Recommendations for the
Utility Air Toxics MACT
Final Working Group Report
October 2002
Working Group for the Utility MACT
Formed Under the Clean Air Act Advisory Committee
Subcommittee for Permits/New Source Reviews/Toxics
Submitted to:
Clean Air Act Advisory Committee
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BACKGROUND
Section 112(n)(l)(A) of the Clean Air Act (CAA) requires that, after considering the results of the study
mandated by the same section, the Administrator determine whether regulation of hazardous air pollutant
(HAP) emissions from electric utility steam generating units was appropriate and necessary. The results
of the study were documented in the Utility Air Toxics Final Report to Congress (RtC), which was
finalized in February 1998 and released to Congress and the public. In the RtC, the U.S. Environmental
Protection Agency (EPA) stated that, for the utility industry, mercury from coal-fired electric utility steam
generating units was the HAP of greatest potential concern for public health. The report noted that for a
few other HAP, "there also are still some remaining potential concerns and uncertainties that may need
further study. First.. .dioxins and arsenic... are of potential concern (primarily from coal-fired plants);
however, further evaluations and review are needed to better characterize the impacts of dioxins and
arsenic from utilities. Second, nickel emissions from oil-fired utilities are of potential concern, but
significant uncertainties still exist with regards to the nickel forms emitted from utilities and the health
effects of those various forms."
To further inform the regulatory finding, the EPA issued an Information Collection Request (ICR) under
the authority of section 114 of the CAA to all coal-fired electric utility steam generating units requesting
coal data (including mercury and chlorine contents) from such units for calendar year 1999. Seventy-nine
units were selected to represent a cross-section of boiler and control device types and were required to
conduct stack tests to evaluate their mercury emissions. In addition, the EPA solicited data from the
public through a February 29, 2000 Federal Register notice. A public meeting was held on June 13, 2000,
in Chicago, Illinois, where the public was invited to provide EPA with their views on what the regulatory
finding should be.
In addition, at the direction of Congress, the EPA funded the National Academy of Sciences (NAS) to
perform an independent evaluation of the available data related to the health impacts of methylmercury
and provide recommendations for EPA's reference dose (RfD ~ the amount of a chemical which, when
ingested daily over a lifetime, is anticipated to be without adverse health effects to humans, including
sensitive subpopulations). The NAS conducted an 18-month study of the available data on the health
effects of methylmercury and provided EPA a report of its findings in July 2000.
On December 14, 2000 (65 FR 79825; December 20, 2000), the EPA made a finding that regulation of
HAP emissions from oil- and coal-fired electric utility steam generating units is appropriate and
necessary. Based on the study and the regulatory finding, EPA at the same time added coal- and
oil-fired electric utility steam generating units to the list of source categories in section 112(c) for which
"maximum achievable control technology" (MACT) regulations must be developed under section 112(d)
of the CAA. Under an existing settlement agreement, such regulations are to be proposed by
December 15, 2003, and promulgated by December 15, 2004.
The EPA also undertook an evaluation of the mercury control performance of various emission control
technologies that are either currently in use on coal-fired units for pollutants other than mercury or that
could be applied to such units for mercury control. The evaluation was conducted along with other
parties, including the Department of Energy (DOE). Their report (EPA-600/R-01-109, "Control of
Mercury Emissions From Coal Fired Electric Utility Boilers: Interim Report") was issued in April 2002.
At the June 2000 public meeting noted above, the EPA indicated a willingness to keep the regulatory
process open and to include all stakeholders involved. Further discussion with the various stakeholder
groups about how to structure the regulatory development process so as to achieve maximum input
occurred in March 2001. Following these meetings, it was decided that the most effective means of
ensuring inclusion of the various groups in the process would be to form a Working Group under the
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existing Permits, New Source Reviews, and Toxics Subcommittee of the Clean Air Act Advisory
Committee (CAAAC), established under the Federal Advisory Committee Act (FACA).
WORKING GROUP
The Utility MACT Working Group was formed with an original constituency of 6 representatives of
State/local/tribal agencies, 8 representatives of environmental organizations, and 16 representatives of
affected sources/fuel producers and suppliers/labor groups. Nine members of the Working Group are
formal members or alternates of CAAAC. (See Appendix A for a full list of members.)
As stated in the charge to the Working Group, the overall goal of the Working Group was to provide input
to the EPA regarding Federal air emissions regulations for coal- and oil-fired electric utility steam
generating units that will maximize environmental and public health benefits in a flexible framework at a
reasonable cost of compliance, within the constraints of the CAA. The Working Group effort was
designed to achieve this goal by:
1. Obtaining active participation from stakeholders, including environmental groups, regulated industries,
and State/local/tribal regulatory agencies in all phases of regulatory development, and encouraging public
input throughout the process;
2. Determining the most effective ways to address the environmental issues associated with the HAP; and
3. Considering strategies to simplify the regulations and allow flexibility in the methods of compliance
while maintaining full environmental benefits.
The Working Group was formed for an initial period of one year, and first met on August 1, 2001.
Subsequent meetings were held nearly every month through October, 2002, for a total of 13 meetings. A
summary of each meeting, plus all relevant documents presented and discussed at each meeting, can be
found at the following website: http://www.epa.gOv/ttn/atw/combust/utiltox/utoxpg.html#CAAAC.
Furthermore, this website will be updated in the future as additional information (e.g., IPM modeling
results, new control technology evaluations, etc.) becomes available.
ISSUES
Consensus of opinion on identified issues was a goal of the Working Group; however, it was recognized
early in the process that there was a divergence of opinions. Therefore, the Working Group concentrated
on identifying issues, thoroughly discussing these issues, and clearly identifying the various stakeholder
positions on each issue. The purpose of this document is to report to the CAAAC the issues identified
along with the various stakeholder positions.
The Working Group identified the following issues which EPA must consider and resolve in its drafting
of the utility MACT:
1. Subcategories for mercury,
2. Floor levels for mercury,
3. Beyond-the-floor levels for mercury,
4. Format of mercury standard,
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5. Compliance method (monitoring) for mercury,
6. Compliance time,
7. Non-mercury HAP, and
8. Oil-fired units.
The following sections contain a description of each issue, the stakeholders' position (based on
information available to the stakeholders at this time; more complete arguments of stakeholder positions
are presented in the white papers included as appendices to this document [where available] and other
stakeholder papers that are a part of the Working Group record and are posted on the EPA website), and a
summary of those positions. The stakeholder positions for each of the eight issues listed above were not
developed in isolation; each stakeholder developed a comprehensive set of recommendations that should
be evaluated as a whole, and not taken out of context. The issues are discussed separately in this report to
present a more detailed summary and a clear picture of where each stakeholder group stands on the issue.
For certain issues, there exists a majority and minority opinion within the stakeholder position. These
intra-stakeholder positions and their representation are more fully explained in each section. It should be
noted that the positions presented in this paper may not reflect the variety of positions held by all potential
stakeholders nor even of all members represented by stakeholders noted herein; the positions presented
are those of the members of the Working Group. A table summarizing all the issues and positions is
presented in Appendix B. It is expected that stakeholder positions may change over time, based on new
information, and the CAAAC and the EPA may expect to receive these revised positions as appropriate.
SUBCATEGORIES FOR MERCURY
The issue is whether and how to subcategorize the source category "oil- and coal-fired electric utility
steam generating units" for the purpose of setting the MACT emission standards. Under the MACT
program, once subcategories are established emission standards are set for each subcategory. This issue
was discussed at length from the outset of the Working Group. The EPA is allowed to develop MACT
subcategories based on "classes, types, and sizes" of the source within a given category (section 112(d)(1)
of the CAA). All stakeholders agreed some form of subcategorization is appropriate for the nation's
approximately 1,143 existing units.
Stakeholder Positions
Environmental Stakeholders.1 As noted, section 112(d)(1) gives the Administrator the discretion to
distinguish among classes, types, and sizes of sources within a source category in establishing emission
standards. Environmental stakeholders believe that boiler types are uniquely different systems that meet
the definition of "subcategory" as defined by section 112(d)(1).
To the extent that the EPA chooses to subcategorize, the Environmental Stakeholders believe the
following four subcategories are appropriate for the utility MACT standard: oil-fired boilers,
conventional coal-fired boilers (i.e., cyclone and pulverized coal [PC]), fluidized bed combustion (FBC),
and integrated coal gasification combined cycle (IGCC) electric generating units.
1 The Environmental Stakeholders supporting this position are the Clean Air Task Force, National Wildlife
Federation, National Environmental Trust, Natural Resources Defense Council, and Environmental
Defense. The Environmental Stakeholders collectively represent about 6 million Americans.
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It is the Environmental Stakeholders' view that conventional boilers, FBC, and IGCC units represent
sufficiently different types of electric generating units such that they can be treated differently in
establishing standards. The Environmental Stakeholders believe that distinctions based on coal type,
geographic location, or process differences do not meet the statutory definition of "classes, types, or
sizes" of source and, therefore, oppose subcategorization on those bases.
Industry Stakeholders.2 The Majority Industry Group position is that the language and legislative
history of the CAA shows that Congress intended for EPA to distinguish among classes, types, and sizes
of sources under three core circumstances: when differences among sources affect (1) the feasibility of
air pollution control technology; (2) the effectiveness of air pollution control technology; and (3) the cost
of control. Subcategorization is the primary mechanism that allows the EPA to account for the fact that
distinctions among classes, types, and sizes of sources may have a very real impact on the feasibility of a
given control technology, the effectiveness of that control technology, and the cost of control. This group
also believes that subcategorization in the utility MACT represents sound public policy because it allows
EPA to formulate a MACT standard that recognizes and allows for the continued use of all coals found in
the U.S. without market disruption. There exists no one fuel in sufficient quantities and availability that
can be used by all parties. Many coal-fired plants, particularly in the west, do not have the option to
change fuel types since they are mine-mouth plants nor do they have the necessary transportation
infrastructure to use other sources of coal.
The Majority Industry Group stakeholders support the creation of a total of at least seven subcategories.
Their view is first, that oil- and coal-fired units should be placed in different subcategories because the
fuels are dissimilar and produce very different emissions. Second, for coal-fired units, FBC units must be
separated from conventional boilers (i.e. cyclones and PC units) because they employ a fundamentally
different process for burning coal and they produce emissions with different mercury characteristics.
Third, conventional boilers must be subcategorized by the rank of coal burned (bituminous,
subbituminous, and lignite) because combustion of those coal ranks produces emissions with widely
varying percentages of the three relevant species of mercury (elemental, particulate, and gaseous ionic)
and these factors are important to the feasibility of control equipment.3 Fourth, process differences within
2 The Majority Industry Group was principally represented by Cinergy, Class of 85 Regulatory Response
Group, Edison Electric Institute, Latham & Watkins. National Mining Association, Seminole Electric
Cooperative, Southern Company Generation, United Mine Workers, Utility Air Regulatory Group, West
Associates, American Public Power Association, and National Rural Electric Cooperative Association. This
group, along with its individual members, represents more than 95 percent of the coal-fired generation in
the United States, as well as all major mining interests. In addition, the Clean Energy Group (CEG) was
represented by PG&E National Energy Group, and two of its other members in the FACA process:
Consolidated Edison, Inc., and Public Service Enterprise Group Incorporated. The CEG members have a
significant percentage of coal generation in a diverse portfolio of generating assets in 27 States. WEST
Associates is an industry association of 17 public and investor-owned utilities in the 11 Western States and
North Dakota, serving over 16 million customers. WEST Associates' members own and operate
approximately 90 percent of the installed coal-based electric power generation in this region. Finally the
Institute of Clean Air Companies (ICAC) represented air pollution control equipment vendors (Equipment
Vendors). These last three offer separate opinions on several issues, and these are noted where they differ.
3 It is the position of industry that IGCC units do not fall within the source category because the coal
gasification portion of an IGCC unit does not meet the definition of an electric utility steam-generating
unit. In addition, the IGCC process is so different from conventional coal boilers that even if they meet the
definition of an electric utility steam generating unit, they would certainly be considered a separate
subcategory.
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the bituminous subcategory related to flue gas temperature can affect emission characteristics and justify
further subcategorization (e.g., hot stack, saturated stack, wet stack).
In addition to the foregoing subcategories, further differentiation based on coal chemistry (e.g., content of
mercury, sulfur, and chlorine) may be warranted, as coal chemistry affects the species of mercury created
during combustion. WEST Associates specifically recommended further subcategorization by chlorine
content within bituminous and subbituminous coal subcategories. This recommendation recognizes the
dominant role chlorine plays with respect to formation of different mercury species in the boiler, and their
subsequent controllability in downstream emission removal equipment for particulates and S02.
Although not all industry representatives from regions outside the Western U.S. have endorsed such
additional subcategorization, there is unanimous industry agreement that the chlorine content of coal is
the dominant factor that determines the fraction of elemental mercury in total mercury emissions.
Furthermore, the feasibility, effectiveness, and cost of controlling mercury emissions are distinctly
different for low chlorine-content Western coal when compared to Eastern coal. This industry
stakeholder group believes that these distinctions meet the definition of "classes, types, and sizes"
consistent with the requirements of the CAA and past EPA practice.
The Clean Energy Group (CEG) has a different position on subcategorization. As a general rule, they
oppose subcategorization. They agree that one subcategory should be FBC technology because it uses a
unique combustion system that operates with cooler combustion temperatures that result in much lower
mercury emissions than conventional PC boilers. A second subcategory should be PC boilers that burn
lignite coals, in recognition of the higher mercury content of lignite, and the reality that few boilers in
limited geographical areas make use of this low-rank coal. Finally, they recommend combining
bituminous and subbituminous coals into one subcategory.
The CEG's position derives from its view that, although a regulatory regime that customizes an emission
standard for each coal type and technology may be attractive to some, such an approach would, in fact,
operate to constrain its members' flexibility to find the most effective solutions to environmental
problems. As a result of emission trading programs, many companies think of fuel supply as a
compliance option, and use various blends of coal to optimize their emission performance. The group
believes that fuel switching and fuel blending may become even more common in the future, and opposes
regulations that may hamper the ability to quickly optimize performance and cost to address economic
and environmental considerations. These companies are concerned that a large number of subcategories
may significantly limit the flexibility to manage a facility's operational conditions and fuel choice, which
are of paramount importance in the context of a competitive market for electric generation.
The Equipment Vendors recommend four subcategories: bituminous, subbituminous, lignite, and FBC.
They believe that existing control technologies commercially available today exhibit considerably
different performance characteristics for the three primary coals, mainly related to the differing
characteristics of the mercury species generated. Future control technology development is expected to
overcome these differences and permit a higher, more broadly applicable standard.
State and Local Agency Stakeholders.4 The State and Local Agency Stakeholders recommend three
subcategories: oil-fired boilers, lignite-fired boilers, and a third subcategory that includes all other coal-
fired boilers. Integrated coal gasification combined cycle electric generating units may or may not be
included in the "all other coal-fired units," depending upon EPA definitions. These units were not
4 The State and Local Agency Stakeholders supporting this position are STAPPA/ALAPCO, Northeast
States for Coordinated Air Use Management (NESCAUM), New Jersey, and the Regional Air Pollution
Control Agency (RAPCA) based in Dayton, Ohio. Texas offers a separate opinion on several issues and
these opinions are noted where they differ.
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thoroughly evaluated in the Working Group; thus, the State and Local Agency Stakeholders have no
recommendation on whether or not they should be a subcategory. The State and Local Agency
Stakeholders believe that FBC units do not need a separate subcategory because their emission
characteristics are similar to those of the "all other" category. The State and Local Agency Stakeholders
also recommend against a subcategory based on size of coal-fired power plant or units. They reason that
all coal-fired power plants can still be significant sources of HAP emissions. Additionally, they are
opposed to subcategories that would distinguish between subbituminous and bituminous coals, given the
increasing use of fuel blends made up of these two coal types and the goal of simplicity and flexibility for
MACT standards. The State and Local Agency Stakeholders oppose subcategorization based on flue gas
temperature and moisture related to existing air pollution control devices. (Texas did not take a position
on this topic.) The State and Local Agency Stakeholders also stated that the range of emissions from the
ICR data was similar for bituminous and subbituminous coal-fired units and that with proper design of the
MACT standard (form and magnitude of the standard), two separate subcategories are not necessary or
useful.
Texas agrees on the separate subcategories for oil-fired boilers and lignite-fired boilers and then
recommends further subcategories for FBC and bituminous and subbituminous coal-fired plants. Texas
feels the different coal ranks produce different exhaust gas temperature profiles and emissions with
widely varying percentages of elemental, particulate, and ionic mercury species. Mercury speciation and
temperature profile, among other factors, dictates the plants' ability to abate mercury emissions on a
continuous basis.
Some Western States have requested additional time to evaluate subcategorization options. The CAAAC
should expect additional comments from these States in the near future.
Summary of Positions on Subcategories for Mercury. There is agreement that oil- and coal-fired
boilers should be separate subcategories. The stakeholders do not agree that IGCC units are subject to the
Utility MACT. The treatment of FBC units as a subcategory is recommended by the Environmental and
Industry Stakeholders and Texas. The State and Local Agency Stakeholders believe that FBC units do
not need a separate subcategory because their emission characteristics are similar to those of the "all
other" category. All stakeholders except the environmental groups supported a separate subcategory for
lignite-fired boilers. The Majority Industry Group, the Equipment Vendors, and Texas supported separate
subcategories for bituminous and subbituminous coals while the CEG, State and Local Agency
Stakeholders, and environmental groups did not. WEST Associates supports additional subcategorization
within bituminous and subbituminous coal ranks based on the chlorine content of Western coals because
of the unique differences in the feasibility, effectiveness, and cost of control of mercury emissions from
such low chlorine-content coals.
MACT FLOOR LEVELS FOR MERCURY
The issue is how the "floor level" for the MACT mercury emission limit should be calculated and what
stringency is required. The EPA, as a part of its MACT rulemaking, has to recommend a "floor"
(minimum level of reduction required) for mercury reductions. All parties considered the ICR data and
took into account the "variability" of the process (variability of mercury and other chemicals in coal, in
measurements, in sampling, and in operation of the best performing plants). However, based on different
views regarding how to address variability in establishing the MACT floor, stakeholders recommended
differing MACT floors for mercury.
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Stakeholder Positions
Environmental Stakeholders. The Environmental Stakeholders recommend that EPA calculate a
MACT floor for existing units based on the average emissions of the top 12 percent of each subcategory
as required under section 112(d)(3). The Environmental Stakeholders recognize that mercury emissions,
even from the same unit, can be variable. This variability is accounted for in the floor level by taking the
average of the emissions of the top 12 percent, and is further accounted for by recommending a 30-day
rolling averaging time for compliance purposes (using continuous emission monitors [CEM] as discussed
in more detail in other sections of this document).
The Environmental Stakeholders recommend an output-based emission rate standard, based on the
following input-based rates for each of the proposed boiler type subcategories and the heat rate of the
specific generating unit:
• Conventional boilers 0.21 pounds per trillion Btu (lb/TBtu)
• FBC 0.19 lb/TBtu (average of four units)
• IGCC 0.54 lb/TBtu
For FBCs, the Environmental Stakeholders use four of the five "MACT-floor" units with measured
mercury emissions ranging from 0.08 to 0.46 lb/TBtu. They omit the fifth unit (which utilized an
electrostatic precipitator and not a fabric filter), which had measured emissions of 3.97 lb/TBtu. The
Environmental Stakeholders believe that setting a standard at 0.95 lb/TBtu (the average of the five FBC
units measured) would not be appropriate, in that four of the five tested units currently emit at less than
half of that standard, such that the MACT standard would not reflect the emission rate that is achieved in
practice. Averaging the emissions over the top four units would be one possibility, which would result in
a MACT floor of 0.19 lb/TBtu, or 92 percent reduction. For IGCC units, the mercury emission limit
would be 0.54 lb/TBtu. (Note the IGCC emission rate is a beyond-the-floor calculation as described in
the next section of this document.)
For new sources, the Environmental Stakeholders recommend a MACT floor level that is no less stringent
than the emission control that is achieved in practice by the best-controlled similar source as required by
section 112(d)(3).
Industry Stakeholders. The Majority Industry Group holds that the MACT floors for the various
subcategories must account for the inherent variability in mercury emissions from the best performing
units and from the use of different types of fuel, including the variation seen within a given coal seam.
The group's position is that a MACT standard must represent the performance of the best sources under
the worst reasonably foreseeable conditions. Their analysis shows that the ICR Part III stack sampling
data, with its three test runs of approximately one hour each, were not able to quantify the worst
reasonably foreseeable conditions. As a result, simply averaging the stack test data is not appropriate.
