COPAC-4
ABATEMENT OF
NITROGEN OXIDES
EMISSIONS
FROM
STATIONARY SOURCES
National Academy of Engineering
National Research Council
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COPAC-4
ABATEMENT OF
NITROGEN OXIDES
EMISSIONS
FROM
STATIONARY SOURCES
Prepared by
Ad Hoc Panel on Abatement of Nitrogen Oxides
Emissions from Stationary Sources
Committee on Air Quality Management
Committees on Pollution Abatement and Control
Division of Engineering
National Research Council
National Academy of Engineering
Washington, D.C.
J 972
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This is the report of a study undertaken
by the Committee on Air Quality Management
Ad Hoc Panel on Abatement of Nitrogen Oxides
Emissions from Stationary Sources for the
National Academy of Engineering in execu-
tion of work under Contract No. CPA 70-48
with the Office of Air Programs of the
Environmental Protection Agency.
As a part of the Division of Engineering of
the National Research Council, the Committees
on Pollution Abatement and Control perform
study, evaluation, or advisory functions
through groups composed of individuals se-
lected from academic, governmental, and in-
dustrial sources for their competence and
Interest in the subject under consideration.
Members .of these groups serve as individuals
contributing their personal knowledge and
judgments and not as representatives of any
organization by which they are employed or
with which they may be associated.
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PREFACE
Americans are justifiably concerned with the
deteriorating quality of their physical environment.
The determination of government—at the federal, state,
and local levels—to reverse this trend is reflected
in recently enacted laws and in strengthened enforcement
actions. Control of pollution involves technical deci-
sions and economic trade-offs of benefits received for
costs incurred, and the decisions that are made will
be the wisest if a considerable portion of the concerned
public is informed on the problems and the facts that
underlie them. This report, which is an assessment of
the control technology for a significant air pollutant—
nitrogen oxides—is addressed primarily to a technical
audience. However, it is hoped that it will have value
to others who are concerned primarily with political
and social aspects of air pollution control.
In preparing this report the ad hoc Panel
on Abatement of Nitrogen Oxides Emissions from Station-
ary Sources met in Washington, D,C. several times over
a period of seven or eight months, generally for two-
day sessions, during which a large number of experts
from government and industry presented Information and
their views and insights. This was supplemented by
review of many technical documents, reports, and papers.
All information received was extensively debated by
the members of the Panel, each of whom is directly con-
cerned in his professional activities with some aspect
of air-pollution control. On this basis, the Panel
arrived at a collective judgment, recognizing that
knowledge about both the degree of health hazard and
the technology of control Is increasing rapidly and
that current judgments may undergo-considerable change
within a few years. The goal of the Panel has been
to provide a balanced viewpoint, verifiable quantita-
tively as far as possible, concerning the current status
of abatement of nitrogen oxides emissions from stationary
sources and what is reasonably achievable in the near
future. It is hoped this will be of value to govern-
ment and to the public in making the complex decisions
that lie ahead.
Charles N. Satterfield, Chairman
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NATIONAL ACADEMY OF ENGINEERING
NATIONAL RESEARCH COUNCIL
DIVISION OF ENGINEERING
COMMITTEE ON AIR QUALITY MANAGEMENT
Jack E. McKee, California Institute of Technology,
Chairman
Reid A. Bryson, The University of Wisconsin,
Ex Officio*
Thomas H. Chilton, Retired, E. I. du Pont de Nemours
and Company, Inc.
Merrell R. Fenske,** The Pennsylvania State University
S. K. Friedlander, California Institute of Technology
Robert L. Hershey4 Retired, E. I. du Pont de Nemours
and Company, Inc.
Chalmer G. Kirkbride, Retired, Sun Oil Company
Charles N. Satterfield, Massachusetts Institute of
Technology
Thomas K. Sherwood, University of California at Berkeley
Staff
R. W. Crozier, Executive Secretary^ Committees on Pollu-
tion Abatement and Control, National Research Council
J. M. Marchello, Staff Engineer, Committees on Pollutiot
• Abatement and Control, National Research Council
Barbara P. Sowers, Administrative Secretarys Committees
on Pollution Abatement and Control, National Research
Council
Liaison Representative - EPA
John 0. Smith, Chief, Office of Engineering Analysis,
Division of Control Systems, Stationary Sources
Pollution Control Programs, Office of Air Programs,
Environmental Protection Agency
*Liaison—NAS-NAE Environmental Studies Board
#*Deceased
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NATIONAL ACADEMY OF ENGINEERING
NATIONAL RESEARCH COUNCIL
DIVISION OF ENGINEERING
COMMITTEE ON AIR QUALITY MANAGEMENT
AD HOC PANEL ON ABATEMENT OF NITROGEN OXIDES
EMISSIONS FROM STATIONARY SOURCES
Charles N. Satterfield, Massachusetts Institute of
Technology, Chairman
David Archer, Westinghouse Electric Corporation
William Bartok, ESSO Research and Engineering Company
Thomas H. Chilton, Retired, E. I. du Pont de Nemours
and Company, Inc.
Donald N. Felgar, Southern California Edison Company
R. M. Lundberg, Commonwealth Edison Company
William H. Manogue, E. I* du Pont de Nemours and
Company, Inc.
M. S. Peters, University of Colorado
Staff
R. W. Crozier, Executive Secretary, Committees on Pollu-
tion Abatement and Control, National Research Council
J. M. Marchello, Staff Engineer, Committees on Pollution
Abatement and Control, National Research Council
Barbara P. Sowers, Administrative Secretary, Committees
on Pollution Abatement and Control, National Research
Council
Liaison Representative - EPA
Stanley J. Bunas, Division of Control Systems, Office
of Air Programs, Environmental Protection Agency
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CONTENTS
I. SUMMARY, CONCLUSIONS, AND RECOMMENDATIONS . . 1
A. Summary . * . . . ....... 1
B. Conclusions 2
C. Recommendations B
II. INTRODUCTION 11
A. The Clean Air Amendments of 1970 11
B. Role of the Academies . 13
C. Federal Research, Development, and
Demonstration 14
III. SOURCES OF NITROGEN OXIDES 18
IV. FORMATION AND CONTROL OF EMISSIONS FROM
COMBUSTION SOURCES. . 27
A. Equilibrium and Kinetics. . 27
B. Factors Affecting Utility Boiler
Emissions . 29
C. Fluidized-Bed Combustion. ........ 36
D. Other Combustion Processes 38
1. Gas Turbines, 38
2. Domestic Heaters. . 41
3. Industrial Furnaces . . 42
4* Incinerators 43
V, STACK-GAS CLEANING. 44
VI. FORMATION AND CONTROL OF EMISSIONS FROM
CHEMICAL OPERATIONS 47
VII. SAMPLING AND ANALYTICAL METHODS 49
TABLES
1. Summary of estimated nitrogen oxide
emissions in the U.S., 1969 . * 19
2. Breakdown of estimated NOg emissions from
stationary industrial sources, 1968 .... 20
APPENDIX
A. Bibliography. . ...... 50
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I
SUMMARY, CONCLUSIONS, AND RECOMMENDATIONS
A. SUMMARY
National and regional standards for air-quality
management are being defined under the Clean Air Amend-
ments cbf 1970 (Public Law 91-604).1 Keeping the costs
of meeting these standards within bounds and minimizing
the burden on our national economy will call for the
best efforts and most careful planning at all levels,
from individuals, civic groups, and companies to local,
regional, state, and federal agencies.
The nitrogen oxides emitted from industrial*
sources are essentially nitric oxide (NO) and nitrogen
dioxide (NO2). They are generally grouped together
and, for convenience, termed N0x» Nitrous oxide, ^0,
at the levels emitted by most chemical processes, is
believed to be innocuous and is not included in the
definition of N0X. About 53 percent of the total man-
made N0X emissions in the United States are from sta-
tionary sources. (The remainder is emitted by vehicles.)
The largest stationary-source contributions are from
the fossil-fuel-fired boilers of electric utilities
and from industrial furnaces. At the 1970 level of
control, NOx emissions from stationary sources would
approximately double by the year 2000. The need to
reverse this trend is clear.
On a world-wide basis, man-made sources of
N0X produce but a tenth of that produced naturally.
But the distribution of man-aade NOx is closely re-
lated to population distribution; over 60 percent of
the emissions in the United States occur in urban areas*
The relative contributions from stationary and mobile
sources vary substantially from city to city and the
proportionate contribution at ground level is presum-
ably more from mobile sources than from stack emissions.
Stack height and meteorological factors also affect
the relative contributions. N0X has a residence time
in the atmosphere of three to four days. Thus, pollu-
tion from N0X Is a regional rather than a global problem.
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Unlike emissions of sulfur oxides (S0X), whij
are directly proportional to the sulfur content of the]
fuel, N0X is formed largely by the reaction of nitroge^
and oxygen from the atmosphere at the high temperature!
existing during combustion. A. smaller contribution is
from organo-nitrogen compounds in the fuel. The most
promising prospects for significant early reduction of
Wx in fuel-combustion stack gases lie chiefly in appl'>
cation of some combination of combustion-modification
processes to reduce the N0X formed. The probability
that processes can be developed for removal of Wx frorh
stack gases is not encouraging.
B, CONCLUSIONS
With regard to combustion-control modificatio!
the following conclusions are drawn:
1. Of the three fuels used in firing, gas,
oil, and coal, gas allows the most precise
control in the attainment of the lowest
levels of N0X. The term "coal" covers a
variety of types of solid fuels varying
greatly in their combustion characteristil
and the nature of the ash formed. A vari-i
ety of boilers and burners are required
to burn these various types satisfactorily
Present emission levels from coal firing
vary greatly. Of the three fuels, least
is known about coal relative to minimizinf
N0X formation from combustion. A realieti
objective for new plants using natural gad
to be placed in operation by 19803 is a
reduction in N0X concentration to about
100 ppm from present-day uncontrolled
levels, which average about 350 to 400
ppmj but range as high as ls400 ppm. How-
ever, natural gas may not be available as
a fuel for utility boilers very far into
the future. For oil, the most common
range today, when the combustion process
has not been modified, is about 180 to
280 ppm for tangentially fired units and
300 to 700 ppm for horizontally fired
units. A realistic objective for oil-firei
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;plants placed in operation by 1980s achiev-
able by flue-gas recirculation and off-
stoichiometric combustion, is about ISO to
200 ppm. For smaller furnaces or where
low-nitrogen oil is available, there is a
possibility of reaching this objective at
an earlier date. Control methods are not
yet established for coal. The Panel recom-
mends a review to establish realistic ob-
jectives after more data become available
in the next two or three years,
2. Both theory and practice indicate that N0X
emissions from combustion sources can be
lowered by: (a) reducing the amount of
oxygen present in the flame zone, as by
use of staged admission of air (or off-
stoichiometric combustion), and (b) re-
ducing the peak flame temperature, as by
use of flue-gas recirculation to the flame
zone. The practicality of these abatement
techniques has been developed primarily
in furnaces burning gas or oil. Little
has been done on coal-fired units.
