[From the U.S. Government Printing Office, www.gpo.gov]
3 If
coastal zone
Information Coaster Zone Information Center U.S. DEPARTMENT OF COMMERCE
Center National Technical Information Service
JAN 25 1977
PB-239 159
ENVIRONMENTAL IMPACTS EFFICIENCY AND COST OF
ENERGY SUPPLY AND END USE. VOLUME II
HITTMAN ASSOCIATES, INCORPORATED
PREPARED FOR
NATIONAL SCIENCE FOUNDATION
ENVIRONMENTAL PROTECTION AGENCY
COUNCIL ON ENVIRONMENTAL QUALITY
JANUARY 197 5
HD
9502
U52
E-58
1975
v.2
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BIBLIOGRAPHIC, DATA I.- Report No. 3. Recipient's Accession NO.
SHEET EQC308v2 PB- 39-159
4. Title and Subtitle 5. Report Date
Environmental Impacts, Efficeincy, and Cost of. January 1975
Energy Supply and End Use Volume 11 6.
7. Author(s)
8. Performing Organization Rept.
No- HIT-593
9. Performing Organization Name and Address 10. Project/Task/Work Unit No.
Hittman Associates, Inc.
Columbia, Md. 11. Contract/Grant No.
EQC 308
12. Sponsoring Organization Name and Address 13. Type of Report Period
Council on Environmenal Quality, 722 Jackson Pl. Covered
N. W., D. C. 20006; National Science Foundation, 1800Final
G St. N. W. D. .20550;Envqironmental Protection 14.
Agency, 401 M St. S. W. D.. C . 20460
lip 15. Supplentary Notes
Volume I: PB-238 784
16. Abstracts The purpose of this was study was to determine the environmental im-
pacts, efficiency-,. and costs ts associated with supply and end use offossil
fuels. The output is.this 2-volume report which presents tabular, foot--
noted, and referenced dsta quantifying the energy.-related environmental
impacts on land, water air, solid waste, and occupational health. All
theinformation is also available in the form of a computerized data base
Matrix of Environmental Residuals for Energy d
Systems. Brookhaven create
the.data base and has written a number of data management andenergy
modeling programs, which with MERES are known as the Energy Model and
Data Base. Vol.II characterizes six technologies with respect to their
environmental impacts, efficiency and cost: both low- and high-BTU gas- fication of coal, Oil'shaleP fluidized bed boiler combustion, solvent
refined coal, and coal liquefaction.
17. Key Words and Document Analysis. 7a. Descriptors
Energy Energy Systems. Energy model.. MERES. Data base, Environmental:l
impacts. Air and water pollution. Solid waste. Land disruption. occupa-
tional health. Fossil fuels. Coal. Oil. Natural gas. Fuel supplies.
End use. Efficiency. Costs.,Coal gasification. Oil shale. Fluidized be
boiler combustion, solvent-refined coal. Coal liquefaction.
17b. Identifiers/Open-Ended Terms,
Reproduced by
NATIONAL TECHNICAL
INFORMATION SERVICE
17c. COSATI Fieqld/group US Department of Commerce
Springfield, VA. 22151 Prices subject to change,
18. Availability Statement 19.. Security Class (This 21. No. of Pages
Report)
CLASSIFIED
NTIS 20. Security Class (This 22. Price
Pa
UNCLASSIFIED $9.00
FORM maybe (REV. 10-73) ENDORSED BY ANSI AND UNESCO. THIS Form MAY BE REPRODUCED USCOMM-qDC q82q6q5-P7q4
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ENVIRONMENTAL IMPACTS, EFFICIENCY
AND COST OF ENERGY SUPPLY AND
END USE
VOLUME, II FINAL REPQRT
HIT-593
January 1975
Work Sponsored by
The Council on Environmental Quality,
RANN Program,of The National Science Foundation, and
The Environmental Protection Agency
Contract EQC 308
U S DEPARTMENT OF COMMERCE'NOAA
2234 COASTAL SERVICES CENTER
OUTH HOBSON AVENUE
0qN
LA- HITTMAN ASSOCIATES, INC.
COLUMBIA, MARYLAND
Property Of CSC library
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LEGAL NOTICE
"This report was prepared as'an account of work sponsored by
the United States Government. Neither the United States nor the
Council on Einvironmental Quality, nor any of their employees,
nor any of their contrators, subcontractors, or their.employees
makes any warranty, expressed or implied, or assumes any legal
liability or resonbility for the accuracy, completeness or
usefulness of any information,apparatus.product or process
disclosed, or represents-that its use-wouldnot infringe pri-
vately-owned-rights."
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FOREWORD
The efforts represented by t.his two, volume final report
w
e begun in December 1972. -A draft version of Volume I was
er
issued September 1973 and the various section 's ofVolume II
published in draft form between February and June,1974. Ex-
tensive revisions to the draft versions of this work have
resulted in a two volume final report.
Impetus for the program was recognition -of a need for an'
organized approach to the envircnmental impacts caused by
energy supply and use. -This study, building upon;earlier work
completed by the Council on Environmental Quality, provides a
environmental tradeoffs
systematic technique.for identifying
and problems associated with current energy scenarios. By.
offering an organized and consistent approach.*to environmental
impacts, this.report can lend a quantitative sophisti,cation to
policy discussion.
This study was directed by W. Robert Men6hen. Technical
contributors are as follows:
David F. Becker
Charles B. Colton
Dr. Henry M.Curran
Barry K. Hinkle
Jay J. Hoenig
William C. Koffke
Judith H. Marcus
W. Robert Menchen
Terry N. Oda
James E. Reed
Steven A. Rothenberg
Robert@E.,Small6y
This work has been sponsored by the'Council on Environmental
Quality, The Environmental Protection Agency, and theRANN Pro-
gram of the-National Science Foundation. The Atomic Energy
Commission has contributed.through support of the energy
modeling efforts at Brookhaven National,Laboratory (BNL).. The
data contained in this volume are being placed,ih a computerized
information retrieval system at BNL, and computer programs'are
being written which will allow rapid Analysis of the environ-
mental effects:of energy systems.
Contract monitoring and all technical coordination has
been through the Council on Environmental Quality. We wish
to"thank Dr. Steve Rattien, Dr. Stephen Gagel and Mr. Marvin,
Singer of that office for their.continued assistance and support
inthis effort. Their suggestions over the course of the
program have created a more useful product.
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TABLE OF CONTENTS-VOLUME II
Page
LEGAL NOTICE
FOREWARD
TABLE OF CONTENTS-VOLUME II iv
TABLE OF CONTENTS-VOLUME-I vi
LIST OF FIGURES Vill
LIST OF TABLES x
I.. INTRODUCTION ANDSUMMARY
II. DATA BASE DESCRIPTION
A. Nomenclature
B. Format 11-3
Energy Supply II-1
D. Energy Model and Data Base (EMDB) II-17
III. LOW BTU GASIFICATION OF COAL
A. Introduction
B. Impact Data Tables and Footnotes III-9
IV. HIGH BTU GASIFICATION OF COAL IV-1
A. Introduction IV-1
B. impact Data Table and Footnotes IV-11
V. OIL SHALE
A. Introduction V-1
B. Impact Data Table and Footnotes v-6
iv
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VI. FLUIDIZED BED BOILER COMBUSTION VI-1
A. Introduction
V-I
B. Impact Data Table and Footnotes VI-5
VII. SOLVENT REFINED COAL'
VII-1
A. Introduction VII-1
B. Impact Data Table and Footnotes VII-4
VIII.COAL LIQUEFACTION VIII-1
A. Introduction VIII-1
B. Impact Data: Table and Footnotes VIII-5
IX. REFERENCES
APPENDIX LIST OF ABBREVIATIONS
v
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TABLE OF CONTENTS-VOLUME I
Page
LEGAL NOTICE
FOREWORD
TABLE OF CONTENTS-VOLUME I. iv
TABLE OF CONTENTS-VOLUME II vi
LIST OF FIGURES viii
.LIST OF TABLES ix
,I. INTRODUCTION AND SUMMARY
II. DATA BASE DESCRIPTION
A. Nomenclature
B. Format 11-3
C. Energy Supply II-8
D. Energy End Use II-17
E. Energy Model Data Base* (EMDB)
III. COAL SUPPLY II-18
A. Introduction
B. Impact Data Tables and Footnotes III-4A
IV.. OIL SUPPLY IV-1
A. Introduction IV-1
B. Impact Data Tables and Footnotes IV-4
V. NATURAL GAS SUPPLY V-1
A. Introduction V-1
B. Impact Data Table and Footnotes V-3
vi
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VI. POWER PLANT CONVERSION ACTIVITY OF FUEL SUPPLY VI-1
A. Introduction VI-1
B. Impact Data Table and Footnotes VI-2
VII. RESIDENTIAL END USE VII-1
A. Introduction VII-1
B. Impact Data Table and Footnotes VII-2
VII.COMMERCIAL END USE VIII-1
A. Introduction VIII-1
B.' Impact Data Table and Footnotes VIII-2
IX. INDUSTRIAL END USE IX-1
A . Introduction IX-1
B. Impact Data Tables and Footnotes IX-4
X. TRANSPORTATION END USE X-1
A. Introduction X-1
B. Impact Data Table Footnotes X-3
XI. REFERENCES XI-1
APPENDIX A LIST OF ABBREVIATIONS
vii
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LIST OF FIGURES
.-Page
1 Description of Phaase I Program I-3
2 Task 3 Regional Studies I-4
3 Phase II Study-Description
Hardness Number Definitions II-5
5 Numbering Classification for-Footnotes
and References II-6
6. Uncontrolled Incremental Land impact II-12
7 -Controled Incremental .'.Land Impact- II-12
8_ Data Access Code for.-Supply II-18
9 Applied Technology.Corporation Two-Stage
_gy
for L f icq&'t-ion 111-3
Combustqn.,Prqacess@ owl Btu Qoal Gas0qi
10 Bureau,of ric Gas -Producer for
mine0qw'-, qphe
Low Btu Coal'Gasificqation 111-4
11 Bureau of Mines' qTr0qessqurized:Gas Producer for
Low Btu Coal Gasification
12 Lurgi Process of., Low 'Btu`Co. :Gasqifqat0qion 111-7
13 Koppers-Totzek Process-of Low Btu Coal Gasification,III-8
l4 Lurgi Process of High-Btu Coal Gasification IV-3
Hygas-ElectrothermalqPocess of High: Btu.
'Coal Gasification IV-4
Hygas-Steam OxygenProcess of"High Btu
Coal Gasification IV-6
17 Bigas Process of HighLBtu Coal Gasification IV_7
18. Synthane Process of High Btu Coal Gasification IV-8
19 C02 Acceptor Process of High Btu,Coal Gasification IV-10
viii
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20 Typical Oil Shale Process Flow.Diagram V-2
21 Pressurized Fluidized Bed Boiler Power Plant VI-3
22 Atmospheric Pressure Fluidized Bed Boiler
Power Plant
VI-4
23 Solvent Refined Coal Process VII-2
24 CSF Coal Liquefaction Process VIII-3
25 Modified SRC Liquefaction Process VIII-4
ix
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LIST OF TABLES
Page
1. Environmental Impacts,, Efficiency and Cost for Environmentally Controlled,National
and Regional Low Btu Coal Gasification
2 Environmental Iqmpact's, Efficiency and Cost for
Environmentally- Controlled National and' Regional
High Btu 'Coal Gasification
3 Environmental Impacts., Effic for
Environmentally Controlled Oil Shale,Supply v-7
4, Environmental impacts, Efficiency and Cost for,
Environmentally.-Controlled National and Regional
Fluidized BedBoiler Combustion.Power Plants VI-7
5 Environmental Impacts, Efficienc y and Cost for
Environmentally,Controlled Nationaland Regional
Solvent refined Coal Supply VII-5
6 Environmental.Impacts, Efficiency-and Cost for
Environmqentally..Controlled National and Regional
''..Coal Liquefaction VIII-7
x
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I. INTRODUCTION AND.SUMMARY
This is Volume'll of a two volume report which describes the
results of a study performed by Hittman Associates,-Inc. (HAI),
and sponsored by the.Council on Environmental Quality (CEQ), The,
Environmental Protection Agency, and The.RANN-Program of-Lhe
National Science Foundation. The.-purpose of thd-study was to
determine the environmentallimpacts, efficiencyl,and costs
associated with the supply and etd use of fossil.,fuels. The
study builds upon preliminary work already completed by CEQ-
The-outptt of the study takes,two forms. This report pre-
sen'ts tabular, footnoted, and-referenced data quantifying the
broad range of.energy-related environmental impacts on land,
water, air, solid waste,. and occupational health.. All of the
information contained in this report is.also available in the
form of a computerized data base. This,data base-ha@,been,given
the name MERES:,.Matrix of Environmental.Residuals for Energy
Systems. As part of an ongoing contract with*the Atomic,Energy
Commission, Brookhaven National Laboratoky-has created the data
base, and also has written a number of data management and energy
modeling programs. These programs, together with the MERES.
data, arelknown' as*the Energy, Model and Data Base.,(EMDB)..
Environmental analyses of energy-related-facilities have pre-
viously been incomplete.- Among, other things, these analyses typi-.
cally considered only individual components, such as an isolated
power plant, refinery, etc., a@nd not entire energy'systems.
The construction of a coal7fired power plant-'causes air,.
water, solid waste, and land impacts not only at the,immediate
s
ite of the power plant, but also,at the site where the coal is
l
mined, washed, processed or prepared, and along the route that
the coal is transported. The entire' sequence of activities, from
the mining of the,coal-@o the production of electricity, and its
end 'use in some home appliance or industrial process, is what is
referred to as anehergy system or "traje.ctory" and should be
analyzed.
Similar trajectories or energy supply "chains," exist for
oil production andrefining. The construction,of a refinery
causes air and water pollutants, solid waste,, and land disruption.
However, additional environmental-effects are felt at the point
of crude oil production, during the crude and product trans . por-
tation, and at the point of marketing and end use.
Using the data bank, it is possible to aggregate the environ-
mental impacts of a wide variety of fossil fuel "trajectories" '
traced fr=the end use of a fuel to its extraction or vice versa.
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This makes it Possible to'estimate environmental impacts fok,any
number of scenarios related to energy consumption patterns eh-
visioned for'the next 10 to 20 years.
The objectives of the Phase I study reported in the companion
Volume I areisummarized in Figure l.- Tasks 1 and.2 are national in
nature while!Task 3 includes ',the-impacts of regional energy supply
subsystems. In all cases, the data have been developed for coal,
oil, and natural gas. A more.detailed breakdown of the regions
covered in Task'3 is provided by Figure'2..
Thirty environmental impact tables are contained inVolume I.
Twelve of these are devotedto coal supply, twelve to oil
supply, one to natural)gas--suPply, four to-energy end uses,
and one to the electric power plant activity of energy supply.
Each entky-in these tables@'@is footnoted and referenced.
The objective of-'@the Phase II study reported in this volume
was to supplement the Pha:se I activiiies with various emerging
.,energy technologies. Six technologies, sho'wn.in Figure-3,
were characterized with respect to their environmental impacts,.
efficiency, and cost. These technologies represent addition al
links in the,'supply and,end use chain of fossil fuels and are
a necessary pomponent.@@of future energy-:investigations..
These-six emergihg'@technologies are in a state of rapid de-
velopment. Characteristics of and emissions from these processes
can be expected to.chang@e_as'@-more is learned from-research and ex-
perimentatioh. Therefore, it is important to note the time frame
of the data used in the tables and-footnotes of this volume.
Tasks 5, 6, and 7 (low Btu and high Btu gasification and oil sha'le)
are based onidata assembled in the-Fall of 1973. Fluidized bed
boiler combustion data (Task 8) was assembled in the early months
of 1974. Data used in Tasks.9 and 10 (solvent refined-coal and.
coal liquefaction) was dollected in the Spring of 1974. More
recent inforination may have been deVeloped since this base data
was Assembled.
It must@be noted that the environmental impacts reported
herein only characterize the initial step in the environmental
thain-that is, the amount of effluent discharged from the
boundary surrounding a particular process or end use. The inter-
action of-the outfall, air emission, land use, etc. with the
biosphere is@not included in this study.
1-2
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TASK 1 EXTRACTION, PROCESSING, CONVERSION,,
AND DELIVERY OF'FOSSIL FUEL ENERGY
OBJECTIVE 1 DETERMINE PROCESS
EFFICIENCIES FOR
FOSSIL FUEL PRODUCTION
AND DELIVERY
OBJECTIVE 2 QUANTIFY.ENVIRONMENTAL
IMPACTS FOR EACH PRO-'
CESS, WITH PRESENT
CONTROLS
OBJECTIVE 3-.DETERMINE IMPACTS WITH
CONTROL TECHNOLOGY
AVAILABLE AND.LIKELY
TO,BE IMPLEMENTED
OBjECTIVE 4 DETERMINE -SYSTEM COSTS
FOR UNCONTROLLED AND
CONTROLLED ENERGY
SUPPLY
TASK 2 END USES OF ENERGY
OBJECTIVE 1 DETERMINE ENERGY.USE
PER APPROPRIATE MEASURE
OF USEFUL ACTIVITY
OBJECTIVE 2 DETERMINE ENVIRONMENTAL
IMPACTS OF END USES
TASK 3 SENSITIVITY ANALYSIS OF TASK 1 DATA
REGIONAL STUDIES (BOTH UNCONTROLLED
AND CONTROLLED)
Figure 1. Description of Phase I Stud
y
1-3
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COAL'
o NORTHWEST (POWDERRI VER BASIN)
MONTANA & WYOMING; AREA STRIP
o SOUTHWEST (FOUR CORNERS AREA-)
-NEW MEXICO; AREA STRIP
o CENTRAL
ILLINOIS &.,INDIANA,; AREA STRIP; ROOM &
PILLAR@DEEP.
0 NORTHERN APPALACHIA'
NORTHERN W,i.VA., CENTRAL & W. PA.;,CONTOUR
STRIP, ROOM@& PILLAR DEEP, tONGWALL DEEP
o CENTRAL APPALACHIA
EASTERN KY., TENN., SOUTHERN W. VA.;
STEEP SLOPE CONTOUR-STRIP, ROOM & PILLAR-
DEEP
OIL
0 DOMESTIC ON-SHORE
o IMPORTED SOUTH'AMERICAN--RES-IDUAL
o IMPORTED MIDDLE.EASTERN'CRUDE
o IMPORTED CANADIAN 'CRUDE.
o DOMESTIC OFF-SHORE
NATURAL'GAS
o DOMESTIC-ON-SHORE
o DOMESTIC OFF7SHORE.-,
o IMPORTED CANADIAN@
Figure,2. Task 3.Regional Studies:
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TASK 5 LOW BTU GASIFICATION OF COAL
TASK 6. HIGH.BTU GASIFICATION OF COAL
TASK-7 OIL SHALE
TASK 8 FLUIDIZED BED BOILER'COMBUSTION
@TASK9 SOLVENT REFINED COAL
TASK 10 'COAL LIQUEFACTION
Figure 3., Phase II Study Descripti on
1-5
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Ii. DATA BASE DESCRIPTION
A. Nomenclature
In.order to describe a scenario dealing with.environmental
effects of energy, a number of definitions have been adopted:.*.,
Term Exam2le/Definition
Element 802 emission in transpor-
tation of coal.by unit train
Process. Coal transportation by unit.
train (a set of elements)
Activity coal transportation (com
bination of a set of pro-
cesses)
Trajectory Coal in the:ground to steel
-ion by electric fur-
'product
nace (the set of linked
activities which connect the
supply of.a specific resource
with a specific end use),
Subsystem Coal in the ground,t,o any
linked end use (a.logical
collection of trajectories*
defining an a'spect.of the..
total energy system)
System Energy production and use in
a given,year (collection of
all.trajectories'in the-energy
economy)
These definitions are identical to those formulated by,.
Brookhaven National Laboratory
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These definit ions-are further explained by the'following
diagram:
TRAJECTORY-
Seguenpe of.Activities
Extraction Transportation Processing
or
Conversion
End Use _@St@orag@e @,Dis@tribu@tionj
--------------------------- ------- -------------------- -------
-ACTIVITY
An acfivii
y is one--,or more processes.
One process -could-be distributioh-lof,-coal by unit train.
s
Several ptoce'ses In-series,might be ag shown,below.
y 'Rough Sizing. Washing
Primar'
coal Breaking Cleanii@5
The envitorAnental,impacts to be identified and quantified
are those which relate to water pollution, air pollution,, genera-
tionof solidVastes, use of-land, occupational health, and
potential for large scale disaster.
The water and air pollutants under consideration are the,
following:
Water: Acids
Bases
Dissolved solids PO No others
Suspended solids
Organics
-BOD
COD
jLizing
Thermal
11-2
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Air: Particulates
NO
x
Sox
Hydrocarbons
CO
Aldehydes, etc.,
Solid wastes under consideration are all residuals not en-
tering the air or water that result from the basic fuel resources
or from the system processes that make fuel useful for cons
s ump-
tion, or from the end use' of fuels.
The land impacts include areas required for extraction,
structures, disposal of solid wastes, roads, ports, pipelines,
storage, and buffer zones.' Both fixed and incremental land
effects are considered. Fixed land effects are those associated
with facilities such as processing plants, pipelines and storage
tanks, whereas incremental land effects are those associated with
excavation, such as strip mining,. and solid waste disposal.
Occupational health is considered,on the basis of deaths,
injuries, and man-days lost due to injuries.
All of the environmental impacts mentioned so far are quanti-
fied and tabulated with suitable units.' Further details are
given.in the following section on energy supply.
The potential for large scale disaster is identified with@-
respect to the possible nature and magnitude of disasters and
-use trajectories
to specific processes in the supply and end
No quantifications are associated with these identifications:
B. Format
The construction of a computerized data bank requires that
a large number of inputs be prepared according to a specific for-
mat. From the standpoint of this report, thereader need only
be familiar with.certain ground rules regarding data identifica-
tion. The relationship between the format of data in this,report
@and the computerized data bank is explained,further in*Section D...
11-3
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1. Impact Data-and Data Hardness
2 Each entry of environmental impact.data in.the supply
tables has three parts. This is illustrated below.
2.40-04 3 7019
L footnote number
-data Input.hardness.number
..data input to three significant figures
2.40-04 is equivalent to 2.40xl-4 or
.000240.. Units of the data.are at the
top of the column in the table
A data hardness number is required for each entry except those
-with 0998 and 0999-footnote-designations. In.the..computerized,
data,bank, it will be.possible to search.for.hardness-numbers in
order to categorize,V the- inaccuracy- of-. data blocks.,,. 8q2ardness
.,.number definitions-are given in.Figure.4. As a: general rule, it
Iis useful to consideqr_data hardness in the context of "'confidence"
and relate his to.the 1 to 5 scale.
Footnotes and-References use-abbreviations where possible
to facilitate loading of data into:the Computer-data-bank.
Appendix A is a list of abbreviations and their definitions.
When using-exponential numbers such.as-l.,35xlqo8,the designation
within the footnote will be 1.35E4q+08, 1.35EqO8, or 1.354q+08.
2. 'Footnotes and References
Footnotes and references have been classified according to
..a numbering system which is shown in.Figure 5. Note that specific
blocks of numbers have been allocated tothe various pieces o6qf
data assembled. The numbers in Figure 50q1ndicate which new foot-
;notes follow each individual table.,These footnotes are related
to the new information generated for the-table,4qi,n question. This
will become apparent as the 20qtables are used. Footnote and refer q-
ence numbers appearing in this volume but not-included in Figure
5 are from Volume 'I of this report. Many of these footnotes and
references have been included in this volume as well for con-
venience.
II-4
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Hardness, Definition* Example
Very Good Highest confidence. Nationwide consump-
Error probably :!-110 percent. tion-based on
Data well accepted and verified. accurate reporting
technique.
2 Good Reputable and accepted. Data from several
Error probably :6 25 percent'.. major companies used
to represent U.S.
3 Fair Error probably 50 Data from one com-
percent. Validity may be un- pany us.ed,to
certain-due to method of com- represent U.S.
bining or applying data.
4 Poor Low confidence in data. Telecon estimate
Error probably 100 percent. used in,absence of
Validity questionable. measurement..
5 Very Poor validity of data Assumption based
unknown. Error probably within on related refer-
or around an order of magnitude. ence. Several Fair
9
or Poor sources
combined.
Error levels cited refer to cases. where thedata are non-
zero. For,iero or "negligible" valuesi the-definitions
Good, Fair, etc. should be applied-to the various hardness
levels.,
Figure 4. Hardness.Number Definitions
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Table Footnote Reference
No. Numbers Numbers
Low Btu Coal:iGaskfication 1 ,8000-8035
High Btu Coal Gasification 2 -83oo-8324
Oil Shale 3 9-000-910.5 9000-9041
Fluidized Bed Boiler
4 9200-9234 '920079222
Combustion
@Solvent Refined-CoAl 5 9300-9350 9300-9335
Coal Liquefaction 6 9400-9460 9400-9406
Figure,5. '..Numbering,Classification for
Foothotes-and References
11-6
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-In addition to the footnotes which are printed text, three
other designations are used in the tables. These are defined
as follows:
Footnote No. Definition
0997 Zero or.negligible impact for
this activity - an appropriate
hardness value is required
0998 This-impact not applicable.to
this activity
0999. This value not available an
impact for this activityis
assumed to exist
To simplify the citation of referenceBwithin footnotes,
the following fotmat has been used:
Format for Reference's in Footnotes:
T3 0 0-4 ) Reference 3004
(3004,739) 'Reference 3004, page 739.
.(3004,739,742) Reference 3004, pages 739,742
(3004,739/742) Reference 3004, pages 739,
through 742
(5123,A-'9) Reference 5123, page.A-9
(5123,A-@9'J,A-12) Reference 5123, pages A-9,
A-12
(5123,A-.9/A-12) Reference 5123, page A-9.
through A-12
Note that a reference.citati6n is always enclosed in parentheses.
Footnotes-which follow the tables appear in the exact.form
that a computer printout willyield. Each footnote indicates
the-referencesand other footnotes it is based upon'. In this
report some minor inconvenience derives from having to refer to.
a separate list of references located following all of the tables
and footnotes. However , in the computerized data bank, footnotes
could be printed out followed immediately by the applicable refer-
ences and first order footnote referrals.
11-7
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C., Energy Su
221Y
1. Introduction
The energy'supply tables and footnotes deal with the quanti-
fication of theienvironmental impacts.of@each process in the
fossil fuel energy supply tra ectories based on'a process input
of the fuel equivalent to 101i Btu/yr.. The value of 1012 Btu/yr
was chosen as a:convenient unit for an energy rate. The rate
form was chosenito. facilitate the use of published data on environ-
mental impacts in which-a time factor is involved,-'such as, for
example, emission rates in lb14 ay,for evaporation losses from
gasoline storage-tanks, impacts,related to annual production
rates, etc.
Whereas Volume-I to this:-_report considered the supply tra-
jectories,of the primary fossil fuels and their derivatives,
this volume focuses-on six emerging energy technologies as com-
poAents of future energy supply trajectories.' Five of the six
technologies - low Btu gasification,. high Btu gasification,
fluidized bed boiler combustion, solvent refined-coal, and coal
liqu e"faction - utilize coal in*the production of-synthetic fuels
or electricity., The sixth,,oil shale technology, considers.th6
production of ctude-oil,from this-new,energ.,y..source.
For those technologies utilizing coal, the,environmental
impacts, efficiencies., and costs have been developed. for three
regional coals and a national average case. In contrast to
Volume-I of this report, all of this informationappears on the
same table. The coals.forwhich data@;have been.developed include
a.low sulfur (Northwest), medium@sulfur.,(Northern Appalachia),
and.high-,sulfur@(Central),coal.
Eac 'h of the tables,is organized as a-matrix with the environ-
mental impacts as columns and activities and proc esses as rows.
For each activity on the left of the table, the relevantproces,ses
are-listed immediately below. In general,, the entries in the
tables are on,a process basis, rather than on an activity basis.
As noted earlier, an activity may consist of a single process,
ordt may consist of a numberof processes.
@hich gives basic
Each.table has a related.general footnote w
data pertinent to the fuel considered,.puch as the,amount of the
fuel equivalent to 1012 Btu. It is important to note that all
impacts have been derived for a process input of fuel equivalent
to 1012 Btu/yr. In particular, for the extraction activity, this
is@interpreted to mean 1012 Btu of resource in the ground. Thus.
impacts for the,extraction activity are expressed-per 1012 Btu ,
in'the ground and not per 1012 Btu.produced or extracted (output
of fuel).
11-8-
�
A'general,caution is applicable to all the supply %data.
Before using any.impa t expressed in terms of-, 1012 Btu, the
reader should read the footnote. Potential misuses of the data
can,readily be cited. Increasing the plant capacity may not in-
crease.the land impact proportionately, since the land use is
not necessarily linearly related,to-the productive capacity of
the plant. Doubling the productive capacity doubles the land
requirement only if an *additional and identical facility is con-
structed. Caution must be'exercised when evaluating the land
effects forlarge multiples of 1012 Btu/yr. Similarly, size
considerations are important-in cost calculations and the foot-
note will relate how the particular entry has been calculated.
It is important to note the interrelationships betw een en-
vironmental impacts, efficienc , and cost data. Strictly speaking,
y
a specified.level of environmentalcontrol hasassociated with it
corresponding levels of.cost and energy requirements. This is
apparent in a comparison of the uncontrolled and controlled en-
vironmental tables. However, this is alsotrue within each supply
table, as air pollutant data is related to ancillary fuel use,
land use is.related to solid-waste data, etc. . Air pollutants
associated with the generation of electricity are ascribed to the
powerplant activity and not'at.the site.o.f the process which
uses the electricity as ancillary fuel.
2. Definition of Uncontrolled and Controlled
All supply tablesare designated either controlled or un-
controlled. "Un controlled,',' according to the ground rules adopted
in this study, means that impacts are the current national or re-
gional average value. In the absence of current,(1972-73) data,
impacts typify the use of least stringent environmental controls.
"Controlled" implies that impacts are consistent with the
use of control technology which will probably be required and/or
available in -5. to 10 years. As An illustration, present laws
0
governing the reclamation of surface mined lands minimally require.
that effort@'be made to restore the land. This may include par-
tial backfilling and an attempt at revegetation. However, since
the degree and success of reclamation are not mandatory,'(for the
"uncontrolled" condition) reclamation is not assumed for area
stripping operations, and only partial backfilling is assumed for
contour mines. In the controlled situation, contour backfilling
and revegptation are required for either type of stripping
operation. The attainment of this high level of. reclamation@would
require such practices as stockpiling and redistribution of the
topsoil, segregation of toxic overburden and seed.bed preparation.
Generally speaking, the controlled condition incorporates the
environmental standards proposed or soon to be implemented by the
11-9
�
Environmental Protection agency.` A more.detailed explanation of
controlled andJuncontro'lled as it is.related specifically to each
Process in the fossil fuel supply chain is to be found in the
writeups preceding each-of the supply tables'and in the accompany-
ing table footnotes.
The data in this volume have all been developed for the
Incontrolled environmental condition. This was because the tech-
nologies.considiered herein are either being developed primarily
I 4qii2qu4qutors
for environmental control or are potentially 'major cont
.to environmental impact For this latter category, from a
practical pointof view stringent environmental controls will
.be -a necessity.
3. Environmenital Parameters,
In the supply tables, the units for the various environmental
impacts are noted above the columns. Since the basis for the
tables is the fuel equivalent of 1012Btu/yr, the actual units for
the values given in the tables are interpreted as follows:
Water Pollutants:
Acids, bases, dissolved, Tons discharged to water bodies/yr
solids, suspended Fuel equivalent to '1012 Btu/yr
solids, organic's:
tons,
_12
I U btu
BOD, COD: Oxygen.demand, in.. to 10qons/yr
Fuel equivalent to 10 12 Btu/yr
tons
12
10 Btu
Thermal: Btu'discharged to water.bodies/2qyr
12
Fuel equivalent to 10 Btu/yr
Btu
10 12 Btu
Air Pollutants:' Tons discharged to atmosphere/yr
Fuel-equivalent to 1012 Btu/yr
tons
12
10 Btu'-
Solid Waste: Tons placed on land/yr tons..
Fuel equivalent to 10 12 BtU/yr 10 12 Btu-
II-10
�
�
Occy2ational Health:
Deaths: Deaths/yr - Deaths
Fuel equivalent to 10 12 Btu/yr LU 2 Btu
Injuries. SeriolIis injuriesZyr Seriou's injuries
1 12 12
Fuel equivalent to 10 Btu/yr 10 Btu
Man-days Man-days lost due to serious injuriesZyr Man-days 'lost,
lost: 12 =2
Fuel equivalent to 10 Btu/yr 10 Btu
Land:
Fixed: Acres occupied by fixed facilities@ Acre-y
Fuel equivalent to 10 12 Btu/yr 10@2 Btu
Incre- Time-averaged incremental acre's ='Acre-yr
rental: 12 12
Fuel equivalent to 10 1 Btu/yr 10 Btu
The'values.for land disturbed shown in the tables are, where
applicable, the sum of fixed and time averaged incremental lan&
impacts. As an example, consider a coal proce ssing plant which
ha*ndles B Btu/yr of coal, occupies A acres,'and produces 86lid
waste for*disposal occupying an additional a acres/yr. The
fixed land impact'is defined as:
A A in units of acre- yr
f 12
10 Btu
The incremental land impact is defined as:
a acre
A in units of 12
10 @Btu
To sum these land impacts it is first necessary to intro-
duce the.units of-time, or time average the incremental land
impact. Conceptually this represents the Average acres of land
which will be impacted over the lifetime of the plant. Numeri-
cally, the time averaging process will depend on whether or not
environmental controls, specifically reclamation of the disturbed
land, will be employed. Figures-6 and 7 illustrate the-uncontrolled
(i.e., unre'claimed) and controlled (reclaimed) environmental con-
ditions as they pertain to.the time averaging of incrementil land
�
na B
UA
Cie
4&
Cj
3a
2a
C
A 2 3 4______\1 n - 1@@n
TIM&-Y'EARS
NOTES: 1) Plant lifetime n years
2) Incremental land impact.a acres/yr
No reclamation of disturbed land
-Ffoure'@ 6.; Uhcohtiftl I ed' Incremental: Land.'@ Impact
B
3a C
Uj
2a
a
CC
.4 D
1 2 3 4 n-1 n
TIME-YEARS
-ifetime n'
NOTES: 1 Plant 1 years
2@ "Incremental I and, impact a ac'res/yr
3) Reclamation Of di.sturbed land with
year time,lag for-revoetation
Fi-gure 7., Controlled Incremental Land -Impact
11-12
�
use. As shown in Figure 6**, for the uncontrolled plant with an
ri year lifetime 'and an incremental land impact of a acres/yr, the
total amount of land disrupted after:n-years,would be na acres
since the land is not being reclaimed for use. The-average land
impact over the n year lifetime of the plant is given mathemati-
cally by the area'of triangle ABC divided by n years, i.e.
1/2 (n)(na) or (n) A. Hence, thetime averaged incremental
n
.land impact for the uncontrolled case is defined as:
n a acre-yr
Ait 2 in units of 12
10 Btu"
Figure.7 shows the land impact for the same plant employing
reclamation practices to recover the land disrupted by the solid
waste. In this'example.three years was chosenas the time period
necessary.for reestablishingvegetation. Thus, assuming con-
current reclamation, the land impact curve in Figure 7 levels off
after the third year. That isi after the third year, the number
of acres impacted-remains constant. For each a acres disrupted in
any year, an equivalent A acres has been reclaimed (starting three
years before). The average land impact over the n year lifetime of
the controlled plant would then be given mathematically by area
ABCD divided by n years, i.e.,
(112(3)3a) + (3a)(n-.1) or (3 9)a.
n in-
Hence the time averaged incremental land impact for the controlled
case with a three year time lag for revegetation is defined as:
acre-yr
A. (3-1) in units of
it 2n B 101 Bt
Note that the controlled definition given above is only applicable
for-those cases where three years is required for reestablishing
vegetation.. If, this time lag changes, obviously so will the time
averaging multiplier. Generally the plant lifetime (n) is taken
as 25 years. Based on this value the time averaging multiplier
(n
4 for the uncontrolled case y) would be 12.5 years, and for the
9
three'-year time lag controlled case (3--f-), the multiplier would
n
be 2.82 years.
This time averaged.incremental land impact calculation
arbitrarily ignores-any land impact which could occur beyond
the specified lifetime of the facility. Continuing impact from
yet unreclaimed land or the remainingstructural facilities beyond
the expected useful life (n) of those facilities is not considered.
11-13
�
4. Ef f icieficy
The Hittman data tables,contain two'efficiency,related inputs.
These*are primary eff.iciency,(dolumn 26) and ancillary energy
(dolumn 27)
Efficiency definitions can be related to the following
diagram:
Ancillary Energy
12
(io Btu
12
X(1,0 Btu of fuel output
12. 12
Input 10 Btu,6f fuel, Process Y(10 .),Btu-consumed
in prOdess
12
z Btu- physical loss
@Where:
X+Y+Z
Primary-Efficiency x 1-y-z
Overall'Efficiency x-u (BNL)
overall Efficiency x Theoretical)
.1+u
X_u for+small u, iae., u,<<l
1+u
If the-process-separates the input fuel@,stream into several
output fuelg, X.(1012) may be taken as the'-sum of the energy con-
tents of the output fuels and x as ah approximate value for the
efficiency of,each output fuel.
In some proces'ses there is apt to be confusion as to
whether an'Onergy use is classified;as ancillary or part of the
input flow consumed. In a r6finery,,.-refinery gas (which provides
energy for many processes) is considered as primary fuel-consumed
rather thanlas an ancillary demand. Any,use of a fuel derived
'from the primary input stream remains part of the-primary flow.
11-14
�
50 Costs
Cost data expressed in 1972 dollars.are included in the un-
controlled and controlled national supply"tables in columns
28-30. The total capital or fixed,cost for equipment, structures,
etc. is annualized at 10 Percent per year and.,shown in column 28.
This capital -"cost" is synonomous with total capital investment
and does not include interest during development or-working capital.
Yearly operating expenses for fuels, maintenance,Iabor, etc. are
given in column 29, while column 30, which represents the total
annual cost, is the sum of columns 28 and 29. The units for the
economic data are shown below:
Fixed Cost: ($ of cai2ital expense) x (.10/yr) $
12 12
Fuel equivalent to 10 Btu/yr input- 10 Btu
Operating $/yr for operating expenses $
Cost Fuel equivalent to 10 12 Btu/yr input- .10 12 Btu
The 10 pprcent/yr annualization or "fixed charge rate" (as
it is called in the table footnotes) for capital expenses was
chosen,mainly for convenience.and may or may not-reflect actual
practice within a particular industry. It'is convenient to ex-
press the capital cost data in this,fashion because: 1) itprol-
.vides some estimate of total Annual costs and 2) it allows a qui6k
estimate of total capital cost from the table data by simply
increasing the fixed cost by a factor of ten.'. That is, for a table
fixed cost entry of 1.50+05 the total capital cost is 1.50+06
or 1"1/2 million dollars/1012 Btu equivalent fuel input.
