Bernard j. Beaudoin
Chairman of the Board President and
Chief Executive Officer
January
28, 2002
The
Honorable George Voinovich
Committee on Environment and Public Works United States
Senate
Washington,
D.C. 20510
Dear
Senator Voinovich:
Thank
you for inviting Kansas City Power & Light to comment on provisions in S.
556, the Clean Power Act of 2001, to address mercury emissions from coal-fired
electric generating units and the technology currently available to address
such emissions.
Kansas
City Power & Light is the second largest investor owned electric utility in
Missouri, with 70 percent of its more than 3,733 megawatt generation capacity
being coal-fired. The remainder of Kansas City Power & Light's generation
is made up of nuclear, natural gas and oil.
At
the outset, let me say that Kansas City Power & Light supports a
multi-emissions strategy that imposes reasonable emissions reductions of sulfur
dioxide, nitrogen oxides, and mercury under timeframes that allow us to achieve
such reductions in a cost-effective manner. In our view, this approach should
allow "co-benefits" for mercury control through installation of
currently available technology to remove emissions of sulfur dioxide, nitrogen
oxides and particulate matter rather than impose a rigid 90 percent source
specific reduction mandate. We firmly believe a co-benefits approach can
achieve real environmental benefits while providing our company and other
companies a degree of business certainty in the foreseeable future.
The
treatment of mercury emissions under S. 556 and a recent proposal by the
Environmental Protection Agency (EP A) is a significant concern to Kansas City
Power & Light because we use western low sulfur subbituminous coal. Mercury
emissions from low sulfur subbituminous coal are lower and in a form, known as
"elemental" mercury, which is extremely difficult to remove, a fact
with which virtually everyone, including EPA, agrees.
The
amount of mercury emitted from a coal-fired power plant is impacted by a number
of factors, including the type of coal being fired, boiler design and
operation, fly ash characteristics, and associated environmental controls.
Estimates of mercury removal are made even more difficult due to the large
volumes of gas to be treated, low concentrations of mercury, and the presence
of difficult to capture species such as elemental mercury.
The
capture of mercury by flue gas cleaning devices is dependent on the chemical and
physical forms of mercury. Factors that affect the speciation and capture of
mercury in coal-fired combustion systems include the type and properties of the
coal, the combustion conditions, the type of flue gas cleaning technologies
employed, and the temperatures at which the flue gas cleaning systems operate.
There are three basic forms of mercury in the flue gas from coal combustion:
elemental mercury (Hg˚), ionic mercury [Hg(II)], and particulate-bound
mercury [Hg(p)].
Both Hg˚ and Hg(II) are in the vapor phase at flue gas
cleaning temperatures. Hg˚ is insoluble in water and cannot be captured in
wet scrubbers.
To
comply with the provisions of S. 556, taking into account proven commercially
available control equipment currently available, each coal-fired unit in the
United States would be required to install a scrubber system for sulfur
dioxide. Selective catalytic reduction for nitrogen oxides, and a fabric filter
for particulate control.
Currently
there is no proven or demonstrated technology to control mercury emissions.
There is evidence, however, based on experience in Europe and the Electric
Power Research Institute's (EPRI) bench scale studies, that mercury can be
co-beneficially removed by air pollution control equipment required to comply
with other Clean Air Act requirements, i.e., wet (flue gas desulfurization,
also known as FGD) or dry scrubber systems (SDA) for suĀ²lfur dioxide (S02)
control, selective catalytic reduction (SCR or SNCR) for nitrogen oxides (NOx),
and fabric filters or baghouses for capture of particulate matter (PM).
After
a thorough study of the research information presently available, KCPL is
confident that any coal- fired unit equipped with SCR, SDA, and fabric filters,
as would be required by S. 556, will achieve the maximum degree of reduction in
emissions of mercury through co-benefits, taking into consideration the costs
of achieving such emission reduction, any non-air quality health and
environmental impacts, and energy requirements associated with the emission
reduction.
The
level of control of mercury through co-benefits is based on several
assumptions:
These
assumptions are based on the limited amount of research data available, and
presume that the EPRI research studies and analyses from Phase ill of
EPA 's Information Collection Request (ICR) are correct and applicable.
At
an August 200l meeting, an EPA official observed that SCR and SNCR might improve
mercury removal. This confirmed the utility industry's position that the use of
post-combustion NOx controls such as SCR and SNCR may enhance oxidation of
Hg˚ to Hg(II) and thus result in the co-benefit of increased mercury
removal in FGD systems.
EPA's
analyses from Phase III of its ICR provide mercury removal efficiencies of
existing air pollution control equipment as shown in the attached chart.
EPA
and industry appear to agree that there are presently two pri~ technologies
that could be considered in establishing a regulatory standard for mercury.
They are co-control with FGD and powdered activated carbon injection.
The
injection of powdered activated carbon or other absorbents upstream of a
particulate control device is one of the most promising methods for controlling
mercury emissions from existing utility boilers equipped only with
electrostatic precipitators (ESPs) or fabric filters. The key statement is
controlling mercury emissions from existing utility boilers equipped only
with electrostatic precipitators or fabric filters. Should S. 556 be
enacted in its present form, each coal-fired unit in the United States will be
required to install a scrubber system for sulfur dioxide control, selective
catalytic reduction for nitrogen oxides, and a fabric filter for particulate
control. This therefore would negate any benefit to be achieved because utility
boilers would not be equipped only with electrostatic precipitators or fabric
filters.
A
number of studies carried out at bench, pilot, and full-scale levels have
examined the influence of carbon type, carbon structure, carbon surface
chemistry, injection method (dry or wet), amount of carbon injected, and flue
gas temperature on mercury removal. Results indicate that a wide variety of factors
influence the mercury removal obtained with sorbent injection upstream of an
ESP or fabric filter baghouse. These factors include the mercury species being
removed (oxidized vs. elemental), the flue gas composition, process conditions
(e.g., temperature), sorbent characteristics (e.g., size), and the presence of
other active surfaces (e.g., fly ash). Results also show that although general
trends between different sorbents and test conditions exist, sorbent
performance tends to be site specific and depends on the exact nature of the
flue gas at a particular site.
Based
on review of the available information, a new unit firing subbituminous coal,
which produces primarily elemental mercury (the hardest form to remove),
equipped with SCR, SDA, and a fabric filter, may not realize any additional
mercury removal due to the addition of powdered activated carbon or other dry
sorbent injection. This is of great concern to Kansas City Power & Light
because we just rebuilt a 550 megawatt unit, our Hawthorn 5 facility, using a
state-of-the-art combination of SCR, dry scrubber and fabric filter and burning
low sulfur subbituminous coal. This combination of equipment and fuel, making
Hawthorn 5 the cleanest coal-fired power plant in the country, may be able to
achieve a 45 percent level of mercury reduction based on currently available
information.
We
therefore urge the Committee to develop a more flexible legislative approach to
mercury that recognizes the limited effectiveness of state-of-the-art
technology in removing elemental mercury from flue gas emissions. Until there
are better technological advances, we believe the Committee should allow a
co-benefits approach to mercury.
We
appreciate your good work on this important issue. We encourage you to continue
your efforts to balance an outcome that will protect the environment and a
reliable and affordable supply of electricity throughout the country.
Sincerely,
B.J.
Beaudoin
ATTACHMENT:
Mean Mercury Emission Reductions for PC-Fired Boilers table_KCP&L.gif