3. The principal problem in reducing N0X
emissions by the use of staged combustion
is to avoid the significant increase of
emissions of CO, hydrocarbons, and smoke.
In addition, with coal, it is important
to avoid increasing the hazard of flame-
outs, the rate of corrosion of boiler
components^caused by a reducing atmosphere,
and the percentage of unburned carbon in
the ash. The applicability of the above
techniques to coal firing is not well
understood and it will vary considerably
with burner design; e.g., flue-gas re-
circulation may be less effective with
cyclone burners than with other burner
designs.
4. The amount of NOx formed per unit quantity
of heat released on combustion can vary
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by a factor of about 10 depending on a
number of interrelated factors: (a) the
fuel (coal, oil, or gas); (b) the per-
centage of excess air used in combustion;
and (c) the size of the furnace—as fur-
nace sizes increase from domestic heating
units to large utility boilers, the amount
of NOx formed per Btu released usually in-
creases, probably because lower surface-
to-volume ratios and increased heat-re-
lease rates per cubic foot lead to less
rapid thermal quenching of the combustion
process. For large utility boilers, in-
creased furnace volume (while holding all
other variables constant) will act to re-
duce the average temperatures and will
therefore always act to reduce NOx.
However, it appears that the effect of
furnace volume on N0X formation is of
secondary importance when compared with
other combustion-control modifications
such as off-stoichiometric combustion*
This is not to say that furnace volume
is insignificant. In designs in which
combustion is spread out in the furnace,
e.g., tangentially fired units, it seems
likely that increasing furnace volume
would cause a reduction in N0X; (d) burner
design—designs that, produce more intense
combustion and higher temperatures, e.g.,
cyclone burners for coal, produce consid-
erably more NOjj than designs that allow
combustion to occur out in the furnace,
e.g., tangentially fired boilers. It is
impractical, however, in an existing in-
stallation to replace cyclone burners with
tangential burners located in the furnace
corners, for this would require nearly
complete rebuilding of the furnace. It
is not the fact that the burners are
positioned to admit fuel and air in a
tangential configuration that brings about
a reduction in NO formation, but rather
the manner in which fuel and air are
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admitted and mixed; and (e) load—as load
is first reduced in any particular instal-
lation, the concentration of N0X formed
at first drops. With further reduction
in load, the change in N0X concentration
is determined primarily by the degree to
which increased air-fuel ratio may be re-
quired to prevent excessive carbon monoxide
or smoke at lower loads.
5. Preliminary data exist regarding the re-
lative importance of conversion to N0X
of fixed nitrogen in oil fuels. These
data suggest that combustion of oil or
coal under reducing (sub-stoichiometric
air) conditions in a first stage helps
reduce the amount of fuel nitrogen con-
verted into N0X or increases the con-
version of NOx to N2 and the combustion
products, but additional research is
needed.
6. Presently feasible technology that can be
applied to NOj,. control in utility boilers
varies with the fuel utilized and the
nature of the installation—retrofitting
an existing boiler or designing a new
boiler. Furnace design (e.g., opposed
vs. tangential firing), burner configura-
tions (e.g.,. cyclone vs. conventional
burners), and provisions for adjusting
fuel and air flows and recycling combus-
tion gases determine the degree of N0X
control achievable in an existing Instal-
lation. Research, development, and design
studies are needed to determine combustor
configurations and designs that will facil-
itate complete combustion of coal and oil
(avoiding carbon, hydrocarbon, and CO
losses and preventing smoke and soot for-
mation), and will at the same time mini-
mize emission of NO^ (formed either by
N2-O2 fixation or oxidation of nitrogen
in the fuel).
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7. Combined-cycle systems involving the com|
bustion of coal or oil in combinations ol
gas and steam turbines are of considerabl
interest to utilities. Some of these maj
involve external coal gasification close!
coupled to a turbine or boiler. N0X emi^
sions are expected to be low, comparable
to those from natural gas, but little in-
formation is available.
8. On the basis of laboratory and pilot-sca]
tests, fluidized-bed-combustion boilers
show promise of appreciably reduced N0X
emissions, compared with conventional
coal-fired boilers. Burning of the coal
is carried out at relatively low tempera-
tures, 1400-1900° F.; tests indicate that
the N0X emissions originate almost entire,
from nitrogen in the fuel. In fluidized
combustors burning coal at atmospheric
pressure, two-stage combustion has reduced!
N0X emissions to about 70 pp®. In pres-
surized combustors, NOx emissions have
been reduced substantially in single-stag^
combustion. Fluidized-bed-combustion
boilers, therefore, show excellent poten-
tial for N0x control, and their develop-
ment should be pursued.
Removal of N0X from stack gases may offer
potential for control in the future. However, no
proven process is available for substantial removal of
Wx from combustion stack gases. Conclusions based on
presently available information are:
9. Any wet scrubber system for NC^ removal
will be expensive for two reasons: (a)
Most of the N0X is in the form of NO,
which is relatively unreactive and in-
soluble. The maximum rate of absorption
in an aqueous system occurs at a NO/NO2
mole ratio of unity, which requires either
(1) recycle of NO2 and a method of gener-
ating NO2 from the scrubbing system, in
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turn requiring very high scrubbing effi-
ciencies for substantial overall removal
of N0X, or (2) oxidation of about half of
the NO to NO2 prior to scrubbing. The rate
of oxidation of NO to NO2 is slow and de-
creases with increasing temperature; and
(b) large vessels are required for scrub-
bing because of the large volumes of gas
that must be handled and the necessity for
low pressure drop,
10. Catalytic reduction of N0X to W2 by a re-
ducing agent as a process for treating
stack gases from large utility boilers
requires a sulfur-resistant catalyst if
coal or oil is used as a fuel. Space
velocity (i.e., catalyst activity) and
catalyst life also limit this approach at
present. The catalytic reduction of N0X
with ammonia or other reducing agents is
being studied by several groups. Informa-
tion is insufficient to assess fully the
potential of any catalytic reduction
methods of control.
11. Decomposition of NOx in the absence of a
reducing agent requires such high tempera-
tures, on even the best catalysts known,
as to be impractical.
The following conclusions have been reached
for other stationary combustion sources and for chemical
manufacture:
12. Somewhere between two percent and 21 per-
cent of the N0X emissions from stationary
sources are produced by internal-combus-
tion engines (burning natural gas or die-
sel fuel, used in conjunction with pipe-
lines and gas plants)* With diesel engines,
techniques such as control of fuel injec-
tion, exhaust-gas recirculation, water
injection, and alteration of combustlon-
chambex design, are available to reduce
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N0X emissions. With gas turbines, rede-
sign of combustors and methods of fuel in-
jection accompanied by more fuel-lean con-
ditions in the combustion zone should pro-
duce significant reduction in NOx emissions.
13. More data are required on emissions from
industrial process and commercial furnaces,
residential furnaces and heaters, and in-
cinerators.
14. Emissions from nitric acid plants and
chemical operations may be "decolorized"
(conversion of NO2 to NO) by catalytic re-
duction with natural gas. A similar
method can be used to reduce NO to N2
(typically from 3,000 ppm to 100 to 500
ppm), but requires careful control. Ad-
sorption by molecular sieves has been
shown in the laboratory to produce even
lower emission levels but no demonstrated
commercial process is yet available. Al-
kaline scrubbing may be used but involves
liquid-waste disposal problems.
15. In some chemical processing with nitric
acid, a substantial portion of the nitro-
gen oxides emitted may be in the form of
N2O, which is considered to be harmless.
C. RECOMMENDATIONS
On the basis of its review and in conjunction
with the above conclusions, the Panel recommends that:
1. Combustion-modification studies be given
first priority in research and development
to control N0X emissions. Studies of coal
combustion are especially required. Stud-
ie8 of the effect of fuel nitrogen on N0X
emissions and the potential of flame-tem-
perature -control techniques in oil and
coal burning are also needed. A sub-
stantial reduction in the amounts of N0X
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released to the atmosphere (i.e., of the
order of 50 to 80 percent) will come least
expensively from modifications of the com-
bustion process rather than from scrubbing
or adsorption systems to remove NOx from
stack gases.
2. Experimentation to develop firing methods
for minimizing NOx emissions be accompanied
by data correlation and theoretical analy-
ses of the data obtained in order to de-
velop the basic understanding for config-
uring and designing new combustors and
for choosing operational modes in a vari-
ety of applications.
3. Boiler manufacturers and utilities incor-
porate as much flexibility as possible in
the design of new boilers to permit taking
advantage in the future of increasing
knowledge of the factors affecting N0X
emissions in combustion.
4. Additional work be funded on new energy-
conversion concepts—such as fluidized-
bed combustion, coal gasification for elec-
tric-power production, and combined-cycle
gas- and steam-turbine generating plants
operating in conjunction with such com-
bustors and gasifiers—to develop their
potential for reducing NOx and other
pollutants.
5. New concepts claiming potential for the
economic simultaneous removal of NOx and
S0X be evaluated carefully.
6. Evaluation of all new electric-power-gen-
eration techniques utilizing fossil fuels-
-including magnetohydrodynamics (MHD),
fuel cells, and combined-cycle plants with
fluidized-bed combustion or coal gasifica-
tion—incorporating estimates of K0X for-
mation and the economic cost of NO* con-
trol, begin as soon as practicable.
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7. Careful consideration be given to improv-
ing present methods of sampling and
analysis of NO and NO2, particularly in
the presence of other pollutants from
stationary sources.