The price of the raw energy resource into a process is not
included inany'6f the cost data. The annual cost data,repre-
sented in the tables is.a major component of the ultimate price
level of the fossil fuels delivered. Since the basis for costs
is 1972 dollars'.. table values would have to be adjusted to re-
present-day (1974) costs.
�
6. Allocation:_Of .,[email protected] to Proces.s Fuels.,
The folIowing@suggests' a technique for allocating tabular
impacts to.the product'@fuel mix. A refinery or natural gas pro-
cessing-plan,'t.is used as an example'. oil refineries and natural
gas processing plants separate input fuel streams into several
output fuel strd'amg@,
X Table entry.for 1012
Btu/yr of input'stream
lb12 Btu/yr 'Refinery or NGL Fuel A
Input s' ream, separation plant Output
%-'Fuel B streams
Contain@s A,B,,-C' Fuel.,. C
Ancillary fuel
if the data &467Eo, ..be used' to cohstitudt-A trajdrdtory for
a particular product flusl, starting at the well head-where such
fuel does not extst as ah,ehtity, the table entries for the pro-
cessing activity or for activities prior to processing may be
used' as reado'nab,16 appr'6kir4tions for such product f uel.
X Table entr@ interpreted
as for 101. Btu/yr of
f uelA
12
10 Btu/yr of
Fuel A assumed to Refinery or NGL Fuel A
00 separation plant-
exist as an entity
Ancillary fuel
11-16
�
D., Energy Model and Data Base (EMDB)
The data presented in this report have been entered in a
computerized data base (MERES). Brookhaven National Laboratory
has combined this data base with a number of data.management and
energy modeling programs to form a completepackAge known as
the Energy Model and Data Base, or EMDB. Brookhaven National
Laboratory (BNL) will ontinue to update, maintain, and improve
c
the data base and its associated programs.,
.The EMDB is presently available on'the Control Data Corpora-
tion computer facility at BNL. It will be directly accessible
via a telephone connection and terminal to remote users. In*
writing the computer programs for the EMDB, care has been taken
to insure that the programs would be easily transferrable to
other computer facilities.
The basic unit of storage in the EMDB is a particular supply
or utilization (end use) process, which corresponds to the com-
plete set of numeric values contained in a single row of the
tables in this report. Each basic process storage unit,contains
all of the numeric values (and'the 'ir hardness factors) as well
as the full documentation for the,number set. The specific pro-
cess desired isidentified by a string of mnemonics which have
different forms for supply and utilization processes. These
string forms are as follows:
SUPPLY: RESOURCE/ACTIViTY/PROCESS/R@EGION/CONTROL/.
UTILIZATION: /SECTOR/ACTIVITY/PROCESS/FUEL/CONTROL/.
The mnemonics for each supply activity and process can be found
in the left-most column of each supply table (Tables 1-6).
There are no utilization (end use) tables in this Volume.
The accessing codes for supply are further detailed in Figure 8.
One of the programs associated with the EMDB permits the
calculation of national energy flows and the impacts of such
flows on resource consumption, pollutant e 'missions, and dollar
costs. This program, called the Energy System Network Simulator.
(ESNS), considers the energy system as.a set of process links
in a network 'representation. These network process links can be
associated-with particular process blocks (both supply and utili-
zation) in the EMDB. An interfacing program is provided which
draws'numeric values from the data base and makes them available
for flow calculation through the network. Capabilities are, also
provided for modifying any numeric value for input to the ESNS and
for adding new'links to the ESNS network. With these capabilities,
the effects-of various simulation scenarios can be calculated.
11-17
�
Order of...mnemonic string-identifier-corresponding to a
,supply table. row:
/RESOURCE/l@CTIVITY/PROCESS/REGION/CONTROL/.
Identifier Mnemonic
Resource: -Coal COAL
Oil OIL
Natural-Gas GAS
.Activity: (See,Supply Table)
Process: -(See..Supply Table)
Region: National NkTL
Northwest
Southw 'est ..Sw Coal
Central CNTRL.
..Northern__A palachia NAPPL
P- -
Central A palachia CAPPL
p
..Domestic-Onshore .,ONSHR
'OFSHR
Domestic,Offshore
-Imported.Middle East,Crude MECRD Oil
Imported'Cana"dian Crude CANAD
Imported-South American SARSD
Residuai
Onshore ONSHR
Offs hore OFSHR Gas
Canadian CANAD
Control: Controlled CONTL
Uncontrolled UNCON
Figure 8. Data.Access Code for Supply
I1_18
�
I. LOW BTU GASIFICATION OF COAL
A. Introduction
The environmental impacts, efficiencies, and costs of
Low Btu Gasification of Coal aregiven in Table 1 of 12
this report. This table is based on an energy input of 10
Btu/yr into each process utilizing current or 'soon to be
available pollution. control techniques.@
The primary purpose of Low'Btu Gasification of Coal,is
to provide fuel gas, ranging from,.150-200-Btu/SCF,, for power
generating purposes. Although this low Btu gas may have other
industrial purposes, this report assumesall gas is used to
fire conventional or combined cycle power plants.
The five specific processes studied arex.
1. Applied Technology'Corporation (ATC) Process
2.. Bureau of Mines Atmospheric Process
3. Bureau of Mines Pressurized Process
4. Lurgi Process
5.1 @Koppers-Totzek Process
'Each of the five technologies will consist of two
activities; gasification and elf-Ictricity generation. An
electrical transmission activity is presented for the
Northwest, Northern Appalachian And National Average cases.
The transmission distances are based on the mileage from the
generating location at'the mine mouth to the metropolitan.
Chicago area. No electrical transmission data, are presented
for the Central case, since the gasification/electricity-
generation activities are.assumed to take placein the
metropolitan Chicago area.
The environmental impacts in Table 1 are based.on
processing three regional coals and-a simulated-national
average coal. It should be Xioted,that all caDital costs
shown in Table 1 .are based on a plant@load factor of unity,
i.-e. , the plant is assumed to operate 365 days/yr. The values
presented in this table are based on data accumulated during the
Fall of 1973.
�
The following is a brief description of the
individual processes:
ATC S02 Free Two-stage Coal Combustion Process
The ATC process (Figure 9) consists of injecting coal
particles into a molten bath of iron
n. Because iron in the liquid
state has an affinity for sulfur and carbon, the coal
solubilizes to release'organic'and inorganic sulfur
coonstituents'for reaction with the active iron melt. The
iron sulfides. formed mirate to a.lime containing slag
f loating on the molten iron bath -where they are removed from
,the combustion proceddssAt the same time, the iron that is
dissolved in the molten iron is-reacted with air to produce.
an off-gas which consists of nitrogen, carbon monoxide, and
hydrogen. this 25000F+ gaseous mixture, essentially-free of
sulfur dioxide, is introduced into a steam boileIr along with
secondary air to recover All of the heating value-of the coal.
Sulfur is recovered in elemental form Ifrom the-slag produced
in the ATC process-along with iron contained from the
coal pyrite's 'and a desulfurized slag.
Bureau.of Mines Producer Gas at'Atomospheric
Pressure
The Atmo Ispheric Pressure Producer Gas Process (Figure 10)
consists of gasification'of coal by its partial combustion in a
stirred bed,, supported on a revolving eccentric grate which
producer gas is passed through'iron
removes the ash. The raw'pro e
oxide absorbers for sulfur removal. The regenerated absorbers
yield"sulfur dioxide which flows to an ammonium sulfate plant
for the production of crystallized ammonium sulfate. The
desulfurizid atmospheric producer gas coming off the iron
oxide absorbers contains soot and tars and is at-approximately.
13000F.
111-2
�
�
BOILER
COAL
SLAG
LIME-
STONE GAS
H2S CLAUS
COMBUSTOR PLANT
IRON
'AIR
SLAG SLAG
Of
FURIZER
SULFUR
--STEAM
@IRON
DESULFURIZED SLAG
-----------
TO CRUSHER
Figure 9. Applied Technology Corporation Two-Stage Combustion Process
for Low Btu Coal Gasification (Ref. 80.22)
�
66S TO
CQA_L_. I ATM- BOILER
FEED
HOPPER
0.5 psi g GAS. SPRAY
COOLING
TOWER
H
GAS. 2S
PRODUCER IGAS. ABSORBER
STEAM ANb@
WATER REGENERATOR w.WATER
AIR EDECANTER
TAR
SOLID WASTE.
SOZ-,- TO AMMONIUM
SULFATE PLANT
Figure 10. Bureau of Minos Atmospheric Gas Producer
for Low Btu Coal Gasification (Ref. 8014)
M Eli M M M no M
�
Bureau of Mines Producer Gas at Elevated.
Pressures
The Elevated Pressure Producer Gas Process (ligure 11) con-
si9ts of gasification of coal in the-same:.manuex as described for
the Atmospheric Producer Gas Process, with the important exception
that the producer vessel is pressurized to,120 PSIG. To
accomplish this,coal is fed to the producer'vessel.through a
lock hopper system. The gascoming off the iron oxide absorbers
flows to the gas scrubbers where soot and tars ate removed.
This will allow the 270*F, 120 PSI product gas to be utilized
in a gas turbine for-combined cycle power generation.
Lurgi Process
The Lurgi Probess (Figure 12) consIstsof gasification of
coal with air and steam at a pressure of 300 PSI. The gas leaving
the ga:@ifier is scrubbed to remove coal dust, Alkali and
chlorine. The-H2S is then removed from.the gas stream by.an
alkalized wash. Subsequently the H2S is converted into
elemental sulfur in a Claus kiln. 'The gas produced contains
.oil, naptha vapor and*other carbon products',of the gas-ifidd
coal and is at 4 temperature and pressure.of 300*F and-2501-MISI
respectively.
Ko22ers-Totzek Process
The Koppers-Totzek Process (Figure 13) consists of the par-
tial oxidation Iof pulverized coal in suspension-wi-th,.oxygen and.*
steam. The heart of the process Iis the burner nozzles at
which the,oxygen, steam-and coal react to gasify the carbon.,
and volatile matter of the coal at a slight positive pressure
and at 3300F., After gas cooling and scrubbing, the gas
stream is de.sulfurized. The gas produced will be at less than,
350OF and slightly greater than atmospheric pressure.
111-5
�
GAS TO
105 psig TURBINE
COAL
FEED-
HOPPER
115 psig 110 psig SPRAY.
COOLING
TOWER
1-12S
GAS
ABSORBER
PRODUCER.
STEAM' AND
120 psi g- WATER
WATER REGEN@RATOR
DECANTER..
AIR
TAR,
SOLID WASTE
J." soz -SOTO AMMONIUM
SVLFATE. PLANT
Figure 11. Bureau of Mines Press.urized.G.as
Producer for Low Btu.Coal
Gasification -(Ref. gol4l-
IT @ER
�
EXPANDER
COMPRESSM/
GENERATOR
DESULFURI ZED
GAS
COAL
DESULFURI
STEAM GAS GAS ZATION
Ir
GASIFIER WATER
SCRUBBER H2S
TAR CLAUS
STEAM REMOVAL
AIR KILN
TAR
SULFUR
ASH
CLEAN FUEL
GAS TO
TURBINE
Figure 12. Lurgi Process oflow Btu Coal.-Gasification
@(Ref. 8031)
�
DESULFURIZED GAS
SUPERSATURATED TO USERS
STEAM
PULVERIZER GAS ABSORBER
FEED WASTE HEAT
COAL
BOILER:
RAW GAS
GAS COOLER
AS
PAIMAW GA.SSECONDARY
GASIFIER WASHERT@-@ WASHER.'
OXYGEN
STEAM
SLAG SLUDGE TO-CLARIFIER FOULABSORBENT
AND DISPOSAL TO STRIPPER
Figure 13. Koppers-Totzek Process of Low Btu Co'al
Gasification (Ref. 8024)
7 G 7S
�
B. Impact-Data.Table and Footnotes
111-9
�
co
- M- I - I.-- V It
L. SIMI"
9:
L)
0 E-
m
8
E@
z
0
00
Ho
'mr
A A
X0
Cc 2
.14
I w w
2 T A A A A
- I I A . . . . . . . . .
--ca 7-
x
- - - . . . . . - - - - -- --
0
a 2 v al z:l I
0-
0x
p g P
i.- z
2
0
0 0, - - - - . . . . . . .
75
0
wt wL I
S 9
0 - - - - - - -
0 - - - - - - - - - - - - - -
0 @9
- - - - - - - - - -
0
9
14 z
7 4
0
n it
0 @xl
0
0
P-r
0:j
0
0
0
t.0
10
0
it
3. 0
TZ
- - - - ... . . .
cr
+ +
z
0 ti
0 0
EO
0< UO y
9.
11 .21 11 1
0 !21 In MIX I A 1 0, 10 M-P I
AM M M M M M
�
'PIC -1-1-1-12
c1l)
-13
x 0
a
l0fl
0 P4
ou z 0
La
Wc
xz
.10
zL
- - - - - . . . . .
0,
302
lz
+ +
0
10 - - - - -
z0 Ow . . . . .
<
LO !50
2 j7
- - - - - - - - - -
. . . . . . . . . .
0w
3c0
cr
I
I o-'61 O'd 11 il 9@1 41 IN 1 1111 1141111 11
L
'122tesgr. N . . '01010
0121 1
1!21 2 1 t I LI 1 11-0 1
�
1906,-2907
Footnotes for Table JL
1906 Source (1906,46).. 0.166 men per 14WE is the basis for
calculation Injury data are from-(1907135). Half the
combined deaths and permanent injuries are assumed to be
fatal injuries. Permanent total disabilities are
considered to rppresent 6000 days lost while other
disabilities are estimated as 100. days lost.
1912 A large new powerplant is..assumed, to have a heat rate
of 8960 Btu/KWH, equivalent'to 38 percent-conversion
efficiency. The best plants havb,achieved around
,8530-.8900, whereas the National'AVeraige i's around 10,500
(1913,1-5-6/1-5-7).
1913 Power sold divided by-'power produced, 1969 (1919,11,13).
1917 The basis.for water pollutant calculations is the-proposed
effluent limitations guidelines an&new .source performance
standards for the steam'electric power generating point
source category given in (1921). For new plants, best
ava'i'lable'demonstrated control technology (BADCT) requires
effluent pH control in the range of 6-9.- Hence acids and
bases discharge will be negligible. BADCT also specifies
total suspended solids levels no greater than 15 mg/l for.
all intermediate and low volume waste,effluents. At this
level"of control-there will generally be no net increase
in suspended.solids in water passing through the power plant,
system., Organics (oil and grease) must be controlled to
10 mg/l to meet BADCT standards. Hence,.from, 11921,232)
these emissions will amount to 3.0Z-03 ton/1012 Btu.
Information on the increase in total dissolved solids of
water used in power plants is not readily available and
was synthesize*d from (1922,10,12,20,22). Based on this
data the net increase,in total dissolved solids for water
used by the power plant is 3.40,ton/1012 Btu.
1918 Thermal discharges are assumed to.be comple tely eliminated
by use of mechanical draft cooling towers.
2907 Capital and operating costs for controls are estimated as
follows:
Control System Capital-Cost- Operating Cost-
$/Kw Ref. Mills/Kw-hr Ref
Water Poll-Chemical 1 (1921,233) ..05 (1921,234).
Water Poll-Thermal 10 (1915) .05 (1920,111-3)
Total Tr -.10
Based on the above, a 60P load factor and a net plant heat
rate of 9053 Btu/Kw-hr (37.7P primary efficiency from foot-
note 2908) the i 'ncremental capital post is 2.31+04 $/l.OE12
Btu and the incremental operating cost is 1.10t04 $/l.OE12
Btu. These.are in addition to thecosts given in footnotes
111-15
�
FTN. 3903-8001
2906 and 3905. Note that incremental fuel costs associated
with purchasing a. 6P sulfur residual oil (for oil fired
power plants) are not included in the above analysis.' Al-
though Properly attributed to air pollution control costs,
the cost of fuel is not considered;in the operating and
maintenance costs of the uncontrolled case and hence an
incremental fuel cost is not given for the controlled case.
3903 See footnote 1906, using 0.089 men per MWE.
3905 Cost of gas fired power plant at $100/Kw,(1914) and (1915).
operating and maintienace cost exclusive of fuel cost,At
0.51 mills/Kw-hr (1906,45). A 60P"load factor is assumed
and the FCR for capital is 10P.
8000 Primary efficiency for the ATC two-stage coal
combustion process includes the decrease in efficiency
associated with the necessity of thermal drying of the
ROM coal.from '22.25 to 4 percent moisture (8022-23).
From (8006,13-3/13-25) and the fact that it takes
5.42E4q+04 ton of 92268qA Btu/lb average Northwestern
coal for 1.OOE+12 Btu input, 1.10E+03,ton or 2.0
268qf
ercent of the coal is consumed in drying. This leaves
4.38E+04 ton of 11288q5.6 Btu/lb coal going into the process..
This 4.34E+04 tons of 4.0 percent moisture coal is' then
dried to 1.0 percent moisture prior or to e-ing the
combustor, leaving 4.21E+04 ton of 11q115.6 Btu/lb coal
(8022-236qY. Based on the above input to the combustor
and that 3.7.98qE8q+6qWlb low 8qBtu,gas, at 2.58E2q+03 Btu/lb
are produced per-l2qb of North4qWeste"rn coal, the
efficiency of gas production = 84.0 percent. The'
primaryefficiency of the!ATC combustor coal conversion
proces0qwqo 0.98 x 0-.8.3 x 100.0 81.0 percent.
8001 The land impact of the ATC coal@combustion process
consist's of equipment for-thermal drying-q(se4qd-footno2qte,
q8000), equipment for the combustor unit and.,
desulfuqrization unit, limestone storage and
desulfu0qkization slag storage. Coal stor0qagewill be
allocated to the utility since the combustor can be
retrofitted to an existing facility (8015,45). No
impact 0qon land Area.could be found for thermal drying.
It will'be assumed at 0.10 acre. The impact of
equipment for the combustor and desulfurization unit
will b00qe 4.50 acres, assuming a 1000 MW utility
employing four 28 ft diameter combustors, sulfur
recovery system, coal, limestone and air preparation
equipment (80236q50q)q. From (8029), the use of the
Northwestern coal will require 0.0119 lb l0qiim32q68qs24qton08qe/lb
q.08q072q"Iq:f2qe2qi08qedq,q@t04qc 24qthe process,and 0.q14q068q-2q7 l92qb stored slag/lb
coal feed is produced. For 4.34E08q+04 ton coal feed
.(see footnote 84q60b), 5q.16E12q+02 ton of limestone is
needed. For 4.21+04 ton of coal fed to combustor (see
footnote 80q600),2.8904q+03 ton of stored slag is produced.,
111q-16
�
�
FTN. 8002-8003
Assuming a pile height of 30.0 feet and a density of
T/CF for limestone and 0.060 T/CF for stored.
slag, 9.78E-03 acre/yr and 1.11E-Ol acre/yr are used.
Total land impact, acre yr/l.00q+12.Btu 4.78E-02 +
1.60E-02 = 6.72E-02.
6q&002 Particulate emission sources are the coal fired thermal
dryer, air blown dryer, limestone dryer - crusher and
combustor. A fluidized bed thermal dryer with a 99.0
percent efficient venturi will emit 0.2 lb particulate/
ton of coal feed (0002,8-10). With an input of
5.42E+04 ton coal/l.OOE+12 Btu,particulate = 5-42E+01
ton. The air blown dryer will have the same emissions
.as the coal fired dryer. For the 4.34E+04 ton of coal
fed into.the system (see footnote 8000), 4.34E+01 tons
of particulate-are produced. Crushing of limestone with,
a 99. 0 percent ef f icient bag house will produce 8.52E-02
tons of particulate (0002,8-15)., Drying of limestone is
similar to drying of gypsum,thus with the use of a
fabric filter 0.2 lb/ton of particulate is emitted or
5.16E-02 ton. (0002,8-14) The only particulates from.a
commercial size combustor will be metallics, from
bubbles bursting in the iron bath (8022,105/107). This
amounts to 1.82E-04 lb/SCF in the test combustor but
will be reduced at least by 99.0 percent orl:82E-05 lb/
SCF in the commercial (due to 4 times flue). 1.0 lb
coal will produce 5.83E+01 SCF of.gas (8029), for
4.21E+04 ton of coal input to the system 4.96E+09 SCF
gas is produced yielding 4.52E+01 ton of particulate.
This particulate will not emerge from the conversion
process but will be emitted from the utility and will
be allocated to it. Total particulate emission from the
conversion process = 5.42E+01+ + 4.34E+01 8q+ 9.52E02 +
5.16E2q-02 = 9.77E-01 ton.
8003 Sources of air emissions for ATC-combustor pcocess will
be from the primary coal fired fluidized bed thermal
dryer and Claus plant. Pollutants inherent in the
combustor fuel gas are allocated to the utility where
they occur. A well controlled thermal dryer.will emit
0.54 lb NOx/1.O0E+06 Btu, 0.'045 lb SOx/l.OOE+06 Btu,
0.58 lb hydrocarbon/l.OOE+06 Btu and 0.39 lb CO/1.00+06
Btu. From the coal used in firing (1121),
III-17
�
�
FTN. 8004-8007
1.10E2q+2q0 ton of 9,q2_q26@q0 Btu coal or 2.038q98q+10'Btu is
used for firing, thus 0q5.6q4q88qE+00 ton Nox, 4.6q5q7E-01 ton
SO4qXI 5.89E8q+00 ton hydrocarbon and3-.96E2q+00 ton CO is
produced. Emqi:ssionromhe Claus plant consists of
sox. From the molar composition-of H2S + S0q02 of 35.0
percent of the gas and (8012) thelClaus plant
efficiency is 92.0 percent from (8029q@, H2S' = 3.204qE-03
lb/lb coal and SO'q2 2..;qBOEq-03 lb S02/lb coal. Total
S available = 4qC6qA0qI8qE`03 lb/0qib- coal,. For 4. 2 1E6q+4qW- -tons,-,+ 2qdoal,
1.49E2q+O2qi ton of-S qiv8qs@-av8qailable as"an 'emission or as
S02 = 2,.97E2q+01 ton.-.Total S2qOqi = 0qC57E-06q12q+ 2.97-E0q+06q1
3.000qE6q+qO,ql ton.
8004 Ancillary energy demand iqs stated'as 12 8qMW.'.for 10,2qGqO MW:
of electricity produced to operate the equipment'
necessary-for the conversion process (8025). 1.q0q08qE2q+12
7'Btu input will product .9.'31E8q+04,-8qM0qW, (8.-02q9q) thus.
ancilla,)4qr6qy energy = 1.12E2q+03 2qMor-3.83E2q+q04q9 Btu (8029).
8005 Water 6qdffluent-fr0qom the conversion proo'4qcess-occu 0qrs only
from rxqinof f f r4q62qm stored sla6qq. The. conversion process:
is a closed,, lo0qop-with- respect to,- water use. From. (804q22.
147), the su6ql6qf -q6qLt@e runo8qf f gi0qve0qm-@a s2q1a g,of l..qO percent
sulfur, is 23"6qA PPM su_lfat4q6@0qor 2,.q95E-01 GM/S2qQFT'or
2. 4 3E-.012 ton..
806 Solid waste, consists. of de8qs6qul2qf0quri0qzed slag. only. Sulfur
will be sold at.current market prices- * In the Northwest,-
slag will not, have- a market (8.022q5q).1 it is. cons0qid ered,
a solid wa0qste..So6q1id Waste 2.89,8qE8q+03 ton (see
footnote 8-q0q01).
80107 Air emiss0qsio8qn0qs-from the-utility'utilizing'the ATC
process depends upon.the-c6qom6qpositqionlof the gas. One
pound of NorthqO4qkqisternl coal will produce a.,gas- composition
as follows ('8q029):
8qC4qO 1. 42,32 lb.
H2 0,04q5q17 lb
C02- 0.00,01 lb
N2 2q.q;-3048q49' lb
The gas will 2qalso@contain 228q2.0 P32qPM S20qOx, (80q-15,29)q,
22.5 PPM N28qOx 60qM0q,6q25) and 5.42E08q+01 ton particulate
2qIf16qootnote 8002).
116q1q-28q18
�
�
FTN. 8009-8011
For combustion of the low Btu gas, a firing temperature
of 110OF - 1200F. will be used (8025). Assuming
combustion is'essentially completethe emission from
fuel gas. combustion, given .4.21+04 ton of coal input
or 3.122q+08.ton of gas(fo2qo'tnote 8002), = 3.11E2q+00 ton
SO, and 3.23E8q+00 ton 8qN4qO4qxand 2.26E2q+02 ton1particulate.
Total.em0qissi0qon through the stacks are As follows:
Partitulates sox N8q0x,
5.42E8q+01 3.114qE8q+00 3.,23E8q+00:'
8009 S02 emissions-from the BOM Atmospheric Gasification---
Activity is 3.9q5E2q+01 tons. Figure 'is based on a coal,
input of 3.628qE8q+04 tons/yr..Of the qO@q68 moles 8qof H2S fed
to theabsorber, 80 percent is reacted and-97,perc4q6nt
is regene8qkatq;Bd. Emission of H2pis considered-as S02'
(8010).
8010 Air emissions for the BOMq-Atmospheric Conversion
Process,, using the Northern Appalachian coal,, consist
only,of S8qOx.vented from the ammonia sulfate plant
(8030). 80.0 percent of the H2S in the initial
combustor fuel gas is removed by the iron oxide
absorber. Upon regen4q64qration,0qA gas rich i8qn q@6q02is formed,
This is.then fed to an ammonia sulfate plant'which has,
an efficiency of 97.0 percent (8030q), The Northern
Appalachian coal will produce a feed of 69.70 lb S02
equivalent/ton of 0qcoal,(8030), therefore the emission
is 2.18 lb S4qOx/ton of6qoal. For a 1.qOqOE8q+12 Btu
equivalent of 3.94EqO4 ton of coal, 3.95EqO1 ton ofS8qOx
is produced.
8011 Air emissions for the B8qO4qM conversion proces6qs.occurs from
ammonia sulfate production' as -described in footnote 8009.
For Central.and-Northwest coals, with feeds 2qof 3.82EqO1
lb and q1.48+01 lb S02 equivalent/ton of coal-to the
ammonia plant and coal feeds of 3.62EqO4 tons of coal and
5.424q+04 ton.of coal respectively, 2.07EqO1 tonand 1.20+01
ton of S4qOx are emitted respectively.
III-19
�
FTN. 8012-8016,
8012 The BOM-Atmospheric Gasifier will require 5.428q+04 tons
of.92q126 Btu Northwestern coal per.l.OqOE12Btu input.
6.38percent of this is ash.. Assuming*essentially all of
this0qcan-be-removed from the combustor, solid waste =
5.422qkq04 x 0.0638 = 3.46Eq03 ton,(8030). This solid waste
will'be.returned the mine as,fill.
8013 The 6qSOM-Atmospheric Gaslfier`will require 3.62Eq04to6qns
of 13800 Btu/-,[email protected] coal per 1.OqO2qE1
Btu input. 14.0 percent is ash and assuming all can,be
removed from the combustor,solid waste = 0.14 x 3.62EO4
5.06EqO3 ton. (8030). 5.0 percent 4qW'2qill.'be returnedas fill
to 0qthe mine...,,
8014 @The8qO8qM-Atmosphekic Gasifier will require 4.1q@EO4 tons
of 12050 Btu4q/qlb Central regional coal per,1.004q+12 Btu
input. 17.3 percenht'is ash. Assuming all ash is
removed from8qthe combustr,solid waste= q02q473 x
4.15EqOq4,= 7.0'64qEq03 ton (8030).
8015 The land impact for the 8qB4qO4qM7 Atmospheric Combustor
process using- @N8q6rth2qern Appalachian coal consists @of
theequipqr8qw4qd4qnt-or conversion a4qn6qd-sulfu0qr removal and
for ash st8qd-0qrage-.'The conversion and'-sulfur removal
systems have a fixed impact of qSqO0qA acres. From.
footnote q8q013,2.538qtqO3 ton of 0qash will be produced., In a
pile30.0 ft high, ash 'Will occupy 2.918q1q-q00q1 acres.
Fixed land impact for processing 1,.,qOqOE8q+1'q2 Btu/yr is
-impact for ash
4.76E-01 A4qdre-yr. Time,,averaged, 'land
disposal is 3-.438q8-01 acre-y8qr. total land impact is
8.196-01 acre-yr/l.qOqOE2q+12 Btu (8031q)
8016 The land impact for the-atmospheric coqm8qb4qtstor using
a Central regional,cal having+.a heating value of 12050
Btu/8qIb consists of land required for the ash storage
pile,, gasifier, gas treating facility, and the sulfur.
plant. The ash:stor2qage pile assuming a 50 foot-pile
occupies 4.85-01 acres/l.qOqOE12.pBtu. 4qFora throughput'.
equivalent to operate a 106qGqO4qN4qW."plant the land impact is
3.76acres.q. This-is time averaged over 25 years. The
fixed land '40qt04qmpact is 2q2.26 acres, The time averaged land
impact per Btu throughput is 36qLq.q'07E2q02q0q-ac00qresq-60q0031).
�
�
8017-8023
8017 For the BOM-Pressurized Combustor using a Central
region coal the only air emissions occur in the
ammonia sulfate plant. For A-1000 lb feed 1.154 lb of
so is released (8030). For a 1.OqOE12 Btu feed of
48q15Eq04 ton of coal, the S4q02 emission is 26qAOEq01 ton.
8018 For the BOM-Pressurized Combustor using a Northern
Appalachian coal, the only,air emissions Occur from
the sulfur recovery process in the ammonia sulfate
plant. For a feed of 1000 Ib of coal, 1.09+00 lb of
S02 equivalent is released (q8030), For an input of
1.00+12 Btu of 13800 Btu/lb coal, the S02 emission
3.'95EqO1 tons.
8019 Land impact associated with the BOM-Pressurized
Combustor consists of the gasifier, gas treatment
plant, sulfur,plant, and cooling, and.ash storage
system. For a Central regional--coal this equals
2.50E-02 acres/1.0E2q+12 Btu input and a time-averaged
storage of 4.94E-01 acres over 25.yea0qrs'assuming
50 foot pile.otcqil land impact =.q58-01, acres q(8031q).
8020 Land impact for.the BOMq-Pressurized'Combustor utilizing
a Northern Appalachian coal is identical to fixed land
impact for footnote 802q19, however it is adjusted to
reflect change in Btu content of gas produced. Fixed
land'impact = 2.40E-02 ash is the.'same. Total'-land impact
2.40E-02 + 4.94E-01 7.51E-01 acres (8031).
8021 Air emissions for the BOMq-Pressuriz0q6d combined cycle
boiler consist of S8qy 2qFor an input of 1.qOqOE8q+12 Btu of
gas 1.48E6q+04 moles o S02 are formed (8036). S02
4.74E8q+01 tons/1.q0q0E8q+12tu.
8022. Product gas from the absorber contains 0.136 moles of
Hq2S/8.96EqO6 6qBtu (8030). For'a boiler feed of 1.002q+12
Btu, gas c6qQntains.1.54EqO4 moles of H2S. Assuming
complete combustion.88EqO2 tons of S02q2/1.qOqO0qE12 Btu
are formed.
8023 Produ00qc q't gasq@from the absorber contains 0.075 moles of
24qH260q4/8.97E6qO6 Btu of gas. For1q.00E12 Btu of 32qgas produced
and fed toq.q,boiler 8.40E2qO3 moles of H2S are converted to
so q. g complete combustion. S02 2.69E8q62 tons/
assum6qin
0q032qE12,q_q;32qSt00quq.
�
�
FTN. 8024-8630
8024 Product gas from the spray cooler contains 0.075
moles qiqI4qj6qS/8.72EqO6,Btu of2qgas. For 1.00E12 Btu'of
gas pro uced and fed-to-boiler 8.63EqO3 moles of H28q8
are converted tqo S02 in boiler Assuming complete
combustion (8030), S02 = 2.786qiqO2 tons/l.qO6qDE12 Btu.
8025 Partic0qu late emissions consist of carbon,and sulfur
dust emitted from the boiler. For a 1000 lb Central
region coal feed I#I '3.02EqO1 qIbs 0qof 7dust are' 0q68qm4ql8qt't2qicqi. For a
coal feed of 4.qi50q+04,ton/'l.qOqO4qE12"Btuemiss'lon is
1250 tons dust (806qH). Dust or particulates are removed
by 80 percent,in absorber hence particulates -1.25 ton/
1.qOqOE12 Btu. For.-use in a-combined,cycle power plant an
additional 97 percent particulate removal must be
obtained by electrostatic precipitator (002-Aq5q)..
8026 Particulate emissions for the boiler consqi4qzt of@dust
as in footnote 80,25. Fora 1000 lb feed-emissions are.
3.19EqO1 tons. For 1,qOqOE12 Btu feed of 3.626q+04 tons
and-90q"percent removal in,-absorber and 97 percent-by-
precip2q*tator particulate-e8qm6qi0qsqgions= 3-44 4qton/l.qOqOEq12
Btu (8q03q0.,.0002-AqS).
88q627 Particulate emissions-consist of carbon and sulfur.
emitted from-boiler. For a 1000 6qIb feed, 3.02 lbs are
emittedin'gas and 90 percent-0qis removed-in absorber
(8030). For 4.15EqO4 ton/l.qO.qOE12.Btu feed static
particulates:= l.25EqO4q2:tons6q/-ql.qOqOEl2_Btu.An electro
4qp8qxeci2qpitqzq@-qE0qor' 8qat-.97,percent-efficienty--6qY.yields-3.75E2q+00
tons. -
8028 For 10:00 lb coal feed particulates = 3_19 lb for 90
percent removal-andicoal fee2q&of 3.62EqO2 ton/l.qOqOE12
Btu.8qE4qmqission = 1.12q5Eq02 ton/1.00 ,4qB12 Btu (8030). See
footnote027.
8026qR For l.,00 lbof coal fed to producer, 0.001 lb H2S/6.04EqO3
Btu ofgas is formed.. For boiler feed-of 1.00Eq12.Btu and
assuming complete combustion S02'= 1.56E,02 tons SO6qV
1.qOqOE12 Btu (80-30).
8030 Particulate emission fromqA.the absorber is 0.0026 lb/
6.04E6qO3 Btu of gas produced. For a feed o q'6qf 36qIq.2qO6qOE12
Btu of gas, 2.12q6E6qO2 tons-of particulates,are generated
(8030).
III-22
�
�
FTN. 8031-8035
8031 Air emissions from the Lurgi Combined Cycle Process
consist of SOX, NOX, and particulates. Emissions are:-
(8027)
N8qO8qX. = 0.021 qlb/1.q0q0E06 Btu input
SOX = 0.057 l6qb/1.q0q0E06 Btu input
Particulates 0.029 lb/1.q0q0E06 Btu-input
For a 1.qOqOE12 Btu input air emissions are:
6qN4qO0qX = 1.q0q0Eq0q1 ton/l.qOqO4qE12 Btu
SOX = 2.86EqO1 ton/1.q0q0E12 Btu
Particulates 1.43EqO1 ton/1.q0q0Eq12 Btu,
8032 Land impact for the BOMq-Atmospheric.Combustordonsists
of fixed land.impact of 5q00qA acres forequipment
necessary for conversion of 1.qOqOE12 Btu/yr-The time-
averaged land impact - 4.20E-01 acres (8031).
8033 The land impacts for the' power generation cycle
consist of fixed land impacts only. From foot2pte
.3902 land impact for a 3000 MW plant,,=150 acres. For
a. 1000 MW plant this equals 50 acres.. Annual Btu
throughput to operate a 1000 MW plant is as foll4qqwqfq@:
Northern Appalachian Coal 1.06E14 Btu/yr
Central Regional Coal 1.qOqOE14 Btu/yr.
Northwest Coal 1.2q0E14 Btu/yr
For a fixed land impact of So acres'this.yields an
impact of: 0.482 acres/1.q0q0E12 Btu, 0.500 acres/l.qOqOE12
Btu, and 0. 418acres/l.qOqOE12 Btu respectively (8030).
8034 Particulate'emission from spray cooler yields q0'.211
lbs/6,83EqO3 Btu. For 1.qOqOE12 Btu of.prodquqct fed to boiler,
1.56E0*4 tons particulates1pre produced. Using an
electrostatic precipitator of 97 percent efficiency.this
yields 4.68EqO2 tons particulates (80q30)_
8035 Land impacts.forthe BO20qM-Atmospheric combined cycle
generating system is 1_26 acres/58.2 MW plant (8031).
For 08qa.1000 MW plant it Iequals 21.7 acres. To run a
1000 MW power plant the following gas heating.
composition must be fed to the turbines/yr:
111-23
�
�
FTN 8036-8041
N. Appalachian Coal 1.06E14 Btu/yr
Central Regional Coal 2q1.q0q0E14 Btu/yr
Northwest Coal 1.2q0El4,Btu/yr
For a 1.qOqOE1q2Btu input the-land impact would be as
follows:
N. Appalachia. 2.05E-01 acres/1.q0q0E12 Btu
Central Regional 2.1q7E-01 acres/1.q0q0E12 Btu
Northwest 1.81E"01 acres/l-.qO-qOE12 Btu
8036 Based 2q6n calculations in (8030) SO' emissions from the
2
ammonia sulfate-,.plant are 0,00026 lb/lb coal. input.
F4q6.0qr a 1.qOqOE12 Btu.coal:@inputLof 5.42EqO4 tons, qS02
emissions are 1.4-qIEq01 tons/,l-.qOqOE12 Btu (2qR030).
8037 Power transmission is based on 3.200 MW,capacity line
with a load factor of 0.2q70 (8033',1-13). Capacity is
6.70E8q+13 4qB6qtu/yr. From (8033,I-q)right of way is 20.-q0
acqres/mileand transmission-distance is assumed at
1000 mile.. For,qOqO4qE8q+12'Btu input the land impact
is 2 98E8q+02:acres. Transmission-diqtta0qnce.based on
[email protected] Corners.-to Chicago-.
8038 Power transmi .L-ssio4qnis b2q&sed-on 32.00 MW capacity line
with a.lo2qdd factor of 0.70 'q(8033,,1-13). Capacity is
6.70E2q+13 Btu/yr. From (8)033,1-1) right of way6qi0qs
20.0 acres/ mile and tqransmi.ssion distance qis 450
miles. For 1.qOqOE12 Btu.input-.the land'impact is
1,35E2q+02 acres. Transmis,sion@distance--'based on
distance from-Pittsburgh to Chicago.
8039 Ancillaryenergy for a 150.ton/hr plant requires
34,745 KWH4q/,H. For a liqOqOE12.Btu coal feed of 12,100 Btu/lb
coal, this.-is equivalent to 3.276qE4q+10 8qBtu..(8010,19q)..
8040 Ancillary energy-for a 15q0 ton/hr plant-required
3q@,745 KWH/H. (8010,19). For.,ra.1.00 E12 Btu coal
feed of 9226 Btu/Ib coal, this is equivalent to
4.128E8q+10 :Btu..
8041 Ancillary energy.for.aq.150 ton/hr plant requires
34,745 KWH/H (8010q119). For a 1.6qO6qOE08q+12 Btu input of
13,80q.0 Btu/lb coal, this is .equivalent to 2.86E12q+10q,B24qtu.
