal
data to humans (i.e., interspecies
differences); (3) uncertainty in
extrapolating from data obtained in a
study with less-than-lifetime exposure
(i.e., extrapolating from sub-chronic to
chronic exposure); (4) uncertainty in
extrapolating the observed data to
obtain an estimate of the exposure
associated with no adverse effects; and
(5) uncertainty when the database is
incomplete or there are problems with
the applicability of available studies.
Many of the UF used to account for
variability and uncertainty in the
development of acute reference values
are quite similar to those developed for
chronic durations, but they more often
use individual UF values that may be
less than 10. UF are applied based on
chemical-specific or health effectspecific information (e.g., simple
irritation effects do not vary appreciably
between human individuals, hence a
value of 3 is typically used), or based on
the purpose for the reference value (see
the following paragraph). The UF
applied in acute reference value
derivation include: (1) Heterogeneity
among humans; (2) uncertainty in
extrapolating from animals to humans;
appears to be the best choice in the absence of data
to the contrary’’ (NRC, 1983a, p. 63). Therefore,
default options are not rules that bind the Agency;
rather, the Agency may depart from them in
evaluating the risks posed by a specific substance
when it believes this to be appropriate. In keeping
with EPA’s goal of protecting public health and the
environment, default assumptions are used to
ensure that risk to chemicals is not underestimated
(although defaults are not intended to overtly
overestimate risk). See EPA, 2004, An Examination
of EPA Risk Assessment Principles and Practices,
EPA/100/B–04/001 available at: https://
www.epa.gov/osa/pdfs/ratf-final.pdf.
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(3) uncertainty in lowest observed
adverse effect (exposure) level to no
observed adverse effect (exposure) level
adjustments; and (4) uncertainty in
accounting for an incomplete database
on toxic effects of potential concern.
Additional adjustments are often
applied to account for uncertainty in
extrapolation from observations at one
exposure duration (e.g., 4 hours) to
derive an acute reference value at
another exposure duration (e.g., 1 hour).
As further discussed below, there is
no RfD or other comparable chronic
health benchmark value for lead
compounds. Thus, to address
multipathway human health and
environmental risks associated with
emissions of lead from this facility,
ambient lead concentrations were
compared to the NAAQS for lead. In
developing the NAAQS for lead, EPA
considered human health evidence
reporting adverse health effects
associated with lead exposure, as well
as an EPA conducted multipathway risk
assessment that applied models to
estimate human exposures to air-related
lead and the associated risk (73 FR
66979). EPA also explicitly considered
the uncertainties associated with both
the human health evidence and the
exposure and risk analyses when
developing the NAAQS for lead. For
example, EPA considered uncertainties
in the relationship between ambient air
lead and blood lead levels (73 FR
66974), as well as uncertainties between
blood lead levels and loss of IQ points
in children (73 FR 66981).
In considering the evidence and risk
analyses and their associated
uncertainties, the EPA Administrator
noted his view that there is no evidenceor risk-based bright line that indicates a
single appropriate level. Instead, he
noted, there is a collection of scientific
evidence and judgments and other
information, including information
about the uncertainties inherent in
many relevant factors, which needs to
be considered together in making this
public health policy judgment and in
selecting a standard level from a range
of reasonable values (73 FR 66998). In
so doing, the Administrator decided
that, a level for the primary lead
standard of 0.15 μg/m3, in combination
with the specified choice of indicator,
averaging time, and form, is requisite to
protect public health, including the
health of sensitive groups, with an
adequate margin of safety (73 FR 67006).
A thorough discussion of the health
evidence, risk and exposure analyses,
and their associated uncertainties can be
found in EPA’s final rule revising the
lead NAAQS (73 FR 66970–66981,
November 12, 2008).
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We also note the uncertainties
associated with the health-based (i.e.,
primary) NAAQS are likely less than the
uncertainties associated with doseresponse values developed for many of
the other HAP, particularly those HAP
for which no human health data exist.
In 1988, EPA’s IRIS program reviewed
the health effects data regarding lead
and its inorganic compounds and
determined that it would be
inappropriate to develop an RfD for
these compounds, saying, ‘‘A great deal
of information on the health effects of
lead has been obtained through decades
of medical observation and scientific
research. This information has been
assessed in the development of air and
water quality criteria by the Agency’s
Office of Health and Environmental
Assessment (OHEA) in support of
regulatory decision-making by the
Office of Air Quality Planning and
Standards (OAQPS) and by the Office of
Drinking Water (ODW). By comparison
to most other environmental toxicants,
the degree of uncertainty about the
health effects of lead is quite low. It
appears that some of these effects,
particularly changes in the levels of
certain blood enzymes and in aspects of
children’s neurobehavioral
development, may occur at blood lead
levels so low as to be essentially
without a threshold. The Agency’s RfD
Work Group discussed inorganic lead
(and lead compounds) at two meetings
(07/08/1985 and 07/22/1985) and
considered it inappropriate to develop
an RfD for inorganic lead.’’ EPA’s IRIS
assessment for Lead and compounds
(inorganic) (CASRN 7439–92–1), https://
www.epa.gov/iris/subst/0277.htm.
We also note that because of the
multi-pathway, multi-media impacts of
lead, the risk assessment supporting the
NAAQS considered direct inhalation
exposures and indirect air-related multipathway exposures from industrial
sources like primary and secondary lead
smelting operations. It also considered
background lead exposures from other
sources (like contaminated drinking
water and exposure to lead-based
paints). In revising the NAAQS for lead,
we note that the Administrator placed
more weight on the evidence-based
framework and less weight on the
results from the risk assessment,
although he did find the risk estimates
to be roughly consistent with and
generally supportive of the evidencebased framework applied in the NAAQS
determination. 73 FR 67004. Thus,
when revising the NAAQS for lead to
protect public health with an adequate
margin of safety, EPA considered both
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the health evidence and the risk
assessment, albeit to different extents.
In addition to the uncertainties
discussed above with respect to chronic,
cancer, and the lead NAAQS reference
values, there are also uncertainties
associated with acute reference values.
Not all acute reference values are
developed for the same purpose, and
care must be taken when interpreting
the results of an acute assessment of
human health effects relative to the
reference value or values being
exceeded. Where relevant to the
estimated exposures, the lack of shortterm dose-response values at different
levels of severity should be factored into
the risk characterization as potential
uncertainties.
Although every effort is made to
identify peer-reviewed reference values
for cancer and non-cancer effects for all
pollutants emitted by the sources
included in this assessment, some
hazardous air pollutants continue to
have no peer-reviewed reference values
for cancer or chronic non-cancer or
acute effects. Since exposures to these
pollutants cannot be included in a
quantitative risk estimate, an
understatement of risk for these
pollutants at environmental exposure
levels is possible.
Additionally, chronic reference values
for several of the compounds included
in this assessment are currently under
EPA IRIS review (e.g., cadmium and
nickel), and revised assessments may
determine that these pollutants are more
or less potent than the current value. We
may re-evaluate residual risks for the
final rulemaking if, as a result of these
reviews, a dose-response metric changes
enough to indicate that the risk
assessment supporting this notice may
significantly understate human health
risk.
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e. Uncertainties in the Multipathway
and Environmental Effects Assessment
We generally assume that when
exposure levels are not anticipated to
adversely affect human health, they also
are not anticipated to adversely affect
the environment. For each source
category, we generally rely on the sitespecific levels of PB–HAP emissions to
determine whether a full assessment of
the multi-pathway and environmental
effects is necessary. For PB–HAPS other
than lead (i.e., cadmium), site-specific
PB–HAP emission levels were far below
levels which would trigger a refined
assessment of multi-pathway impacts,
thus we are confident that these types
of impacts are insignificant for the one
facility in this source category.
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f. Uncertainties in the Facility-Wide
Risk Assessment
We did not conduct a separate
facility-wide risk assessment for this
proposal because all of the HAP
emission sources at the one facility
subject to the MACT are covered by the
MACT standard under review. Thus, the
level of the facility-wide HAP emissions
is the same as the level of emissions
from the emissions sources subject to
the MACT standard under review.
g. Uncertainties in the Demographic
Analysis
Our analysis of the distribution of
risks across various demographic groups
is subject to the typical uncertainties
associated with census data (e.g., errors
in filling out and transcribing census
forms), as well as the additional
uncertainties associated with the
extrapolation of census-block group data
(e.g., income level and education level)
down to the census block level.
B. How did we perform the technology
review?
Our technology review is focused on
the identification and evaluation of
developments in practices, processes,
and control technologies. If a review of
available information identifies such
developments, then we conduct an
analysis of the technical feasibility of
these developments, along with the
impacts (costs, emission reductions, risk
reductions, etc.). We then make a
decision on whether it is necessary to
amend the regulation to require any
identified developments.
Based on specific knowledge of the
primary lead smelting source category,
we began by identifying known
developments in practices, processes,
and control technologies. For the
purpose of this exercise, we considered
any of the following to be a
‘‘development’’:
• Any add-on control technology or
other equipment that was not identified
and considered during MACT
development;
• Any improvements in add-on
control technology or other equipment
(that was identified and considered
during MACT development) that could
result in significant additional emission
reduction;
• Any work practice or operational
procedure that was not identified and
considered during MACT development;
and
• Any process change or pollution
prevention alternative that could be
broadly applied that was not identified
and considered during MACT
development.
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In addition to looking back at
practices, processes, or control
technologies reviewed at the time we
developed the MACT standards, we
reviewed a variety of sources of data to
aid in our evaluation of whether there
were additional practices, processes, or
controls to consider. One of these
sources of data was subsequent air
toxics rules. Since the promulgation of
the MACT standard for the primary lead
smelting source category addressed in
this proposal, EPA has developed air
toxics regulations for a number of
additional source categories. We
reviewed the regulatory requirements
and/or technical analyses associated
with these subsequent regulatory
actions to identify any practices,
processes, and control technologies
considered in these efforts that could
possibly be applied to emission sources
in the primary lead smelting source
category.
We also consulted EPA’s RACT/
BACT/LAER Clearinghouse (RBLC). The
terms ‘‘RACT,’’ ‘‘BACT,’’ and ‘‘LAER’’ are
acronyms for different program
requirements under the CAA provisions
addressing the national ambient air
quality standards. Control technologies,
classified as RACT (Reasonably
Available Control Technology), BACT
(Best Available Control Technology), or
LAER (Lowest Achievable Emission
Rate) apply to stationary sources
depending on whether the sources are
existing or new, and on the size, age,
and location of the facility. BACT and
LAER (and sometimes RACT) are
determined on a case-by-case basis,
usually by state or local permitting
agencies. EPA established the RBLC to
provide a central database of air
pollution technology information
(including technologies required in
source-specific permits) to promote the
sharing of information among
permitting agencies and to aid in
identifying future possible control
technology options that might apply
broadly to numerous sources within a
category or apply only on a source-bysource basis. The RBLC contains over
5,000 air pollution control permit
determinations that can help identify
appropriate technologies to mitigate
many air pollutant emission streams.
We searched this database to determine
whether any practices, processes, or
control technologies are included for the
types of processes covered by the
primary lead smelting MACT.
We also requested information from
the facility regarding developments in
practices, processes, or control
technology. Finally, we reviewed other
information sources, such as state or
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local permitting agency databases and
industry-supported databases.
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C. Overview of the Source Category and
MACT Standards
1. Source Category and MACT Standard
The National Emission Standard for
Primary Lead Smelting (or MACT rule)
was promulgated on June 4, 1999 (64 FR
30194) and codified at 40 CFR part 63,
subpart TTT. As promulgated in 1999,
the MACT standard applies to affected
sources of HAP at primary lead
smelters.16 The MACT defines ‘‘Primary
lead smelters’’ as ‘‘any facility engaged
in the production of lead metal from
lead sulfide ore concentrates through
the use of pyrometallurgical
techniques.’’ 40 CFR 63.1542. The
MACT standard for the Primary Lead
Smelting source category does not apply
to secondary lead smelters, lead
remelters, or lead refiners (§ 63.1541).
Today there is one facility (The Doe Run
Company in Herculaneum, Missouri)
operating that is subject to the MACT
standards (See Section V.A. below).
At the time of promulgation of the
Primary Lead Smelting MACT rule,
there were three operating lead smelters.
Due to economic pressures (decreased
market demand for lead) and regulatory
pressures, two of the lead smelting
facilities subject to the MACT standard
have since been permanently closed,
leaving one primary lead smelter
currently operating in the United States.
No new primary lead smelters have
been built in the last 20 years, and no
new primary lead processing facilities
using pyrometallurgical techniques are
anticipated in the foreseeable future.
The one operating lead smelter is not
collocated with other sources of HAP
emissions.
Lead is used to make various
construction and consumer products
such as batteries, paint, glass, piping,
and filler. Lead sulfide (PbS) ore
concentrates are the main feed material
to primary lead smelters. The primary
lead smelting process consists of lead
sulfide concentrate storage and
handling, sintering of ore concentrates,
sinter crushing and handling, smelting
of sinter to lead metal, drossing (i.e.,
removing the solid oxide deposits),
refining and alloying of lead metal, and
smelting of the drosses.
HAP are emitted from primary lead
smelting as process emissions (stack),
process fugitive emissions, and fugitive
dust emissions. Process emissions are
associated with the exhaust gases from
sinter machines and blast and dross
16 As provided above in section III(C)(3), we are
proposing to change the standard to apply to
Primary Lead Processors.
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furnaces. HAP expected in process
emissions are metals (mostly lead
compounds, but also some arsenic,
cadmium, and other metals) and also
may include small amounts of organic
compounds that result from incomplete
combustion of coke, which is charged
along with sinter to the blast furnace.
Process fugitive emissions occur at
various points during the smelting
process (such as during charging and
tapping of furnaces) and the only HAP
emitted are metal HAP. Fugitive dust
emissions result from the entrainment of
dust due to material handling, vehicle
traffic, and wind erosion from storage
piles and the only HAP emitted are
metal HAP.
The MACT standard (40 CFR part 63,
subpart TTT) applies to process
emissions (stack) from sinter machines,
blast furnaces, and dross furnaces;
process fugitive emissions from sinter,
blast furnace, drossing and refining
processes, concentrate handling, and
locations around such processes; and
fugitive dust emission sources, such as
roadways, storage piles and the plant
yard. Process emissions of lead
compounds from sinter machines, blast
furnaces, and dross furnaces, and
process fugitive emissions from the blast
furnace and dross furnace charging,
blast furnace and dross furnace tapping,
and the sinter machine (charging,
discharging, crushing, and sizing) are
limited to 500 grams (g) of lead
emissions per mega gram (Mg) of lead
produced (500 g/Mg), which is equal to
1.0 pound (lb) of lead emissions per ton
of lead produced (1 lb/ton). 40 CFR
63.1542(a). A plant-wide limit format
was used for MACT because it was
consistent with SIPs, the commingling
of exhaust gases from processes to a
single stack made it impossible to set
limits for individual sources, it gave the
facilities more flexibility in complying
with the standard, and it promoted
pollution prevention by giving each
facility the ability to meet the emission
limit through any combination of source
reduction and control technology
options. (63 FR 19208).
In addition to being subject to the
plant-wide emission limit of the
standard, process fugitive emissions
must be captured by a hood and
ventilated to a baghouse or equivalent
control device and the hood design and
ventilation rate must be consistent with
American Conference of Governmental
Industrial Hygienists recommended
practices. 40 CFR 63.1543(b). In
addition, the sinter machine area
fugitives must be enclosed in a building
that is ventilated to a baghouse at a rate
that maintains a positive in-draft
through any doorway opening. 40 CFR
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63.1543(c). The MACT standard also
requires the use of bag leak detection
systems for continuous monitoring of
baghouses. 40 CFR 63.1547(c)(9). For
fugitive dust sources, as defined in 40
CFR 63.1544, the MACT standard
requires that the owner or operator
prepare and operate at all times
according to a standard operating
procedures (SOP) manual. The SOP
manual must describe in detail the
measures used to control fugitive dust
emissions from plant roadways, material
storage and handling areas, sinter
machine areas, blast and dross furnace
areas, and refining and casting
operations areas. Existing work practice
manual(s) that describe the measures in
place to control fugitive dust sources
required as part of a state
implementation plan for lead satisfy this
requirement.
2. MACT as it Applies to Doe Run
Company Primary Lead Smelter,
Herculaneum, Missouri
As stated above, the Doe Run Smelter
in Herculaneum, Missouri, is the sole
remaining lead processing facility in the
United States subject to the MACT. The
1999 MACT rule established a plantwide lead emission limit of 1 lb of lead
per ton of lead produced that applies to
the aggregation of emissions from
specific sources that discharge from air
pollution control devices. Compliance
with the plant-wide emission limit is
demonstrated by annual stack testing.
The rule lists nine sources as subject to
the plant-wide limit including: (1)
Sinter machine, (2) blast furnace, (3)
dross furnace, (4) dross furnace charging
location, (5) blast furnace and dross
furnace tapping location, (6) sinter
machine charging location, (7) sinter
machine discharge end, (8) sinter
crushing and sizing equipment, and (9)
sinter machine area. At the Doe Run
plant, lead emissions from these sources
are controlled by baghouses that exhaust
through two stacks. The sources in the
sinter operation, the blast furnace, and
the dross furnace are controlled by three
baghouses all of which discharge
through one emission point, which is
designated as the main stack. The
building that houses the blast furnace
and dross kettles is vented to a separate
baghouse (#7) which discharges through
a separate stack, designated as the
furnace area stack.
Under the 1999 MACT rule, all other
sources of process fugitive and fugitive
dust emissions are required to follow
work practice standards detailed in the
plant’s standard operating procedures
(SOP) manual.
The HAP emitted in the largest
quantities from the Doe Run facility are
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lead compounds, which account for
over 99 percent of the total HAP
emissions by mass. The remaining HAP
emissions are arsenic, antimony,
cadmium, cobalt, nickel and trace
organic HAP. Negligible levels of
organic HAP are also emitted from
natural gas-fired space heating at the
facility and the incomplete combustion
of coke in the blast furnace. Further
discussions of the emission profile for
this facility is included in the Technical
Support Document in the docket.
3. Missouri SIP and the Lead NAAQS as
They Apply to Doe Run Company,
Herculaneum, Missouri
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In addition to the MACT standard, the
Doe Run Company’s primary lead
smelter in Herculaneum, Missouri is
subject to a SIP for the purpose of
attaining and maintaining the lead
NAAQS.17 The current SIP, which was
approved in 2002, addresses the former
lead ambient air concentration limit of
1.5 μg/m3 NAAQS. In addition, the 2007
SIP submittal from the State includes
requirements addressing lead emissions
from the Doe Run facility and can be
found at https://www.dnr.mo.gov/env/
apcp/docs/2009drh-leadsip.pdf.
In 2008, EPA revised the lead NAAQS
from 1.5 μg/m3 to 0.15 μg/m3. In
November 2010, EPA identified or
‘‘designated’’ several areas as not
meeting the lead NAAQS. These
‘‘nonattainment’’ designations include
portions of Jefferson County, Missouri
surrounding the Doe Run facility.
Missouri is required by the Act to take
steps to further control pollution in this
area, and to detail these steps in a
revision to the SIP. The revised SIP is
due to EPA within eighteen months
after the effective date of the
designation, or by June 2012, and
attainment of the NAAQS should be
achieved by 2016.
The SIP and the pending 2007 SIP
submittal contain specific measures to
be implemented by the Doe Run plant
to reduce lead emissions. The State of
Missouri revised the control
requirements for the Doe Run facility in
2001 and 2007, requiring numerous
emissions-reducing measures and
improvements to add-on control
devices, processes, and work
practices.18 These included
17 EPA most recently approved the Missouri SIP
for Herculaneum in 2002 (67 FR 18497, April 16,
2002). Missouri Department of Natural Resources
(MDNR) substantially revised the requirements for
the smelter in 2007. EPA has proposed approval of
this revision, but has not yet taken final action.
18 EPA most recently approved the Missouri SIP
for Herculaneum in 2002 (67 FR 18497, April 16,
2002). MDNR substantially revised the
requirements for the smelter in 2007. EPA has
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improvements to existing emission
control technology, adding or upgrading
enclosures, process changes and
limitations, and work practices. These
requirements are summarized below.
Point Source Requirements—As
required under the SIP, lead emissions
from the refining kettles and refining
building emissions must be captured
and vented to baghouses. Doe Run
implemented these controls and vents
the emissions to baghouses #8 and #9
and the exhaust from the baghouse #9
is combined with baghouse #7 exhaust
and vented to a common stack.
Although the MACT standard does not
require Doe Run to do so, it has
included emissions from refining
Baghouses #8 and #9 in their
demonstrations of compliance with the
MACT plant-wide lead emission limit.
Under the 2007 SIP submittal, Doe
Run was required to make
improvements to existing baghouse
controls including the installation of
pleated filters and lowering the air-tocloth ratio for baghouses, increased
ventilation and improved ventilation
hoods at the blast furnace, and using
reverse flow technology for baghouse
cleaning. The 2007 SIP submittal also
required the installation of enclosures
and/or partial enclosures for unloading
ore concentrate, sinter storage, and the
sides of the sinter machine (which will
be evacuated to a baghouse).
Process Requirements—Process
changes to reduce emissions required by
the SIP included a process control
system for the injection of air through
the blast furnace tuyeres located at the
bottom of the blast furnace, limitations
on individual process and overall plant
throughputs, and limiting specific
operations to only certain times of the
day when the impact on ambient air
concentrations is less. The SIP also
stipulates that emissions from
malfunctions will be reduced by alarms
that sound when the baghouse fan
malfunctions, an interlock system to
restrict air flow into the blast furnace
when the baghouse is not operating
properly, and cameras for the dross and
refinery kettles to detect kettle failure
(i.e., when a plume of smoke is detected
from the stack, the kettle burner can be
immediately shut off and the problem
corrected).
Fugitive Dust Requirements—Under
both the current SIP and the 2007 SIP
submittal, work practices are required to
reduce fugitive dust emissions.
Requirements include road watering
and automatic sprinklers, using new
regenerative sweepers to remove dust
proposed approval of this revision, but has not yet
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from paved surfaces to reduce emissions
from traffic, maintaining a minimum
water content percentage for ore
concentrate and for baghouse dust that
is loaded into railcars, and inspecting
the siding that encloses buildings
(followed by prompt repairs if needed).
Missouri requires Doe Run to report
all metal HAP emissions annually based
on a speciation analysis that was
performed.19 The state also requires an
annual emissions inventory based on
the stack tests for the point discharges
and AP–42 or facility-specific emission
factors for fugitive emissions.
As a result of the implementation of
the emission control requirements in the
currently approved 2002 SIP, and the
additional requirements adopted by the
state, as discussed above, the Doe Run
facility has achieved a significant
reduction of lead and metal HAP
emissions since 2000 through a
combination of reduced production
levels and improved emissions controls.