There are numerous methods for addressing variability, including a correlation approach offered by the
Utility Air Regulatory Group (UARG) and a statistical approach presented by EPA. The position of the
Majority Industry Group is that none of the methods presented to the Working Group fully accounts for
all the variability in mercury emissions from a coal-fired plant. The EPA model, for instance, does not
factor in coal variability; in contrast, the UARG model does not incorporate operational variability.
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The approach offered by UARG addresses fuel variability by using correlations developed by EPRI from
the Part III ICR data and then using these correlations and the coal data from 1999 for the best performing
units to produce cumulative distributions of emissions for 1999 from those units. This analysis was
discussed at several of the Working Group meetings. Two approaches for MACT floor levels are offered
in the following table. They are based on the performance of the best 12 percent of the plants tested in
each category (or the average of the five best performing units for subcategories with less than 30 units) at
the 95th percentile of each cumulative distribution, and provide for an alternative standard (rate based or
percent reduction).
Subcategorization Approach 1 - Coal Rank - considering only fuel variability
Subcategory
Stack Limit, lb/TBtu
Overall Reduction
Bituminous
2.2
73%
Subbituminous
4.2
31%
Lignite
6.5
47%
FBC
2.0
91%
Subcategorization Approach 2 - Coal Rank and Process - considering only fuel variability
Subcategory
Stack Limit, lb/TBtu
Overall Reduction
Bituminous - Hot
3.7
55%
Bituminous - Saturated
2.2
63%
Bituminous - Wet
3.2
62%
Subbituminous
4.2
31%
Lignite
6.5
47%
FBC
2.0
91%
However, to fully understand the capabilities of the best performing plants, the MACT floor must
consider both the fuel variability and variability from other causes such as sampling and monitoring,
operational, and plant-to-plant variability.
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The Majority Industry Group also points out that mercury reductions at all existing coal-fired power
plants, including the "best" performing units, result from control equipment that was installed to reduce
the emissions of other pollutants. New coal-fired power plants are subject to stringent regulation under a
number of CAA provisions including new source performance standards (NSPS). These requirements
cause new plants to install high efficiency particulate removal devices, scrubbing systems for sulfur
dioxide (S02), and nitrogen oxides (NOx) reduction devices. These technologies are found on existing
units that achieve the "best" mercury control. Additional control strategies that specifically address
mercury, such as activated carbon injection, are developmental and are not commercially available. As a
result, this group's position is that the MACT floor for new units should reflect the mercury control co-
benefits of NSPS devices and should not be based on speculation about the potential capability of
developmental technologies. The MACT floor for new units should reflect the same categories and be at
least as stringent as the MACT floor for existing units and must address the variability in mercury
emissions of the best performing units.
The CEG proposes a somewhat different approach, which would (1) identify the top 12 percent of
facilities from the available database; (2) identify the primary emissions control technology used by the
facilities in that group with emission levels at or better than the average for the group; (3) then look to all
sources in the database using the identified control technology, provided the control was well designed
and operated; and then (4) set the MACT floor such that the floor accounts for operational variability.
The CEG did not take a position on how best to account for variability, and, thus, does not have a
numerical proposal for the MACT floor for the subcategories it proposes.
The CEG suggests that a similar methodology to the one described for existing coal-fired units be applied
to new units. However, instead of using the control technology used by the best 12 percent of facilities,
the emission control technology used by the best performing plant would be identified. Then, considering
all facilities in the database using that technology, the floor would be set based on some mathematical or
statistical measure that reflects inherent operational variability, using, for example, an average, a median
or a 95 percent confidence interval value.
The Equipment Vendors based their review on pilot plant and large unit testing of new control
technologies, and recommends a MACT floor for mercury set at 90 percent mercury removal for
bituminous-fired units, or a comparable emission rate. For subbituminous-fired units, a floor based on a
70 percent removal rate, or comparable emission rate, is appropriate. No recommendations were offered
for FBC or lignite-fired plants. For new sources, they recommend a floor based on a 90 percent mercury
reduction.
State and Local Agency Stakeholders. The State and Local Agency Stakeholders evaluated the average
performance of the best 12 percent in two ways: with the test data (80 tests) as well as with extrapolated
test data (411 plants), based on the coal data and EPA's estimates of emissions from each of these plants.
The best percent reductions were determined independently of the best rate-based limit, and do not
represent an alternative limit for a combined rate or percent reduction standard.
1. Average of best 12 percent of 411 plants - 0.3 lb/TBtu (1.5 mg/MWh); 94 percent control.
2. Average of best 12 percent of 80 tests - 0.2 lb/TBtu (1.0 mg/MWh); 93 percent control.
The State and Local Agency Stakeholders believe that consideration of the variability of the data is
appropriate. Although their primary recommendation is to deal with variability by averaging quarterly
tests in a year (3 test runs per quarter), adding a compliance margin to the average of the best 12 percent
of the actual emission level is also reasonable when determining an appropriate emission limitation.
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They recommend a factor of 2 times the actual tested average as a reasonable compliance margin when an
annual average of quarterly tests is used or a 30-day or greater average of CEM data is used.
The State and Local Agency Stakeholders also recommend that a percent reduction alternative be part of
the MACT standard to enable any plant the opportunity to continue to burn the same coal if best available
control technology (BACT) is employed. Their estimated range for the percent reduction alternative for
bituminous/subbituminous coal is 90 to 95 percent. This range is also consistent with the average control
efficiencies for the best 12 percent of the test data (93 percent control) and the 411 plant evaluation (94
percent control) without carbon. Hence, this MACT floor does not depend on the use of carbon. Rather,
carbon and baghouse control are available as an option to comply with the 90 percent alternative limit. A
90 percent alternative limit is recommended by the State and Local Agency Stakeholders to provide a
reasonable assurance of compliance if the percent reduction option is chosen.
The State and Local Agency Stakeholders' recommendation for a MACT floor for bituminous and
subbituminous coal would be 0.4 lb/TBtu (2 mg/MWh) or 90 percent control, based on the data from the
80 tests; 0.2 lb/TBtu (1 mg/MWh) would be a literal reading of section 112(d) if applied to the test data
with no further consideration of variability. The 0.4 lb/TBtu level includes a factor of 2 compliance
margin to further address variability beyond the averaging of 12 tests or long-term CEM data.
The State and Local Agency Stakeholders also believe that consideration of information on the universe
of coal plants is appropriate. If the extrapolation of the average test data to the 411 coal plants is used to
develop the MACT floor, the MACT standard would be 0.6 lb/TBtu (3 mg/MWh) or 90 percent control
based on the same consideration of variability. Looking at Appendix 4 in the September 9, 2002, white
paper, they conclude that when a 90 percent alternative limit is used, the 0.6 lb/TBtu rate-based option is
the appropriate rate level for a combination standard. In conclusion, the State and Local Agency
Stakeholders recommend that the MACT floor for bituminous and subbituminous coal-fired units be 0.4
to 0.6 lb/TBtu (2 to 3 mg/MWh) or 90 percent control.
Texas holds a different position than the other State and local stakeholders in pointing out that
section 112(d)(3) requires that "Emission standards promulgated under this subsection for existing
sources in a category or subcategory may be less stringent than standards for new sources in the same
category or subcategory but shall not be less stringent, and may be more stringent than the average
emission limitation achieved by the best performing 12 percent of the existing sources (for which the
Administrator has emissions information)." The term "emission limitation" is defined in section 302(k)
as "a requirement established by the State or the Administrator which limits the quantity, rate, or
concentration of emissions of air pollutants on a continuous basis, including any requirement relating to
the operation or maintenance of a source to assure continuous emission reduction, and any design,
equipment, work practice or operational standard promulgated under this Act." Therefore, the CAA
requires the MACT floor for existing units to be based on existing State or Federal requirements, which
limit emissions on a continuous basis. Any recommendations beyond this standard would be "beyond the
MACT floor."
Some Western States have requested additional time to evaluate MACT floor level options. The CAAAC
should expect additional comments from these States in the near future.
Summary of Positions on MACT Floor Levels for Mercury. Stakeholders' recommendations for
MACT floor levels are driven by how each handles the issue of subcategories (how many and on what
basis, since floor determination for each category is based on the ICR data for that subcategory) and the
issue of variability. Also, the form of the standard (emissions rate alone as offered by environmental
groups, a combination standard as offered by others) determines the actual numerical values proposed.
All stakeholders agree that addressing variability in mercury emissions in setting the MACT floor for
mercury is important, but suggest different ways of accomplishing this. The Environmental Stakeholders
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recommend addressing variability through the averaging of the top twelve percent of performers for
existing units, and by an extended compliance monitoring time for new and existing units. The industry
stakeholders contend that simply averaging the ICR Part III stack sampling results does not represent the
performance of the best sources under the worst reasonably foreseeable conditions. As a result of their
analysis, they recommend MACT floors based on an analysis of ICR Part II and III data. The State and
Local Agency Stakeholders recommend a factor of 2 compliance margin and the use of long-term
averages to address variability.
For new sources, all of the stakeholders agree that the best performing similar source will be the basis for
new source MACT. The Equipment Vendors recommend a standard for bituminous of 90 percent
removal, or a comparable emission rate; a standard for subbituminous of 70 percent removal, or a
comparable emission rate; and made no recommendations for lignite or FBC.
BEYOND-THE-FLOOR LEVELS FOR MERCURY
The issue is, should EPA establish MACT standards for mercury that are more stringent than those
established by the floor analyses based on the statutory requirement to consider "the cost of achieving
such emission reduction, and any non-air quality health and environmental impacts and energy
requirements" in establishing such standards. The various stakeholders hold differing views on whether
the EPA should develop these more stringent standards ("beyond-the-floor").
Stakeholder Positions
Environmental Stakeholders. The Environmental Stakeholders recommend that bey ond-the-floor
MACT standards for mercury be developed for IGCC units. With IGCC plants becoming a more
attractive option for new electric generation, the Environmental Stakeholders assert that MACT for this
source type should not be set at uncontrolled levels. A recent analysis by the DOE illustrates that a fixed
carbon bed, similar to those already in use by industrial gasifiers, is readily adapted to an IGCC power
plant at a reasonable cost and can achieve mercury reductions of 90 percent or higher (as high as 99
percent if the carbon beds are placed in series). The Environmental Stakeholders recommend 90 percent
removal from existing levels. This level of control results in a mercury emission rate of 0.54 lb/TBtu.
Because of insufficient data, the Environmental Stakeholders do not have a recommendation for beyond-
the-floor levels for other boiler types.
Industry Stakeholders. The Majority Industry Group believes that, based on information in EPA's
Utility and Mercury Studies, it is unlikely that a case can be made for regulation beyond the MACT floor.
The remaining mercury emissions from coal-fired power plants will be small and constitute a very small
percentage of the overall mercury pool. Hence, further control will have little incremental effect on
public health while the costs of achieving additional control will be very high.
The Majority Industry Group believes that, at this time, insufficient information has been presented to
draw a definitive conclusion on whether regulation is needed beyond the MACT floor. Bey ond-the-floor
analyses require EPA to look at the cost of achieving more stringent emission reductions, any non-air
quality health and environmental impact of further reductions, and energy requirements. Thus, EPA must
complete: (1) its IPM runs to assess the cost impacts of regulation, (2) its REMSAD (or equivalent) runs
to understand mercury deposition and possible health effects, and (3) an assessment of the energy
requirements of additional control. Moreover, because beyond-the-floor control technologies (e.g.,
activated carbon) are generally not commercially available, EPA must carefully assess the cost and actual
availability of those technologies. According to this group, only when this work is concluded, and made
available for public comment, will EPA be in a position to make a reasoned decision on whether
regulation is needed beyond the MACT floor.
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The CEG, however, observes that a number of new technologies for reducing mercury emissions are in
various stages of research and development. They observe that some of these new technologies may
prove to be attractive control options for mercury, based on the results of studies performed thus far.
They point to activated carbon injection as a potentially cost effective technology. Beyond-the-floor
analyses will require EPA to weigh cost, energy requirements, and non-air quality impacts to determine
whether a mercury MACT standard stricter than the floor level is achievable.
It is noted that the MACT recommendations of the Equipment Vendors (70 percent mercury control for
subbituminous coal-fired boilers and 90 percent mercury control for bituminous coal-fired boilers) is not
an "average of the best 12 percent" approach. Rather, it is really a beyond-the-floor recommendation,
based on technology which this industry group believes will be available for compliance.
State and Local Agency Stakeholders. The State and Local Agency Stakeholders recommend that EPA
consider several factors for "beyond-the-floor" limits for mercury emissions from coal.
• Emissions data for control of the criteria pollutants (particulates, S02, volatile organic substances,
NOx, and carbon monoxide [CO]), BACT/LAER determinations.
• The additional mercury emissions reduction benefits of control systems which minimize other
HAP, including fine-particulate HAP and acid-gas HAP.
• Technology transfer of air pollution control technologies used on other mercury source
categories.
• Pilot and full-scale demonstration programs of mercury control technologies.
• The role of environmental regulation as a driver of technology innovation and implementation.
• Coal combustion is the greatest source of mercury and other HAP emissions in the U.S.
The State and Local Agency Stakeholders do not provide specific beyond-the-floor emissions limit
recommendations.
Texas argues that the section 112(d)(2) of the CAA requires the Administrator to take into consideration
the cost of achieving emission reductions. Texas feels some of the controls being considered, such as
activated carbon injection, are beyond-the-floor requirements which may prove to be unreasonably
expensive.
Summary of Positions on Beyond-the-floor Levels for Mercury. As with the MACT floor levels, there
is little agreement on the need for beyond-the-floor controls for mercury. Because of insufficient
information, the Environmental Stakeholders do not specifically advocate beyond-the-floor controls,
except for IGCC units. The State and Local Agency Stakeholders do not provide specific beyond-the-
floor limits but provide criteria for EPA to consider in developing beyond-the-floor limits. The Majority
Industry Group maintains that it is premature to discuss the need for beyond-the-floor controls, as
substantial additional modeling is needed from the EPA first. The CEG, however, holds that beyond-the-
floor emerging technologies may prove to be attractive control options for mercury.
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FORMAT OF MERCURY STANDARD
At issue here is whether the mercury standard should be in the form of an emissions limit, a percent
reduction, or a combination of the two. There is also an issue of input- vs. output-based emission limits.
The various stakeholders hold differing views on the form of the mercury standard.
Stakeholder Positions
Environmental Stakeholders. The Environmental Stakeholders do not recommend a standard that
offers a choice between an emission rate and a percent reduction standard (an "either/or" approach). The
Environmental Stakeholders believe that a percent reduction approach results in a weaker standard than
an emission rate approach if the percent reduction target were calculated using a methodology consistent
with the one they used to calculate a MACT floor emission rate. Therefore, a percent reduction
requirement that more closely correlates with the emission rate would be needed.
The Environmental Stakeholders recommend an output-based standard to reward efficiency and provide
compliance flexibility by adding unit efficiency to the mix of available compliance strategies. They
believe that an output-based standard more closely reflects the language of section 112(d) as interpreted
by the courts that encourages investment in alternative compliance methods in addition to stack controls,
such as process changes and work practice standards. Several States have adopted output-based standards
for electric generating units under the NOx SIP Call, demonstrating the feasibility of such an approach.
The Environmental Stakeholders support compliance on a unit-by-unit basis.
Industry Stakeholders. All of industry recommends that MACT standards afford plants flexibility in
demonstrating compliance with the emission limits. The MACT standard for electric utility steam
generating units should specify both an emission rate limit and a percent reduction. Plants should be
given the option of demonstrating compliance with either of these limits. With the exception of the CEG,
industry holds that the emissions rate limit should be based on heat input and not energy output. The
Majority Industry Group points out that sources already have an incentive to maximize fuel efficiency,
because fuel costs account for over three-quarters of variable production costs. In addition, this group's
position is that regulations specifying output-based limits would become overly complex because of the
many technical details that would have to be addressed. (Examples include the cogeneration of steam,
common systems where multiple boilers feed one or more steam turbines, and the need for appropriate
instrumentation.) The CEG, however, strongly endorses expressing the rate-based standard on an output
basis rather than a heat input basis, and notes that output-based standards are currently used in EPA's
recent NOx NSPS for new utility boilers, as well as in the air pollution regulations of a number of States.
The Majority Industry Group also recommends that fuel blending and/or switching (i.e. using both
bituminous and subbituminous in the same compliance period) should be handled using a blended
standard.
The industry groups observe that there is a precedent in other MACT standards to require compliance on
a facility basis. Therefore, compliance with MACT limits should be on a facility basis (i.e. averaged
across all the coal fired boilers at a facility) rather than on a boiler-by-boiler (unit-by-unit) basis. A
facility-based limit allows some flexibility in unit operation without having any adverse impact on total
emissions.
State and Local Agency Stakeholders. The State and Local Agency Stakeholders prefer an output-
based standard to reward higher efficiency plants and encourage higher efficiency (and lower emissions)
in new and modified plants. The State and Local Agency Stakeholders believe that a combination
either/or standard could be an acceptable format. However, the State and Local Agency Stakeholders
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recognize that a combination standard would have to be sufficiently stringent so as to approximate, in
terms of national emissions remaining, a standard based on an emission rate alone or a percent reduction
requirement alone. The reason for incorporating a percent reduction requirement (based on inlet-outlet
concentration across the control device) in a combination standard is to provide a mechanism to meet the
standard for units burning a high mercury coal. Compliance determination with a percent reduction limit
is usually based on simultaneous boiler outlet and stack testing, but simultaneous testing of coal and stack
may be feasible with representative testing of the coal as fired. The State and Local Agency Stakeholders
are agreeable to a facility-wide compliance basis, if limited to coal units in the same subcategory.
Texas feels that any mercury MACT standard should allow facilities to choose between a percentage
reduction limit (between mercury in the coal and mercury in the flue gas) and a concentration limit (either
a stack concentration limit or an input concentration limit).
Summary of Positions on Format of Mercury Standard. All stakeholders, except the Environmental
Stakeholders, support allowing some form of facility-wide averaging as a means of providing flexibility
and enhancing the cost-effectiveness of the rules. The State and Local Agency Stakeholders,
Environmental Stakeholders, and CEG support using output-based, rather than input-based, emissions
limits, although this position is strongly opposed by the Majority Industry Group. The State and Local
Agency Stakeholders note that an input-based standard could be acceptable. The industry and State and
Local Agency Stakeholders support allowing sources to comply with the rule either by meeting an
emission rate or a percent reduction standard, although this approach is opposed by the Environmental
Stakeholders.
COMPLIANCE METHOD (MONITORING) FOR MERCURY
The issue is which are the appropriate measurement methods, protocols, and averaging times for
determining compliance with the applicable mercury MACT standards. The stakeholders hold varying
opinions regarding which measurement methods, protocols, and averaging times should be used.
Stakeholder Positions
Environmental Stakeholders. The Environmental Stakeholders recommend that CEM systems be used
for compliance with the mercury MACT standard. These units simply represent the most accurate way to
measure stack emissions. Mercury CEM are already commercially available and there are ongoing EPA
validation programs. The Environmental Stakeholders are confident that if the MACT standard requires
CEM, by December 2007 manufacturers will have several commercially available options for power
plants. To account for variability in stack emissions, the Environmental Stakeholders recommend a 30-
day rolling average with periodic stack tests (at least annually) using Method 101A or Method 29 to
calibrate the CEM. The Environmental Stakeholders also recommend that if a facility-wide standard
were adopted over their objections, EPA should explore the feasibility of allowing a multi-unit facility to
meet the MACT emissions rate across all the units comprising the major source, even if one of the units
switches to a cleaner fuel not subject to the MACT standard. For example, a source comprised of four
coal-fired units that switched one unit to natural gas, could still include that unit in the defined source that
must meet the MACT emissions rate. This would allow the rate to be spread, in effect, over the three
remaining coal-fired units, while taking advantage of the MWh electric output of the gas-fired unit in the
compliance averaging.
Industry Stakeholders. The industry position is based on the potential health concerns identified by
EPA in its December 2000 listing decision for mercury and in the extensive studies on which that
decision is based arise from the long-term accumulation of mercury in the environment. Accordingly,
short compliance averaging periods (e.g., hourly or daily) are unnecessary. In addition, there has not been
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any suggestion that compliance with a mercury MACT should be based on anything other than total
mercury. As a result, speciated mercury data are not required for compliance purposes.
Industry believes EPA can not assume that mercury CEM will be available when regulations are
promulgated. The EPRI and DOE continue to have their automated CEM projects continuously staffed in
order to achieve reasonably reliable results, and there is no certainty that these issues will be resolved
prior to proposal of the mercury MACT. Therefore, compliance should be monitored using EPA Method
101 A, which is currently the only approved method for sampling and analyzing total mercury. Sources
would have the option to use the Ontario Hydro method since it is a variation of Method 101 A. Once
properly validated, EPA can adopt CEM for measuring compliance through an appropriate regulatory
process.