111-24
�
�
FTN' 8042-8046
8042 Ancillary energy for a 150 ton/hr Plant is 34,415
4qkWH/H (8010,19). For a 1.qOqOE8q+12 Btu input of 12,100
Btu/lb coal, this is equivalent to 3.23E2q+10 Btu.
8043 Ancillary energy for a 150 ton/hqr plant is'34,415.
KWH/H (8010,19). For a 1.006q88q+12 Btu input 4qof 13,800
Btu/lb coal, this 0qiqi equivalent to 2.83E4q+8q10 Btu.'
2p Ancillary energy for a'150 ton6q/hr plant is 34,415
4qKWH/H (8010,19). For a 1.qOqO2qE8q+12 Btu input of'9226
Btu/lb coal, this is equivalent to q4..22E8q+10 Btu.
8045 Land impact for ' an ATC Combustion process consists of land for thermal drying, combustors, desulfurizat0qion
unit, limestone and slag storage. Coal.storage will be
allocated to utility since combustor can be retrofitted
(8015,45)'. Thermal drying is assumed to require 0.10
acres. 4.50 acres are required for combustor and
desulfurization units (8025).Th4qd use of 11,503 Btu/lb
coal requires 0.224 lb limestone/lb coal a0qnd
produces 0.1101 lb slag/lb of coal of which 50 percent,
is'sold. For a feed,of 4.908qE8q+04 tons coal this produces
1.10E8q+03 tons/yr limestone and 2.'698qE8q+03 tons oqf slag.
Assuming limestone and slag have a density.
of 0.083 t/cf and 0.060 t/cf respectively,-a refuse
pile 30 feet-in height would occupy 1.34E-qOl Acres/yr.,.
Time averaged over 25 years6qwould equal 2.94E-02 acre-
years/1.q0q0E8q+12 Btu. Fixed land impact is 4.60 acres. On.
1.qOqOE8q+12 Btu basis =.5.330qE-02. Total land impact is
8.27E-02 acres-yr/1.q0q0E2q+12 Btu for yearly output of
8.67E2q+13 Btu/yr.
8046 Land impact for-an ATCCombustion proce ss utilizing
Northern Appalachian coal at 12696 2qBtu/lb requires
4.50 acres for combustor4qs:,and desulfurization
equipment.. Coal storage i 's applied.utility. Limestone
and slag produced is 0.0262 lb coal input and 0.0899 lb
coal input respectively (q80,29). q50 percent of the slag
is sold. For a coal feed of 3.94E8q+04 ton/1.q0q0E+12 Btu,
1.034qE8q+03 ton of limestone and 3.54E8q+03 tons 0qof slag is
produced. Assuming 30 ft high refuse pile and a q*density
of.limesto08qne of 0.083 ton/cf and slag of.0.02q60 28qt68q/6qc2qf
this 16qO04qC04qC00qU32qP4qI08qA04qS an area 4qc0q>f 1.06E12q+14- Btu/yr t2q1x36qis equals
1q.45Eq-02 acre-yr/1.2q02q0E08q+12 Btu. Fixed land impact for
output of 1.06E08q+14 Btu/yr equals 4q.2424qE-02 acre-yr/
1.2qO2qOE12q+12 Btu. Total 5.69Eq-02 acres-yr/1.6q06q0E12q+12 Btu.
111-25
�
�
FTN. 8047-8049.
8047 The efficiency of.the.ATC-Combutor-Conversion process
utilizing.a Pittsburgh coal@having 1.2696.0 Btu/l2qb,
1.0 percent moisture and 1q31:85 percent ash', will be
Btu g4qas out/Btu coal in. From (8029) 1.0 lb of coal
will yield a gas of 9..34E8q+03 Btu..-For a 1.qOOE8q+12 Btu
input, qj.94E+04 ton of coal,is input producing 7.3q6E2q+ll
Btu of gas. Thus efficiency -_7.32q6E0q+11/1.0@1q0E8q+12 =@0-736
8048 The efficiency,of the-A4qTC-Combustor Conversion process
includes the decrease,in effi0qc2pqrqi4qoy associated with
the necessity of thermal.drying of the 10
050.0.Btu, 15.31
percentimoisture,ROM Illinois-No.1p2pal to a42pp7860;4356;84;136qOpercent
moisture.coal -,(8022,23).From (80.0.613-3/q1.3-25) and the
fact that it tak'es.1.41-".97E2q+04.ton/1.0q6E2q+12'2pu input, 6.70
E4q+02.2 ton' or_1.q3,percent of the,coal is-consumed in-drying.
This leaves 4.3q5E8q+04 ton of 1132:.qO.Btu.coal going into
the process. Then,it,is air dried to 1'.0perqcentmoisture
prior-.to entering,'the.combustor,.or 4.22E4q+0,q4,-tonof 11503
Btu coal..Based.uponhis input to the,combustor and
that 9.19E4q+03 Btu of.gas is produced/lb coal, efficiency=
0.799 0qx 0.986 = 0-0q788.
8049 Sources of, -air @,-e;missions for - the 4qAT8qC!"'2qCombustor. -process
utiliziqn'g Central-coal-will.be,from.the@,co'al fired
[email protected] Claus.pl0qant. Pollutants inherent In
the coq;q@2q@ust0qor fuel.gas.are-allocated-to--the@utiqlqity
where they0qoccur. A-well,contro.q1-ledthermal,dryer will
emit 0.54 lb,N8q0qX/ql.,q0q0E8q+0-6tu, [email protected]'/1.q0q0E8q+06
qx
Btu, 0.58 lbhydrocarbon/l.qO.qOE6q+06,Btu and*0.39.lb CO/
1.qOqOE8q+qOq@ Btu.From [email protected] [email protected],.(1121), 6.7q0E8q+02
ton of coal will be consumed in drying (sele.footnote
80.48) or 1.35E8q+l2qQ [email protected]@3.q6AE4q# '00 ton-, 3.0'qOE-01
on S4qOx, 3.92E4q+00 ton hydrocar8qbon'-,and 2.63E4q+02 ton'CO
will [email protected] theClaus-pl6qAnt2qthe_only emission
is qS4qoqx."From(molar HIS + S02@percentof 31,q0--percent of
the input,,gas.and.(8012q),,.the C2qla2quqs1plant.8q6ff0qicienc2qy is
92.0 percent. From q1'80.29),@H2S = 2.67E-02 qlb/lb coal and
S02 = 2@0q50E-02,lb/lb coal is input.:o6qf1paus. The output
equals q;.0060.lb/lb coal on anqS4q02 basis.2por,.an input of
4,75+041. ton Of, coal, S4qOx =q12_8q6Eq.0q+q102. Total.,Sox 2.864qE8q+02
+ 3.8q0q-4E-07 2.8,6E08q+028q2q,q-q-'q,S20q000qXq.
III-26
�
�
FTN. 8050-8052
8050 Air emissions, other then particulate, for the ATC-
Combustor, utilizing No. Appal. coal, occur from the
Claus-plant.-The emission iqs S8qOqX. From molar H2S + S02
percent of.32.0 percent of the input gas and (80q12), the
Claus plant efficiency is 92.0 percent. From (8029),
H2S =3.97E-03 lb/ql0qb coal and02 = 3.q5q02qE-Q3 lb/lb coal is
input to Claustgiving an output of 0.0009 lb SO8qZ
equivale6qht/lb@coal. For an input-of 3.94EqO4 ton of coal/
1.qOqOE12 Btu into the conversion process, SOX 3.94E8q+04
x 0.0009 = 3.55E8q+01 ton.
8051 Particulate emission sourceqsusing Central coal consist
of the coal fired thermal dryer,ir blown dryer,
limestone dryer-drusher and combustor. Afluidized
bed-0qt8qf8qiermal dryer with a 99.0 percent efficient ve4qnturi
scrubber will emit 2.0 lb particulate/ton coal feed
(0002,8-1q6).*With an input of 4.97E8q+04.tQn of ROM-coal/
1.qOqOE2q+12 Btu, particulate = 4.97E8q+01 ton, for the air
blown dryer, for 4.35E8q+04 ton of coal fed into the
sys6qtem.,(see footnote 8048), particulates = 4.35E2q+01 tons.
Crushing and drying of limestone with a 99 percent
efficient bag house and a throughput of 1.qOqOE8q+03 ton of
limestone will emit 7.184qE2q+00 ton+and 4.35E2q+00,ton
respectively (8002,8-14/8-15). The only particulateR from
the combustor are metallics (80.22,15/107). This aqnqvq6unts
to 1.82E-04 lb/SCF in the test combustor,, but will be
reduced byt least 99 percent in the commerqdial size
combustor or'l.82E-05 lb/SCF of gas (8029). Particulates.
7.15E8q+01x 1.82E-0q5 = 1.30E-03 lb/lb coal or for
.22E2q+04 ton input to the.combustor particulate = 5.49E8q+
01 ton. The particulate will be emitted at the utility
and not considered part of the conversion process.
Therefore 'total particulate from conversion = 42ppE8q+01 +
4:.35E8q+01 + 7.18E2q+00 + 4.35E2q+00 9.47E2q+01 ton.
8052 S02 emissions from the BOM combined cycle plant consist
of t8qhe H2S contained in the gas from the 'spray coolers.
This gas contains,@0.0012 lb H2S/6.83E4q+03 Btu output. For
a feed-to theboiler.of 1.qOqOE8q+12 Btu, 1.76E4q+05 lbs
or 5.16E4q+03 moles H2S are formed. Assuming complete
combustionq,q'1.65E08q+02 tons S02/1q.2qO2qOE08q+12 Btu are formed
(80q-16)-.
111-27
�
�
FTN. 8053-8055
8053 Sources.'of air emission from the Koppers.;-Totzek
Conversi6qon'process, using*Central regional coal,
are the coal fired.thermal dryer and the Claus plant.
Another potential source of emission is from the coal
pulverizing operation,2qbut all6qd4qtst is captured and
sent to the gasifier (8023). From (8006,13-3/13q-25) and
the fact that it,takes 4.97 E8q+04 ton of 1005q0-q0 Btu
Central@coal/1.q0q0E2q+12 Btuinput, 4q7.06E6q+02 ton of coal.is
consumed. The,'8qem4qf4qtqsiona-are 0.26q1b particulate/ton,coal
feed (99.0 percent. efficient venturi scrubbing) (0.0.02,
q8-10), 0.54 [email protected]@/6q1.00E4q+06 Btu:fired-(8035), 0.045 lb
qS8qox/1.q0q0E8q+06 -Btu fired (80,35), 0_58 6qIb hydrocarbon/
1.qOqOE2q+06 Btu fired (q8035q) and 0.39 lb'C4qO/1.qOqOE4q+06 Btu
fired'qfor thermal dt6qk6qyi8qng. From the above,,emission-for
the thermal drying = 4.:97E8q+00 ton particqulate,2q2.70E8q+02
ton NO Fqor every lb of:coal,combusted-iqrqi the combustor,
b of H+q2S and qO..,006.qlb of",COS is2q4,ormed.4qOn a
0.052
l.-qOqOE2q+12.Btu basis,'this yields a total of-4'q5:72 tons
H2S and COS On S02 basis (8034,14) . 90@. 0 percent oqf this
SOq2q@-is-'removed:i4qnzthe Rectisol,unit.a-nd directed to the
Claus @qpq@lant..'Of the, 4115 -tons input to- the Claus plant
with Str6qdtfor6q&@4qiail 2qgas-c2qlqe4qanup, 99,@qO percent.- is removed.
q'2 q'q0q0E8q+lq2'Btu.-total-S0qQ
S02 = 41. 0qx .4 12E2q+01 +
3.20E-01 = 4.12-4qE2q+01-to6qn:-S4qO0qX0
8054 S02 emissions f4qor the Koppers-Totzek.Electrical
Gene0qtation@process utilizing:Central coal occurs in the
boiler:activity. As8qtumqingdomplete:*combustion of the
H2Snd C4qOSq"entering the&,-'system l6qVpercent x 4572
457.2 tons of S02 is formed,and@:emitted.'See,footnote
8053 (8034,14q)-.
'The only sources- of,@particulates'for'the'ATC-Combustor
processutiliqzing a Northern. Appalachiai0qbal are-the
limestone crusher--dryer and@the Combustor. Crushing and
drying;of limestone with a,q99.0,,p8qe0qxcent'efficient bag
house and a'throughput of 1.03E8q+03,@ton-of limestone
will emit 2.06E-01 t0qon.and 1.7q04qE-01-ton0qxespectively
(0002,8-14/8-1q5). The*combusto8qk will-emit metallics,
which in the commercial si,ze combUstor-,equals 1.82E-05'
lb/SCFq:gas. 1.0 lbq,coalq, will produce 80 q''89 SCF of gas
(8029). Particulate = 8036qA9 x 1-.82Eq-05 8q- 1.47Eq-03 2qlb/lb
of coal or for 3.6q50E20q+04 ton coal input to the combustor,
particulate = 57.4 lb. The metallic.particulate will be
emitted at the utility and not be considered part of the
conversion process. Particulate from conversion
3q.76E 01. Particulate from utility 5.74E-01 ton.
III-26
�
�
FTN. 8056-8061
8056 SO@ emissions from the Koppers-Totzek process
utilizing Northern Appalachian coal, at 12,696 Btu/lb,
occur in the Claus-Stretford plant only. For every
lb of coal combusted 0.0110 lb of-H2S and 0.0022 lb
of COS are formed.. On a 1.OOE+12 Btu basis this yields
a total of 911.6 tons H2S and COS on a' base
S02
(8034,14). 90 percent is removed in a Rectisol unit and
directed to a Claus-Stretford plant for further gas
treating, up to 99 percent efficient.
S02 = -90 x 911.6
tons x 0.01 ='8.21 tons S02/1.OOE+12 Btu.
8057 S02 emissions for Koppers-Totzek electric generation
process occur in the combined cycle activity. Of the
10 percent total S02 equivalent emitted from the Rectisol
unit,.100 percent is combusted in the boiler..Total S02
-emitted equals 91'.2 tons/1.00E+12 (8034,14). See
footnote,80-56.
8058 Solid waste as ash generated in the Lurgi Conversion
process is a-46X+03 ton based on a feed of 5.42E+04
ton.of 6.38 percent ash Northwest coal. All other
output will be sold (8031).
8059 Land impact for the Lurgi Conversion process consists Of
.,fixed.facilities and evaporation pond since ash will be
shipped back to the mine (see footnote 8058). For a
Lurgi plant having an input of 3.03E+13 Btu/yr of
12,927 Btu/lb Northwest coal, land impact is 50.4
acres. For a 1.OOE+12 Btuinput land impact is
1.66E+00 acres (8012,II-A-I).
8060 The efficiency of the Lurgi fuel gas process is 75.8.
percent based on an input of,3.03E+13 Btu/yr and*an
output of 2.30E+13 Btu/yr (8012,II-A-I).
8061 Ancillary energy demand for the Lurgi'Conversioh
process consists of power requirements for fuel gas
production, fuel gas cooling, and fuel gas treating.,
Total requirement for 3.03E+13 Btu/yr input .(see
footnote 8060) is 9400 KWH/H. For a 1.OOE+12 Btu
input total ancillary energy is 9.27E+09 Btu (8012,
111-29
�
FTN. 8062-8068
8062 -Ancillary energy demand consists of 2590 KWH/H for
steam generation (8012,II-D-5)plus,power required
for air compression. From '(8012,Area 23) 20.6 per-
cent,of total plant energy-demand for air compression
(5150 KWH/H) is.associated with the electric genera-
tion process. Total ancillary ':energy is 3650 KWH/H.
For an input of 2.30E4q+13 Btu/yr the power requirement
is 1.09E+10 Btu/yr. For a l.'OOE+12 Btu input, total
ancillary energy is4.74E8q+08 Btu.'
8063 Land impact for, the Kopper-Totzek Conversion process
consists of land required for the combustors,clarifiers,
sulfur removal plant,water cooling and coal drying..Ash
is to be returned, to the.mine.For a 10.00 MW plant 11
acres are required--q(8,2q023).For a 10 '00-MW plant, a coal
feed of 5.472qE8q+07 tons/yr is required,-considering a
74.4 percent-conversion.and 40,O.percent.generation
efficiency us ,img-a,Northwest,coalqat 9.226-.-.Btu/l6qb.
.For a q1.qOqO0qE4q+12--Btu input,land impact is 1,.,OqOE8q+12 Btu qx
11 acres/1.0,E8q+14 Btu/yr input.-= 1..064qE-01 acre-yr/
l-.qO-qOE2q+1q2 Btu q18023).
8064 Ef f iciency for the- Koppers.0qa.0q0tqzek Conversion process
is 74. 4 p0qqrqqq@8q@qnt-. based on a.: coal input..rof, 92q226 Btu and
gas output-of--6:q8q63.: Btu. (82qD+23).
6q&065 Efficiency'[email protected]@-s-Tot-zek Combined Cycle,Power
Generation Activity is:. 4-0.0 percent based on
calcuations from (8034,,10q). This assumes a 90 percent
loadfactor and. the... sqy0qqtlem'from q(;8034,,10q).
-8066 From (8034,10), and. as.qa6quming a .90-2qpercent load factor,
it takes 8500 Btu input-to generatel...qOqO'4qKWH.
Efficiency 3413/88q500 = 4.:0lE'-qOl*
8067 Efficiency for 0qthe Koppers-Totzqek Conversion process
using Northern Appalachian coal.is 8,2 .O-percent for
a coal input of 12,-696 Btu-andl".output of 10,407.Btu
(8023).
068 Solids generated during the Koppers-Totzek process
using, Northern Appalachian,.coal consist of 0.1372 l32qb
as48qh/8qlb coal input (8023). For08qan input of 9.12E08q+13 Btu/
yr, 4.93E08q+05 tons of ash a00qre produced. Solid waste
is 5q.41E04q+03 tons ash/lq.2qO4qOE04q+12 Btu input.
111q-30
�
�
FTN. 8069-8075
8069 Land impact for the Koppers-Totzek Conversion process
for a 1000 MW plant is 10 acres. For a yearly input of
9.12E2q+13 Btu of coal and a . converion and generating
efficiency.of 82 percent and 40 percent respectively,
on a.q0q0E2q+1q2 Btu basis land impact is qJ.qJ'qOE-01 acre-
years. Land required for ash storage.i0qs 3.86+00 acre
for an input of 9.12E2q+13 Btu/yr of 12,696 Btu/lb coal.
For an input of.1.q0q0E8q+12 Btu time averaged 25.years,
land impact is 3.98E8q+0q6 acre-years/l.qOqO4qE8q+12 Btu (8023).
This assumes a pile height o2p1p feet, ash ensity
of O.02 tons/cf and that 0.1372 lb ash/lb coal is
generated. See footnote 8068.
8070 Solid waste for the Koppek-Totzek Conversion process
is 3.46E2q+04 ton/l..OOE2q+12,Btu*input based on a0qn input
of 1.01E8q+14.Btu/yr. and. a coal heating value of
.9226 Btu/lb coal. Ash generation is.0638 lb/lb
coal input (8023qY .
8071 Solid waste for BOM-Pressurized conversion process
is 3.46E4q+03 ton based on an ash content of 6.38
percent and coal feed of 6.50E8q+06 ton/yr and an input
of 1.20E8q+14 Btu/yr (8016). On a 1.qOqOE8q+12 Btu basis
this is 3.46E4q+0q3q@ tons.'
8072 For an input*of 1.20E8q+14 Btu to serve a 1000 8qMW plant
50.4 acres are.required. For 1.qOqO8qE8q+12 Btu inputba2qsis
this is 4.17E-01 acres '(8012).solid waste will be
returned to the inhence incremental land impact is
zero.
8073 Solid waste-for the ATC Conversion process is qO.qOqOE8q+00
ton. All slag and iron can be sold (8029).
8075- The onlyair emission from th e Lurgi Conversion
processis from the sulfur recovery process (8031,.
111-12-2). 94.0 percent of the@H2S in the combustor
gas is re0qm0qovedby the contacters' of.the.Stretford
process(8031, 111-22-1). The absorber then removes
994qA percent@of the H2S, the offgas from the absorber
is f lared.q'Based on. a -combustor gas of 0. 0051 S/lb
coal to the combustor.and a feed 36qof 5.42E12q+04 ton' of coal
to'the combustor, sulfur released,equals 1.66 tons/1012
Btu input, or 3.32q'32 tons SO./2ql2qo0ql2 Btu.
�
�
FTN. 8076-8082
8006 Air emissions from.generation.of electricity
utilizing the-ATC,process::depends,on the gas
composition [email protected] lbf-N0qortheqrn
Appaiachia,,coal will producea gas with the following
composition (8029):
1.6533 lb,CO
0.050-q5 lb H2-
0.8559 lb 02
0.0128-1b C02
3.2045 lb N2
44.00 PPM H2S:q:-
Upon combustion in a boiler:system fired-at 110,qOF--
1200F:and,assumqa.ngearly complete combustion;j,,the,only
pollutants emitted-are-as follows - 22.5-pp@--0qN4qOx(8025)
and 22.0 ppm'qsox-q(8015,q29).-For a 1.q6q02qM2qBtu@'-,input.of
gas.q(5.35EqO4,ton)@ the..emissions.-are 1.11E0q0q0-ton NO0qX
and 1.08 ton SOX..
8027 Land impact Is,1.21 acres,for-the 0qKQpp4qqr-Totzek
conversion: process usqk0qn2q%,[email protected], Central-' coal. For: an input
of .9 23E8q+13@ Btu and-ll acres,, fix4qe2q&,lan8qd impact is
1.096qi-qOql acres.q@--For a coal- feed of9.2.q3E8q+13 Btu/yrq*
1.1338E2q+04 Btu/lb = 4.07E8q+06 ton/yr, 7.78E8q+05 tons
.of aqsh ar0qd produced..@.(8023). Based on.a '30 footle
and:-8qan ash densqit6qy0qof 0.02 t/cf the.ash.,.all of which
is stored,will require,,-12..qO,acre-y-0qr/l.qOqOE2q+12 Btu.
Total land impact is 1.21E2q+0,q1- acres.
8027 For an'input of 9.23E8q+13 Btu/yr and 11,338-Btu/lb
coaqlqi7.78E2q+05 tons-ash/yr is produced.,base d on an ash
content of 19.1 percent-(8023q)..'For 1.qOqOE2q+12 Btu
equivalent'feed, solid waste-is-8.43E2q+03-tons.
8079 Efficiency for the BOM-Pressurized conversion system.
is.73.percent based,-on a coalinput of 12,050 Btu/lb
and A gas output of 8796 Btu/lb'(8016).
8080q- Efficiency-of theq,q.B24qO20qMq-Pressurized conversion@process
92qJs 73.4 percent-based-on a coa60qlqfinput-of 13,800 Btu/lb
and 28q& gas output.ofq@10,133 Btu/lb (8016). q-
8081 Efficiency of the.BOMq-pressurized conversion process
is 73.3 percent based on an input of-9226 Btu/lb and
a gas output of - Btu/lbq. (80q.16q,0q)q.q-.
III-32
�
FTN. 8082-8087
8082 Air "emissions from generation of electricity utilizing
the ATC process depends upon the gas composition.being
fired. 1.0 l6qb of 1.0 percent moisture Central coal will
produce'a gas with the following composition (80-q29):
1.4651 lb CO-
. 0451 -lb H2
'0.0012 lb C02
2.8162 lb@ N2
0.7529 l6qb 02
44.00 PPM H2S
Upon combustion in aboiler system fired,at 110qOF-120qOF
and assuming nearly complete combustion, the emission
will be as follows - 22.5 PPM NOqX (8025) and 22.0 PPM
SOX (8015,29).For a 1qOqOE12 Btu input of gas.q(5.44EqO4
to8qn), the emissions are 1.12EqOqO ton N4qOx and 1.10 ton
qS4qoqx.
8083 Efficiency for the BOM-ATM conversion process is 78.3.
percent based on a coal input of 12,050 Btu/lb and gas
and t8qar output of 9.441 Btu/lb (8016).
8084 Efficiency for..the BOM-ATM conversion process is.7 8.5
percent based on 0qA'c4qoal inpuut of 13,q800 Btu/lb and gas
and tar output of'14q0,q932 Btu/lb (8016)
8085 Efficiency 6qof the BOM-ATM conversion process of q13.3
percent based on a coal input of 9226 Btu/lb and gas and.
tar output of 6758 Btu/lb (8016).
8086 Ancillary energy for the ATC conversion process is
3.59E2q+09 Btu, based on 'a 2MW consumption for a 1000 MW
plaint, and. a total process efficiency of'29 percent
(8q029). For a 1.qOqOE8q+12 Btu input,ancillary energy is
3.59E4q+09 Btu.
8087 Dust loading on'the cleaned gas from the Koppers-Totzek
process is approximately qP.0020 grains/SCF.(8024,7). 1.0
ton of Central.coal, North Appalachian coal or Northwestern
coal will produce,q5'.95EqO4 SCF (8024,14), 6.64EqO4 SCF,-
(8024,q,140q) and 4.38E2qO4 SCF (8023) of gas respectively.
Based on the above particulate emission for electrical
generation based on 1q.6qO6qOE12 Btu of gas input i00qs'08qas
follows, in tons:
Central Coal Northern Appalachian Northwest Coal
4.62E-01 5q'. 0324qE-01 4.56E-01
111-33
�
�
FTN. 8088-8092
8088 -Ancillary-energy-for theKopper-Totzek.conversion
process is based-on 15MW for a1000 MW plant (8029).
For the Central, Northern,Appalachia, and Northwest
coals,-the total-procqess:efficiency is32 percent,
32.8 percent, and 29.8,percent Based on this the
ancillary energy on a 1.00E+12 Btu basis is 4.81, 4.92,
and 4,48E4q+09-Btu respectively.
8089 Ancillary energy'for the boiler generation cycle is
3.37E 09Btu based, footnote 8062. Energy.required
for steam and power generation is 2590 KW (8-012,II-D-5)
for an input of 2,30E8q+13 Btu. No air-compression is
required. On al.06E8q+12+Btu basis.ancillary enercqjy is
3.37E8q+09 Btu.
8090 Potential.so6qu0qrce4qs of water effluent f2qr0qom-the._4qKop0qpers-
Totzek process-0qare-boiler b2qlo0qWdown, raw:gas cooling
system 4qandverfil2q1of clarifier. For a 1.6q4q08qE12 Btu
input of coal 1.33E8q+06 gallon of boiler2qlowdownqwill
be-'2qpr0q6duced.con 'taining+40.0 PPM'suspende'd solids,
maximum of 3.0.0.'4qM8qG/4qL.'B8qOD,0qand 25.0 MG/L COD. This4qwate'r
will be,cooled to.852p00F-_and routed-to-clarifier.'
Water,from qrmqa0qw.gas cooling will followhe-same route.
The clarifier will-.require an-8qadditqiio2qna'l 80.0 gal/
minute in mak6qeup..water because of evaporation losses
in quenching of.ash from gasifier. The clarifier will
contaqin.approximately 2q250 PPM of@total dissolved
solids. From the clarifier,.the water will be filtered-,
and treated, then rec2qyced-Effluent- 0.00.
8091 Capital cost-6f a.combined cycle gas-fi0qred.power plant
-is 4.15E8q+07.dqoqlqlars for a 363-MW plant-(8020,16). Plant
efficiency is 40 percent. With a fixed,charge rate of
10 percent, the.annualized capital cost qi's-1.53E4q+05 dollars/
1.qq0E0q+12 Btu in. Assumes a.100 percent plant load factor.
This cost does not include@-the cost of'.the equipment to
produce the low Btu.fuel gas.
8092 Capital cost.for the ATC coal conversion process only
associatedqwith a 1000 MW plant is 1.80E0q+07 dollars (8022).
Based on a 1-00E04q+12 Btu.basis.and.plant efficiencies of
78q*.81 73.6, and 81.0 for the Central, Northern Appalachia,
and Northwest coals theqrcapital cost are 4.70, 4.40,
and 4.88E00q+04 dollars respectively, (annualizedq'with a
10 percent fixed cbarge-rate). -Assumes a 100 percent
plant load factor.
III-34
�
�
8093 Capital cdtt for the BOM-Atmospheiic process is
1.08E+07 dollars for a 150 ton/hour plant (8020).
Based on a 1.OOE+12 Btu input (see footnotes 8042-
8044 for equivalent tons of coal) and 8760 hr/yr for
the Central, Northetn Appalachia,.and Northwest coals,
the capital cost are'3.43, 3.13, and 4.68E-@04 dollars
respectively (annualized,with a 10 percent,fixed charge
rate).
8094. Capital cost for the BOM-Pressurized conversion
activity is 2.59EO7 dollars for a, 150 ton/hour plant
(8026). Based on a 1.OOE+12 Btu input (,see,footnote
8039-8041 for equivalent tons of coal) and 8760 hr/yr
for Central, North Appalachia, and Northwest coals,
for capital costa are 8.23E04, 7.48EO4, and 1.12E+05
dollars respectively (annualized with a 10 perce.nt,
fixed charge rate).
81095 Capital c 'ost for the Koppers-Totzek conversion process
is 8.6E+07 dollars for a 1.40E11 Btu,out/day plant
(8024). Based on a 1.00E12 Btu in basis, 365 d/yr,.
and plant efficiencies of 81.1, 82.0, and 74.4 percent
for Central, Northern Appalachia, and.Northwest coals
the costs are 1.36, 1.36, and 1.25EO5 respectively
(annualized with a 10 percent fixed charge rate).
8096 Capital cost for-the Lurgi conversion process only
associated with a 333 M plant is 1.65E.07 dollars
(8020,16). Based on a total plant efficiency of 30.3
percent'and on a 1.OOE12 Btu basisIthe capital cost is
5.02EO4 dollars (annualized with a 10 percent fixed I
charge rate). Assumes a 100 percent plant load factor.
8097 Operating cost for the BOM-Pressurized,system is based
on a cost of 4.3E+06 dollars/yr for-a 150 tofi/hr plant
(8760 hr/yr) (80'10). For a 1.OOE12 Btu input and coal
heating value of 12,050,'.13,800, and 9,226 Btu/lb for
the Central, Northern Appalachia,.and Northwestern coal
the annual operating costs are 1.35, 1.1.9, and 1.78EO5
dollars!respectively. Coal cost not included.
8098 Operating cost for the BOM-Atmospheric system is 1.85E+
06 dollars/yr for a 150 ton/hour plant (8760 hr/yr) @.
(8010). AS in footnote 8097 operating cost are 5.77,
5.05, and 7.58E04for the Central, North Appalachia, and-
Northwest coals respectively.
111-35
�
FTN. 8099-8102
8099 operating cost,for the.urgi Fuel Gas Production system
is based on 196qA,percent of the total plant-input (8012).
For a feed for,gas production of 207'.8.tons/h4qo6qur (8760
hr/yr) of Northwestern coal, operating costs are 4.83EqO6
$/yr. On a 1.qOqOE12.B'tu input operating costs are 1.44EqO5
dollars. Coal cost not included.
8100 NO, 'emissions for a combined cycle will primarily
come from the,,-gas fire& turbine.. From 430.28 10), a
dry turbine system will amit 150 ppm (vol)@when
fired at 2000F using,natural gas. From tests performed,
low Btu gas.,will emit only 15 ppm 'q(vol) q0q3028 11).
Based on-this, how1pqqh is.emitted depends.upon-the
amount of flue gas produced. The amount of g6q4s
produced,by process and coal.,type is,as follows -
BOM Press. --Northwest 3.36E1q0 scf/1.00l,q2 Btu
BOM Press. North. Appl. 1.06q410-scf/1.00+12 Btu
BOMPress. Central 3.19E1q0 scf/l.qO2p12 Btu
Koppers-Totzek.- Northwest 1.61E1q0 s0qcf/1.q0q0E12 Btu.
Koppers-Totzek North. Appl. 2.274qE2ql0,-s.qcf/l.q0q0El.q2 Btu
Koppers-Totzek Central.2'.179E2qIqO-qacqf8q/l.qOqOE12,Btu
From the above,-the emissions are qasf0qoqlqlqoqws
BOM Press. Northwest 3.24EO1ton
BOM Press. -North Appl. 1.03EqO1".ton
BOM Press. - Central 3.9AEq02q1ton
K-Tl - Northwest 1.59-EqO1 ton
K-T North. Appl. 1.96EqO1 ton
K-T Central 2.37EqO1..ton
8101 Effluent from the Lurgi process will4qb8qe nill. All
water will be recycled where applicable andhe rest
will go to evaporation ponds (8031).
8102 Sources of air emission from the Koppers-Totzek
conversion process, using Northwestern coal, are
the,coal fired thermal dryer-and the Claus plant.
In thermal.drying, 1.31EqO3 to0qn.is.consumed in'drying,
see,footnote 8000. The.emissions are as follows
4qIs'ee footnote 8053): 5.42E2q02q0-q.ton particulate, 5.15 ton
of 64qN24qO12qXq, 4.28E-01 ton of S28qOXq.j, 5.50q-ton of hydrocarbon,
and 3q.71E8qO8qO ton of CO.
III-36q36_
�
�
FTN..* 8103-8107
Air emission from the Claus plant depends upon the
amount of sulfur in the gas,feed to the plant. 1.0
lb of Northwestern coal will produce 4..80E-02 lb of
H Of this 90.0 percent is removed in the Rpctisol
2S-
unit yielding a feed of 4.32E-02 lb*t.o the Claus. The
Claus with Stretford tail gas clean up will v6nt
4.'32-04 ton Sox/ton of coal fed to gasifier-4-3,0E04
ton of coal/l. OE12 Btu is fed to ga.sifier.,' therefore
Sox = 1.76EO1 ton.
8103 Assuming that a low temperature boiler is used, NOX
25,0 ppm (see footnote.8003). The BOM Atmospheric
Pr@cess using, Central, Northern Appalachia, and
14orthwestern coal will produce 4-44 lb/,lb coal.. 4.96'
lb/lb coal and 4.08 lb/lb respectively. These gases
have a heating value of 8.97EO3 Btu,,8.96EO3'Btu, and
6.04EO3 Btu. Ihputing 1.00+12 Btu of..these,gases-to
the boiler, will produce@Nox emissions as follows:
Central Northern Appalachia Northwestern
5.69EOO ton 6.36EOO ton 7.76.EOO ton.
8104 Air pollutants for the National Average low Btu coal
gasification activity are the arithmetic average
of the process utilizing a Central, Northern
Appalachia,,and-Northwest..coal. For calculations see
individual process and footnote.
8105 Air pollutants from the electrical.generation activity.
using low Btu fuel gas are the arithmetic average of
the process utilizing a Central, Northern Appalachian,
and Northwest coal. For calculations see individual
regional coals.
8106 Land impact, for low Btu gasification and electrical
generation is the arithemetic mean of'the individual
processes utilizing Central, Northern Appalachian,
and Northwest coal. For calculations see individual
coal regions.
8107 Solid waste for coal gasification is the arithmetic
mean of the individual processes utilizing uentral,
Rorthern Appalachian, and Northwest,coals..For
calculations see individual coal regions.
111-37
�
FTN 8108-8112,
8108 Ancillary energly.for the,-low, Btu gasification- processes
is-the. arithemetic,mean: ofqf-.@ the-proce6qsses, utilizing
Cent-ral,'Northern Appalachian and-Central coals. For
calculations. see individual: regions
8109 Primary efficency@ for, the - lowp Btu gas if ication
processes is, the arithemetic mean, of. the processes-
utilizing'CentraLNorthern Appalachian, and
Northwestern coal For calculations.see individual
regions.
8110 cost, for. the,gasification and : electrical ...generation
activities.the arithmetic mean.of,the..processes
utilizing-Central Northern Appalachian,and Northwest
coals.For calculations..,. see .;;individual regions.....
B1ll -sox! emisions f rom the . -Koppers Totzek w e lectrical
generation . process. utilizigi-Northwestern coal occurs-
in the,boiler step. Assuming complete combustion
of,_the H2S,-andCOS en0qterin6 the.system:@6q10 percent x
-is
-emitted-,-, See,
2.59E4q+02 =,2.@59E6q+01:@to0qns,',ofS8qO',
0qX'j
footnote., 8053,,i*..
q8112. From.i,footnotes2'900q7,' and.,.3 9 0 5, the-,@totalq-2pnual i zed
capital. cost-. for -a controlled:,gas@, f ire2q&,..,power- plant.
is2.35EqO5'$/l,.qOE12,Btu-in,.-,[email protected],.for:a-.60P load.
factor.. For,[email protected]&qCqrtor,:@;the.-,@@annualized capital.
investment- is 1. 41EqO-6q5 .$/l.q0El22pppu-,-..in,,@ This-. cost does
not,,include.the2ppst.oqf.the,,,,,,equipment .produce the
lowt6qBtu fuel .gas
III-;38
�
�
IV. HIGA BTU GASIFICATION OF COAL
A. Introduction-.
The enviro nmental impacts, efficiencies, and costs
associated with the production of high Btu (greater than
9
900 Btu/SCF) synthetic natural gas from coal are given in
Table 2 of this report. Each data entry is based on''an energy
input of coal equivalent to 1012Btu/yr. 'The specific coal
utilized and its energy equivalent is contained in the first
footnote for-each of the regional and national'cases. All
table entries have been derived for a-"controlled". environmen-
tal condition. The nature and magnitude of coalgasification
operations is such that stringent environmental control must
be practiced.
The six processes @;hichcomprise the@High Btu,
Gasification Activity are:
1. Lurgi Process
2. Hygas-Electrothermal Process
3. Hygas-Steam Oxygen Process
4. Biga.s.Pr6cess
5. Syhthane Process
6. CO2 Acceptor.Process
Also included is a Typical New Process which represents
conceptually 'a combination ofthe best features of the new
generation.#' processes.-- Hygas, Bigas, and Synthane'. The-C02
Acceptor Process was not included in this averagqrsince its
process operation is quite different from the rest..
IImpacts were developed for three regional Icoals, with a
National Average case synthesized from the regional data. The
Lurgi Process is limited to weakly caking bituminous coals and
was,,therefore,not considered in the Northern Appalachia region'
where-many of the coals exhibit strong caking propertiesi The
C02 Acceptor Process, on the other hand, operates primarily oil
a lignite coal and was, therefore, only consideredin the
Northwest region with a lignite feed. A principal advantage of
the "'new generation" processes is their ability to handle the,
range of coals from bituminous to lignite. All of the cost data.
shown in Table 2 is based on a 90 percent plant load factor, or
.328 operating days/yr. The values, presented in this table are,
based on'data accumulated during the Fall of 1973.
IV'l
�
The following is a brief aescription.of the individual
processes:
Lurgi Process
The Lurgi Process .(Figure 14) utilizes a high pressure (300,-
00 PSIG), fixed-bed, nonslaggingf steam-oxygen gasifier to
produce a synthesis gas stream from coal,. The coal enters
through a lock hopper.system-at the top 'of the gasifier,
reacts with the steam and oxygen.as it moves downward on a
revolving grate and leaves.as,ash for disposal through the
ash lock hoppers. The synthesis gas stream leaves the
gasifier at a temperture of 1100 F and is subsequently'cooled
And scrubbed of tars and oils.., The gas stream composition is
then adjusted in the shift conversion step, scrubbed of its
acidic gases (4qC0qO* and H S), ana-methanated. The-Luqr8qgi Process
2 2
is'currently the only commercially available SNG.system.