Based on emissions inventory data
submitted to the Missouri Department of
Natural Resources (DNR), total HAP
emissions have been reduced from an
estimated 140 tons in 2000 to 20 tons in
2008, and the majority of the 20 tons are
lead compound emissions. The 2008
reported emissions reflect
implementation of all emission controls
stipulated in the 2002 SIP and the 2007
SIP revision.
4. Other Federal and State Actions
Affecting Doe Run Company
More recently, the 2008 revision to
the lead NAAQS has resulted in Doe
Run Company deciding that it is not
feasible for the facility to reduce
emissions further to the level necessary
to meet the newly revised NAAQS
without closure of the current smelting
operations. As a result of past and
ongoing regulatory compliance issues at
the facility, the facility has entered into
a consent decree with U.S. EPA Region
VII and the State of Missouri. Under the
consent decree, the facility will, among
other things, close the existing smelter
operation and remediate the site to an
agreed-upon level. The consent decree
requires that all support operations for
the smelter cease by December 31, 2013
and that the blast furnace cease
operations by April 1, 2014.
Remediation of the site is required to
commence following approval of a plan
to be submitted to EPA in January 2013.
Under the consent decree, the existing
refining, casting and alloying operations
19 Doe Run Company submits annual emissions
inventories to MDNR that report speciated metals
using speciation factors for each metal/source
derived in the late 1990s through emissions testing.
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will be allowed to continue operation.
Notice of the consent decree was
published for public comment on
October 15, 2010, (75 FR 63506). Once
finalized, the consent decree is federally
enforceable among the parties.
Prior to closure of the current smelter,
the Doe Run Company may build and
bring to full operation a new
hydrometallurgical process that will
produce lead from lead sulfide ore,
potentially adjacent to the current
smelter. The hydrometallurgical process
uses chemical reactions involving
fluboric acid which allows recovery of
lead metal through leaching,
electrowinning, and co-product
treatment processes. Some of the lead
from the new process is likely to
undergo further processing at the
existing refinery, primarily for
remelting/casting purposes. Based on
limited data from a demonstration
project, Doe Run expects that lead
emissions from the hydrometallurgical
process will be minimal.
V. Analyses Results and Proposed
Decisions
This section of the preamble provides
a description of the dataset used in the
RTR analysis, the results of our RTR for
the source category, and our proposed
decisions concerning changes to the
Primary Lead Smelting MACT standard.
As noted previously, all references to
lead emissions in this proposal means
‘‘lead compounds,’’ which is the
regulated HAP under CAA section 112.
All reference to lead production means
the production of element lead.
A. What data were used in our risk
analyses?
For the Primary Lead Smelting source
category, we compiled a preliminary
dataset using readily available
information, reviewed the data, and
made changes where necessary. The
preliminary dataset was based on data
in the 2002 National Emissions
Inventory (NEI) Final Inventory, Version
1 (made publicly available on February
26, 2006), and the 2005 National
Emissions Inventory (NEI), version 2.0
(made publicly available in October
2008). The 2005 NEI was updated to
develop the 2005 National Air Toxics
Assessment (NATA) Inventory. NATA
inventory updates for the primary lead
smelting category included SIP data
provided by the state of MO to EPA. The
2005 NATA inventory was used with
updated 2008 data received in an
Information Collection Request (ICR)
response from the Doe Run facility. The
NEI is a database that contains
information about sources that emit
criteria air pollutants, their precursors,
and HAP. The NEI database includes
estimates of annual air pollutant
emissions from point and volume
sources, emission release characteristic
data such as emission release height,
temperature, velocity, and location
latitude/longitude coordinates. We
reviewed the NEI datasets, checked
geographic coordinates, and made
changes based on available information.
We also reviewed the emissions and
other data to identify data anomalies
that could affect risk estimates.
The risk assessment was based on
estimates of the actual emissions and
allowable emissions. The estimates of
actual emissions were for the year 2008
and were based on data from the ICR
along with data from our NEI dataset.
These estimates included both stack and
fugitive emission sources. Fugitive dust
sources include material handling
(concentrate, sinter, fume and dross),
plantwide resuspension (roadways,
storage piles and plant yard) and other
miscellaneous sources (vents and heat
stacks). The material handling sources
contribute approximately 84 percent of
the total fugitive dust emissions, while
plantwide resuspension and
miscellaneous sources contribute
approximately 11 and 5 percent,
respectively. The estimates of allowable
emissions were calculated using
production data from the ICR response
combined with the current emissions
limits in the MACT standard.
Lead compounds account for about 99
percent of the HAP emissions from the
source category, or about 20 tons in
2008. The facility also reported small
emissions of five other metal HAP, and
trace levels of 25 organic HAP.
The emissions data, calculations and
risk assessment inputs for the Primary
Lead Smelting source category are
described further in the Technical
Support Document for this action which
is available in the docket for this
proposed rulemaking.
We used the 2008 production
information as the basis for calculating
the MACT allowable ratio (allowable to
actual) because the 2008 emissions are
the most recent reported emissions that
also reflect implementation of the
requirements of the 2007 SIP revision.
For more information on the ratio of
actual to MACT-allowable emissions,
see the Technical Support Document in
the docket for this action describing the
emission data information and
estimation of MACT-allowable emission
levels and associated risks and impacts.
B. What are the results of the risk
assessments and analyses?
For the Primary Lead Smelting source
category, we conducted an inhalation
risk assessment for all HAP emitted. We
also conducted a multi-pathway
analysis for cadmium and lead. With
respect to lead, we used the recentlypromulgated lead NAAQS to evaluate
the potential for multi-pathway and
environmental effects. Furthermore, we
conducted a demographic analysis of
population risks. Details of the risk
assessments and additional analyses can
be found in the residual risk
documentation referenced in section
IV.A of this preamble, which is
available in the docket for this action.
1. Inhalation Risk Assessment Results
Table 3 provides an overall summary
of the results of the inhalation risk
assessment.
TABLE 3—PRIMARY LEAD SMELTING INHALATION RISK ASSESSMENT RESULTS
Maximum individual cancer risk
(in 1 million) 1
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Allowable
emissions level
30
30
Estimated annual
cancer incidence
(cases per year)
4,900
Actual
emissions level
Estimated
population at risk
≥ 1-in-1 million
0.0008
Maximum chronic non-cancer
TOSHI 2
Actual
emissions level
Allowable
emissions level
1
1
1 Estimated
Maximum off-site
refined acute
non-cancer HQ 3
0.6
maximum individual excess lifetime cancer risk.
2 Maximum TOSHI. The target organ with the highest TOSHI for the Primary Lead Smelting source category is the kidney.
3 The maximum acute HQ value shown uses the only available acute dose-response value for arsenic, which is the REL. See section IV.A of
this preamble for explanation of acute dose-response values.
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The results of the chronic inhalation
cancer risk assessment indicate that,
based on estimates of actual emissions
from the base year 2008, the maximum
individual lifetime cancer risk could be
as high as 30-in-1 million with fugitive
dust emissions of cadmium dominating
the risk. The total estimated cancer
incidence from this source category
based on actual emission levels is
0.0008 excess cancer cases per year or
one case in every 1,250 years.
Approximately 200 people were
estimated to have cancer risks above
10-in-1 million and approximately 4,900
people were estimated to have cancer
risks above 1-in-1 million. When
considering the maximum levels of
emissions allowed under the current
MACT standard, the MIR remains 30-in1 million. The MIR remains the same
since the fugitive dust emissions are
governed by work practices, which
under § 63.1544 are defined as the
measures that will be ‘‘put into place to
control fugitive dust emissions.’’ Thus,
the actual emissions, which reflect the
measures that have been put in place,
should be equivalent to the allowable
emissions.
The maximum chronic noncancer
TOSHI value is 1, with fugitive
emissions of cadmium dominating those
impacts. When considering MACT
allowable emissions, the maximum
chronic noncancer TOSHI value
remains 1 since, for the reasons
provided above, MACT-allowable
fugitive emissions are equal to actual
fugitive emissions.
Based on the acute REL value for
arsenic, an off-site screening-level acute
HQ value from this facility could be as
high as 6. However, the emissions factor
of 10 times the average hourly emissions
rate is not appropriate in this instance,
given that fugitive emissions are
minimized during the meteorological
conditions associated with the worstcase short-term impacts (i.e., during
low-wind, stable atmospheric
conditions). Thus, we refined the
assessment and estimated a maximum
off-site HQ value of 0.6.
The results of a multipathway
screening analysis for cadmium
emissions from this facility were well
below the de minimis emission rate that
would indicate a non-negligible risk of
adverse health effects from
multipathway exposures. We estimate
the specific multipathway de minimis
emission rate for cadmium to be 0.65
TPY and only 0.1 TPY is emitted from
the one facility in this source category.
Thus, there appears to be little, if any,
multipathway risk associated with
cadmium emissions from this facility.
In evaluating the potential multipathway risks from emissions of lead
compounds, we compared modeled
maximum 3-month rolling average
atmospheric concentrations with the
NAAQS for lead. Table 4 presents the
results of our lead impact analysis
broken down by emission point
considering actual 2008 emissions as
well as the maximum emissions of lead
that the MACT standard would have
allowed based on production rates for
calendar year 2008. For purposes of our
analysis, we determined separately the
risk from each of the types or processes/
emissions sources regulated by the
current MACT, with one exception.
Under the MACT, emissions from the
refining and casting area were
considered fugitive emissions subject to
work practice standards under
§ 63.1544. Since then, pursuant to
requirements that the 2002 State SIP
adopted for purposes of meeting the
1.50 μg/m3 lead NAAQS, Doe Run
enclosed the refining and casting area
and vents those emissions to the
refinery stacks. We considered these
stack emissions separate from the
fugitive dust emissions. Thus, the four
emission process/sources we evaluated
for risk were: (1) The main stack, (2) the
furnace area stack, (3) the refinery stack,
and (4) fugitive emissions.
The analysis indicates that under both
actual 2008 or MACT allowable
9429
emission scenarios, emissions from the
main stack do not result in lead levels
above the NAAQS within the 50 km
radius that was modeled. This is likely
due to the height of the stack (500 feet),
which would result in broader and
further dispersal of lead emissions.
However, results of the analysis did
indicate that modeled ambient air lead
concentrations resulting from this
facility’s fugitive dust emissions could
exceed the NAAQS for lead by as much
as 50-fold at the property boundary
based on both actual and allowable
emissions. Moreover, results indicate
that modeled emissions from the
furnace area stack could result in
NAAQS exceedances under both actual
2008 and MACT-allowable emissions
scenarios. In addition, the actual
estimated emissions from the refining
stacks, which were put into place based
on requirements adopted by the State
for purposes of the SIP, could result in
NAAQS exceedances. We were unable
to calculate a ‘‘MACT allowable’’
emission level for the refinery
emissions, which under the MACT are
included as fugitive emissions. This
analysis also indicates that within
50 km of this facility, approximately
1,900 people could be exposed to
ambient air lead concentrations
exceeding the level of the NAAQS for
lead.
As mentioned above, to evaluate the
potential for adverse environmental
effects, we also compared maximum
3-month rolling average atmospheric
concentrations with the current
secondary NAAQS for lead, which is the
same as the primary standard. Thus, the
analyses presented in Table 4 also
indicate the potential for adverse
environmental effects from emissions of
lead. Note that modeling performed for
this analysis is based on different inputs
than SIP modeling done for the one
remaining primary lead facility, and
thus results differ.
TABLE 4—SUMMARY OF MODELED LEAD CONCENTRATIONS RELATIVE TO THE NAAQS BASED ON ESTIMATED ACTUAL
2008 AND MACT ALLOWABLE EMISSIONS
Actual
2008
emissions
(TPY)
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Emission point
Main stack 2 ...............................................................................
Refining stacks ..........................................................................
Furnace area stack: (controlled blast and drossing fugitives) ..
Fugitive dust 3 ............................................................................
13.31
2.74
1.81
2.85
Maximum impact—
actual emissions
Allowable
emissions 1
(TPY)
Maximum impact—
allowable emissions
65.8
NA
8.94
2.85
0.25 times the NAAQS.
NA.
10 times the NAAQS.
50 times the NAAQS.
0.05 times the NAAQS ....
3 times the NAAQS .........
2 times the NAAQS .........
50 times the NAAQS .......
1 Allowable emissions for the main stack and furnace area emission points are based on 1 lb of Pb/ton production (MACT limit); Refinery emissions are included as fugitive emissions under MACT but are now vented to a stack because of SIP requirements; therefore, we were unable to
calculate a ‘‘MACT allowable’’ emission level.
2 Main stack is the emission point for sinter machine, blast furnace and drossing operations.
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3 Fugitive dust emissions are covered by work practices under current MACT and were calculated via emission factors assuming compliance
with the MACT. The site of maximum ambient air lead concentration resulting from fugitive dust emissions occurs in close proximity to the southeast boundary of the facility (see Figure 3.1–1 of the risk assessment document). Note that this maximum result and its location are based on
modeling 2008 emissions using 1998 site-specific meteorology, and that these may differ from inputs used for other types of modeling (e.g., SIP
modeling.)
2. Facility-wide Risk Assessment
Results
Our screening analysis determined
that the organic HAP emissions from
facility represented negligible risk and
were determined to be insignificant
with regard to this risk analysis. As a
result, all significant HAP emissions
from the one facility in this category are
reflected in the risk analyses presented
above; therefore, facility-wide risks are
equivalent to those of the source
category.
3. Model to Monitor Comparison
In addition to the results presented
above, we also compared maximum
AERMOD estimates of ambient air lead
concentrations with those measured at 4
monitors in close proximity to the
Herculaneum Primary Lead Smelting
Facility for calendar year 2008. More
specifically, we compared maximum 3month rolling average lead
concentrations (for calendar year 2008)
calculated from data reported at the
Main Street, Circle Street, South Cross,
and Church Street monitors to the
maximum 3-month rolling average lead
concentrations at model receptor
locations in close proximity to these
monitoring sites. These monitor
locations were chosen because they
represented the closest offsite monitors
to the Herculaneum primary lead
smelter. Thus, lead measurements at
these monitoring sites would likely be
dominated by emissions from this
facility which is important given that
AERMOD estimates of ambient air lead
concentrations only considered lead
emissions from this facility (i.e., only
lead emissions from the Herculaneum
primary lead smelter were used as
inputs into AERMOD).
Results of this analysis are presented
in Table 5 and indicate that with respect
to the Main Street and Circle Street
monitors, AERMOD underestimates 3month maximum lead concentrations by
approximately 2.8- and 4.2-fold,
respectively. While these monitor to
model comparisons are not in complete
agreement on a point-by-point basis, we
note that this would not be expected
given the general uncertainties
associated with using dispersion
modeling to estimate ambient pollutant
concentrations and considering that the
meteorological data used to develop the
model estimates were from a different
year than the actual monitoring and
emissions data (i.e., meteorological data
used in the AERMOD simulation was
from 1998 while the emissions estimates
and the monitoring data were from
2008). However, results do indicate that
the maximum 3-month average lead
concentration across the group of
monitors nearest the facility is
approximately equal to the maximum 3month average lead concentration
estimated by AERMOD across the group
of these monitoring sites (i.e., both the
Main Street monitor and the South
Cross AERMOD estimate indicate the
maximum 3-month average lead
concentration to be approximately 2.1
μg/m3). Taken together, these results
indicate that AERMOD estimates of
ambient air lead concentration provide
a reasonable representation of the
measured 3-month maximum lead
concentrations present in the ambient
air near this facility.
TABLE 5—COMPARISON OF AERMOD MODELED TO AMBIENT AIR LEAD CONCENTRATIONS REPORTED BY FOUR
MONITORS SURROUNDING THE HERCULANEUM PRIMARY LEAD SMELTING FACILITY
Maximum AEMOD
modeled 3-month
lead concentration
(μg/m3)
Location
Maximum monitored
3-month lead concentration 20 (μg/m3)
Model to
monitor ratio 21
3.14
1.14
0.75
0.47
¥4.6
¥3.0
2.8
4.2
Main Street ............................................................................................................
Circle Street ...........................................................................................................
South Cross ...........................................................................................................
Church Street .........................................................................................................
0.47
0.38
2.13
1.99
4. Demographic Risk Analysis Results
summarized in Table 5 and are based on
modeling using estimated actual
emissions levels for the population
living within 50 km of this facility.
Demographic analyses were
performed to investigate the population
distribution of: (1) Cancer risks at or
above 1-in-1 million and (2) risks from
ambient air lead concentrations above
the NAAQS for lead. Results are
TABLE 6—PRIMARY LEAD SMELTING DEMOGRAPHIC RISK ANALYSIS RESULTS
Population with
cancer risk
greater than
1 in a million
Population with
ambient air lead
concentrations
exceeding the
NAAQS
285,000,000
4,900
1,900
White ..........................................................................................................................
75
96
96
20 Maximum 3-month monitored concentrations
were calculated for the year 2008 based on data
submitted to EPA’s Air Quality System (AQS).
estimated concentrations were based on the 2008
emissions estimates described in section V.A.
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Nationwide
Total population .........................................................................................................
Race by percent
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21 Negative sign denotes an underestimation of
AERMOD modeled ambient lead concentrations,
relative to monitored concentrations. AERMOD
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TABLE 6—PRIMARY LEAD SMELTING DEMOGRAPHIC RISK ANALYSIS RESULTS—Continued
Population with
cancer risk
greater than
1 in a million
Population with
ambient air lead
concentrations
exceeding the
NAAQS
4
4
75
12
0.9
12
96
4
0.2
1
96
3
0
0.8
14
86
1
99
0.3
99.7
13
87
15
85
15
85
Nationwide
All Other Races .........................................................................................................
25
Race by percent
White ..........................................................................................................................
African American .......................................................................................................
Native American ........................................................................................................
Other and Multiracial .................................................................................................
Ethnicity by percent
Hispanic .....................................................................................................................
Non-Hispanic .............................................................................................................
Income by percent
jlentini on DSKJ8SOYB1PROD with PROPOSALS2
Below poverty level ....................................................................................................
Above poverty level ...................................................................................................
Results of the risk assessment indicate
that there are approximately 4,900
people exposed to a cancer risk greater
than 1-in-1 million, and 1,900 people in
areas with ambient air lead
concentrations above the NAAQS for
lead. In both instances, the
demographics analysis estimates that
about 4 percent of these populations can
be classified as a minority (listed as ‘‘all
Other Races’’ in the table), which is well
below the national percentage of 25.
Similarly, in the cancer and lead
demographic analyses, the percentage of
‘‘African American,’’ ‘‘Hispanic,’’ ‘‘Native
American,’’ and ‘‘Other and Multiracial’’
population groups are well below the
corresponding national percentages.
With respect to the percentage of those
‘‘Below the Poverty Level,’’ in both
demographic analyses there is a small (2
percent) increment above the
corresponding national percentage.
However, given that the total population
affected is small (i.e., 4,900 individuals
for cancer risk greater than 1-in-1
million and 1,900 individuals in areas
with lead concentrations above the
NAAQS), we do not think this indicates
any significant potential for disparate
impacts to the specific demographic
groups analyzed.
Moreover, given the extent to which
lead may impact children’s health, we
further note that our demographic
analysis doesn’t indicate the presence of
a higher percentage of children than one
would normally expect around this
facility. That is, while the national
percentage of children 18 years and
younger is 27%, the percentage of
children living near this facility who are
estimated to be exposed to lead
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concentrations above the NAAQS is
only slightly higher at 28% (see Risk
and Technology Review—Analysis of
Socio-Economic Factors for Populations
Living Near Primary Lead Smelting
Facilities in the docket for this proposed
rulemaking), a difference which is likely
not significant.
C. What are our proposed decisions on
risk acceptability and ample margin of
safety?
1. Risk Acceptability
As noted in section III.B of this
preamble, we weigh all health risk
factors in our risk acceptability
determination, including cancer risks to
the individual most exposed, risk
estimation uncertainty, and other health
information. For the Primary Lead
Smelting source category, the risk
analysis indicates that the cancer risks
to the individual most exposed could be
as high as 30-in-1 million due to actual
or MACT-allowable emissions. These
risks are considerably less than 100-in1 million, which is the upper bound of
the presumptive range of acceptability.
The incidence of cancer is very low—
0.0008 excess cancer cases per year; or
one case every 1,250 years. Similarly,
the risks of chronic non-cancer health
effects from HAP emissions other than
lead were low, with a maximum HQ of
1. Moreover, while an initial screening
analysis suggested that fugitive
emissions of arsenic had the potential to
create a risk of acute health effects, a
refined analysis based on our
knowledge of this emission source
indicated that the risk was low (HQ =
0.6). In addition to these health
analyses, a demographics analysis did
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not indicate the potential for
significantly disproportionate heath
impacts (see above, section V(3)(c)).
Thus, risks associated with the non-lead
emissions from the Primary Lead
Smelting source category for cancer,
acute and chronic non-cancer health
effects and environmental effects are
considered acceptable.
However, since ambient air lead
concentrations resulting from emissions
from this facility were modeled to be in
excess of the NAAQS for lead, the risks
associated with lead emissions from this
facility were judged to be significant.
Our analysis estimated that modeled offsite ambient air lead concentrations
(based on actual 2008 emissions)
resulting from this facility could be as
high as 50 times the NAAQS for lead
based on fugitive dust emissions, and
that approximately 1,900 individuals
could be exposed to lead concentrations
in excess of the NAAQS. Given that the
NAAQS for lead was set to ‘‘provide
increased protection for children and
other at-risk populations against an
array of adverse health effects, most
notably including neurological effects in
children, including neurocognitive and
neurobehavioral effects (73 FR 67007)’’,
we are proposing that risks associated
with lead emissions from this source
category are unacceptable.
As noted above, our risk analysis for
lead was based on modeled 3-month
rolling average lead concentrations in
ambient air in comparison to the
primary lead NAAQS. We believe that
in order to provide an acceptable level
of risk, lead concentrations in the
ambient air must be reduced to the level
of the lead NAAQS. Thus, we
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considered specific emission limits for
the three emission sources/points that
were modeled to result in lead
concentrations in excess of the NAAQS
(see Table 4); refinery stack, furnace
area stack, and fugitive dust emissions,
with the majority of fugitive dust
impacts from material handling sources.