The scheduling and performance of compliance testing should provide utilities sufficient flexibility to
assure system reliability and economic dispatch of their systems. Title V permits will include compliance
assurance monitoring (CAM) plans for periods between compliance tests. Industry recommends an initial
compliance demonstration followed by annual testing for large sources and biennial testing for small
sources to demonstrate compliance with mercury MACT limits.
The Equipment Vendors recommend a compliance averaging period of 30 days based on their belief that
CEM will be available before they are needed for use with this rulemaking. A 30-day averaging period
accommodates variability (e.g., coal type, plant operation). If, however, manual measurements are
needed, then they support an averaging time on the order of a year due to the needed turnaround time and
to accommodate the number of samples that might be recognized as constituting an accurate
representation of a given plant's performance.
State and Local Agency Stakeholders. The State and Local Agency Stakeholders recommend using
Method 29A for measurement of mercury and other metals. They further recommend that there should be
a transition to CEM, once CEM are demonstrated, reliable, and commercially available. At that time, the
standard should be based on either a monthly average or a 12-month rolling average. In the interim
(while Method 29A is being used), there should be quarterly testing, with compliance assessed using the
average of 4 quarterly averages (each of which includes 3 test runs).
Summary of Positions on Compliance Method (Monitoring) for Mercury. All parties agree that the
mercury MACT standard, and its compliance method, should be based on evaluating long-term loadings
(30-day standard to as long as an annual standard). Industry's position is that CEM will not be
sufficiently automated, accurate, reliable, and validated at the time a MACT standard is promulgated. As
a result, they recommend stack testing for compliance (at least in the short term), as do other stakeholders,
should CEM not be available. The difference in recommended stack testing methods (Method 101A for
Industry Stakeholders versus Method 29A for State and Local Agency Stakeholders) results from their
differing positions on the regulation of non-mercury HAP. If EPA regulates only mercury (as Industry
Stakeholders recommend), then there is no need to use Method 29A, which measures mercury in addition
to other metals. In contrast, if EPA regulates multiple metals, Method 29A makes more sense. The
Industry Stakeholders recommend annual/biennial stack testing, while the State and Local Agency
Stakeholders recommend quarterly stack testing. The Environmental Stakeholders and Equipment
Vendors recommend that CEM be used for compliance beginning in December 2007 and are confident
that CEM will be validated and commercially available in that time frame. The State and Local Agency
Stakeholders believe that a transition to CEM should be made as soon as they are available. The
Environmental Stakeholders' recommended 30-day rolling average for compliance testing is supported by
the Equipment Vendors and the State and Local Agency Stakeholders, although the State and Local
Agency Stakeholders also recommend consideration of an annual rolling-average standard.
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COMPLIANCE TIME
The issue is the statutorily-defined compliance time and the considerations by which extensions may be
granted. This issue received limited discussion during the Working Group process, and it was agreed that
the provisions outlined in the CAA for installation of controls and compliance may be triggered.
Summary of Positions on Compliance Time. Stakeholders agree that a utility mercury MACT
regulation has the potential to require retrofit controls to be installed at existing generating units. The
CAA outlines timeframes in which compliance must be achieved, and includes additional time to install
controls when necessary. Implementation of these CAA provisions may be triggered during the utility
mercury MACT regulatory process.
NON-MERCURY HAP
The issue is whether EPA is obligated to set emission standards for HAP other than mercury for coal-fired
boilers, and HAP other than nickel for oil-fired boilers. The various stakeholder groups hold differing
views on this issue.
Stakeholder Positions
Environmental Stakeholders. The Environmental Stakeholders recommend that EPA set emission
standards for all HAP (in addition to mercury) because they believe these HAP also pose a public health
and environmental risk and that such emissions should be minimized. If EPA finds that the available data
for non-metal HAP are inadequate to set standards, then EPA should immediately initiate efforts to gather
additional data for the other emitted HAP. The EPA's regulatory determination listed the source category
"coal- and oil-fired electric utility steam generating units" and declared that regulating HAP emitted by
this source category is appropriate and necessary. The determination advised that the HAP of "greatest
potential concern" for coal-fired units was mercury, and nickel for oil-fired units. The EPA also
determined that several metals are of "potential concern for carcinogenic effects." The determination also
advised that hydrogen chloride (HC1), hydrogen fluoride (HF), and dioxins are three additional HAP of
potential concern which may be further evaluated during the regulatory process. The Environmental
Stakeholders believe the statutory language of CAA section 112(d) and existing case law support the
requirement that regulation of all HAP on the section 112(b) list is required for each listed category or
subcategory of major sources. They believe the regulatory determination had the legal effect of listing
power plants on the section 112(c) source category list, thereby triggering the requirement of
section 112(c)(5) for EPA to set MACT emission standards for listed HAP emitted by this source
category. The regulatory determination, in and of itself, cannot limit EPA to setting emission standards
only for the HAP listed under section 112(b) that were discussed in the determination.
When EPA sets standards for the non-mercury HAP, the Environmental Stakeholders recommend
promulgation of an output-based standard for the non-mercury HAP metals based on the average of the
best performing top 12 percent of the tested units. A percent reduction standard also could be developed,
but is not preferred by the Environmental Stakeholders because it is more difficult to determine
compliance compared to an emission rate standard. A surrogate approach to regulating non-mercury
HAP also could be acceptable, so long as the surrogate measure: (1) reflects the actual emissions of the
grouped pollutants, (2) represents the calculated floor, (3) has substantially the same properties as the
grouped pollutants, and (4) is controlled by the same mechanisms or measures as the grouped pollutants.
Recommended pollutant groupings are "low-volatility HAP metals," "semi-volatile HAP metals," "acid
gases," "radionuclides," "organic HAP other than dioxins/furans," and "dioxin/furans." The table below
lists the input-based emission rates that represent the average of the best performing 12 percent for the
tested units, from which an output-based standard can be calculated.
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Metal
Emission Rate, lb/TBtu
Metal
Emission Rate, lb/TBtu
Antimony
0.15
Copper
1.3
Arsenic
0.24
Lead compounds
0.34
Barium
1.34
Manganese
2.38
Beryllium
0.01
Molybdenum
0.61
Cadmium
0.16
Nickel
1.34
Chromium
0.91
Selenium
0.19
Cobalt
0.19
Vanadium
0.58
The Environmental Stakeholders support creation of MACT emission limits for acid gases and organics,
but do not offer specific recommendations as to what those limits should be.
Industry Stakeholders. The Industry Stakeholders take the position that EPA's authority under
section 112 is limited to regulating mercury emissions from coal-fired plants. Electric utility steam
generating units are treated differently than other sources under section 112. Section 112(n)(l)(A)
requires EPA to study the hazards to public health reasonably anticipated to occur as a result of HAP
emissions from electric utility steam generating units. The EPA is then to regulate as is "appropriate and
necessary" to protect public health. The EPA's decision to list coal- and oil-fired electric utility steam
generating units under section 112(c) was based on a conclusion that mercury emissions from coal-fired
power plants presented public health concerns. The EPA did not identify public health concerns
associated with the emissions of any other HAP. Thus, EPA's December 2000 listing decision must be
viewed as only involving mercury emissions from coal-fired plants. The EPA can regulate non-mercury
HAP only if it concludes that emissions of these HAP from power plants pose an unacceptable risk to
human health.
Even if EPA identifies health concerns associated with non-mercury HAP, the Industry Stakeholders
believe historical sampling data are insufficient either to characterize non-mercury HAP emissions from
coal- or oil-fired units or to set MACT floors. They believe that before EPA can regulate these
compounds, it must fill existing data gaps by collecting emissions data at a representative group of
electric utility steam generating units using validated sampling and analytical methods.
The Majority Industry Group takes the position that suggestions for grouping non-mercury HAP or
designating "surrogate" compounds are, therefore, premature and inappropriate. The CEG, however,
urges that if EPA decides to regulate other HAP from coal- and oil-fired utility generating units, the EPA
use appropriate "surrogates" for certain classes of HAP emitted from these units, including metals, acid
gases, and organic compounds. These surrogates should be used not only in the MACT determination
process, but also in the determination of compliance.
State and Local Agency Stakeholders. The State and Local Agency Stakeholders agree with the basis
for regulating non-mercury HAP and stated that the non-mercury HAP emissions from power plants are a
significant fraction of the national loadings of these pollutants (including metals and acid gases), and
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should be regulated. Pollutants of particular concern include metals (especially arsenic, cadmium,
chromium, lead and manganese), acid gases (HC1 and HF) and organics (including dioxins). The State
and Local Agency Stakeholders support the conclusion that, consistent with past EPA precedent, the
technology-based MACT program should ensure that all significant sources of HAP implement controls
to reduce emissions of all HAP to the maximum extent achievable.
The State and Local Agency Stakeholders recommend grouping HAP from power plants into four
categories: (1) mercury; (2) fine-particulate HAP (including arsenic, cadmium, and chromium;
radionuclides; and polycyclic organic matter [POM]); (3) acid gases; and, (4) organic HAP such as
dioxins, polycyclic organic matter (POM) and other products of incomplete combustion (PICs).5 The
State and Local Agency Stakeholders recommend the use of surrogates as a practical mechanism to
address the large number of non-mercury HAP emitted by power plants. The following surrogates and
limits are recommended:
• Fine particulate HAP: Particulate emissions should be used as a surrogate, with a floor level of
0.030 lb/million Btu (lb/MMBtu) for total particulates based on the NSPS, and a beyond-the-floor
limit of total particulates at 0.0150 lb/MMBtu based on BACT. The State and Local Agency
Stakeholders prefer that the particulate limit be based on the fine particulate fraction if the NSPS
and BACT levels for total particulate can be converted to fine particulate equivalents.
• Acid Gases: S02 or HC1 should be used as a surrogate. When SO2 is chosen as a surrogate for
HC1 and HF, the States and locals recommend a floor limit of 90 percent S02 reduction based on
NSPS, and a beyond-the-floor limit of 95 percent S02 reduction based on BACT. The same or
greater reductions are appropriate if HC1 is used as a representative acid gas HAP.
• Organic HAP: Carbon monoxide should be used as a surrogate, with a floor limit of 100 parts per
million (ppm) CO on a 24 hour average (reasonable available control technology, RACT). The
State and Local Agency Stakeholders do not recommend a specific beyond-the-floor limit, but
believe EPA should consider recent BACT/LAER determinations in identifying an appropriate
MACT level. The EPA should consider an averaging time as low as one hour to address high
emission of HAP PIC over shorter time periods of poor combustion conditions.
Texas does not support the regulation of HAP other than mercury and cites section 112(n)(l) of the CAA
which requires the Administrator to "regulate electric utility steam generating units under this section, if
the Administrator finds such regulation is appropriate and necessary after considering the results of the
study required by the subparagraph." The RtC provides justification for regulating mercury from coal-
fired power plants, but then states "[f|or a few other HAP, there also are still some remaining potential
concerns and uncertainties that may need further study." No further study was conducted to establish the
need to control HAP other than mercury from coal-fired plants.
Summary of Positions on Non-mercury HAP. There is disagreement among the stakeholders regarding
EPA's authority to set a MACT standard for non-mercury HAP. The Environmental and State and Local
Agency Stakeholders (except Texas) believe that EPA has the obligation to set such standards. Industry
and Texas cite section 112(n)(l)(a) and believe that EPA's failure to make a health determination for non-
mercury HAP precludes EPA from regulating anything but mercury. All stakeholders agree that the
available data for the non-mercury HAP could be strengthened, although the Environmental Stakeholders
Note: The State and Local Agency Stakeholders include POM in both the fine particulate HAP and the
organic HAP groupings and believe that both good combustion and particulate controls are necessary to
minimize POM emissions.
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and State and Local Agency Stakeholders (except Texas) believe the data for metals are sufficient to
establish MACT floors. The Environmental Stakeholders further believe the data are adequate to set
emission limits for all non-metal HAP. However, if EPA determines that current data for these pollutants
are insufficient, the Environmental Stakeholders also support EPA conducting further data collection to
enable the development of MACT limits for non-metal HAP. However, the State and Local Agency
Stakeholders (except Texas) take a different approach. They believe EPA can derive MACT floors from
the use of surrogates and existing NSPS and RACT determinations for relevant criteria pollutants, and the
beyond-the-floor limits from the use of BACT/LAER determinations for relevant criteria pollutants.
OIL-FIRED UNITS
The issue is how to set MACT standards for oil-fired generators. This issue encompasses all of the issues
that have been raised for coal-fired generators, namely what pollutants must be regulated, the required
level and format of the floor for the standards, what compliance methods are required, and how much
time is permitted for existing sources to meet the MACT standards once promulgated. The stakeholders
have differing views on these issues.
Stakeholder Positions
Environmental Stakeholders. The EPA's December 20, 2000 Notice of Regulatory Finding listed coal-
and oil-fired electric steam generating units as a source category under section 112(c). Section 112(c)(5)
requires that "emissions standards under [section 112(d)] for the category or subcategory shall be
promulgated." Section 112(d) requires regulation of all HAP for each listed category or subcategory of
major sources. The Environmental Stakeholders read that the District of Columbia Circuit Court further
held, in National Lime Ass 'n v. EPA, that section 112(d) defines a "clear statutory obligation" on the part
of EPA "to set emission standards" for all the HAP listed in the statute at section 112(b). If the EPA finds
that the data are inadequate for setting standards for all of the non-mercury HAP, then the EPA should
immediately gather additional data, using its authority under section 114 of the CAA or through other
means. However, the Environmental Stakeholders emphatically believe that the nickel emissions data for
oil-fired units is adequate for the purpose of setting emission standards.
The Environmental Stakeholders believe EPA should set a MACT floor for nickel emitted by oil-fired
units. The Environmental Stakeholders lack information as to whether oil-fired units burning lighter than
number 2 oil should be exempt. They conclude that about 90 facilities burn 100 percent oil. The 12 data
points represent about 13 percent of the facilities. Using the top 12 percent of facilities with data would
result in a standard set from the average of the top 2 facilities. On this basis, the MACT standard would
be 26.05 lb/TBtu. If EPA excludes the fabric filter pilot test, the standard would then be 144 lb/TBtu.
Although the Environmental Stakeholders do not have specific MACT floor recommendations for HAP
other than nickel, they recommend EPA establish limits for these materials. An "either/or" standard may
be appropriate provided appropriately stringent targets are set. The concerns previously expressed for
coal also pertain to HAP from oil-fired units (or their surrogates). For new sources, the MACT floor
should reflect the best performing unit. In all cases, the standards for all HAP should be on an output
basis.
Similarly to non-mercury HAP for coal units, a surrogate approach for oil-fired units is acceptable
provided the surrogate reflects the emissions of the represented pollutants, and the surrogate emission rate
represents the calculated floor. A surrogate would at a minimum have to have substantially the same
properties as the grouped pollutants and be controlled by the same mechanism or measures. Compliance
should be based on monthly composite sample of oil, determining a weighted average, and the amount of
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011 used each month. Where particulate controls are in place, additional annual testing of the control
device should be required to determine metal removal efficiency.
Each unit would be required to meet the floor over a quarterly averaging period. There is high variability
in the data set from the small number of data points and seasonal variation in oil use. Providing facilities
a long compliance period allows them flexibility in dealing with variability. Although utilities may prefer
an annual averaging period, such a long time period is not necessary as long as facilities have the ability
to burn less oil as a compliance option. This approach, unlike a tonnage cap, does not rely on historical
data on oil use to establish a standard, which may not be indicative of future use.
Industry Stakeholders. The EPA did not identify specific health concerns associated with HAP
emissions from oil-fired units when it listed those units under section 112(c). Until EPA demonstrates
specific public health concerns, there is no jurisdiction to regulate HAP emissions from these units.
The EPA has stack-test data from 12 of the 130 to 145 oil-fired units. The tests show an extremely broad
range of nickel emissions ranging from 50 lb/TBtu to over 2,167 lb/TBtu, even with similar controls. The
EPA also has limited data on the nickel content of oil that also reflects extreme variability. Similarly,
EPA's data on non-nickel HAP is of even lesser quality such that it is insufficient to set a standard. The
limited available data makes it very difficult, if not impossible, to set a MACT standard that meets the
section 112 achievability and performance requirements. The CAA requires EPA to set a MACT
standard for existing sources based on the "average emission limitation achieved by the best performing
12 percent of the existing sources (for which the Administrator has emissions information)." The same
section states that, for source categories with less than 30 sources, the standard should be based on "the
average emission limitation achieved by the best performing 5 sources (for which the Administrator has
or could reasonably obtain emissions information)." If EPA sets the standard based on the top 12 percent
of all units, it would need data from 16 to 17 units. If EPA chooses not to obtain additional data, it should
establish the MACT using the data it has from all 12 units. It should not set the MACT standard based on
two data points, as has been suggested by some stakeholders, or use only the lowest five stack tests from
the limited data base. Any MACT standard must be based on all relevant data, excluding pilot plant
research testing.
If power plant nickel emissions do pose a risk, the objective should be to reduce the total mass emissions.
The Majority Industry Group holds that the preferred option is for an annual mass-emissions standard.
This approach would allow units greater flexibility, while achieving the same environmental objective.
The group takes the position that the alternative would be to establish a rate-based standard with an
annual compliance period. They argue that most of the oil-fired generators in the country are utilized for
non-baseload purposes. Many have dual-fuel capability. Dual fuel capability is critical for many units to
ensuring reliability from frequent winter gas curtailments. Without this ability, many units would be
forced to retire. Similarly, requiring peaking units to install control devices to meet a short-term emission
rate limit will likely force many units to retire. According to this group, the standard must also be fuel
neutral, based on total heat input, or be output based (i.e., lb/MWh). Finally, low-utilization and small
units should be exempted from applicability based on an amount of fuel burned.
The CEG shares much of the perspective of the Majority Industry Group on these issues. It argues
strongly for a fuel neutral approach, with an annual averaging period and an output-based standard.
State and Local Agency Stakeholders. The State and Local Agency Stakeholders believe that MACT
standards should be developed for HAP from all units which combust oil heavier than light or number 2
oil. There should be no subcategories for power generating units burning heavy oil. Effective particulate
control and good combustion should be the goal of the MACT for heavy-oil combustion. The MACT
requirements should be set for particulate HAP and organic HAP emitted by heavy oil combustion.
21
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Nickel may be appropriate as a representative HAP for the heavy metals in oil. Alternatively, a limit on
fine particulate emissions may be an appropriate surrogate for HAP heavy metals. Carbon monoxide
would be an appropriate surrogate for organic HAP, which are PIC. The State and Local Agency
Stakeholders have not determined a MACT floor limit for nickel. A rate-based standard using energy
output is the preferred form of the standard. A rate-based standard using heat input is also useful, but not
preferred.
If a fine particulate emission rate is used as a surrogate, the MACT floor should be no higher than the
floor for coal (i.e., no higher than 0.030 lb/MMBtu). A "beyond-the-floor" level should also be
considered at the 0.015 lb/MMBtu level. These total particulate limits should be adjusted, if possible, to
create a fine particulate emission limit to reflect the fact that metals in oil, like trace metals in coal,
accumulate in the fine particulate fraction.
Organic HAP should be controlled using CO as a surrogate. The floor should be set no higher than 100
ppm (at 7 percent oxygen). An averaging period between 1 and 24 hours should be considered. BACT
and LAER determinations should be considered for a "beyond-the-floor" MACT limit. Oxidation
catalysts should be considered, but good combustion control should be sufficient in most cases. Carbon
monoxide CEM should be used to determine compliance.
If nickel is used as a surrogate for metal HAP emissions, then a composite oil sample should be tested
monthly, and the efficiency of the fine particulate air pollution control, if any, should be tested annually.
A weighted annual average of the nickel emissions per MWh can be determined based on the monthly
amount of electricity produced, and the rate of nickel emitted can be adjusted by the efficiency of the
particulate air pollution control. If fine particulates are used as a MACT surrogate, then an annual
particulate test would be appropriate, using standard EPA methods and averaging three test runs.
Future BACT and LAER determinations for particulate and CO emissions from new oil-fired units should
be sufficient to reduce HAP levels from new units to lower levels than for existing units, provided New
Source Review (NSR) technology requirements remain for new major units.
Summary of Positions on Oil-fired Units. There is little agreement on the regulation of oil-fired units.