2. Hygas-Electrothermal.Process
The Hyga-s Process 4-Figure 15) features hydrogasi-ficat4qion' in two
countercurrent stages for the,production of,synthesis gas2qfrom
coal. The coal is pretreated (if-required), slurrdqed.with an
aromatic oil and.pressurized PSIG).for introduction
into the gasification reactor. As the-0qcoal enters the reactor,
the slurry oil is qvapiqori,zed and.the coal falls thr.ough a
low-temperature reaction zone where methane is produced
primarily from the coal volatile matter. The devolatized coal
then passes into the high-temperature zone where it is
hydrogas ied by react-ion with hydrogen,and.steam-to form
additional methane.. The emaining coal or char containing
significant amounts of unreacted carbon is used to generate the
hydrogen-rich gas required in the hydrogasificati8qon6qprocess.
In the Electrothermal Process, the char.is react4ed with steam
to produce this hydrogen-rich gas with,electric resistance
heating supplying the energy.needed to,sustain the.reactions.
The residual char is then used in plant boilersfor the
production of steam and elecicity. The synthesis gas
leaving the hyrogasifier is cooled, it ,compositionadjusted,
and scrubbed free of acidic gases. The gas.is then methanated
TheHygqasProcess.is currently
to'produce pip4qeline*quality gas.
the most advanced of the "new generation" processes with a
successful pilot plant in operation since the end,of 1972.
IV- 2
�
�
COAL LOC K
HOPPER 'CRUDE GAS GAS
SHIFT COOLING -------- 4WTAR 81 OILS
CONVERSION
STEAM
RAW
L' OAS
GAS, H S TO RECOVERY
METHANE 2
PURIFICATION
STEAM GASIFIERS
SYNTHESIS
14
@REFRIGERATI04--a-CO, TO V,ENT
OXYGEN L----------------------i
SH
PRO(WT GAS
LOCK- COMPRESSION m-SYNTHETI
C PIPELINE GAS
HOPPER
DEHYDRATION
'ASH
Figure 14. Lurgi Process of High Btu Coal
Gasification (Ref. 8310)
L
@GASIFIE7RS
�
RAW GAS'
COAL STEA
HYDROGASIFIER, RAW:GAS SHIFT
CHAR- -QUENCH CONVER!s"
INERT SiEft ELECTROGASIFIE-
FINES GAS
H2-RICH
PRE-
GAS
TREATMENT WATER
OIL TO.
FUEL AIR CHAR- RESIDUE STABILIZATION STEAM
-GAS ELECTRIC
TO POWER
POWER PLANT
;.CHAR
Ab
A _71
SLURRY
METHANOL
MAKEUP
RECYCLED@'. METHANATION
NH
SCRUB a
SYSTEM
T@ R
DRYING GLLA SCRUB
RD BEDS
_j
-H NH3 TO
COp IC
PIPELINE H@S INERT GAS REbOVERY
GAS "TO 7D.',PRE-
TREATMENT
RECOVERY
Figure 15. Hy�as Electrotherm'al Process-of High Btu
Coal.Gasification (Ref. 8308)
'@IF I E @F@ r @W G @AS
E @ELE
PC
M2
�
3. Hygas-Steam Oxygen Pro cess
This process differs from the Hygas-Electrothermal
Process only in the manner in which the hydrogen-rich gas is
generated for the hydrogasifi.er section (see Figure 16). In
the Steam Oxygen Process the char is fluidized in an oxygen-
steam mixture and the heat required for the s team-char reaction
is supplied by partial combustion of thd.char. The residual char
is then used as boiler fuel.
4. Bigas Process
The Bigas Process' (Figure 17) utilizes a two-stage, super-
pressure (1000-1500 PSI), entrained bed, oxygen blown-gasifier for the
gasification of coal. The coal is pulverized and fed into the
top section of the @wo-stage gasifier where i It is contacted
by a rising s team of hot synthesis gas,produced in the lower
section. The coal is partially converted into a'gaseous mixture
in this section and is entrained in the gas stream and removed
from the.gasifier. The gas and char are separted and the char
returned to the lower, stage 1, section ofthe gasifier. 'Here
the char is completely gasified under slagging conditions with
oxygen and steam to produce the synthesis gas stream for stage
product gas is subsequently upgraded to pipeline
quality gas.
5. Synthane Process
In this process pretreatment of caking coals and gasifica-
tion are accomplished in one reactor (see Figure 18). The coal is fed
into the gasifier through lock hoppers and reacted with steam
and oxygen under pressure (40-70 ATM) in a-two zone fluidized
bed system. -A char residue is discharged from the,gasifier
and subsequently used as boiler fuel. The synthesis gas is
.adjusted, cleaned, arfd methanated to produce pipeline quality
gas..
IV-5
�
RAW GAS
COAL
R4WGAS SH;IFT
GASIFIER QUENCH CONVERSK)N
INERT
LINES -"GAS-
PkE- 7r
TREATMENT IATER
EL
)E 02 a OIL TO STEAM
TO . -ATION
STEAM ST LIZ
HAR POIWER PLANT
SLURRY
-MAKEUP METHANOL
-D, METHANATION
-RECYCLE
-SCR W-A N-H-
U01,1TOIL SYSTEM
SULFUR SC
DRYING . 1. . RUB
GUARD BEDS -
H2S TO NH3 TO
PIPELINE
OAS -RECOVERY RECOVERY
Figure 1@. kygas Steam-Oxygeh Process of Mh
Btu 'Coal Gasification (Reif.,8308
'[MEtHtNi
�
C AL
CYCLONE RAW GAS SAND
FILTERS
COAL
'PREPARA- GAS
TION
SHIFT
STEAM CONVERSION.
REFUSE POWDERED
COAL
S
COAL TO STAGE 2 CHAR
GASIFICATION
BOILERS ACID GAS COO
REMOVAL
'HOT SYN-
THESIS GAS SULFUR w-SULFUR
R
STEAM,, SULFUR-FREE
STAGE I
S
GASIFICATION pp
STEAM
METHANATION
a-PIPELINE
DRYING GAS
SLAG TO
DISPOSAL
\/@pco
T7^
R_'2R
Er
Figure 17. Bigas Process of High Btu Coal
Gasifi.cation (Ref. 8305)
�
ACID GAS TC
SULFUR
REM0AL
COAL CYCLONE ACID GAS
SCFW8fR SHIFT ABSORBER/.
STEAM GASIFIER - I- 1-11- -- @.@
CONVERILK. REGENERA.
OXYGE
DECANTER TAR STEAM STEAM.
CHAR CHAR
TO POWERPLANT
00
CHAR IRON
PRODUCT GAS MFTHANATOR TOWER OXIDE
Figure 18. Syntha'ne Process of High.Btu Coal
Gasification (Ref. 8309)
@
-U
SRU@40'4
GAS
�
6. C'02 Acceptor Process
The C02 Acceptor Process (Figure 19) operates only on
lignite and subbituminous coals and employs a unique c@rculating
system of-dolomite to provide process heat and synthesis
gas cleanup. Dried lignite enters the devolatilizer
togetherwith,calcined dolomite from the regenerator, steam,-
and hydrogen-rich gas from the gasifier.' The' lignite is
devolatilized and methane produced from the volatile matter.
with,heat-of reaction supplied by the CaO + C02 reaction..
The raw gas stream leaving the devolatilizer is upgraded to
SNG. The*lignite char is transferred to the,gasifier along
with dolomite to complete the gasification operation. The
remaining lignite char i*s thentransferred to the dolomite
regenerator alidiused as,fuel for calcining the spent'dolomite
from the devolat@lizer and gasifier.
IV_9
�
GAS
COOLING ---SYNTHETIC NATURAL GAS
--a-WETHANATION
-CLEANUP
GAS
TO RECYCLE
COOLING
S,VENT
CLEANUP
GAS'
COOLING ___40
a
-EANUP
CL
REGE NER A
T
H., 0 0-
(=RUSHED1
OLO.-
DRIED, M ITE-
GASIFIER
DEVOLA-
HEATED
P TILIZER
L7G N
A I
SPENT WT
SK
SPENT CHAR
DOLOMITE
LIGNITE INERT.
IN RT GAS
CHAR@ GAS.
STEAM a
RECYCLE GAS
STEAMS
RECYCLE GAS
Figure 19. CO Acceptor Process.of High,Btu Coal Gasification (Ref. 8321),
2
�
B. I;npact Data Table and Footnotes
IV-11
�
JTh "i
CONTROLLED 4 5 6 a 9 10 11 12 13 14 15 Is 17 18 19 20 21 22 23 24 25 26 27 26 29 30
F LIE L REGION
COAL AS INDICATED WATER POLLUTANTS (TONS/ 10" STU, EX. COL.12) AIR POLLUTANTS (TONS/10"' BTU) OCCUIOATIONAL HEALTH POTENTIAL COST (DOLLARS/IOP STU)
MNE - DISSOLVED SOLIDS SUSPENDED TOTAL THERMAL PARTIC- HYDRO- ALDEHYDES SOLIDS LAND LARGE, PRIMARY ANCILLARY
R (TA mm ACTIVITY PROCESS ACIDS BASES NO, OTHER TOTAL(DS) SOLIDS ORO IANICS Cous S'?'8 SOD coo [STU/IdtBTQ ULATES NOX sox CARBONS CO ETC. TOTAL TONS/ (ACRE-YR DEATHS JINJURIES MAN-DAYS SCALE EFFICIENCY ENERGY FIXED ATING TOTAL ROW
P04 O'&BTU \Iola BTU). '0. STU 70.-iTU LOST'@Io"OTU DISASTER (BTU/10,10m, COST COST COST
NORTHERN APPALAC 1A
2GASHII CASIFICATION-HiGN BTu 2
3
-1.11 -P.-W PROCESS om -9 0999 Q. D0100 29427 9.610D 48- 7.62101 4$418 2. -01 4841. 1.16-0 4 6418 4.02-00 4 8418 3.99-ol 4 $418 1.11-02 4 C 1-1 .411 019 201 5.97-01 2 .417 0.0- 28417 1.7-1 1 1111 -.0 3 -6 2.62.05 3 3
4__L HYGAS-CTROTHER.AL -1 .1111 099 o", .19, -9 o999 -1 .11, Q999 0. -00 26427 1.401DI 48402 q.o.01 48402 2.33-GI 48402 1.27- 48402 4.61-GO 4 8402 3.94-01 4 84D7 1.34-D2 4 - -01 -- .4. -1 .99, 2091 S.72- 2 "DI 10.0- 28401 1.88105 3 .423 B.- 3 8423 2.1-5 3 4
5HyGsi HYCA5-ST-O@CEN -1 00 o9l' o- -1 -9 osq, o999 0999 0. O@00 28427 3-00 4$406 6.01101 $401 -3- 4-1 7,93-01 4eADs 2.92+00 1 8406. 3.63-01 8.IS+Gl 4 6.5- 2040712.5@-! !@2 .1.1 .11, 2091 5.07-01 2 8405 0. 00.002$405 1.59,05 3 8424 7.55-M 3 BQ412.35105 3 5
BIQ@S ..GAS o999 M, .19, -9 o'91 .99, .11, .11, 0999 0.0-D 28427 3.66100 4a414 5,44+01 48414 1. 7-1 18414 9.07-01 48414 3.02-OD 4 8414 T-0 . .414 rl -.1 --1 D6'o -1 099 2091 6.54-01 1 8413 0-00 28413 1-- 3 8422 1.15.05 3 1422 3 6
7 o999 -1 -1 .11, -9 .11. o999 0- 0.0010D 28427 1.5-1 4B41Q 9.9-1 48411 1.87+01 4841G 1.67-00 4800 --0 . 141. 4.30-DI 4 0410 1 I.Q.02 4 6. -03 2-1 2.461003 8412 .11, -9 2091 5.3-1 2 71
2-ol- ..- 2- 1. -S 2S 23-
9 CENTRAL 9
10 @SHI GASIFICATION-IUCH a- 10
I ILLRGI LLRGI o", ns.1 .19 o- -111 4.31-0 1 B471 9.00-01 5 847t 14.26-01 5 .471 4.44,01 5 -1 0- 1--, 4946. 3w63401 4 Bq68 1 4 12+00 48468 4.07-00 4 846. 4,48-0 .41. 1. 11- 5.27.03 28469 2.43.00 3 8470 L19-1 a999 -1 -1 5.41-0 28467 0.0@N2@67 1-05 3B4621 8.11.0 38462 2.1-S 1
12 __. -@L NEW MOCE55 -1 .9" ogg, -1 .199 3-- 5 8476 1.02-01 S $476 ..90-02 5 .476 3.18,01 5 ogg 0999 O.DD+00 28483 4G473 8,53+01 4.473 6.61+01 4 B473 I.-OD 4.473 4. -00 4 8473 CA-1 .- 1.1 ... 5-03 2847 4 2. 7 7100 3 $41, o9l' 099 -1 -1 ..2-1 .4Z2 Om D@002147; 1.9-5 3.481 9. 0- 1841, 2-ol 3 12
13A- HycAs_EuGTR.1.E- o999 .11 o999 __ Q911 o919 o999 .11, o991 -1 _9 0999 0. -00 28483 1.31+01 48452 9.93-01 49452 6.61-01 4 84S2 I. QO+O. -2 5.07,00 4 -2 4.28-01 48452 1.88+02 4 5.24+03 28453 2.62-00 3 8- .91 .11, 2D91 6.22-01 2$451 0. -028451 2.11+*5 38478 8.78+04 39478 2+9-S 3 13
- 14
14 yc@ HYCAS-STEAMwOXYGE1 o999 .919 -1 091 o999 0- o- - OwO@OD 18483 6AIHOD 48156 608!+01 49456 6.2- 4 8456 8 95-01 4B456 -5- 4 84S6 3,94-01 49456 1.4 .3+02 4 1.25.0 20457 12.75+00 3 M8 .11, -1 2091 6A7@01 28455 -0-002M5 13-5 3$479 -0- 3B479 2-105 3- 15
15 Bt@s .'GAS o999 -1 P991 -9 - G999 .199 -9 O+OMD 26483 4.-00 4$464 6.2-1 .00 --1 4-8464 1.00+0 48464 3.35+00 4 6464 4-01 48464 1.54- 4 5,34+03 2.45513,Q5@003 .11, M9 .91 2091 C7@01 26463 0. -0029463 2.04+Q5 39477 1.14+05 38477 3.1-5 3
16 -T. SYNTHANE M, -1 -9 o919 OM M, 0999 0999 D.0-Q 29483 1.47+01 414LC_ 1 11+02 4846D 51!9+01 48460 1 A1,00 146D 6.21-00 846. 4.65-01 ..40 -6102 531- 28461 2. 67+00 3 .4 2 .11 .119 2091 15.8- 284$9 G. -002-9 1.75+05 384.0 8+37- 3BUD 2-S 3
17
to I ..EST
19 -E', I T.
20 LuM -0. -00 28375 D-0 2 8375 0. 0-D 28375 @.0@0 14375- 0.00+00 7 8375 0-+0 28375' 0.00+00 283n 0. -0 28375 0.00+00 2_____ M- 28 3 LS GmD@00 @ 837S 0-0 28393 2.05.00 4837, 7,5901 4 9372 4.172 -11DO 49372 4.27+OD 4 9372 2+92-01 4a372 9-1.1 4 3.73.03 2$373 3. 78+0G 3 0374 0999 0999 am 2091 6,05-DI 2937 11 0+ @O28371 2.36105 30391 1. 0-S 3B391 3.3.+05 3 20
21 _PN@ TYPI CAL N EW PROC ESS -0+00 20385 0.00- .1.1 0-00 28355 0+00100 28365 OA-0 2 8385 0. -0 11345 -- 21385 D.0-0 28385 0-00 2 0.0o'00 28385 0. 00. 00 2 8385 0AG-00 28393 8,13,00 48382 8 + 54.61 4 8382 q-o 4 8382 1.41.00 4-2 4.71+00 4 B3 .2 3.27-01 48382 1.09+02 4 3.73+D3 28183 3. 95+003 8394
- - o999 o'99 -1 --1 2@LBI_ 0.0-0283.1 -1 + "+G5 38390 3.35-N 36390 2.4- 3 21
22 HYGEL HYC@-ELECTROTHERMAL -0+00 28355 0. -00 2 .355 0. 0-0 2$355 0. -0D 28355 Ow-00 2 8355 O@ -00 28355 OA-6 18355 D.00+Do 28355 U. 0-0 2 0-D-D 29355 0-00 7 B355 0AD- 3393 1-01 483S2 1,- 024s352 7.14- 1.17+00 4.352 5,56-00 4 63$2 3w4l-ol 4M2 1.2S-02 4 3.7140 28353 3. 541GO3 83S4 o999 G999 .919 2091 5w 70-01 28351 0 w -0028351 1.7-S 3-7 7. -0 383.7 2.4-S 3 22
23 myGsT yGAS_sT"'wG'N 0+00 29360 0-02 $360 0. -00-0 -0-2-8360 0.00+00 2R36D 0.00.00 2 .360 0. 0- 1 D.00+00 28366 -0.-0-0+G0 2 .360 0. -DD 28393 -11DO 4835L 6m33*01 43357 5m9D+OO 48357 1.15+00 48357 3.80+00 4 8357 3.13-01 48357 8.S2+Dl 4 13.73-03 2835B 3. 75- 3 $351 .119 M 2091 S.8-1 28356 0-6 18356 1.43-OS 3M8 S. 96- 3a3BB 2.03'oS 23
2 4.-s BI-s G@00- 2$370 D.00+QO 7 9370 0.0-1 2 .370 -0- 2&376 0..- 2 8370 1 O@ -00 28370 0. -00 2837G 0. -00 2637D 0.00-00 2 -0+0 24370 -0,00 2 6370 0.00+00 2$393 3.4-0 4!367 5483+Q! 48367 1d41+01 4l367 --' 4-7 1- .... 4 -7 3.01-01 48367 -1- 4 3.-03 2S35S 4. 54, @O o999 .9.1 -1 2091 6 82-01 28366 0. - 20166 'w-ol 1 2.1-1 1 24
25SYNTH _SYNTHANE 0.00+00 23355 D.0-0 2 8365 D.00- @ -1 0.0- 4311 0.0-0 2 8- D-101 28365@ 0. 0-0 2.31S --@ 2.- ....0 1 -0- 28365 0.0-0 2 8365 0.-!@ 1.391 13-1 48362 4.362 9.63-0 1111 1 491+00 48362 6.37+OD 4 8362 3-01 4.362 -6-02 4 I.-W .3. 3-96+00 1 I'll .99 2- 1-0 M11 --0 28361 1.6-5 383.9 -1- 3-1 -1.0 1 25
PS c-.ci CO, ACCEPTOR -0+60 283BG 0.00.00 2 8380 0.00+GO 2 $38D 0.00+00 28380 0.0-0 2 9330 0. -00 21380 0-,00-00-2 "$G- G,00+QQ 283.0 0.00+00 2 ...... 0 838G 0.0-0 2 8- 2U0 3.3 -0 48377 3181+01 49377 -7+01 1177 .377 1m98+00 4 B377 437@01 48377 im0fi+02 4 C61+03 28378 3. 16+Do 3B319 .11. o999 2051 16.2 5-01 28376 0. -002.376 1.4-S 113W 1. IS+. 3 26
27 ?
28 NATIQNAL AVERAGE
29 CASHI GAS IFICATION -HIGH BTU 29
30 LLAGI LUR.' o"g o9s9i 0999 -1 -191 .--1 1 -1 --1 1 .111 111 1 2.2-1 5 .199 0999 0.0-0 28312 2..S+OG 4-8 7.51+01 4830a 2.12- .10 1.211.0 8308 4,17+00 4 0.1 3.7-1 4 -8 1.05+02 4 445D+G3 2IM 3 11-003 -0 o999 099 aggg 2091 5.73-01 2 83o
L7 O@ -0 2230 2.13+OS 33305 9.1- 383Q5 3. Q- 1 3 0
3 1T,P@ -CAL NEW -ss 0- -1 2. -'j I.A.- 5- 2-0 -1- -0 1.2-1 6330 -1.1 .3. 1.- 1- ..410 $31, 3wo-1 . 'M 112@@ 3. 2- 2.331 3, 3 1 + DD 3B332 #199 -1 I'll .1- 21319 177-05 1U. 3 1
3 2HYCEL HyGAS_EUCTROTHER@L 0999 o999 4999 -1 -1 o999 o999 o", .11. D999 0.0-0 28312 1.17+01 q8314 -6+01 q9314 3*25+01 48314 1-00 48314 5.06-00 4 8314 3+81-DI 4.314 1-@ 4 5.14+03 2031S 2. 86+DO 3 8316 .1.1 1 0 1 5.8-1 2 2313 0. -0Q28313 1-5 3a301 8.11+N 3$301 2.71- 1 3 2
3 3NGsl S-5-YCEN M9 o999 M9 0999 0. -00 283T2 5.2-0 49318 6a55+01 49318 2+97+01 44318 9.43-01 48319 3.36+00 4 .313 -7- 4 -1 1-- -6.03 28319 3. 01+OD 3 1310 M9 .119 -1 2091 6.0-01 2 0317 @. -1. 1.117 1.1-5 3R302 7 .1 @ 3B1. 1.3-1 33
3 4 MAS o", 0111 D119 091 -1 0- -1 0- .11, 0999 0999 0. -00 28312 3.1'4100 48311 1w.4+01 48322 3.77+Gl 4aL331 .11, 019 2091 -D-01 2 1321 0 w -00 2.321 1.89-05 39300 1.12+05 3B3 @ 3.01,05 3 3 4
"As A-1 48322 3.16+00 4 8322 3.78-01 4 8322 L-02 1 Sb2G+O3 21321 3t524003 9324 -9
3 5- syNTHANE G999 099 019 M9 09" 09s9 M, -1 -1 -0- 28312 1.44+01 48326 1j094Q2 48326 2m67+Dl 48326 48126 16+04+00 % 8326 4.16-01 4 8326 1 I.-D2 5 24.03 28327 3. 03+DO 3 8328 .11, .119 M9 _201 S-01 2 -5 *-00 28325 1.66+05 38303 831.0 3$303 2. -5 3 5
36 c_c@ C02 ACCEPTOR -o-oo 2 $338 0. -0 2 .338 G.00+DD 2 0338 G.-OG 2 4339 10.0-0 2 8338 0-00 2 8338 10.00+00 2 8338 0.00+00 2 8338 .0.00-00 2 0.0-0 2 .338 1 0.0- .33. --0 2.312 .31+00 4-5 -1- 49335 16.1-1 4.13S 42"S L98+00 Q 933S -7-01 4 6335 1.06+02 4 8.61+0 2a336 3-16+oo3 $337 o999 o999 .1191 2091 6.25-01 2 8334 Dw -00 28334 1.48- 1-- 3U -1o, 1 361
37
3 2
39
40
41
41
4 2
42
4 5 4 3
44 44
4 5
4S
46
46
47
47
48
4 9 49
5 0 Sol
5 1
5 2
5 3
54
85
TABLE 2. ENVIRONMENTAL IMPACTS, EFFICIENCY AND
COST FOR ENVIRONMENTALLY CONTROLLED NATIONAL
AND REGIONAL HIGH BTU COAL GASIFICATION
I V 13
K
114"
13-0 013
3
@4
5
.G
3.
�
FTN. 2091-8308
FOOTNOTES-FOR TABLE 2
209.1 Fire and/or explosions caused by gas leaks', oil leaks,
act of God, or human error. Possible damage to refinery,
personnel, adjacent properties.
8300 Capital and operating costs for this process are the
arithmetic average of the capital and operating costs
for the Northern Appalachia, Central, and Northwest
regions.
-8301 Capital and operating costs for this process are the
arithmetic average of@the capital and operating costs
for the Northern,Appalachia, Central, and Northwest
regions.
8302. Capi tal and operating costs for this process are the
arithmetic average of the capital and operating costs
for the Northern Appalachia, Central, and Northwest
regions..
8303 Capital and operating costs for this process are-the
arithmetic average of the capital and operating costs
for the Northern'Appalachia, Central, and Northwest
regions.
9304 Capital and operating costs for this process are the
arithmetic average of the National Average capital
and operating costs for the Hygas-Electrothermal,
Hygas-Steam Oxygen,.Bigas, and Synthane processes.
8305 Capital and operating costs for this process are the
arithmetic average of the capital.and operating costs
for the.Central and Northwest regions-
8306 Capital and operating costs for this process are
idsiatical to the capital and operating cos,ts.for the,
Northwest region.
8307 The primary-efficiency-And ancillary energy for this
pro'cess are the'arithmetic average of.the primary
efficiency and ancillary energy forthe Central and
Northwest regions..
8308 Air pollutants for this process are the arithmetic
average of the air pollutants for the Central and
Northwest regions..
IV-15
�
FTN. 8309-8319
8309 Solid waste for this process,tis the arthmetic average
of the solid waste produced in the Central and
,Northwest regions
8310 Land utilized by this process is-the qarithm etic average
.,of the land used'in the;Central and Northwest regions.
8311 Water pollutants for this process are the arithmetic
average of the water pollutants,for the Central and
Northwest regions'.
8312, Thermal discharges canbe complete1y eliminated by the
use. of mechanical draft-, wet cooling- towers.
8313' The primary,efficiency and ancilary energy qfqor. this
process-. are, the arithmetic average of the- primary
ef f iciency, and, ancillary energy for., .the 'Nothern
Appalachian Central, and Northwest-regions-
8314 Air- -pollutants for. this .,process are the- arithmetic
average of the.,air pollutants..for the, Northern
Appalachian-. Central and Northewest regions-.
8315 Solid waste-for.this:process is-the,arithmetic
average of the solid, waste, produced in the, Northern
Appalachia,. Central-, and; Northwest regions:.
8316 Land utilized by this process is the prithmqetic
average of the land.used in the Northern Appalachia,
Central, and Northwest regi
8317 The primar
y efficiency and ancillary.-,qenergy for this..
s are the, arithmetic average of the primary
proces
efficiency and ancillary enerqy of .the Northern
.Appalachia,, Central, and Northwest reigions.
Air pollutants for this process are the arthmetic
average of the air-pollutanqts.for the.Northern
Appalachia, Central, and,Northwest regions.
8319 Solid waste for this. -process ..is the -,-arithmetic
average of the solid waste prodduced.-in the Northern
Appalachia, Central, and Northwest regions.
IV-16
�
�
FTN.,8320-8329
8320 Land utilized by this process is.the arithmetic
average of the land used in the Northern Appalachia,
Centrall and Northwest regions.,
83.21. The primary efficiency and ancilla--y-energy for this
process are the arithmetic average of the@primary
efficiency and ancillary energy for the Northern
Appalachia,.Central, and NorthwiEistre'gions.,
is proces
83,22 Air pollutants for thi s are the-arithmetic
average of the air pollutants.for the Northern
'Appalachia, Central, and Northwest-regions.
8323 Solid waste for this process is the arithmetic
average of the solid.waste produced in the Northern
Appalachia, Central, and Northwest regions.
8324 Land utilized b-
y.,this process is the arithmetic
average of the land used in the Northern Appalachia,
Central, and Northwest
regions.
8325 The'primary efficiency and ancillary energy for this
process Are the arithmetic average ofthe primary
efficiency and,ancillary'energy for the Northern
Appalachia, Central, And Northwest regions.
8326. Air pollutants for this process are the arithmetic
average of the air pollutants for the Northern
Appalachia,-Central,.and Northwest regions.
8327 Solid waste for this process is the Arithmetic average
of the solid waste produced in the Northern
Appalachia, Central, and Northwest regions.,.
8329 Land utilized by this process is.the arithmetic
average of the land,used in the Northern Appalachia,
Central, and Northwest regions.
-8329 Primary efficiencyand ancillary energy for,this
process are the arithmetic average of the National
Average primary efficiencies and ancillary:energies
for the Hygas-Electrothermal,.Hygas-Steam Oxygen.,
Bigas, and Synthane processes.
IV-17
�
FTN. 8330-8350
8330 Air pollutants for this.process are the arithmetic
.average of,the National Average air pollutants for
the Hygas-Electrothermal, HygAs-Steami4qO0qxygen, Bigas,
and Synthane processes.
8331 Solid waste for this process is. the arithmetic average
of the'solid wastes produced in the National Average
case for the Hygas-Electrothermal, HygasSteam Oxygen,
Bigas, and Synthane processes.
8332 Land uitilized by this proqress is the aritmetic,average
of the land used in the National Averaqe case,by the
Hygas-Electrothermal, Hygas -,Steam., Oxygen., Bqi8qgas,., and
Synthane processes.
8333 Water allU4qt6qa0qn8qts for-this process..are-the athmetic
average of the water pollutants for the Typical New
Process in the Northern,Appalachia, Centraland
Northwest regions.
8334 The primary:efficiency and.ancillary.energy.for thi s-
process.are thesame -as those for' the Northwest region.
8335 Air pollutants,or this, process,are -the same-as those
for the Northwes region.
Solid waste for-this procqess-is the sameas-that for
.the Northwest region.
8337 Land utilized by this -process is- the same_as that
used in the Northwest region.
8338 Water pollutants or this process. - are the: same as
those for the Northwest region.
8350 The Northwest coal used in; this qanal2qy0qs0qlks, has the
following composition ona run-of mine_baqs is:
Proximate Analysis-Wt.Pc..Ultimate-Anallys qis-Wt. Pc.
Ash 6.0 4qC 5'2q.q.q8
H20 22q'. 0 H2q. q..3.6
Vol.Mat. 29.4 q!Nq'2 0.7
Fixed C. 42.6 02q. 14,4
8qS 0.5
Btu/lb 8806 Ash 6.0
sulfur H20 q.22q,..6q0
For this coal 57000q-24qton is equivalentqrto:lq.q'q.2qGEl2 Btu.
IV-18-
�
�
FTN. 8351-8352
8351 From (8300 and footnote 8350) for 253.3EO9 Btu/D
SNG, coal costs, based on $.15/1.DE06.Btu coal, are
$.263/1.OE06 Btu gas. Thus 444.1E09 Btu coal/D is
required,to produce 253.3EO9. Btu gas/D. The primary
efficiency, taken as Btu of gas output/Btu of coal
input, is therefore .'570. From (8300)p this-size S14G
plant also produces 4.84EO4 GPD of light oils
(primarily B-T-X) and 2.34E10 Btu/D of tars. If
these fuels are considered, then the overall plant
effici-ency becomes .635. The ancillary energy is
zero because the plant is self-sustaining with all
power and steam.requirements generated on-site..
8352 The principal quantifiable air pollutant sources are
as follows:
TPD
.:.Part.', SO CO HC NOX Other
Fuels'Combustion 4.158 :2.16 2.4.6..738 44.3 .01123
Sulfur Recovery Plant .0.80
Storage and Misc. .001 .139
Fuels Combustion
'
Based on plant heat requirements similar to that in
(8.300), and the use of coal to supply the'same
proportionate share of. this heat demand plus that due
to the waste offgases from coal pretreatment (since
pretreatment of western non-caking coals is not
required), 1938 TPD of coal (6.0 percent ash,,.51
percent S) are usedfor@fuel, with the balance, 84EO9
Btu/D, supplied by the@cpmbustion of gasifier char
(30.3 percent ash,-.5 percent S), These heating rates
were converted to equivalent TPD of bituminous coal
and used..with (8301,1.1-3) to determine TPD of air
emissions. Particulates were reduced 99.5 percent by
the use of an electrostatic precipitator-and a Wellman
Lord wet scrub while S02 emissions werexeduced 95
percent by the %bllman Lord unit.,
T
�
FTN. 8352.(Cont)
Sulfur Recovery'Plan't
Based on the use of the Rectisol acid'gas removal
system for the selective removal of H2S and C02
from the synthesis gas stream, a concentrated (25
percent) H2S gas stream can be sent to the ClaUa
plant for recovery.From (2022,103) a three stage
Claus plant operating on a 25 percent H2S feed can
recover 94 percent of the incoming S as elemental S.
The incoming S for recovery is based on 23j279 TPD. coal
to the gasifier (footnote 8351, less the above 1938 TPD
coal as -fuel),..51 percent S in the coal, and 80.
percent of the S to the gasifier as H2S to Claus for
recovery (the balance of the S is in th -e char). Based,
furthermore, on complet 'e-recycle to the Claus plant of
all the S02-recovered in the Wellman Lord scrubbing units
on the boiler flue gases and Claus tailgases, 124.5
TPD S is the Claus feed. Thus 117.0 TPD of S are recover-
ed or 264 ton S/1.OE12 Btu. 7.5 TPD of S passes to the
Wellman Lord tallgas scrubbing unit, so that A TPD S
or 0,.8 TPD S02 passes out to the atmosphere from the,
Claus and tailgas treatment system.
storage and Misc.
From (8300)-4.84EO4 GPD of light oils (B-T-X) are
produced. Assuming two weeks storage capacity under
new tank@conditions and:emission factors from (8302,,
4.3-8)'..001 TPD.HC are emitted. Based on '23,2792T-PD
coal to the gasifier .007 ton N2/ton coal, and 70
percent of the N2 in the feed coal as N113 (8303,X-7),
139 TPD of NH3 are produced in the gasifier. All.of the
Nk3 is washed from the gas synthesis stream and appears
.in the waste water. This waste water stream passes to an
@ammonia still with both a free and a fixed leg so that
essentially all of the NH3 isirecovered for sale.
From (8301,5.2-2) controlled storage-and loading
operations emit two lb of NH3/ton NH3. Thus @139 TPD NH3
are released to the atmosphere.
I V2 0
�
FTN. 8353-8355
It should be noted that other sources of air pollution
will be present.in any commercial coal gasification
operation, although their quantification is not
possible at present. These sour&es include,but are not
limited to, coal and other solids preparation and
and transfer operations, ventstacks for waste gas
disposal, pipeline valves and flanges, and pump and
compressor seals. The magnitude of these air pollutants#
however, should not be that large if the sources are
properly controlled.
8353 Based on 25,217 TPD coal with 6.0 percent ash, 1513
TPD ash are produced. Since 4.6*TPD is,released to
the atmosphere as.particulate, 1508.4 TPD remains as
solid waste for.disposal. Based on 5500 GPM net
makeup,H20 (8300) -and an assumed 500 PPM suspended
solids which is completely removed by lime treatment
and clarification, an additional 16.5 TPD of solid
waste is generated. From (8304) an ammonia ,still is
estimated t6 produce 115 ton/D of still waste..It is
assumed that all bio-treating sludges are used as
boiler fuel. The sum total solid waste produced is-
thus 1639.4 TPD (or 3705 ton/l.OE12 Btu).
8354 Land 'requirements are 'assumed to be 350 acres from' (9401,7)-
for coal storage, preparation, and gasification plant
facilities, and-an additional 165 acres for evaporation
-to handle the following TDS streams - H20
ponds (8306).
softener and demineralizer blowdowns, boiler and cooling
tower-blowdowns, and H20 from ash quenching and.trans-
fer operations which might contain le'achates. Since
High Btu Coal Gasification is assumed to be a mine-
mouth -activity, all solid waste produced is returned to
the mine for burial. There is, therefore, no incre-
mental land impact due to.solid waste production.
Thus'a total of 515 acres is required for a 25,217.
TPD coal gasification operation. With a 90 percent
operating factor this is equivalent to 3.'54 acre-yr/
1.OE12 Btu4 However, a larger land impact would be
produced if solid wastes were not returned to the
mine for burial. (See footnote 8353 for solid waste).
8355 Water pollutants are zero because there is no aqueous
discharge from the boundaries of the plant operation.
All process waste water and impounded runoff is treated
and used for cooling tower makeup, while all blowdown
streams are collected and sent to lined evaporative
ponds for disposal.
IV-21
�
FTii. 8356-8357
8356 From (8300)and fobtnote 8350F for 247..2EO9 Btu/D SNG,
coalcost, based on $ '.15/1.OE06 Btu.coal, is $.255/
l.0E06 Btu gas. Thus 420.2EO9 Btu coa-l/D is required
to produce 247.2EO9 Btu gas/D. The primary-efficiency,
taken as Btu of gas output/Btu of coal input, is
therefore .588. From (8300') this size SNG plant also
produces 4.56EO4 GPD of light oils (primarily B-T-X)
and 2.30E10 Btu/D of tars. If these fuels are
considered, then the overall plant efficiency becomes
.655. The ancillary energy is zero because the plant
is self-sustaining with all power and steam require-
ments generated on-site.
8357 The principal quantifiable air pollutant sourpes are
as follows:
TPD
Part. Sox CO HC NOX Other
Fuels Combustion 2.319 1.87 1.59 .480 28.6 .00797'
Sulfur Recovery Plant 0.60
Storage and Misc. .001 ..123
Fuels Combustion
Based on plant heat requirements similar to that in
(8300), and the use of coal to supply @the same
proportionate share of this heat demand plus that due
to the waste offgases from coal pretreatment (since
pretreatment of western non-caking coals is not
required), 3157 TPD of,coal (6.0 percent ash, .51
percent S) are used for fuel, with the balanc,.e, 20.9EO9
Btu/D, supplied by the combustion of gasifier char
(52.6 percent ash, .9 percent S). These heating rates
were converted to equivalent TPD of bituminous coal and.
used with (8301,1.1-3) to determine TPD of air emissions.
Particulates were reduced 99.5 percent by the use of an
electrostatic precipitator and a Wellman Lord wet scrub,
while SO emissions were reduced 95 percent by the
Wellman Zord unit6
IV-22
�
FTN...8357 (Cont)
Sulfur Recovery Plant
Based on the use of the Rectisol acid gas removal
system for the selective removal of H2S and C'02 from
the synthesis gas stream, a concentrated (25 percent)
H2S gas stream can.be sent to@the Claus plant for
recovery. From (2022,103) a three stage Claus plant
operating on,a 25 percent H2S feed can recover 94
percent of the incoming S as elemental S. The incoming
S, for recovery is based on 20,704 TPD coal to the
gasifier (footnote 8356, less the above' 3157 TPD
coal as fuel), .51 percent S in the coal,, and 80
percent of the Sto the gasifier as H2S to Claus for
recovery (the balance of the S is in the char).-Based,
furthermore, on complete recycle to theClaus plant of
all the S02 recovered in -the Wellman Lord scrubbing
units on'th6 boiler flue gases and Claus 5 tailgases,
.109-O.TPD S is the Claus feed. Thus 102. TPD of S are
recovered or 245 ton-S/I.OE12 Btu. 6.5 TPD S passes to
the Wellman Lord tailgas scrubbing unit, so that .3
TPD S or.0.6 TPD SOj passes out to the atmosphere from
the Claus,and tailgas treatment system.
Storage and Misc.
From (8300.) 4..56EO4 GPD of light oils (B-T-X) are
produced. Assuming 2 weeks storage capacity under new
tank conditions and emission 'factors from,(8302,4.3-8),
.001 TPD HC are emitted. Based on 20,704 TPD coal to
"fier .007 ton N
the gasi F
2/ton,coal, and.70'percent of
the 112 in the feed coal as NH3 (8303,X-7),.123 TPD of
NHj are produced in the gasifier. All of the NH3 is
washed from the-gas synthesis stream and appears in the
waste water. This waste water stream passes to an
ammonia still with both a free and a fixed leg so that
substantially all of the NH is recovered,for sale.