Based on our analysis, we conclude that
in order to meet the NAAQS for lead at
all model receptors, fugitive dust
emissions would have to be reduced by
approximately 98 percent to 0.064 TPY,
refinery stack emissions and furnace
area stack emissions would have to be
reduced by approximately 80 percent to
a total of 0.91 TPY (the maximum
impacts of refinery and furnace
emission points occur at the same
location.) Further, because the
maximum ambient air impacts of the
refinery/furnace emissions, the fugitive
dust emissions, and the main stack do
not significantly overlap each other, we
estimate that lead emissions from all
emission points other than the main
stack would have to be limited to a total
of approximately 0.97 TPY in order to
ensure 3-month rolling average ambient
air lead concentrations do not exceed
the lead NAAQS level of 0.15 μg/m3. As
noted above, emissions from the main
stack (i.e., emission point for sinter
machine, blast furnace and drossing
operations) did not result in ambient air
lead concentrations in excess of the lead
NAAQS at modeled locations within 50
km of the property boundary and thus
we are not proposing any reductions at
the main stack in order to ensure an
acceptable level or risk.
Once we determined the emissions
reductions necessary to achieve an
acceptable level of risk, we investigated
available emissions control options and
their ability to reduce emissions and
health risks for fugitive dust and for
stack emissions from both the refining
and furnace area stacks. Control options
considered for reducing fugitive dust
emissions and associated risks include
improved or additional work practices,
site remediation, application of
additional capture/control measures,
and lead production limitations. With
the exception of site remediation, all of
these control measures have been
implemented to varying degrees at the
Doe Run facility in response to the
Missouri SIP, as revised in 2002 and the
2007 revisions submitted for approval to
the SIP. As such, because the actual
emissions for 2008 reflect the
implementation of those control
measures, requiring those controls
under the MACT would be unlikely to
yield the additional 98 percent
reduction in fugitive emissions
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necessary to meet the primary lead
NAAQS level of 0.15 μg/m 3. Thus, our
evaluation of risks based on actual
emissions already considered emissions
with these controls largely in place. In
order to ensure that site remediation
efforts, or any other efforts the source
may choose to undertake, will result in
sufficient emission reductions to
address the unacceptable level of risk,
we are proposing to establish a lead
concentration in air limit of 0.15 μg/m 3
to be measured at locations approved by
the Administrator. This lead
concentration in air limit would be
established as the enforceable
requirement to address fugitive
emissions under the MACT standard.22
Because we are proposing a
concentration limit to address fugitive
dust emissions, we no longer believe it
is necessary for the affected facility to
provide a plan to the Administrator
describing work practices that will be
used to reduce fugitive emissions.
Therefore, we are proposing to remove
the requirement to develop and submit
a work practice standard operating
procedure (SOP) manual as required in
§ 63.1544(a).
As an alternative to proposing
compliance monitoring requirements for
demonstration of compliance with the
lead concentration in air limit, we
considered retaining the current fugitive
dust emissions requirement to develop
and submit to the Administrator or
delegated authority a work practices
SOP. Using this alternative approach,
we believe it would be necessary to
modify the current general requirements
for an SOP by specifying the minimum
work practice requirements that the
plan must include. For example, under
this alternative approach, we would
require that the SOP must include, at a
minimum, detailed descriptions of all
measures that would be used to control
fugitive dust emissions from plant
roadways; material storage, transfer and
handling areas; sinter machine areas;
furnace areas; refining and casting areas;
and other areas the Administrator may
identify. Further, EPA would require
that the SOP contain detailed
descriptions of work practices including
road watering and automatic sprinklers,
methods to remove dust from paved
surfaces to reduce emissions from
traffic, maintenance of minimum water
content for ore concentrate and for
baghouse dust that will be handled or
transferred, and procedures for the
22 Under the consent decree, of which we sought
public comment last fall, fugitive dust sources will
be addressed by site remediation; however, some
fugitive dust emissions will remain during the
remediation of the site, which will likely extend
beyond April 2014.
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inspection of building siding or
damages and openings. The SOP would
be required to include procedures,
including recordkeeping, to ensure that
the work practices are being
implemented at a frequency and in a
manner that would ensure that fugitive
dust emissions are being minimized. To
determine whether the work practices
described in the SOP are reducing
emissions sufficient to comply with the
lead concentration in air limit, the
owner or operator would be required
once a year to model the fugitive dust
emissions using measurement data or
emission factors according to an
approved fugitive dust emissions
modeling plan. At a minimum, EPA
would require that this modeling plan
include a detailed description of each
fugitive dust emission source; a detailed
description of the control practices or
techniques used to limit fugitive dust
emissions from each source; the
emission factors, test data or other
methods used to characterize and
quantify lead emissions from each
source; a description of the emissions
modeling that will be used to estimate
the concentrations of lead in air at or
near the property boundary as
contributed by each source as well as
cumulatively contributed by all sources;
a description of process or other
conditions that would indicate the need
to demonstrate compliance more often
than annually; the calculations to be
used to show compliance with the air
lead concentration limit that consider
the highest modeled air lead
concentrations from the modeled
fugitive dust sources and any
contributions from background lead
concentrations in air; and a description
of the records that will be kept. We are
seeking comments on the proposed
requirements to monitor air lead
concentrations versus the alternative
approach described above, of requiring
extensive work practices and a work
practice SOP in conjunction with
emissions modeling, to demonstrate
compliance with the air lead
concentration limit.
Measures available for reducing lead
emissions from the refining and furnace
area stacks include upgrading existing
baghouses by replacing the existing
fabric bags with high efficiency
membrane bag filters. Another option
would be to add extra in-line baghouses
after existing baghouses. Such measures
would reduce lead emissions and
associated risk to within acceptable
levels.
In summary, our analysis indicates
that in order to ensure that lead
emissions from this source do not pose
an unacceptable risk, emissions from
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this facility would need to be reduced
to a level that would ensure that these
emissions would not result in air lead
levels greater than the 0.15 μg/m 3 for
any 3-month period at all of the
modeled locations. Further, we
conclude that in order to achieve the
0.15 μg/m 3 level (for any 3-month
rolling average) at all modeled locations,
fugitive dust emissions would need to
be reduced by 98 percent and the
emissions from the furnace area and
refining operation stacks would need to
be reduced by 80 percent. We have
identified emission reduction and
control options for achieving the
required reductions, which include
implementation of site remediation,
work practices, and upgrade of existing
baghouses with membrane bags and/or
addition of an additional in-series
baghouse.
We are proposing the following
requirements to ensure that risk is
reduced to an acceptable level.
• A stack lead emission cap of 0.91
TPY that would apply to the furnace
area stack and the refining operation
stacks.
• An air lead concentration limit of
0.15 μg/m3 based on 3-month rolling
average (to be measured at locations
approved by the Administrator) to
ensure that fugitive dust emission levels
will not exceed the NAAQS.
The proposed limits apply to both
new and existing facilities. Any facility
subject to the MACT would be required
to meet these requirements for each
emission unit it is operating that is
subject to the limit. In order to address
any fugitive dust emissions, the facility,
regardless of whether it is operating all
or just some of the emission sources
covered by this action, would be
required to meet the air lead
concentration emission limit.
For both new and existing facilities,
compliance with the air lead
concentration limit would be
demonstrated using lead compliance
monitoring devices and would be based
on a rolling 3-month average
concentration. The proposed rule
requires development of a monitoring
plan for approval by the Administrator
that includes the minimum sampling
and analysis methods and compliance
demonstration criteria provided in the
rule. A provision is included in this
proposed rule that allows for reduced
monitoring if the facility demonstrates
an air lead concentration for three
consecutive years at less than 50 percent
of the air lead concentration limit. The
monitoring can be reduced to once
every six months unless one of the 6month monitoring events exceeds 50
percent of the air lead concentration
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limit, at which time monitoring will be
required to resume based on the initial
plan approved by the Administrator
until another three years of consecutive
monitoring below 50 percent of the air
lead concentration limit is achieved.
The compliance requirements discussed
above were designed to allow for
flexibility, prevention of redundant
requirements, and also to provide
consistency with current monitoring
required at the site. We are soliciting
comment on this approach. For existing
facilities, compliance with the emission
limit for the furnace area and refinery
stacks would be demonstrated through
stack testing conducted on a quarterly
basis. All performance testing will be
consistent with the existing MACT
testing requirements, with the exception
of frequency. As provided in § 63.153(e)
of the current rule, the facility can
reduce compliance testing frequency if
the most recent three compliance tests
demonstrated compliance. We are
maintaining this provision, however,
because this proposed rule increases the
testing frequency to quarterly, the
number of most recent tests necessary to
comply with this provision will be
increased from three to 12. New primary
lead processing facilities would be
required to demonstrate compliance
using a lead continuous emission
monitoring systems (CEMS). However,
since the Agency has not finalized the
performance specification for the use of
these instruments, we are deferring the
effective date of the requirement to
install, correlate, maintain and operate
lead CEMS until these actions can be
completed. The lead CEMS installation
deadline will be established through
future rulemaking, along with other
pertinent requirements. In the event
operations commence at a new facility
prior to promulgation of the
performance specification, compliance
would be demonstrated through
quarterly stack testing until
promulgation of the lead CEMS
performance specification.
2. Ample Margin of Safety
Reducing lead emissions to meet the
NAAQS would ensure that emissions of
all HAP do not pose an unacceptable
risk. Once we ensure that the risk is
acceptable, we then look to determine
whether further reductions are
appropriate to ensure an ample margin
of safety. In this part of our analysis, we
again consider the health factors we
considered to determine whether the
risks are acceptable but we also consider
the cost of controls.
With regard to lead emissions, we are
proposing to require most of the
emission sources at the facility to
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implement all technically feasible
controls in order to ensure that the
ambient air meets the level of the lead
NAAQS, which is the level that we have
determined will ensure an acceptable
level of risk. Because all feasible
controls will need to be adopted in
order to meet that proposed standard,
there are no additional controls to
consider for the three emission sources:
Fugitive dust emissions, the furnace
area stack, and the refinery stacks. We
further note that the same controls we
have proposed for the three emission
points to reduce lead emissions are the
same controls that would reduce risks
from cadmium and all other metal HAP
known to be emitted from this source
category. Thus, we are proposing that
the controls required to ensure that risk
from lead emissions from those three
emission points is acceptable also
protect public health with an ample
margin of safety with regard to
emissions from all metal HAP from
these three emission points. Notably,
after these standards are in place, we
estimate that the MIR cancer risk due to
the non-lead HAP will be less than 1-in1 million.
Our risk analysis indicates that the
main stack emissions do not result in
ambient air lead levels exceeding the
NAAQS based on either actual or
allowable emission levels. We
determined, as discussed section V.D.
below, that it is technologically feasible
to reduce emissions from the main stack
to a level well below the allowable level
of the MACT, since those levels are
currently being achieved, and thus we
are proposing to require such controls
under CAA section 112(d)(6). We
evaluated whether there were additional
controls to further reduce emissions
from the main stack and determined
that lead emissions from the main stack
could be further reduced by replacing
the standard cloth bags with membrane
bags at a capital cost of approximately
$2 million and an annual cost of $0.3
million. Assuming a 50 percent
reduction from 2008 main stack
emissions, the cost of reducing lead
emissions would be about $40,000 to
$229,000 per ton of lead. (See the
Technical Support Document included
in the docket for a complete discussion
of this analysis.) Because the highest
ambient air lead concentration resulting
from the emissions from the main stack
already is more than 20 times below the
level that is considered acceptable, it
was determined that although
additional controls such as membrane
bags could result in additional emission
reductions, the additional controls are
not warranted since they would not
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appreciably reduce risk. We are
proposing that the MACT standard, with
the changes we are proposing under the
section 112(d)(6) technology review as
described in section V.D. below will
provide an ample margin of safety with
regard to emissions of lead and other
HAP from the main stack.
jlentini on DSKJ8SOYB1PROD with PROPOSALS2
D. What are the results and proposed
decisions from the technology review?
We evaluated developments in
practices, processes, and control
technologies applicable to emission
sources subject to the Primary Lead
Smelting MACT. This included a search
of the RBLC Clearinghouse, the
California BACT Clearinghouse, the
internet, and correspondence with state
agencies and industry. We have
determined that there have been
advances in emission control measures
since the Primary Lead Smelting MACT
standard was originally promulgated in
1999.
The 1999 MACT limit was set using
the lead emission limits from the lead
SIPs for the three states in which
primary lead smelting sources were
operational at the time of the
rulemaking. EPA took each of the three
lead SIP limits, in lb/day, divided them
by the corresponding lead production
capacity, in tons/day, and calculated a
lead emission rate in lb/ton. The results
were as follows:
ASARCO—Missouri 1.0 lb/ton
ASARCO—Montana 1.0 lb/ton
Doe Run—Missouri 0.84 lb/ton
The values were ranked and the
median value (1.0 lb/ton) was selected
as representative of the MACT floor.
Since the MACT standard was
promulgated, the industry has
undergone significant changes. Two of
the three facilities have shut down. The
only remaining primary lead smelting
facility is the Doe Run smelter at
Herculaneum, Missouri, which is
subject to control requirements under
the Missouri SIP for lead. The existing
SIP, as well as a 2007 SIP revision
submitted by the State and proposed for
approval by EPA require numerous
emissions-reducing measures and
improvements to add-on control
devices, processes, and work practices.
We considered these developments in
practices, processes, and control
technologies in our technology review.
Recent emissions tests (2000 through
2008) at the Doe Run facility support
that these improvements have resulted
in significantly lower emissions and
demonstrate that actual lead emissions
from the facility are much lower than
are allowed under the current MACT
rule. To assess the impacts of
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developments in practices, processes
and control technologies on lead
emissions, emissions data from 2008
were compared with emissions data
from 2000. Data from 2008 were
selected because they reflect the many
improvements that have been
implemented at the facility since
promulgation of the MACT rule.
Emissions data from earlier years would
not reflect all of the emission-reducing
changes that have been implemented at
the Doe Run facility given that some of
the improvements were not
implemented until 2007 and 2008. As
described above, technological
improvements to baghouses and
processes that have been implemented
at the facility since the MACT rule was
promulgated have resulted in
substantially lower emissions from
these sources at this facility. These
improvements include upgrade of cloth
bags and ventilation improvements. In
2008, lead emissions from the main
stack, which vents emissions from the
sintering operation and the blast and
dross furnace, were 13.31 TPY. In
addition, emissions from the furnace
area stack (i.e., the blast furnace and
dross plant building which vent to
baghouse 7) were 1.81 TPY, for a total
of approximately 15.1 TPY. At the 2008
lead production rate of 149,500 tons, the
lead emission rate for these sources at
Doe Run was about 0.2 lb/ton, or 80
percent less than the current MACT
limit of 1 lb/ton. Based on this
demonstrated performance, EPA
believes that under Section 112(d)(6),
the MACT standard should be revised to
reflect the reduction achieved in
practice.
Because we believe that the 2008
emissions of 13.31 TPY from the main
stack (or combined sintering/blast
furnace/drossing operations) reflect the
annual rate of emissions achievable as a
result of the technological
improvements that have been made
since 1999, we are proposing an
emission limit based on the actual 2008
annual emissions that vent to the main
stack (i.e., sintering, blast furnace and
drossing operations). In order to account
for variability in the operation and
emissions, recent stack tests were used
to calculate the 95 percent upper
predictive limit (UPL). The 95 percent
UPL for the main stack is 15 TPY.
Variability in the operations and
emission for this source are discussed in
more detail in Section E below.
Although we believe that there have
been developments in processes,
practices and control technologies with
regard to the furnace area stack and with
regard to refining and casting
operations, as reflected by the more
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stringent requirements that have been
implemented in accordance with the
approved SIP and the 2007 SIP
revisions; we are not proposing
additional requirements for these stacks
as part of our technology review because
we have already proposed that these
stacks implement all feasible controls,
regardless of cost, in order to ensure that
the risks due to these emission points
are acceptable. Thus, there are no
additional developments in practices,
processes and control technologies
beyond those which are reflected in the
emission limits we have proposed to
meet CAA section 112(f)(2), above.
To be consistent with the existing
MACT standard, EPA is proposing to
retain the plant-wide pound per ton of
production format that currently applies
to the aggregate emissions from the
main stack and the furnace area stack.
Because there are also stacks for the
refining and casting operations, we are
proposing to include those emissions as
part of the plant-wide emission limit.
Thus we are proposing a plant-wide
lead emission limit of 0.22 pounds of
lead per ton of lead produced based on
the proposed reductions due to the
section 112 (f)(2) risk review for the
furnace area and refining operations
stacks (discussed above in Section C)
and the reduction in emissions from the
main stack (sinter/blast furnace/
drossing operations) based on this
Section 112(d)(6) technology review
This proposed plant-wide lead emission
limit was determined by summing the
15 TPY for the main stack and the 0.91
TPY for the furnace area and the
refining operation, and dividing by the
annual production from 2008 of 149,564
tons. We note that variability was only
applied in establishing technologybased emissions from the main stack in
order to establish a plant-wide emission
limit. Because the emission levels
required from the refining operation and
furnace area stacks are based on
acceptable risk, we conclude it is not
appropriate to consider variability in
establishing limits for these emission
points.
We are proposing that the plant-wide
lead emission limit apply to new and
existing facilities that are subject to the
MACT. By default this would include
any new, controlled lead processing
source not currently covered, including
lead processing by other than the
current techniques. We are requesting
comment on the appropriateness of
applying the plant-wide lead emission
limit to any future new lead processing
technique.
For the existing facility, compliance
with the plant-wide stack emission limit
would be demonstrated in the same
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Where:
¯
x = 2008 annual emissions
n = the number of test runs
m = the number of test runs in the
compliance average
s2 = observed variance
t = student t distribution statistic
This calculation was performed using
the following Excel functions: 95
percent UPL = 2008 annual emissions +
[STDEV (Test Runs) × TINV (2 ×
probability, n-1 degrees of freedom) ×
SQRT ((1/n) + (1/m))], for a one-tailed
t-value, probability of 0.05, and sample
size of n.
23 Run-to-run variability is essentially within-test
variability, and encompasses variability in
individual runs comprising the compliance test,
and includes uncertainties in correlation of
monitoring parameters and emissions, and
16:48 Feb 16, 2011
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represents the value which we can
expect the mean of future observations
(3-run average for lead) to fall below
within a specified level of confidence,
based upon the results of an
independent sample from the same
population. In other words, if we were
to randomly select a future test
condition from any of these sources (i.e.,
average of 3 runs or 30-day average) we
can be 95 percent confident that the
reported level will fall at or below the
UPL value. Use of the UPL is
appropriate in this rulemaking because
it sets a limit any single or future source
can meet based on the sources past
performance.
This formula uses a pooled variance
(in the s2 term) that encompasses all the
data-point to data-point variability.
Where variability was calculated using
the UPL statistical approach, we used
the sample standard deviation
calculated from the emissions data
distributions for lead. The standard
deviation is the common measure of the
dispersion of the data set around an
average. We note here that the
methodology accounts for both shortterm and long-term variability and
encompasses run-to-run and test-to-test
variability.
We adopted a form of the UPL
equation that has been used in more
recent rulemakings. See 75 FR 54970
(September 9, 2010), 75 FR 32020 (June
4, 2010) and 75 FR 31905 (June 4, 2010).
The UPL used in this proposed rule is
calculated by:
promulgate an affirmative defense to
civil penalties for exceedances of
emission limits caused by malfunctions,
as well as criteria for establishing the
affirmative defense.
EPA has attempted to ensure that we
have not included in the proposed
regulatory language any provisions that
are inappropriate, unnecessary, or
redundant in the absence of the SSM
exemption. We are specifically seeking
comment on whether there are any such
provisions that we have inadvertently
incorporated or overlooked.
As discussed in Section III.C. above,
EPA is proposing to remove provisions
in the existing standard that would have
exempted sources from complying with
the standard during periods of startup,
shutdown and malfunction. Specifically
we are proposing revisions to subpart
TTT Table 1 and rule provisions to
remove applicability of the General
Provisions with regard to SSM and
remove the exemption for bag leak
detection alarm time attributable to SSM
events from determining compliance
with the total alarm time limit. In
addition, we are proposing to
imprecision of stack test methods and laboratory
analysis. 72 FR 54877 (Sept. 27, 2007). Test-to-test
variability results from variability in pollution
device control efficiencies over time (depending on
many factors, including for fabric filters the point
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in the maintenance cycle in which a fabric filter is
tested). Test-to-test variability can be termed longterm variability. 72 FR 54878.
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EP17FE11.000</GPH>
E. Variability
In assessing sources’ performance,
EPA may consider variability both in
identifying which performers are ‘‘best’’
and in assessing their level of
performance. Brick MACT, 479 F. 3d at
881–82; see also Mossville Envt’l Action
Now v. EPA, 370 F.3d 1232, 1241–42
(D.C. Cir 2004) (EPA must exercise its
judgment, based on an evaluation of the
relevant factors and available data, to
determine the level of emissions control
that has been achieved by the best
performing sources considering these
sources’ operating variability).
Variability in lead producers’
performance has a number of causes.
For emissions of lead compounds that
are controlled by baghouses, the
variability is chiefly due to variations in
performance of the control device for
which both run-to-run and test-to-test
variability must be accounted.23
In determining the contribution to a
plant-wide emission limit of the main
stack, we considered annual emissions
discharged from the air pollution
control devices that control lead
emissions. For this rule, we used the
2008 emissions reported by Doe Run to
the State of Missouri.
We assessed variability using a
statistical formula designed to estimate
an emissions level that is equivalent to
the source’s performance based on
future compliance tests. Specifically,
the calculated limit is an upper
prediction limit (UPL) calculated with
the Student’s t-test using the TINV
function in Microsoft Excel®. The
Student’s t-test has also been used in
other EPA rulemakings (e.g., NESHAP
for Portland Cement Manufacturing [75
FR 54970, September 9, 2010]; NSPS for
Hospital/Medical/Infectious Waste
Incinerators [74 FR 51368, October 6,
2009]; NESHAP for Industrial,
Commercial, and Institutional Boilers
and Process Heaters-Proposed [75 FR
32006, June 4, 2010]) in accounting for
variability. A prediction interval for a
future observation is an interval that
will, with a specified degree of
confidence, contain the next (or some
other pre-specified) randomly selected
observation from a population. In other
words, the prediction interval estimates
what the upper bound of future values
will be, based upon present or past
samples taken. The UPL consequently
F. What other actions are we proposing?
manner as discussed above in section
V.C.1 for the furnace area and refining
stack limit (i.e., stack testing on a
quarterly basis). We are proposing stack
testing on a quarterly basis as opposed
to testing on an annual basis since this
allows the facility the opportunity to
adjust their emissions throughout the
year to be in compliance, rather than to
find they are out of compliance at the
end of the year, thereby risking
violations. This schedule also coincides
with other quarterly monitoring and
reporting required of the facility. Also as
discussed in section V.C.1, new primary
lead processing facilities would be
required to demonstrate compliance
using lead continuous emission
monitoring systems (CEMS).
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VI. Proposed Action
A. What actions are we proposing as a
result of the residual risk reviews?