8. The potential for the generation of N0X
by such sources as stationary internal-
combustion engines, industrial and
commercial furnaces, residential furnaces
and heaters, incinerators, electrostatic
precipitators, and other high-voltage
equipment needs further evaluation. If
the level of emissions is significant and
the effect on ambient air quality is detri
mental, then control techniques should be
sought.
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II
INTRODUCTION
A. THE CLEAN AIR AMENDMENTS OF 1970
The increasing concern of Americans for the
deterioration of the nation's air resources is re-
flected in the Air Quality Act of 1967 (Public Law
90-148 as amended)2 and the Clean Air Amendments of
19701 (Public Law 91-604 in which Public Law 90-148
was further amended to provide for a more effective
program to improve the quality of the nation's air).
These acts include emission standards for existing
sources that are to be enforced by the states, and
performance standards for new sources that were promul-
gated during 1971 and are to be enforced by the
Environmental Protection Agency (EPA). Responsibility
for carrying out the provisions of these laws is
assigned to the EPA Administrator.
Under the provisions of these laws, the EPA
published in the Federal Registerguidelines to the
states for preparation, adoption, and submittal of
implementation plans for enforcement of national
ambient air quality standards. On April 30, 1971,
the EPA published the National Primary and Secon-
dary Ambient Air Quality Standards.4 National pri-
mary and secondary ambient air quality standards
are those judged by the Administrator, based on the
air quality criteria documents8*9»10»12*13*lif
published by the EPA and allowing an adequate margin
of safety, as requisite to protect the public health
(primary standards) and the public welfare (secondary
standards) from any known or anticipated adverse
effects associated with the presence of pollutants in
the ambient air.
The national primary ambient air quality
standards for nitrogen oxides were promulgated as
follows:
The national primary emd secondary ambimt
air quality standard for nitrogen dioxide 3 measured
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by the reference method described^ (sodium hydroxide
absorption and subsequent colorimetrie determination)*
or by an equivalent method, is: 100 micrograms -per
aubia meter (0*055 parts per million)—annual arith-
metic mean.
Under Section 110,1 the states have nine
months to submit a plan for implementation, maintenance,
and enforcement of the primary standard in each air-
quality-control region and an additional nine months
to submit a similar plan for secondary standards. The
plans are to include a timetable for compliance within
three years, and state standards may be more stringent
than the federal standards. For nitrogen dioxide, the
national secondary ambient-air-quality standard is the
same as the primary standard.
In applying these standards it is assumed
that any NO present in the air is converted to the di-
oxide, but the extent to whiah NO is actually converted
to NO2 can vary greatly.
Recommendations by EPA5 to the states for
possible inclusion in their implementation plans for
existing sources cover emissions of nitrogen oxides
from fuel-burning equipment and nitric acid manu-
facture. These emission standards together with
standards of performance for new stationary sources7
are as follows:
Nitric Acid
Fuel-Burning Equipment Manufacture
(pounds per million Btu) (pounds per ton)
Gas Oil Coal
Required for
New Sources 0.20 0.30 0.70 3.0, 10 per-
cent opacity
Recommended for
Implementation 0.30 0.30 5.5
Plans* (175) (230) (575) (400)
*The figures in parentheses are approximate ppm, in
dry flue gas containing 3 percent oxygen*
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The reasons for concern about N0X emissions
to the atmosphere are threefold: (1) Both NO and NO2
can of themselves have adverse health effects, NO2 being
considerably more toxic than an equal concentration of
NO14; (2) NO and NO2 interact with hydrocarbons in the
atmosphere under the influence of the ultraviolet energy
of sunlight by a highly complex and only partially under-
stood series of reactions, to generate eye irritants
such as PAN (peroxyacetyl nitrate and related compounds),
PBZN (peroxybenzyl nitrate and related compounds), and
Oq (ozone) .9 *111 In addition, the reddish color of N0«
(NO is colorless) can contribute to haze and decreased
visibility; and (3) detrimental effects on vegetation.14
Following combustion, NO reacts relatively
slowly with residual oxygen in the combustion equipment
and in the flue gases to yield N02. This conversion is
usually less than 10 percent because of the short resi-
dence time. Thus, NO released to the atmosphere from
combustion processes is largely in the form of NO*14*15
In the typical daily urban pattern, the concentration
of NO and NO2 in the atmosphere begins to increase
rapidly at dawn as human activity, particularly auto-
motive traffic, increases, the ratio of NO to NO2
initially being very high. Under the influence of
sunlight, much of the NO is converted during the day
to NO2 and concentrations of PAN, PBZN, and O3 increase.
After sunset, photochemical conversion of NO to NO2
ceases but O3 formed during the day continues to react
with NO to form N02 until O3 is depleted. In ordinary
circumstances, winds and dispersion during the night
reduce the concentration of pollutants to a low level
and the cycle recommences the following dawn, What
happens to as much as 50 percent of the nitrogen oxides
that become incorporated into the photochemical complex
is still undetermined, since many of the nitrogen oxide
end products remain unidentified.14
B* ROLE OF THE ACADEMIES
The National Academy of Sciences and the
National Academy of Engineering established the Environ-
mental Studies Board in 1967 to coordinate activities
of the two Academies in the environmental field. One
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of the first acts of this Board was to recommend estab-
lishment of four committees on air, water, noise, and
solid-waste management within the Division of Engineer-
ing of the National Research Council. These committees
have an engineering orientation and are available for
furnishing advice and assistance to the Congress and tat
agencies of the executive branch of government having
responsibility for pollution abatement and control.
In June, 1969, the National Air Pollution Conj
trol Administration of the U. S. Department of Health,
Education, and Welfare (now the Office of Air Programs
of the EPA), requested the National Academy of Engineerj
ing to make a comprehensive review of present industry :
and government research, development, and demonstration
programs, to include technical and economic potentials,
adequacy of scope, proper integration with similar ef-
forts, and responsiveness to national needs directed to
ward control of sulfur oxides effluents from stationary
sources of combustion. The report on that study, Abate*
ment of Sulfur Oxide Emissions from Stationary Combus-
tion Sources^ was published in May, 1970.
The newly formed Office of Air Programs (OAP)
of the EPA then requested the National Academy of
Engineering—National Research Council to follow this
study with studies of sulfur oxides emissions from in-
dustrial sources, nitrogen oxides emissions from sta-
tionary sources, and particulate emissions from station-
ary sources. Each study includes an assessment of the
adequacy of present technology; the need for additional
technology; the scope, integration, and coordination of
industry and government effort; and responsiveness to
the national need for control and abatement of air
pollution from each of the three sources. Other similar
studies are expected to follow within the next year*
This report deals with the emissions of nitrogen oxides.
C, FEDERAL RESEARCH, DEVELOPMENT, AND DEMONSTRATION
PLANS
The EPA has developed a five-year research
and development plan for control of N0X emissions from
stationary sources.17*18 The Panel hopes this report
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will be useful to the EPA and its Office of Air Programs,
other government agencies, industry, fuel suppliers, and
others in planning and coordinating the research, de-
velopment, and demonstration programs required to meet
the national need for cleaner air.
The implementation of this plan will need to
be closely coordinated with national energy policies for
optimum use of resources.19 The major emphasis will be
placed on developing combustion-modification techniques
that will reduce N0X formation in coal-, oil-, and gas-
fired industrial and utility boilers. Electric utility
sources have received the highest priority for funding
in the Development Engineering Branch of the EPA's
Office of Air Programs for the following reasons:
(1) Electric utilities are the largest single source
of N0X emissions; (2) the internal-combustion engines
that produce the N0X in conjunction with pipelines and
gas plants can be controlled with technology developed
by OAPfs motor vehicle research and development program
and by the automobile industry; (3) industrial, domestic,
and commercial combustion sources may be controlled by
selectively adapting the technology developed for elec-
tric utility sources. Combustion in furnaces produces
about two-thirds of the NOx emissions from stationary
sources in the United States and will be responsible
for an increasing share of this total. Combustion-mod-
ification techniques, such as low-excess-air combustion,
staged combustion, flue-gas recirculation, and water or
steam Injection, will be investigated up to full-scale
application. Basic theoretical and experimental com-
bustion studies will be performed through fiscal year
1975 in support of the large-scale work.
The complex nature of control of NO^, SO2,
and other pollutants from coal combustion, and to a,
lesser extent from the combustion of other fuels, fully
justifies serious federal attention and support for de-
velopment of processes for production of "clean" fuels
by such methods as fluidized bed gasification, coal
gasification, coal liquefaction, and processing of our
vast deposits of oil shale. This requires careful
planning and coordination by OAP with other federal
agencies especially the Office of Coal Research and
15
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the Bureau of Mines. Projections for use of fuel re-
sources20 should include considerations such as burning
low-sulfur fuel in commercial and industrial boilers
and higher sulfur fuels in electric utility boilers.
The second area of emphasis for the next five
years will involve the development of combustion flue-
gas treatment processes to remove nitrogen oxides once
they have been formed. The control of N0X emissions by
combustion modification may be limited by special pro-
cess requirements for very high temperatures, limited
space restrictions, or possibly the inherent fixed-
nitrogen content of the fuel. Flue-gas treatment tech-
niques, including selective catalytic reduction, aqueous
alkaline scrubbing, and other selective adsorption and
absorption techniques, will be scheduled for research
and development.
The third area of emphasis through fiscal
year 1975 will be the development of needed control
technology for processes that manufacture or use nitric
acid. Such processes emit small quantities but high
concentrations of nitrogen oxides. Limited control
technology is already available, but OAP support may be
necessary to encourage further improvements in such
techniques as catalytic reduction, alkaline scrubbing,
and adsorption. This area may profit from developments
in combustion flue-gas cleaning.
The EPA budget for stationary-source nitrogen
oxides control in FY 1971 was just over $1 million. In
FiT 1972 it is $1.5 million; it is projected to be $4.2
million in FY 1973, $8.0 million in FY 1974, $12.0
million in FY 1975, $23.0 million in FY 1976, and $17.0
million in FY 1977. Funding is then expected to de-
crease sharply. The Panel concludes that the research
and development plans and the funding levels proposed
by EPA are prudent and are required for achievement of
national goals as presently defined.