The Environmental and State and Local Agency Stakeholders recommend regulating all HAP (including
nickel) from oil-fired plants. The industry stakeholders question EPA's legal authority even to regulate
nickel, claiming the absence of any specific regulatory finding for nickel, and believe EPA has no legal
authority to regulate any HAP other than nickel from oil-fired boilers. The Environmental Stakeholders
firmly believe the nickel emission data are adequate to set standards and recommend that if EPA makes of
finding of inadequacy, then the EPA act immediately to collect additional data on the other non-mercury
HAP. The State and Local Agency Stakeholders generally consider the data adequate to set standards.
The Industry Stakeholders believe that if EPA regulates nickel, it must use all 12 available data points,
while the Environmental Stakeholders believe that the top 2 data points are sufficient. The State and
Local Agency Stakeholders believe that the MACT limits can be set by evaluating NSPS, BACT,/LAER,
and RACT limits established for surrogates, such as fine particulate (for metals such as nickel). The
Industry Stakeholders support a mass limit with an annual emission rate as an alternative (the latter being
CEG's preference), with both industry groups strongly supporting a fuel neutral annual standard, while
the Environmental Stakeholders support a quarterly averaging period as being sufficient to address
variability. The State and Local Agency Stakeholders support performance standards and annual testing
for HAP metals (using particulate as a surrogate), and continuous monitoring for organic HAP (using CO
as a surrogate).
22
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Appendix A
Membership of Utility MACT Working Group
1
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Name
Constituency
Representing
Bill Becker
State/local/tribal
STAPPA/ALAPCO
Bill O' Sullivan
State/local/tribal
New Jersey Department of Environmental Protection;
STAPPA/ALAPCO
Praveen Amar
State/local/tribal
NESCAUM
David Schanbacher
State/local/tribal
Texas Commission on Environmental Quality (formerly
Texas Natural Resources Conservation Commission or
TNRCC); Environmental Council of the States (ECOS)
Wilson Laughter (alternate: Mike Connolly)
State/local/tribal
Navajo Air Quality Control Program (NAQCP)
John Paul (Co-chair)
State/local/tribal
Regional Air Pollution Control Association/Dayton;
STAPPA/ALAPCO
Patricio Silva
Environmental
Natural Resources Defense Council (NRDC)
Wilma Subra
Environmental
Louisiana Environmental Action Network;
Environmental justice
Michael Shore
Environmental
Environmental Defense
Martha Keating (alternate: Ann Weeksj
Environmental
Clean Air Task Force (CATF)
Felice Stadler
Environmental
National Wildlife Federation
Tom Natan (alternate: John Stanton)
Environmental
National Environmental Trust
Sandra Schubert (alternate: Jim Pew)
Environmental
Earthjustice
Eric Uram
Environmental
Sierra Club Midwest
Jeffrey Smith
Vendors
Institute of Clean Air Companies (ICAC)
Frank Cassidy (alternate: Mark S.
Brawnstein)
Industry
PSEG Power
Charles Goodman (alternate: Larry Monroe)
Industry
Southern Company Generation
William Tyndall (alternate: Michael Geers)
Industry
Cinergy
Robert LaCount (alternate: Ann Berwick)
Industry
PG&E National Energy Group; Clean Energy Group
Bill Bumpers (alternate: Debra Jezouit)
Industry
Baker Botts; Class of 85 Regulatory Response Group
Peter Jonker
Industry
Consultant
Patrick Raher
Industry
Hogan & Hartson
Dick Wilson
Industry
National Environmental Strategies; Consultant
Robert Wyman (alternate: Claudia 0 'Brien)
Industry
Latham & Watkins; Energy for a Clean Air Future
(ECAF)
John Shanahan
Industry
National Mining Association
Michael Rossler (alternate: Quin Shea)
Industry
Edison Electric Institute (EEI)
Lee Zeugin
Industry
Hunton & Williams; Utility Air Regulatory Group
(UARG)
Richard Midulla (alternate: Mike Opalinski)
Industry
Seminole Elec. Coop.; Rural Electric Cooperatives
Dan Cunningham
Industry
Con Edison
David Steele (alternate: C. VMathai)
Industry
WEST Associates
Gene Trisko
Unions
United Mine Workers
Members of the CAAAC are noted in bold.
2
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Appendix B
Summary of Issues and Stakeholder Positions
1
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Summary of Stakeholder Positions
Issue
Environmental
Groups
Majority
Industry Group
CEG
WEST
Associates
ICAC
State/local
Air
Agencies
Texas
Subcategories for
mercury
-Coal
FBC
IGCC
All others
-Oil
-Coal
Bit
Hot stack
Sat stack
Wet stack
Subbit
Lignite
FBC
IGCC (not
within scope of
rule)
-Oil
-Coal
Bit/subbit
Lignite
FBC
-Oil
-Coal
Bit
High CI
Low CI
Subbit
High CI
Low CI
Lignite
FBC
-Oil
-Coal
Bit
Subbit
Lignite
FBC
-Oil
-Coal
Bit/subbit
Lignite
-Oil
Heavy oil
-Coal
Bit
Subbit
Lignite
FBC
-Oil
Floor levels for
mercury (unless
otherwise noted;
lb/TBtu unless
otherwise noted)
-FBC-0.19
- IGCC - 0.54
- Others - 0.21
-Bit
Hot stack - 3.7
Sat stack -2.2
Wet stack - 3.2
- Subbit - 4.2
- Lignite - 6.5
-FBC-2.0
- Approach to
setting floor
levels
proposed
- To be determined
- Bit - 90% red.
- Subbit - 70% red.
- Lignite - TBD
- FBC - TBD
- Bit/subbit -
range from 0.4
to 0.6 or 90%
removal for
mercury; 0.03
lb/MMBtu for
PM; 90%
removal for
S02; 100 ppm
for CO
- Lignite -
TBD
Beyond-the-floor
for mercury
- Beyond-the-floor
levels
recommended for
IGCC units
- No beyond-the-
floor levels
- EPA's analyses
are not complete
- Will require
significant
further
analysis, but
- No beyond-the-
floor levels
- EPA' analyses are
not complete
- Limits specified
are beyond-the-
floor
- Provided
criteria for
mercury; use
BACT levels
2
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Issue
Environmental
Groups
Majority
Industry Group
CEG
WEST
Associates
ICAC
State/local
Air
Agencies
Texas
emerging
technologies
look
promising
for surrogates
(e.g., 0.015
lb/MMBtu for
PM; 95% for
S02)
Format of
mercury standard
- Output-based
emission rate
- No percent
removal unless
standard is
equivalent to
recommended
floor levels
- Less stringent of
lb/MMBtu or
percent removal
- Less
stringent of
emission rate
(output-based
preferred) or
percent
removal
- Less stringent of
lb/MMBtu or
percent removal
- Less stringent of
lb/MMBtu or
percent removal
- Less
stringent of
emission rate
(output-based
preferred) or
percent
removal
- % reduction
limit or
concentration
limit
Compliance
method
(monitoring) for
mercury
- Mercury CEM
- EPA Method
101A
- EPA Method
101A until
CEM
performance is
satisfactory
- EPA Method
101A
- Assume CEM
will be available
- EPA Method
29A;
transition to
CEM for
mercury;
annual test for
PM; CEM for
S02 and CO
Compliance time
- As required by
CAA (3 years plus
1 allowed under
Title V)
- 3 years is too
short - 5-8 years
likely to be needed
- 3 years is too
short - 5-8 years
likely to be needed
- Extension of
time beyond
the 12/15/07
deadline can
be considered
if justified by
scope of
retrofits
3
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Issue
Environmental
Groups
Majority
Industry Group
CEG
WEST
Associates
ICAC
State/local
Air
Agencies
Texas
Non-mercury
HAP
- Should be
regulated
- Surrogates may
be acceptable
(e.g., fine PM for
metals; S02 for
acid gases)
- Should not be
regulated
- Current
determination
does not
provide legal
authority
- If EPA does
so, surrogates
should be used
- Should not be
regulated
- No position
whether EPA
should regulate
- Surrogates (PM
for metals; S02 for
acid gases) should
be used
- Should be
regulated
- Surrogates
should be used
(PMfor
metals; HC1 or
S02 for acid
gases; CO for
organics)
- Should not be
regulated
Averaging period
- 30-day rolling
average
- Annual stack test
(biennial for small
sources)
- Annual stack
test
- Annual stack test
(biennial for small
sources)
- 30-day rolling
average
- Quarterly
stack test,
averaged
annually
(rolling 4-
quarter
average)
- Once CEM
are available,
30-day or 12-
month rolling
average
Compliance unit
-Unit
- Facility (allows
emissions
averaging among
units at same
facility)
- Facility
- Facility (allows
emissions
averaging among
units at same
facility)
- All coal-
burning units
in same
subcategory at
a facility
Oil-fired units
- Limits for nickel
and other non-
mercury HAP
- No legal authority
to regulate
-If EPA decides to
-If EPA
decides to
regulate
- No legal authority
to regulate
-If EPA decides to
- Limits for
PM and CO
for heavier
4
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Issue
Environmental
Groups
Majority
Industry Group
CEG
WEST
Associates
ICAC
State/local
Air
Agencies
Texas
regulate nickel,
nickel, prefer
regulate nickel,
than No. 2 oil;
prefer an annual
an output-
prefer an annual
nickel can be
mass-based
based annual
mass-based
used instead of
standard to
standard; fuel-
standard to
PM; output-
maximize
neutral to
maximize
based standard
flexibility;
utilize gas as a
flexibility;
preferred
otherwise, input-
compliance
otherwise, input-
based standard with
alternative to
based standard with
12-month
address
12-month
compliance period
emissions
compliance period
Variability
- Combination of
- MACT floor must
- MACT floor
- MACT floor must
- Variability
average of top
consider variability
must consider
consider variability
primarily
12% of sources
under worst
variability
under worst
addressed
and 30-day rolling
foreseeable
under worst
foreseeable
through more
average
circumstances
reasonably
circumstances
frequent
adequately
- ICR Part III stack
foreseeable
- ICR Part III stack
testing and
addresses
test data do not
circumstances
test data do not
annual
variability
represent the
reasonably
foreseeable worst-
case level of
performance or
even average
performance of the
units tested
- Floor
recommendations
include
consideration of
fuel variability;
variability from
other causes, such
- Recommend
options for
how to
address
represent the
reasonably
foreseeable worst-
case level of
performance or
even average
performance of the
units tested
- Floor
recommendations
include
consideration of
fuel variability;
variability from
other causes, such
averaging (or
CEM)
- Additionally,
provide a
factor of 2
compliance
margin on the
average of the
best 12% of
the test data
5
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Issue
Environmental
Groups
Majority
Industry Group
CEG
WEST
Associates
ICAC
State/local
Air
Agencies
Texas
as sampling and
monitoring,
operational, and
plant-to-plant, also
need to be
addressed
as sampling and
monitoring,
operational, and
plant-to-plant, also
need to be
addressed
6
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Appendix C
Stakeholder Position Papers
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Utility MACT for Coal- and Oil-Fired Electric Utility Boilers
Recommendations by:
Clean Air Task Force, Environmental Defense, National Environmental Trust, National Wildlife Federation, Natural
Resources Defense Council
Submitted September 9, 2002 (revised September 20, 2002)
MERCURY MACT FOR COAL-FIRED ELECTRIC GENERATING UNITS
A. Subcategories
Recommendation: Three "boiler type" subcategories are recommended: fluidized bed combustors,
conventional boilers, and coal gasification.
Rationale: Based on the information provided to the Utility Working Group there appears justification for
treating conventional boilers differently than fluidized bed combustors and coal gasification units because
they are uniquely different systems.
Other subcategories are not appropriate, especially subcategorizing by fuel type, because fuel type does
not represent a "class, type or size" distinction, as defined under Section 112 of the Clean Air Act.
B. Emission standards
a. New sources
Recommendation: We recommend that for new sources, the MACT for mercury should reflect the best
performing unit in each boiler type subcategory, except for coal gasification units. For these units, given
that cost-effective technology is commercially available and has been demonstrated in industrial
applications, a 95% control level or greater for these units is appropriate.
b. Existing sources
Recommendation: We recommend an output based emission rate standard, calculated using the following
input based rates for each of the proposed boiler type subcategories and the boilers' specific heat rates
efficiencies:
FBC boilers (averaged over 4 units—the 5th unit appears to be
an outlier and thus should not be included)
0.19 lbs/TBtu
Conventional boilers (averaged over 7 units)
0.21 lbs/TBtu
Coal gasification (beyond-the-floor)
0.54 lbs/TBtu (90% control)
Rationale for emissions standards for FBC and coal gasification units: For fluidized bed combustors,
four of the five "MACT-floor" units measured mercury emissions ranging from 0.08 to 0.46 lbs/TBtu; the
fifth unit measured emissions at 3.97 lbs/TBtu (it was equipped with a CS-ESP whereas all the other units
had baghouses installed.). Setting a standard at 0.95 lbs/TBtu (the average over the five FBC units
measured) would not have the desired effect that a MACT standard should have: It would allow more
mercury to be emitted than is currently measured at existing units. For this reason, a standard more
1
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stringent than the 0.95 lbs/TBtu would be appropriate. Averaging the emissions over the top four units
would be one possibility, which would result in a MACT floor of 0.19 lbs/TBtu, or 92% reduction.
For coal gasification units, demonstrated cost-effective technology is commercially available that would
allow these units to get significant mercury reductions. Carbon filter beds for metals cleanup from syngas
have already been demonstrated on industrial gasification units. In addition, the U.S. Department of
Energy has already completed an engineering analysis for installation of a carbon filter bed at Tampa
Electric's Polk Station that would achieve a 99% mercury removal at a very reasonable cost. A 90%
beyond the floor control level for coal gasification units is appropriate given the likely ease with which
units can meet this level. New integrated gasification combined cycle units are being proposed and far
more are likely in the future. Thus, without a mercury emission standard, this will be a source category of
increasing concern with respect to mercury emissions.
C. Format of Standard
a. Input versus output
Recommendation: We recommend an output-based standard (lbs/MWh) using net generation as reported
to EIA Form 767.
Rationale: An output-based standard rewards efficiency and provides utilities with compliance flexibility
by adding efficiency to the mix of ways to meet an emission limit. Given that current boilers operate, on
average, at 30% efficiency significant gains can be made if the Agency takes steps to promote increased
efficiency through establishment of output based emissions standards. For example, analyses completed
by DOE found plants that raised their heat rates from 30% to 36% increased their efficiency by 20%. An
output based standard also most closely reflects the spirit of Sec. 112, where it was Congress' intent to
establish a toxics regulatory program that encouraged investment in compliance methods in addition to
stack controls, including process changes, work practice standards, etc., to meet a new emission limit.
b. Percent reduction versus emission rate versus both
Recommendation: We recommend the use of an output-based emission rate that would apply to each
category/subcategory of units.
Rationale: We believe that output-based standards promote efficiency, as described above. In addition,
setting an output-based emission rate takes into consideration already installed equipment that captures
mercury; and lends itself to more reliable and less burdensome compliance monitoring than what would
be required through alternate approaches like percent removal (which would require a combination of
coal sampling and stack testing, raising verification/accuracy issues).
Not only would compliance monitoring be more difficult under a percent reduction standard, it would also
be more burdensome to industry, thereby potentially discouraging coal blending or switching as a control
option. This is a crucial consideration given that historically power producers have relied heavily on fuel
switching as a cost effective regulatory compliance strategy.
c. Alternate EITHER/OR standard:
Recommendation: We recommend against an either/or approach (i.e., the facility chooses whether to
meet an emission rate or a percent reduction requirement). .
Rationale: Our analysis of the ICR data shows that the percent reduction approach is always less
stringent than the emission rate approach (this holds true for nearly every power plant) for bituminous and
subbituminous coals. For lignite coals, under the top 12% scenario there are a few power plants where
2
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the emission rate (4.01 lb/Tbtu) is less stringent than a percent reduction scenario (70%). This is because
they already are achieving an emission rate lower than 4.01 lb/Tbtu. In these instances, the plants would
actually be allowed to emit more than they are emitting now.
If EPA is inclined to promulgate an either/or standard, it should consider appropriately stringent targets to
avoid this effect.
D. Averaging period
Recommendation: We recommend using a 30-day averaging period to take into account variability that
has been measured in stack tests.
Rationale: A 30-day averaging period addresses the inherent variability found in mercury flue gas.
EPRI's April 14, 2002 presentation on the initial results of its SCEM data showed that as averaging times
increased (from hourly to daily and then over several days), variability decreased. The 30-day averaging
period will provide facilities an even longer timeframe over which to meet the emission rate.
E. Compliance monitoring methodts)
Recommendation: We recommend the use of continuous emissions monitors (CEMs) for mercury.
Rationale: It is the most accurate method for measuring stack emissions, and given the variability that has
been observed through short term stack tests, and the verification/accuracy issues observed while using
combined coal sampling and stack testing (to measure % reduction), CEM's are the best tool.
Several mercury CEMs already are commercially available. A project underway at EPRI uses a mercury
CEM that takes measurements at 2.5 minute intervals. While there are some technical issues that need to
be worked out (specifically the issue re: frequent oversight to ensure that the equipment is functioning
properly) the compliance deadline of December 2007 gives manufacturers ample time to perfect the
technology and to develop several CEM options for the industry.
MACT FOR NON-MERCURY HAZARDOUS AIR POLLUTANTS FOR COAL- AND OIL-FIRED
ELECTRIC GENERATING UNITS.
A. Emission Standards
We firmly believe that EPA has a clear statutory duty to set emission standards for all of the non-mercury
HAPs emitted from coal- and oil-fired power plants.
Recommendation: If the Agency finds that the data are inadequate for the purpose of fulfilling its
statutory duty of setting standards for all of the non-mercury HAPs, we recommend that EPA
immediately initiate efforts to gather additional data, using its authority under section 114 of the Act or
through other means (e.g., state emissions tests data), in order to meet its legal requirement.
Rationale: EPA's December 20, 2000 Notice of Regulatory Finding, 65 Fed. Reg. 79825 (Dec. 20,
2000), had the legal effect of listing coal- and oil-fired electric steam generating units as a source category
under section 112(c). See UARG v. EPA, No. 01-1074, (D.C. Cir. July 26, 2001)(order dismissing
industry's challenge to the Notice of Regulatory Finding, on the grounds that "judicial review of the
listing of a source category under section 112(c) of the Act is not available until after emission standards
are issued.") The listing of these electric generating units had the legal effect of triggering the
requirement in section 112(c)(5) of the Act that "emissions standards under [section 112(d)] for the
3
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category or subcategory shall be promulgated ..." Section 112(d) requires that regulation of all HAPs is
required for each listed category or subcategory of major sources. The D.C. Circuit further held, in
National Lime Ass 'n v. EPA, 233 F.3d 625, 634 (D.C. Cir. 2000), that section 112(d) defines a "clear
statutory obligation" on the part of EPA, "to set emission standards" for all the HAPs listed in the statute
at section 112(b), for the enumerated major source categories.
B. MACT Floor for Existing Sources
Currently, we do not have recommendations for specific MACT floor levels for pollutants other than non-
mercury metals emitted by coal-fired electric generating units. Similarly, we do not have
recommendations for MACT floor levels for pollutants other than nickel emitted by oil-fired electric
generating units.
Recommendation: We believe that the available stack test data are sufficient to support a floor for 'non-
mercury HAP metals' emitted by coal fired units and recommend that the Agency use these data to set
emission standards for all of the non-mercury HAP metals.
A floor for the non-mercury HAP metals emitted by coal-fired units is represented by the average of the
best performing 12 percent of the 30 power plants tested. Based on these data we recommend a MACT
floor in the form of an output-based emission rate that would reflect a 99 percent removal for all metals
(or each non-mercury HAP metals groups. See section D.b. below for a discussion of an alternate
surrogate approach). Alternatively, an emission rate could also be set for each individual metal based on
measured stack test data. The table below lists the input-based emission rates that represent the average of
the best performing 12 percent for the tested units from which an output-based standard can be calculated.
Metal
Emission Rate (lb/Trillion Btu)
Antimony
0.15
Arsenic
0.24
Barium
1.34
Beryllium
0.01
Cadmium
0.16
Chromium
0.91
Cobalt
0.19
Copper
1.3
Lead Compounds
0.34
Manganese
2.38
Molybdenum
0.61
Nickel
1.34
Selenium
0.19
Vanadium
0.58
For oil fired units, set a MACT floor for nickel emitted by those units.
About 90 facilities burn 100% oil. With 12 data points, we have data for about 13% of the facilities. The
top 12% of the facilities for which we have data would result in a standard derived from the top 2
facilities. Thus, the standard would be based on the average of the top 2 facilities (1.60 and 50.50
lbs/trillion Btu). The MACT standard would be 26.05 lbs/tBtu.