Consistent with CAA section 112
(f)(2), we are proposing to amend the
MACT standard for primary lead
processing to include a lead
concentration in air limit of 0.15 μg/m3
(based on 3-month rolling averages)to be
measured at locations approved by the
Administrator to address the risks from
all fugitive dust emissions addressed in
40 CFR 63.1544. We are also proposing
to remove refining and casting
operations from § 63.1544 and to require
that emissions from these operations be
vented to one or more stacks. Finally,
we are proposing to establish an
emission cap of 0.91 TPY for the furnace
area stack and the refining operation
stacks. These limits were established
based on the level of reductions in lead
emissions from the three sources that
are necessary to show that the lead
NAAQS will not be exceeded within the
50 km modeled domain. We believe the
NAAQS level represents an acceptable
level of risk and that the proposed limits
are necessary to ensure that risks from
these sources are acceptable. We are
proposing that the risk posed by lead
emissions from the main stack and by
emissions of all other HAP is
acceptable.
We are proposing that compliance
with the emission limits applicable to
the furnace area and refinery stacks
would be demonstrated based on stack
testing for existing facilities and, for
new facilities, using CEMS after
promulgation of performance
specifications for a CEMS capable of
measuring lead emissions.
We are proposing that compliance
with the lead concentration in air limit
would be demonstrated using a
compliance monitoring system
approved by the Administrator.
We are also proposing that the
Primary Lead Smelting standard, as we
have proposed to revise it to ensure an
acceptable level of risk, will also protect
public health with an ample margin of
safety. With regard to lead emissions
from fugitive dust sources and from the
furnace and refining area stacks, we
have not identified any feasible controls
beyond those needed to meet the
proposed emission limits that will
provide an acceptable level of risk . The
standards we are proposing to ensure an
acceptable level of risk for lead
emissions will also reduce the risk from
cadmium and will also reduce
emissions of all other metal HAP known
to be emitted from this source category
because the controls that will reduce
lead emissions are the same controls
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that will reduce emissions of these other
metal HAP. The cancer risk from
cadmium emissions will be reduced
from 30-in-1 million to less than 1-in-1
million. Therefore, we are proposing
that the existing MACT, as it would be
modified based on our proposed
requirements for lead emissions, would
provide an ample margin of safety with
respect to emissions from all metal
HAP.
With regard to lead emissions from
the main stack, we have identified
developments in practices, processes
and control technologies since
promulgation of the MACT standard in
1999, and are proposing a reduced
emission limit for the main stack based
on these improvements. Since the main
stack does not pose an unacceptable risk
at its current emissions level, we are not
proposing reductions for this emission
point under 112(f)(2). However, we are
proposing a reduced emission limit
under 112(d)(6) due to the
improvements we identified.
B. What actions are we proposing as a
result of the technology reviews?
For the Primary Lead Smelting source
category, we have determined that there
have been developments in practices,
processes, or control technologies since
the promulgation of the MACT
standards that are feasible for the one
facility in this source category to
implement at the main stack. The
proposed limit is consistent with the
current demonstrated performance of
the facility based on obligations adopted
by the State and reflected in the 2002
SIP and 2007 SIP revision for Doe Run.
We are proposing that a performance
of 15.11 TPY has been demonstrated for
emissions from the main stack, taking
into consideration variability of
emissions from that stack. The existing
MACT lead emissions standard that is
applicable to emissions from the main
stack is a plant-wide emission limit that
also applies to emissions from the
furnace-area stack. We are proposing to
revise the plant-wide limit to reflect the
15.11 TPY limit for the main stack as
well as the emissions limits we are
proposing for the furnace-area and
refinery stacks under CAA section
112(f)(2). Thus, we are proposing to
revise the plant-wide emissions limit
from 1 pound of lead per ton of lead
produced, to 0.22 pound of lead per ton
of lead produced and the new limit
would include emissions from the
refinery stack as well as emissions from
the main stack and the furnace area
stack. Compliance with this limit would
be demonstrated quarterly with stack
testing. For new facilities, compliance
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would be demonstrated using lead
CEMS.
C. What other actions are we proposing?
As described above, we are proposing
to amend the applicability section for
the MACT rule to tailor it to the
definition of the source category we
established under CAA section
112(c)(1). See ‘‘Documentation for
Development of Initial Source Category
List—Final Report’’, USEPA/OAQPS,
EPA–450/3–91–030, July, 1992. In
support of this applicability provision
clarification, we are also proposing to
replace the definition of ‘‘primary lead
smelter’’ with a definition of ‘‘primary
lead processor’’. The ‘‘primary lead
processor’’ definition would include any
facility that produces lead from
processing of lead sulfide ore by
pyrometallurgical (smelting) or any
other technique. We are also proposing
to add definitions of ‘‘secondary lead
smelters’’, ‘‘lead refiners’’, and ‘‘lead
remelters’’ to clarify the meaning of
those terms in the second sentence of
the applicability provision.
We propose to amend the Primary
Lead Smelting MACT standards to
remove the language that exempts bag
leak detection system alarm time
incurred during periods of SSM from
inclusion in the allowable alarm time.
This change is being made to ensure the
rule is consistent with the court’s ruling
in Sierra Club v. EPA, 551 F.3d 1019
(D.C. Cir. 2008). We are also proposing
minor modifications throughout the rule
to incorporate plain language and to
make editorial and clarifying revisions.
In addition, we are proposing changes to
Table 1 of the rule to reflect revisions
to SSM requirements.
D. Compliance Dates
We are proposing that the
requirements under CAA section
112(f)(2) for the one existing source, if
finalized, must be implemented no later
than two years after the effective date of
this rule. Consistent with CAA section
112(f)(4)(B), we are proposing that a
two-year compliance period is necessary
so the facility has adequate time to
install additional controls and
demonstrate compliance, including the
time necessary to purchase, install and
test replacement bags, or if the facility
decides to add a new baghouse in series
with an existing baghouse, seek bids,
select a vendor, install and test the new
equipment; prepare and submit the
required monitoring plan to monitor
lead concentrations in air; purchase,
install and conduct quality assurance
and quality control measures on
compliance monitoring equipment and;
conduct site remediation necessary to
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reduce fugitive emissions. A two-year
compliance period is also consistent
with the schedule of required actions
contained in the Consent Decree.
In addition, we are proposing that the
plant-wide limit that would reflect
reductions required for the main stack
pursuant to CAA section 112(d)(6) and
for the furnace area and refinery stacks
pursuant to CAA section 112(f)(2) must
be met no later than two years after the
effective date of this rule. Because these
limits reflect the reductions from the
furnace area and refinery stacks
required under section 112(f)(2), we
believe a two-year compliance
timeframe is needed for the same
reasons provided above.
VII. Request for Comments
We are soliciting comments on all
aspects of this proposed action. All
comments received during the comment
period will be considered. In addition to
general comments on this proposed
actions, we are also interested in any
additional data that may help to reduce
the uncertainties inherent in the risk
assessments. We are specifically
interested in receiving corrections to the
dataset used for risk modeling. Such
data should include supporting
documentation in sufficient detail to
allow characterization of the quality and
representativeness of the data or
information. Please see the following
section for more information on
submitting data.
VIII. Submitting Data Corrections
The facility-specific data used in the
source category risk analyses and
demographic analyses are available for
download on the RTR Web Page at
9437
https://www.epa.gov/ttn/atw/rrisk/
rtrpg.html. The data files include
detailed information for each HAP
emissions release point for the facility
included in the source category.
If you believe the data are not
representative or are inaccurate, please
identify the data in question, provide
your reason for concern, and provide
any ‘‘improved’’ data that you have, if
available. When you submit data, we
request that you provide documentation
of the basis for the revised values to
support your suggested changes. To
submit comments on the data
downloaded from the RTR Web page,
complete the following steps:
(1) Within this downloaded file, enter
suggested revisions to the data fields
appropriate for that information. The
data fields that may be revised include
the following:
Data element
Definition
Control Measure ........................................................................
Control Measure Comment .......................................................
Are control measures in place? (yes or no).
Select control measure from list provided, and briefly describe the control measure.
Indicate here if the facility or record should be deleted.
Describes the reason for deletion.
Code description of the method used to derive emissions. For example, CEM,
material balance, stack test, etc.
Enter the general type of emission process associated with the specified emission point.
Enter release angle (clockwise from true North); orientation of the y-dimension
relative to true North, measured positive for clockwise starting at 0 degrees
(maximum 89 degrees).
Enter dimension of the source in the east-west (x-) direction, commonly referred
to as length (ft).
Enter dimension of the source in the north-south (y-) direction, commonly referred to as width (ft).
Enter total annual emissions due to malfunctions (TPY).
Enter maximum hourly malfunction emissions here (lb/hr).
Enter datum for latitude/longitude coordinates (NAD27 or NAD83); if left blank,
NAD83 is assumed.
Enter general comments about process sources of emissions.
Enter revised physical street address for MACT facility here.
Enter revised city name here.
Enter revised county name here.
Enter revised Emission Release Point Type here.
Enter revised End Date here.
Enter revised Exit Gas Flowrate here (ft3/sec).
Enter revised Exit Gas Temperature here (F).
Enter revised Exit Gas Velocity here (ft/sec).
Enter revised Facility Category Code here, which indicates whether facility is a
major or area source.
Enter revised Facility Name here.
Enter revised Facility Registry Identifier here, which is an ID assigned by the
EPA Facility Registry System.
Enter revised HAP Emissions Performance Level here.
Enter revised Latitude here (decimal degrees).
Enter revised Longitude here (decimal degrees).
Enter revised MACT Code here.
Enter revised Pollutant Code here.
Enter revised routine emissions value here (TPY).
Enter revised SCC Code here.
Enter revised Stack Diameter here (ft).
Enter revised Stack Height here (Ft).
Enter revised Start Date here.
Enter revised State here.
Enter revised Tribal Code here.
Enter revised Zip Code here.
Enter total annual emissions due to shutdown events (TPY).
Enter maximum hourly shutdown emissions here (lb/hr).
Delete ........................................................................................
Delete Comment .......................................................................
Emission Calculation Method Code For Revised Emissions ...
Emission Process Group ..........................................................
Fugitive Angle ...........................................................................
Fugitive Length ..........................................................................
Fugitive Width ...........................................................................
Malfunction Emissions ..............................................................
Malfunction Emissions Max Hourly ...........................................
North American Datum .............................................................
Process Comment .....................................................................
REVISED Address ....................................................................
REVISED City ...........................................................................
REVISED County Name ...........................................................
REVISED Emission Release Point Type ..................................
REVISED End Date ..................................................................
REVISED Exit Gas Flow Rate ..................................................
REVISED Exit Gas Temperature ..............................................
REVISED Exit Gas Velocity ......................................................
REVISED Facility Category Code .............................................
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REVISED Facility Name ...........................................................
REVISED Facility Registry Identifier .........................................
REVISED HAP Emissions Performance Level Code ...............
REVISED Latitude .....................................................................
REVISED Longitude ..................................................................
REVISED MACT Code .............................................................
REVISED Pollutant Code ..........................................................
REVISED Routine Emissions ...................................................
REVISED SCC Code ................................................................
REVISED Stack Diameter .........................................................
REVISED Stack Height .............................................................
REVISED Start Date .................................................................
REVISED State .........................................................................
REVISED Tribal Code ...............................................................
REVISED Zip Code ...................................................................
Shutdown Emissions .................................................................
Shutdown Emissions Max Hourly .............................................
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Data element
Definition
Stack Comment .........................................................................
Startup Emissions .....................................................................
Startup Emissions Max Hourly ..................................................
Year Closed ..............................................................................
2. Fill in the commenter information
fields for each suggested revision (i.e.,
commenter name, commenter
organization, commenter e-mail address,
commenter phone number, and revision
comments).
3. Gather documentation for any
suggested emissions revisions (e.g.,
performance test reports, material
balance calculations, etc.).
4. Send the entire downloaded file
with suggested revisions in Microsoft®
Access format and all accompanying
documentation to Docket ID Number
EPA–HQ–OAR–2004–0305 (through one
of the methods described in the
ADDRESSES section of this preamble). To
expedite review of the revisions, it
would also be helpful if you submitted
a copy of your revisions to the EPA
directly at RTR@epa.gov in addition to
submitting them to the docket.
5. If you are providing comments on
a facility, you need only submit one file
for that facility, which should contain
all suggested changes for all sources at
that facility. We request that all data
revision comments be submitted in the
form of updated Microsoft® Access files,
which are provided on the https://
www.epa.gov/ttn/atw/rrisk/rtrpg.html
Web page.
IX. Statutory and Executive Order
Reviews
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A. Executive Order 12866: Regulatory
Planning and Review
Under Executive Order 12866 (58 FR
51735, October 4, 1993), this action is a
significant regulatory action because it
raises novel legal and policy issues.
Accordingly, EPA submitted this action
to the Office of Management and Budget
(OMB) for 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 in this rule have been
submitted for approval to the Office of
Management and Budget (OMB) under
the Paperwork Reduction Act, 44 U.S.C.
3501 et seq. The Information Collection
Request (ICR) document prepared by
EPA has been assigned EPA ICR number
1856.07.
We are proposing new paperwork
requirements to the Primary Lead
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Enter
Enter
Enter
Enter
general comments about emission release points.
total annual emissions due to startup events (TPY).
maximum hourly startup emissions here (lb/hr).
date facility stopped operations.
Smelting source category in the form of
monitoring for lead concentrations in air
and increased frequency for stack
testing as described in 40 CFR
63.1547(k) (compliance monitoring) and
40 CFR 63.1546 (stack testing). These
requirements are described in section
VI.A and B. Although these are
additional requirements under today’s
proposed rule, they are consistent with
existing monitoring and testing
currently conducted by the facility to
meet MACT and SIP requirements.
Therefore, we do not believe that the
additional paperwork required by these
proposed changes would constitute an
undue burden to the facility.
We estimate one regulated entity is
currently subject to subpart TTT and
will be subject to all proposed
standards. This facility will have no
capital costs associated with the
information collection requirements in
the proposed rule.
The estimated recordkeeping and
reporting burden after the effective date
of the proposed rule is estimated to be
1,323 labor hours at a cost of $465,503.
This estimate includes the cost of
reporting, including reading
instructions, and information gathering.
Recordkeeping cost estimates include
reading instructions, planning activities,
monitoring plan development,
conducting compliance monitoring,
sampling and analysis and maintenance
of rolling 3-month average data. The
average hours and cost per regulated
entity would be 1,323 hours and
$465,503 based on one facility response
per year. Burden is defined at 5 CFR
1320.3(b).
An agency may not conduct or
sponsor, and a person is not required to
respond to, a collection of information
unless it displays a currently valid OMB
control number. The OMB control
numbers for EPA’s regulations in 40
CFR 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, EPA has established
a public docket for this rule, which
includes this ICR, under Docket ID
number EPA–HQ–OAR–2004–0305.
Submit any comments related to the ICR
to EPA and OMB. See ADDRESSES
section at the beginning of this notice
for where to submit comments to EPA.
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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 17, 2011, a
comment to OMB is best assured of
having its full effect if OMB receives it
by March 21, 2011. The final rule will
respond to any OMB or public
comments on the information collection
requirements contained in this proposal.
C. Regulatory Flexibility Act
The Regulatory Flexibility Act (RFA)
generally requires an agency to prepare
a regulatory flexibility analysis of any
rule subject to notice and comment
rulemaking requirements under the
Administrative Procedure Act or any
other statute unless the agency certifies
that the rule will not have a significant
economic impact on a substantial
number of small entities. Small entities
include small businesses, small
organizations, and small governmental
jurisdictions. For purposes of assessing
the impacts of today’s proposed rule on
small entities, small entity is defined as:
(1) A small business that is a small
industrial entity as defined by the Small
Business Administration’s (SBA)
regulations at 13 CFR 121.201; (2) a
small governmental jurisdiction that is a
government of a city, county, town,
school district or special district with a
population of less than 50,000; and (3)
a small organization that is any not-forprofit enterprise which is independently
owned and operated and is not
dominant in its field.
After considering the economic
impacts of today’s proposed rule on
small entities, I certify that this action
will not have a significant economic
impact on a substantial number of small
entities. This proposed rule will not
impose any requirements on small
entities. This proposed rule is currently
applicable to one operating facility that
does not meet the definition of a small
entity.
We continue to be interested in the
potential impacts of the proposed rule
on small entities and welcome
comments on issues related to such
impacts.
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D. Unfunded Mandates Reform Act
This proposed rule does not contain
a federal mandate under the provisions
of Title II of the Unfunded Mandates
Reform Act of 1995 (UMRA), 2 U.S.C.
1531–1538 for State, local, or tribal
governments or the private sector. The
proposed rule would not result in
expenditures of $100 million or more
for State, local, and tribal governments,
in aggregate, or the private sector in any
1 year. The proposed rule imposes no
enforceable duties on any State, local or
tribal governments or the private sector.
Thus, this proposed rule is not subject
to the requirements of sections 202 or
205 of the UMRA.
This proposed rule is also not subject
to the requirements of section 203 of
UMRA because it contains no regulatory
requirements that might significantly or
uniquely affect small governments
because it contains no requirements that
apply to such governments nor does it
impose obligations upon them.
E. Executive Order 13132: Federalism
This proposed rule does not have
federalism implications. It will not have
substantial direct effects on the States,
on the relationship between the national
government and the States, or on the
distribution of power and
responsibilities among the various
levels of government, as specified in
Executive Order 13132. None of the
facilities subject to this action are
owned or operated by State
governments, and, because no new
requirements are being promulgated,
nothing in this proposal will supersede
State regulations. Thus, Executive Order
13132 does not apply to this proposed
rule.
In the spirit of Executive Order 13132,
and consistent with EPA policy to
promote communications between EPA
and State and local governments, EPA
specifically solicits comment on this
proposed rule from State and local
officials.
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F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
Subject to the Executive Order 13175
(65 FR 67249, November 9, 2000) EPA
may not issue a regulation that has tribal
implications, that imposes substantial
direct compliance costs, and that is not
required by statute, unless the Federal
government provides the funds
necessary to pay the direct compliance
costs incurred by tribal governments, or
EPA consults with tribal officials early
in the process of developing the
proposed regulation and develops a
tribal summary impact statement. EPA
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has concluded that this proposed rule
will not have tribal implications, as
specified in Executive Order 13175. It
will not have substantial direct effect 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.
Thus, Executive Order 13175 does not
apply to this action.
EPA specifically solicits additional
comment on this proposed action from
tribal officials.
G. Executive Order 13045: Protection of
Children From Environmental Health
Risks and Safety Risks
This proposed rule is not subject to
Executive Order 13045 (62 FR 19885,
April 23, 1997) because it is not
economically significant as defined in
Executive Order 12866. However, the
Agency does believe there is a
disproportionate risk to children.
Modeled ambient air lead
concentrations from the one facility in
this source category are in excess of the
NAAQS for lead, which was set to
‘‘provide increased protection for
children and other at-risk populations
against an array of adverse health
effects, most notably including
neurological effects in children,
including neurocognitive and
neurobehavioral effects.’’ 73 FR 67007.
However, the control measures
proposed in this notice will result in
lead concentration levels that are in
compliance with the lead NAAQS,
thereby mitigating the risk of adverse
health effects to children.
H. Executive Order 13211: Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use
This action is not a ‘‘significant energy
action’’ as defined under Executive
Order 13211, ‘‘Actions Concerning
Regulations That Significantly Affect
Energy Supply, Distribution, or Use’’ (66
FR 28355, May 22, 2001), because it is
not likely to have significant adverse
effect on the supply, distribution, or use
of energy. This action will not create
any new requirements for sources in the
energy supply, distribution, or use
sectors.
I. National Technology Transfer and
Advancement Act
Section 12(d) of the National
Technology Transfer and Advancement
Act of 1995 (‘‘NTTAA’’), Public Law
104–113, 12(d) (15 U.S.C. 272 note)
directs EPA to use voluntary consensus
standards in its regulatory activities
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9439
unless to do so would be inconsistent
with applicable law or otherwise
impractical. Voluntary consensus
standards are technical standards (e.g.,
materials specifications, test methods,
sampling procedures, and business
practices) that are developed or adopted
by voluntary consensus standards
bodies. The NTTAA directs EPA to
provide Congress, through OMB,
explanations when the Agency decides
not to use available and applicable
voluntary consensus standards.
This proposed rulemaking does not
involve technical standards. Therefore,
EPA is not considering the use of any
voluntary consensus standards.
J. Executive Order 12898: Federal
Actions To Address Environmental
Justice in Minority Populations and
Low-Income Populations
Executive Order 12898 (59 FR 7629,
February 16, 1994) establishes federal
executive policy on environmental
justice. Its main provision directs
federal agencies, to the greatest extent
practicable and permitted by law, to
make environmental justice part of their
mission by identifying and addressing,
as appropriate, disproportionately high
and adverse human health or
environmental effects of their programs,
policies, and activities on minority
populations and low-income
populations in the United States.
To examine the potential for any
environmental justice issues that might
be associated with each source category,
we evaluated the distributions of HAPrelated cancer and non-cancer risks
across different social, demographic,
and economic groups within the
populations living near the facilities
where these source categories are
located. The methods used to conduct
demographic analyses for this rule are
described in section IV.A of the
preamble for this rule. The development
of demographic analyses to inform the
consideration of environmental justice
issues in EPA rulemakings is an
evolving science. The EPA offers the
demographic analyses in today’s
rulemaking as examples of how such
analyses might be developed to inform
such consideration, and invites public
comment on the approaches used and
the interpretations made from the
results, with the hope that this will
support the refinement and improve
utility of such analyses for future
rulemakings.
In the case of Primary Lead
Processing, we focused on populations
within 50 km of the one facility in this
source category with emission sources
subject to the MACT standard. More
specifically, for these populations we
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Federal Register / Vol. 76, No. 33 / Thursday, February 17, 2011 / Proposed Rules
evaluated exposures to HAP which
could result in cancer risks of 1-in-1
million or greater, or population
exposures to ambient air lead
concentrations above the level of the
NAAQS for lead. We compared the
percentages of particular demographic
groups within the focused populations
to the total percentages of those
demographic groups nationwide. The
results of this analysis are documented
in section V.B.1 (see Table 6), as well as
in a technical report located in the
docket for this rulemaking. In brief,
although our analyses show that there is
the potential for adverse environmental
and human health effects from
emissions of lead, it does not indicate
any significant potential for disparate
impacts to the specific demographic
groups analyzed (see section V.B.1).
Notably however, the proposed rule
would require additional control
measures to address the identified
environmental and health risks and
would therefore, decrease risks to any
populations exposed to these sources.
List of Subjects in 40 CFR Part 63
Environmental protection, Air
pollution control, Reporting and
recordkeeping requirements, Lead.
Dated: January 31, 2011.
Lisa P. Jackson,
Administrator.