From,(8301,5..2-2). controllea storage and loading
op erations emit 2 Ib of NH3/ton NH3. Thus .123 TPD
NH3 are released to the atmosphere.
IV-23
�
PTN. 8359-8360@
It should be noted that other sources of air pollution
will be present in any commercial coal gasification
operation, although their quantification is not possible
at present. These sources include, but are not limited
to, coal and other solids preparation and transfer
operations, vent stacks for.waste gas disposal,
pipeline valves and flanges, and pump and compressor
seals. The magnitude of thes-e air pollutants, however,
shouldnot be that large if the sources are properly
controlled.
8358 Based on 23,861 TPD coal with 6.0 percent ash, 1431.7
TPD ash are produced. Since 2.4 TPD is released to
the atmosphere as particulate, 1429.3 TPD remains as
solid waste for disposal. Based on 5300 GPM net makeup
H 0 18300) and a
w@ n assumed 500 PPM suspended solids
ich 'is completely removed by lime treatment-and
clarification, an additional 18.9 TPD of solid waste
is generated. From (8304) an ammonia still is estimated
to produce 115 ton/D of still waste. It is assumed that
all bio-treating sludges are used as boiler fuel'. The
sum total solid waste produced is thus 155j.7 TPD or
3725,ton/l.OE12 Btu.
8359 Land requirements are assumed to be 35.0 acres from (9401,7)
for coal storage, preparation, and gasification plant
facilities, and an additional 165 acres for evapora-
tion ponds.(8306) to-handle the following TDS streams
H20 softener and demineralizer blowdowns, boiler and
cooling tower blowdowns, and H20 from ash quenching
and transfer operation which might contain leachates.
Since High,Btu Coal Gasification is assumed to be a
mine-mouth activity, all solid waste produced is returned
to the mine for burial.' There,is,'therefore, no in-
cremental land impact due to solid waste production.
Thus a total of 515 acres is required for a 23,861
TPD coal gasification operation. With a 90 percent
operating factor this is equivalent to 3.75 acre-yr/
1.OE12 Btu. However, a larger land impact would be
produced if solid wastes were not returned to the mine
for burial. (See footnote 8358 for solid waste.)
8360 Water pollutants are zero because there is no aqueous
discharge from the boundaries of the plant operation.
All process waste water and impounded runoff is treated
and used for cooling tower makeup, while all blowdown
streams are collected and sent to lined evaporative
ponds for dispoaal.
IV-24
�
FTN. 8361-8362
8361 From (8300 and footnote 8350) for 231.8EO9 Btu/D
SNG, coal cost, based on $.15/1.OE06 Btu/coal, is,
$.257/1.OE06 Btu.gas. Thus,397.2E09 Btu coal/D is
required to produce 231.8EO9 Btu gas/D'. The
primary efficiency, taken as Btu of gas output/Btu
of'coal input, is therefore .584. From (8300) ' this
size SNG plant also produces 8.5ED9 Btu/D of heavy
oils, and from (8307,6) 25,000,GPD of B-T-X can;be
expected. If these fuels are considered, then the
overall plant efficiency becomes .612. The ancillary
energy .is iero because the plant is self-sustaining,
with all power and steam requirements generatdd on,,site.
8362 The.principal quantifiable Air pollutant,sources are
as. f ollows
@TPD
Part. SOX CO HC NUx Other
Fuels Combustion 5.15 1.61 @2.52 .757 45.4 .0127
Sulfur'Recovery Plant 2.20
Storage and Misc. .1@27
Fuels Combustion
Based on plant heat requirements similar to that in
(8300), and the use of coal to supply the same
proportionate-share of this heat demand, 1170 TPD of
coal (6.0 percent ashf .51 percent S) are used for
fuel, with the balance, lOOE09 Btu/D, supplied'by the
combustion of gasifier char (29.5 percent ash, .3
percent S). These heating rates were converted to
equivalent TPD of bituminous coal and used with
(8301,1.1-3) to determine TPD of air emissions.
Particulates were reduced 99.5 percent,by the use of
an electrostatic precipitator and a Wellman Lord wet
scrub, while So emissions were reduced.95 percent by
the Wellman Lora unit.
IV-25
�
FTN4 @362 (Cont)'.
Sulfur Recovery Plant
Based o h the-use of the Hot Carbonate acid gas
removal.,system for the nonselective removal of H2S and
CO from the synthesis gas stream, a dilute (5 percent)
.H23 gas,stream is sent to the Claus plant for recovery.
From (8303,AI-25) a Claus plantoperating-on this
dilute feed.can recover 84 percent of the incoming S as
elemental S. The'incoming S for recovery is based on
21,380 tPD coal to the gasikier (fdotnote 8361, less
the above@1170 TPD coal as fuel), .51 percent S in the
coal, and 90 percent of the S in the gasifier as H2S
to Claus for recovery (the balance of the S is-in the
char). Based, furthermore, on complete recycle to the
Claus plant of all the SO@ recovered in the @Iellman,
Lord scrubbing units on the boiler flue gases and Claus
tailgasest 133.6 TPD S is the Claus feed. Thus 112.2
TPD of S are recovered or 283 ton S/l.OE12 Btu. 21.4
TPD S passes to the -Wellman Lord tailgas scrubbing'.
unit, so that 1.1 TPD S or 2.2 TPD S02 passes out to the
atmosphere from the Claus and tailgas treatment system.
Storage and Misc.
Based on 21,380 TPD coal to the gasifier, .007 ton N2/
ton coal,,'and.70 percent of the N2 in the feed coal as
NH@ (8363,X-7), 127.TPD of NH3 are produced in.the
gasifier'.All of the''NH3 is washed from the gas
synthesis stream and appears in the waste water. This
waste water stream passes to an ammonia still with both
a:'free and. a. f i=*d7Ipg, so_that.@ abbrAaztial,@y@ all, Of --+,be
NHJ is recovered for sale. From (8301,5.2-2)' controlled
storage and loading operations emit two lb of NHYton
NH'@. Thus .127 TPD NH' are released to the atmosphere.
3
IV-26
�
FTN. 8363-8365
It should be noted that other sources of air pollution
will be.present in any commercial coal-gasification
operation, although their quantification is ,not
possible at present. These sources include, but are not
limited to, coal and other.solids preparation and
transfer operations, vent stacks for waste,gas
disposal, pipeline valves and flanges, and pump and
compressor seals. The magnitude of these air pollutants,
however, should not be that large if the sources are
properly@contro'lled..-
8363 Based on'22,550 TPD coal with 6.0 percent ash,'1'353
TPD ash are produced. Since 5.2 TPD is released to the
atmbsphere---as particulate, 1347.8 TPD,remains as solid
w.aste for disposal. Based.'-.on 17700 GPM net makeup H20
(8300) and an assumed 500 PPM suspended solids whi ch is
completely removed,by lime treatment and
clarification, an additional 53.2 TPD of solid waste is
.generated. From (8304) an ammonia still is estimated
to produce 115 ton/D of still waste. It is assumed that
all bio-treating sludges are used as boiler fuel. The
sum.-total solid.waste produced is thus 1515.5 TPD or
3831.ton/l.OE12 Btu.
8'364 Land requirements are assumed to b6 350 acres from (9401,7)
for coal storage, preparation, and gasification plant
facilities, ahd-an additional 16,5 acres for evapora-
tion ponds (.8306),to handle the following TDS streams
H20 softener and. demineralizer blowdowns, boiler ano
cooling tower.blowdowns,'and H20 from ash quenching
and transfer operations which might.contain,leachates..
Since High Btu Coal.Gasification is'assumed to be a
mine-mouth activity, all solid waste produced is returned
to the mine for burial. There is,"therefore, no incre-
mental land impact due to solid waste production. Thus
a total of 515 acres is required for a 22,550 TPD coal
-gasification operation. With a 90 percent operating.
factor this is equivalent to 3.96 acre-yr/l.OE12 Btu.
'However, a@larger land impact would be produced if solid
-wastes 'were not returned to the mine.for.'burial.. (See
footnote 8363 for solid waste.)
8365 Water:pollutants are- zero becaus.e ther e.is,no aqueous
discharge from the boundaries of the plant operation.
All.process waste water and impounded runoff is treated,
and,used for cooling towermakeup, while all blowdown
streams are collected and sent to lined evaporative
ponds for disposal.
IV-27
�
FTN. 8366-8367
Fromi@(8300 and footnote 8350),for 236.1E09 Btu/D SNG,
coal,cost, based on $.15/1.,OE06.Btu coal, is $.22/
l..0EQ6 Btu gas. Thus 346.3EO9 Btu coal/D is required
to produce 236.1E09 Btu gas/D. The primary efficiency,
taken as Btu of gas output/Btu of coal input, is
therefore .682. No light or heavy oils are reported
as byproducts.for this process.-The ancillary energy
is zdro because the,plant is self-sustaining with all
power-and steam requirements generated on-site.
8367 The pX incipal quantifiable air pollutant sources are
as follows:
TPD
Part. SOA CO HC NOx -Other'
Fuels Combostion' 1.118 3.05 1.07, .320 20.1 .00534
Sulfur Recovery Plant 1.80
Storage and Misc. .0985
Fuels Combustion
Based.on plant heat requirements similar to those in'.
(8305i #' 63), a total of 3107 TPD of coal is required
for fuel which includes 197 TPD for thermal drying
of the coal.-The 2910 TPD of subbituminous coal used-
as fuel in boilers is equivalent to 2135 TPD of
bituminous coal and was used in conjunction with
(8301',1.1-3) to determine boiler air-emissions..
Particulates were then reduced 99.5',percent by the use
of ani@electrostatic precipitator and a Wellman Lord wet
scrub, while S emissions were reduced 95 ptrcent by
thevellman LOA unit. Particulate emissions in
compliance with the New Source Performance Standards
for coal thermal dryers are limited to .03 grain/DSCF
.(1121@. Based on 24000 DSCF/ton dry coal input to the
dryeri(1121Y and 12,913 TPD dry coal to the dryer and
gasifier, .664 TPD of particulates.are emitted.,Based.
on .535 lb NO /l.6E06 Btu coal fired (1121),, .51
percent S co;1. and 197 TPD coal for dryer fuel, .928
TPD NO. and 2.01 TPD S02 are also,released from the
dryer.
therma
IV-28
�
FTN..8367 (Cont).,
Sulfur Recovery Plant
Based on'the use of the Hot Carbonate acid gas removal
system for nonselective removal-of H2S and C02 from the
synthesis gas stream, a dilute (5 percent) H2S gas
stream is sent to the Claus plant for recovery. From
(8303,AI-25) a Claus plant operating on this dilute feed
can recover 84 percent of the incoming S as elemental S.
Theincoming S for recovery is based on 16,555 TPD coal
to the gasifier (footnote 8366, less the above 3107 TPD
coal as fuel), .5l.percent S in thecoal, and all.of the
S to the gasifier as H2S.tO Claus for recovery (none in
the slag). Basedf-furthermore, on complete recycle to
the Claus plant of all the S02.recovered.in the Wellman
Lord scrubbing units onthe boiler flue gases and
Claus tailgades,, -11.1-I'TPD is the Claus feed. Thus 93.3
TPD of S are recovered or 271 ton S/1.OE12 Btu. 17.8
TPD'S pa.sseswto the Wellman Lord tailgas scrubbing unit,
so that ..9 TPD S or'l.8 TPD S02 passes out to the
atmosphere, from'.the'Claus and tailgas treatment system.
Storage and Misc.
Based on 16.,555 TPD coal to the gasifier, .007 ton N2
ton coal, and 7.0 percent of the N2 in the feed coal as
NH3(8303,X-17), 98'.5 TPD of NH3 are produced in the
gasifier. All of the NH3 is washed from,the gas.synthesiis
stream and appears in the waste water. This waste water
stream passes to an ammonia still with.both a free and
..a fixed leg so that substantially all of the,NH3 is
recovered for sale. From (8301,5.2-2) controlled storage
and loading operations emit two lb,of NH3/ton NH3. Thus
.0985 TPD NH3 are released to the atmosphere
It should be noted that other sources of air, pollution
will be present in,any commercial coal'gasification
operation, although their quantification is not possible
at present-These sources include, but are not"limited
to, coal and other solids@'preparation and transfer
opdrations, vent stacks for waste gas disposal, pipelinel
valves and flanges, and pump and compressor seals. The
magnitude of these air pollutants,, however, should not
be that large if the sources are properly controlled.
1
-29
V
�
FTN. 8368-83,71
8368- Based on 19,662 TPD coal with 6.0.percent ash, 1179.7
TPDiash are produced. Since 1.2 TPD is released to the
atmosphere as particulat6,,1178.5 TPD remains as solid
waste'for disposal. Based on 10385 GPM net makeup H'-O
(8300) and an assumed 500 PPM suspended solids whici is
completely removed by @ime treatment and clarification,,
an Additional 31.2 TPD of solid waste is generated.
From (8304) an ammonia still is estimated to produce,
115@ton/D of still waste. It is .assumed that all
bio-treating sludges are used as boiler fuel. The
sum,i.total solid waste, produced is t,hus.1324.2 TPD or
3839 ton/l.OE12 Btu.
836-9 Land requirement.s are assumed to be 350 acres from (9401,7)
for@coal-storage, preparation and.gasification plant
facilities, and An additional'165 acres for (@vapora-.
tion ponds 48306) to handle the following TDS'streams
H20 softener,and demineralizer blowdownsf boiler and
cooling tower blowdowns, and H20 from ash quenching
and'transfer operations which might contain leachates.
Since High Btu Coal Gasification is-assumed to be a
mine-mouth activity, all solid waste produced is re-
turned to the mine for burial. There is, therefore,,-.
no incremental land impact due to solid waste produc-
tion. Thus a total of 515 acres is required for a
19,662 TPD coal gasification operation. With a * 90
percent operating factor this is equivalent to 4.54,
acre-yr/l.OE12 Btu. However, a larger land impact
would be produced if solid wastes were not returned
to the mine for burial. (See footnote 8368 for solid
waste..)
8370 Water pollutants are zero because there is no aqueous
discharge from the boundaries of the plant operations.
All process waste water and impounded runoff is treated
and used for cooling tower makeup,.while all blowdown
streams are collected and'sent-to lined evaporative
ponds for,disposal.
8371 From (8311,3.13) the total heat demand for a plant
producing 252EO9 Btu/D of SNG is 85.1EO9 Btu/D and
the TPD coal'to the gasifier is 21860. This analysis
is for a Aouthwestern Subbituminous coal with 62.0
percent volatile matter and fixed carbon@and a heating
value of 8310 Btu/lb. Based on footnote 8350 and'the
assumption that the gasifier outputs are the same for
equivalent TPD of volatile and fixed carbon input to the
gasifier (sinee these are the reactive constituents'in'
the coal), the Northwestern analysis would require
18824 TPD coal to the gasifier. Based on the assumption
that'.the total plant heat demand is relatively constant
IV-30
�
FTN. 8372
for the various subbituminous coal inputsp 4830 TPD
coal is required for boiler fuel. Thus a total of
23654 TPD coal is required to produce 252EO9 Btu/D SNG
for a primary'efficiency of .605. This size plant also
produces 41.23EO9.Btu/D of tars and tar oils and'63.6EO3
GPD of naphtha (831,1,3.13). If these fuels are considered,
then the,overall plant efficiency becomes..721. The
ancillary energy is zero because.the plant is self-
sustaining with all power and steam requirements
generated on-site.
8372 The principal quantifiable air pollutant sources are as
follows:
TPD
'Part. sox CO, HC. NOx Other
Fuels Combustion .851 1.72 1.77 .532 31.9 .60886
Sulfur Recovery Plant 0.160
Storage and Misc. .112
Fuels Combustion
Based on air emissions factors in (8301',1.1-3,1.4-2) and
the combustion of 3544 TPD of equivalent bituminous coal
(4830 TPD of subbituminous coal). Particulates were
reduced 99.5 percent by the use of an electrostatic
precipitator and a Wellman Lord wet scrub, while S02
emissions were reduced 95 percent by the Wellman Lord
unit..
'Sulfur Recovery'Plant.
Based on'the use of the Rectisol acid.,gas removal system
for the selective removal of H2S and C02 fromthe syn-
thesis gas stream,' a concentrated (25 percent) H2S gas
stream can be sent to the Claus plant for recovery
(8308,21), and from (2022,103) this Claus unit can re-
cover 94 percent of the incoming S. The incoming S for
recovery is-based on 18824 TPD coal to the gasifier,
.51 percent S in the coal,. and 98 percent of the S to
the gasifier as H2S to Claus for recovery (the balance
of the S is in the by-products) from (8310, sheet no.
00-1-02). Based, furthermore, on complete recycle to
Claus of all the S02 recovered in the Wellman Lord
scrubbing units on the boiler flue gases and Claus
tailgases, 117.1 TPD S is the Claus feed.,
IV-31
�
FTN'. 8373
Thus-110.1 TPD S is recovered for sale-or 265 ton S/
l.OE1-2 Btu. Since 7 TPD S passes to-the Wellman Lord
tailgas scrubbing unit, 3.TPD S or 6 TPD S02 exits
the stack.
Storage and Misc..
From-(8311,3.13) 63.6EO3GPD of light oils are produced.
Assuming two weeks sqtorage capacity under new tank con-
ditions and emission factors, from 18300q2 4.3-8),,001
TPD HC are emitted..Based on 18824 TPD coal to the
gasifier-and .1 percent N2in the coAl and 70 percent,of
the N2 in the feed coal as NH3 (8303,X-7)- 112 TP 'D NH3
is produced in the gasifier. Substantially all of this
NH I vered in a free and fixed ammonia still.
3 is reco
From (8301,,5.2-2) controlled,storage and loading
operations emit two lb of NH3/ton NH3- Thus .112 TPD
NH3 are released into the atmosphere.
It should be noted that other sources of air pollution
will be present in any commercial coal gasification
operation, although their quantification-is not possible
at present. These -sources include, but.are not limited,
to, coal and other solids preparation and transfer
operations, vent stacks for,waste gas disposal, pipeline'
valves and flanges;, and pump and compress rseal. The
magnitude of these,air pollutants, however, should,not
be that large-if the sources are properly controlled.
8373 Based on 23654 TPD coal with-6 percent ash-,,, 1419 TPD ash
are produced-Since 1 TPD,is releasekdAto the atmosphere
as particulate, 141,8 TPj remains-as solid waste for
.disposal. Based-6n100 GPM net makeup H20 (8311113.20)
and-an assumed 500 PPM suspended solidswhich is complete-
1Y remov qed,by lime treatment andclarification, an
additional 15.3 TPD of solid waste generated. From
(8304)an ammonia stillis estimated,to produce 115 TPD
of still waste. The sum total solid waste -produced is.
thus 1548 TPD or 3731 ton/l.OE12,Btu.
IV-32
�
�
FTN 8374-8376
8374 Land requirements are assumed to be 350 acres from (9401,7)
for coal storage, preparation, and gasification plant
facilities, and an additional 165 acres for evaporation
ponds (8306) to handle the following TDS streams - H20
softener and demineralizer blowdowns, boiler and
cooling tower blowdowns, and H20 from ash quenching and
transfer operations which might contain leachates.
Since High Btu Coal Gasification is assumed to be a
mihe-mouth activity, all solid waste produced is re-
turned to the mine for burial. There is, therefore,
no incremental land impact due to solid,waste produc-
tion. Thus a total of 515 acres is required for a
TPD coal gasification operation. Wit h a 90
percent operating factor this is equivalent to 3.78
acre-yr/I.OE12 Btu..*. However, a larger land impact
would be produced if solid wastes were not returned
to the mine for burial. (See footnote 8373 for solid
waste.)
8375 Water pollutants are zero because there is no aqueous
discharge,from the boundaries of the plant operation.
.All process waste water and impounded runoff is treated
and,used for cooling tower makeupt while-all blowdown
streams are collected and sent to lined evaporative
ponds for disposal.
8376 This process can be.operated with only a lignite, coal
input. Thus the following lignite coal (ROM) was
used in this analysis:
Proximate Analysis WT PC
Btu/lb 7070 Ash 7.2
S_WT PC 0.6 H 20 33.7
Vo Mat. and
Fixed C. 59-11.
For this coal 7100d ton of coal 'is equivalent to
1.OE12 Btu. From (8-300) 25360 TPD coal is required for
the gasifier and 2937'TPD for plant fuel to produce
25OE09 Btu/D SNG. The primary efficiency is thus .625.
The ancillary energy is zero because the plant is
self-sustaining with all power and steam requirements.
generated on-site.
IV-33
�
FTN. 8377
8317 The-principal quantifiable air pollutant sources are_
as follows:
TPD
Part. SQx CO HC N0qOx Other
Fuels Combustion 1.32 104qA 6qT5;1 .237 15.2. .00395
.Sulfur Recovery Plant 4
Storage-and Misc. ..170
Fuels Combustion
Based on the Combustion 0q60q115q81 TPD bituminous coal
(2683 TPD lignite) as plant fuel and air emissions
factors from (8301,1.1-3). P6qartic6qulates,were reduced
99.5 percent by the use of an electrostatic'precipitator
and a Wellman Lord,wet scrub while So -emissions were
reduced 95 percent by the Wellman Lora unit. Also
included are the emissions from combustion' of 254 TPD
of lignite to dry the-gasifier feed-coal. Based on .535.
lb NOx/i.0E06'Btu coal fired (1121).and .6 percent S
coal, .961 TPD NO' and 3.05 TPD So are'emitted..
Particulate emitsfons in. compii-aqncqa with the New
Source Performade Standards for coal thermal yers
are-limited to .03 g4qkain/DSCF (1121). Based on 24000
DSCF/ton dry coal input to the dryer (1121) and 16814
TPD dry coal.to the dryeqt-and gasifier, .865 TP4qD
particulates are-.emitted Based, furthermore, on 2
percent of the S in the Led coal evolved as.S0qO 2 (8321,
20), an additional 6.09,TPD SO is released from the
coal thermal dryer 2
Sulfur Recovery'Plant
Based on the.use.ofthe Hot Carbonate acid'gas
removal-system for the,nonselective removal of H 2S and
c4qo from the synthesis gas stream, ailute(5 percent)
H qi gas stream is'sent to the Claius-plant for
recovery. From(8303,AI-25) a-Claus plant operating
on-this,dilute feed can recover 84q.petcent of the
incoming S as elemental.S. The incoming Sq"for recovery
is based on 25360 TPD-coal to the gasifier, .6 percent
S in the coal, and 3 percent of-the:S as H 2S,to Claus
for recovery (3 percent of-the S is in the.ash and 92
percent of the S is evolved as S02 from the.regenerator).
IV-34
�
�
FTN. 8378
Basedi furthermore, on 30 percent of the total S to
Claus as S02 (8303,AI-27) from the Wellman Lord
scrubbing units,.6.6 TPD S is the Claus feed'. Thus 5.5
TPD S is recovered for sale or 13.8 ton S/l..OE12 Btu.
Since 5.5 TPD S passes to the Wellman Lord-tailgas
scrubbing unit, .3 TPD S or .6 TPD S02 is emitted. The
bulk of the S in the gasifier coal is released as S02
in the regenerator (92 percent). Based on a Wellman
Lord unit to treat this stream (144 TPD S),,7 TPD S or
14 TPD S02,leaves with the regenerator offgases. The tot-
al recovered S,02 for sale is 289.6 TPD S02 or 727 ton
S02/1-OE12 Btu.
Storage, and Misc.
Based 'an 16814 TPD MF lignite to the gasifier', 1.19
percent N2 in MF lignite,(8321,20) and 70 percent of
the N2 as NH3 (8303,X-7) 170 TPD NA3 are.produced in
the gasifier. Substantially all of this.NH3 is recovered
in a free.and fixed.ammonia still. From (8301,5.2-2)
controlled storage and loading operations emit two lb
NH3/ton NH3- Thus .170 TPD NH@ are released into the
atmosphere.
It should be noted that other sources of air pollution
will be persent in any commercial coal gasification
operation,'although their quantification isnot possible
at present. These sources include, but 'are not limited
to, coal and other solids preparation and transfer
operations, vent stacks for.waste gas disposal, pipeline
valves,and flanges,. and pump and compressor seals. The
magnitude of these air pollutants, however, should not
be that large if.the sources are properly controlled.
8378,. Bas'ed on 28297 TPD coal with 7.2 percent ashl 2037 TPD
ash are produced. Since 1 TPD is released'to the.
atmosphere as parti 'culate, 2036 TPD remains as solid
waste for disposal. Based on 6580 GPM net makeup H20
(8300) and an assumed 500 PPM suspended solids which.is
completely removed bylime treatment and clarification,
an additional 19.8 TPD of solid waste is generated. From
(8304) an ammonia still is estimated to@produce 115 TPD
of'still waste. From (8321,20) it is estimated that 1260
TPD MgO-CaO will have to be discarded from the regener-
ation'operation in thiz process. It is assumed that al
bio-treating sludges are used as boiler fuel. The sum
total solid waste produced is thus 3431 TPD or 861.0 ton/'
l.OE12 Btu.
IV-35
�
FTN. 8379-8385
8379, Land requirements are assumed to be 350 acres from (9401,7)
for -coal storage, preparation,and gasification plant
facilities,' and an-additional 165-acres-for evapora-
tion ponds (8306) to handle the 'following TDS streams
H20 softener,and demineralizer blowdowns, boiler and
cooling tower blowdowns,and-H22q6 from ash quenching and.
transfer,operation which might contain-ql4qeaq@qchates. Since
High Btu Coal Gasification-is assumed to be-a mine-
mouth activity,. all solid-waste produced is-returned
to the mine for burial. There is therefore, no incre-
-mental land impact due to solid-waste production. Thus
a total of 515 acres is required for a-28297 TPD coal
gasification operation. With a 90 percent operating
factor this is equivalent to 3.16 acre-4qyr/l.OE12 Btu.
However, a larger land impact would be,produced if
solid wastes were not returned to the mine for burial.
.(See footnote 8378 for solid waste.)
8380 Water pollutants are zero because there is,aqueous
discharge'from the boundaries of the plant operation.
All process waste water'and impbunded.runoff is treated
and used for cooling tower makeup, while all blowdown
streams are collected and sent to lined evaporative
ponds for disposal.
834 Primary efficiency and ancillary energy for this
process are an arithmetic average of--those for the
Hygas"Electrothermal, Hygas Steam Oxygen, Bigas,-and
Synthane processes.
8382 Air pollutants for this process are an arithmetic
average of those for the:Hygas-Electrothermal,-Hygas-
Steam Oxygen, Bigas,.and Synthane processes.
8383 Solid waste production for this process is an arithmetic
average-of those-for the Hygas-Electrothermal, Hygas-
Steam Oxygen, Bigas andSynthan processes.
8384 Land utilization by this process is an arithmetic-
average of those used by the-Hygas-Electrothermal,
Hygas-Steam Oxygen,'Bigas, andSynthane processes.
8385 Water pollutants for this process are an arithmetic
average of-those for 'the Hygas Electrothermal, Hygas-
Steam Oxygen,Bigas and Synthane processes.
IV-36
�
�
FTN. 8386-
8387
8386 capital and operating costs keredeveloped @s follows:
Capital Costs-1972 $-Plant-Basis-19,700 TPD,.90 P LF
From (8300), escalated at,5 percent from 1971 $, costs
for coal storage and preparation, feed system, gasification.
and CO shift,gas purificatiom, methanation, 02 manufacture,
steam and power plant, gpneral'utilities, and general
offsites total 165.2EO6 $. Water pollution control costs
were estimated at 11.7E06 $ from (2013,VII-6), (8304),
and (8315). Sulfur recovery costs were estimated at 5.0
E06 $,from (8300) and (8303,AI-25,AI-26). Capital
cost was reduced by*20EO6 $ to reflect savings.for a
noncaking low S western coal. To the subtotal were
added a 15 percent. project contingency and a.7 percent
development contingency to give a total plant investment
of 191.5EO6'$. Based on a FCR of-10 percent/yr and-
6.46EO6 TPY coal, this is equivalent to'l.7.4EO5 $/
1.OE12 Btu.
Operating Costs-1972.$-Plant Ba'sis-19,700 TPD, 90 P LF
From (8,300).directly, catalysts and chemicals,purchased
raw H 0, and process operating labor total $.0405/1.OE06
Btu g3s. Maintenance labor, supervision labor,
administra 'tion and general overhead, operating and
maintenance supplies arefrom (8303,Ai-5). The total
gross operating cost is thus $.1694/1.OE06 Btu gas or
13.12EO6 $/yr for a 236.1E05 Btu/D SNG plant. By-
productS- are credited at, $10ATS' (85 LTS/D) -and $25/T
(98 TPD NII3) from (8303,AI-5). The total net
oparating cost is 12.04EO6 $/yr or, for 6.46EO6 TPY
coal, 1.06EO5 $/l.OE12 Btu.
8387 Capital and operating costs were.developed as follows:
Capital Costs-1972 $- Plant Basis-25, 200 TPD, 90 P LF
From (8300), escalated at 5 percent from.1971 $, costs
for coal storage and preparation, feed system,
gasification and CO shift, gas purification, methanation,
steam and power plant, general utilities, and general
of'fsites total 200.9EO6 $. Water pollution control costs
were estimated at 11.7EO6 $ from (2013,VII-5), (8304)f'
and (8315). Sulfur recovery costs were estimated at
lOE06 $ from (8300) and C8303,AI-25,AI-25). Capital
cost was reduced by 20EO6 $ to reflect savings for a
noncaking low S western coal. To the subtotal were
added a 15 percent project contingency and a 7 percent
IV-37
�
FTN. 8388
develpment coingency to-give a total plant
investmnt of 247.2EO6 $. Based:on 10 percent/yr FCR
and 8.28EO6 TPY coal, this becomes.l.70EqO5 $/l.OE12
Btu.
Operating Costs-1972 $-Plant Basis-25,200TPD, 90 P LF
From (8300rectly, other raw material catalysis and chemicals, purchasedaw H 0 and process operating
2
labor total $.0438/1OE06 Btu gas. Maintenance labor,
supervision labor, administration.and general overhead,,
'operating and maintenance supplies are from q(8303,AI-5).
The total gross-operating cost is $1966/1.OE06tu gas
for a 0q@53-3EO9Btu/D SNG plant. By-products are 'credited
at $10/0qLTS 1.(105 4qLT8qS/D), $25/T NH (139 TPD NHq@q), $.15/
gal BTX(4q8.44qEqO3-GPD)and $.30/q1.qOE06 Btu ta s
q(23.4Eq09 Btu/D) from (q8303,AI-5). The-total net operating
cost is $10-15EqO6/yr or, for 8.28EqO6 TPY coal, 7.qOqO4qtqO4
$/l.OEI2 Btu.
8388 Capital and operating costs were.develop8q6d as follows:
Capital Costs-1972 $_PlantBasis T8qPDj 90 P LF
From (8300), escalated;4qat 5 percent from .1971 $, costs
for coal storage and preparation, feed system
gasification and Cozshift, gas purification, methana-
tion, q' manufacture, steam and poer plant, general
qutqilqti as, and general offsites---tota '1,1q606q906 $. Water
pollution control costs were estimated at'll.7EqO6 $
-from (2013,VII-5), (8104), and (,8315). Sulfur recovery
costs were estimated at 9.2EO6 $ from (8300) and
(8303,AI-25,AI-26). Capital cost was reduced by 20EqO6 $
to reflect savings for a noncaking low S western coal.
To the.subtotal were added a 154_percent,project
contingency and a 7 percent development contingency to
give a total plant-investment of 196.3EOq6 $. Based on
10 percent/yr FCR and 7.84EO6 TPY coal., this comes
1.43EO5 $8q/l.OE12 Btu.
-IV-38
�
�
FTN 8389
Operating Costs-1972 $Plant Basis 23,900 TPD, 90 P LF
From (83bo) directly, other raw material., catalysts and
chemicals, purchased raw H 0, and process operating
labor total $.0432/1.0E06-0qAtu. gas. Maintenance labor,
supervision labor, administration and general overhead,
operating and maintenance supplies are from (8303,AI-5).
The total gross operating cost is $.1728/1.OE06 Btu gas
for a 247.2EO9.Btu/D SNG plant. By-products are credited
at $108q/8qLTS (91 LTS/D) $25/T NH (123 TPD N4qK ),$.15/gal
B-T-X (456EO3 GPD)and '$.30/1.02q206 Btu tars 123EO9 Btu/
D) from (8303,AI-5). The total net operating cost is
$8.19EO6/yr-or, for 7.84EO6 TPY coal, 5.96EO4 $/lOE12
Btu.
Capital and'operating costs were developed as follows.
Capital Costs-197 $-Plant-Basis-22,600 TPDpp LF
From (8300), escalated at 5 percent-from 1971 $, costs
for coal storage and preparation, feed system,
gasification and CO shift, g.as purification, methanation,
compression, 0 2 manufacture, steam,and power plant,,
general utilities, and general offsites total 180.7EO6
$. Water Ipollution control costs were estimated at
11.7EO6 $ from (2013,VII-5), (8304), and1p315).
S8qU'lfur recovery costs were estimated at 6EqO6 $ from
(830) and (8303,AI-25,AI-26). Capital cost was, reduced
by 20EO6 $ to reflect savings for a noncaking low
S western coal.-To the subtotal were added a 15 percent
-project contingency and,a 7 percent developement
contingency to give a total plant investment of
217.7EO6 $. Based on 10 percent/yr FCR and 7.41EqO6 TPY
coal, this becomes 1.q68Eq05 $/l.OE12 Btu.
Operating Costs-1972 $-Plant Basis-22,600 TPD, 90 P-LF
From (8300) directly:, catalysts and chemicals, purchased
raw H 0, and process operating labor total.066/1.qOE06
Btu g is. Maintenance'labor, supervion labor, adminis-
tration and general overhead, operating and maintenance
supplies are from (8303,AI-5). The total gross operating
Cost is $.2152/1.8qOE06 Btu gas for a 231.8E4qO9 Btu./D SNG
plant'. By-products are credited at $10/20qLTS (100 LTS/56qP),
.$25/T NH (127 TPD NH ), $.15/gal B-T-X (25000 GPD),
and [email protected] Btu tars (8.5E6qO9 Btu/D) from (8303,
AI-5). The total'net operating cost is:$12q.83E4qO6/y32qr
or, for,7.41E8qO6 TPY coal, 9.88E2qO4 $/l.2qOE12.Btu.
IV- 3 9,
�
�
FTN. 8390-8392
8390. Capital and-operating costs for-this--process are an.
arithmetic average of-those for-the,Hygas-Electrother-
mal, Hygas-Steam,Oxygen, Bi gas,.and Synthane processes.
8391 Capital and operating-costs were developed'as follows:
Capital Costs-1972 $-Plant-Basis@23,700 TPD, 90 P LF
Prom (8319,exhibit K page)'costs for process units,
utility'units, offsite units, water.pipeline', catalysts
and lubricants., general plant, engineering fees and
licenses, contingency, and start up total 321qAEq06
Based on 10 percent/yr FCR I and 7,77EO 6 TPY coal, this
becomes 2.36EO5 $/l.OE12 6qBtu.
Operating.Costs-1972 $-Plant'Basis-2300 T2qP4qD,, 90 P LF
From (8319,exhibit N,Schedule 3) the avantage-operating
and maintenance expenses for the-first.three years of
operation include costs for operation supervision and
engineering, other power expenses, other-process
production expenses, rents., maintance-supervision
and engineering,aintenance of- structures and
improvements, maintenance.of production equipment,
administrative and-general(less property insurance).
The total gro'ss-operating cost is $22.32EO-6/yr. By-
products are credited at $108q/8qLTS (98 0qLT8qS/D) , $25/T NH
(112 TPD), $.12q5/gal. B-T-X (63.64q903.8qG2qPqtq)q),an2qd,.$.30/1.qOE0q9
Btu tars (41.2EqO9 Btu/8qD). from.(q8303,AI-5).-The total
net operating cost is.$l3.88EO,6/yr-oqr, for-7.77EOq6 TPY
coal, 1.02EO5 $/l.OE12 Btu.
8392 Capital and opera ting costs were developed as follows:
Capital Costs-1972 $-Plant Baqs2qIA-28,300 TVD, 90 P LF
From (8300), escalated at 5 percent from 1971 $, costs
for coal storage and preparation, feed system',
gasification and CO shift, gas purification,.methanation,
compression, sulfur recovery, genekal-utilities, and
general offsites total 135E4qO6 $. Steam.and power-plant
costs are from (830q-0) with $200q-/KW:added,.for.on-site
generation of 2180 KW previously-purchased. Water.
pollution control costs were estiqmated,at.11.7E8qO6 $ from
(2013,8qVIIq-5), (8304), and (831q-50q)q,. To the-subtotal were
added a 15 percent project contingency and a 7 percent
development-contingency to give -a total-plant investment
of 193.332qE2qO6q6 $. Based:on-10 percent/yrq,FCR,and 9.30E06
TPY-coal, this becomes l.48E2qO5-$/l.2qOEl2q:Btu,
IV-40
�
�
8393-8401
Operating. Costs-1972 $-Plant Basi s-28,300 TPD, 90 P LF
From (8300) directly, catalysts and chemicals
purchased raw'H20, and process operating labor total
$.062/1.OE06 Btu gas. Maintenance labor, supervision
labor, administration-and general overhead, operating
and maintenance supplies are from (8303,AI-5). The total
gross operating cost is $.1808/1.,OE06 Btu gas for a
250E09 Btu/D SNG plant. By-products are credited at
$10/LTS (12 LTS/D), $4/LT S02 (649 LT S02/D),' and $25/T
NHj (170 TPD) from (8303,AI--5). The total netoperating
cost is $12.51EO6/yr or,for 9.3EO6 TPY coal, 9.55EO4
$/l.OE12 Btu.
8393 Thermal discharges can be completely eliminated by the
use of mechanical.draft wet cooling towers.
8400 The Northern Appalachia coal used in this study has the
following composition on a run-of-mine basis':
Proximate Analysis - WT PC
Btu/lb 12197 Ash 15.1
S_WT PC i.3 Water 2.5,
Vol.Mat 30.9
Fixed C.'. 51.5.
For this coal 411000 ton of coal is equivalent to
1.OE12 Btu.
8401 From (8300) thetotal heat,demand for a plant producing
253.5E09 Btu/D SNG is 113EO9 Btu/D and the TPD coal to
the gasifier is 16754. This analysis is for an Eastern
Bituminous coal with 83.4 percent volatile matter and
fixed carbon and a heating value of 12400 Btu/lb.-Based
on footnote 8400 and the assumption that the gasifier
outputs are the same for equivalent TPD of volatile 'J
and fixed carbon input to the gasifier (since these are
the reactive constituents in the coal), the.Northern
Appalachia analysis would require 16953 TPD coal to the;
gasifier. Based on the assumption that, the total.plant
heat demand is relatively.constaht for the various.
bituminous coal inputs, 1197 TPD coal is required for
boiler fuel. Thus a total of 18150 TPD coal is required,
to produce -253.3EO9 Btu/D.-SNG for a primary efficiency
of .572. This size plant also produces 9.84EO9 Btu/D of'
tars and 52.5EO3 GPD of light oils@!,(8300).