If EPA determines that the emissions data from the top performing facility should not be used to calculate
the floor because it is a pilot test, the standard would be the average of top second and third performers
(50.50 and 238.00 lbs/tBtu). The MACT standard would be 144 lbs/tBtu.
4
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C. MACT Floor for New Sources
Recommendation : For new sources, the MACT floor for the non-mercury HAPs should reflect the best
performing unit.
D. Format of the Standard
a. Input v. output
Recommendation : We prefer an output-based standard and recommend exploring the feasibility of
establishing such a standard for the non-mercury HAPs (or groups of non-mercury HAPs). We further
recommend the use of a nickel output-based standard for oil-fired units.
Rationale: An output-based standard rewards efficiency which in the case of electric generating units, can
play a significant role in determining a unit's emissions in relation to its electricity generation. Improving
efficiency should be a compliance option, much like burning alternate fuels or installing control devices.
Only through issuance of an output-based standard will this more likely be the case.
b. Alternate Surrogate Standard
We understand that in previous rulemakings the Agency has chosen to group pollutants and establish
surrogate measures as an alternate approach to setting individual emission rates. A surrogate approach to
regulating non-mercury HAPs could also be acceptable, but only if it can be shown that the surrogate
measure reflects the actual emissions of the represented pollutants, and the surrogate emission rate
represents the calculated floor. In addition, any surrogate would, at a minimum have to have substantially
the same properties as the grouped pollutants and be controlled by the same mechanism or measures.
Controls could include feed rate or type of coal as well as control technologies.
Recommendation : If a surrogate approach is taken we recommend that the non-mercury HAP metals be
grouped into two categories for the purpose of setting a MACT floor: a 'low-volatility HAP metals'
category and also a 'semi-volatile HAP metals' category. The 'low-volatility HAP metals' group
includes antimony, barium, beryllium, chromium, cobalt, copper, manganese, molybdenum, nickel,
vanadium. The 'semi-volatile HAP metals' group includes lead compounds, cadmium, arsenic and
selenium.
In theory, other groupings of non-Hg HAPs make sense, based on the similar properties within the group.
These groupings could include 'Acid Gases', 'Radionuclides,' 'Organics other than dioxins/furans,' and
'Dioxins/Furans.' For acid gases, we believe that additional data must currently be available. For
example, there are emission factors for HC1 and HF that are used to calculate acid gas emissions for the
purpose of reporting to the Toxics Release Inventory. These emission factors required the development
of an underlying dataset that could be made available to EPA. We urge EPA to take all necessary steps
required for the control of acid gas emissions.
c. Alternate Emission Rate/ Percent Reduction Standard
An 'either/or' standard may be appropriate if appropriately stringent targets are set. The concerns noted
above relating to the either/or form of the mercury standard would also pertain to the non-Hg HAPs (or its
surrogates).
d. Averaging Period
Recommendation: We recommend a 30-day averaging period for the non-mercury HAPs emitted by
coal-fired units, to be consistent with the averaging period for mercury.
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For oil-fired units, each unit would be required to meet the floor over a quarterly averaging period.
Rationale for oil-fired units: There is high variability in the data set from the small number of data points
and seasonal variation in oil use. Providing facilities a long compliance period allows them flexibility in
dealing with variability and in finding cost effective ways to comply with the standard. Although utilities
may prefer an annual averaging period, such a long time period is not necessary as long as facilities have
the ability to burn less oil as a compliance option. This approach, unlike a tonnage cap, does not rely on
historical data on oil use to establish a standard, which may not be indicative of future use.
E. Compliance Monitoring Method
Recommendation : In the case of individual emission standards for the non-mercury HAPs emitted by
coal-fired units, we recommend that EPA devise a monitoring system of sufficient frequency to ensure
compliance with the standard.
If a surrogate approach is taken, we recommend continuous emission monitoring of the surrogate
pollutant (e.g., S02 for the acid gases). In addition, to ensure that the surrogate reflects each individual
HAP emission rate (or percent reduction, depending on the format of the standard), a periodic compliance
test should be required (at least semi-annually) during which each pollutant should be measured as well as
the surrogate so there are data for a direct comparison.
For oil-fired units:
a. where no particulate controls are in place: (1) analyze monthly composite sample of oil; (2)
determine annual weighted average based on rolling 12 months; and (3) weight average by amount of oil
used each month.
b. where particulate controls are in place: In addition to the oil sampling, (1) do annual testing of
control device to determine metal removal efficiency, and (2) apply that efficiency factor to the metal
emission rate as determined.
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EXPLANATION OF INDUSTRY STAKEHOLDER RECOMMENDATIONS TO EPA
HAPs To Be Regulated
EPA's authority under the MACT provisions of §§ 112(c) and (d) is limited to regulating mercury
emissions from coal-fired plants. This limitation results from the unique way electric utility steam
generating units are treated under § 112 of the Clean Air Act and in particular § 112(n)(l)(A). Section
112(n)(l)(A) requires EPA to study the hazards to public health reasonably anticipated to occur as a result
of hazardous air pollutant (HAP) emissions from electric utility steam generating units. EPA is then to
regulate as is "appropriate and necessary" to protect public health. EPA's decision to list coal- and oil-
fired electric utility steam generating units under § 112(c) was based on a conclusion that mercury
emissions from coal- and oil-fired power plants presented public health concerns. EPA did not identify
public health concerns associated with the emissions of any other HAP. Thus, EPA's December 2000
listing decision must be viewed as only involving mercury emissions from coal-fired plants. EPA can
regulate non-mercury HAPs only if it concludes that emissions of those HAPs pose an unacceptable risk
to human health and further concludes that controlling those emissions will reduce human health risks to
acceptable levels.6
Even if EPA identifies health concerns associated with non-mercury HAPs, historical sampling data are
insufficient either to characterize non-mercury HAP emissions from coal- or oil-fired units or to set
MACT floors. Before EPA can regulate these compounds it must fill existing data gaps by collecting
emissions data at a representative group of electric utility steam generating units using validated sampling
and analytical methods. Suggestions for grouping non-mercury HAPs or designating "surrogate"
compounds are therefore premature and inappropriate.
Subcategorization
The legislative history of the Clean Air Act makes clear that Congress intended EPA to distinguish
among classes, types, and sizes of sources under three core circumstances: when differences among
sources affect (1) the feasibility of air pollution control technology; (2) the effectiveness of air pollution
control technology; and (3) the cost of control. Subcategorization is the primary mechanism that allows
the agency to account for the fact that distinctions among classes, types and sizes of sources may have a
very real impact on the feasibility of a given control technology, the effectiveness of that control
technology, and the cost of control. EPA's past practices and case law support the use of this discretion.7
The industry stakeholder group believes that the primary objective for subcategorization is to formulate a
MACT standard that recognizes and allows for the continued use of the wide range of coals found in the
U.S. There exists no one fuel in sufficient quantities and availability that can be used by all parties. The
recommended subcategorization scheme outlined in the following paragraph, coupled with the flexibility
of alternate standards (emission rate limit or percent reduction) would work to achieve this objective.
The source category of electric utility steam generating units must be subcategorized before MACT limits
are set. Subcategorization is justified and required for a number of reasons. First, oil- and coal-fired units
should be placed in different subcategories because the fuels are dissimilar and produce very different
6 Additional information was presented in the paper "Legal and Policy Basis for EPA to Forego
the Regulation of Non-Mercury HAP Emissions From Utility Boilers", by Wyman, O'Brien, and Gertler,
August 5, 2002.
7 Additional information was presented in the paper "Basis and Rational For Potential
Subcategorization Of Coal-Fired Electric Utility Steam Generating Units," by Geers and O'Brien, March
8, 2002
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emissions. Second, for coal-fired units, fluidized bed combustion (FBC) units must be separated from
conventional boilers because they employ a fundamentally different process for burning coal and they
produce emissions with different mercury characteristics. (IGCC units do not fall within the source
category because the coal gasification portion of an IGCC unit does not meet the definition of an electric
utility steam generating unit.) Third, conventional boilers (pulverized coal, cyclones) must be
subcategorized by the rank of coal burned (bituminous, subbituminous and lignite) because combustion of
those coal ranks produces emissions with widely varying percentages of the three relevant species of
mercury (elemental, particulate and gaseous ionic). Fourth, process differences related to temperature can
affect emission characteristics and justify further subcategorization. Fifth, coal chemistry (e.g., content of
mercury, sulfur and chlorine) affects the species of mercury created during combustion and hence support
further subcategorization.
MACT Floors
MACT floors for these subcategories must account for the inherent variability in mercury emissions from
the best performing units and from the use of different types of fuel. There are numerous methods for
addressing variability, including a correlation approach offered by UARG and a statistical approach
presented by EPA. None of the methods that have been presented at the Working Group meetings fully
accounts for all the variability in mercury emissions from a coal-fired plant. The approach offered by
UARG addresses fuel variability by using correlations developed by EPRI from the Part III ICR data and
then using these correlations and the coal data from 1999 for the best performing units to produce
cumulative distributions of emissions for 1999 from those units. MACT floor levels in the following
tables look at the performance of the best 12% of the plants tested in each category (or the average of the
five best performing units for subcategories with less than 30 units) at the 95th percentile of each
cumulative distribution. However, to fully understand the capabilities of the best performing plants, the
MACT floor must consider both the fuel variability and variability from other causes such as sampling
and monitoring, operational and plant to plant variability.
New Sources
Mercury reductions at all existing coal-fired power plants, including the "best" performing units, result
from control equipment that was installed to reduce the emissions of other pollutants. New coal-fired
power plants are subject to stringent regulation under a number of Clean Air Act provisions
including new source performance standards (NSPS). These requirements cause new plants to install
high efficiency particulate removal devices, scrubbing systems and NOx reduction devices. These
technologies are found on existing units that achieve the "best" mercury control. Additional control
strategies that specifically address mercury, such as activated carbon injection, are developmental and are
not commercially available. As a result, the MACT floor for new units should reflect the mercury control
co-benefits of NSPS devices and should not be based on speculation about the potential capability of
developmental technologies. The MACT floor for new units should reflect the same categories and be at
least as stringent as the MACT floor for existing units and must address the variability in mercury
emissions of the best performing units.
Bevond-the-Floor Regulation
Based on information in EPA's Utility and Mercury Studies, it is unlikely that a case can be made for
regulation beyond the MACT floor. The remaining mercury emissions from coal-fired power plants will
be small and constitute a very small percentage of the overall mercury pool. Hence, further control will
have little incremental effect on public health while the costs of achieving additional control will be very
high.
Insufficient information has been presented to draw a definitive conclusion on whether regulation is
needed beyond the MACT floor. Beyond-the-floor analyses require EPA to look at the cost of achieving
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more stringent emission reductions, any non-air quality health and environmental impact of further
reductions, and energy requirements. Thus, EPA must complete (1) its IPM runs to assess the cost
impacts of regulation, (2) its REMSAD (or equivalent) runs to understand mercury deposition and
possible health effects, and (3) an assessment of the energy requirements of additional control. Moreover,
because beyond-the-floor control technologies (e.g., activated carbon) are generally not commercially
available, EPA must carefully assess the cost and actual availability of those technologies. Only when
this work is concluded, and made available for public comment, will EPA be in a position to make a
reasoned decision on whether regulation is needed beyond the MACT floor.
Industry does note however that at the May 13, 2002 workgroup meeting, EPA presented some initial
IPM modeling results. The modeling process and the assumptions used were discussed in greater detail at
a dedicated modeling meeting held on May 30, 2002. During both meetings industry expressed concerns
with the accuracies of the modeling and its assumptions. These concerns were documented in
presentations and papers provided to the entire workgroup.8 9
Format of Standard and Compliance Monitoring Method
MACT standards should afford plants flexibility in demonstrating compliance with the emission limits.
The MACT standard for electric utility steam generating units should specify both an emission rate limit
and a percent reduction. Plants should be given the option of demonstrating compliance with either of
these limits. The emissions rate limit should be based on heat input and not energy output. Sources
already have a powerful incentive to maximize fuel efficiency because fuel costs account for over three
quarters of variable production costs. In addition, regulations specifying output-based limits would
become overly complex because of the many technical details that would have to be addressed.
(Examples include the cogeneration of steam, common systems where multiple boiler feed one or more
steam turbines, and the need for appropriate instrumentation.)
The mercury health concerns identified by EPA in its December 2000 listing decision are chronic in
nature and not acute. Accordingly, short compliance averaging periods (e.g., hourly or daily) are
unnecessary. In addition, the only currently approved method for sampling and analyzing total mercury is
EPA's Method 101A—a cumbersome and labor-intensive sampling method. While work is ongoing to
develop mercury CEMs, those efforts have yet to produce a validated instrument that can be reasonably
maintained. Compliance should be monitored using EPA Method 101 A. The Ontario Hydro method
could be specified as an alternative compliance method, but the lack of need for speciation data suggests
the choice of the simpler Method 101 A.
The scheduling and performance of compliance testing should provide utilities sufficient flexibility to
assure system reliability and economic dispatch of their systems. Title V permits will include compliance
assurance monitoring (CAM) plans for periods between compliance tests. There should be an initial
compliance demonstration followed by annual testing for large sources and biennial testing for small
sources to demonstrate compliance with mercury MACT limits.
EPA should avoid assuming, as some Working Group members have suggested, that mercury CEMs will
be available when compliance is required. EPRI projects indicate that insufficient progress has been
SUARG paper "Comments on Selected EPA assumptions Regarding Mercury Control Costs"
presented at the June 3, 2002 Utility MACT Workgroup Meeting
4 "Comments concerning EPA's Initial IPM Modeling For The Utility MACT Workgroup, " by
Geers and O'Brien, May 24, 2002
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made in the last few years with respect to mercury CEMs achieving the reliability and accuracy needed
for compliance monitoring. EPRI and DOE continue to have their automated CEMs projects
continuously staffed in order to achieve reasonably reliable results.
Compliance Unit
There is a precedent in other MACTs to require compliance on a facility basis. Therefore, compliance
with MACT limits should be on a facility basis rather than on a boiler-by-boiler basis. A facility or unit-
by-unit standard should result in the same amount of mercury being emitted by the facility. A facility-
based limit would allow some flexibility in unit operation without any adverse impact on total emissions.
Compliance Time
The presumptive three-year compliance period contained in § 112(d) is too short to bring all coal-fired
units into compliance with mercury MACT limits. The reasons why a three-year compliance period is too
short are numerous, including: the amount of total electric generation affected by this rulemaking (some
325,000 MWe of capacity), the need to provide reliable electric service while mercury control retrofits are
ongoing, the time needed to permit, assess, design, procure and install the equipment needed to meet the
MACT limit (for example, it will take more than three years to design, procure and install a scrubber,
should that be the chosen control option), the availability of control equipment and raw materials (like
activated carbon and baghouse bags), the limited supply of construction equipment and skilled craft labor
to install mercury control equipment, and the time needed for start-up testing. Additionally, the
installation of necessary mercury controls at coal-fired electric generating plants must be integrated with
existing and new particulate, sulfur dioxide and nitrogen oxide controls over the next decade. EPA
should conduct an analysis of the time needed for all utilities to comply with new MACT limits while
maintaining a reliable electric supply in the United States.
Based on the above considerations, and particularly for those facilities that would be required to make
major capital expenditures (e.g., installing a scrubber), it will take five years or more to bring all coal-
fired electric utility steam generating units into compliance with a mercury MACT limit. The time for
compliance could be even longer if more stringent MACT limits than those presented in the attached
tables are imposed, as the technologies required for high levels of control are still under development.
Oil-Fired Plants
Similar to the discussion of non-mercury HAPs above, EPA did not identify specific health concerns
associated with HAP emissions from oil-fired units when it listed those units under § 112(c). See 65 Fed.
Reg. 79,830 col. 2 (Dec. 20, 2000). Until EPA identifies and factually supports specific public health
concerns associated with the emission of a given HAP, the Agency does not have jurisdiction to regulate
that HAP emission from oil-fired units. Further, EPA's limited database of 13 stack tests is inadequate to
establish a MACT standard for a source category with 140+ units.
Additional Information from EPA
Industry members of the Working Group agree that additional information from U.S. EPA would
facilitate understanding of the complex issues involved in the utility MACT standard-setting process.
Additional information that should be provided to the Working Group includes, for example:
1. Further analyses of statistical variability as discussed in the August 8, 2002, memorandum
from Jeffery Cole to William Maxwell;
2. Additional analyses of statistical variability taking into account variability reflected in the
ICR coal data;
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3. IPM modeling results for alternative MACT floors, including projected cost and coal market
impacts;
4. REMSAD modeling results for alternative MACT floors; and
5. Analysis of the reliability implications of achieving alternative MACT floors.
Subcategorization Approach 1 - Coal Rank
Subcategory
Stack Limit, lb/1012
Btu*
Overall Reduction
Bituminous
2.2
73%
Subbituminous
4.2
31%
Lignite
6.5
47%
FBCs
2.0
91%
Subcategorization Approach 2 - Coal Rank and Process
Subcategory
Stack Limit, lb/1012
Btu*
Overall Reduction
Bituminous - Hot
3.7
55%
Bituminous - Sat.
2.2
63%
Bituminous - Wet
3.2
62%
Subbituminous
4.2
31%
Lignite
6.5
47%
FBCs
2.0
91%
* Limits include only a consideration of fuel variability and not other forms of variability.
5
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The
Cloan
Energy
Group
Michael J. Bradley
Director
The Clean Energy Group
47 Junction Square Drive
Concord, MA 01742
3 978-369-5533
JL 978-369-7712
September 6, 2002
Ms. Sally Shaver, Co-Chair
Mr. John Paul, Co-Chair
U.S. EPA Mercury Work Group
Permits/New Source Review/Air Toxics Subcommittee
Clean Air Act Advisory Committee
Washington, D.C.
(via e-mail)
Re: The Clean Energy Group's Position on the Utility MACT Issues
Dear Ms. Shaver and Mr. Paul:
The Clean Energy Group (CEG) appreciates the opportunity to convey its positions to EPA on the issues
that the Agency must resolve in setting MACT standards for electric utility steam generating units.
1. HAPs To Be Regulated
Section 112(c)(2) of the Clean Air Act (the Act) requires EPA to establish emission standards for listed
categories and subcategories of hazardous air pollutants (HAPs). However, Congress elected to address
the electric utility steam generating unit category separately under § 112(n)(l)(A) of the Act. Under this
subsection, EPA is authorized to regulate HAP emissions emitted from electric utility steam generating
units only if the Agency finds that it is "appropriate and necessary" to do so in order to protect public
health. To date, EPA has concluded that such regulation is necessary with respect to mercury emissions
from coal-fired units and, potentially, with respect to nickel from oil-fired units. Although EPA has
indicated that other pollutants may be cause for concern, it has not made a formal determination that it is
"appropriate and necessary" to regulate other HAPs associated with electric utility steam generating units.
The CEG members would be pleased to work with the agency in developing the data and analysis
required for EPA to reach a decision on these other HAPs, but - in contrast to the determination to
regulate mercury - we do not believe that EPA has currently made the case to proceed with regulating
other HAPs.
That said, it is also true that many of the emission reduction strategies necessary to reduce mercury
emissions from electric utility steam generating units will have beneficial effects in reducing other HAPs
from these units. Likewise, emission reduction strategies likely to be employed to meet coming
requirements associated with the federal health standard for fine particulates and federal regional haze
requirements may also have beneficial effects in reducing utility HAPs. Irrespective of EPA's decision to
proceed with a determination on the need to regulate other electric utility HAPs, we encourage the
Agency to think about the multi-pollutant effects of any emission reduction requirement imposed upon
our industry and incorporate both the benefits and costs of these multipollutant effects in the Agency's
regulatory decision making.
During the course of FACA discussions it has been suggested that EPA address the broader category of
electric utility HAPs through the use of "surrogates." If EPA decides to regulate other HAPs from coal
and oil-fired utility generating units, CEG believes that the Agency should use appropriate "surrogates"
for certain classes of HAPs emitted from these units, including metals, acid gases and organic
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compounds. It is important that these surrogates be used not only in the MACT determination process, but
also in the determination of compliance.
2. Subcategorization
As a general rule, CEG members oppose subcategorization. Although the notion of a regulatory regime
that customizes an emission standard for each coal type consumed and technology employed is attractive,
we believe that the practical reality of such a regulatory regime would be the worst form of command-
and-control regulation. As companies that are active in competitive wholesale energy markets, we cannot
tolerate environmental regulations that constrain our flexibility to find the most effective solutions to
environmental problems.