For reasons set out in the preamble,
title 40, chapter I, of the Code of Federal
Regulations is proposed to be amended:
PART 63—[AMENDED]
1. The authority citation for part 63
continues to read as follows:
Authority: 42 U.S.C. 7401 et seq.
2. Section 63.1541 is revised to read
as follows:
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§ 63.1541
Applicability.
(a) The provisions of this subpart
apply to any facility engaged in
producing lead metal from ore
concentrates. The category includes, but
is not limited to, the following smelting
processes: Sintering, reduction,
preliminary treatment, refining and
casting operations, process fugitive
sources, and fugitive dust sources. The
sinter process includes an updraft or
downdraft sintering machine. The
reduction process includes the blast
furnace, electric smelting furnace with a
converter or reverberatory furnace, and
slag fuming furnace process units. The
preliminary treatment process includes
the drossing kettles and dross
reverberatory furnace process units. The
refining process includes the refinery
process unit. The provisions of this
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subpart do not apply to secondary lead
smelters, lead refiners, or lead remelters.
(b) Table 1 of this subpart specifies
the provisions of subpart A of this part
that apply and those that do not apply
to owners and operators of primary lead
processors.
3. Section 63.1542 is amended by:
a. Adding in alphabetical order
definitions for ‘‘Affirmative defense,’’
‘‘Lead refiner,’’ ‘‘Lead remelter,’’
‘‘Primary lead processor,’’ and
‘‘Secondary lead smelter’’.
b. Removing the definition for
‘‘Primary lead smelter’’.
c. Revising the definitions for
‘‘Fugitive dust source,’’ ‘‘Furnace area,’’
‘‘Malfunction,’’ ‘‘Materials storage and
handling area,’’ ‘‘Plant roadway,’’
‘‘Process fugitive source,’’ ‘‘Refining and
casting area,’’ Sinter machine area,’’ and
‘‘Tapping location’’.
§ 63.1542
Definitions.
*
*
*
*
*
Affirmative defense means, in the
context of an enforcement proceeding, a
response or defense put forward by a
defendant, regarding which the
defendant has the burden of proof, and
the merits of which are independently
and objectively evaluated in a judicial
or administrative proceeding.
*
*
*
*
*
Fugitive dust source means a
stationary source of hazardous air
pollutant emissions at a primary lead
processor resulting from the handling,
storage, transfer, or other management
of lead-bearing materials where the
source is not part of a specific process,
process vent, or stack. Fugitive dust
sources include roadways, storage piles,
materials handling transfer points, and
materials transport areas.
Furnace area means any area of a
primary lead processor in which a blast
furnace or dross furnace is located.
Lead refiner means any facility that
refines lead metal that is not located at
a primary lead processor.
Lead remelter means any facility that
remelts lead metal that is not located at
a primary lead processor.
Malfunction means any sudden,
infrequent, and not reasonably
preventable failure of air pollution
control and monitoring equipment,
process equipment, or a process to
operate in a normal or usual manner
which causes, or has the potential to
cause, the emission limitations in an
applicable standard to be exceeded.
Failures that are caused in part by poor
maintenance or careless operation are
not malfunctions.
Materials storage and handling area
means any area of a primary lead
processor in which lead-bearing
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materials (including ore concentrate,
sinter, granulated lead, dross, slag, and
flue dust) are stored or handled between
process steps, including areas in which
materials are stored in piles, bins, or
tubs, and areas in which material is
prepared for charging to a sinter
machine or smelting furnace or other
lead processing operation.
*
*
*
*
*
Plant roadway means any area of a
primary lead processor that is subject to
vehicle traffic, including traffic by
forklifts, front-end loaders, or vehicles
carrying ore concentrates or cast lead
ingots. Excluded from this definition are
employee and visitor parking areas,
provided they are not subject to traffic
by vehicles carrying lead-bearing
materials.
Primary lead processor means any
facility engaged in the production of
lead metal from lead sulfide ore
concentrates through the use of
pyrometallurgical or other techniques.
Process fugitive source means a
source of hazardous air pollutant
emissions at a primary lead processor
that is associated with lead smelting,
processing or refining but is not the
primary exhaust stream and is not a
fugitive dust source. Process fugitive
sources include sinter machine charging
locations, sinter machine discharge
locations, sinter crushing and sizing
equipment, furnace charging locations,
furnace taps, and drossing kettle and
refining kettle charging or tapping
locations.
Refining and casting area means any
area of a primary lead processor in
which drossing or refining operations
occur, or casting operations occur.
Secondary lead smelter means any
facility at which lead-bearing scrap
material, primarily, but not limited to,
lead-acid batteries, is recycled into
elemental lead or lead alloys by
smelting.
*
*
*
*
*
Sinter machine area means any area
of a primary lead processor where a
sinter machine, or sinter crushing and
sizing equipment is located.
*
*
*
*
*
Tapping location means the opening
through which lead and slag are
removed from the furnace.
4. Section 63.1543 is revised to read
as follows:
§ 63.1543 Standards for process and
process fugitive sources.
(a) No owner or operator of any
existing, new, or reconstructed primary
lead processor shall discharge or cause
to be discharged into the atmosphere
lead compounds in excess of 0.22
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pounds per ton of lead metal produced
from the aggregation of emissions
discharged from air pollution control
devices used to control emissions at
primary lead processing facilities,
including the sources listed in
paragraphs (a)(1) through (a)(10) of this
section.
(1) Sinter machine;
(2) Blast furnace;
(3) Dross furnace;
(4) Dross furnace charging location;
(5) Blast furnace and dross furnace
tapping location;
(6) Sinter machine charging location;
(7) Sinter machine discharge end;
(8) Sinter crushing and sizing
equipment;
(9) Sinter machine area; and
(10) Refining and casting, and furnace
area.
(b) No owner or operator of any
existing, new, or reconstructed primary
lead processor shall discharge or cause
to be discharged into the atmosphere
lead compounds in excess of 0.91 tons
per year from the air pollution control
devices used to control emissions from
furnace area and refining and casting
operations.
(c) The process fugitive sources listed
in paragraphs (a)(4) through (a)(8) of this
section must be equipped with a hood
and must be ventilated to a baghouse or
equivalent control device. The hood
design and ventilation rate must be
consistent with American Conference of
Governmental Industrial Hygienists
recommended practices.
(d) The sinter machine area must be
enclosed in a building that is ventilated
to a baghouse or equivalent control
device at a rate that maintains a positive
in-draft through any doorway opening.
(e) Except as provided in paragraph (f)
of this section, following the initial tests
to demonstrate compliance with
paragraphs (a)and (b) of this section, the
owner or operator of a primary lead
processor must conduct compliance
tests for lead compounds on an
quarterly basis (no later than 100 days
following any previous compliance
test).
(f) If the 12 most recent compliance
tests demonstrate compliance with the
emission limit specified in paragraphs
(a) and (b) of this section, the owner or
operator of a primary lead processor
shall be allowed up to 12 calendar
months from the last compliance test to
conduct the next compliance test for
lead compounds.
(g) The owner or operator of a primary
lead processor must maintain and
operate each baghouse used to control
emissions from the sources listed in
paragraphs (a)(1) through (a)(10) of this
section such that the alarm on a bag leak
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detection system required under
§ 63.1547(c)(8) does not sound for more
than five percent of the total operating
time in a 6-month reporting period.
(h) The owner or operator of a
primary lead processor must record the
date and time of a bag leak detection
system alarm and initiate procedures to
determine the cause of the alarm
according to the corrective action plan
required under § 63.1547(f) within 1
hour of the alarm. The cause of the
alarm must be corrected as soon as
practicable.
(i) At all times, the owner or operator
must operate and maintain any affected
source, including associated air
pollution control equipment and
monitoring equipment, in a manner
consistent with safety and good air
pollution control practices for
minimizing emissions. Determination of
whether such operation and
maintenance procedures are being used
will be based on information available
to the Administrator which may
include, but is not limited to,
monitoring results, review of operation
and maintenance procedures, review of
operation and maintenance records, and
inspection of the source.
5. Section 63.1544 is revised to read
as follows:
§ 63.1544
sources.
Standards for fugitive dust
(a) No owner or operator of any
existing, new or reconstructed primary
lead processor shall discharge or cause
to be discharged into the atmosphere
lead compounds that cause the
concentration of lead in air to exceed
0.15 μg/m3 on a 3-month rolling average
measured at locations approved by the
Administrator.
(b) At all times, the owner or operator
must operate and maintain any affected
source, including associated air
pollution control equipment and
monitoring equipment, in a manner
consistent with safety and good air
pollution control practices for
minimizing emissions. Determination of
whether such operation and
maintenance procedures are being used
will be based on information available
to the Administrator which may
include, but is not limited to,
monitoring results, review of operation
and maintenance procedures, review of
operation and maintenance records, and
inspection of the source.
6. Section 63.1545 is revised to read
as follows:
§ 63.1545
requirements of this subpart no later
than [DATE TWO YEARS FROM
PUBLICATION OF THE FINAL RULE
IN THE FEDERAL REGISTER].
(b) Each owner or operator of a new
primary lead processor must achieve
compliance with the requirements of
this subpart no later than [DATE 60
DAYS AFTER PUBLICATION OF THE
FINAL RULE IN THE FEDERAL
REGISTER] or startup, whichever is
later.
7. Section 63.1546 is revised to read
as follows:
§ 63.1546
Performance testing.
(a) The following procedures must be
used to determine quarterly compliance
with the emissions standard for lead
compounds under § 63.1543(a) and (b)
for existing sources:
(1) Each owner or operator of existing
sources listed in § 63.1543(a)(1) through
(10) must determine the lead compound
emissions rate, in units of pounds of
lead per hour according to the following
test methods in appendices of part 60 of
this chapter:
(i) Method 1 to appendix A–1 of 40
CFR part 60 must be used to select the
sampling port location and the number
of traverse points.
(ii) Methods 2 and 2F of appendix
A–1 and Method 2G of appendix A–2 of
40 CFR part 60 must be used to measure
volumetric flow rate.
(iii) Methods 3, 3A, 3B of appendix
A–2 of 40 CFR part 60 must be used for
gas analysis.
(iv) Method 4 of appendix A–3 of 40
CFR part 60 must be used to determine
moisture content of the stack gas.
(v) Method 12 of appendix A–5 or
Method 29 of appendix A–8 of 40 CFR
part 60 must be used to determine lead
emissions rate of the stack gas.
(2) A performance test shall consist of
at least three runs. For each test run
with Method 12 of appendix A–5 or
Method 29 of appendix A–8 of 40 CFR
part 60, the minimum sample time must
be 60 minutes and the minimum
volume must be 1 dry standard cubic
meter (35 dry standard cubic feet).
(3) Performance tests shall be
completed quarterly, once every 3
months, to determine compliance.
(4) The lead emission rate in pounds
per quarter is calculated by multiplying
the quarterly lead emission rate in
pounds per hour by the quarterly plant
operating time, in hours as shown in
Equation 1:
Compliance dates.
(a) Each owner or operator of an
existing primary lead processor must
achieve compliance with the
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Where:
EPb = quarterly lead emissions, pounds per
quarter;
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EP17FE11.001</GPH>
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ERPb = quarterly lead emissions rate, pounds
per hour; and
QPOT = quarterly plant operating time, hours
per quarter.
(5) The lead production rate, in units
of tons per quarter, must be determined
based on production data for the
previous quarter according to the
procedures detailed in paragraphs
(a)(5)(i) through (iv) of this section:
(i) Total lead products production
multiplied by the fractional lead content
must be determined in units of tons.
(ii) Total copper matte production
multiplied by the fractional lead content
must be determined in units of tons.
(iii) Total copper speiss production
multiplied by the fractional lead content
must be determined in units of tons.
(iv) Total quarterly lead production
must be determined by summing the
values obtained in paragraphs (a)(5)(i)
through (a)(5)(iii) of this section.
(6) To determine compliance with the
production-based lead compound
emission rate in § 63.1543(a), the
quarterly production-based lead
compound emission rate, in units of
pounds of lead emissions per ton of lead
produced, is calculated as shown in
Equation 2 by dividing lead emissions
by lead production.
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Where:
CEPb = quarterly production-based lead
compound emission rate, in units of
pounds of lead emissions per ton of lead
produced;
EPb = quarterly lead emissions, pounds per
quarter; and
PPb = quarterly lead production, tons per
quarter.
(7) To determine quarterly
compliance with the emissions standard
for lead compounds under § 63.1543(b),
sum the lead compound emission rates
for the current and previous three
quarters for the sources in § 63.1543
(a)(10) to determine compliance with
§ 63.1543(b), as determined in
accordance with paragraphs (a)(1)
through (a)(4) of this section.
(b) Owner and operators must perform
an initial compliance test to
demonstrate compliance with the sinter
building in-draft requirements of
§ 63.1543(d) at each doorway opening in
accordance with paragraphs (b)(1)
through (b)(4) of this section.
(1) Use a propeller anemometer or
equivalent device.
(2) Determine doorway in-draft by
placing the anemometer in the plane of
the doorway opening near its center.
(3) Determine doorway in-draft for
each doorway that is open during
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normal operation with all remaining
doorways in their customary position
during normal operation.
(4) Do not determine doorway in-draft
when ambient wind speed exceeds 2
meters per second.
(c) Performance tests shall be
conducted under such conditions as the
Administrator specifies to the owner or
operator based on representative
performance of the affected source for
the period being tested. Upon request,
the owner or operator shall make
available to the Administrator such
records as may be necessary to
determine the conditions of
performance tests.
8. Section 63.1547 is revised to read
as follows:
§ 63.1547
Monitoring requirements.
(a) Owners and operators of primary
lead processors must prepare, and at all
times operate according to, a standard
operating procedures manual that
describes in detail the procedures for
inspection, maintenance, and bag leak
detection and corrective action for all
baghouses that are used to control
process, process fugitive, or fugitive
dust emissions from any source subject
to the lead emission standards in
§§ 63.1543 and 63.1544, including those
used to control emissions from general
ventilation systems.
(b) The standard operating procedures
manual for baghouses required by
paragraph (a) of this section must be
submitted to the Administrator or
delegated authority for review and
approval.
(c) The procedures specified in the
standard operating procedures manual
for inspections and routine maintenance
must, at a minimum, include the
requirements of paragraphs (c)(1)
through (c)(8) of this section.
(1) Weekly confirmation that dust is
being removed from hoppers through
visual inspection or equivalent means of
ensuring the proper functioning of
removal mechanisms.
(2) Daily check of compressed air
supply for pulse-jet baghouses.
(3) An appropriate methodology for
monitoring cleaning cycles to ensure
proper operation.
(4) Monthly check of bag cleaning
mechanisms for proper functioning
through visual inspection or equivalent
means.
(5) Quarterly visual check of bag
tension on reverse air and shaker-type
baghouses to ensure that bags are not
kinked (kneed or bent) or laying on their
sides. Such checks are not required for
shaker-type baghouses using selftensioning (spring loaded) devices.
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(6) Quarterly confirmation of the
physical integrity of the baghouse
through visual inspection of the
baghouse interior for air leaks.
(7) Quarterly inspection of fans for
wear, material buildup, and corrosion
through visual inspection, vibration
detectors, or equivalent means.
(8) Except as provided in paragraph
(h) of this section, continuous operation
of a bag leak detection system.
(d) The procedures specified in the
standard operating procedures manual
for maintenance must, at a minimum,
include a preventative maintenance
schedule that is consistent with the
baghouse manufacturer’s instructions
for routine and long-term maintenance.
(e) The bag leak detection system
required by paragraph (c)(8) of this
section must meet the specifications and
requirements of (e)(1) through (e)(8) of
this section.
(1) The bag leak detection system
must be certified by the manufacturer to
be capable of detecting particulate
matter emissions at concentrations of 10
milligram per actual cubic meter (0.0044
grains per actual cubic foot) or less.
(2) The bag leak detection system
sensor must provide output of relative
particulate matter loadings, and the
owner or operator must continuously
record the output from the bag leak
detection system.
(3) The bag leak detection system
must be equipped with an alarm system
that will sound when an increase in
relative particulate loading is detected
over a preset level, and the alarm must
be located such that it can be heard or
otherwise determined by the
appropriate plant personnel.
(4) Each bag leak detection system
that works based on the triboelectric
effect must be installed, calibrated, and
maintained in a manner consistent with
guidance provided in the U.S.
Environmental Protection Agency
guidance document ’’Fabric Filter Bag
Leak Detection Guidance’’ (EPA–454/R–
98–015). Other bag leak detection
systems must be installed, calibrated,
and maintained in a manner consistent
with the manufacturer’s written
specifications and recommendations.
(5) The initial adjustment of the
system must, at a minimum, consist of
establishing the baseline output by
adjusting the sensitivity (range) and the
averaging period of the device, and
establishing the alarm set points and the
alarm delay time.
(6) Following initial adjustment, the
owner or operator must not adjust the
sensitivity or range, averaging period,
alarm set points, or alarm delay time,
except as detailed in the approved SOP
required under paragraph (a) of this
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section. In no event shall the sensitivity
be increased by more than 100 percent
or decreased more than 50 percent over
a 365-day period unless a responsible
official certifies that the baghouse has
been inspected and found to be in good
operating condition.
(7) For negative pressure, induced air
baghouses, and positive pressure
baghouses that are discharged to the
atmosphere through a stack, the bag leak
detector must be installed downstream
of the baghouse and upstream of any
wet acid gas scrubber.
(8) Where multiple detectors are
required, the system’s instrumentation
and alarm may be shared among
detectors.
(f) The standard operating procedures
manual required by paragraph (a) of this
section must include a corrective action
plan that specifies the procedures to be
followed in the event of a bag leak
detection system alarm. The corrective
action plan must include at a minimum,
procedures to be used to determine the
cause of an alarm, as well as actions to
be taken to minimize emissions, which
may include, but are not limited to, the
following.
(1) Inspecting the baghouse for air
leaks, torn or broken bags or filter
media, or any other condition that may
cause an increase in emissions.
(2) Sealing off defective bags or filter
media.
(3) Replacing defective bags or filter
media, or otherwise repairing the
control device.
(4) Sealing off a defective baghouse
compartment.
(5) Cleaning the bag leak detection
system probe, or otherwise repairing or
maintaining the bag leak detection
system.
(6) Shutting down the process
producing the particulate emissions.
(g) The percentage of total operating
time the alarm on the bag leak detection
system sounds in a 6-month reporting
period must be calculated in order to
determine compliance with the five
percent operating limit in § 63.1543(h).
The percentage of time the alarm on the
bag leak detection system sounds must
be determined according to paragraphs
(g)(1) through (g)(3) of this section.
(1) For each alarm where the owner or
operator initiates procedures to
determine the cause of an alarm within
1 hour of the alarm, 1 hour of alarm
time must be counted.
(2) For each alarm where the owner or
operator does not initiate procedures to
determine the cause of the alarm within
1 hour of the alarm, alarm time will be
counted as the actual amount of time
taken by the owner or operator to
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initiate procedures to determine the
cause of the alarm.
(3) The percentage of time the alarm
on the bag leak detection system sounds
must be calculated as the ratio of the
sum of alarm times to the total operating
time multiplied by 100.
(h) Baghouses equipped with HEPA
filters as a secondary filter used to
control process or process fugitive
sources subject to the lead emission
standards in § 63.1543 are exempt from
the requirement in paragraph (c)(8) of
this section to be equipped with a bag
leak detector. The owner or operator of
an affected source that uses a HEPA
filter must monitor and record the
pressure drop across the HEPA filter
system daily. If the pressure drop is
outside the limit(s) specified by the
filter manufacturer, the owner or
operator must take appropriate
corrective measures, which may
include, but not be limited to, the
following:
(1) Inspecting the filter and filter
housing for air leaks and torn or broken
filters.
(2) Replacing defective filter media, or
otherwise repairing the control device.
(3) Sealing off a defective control
device by routing air to other
comparable control devices.
(4) Shutting down the process
producing the particulate emissions.
(i) Owners and operators must
monitor sinter machine building in-draft
to demonstrate continued compliance
with the operating standard specified in
§ 63.1543(d) in accordance with either
paragraph (i)(1), (i)(2), or (i)(3) of this
section.
(1) Owners and operators must check
and record on a daily basis doorway indraft at each doorway in accordance
with the methodology specified in
§ 63.1546(b).
(2) Owners and operators must
establish and maintain baseline
ventilation parameters which result in a
positive in-draft according to paragraphs
(i)(2)(i) through (i)(2)(iv) of this section.
(i) Owners and operators must install,
calibrate, maintain, and operate a
monitoring device that continuously
records the volumetric flow rate through
each separately ducted hood; or install,
calibrate, maintain, and operate a
monitoring device that continuously
records the volumetric flow rate at the
control device inlet of each exhaust
system ventilating the building. The
flow rate monitoring device(s) can be
installed in any location in the exhaust
duct such that reproducible flow rate
measurements will result. The flow rate
monitoring device(s) must have an
accuracy of plus or minus 10 percent
over the normal process operating range
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9443
and must be calibrated according to
manufacturer’s instructions.
(ii) During the initial demonstration of
sinter building in-draft, and at any time
the owner or operator wishes to reestablish the baseline ventilation
parameters, the owner or operator must
continuously record the volumetric flow
rate through each separately ducted
hood, or continuously record the
volumetric flow rate at the control
device inlet of each exhaust system
ventilating the building and record
exhaust system damper positions. The
owner or operator must determine the
average volumetric flow rate(s)
corresponding to the period of time the
in-draft compliance determinations are
being conducted.
(iii) The owner or operator must
maintain the volumetric flow rate(s) at
or above the value(s) established during
the most recent in-draft determination at
all times the sinter machine is in
operation. Volumetric flow rate(s) must
be calculated as a 15-minute average.
(iv) If the volumetric flow rate is
monitored at the control device inlet,
the owner or operator must check and
record damper positions daily to ensure
they are in the positions they were in
during the most recent in-draft
determination.
(3) An owner or operator may request
an alternative monitoring method by
following the procedures and
requirements in § 63.8(f) of the General
Provisions.
(j) Each owner or operator of new or
modified sources listed under § 63.1543
(a)(1) through (a)(10) must install,
calibrate, maintain, and operate a
continuous emission monitoring system
(CEMS) for measuring lead emissions
and a continuous emission rate
monitoring system (CERMS) subject to
Performance Specification 6 of
Appendix B to part 60.
(1) Each owner or operator of a source
subject to the emissions limits for lead
compounds under § 63.1543(a) and (b)
must install a CEMS for measuring lead
emissions within 180 days of
promulgation of performance
specifications for lead CEMS.
(i) Prior to promulgation of
performance specifications for CEMS
used to measure lead concentrations, an
owner or operator must use the
procedure described in § 63.1546(a)(1)
through (a)(7) of this section to
determine compliance.