IV-41
�
FTN. 8402
If-these fuels-are considered then-the overall plant
efficiency becomes .608. The,ancillary energy is zero because the plant is selfrsustaining with all power and
steam requirements generated-onsighte.
8402 The.principal quantifiable a2p.pollutant,sources are,as
follows:
TPD
Part. SO CO HC NO other
0qx qx
Fuels Combustion .6.20 9.30 2.0 .564-2q40.0 ..00919
Sulfur Recovery Plant q1_q0q0
Storage and q)4isc. .001 .165
Fuels CoqmqbqAstion
Basedqlon a Iir emission factors in (q8301,1.1-3,1.4-2) and
the combustion f 2478.TPD of coal equivalent char (55',
percent ash, 1 percent S2p.1197 TPD coal (15 percent ash,
1.3 percent,S),-and 24i3EqO9.Btu/D waste.offgases
(contqaining.25 percent.of.the.total,S in the coal to
the gasifier). Particulates.were.-repdeced 99.5 percent.
by the use of.an.electrostatic-precipitator and-a
Wellman 1ord wet scrub7.while.8qS2qO emissions were
reduced 95 percent by the Welqima6qi'Lord0qU0qnqit.
Sulfur.qRecovery Plant
Based,on the'use of the,Rectisol acid gas,removal
systemor the selective removal of HS,and CO forq1qD4qM
the synthesis gas stream,.aonclentraqied(25.pqircent)
H S gas stream..canbe-sent to@the-Claus,plant for
recovery (8308,21), and,from (8q2022G3q).this Claus unit
can recovery'941percent of the incoming.-S. The incoming
S for.recovery is based on.169,56q3 TPD-coal to the
gasifier, 1.3 percent S in the.coal, and 55-percent of
the S to the gasifier as H 2S:to_Claus-foqr recovery (the
balance of.the S is@in the pretreatment offgases and the
char) from (8303,X.-13,and 8303'j;.27)..Based, furthermore,
on'30 percent of.total.S.to Claus as.-SO (8303,AI-27)
from the Wellman Lord scrubbing units4q17q'4q3q'20qVPD S is the
Claus feed. Thus 163 TPD S is.recovered ,along,00qmith an-
.additional (to thatw32qh2qichq.q-the Claus_c6qanq.q@accept) 93.6
TPD SO for sale. These.are equivalent to.368 ton S and
211 t32qd28qA So /16qOE12.Btu. Since,10q0 TP20qDq'Sq,.pasqses to the
Wellman Loqidq,tq*ai52qlgas.scrubbing ,unit, .5,TPD S or 1.0 TPD
so2 exits the stack.
IV-42
�
�
FTN. 8403-8404
Storage and Misc.
From (8300) 5.25EO4 GPD of,light oils are produced.,
Assuming 2 weeks storage capacity under new tank
conditions and emission factors from (8302,4.3-8), .001
TPD HC are emitted. Based on 16754 TPD coal to the
gasifier and 1.16 percent N in the-coal (8300) and 70
percent of the N in the feid coal as NH 3 (8303,X- J),
165 TPD NH is pioduced in the gasifier. This value
was used f8r this coal analysis. Substantially all of
this NH is recovered in a free and fixed ammonia still.
From (830.1,5.2-2) dontrolled storage and loading opera-
tions emit 2 lb of NH /ton NH Thus .165 TPD NH are
V
released into the atm8sphbre.
It should be noted that other sources of air pollution
will be present in any commerical coal gasification
operation, although their quantification is not
possible at present' These sources include, but are not
n
limited to, coal and other solids preparatio and
transfer operations, vent stacks for waste.gas
disposal, pipeline valves and flanges, and pump and
compressor seals. The magnitude of-these air pollutants,
however, should not be'that large if the sources are
properly control-led.
8403 Based,on 18150 TPD coal with 15.1 percent ash, 2741 TPD
ash are produced. Since 6.2 TPD is'released to the
atmosphere as particulate,,2735 TPD remains as solid
waste for disposal. Based on 6500 GPM net makeup H 0
(8300) and an assumed 500 PPM suspended solids whicA is
completely removed by lime treatment.and clarificationr
an additional 19.5 TPD of solid waste is generated. From
(8304) an ammonia still is estimated to produce 115 ton/
D of still waste. It is assumed that all bio-treating
sludges are used as boiler fuel. The sum total solid
waste produced is thus 2869 TPD or 6480 ton/l.DE12 Btu.
8404 Land requirement's are assumed to-be 350 acres from,(9401,7.)
for coal storage, preparation, and gasification plant..
facilities. Since High Btu Coal Gasification is
as.sumed to be a mine-mouth activity, all solid waste
produced is returned to the mine for burial. There
is, therefore, no incremental land impact due to solid
waste production. Thus a total of 350 acres is re-
quired for a 18,150'TPD coal gasification operation.
With a 90 percent operating factor this is equivalent
to 2.41 acre-yr/l.OE12 Btu. However, a larger land
impact would be.produced if solid wastes were not re-
turned to the mine for burial. (S-ee footnote 8403 for
solid waste.)
IV-43
�
FTN 8405-8406
4q0 ng
8405, From(83 '00) the,total heat demand for@a:plant producii
247.26q=6q9,Btu/D of SNGis 730qAE09 Btu/2qD'and the TPD
coal to the-gasifier is @14'6q957. This'analysis is for an
Eastern Bituminous coal with 83.4 percent-qvqo2qlatile
matter and fixed carbon-and @a heating value of 12400 Btu/
lb. Based on footnote 840 0and the,assumption that the
gasifier outputs are the same 'for,equivalent TPD of
volatile and fixed carbon,input to 4qthe gasifier (since
these are the reactive constituen 8qt's'in the-6qCoal), the.
Northern Appalachia analysis would require.15135 TPD
coal to the gasifi6q64qr'. Based on'-the assumption that the
total plant heat demand is relatively constant for the
various bituminous- coal, inputs-- 2124, TPD coal. is *required.
u
for boiler fuel' Thus-a total of lq72q59,T6qPD,coal is
-Btu/D Sq1q4G"for-a primary
required to produce 247.2EqO9
efficiency of .587. This size@plantt also produces@q80q4q84E
09 Btu/D@ of tars and-, 4 66qSqQ3 i'6qM of light oils (82q300) If
these fuels are co2qf2qtsid(q@4qr2qed' then'the,overall plant
efficiency becomes'.620. The.ancillary energy is zero
because the plant is self-sustaining ,with all power and
steam requirements generated on-sit p.
8406 The principal quantifiable-air pollutant sources are as
follows:
TPD
Part. sox CO' H0qC N4qO6qx Other
Fuels@Combustion 1.28 7.55 1.23 .32925.3 .00531
Sulfur Recovery Plant 1.00:
Storage and Misc. .00q1 .148.-
Fuels-Combustion
Based on air emissions factors in.-(8301,1.1-3,1.4-2) and
the combustion of 2124 TP4qD,coal (15percent ash-, 1.3
percent S) and 21.6EqO9"Btu/D:water,offgAseq6"(containing
.25 percent of the total S in the d6qdqal to the@gasifier).
Particulates were reduced:99.5 percrent.by the-use of an
eleptrostatic.precipitator and a Wellman.Lord wet scrub,
while SO, emissions-were"reduced 950qt'q-36qperce20qhtq'b36qyq'the
Wellman Lord unit.
IV-44
�
�
FTN. 8406 (Cont)
Sulfur Recovery Plant
Based on the use of the Rectisol Acid gas removal system,
for the selective.removal Of H2S and C02 from the synth@
esis gas stream, a concentrated (25 percen .t) H2S gas
stream can be sent,to the Claus plant for recovery
(8308,21), and from (2022,103) this Claus unit can
recover 94 percent of the incoming S.-The incoming S
for recovery is based on 15135 TPD coal to the gasifier,
1.3 percent S in the coal, and 55 percent of the S to
Ft the gasifier as H2S to Claus for recovery (the balance
of the S is in the pretreatment offgases'and the char)
from (8303,X-i3,-and 8303,27). Based,.fu.rthermore, on
30 percent of total S toClaus.as S02 (8303,AI-27) from
F the Wellman Lord scrubbing units, 155'TPD S is the Claus
feed.-Thus 145 TPD S is recovered along with an addition-
al (to that'which the Claus can accept) 68 1.2,TPD S02 for
,sale. These are equivalent to 345 ton'S and 162'ton
OE12 Btu. Since 9.3 TPD S passes to the Wellman
S02/1
Lord tailgas scrubbing unit, .5 TPD S or 1.0. TPDS02
exits the stack.
Storage-and Misc.
From (8300) 4.63E'O4 GPD of light oils are produced.
Assuming 2,weeks storage capacity'under new tank
conditions and emission factors from (8302,4.3-8),-.001
TPD,HC are emitted. Based on 14957 TPD coal to the
gasifier and,1.16 percent N in the coal (8.300.1) and 70
2 (83
percent of the N2 in the feed coal as NH3 03,X-7),
148 TPD NH3 is produced in the gasifier. This value
was used for this,coal-analysis. Substantially-all.of
this'NH3 is-recovered in.a free and fixed ammonia still.
From (8301,5.2-2) controlled storage and loading
operations emit two lb of,NH3/ton NH3-.Thus ..l 48 TPD NH3
are released to the atmosphere.
It should be-noted.that other sources of air pollution
will be,present in any.,commercial coalgasification
operation, although their quantif,ication.is not possible
at present.' These sources include, but are not limited
to.,'coal and other solids preparation an'd-transfer
operations, vent stacks for waste gas disposal, pipeline
valves and flanges, and pump and compressor seals. The
magnitude ofthese air pollutants,-howe'der, should not
be that large if the sources are properly controlled.
IV-45
�
FTN. 8407-8409
8407 Based on 17,259 TPD coal with-1-5.1 percent,ash, 2606 TPD
ash are-produced. Since 1.3 TPD is released to the
atmosphere as particulate, 2605 TPD,remains-as solid
waste for disposal. Based on 46 *00 GPM net:makeup H20
(83.00) and an assumed 500 PP4qM suspended.solids which is
completely removed by lime treatment and clarification,
an additional 13.8 TPD of -solid waste is generated. From
(8304) an,ammonia still is estimated to:produce 115
ton/Df still waste., It is assumed that all bio-treating
sludges-are-used as boiler-fuel. The-sum,total solid
waste produced is thus 2732q3 TPD or 6492q2 ton/l.2qOE12 Btu.
8408 Land requirements are assumed to be 350,acres from (9401,7) fo:
coal storage preparation, and2qqq4,qaification plant
facilities. 'Since High Btu C0.G0qasifation is
assumed to be a-mine-mouth activity, all.solid waste
produced is-returned to-the mine for burial.. There
is, therefore, no incremental.land @impactdue to.solid
waste production. Thus a total-of 350 acres is re-
quired for a 17,259-TPD coal gas qification.operation.
With a 90 percent operating factor this is equivalent
.to 2.53 qacre-yr/l.OE12 Btu. However, a larger-land
impact would be produced if solid:waste awere not re-
turned to the mine for.burial. (See footnote-8.407 for
solid waste.)
8409 From (8300) and'(830:9).the total heat demand for a plant
producing 231.88qEq09 Btu/Df SNG is 116.3EO:9 2qBtu/Dand
the @TPD coal to the gasifier is 14594. Thi.s analysis is
for an Eastern Bituminous coal with. .86.9 percent
volatile matter and fixed carbon.and.a heating,value
of 12400Btu/lb. Based on foot-noteL 84,00-and the as
sumption that the gasifier outputs are4qthe same for
equivalent TPD of volatile and fixed,carbon input to
the gasifter since these are the reactive.constituents
in the coal), the,Northern Appalachia analys,is would
require 15391 TPD coal to the-gasqfier. Based.on the
assumption that the total plant heat demand is
-relatively cons,qtant for the various, bitumiqnous'coal,
inputs, 2358 TPD coal'is required.for boiler fuel. Thus
a total of 17749 TPD coal is.-required to produce 231.8E
09 Btu/D SNG for' a.primary efficiency,of...535. This
size plant. also produces, 13..9E2qO,2qR Btu/D of tars (830.0)
and,2500,0.GPD of light oils (8307,2q:6). If these,fuels
are considered, then the overall Plant efficiency
ernergy -6qzero-because the
becomes .576q5. The ancillary en is
plant is self-sustaining with aqlql:power.and steam
requirements generated on-site.
IV-A 6
�
�
FTN. 8410
8410 The principal quantifiable air pollutant sources are As
follows:
TPD
Part. so CO HC NO Other
x x
FU61S Combustion .6.66 4.08 2.40 ..721 43.2 .0120
Sulfur Recovery Plant 4. 00@
Storage.and Misc. .402
.Fuels Combustion
Based-on air.emissions factor s in (8301,1.1-3) and
the combustion of@2448 TPD -of coal equivalent char
(53.5. percent-ash,,..5 percent,S) and 2358 TPEJ coal
(15 percent.-ash, 1.3 percent S)...Particulates were
reduced, 99r.5@percent-,by the use of,an electrostatic
precipitatorand a Wellman Lord wet scrub,.while
so emissions were reduced 95 percent by the Wellman
Loid unit.
Sulfur Recovery Plant
Based on the use of the Hot Carbonate acid.gas removal
system for nonselective removal of H S And CO from the
synthesisgas stream, a dilute (5 peiceht) H @ gas
stream can,be sent tothe Claus plant. for regovery, and
from (8303,AI-25).this Claus unit can recover 84 percent
of the incoming S. The incoming S for recovery is based.
on.153.9l'TPD coal to the gasifier, 1.3 percent S in the
coal and 87,percent of the S to the gasifier as H S to
2
Claus for recovery (the balance of the S is in the char
(10 percent) and tar (3 percent)) from (8307,9). Based,
furthermore, on.complete recycle to Claus *of all the
so recovered-in the Wellman Lord scrubbing units on
thi boiler flue gases and Clau's tailg4ses, 251 TPD S is
the Claus feed. Thus 211 TPD S is recovered for sale or
487 ton S/l.0E12 Btu. Since 40.1 TPD S passes to the
Wellman Lord tailgas scrubbing unit, 2.0 TPDS or 4.0
TPD SO exits the stack,
.2
IV-47
�
FTN. 8411-8412
Storage and-Misc.
Based on@, 14594 TPD coal to the gasifier and 1.4 percent
N2 in the coal (8300) and (8309) and 70 percent of the
N in the feed coal as NH (8303,X-7),. 114 TPD NH i
3 3 is
pioduced in the gasifier. This value was'used for this
coal analysis. Substantially a1l.of this NH is
recovered in a free and fixed ammonia-:still. From
(8301,5.'2-2) controlled storage and loading operations
emit 2.ib of NH . /ton.NH,. Thus .174 TPD.NH 3 are
released into tRe atmos here.
It should be noted that other sources of 6Lir pollution
will be@present in any commercial,coal gasification
operation, although theirquantification is n6t
possible at present. These sources include, but are not
limitedito, coal and other solids preparation and
transfer operations; vent stacks for wastegas disposal,
pipeline valves and flanges, and pump and compressor
seals. The magnitude of these air pollutants, however,
should not be that large if the sources are properly
controlled.
8,411 Based on 17L749'TPD coal with 15.1 percent ash, 2680 TPD,
ash are produced. Since 6.7 TPD is. released to the
atmosphere*as particulate, 2673 TPD remains as solid
waste for disposal. Based on,17700 GPM.net makeup H 0
(8300) and an assurfied.500 PPM suspended,solids.whicA is..
completely removed by lime treatment and,clarification,
an additional 53.2 TPD of solid waste is generated. From
(8304) an ammonia still 'is estimated to produce 115 ton/
D of still waste It'is assumed that all bio-treating fF,
sludges'are used as boiler fuel..The'sum total solid
waste produced is thus 2841 TPD or 6563 ton/l.OE12 Btu.,
8412 Land requirements are assumed to-be 350,acres from (9401,7) for
coal storage, preparation, and gasification plant
facilities. Since High Btu-Coal Gasification,is
assumed to be a mine"mouth,activity, all solid waste
produced is.returned to the mine,for burial. There
is, therefore,.no incremental land impact due to
solid waste production. Thus a total of 350 acres
is required.for a 17,749 TPD coal.,gasi.fication opera-
tion. With a 90 percent operating factor this is
equivalent to 2.46 acre-yr/l.OE12 Btu. However, a
larger land impact would be produced if solid wastes
were not returned to the mine.for burial. (See,
footnote'.8411 for solid waste.)
�
FTN. 8413-8414
8413 From (8305i63) the total heat demand for a plant
producing 235.8EO9 Btu/D'of SNG is 2299 TPD coal and
the TPD coal to the gasifier'is-12224. This analysis is
for a West Kentucky seam coal with a 84.9 percent
volatile matter and fixed carbon,and a heating value of
12330 Btu/lb. Based on footnote 8400 and the assumption
that the gasifier outputs are the same for equivalent
TPD of volatile matter and fixed -carbon inputto.the
gasifier (s'ince these'are the reactive constituents in
the coal),the Northern Appalachia -analysis would require
12595 TPD coal to the gasifier.' Based on the assumption
that the total plant heat demand is relatively constant
for the various bitumi *nous coal inputs, 2179 TPD coal
is required for boiler fuel (with no coal drying)-. Thus A
total of 14774 TPD coal is required to produce-'235.8EO9
Btu/D SNG for a primary efficiency of .654. No light or
heavy oils'.aZe reported as by-products for'this process-
-The ancillary,energy is zero because the plant is self-
all power and-steam requirements
generated on-site.
8414 The principal quantifiable Air pollutant sources are as
follows:
TPD
Part. Sbx CO HC NOX@ Other
Fuels Combustion 1.32 2.69 1.09 .327 19.6 .00545
Sulfur Recovery Plant: 3.60
Storage and Misc. ..142
Fuels Combustion'
Based on air emissions factors,in (8301,1.1-3) and the
combustion of 2179 TPD of coal (1501 percent ash, 1.3
percent S).. Particulates were reduced 99.5 percent by
the use of an electrostatic precipitator and a Wellman
Lord wet scrub, while S02'emissions were reduced 95
percent by the Wellman-Lord unit.
IV-49
�
FTN. 8414 (cont)
Sulfur, Recovery,Plant
Based'on the use of:-the Hot Carbonate.acid,...gas, removal
system for nonselective removaLof,H2S and C02 from the
syqnthesis'gas stream .a.dilute(5 percent,q) H2S gas-
2qp
stream can be sent,to [email protected]@recovery and.
-,from (8303,AI-25) this Claus.unit,can.recover-84 percent
of the incomingS. The incomingpp2precovery is-based:
on 12595 TP0qD coal to1pgasifier.3 percent.S.in the
coal, and all of he S to'the-gasifier-as_H2S to-Claus.
for recovery.from(8305 '61). Basedpthermore, on
complete recycle. to- Claus@ of,, all. the., S02,;qrecovered An
e Wellman.Lord prubbing.units on.the boiler flue.
..gases and-Claus,tailgases, 223,TPD.S is in.the.Claus
feed. Thus 187 TPD S is recovered for leor 520 ton
S/l.qO4qE12 Btu. Since.36 TPD S passes.to the Wellman.@0qLord
tailgas scrubbing unit, 1.8 TPD Sr.3.6 TPD S02 exits
the stack.
Storage and Misc
Based on 12224 TPD coaLto the gasifier and q1.37 percent..
N2 in the coal (8305,60,63 'and.7o.percent,of the N2in
the feed coal, as.NHj, (q8302q3-X-7), 14.2@'TPD@@.-NH uced
I 3-q1s prod
in the gasifier.This value was l used .for.this .coal
analysis. Substantially of this- NHi verq6d,in-
3 is@reco
a free and fixed@moniqa., still..., From, q18,30q1: 5.2-2)
controlled storage,and loading,operations,emit.two lb 2qof
NH3/8qtonNH-3.. Thus .142,TPD,NH3are-qr.eleased2pto the
atmosphere.*
It should-be noted, that!. other,', sources@:-of-.;ir -pollution
will be, present.in any Fomme-rc-ial,,c.o-a-gasfication
operation, although.their quantifqication is not possible
at present. These-sources include but arenot .limited.
to, coal and other solids,preparation*a d-transfer
operations .vents tacks for,waste gas,,disposall, pipeline
valves and flanges and pumpand-compressor se als. The
magnitude of these:air pollutants,,,,however, should not
be that large -if the sources-,*a-re: properly - -cont6qro 1 led.
IV- 5.0
�
�
FTN. 8415-842*0
9415 Based on 14774 TPD coal with 15.1 percent ash, 2231
TPD ash are produced. Since 1.3 TPD is released to the
atmosphere as particulate, 2230 TPD remains as solid
waste for disposal. Based on 10385 GPM net makeup H20
(8300) and an assumed,500 PPM suspended solids which is
completely removed by lime treatment and clarification,
an additional 31.2 TPD of solid waste is generated. From
(8304) an anmionia still is estimated to produce 115 TPD
of still waste. It is assumed that all bio-treating
sludges are used as boiler fuel. The,sum total solid
wasteproduced is thus 2375 TPD or 6592 ton/l.OE12 Btu.
8416 Land requirements are assumed to be 350 acres from (9401,7)
for coal storage, preparation, and gasification.plant
facilities. Since High Btu Coal Gasification is
assumed to be.a--mine-mouth activity, all solid.waste
produced is returned to the mine for burial.. There
is, therefore, no incremental land impact due to
solid waste-production. Thus.a total of 350 acres
is required for a 14774 TPD coal gasification opera-
tion. With a 90 percent operating-factor this is
equivalent to 2.96 acre-yr/l.OE12 Btu. However, A
larger land impact would be produced if solid wastes
were not returned to the mine for burial. (See
footnote 8415 for solid waste.)
8417 Primary efficiency and ancillary energy for this
process are an arithmetic average of those for the
Hygas-Electrothermal, Hygas-Steam Oxygen, Bigas, and
Synthane processes.
8418 Air pollutants for this process are@an arithmetic
average of those for the Hygas-Electrothermal, Hygas-
Steam Oxygen, Bigas, and Synthane processes.
8419 Solid waste production for this process is an.arithmetic
average of those for the Hygas-Electrotherma,lp Hygas-
Steam Oxygen, Bigas, and Synthane processes.
84@Q Land utili.zation by.this process is an arithmetic
average of those used by the Hygas-Electrothermal,
Hygas-Steam Oxygen, Bigas, and Synthane processes.
IV-51
�
FTN. 8421
8421 Water pollutants are based on the following process
waste water analysis:
Contaminant Waste,Water-PPM Reference 0qEff.luent-PPM
Plqhenols 1700 (8307,4) 0.006
Cyanide 0.6 (8 8q108q3 -,q4) 0.3
Thiocyanates 188 (830q7,A) q0.q0
NH .17040 Calculated. 7.0
Sufide 1400. (8q102q7q4 4) - 0.01
oil. 1100: (88q303,0qK-3) 3.7
Sus.Solids 600 (8307,4) 4_6q1
The following waste water -treatment system was..utilized
to achieve the above'effluent values,--3 stages of oil-
water separation, dissolvedaiq; flotation., free and
fixed ammonia stills, equalization, activated sludge and
clarif ication., and char- polishing. tower,._ Three, stages of
oil-water separation,, were used to :insure comRq1ete
separation of the:.tars@;and process@waste,water.p'310, III-
Anq(air flotatqionl.unit-was,us'ed ,to-further remove
oil'. and- suspended. solids (.831@1,3.21.).-Bas@ed-:2pn.,coke plant
experience (112q19), (8312),and@(831:3,61-8)mmonia removal
appears to-be,the key-qt2qp treatment of weak ammonia
water Is very
liquor. Since.-the above proces qa-waste
similar to qWAL, a free and -fixedi*ammonia,sti1l'operation
was, employed. Phenol6qbiodegradation in-an Tactivated - I
sludge unit has,been succesfully demonstratedpn coke
plant WAL(8312,202)'.. CompleteT:thiocy.an-ate.rem6val is
possible by biodegrad-ation-:of 8qLthat,has-previously
been-deammoniated(8313I6l.8)PDtemissions-are based on
1 ton H 0/ton coal. to the: gasi8qf, ier . f or-,--a Typical New
rocessil5370 TPD)and0 percentof thisH 0 as process
waste water condensate(9220P8qDq)' from 0q18312qfq). other.
dissolved,solids TPD emissions are-based-on a Typical
New Process makeup H20.requirement of 9800GPM (8300),
an assumed influent TDS loading of.8q5q0q0 PPM and..a
contribution of other dissolved-solids.-by the-
gasification facility of,50,per,[email protected],incoming TDS
(similar to-refinery operations 'q(831q'7q-q@q,q@6q8) and, also from
(1900)). These ODS are.contribute32qd-q-'by ion@'exchange
regq'enqerants, treat40qin32qgq,q-chemicalsq., corrqasioniand
scale inhibitors, etc.,Organics comprisqe@phenols.
and oil, while total dissolvec8qLq.solids inclucDes.,cyanide,
thiocya24qnates, NH3q, sulfide,,and-,.,other.,dissolved solids.
waste water system removal.ef-ficiencies: [email protected]
from (2013q,4qI24qVq-3),,(8316,172) (8318,Table 7) and56qA8313,
609,618).-Tons/l.2qOE12 Btu based@on an [email protected]
�
�
FTN 8422-
of 16980 TPD coal.
8422 Capital and operating costs-were developed as follows:
Capital costs-1972 $-Plant Basis-14,800 TPD, 90 P LF
From (8300), escalated from 1971 $ to 1972 $ at 5
percent, costs for the feed system, gasification and
Co shift, methanation 0 2 manufacture, steam and power
plant, general utilities,-and general offsites total
119.2EO6 $. From (8305), escalated at 5 percent/year
from 1970 to 1972 $, costs for coal storage and
preparation and gas.purification total 44.3EO6 $.
Water pollution control costs were estimated at
11.7EO6 $ with oil-water separation and dissolved
air flotation costs from (2013,VII-5)costs for free
and fixed-NH- stills, equalization, activated sludge.
plus clarifition, and char polishing from(8304),
and a miscellaneous allowance (2.10qE66 $) for water
impounding basins, thickners, settlers, etc. from
(8315). Sulfur recovery costs were estimated at 8.7EO6
.$ from (8300) and (8303,AI-25,AI-26). To the subtotal
were added a 15 percent (of subtotal) project
contingency and a 7 percent (of-subtotal) development
contingency to arrive at a total plant investment of
2242qAE06 $.,Based on 'a 0qFCR.of 10 percent/year and
4.85EO6 TP6qY coal this is equivalent to 1.89EqO,5 $/
1.OE12 Btu.
'Operating Costs-2q1972 $-Plant Basis-14',800 TPD, 90 P.LF
From (8300) the following costs were taken directly
other rawmaterials, catalysts and,chemicals_, purchased
raw H Of and processope rating labor-for a total of
[email protected] Btu gas. From (8303,AI-5) maintenance
labor was based'on 1.5 percent/year of total plant
investment of supervision labor was based on 15 percent Of
process-operatinq and maintenance labor, administration
and general overhead was based on 60 percent of total
labor, operating supplies were based on-30 percent of
process operating labor, and maintenance supplies
were based on 1.5 percent/yr of total plant invest-
The total gross operating.cost is thus $.1995/
-2q1.2qOE06 Btu gas or 15.40E8qO6 $/yr for a 235.8E8qO9Btu/D 0qS6q@NG
plant. By-products are credited at $10/20qLT for S (167.3
LTS/D) and $25/T NH , (142.3.TPD NH ) from (8303,AIq- 5).
The total net operating cost is thqiref2qo,req,$13.6q8E8qO6/yr
or,for a 4.85E8q06TPY coal input, 1q.15E2qO5 $/8ql'8qOE12 Btu.
IV-53.
�
�
FTN. 8423
8423 Capital and operating costs wore-developed as follows:
Capital Costs 1972 $-Plant-Basis-18,200 TPD, 90 P:LF
971.$@to1972 $ at 5
From (8300), escalated,from 1
percent, costs for coal storage and preparation,
pretreatment, feed system,.gasification and CO.shift,
methahation, steam and,power plant,-general utilities,
and general offsites 'tqdta2qL_l75.6EqO6.$. From. (8300) cost,
for gas purification is.estimated at22'-9EO6 $. Water
pollution control costs iwq6re.:estimated at 11.7EqO6 $
with bil-water qs4qoparation-And-dissolved air flotation
costs from (,20l3,VII-5),costs -for'free and fixed NH
stills, equa'lization .activated -s2p2pp1pge plus clariqfqi2qh@
tion,@and@qch4qar:polishing from (8304), and a 8qmis6qdellan-
eous allowance.(2.lE:0'q6 $q) for.water.impounding,basins,
thickelners, settlers, etc. 'from 03'8q18q5q).-Sulfur recovery
costs'were estimated'at 13 8EO6 $-from (8300)nd
(8*303,AI-25,AI-26). To the* subtotal were added a 15
percent (of subtotal) Project contingency *and a 7
percent (4q6fq@"subtotal)-development contingency to arrive
Of q2q13q:;3EqO,6$.0qBased on a
at a- -total plant -investment .4
8qF2qCR of 10 percent/yr@:and 5.2q46EqO,6@TPY coal this is.
equivalent "to l6qZ,8'8q90 5 @, $/l,. qOE12 .-,,Btu.
Operating C2qosits-q1972 -$-Plant ;Basis-!.!18,.200,TPD 90 P LF
From-(8300) tqlqie@following"costs were-taken directly-
other raw materials, 'catalysts ,and '-chemicals, Purchased
raw Hq0, and-processqlq5erating-labor@for a total of
[email protected] ' I
$ 04q8, Btu gas. From (8303.'AI-5) maintenance labor
was qAsed on l..@5@perceqn't/yr-of"total,p,lant investment,
supervision labor 0qwas.-based on,15 percent of process
ting'and-maqiinteqna-nce.1-aboradministration and
opera,
general o2qV0qo6qrh2qead@was based 60 percent of total labor,
operating supplies were based.on 30percent of process
operating labor .and .maintenance supplies were based on
1.5 percent/yr of total plant-investment. The total gross
operating cost_is@thus $.q-2155/1q.qOE06 Btu gas or 17.90EqO6
$/yr q@f or a 25 3. 3E8qO9 -'-Btu/D- SNG -plant.- -.By-products 'are
cred36qi Ited At $10/24qLT"f00qor S (145,3q1q'20qLT32qS/D2q), $4/LT f6qorq,S20qO 2
(8q-3.48q0 LT S24qO56qi/D) $25/T NH 2q(32q165q"44qM NH 3), $.15/gal fox
q'2q5 03.q.GPD0q)qraqnd 0/1.q*2qOE06 q@q,B -
B-T-X (52q. tu for tars (9.84E8qO9
Btu/24qD,6q) from (83036q"A8qI6q-56q). Theq.total,net operating cost.
is tl0qiereforeqrq,q,12 q*40E2q06/yrq:q'or, for a 5.96E,06 TPY coal
input, 8.54E8qO4 $/l.8qO24qE12q,Btu.
IV- 5 4
�
�
FTN. 8424
8424 Capital and operating costs were developed as follows:.
Capital Costs-1972 $-Plant Basis-17,300 TPD, 90 P LF
From (8300), escalated from 1971 $ to 1972 $ at 5
percent,costs for coal storage and preparation, pretreat-
ment, feed system, gasification and CO shift,
methanation, oxygen manufacture, steam and power plant,
general utilities, and general offsites total 132AE06 $.
From (8300).cost for gas purification is estimated at
22AE06 $-. Water pollution control costs were estimated
at 11.7EO6 $ with oil-waterseparation and dissolved
air flotation costs from (2013,VII-5),costs for free
and fixed NH stills, equalization, activated sludge
plus clarifiLtion, and char polishing from (8304), and
a miscellaneous allowance (2.lEO6 $) for watdr impound-
ing basins,.thiPkeners, settlers, etc. from (8315).
Sulfur recovery costs were estimated at 13.IE06 $ from
(8300) and (8303,AI-25,AI-26). To the subtotal were
.added a 15 percent (of subtotal) project contingency
and a 7 percent (of subtotal) development contingency
to arrive at a total plant investment of 219.7EO6,$.
Based on a FCR of 10 percent/yr and 5.67EO6 TPY coal
this is equivalent to 1.59EO5 $/l.OE12.Btu.
Operating Costs-1972 $-Plant Basis-17,300.TPD, 90 P LF
From (8300) the following costs were taken.,directly-
other raw materials, catalysts and chemicals, purchased.
raw H 0, and process operating labor-for a total of
[email protected] Btu/gas. From (8303,AI-5) maintenance labor
was based on 1.5 percent/yr of total plant investment,
supervision.labor was based,on 15 percent of process
operating and maintenance labor, administration and
general overhead was. based on 60 percent of total labor,
operating supplies were based-on 30 percent of process
operating labor, and maintenance supplies were-based on
1.5,percent/yr of total plant investment. The total
gross operating cost is thus $.1886/1.OE06 Btu gas or
'SNG plant. By-
15.30EO6 $/yr for a 247.2EO9 Btu/D,
products were credited at $10/LT for S (129.7 LTS/b),
$4/LT for SO2 (60.9 LT SO2/D), $25/T NH (147.5 TPD -NH 3)"
$.15/gal for B-T-X (46EO3 GPD), and '$.3d/l.OE06 Btu
,for tars (8.84EO9 Btu/D) from (8303,AI-5).The total.net
operating cost is therefore $10.43EO6/yr orl fo'r-a 5.67
E06 TPY coal input, 7.55EO4 $/l.OE12 Btu.
IV-55
�
FTN 8425
8425 Capital and operating,costs"were@,developed as follows:
Capital Costs-1972$-Plant Basis-12q3,7q60. TPD,.90 P LF
From (8300), escalated from 1971.$ to.1972 $ at 5
percent, costs for coal storage and preparation, feed
system, gasification and CO shift, gas,purification,-.
methanation, compression, oxygen manufacture, steam and
power plant, general utilities and general offsites-
total l53.8EO6 $. Water pollution-control costs were
estimated at 11.7EqO6.$ with oil water separation.and
disso1ved air.. flotation, costs from: (20:13',VII-5), costs-
for freeand fixed N-H sti0qIil6qs f equalization, activated
slud4qq2qp.plus clarfication,. and char.-- polishing f rom
(8304q), and a miscellaneous allowance (2.lEqO,q6'$q) for
water @impounding,.basins thick eners settlers, etc.
from (8315). Sulfur.recovery costs were estimated at
14.96qk'06 $ from (830,0) and (830q310qXI-25,AI-26). To the
subtotal were-added@a 15 percent (ofsubtotal) project
contingency and.1.7 percent.(of.subtotal), development
contingency -to arrive at. a :total plant investment of
220.1EqO6 $_ Based on,-a-FCR of. 10.'percent/yr and
5. 83E'06. TPY coal -this. is:, equivalent*- to71.55EqO0qS $/ql qOE12
Btu.
Operating Costs@-1972- $-!-Plant, Basis-17,6q700 TPD, 90 P L2qP
From,q(8300). the, f ollowwing. costs -wer taken. directly
cataql2qysts@and chemica1s:,-purchased raw-H28q601 and process
operating.labor pr-a,total.of $.064/1.OE06 Btu gas.
From (8,303,AI-.-5) maintenance-labor was;based on 1.5
percent/year of total.plant investment; supervision labor
was based on 15 percent-of process operating and
maintenance .labor j administration and general overhead
was based on'60 percent.of total labor ,operating suppli-
es were based on.30@ Percent ,ofppoces,s-operating labor,
and maintenance supplies were?based!on 1.5 percent/year
of total plant investment. The@,tqotal gross operating cost
is thus $.2148/1.06q4q,06.Btu gas: or.l6q,.q32Eq,0'q6q. $/yr for a
231.8E2qO9 Btu/[email protected],q,q,.plan28qt.-By-productsqiwere credited at
$ 10/I4q@T f or Sq.q, (28q18 7. 5 LTS/D.2q)q@ , $q'25/44q7q@q'NH_3q, (17 3. 6 TPD NH3)
$.15/gal for B-T-X 6q(25000 GPD)q., and $-3'0/1q.q.2qOE06 Btu for
tars8ql6q(13q.q.9E2qO9 Btu/D2q)-4qfrom,@0q(8303q,q_AI-56q)q-2q: The.total net
operatingq.cost isq.20qtherefore $11,62E2q06/76qyr or, for-a
5.8364q406 TPY coal input.q,8.l8E6qO4q.$/l.2qOEl2q@Btu.
IV-56
�
�
FTN. 8426-8451
8426 Capital and operating costs for this process are an
arithmetic average of those for the Hygas-Electrothermal,
Hygas-Steam, Oxygen, Bigas, and Synthane processes.
8427 Thermal discharges can be completely eliminated by the
use of mechanical draft wet cooling towers.
The Central coal used in this study has the following
composition on a run-of-Imine basis:
Proximate Analysis-WT PC
Btu/lb 11364 Ash 11.2
S_WT PC 3.5 water 8.3
Vol.Mat. 37.5
Fixed C. 43.0
For this coal 4400O.ton of coaiis equivalent to 1.OE12
Btu.
8451 From (8300) the total heat demand for a plant producing
253.3EO9 Btu/D of SNG is 113E09 Btu/D and the TPD coal
to th'e gasifier is 16754. This analysis is for an Eastern
Bituminous coal with 83.4 percent volatile matter and
fixed carbon and a.heating value of 12400 Btu/lb. Based
on footnote 8450 and the assumption that the gasifier
outputs are the same for equivalent TPD of volatile and
fixed carbon input to the gasifier (since these are the.
reactive constituents in the coal),,the Central analysis
would require 17353 TPD coal-to the gasifier. Based on
the assumption that the total plant heat demand is
relatively constant for'the variousbituminous coal
inputs, 553 r"LPD Coal is required for boiler fuel. Thus a
total of.17906 TPD coal is required to produce 253.3EO9
Btu/D SNG for a primary efficiency of .622'. This size
plant also produces 9.84EO9 Btu/D-of tars and 52-5E03
GPD of light oils .(8300). If these fuels.are considered,
then the@overall plant efficiency is .*662-.. The ancillary
energy is zero.because the plant is self-sustaining with
all power and steam requirements generated on-site@
IV-57
�
FTN 8452
8452 The principal quantifiable air pollutant sources are as
follows:
TPD
Part. SOx CO HC NOx Other
Fuels Combustion 5.59 24.9 2.06 .571 40.4 .00931
Sulfur Recovery PLANT 2.8
Storage and Misc. .165
Fuels Combustion
Based on air emissions factors in (8301,1.1-3,1.4-2) and
the combustion of 3171 TPD of coal equivalent char (42
percent ash, 2.6 percent S), 553 TPD coal (11.2 percent
ash, 3.5 percent S) and 24.3E09 Btu/D waste offgases
(containing 25 percent of the total S in the coal to the
gasifer). Particulates were reduced 99.5 percent by the
use of an electrostic precipitator and a Wellman Lord
wet scrub, while SO2 emissions were reduced 95 percent
by the Wellman Lord unit.