Over the past ten years, there has been a tremendous change in our industry as a result of FERC Order
888 and other federal and state initiatives to encourage competition in both wholesale and retail electricity
markets. In many jurisdictions, operating costs that were once directly passed on to retail customers
through periodically adjusted fuel tariffs incorporated into retail rates are now borne solely by wholesale
generation companies, which have no other mechanism for recovering costs other than through the
wholesale price of energy determined in a competitive market. Among all companies doing business in
these markets, this new dynamic has heightened attention to fuel costs, which account for approximately
75 percent on any generating unit's variable cost. The trend in the industry has been away from long-
term fixed price contracts for coal and other fuels toward contracts of a year or two - at most - as
companies strive to capture these subtle changes in fuel price while using newly developed financial
strategies to hedge against fuel price risk.
At the same time, the compliance flexibility afforded companies through the federal Acid Rain Program
and other emission trading programs has encouraged companies to think of fuel supply as a compliance
option, and today many companies use various blends of coals to optimize their emission performance.
The variability we see in EPA's mercury ICR data, and the role that chlorine content, sulfur content, and
other constituents in coal may play in optimizing the effectiveness of various control technology options
suggest to us that fuel switching and fuel blending may become even more common in the years ahead.
We would oppose any regulation that hampers our ability to quickly optimize performance and cost as
necessary to meet the economic demands of the market and the environmental expectations of the public.
Today, in most jurisdictions, we enjoy the ability to shift among fuel supplies and suppliers at will,
without the need to seek the time-consuming approval of regulators to switch. Schemes that tie emission
rate to fuel type imply a regulator's interest in the fuel being used. We can only imagine the permit
conditions surrounding fuel choice that will be written and the reports on fuel use that will be required to
provide the regulatory community with comfort that the regulatory obligation is being met. This may be
particularly problematic in cases where a unit utilizes more than one fuel category, such as those facilities
that burn blends of bituminous and sub-bituminous coal. In sum, from the perspective of the electric
utilities a large number of subcategories may significantly limit the flexibility to manage a facility's
operational conditions and fuel choice. In the context of a competitive market for supplying electric
generation, operational flexibility and fuel choice are of paramount importance. Overly prescriptive
emissions standards are not consistent with these objectives.
At the same time, we concede that the design and operation of electric utility steam generating units differ
such that certain subcategories should be established before MACT limits are set. CEG believes that one
such subcategory should be Fluidized Bed Combustion (FBC) technology because it uses a unique
combustion system that operates with cooler combustion temperatures that result in much lower mercury
emissions than conventional pulverized coal (PC) boilers. A second subcategory should be PC boilers
that burn lignite coal, in recognition of the high mercury content in lignite, and the reality that few boilers
in limited geographical areas make use of this low-BTU coal. The third subcategory should be PC boilers
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that burn bituminous and/or sub-bituminous coal. The grouping together of bituminous and
subbituminous coals will provide the flexibility needed for coal blending and coal switching.
3. MACT Floor
A MACT floor for the three subcategories of existing sources identified above (i.e., FBC, PC boilers
burning lignite and PC boilers burning bituminous and/or sub-bituminous coal) must be established
through a determination of the "average emission limitation achieved by the best performing 12 percent
of the existing sources" for which emission test data is available. The issue is how to determine the
average performance of the top 12 percent of existing facilities, considering the variability in emissions at
the best performing sources under the worst foreseeable circumstances.
We propose the following approach:
• For existing sources, EPA should first identify the top 12 percent of facilities from the available
database.
• The Agency should then identify the primary emissions control technology used by the facilities
in that group with emission levels at or better than the average for the group.
• EPA should then look to all sources in the database using the identified control technology,
provided the control was well designed and operated.
• Finally, EPA should set the MACT floor such that the floor accounts for operational variability.
CEG does not currently have a view as to how best to account for variability, but believes that the
approach outlined sets forth a reasonable strategy for establishing a mercury MACT floor for
coal-fired power plants that reflects emissions variability under worst-case operating conditions.
With respect to new sources, the Act requires that MACT standards not be less stringent than the control
level achieved in practice by the best controlled similar source. CEG suggests that a similar methodology
to the one described above for setting the MACT floor for existing coal-fired units be applied to new
units. In the case of new sources, however, instead of identifying the control technology used by the best
12 percent of facilities, the emission control technology used by the best performing plant would be
identified. Then, considering all facilities in the database using that technology, the floor would be set
based on some mathematical or statistical measure that reflects inherent operational variability, using, for
example, an average, a median or a 95 percent confidence interval value.
4. Bevond-the-Floor Regulation
Beyond-the-floor analyses will require EPA to weigh cost, energy requirements, and non-air quality
impacts to determine whether a mercury MACT standard stricter than the floor level is achievable. A
number of new technologies for reducing mercury emissions from coal-fired boilers are in various stages
of research and development. Some of these new technologies may prove to be attractive control options
for mercury, based on the results of studies performed thus far. For example, activated carbon injection is
a potentially cost-effective technology for achieving high levels of mercury reduction from coal-fired
electric utility generating units.
5. Format of Standard
As indicated earlier, MACT standards should provide facilities with operational flexibility in
demonstrating compliance with the standards, including flexibility with regard to fuel choice. One option
for the format of the MACT standard for electric utility steam generating units is an emission rate;
another is an emission control efficiency level. One advantage of an emission rate approach as opposed
to an emission control efficiency approach is that the former gives a greater degree of certainty in terms of
emissions. In addition, an emission rate standard would be administratively simple to implement. On the
3
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other hand, if a facility installs MACT controls, the public will expect it to operate at optimal
performance efficiency even if the current coal stock is low in mercury content. A control efficiency
standard could be a better alternative for the utilities if there is a wide variability in the mercury content of
the coal purchased. A third option is a combined standard that allows the opportunity to meet either the
emission rate or the control efficiency. Without specifying the appropriate rate or control efficiency, CEG
supports the either/or approach, since it is most responsive to the need for operational flexibility in
achieving compliance. Additionally, CEG generally supports output-based standards.
With respect to the averaging time for a mercury MACT standard, CEG recommends that a long-term
(i.e., annual) averaging time be adopted. The potential health concerns identified by EPA in its December
2000 listing decision for mercury and in the extensive studies on which that decision is based are believed
to arise from the long-term accumulation of mercury in the environment; thus, there is no demonstrated
need for a short-term averaging period.
6. Compliance Monitoring Method
The ability to comply with a long-term standard typically involves the use of a continuous emission
monitoring (CEM) system. Currently, work is on-going to develop mercury CEMs. To date, however,
mercury CEMs have not been proven to have the necessary accuracy and reliability to be used as a
compliance tool. Until the CEM accuracy and reliability issue is resolved to EPA's satisfaction,
compliance should be monitored using EPA Method 101A for total mercury. This testing should be
performed on an annual basis in conjunction with annual RATA (relative accuracy test audit) testing. To
ensure compliance prior to the availability of mercury CEMs, in addition to annual testing using method
101 A, parametric monitoring of pollution control equipment could be required on a reasonably frequent
basis. For example, appropriate parametric measures such as scrubber slurry rates (gpm) for scrubbed
units or, for units with ESPs, appropriate amp rate, spark rate and/or rapping rate could be considered.
There should be an initial compliance demonstration using Method 101A, as a means to calibrate the
CEM, followed by additional testing that would become less frequent as the accuracy of the CEM is
validated and the transition to this monitoring method occurs.
7. The Compliance Unit
Compliance with MACT limits should be on a facility basis rather than on a boiler-by-boiler basis. In
many cases, the emission control equipment handles multiple units at a facility. A facility-based limit
would allow some flexibility in unit operation without any adverse impact on total emissions.
8. Oil-Fired Units (Nickel)
If EPA finds it appropriate and necessary to regulate nickel from oil-fired units, we recommend,
consistent with the views put forth above, that MACT standards provide facilities with operational
flexibility for compliance, including flexibility with regard to fuel choice. In that regard, we recommend
a rate-based standard, regardless of fuel burned. In many cases, oil-burning units have the ability to burn
natural gas. Use of natural gas as a means to comply with a rate-based MACT standard will increase
operational flexibility while decreasing the amount of nickel emitted.
As mentioned above with respect to the averaging time for a mercury MACT standard, CEG recommends
a long-term (i.e., annual) averaging time for any nickel standard. Possible health effects from nickel, as
from mercury, are believed to arise from the long-term accumulation of nickel in the environment, thus
obviating the need for a short-term averaging period.
That said, CEG shares the views of other stakeholders that the database for nickel raises serious concerns,
both because of its small size and because of the apparent absence of discernable trends.
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Sincerely,
Robert LaCount
for The Clean Energy Group and
PG&E National Energy Group
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Ktic
INSTITUTE OF
CLEAN
AIR
COMPANIES
August 27, 2002
Via Email
Ms. Sally Shaver, Co-Chair
Mr. John Paul, Co-Chair
U.S. EPA Mercury Work Group
Permits/New Source Review/Air Toxics Subcommittee
Clean Air Act Advisory Committee
Washington, D.C.
Re: ICAC Recommendations for Coal-Fired Plants
Dear Sally and John:
The following recommendations for coal-fired facilities assume facility averaging. They are not based on
the "average of the best-performing 12%" of facilities in each subcategory. Rather, they are based on
technology available today, and consider the goals of flexibility and cost-effective mercury reductions.
Although this basis differs from the statutory MACT analysis, the issue of "achievability" and cost-
effective compliance on a wide-spread basis is one the Mercury MACT Work Group has spent a lot of
time on, and is of course central to the compliance efforts of affected sources. Thus, we feel these
opinions will be helpful.
1. There should be four subcategories: bituminous, sub-bituminous, lignite, and fluidized bed
combustors (FBC). Existing control technologies commercially available today exhibit considerably
different performance characteristics for the three primary coals, mainly related to the differing
characteristics of the mercury species generated. Future control technology development is expected
to overcome these differences and permit a higher, more broadly applicable standard.
2. Sources should be allowed to meet either a percent reduction (percent mercury removed as difference
between mercury in coal and mercury emitted from stack) or an emission rate (stack concentration in
lb/Tbtu). An alternative standard allows the greatest opportunity to select among control options to
achieve the most cost-effective compliance, and also does the most to accommodate variability in
coals and control technology performance.
3. The emission rate should be input-based (stack concentration in lb/TBTU) for reasons of ease of
measurement and comparability with other common emission limits (particulate, S02, NOx).
4. The standard for bituminous should be 90% removal or a comparable emission rate. The standard
for sub-bituminous should be 70% removal or a comparable emission rate. These limits can be
achieved. We make no recommendations for lignite or FBC.
5. The averaging period should be 30 days on the assumption (which we believe is valid) that CEMS
will be available before they are needed for use with this rulemaking. A 30-day averaging period
accommodates variability, e.g., coal type, plant operation. If, however, manual measurements are
needed, then we support an averaging time on the order of a year due to the needed turnaround time
and to accommodate the number of samples that might be recognized as constituting an accurate
representation of a given plant's performance.
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6. For new sources, current information and experience supports best achievable control technology
yielding a mercury reduction percentage of 90%.
7. If EPA decides to regulate non-mercury hazardous air pollutants (HAPS), then PM2 5 should be used
as a surrogate for metal HAPS (e.g., cadmium, chromium, and lead). (N.B. some air toxics,
especially selenium and arsenic, could be in the vapor phase). S02 should be used as a surrogate for
HC1 and HF removal, provided a calcium-based scrubber is used for S02 removal. Removal of these
surrogates correlates well with the air toxics indicated.
ICAC appreciates the opportunity to participate on the Work Group and looks forward to assisting the
U.S. EPA as development of this rule progresses.
Sincerely,
Jeffrey C. Smith
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October 22, 2002
STATE AND LOCAL AIR POLLUTION CONTROL OFFICIALS RECOMMENDATIONS
FOR UTILITY MACT STANDARDS (DISCUSSED AT SEPTEMBER 9, 2002 AND
OCTOBER 17, 2002 UTILITY MACT WORKGROUP MEETINGS AND AMENDED
OCTOBER 22, 2002)
PRAVEEN AMAR, NESCAUM
WILLIAM O'SULLIVAN, NEW JERSEY
JOHN PAUL, DAYTON, OHIO
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A. BACKGROUND AND INTRODUCTION
The state and local agency representatives on this working group would like to thank EPA for convening
the group and providing the opportunity to meet and discuss this important MACT standard. We
sincerely appreciate the time, effort, and resources that EPA has devoted to this process. We would also
like to thank our fellow working group members and acknowledge the dedication of many to the process.
Those that participated in the "mini" work groups to address specific issues, and those that authored and
presented various special reports throughout the process are deserving of special thanks. We believe this
has been a useful process and we trust EPA feels the time spent in our discussions will be helpful in its
writing of the Utility MACT standard.
State and local agency participation in the working group was somewhat limited by the size of the
committee. Some Western states have recently indicated an interest in evaluating the utility MACT
workgroup recommendations and may present alternative or supplemental recommendations. We
recommend that EPA consider this Western States submission, as well as any other state or local agency
opinions which may be submitted on this topic. Those of us that have been on the working group have
taken steps to incorporate STAPPA/ALAPCO membership positions into our report,and we have
communicated with our membership on the process throughout the past year.
Regarding the incorporation of STAPPA/ALAPCO positions, cited below from STAPPA/ALAPCO
documents are three references to non-mercury HAPs from utility boilers.
On June 5, 1998, STAPPA toxics committee chair Bliss Higgins of Louisiana sent a letter to EPA
regarding the U.S. Environmental Protection Agency's (EPA) proposed Information Collection Request
(ICR) related to coal-fired electric utilities proposed in the Federal Register on April 9, 1998 (63 FR
17406). In that letter a number of recommendations were made, including one that EPA "should
seriously consider also requiring the analysis of other chemicals of concern in the coal, ash, and flue
gases. Most of the cost of stack testing is related to the labor of obtaining the samples and the supporting
measurements, not the analysis of the mercury. To add the analysis of arsenic and other chemicals of
concern would add insignificantly to the overall cost. The collection of these samples represents an
opportunity for obtaining statistically representative data on other chemicals very cost-effectively. "
On June 12, 2000 STAPPA/ALAPCO sent a letter to Administrator Carol Browner regarding the pending
regulatory determination to regulate hazardous air pollutants from electric utility steam generating units
(Public Docket No. A92-55). Quoting from that letter, "STAPPA and ALAPCO believe a regulation is
warranted and strongly recommend that the U.S. Environmental Protection Agency (EPA) establish
standards to control emissions of HAPs from electric utilities, including, but not limited to, mercury.
Other pollutants you may wish to consider addressing include dioxin, arsenic, nickel and acid gases. "
In May, 2002 the STAPPA/ALAPCO membership adopted a set of "Principles for a Multi-Pollutant
Strategy for Power Plants. " Quoting from that document, "Power plants also emit substantial quantities
of hazardous air pollutants. EPA's Study of Hazardous Air Pollutant Emissions from Electric Utility
Generating Units - Final Report to Congress (1998) concludes that electric utility steam generating units
emit 67 hazardous air pollutants (HAPs), including mercury, arsenic, nickel, hydrogen chloride and
dioxins. In fact, electric generating units are the major emitter of hydrochloric acid, which is the HAP
emitted in the greatest quantity in the U.S... Given the significant contribution ofpower plant emissions
to public health and environmental problems in the U.S., the State and Territorial Air Pollution Program
Administrators (STAPPA) and the Association of Local Air Pollution Control Officials (ALAPCO) believe
that, ifproperly structured, a comprehensive, integrated control strategy for electric utilities is an
appropriate approach that will offer multiple important benefits. "
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Clearly, it can be seen in these documents that state and local agencies desire that EPA consider carefully
the control of all HAPs emitted by utilities.
In addition to the written documentation on this issue, we also considered an electric utilities MACT
project stakeholder meeting EPA held with 17 state and local representatives on March 12, 2001. At that
meeting, the State/local/tribal representatives indicated that their preferred outcome would be a rule that
provided for:
- minimal subcategorization of the industry;
- the most stringent levels of mercury control possible;
- a multi-pollutant approach;
- limited flexibility by the sources so as to enhance the States ability to implement the standards;
- early compliance encouraged through the use of incentives; and
- no trading of toxics.
The recommendations included in this report reflect the historical positions taken by STAPPA/ALAPCO,
our personal knowledge, and our observations gleaned from the working group meetings. Our general
views were presented to the STAPPA/ALAPCO Board of Directors on July 27th and to the
STAPPA/ALAPCO toxics committee on September 6th. Also, an overview of our recommendations was
provided to the STAPPA/ALAPCO membership on September 29, 2002, along with copies of the
presentation for the September 9 workgroup meeting. The authors of this paper are Praveen Amar
(NESCAUM), Bill O'Sullivan (N.J.) and John Paul (Dayton, Ohio). This paper does not reflect the views
of the Hg MACT workgroup member, Dave Schanbacher (Texas) who has provided separate
recommendations.
B. SUMMARY
A good summary of the recommendations contained in this white paper are included in the Workgroup's
Final Report to the CAAAC. Within that report the States and Local's column in the Table entitled
"Summary of Stakeholder's Positions on Key Issues" gives a thumbnail sketch of recommendations in
this white paper.
C. COAL MACT RECOMMENDATIONS
1. COAL HAPS TO BE REGULATED
In addition to mercury, which has been identified as the hazardous air pollutant (HAP) of "greatest
potential concern," many other HAPs are emitted by coal-fired power plants in significant amounts and
also are of potential concern. In EPA's electric utility study, specific concerns were identified for arsenic,
dioxin, and radionuclides. Additionally, coal-fired utilities are the largest source category of hydrochloric
acid and hydrofluoric acid emissions in the US. Coal-fired utilities are also the largest, or among the
largest, emitters of many other HAPs.
On December 2000, the EPA made the "Regulatory Finding" that regulation of HAP emissions from
coal-fired and oil-fired electric steam generating units under section 112 is appropriate and necessary
(Federal Register Volume 65, p. 79825-79831). The "Regulatory Finding" stated the following: "With
regard to the other HAPs, arsenic and a few other metals (e.g., chromium, nickel, cadmium) are of
potential concern for carcinogenic effects. Although the results of the risk assessment indicate that cancer
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risks are not high, they are not low enough to eliminate those metals as a potential concern for public
health. Dioxins, hydrogen chloride, and hydrogen fluoride are three additional HAP that are of potential
concern and may be evaluated further during the regulatory development process. The other HAPs
studied in the risk assessment do not appear to be a concern for public health based on the available
information. However, because of data gaps and uncertainties, it is possible that future data collection
efforts or analyses may identify other HAPs of potential concern."
This same "Regulatory Finding" estimated HAP emissions from coal as follows:
Arsenic 61 tons/year
Chromium 73 tons/year
Lead 75 tons/year
Manganese 164 tons/year
Mercury 46 tons/year
Hydrogen chloride 143,000 tons/year
Hydrogen fluoride 19,500 tons/year
In keeping with precedents to regulate all significant HAPs when a MACT rule is developed for a source
category, EPA's MACT rules for coal-fired utilities must include HAP emission limits which address the
majority of HAPs emitted by coal-fired power plants. The technology-based MACT program under the
Clean Air Act (CAA)is designed to ensure that all significant sources of HAPs implement controls to
reduce emissions to the maximum extent achievable. High stacks, which are common to coal-fired power
plants, should not be relied upon to limit high local risk from HAPs and are not an acceptable substitute
for MACT. Power plants contribute to the nationwide soup of toxic air pollutants, which need to be
minimized consistent with the MACT mandate of the Clean Air Act.
a. Coal HAP Groupings
Coal HAPs can be grouped by chemical and physical properties relevant to air pollution control measures
for the purpose of developing MACT limits. The following groups of HAPs from coal-fired power plants
cover most of the HAPs emitted from coal-fired power plants.
i. Mercury - Mercury and its compounds require a separate grouping for MACT limitation
because of the unique chemical and physical properties of mercury with respect to air pollution
control.
ii. Fine-particulate HAPs - Fine-particulate HAPs include the heavy metals, including but
not limited to arsenic, cadmium, and chromium; radionuclides; and polycyclic organic matter
(POM). Some of the adverse health effects of fine particulates (PM 2.5) are certain to be related
to these HAPs, which are components of PM 2.5 in the ambient air. For the purpose of MACT
standards for heavy metals, it may be appropriate to have a subgroup of HAP particulates which
are semi-volatile at temperatures present in boilers.
iii. Acid-Gas HAPs - These are primarily hydrochloric acid (HC1) and hydrofluoric acid
(HF). These acid-gas HAPs are the bulk of the 784 million pounds of HAP emissions reported by
utilities in the 1998 Toxic Release Inventory (TRI) and account for over 1/3 of the entire TRI
inventory.
iv. Organic HAPs - Coal-fired power plants are a major emitter of polycyclic organic matter
(POM) and other products of incomplete combustion (PICs). Dioxin is a PIC of potential concern
where combustion is inefficient.
b. Surrogates
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One practical way to address the large number of non-mercury HAPs emitted by coal-fired boilers is
through the use of surrogates. Surrogates may be non-HAPs (for example, CO or PM2.5 mass) or a
single HAP that is representative of many HAPs. This approach is useful to efficiently and effectively
address the majority of HAPs emitted by coal-fired power plants.