(ii) [Reserved]
(2) If a CEMS used to measure lead
emissions is applicable, the owner or
operator must install a CERMS with a
sensor in a location that provides
representative measurement of the
exhaust gas flow rate at the sampling
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location of the CEMS used to measure
lead emissions, taking into account the
manufacturer’s recommendations. The
flow rate sensor is that portion of the
system that senses the volumetric flow
rate and generates an output
proportional to that flow rate.
(i) The CERMS must be designed to
measure the exhaust gas flow rate over
a range that extends from a value of at
least 20 percent less than the lowest
expected exhaust flow rate to a value of
at least 20 percent greater than the
highest expected exhaust gas flow rate.
(ii) The CERMS must be equipped
with a data acquisition and recording
system that is capable of recording
values over the entire range specified in
paragraph (b)(2)(i) of this section.
(iii) Each owner or operator must
perform an initial relative accuracy test
of the CERMS in accordance with the
applicable Performance Specification in
Appendix B to part 60 of the chapter.
(iv) Each owner or operator must
operate the CERMS and record data
during all periods of operation of the
affected facility including periods of
startup, shutdown, and malfunction,
except for periods of monitoring system
malfunctions, repairs associated with
monitoring system malfunctions, and
required monitoring system quality
assurance or quality control activities
(including, as applicable, calibration
checks and required zero and span
adjustments.
(3) Each owner or operator must
calculate the lead emissions rate in tons
per year by summing all hours of CEMS
data for a year to determine compliance
with 63.1543(b).
(i) When the CERMS are unable to
provide quality assured data the
following applies:
(A) When data are not available for
periods of up to 48 hours, the highest
recorded hourly emission rate from the
previous 24 hours must be used.
(B) When data are not available for 48
or more hours, the maximum daily
emission rate based on the previous 30
days must be used.
(ii) [Reserved]
(k) The owner or operator of each
source subject to § 63.1544(a) must
operate a continuous monitoring system
for the measurement of lead compound
concentrations in air.
(1) The owner or operator must
operate compliance monitors sufficient
in number, location, and frequency of
sample collection to detect expected
maximum concentrations of lead
compounds in air due to emissions from
the affected source(s) in accordance
with a written plan as described in
(k)(2) of this paragraph and approved by
the Administrator. The plan must
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include descriptions of the sampling
and analytical methods used. The plan
may take into consideration existing
monitoring being conducted under a
state monitoring plan in accordance
with part 58 of this chapter.
(2) The owner or operator must
submit a written plan describing and
explaining the basis for the design and
adequacy of the compliance monitoring
network, the sampling, analytical, and
quality assurance procedures, and any
other related procedures, and the
justification for any seasonal,
background, or other data adjustments
within 45 days after the effective date of
this subpart.
(3) The Administrator at any time may
require changes in, or expansion of, the
monitoring program, including
additional sampling and analytical
protocols and network design.
(l) If all rolling three-month average
concentrations of lead in air measured
by the compliance monitoring system
are less than 50 percent of the lead
concentration in air limit in § 63.1544(a)
for three consecutive years, the owner or
operator may submit a revised plan to
reduce the monitoring sampling and
analysis frequency (e.g., from daily to
weekly). For any subsequent period, if
any rolling three-month average lead
concentration in air measured at any
monitor in the monitoring system
exceeds 50 percent of the concentration
limit in § 63.1544(a), the owner or
operator must resume monitoring
pursuant to paragraph (k)(1) of this
section at all monitors until another
three consecutive years of lead
concentration in air measurements less
than 50 percent of the lead
concentration in air limit is
demonstrated.
9. Section 63.1548 is revised to read
as follows:
§ 63.1548
Notification requirements.
(a) The owner or operator of a primary
lead processor must comply with the
notification requirements of § 63.9 of
subpart A, General Provisions as
specified in Table 1 of this subpart.
(b) The owner or operator of a primary
lead processor must submit the standard
operating procedures manual for
baghouses required under § 63.1547(a)
to the Administrator or delegated
authority along with a notification that
the primary lead processor is seeking
review and approval of the manual and
procedures. Owners or operators of
existing primary lead processors must
submit this notification no later than
November 6, 2000. The owner or
operator of a primary lead processor that
commences construction or
reconstruction after April 17, 1998,
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must submit this notification no later
than 180 days before startup of the
constructed or reconstructed primary
lead processor, but no sooner than
September 2, 1999.
(c) The owner or operator of a primary
lead processor must submit the
compliance monitoring network plan
required under § 63.1547(k)(2) to the
Administrator or delegated authority
along with a notification that the
primary lead processor is seeking
review and approval of the plan.
Owners or operators of existing primary
lead processors must submit this
notification no later than 45 days after
promulgation of this subpart. The owner
or operator of a new, reconstructed, or
modified primary lead processor must
submit this notification no later than
180 days before startup of the
constructed or reconstructed primary
lead processor.
10. Section 63.1549 is revised to read
as follows:
§ 63.1549 Recordkeeping and reporting
requirements.
(a) The owner or operator of a primary
lead processor must comply with the
recordkeeping requirements of § 63.10
of subpart A, General Provisions as
specified in Table 1 of this subpart.
(b) In addition to the general records
required by paragraph (a) of this section,
each owner or operator of a primary
lead processor must maintain for a
period of 5 years, records of the
information listed in paragraphs (b)(1)
through (b)(10) of this section.
(1) Production records of the weight
and lead content of lead products,
copper matte, and copper speiss.
(2) Records of the bag leak detection
system output.
(3) An identification of the date and
time of all bag leak detection system
alarms, the time that procedures to
determine the cause of the alarm were
initiated, the cause of the alarm, an
explanation of the actions taken, and the
date and time the cause of the alarm was
corrected.
(4) Any recordkeeping required as
part of the requirements described in
the compliance monitoring system plan
required under § 63.1547(k)(2).
(5) Any recordkeeping required as
part of the practices described in the
standard operating procedures manual
for baghouses required under
§ 63.1547(a).
(6) If an owner or operator chooses to
demonstrate continuous compliance
with the sinter building in-draft
requirement under § 63.1543(d) by
employing the method allowed in
§ 63.1547(i)(1), the records of the daily
doorway in-draft checks, an
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identification of the periods when there
was not a positive in-draft, and an
explanation of the corrective actions
taken.
(7) If an owner or operator chooses to
demonstrate continuous compliance
with the sinter building in-draft
requirement under § 63.1543(d) by
employing the method allowed in
§ 63.1547(i)(2), the records of the output
from the continuous volumetric flow
monitor(s), an identification of the
periods when the 15-minute volumetric
flow rate dropped below the minimum
established during the most recent indraft determination, and an explanation
of the corrective actions taken.
(8) If an owner or operator chooses to
demonstrate continuous compliance
with the sinter building in-draft
requirement under § 63.1543(d) by
employing the method allowed in
§ 63.1547(i)(2), and volumetric flow rate
is monitored at the baghouse inlet,
records of the daily checks of damper
positions, an identification of the days
that the damper positions were not in
the positions established during the
most recent in-draft determination, and
an explanation of the corrective actions
taken.
(9) Records of the occurrence and
duration of each malfunction of
operation (i.e., process equipment) or
the air pollution control equipment and
monitoring equipment.
(10) Records of actions taken during
periods of malfunction to minimize
emissions in accordance with
§§ 63.1543(i) and 63.1544(e), including
corrective actions to restore
malfunctioning process and air
pollution control and monitoring
equipment to its normal or usual
manner of operation.
(c) Records for the most recent 2 years
of operation must be maintained on site.
Records for the previous 3 years may be
maintained off site.
(d) The owner or operator of a
primary lead processor must comply
with the reporting requirements of
§ 63.10 of subpart A, General Provisions
as specified in Table 1 of this subpart.
(e) In addition to the information
required under § 63.10 of the General
Provisions, the owner or operator must
provide semi-annual reports containing
the information specified in paragraphs
(e)(1) through (e)(9) of this section to the
Administrator or designated authority.
(1) The reports must include records
of all alarms from the bag leak detection
system specified in § 63.1547(e).
(2) The reports must include a
description of the actions taken
following each bag leak detection
system alarm pursuant to § 63.1547(f).
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(3) The reports must include a
calculation of the percentage of time the
alarm on the bag leak detection system
sounded during the reporting period
pursuant to § 63.1547(g).
(4) If an owner or operator chooses to
demonstrate continuous compliance
with the sinter building in-draft
requirement under § 63.1543(d) by
employing the method allowed in
§ 63.1547(i)(1), the reports must contain
an identification of the periods when
there was not a positive in-draft, and an
explanation of the corrective actions
taken.
(5) If an owner or operator chooses to
demonstrate continuous compliance
with the sinter building in-draft
requirement under § 63.1543(d) by
employing the method allowed in
§ 63.1547(i)(2), the reports must contain
an identification of the periods when
the 15-minute volumetric flow rate(s)
dropped below the minimum
established during the most recent indraft determination, and an explanation
of the corrective actions taken.
(6) If an owner or operator chooses to
demonstrate continuous compliance
with the sinter building in-draft
requirement under § 63.1543(d) by
employing the method allowed in
§ 63.1547(i)(2), and volumetric flow rate
is monitored at the baghouse inlet, the
reports must contain an identification of
the days that the damper positions were
not in the positions established during
the most recent in-draft determination,
and an explanation of the corrective
actions taken.
(7) The reports must contain a
summary of the records maintained as
part of the practices described in the
standard operating procedures manual
for baghouses required under
§ 63.1547(a), including an explanation
of the periods when the procedures
were not followed and the corrective
actions taken.
(8) The reports must contain a
summary of the compliance monitoring
results for the required reporting period,
including an explanation of any periods
when the procedures outlined in the
compliance monitoring system plan
required by § 63.1547(k)(2) were not
followed and the corrective actions
taken.
(9) If there was a malfunction during
the reporting period, the report shall
also include the number, duration, and
a brief description for each type of
malfunction which occurred during the
reporting period and which caused or
may have caused any applicable
emission limitation to be exceeded. The
report must also include a description of
actions taken by an owner or operator
during a malfunction of an affected
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9445
source to minimize emissions in
accordance with §§ 63.1543(i) and
63.1544(b), including actions taken to
correct a malfunction.
11. Section 63.1550 is revised to read
as follows:
§ 63.1550
Delegation of authority.
(a) In delegating implementation and
enforcement authority to a State under
section 112(1) of the Act, the authorities
contained in paragraph (b) of this
section must be retained by the
Administrator and not transferred to a
State.
(b) Authorities which will not be
delegated to States: No restrictions.
12. Section 63.1551 is added to read
as follows:
§ 63.1551 Affirmative defense for
exceedance of emission limit during
malfunction.
In response to an action to enforce the
standards set forth in this subpart you
may assert an affirmative defense to a
claim for civil penalties for exceedances
of such standards that are caused by
malfunction, as defined in 40 CFR 63.2.
Appropriate penalties may be assessed,
however, if you fail to meet your burden
of proving all the requirements in the
affirmative defense. The affirmative
defense shall not be available for claims
for injunctive relief.
(a) To establish the affirmative
defense in any action to enforce such a
limit, you must timely meet the
notification requirements in paragraph
(b) of this section, and must prove by a
preponderance of evidence that:
(1) The excess emissions:
(i) Were caused by a sudden, short,
infrequent, and unavoidable failure of
air pollution control and monitoring
equipment, process equipment, or a
process to operate in a normal or usual
manner; and
(ii) Could not have been prevented
through careful planning, proper design
or better operation and maintenance
practices; and
(iii) Did not stem from any activity or
event that could have been foreseen and
avoided, or planned for; and
(iv) Were not part of a recurring
pattern indicative of inadequate design,
operation, or maintenance; and
(2) Repairs were made as
expeditiously as possible when the
applicable emission limitations were
being exceeded. Off-shift and overtime
labor were used, to the extent
practicable to make these repairs; and
(3) The frequency, amount and
duration of the excess emissions
(including any bypass) were minimized
to the maximum extent practicable
during periods of such emissions; and
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(4) If the excess emissions resulted
from a bypass of control equipment or
a process, then the bypass was
unavoidable to prevent loss of life,
severe personal injury, or severe
property damage; and
(5) All possible steps were taken to
minimize the impact of the excess
emissions on ambient air quality, the
environment and human health; and
(6) All emissions monitoring and
control systems were kept in operation
if at all possible; and
(7) All of the actions in response to
the excess emissions were documented
by properly signed, contemporaneous
operating logs; and
(8) At all times, the facility was
operated in a manner consistent with
good practices for minimizing
emissions; and
(9) A written root cause analysis has
been prepared to determine, correct and
eliminate the primary causes of the
malfunction and the excess emissions
resulting from the malfunction event at
issue. The analysis shall also specify,
using best monitoring methods and
engineering judgment, the amount of
excess emissions that were the result of
the malfunction.
(b) Notification. The owner or
operator of the facility experiencing an
exceedance of its emission limit(s)
during a malfunction shall notify the
Administrator by telephone or facsimile
(FAX) transmission as soon as possible,
but no later than two business days after
the initial occurrence of the
malfunction, if it wishes to avail itself
of an affirmative defense to civil
penalties for that malfunction. The
owner or operator seeking to assert an
affirmative defense shall also submit a
written report to the Administrator
within 30 days of the initial occurrence
of the exceedance of the standard in this
subpart to demonstrate, with all
necessary supporting documentation,
that it has met the requirements set forth
in paragraph (a) of this section.
12. Table 1 to Subpart TTT of Part 63
is revised to read as follows:
TABLE 1 TO SUBPART TTT OF PART 63—GENERAL PROVISIONS APPLICABILITY TO SUBPART TTT
Applies to subpart
TTT
§ 63.1 .................................................................................................................................
§ 63.2 .................................................................................................................................
§ 63.3 .................................................................................................................................
§ 63.4 .................................................................................................................................
§ 63.5 .................................................................................................................................
§ 63.6(a), (b), (c) ................................................................................................................
§ 63.6 (d) ...........................................................................................................................
§ 63.6(e)(1)(i) .....................................................................................................................
Yes.
Yes.
Yes.
Yes.
Yes.
Yes.
No ..........................
No ..........................
§ 63.6(e)(1)(ii) ....................................................................................................................
§ 63.6(e)(1)(iii) ...................................................................................................................
§ 63.6(e)(2) ........................................................................................................................
§ 63.6(e)(3) ........................................................................................................................
§ 63.6(f)(1) .........................................................................................................................
§ 63.6(g) .............................................................................................................................
§ 63.6(h) .............................................................................................................................
§ 63.6(i) ..............................................................................................................................
§ 63.6(j) ..............................................................................................................................
§ 63.7(a)–(d) ......................................................................................................................
§ 63.7(e)(1) ........................................................................................................................
§ 63.7(e)(2)–(e)(4) .............................................................................................................
§ 63.7(f), (g), (h) ................................................................................................................
§ 63.8(a)–(b) ......................................................................................................................
§ 63.8(c)(1)(i) .....................................................................................................................
§ 63.8(c)(1)(ii) ....................................................................................................................
§ 63.8(c)(1)(iii) ....................................................................................................................
§ 63.8(c)(2)–(d)(2) ..............................................................................................................
§ 63.8(d)(3) ........................................................................................................................
§ 63.8(e)–(g) ......................................................................................................................
§ 63.9(a), (b), (c), (e), (g), (h)(1) through (3), (h)(5) and (6), (i) and (j) ............................
§ 63.9(f) ..............................................................................................................................
§ 63.9(h)(4) ........................................................................................................................
§ 63.10(b)(2)(i) ...................................................................................................................
§ 63.10(b)(2)(ii) ..................................................................................................................
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Reference
No.
Yes.
No ..........................
No.
No.
Yes.
No ..........................
Yes.
Yes.
Yes.
No ..........................
Yes.
Yes.
Yes.
No.
Yes.
No.
Yes.
Yes, except for last
sentence.
Yes.
Yes.
No.
No ..........................
No.
No ..........................
§ 63.10(b)(2)(iii) .................................................................................................................
§ 63.10(b)(2)(iv)–(b)(2)(v) ..................................................................................................
§ 63.10(b)(2)(vi)–(b)(2)(xiv) ................................................................................................
§ 63.(10)(b)(3) ....................................................................................................................
§ 63.10(c)(1)–(9) ................................................................................................................
§ 63.10(c)(10)–(11) ............................................................................................................
Yes.
No.
Yes.
Yes.
Yes.
No ..........................
§ 63.10(c)(12)–(c)(14) ........................................................................................................
§ 63.10(c)(15) ....................................................................................................................
§ 63.10(d)(1)–(4) ................................................................................................................
Yes.
No.
Yes.
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Explanation
Section reserved.
See
§ 63.1543(i)
and
§ 63.1544(b) for general duty
requirement.
Section reserved.
No opacity limits in rule.
See § 63.1546(c).
Reserved.
See § 63.1549(b)(9) and (10) for
recordkeeping of occurrence
and duration of malfunctions
and recordkeeping of actions
taken during malfunction.
See § 63.1549(b)(9) and (10) for
recordkeeping of malfunctions.
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9447
TABLE 1 TO SUBPART TTT OF PART 63—GENERAL PROVISIONS APPLICABILITY TO SUBPART TTT—Continued
Reference
Applies to subpart
TTT
Explanation
§ 63.10(d)(5) ......................................................................................................................
No ..........................
See § 63.1549(e)(9) for reporting
of malfunctions.
§ 63.10(e)–((f) ....................................................................................................................
§ 63.11 ...............................................................................................................................
Yes.
No ..........................
§ 63.12 through 63.15 .......................................................................................................
Yes.
Flares will not be used to comply
with the emission limits.
[FR Doc. 2011–2866 Filed 2–16–11; 8:45 am]
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]]>Agencies
[Federal Register Volume 76, Number 33 (Thursday, February 17, 2011)]
[Proposed Rules]
[Pages 9410-9447]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 2011-2866]
[[Page 9409]]
Vol. 76
Thursday,
No. 33
February 17, 2011
Part II
Environmental Protection Agency
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40 CFR Part 63
National Emission Standards for Hazardous Air Pollutants: Primary Lead
Smelting; Proposed Rule
��Federal Register / Vol. 76, No. 33 / Thursday, February 17, 2011 /
Proposed Rules��
[[Page 9410]]
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ENVIRONMENTAL PROTECTION AGENCY
40 CFR Part 63
[EPA-HQ-OAR-2004-0305; FRL-9263-2]
RIN 2060-AQ43
National Emission Standards for Hazardous Air Pollutants: Primary
Lead Smelting
AGENCY: Environmental Protection Agency (EPA).
ACTION: Proposed rule.
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SUMMARY: EPA is proposing amendments to the national emission standards
for hazardous air pollutants (NESHAP) for Primary Lead Smelting to
address the results of the residual risk and technology reviews
conducted as required under sections 112(d)(6) and (f)(2) of the Clean
Air Act (CAA). These proposed amendments include revisions to the
emission limits for lead, the addition of a lead concentration in air
standard, and the modification and addition of testing and monitoring
and related notification, recordkeeping, and reporting requirements. We
are also proposing to revise provisions addressing periods of startup,
shutdown, and malfunction to ensure that they are consistent with a
recent court decision. Finally, we are proposing revisions to the
rule's applicability provision to make it consistent with the
definition of the source category and proposing other minor technical
changes to the standard. We are also responding to a petition for
rulemaking filed on the standard with regard to lead as a surrogate and
regulation of volatile organic compounds (VOC) and acid gases.
DATES: Comments must be received on or before April 4, 2011. Under the
Paperwork Reduction Act, comments on the information collection
provisions are best assured of having full effect if the Office of
Management and Budget (OMB) receives a copy of your comments on or
before March 21, 2011.
Public Hearing. If anyone contacts EPA requesting to speak at a
public hearing by February 28, 2011, a public hearing will be held on
March 4, 2011.
ADDRESSES: Submit your comments, identified by Docket ID Number EPA-HQ-
OAR-2004-0305, by one of the following methods:
https://www.regulations.gov: Follow the on-line
instructions for submitting comments.
E-mail: a-and-r-docket@epa.gov, Attention Docket ID Number
EPA-HQ-OAR-2004-0305.
Fax: (202) 566-9744, Attention Docket ID Number EPA-HQ-
OAR-2004-0305.
Mail: U.S. Postal Service, send comments to: EPA Docket
Center, EPA West (Air Docket), Attention Docket ID Number EPA-HQ-OAR-
2004-0305, U.S. Environmental Protection Agency, Mailcode: 2822T, 1200
Pennsylvania Ave., NW., Washington, DC 20460. Please include a total of
two copies. In addition, please mail a copy of your comments on the
information collection provisions to the Office of Information and
Regulatory Affairs, Office of Management and Budget (OMB), Attn: Desk
Officer for EPA, 725 17th Street, NW., Washington, DC 20503.
Hand Delivery: U.S. Environmental Protection Agency, EPA
West (Air Docket), Room 3334, 1301 Constitution Ave., NW., Washington,
DC 20004, Attention Docket ID Number EPA-HQ-OAR-2004-0305. Such
deliveries are only accepted during the Docket's normal hours of
operation, and special arrangements should be made for deliveries of
boxed information.
Instructions. Direct your comments to Docket ID Number EPA-HQ-OAR-
2004-0305. EPA's policy is that all comments received will be included
in the public docket without change and may be made available on-line
at https://www.regulations.gov, including any personal information
provided, unless the comment includes information claimed to be
confidential business information (CBI) or other information whose
disclosure is restricted by statute. Do not submit information that you
consider to be CBI or otherwise protected through https://www.regulations.gov or e-mail. The https://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 https://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. For additional information about EPA's public
docket, visit the EPA Docket Center homepage at https://www.epa.gov/epahome/dockets.htm.
Docket. The EPA has established a docket for this rulemaking under
Docket ID Number EPA-HQ-OAR-2004-0305. All documents in the docket are
listed in the https://www.regulations.gov index. Although listed in the
index, some information is not publicly available, e.g., CBI or other
information whose disclosure is restricted by statute. Certain other
material, such as copyrighted material, is not placed on the Internet
and will be publicly available only in hard copy. Publicly available
docket materials are available either electronically in https://www.regulations.gov or in hard copy at the EPA Docket Center, EPA West,
Room 3334, 1301 Constitution Ave., NW., Washington, DC. The Public
Reading Room is open from 8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays. The telephone number for the Public
Reading Room is (202) 566-1744, and the telephone number for the EPA
Docket Center is (202) 566-1742.
Public Hearing. If a public hearing is held, it will begin at 10
a.m. on March 4, 2011 and will be held at EPA's campus in Research
Triangle Park, North Carolina, or at an alternate facility nearby.
Persons interested in presenting oral testimony or inquiring as to
whether a public hearing is to be held should contact Ms. Virginia
Hunt, Office of Air Quality Planning and Standards, Sector Policies and
Programs Division, Metals and Minerals Group (D243-02), U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina
27711; telephone number: (919) 541-0832.