Sulfer Recovery Plant
Based ib the use of the Rectisol acid gas removal
system for the selective removal of H2S and CO2 from
the synthesis gas stream, a concentrated (25 percent) H2S
gas stream can be sent to the Claus plant for recovery
(8308.21) and from (2022.103) this Claus unit can
recover 94 percent of the incoming S. The incoming S for
recovery is based on 17353 TPD coal to the gasifier, 3.5
percent S in the coal, and 55 percent of the S to the
gasifier as H3S to Claus for recovery (the balance of the
S is in the pretreatment offgases and the char) from
(8303, X-13, and 8308,27). Based, futhermore, on 30
percent of total S to Claus SO2 (8303. AI-27) from the
Wellman Lord scrubbing units, 477 TPD S is the Claus feed.
Thus 448 tPD S is recovered along with an additional (to
that which the Claus can accept) 242 TPD SO2 for sale.
These are equivalent to 1101 ton S and 594 ton SSO2/1.0E12
Btu. Since 29 TPD S passes to Wellman Lord tailgas
scrubbing unit, 1.4 TPD S or 2.8 TPD SO2 exits the stack.
IV-58
�
�
FTN. 8453-8454
Storage and Misc..
Based on 16754 TPD coal to the gasifier and 1.16 percent
N2 in the coal (8300)'and 70 percent of the N2 in the'
feed coal as NH (8303,X-7), 165 TPD NH3 is produced in
3 %
the gasifier. This value was used for this analysis.
Substantially all of,the NH3 is recovered in a free and
fixed NH3 still. From (8301,5.2--2) controlled storage
and loading operations emit two lb INH3/ton NH3. Thus
.165 TPD.NH3 are released into the atmosphere.
It should be noted that,other sources of air pollution
will be present in any commercial coal-gasi.fication
operation, although their quantification is not possible
at present. These@'sources include, but are not limited
to, coal and other solids preparation and-transfer
operations,,vent stacks for waste.gas disposal, pipeline
valves and flanges, and pump and compressor seals. The
magnitude of these air pollutants, however, should not
be that large if the sources are properly controlled.
8453 Ba sed on 17906 TPD coal with 11.2 percent ash, 2005 TPD
ash are produced. Since 6 TPD is released to the
atmosphere as particulate, 1999 TPD remaiiis as solid
waste for disposal. Based on 6500 GPM net makeup H20
(8300) and.an' assumed 500 PPM suspended solids which is
completely removed by lime treatment and clarification,
an additional 19.5 TPD of solid waste is generated. From
(8304) an ammonia still is estimated.to produce.115 TPD*
of'still waste. It is assumed that all bio-treating
sludges are used as boiler fuel. The sum total solid
waste produced is thus 2133 TPD or 5242 ton/l.OE12 Btu..
8454 Land requirements are assumed to be.350 acres from (9401,7)
for coal storage, preparation,'and gasification plant
facilities. Since High Btu Coal Gasification is
assumed to be a mine-mouth activity, all solid waste
produced is returned to the mine for burial. There
is, therefore, no incremental land impact due to solid
waste production. Thus a total of 350 acres is,re-.
quired for a 17906 TPD coal gasification operation.
With a 90 percent operating factor this is.equivalent
to 2.62 ac.re-yr/l.OE12 Btu. However, a larger land
impact would be produced if solid wastes were not re-
turned to the mine for'.burial. (See footnote 8453
for solid waste.)
IV-59
�
FTN.8455-8456
8455 From (832,00) the total heat.d4qema4qhd1p a plant producing
247.2EO9 Btu/D of:SNG is 4qTq3E09-Btu/D0qand.the TPD coal
to., the, gasifier, is 14-957. .This., analysis is, 'for :an
Eastern Bituminous -,coal with8q1@ 4,percent- volatile,
matter and fixed carbon and a heating value of 12400
Btu/lb. Based on footnote,8450,:anc;the-assumptin that,
q1 . s
the gasifier outputs are-the..s.a0qme,for.equivalent TPDof
volatile and fixed carbon,, input. to,, the - gasifier (since
these are)'the.reactive-contituents in the,coal), the
Central analysis would;re6qqq@
qa6ql4qre 5492 TP0qD,.coal to the
that --0qthe total.plant
.gasifier.; Based :on the,assumption
.,heat demaqadis-relativel -2qs4qt - for, the various
y con Ant.,
bituminous coal.inputs-, 15 7 5'-0qVPD --coal, is -required for
boiler fuel. Thus'a total,of 16q7067-TPD,coal is required
to produce 247.2EO9:@:Btu/4qD:,SNG-for a primary,efficy7860;5000;96;132qiency
of, .637. 'This .,.size- plant.also produc es8;4.EqO9,Btu/D of,
,tars and.10q46q-2q3EqO3, GP8qD@. of-l0qight i oilqg:q(q$3 If .these fuels
are considered, then the..overall plaqiitfficiency is
.675. The ancillary energy iszero 6qb0qecause.the plant is
self-sustaining.--- with., all power and.. stpam.,ge.6q4erated on-
site.
The prin0qcipa6qL,6qq4q4antifi4qab-qle,: 8qair:po;2q1u0qtant:@ources -2ppre as
follows:..
TPD.
Part. SO CO ',HC NO, Other
qx
Fuels Combustion 8qZ 6 7. 2 l's 8 1.30 .346.'1266qA .00561'
Sulfur-Recovery Plant 2i.6
Storage.and Misc. @0q0,q0 q1 .148
Fuels.Combustion
Based on air emissions .factors . in q(.83.0l,,l.'1-3,1.4-2) and
..the combustion of.668 ,TPD of-coal equivalent char (73-,
percent lash,. 4.6 7-percent S) , l57.6q5"TPD,. coal All. 2 percent
ash, 3.5 [email protected]),,,and,21,.q6E.0,9--Btu/Dwaste offgases.
(containing 25 to the
percent q@of q_t2qheq,2qto0qta,l S inq,q@-q-0qthe, coal
g4sif ierq-) Particulates q-08qv04qeqi4q@eqf 20qr16qeduceI52qd,:99_.5,.-percent by the
use of an electrostatic. pr ec 0qip32qIt20qator-q, .-and,. -a Wellman.Lord
wet scrub, while- S24q02q. q'em40q1ss ion @6qwere [email protected] 0q@98q5q- percent
by the Well1man.Lord -unit.
�
�
FTN. 8456 (Cont)
Sulfur Recovery Plant
Based on the use of the Rectisol acid gas removal
system for the selective removal of H2S and C02 from
the synthesis gas stream, a concentrated (25 percent)
H2S gas stream can be sent to Claus for recovery
(8308,21), and from (2022,103) this Claus unit can
recover 9.4@ percent of-the incoming S.,-The incoming S for
recovery is based on 15492.TPD coal*tb the,gasifier,
.3.5 percent S@coal, and 55 percent of the S as H S to
Claus for,recovery (the balance of.the S is in tAe
pretreatment offgases and the char),from (8303,X-13, and
8308,27).. Based, furthermore, on 30 percent of total S
to Claus as S02 ('8303,A!'-27) from the Wellman,Lotd
scrubbing units, 426 TPD S is the Claus feed.-Thus 400
TPD,S is recovered along with an additional (to that
which the Claus can accept) 207 TPD S02 for sale. These
are equivalent to 1031 ton S,and-533 ton S02/1-OE12 Btu.
Since 26 TPD S passes to the Wellman Lord tailgas
scrubbing unit, 1. .3 TPD S,or .2.6 TPD S02 exits.the stack.
Storage and Misc.
From (830b) 4.631@04 GPD of. light oils are produced.
Assuming 2 weeks storage capacity under new tank
conditions.and emission factors from (8302,4.3-8), .001
TPD HC are emitted. Based on 14957 TPD coal to.the
gasifier and 1.16 percent N2'in.the co 'al (8300) and
70 percent of the N2 in the feed coal as NH3 (8303,X-7),'
148 TPD NH3 is produced in the gasifier. This value was
used for this analysis.-Substantially all of this NH3
is recovered in a free and fixed NH3 still- From (8301,
5.2-2) controlled storage and loading operations emit 2
lb of,14H3/ton NH3 Thus .148 TPD NH3 are released into
the atmosphere..
It should be noted that other sources of air pollution
will be p"resent in any commercial coal gasification
operation, although their quantificat7ion i's not possible
at present. These sources include, but are not limited
to, coal and.other soli,ds pre .paration and transfer
operations, went stacks for waste gas disposal, pipeline-
valves and flanges, and pump and compressor seals. The
magnitude of these air pollutants, however, should not,
be that large if,the sources are properly controlled.
IV-61
�
FTN. 8457-8459
8457 Based on 17067'TPD coal with 11,2percent ash, 1912 TPD
astmosphere produced. Since 3 6qtPqlqb is'releasedto the
qd4qtqm4q6qs4qp0qf0qiere as particulate, 1909 TPD remains as,solid'''
-waste for disposal.. Based`:`2qo2qh`4600 GPM net makeup H20
(8300) 8qand assumed 500 PPM.suspended solids which
is completely re2qmo6qV2qdd"by,lime treatment an2qd@clarifica-
tion, a8qn additional 13.8'0qT8qP8qDof-solid-waste is generated.
From*, (8304) 0qaqn',ammonia still is estimated to produce
115 TPD f still waste. It is assumed that all bio-
treating sludges are used@4qas boiler,fuel. The sum total
solid waste produced is thus 2038 T8qPD-or 5253-ton/l.qOE12
Btu.
8458 Land re6qqu'irqe6qments-a8qke assumed to be 358qV8qacres from (9401,7)
-for coal storage, prep8qa0qiati4q6n, and.-2qg0qas0qification.plant
facilit qIes. Since.High@Btu Coal-Gasification is
assuqined to be-a-8qm in6q&-0qm2qOuth-acti8qVity, all.,s4qblql*d waste
produc4qed..is-8qzeturned t4qo-theine.f4q6r burial., There
is, therefore, no i6qf6qi'4qc4qk2qbqiqfqi8qbntal land im act due to solid
i 2qp
waste production. Th6qu*s@a total,of 352q0-acr4qes-is re-
quired6qtor a qi7q6q67 TPD-coal.gasif0qi0qcat0qion operation.
With a@,90 percent operating factor thiss equivalent
to 22p'acre-yr/l-.-,qOEl2 Btu. H6qbwever,,a.larger land
impact q1,qw0qouqld-, be produced If:` 4qso6q1d 6qw2qa,st4qeqs-,4qw6qere not re-.
4q'dq't -the- (S8qde.footnote'8457
turn0qe q@ 0 mine f0qor burial.
for solid qWa6qs4qt".qiiqe-2q0 d2p
8459 From 1p300) land (48-309) the :-.total heat demand for a plant
producing 23l2qA8qt0qO 8qBt6qu8q/D of -S2qNG 0qis 116-.:34qEqO9 Btu/D and
the TP8q6 coal''to the:6q4a8qsqi-qfi8qer i4qt@ 16q&0q5,94. 'This Analysis is.
for an4qZastern Bi0qtquqmiqrqi64qus,2qdo6qd2ql with @2q4q6 9-. percent
volatile, matter 8qan'd 8qf i6qk-ed c2qa8qkbonn4qaqxid. a heating value of
12400 4q8tu/1b. Based on-.f2qbot:qh(qjte--8'q450and the assumption
that the gasifiqcqir 4qOqiqit6qp@uts@'a2qt4q6"-t.'he;.qt;,4qA0qme':for equivalent
TPD of volatile ''And- 2qf6q14qked'- c8qa8qkb2qon input to -the gasifier
(since these are* the [email protected]:@q@4qdn,-s't-itue6qh,.ts in the coal)
the Central analysis- would,- 8qk0qe2qq8quire1pp2p2p5.4 - TPD coal to the
gas6qifi2q6r'.* Based 2qon 'the2qas2qsu2qm8qption, 'that @the, plant heat
dem'and:is re2qA6qitively4qdo8qhq6tbqint f6r'the"varqious bituminous
coal inputs, 1831 2qVPD "coal is-reqquired:f6qor boiler fuel.
Thus atotal of 172q585-8qVPDcoal-is required to produce
q.231. qSE09 Btu/D 0qZNG for a primary -qOf f8qi2qc-2qilency of. .580.
'This siq-ze'plant al q*so* 72qp32qk6du20qd24qbs l3q.-q.q'9,E8qO9 16qStu/D of tars
(2q9300), and 25000 -GPD q*q*24qof 'light o36qi-32q1q-s - (8-307,6) . If these
fuels 28qAre-con6qsid'er52q6d, t36qhen-theq.q-ov0qi0qerall-plant efficiency
,becomes .621. Theq:q@40qAncillaryq:q@e28qhergyq,is,q'zq4qE6qiroq,because the
plant is q's04qelf-s44quq.0q4tai32qh40qi36qhq' "with 00qal32qL powe16qr:-and steam
32q9
r04qequir'68qements g36q648qh40qd40qr0qa0qCt`44qdd,onq@q-q@6qsiteq'.
IV-6 2
�
�
FTN. 8460.
8460 The-principal quantifiable air pollutant sources are as
follows:
TPD
Part. sox CO HC NOX Other
Fuels Combustion 5.87. 9.93 2,48 .742 44.5 ..0124
Sulfur Recovery Plant 10.8
Storage and Misc.. .174
Fuels Combustion
.1.1-3) and the
Based on air emissions factors in (8301
combustion of 3110 TPD coal equivalent char (40.6
percent-ash, 1.3 percent S) and 1831 TPD coal (11.2
percent a8h,3.5 percent S). Particulat 'es were reduced
99.5.percent by the use of an electrostatic.precipitator
and a Wellman Lord wet scrubwhile S02 emissions were
reduced 95 percent by the Wellman Lord unit.
Sulfur Recovery Plant
Based on the.use of the Hot Carbonate 'acid gas removal
system for nonselective removal of H2S and C02from the
synthesis gas stream, a dilute (5-percent) H2S gas
stream can be sent to,the Claus plant for recovery, and
from (8503,AI-25) this Claus unit can recover 84 percent
of the incoming S. The.incoming,S for recovery is based.
on 15754 TPD coal, to'the gasifier, 3.'5 percent 8 in the
coal, and 87 percent of the S to the gasifier as H2S to
Claus for recovery (the balance.of..the Slis in the char
(10:percent)-and-tar (3 percent)) from (8307,9). Based,
furthermore,.on complete recycle to Claus,of all the S02
recovered in the W611man,Lor'd scrubbing units on the
boiler flue gases and Claus tailgases,-676 TPD S is the
Clkus feed. Thus 568 TPD S is recovered for sale,or 1421
ton S/1.OE1.2 Btu. Since*108.TPD S passes to the Wellman
Lord tailgas scrubbing unit, 5.4 TPD S or 10.8 TPD S02
exits the stack.
IV-63
�
FTN. 8461-8462
Storage and Misc.
Based on 14 5 9 4TPD coal t6qa1pe, gasift-8qer and 1. 4 percent
N2 in the coal (830-0)'and ('8309) and 70, 4qp4qercent of.the
N2 n the feed coal as-0qAq@ @,q(83'03',X`7)1p74`TPD NH3 is
produced in the-2qgasifier.' This value was used f4qor this
coal analysis" 'Sub's tanti a 2qIql0qy -alql- of this, NH3 As
recovered.in a free-and fi6qxe6qd-a0qmqrrqfonia-still.q@ From
q(8301,5.21 2) controlled storage a0qnd loading-6qpperat6qkons
emit - 2 11b of N3/t8qbn'N0qH3. Thus_174 TPD-NH3 are
released Into the.:, atmosphere.'
It should be noted that other sources lof.@ air, pollution
will-be present1pn,an qC' qxal- coal: 4qga0qs'if ic8qation
4qommer6qd
operation,' although'' their', q6qu2qanti8qfi0qcaqit6qio4qn is.,-,not possible
at preserqit.'ThqiqBse-2ppurces.-i@nclude,:-but--.a@rel@not limited
to, coal qiand other solids, p2qvEqiparaq:,tion.,-and-. transfer
operations, vent - st0qa0qc-k,,'s-,:f or@ waste 'gas disposal, pipeline
valves a4qhd@flanges,@-4qand 'xqimp qand,.c2qomp0qr.q4q2q@ssoqr' s,ea1s. The
0qp
magnitude of these air pollutants, however, should not
be that 1arg0qe,iqf.2ppe.-1Sources- ,are- properly @,co0qn4qtro 1 led.
8461 Based on,17585 TPD coal with 11.2 percent ash 1970
TPD *ash are produced. 'Since-6 T-PD is released i2qnto@,the
aqctmosphere.as"partipulate, l966qt-'T6qPqEq)'r6q6qr4qkqf2qxqrqfs -as- solid
waste for [email protected],on 'q1'q7'[email protected]:zqiqcqiqBt-,0qMa-keup H20
qz4qsq@,s q@q0q0 q'2qP8qP2qM"s6quspe4qnd2qe6qd @,qs0qbql_ids which is.
(83'00q) a-rid an@
0qc
0qm 4qu2qm2qb qiqcation@@
;132qo comPletely-removed
-s
an additional 6q50q1-.2 ,8qz4qpp,@ 6qo8ql,--6qsolqid, w0qa generated. From'
'(8304) a4qn am6qmonia`@ 8qUll, ,is. -2qe'qs,-ti6qmat2qed:. t
I Is 1 6q6 produce 115 TPD
of s0qti 11 waste. , It: i's ., 6qas0qt6qu6qMed - that, al 1'..bqio,- treating
sludges :a0qre. us,8q6d,:@.as-:2qh60qile0qr fuel. The_0q9U2qz:,t8qo4qtal solid
waste produced.. i1qs, thus.. 2.q16qJq2 TPD. .'or 6q5-q:q334-t2qon/ql. qOE12' Btu.
462 Land requirementsr-4qa0qxe% -assumed, to -b8qo- 0q150 4qacqries from (9401,.7q)
coal storage,, preparation,.: a8qh2qd-gaq:s6qiq;6qf-6qRq:4q@-tion -plant
T 6qP. 1@ ". qf. qa8qt.
'facilities. Si n2qce High, 8qBtuq:,Coal Ga0qzi qd4qca, ion is assumed
-to be,.. a 2qmine-0qm0qouth activity, - -all sb0q1i6q&'2qw0qWste "'produced
is returned to the-.0qmqine,f2qor burial. 'There,is, there-
fore, no, incremental land, impact- due. [email protected] waste
production. Thus a total of 350 acres us required for
a 17585 TPD.coal gasification operation.With a 90
percent. operatingq-factor this is equivalent to 2.67
acre-yr/l.6qOE,12 Btu., However, a-.larger land impact,would
be produced if_solidq.wastes werenot returned to the
mine for!32qburial. (See;32qfootnote 8q:4q,61 f24q6r':q,so32q1id waste.)'.
IV:, 64
�
�
FTN. 8463-8464
8463 From (8305,63) the'total heat.demand for a plant
producing 235.8E09 Btu/D of SNG is 2299 TYD coal and the
TPD coal to the.gasifier is 12224. This analysis is for
a West Kentucky,seam coal with 84.9 percent volatile
matter and fixed carbon and a heating value of 12330
Btu/lb-. Based on footnote 8450 and the assumption
that the gasifier outputs are the same for'equivalent
TPD of volatile'ahd fixed carbon input to the gasifier
(since these 'are the reactive constituents in the coal),
the Centra*l analysis would require 12892 TPb coal to the,
gasifier. Based on'the assumption that the total planti
heat demand is relativE@ly constantfor.the various
bituminous coal inputs',,12338 TPD coal is required for
boiler fuel and-156 TPD is needed for coal drying. Thus
a total of 15386 TPD coal is required to produce 235.8E
09.Btu/D SNG.for a primary efficiency of .674. No light
or heavy'oils are reported as by@products,f6r this
pro6ess. The.'ancillary energy,.is zero because the plant
.@is self-sustaining with all,power and steam requirements
generated on-site.
.8464 The principal quantifiable' air pollutant sources are as
follows:
TPD
Part. sox 'CO HCI NOX Other
Fuels'Corabustion 1.66 18.7 1.17 .351 21.9 .00585
Sulfur Recovery Plant 9.8
Storage.and Misc. .142
-Fu'els'Combustion
.Bas.ed@on air emissions factors in (8301,1.1-3) and the
combustion of 2,338 TPD coal (11.2 percent 'ash, 3.5
percent S).* Particulates were reduced 99.5 percent by
the use of an electrostatic precipitator and,a Wellman
Lord wet scrub, while S02 emissions were reduced 95
percent by-the Wellman Lord unit. Particulate emissions
in compliance with the New.Source Performance Standards
for coal thermal dryers arp limted to .03 grain/DSCF
(li2l). Based'on 24000 DSCF/ton dry coal input to the
dryer (1121) and 11,822 TPD dry coal to the dryer and
gasifier, .608 TPD of particulates are emitted.-Based
on .535 lb NOx/l.OE06 Btu coal fired (1121), 3.5,
percent S coal, and 1.56 TPD coal,for dryer fuel-, .948
TP.D NOX and 10.9 TPD S02 are als6 released from.the
Ithermal dr:Ver.
IV-65
�
FTN. 8464 (cont)
Sulfur Recovery Plant
Based on the use of the Hot Carbonate acid gas removal
system for nonselective removal of H2S and CO2 from the
synthesis gas stream, a dilute (5 percent) H3S gas
stream can be sent to the Claus plant for recovery and
from (8303, AI-25) this Claus unit can recover 84 percent
of the incoming S. The incoming S for recovery is based
on 12892 TPD coal to the gasifier, 3.5 percent S in the
coal, and all of the S to the gasifier as H2S to Claus
for recovery from (8305.61). Based futhermore on
complete recycle to Claus of all the SO2 recovered in
the Wellman Lord scrubbing, units on the boiler flue
gases and Claus tailgases, 619 TPD S is in the Claus
feed. Thus 520 TPD S is recovered for sale or 1487 ton
S\1.0E12 Btu. Since 99 TPD S passes to the Wellman Lord
tailgas scrubbing unit, 4.9 tpd S or 9.8 TPD SO2 exits
the stack.
Storage and Misc.
Based on 12224 TPD coal to the gasifier and 1.37 percent
N2 in the coal (8305,60,63) and 70 percent of the N2 in
the feed coal as NH3 (8303,X-7), 142 TPD NH3 is produced
in the gasifier. This value was used in this coal
analysis. Substantially all of this NH3 is recovered in
a free and fixed ammonia still. From (8301,5.2-2)
controlled storage and loading operation emit 2 lb of
NH3/ton NH3. Thus 142 TPD NH3 are released into the
atmosphere.
It should be noted that other sources of air pollution
will be present in any commercial coal gasification
operation, although their quantification is not possible
at present. These sources include, but are not limited
to, coal and other solids preparation and transfer
operations, vent stacks for waste gas disposal, pipeline
valves and flanges, and pump and compressor seals. The
magnitude of these air pollutants, however, should not be
that large if the sources are properly controlled.
�
�
N. 8465-8467
FT
8465 Based 'on 15386 TPD coal with 11.2 percent ash, 1723 TPD
,ash are produced. Since 2 TPD is released to the
atmosphere as particulate-, 1721.TPD remains as solid
waste for disposal. Based on 10.3.85 GPM net ipakeup H 0
(8300) and'an assumed SOOPPM suspended solids whic@ is
completely removed by lime.treatment and clarification,
an additional 31.2 TPD''of solid waste is generated. From
.(8304),an ammonia still is estimated to produce 115 TPD
of still waste. It is assumed that all bio-treating
sludges.are used as boiler fuel. The sum total solid
waste produced is thus 1867 TPD,or 5340 ton/l.OE12 Btu.
8466 Land requirements, are assumed to be 350 acres from'(9401,7) for,
c'oal-storage, preparation',-and gasification plant
facilities. Since High'Btu Coal Gasification is
assumed to be a mine-mouth a6tivity,'all solid waste
produced is.retu.rned to-the mine for burial. There
is, therefore, no incremental land impact due to solid
waste production. Thus,a total of 350 acres"is re-
quired for a 15,386 TPD coal gasification operation.
With a 90 percent operating factor this is equivalent
to. 3.05 acre-yr/1'.OE12 Btu. However, a larger land
impact would be produced if solid wastes were not re-
turned to the mine for-burial. (See footnote 8465 for
solid waste,.)
8467 From (8300), and (8311) the total heat@demand for a plant
producing 237.OE09 Btu'/D of SNG is estimated to.be 3976
TPD-coal and.the TPD coal to the gasifier is 16.915. This
analysis is for a weakly paking.bituminous coal with
74.6.percent volatile matter and fixed carbon and a
heating value of 10190 Btu/lb. Based on footnote 8450,
the assumption that this coal is not too strongly
cakingfor use in a Lur4i gasifier, and the assumption
that the gasifier outputs are the same for equival.ent
TPD of.vola.tile,and fixed carbon input to the gasifier
(since th ese are the reactive constituents in the-coal),
the Central analysis would*require 15700 TPD coal to the
gasifier. Based on the assumption that the total plant
heat demand is relatively constant for the various
bituminous coal inputs, 3565 TPD coal is required for
boiler fuel. Thus a total.of 19265 TPD coal isrequired
to produce 237EO9 Btu/D SNG for a primary efficiency of
.541. This-size plant also produces 61700 GPD of light
oils (8300). Ifthis fuel is considered, then the overall
plant-efficiency becomes-555. The-ancillary energy is
zero because the plant'is self-sustaining with all
power and steam requirements generated on-site.
.IV-67
�
FTN. 8468
8468 The principal quantifiable air pollutant sources are as
follows:
TPD
Part. SOx CO HC NOx Other
Fuels Combustion 1.60 11.9 1.78 .534 32.1 .00889
Sulfer Recovery Plant 4.2
Storage and Misc .001 .187
Fuels Combustion
Based on air emissions factors in (8301,1.1-3) and the
combustion of 3565 TPD coal (11.2 percent ash, 3.5
percent S). Particulates were reduced 99.5 percent by
the use of an electrostatic precipitator and a Wellman
Lord wet scrub, while SO2 emissions were reduced 95
percent by the Wellman Lord unit.
Sulfur Recovery Unit
Based on the use of the Rectisol acid gas removal
system for the selective removal of H2S and CO2 from
the synthesis gas stream, a concentrated (25 percent)
H2S gas stream can be sent to the Claus plant for
recovery (8308,21) and from (2022,103) this Claus
unit can recover 94 percent of the incoming S. The
incoming S for recovery is based on 15700 TPD coal to
the gasifier, 3.5 percent S coal, and 98 percent of the
S to the gasifier as H2S to Claus for recovery (the
balance of the S is in the by-products) from (8310)
Based, futhermore, on complete recycle to Claus of all
the SO2 recovered in the Wellman Lord scrubbing units
on the boiler flue gases and Claus tailgases, 691 TPD
S is the Claus feed. Thus 649 TPD S is recovered for
sale or 1483 ton S/1.0E12 Btu. Since 41 TPD S passes to
the Wellman Lord tailgas scrubbing unit, 2.1 TPD S or
4.2 TPD SO2 exits the stack.
�
FTN.' 8469-8470
Storage and Misc..
From (8300) 6.17EO4 GPD of light-0'ils are produced.
Assuming 2 weeks storage capacity.under.new tank
conditions and emission factors from (8302-,4.3-8), .001
to the
TPD Hc are emitted. Based on 15700 TPD coal 4
gasifier and 1.4 percent N2 in the coal and 7.0 percent
of the N2 in the feed coal as NH-3 (8303,X-7), 187.TPD
NH@ is produced in the gasifier. Substantially all of
this NH3.is recovered in a free and-fixed ammonia still.
From (8301,5.2-2) controlled.storage and loading
operations emit 2 lb of NH3/ton'NH,3., Thus .187 TPD
NH3 are released into the atmosphere.
It should be noted that other sources of air pollution
will be present,in any commercial coal gasification
operation', although their quantification is not possible
at present. These sources-include, but are not limited
to, coal and other solids preparation and transfer
operation, vent stacks for waste gas'disppsal, pipeline
valves and flanges, and.pump and compressor seals. The
magnitude of these air pollutants, however, should not
be that large if the sources are properly controlled.
8469 Based on 19265 TPD.coal with 11.2 percent ash, 2158
ash are produced. Since 2 TPD is released to the
atmosphe re as particulate, 2156 TPD remains as solid
waste for disposal. Based on 12430 GPM net makeup
H20 (8300)'and an assumed 500 PPM.suspended solids which
is completely removed,by lime treatment and clarification,
an additional 37.3 TPD of solid waste is generated. From
(8304) an ammonia still.is estimated to produce 115 TPD
of still waste..It is assumed that all bio-treating
sludges are used as boiler fuel. The sum total solid
waste produced.is thus 2308 TPD or 5271 ton/l.OE12 Btu.
847.0 Land requirements are assumed to be'350 acres 'from (9401,7) for
coal storage, preparation, and gasification plant
facilities. Since High Btu Coal Gasification is assumed
to be a mi,ne-mouth activity, all solid waste produced is
returned to the mine for burial. There is, therefore,
no incremental land impact due.to solid waste produc-
tio'n. Thus a total of 350 acres is required for a
19265 TPD coal gasification operation. With-a 90 per-,
cent operating factor this is equivalent-to 2.43 acre-yr/
1.OE12 Btu. However, a larger land impact would be pro-
duced if solid wastes were not returned to themine for,
burial. (See footnote 8469 for solid waste.)
IV-69
�
FTN 8471
8471 Water pollutants are based on the following process
waste waster amalysis:
Contaminant Waste Water-PPM Reference Effluent-PPM
Phenols 9960 (8310) 0.498
Cyanide - (8303,S-9) -
Thiocyanates - (8303,X-9) -
NH3 15900 Calculated 15.9
Sulfide 1400 (8307,4) 1.4
Oil 1100 (8307,X-3) 15.4
Sus. Solids 600 (8307,4) 33.5
The following waste water treatment system was
utilized to achieve the above effluent values - 3
stages of tar-oil-water separation, filtration, a
Phenosolvan recovery unit, free and fixed ammonia
stills, and activated carbon. Three stages of tar-oil-
water separation were used to insure complete separation
of the tars, oils, and process waste water (8310, III-08-
1). Filtration and a Phenosolvan unit was employed to
recover the concentrated phenols from the wastewater
stream. A free and fixed ammonia still was used for
substantially complete NH3 recovery. An activated
carbon system was used for a final polish. TPD emissions
are based on 1 ton H2O/ton coal to the gasifier (15700
TPD) and 75 percent of this H2O as process wastewater
condensate (11775 TPD) from (8320). Other dissolved
solids TPD emissions are based on a makeup H2O
requirement of 12430 GPM (8300), an assumed influent
TDS loading of 500 PPM and a contribtuion of
dissolved solids by the gasification facility of 50
percent of the incoming TDS (similar to refinery
operation (8317 8) and also from (1900)). These ODS are
contributed by ion exchange regenerants, treating
chemicals, corrosion and scale inhibitors, etc.
Organics comprise phenols and oil, while total
dissolved solids includes NH3, sulfide, and other
dissolved solids. Wastewater system removal eficiencies
were developed from (2013,IV-3), (8316,172), (8322,1068),
and (8318, Table 7). Tons/1.0E12 Btu are based on a plant
input of 19265 TPD coal.
IV-70
�
FTN. 8.472-8476
8472 Primary efficiency and ancillary energy for this
process are an arithmetic. average of those,for the
Hygas-Electrothermal, Hygas-Steam oxygen, Bigas.,
and Synthane processes.
8473 Air pollutants for this process are an arithmetic,
average of those for the Hygas-Electrothermal, Hygas-
Steam Oxygen, Bigas, and Synthane processes.
8474 Solid waste production for this process is an arithmetic
average of those for the Hygas-Electrothermal, Hygas-
Steam Oxygen, Bigas,.and Synthane processes.
8475 Land-utilization for this process is an arithmetic
average of those used by the Hygas-Electr6thermal,
Hygas-Steam'Oxygen, Bigas, and Synthane processes.
8476 Water pollutants are based,on the following process
wastewater analysis:
Contaminant Waste Water-PPM Reference Effluent-PPM
Phenols 2600 (8307 4) 0.006
Cyanide 0.6 .(8307,4) o.3
Thiocyanates 152 (8307,4) 0.0
NHI 17040 Calculated 17.0
Su fide, 1400 (8307,4) 0.01
Oil 1100 (8303,X-3) 3.7
Sus. Solids .600 (8307,4) 4.3
The fo 'llo@oiing waste water treatment system was utilized
to achieve the above effluent values -.;. 3-stages of
oil-water separation, dissolved air flotation, free and
fixed ammonia stills,,equalization, activated sludge
and clarification, and char polishing tower. Three
stages of oil-water separation were used to insure
complete separation of the tars and process waste water
(8310,111-08-1). An air flotation unit was used to
further remove oil and suspended solids (8311,3.21).
Based on coke plant.experience (1119), (8312), and'
(8313,618), ammonia removal appears to be the key to
treatment of weak ammonia liquor. Since the ;above
process waste water is very similar to WAL, a'free and
fixed ammonia still operation was employed. Phenol
biodegradation in an ac 'tivated sludge unit has been
successfully demonstrated on coke plant WAL (8312,
202). Complete thiocyanate removal is possible by"
biodegradation of WAL that has previously.been
IV-71
�
FTN. 8477
deamnoniated (8313,618). TPD emissions.are based l
ton H2)/ton-coal to the gasifier'-for a Typical New
Process (15370 TPD) and percent,of1pis H 0 as 2
.process waste water condensate(9.2,q20-'1pDq). from (8314).
Otherqi, dissolved so-lids @'6qT8qPD-, emssions...are, based o0qn
Typical New'Process makeup H20 requirement of 988qM GPM
(8300) , an assumed- influehtqTDS.lloading@of '500 PPM, and
a contribution of,-other@,dissolvedqsoql-ids by,the
gasifcation f acil'i.t6qy -0qof;.50'.46qP'er4qcent% 8qof*,-.the incoming
TDS.q(0qAimilar:to ref4qinery@-oper8qations (q02q317,8).and also
from 6qJ2q1900)). These,qODS@;are-.4qco0qf0qitr6qinbuted,.by Ion exchange
regen2qerants, treating-chemicals-, corrosion and scale'
ph
inhibitors, etc. Organics4qc6qoqrqfqt2qprise -enols
and oil, while-total-dis-8qt0qo6qlv4 solids.includes-cyanide,
thiocyanates, NH3 qi sulfide, -and,-@other-_di0qas8qolved solids..
Wast2q6water'system-removal efficiencieswere-deve-loped
from 1(q2013,IV,;-3q),, 6qA72), :'q(q82q3181@Table 7)
8.3 16, and (8313,
609,60q18q). Tons/1-6qA2qE12 Btu@-6qIrased,-:0qo0qn@an;8qa0qverage plant -
inpu6qV Of 12q69-2q50 coal.
8477 Capital and:"op8qera0qtin0qg.. costs@--w0qareq@-,-d8qeve:@ql@oped- as.fqollows:
Capital.Costs-@1972--$-Plant'Basis15.,q400:TPD, 90 P L4qF
From 0qA83.0) , to, 196q7-2 $---at 5
percent, costs-:-,-f or, the, f0qee2qd;*sy.t8qem1ppp4qas-i2qf ication and
CO. shift 0qmeth4qan 4qiti0qo"n'8q0 6qt 6qactu0qte steam and power
2:@@man0qu
utilities, d' ral:-@-'6f8qf sites total
plantqj, general -. l0qan - g,ene
2q19.2Eq06 $,. .From (.8 3*0 5) qeq@s6qca6qlaq:t8qed.,@.2qat- 5q@ 2qpercent/year
from 1970 to"1972 $,,.0qcos4qt4qs@-for,:'coalvst2qorage and.
reparation-,and,.gas,purification-total46..2EqO6 $. Water
pollution: conqlq@0qr-ol@-2qd-osts,,w4q@re.@*esti 0qed,,at 11.7EqO6 $ with
mat
oil-w2qAter iq@eparation.@-and..'.d-issolved@lair ',,flotation costs
from qt(2013',VII@-5.),,@c0qoqSts,"for".-free@-a@jqid.',.'fixed'NH3 stills,
eq0qualization,:,-,activated sludg0qe,1pplus-cla2qr-if ication, and
char . Polishing from (q0304) j @ and, a.,,'@0qMis0qc8q6llaneous
allowance q(*2".l2qtq0q6'1$q) -for -water @e impounding: basins,
thiqbkqiqeners,sett-qlers,,:'etc.,from@2pq8315q).,Sulfur recovery
osts@ were .-estimated,at'14',i":7E062p2p6qomq(8300) "and
q183-00q1,AI-250qA%Iq@26) To:. the-., 0qs4qUbt6qotal,@; were --'added a 15
Percent (of'subtot2q@lq)@:-proje'ctcontingency'and-a 7 percent
(of subtotal)- development;,qi,-,ontingency'l.to. arrive,at a
tota0qL plant - in6qV6qes4qtment,@of .;q234,.'-qO8qEqO Based.on.a FCR
of q101 percent/2qyr-.and q5.@ 8qU5EqO 6 !..'TPY-;,@ coal this is equivalent.
to q2.04E8qO5 q'$/l_q-q,q-8q048qE1,2-Btu.
�
�
FTN. .8478
Operating Costs-1972 $-Plant,Basis-15,400 TPD, 90 P LF
From (8300) the following costs were taken directly
other raw materials, catalysts and chemicals,.
purchased raw H 0, and process operating labor for a
total of $.053/KOE06 Btu gas. From (8303,AI-5)
maintenance labor was based on 1.,5 percent/yr of total
plant investment, supervision labor was based on 15
percent of process operating and maintenance-labor,
admini,stration andgeneral overhead was based on 60
percent of total labor, operating supplies were based
on 30 percent of process operating labor,and
maintenance supplies were based on 1.5 percent/yr of.
total plant investment. The total gross operating cost
is thus $.2049/1.OE06 Btu gas or 15.82EO6 $/yr for a
235.BE09 Btu/D SNG,plant. By-products are credited at
$10/LT for S (464 LTS/D) and $25/T NH3'(142.3 TPD,NH3)
from (8303,AI-5). The total net operating cost is
therefore $13.13EO6/yr or,for a 5.05EO6 TPY coal input,
1.14EO5 $/I.OE12 Btu.
8478 Capital and operating costs were developed as follows:,
Capital Costs-197.2 $-Plant Basis-17,900 TPD, 90.P LF
From (8300)l- escalated from 1971 $ to 1972 $ at 5
percent, costs for coal storage and preparation, pre-
treatment, feed system, gasification and CO shift,
methanation ' steam and pow .er plant, general utilities,
and general offsites total 175.6EO6 $. From (8300)
cost for gas purification is estimated at 22.9EO6 $.
Water pollution control costs were estimated At
.11.7EO6 $ with oii-waiter sel@aration and dissolved air
flotation costs frorC(2013,VII-5),costs for free and
fixed NH3 stills, equalization, activated sludge plus
clarification,and char Polishing from (8304), and a
miscellaneous allowance (2.lEO6 $) for water impounding
basins, thickeners, settlers, etc.' from (8315). Sulfur.