Most of the information on health hazards
associated with N0X, on ambient air and emission stan-
dards, on combustion-modification methods, and on pro-
gress in control of N0X from mobile sources has been
16
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developed very recently, much of it during the course
of the Panel meetings. The Panel believes it to be de-
sirable to issue its findings now even though the rapidly
developing understanding of this problem may cause some
revisions in judgment in the near future, particularly
with respect to those sources for which standards are
soon to be established. The Panel's assessment was
completed before all the background information was
available from EPA on the proposed new source perfor-
mance standards.6»7
17
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Ill
SOURCES OF NITROGEN OXIDES
Of the various oxides of nitrogen, the most
important as air pollutants are nitric oxide (NO) and
nitrogen dioxide (NO2)» generally grouped together and
referred to as nitrogen oxides (NQx). Other oxides of
nitrogen, N2O3, N2O4, N2O5, and NO3 are present in very
low concentrations, and although they may participate
in photochemical reactions they can be neglected for
present purposes. Nitrous oxide or laughing gas CN2O)
is present in the atmosphere in concentrations of about
450 ug/m3 (0.25 ppm)14 but is regarded as being harmless
physiologically, and there is no evidence that it par-
ticipates in photochemical reactions in the lower at-
mosphere, ll+
Most N0X is produced biologically; fixation
by lightning seems to be relatively unimportant.15
Natural sources produce on the order of 50 x 107 tons
per year (about 90 percent of the total) of NOx, world-
wide, while man-made sources emit about 5 x 107 tons
per year (about 10 percent of the total). Naturally
occurring sources of N0X have been found to cause non-
urban concentrations, usually less than 10 ug/m3. How-
ever, urban concentrations are generally 10 to 100
times higher, which indicates the importance of the
man-made sources even though, overall, they are a small
fraction of the natural sources. Nationwide, the man-
made sources that are the major cause of N0X emissions
are fuel combustion in furnaces and in engines.15'21
Industrial chemical processes are responsible for high,
localized emissions, but are not significant on a large
scale. A summary of estimated man-made N0X emissions
in the United States in 1969 is given in Table 1 and
a breakdown of estimated emissions from stationary
sources, 1968, is given in Table 2.
About 53 percent of the total Wx emissions
in the United States are from stationary sources. The
largest contributions are from fossil-fuel'fired boilers
for electric utilities and from industrial furnaces.
At the 19?0 level of control, N0X emissions from
18
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TABLE 1
SUMMARY OF ESTIMATED MAN-MADE NITROGEN OXIDES
EMISSIONS IN THE UNITED STATES, 1969
(Environmental Protection Agency, May 1971)
Source 106 Tons/Year
Transportation 11.1
Motor vehicles, gasoline 7.6
Motor vehicles, diesel 1.1
Aircraft 0.3
Railroads 0.1
Vessels 0.2
Nonhighway 1.8
Fuel Combustion in Stationary
Sources 10.0
Coal 3.8
Fuel oil 1.3
Natural gas 4.7
Wood 0.2
Industrial Process 0.2
Solid waste 0»4
Miscellaneous 2.0
Forest fires 1.6
Structural fires
Coal refuse 0.1
Agricultural 0.3
TOTAL 23.7
19
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TABLE 2
BREAKDOWN OF ESTIMATED NOx EMISSIONS FROM
STATIONARY SOURCES IN THE UNITED STATES, 1968
(Environmental Protection Agency, May 1971)
Source Percentage of Total
Electric utility boilers
38
Industrial combustion
29
Pipelines and gas plants
21*
Domestic and commercial
10
Noncombustion sources
2
*Estimates range from 2 percent to 21 percent.
(See remarks on page 39.)
20
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stationary sources would approximately double by the
year 2000.17
N0X emissions from stationary sources in the
United States result primarily from the combustion of
fossil fuels in boilers, furnaces, and stationary in-
ternal-combustion engines. The bulk of the N0X emitted
by industrial sources comes from steam boilers and pro-
cess heaters, with smaller amounts from internal-com-
bustion engines, boilers burning waste-fuel gases,
catalytic cracking regenerators, metallurgical ovens,
furnaces, and kilns. On the other hand, emissions from
pipeline and gas plant operations, result primarily
from the use of internal-combustion engines to drive
pumps and compressors, and»to a lesser extent from pro-
cess heaters and boilers. Domestic and commercial
sources include incinerators, space heaters, water
heaters, ranges, and clothes dryers. Essentially all
the N0X emitted by noncombustion sources comes from
the manufacture or use of nitric acid.
N0% distribution is closely related to popu-
lation distribution; over 60 percent of the Wx emie-
sions in the United States occur in urban areas. The
relative contributions from stationary and mobile
sources vary substantially from city to city and the
contribution at ground level presumably comes propor-
tionately more from mobile sources than from stack
emissions. Stack height and meteorological factors
also affect the relative contributions» has a
residence time in the atmosphere of three to four
days. Thus, pollution from a regional rather
than a global problem.
Almost all N0X emissions arise from combus-
tion processes. The nitrogen oxides are formed during
combustion by chemical combination of oxygen and nitro-
gen in the air (fixation), and by oxidation of some of
the nitrogen combined with organic substances in the
fuel. Only a small fraction of the nitrogen in the
air passing through a furnace or an engine is converted
to N0X, Likewise, only a portion of the nitrogen in
the fuel is converted to N0X. However, the total
tonnage of N0X emitted, if it were converted to nitric
21
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acid, is 10 times the U.S. production of this chemical.
Coal varies between about 1.0 and 1.5 percent by weight
and fuel oil between about 0.02 and 1.2 percent by weigh
in the amount of combined nitrogen they contain. Natura
gas contains no significant amount.
Unlike emissions of S0Xi which are directly
proportional to the sulfur content of the fuel> NOx is
formed in conventional combustion processes largely by
fixation of nitrogen and oxygen from the atmosphere at
the high temperatures existing during combustion. Under
conventional combustion conditions a smaller contribution
is from organo-nitrogen compounds in the fuel.
The major factors influencing N0X emissions
from combustion processes are: the percent of excess
air; mixing; heat release and removal rates; fuel type;
and fuel composition.17*48 These factors provide a
basis for modifying combustion techniques of N0X con-
trol. Modification of operating conditions include:
operation at reduced load; low excess-air firing; staged
or off-stoichiometric combustion; flue-gas recirculation
steam or water injection; reduced air preheat; and com-
binations of these methods. The N0X level can also be
reduced by changes in design such as: altering burner-
design configuration, location, and spacing; use of
tangential firing; and, potentially, fluidized-bed
combustion.
The meteorological aspects of the N0X pollu-
tion problem can be considered in three general areas,
which are not necessarily mutually exclusive in all re-
spects:14
1. The transport and dispersion of nitrogen
oxides—of particular importance in urban
areas.
2. The relationship between concentrations
of oxides of nitrogen and meteorological
factors, especially in relation to trans-
formation processes in the atmosphere.
22
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3. The effects of NO2 concentrations on
visibility and sky coloration*
Studies in Los Angeles give the following re-
sults for the relationships between oxides of nitrogen
and meteorological factors:
1. A correlation was found between the "hourly
average concentrations" of hydrocarbons
(HC) and N0X
2. The HC/N0X and HC/CO ratios indicate that
NO concentration is a complex function
of temperature.
3. The maximum daily N0X concentration is
inversely related to inversion height and
wind speed and is independent of light
intensity.
4. The maximum daily oxidant concentration
is a function of the square root of light
intensity.
Similar studies In Cincinnati^ generally con-
firm these and other observations. For example: HC,
NO, and CO reach their peak concentrations at about
8:00 a.m., NO2 about 9:30 a.ia. » while O3 increases
monotonically through the period. The ratios C0/N02,
CO/NO, and NO2/NO increase rapidly on warm days, where-
as the NO2 peak occurs later on cold days. However,
to a considerable extent each city is unique. The rela-
tive ratios and quantities of pollutants emitted and
their effect on ambient conditions vary greatly because
of differences in fuels burned, types of boilers and
furnaces, nature of industry and of transportation,
and meteorological conditions. Although nationwide
emission standards are being established, it is impor-
tant that better models be developed for individual
cities and local air-quallty regions with respect to
the sources and fate of air pollutants, so that local
decisions can reflect optimum strategies both for con-
tinuous control and for action under emergency
conditions.
23
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The national ambient air quality standards for
NO rest very heavily on a series of studies in Chatta-
nooga, Tennessee, on school children. 3»i+* 5»5* 7»22*23
These standards call for a mean concentration of NO2
not exceeding 100 pg/m3 during the year. It is not
clear, however, that these studies provide a sufficiently
broad data base for firmly establishing ambient air stan-
dards for N0X. It involved primarily children, and the
majority of the N0X was produced by a single source.
The fluctuations of N0X concentrations around mean values
(including relatively higher peak concentrations) are
wider with a single source than witfi multiple sources.
Health and environment effects may be more attributable
to peak concentrations than to mean values. The current
ambient-air standard for NOx is probably being exceeded
in portions of major cities of the United States; there-
fore, additional data should be sought to confirm this
standard. The current view of the EPA appears justified
in that it is reasonable and prudent when promulgating
air quality standards, to give consideration to re-
quirements for a margin of safety that would take into
account possible effects on health, vegetation, and
materials that might occur. However, the Panel does
not feel competent to evaluate the standard itself,
from the viewpoint of hazard to health and welfare.
A national strategy may be needed to achieve
substantial reduction of N0X levels in urban areas.
Ground-level concentrations appear to be related to
mobile sources and domestic heating more than to large
single sources that discharge through tall stacks. A
program of monitoring, modeling, and land-use planning
will need to be developed for each urban area in order
to obtain acceptable air quality with respect to nitro-
gen oxides and other pollutants.
In 1970, electric utilities placed new orders
for electric generating equipment of about 30 million
kilowatts capacity to burn fossil fuels and of about
15 million kilowatts capacity using nuclear fuel. For
various reasons it is expected that this ratio of two
to one for new equipment using fossil and nuclear fuels
will be maintained for the next several years, thus
ensuring that the generation of N0X will be a continu-
ing significant problem. Electric utilities in the
24
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past have been dependent upon equipment manufacturers
for research and development. Control of NOg and other
pollutants may require them to engage in research and
development to solve their individual problems. Encour-
agement to do so will depend heavily on the attitudes
of the regulatory agencies, which must approve the rates
charged by the utilities for electrical energy.