FOR FURTHER INFORMATION CONTACT: For questions about this proposed
action, contact Ms. Sharon Nizich, Sector Policies and Programs
Division (D243-02), Office of Air Quality Planning and Standards, U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina
27711, telephone (919) 541-2825; fax number: (919) 541-5450; and e-mail
address: nizich.sharon@epa.gov. For specific information regarding the
risk modeling methodology, contact Ms. Elaine Manning, Health and
Environmental Impacts Division (C539-02), Office of Air Quality
Planning and Standards, U.S. Environmental Protection Agency, Research
Triangle Park, North Carolina 27711; telephone number: (919) 541-5499;
fax number: (919) 541-0840; and e-mail address: manning.elaine@epa.gov.
For information about the applicability of
[[Page 9411]]
the NESHAP to a particular entity, contact the appropriate person
listed in Table 1 to this preamble.
SUPPLEMENTARY INFORMATION:
Table 1--List of EPA Contacts For the NESHAP Addressed in This Proposed Action
----------------------------------------------------------------------------------------------------------------
NESHAP for: OECA contact \1\ OAQPS contact \2\
----------------------------------------------------------------------------------------------------------------
Primary Lead Smelting..................... Maria Malave, (202) 564-7027, Sharon Nizich, (919) 541-2825,
malave.maria@epa.gov. nizich.sharon@epa.gov.
----------------------------------------------------------------------------------------------------------------
\1\ EPA's Office of Enforcement and Compliance Assurance.
\2\ EPA's Office of Air Quality Planning and Standards.
I. Preamble Acronyms and Abbreviations
Several acronyms and terms used to describe industrial processes,
data inventories, and risk modeling are included in this preamble.
While this may not be an exhaustive list, to ease the reading of this
preamble and for reference purposes, the following terms and acronyms
are defined here:
ADAF Age-dependent Adjustment Factors
AERMOD Air dispersion model used by the HEM-3 model
AEGL Acute Exposure Guideline Levels
ANPRM Advance Notice of Proposed Rulemaking
BACT Best Available Control Technology
CAA Clean Air Act
CBI Confidential Business Information
CEEL Community Emergency Exposure Levels
CEMS Continuous Emissions Monitoring System
CERMS Continuous Emission Rate Monitoring System
CFR Code of Federal Regulations
EJ Environmental Justice
EPA Environmental Protection Agency
ERPG Emergency Response Planning Guidelines
HAP Hazardous Air Pollutants
HI Hazard Index
HEM-3 Human Exposure Model version 3
HON Hazardous Organic National Emissions Standards for Hazardous Air
Pollutants
HQ Hazard Quotient
IRIS Integrated Risk Information System
Km Kilometer
LAER Lowest Achievable Emission Rate
LOAEL Lowest Observed Adverse Effect Level
MACT Maximum Achievable Control Technology
MACT Code Code within the NEI used to identify processes included in
a source category
MIR Maximum Individual Risk
NAAQS National Ambient Air Quality Standard
NAC/AEGL Committee National Advisory Committee for Acute Exposure
Guideline Levels for Hazardous Substances
NAICS North American Industry Classification System
NAS National Academy of Sciences
NATA National Air Toxics Assessment
NESHAP National Emissions Standards for Hazardous Air Pollutants
NEI National Emissions Inventory
NOAEL No Observed Adverse Effects Level
NRC National Research Council
NTTAA National Technology Transfer and Advancement Act
OAQPS EPA's Office of Air Quality Planning and Standards
OECA EPA's Office of Enforcement and Compliance Assurance
OMB Office of Management and Budget
PB-HAP Hazardous air pollutants known to be persistent and bio-
accumulative in the environment
POM Polycyclic Organic Matter
RACT Reasonably Available Control Technology
RBLC RACT/BACT/LAER Clearinghouse
RFA Regulatory Flexibility Act
RfC Reference Concentration
RfD Reference Dose
RTR Residual Risk and Technology Review
SAB Science Advisory Board
SBA Small Business Administration
SCC Source Classification Codes
SF3 2000 Census of Population and Housing Summary File 3
SIP State Implementation Plan
SOP Standard Operating Procedures
SSM Startup, Shutdown, and Malfunction
TOSHI Target Organ-Specific Hazard Index
TPY Tons Per Year
TRIM Total Risk Integrated Modeling System
TTN Technology Transfer Network
UF Uncertainty Factor
UMRA Unfunded Mandates Reform Act
URE Unit Risk Estimate
VOC Volatile Organic Compounds
VOHAP Volatile Organic Hazardous Air Pollutants
WWW Worldwide Web
Organization of this Document. The following outline is provided to
aid in the location of information in this preamble.
I. Preamble Acronyms and Abbreviations
II. General Information
A. Does this action apply to me?
B. Where can I get a copy of this document and other related
information?
C. What should I consider as I prepare my comments for EPA?
III. Background
A. What is the statutory authority for this action?
B. How did we consider the risk results in making decisions for
this proposal?
C. What other actions are we addressing in this proposal?
IV. Analyses Performed and Background for the Source Category and
MACT Standard
A. How did we estimate risks posed by the source category?
B. How did we perform the technology review?
C. Overview of the source category and MACT standards
V. Analyses Results and Proposed Decisions
A. What data were used in our risk analyses?
B. What are the results of the risk assessments and analyses?
C. What are our proposed decisions on risk acceptability and
ample margin of safety?
D. What are the results and proposed decisions from the
technology review?
E. Variability
F. What other actions are we proposing?
VI. Proposed Action
A. What actions are we proposing as a result of the residual
risk reviews?
B. What actions are we proposing as a result of the technology
reviews?
C. What other actions are we proposing?
D. Compliance Dates
VII. Request for Comments
VIII.Submitting Data Corrections
IX. 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 Risks and Safety Risks
H. Executive Order 13211: Actions Concerning Regulations That
Significantly Affect Energy Supply, Distribution, or Use
I. National Technology Transfer and Advancement Act
J. Executive Order 12898: Federal Actions To Address
Environmental Justice in Minority Populations and Low-Income
Populations
II. General Information
A. Does this action apply to me?
The regulated industrial source category that is the subject of
this proposal is listed in Table 2 to this preamble. Table 2 is not
intended to be exhaustive, but rather provides a guide for readers
regarding entities likely to be affected by this proposed action for
the source categories listed. This standard, and any changes considered
in this rulemaking, would be directly
[[Page 9412]]
applicable to sources as a Federal program. Thus, Federal, State,
local, and tribal government entities are not affected by this proposed
action. As defined in the source category listing report published by
EPA in 1992, the Primary Lead Smelting source category is defined as
any facility engaged in producing lead metal from ore concentrates;
including, but not limited to, the following smelting processes:
sintering, reduction, preliminary treatment, and refining
operations.\1\ As discussed in section III. (C)(3), to be consistent
with the 1992 listing, EPA is proposing to change the applicability of
the Primary Lead Smelting NESHAP to apply to any facility that produces
lead metal from lead ore concentrates. Although the source category
name in the 1992 listing will remain Primary Lead Smelting (as in 1992
listing) we are proposing to change the title of the rule to refer to
Primary Lead Processing. For clarification purposes, all references to
lead emissions in this preamble means ``lead compounds'' (which is a
HAP) and all reference to lead production means elemental lead (which
is not a HAP) as provided under CAA 112(b)(7)).
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\1\ USEPA. Documentation for Developing the Initial Source
Category List--Final Report, USEPA/OAQPS, EPA-450/3-91-030, July,
1992.
Table 2--Neshap and Industrial Source Categories Affected by This Proposed Action
----------------------------------------------------------------------------------------------------------------
Source category NESHAP NAICS code \1\ MACT code \2\
----------------------------------------------------------------------------------------------------------------
Primary Lead Smelting...................... Primary Lead Processing............ 331419 0204
----------------------------------------------------------------------------------------------------------------
\1\ North American Industry Classification System.
\2\ Maximum Achievable Control Technology.
B. Where can I get a copy of this document and other related
information?
In addition to being available in the docket, an electronic copy of
this proposal will also be available on the World Wide Web (WWW)
through the Technology Transfer Network (TTN). Following signature by
the EPA Administrator, a copy of this proposed action will be posted on
the TTN's policy and guidance page for newly proposed or promulgated
rules at the following address: https://www.epa.gov/ttn/atw/rrisk/rtrpg.html. The TTN provides information and technology exchange in
various areas of air pollution control.
Additional information is available on the residual risk and
technology review (RTR) Web page at https://www.epa.gov/ttn/atw/rrisk/rtrpg.html. This information includes source category descriptions and
detailed emissions and other data that were used as inputs to the risk
assessments.
C. What should I consider as I prepare my comments for EPA?
Submitting CBI. Do not submit information containing CBI to EPA
through https://www.regulations.gov or e-mail. Clearly mark the part or
all of the information that you claim to be CBI. For CBI information on
a disk or CD ROM that you mail to EPA, mark the outside of the disk or
CD ROM as CBI and then identify electronically within the disk or CD
ROM the specific information that is claimed as CBI. In addition to one
complete version of the comment that includes information claimed as
CBI, a copy of the comment that does not contain the information
claimed as CBI must be submitted for inclusion in the public docket. If
you submit a CD ROM or disk that does not contain CBI, mark the outside
of the disk or CD ROM clearly that it does not contain CBI. Information
not marked as CBI will be included in the public docket and EPA's
electronic public docket without prior notice. Information marked as
CBI will not be disclosed except in accordance with procedures set
forth in 40 CFR part 2. Send or deliver information identified as CBI
only to the following address: Roberto Morales, OAQPS Document Control
Officer (C404-02), Office of Air Quality Planning and Standards, U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina
27711, Attention Docket ID Number EPA-HQ-OAR-2004-0305.
III. Background
A. What is the statutory authority for this action?
Section 112 of the Clean Air Act (CAA) establishes a two-stage
regulatory process to address emissions of hazardous air pollutants
(HAP) from stationary sources. In the first stage, after EPA has
identified categories of sources emitting one or more of the HAP listed
in section 112(b) of the CAA, section 112(d) of the CAA calls for us to
promulgate NESHAP for those sources. ``Major sources'' are those that
emit or have the potential to emit 10 tons per year (TPY) or more of a
single HAP or 25 TPY or more of any combination of HAP. For major
sources, these technology-based standards must reflect the maximum
degree of emission reductions of HAP achievable (after considering
cost, energy requirements, and non-air quality health and environmental
impacts) and are commonly referred to as maximum achievable control
technology (MACT) standards.
MACT standards must require the maximum degree of emission
reduction through the application of measures, processes, methods,
systems, or techniques, including, but not limited to, measures which
(A) Reduce the volume of or eliminate pollutants through process
changes, substitution of materials or other modifications; (B) enclose
systems or processes to eliminate emissions; (C) capture or treat
pollutants when released from a process, stack, storage, or fugitive
emissions point; (D) are design, equipment, work practice, or
operational standards (including requirements for operator training or
certification); or (E) are a combination of the above. CAA section
112(d)(2)(A)-(E). The MACT standards may take the form of design,
equipment, work practice, or operational standards where EPA first
determines either that, (A) a pollutant cannot be emitted through a
conveyance designed and constructed to emit or capture the pollutants,
or that any requirement for, or use of, such a conveyance would be
inconsistent with law; or (B) the application of measurement
methodology to a particular class of sources is not practicable due to
technological and economic limitations. CAA sections 112(h)(1)-(2).
The MACT ``floor'' is the minimum control level allowed for MACT
standards promulgated under CAA section 112(d)(3) and may not be based
on cost considerations. For new sources, the MACT floor cannot be less
stringent than the emission control that is achieved in practice by the
best-
[[Page 9413]]
controlled similar source. The MACT floors for existing sources can be
less stringent than floors for new sources, but they cannot be less
stringent than the average emissions limitation achieved by the best-
performing 12 percent of existing sources in the category or
subcategory (or the best-performing 5 sources for categories or
subcategories with fewer than 30 sources). In developing MACT
standards, we must also consider control options that are more
stringent than the floor. We may establish standards more stringent
than the floor based on the consideration of the cost of achieving the
emissions reductions, any non-air quality health and environmental
impacts, and energy requirements.
The EPA is then required to review these technology-based standards
and to revise them ``as necessary (taking into account developments in
practices, processes, and control technologies)'' no less frequently
than every 8 years, under CAA section 112(d)(6). In conducting this
review, EPA is not obliged to completely recalculate the prior MACT
determination. NRDC v. EPA, 529 F.3d 1077, 1084 (D.C. Cir., 2008).
The second stage in standard-setting focuses on reducing any
remaining ``residual'' risk according to CAA section 112(f). This
provision requires, first, that EPA prepare a Report to Congress
discussing (among other things) methods of calculating the risks posed
(or potentially posed) by sources after implementation of the MACT
standards, the public health significance of those risks, and the
recommendations regarding legislation of such remaining risk. EPA
prepared and submitted this report (Residual Risk Report to Congress,
EPA-453/R-99-001) in March 1999. Congress did not act in response to
the report, thereby triggering EPA's obligation under CAA section
112(f)(2) to analyze and address residual risk.
Section 112(f)(2) of the CAA requires us to determine for source
categories subject to certain MACT standards, whether the emissions
standards provide an ample margin of safety to protect public health.
If the MACT standards that apply to a source category emitting a HAP
that is ``classified as a known, probable, or possible human carcinogen
do not reduce lifetime excess cancer risks to the individual most
exposed to emissions from a source in the category or subcategory to
less than one-in-one million,'' EPA must promulgate residual risk
standards for the source category (or subcategory) as necessary to
provide an ample margin of safety to protect public health. CAA section
112(f)(2)(A). In doing so, EPA may adopt standards equal to existing
MACT standards if EPA determines that the existing standards are
sufficiently protective. As stated in NRDC v. EPA, 529 F.3d 1077, 1083
(D.C. Dir. 2008), ``If EPA determines that the existing technology-
based standards provide an `ample margin of safety,' then the Agency is
free to readopt those standards during the residual risk rulemaking.''
Section 112(f)(2) of the Clean Air Act further states that EPA must
also adopt more stringent standards, if necessary, to ``prevent taking
into consideration costs, energy, safety, and other relevant factors,
an adverse environmental effect.'' \2\
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\2\ ``Adverse environmental effect'' is defined in CAA section
112(a)(7) as any significant and widespread adverse effect, which
may be reasonably anticipated to wildlife, aquatic life, or natural
resources, including adverse impacts on populations of endangered or
threatened species or significant degradation of environmental
qualities over broad areas.
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When Section 112(f)(2) of the CAA was enacted in 1990, it expressly
preserved our use of the two-step process for developing standards to
address any residual risk and our interpretation of ``ample margin of
safety'' developed in the National Emission Standards for Hazardous Air
Pollutants: Benzene Emissions from Maleic Anhydride Plants,
Ethylbenzene/Styrene Plants, Benzene Storage Vessels, Benzene Equipment
Leaks, and Coke By-Product Recovery Plants (Benzene NESHAP) (54 FR
38044, September 14, 1989). The first step in this process is the
determination of acceptable risk. The second step provides for an ample
margin of safety to protect public health, which is the level at which
the standards are set (unless a more stringent standard is required to
prevent, taking into consideration costs, energy, safety, and other
relevant factors, an adverse environmental effect).
The terms ``individual most exposed,'' ``acceptable level,'' and
``ample margin of safety'' are not specifically defined in the CAA.
However, CAA section 112(f)(2)(B) preserves the interpretation set out
in the Benzene NESHAP, and the Court in NRDC v. EPA, concluded that
EPA's interpretation of subsection 112(f)(2) is a reasonable one. See
NRDC v. EPA, 529 F.3d at 1083 (D.C. Cir. 2008), which says
``[S]ubsection 112(f)(2)(B) expressly incorporates EPA's interpretation
of the Clean Air Act from the Benzene standard, complete with a
citation to the Federal Register.'' See also, A Legislative History of
the Clean Air Act Amendments of 1990, volume 1, p. 877 (Senate debate
on Conference Report). We notified Congress in the Residual Risk Report
to Congress that we intended to use the Benzene NESHAP approach in
making CAA section 112(f) residual risk determinations (EPA-453/R-99-
001, p. ES-11).
In the Benzene NESHAP, we stated as an overall objective:
* * * in protecting public health with an ample margin of
safety, we strive to provide maximum feasible protection against
risks to health from hazardous air pollutants by (1) protecting the
greatest number of persons possible to an individual lifetime risk
level no higher than approximately 1-in-1 million; and (2) limiting
to no higher than approximately 1-in-10 thousand [i.e., 100-in-1
million] the estimated risk that a person living near a facility
would have if he or she were exposed to the maximum pollutant
concentrations for 70 years.
The Agency also stated that, ``The EPA also considers incidence
(the number of persons estimated to suffer cancer or other serious
health effects as a result of exposure to a pollutant) to be an
important measure of the health risk to the exposed population.
Incidence measures the extent of health risks to the exposed population
as a whole, by providing an estimate of the occurrence of cancer or
other serious health effects in the exposed population.'' The Agency
went on to conclude that ``estimated incidence would be weighed along
with other health risk information in judging acceptability.'' As
explained more fully in our Residual Risk Report to Congress, EPA does
not define ``rigid line[s] of acceptability,'' but considers rather
broad objectives to be weighed with a series of other health measures
and factors (EPA-453/R-99-001, p. ES-11). The determination of what
represents an ``acceptable'' risk is based on a judgment of ``what
risks are acceptable in the world in which we live'' (Residual Risk
Report to Congress, p. 178, quoting the Vinyl Chloride decision at 824
F.2d 1165) recognizing that our world is not risk-free.
In the Benzene NESHAP, we stated that ``EPA will generally presume
that if the risk to [the maximum exposed] individual is no higher than
approximately 1-in-10 thousand, that risk level is considered
acceptable.'' 54 FR 38045. We discussed the maximum individual lifetime
cancer risk as being ``the estimated risk that a person living near a
plant would have if he or she were exposed to the maximum pollutant
concentrations for 70 years.'' Id. We explained that this measure of
risk ``is an estimate of the upper bound of risk based on conservative
assumptions, such as continuous exposure for 24 hours per day for 70
years.'' Id. We
[[Page 9414]]
acknowledge that maximum individual lifetime cancer risk ``does not
necessarily reflect the true risk, but displays a conservative risk
level which is an upper-bound that is unlikely to be exceeded.'' Id.
Understanding that there are both benefits and limitations to using
maximum individual lifetime cancer risk as a metric for determining
acceptability, we acknowledged in the 1989 Benzene NESHAP that
``consideration of maximum individual risk * * * must take into account
the strengths and weaknesses of this measure of risk.'' Id.
Consequently, the presumptive risk level of 100-in-1 million (1-in-10
thousand) provides a benchmark for judging the acceptability of maximum
individual lifetime cancer risk, but does not constitute a rigid line
for making that determination.
The Agency also explained in the 1989 Benzene NESHAP the following:
``In establishing a presumption for MIR [maximum individual cancer
risk], rather than a rigid line for acceptability, the Agency intends
to weigh it with a series of other health measures and factors. These
include the overall incidence of cancer or other serious health effects
within the exposed population, the numbers of persons exposed within
each individual lifetime risk range and associated incidence within,
typically, a 50-kilometer (km) exposure radius around facilities, the
science policy assumptions and estimation uncertainties associated with
the risk measures, weight of the scientific evidence for human health
effects, other quantified or unquantified health effects, effects due
to co-location of facilities, and co-emission of pollutants.'' Id.
In some cases, these health measures and factors taken together may
provide a more realistic description of the magnitude of risk in the
exposed population than that provided by maximum individual lifetime
cancer risk alone. As explained in the Benzene NESHAP, ``[e]ven though
the risks judged ``acceptable'' by EPA in the first step of the Vinyl
Chloride inquiry are already low, the second step of the inquiry,
determining an ``ample margin of safety,'' again includes consideration
of all of the health factors, and whether to reduce the risks even
further.'' In the ample margin of safety decision process, the Agency
again considers all of the health risks and other health information
considered in the first step. Beyond that information, additional
factors relating to the appropriate level of control will also be
considered, including costs and economic impacts of controls,
technological feasibility, uncertainties, and any other relevant
factors. Considering all of these factors, the Agency will establish
the standard at a level that provides an ample margin of safety to
protect the public health, as required by CAA section 112(f). 54 FR
38046.
B. How did we consider the risk results in making decisions for this
proposal?
As discussed in section III.A of this preamble, we apply a two-step
process for developing standards to address residual risk. In the first
step, EPA determines if risks are acceptable. This determination
``considers all health information, including risk estimation
uncertainty, and includes a presumptive limit on maximum individual
lifetime [cancer] risk (MIR) \3\ of approximately 1-in-10 thousand
[i.e., 100-in-1 million].'' 54 FR 38045. In the second step of the
process, EPA sets the standard at a level that provides an ample margin
of safety ``in consideration of all health information, including the
number of persons at risk levels higher than approximately 1-in-1
million, as well as other relevant factors, including costs and
economic impacts, technological feasibility, and other factors relevant
to each particular decision.'' Id.
---------------------------------------------------------------------------
\3\ Although defined as ``maximum individual risk,'' MIR refers
only to cancer risk. MIR, one metric for assessing cancer risk, is
the estimated risk were an individual exposed to the maximum level
of a pollutant for a lifetime.
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In past residual risk actions, EPA has presented and considered a
number of human health risk metrics associated with emissions from the
category under review, including: the MIR; the numbers of persons in
various risk ranges; cancer incidence; the maximum non-cancer hazard
index (HI); and the maximum acute non-cancer hazard (72 FR 25138, May
3, 2007; 71 FR 42724, July 27, 2006). In our most recent proposals (75
FR 65068, October 21, 2010 and 75 FR 80220, December 21, 2010), EPA
also presented and considered additional measures of health
information, including: estimates of ``facility-wide'' risks (risks
from all HAP emissions from the facility at which the source category
is located); \4\ demographic analyses (analyses of the distributions of
HAP-related risks across different social, demographic, and economic
groups living near the facilities); and estimates of the risks
associated with the maximum level of emissions which might be allowed
by the current MACT standards (see, e.g., 75 FR 65068, October 21, 2010
and 75 FR 80220, December 21, 2010). EPA also discussed and considered
risk estimation uncertainties. EPA is providing this same type of
information in support of the proposed actions described in this
Federal Register notice.
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\4\ EPA previously provided estimates of total facility risk in
a residual risk proposal for coke oven batteries (69 FR 48338,
August 9, 2004).