A surrogate is useful if efforts to minimize the surrogate also result in the minimization of a group of
HAPs which have common air pollution control properties. Under section 112(d) of the CAA, the
Administrator is directed to use emission information to set MACT limits. The Administrator is not
limited to using only HAP emission information, and it is reasonable to conclude the Administrator may
also use information on other emissions which are associated with HAP emissions. A surrogate is
particularly useful if it can be continuously monitored and serve as a continuous indicator of HAP
emissions.
A representative HAP is a HAP within a group of HAPs where its emission minimization indicates the
emissions of other HAPs in the group are also being minimized.
Using the above (C. 1 .a.) HAP groupings for coal- fired power plants, the following surrogates or
representative HAPs are reasonable choices to regulate the majority of HAPs from coal-fired power
plants:
i. Fine-particulate HAPs - Fine particulate mass emissions may be an adequate surrogate.
Alternatively, representative HAPs such as arsenic (semi-volatile) and chromium (non-
volatile) could have MACT limits. POM control is best achieved by good combustion,
and consequently, the CO surrogate discussed in C.l.b.iii. below is most relevant to
POM.
ii. Acid-Gas HAPs - Hydrochloric acid is the HAP emitted in greatest amounts from coal-
fired power plants. An HC1 limit may be adequate for all acid-gas HAPs, but there are
insufficient data on HF emissions to confirm that an HC1 limit would be adequate for the
control of HF. Additional testing of HF should be required to show that HC1
minimization also minimizes HF emissions, or that a separate MACT standard for HF
may be more appropriate. Alternatively, sulfur dioxide limits may be an appropriate
surrogate for acid-gas HAPs since scrubbers used to control S02 have been shown to
control HC1 at even higher efficiencies. Using S02 as a surrogate for acid-gas HAPs has
the added advantage of continuous emission monitoring for S02.
iii. Organic HAPs - These HAPs are products of incomplete combustion (PICs), which can
be largely avoided with good combustion control. The traditional and most common
indicator of good combustion is a low concentration of carbon monoxide (CO), which is
generally monitored continuously in large fossil-fuel-fired boilers. Hence, a reasonable
surrogate for limiting organic HAP emissions is setting a MACT limit for carbon
monoxide. Additional testing is needed to confirm that the CO MACT limit results in
negligible amounts of all organic HAP emissions. Special emphasis needs to be placed
during this testing on evaluating the relationship between combustion temperatures and
the concentrations of CO and organic HAPs.
2. COAL SUBCATEGORIES
Depending on the design of the MACT mercury standard for coal-fired power plants, subcategorization
may not be necessary or useful, especially subcategorization based on the use of bituminous and
subbituminous coals. However, a subcategory for lignite may be acceptable for reasons described below.
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a. Lignite
Lignite is burned in relatively few plants, and therefore, such subcategorization has relatively low impact
on overall mercury emissions from coal-fired power plants as a group. If separate MACT limits are set
for lignite, the limits should not be so different from MACT limits for bituminous/subbituminous coals
that existing lignite fired boilers remain uncontrolled for mercury or the construction of new high mercury
emitting lignite plants is encouraged over much lower emitting power plants burning other fuels.
b. Bituminous and Subbituminous
The majority of the coal-fired plants in the USA are fired with bituminous or subbituminous coals, or a
combination of these. The increasing use of bituminous and subbituminous blends argues against
different standards for each of these coals. Also, the use of an emission rate standard as the primary limit
for both bituminous and subbituminous coal can address the different properties of these coals. The
generally lower mercury content of subbituminous coal is offset by the greater proportion of elemental
mercury emitted, as compared to bituminous coal. These properties tend to offset each other with respect
to resultant mercury emissions after control. Also, EPA analysis of potential floors for bituminous and
subbituminous coal showed little difference. The minor potential difference in limits and the difficulty in
applying separate standards to mixtures of bituminous and subbituminous coal makes it unnecessary to
differentiate between these two most commonly used coals. Therefore, we recommend that a single
standard should be developed for both bituminous and subbituminous coal. We do note that Texas
supported a separate subcategory for subbituminous coal, and some Western states are considering this
issue further.
c. Small Power Plants
EPA should not subcategorize or exempt coal-fired power plants based on the size of the power plant or
units. Relative to other sources of HAP emissions, even the smallest coal-fired power plants are a
significant source of HAP emissions.
d. Stack Gas Parameters
EPA should not subcategorize based on flue gas temperature or moisture content related to the air
pollution control system in place. This may inappropriately exempt currently poorly controlled power
plants from any further HAP reductions or inappropriately limit the extent and the effect of MACT
application.
e. FBC and IGCC
Fluidized bed combustors (FBCs) do not need a separate category because their emissions characteristics
are similar to either bituminous/subbituminous coals or lignite coal for other types of coal combustors.
Integrated gasification combined cycle (IGCC) electric generating units might also be included with "all
other coal fired units." However, these units were not thoroughly evaluated by the working group, and
we have no specific recommendation on whether or not they be a separate subcategory.
3. MERCURY LIMITS FOR COAL COMBUSTION
a. Format of Hg MACT Limit for Coal
The primary MACT emission limit should be based on useful energy output to reward higher efficiency
plants and encourage higher efficiency (and lower emissions) in new and modified power plants. For
example, emission limits in units of milligrams per MWhr are appropriate for an output-based standard.
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Conversion of useful heat output from a cogeneration facility to MWhr units would be necessary to
provide credit for more efficient energy use from such facilities.
A percentage reduction component to the emission limit can be added to the primary emission rate limit
to form a "combination standard." Precedents for combination standards include the mercury limits for
municipal solid waste incinerators and the NSPS for sulfur dioxide from coal-fired power plants. In the
case of mercury from coal-fired power plants, the percent reduction component of a combination standard
could provide a reasonable alternative limit for those coal-fired units that burn high mercury content coal.
The percent reduction option, however, needs to be developed in such a manner that it does not result in a
less stringent alternative for "average" mercury content coal. Rather, the output based emission limit
standard should be applicable to most units because emission limits based on useful output are
economically and environmentally preferable to a percent reduction limit. Also, an important benefit of an
emission rate standard is the relative ease of determining compliance since it does not rely on
simultaneous testing of "before and after" emission controls. The corollary of this, however, is that one
must develop an effective compliance strategy for those units that choose the percentage reduction option
since it requires the clear determination of baseline, e.g. the determination of "what" in the "percentage
reduction of WHAT". Rather than attempt to simultaneously test the mercury in the coal being burned, it
would be more appropriate to test the outlet of the boiler, prior to the air pollution control system, to
obtain the uncontrolled mercury emission rate for determining the percent emission reduction.
The format of the combination standard could be "X mg of mercury per MWhr or Y percentage reduction
of mercury, whichever is less stringent. " An alternative, but less desirable, combination standard could be
input based in the form of "A lbs per trillion Btu or B percentage reduction of mercury, whichever is less
stringent."
As discussed in C.3.b. below, when a combination standard is developed, the specific numerical values of
emission rates and percentage reduction need to be chosen in such a way that they result in a national,
controlled mercury emission level (in TPY) that is as stringent as the ones that will be achieved through
MACT floor levels determined for a percentage reduction standard alone or an emission rate standard
alone. Appendix 3 estimates the national tons per year of resultant mercury emissions for various
combinations of emission rates and percentage reductions. Appendix 4 is the same as Appendix 3 but
focuses on mercury emission rate limits below 1.00 lb per trillion Btu. These graphs demonstrate a
combination standard achieves an equivalent degree of emission reductions as a standard based on percent
reduction alone or emission rate alone.
b. Floor for Hg MACT Limit for Coal
This section relates to setting a mercury MACT limit for all coal-fired power plants without
subcategorization. See the discussion in section 2 above for potential subcategories, which could result in
different limits for lignite. If higher limits are set for lignite, then the floor for bituminous/subbituminous
may be lower than indicated below.
The floor for mercury must be no higher than the mercury emission levels achieved by the best
performing 12% of the power plants for which there are emission data. Emission data should consider all
the estimated HAP emission rates that EPA derived from application of stack test and plant specific data
to the approximately 450 coal-fired power plants in the USA.
The floor level depends on the format of the standard discussed in C.3.a. above. The recommended
combination standard (output emission rate level or percent reduction level, whichever is less stringent)
should be evaluated holistically and not rely on separate evaluations of the "12% best emission rate
performers" or the "12% best percent reduction performers." Instead, evaluation of each of these two
parameters can be done to set boundaries for each of the two parameters for the combination standard.
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The "12% best combination standard" logically results in a lower mercury emission rate component and a
higher percent reduction component than the best 12% of each of these levels when evaluated
individually.
Mercury emission rate estimates can be evaluated for 411 out of 452 coal-fired power plants in the US
EPA Utility Air Toxics Study data. USEPA plant by plant emissions estimates were obtained from the
wpd file, "plant by plant emissions estimates", downloaded from
www.epa.gov/ttn/atw/combust/utiltox/utoxpg.html. 3/26/02. These data were compared with data on
mercury concentrations in coal purchased by power plants obtained from the 1st, 2nd, 3rd, and 4th quarter
coal data, downloaded from the same source. There were 411 plants for which both coal data and EPA
plant emissions estimates existed for mercury. Subsequent analyses of emissions rates and percentage
reductions were limited to these 411 plants.
Appendix 1 groups power plants by levels of emissions based on heat input, in units of lbs of mercury
emitted per trillion Btu. Output rates can be derived by approximating the heat rate at 10,000 Btu per
KWhr. This graph indicates that approximately 50 of the 411 plants in the database have emissions of less
than 1 lb per trillion Btu. These 50 plants constitute just over 12% of the 411 plants. Hence, the baseline
for an input heat rate based mercury MACT emission limit where there are no subcategories should be no
higher than 1 lb per trillion Btu, and should be lower when the average of the best 12% is considered.
Appendix 2 is a similar evaluation of "percentage reduction" estimates in the US EPA Utility Air Toxics
Study data. The percentage reductions are based on the emissions of mercury estimated from the stacks
compared to the mercury in the coal. Appendix 2 includes 411 plants for which removal efficiency data
could be estimated. This evaluation of data indicates that approximately 55 of the 411 plants had mercury
removal efficiencies of greater than 80%. 55 out of 411 is about 13.4% of the plants. Therefore, a MACT
floor based solely on the percentage control efficiency of mercury removal from the coal being burned
should be no lower than 80%, and should be higher than 80% when the average of the "best 12%" is
considered.
A combined MACT limit in terms of lbs per trillion Btu or percentage reduction should be more stringent
than combining the best 12% derived from the components individually. Therefore, a combined limit
floor should have components which require an emission rate limit more stringent than 1 lb. per trillion
Btu and a percentage reduction greater than 80% if based on heat input.
As discussed in C.3.a. above, the preferable standard is output based. Conversion to an output based limit
using a heat rate of 10,000 Btu per kWh gives an upper floor level of 4.54 mg/MWhr. Increasing the
stringency of both the efficiency and the output based limit, to account for the ability to choose the less
stringent component of a combined standard, gives a MACT floor of about "4.00 mg/MWhr or 85
percent reduction (0.0800 lb per trillion Btu or 85%). This standard would result in about 10.5 TPY of
national mercury emissions from coal-fired power plants, based on data from USEPA's Utility Air Toxics
Study. (See Appendix 4, which evaluates combination standards using this data.)
Also, as discussed in 3 .a. above, the purpose of including a percentage reduction component in a
combined standard is to provide a "safety valve" for coals with very high mercury content, rather than
being a less stringent choice for "average mercury" content coal. Hence, the percentage reduction
component should be reflective of the best removal efficiencies achieved with the best control systems
possible. While control efficiencies of up to about 98% have been demonstrated for some plants, the
efficiency component would more reasonably be in the range of 90 to 95%.
Choosing a higher control efficiency component allows a higher emission rate component, while still
maintaining equivalent national emission reductions.
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Following are examples of "combination standard" which would result in estimated USA mercury
emissions between 8.5 and 11.5 tons per year. Similar alternatives can be developed for the MACT floor
recommendation of about 7 tons per year.
Combination Standard Floor Hg (TPY)
1.0 or 85%
1.1 or 90%
0.9 or 85%
0.8 or 85%
1.0 or 90%
0.9 or 90%
0.8 or 90%
11.5
11
11
10.5
10
9.0
8.5
Based on discussion at the September 9, 2002, Utility MACT Working Group meeting, we reevaluated
the recommendations made in our white paper for that meeting. The September 9, 2002, white paper used
the "worst" of the "Best 12 percent" of the test data and extrapolated the 80 tests to 411 plants to
determine a generous MACT floor which also considered variability beyond the averaging procedure
specified in section 112(d). We have reevaluated the MACT floor based on the literal reading of section
112(d) which specifies the "average emission limitation" for the best 12 percent of the sources for which
there is emission information. We have averaged the test results of the "Best 12 percent" for the 80 ICR
stack tests, as well as the extrapolated emissions information for 411 plants.
Following are results of this reevaluation. It compares the average performance of the best 12 percent in
two ways, with the test data (80 tests), as well as with the extrapolated test data (411 plants), based on
EPA's estimates of emissions from each of these plants. The best "percent reductions" were determined
independently of the best "rate-based limits," and do not represent stand-alone alternative limits to a
"combined rate or percent reduction standard."
1. Average of best 12 percent of 411 plants - 0.3 Ib/Tbtu (1.5 mg/MWh); 94 percent control.
2. Average of best 12 percent of 80 tests -0.2 Ib/Tbtu (1.0 mg/MWh); 93 percent control.
We believe that consideration of the variability of the data is appropriate. Although our primary
recommendation is to deal with variability by averaging quarterly tests in a year (3 test runs per quarter),
adding a compliance margin to the average of the best 12 percent of the actual emission level is also
reasonable when determining an appropriate emission limitation. We recommend a factor of 2 times the
actual tested average as a reasonable compliance margin when an annual average of quarterly tests is used
or a 30-day or greater average of continuous emission monitor (CEM) data is used.
We also recommend that a percent reduction alternative be part of the MACT standard to enable any plant
the opportunity to continue to burn the same coal if best available control technology (BACT) is
employed. Our estimated range for the percent reduction alternative for bituminous/subbituminous coal is
90 to 95 percent. This range is consistent with the average control efficiencies for the best 12 percent of
the test data (93 percent control) and the 411-plant evaluation (94 percent control) without activated
carbon injection. Hence, this MACT floor does not depend on the use of activated carbon injection
(ACI). Rather, ACI and baghouse control are available as an option to comply with the 90 percent
alternative limit. A 90 percent alternative limit is recommended to provide a reasonable assurance of
compliance if the percent reduction option is chosen.
Our recommendation for a MACT floor for bituminous and subbituminous coals would be 0.4 lb/Tbtu (2
mg/MWh) or 90 percent control, based on the data from the 80 tests. The 0.2 lb/Tbtu emisison limit (1
mg/MWh) would be a literal reading of section 112(d) if applied to the test data with no further
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consideration of variability. The 0.4 lb/Tbtu emission limit includes the factor of 2 compliance margin to
further address variability beyond the averaging of 12 tests or long-term CEM data.
We also believe that consideration of information on the total population of coal plants in the US is
appropriate. If the extrapolation of the average tests data to the 411 coal plants is used to develop the
MACT floor, the MACT standard would be 0.6 lb/Tbtu (3 mg/MWh) or 90 percent control based on the
same consideration of variability. Looking at Appendix 4 we conclude that when a 90 percent alternative
limit is used, the 0.6 lb/Tbtu rate-based option is the preferred rate level for a combination standard. This
is because there is little difference in the overall amount of mercury control between these two
combination standards, and the 0.6 or 90% standard provides more flexibility and an higher incentive to
use the simpler component (e.g. rate based component) of the combination standard. In conclusion, we
recommend that the MACT floor be in the range of 0.40 to 0.60 lb/Tbtu (2 to 3 mg/MWh) or 90%
control, with a preference for the 0.60 lb/Tbtu level.
c. Beyond-the-Floor for Mercury from Coal
Beyond-the-floor refers to setting a MACT standard which is more stringent than the floor level (best
12%). EPA should establish "beyond-the-floor" limits for mercury emissions from coal by considering:
i. Emissions data for control of the criteria pollutants (particulates, sulfur dioxide, volatile
organic substances, nitrogen oxides, and carbon monoxide), including BACT/LAER
determinations, as discussed in section E.3;
ii. The additional mercury emissions reduction benefits of control systems which minimize
other HAPs, including fine-particulate HAPs and acid-gas HAPs;
iii. Technology transfer of air pollution control technologies used on other mercury source
categories, especially carbon injection and fabric-filter control of municipal solid waste
incinerators;
iv. Pilot and full scale demonstration programs for mercury control technology for coal-fired
power plants, especially carbon injection along with fabric-filter control;
v. The well-documented history of the role of environmental regulation as a strong driver of
technology innovation and implementation for the electricity-generating sector in the US. (For
example, see the September 2000 NESCAUM report "Environmental Regulation and Technology
Innovation: Controlling Mercury Emissions from Coal-Fired Boilers"). The major advances in the
development of control technologies and substantial reductions in costs will occur only after (and
not before) EPA adopts performance-based emission standards and clear time schedules; and
vi. The fact that coal combustion is the single greatest source category for mercury and other
HAP emissions in the US.
In going beyond the floor, EPA should not put significant emphasis on estimates of control technology
costs, which will certainly decrease significantly in the future as a result of technology innovation that
will occur in response to well- defined environmental regulation. Instead, EPA needs to put more
emphasis on the latest information on the technical feasibility of meeting the maximum achievable
emission reductions. This includes the recent results from full-scale field tests completed at the three
power plants in Alabama, Wisconsin, and Massachusetts.
d. Averaging Method and Monitoring Requirements for Hg from Coal
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Selection of reasonable averaging time periods is appropriate and necessary to address the issue of
variability of mercury concentrations in coal and flue streams. Until such time as mercury continuous
emission monitors(CEMs) are proven(which appears likely), annual averaging of quarterly emission rates,
determined by averaging 3 test runs per quarter, is appropriate. Compliance determination with a percent
reduction limit is usually based on simultaneous boiler outlet and stack testing, but simultaneous testing
of coal and stack may be feasible with representative testing of the coal as fired. This periodic testing
should be replaced with monthly or annual averages of CEM data when Hg CEMs become commercially
available. Averages might be weighted by the amount of coal burned or electricity generated. The CEM
averaging could be a 12-month moving average, calculated each month, or a monthly average. The
interim quarterly periodic testing should be a 12-month moving average, calculated each quarter. EPA
method 29 is most appropriate in order to obtain data on mercury and other metals.
e. Types of Mercury Control Expected
The mercury MACT standard for coal-fired power plants should reflect the following best control
measures:
i. Fabric filtration
ii. Wet or dry scrubbing
iii. Activated carbon injection
We note that a large electrostatic precipitator (ESP) may approach a fabric filter in control efficiency for
TSPs or total particulates (99 to 99.7% for cold-side ESPs, 99 to 99.9% for fabric filters), but is inferior to
a fabric filter for both the fine particulate control (less than PM2.5, the fraction where most of the trace
metal HAPs are expected to accumulate) and mercury control. For example, EPA ORD's April 2002
report, "Control of Mercury Emissions from Coal-Fired Electric Utility Boilers" notes that cold-side ESPs
are only 80 to 95% efficient in controlling PM less than 0.3 micron compared to 99 to 99.8% control
efficiency of baghouses for the same size fraction. Also, experience with ESPs and fabric filters on MSW
incinerators has shown fabric filters to have about 5 times lower mercury emissions with the same carbon
injection rate. In some cases large ESPs, along with scrubbers and carbon injection, may result in low
mercury emissions and achieve the eventual MACT standard, but the MACT standard should not be
designed with the intent of not requiring existing ESPs to be supplemented with or replaced by fabric
filters. For plants with existing ESPs, the most cost-effective mercury control measure to achieve
significant mercury reductions is likely to be the addition of a polishing fabric filter (similar to EPRI's
COHPAC system) with carbon injection.
Scrubbers can be wet or wet/dry. They will assist with minimizing mercury emissions, as well as provide
effective control of acid-gas HAPs. In addition, EPA should evaluate the most recent data on the
effectiveness of the joint SCR-FGD/SDA systems in controlling emissions for units burning either
bituminous or subbituminous coals.