Fuel use involves many factors* One has been
the increasing emphasis on air-pollution control and
the substitution of low-sulfur oils for some of the
high-sulfur coals. There has also been a balancing of
installed equipment in utilities systems to use low-
capital -cost t peaking-type (gas ox oil) equipment to
supplement the base-loaded nuclear equipment as it is
added to a system, so some of the growth in oil firing
during the recent past was of the peaking variety, and
some of it was the substitution of oil for coal (espec-
ially along the Eastern Seaboard) where oil can often be
brought directly into the power plant. Considerations
of fuel availability and strategies for N0X control could
lead to conversion of smaller sources to gas.
other factors are expected to spur research and deve op-
ment of coal gasification, fluidized-bed combustion, and
changes in combustor design. It is generally agreed
that at present the state of the art for gas and o 1
firing permits the concentration of NO in the stack
gas to be reduced to somewhere in the range of 150 to
250 ppm* on large units employing one or more of the
latest combustion modifications.
The importance of air-pollution control is
clear. However, an economic price must be paid and the
cost of reduction of any pollutant, per unit quantity of
*The concentration of NO* is obviously affected by the
amount of excess air used. To have a common basis or
comparison it is customary to calculate the NO* concen-
tration that would exist on a water-free basis if the
oxygen concentration in the exit gases were 3 percent.
For regulatory and other purposes, it may be desirable
to express N0X emissions in terms of quantity produced
per Btu released or kilowatt-hour generated.
25
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that pollutant, increases the higher the percentage re-
moval specified. For lower concentration streams the
cost per unit removal also increases with the total
volume processed. These economic costs can be major
and will ultimately be borne by the economy as a whole.
They should not be glossed over in the nation's drive
toward cleaner air. For those pollutants that already
are or may become global problems, it is important that
global standards be adopted.
26
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IV
FORMATION AND CONTROL OF EMISSIONS
FROM COMBUSTION SOURCES
A. EQUILIBRIUM AND KINETICS
It appears that most of the NO is formed "by
the high-temperature reaction of molecular nitrogen and
oxygen present in the combustion air via the following
chain-reaction mechanism:2I+
O2 $ 0* + 0*
0- + N2 $ NO + N«
N- + 02 $ NO + 0-
Some of the NOx doubtless also results from the oxida-
tion of organically bound nitrogen in the fuel.
The fixation of nitrogen atid oxygen is thus
represented by the overall reaction:
N2 + 02 » 2N0
The rate and extent of this reaction increases very
rapidly with increased temperature. The theraodynaiaic
equilibrium constant is given by:^7
K ¦ 21.9 exp (-43.40G/RT)
The formation of NO is favored at high temperatures.
Equilibrium concentrations of NO at flame temperatures
are of the order of 3,000 ppm, while the NO2 levels
are negligible.
The concentrations of NO actually found in
the stack gases are usually much less than the equilib-
rium concentration that -could ©x:U£ at the £lame Tem-
perature in the furnace but much greater than that
corresponding to the temperature of the gases leaving
the furnace. It seems likely, then, that the NO con-
centration is determined by the time-temperature-com-
position history of the gases as they move through a
27
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furnace or other combustion system. This theory is
supported by theoretical chemical kinetic calculations
and experimental studies on premixed flames that show
that the NO is formed after most of the fuel combustion
has been completed. These experiments also indicate
that the NO-formation process is strongly temperature-
dependent (the most rapid rates occurring at peak com-
bustion temperatures) and that little, if any, NO de-
composition occurs. It is therefore concluded that the
amount of NO emitted in gas- and oil-fired systems is
essentially determined by the characteristics of the
forward reaction forming NO. For coal firing, however,
the amount of NO in the gases may go through a maximum
and decrease as the gases cool. It is possible that the
ash may have a catalytic effect in decomposing some of
the NO initially formed at the higher temperatures. Al-
though NO2 is favored thermodynamically over NO at lower
temperatures, relatively little is formed during the
rapid cooling of combustion gases in passing through a
furnace and in dispersion into the atmosphere. About 90
to 95 percent of the N0X dispersed into the atmosphere
is in the form of NO.
Fundamental differences remain in understand-
ing just how NO is formed in a furnace. One viewpoint
applicable to one-dimensional premixed air-fuel systems,
which lends itself readily to quantitative modeling, re-
gards most of the NO as being formed after much of the
fuel combustion has been completed. The NO concentra-
tion is thus regarded as being determined by the time-
temper ature-compos it ion history of the gases as they
flow through a furnace or other combustion system* An-
other viewpoint applicable particularly to gas fuel, but
also to some extent to oil and coal, considers most of
the NO in a furnace (which is not operated to minimize
NO formation) as being formed in the primary combustion
zone within a few feet of the burner. NO is visualized
as being formed as pockets of fuel react in the primary
zone near the burners at near-stoichiometric conditions-
-conditions essentially unrelated to the burner air-fuel
ratio. The burner air-fuel ratio, rather, determines
the number of pockets or eddies that react at near-
stoichiometric conditions, each reaching peak tempera-
ture and forming high NO. The amount of NO formed in
28
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each pocket depends upon the temperature-concentration
history of the products in each pocket as it passes out
into the bulk-gas region, mixing with air and products
of combustion as it goes. Firing fuel-rich may be con-
sidered as reducing the number of pockets reacting in
the primary zone, thus reducing NO formation.
The amount of NOjj formed in boilers can, in
principle, be calculated by solving the coupled set
of three-dimensional differential equations describing
the transfer of mass, momentum, energy, and species.
Such a solution would include the effects of flow pat-
tern, interaction between flow patterns, molecular and
turbulent diffusion, chemical kinetics, two-phase flow,
and radiation-heat transfer. However, due to basic
uncertainties concerning how to describe such phenomena
as turbulence and to the complexity of solving these
equations, the mathematical models are necessarily a
simplification of the real situation. They have made
valuable contributions to understanding the basic pro-
cesses relating to NOx formation and thus to suggesting
ways of modifying boilers for lower NOx production. They
cannot, at present, accurately predict the change in NOx
formation that will be caused by a given modification.
These mathematical models are undergoing constant refine-
ment as their predictions are tested against data and
as the effects of various simplifying assumptions be-
come clearer. They may be used as aids to the planning
of laboratory and field testing of combustion-modifica-
tion techniques, in the evaluation of data from such
testing, and in the design of new boilers and modifica-
tion of old ones to achieve minimum NOx.
Experimentation to develop new firing methods
for minimizing NOx emissions should be aooompccnied by
theoretical analyses -of the data, obtained in orderto
develop mathematical models of general usefulness for
prediotion,
B. FACTORS AFFECTING UTILITY BOILER EMISSIONS
The major factors affecting the formation of
nitrogen oxides in combustion processes, based on both
theory and practice, are:
29
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1. Combustion temperature, NO-formation
equilibrium and kinetics are extremely dependent upon
peak combustion temperatures, with higher peak tempera-
tures favoring higher emissions.
2. Availability of combustion air. NO for-
mation is dependent upon the availability of air for
the "fixation" reaction shown.
3. Mixing of fuel3 airA and combustion pro-
ducts. Internal recirculation or "backmixing" of com-
bustion products into the combustion zone dilutes the
fuel and air, lowers the flame temperature, and thereby
reduces N0X emissions. Distribution of the fuel and
air so as to achieve most of the combustion under fuel-
rich conditions and the rest under fuel-lean (excess
air) conditions also reduces N0X emissions. Slow
diffusion of the fuel and air streams can also accom-
plish this objective.
4. Heat release and removal. Low heat-re-
lease rates and high heat-removal rates reduce NO for-
mation, because lower peak temperatures and shorter
residence times at high temperatures are achieved.
5. Fuel type. On an equivalent heat-input
basis, using modified combustion techniques, coal firing
usually emits the most N0X; oil emits less; and gas the
least,
N0X emissions from combustion sources can be
reduced by two major techniques—combustion modification
and flue-gas treatment. Combustion-modification tech-
niques presently appear to be the quickest and most
economical methods of accomplishing major reduction of
N0X emissions. Those techniques¦that have been con-
ceived (some have been tried) are low-excess-air opera-
tion, staged or off-stoichiometric combustion, flue-gas
recirculation, reduced air preheat, steam or water in-
jection, or a combination of these techniques.
Low-excess-air combustion reduces NOjc emis-
sions because the availability of oxygen is reduced.
Staged or off-stoichiometric combustion is the technique
30
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of introducing combustion air in stages so that the par-
tially burned fuel and combustion products are permitted
to cool before the completion of combustion; thus, the
simultaneous exposure of the nitrogen to oxygen and to
high temperatures is avoided. Much of the combustion
occurs under fuel—rich conditions*
External recirculation of flue gas into the
combustion zone, like internal "backmixing," dilutes the
fuel and air, lowers the flame temperature, and thereby
reduces NQX emissions. Injection of steam or water into
the combustion zone or the reduction of air preheat also
has the same effect. Flue-gas recirculation has been
practiced for many years as a method of adjusting tem-
perature distribution in a boiler, but this has usually
not involved recirculation back to the burner region,
which is required for optimum NOx control.
Low-excess-air staged-combustion and gas-
recirculation techniques have been used successfully
by some California utility companies firing gas25 and
applicability to oil firing is being investigated by
these same companies.26 However, very little work has
been done to apply these and other combustion-modifica-
tion techniques to coal-fired units. The alteration
of firing procedures may also affect the heat-transfer
characteristics of a boiler and hence the thermal
efficiency, consequences that must be kept in mind in
searching for suitable modifications.
Flue-gas treatment, the second technique, is
the removal or decomposition of the NOx after it has
been formed and is described in more detail in Chapter
V of this report. The most promising candidates for
further development are aqueous scrubbing systems using
alkaline solutions or concentrated sulfuric acid. To
be effective, however, the N0X must be scrubbed out in
equimolar concentrations of NO and NO2* Since less
than 10 percent of the NOx present in stack gases is
NO2 and the remainder is HO, some method of equalizing
the concentrations is needed. The best method appears
to be the recycle of N02» since catalytic oxidation
of "NO to N02 in the main flue-gas stream is both too
expensive and too slow. Other flue-gas treatment
31
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techniques that are candidates for development are cata-
lytic reduction, adsorption by solids, and catalytic de-
composition, the last being probably the least promising.