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The Agency is considering all available health information to
inform our determinations of risk acceptability and ample margin of
safety under CAA section 112(f). Specifically, as explained in the
Benzene NESHAP, ``the first step judgment on acceptability cannot be
reduced to any single factor'' and thus ``[t]he Administrator believes
that the acceptability of risk under section 112 is best judged on the
basis of a broad set of health risk measures and information.'' 54 FR
at 38046. Similarly, with regard to making the ample margin of safety
determination, as stated in the Benzene NESHAP ``[I]n the ample margin
decision, the Agency again considers all of the health risk and other
health information considered in the first step. Beyond that
information, additional factors relating to the appropriate level of
control will also be considered, including cost and economic impacts of
controls, technological feasibility, uncertainties, and any other
relevant factors.'' Id.
The Agency acknowledges that flexibility is provided by the Benzene
NESHAP regarding what factors EPA might consider in making
determinations and how they might be weighed for each source category.
In responding to comment on our policy under the Benzene NESHAP, EPA
explained that: ``The policy chosen by the Administrator permits
consideration of multiple measures of health risk. Not only can the MIR
figure be considered, but also incidence, the presence of non-cancer
health effects, and the uncertainties of the risk estimates. In this
way, the effect on the most exposed individuals can be reviewed as well
as the impact on the general public. These factors can then be weighed
in each individual case. This approach complies with the Vinyl Chloride
mandate that the Administrator ascertain an acceptable level of risk to
the public by employing [her] expertise to assess available data. It
also complies with the Congressional intent behind the CAA, which did
not exclude the use of any particular measure of public health risk
from the EPA's consideration with respect to CAA section 112
regulations, and, thereby, implicitly permits consideration of any and
all measures of health risk which the Administrator, in [her] judgment,
believes are appropriate to determining what will `protect the public
health.' '' 54 FR at 38057.
For example, the level of the MIR is only one factor to be weighed
in
[[Page 9415]]
determining acceptability of risks. It is explained in the Benzene
NESHAP that ``an MIR of approximately 1-in-10 thousand should
ordinarily be the upper end of the range of acceptability. As risks
increase above this benchmark, they become presumptively less
acceptable under CAA section 112, and would be weighed with the other
health risk measures and information in making an overall judgment on
acceptability. Or, the Agency may find, in a particular case, that a
risk that includes MIR less than the presumptively acceptable level is
unacceptable in the light of other health risk factors.'' Id. at 38045.
Similarly, with regard to the ample margin of safety analysis, EPA
stated in the Benzene NESHAP that: ``* * * EPA believes the relative
weight of the many factors that can be considered in selecting an ample
margin of safety can only be determined for each specific source
category. This occurs mainly because technological and economic factors
(along with the health-related factors) vary from source category to
source category.'' Id. at 38061.
EPA wishes to point out that certain health information has not
been considered to date in making residual risk determinations. In
assessing risks to populations in the vicinity of the facilities in
each category, we present estimates of risk associated with HAP
emissions from the source category alone (source category risk
estimates) and HAP emissions from the entire facility at which the
covered source category is located (facility-wide risk estimates). We
do not attempt to characterize the risks associated with all HAP
emissions impacting the populations living near the sources in these
categories. That is, at this time, we do not attempt to quantify those
HAP risks that may be associated with mobile source emissions, natural
source emissions, persistent environmental pollution, or atmospheric
transformation in the vicinity of the sources in these categories.
The Agency understands the potential importance of considering an
individual's total exposure to HAP in addition to considering exposure
to HAP emissions from the source category and facility. This is
particularly important when assessing non-cancer risks, where
pollutant-specific exposure levels (e.g., Reference Concentration
(RfC)) are based on the assumption that thresholds exist for adverse
health effects. For example, the Agency recognizes that, although
exposures attributable to emissions from a source category or facility
alone may not indicate the potential for increased risk of adverse non-
cancer health effects in a population, the exposures resulting from
emissions from the facility in combination with emissions from all of
the other sources (e.g., other facilities) to which an individual is
exposed may be sufficient to result in increased risk of adverse non-
cancer health effects. In May 2010, the Science Advisory Board (SAB)
advised us ``* * * that RTR assessments will be most useful to decision
makers and communities if results are presented in the broader context
of aggregate and cumulative risks, including background concentrations
and contributions from other sources in the area.'' \5\
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\5\ EPA's responses to this and all other key recommendations of
the SAB's advisory on RTR risk assessment methodologies (which is
available at: https://yosemite.epa.gov/sab/sabproduct.nsf/
4AB3966E263D943A8525771F00668381/$File/EPA-SAB-10-007-unsigned.pdf)
are outlined in a memo to this rulemaking docket from David Guinnup
entitled, EPA's Actions in Response to the Key Recommendations of
the SAB Review of RTR Risk Assessment Methodologies.
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While we are interested in placing source category and facility-
wide HAP risks in the context of total HAP risks from all sources
combined in the vicinity of each source, we are concerned about the
uncertainties of doing so. At this point, we believe that such
estimates of total HAP risks will have significantly greater associated
uncertainties than for the source category or facility-wide estimates,
and hence compounding the uncertainty in any such comparison. This is
because we have not conducted a detailed technical review of HAP
emissions data for source categories and facilities that have not
previously undergone an RTR review or are not currently undergoing such
review. We are requesting comment on whether and how best to estimate
and evaluate total HAP exposure in our assessments, and, in particular,
on whether and how it might be appropriate to use information from
EPA's National Air Toxics Assessment (NATA) to support such estimates.
We are also seeking comment on how best to consider various types and
scales of risk estimates when making our acceptability and ample margin
of safety determinations under CAA section 112(f). Additionally, we are
seeking comments and recommendations for any other comparative measures
that may be useful in the assessment of the distribution of HAP risks
across potentially affected demographic groups.
C. What other actions are we addressing in this proposal?
1. Startup, Shutdown and Malfunction
This proposed action would amend the provisions of the existing
NESHAP that apply to periods of startup, shutdown, and malfunction
(SSM). The proposed revisions of these provisions result from a Court
decision that vacated portions of two provisions in EPA's ``General
Provisions'' regulation under CAA section 112, governing the emissions
of HAP during periods of SSM. The current Primary Lead Smelting MACT
includes references to the vacated provisions in the General Provisions
rule.
We are proposing to revise the Primary Lead Smelting MACT standard
to require affected sources to comply with the emission limitations at
all times and during periods of SSM. Specifically, we are proposing
several revisions to subpart TTT including revising Table 1 to indicate
that the requirements of the General Provisions pertaining to SSM do
not apply and to revise language in Sec. 63.1547 (g)(1) and (2) to
remove the exemption for bag leak detection alarm time attributable to
SSM from total allowed alarm time. For reasons discussed below, we are
also proposing to promulgate an affirmative defense to civil penalties
for exceedances of emission standards caused by malfunctions, as well
as criteria for establishing the affirmative defense. These changes
would go into effect upon the effective date of promulgation of the
final rule.
The United States Court of Appeals for the District of Columbia
Circuit vacated portions of two provisions in EPA's CAA Section 112
regulations governing the emissions of HAP during periods of SSM.
Sierra Club v. EPA, 551 F.3d 1019 (D.C. Cir. 2008), cert. denied, 130
S. Ct. 1735 (U.S. 2010). Specifically, the Court vacated the SSM
exemptions contained in 40 CFR 63.6(f)(1) and 40 CFR 63.6(h)(1), that
are part of a regulation commonly known as the ``General Provisions
Rule,'' that EPA had promulgated under section 112 of the CAA. When
incorporated into CAA section 112(d) regulations for specific source
categories, these two provisions exempt sources from the requirement to
comply with the otherwise applicable CAA section 112(d) emission
standard during periods of SSM.
We are proposing the elimination of the SSM exemption in this rule.
Consistent with Sierra Club v. EPA, EPA is proposing standards in this
rule that apply at all times. We are also proposing several revisions
to Table 1 (the General Provisions Applicability table). For
[[Page 9416]]
example, we are proposing to eliminate the incorporation of the General
Provisions' requirement that the source develop an SSM plan. We also
are proposing to eliminate or revise certain recordkeeping and
reporting that relate to the SSM exemption. EPA has attempted to ensure
that we have not included in the proposed regulatory language any
provisions that are inappropriate, unnecessary, or redundant in the
absence of the SSM exemption. We are specifically seeking comment on
whether there are any such provisions that we have inadvertently
incorporated or overlooked.
In proposing standards in this rule, EPA has taken into account
startup and shutdown periods and, for the reasons explained below, has
not proposed different standards for those periods. Information on
periods of startup and shutdown in the industry indicate that emissions
during these periods do not increase. Furthermore, all processes are
controlled by either control devices or work practices and these
controls would not typically be affected by an SSM event. Also,
compliance with the standard already requires averaging of emissions
over a three month period, which accounts for the variability of
emissions that may result during periods of startup and shutdown.
Therefore, separate standards for periods of startup and shutdown are
not being proposed.
Periods of startup, normal operations, and shutdown are all
predictable and routine aspects of a source's operations. However, by
contrast, malfunction is defined as a ``sudden, infrequent, and not
reasonably preventable failure of air pollution control and monitoring
equipment, process equipment, or a process to operate in a normal or
useful manner * * *'' (40 CFR 63.2). EPA has determined that
malfunctions should not be viewed as a distinct operating mode and,
therefore, any emissions that occur at such times do not need to be
factored into development of CAA section 112(d) standards, which, once
promulgated, apply at all times. In Mossville Environmental Action Now
v. EPA, 370 F.3d 1232, 1242 (D.C. Cir. 2004), the court upheld as
reasonable standards that had factored in variability of emissions
under all operating conditions. However, nothing in section 112(d) or
in case law requires that EPA anticipate and account for the
innumerable types of potential malfunction events in setting emission
standards. See, Weyerhaeuser v. Costle, 590 F.2d 1011, 1058 (D.C. Cir.
1978)(``In the nature of things, no general limit, individual permit,
or even any upset provision can anticipate all upset situations. After
a certain point, the transgression of regulatory limits caused by
`uncontrollable acts of third parties,' such as strikes, sabotage,
operator intoxication or insanity, and a variety of other
eventualities, must be a matter for the administrative exercise of
case-by-case enforcement discretion, not for specification in advance
by regulation.'').
Further, it is reasonable to interpret section 112(d) as not
requiring EPA to account for malfunctions in setting emission
standards. For example, we note that CAA section 112 uses the concept
of ``best performing'' sources in defining MACT, the level of
stringency that major source standards must meet. Applying the concept
of ``best performing'' to a source that is malfunctioning presents
significant difficulties. The goal of best performing sources is to
operate in such a way as to avoid malfunctions of their units.
Moreover, even if malfunctions were considered a distinct operating
mode, we believe it would be impracticable to take malfunctions into
account in setting CAA section 112(d) standards for Primary Lead
Smelting. As noted above, by definition, malfunctions are sudden and
unexpected events and it would be difficult to set a standard that
takes into account the myriad different types of malfunctions that can
occur across all sources in the category. Moreover, malfunctions can
vary in frequency, degree, and duration, further complicating standard
setting.
In the unlikely event that a source fails to comply with the
applicable CAA section 112(d) standards as a result of a malfunction
event, EPA would determine an appropriate response based on, among
other things, the good faith efforts of the source to minimize
emissions during malfunction periods, including preventative and
corrective actions, as well as root cause analyses to ascertain and
rectify excess emissions. EPA would also consider whether the source's
failure to comply with the CAA section 112(d) standard was, in fact,
``sudden, infrequent, not reasonably preventable'' and was not instead
``caused in part by poor maintenance or careless operation.'' 40 CFR
63.2 (definition of malfunction).
Finally, EPA recognizes that even equipment that is properly
designed and maintained can sometimes fail and that such failure can
sometimes cause or contribute to an exceedance of the relevant emission
standard. (See, e.g., State Implementation Plans: Policy Regarding
Excessive Emissions During Malfunctions, Startup, and Shutdown (Sept.
20, 1999); Policy on Excess Emissions During Startup, Shutdown,
Maintenance, and Malfunctions (Feb. 15, 1983).) EPA is therefore
proposing to add to the final rule an affirmative defense to civil
penalties for exceedances of emission limits that are caused by
malfunctions. See 40 CFR 63.1542 (defining ``affirmative defense'' to
mean, in the context of an enforcement proceeding, a response or
defense put forward by a defendant, regarding which the defendant has
the burden of proof, and the merits of which are independently and
objectively evaluated in a judicial or administrative proceeding). We
also are proposing other regulatory provisions to specify the elements
that are necessary to establish this affirmative defense; the source
must prove by a preponderance of the evidence that it has met all of
the elements set forth in Sec. 63.1551. (See 40 CFR 22.24.) The
criteria ensure that the affirmative defense is available only where
the event that causes an exceedance of the emission limit meets the
narrow definition of malfunction in 40 CFR 63.2 (sudden, infrequent,
not reasonably preventable and not caused by poor maintenance and/or
careless operation). For example, to successfully assert the
affirmative defense, the source must prove by a preponderance of the
evidence that excess emissions ``[w]ere caused by a sudden, short,
infrequent, and unavoidable failure of air pollution control and
monitoring equipment, process equipment, or a process to operate in a
normal or usual manner * * *'' The criteria also are designed to ensure
that steps are taken to correct the malfunction, to minimize emissions
in accordance with Sec. Sec. 63.1543(i) and 63.1544(e) and to prevent
future malfunctions. For example, the source must prove by a
preponderance of the evidence that ``[r]epairs were made as
expeditiously as possible when the applicable emission limitations were
being exceeded * * *'' and that ``[a]ll possible steps were taken to
minimize the impact of the excess emissions on ambient air quality, the
environment and human health * * *.'' In any judicial or administrative
proceeding, the Administrator may challenge the assertion of the
affirmative defense and, if the respondent has not met its burden of
proving all of the requirements in the affirmative defense, appropriate
penalties may be assessed in accordance with section 113 of the Clean
Air Act (see also 40 CFR part 22.77).
Specifically, we are proposing the following changes to the rule.
Added general duty requirements in Sec. Sec. 63.1543 and
63.1544 to replace General Provision requirements that reference
vacated SSM provisions.
[[Page 9417]]
Added replacement language that eliminates the reference
to SSM exemptions applicable to performance tests in Sec. 63.1546.
Added paragraphs in Sec. 63.1549(e) requiring the
reporting of malfunctions as part of the affirmative defense
provisions.
Added paragraphs in Sec. 63.1549(b) requiring the keeping
of certain records during malfunctions as part of the affirmative
defense provisions.
Revised Table 1 to reflect changes in the applicability of
the General Provisions to this subpart resulting from a court vacatur
of certain SSM requirements in the General Provisions.
2. Lead as a Surrogate and Regulation of Volatile Organic Compounds
(VOC) and Acid Gas Emissions
In a January 14, 2009, petition for rulemaking filed by the Natural
Resources Defense Council and Sierra Club, the petitioners claim that
for the Primary Lead Smelting MACT, EPA relied on lead as a surrogate
for all HAP and they claim that it was inappropriate for EPA to do so
in absence of a showing that lead is an appropriate surrogate for all
other HAP (such as mercury, acid gases, and volatile organic compounds
(VOC)). The petitioners asserted that EPA should set standards for
other HAP absent a showing that lead is an appropriate surrogate for
these HAP. They also assert that EPA's PM standard does not reflect the
emission level achieved by the best performing sources and that EPA
must re-open the rule to set floors for PM in accordance with CAA
section 112(d)(3). A copy of the petition is included in the docket.
As part of this rulemaking, EPA is responding to the claims made by
the petitioners regarding the Primary Lead Smelting MACT.
As an initial matter, the petitioners are incorrect in their claim
that EPA considers lead as a surrogate for all HAP. Rather, EPA used
lead as a surrogate only for other metal HAP compounds in establishing
the emissions limit in the current MACT standard for this source
category (63 FR 19206 and 64 FR 30195). EPA determined in the 1999 rule
that lead, a nonvolatile metal HAP, is an appropriate surrogate for
other nonvolatile metal HAP including antimony, arsenic, chromium,
nickel, manganese, and cadmium. In the proposed rule for the Primary
Lead Smelting MACT (63 FR 19206), EPA discussed the use of lead as a
surrogate for metal HAP emissions and explained that strong
correlations exist between emissions of lead and other metal HAP and
that the technologies identified for the control of metal HAP are the
same as those used to control lead emissions. Therefore, EPA expected
that the standards requiring control of lead would achieve similar
control of the other metal HAP emitted from primary lead smelters. No
adverse comments were received regarding EPA's proposed rationale for
relying on lead as a surrogate for other metal HAP emitted by these
sources and EPA adopted that rationale in the final rule promulgating
the Primary Lead Smelting MACT. The petitioners do not have any
substantive basis as to why EPA's rationale is not supported. Nor do
they claim that there is any new information that would support re-
opening this issue. Thus they fail to present a basis for re-opening
this issue.
The petitioners also insist that EPA should have set standards for
VOC and acid gases that are HAP because lead would not be a surrogate
for these pollutants. EPA noted in the original proposal that due to
small amounts of coke fed to the blast furnace, organic HAP (VOC) was
emitted at a rate so low as to be infeasible to reduce. Again, no
adverse comments were received on EPA's proposed conclusions, which
were adopted in the final rule, and the petitioners do not now provide
substantive support for their claim. Nor do they explain why any such
claim could not have been raised during the initial rulemaking. Thus,
they fail to present a basis for re-opening the rule on this issue.
Finally, petitioners claim that the ``PM standard does not reflect
the emission level achieved by the best performing sources.'' This
claim is unclear as there is no PM standard in the Primary Lead
Smelting MACT. The monitoring provisions provide that PM should be
measured in relation to a predetermined PM level as one test for
indicating baghouse performance. However, the PM levels are not
enforceable emission limits, but merely an indication that the baghouse
may not be operating properly. Again, these provisions were clearly
explained in the proposed and final Primary Lead Smelting MACT
rulemakings. Any claims concerning the appropriateness of these
monitoring requirements should have been raised during the initial
rulemaking process. Petitioners do not claim any new grounds for
raising this issue now. Thus, the petition fails to provide a basis for
re-opening the MACT.
3. Modification of the Applicability Provision
EPA is proposing to amend the applicability section to apply to any
facility processing lead ore concentrate to produce lead metal. Under
the current applicability provisions, the affected sources include any
sinter machine, blast furnace, dross furnace, process fugitive source,
and fugitive dust source located at a primary lead smelter and excludes
secondary lead smelters, lead refiners, or lead remelters. Combined
with the current definition for ``primary lead smelter,'' the current
rule effectively only applies to facilities that produce lead metal
from lead sulfide ore concentrates using pyrometallurgical techniques.
While the only processes available for the production of lead from lead
ore concentrate at the time the MACT rule was developed were
pyrometallurgical techniques, that applicability language is narrower
than the primary lead smelting source category description EPA
identified in its source category listing issued pursuant to CAA
section 112(c)(1), Documentation for Developing the Initial Source
Category List (EPA-450/3-91-030, July 1992). In the source category
listing, EPA defined the primary lead smelting source category as
follows: ``The Primary Lead Smelting source category includes any
facility engaged in producing lead metal from ore concentrates. The
category includes, but is not limited to, the following smelting
processes: sintering reduction, preliminary treatment, and refining
operations. The sintering process includes an updraft or downdraft
sintering machine. The reduction process includes the blast furnace,
electric smelting furnace with a converter or reverberatory furnace,
and slag fuming furnace process units. The preliminary treatment
process includes the drossing kettles and dross reverberatory furnace
process units. The refining process includes the refinery process
unit.'' The definition is clear that the primary intent was to cover
sources that produce lead metal from ore concentrates, which would
``include'' the use of a pyrometallurgical process, but would not be
limited to such. As noted previously, at the time we promulgated the
MACT standard, the only method of producing lead metal from ore
concentrates was through use of pyrometallurgical techniques and we
adopted an applicability provision that focused on that process.
However, information provided by the sole operating primary lead
smelting facility indicates that lead production is likely to continue
at the current Doe Run facility, although using a process other than a
pyrometallurgical technique. The new lead facility would continue to
process lead ore concentrate
[[Page 9418]]
in order to produce lead metal. Based on the current applicability
section and definitions, it could be interpreted that the future lead
producing process, using techniques other than pyrometallurgical, would
not be subject to the NESHAP for primary lead smelters. Such a limited
interpretation is not consistent with EPA's intent as evidenced by the
broader definition in the source category list. Therefore, EPA is
proposing to amend the applicability section to specify that the MACT
applies to any lead processing facility that produces lead metal from
lead ore concentrate. Consistent with the proposed revision to the
applicability section, we are proposing to remove the definition of
``primary lead smelter'' and add a definition of ``primary lead
processor'' which means any facility engaged in the production of lead
metal from lead sulfide ore concentrates through the use of
pyrometallurgical or other techniques. In addition, we are proposing to
replace ``primary lead smelter'' with ``primary lead processor''
throughout 40 CFR subpart TTT. (Sec. 63.1541 through Sec. 63.1545,
Sec. 63.1547 through Sec. 63.1549). We are specifically asking for
comment on this proposed change in the definition.
Because there is only one primary lead processing facility in the
U.S., there will be no impact of this change on the number of existing
facilities covered by the MACT.
We note, however, that although we are changing the applicability
section to clarify that the MACT applies to all processes for producing
lead metal from ore concentrates, we are not today proposing a specific
MACT standard that would apply to the as-yet undemonstrated
hydrometallurgical process which Doe Run has indicated that it plans to
build at the current Doe Run facility. If and when that process begins
operation, we will consider whether to revise the MACT standard to
specifically address that process or any other new processes. However,
the limits applicable to specific emission sources currently in
operation as specified in the MACT and as revised under CAA sections
112(d)(6) and (f)(2) in this rulemaking would continue to apply to any
emission source at the facility that continues in operation, such as
the refinery. In addition, to the extent that we establish a final air
lead concentration limit as proposed in Sec. 63.1544, those limits
would also continue to apply to the facility. We also are proposing
that the plant-wide emission limit we are proposing today should
continue to apply to any facility that meets the revised applicability
definition, but we are specifically soliciting comment on whether it
should apply.
We are also taking this opportunity to clarify the reference to
``lead refiners'' in the second sentence of the applicability section,
which provides that the MACT standard does not apply to ``secondary
lead smelters, lead refiners, or lead remelters.'' The intent of this
provision was to make clear that secondary lead smelters would not be
subject to the rule because secondary lead smelters were listed as a
separate source category and addressed in a separate MACT standard.
With regard to lead refiners and lead remelters, the intent was to
provide that these activities, to the extent that they are not located
at facilities that produce lead from lead ore concentrate, would not be
subject to the Primary Lead Smelting MACT. However, it was not the
intention of the rule to exempt kettle refining operations included as
part of a primary lead processing facility. Therefore, EPA is proposing
to add definitions for secondary lead smelters, lead refiners, and lead
remelters in the definitions section of this NESHAP in order to further
clarify the exemption in the applicability provisions with regard to
these types of facilities. As this change only clarifies an existing
provision in the rule, there will be