Activated carbon injection with fabric-filter control should be able to consistently reduce mercury
emissions by over 90%. For MSW incinerators with baghouses, initial testing of activated carbon
injection showed over 90% mercury control of the flue gas, and the technology subsequently proved out
at over 98% control. While use of activated carbon for control of Hg from coal is also expected to show
improvement as the technology is applied, 98% is not likely to be routinely achieved because of lower
mercury inlet concentrations in coal. The 90% or better expected control efficiency is based on pilot and
full scale demonstration tests indicating that 90% control is reachable and the expected refinement of the
technology as it is applied to coal.
f. New Coal Electric Generating Units
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An emission rate limit for new coal-fired boilers should be set to reflect the lowest mercury limits being
met, and the presumptive MACT limit should be based on the application of the following technologies:
fabric filters, activated carbon injection and wet/dry scrubbing. The mercury limit for new units should
be near the lower end of the range recommended in C.3.b. above.
4. RECOMMENDATIONS ON OTHER HAPS FROM COAL
See section C above on the coal HAPs to be regulated. This section will address MACT emission limits
for these groups of HAPs, other than mercury.
a. Floors and "Beyond-the-Floors" for Other HAPs from Coal
i. Particulate HAPs - We believe there is sufficient information to calculate floors for
individual heavy metal HAPs. However, use of a fine particulate (PM2.5) emission mass limit as
a surrogate for particulate HAPs emitted by coal combustion may eliminate the need for floor
calculations for individual heavy metal HAPs, other than mercury. If there are sufficient data,
EPA might use the best 12% of the criteria pollutant fine particulate emission data from coal
firing to develop a surrogate particulate HAP floor. Using the reasoning in section E.3., the
particulate HAP floor should be no higher than the 0.030 lb. per million Btu New Source
Performance Standard (NSPS) for particulate emissions adjusted to incorporate the fine fraction
since the 0.030 limit is for total PM. BACT and LAER limits for particulate emissions should be
considered in determining a "beyond-the-floor" particulate emission limit. BACT limits for total
particulate emissions have been set and achieved at the 0.0150 lb. per million Btu level, which
may be an appropriate "beyond- the-floor" surrogate limit for particulate HAPs. A particulate
MACT limit based on fine particulate emissions(PM-2.5) is preferable, since heavy metals are
found mostly in the fine fraction. EPA may be able to establish a MACT limit based on the
available total or PM10 emissions data with appropriate adjustment to estimate the PM2.5
fraction.
If test data for fine particulates (PM2.5 or PM10) are insufficient for developing a particulate
HAP surrogate standard, and if converting total particulate test data to estimate fine particulate
levels is not reasonable, then total particulate test data should be used to develop a total
particulate HAP surrogate at this time. Subsequently, additional testing should be done to
determine if the adopted total particulate MACT standard is sufficient to minimize the emissions
of particulate HAPs.
ii. Acid-Gas HAPs - The floor for acid-gas HAPs should be in the range of 90% to 95%
control of sulfur dioxide ( non-HAP surrogate) or hydrochloric acid (representative HAP
surrogate). The number of coal plants with scrubbers and the general knowledge that these are
routinely over 90% efficient, and typically greater than 95% efficient, at removing acid gases,
should be sufficient emission information to set a floor for acid-gas HAPs which requires such
wet or wet/dry scrubbing. Utility emission factors and estimates of hydrochloric acid emissions
when reporting emissions pursuant to "Right to Know" are other useful pieces of emission
information which are relevant in establishing the MACT floor for acid-gas HAPs. Also, NSPS
limits for sulfur dioxide could be the basis for an acid-gas HAP floor, and the more recent
BACT/LAER decisions for sulfur dioxide could be the basis for a "beyond the floor" acid-gas
HAP limit if sulfur dioxide is used as a surrogate for acid-gas HAPs.
iii. Organic HAPs - Since organic HAP emissions are products of incomplete combustion,
carbon monoxide (CO), which is the most common product of incomplete combustion, could be
used as a surrogate for setting the MACT floor for organic HAPs and ensuring efficient
combustion. New Jersey has a 100 ppm (corrected to 7% oxygen) RACT emission limitation for
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CO, and this level may be a potential highest floor for organic HAPs. More recent BACT and
LAER decisions for carbon monoxide should be considered in a "beyond-the- floor"
determination. Oxidation catalysts also should be considered in the "beyond-the-floor"
determination.
b. Format of Standards for Other HAPs from Coal
If a fine particulate limit is used as a surrogate for particulate HAPs, then EPA's adopted test methods for
fine particulate concentrations in lb. per million Btu should be used. If representative HAPs are selected
for particulate HAP MACT limits, then there should be quarterly testing of those HAPs (along with
quarterly testing for mercury), and the format of the limits should be the same as for mercury.
Where continuous emission monitors are used to determine compliance, as should be the case if S02 and
CO are selected as surrogates for acid gas and organic HAPs, then the emission limit should be a
concentration limit in the form of ppmv with a correction factor for oxygen.
For the acid gases, a "combination standard" of the form "ppmv or % reduction, less stringent of the two"
is reasonable to address high chlorine coal.
c. Averaging and Monitoring Methods for Other HAPs from Coal
Where criteria pollutant surrogates are selected as surrogate MACT limits, the traditional testing and
monitoring methods for criteria pollutant limitations should be used. Averaging times may be different
and should reflect the probability of short-term unusually high emissions and whether there are adverse
health effects associated with these short-term peak values. EPA method 29 would be appropriate to
obtain data on multiple metals, even if a surrogate limit for one metal is adopted.
i. For particulate limits, the average of 3 test runs is traditional and should be retained.
Annual particulate testing would be appropriate. If representative HAPs are selected for
particulate HAP MACT limits, then quarterly testing and the same averaging procedure as
recommended for periodic testing of mercury could be used to address variability of metal
emission levels.
ii. If S02 is used as an acid-gas HAP surrogate, daily limits with compliance determined by
CEMs is appropriate. If HC1 is used as a representative acid-gas HAP, then annual testing and
averaging 3 test runs (similar to particulate testing) is appropriate.
iii. For products of incomplete combustion, a short-term (hourly to daily) limit for CO and
the requirement of a CO CEM are appropriate.
d. New Coal-Fired Electric Generating Units
Future BACT and LAER determinations for criteria pollutants emitted by new coal units should provide
for equal or lower emissions than MACT limits which are consistent with today's BACT and LAER
technology, which should be applied to existing plants. Hence, setting separate MACT emission limits
for other than mercury from new coal-fired power units may not be necessary, provided New Source
Review (NSR) technology requirements remain for new units.
e. Additional HAP Testing of Coal Combustion
Where a surrogate criteria pollutant or a representative HAP is used as a MACT performance standard for
a group of similar HAPs, the MACT rule should include testing for some or all of those HAPs to confirm
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effective control. This is especially prudent for the organic HAPs for which there are little test data at this
time.
D. OIL MACT RECOMMENDATIONS
MACT standards should be developed for electric generating units which combust other than light oil.
Effective particulate control and good combustion should be the goal of the MACT for heavy-oil
combustion.
1. OIL HAPS TO BE REGULATED
MACT requirements should be set for particulate HAPs and organic HAPs emitted by heavy oil
combustion. Nickel may be appropriate as a representative HAP for the heavy metals in oil.
Alternatively, a limit on fine particulate emissions may be an appropriate surrogate for both heavy metals
and particulate organic matter emissions which contain HAPs. Carbon monoxide would be an
appropriate surrogate for organic HAPs which are products of incomplete combustion.
2. OIL SUBCATEGORIES
There should be no subcategories for power generating units burning heavy oil. All oil heavier than
number 2 oil should be subject to the same MACT requirements.
3. OIL MACT LIMITS AND FORMAT
a. Particulate HAPs
We have not determined a MACT limit for nickel. An output-based standard is preferred in the form of
milligrams per megawatt hour. An input standard in the units of lb. per million Btu is also useful, but less
desirable. If a fine particulate emission rate is used as a surrogate, the MACT floor should be no higher
than the floor for coal, i.e., no higher than 0.030 lb. per million Btu. A "beyond-the-floor" level should
also be considered at the 0.015 lb. per million Btu level. These total particulate limits should be adjusted,
if possible, to reflect the fact that metals in oil, like trace metals in coal, accumulate in the fine fraction of
PM (see the earlier section 4.a.i)
b. Organic HAPs
The carbon monoxide floor should be no higher than 100 ppm (at 7% oxygen) averaged daily, which is
the New Jersey RACT limit for both coal and oil fired boilers.
An averaging period between 1 and 24 hours should be considered. BACT and LAER determinations
should be considered for a "beyond-the-floor" MACT limit. Oxidation catalysts should be considered,
but good combustion control should be sufficient in most cases.
4. OIL HAP AVERAGING AND MONITORING METHODS
a. Particulate HAPs
If nickel is used as a surrogate for metal HAP emission from heavy oil combustion, then the nickel in a
monthly composite oil sample should be tested monthly, and the efficiency of the fine particulate air
pollution control should be tested annually. A weighted annual average of the nickel emissions per
MWhr can be determined based on the monthly amount of electricity produced, and the rate of nickel
emitted can be adjusted by the efficiency of the particulate air pollution control. If fine particulates are
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used as a MACT surrogate, then an annual particulate test would be appropriate, using standard EPA
methods and averaging 3 test runs.
b. Organic HAPs
Carbon monoxide CEMs should be used to determine short-term (hourly to daily) average emission
concentrations.
5. NEW OIL ELECTRIC GENERATING UNITS
Future BACT and LAER determinations for particulate and carbon monoxide emissions from new oil
fired electric generating units should be sufficient to reduce HAP levels from new units to lower levels
than for existing units, provided New Source Review (NSR) technology requirements remain for new
major units.
E. OTHER CONSIDERATIONS
1. DATA SUFFICIENCY
There are a wealth of data for setting MACT limits for mercury emitted by coal combustion. EPA's
testing of many electric generating units during the 1999 ICR (Information Collection Request), and the
application of those test data to similar units that were not tested is appropriate and sufficient to set a
mercury emission limit for coal combustion.
For other HAPs emitted by coal, there are less emission data, and for some HAPs the data is not sufficient
for setting a MACT emission limit specific to that HAP. There are, however, sufficient data for setting
HAP-specific MACT emission limits for most heavy metals. There are not sufficient data to set HAP
specific limits for organic HAPs.
Emission data other than HAP emission data should also be used in determining MACT limits for coal
and oil fired power plants. Criteria pollutant emission data for particulates (including data on fine
particulate mass), sulfur dioxide, carbon monoxide, and volatile organic substances are relevant to HAP
emissions, which are mostly fine particulates, acid gases and products of incomplete combustion. For
example, emission data on the effectiveness of S02 control should be used to help determine a MACT
emission limit for HC1.
Data on criteria pollutant emissions are particularly relevant when they are used as surrogates for groups
of HAPs with similar properties relevant to controlling their emissions. Continuous emission monitoring
data for sulfur dioxide and carbon monoxide would be useful for setting surrogate HAP standards, as well
as determining compliance with those standards.
Emission data provided by utilities in response to "Right to Know" surveys are of lower quality than stack
test data, but nonetheless also relevant and useful in determining MACT emission limits. All emission
data which are available and related to HAP emissions should be considered holistically in developing
MACT emission limits.
2. VARIABILITY OF DATA
Variability of emission data is not new to HAPs. For mercury and other heavy metals which have a wide
range of concentrations in coal and oil, this variability is best addressed through the optimum design of
the magnitude and form of the standard and through the selection of averaging time period and
procedures. Equally important, the numerical value, form, and averaging time period of the standard
should be based not on the variability of the incoming Hg concentrations in coal or the flue gases, but on
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the best evaluation of how control technologies are capable of handling and "damping" the incoming
variability through equipment and operating design (for example, activated carbon injection based
systems should be able to meet a fixed output limit by injecting more or less carbon; feedback control
systems can be used for wet scrubber-based systems).
Statistical manipulation of the coal or test data to generate unreasonably high emission limits is
inappropriate. To reasonably address variability in the system (monitoring, sampling, mercury content of
coal,etc.), we recommend using the combination of these three components: 1. the average of emissions
from the "best 12%" of the units, 2. a factor-of-2 compliance margin, and 3. the use of long term
averaging of compliance data for mercury or other individual HAPs.
For periodic testing of mercury, quarterly testing and averaging 3 test runs each quarter and the 4 quarters
each year should be sufficient to provide a reasonable determination of average annual emission rate.
Similar procedures have been successfully used for municipal solid waste incineration which has more
mercury variability than coal.
When CEMs are used for mercury emission determination, there are many ways to average the data to
address variability and obtain a reasonable determination of average emission rates. A moving 12-month
average of the average emission rate for each month is a common procedure. A monthly average should
also be sufficient to address variability of mercury.
Where criteria pollutants are used as surrogates for HAP emissions, there is also sufficient experience to
develop appropriate averaging procedures.
3. SPECIAL CONCERN ABOUT VARIABILITY OF HAP PRODUCTS OF INCOMPLETE
COMBUSTION
The variability of carbon monoxide (and HAP products of incomplete combustion) is not directly related
to coal or oil properties, but rather is related to operation of the unit. Very high carbon monoxide and
other products of incomplete combustion (including HAP organics) can result from poor combustion
practices over a relatively short period of time. Therefore, the MACT standards for HAPs which are
products of incomplete combustion should be of sufficiently short averaging time to promote good
combustion practice at all times and not enable poor combustion practices to be lost in long averaging
time. The MACT standard for HAP products of incomplete combustion should catch bad combustion
practice and cause corrective actions to be taken immediately. The use of continuous emission monitors
for carbon monoxide is appropriate to instantaneously determine a poor combustion problem and enable
timely corrective action. To encourage timely corrective action, the averaging time for carbon monoxide
should be no greater than 24 hours and could be as low as 1 hour.
4. RELATIONSHIP OF MACT TO RACT, NSPS, BACT AND LAER
MACT is an emission limit based on maximum achievable control technology, including pollution
prevention measures. Section 112(d) of the Clean Air Act requires that bey ond-the-floor MACT
standards "require the maximum degree of reduction in emissions of the hazardous air pollutants...taking
into consideration the cost of achieving such emission reduction, and any non-air quality health and
environmental impacts and energy requirements achievable for new or existing sources..." Other
technology based emission limits required by the Clean Air Act include, in order of least stringent to most
stringent: Reasonably Available Control Technology (RACT); New Source Performance Standards
(NSPS); Best Available Control Technology (BACT); and Lowest Achievable Emission Rate (LAER).
These 4 technology-based emission standards are applied to the criteria pollutants and their precursors,
including fine particulates (PM2.5 and PM10), sulfUr dioxide, oxides of nitrogen, volatile organic
substances, carbon monoxide, and lead. These criteria pollutant emission limits are also relevant to HAPs
from coal-fired power plants which emit significant amounts of HAP particulates, HAP acid gases and
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HAP products of incomplete combustion; all of which can be controlled by the same air pollution control
technologies as used for the more encompassing criteria pollutant category.
Comparing the definition of MACT for HAPs with RACT, NSPS, BACT and LAER for criteria
pollutants shows similar language for MACT, BACT and LAER. Therefore, BACT and LAER
technology for criteria pollutants is equally relevant for HAPs which are also within the same criteria
pollutant category. In addition, HAPs should be minimized to an even greater degree than criteria
pollutants in view of their higher toxicity. Hence, MACT standards for fine-particulate HAPs, acid-gas
HAPs, and products-of-incomplete-combustion HAPs should result in more stringent air pollution control
technology requirements (including pollution prevention) than RACT and NSPS standards for criteria-
pollutant requirements for particulates, sulfur dioxide, volatile organic substances and carbon monoxide.
MACT standards should be consistent with BACT and LAER determinations for the analogous criteria
pollutants.
Current BACT limits for coal-fired power plants require baghouse control or the equivalent, wet or dry
scrubbers, and good combustion. These technologies and measures are also directly relevant to
minimizing HAPs from coal-fired power plants. BACT limits have been set for many power plants to
control particulates, acid gases, and products of incomplete combustion (CO and VOC). BACT/LAER
limit should be considered for "beyond-the-floor" MACT limits for all coal-fired power plants.
RACT and NSPS are generally less stringent than MACT, but can be considered as highest MACT floors
where criteria pollutants are used as surrogates for HAPs.
5. AIR POLLUTION CONTROL TECHNOLOGY: INNOVATION, IMPLEMENTATION AND
TECHNOLOGY TRANSFER
It is important for EPA to recognize the important role the EPA MACT determination ("environmental
driver") will play in the near-term future innovation in alternative technologies and strategies for
controlling mercury emissions. In the long-term, the full-scale field implementation of different
technologies and strategies will result in even more innovation and substantial cost reduction through the
optimum selection of combination of technologies, operating methods, and fuels. These are expected to
include: pollution prevention, coal cleaning, fuel blending and switching, injection of carbon or other
sorbents, enhanced wet scrubbing, catalysts to oxidize mercury in flue streams before its capture in wet or
dry scrubbers, SCR-FGD/SDA combinations to capture Hg besides controlling NOx and S02. In
addition, there are a number of emerging technologies including electro-catalytic oxidation (ECO) that
may find commercial application once the MACT standards are established. The historical fact that more
effective control technologies have always appeared in the marketplace after (and not before) the
performance standards are set is of particular importance when EPA establishes "beyond-the floor"
MACT limits as it takes into account not only the current status of technology, but its realistic future
potential.
The technology-transfer capability from other sources also needs to be taken into consideration by the
EPA. The successful use of carbon injection and baghouse control on municipal solid waste (MSW)
incinerators should be considered in developing the MACT standard for mercury from coal-fired power
plants. While uncontrolled mercury concentrations in the flue gas of MSW incinerators are much higher
than for coal combustion, pilot and full-scale testing of carbon injection on coal shows the same
relationships as for MSW incineration. The more carbon injected, the better the mercury control, up to a
point. The MSW experience has shown that baghouses are far superior for mercury control than ESPs
and can be used to avoid high carbon use and the associated costs, as well as to effectively control fine-
particulate HAPs. Thus, while the working experience with other sources such as waste combustors may
not be directly transferable to large coal-fired boilers because of their different flue-gas characteristics, it
is nevertheless helpful in informing the MACT determination for the coal-fired boilers.
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Appendix 1
Contribution to Hg total emissions by groups,
groups based on estimated emission rate*
* of those plants for which emisison rate could be estimated
50%
120
100
Q.
3
2
U)
c
W
+¦>
c
TO
Q.
d)
n
E
D
>=6
>=4 <6
>=2 <4
>=1 ,< 2
< 1
Group; range of emission rate, lbs/1012 Btu
Note: Estimates are based on data for 411 coal-burning power plants for which plant by plant emissions data and coal analysis data
were both available. Emission rates are based on pounds per year per plant as estimated by USEPA in the file "plant by plant emissions
estimates" divided by total Btu content of coal purchased by that plant obtained from the 1st, 2nd, 3rd, and 4th quarter coal data. All files
were dated June, 2001, and were downloaded from www.epa.gov/ttn/atw/combust/utiltox/utoxpg.html. 3/26/02.
1
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Appendix 2
Contribution to Hg total emissions by groups,
groups based on estimated percent removal efficiency*
* of those plants for which removal efficiency data could be estimated
45%
160
<= 20 >20, <=40 >40, <= 60 >60, <= 80 >80, <= 100
Group; range of percent removal efficiency
Note: Data source is the same as Appendix 1. Percent removal efficiency was based on comparison of USEPA
estimated plant by plant emissions compared with total mercury content of coal purchased by that plant, as estimated
from the quarterly coal data files.
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Appendix 3
Total U.S. mercury emissions from coal-burning power plants,
with various control options
50
45
40
35
30
to
§ 25-
+-»
20
15
10
5
0
0 1 2 3 4 5
lbs Hg per 1012 Btll (multiply by 5 to convert to approximate mg/MWh)
Note: Plant by plant emissions were estimated for various combination standards in the form of A lbs. per trillion Btu or B percentage
reduction of mercury (based on coal mercury content), whichever is less stringent, with the assumption that a plant's emissions will
reflect the less stringent applicable standard. Estimated emissions for all plants were totaled. Data source is the same as Appendix 1.
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Appendix 4
Total U.S. mercury emissions from coal-burning power plants,
with various control options
Note: This graph is identical to graph in Appendix 3, except that the lbs. per trillion Btu scale (x-axis) extends only to 1 lb. per trillion
Btu, 80% and 90% reduction options have been added, and the 65% option is not included. Data source is the same as Appendix 1.
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