The amount of N0X formed per unit quantity
of heat released an uncontrolled combustion can vary
by a factor of about 10 depending on a number of inter-
related considerations:
1. The fuel (coal3 oita or gas),
2. The percent excess air used in combustion.
Z. The size of the furnace. As furnace sizes
increase from domestic heating units to large utility
boilers, the amount of N0X formed per Btu released usu-
ally increases, probably because of lower surface-to-
volume ratios, which lead to less rapid thermal quench-
ing of the combustion process. For large utility
boilers, increased furnace volume (while holding all
other variables constant) will act to reduce the average
temperatures and will therefore always act to reduce
N0X. However, it appears that the effect of furnace
volume on NQX formation is of secondary importance when
compared to other combustion-control modifications such
as off-stoichiometric combustion. This is not to say
that furnace volume is insignificant. In designs in
which combustion is spread out in the furnace (e.g.,
tangentially fired units) it seems likely that in-
creasing the furnace volume would cause a reduction
in H0X.
4. Burner design. Designs that produce
more intense combustion and higher temperatures, (e.g.,
cyclone burners for coal) produce considerably more
N0X than designs that allow combustion to occur out
in the furnace, (e.g., tangentially fired boilers).
It is impractical, however, in an existing installation
to replace cyclone burners with tangential burners lo-
cated in the furnace corners, for this would require
nearly complete rebuilding of the furnace. It is not
the fact that the burners are positioned to admit fuel
and air in a tangential configuration that brings about
a reduction in NO formation, but rather the manner in
32
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which fuel and air are admitted and mixed. It may be
possible in some instances to incorporate the mixing
features of tangential burners into wall-fired burner
designs as more is learned of these features. In other
instances where cyclone burners are required because
of the specific type of coal used, this may not be
possible.
5. Load. As load is first reduced in any
particular installation, the concentration of N0X formed
at first drops. With further reduction in load, the
change in N0X concentration is determined primarily by
the degree to which increased air-fuel ratio may be
required to prevent excessive carbon monoxide or smoke
at lower loads.
Certain residual fuel oils, e.g., those from
California and Venezuela, have a relatively high content
of organo-sulfur and organo-nitrogen compounds. Fuel
oils from California are especially high in organo-
nitrogen compounds. The nitrogen content is usually
lower than the sulfur content in oils that have not
been desulfurized. The range of the nitrogen in Califor-
nia residual fuel oil is about 0.3 to 1.0 percent, and
for a Venezuelan fuel oil, from 0.1 to about 0.5 percent.
Desulfurization of fuel oil also removes some of the
nitrogen and the fraction of nitrogen removed increases
as operating conditions are altered to increase sulfur
removal. With firing of residual fuel oil in conven-
tional equipment, as a rough guide, perhaps about a
third of the fixed nitrogen is emitted as N0X.
Many coals contain substantial quantities of
fixed nitrogen. One percent nitrogen in coal would re-
sult in about 1,500 ppra of N0? in the stack gases
(stoichiometric conditions) if it were all coiivferted
to N0X. Even though much is in fact released in the
form of S2, the remainder can be a significant contri-
bution to total HQX emissions.
Pvetirninapy d/oLtaexist regard'ingthe relative
importance of conversion of fixed nt-tvogen vn &&lvfuet$
to N0X. These data suggest that combustion of oil
ox* coal under reducing (sub-stoiohiometria air) con-
ditions in a first stage helps reduce the amount of
33
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fuel nitrogen converted into NOx or increases the con-
version of N0X to N2 and combustion products, but addi-
tional work is needed.
Boiler manufacturers are being asked to pro-
vide guarantees on the maximum amount of NO^ that will
be emitted. Of the three fuels used in firvng3 gass
oilj and coaly gas allows the most precise control in
the attainment of the lowest levels of N0X, The term
"coal" covers a variety of types of solid fuels varying
greatly in their combustion characteristics, and there-
fore a substantial variety of boiler and burner designs
are required to burn these various types satisfactorily.
Present emission levels from coal firing vary greatly.
Of the three fuels3 least is known about coal relative
to minimizing N0X formation from combustion. The Panel
is aware of only three instances in which coal-fired
utility boilers have been operated with staged admission
of air or two-stage combustion. The results were en-
couraging and need to be extended.
A long lead time is required for the sequence
of research, development, design, construction, and
operation. A realistic goal for 1980 for firing of
natural gas in new plants is a reduction in concen-
tration to about 100 ppm from present-day values, which
are about 350 to 400 ppm uncontrolled,, but range as
high as 1J400 ppm. However, natural gas may not be
available as a fuel for utility boilers very far into
the future. For oils the most common range today when
the combustion process has not been modified is about
180 to 280 ppm for tangentially fired units and ZOO
to 700 ppm for horizontally fired units. A realistic
goal for 1980 in new plants, achievable by flue-gas
recirculation and/or staged combustion, is 150 to 200
ppm.
Both theory and practice indicate that N0X
emissions from combustion sources are lowered by:
(a) reducing the amount of oxygen present in the flame
zone, as by use of staged or off-stoichiometric combus-
tion admission of air, and (b) reducing the peak flame
temperature, as by use of flue-gas recirculation. The
practicality of these techniques has been tested pri-
marily in furnaces burning gas or oil. Limited data
34
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make it appear that flame-temperature-con caseous
may not be as beneficial with oil a® w
fuel. Little has been done on coal-fired un
The principal problem in reducing N0X e*^sions
by the use of staged and off~stoichl^eJl!fJi^vUi,l_
is achieving the reduction without sign or
creasing emissions of CO, hydrocarbons, an »
«ith coal, increasing the hazard from
creasing unbumed carbon in the ash. e ^nns4(jerably
of these techniques to coal firing ^V^^^nd with
with the slagging characteristics of the coal and with
burner designj e.g., gas recirculation may hurner
effective with cyclone burners than with other
designs, if gas is recirculated into
cause most of the combustion occurs within
burners. However, if a modified operation ( fltion
burner redesign) could be established for rec e_
directly into the cyclone, this approach mig
ful.
Costs for boiler modifications are ,
varied. For example, as of March 1971, J-os®* "J
Power plant costs range from $100 to $3 P _
of capacity. The boiler alone costs $35 to .
kilowatt. 3?or large new gas-fired units the
of flue-gas recirculation (to the windbox) adds about
$2.65 per kilowatt. The cost of
staging would add about $0.15 to $0.2 m _ * ar*. of the
fired units some recirculation is generally P
basic designj to modify it to recirculate to
box adds about $1,50; over-fire air $0.50.
$3.50; staging costs an additions • $ . ^ an additional
Oversizing a boiler by 50 percent wi „ used.
$3.75 to 57.50 per kilowatt depending '
The potential benef its of ln oomparison with
reduction of NO appear to be small in P ^lstinjj
other methods of NO control•
units for gas recirculationor redis ^ clted above.
vould be much more expensive than
The definition of what cons« "V
Plant is difficult but iaportant, since the^firsts^
of emission standards are specified PP y
35
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plants." For nitrogen oxides particularly, most of the
control methods now available depend on boiler modifica-
tions, so it would appear that once the purchaser has
specified the boiler, the plant can no longer be termed
new. There is about a seven-year pferiod between initial
commitment by the utility and the operation of a new
power plant. The first set of ambient air standards
that will become applicable in 1975 is based, first,
on what is desirable, and second, on what is achievable.
With respect to utility boilers, presently
feasible technology for control of NO varies greatly
with the fuel used, the nature of the Durners (e.g.,
cyclone versus tangential burners), and the age of the
unit. Boiler manufacturers and utilities should in-
corporate as much flexibility as possible in the design
of new boilers to be able to take advantage in the
future of the growing knowledge of the factors affecting
N0X emissions in combustion. A long time scale is
involved between design and actual operation of a
boiler which tests out-the effect of substantial mod-
ifications. Because boilers are highly complex, only
a two-to-one to four-to-one extrapolation on size in
construction can be justified and much testing must be
done on full-size units. Thus the testing of new con-
cepts is a lengthy and expensive procedure,
C. FLUIDIZED-BED COMBUSTION
Coal (or oil or gas)*can be completely burned
at l,400p F. to 1,8Q0° F. within a bed of limestone,
dolomite, ash, or inert particles suspended by the flow-
ing combustion air and products* Such a system promotes
high volumetric heat release, and high heat-transfer
rates to steam tubes submerged in the particle bed.
Boilers can thus be made smaller and cheaper. Such
boilers may also reduce atmospheric pollution. The
limestone or dolomite absorbs most of the sulfur con-
tent of the fuel and the production of N0X is reduced
due to the low combustion temperature in the bed. The
quantity of fine particulates produced is also less be-
cause typically the coal is in the size of 100 mesh to
1/4-inch material in contrast to 200 mesh in pulverized
coal burners.
36
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Research and development in fluidized-bed com-
bustion was begun by the British Central Electricity
Generating Board and has been continued by the National
Coal Board (NCB) in Great Britain and by the U.S. Depart-
ment of the Interior's Office of Coal Research (OCR),
and more recently by contractors of the OAP of the EPA
in the United States. Steam-generating pilot plants
have been built and operated at both atmospheric and
superatmospheric pressures.
Fluidized-bed boilers can be operated at at-
mospheric pressure as a replacement for conventional
pulverized fuel boilers or at pressure (8 to 30 atmos-
pheres) with air compressors and gas turbines in a com-
bined-cycle power plant. The British NCB and Westing-
house, under contract to OAP, have produced boiler de-
signs and have estimated the performance of fluidized-
bed boilers in utility power plants. Estimates indicate
that the cost for power plants based on pressurized
fluidized-bed boilers will be 20 to 30 percent less
than for conventional plants with stack-gas scrubbing
systems (for removal of SO2)• Six contractors to OAP
have also demonstrated the air-pollution-control poten-
tial of such devices.
Fluidized-bed combustion in the past has been
used for coal, oil, gas, or waste material. Currently,
paper-mill wastes are burned in fluidized-bed combustors,
as are oily wastes from refineries, sewage sludge, and
trash. N0X formation in fluidized-bed combustion can
be reduced to below that ih conventional furnaces. The
equilibrium concentration of NO with 10 percent excess
air at temperatures between 1,400° F. and 1,900° F. is
about 30 to 70 ppm. It has been generally observed
that burning coarse coal containing approximately 1.0
to 1,4 percent fixed nitrogen in fluidized beds results
in 250 to 500 ppm of N0X in the off-gases. However,
the Argonne Laboratory has observed that, with use of
80 percent of stoichiometric air, the N0X concentration
is only 50 to 70 ppm. The NCB, under contract to OAP,
has carried out fluidized-bed combustion in tests at
five atmospheres in which N0X emissions have ranged
from 50 to 150 ppm. It appears that the lower the SO2
content, the higher the N0X content of the flue gases,
37
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i.e., that some reaction occurs between limestone, S02>
and N0X in a fluidized bed to help remove N0X.
On the basis of taboratory and small-scale
workt pressurized fluid-bed boilers show -promise of
having advantages over conventional coal-fired boilers*
Combustion occurs at substantially lower temperatures
than in ordinary combustion processes and the N0X formed
comes largely from fixed nitrogen in the fuel. N0X
emissions may be somewhat reduced by additives to the
bed. "Two-stage" fluid-bed combustion (reducing con-
ditions in the bed, followed by secondary air injection)
can reduce N0X to low levels, according to laboratory
data. Pressurization also appears to reduce N0X emis-
sions from fluidized-bed combustion of coal to a low
level.
D. OTHER COMBUSTION PROCESSES
1. Gas Turbines
Stationary gas turbines and diesel engines
are sources of significant NOx emissions. Some of the
simplest approaches to control of emissions from diesel
engines are: retard the timing to the range in which
both the smoke and N0X emissions decrease; and use a
larger period of injection for the same amount of fuel
so that the rate of heat release in the cylinder is de-
creased. Rate of injection and retarded timing tend
to be more of a problem on high-swirl chambers and less
of a problem on quiescent chambers. Another method is
staged injection—pilot injection followed by main in-
jection. These techniques have been shown to produce
a fairly high reduction in N0X from existing engines,
although there is a penalty in some loss in thermal
efficiency. Water injected into the intake manifold
or emulsified in the fuel for diesel engines has also
proven successful, as has exhaust-gas recirculation
and lowering of the compression ratio.
On turbines the techniques of exhaust re-
circulation, water injection, and combustor redesign
are also applicable. A combination of fuel-injection
techniques and lean operation appears to offer the most
38
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promise for reducing N0X from gas turbines.11!12 This
involves changing the mixing patterns, adding excess
air at various points along the length of the combustor,
and recirculation of a portion of the exhaust gases.
Various fuel additives may possibly reduce emissions,
but no demonstrated technology or promising research
data exist.
Approximately 20 percent of the capacity of
the electrical generating additions in 1970 were in the
form of gas turbines for peaking power. In 1985, perhaps
as much as 30 percent of the capacity of the additions
may be in the form of gas turbines, both for supplying
peaking power and for use in combined cycles. The com-
bined cycles would be for intermediate generation, 40-
to-60-percent load factor. A variety of combined-cycle
plants can be visualized but typically a portion of the
power is generated by a gas turbine and the remainder
by a steam turbine. The outlet temperature from the
combustor of a gas turbine is typically 1,600° F. and
will probably be 1,800° F. in a few years. A rise to
2,000° F. or 2,200° F. can be projected as the years
pass and higher efficiencies are sought and technology
becomes available. An 1,800° F. outlet temperature
gives approximately 170*27 ppm of N0X with 250-to-300-
percent excess air, which is equivalent to 570 ppm (dry,
3 percent O2). These gas-turbine N0x emissions were
measured while burning jet fuel; the amount of N0X pro-
duced while burning low-Btu gas produced by coal gas-
ification is unknown and needs to be determined. With
gas turbines, more of the NOx produced is in the form
of NO2 because of the high excess air at which they
operate, and they can show a noticeable plume with
about 9 or 10 ppm NO2.
Estimates of N0X emissions produced by in-
ternal-combustion enginesj either reciprocating or
turbines9 used with pipelines and gas plants vary
widely. Estimates range from 21 percent to 2 percent
of the total N0X emissions from stationary sources.
*Heavy-duty gas turbine at full load (19 megawatts)
using jet fuel*27
39
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The resolution of this discrepancy requires further in-
vestigation. With diesel engines> a variety of tech-
niques, such as control of fuel injection, exhaust-gas
recirculation, water injection, and alteration of com-
bustion-chamber design, are available to reduce NOx
emissions to substantially below the uncontrolled level.
Exhaust-gas recirculation and water injection are also
potentially applicable to stationary engines other than
diesels. Catalytic mufflers developed for control of
emissions from vehicles may also be applicable to sta-
tionary engines. Indeed, control of emissions from
stationary engines should be easier than with mobile
engines. They usually run continuously at constant
load, and space and weight limitations are less. With
gas turbines, redesign of combustors and methods of
fuel injection accompanied by more fuel-lean conditions
in the combustion zone should produce significant re-
duction in NCL emissions.
Burning coal in a reducing atmosphere (e.g.,
60 percent theoretical air) with added water or steam
generates a low-Btu gas, which can be burned in a
boiler or gas-turbine combustor. This process, called
gasification, reduces the quantity of NOx formed in
steam or power generation much as does two-stage com-
bustion of natural gas. Coal and/or oil gasification
provides interesting possibilities not only for re-
ducing N0X but also for removing particulates and
sulfur in the form of hydrogen sulfide. The volume
of fuel gas, usually produced at 10-30 atmospheres
pressure is much less than that of the stack gases,
and thus particulate and sulfur removal are simplified.
Many different gasification processes and power-gen-
eration cycles have been suggested. The supercharged
combined gas turbine-steam turbine and magnetohydro-
dynamic (MHD) cycles have the potential of further
improving the heat efficiency of the entire cycle and
reducing power-plant capital costs, whereas other sys-
tems for removing NQX and S0X may offer only air-pollu-
tion control.
Combined-cycle systems involving the combus-
tion of coal or oil in a combination of steam turbines
and gas turbines are of considerable interest to util-
ities. Some of these may involve external coal-gasifica-
40
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tion processes close-coupled to a turbine or boiler.
N0X emissions are expected to be low, but little infor-
mation is available.
Reliable commercial methods for gasification
of coal to produce both a synthetic natural gas to sup-
plement existing natural-gas supplies, and a gas of less
than pipeline quality to be used as an electric-utility
fuel and probably having other commercial, industrial,
and residential uses, are of considerable interest.
Fuel costs will be higher than projected gas prices or
the cost of the same amount of energy from coal. How-
ever, the advantages of an environmentally acceptable
"clean" fuel and the reduced capital cost and increased
efficiency of combined-cycle plants may outweigh the
higher fuel costs for power generation.
Magnetohydrodynamic generation of electricity
uses high pressure and temperature combustion with seed-
ing of potassium or cesium to raise the gas-ionization
level. The gas is then passed through a magnetic field
to generate direct-current electricity. The hot exhaust
gas is sent to a boiler or turbine for additional elec-
tricity generation so that the complete system is very
efficient. The combustion occurs at such high tempera-
tures that significant quantities of N0X are produced.
Any economic evaluation of MED as a future
power source should incorporate as a part of the ana-
lysis the economic costs of control of the large amounts
of N0X that will undoubtedly be formed. If flue-gas
recovery methods for N0X were developed in conjunction
with MHD, they could have a major Impact on nitric
acid (HNO3) manufacture. Pollution-control costs have
a significant influence on the economics of this method
of energy generation.
2. Domestic Heaters
Since domestic heaters are small and involve
a great diversity of equipment, no single solution is
universally applicable.28 Rather, control of pollution
emissions will require a series of solutions tailored
to the various classes of furnaces or boilers. Two
41
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courses of action are available for development of the
required control techniques: (1) improve current com-
bustion equipment for short-term abatement, and (2) de-
velop new burner systems for the future.
Domestic heaters are generally used in single-
family homes and typically have an output of about
150,000 to 200,000 Btu/hr. These units are numerous
and emit pollutants at ground levels in highly populated
areas. However, the NOx-concentration levels are lower
than those of large boilers. The same is true of
domestic incinerators. Control of nitrogen oxides and
combustible particulates from these units will require
a better understanding of the critical features of the
burner and combustion chamber designs and the flame
structure. Changes in design of nozzles, ignition units,
air-introduction devices, pressure controllers, and fuel
pumps offer ways of reducing emissions. Better control
of heating cycles, improved combustor design, and fuel
composition may also be important.
3. Industrial Furnaces
Large commercial heating units and industrial
furnaces generally fall in the size range between do-
mestic furnaces and utility boilers.17* Methods of
control developed for these two extremes will be gen-
erally applicable to industrial and commercial units.
Flue-gas recirculation and "staged" combustion offer
significant potential in such units.
Industrial furnaces in refineries, cement and
lime kilns, glass manufacturing, and metallurgical op-
erations represent a special class since their primary
function is to provide heating at high temperatures.
It is not generally possible to apply such methods
as flue-gas recirculation and staged admission of air.
Therefore, combustion-modification techniques using
peak temperature reduction are not possible. con-
trol from these isolated single sources will require
special consideration in keeping with the unique appli-
cations of the units.
In petroleum refineries or petro-chemical
42
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processing, feed or process streams are heated in a con-
trolled manner and they generally cannot be subjected
to conditions that would result in thermal cracking or
product degradation, as might occur on dilution or tem-
perature reduction.
4. Incinerators
Refuse disposal by incineration results in
N0X emissions that may be significant locally.29 For
large units, emissions average about 25 ppm or approx-
imately two to three pounds of NOx per ton of refuse
burned. It appears unlikely that reduction of N0X
emissions to lower levels can be achieved by process
changes.
A3
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V
STACK-GAS CLEANING
The observations and conclusions of the Panel
presented in this section are in general agreement with
a recent study by ESSO Research and Engineering that
included an assessment of existing and potential N0X-
control technology for stack gases.17
(a) If a flue-gas treatment process is re-
quired, aqueous scrubbing systems using aqueous alka-
line solutions or concentrated sulfuric acid appear to
offer potential for the control of both sulfur oxides
and nitrogen oxides emissions.
(b) Selective catalytic reduction of N0X
with ammonia, hydrogen sulfide, hydrogen, or carbon
monoxide is also a possibility.
(c) Silica gel, alumina, molecular sieves,
chars, and ion-exchange resins all show some catalytic
activity for oxidizing NO to N0£, a step that is re-
quired in conjunction with any scrubber system to raise
the NO2/NO ratio to at least unity. However, the capac-
ities are quite low at typical NO flue-gas concentrations.
(d) No flue-gas treatment process has so far
been directly applied to NOx-emission control in power
plants.
(e) No catalyst has been found that is effec-
tive for a single low-investment NO-decomposition pro-
cess, and the probability of discovering such a catalyst
is small. In some reports of catalytic decomposition
it appears that the N0X was actually reacting with the
"catalyst" or with a reducing agent rather than decom-
posing as such.
(f) Success in the removal of NOx from com-
bustion flue gases based on differences in physical
characteristics such as molecular size, condensation
temperature, or magnetic susceptibility appears to
be highly remote.
44
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Two systems that appear to offer the best
possibility for removal of N0X in the exit gases are
magnesium oxide scrubbing and the Tyco modified lead-
chamber process.12,20»31 Catalyst systems being de-
veloped for automobile exhaust control may also be
applicable in specific cases.
The low solubility of NO requires that NO2
be added to the flue gas to form soluble N2O3 or that
about half of the NO be oxidized to NO2, in either
magnesia scrubbing or the Tyco process. The use of
two scrubbing systems to remove SOx and N0X in sequence
is a major expense. However, the Tyco process has the
potential for removing SOx and NOx simultaneously.
Since NO2 must be recycled to achieve the least equal
parts of SO2 and N02, the scrubber that removes N0X
miist be highly efficient* For typical conditions
(3,000 ppm S0X) about 90-percent scrubber efficiency
in NOx removal is required just to keep the process
going for S0X removal even with no net NOx removal.
Ninety-nine percent efficiency is required to achieve
a level of 50 ppm N0X in the final stack gas, starting
with an initial concentration of about 800 ppm. Esti-
mates of the cost of the process are highly sensitive
to the degree of removal of N0X in the flue gas, assumed
scrubber efficiencies, and the value of the sulfuric
acid and nitric acid produced.
No proven process is available for substantial
removal of N0X from combustion stack gases. The Panel's
definition of a proven process is one year of satis-
factory operation on an industrial scale. Scrubber
or adsorption systems proposed primarily for S0X re-
moval should also be evaluated for their potential in
removing Wx simultaneously.
Any wet scrubber system for N0y removal will
be expensive because:
(a) Most of the N0X is in the form of NO,
which is relatively unreactive and relatively insoluble.
The maximum rate of absorption in an aqueous system
occurs at a NO/NO2 molar ratio of unity, which requires
1) recycle of NO2 and a method of generating NO2 from
45
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the scrubbing system or 2) the oxidation of half of the
NO to NO2. The rate of oxidation of NO to NO2 is slow
and decreases with increasing temperature,
(b) Large vessels are required for scrubbing
because of the large volume of gas that must be handled
and the necessity for low-pressure drop.
Aqueous scrubbing systems, such as those using
sulfuric acid, are In an early stage of development.
It is necessary to generate NO2 and recycle it to the
scrubber in order to achieve practical rates of NQx
absorption, which in turn requires very high scrubbing
efficiencies for substantial overall removal of N0X.
Any new concepts showing potential for simul-
taneous removal of NOx and S0X should be encouraged,
but their economic practicality should be carefully
scrutinized.
It is deemed unlikely that a good absorbent
can be found for removal of NO as such. However, any
new ideas in this respect should be examined.
Catalytic reduction of N0X to N2 by a reducing
agent such as ammonia as a process for treating stack
gases from large utility boilers requires a sulfur-
resistant catalyst If coal or oil is used as a fuel.
Space velocity (i.e., catalyst activity) and catalyst
life also limit this approach at present. Available
information is insufficient £0 assess the potential
of this method of control.
Decomposition of N0X In the absence of a re-
ducing agent requires such high temperatures, on even
the best catalysts known, that It Is impractical.
A substantial reduction In t.he amounts of NO*
released to the atmosphere (e.g.s of the order of 50
to SO percent) will come most economically from modifica-
tions of the combustion process rather than from scrub-
bing or adsorption systems to remove N0X from stack
gases.
46
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VI
FORMATION AND CONTROL OF EMISSIONS
FROM CHEMICAL OPERATIONS
Relative to emissions considered nationally,
NOx from chemical operations is quite small; but locally
these emissions can be significant.12*32»33 Essentially
all these emissions are associated with the manufacture
or use of nitric acid. About 75 percent of the nitric
acid produced in the United States is consumed in ammo-
nium nitrate production. The remainder is used in a
variety of processes, with manufacture of adipic acid
consuming 9 percent.
Because of the high ratio of NO£ to NO in the
stack gases from nitric acid plants, colored plumes are
visible at relatively low NC^ levels, on the order of
a few hundred ppm or much less, depending upon the stack
diameter. The present method of control of emissions
from nitric acid plants is primarily by catalytic re-
duction, using natural gas. It appears that, in much
of the current practice, NO2 is reduced only to NO.
This is only decolorization, not emission control.
Complete reduction to N2 using methane requires complete
burnout of the O2 present, more consumption of natural
gas, and closer control of the equipment. In addition,
CO and hydrocarbon emissions increase with increasing
NO reduction. Selective reduction of NO to N2, using
ammonia as a fuel, has been described, but there Is
insufficient information to determine whether this
process is a practical alternative.
Scrubbing with caustic soda has long been
practiced with N0X emissions from nitration reactions,
but it presents a disposal problem. Recent developments
with molecular sieves3J+ indicate that adsorption pro-
cesses based on their use may be capable of reducing
emissions to the 10 to 50 ppm level. In a nitric acid
plant, the desorbed N0„ can then be recycled to the
absorption tower. Evaluation of a molecular-sieve
adsorption process an a large demonstration scale is
timely.
47
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The quantities of N0X emitted from nitric
acid plants and chemical operations are but a small
fraction of the total man-made emissions on a nation-
wide basisj but they may comprise a significant local
source of pollution. Technology for 'decolorization"
(conversion of N0£ to NO) by catalytic reduction with
natural gas is well established. Present methods of
abatement (reduction to N2) are available to reduce
NOq from typically 3,000 ppm to 100-500 ppm3 but re-
quire careful control*17 Adsorption by molecular
sieves or other adsorbents has been shown on a bench
scale to result in even lower emission levels but no
commercially proven process is yet available. Alka-
line scrubbing is a proven process3 but would involve
liquid waste disposal problems.
In some chemical processing with nitric acid,
a substantial portion of the nitrogen oxides emitted
may be in the form of N2O. N2O is believed to be
innocuous and should be distinguished from NO and NC^.
N2O is not included with NOx-emission data.
48
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VII
SAMPLING AND ANALYTICAL METHODS
Enforcing nitrogen oxide emission standards
will require monitoring, as will enforcing particulate
emission standards.35 The circumstances are different
from those associated with sulfur oxide emissions, in
which fuel sulfur specification frequently has been
satisfactory. The method recommended by EPA for 24-
hour sampling of ambient NO2 is the Jacobs-Hochheiser
method. 3»l+»5»5»7 Nitrogen dioxide is collected by
bubbling air through a sodium hydroxide solution to
form sodium nitrite. The nitrite ion is then detected
colorimetrically by reacting the exposed reagent with
phosphoric acid, sulfanilamide, and N-(l-Napththyl)-
ethylenediamine dihydrochloride. Corrections must
be made for SC^ interference. Relative standard devi-
ations are reported to be between 14 and 21 percent
and no accuracy data are available. Alternate tech-
niques such as the Saltzraan method may differ by as
much as a factor of 3. The Jacobs-Hochheiser method
is for ambient-sample analysis and does not bear on
the validity of source-sampling data.
Nondispersive infrared and electrochemical
methods under development offer the potential of rapid
analysis and improved accuracy. Photo-ionization or
chemiluminescent procedures may also provide general-
purpose portable detectors in the future.
Maintenance of emission and ambient air quality
standards depends on accurate methods of sampling and
analysis. Careful consideration must be given to the
reliability of present methods of sampling and analysis
for NO and NO2, particularly in the presence of other
pollutants. Sufficient attention should be paid to
those problems to ensure that decisions are being made
on the basis of well-established facts.
49
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APPENDIX A
BIBLIOGRAPHY AND REFERENCES
U.S. Congress. Public Law 91-604, H.R. 17225. Clean
Air Amendments of 1970. 91st Congress. 2nd
Session. December 1970.
. Public Law 90-148. The Clean Air Aat of 1967.
90th Congress. 1st Session. January 1969.
General Services Administration. National Archives
and Records Service. Office of the Federal
Register. National Ambient Air Quality Stan-
dards. Notice of Proposed Regulations for
Preparationj Adoption9 and Submittal of
Implementation Plans. Vol. 36. No. 67.
Washington: Government Printing Office.
April 7, 1971.
. National Primary and Secondary Ambient Air
Quality Standards. Vol. 36. No. 84 (Part II).
Washington: Government Printing Office.
April 30, 1971.
. Requirements for Preparation, Adoptionj and
Submittal of Implementation Plans. Vol, 36.
No. 158. Washington: Government Printing
Office, August 14, 1971.
. Standards of Performanoe for New Stationary
Sources. Vol. 36. No. 159. Washington:
Government Printing Office. August 17, 1971.
. Standards of Performance for New Stationary
Sources. Vol. 36. No. 247. Washington:
Government Printing Office. December 23, 1971.
U.S. Department of Health, Education, and Welfare.
Public Health Service Consumer Protection
and Environmental Health Service. National
Air Pollution Control Administration. Air
Quality Criteria for Hydrocarbons. Washing-
ton: National Air Pollution Control Adminis-
tration. (NAPCA Publication No. AP-64) 1970.
50
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9. . Air Quality Criteria for Photochemical
Oxidants. Washington: National Air Pollution
Control Administration. (NAPCA Publication
No. AP-63) 1970.
10. . Control Techniques for Carbon Monoxide Emis-
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