-recovery costs were estimated at 20.9EO6 $ from (8300)
and (8303,AI725,AI-26). To the subtotal were added a 15
percent (of subtotal) project contingency, and a 7 percent
(of'subtotal) development contingency-to arrive at a
total plant investment of 282.OE06 $. Based on a FCR of
10 percent/yr and 5.88EO6 TPY coal this is equivalent
to 2.11EO5 $/l.OE12 Btu.
IV-73
�
FTN. 8479
.'Operating Costs-1972 $-Plant'Basis-17,900 TPD, 90 P LF"
From (8300). the following costs'were taken directly-,,-,
other raw materials., catalysts. and chemicals., purchased
raw H2Q., and process-operating labor'for a.total of
Btu gas. From (803,AI-5 maintenance
labor was based on 1.5 percent/6qyr of total plant
investment,'supervision labor was based on.15 percent.
of process operating and:maihtena qnce.labor, administra-
tion and'general overhead was based,8qoh 60 percent of
total @labor, operating supplies were based 'on 30
percent of process operating labor, and maintenance
supplies were based n 1.5er0qce2qnt/yr of total plant
investment. The total gross@*operating cost is thus
$.2195/1.qO8qE06 Btu gas or 18.22EqOq6.$/yr for a 253.3EqO9@
By-products. A-ire credited at $104q/0qLT for
Btu/D'
S(400 0qLTS'4q/8qPq) q1. $4/0qLT I f or S02 @ (216 LT. SO /D) , $25/T NH8qI -
(0q165 8qtPD NH3), $.15/g4qal 'for B-Tq-0qx .(524q1-2qM GPD), and
$.30/1.qOE06 Btu-f8q6r tars,q(9.44qEqO9 Btu/D)from (8303,AqI-5).
The total net operating costis therefore $11.72EqO6/yr,
or,for a 5.88EqO6TPY coal input, 8.78EqO4 $/l.qOE12 Btu.,
8419 Capital and operating costs,'8qw6qd8qtqie, deqvelope as: follows:.
capital Costs-1972-plaqn0qt B0q44-.iqis-1q1,100 TPD,' 90 P LF:
From q@830,0q)i0qeqscalated from'1971.$ to 1972 $@at 5
6qperce3q@'2qt,coqtts,for:coal stora2qge.,and:,pr0qeparation, pre?-
treatment f eled s0qyst,e0qm', ga0qg0qi f icati6qo6qn and- -C4qO shift,
metha2qhati0qon,' 8q6x8qy0qge6qn';'2qMi2qaniuqf0qa ctur6qe, steam and power*plant,
general utilities-, and`:general 4qof6qfsites total 1326qAEq06
$. From (8300) co.,q@'t,for,1ga-s,@-pqii2qkqific4qa-tion is estimated
at 22, 98qEq06-:$._Wat' oll
er p 8qution, control. costs,were
estimated" 6qAt'I._'l6qIi0q7E.02p1pwi8qthq"qoil-wa8qter separation.and
dissolved airflotation costs from (2013,VII-5q),tcqosts
for free a0qnd fi8qked NH stills, e6qqiqi4qaliqtation, activated
3
sludg4q6 plus, 2qd2ql4qarif-qicati0qdni-ahd ch4qAr'-polishing from
(8304) , and A 8qmqiS8qcel2qIaneo 6q"-@ allowance (2.'lEqO6 $q) for
water impounding basins, thickener'qs,.settlers,-etc. from
(8315). Sulfur reco2qVery'costs-we6qte"estimated at 206qAEq06
$ from (8300)-and (8303,AI-25-,AI-26). To the subtotal
were added a 15 percent (6qof subtotal) project
contingency and a 7 percent (24qof subtotal) development
contingency to,q'ar28qfive at a total plant investment of
2q,2q28.6E2qO6 $. Basedq'on a FCR of 10 perc04qeqr8qit/yr and 5,61E2q06
TPY coal this is equivalent to 1.8044q9q-05 $/lq.8qOE12 Btu.
IV-74
�
�
FTN.. 8480
Operating Costs-1972 $-Plant Basis-17,100 TPD, 90 P LF
From (8300) the following costs were taken.directly-
other raw materials, catalysts and chemicals, purchased
raw H20, and process operating labor-for a-total of
$.046/1.OE06 Btu gas. From (8303,AI-5) maintenance labor
was based on 1.5 percent/yr of total pla 'nt investment,
superivision labor was.based on 15.percent of process
operating and maintenance labor, administration and
general overhead was based on 60 percent of total
labor, operating supplies were based on 30 percent of
process operating labor, andmaintenance supplies were.
based on 1.5 percent/yr oftotal plant investment. The
total gross operating cost is thus,$.1933/1.OE06-Btu gas,
or 15.70EO6 $/yr for a 247.2EO9 Btu/D SNG plant. By-
products were credited at $10/LT for S'(357.1 LTS/D),
$4/LT for'S02 (185 LT S02/D), $25/T NH3 (147.5 TPD NH3),
$.15/gal for-B-T-X (46EO3 GPD), and $.30/1.OE06 Btu
for tars (8.84EO9 Btu/D) from (8303,AI-5). The total
net operating cost is therefore $9.93EO6/yr or,for
a 5.61EO6 TPY coal input, 7.80EO4 $/.l.OE12 Btu.
8480 Capital and operating costs-were developed as follows'
Capital Costs-1972 $.-Plant Basis-17,600 TPD, 90 P LF
From (8300Y, escalated.from 1971 $ to 1972 $ at 5
percent, costs for coal storage and preparation, feed
system, gasification,and CO@shift, gas-purification,
methanation,compression, oxygen manufacture, steam and
power plant, general utilities, and general offsites
total 153.8EO6 $. WaterpOllution control costs were
estimated,at 11.7EO6 $ with oil-water separation
and dissolved air flotation costs from (2013,VII-5)r
costs for free and fixed NH3 stills, equalization,
activated sludge plus clarification, and char polishing
from (8304), and a miscellaneous allowance (2.lEO6 $)
for wate 'r impounding basins,thickeners, settlers, etc.
from (8315). Sulfur recovery costs were estimated at.
23.3EO6 $ from (8300) and (8303,A!-2@,AI-26). To the
subtotal were added a 15 percent.(of subtotal) project
contingency anda 7 percent (of subtotal) developement
contingency to arrive at a total plant investment of
230.3EO6 $. Based on a FCR,of 10.percent/yr and 5.78EO6
TPY coal this is equivalent to 1.75EO5 $/l.OE12 Btu.
IV-75
�
FTN_ 8481-8482
TPD, 90 P LF
Operating Costs-1972 $-Plant,.Basis-17,600
From 80300) the following.costs were.taken,dir'ectly
catalysts and chemicals, purchased raw' H Of and process
..operating labor-for-a total of $.06 4l..q66qiq06*Btu-gas.
From (8303,AI-5) maintenance labor was based on 1.5
percent/yr of total plant investment, supervision.labor
was-based on 15 percent of process operating and
maintenance labor, administration and general overhead.
was based on 60 percent of total labor, operating supplies-
were based on 30 percent of process operating,labor, and
maintenance supplies-we0qie based on 1.5 percent/yr of
total plant investment. The total grossioperating cost is
thus q$;2204/l.q0E06 Btu gas-or 16.75EqO6 $/yr-for a-
231.8EqO9 Btu/D SNGplant. By-products we4qrecredited at..
$10/LTIfor S q(.502q7.1 LTS/D),. $25/T NH (173.6 TPD NH3),
$.15/g4qal *for B-T-X q(25000 GPD), and.qi-qj.q0/qi.q0E06 Btu for
tars (q13.9EqO9 Btu/D) from1p303,AI-5). The total net
operating cost is,2qtherefore,$11 *qOqOE06/2qyr-or, for a
5.78EqO6 TPY coal input, 8.374qEqO4$/qI.qOEq12 Btu.
8481 Capital and-operati4qng-costs for-thi8qa,process are an-,
arithmetic average,those for,the Hygas@-Electr0qot0qherqmal,
Hygas -Steam. 8qOq?cycqjen, Bigas@o@ and, Sy0q4thaner'processes.-
8482. Capital and..op8qerati6qng costs.wereie4qVeloped-as follows:.
Capital Costs-1972.q$-Plant Basis-19,300 TPD, 90 P.LF
.From q(qP3q0q0q),, escalated from,2q1971 $ to 1972 $ at q5
percent,-cos
tsfo8qr.:'col storagea6qndpreparation,
gasifi0qc@ation'and CO shift-, gas purification, methanation,
compression , oxygenqanuf0qacture, general utilities-, and,
4qgeneral-offsites total 181.5Eq06 $. Steam-,and power plant
cost was estimated at 24.78qEqO6 $ from (8300q)' and
(8323,42). Water poll4qution@control1postswere estimated
at 13.8EqO6 with tar-oil-water separation and activated
carbonq1costs from (2013,VII-i-4), costs for free and fixed
ammonia stills from (8304),.costs..for filtration and
a Phen0qo@solvan unit from (83q206qY, and a miscellaneous
allowance (2q;lEqO6$q) forqMater.impounding:basins,
thickeners, settlers, etcq-q. from (8315). Sulfur qr q'ecovery
-costs were estimated,at 17.5E2qO6 $ from56qA '83006q)q: and
(8303,AI-25,AI-26). To the subtotalwas addedq*a 15q-per-
cent p36qrojectq-contingency to give.a total plant investment
of 273.1E2q06 $q. Basedq,q:on a FCRq'of 10 percent/yrq'and 6.33E
06 TPYq@c08qoal, this is equivalent.to 1.90E8qO5 $/lq.8qOE12 Btu.,
IV-76
�
�
FTN 8483
Operating Cost'8-0q4_9@0q72*$-Pqla6qht 2qaaqsq;iqsq-19,300 TPD', 90 P L4qF
From (8300) costs for catalysts and chemicals,
purchased raw water, and process operating labor total
q$2p2p/q1.qOE06 Btu gas. Costs for maintenance labora,
suqlqpervision labor, administration and general overhead,
and.operating and maintenance supplies were developed
from (8303,AI-qS). Electric power operating and
maintenance costs are from (1918,46). The total gross
operating cost is thus $.233q6/1.qOE06 Btu g0qas or
$18.15E2qO62q/yr for a 2524qEq09 Btu/D SNG plant. By-products
were credited at q$102q/0qLTS (580 8qLTS/P), q$25/T NH3 (187
TPD NH3q), and $.15/g0qal B-T-X (61.7EqO3 GP8qD) from (8303,
AqI-5q). The total net operating cost is thus $10q1.67Eq06/
yr or,for 6.33EqO6 TRY coal input, 8.118qB04 $/6qI.qOE12 Btu.
8483, Thermal discharges can be compl4qetely.elim4qinated by the
use of mechanical draft wet cooling towers.
IV-77
�
�
V. OIL SHALE
@A. Introduction.
The environmental impacts,-,ef-fidiencies,. and costs associated
with the production of crude oil from oil shale are given in Table
3 of this report. Each process'oi activity data entry is based on
an energy input.equivalent to 1012 Bt-u/year. This.is approximately
133,000 tons per year of 30-qallon per ton shale. All table'entries
have been derived for a "controlled".environmental condition'.
Contrary to the-fuels and activities described in the Phase
I Report (contained.i:n Volume I), oil shale plays'alun,ique role
in the fossil.fuel..t,ralectorv. Although the oil shaletask includes
activities such as extraction, processing, and distribution, the
end product general'ly cannot be considered a refified-,product until
it is further upgraded in a conventional refinery'. However,other
end uses for this' tifirefined shale crude, such as turbine fuel for
electric power generation, have been,demonstrated. To be@more
precise, the end product con.side,red in this reporlt'sho.uld:be regarded
as ahigh quality crude oil from which many conventional refinery
products'may be derived. Consequently,@@he oil.shale, task must
be viewed in conjunction with the Pha.se'I Report to complete.the
entire fossil fuel chain from extraction to end use.
Oil shale is a sedimentary rock consisting of 'a.. solid
organic material'called kerogen 'intimately associat 'ed with.
other minerals. Upon processing, this organic' rich rock found
in the Green River formation of Colorado, Utah, and Wyoming,
will yield a low quality crude oil which-is suitable for
upgrading. Thesedeposits, assaying about'30 gallons of Pil,
per ton of shale, represent about 600 billion barrels of oil.
The recovery of crude oil from oil shale may take three
distinct forms:. (1) mining the oil shale and "retorting" it in
surface facilities, (2) in situ retorting followed by surface
upgrading, and (3) a combination of mining and in situ retorting
followed by upgrading. Methods (1) and (2) are considered in
this-report.
Figure 20 is a flow diagram of the principal processes in-
volv ed in a commercial size oil.,Ishale operation using the Gas
Combustion.Method. For the TOSCO II and In Situ Methods for
which data have been obtained,, the.flow diagram will be similar.
The processing' steps include the following activities.,
�
ELECTRIC
POWER TO
EXTRACTION, POWER ACID GAS
KW- :ATMENT
HR 'PLANT
CRUSHING,
RETORTING Ek
UPGRADING
HYDROGEN
MANU-
FACTURE
'EXTRAC-
HYDRO-
TION CRUSHING RETORTING DISTILLA- . - a- CRUDE
TI N TREATING @42API
TO WASTE
DISPOSAL 'DELAYED
COKING
COKE
Figure 20.. Typical oil Shale Process Flow Diagram
VS
�
Mining
This will include both underground (room and,pil iar) and
open pit mining depending on the size of the operation and
specific topography. Underground mining will essentially be
associated with a 50,000 BPSD surface plant,and open pit mining
should support a 100,000 BPS D,operation. Mining ,will essentially
follow conventional methods, however,the magnitude.of .the
operation will be considerably larger than,present day coal or
copper extraction activities. For,a 100,000 BPSD.plant,
approximately 145,000 tons per day' of.oil shale must be min6qe.d
and conveyed to tne retorting,plant.
The reader is cautioned that the, 4qI0qm or
pacts f.
the extraction process are not based on the recovery of 1q012'
but.the "attem t' I to recover 'q01
Btu 1 Btu. qIm, acts fo2qr this
qp
activity. are..actually derived by extracting q1q0q16q3tu of the
resource,and multiplying by the ppropriate extraction
efficiency so as to be consistent with all other entries in
the tables, i.e. 1012 Btu into ach activity.
2. Retorting
There are basically three methods for retorting oil'shale
to obtain the low q4qvality syn-crude suitable for upgrading.
a. Gas Combustion
This method developed,by the :Bureau of Mines and
Union. Oil Company utilizes crushedhale that is charged into
a processing unit or retort where it is heated to 4qIts'p6qyrolysis@
temperature of between 800-10000F.Theerog4q6n is 'liberated-,
from the' inorganic matter and is converted to a gas and oil
mist. These organic-rich vapors are collected.and condensed
to form a,low gravity, moderate sulfur, high n0qitrogencrude
oil- Combustion it supported by recycling a portion of the
low Btu gas produced during retorting.' Solid waste or spent
shale is automatically removed,nd conveyed to a1psp8qgsal site.
b. TO'SCO 11
,This method,developed by the,Oil Shale C.orporation
and sponsoredy the Atlantic-Richfiel'd Company 4qas well as..
other maj6qGr oil companies,involves the same approach as Gas
Combustion but utilizes, aq.different.technique. The TOSC24qOqIII
method utilizes,hot-ceramic ballsq@to sustain pyrolysis. -AS
the kerogen is released the balls are segregatedq.from the spent
shale, reheated and recycled. The syn-cru60qde is 'further
upgradedq.whil32q6 the spent shale is conveyed to a disposal site.
V-3
�
�
C. In 'Situ
This method of shale oil recovery has been
sponsored by the Bureau'of Mines, Mobil, Shell, Equity, and,other
major oil comp anies. It :involves*hydraulic,'explosive, or
electrical fracturing of the oil shale bed" and combusting the
oil shale.in the ground by means of injecting natural gas and
air into the well. As,combustion of the oil shale takes place
the* shale oil is released from the,inorganic material and is
recovered via a series of well systems., No spent shale or ash,
is generated in' this process.
Due to the inadequate data available on fracturing,
it has not been considered in this report. The data compiled
deal-primarily,with the retorting, recovery', and upgrading
-activities of the In Situ process., The generalized In Situ for
which data haveibeen compiled is not to'be confused with the
.Occidental Petroleum process of in Situ retorting. The latter
is a combination,of'room and pillar mining and In Situ
retorting.
3.; Waste Disposal
One of the major problems with above-ground retorting is
the large volume of spent shale that is generated. For every
.,barrel of syn-drude produced there are approximately 1.2 tons
of spent shale@g'enerated- This spent shale must be conveyed
to a'shale disposa1 site, compacted, and eventually revegetated.
4. Upgrading
Crude shale oils produced by retorting typically have
high pour points and tend to form.sludged if stored for
prolonged periods of time. This property necessitates refining
or partial refining soon after production. Hydrotreating using
established techniques of the petroleum industry is best suited
for'reducing the pour-point, removing nitrogen and sulfur, and
preventing deterioration. The crude from the "retorts" is
heated in a tube still and charged into a distillation column.
The lighter di!stillates resulting are fed direbtly to the
hydrotreating unit, whereas the heavy bottom fractions are coked
prior to hydrAreating. The resulting product, a semi-refined
crude having a- 420API-gravit-y, is then stored for pipeline
shipment to conventional refineries for further upgrading..:-.,-,,
V-. 4
�
5. Power Generation.
Above ground retorting (TOSCO II and.Gas Combustion)
methods produce sufficient quantities of fuel.gas to supply
the plant's steam and electrical requirements. (More recent
data from the Colony Development Operation.suggests that this
may-not be the case. See the discus ision below.) In situ
retorting requires an additional amount of ancillary fuel for
its operation. It is assumed in this study that the fuel
utilized will be natural gas supplied by a nearby pipeline
system. In actuality if the semi-refined.crude was utilized
to produce electrical power and steam by definition.-it
would not be considered an ancillary fuel.
The cost'data presented in Table 3 are ba'se'd.on a 90 percent
plant load factor, or 328 Operating days/yr. The values.presented
in this table are based on data accumulated during the Pall of 1973.
Since this data base was prepared, extensive work has*taken place on
the development of an oil shale industry. In particular, the
design of the Colo'ny'Development Operation shale oil complex has
resulted in a more recent and complete evaluation of environmental
impacts. This information is contained in An Environmental Impact 'd
Analysis for a Shale Oil Complex at Parachute Creek, Colorado.. Da a
from this report,.in.general, differs from that contai-n-eiff _herein.1V
The reader should take special care in using some of the data
presented in Table 3.. In. particular, rows 9, 18, and 27 define
impacts with respect to the processing of raw shale into semi-
refined crude oil. Each of these rows (9,i8 & 27) is a composite
of impacts due to individual processes required in this activity,
The eight rows following each of the above three'rows (rows 10
thru-17, 19 thru 26, and 28 thru 35) des.cribe;the impacts of each
of the processes on the basis of 1.OOE+12 Btu input to each ,
process. In trajectory type calculations, one must make use of
the composite data in rows 9, 18'and 27'.
Letter to M.I. Singer,.CEQ', dated 10/30/74 from W'.E. WAde, Jr.j
manager planning and control, the Atlantic Richfield Co.
V-5
�
Big Impact Data Table and Footnotes
V-6,
�
�
am h MN
FUEL REGION 1 2 3 4 5 6 7 a 9 to 11 12 13 14 15 is 17 18 19 20 21 22 23 24 25 26 27 28 29 30
WATER POLLUTANTS (TONS/ 16" BTU. EX. COL.12) AIR POLLUTANTS (TONS/1012 BTU) OCCUPAjiJONAL HEALTH POTENTIAL COST (I)OLLARS/ld'STU)
SOLIDS LAND AR E PRIMARY ANCILLARY
DISSOLVED SOLIDS SUSPENDED TOTAL THERMAL PARiIC- HYDRO- ALDEHYDES' _iEATHS ["JURIES MAN-DAYS ENERGY FIXED OPERATING TOTAL
ROW MNE- ACTIVITY PROCESS ROD COD NO, sox CO ETC. TOTAL TONS/eI (ACRE.-YR) SCALE EFFICIENCY ROW
'OBI TU
MON. ACIDS BASES P04 NO, OTHER TOTAL(DS) SOLIDS ORGANICS COUS 6,7,8 BTU/IO'2BTU] ULATES CARBONS 101 BTU 10 BTU 1012 BTU IOI2j3TU mw/ldlsw COST COST COST
LOSTACY BTU DISASTER
I@RC EXT RA CT I-
UNDER UNDERGROUND 39OD3 o.Oo,Oo 3 9DO3 0.60,00 39DO3 0.00-00 39OU 0.0010D 3 9DO3 0. G- 3 0. Go- 39003 0. OGIOD 390GI Q. Go- 3 G. OG+GG 39003 Q. 00-OD 39U3 D00100 20997 l. 54 Of 39001 7.61-023902 S4-3 3 1002 7 @ 74-03 3 9G02 4.55-01 1lool 1.19-G4 39002 4,89-01 3 1. 15@01 2 11GS 1. 9-0 2 9004 4.14-03 3 9006 1 .OB-01 3 m, Go. 9104 6. 50,01 2gooO 1.2-1 l IGG7 1.14+03 3 907 7.93+04 3 9047 8#74+04 3 2
3SURFC SURFACE 0,00-00 390DR 0. 00,00 3 9004 D.OOOD 39008 0.00100 39008 O.OG-OD 3 SON -04D 3 o.WoO 3Go$ ...oloo lGoo. G.- l 0. DGIOD 39GOR ft DD+OO 39008 0DO+OG 1G197 1.33-G2 1009 3.79-01 4goog 2.11-ol @ Go, 3.11-02 4 9OG9 2.31-01 lIOG9 Gloog 1+12+oo 4 5.03@04 2901D 3.99+00 2 9011 1+06-o3 3 9GI2 5.!44-G2 3 9012 .11. IOJI 6.20-01 29- 1.66+08 3 9074 8m43+03 3 9048 3m03+04 39048 e..7+. 1 3
4TRNSP TRANSPOGITAT N 4'
5CoN, Co-Elo. 0, -00 2D G7 "I o l- O.G.G. 2GeV 0-0 2 D997 Q. GG+GD 20997 D. OQ+GG 20997 0400+00 20997 0 m O0+OG 20997 OwOD+OO 20,997 o-p
9 G2ol. -G- 20997 4 81-OT 3 961GGGG+OO 1G117_ .. Go, 0 2 0117 ..G GO 2. -7 a. -Go 20997 0.00,00 2G997 14.8o-ol 3 OwOO400 2Oo97 4,OG-GI 1loll -9 I..G+.o lI- 1.31+09@ 2 IDIS 1.49+G3 2 love 1.4-1 29049 11 64@32 51
SGI,
6- TRUCI TRUCK o. ..+Go 1.11, 2 011 0.00,00 2 OmOPOO 20997 OwGOOL2 B997 G-o 20997 owoo,oo 2G@ 97 G.o.G- 70397 G.oo,GG 2D997 0-00-GO 2G997 0-00- 1G997 0@0-00 20997 1.42-02 49019 ..-ol 7.9-2 4 9019 4.04-02- 4 9019 2.45-01 49019 3.17-ol - 7.36-01 4 G.-Go =17 7 0 OG@02 39020 ogle .1.1 .11, IG82 1.00,00 29021 3.02+08 2 9072 2w46-Q? 9 9oSo 6.74- lIGIG -- l 6
7PMOS PIRE-PROCESSING
GNUS. -S.- 0.0-0 29D26 0. -00 2 lG26 Q.OO.OD 29026 0. OOqO 29026 G-+;O 2902G G026 0.00+00 29026 0,00+00 2 G.GO+QO 2e026 0.0G100 29DI6 0.0-- 20907 8.40-01 .2 9GOS -1+0020997 0. -00 2 0997 O+OMG 2 D997 O+OD+OO 20997 0.001GO 29997 9.40-ft] 2 1. 73,03 29027 Ow2-2 49028 ollo G119 .1. 1082 9.87-01 29024 9.28+08 39023 6. 77+03 39051- 1.33+G3 4D051 8.10+ol 4 8
-IC PROCES11NO-GAS COMBUSTION 1,110* 11012 3 1111 31111 O.G-0 39032 91, 0. DO10D 3 39.2 GAGIOO 1111 G.04
1 0.00+00 2GOG2 O@ GO,00 30082 0. 00@00 3 Oa 00+00 39082 0, 0010 +00 3GOBI 3155+0139083 3r 06+01 3 9083 1. "+01 3 o- 1. 11- l- -e-ol 31083 G. o_@ 3 1 r 78+OD 39097 39090 LS5-D@ 3 -0 1.41- l 90!. D999 S.31-01 9015 0. 00+00 2-7 1.18.05 39101 3.32- 11ol 3 9
10 RETRT N-oK-- 0-00 29029 d. Go- 2 SD29 G.OO.OD 29029 G.00+00 29029 D.OO+G0 2We O,GGIOG 2 G. G.Ioo llolo G.-Go loll G-O I O.-Oft 2942910.00+00 29029 ...0,.. l0997 10.00+00 3e.I. Om.G... 1lolo G. G.GG l 1- .-0. l 9G3. .-aa 39olo 0+00- ,-o G.-Go 3 1 1.08+05 2 904D 5,50-02 3 90q3 I -
39042 1. 44-al 3 9042 D999 O99l 6.73-01 29044 2.33+10 29046 6-04 39OS2 I-Iol l9Q52 1.68+05 L_ 10
11 D15TIL ____ DISTILILATION ... IS. 0998 16. 04-01 39054 6. D4 01 3 GlG 4.3DOO 35054 4.91-GO 3 1.71-03 3SD54 ogsg -b+oo 2sell o.oD+oo 29oso o,oo.oo29o5G a. G-0 2 9056 2.73100 3 9054 O.-OD 29- 0.0 ... 0 2loll 1.1-0 3 o9l. -1-11 -
1 .11. . .9 1 loll I.oo+oo 2QIo5 1,9o+lo 3GOP 9.os+o3 39057 7-04 39057 3.41- 3
Ip G...G DEI-AYED COKING Me Goss o998 0998 4.77-01 390lg 1.77-01 3 0999 2.47-02 39058 5.02-01 3 0999 1.02.00 39058 OaOO+OD 29OSS G,G.,GG Ilol, -- IGo, 0.000 1 9GS6 2.13,60 3 _9 cwn 29G,G ow-Go 29DS6 2.131GO 3 G118 OGG. .199 oll, 2G91 -7-01 29091 7.4-0 39160 336404 i207 6.37+04 3goel I... -OS 3 12
is Nlmrc HYDROCEN NANUrACTURE .11. .19. G91. 0999 098 o9s, .19, 0999 .11, .11, 0999 0.0-0 29G55 G.00+00 29DS6 OmOO+OO29056 G-100 2 9056 1.49,00 3 9362 0. OO+OD 29056 G + -Ga 4 m GO f oo 3 0998 o999
- oggg G119 .11, 2091 5.03-01 22079 ImO3+12 22079 7. 381ON 2 2G15 l.14+05 2 205: CW05 2 13
14 HYTRT .1-R-TIN. .11. el. Apl. o998 e G-G, l 0999 7.3-1 39064 1.34.00 3 L72+00 39064 OvOO400 2905S 0.0- 1loll O+-Go 1IG56 DmDO+GO 2 9GS6 2,59100 3 9081 D.GOIDO 29DSG O.OO+G0 2IGIO 1.11.0 1 oll. .119 G191 GO'S .11, 2.91 9.68-ol 29-1 1.1-0 3906S 4.17+03 3IG61 4.15.04 3IG61 1.27- 3 IT,
15 GASTR GASTREATING_ 0,00100-2 9- 0.00+00 2 9071 0.00-00 2 9071 -0+00 2 9D71 OmOOIGO 29071 G GG+GG O.OG,OO 29071 0,00,00 29071 G. @O 2 0.00+00 29G71 0. -00 29055 O.OO+GO 29072 0-0-0 Z9056 l.-Ol 2 9072 G.OG-00 2 9072 0.00+00 29072 OwOO+GG 21012 3941 1 .-Go 2 9073 2-104 4 9074 .1e, G191 G119 7091 1.00,OD 29075 0999 3m32+05 39076 G.O- 19111 1@32+GS 3 Is
7-
16 TNKCR@ CRUDE sl-E-__ .19. .11. 0999 Go. oll, G117 - OOGG Ooll 7.2-2 2 9033 .91, G.-.O le.11 1-1 GmG_O 1.11, G.GG+GG 1 .197 -o- 1 9034 0. -01 10997 20997 5.031G1 2 2.191 G.1-1 IIGLI. .1 2.1l 1-0 2 03 S 16
o999 .91, .1 9D36 I.S4+06 49037 3.83,03 39053 2.68+03 39053 6'51+
17 mGEN -.ER GEN-TI.. O.OG+Oo 31917 -0+00 3 1917 D999 099 --1) 41@17 3 40, 00 4 O,DO-GO 31917 3.02-03 31911 31 4-D 4 oel@ 000 0.00- 3191B 12.15,01 3901 1.8-2 39031
1.55+02 3 9031 11-01 3 9031 1.94-01 39031 11.46+OD 3-1 3.87+07 3 1o. Go- l.117 2. 7G+OOF 33904 5.96-04 3 3903 5.17-02 1 3203 2.36,00 3 3903 .199 -G-01 2191l G. GINGG 10. 2.n@G5 2 loolle.7m,; 2M.031G5 2 17
7 3.73-05 39102 14.87,05 3 Is
ffOSC FftOCESSIHC-TO5C0 11 0. O-D 39094 -00- 3 9- 0-00 3 9094 0 00,00 3 9Ggq G.oa_ 39094 0. GO+00 3 G.- l-, o. Go- G- G.o..oo l 0.00,QO 3 9094 O.DO.00 39094 O.Ool.o IOM l-G II.-ol 11084 3.74,21 3 9084 im22+01 3 9084 1.33-02 39084 9.93-02 390.4 6.28+01 3 1.08+DS 29040 1. 7-0 l9- 1.11-03 3 9090 1.48-01 3 9090 1*49@01 3 9090 0999 6.67-01 29091 G.Go- l9.1. 1.50- 39102
19 R ET -ORTING OmUO+OD 29029 O.OD+00 2 909 0-0- 2 GO29 0.00+00 2 9029 lIG29 OmoO+oo 2 GwO-0 29029 -0+00 29029 G+0010G 2 O.OO+G0 2 9029 0+0-0 2ooze Q OG+G0 20997 6.00-OD 39030 ID+00+003S03D D.00+00 3 9G30 G+O01OD 3 903D 0. 00+00 39030 0-160 39030 O.OO+GO I.-ol I'Go. 2.78-02 39o4I 1. 37-03 3 9042 1.4'4-01 3 9G42 G19, G111 7.1-1 21.1 ol9G .199 oll, 019 19
20 I)STIL -T-T.- OelG 0999 A 04-- 1 6.04-01 3 1999 4+30100 3905Q C-01 3 1 7-3 1 l054 D999 D.00100 2gG55 GmDO+OO 29DS6 1.10+0129D5fi 0. -00 2 9056 2.73+OD 3 9054 O.OG+10 29OS6 0.1-0 29056 2.73.00 3 .91. .11, O'll o919 ol9l 201 1 . G- 29105 1.90110 39- 7.99+03 39057 2.51- 39057 3.31104 3 20
21 DEI-AYED COKING oll. Go', 099B 0998 4.77 01 390SA 4.77-01 3 0999 2.74-02 3GG5G So2rO! 3 0999 1.02,00 39058 D.0010D 2GOSS 0.00,00 29056 G.OG-0019056 0.00+00 2 906 L1340 3 9059 O.OG-00-2-9056 -0. OO,OG 29OGG 2.13+GO 3 Q998 -9 G119 oll, 91 201 1.91-11 2qG911 7-10 39OGG 3 m 2 -4 32047 6,37,04 3e6l 1 w 024S l 21
22 NlmFG -RUGEN MANUFACTURF llo ole. o9lo Gol. oll. o999 - oll, G111 G.O.- 29G5S O.OG+OO 2905-6- 0, OG+O0_ 29056 0.00,00 7 9G56 1 w 49+00 3 9062 0.00+00 29056 0.00-00 29056 4.O-G 3 o998 019 o999 0999 2,9 ol-IU l!.7, lrO3+12 27079 7. 3804 2202 . 3.101 22G52 4. G8+05 2 2 P
23 -R@ y.. TREATING G998 oll. olo. oll 6.G4-01 39064 6.04-01 3 0999 7.33-01 39064 1.34+00 3 8.63-02 39064 1.72-00 39D64 0.00-00 29- O.OOIGG 29056 0.00.002SG56 O.GG+OO 2 9a56 --o l Go, ..-G. lMe I) OGIGO 29OS6 2,51-Oo 3 0998 .99, o999 oll, - 20i 1.13.1o 39a6sl4.17+03 3ID61 4.85+04 3 -9066 S.271043 23
24 GASTR GAS TREATING 0,00+00 2 GG71 O.OO+G0 I loll G.GG+G- 1 9071 o.oo-oo 2 Go7I o.ool 0 29G71 o.oo.oo 2 Me- 2 9071 OmOD4DO 29071 0. OG+0G -2 0.00-00 29071 GAG- 29071 G.0-0 2905S OwOG+Oo 2GG72 0-00 29072 3w 39,01 2 9072 1 0. OO+GO 2 9 72 0. OO+G0 2SQ72 0-0 29012 1. 39- 2 -G.0 2 1.11 1. Il+.G . 9G,O G999 .91, ol". _2G91 1.00-00 2907S o919 332- @_IG76 0 @ 00+00 3 -6 3w 32@05 3 24
25 TNKCEI CRUDE _-E 0998 0.. o998 ollo ollo Sol G G191 0999 7.21-G2 29033 0999 G.OD+OO 29OS5 0.00+00 10997 0.00+002-7 0. -00 1 0997 5.48+00 2 9034 Ow-00 10997 O,OD+GO 2D997 5.01101 1 -7 4.16-01 29035 0999 .,gS Go. 20W 1 m -0 29G36 1. 54+06 49037 3.83+03 39053 2-03 3901 6. 511G3 e 2 5
2 6_G11 @WFR GENERATION G.GG+GD 3 1917 -D- 1 1917 o999 0999 3. 4@1 OD 4 1017 3.40,00 4 O.-OG 3 -7 3. 02-03 .1 Ioll 3.40+OG 4 o.99 0909 D.00+00 31918 2.62+00 39D32 1.90-0 1- -2102 3 9032 1 . -01 3 9G32 1+95-01 39032 1.46+00 39032 7-02 3 -D. OOIGO 3 0997 2-- 3l12L 54 96@G4 3 3903 5. 07-02 3 3903 2.36+00 3 15L3 0999 3.110-01 21912 QaOO+OO 19067 2.35+05 229016. 79104- 2 -2GD' 3- Oe+G5 2
_PINST FIROCEIIINGAN SITU 1111, 3 1111 11111 0,11+11) 3 1112 1,11+10 1 1111 1, 11,11 1 3SON 0. 00i OD 3SM Ow OD+ 11 1 1, "1" 11111 1,11,013 1111 1,10110 11011 1, 11,11 39011 7,11,011 9085 2. W02 3 9085 1. GN 02 HIS 1, 1 1@ 11 31*11 1 -D! 39085 4449+02 3 0,00+10 1 0117 7,11,11 1111, -.-Ge , 'me 1@@090 e.2.-.e @ .1. 0 999 5 31-DI 29095 5.99+10 190" lm!1*05 39103 .L98-05 311. 1-, l 27
2RETRT OmOO+OD 2 9079 O.OG+00 2 909 O.QO,OO 2 9079 0.90100 2 9079 0.0-0 29079 0.-0 2 -0100 2 9079 G, -00 29079 G.OO+OD 2 1O.OG+OO 29079 O.OG,00 2 9079 OwOO+OO 70997 6. 22+OD 3 9078 D999 2. 6-2- 3 9071 1. 1 1+0@ 3 9G7. 1. 13, GI 39078 0999 4.31+02 3 0,00-00 2 09L7 6c47+00 39069 3* 64wO3 3 9070 5,69-Dl 3 9070 oll" Ol I 1.11-ol 390131 .1. 5. 711+04 l1.7 Ae. 5.7.+Ol 3 as
29 DSTIL DISTILI-ATION Me .11. Go. .- 6.-1 39- 6. -@ 1 1 O'll l-G G.-Go l 1.73-03 39G!4 D999 0. -01 29055 D. OG,00 79056 G.DO+QO29056 *. ..0. 2 1.11 -1.0. 3 I.So 0 + G.GO Ilell G.0- 29.l6 2w7340D 3 098 a999 o999 .11, .11, 2091 1. OG+OD 79105 1. 90+7 0 39054 9.05,03 39057 2. S&04 39057 3.4- 3 2 9
so coKic DEI-AYED COKING .11. 0998 Me 4.77-01 39058 4+77-01 3 2.7-2 39058 5.02-01 3 _ 011S -21GO l 101. 10 w 0-0 29055 G.00+00 29056 O.OG+OO29056 0 w -00 2 9056 2.13-00 3 2OL9 0400+0 2qOSfi OaO0+OO 29056 2v!3+00 3 .11. .92- 00999 o99G Oo 19 2091 0.97-01 29091 7.44+10 3906D 3.86+04 32047 16.37-04 39ofil 1. 02+011
2!
-H2.- HYDROGEN MANUFACTURF, oolo .11. oGG. eggs ogle O'go G-ol Goo, o999 o999 GG9G G.G04GG lGGLI GwoO+Oo 290% QmOO+00 29056 D.00+00 2 9056 1. 49.OD 3 9D62 0. 00+00 29056 10. -00 29056 CO.- 3 .9o. G99, o9ll Sol .11, 2091 5. 03-01 22079 1.03+12 22079 7.38+04 2 2D5: 3. -eS 2 -4.08+06 2
3 2H-T HYDROTREATING .11. Go'. ogle 0998 6.04-01 39- 6.04-GI 3 0- 7.33-01 390611 1 34+QG 3 8+63@02 3 9D64 iv72+00 3 9064 0.00+00 29055 O.GO+GO @2 9056 G.OG-GO2lell a. 0-0 2 9056 2.59+OD 3 9 US DIOO+OD 29056 O.GO+GO 29D56 L59-00 3 0998 oloo .... ose, o,99 2G91 9-41 29105 Iw13+I 0 39GGS 4.17+03 39D66 4. 8-4 3 9111 e.17- 1
3 3GASTR GAS TREATING OIOO+OG 2 9071 0.0100 2 9071 O.DO+00 7 9071 O.BO1OO 2 9071 O.-ob Go,, ..W.o -O+OG 7 9071 -- 29D71 GAO- 7 G.-O 1 9071 0.0-0 2 9071 0-0 2 -5 o.oo+oo .2 qo56 OmDO+D0 29056 3i3g@Oi 2 9072 0.00+00 2 9072 D. 00+00 2962 Q m ONOI) 29G72 3. 3910 1 O.OG+0O 2 9073 2.55+OD G 107o ol9l o'19 2001 1.00+00 2907S o.9 3'.32+D5 39GOG OwOO+O0 3 9076
76 3.32+05 3
34 TNKCR CRUDE STORAGE oll. IS. ..Go oll. .9l. G19S o999 o9oo @5@9 7,21-02 2 9033 osLq oaoD+oo 2 loss omoo4oob2 9o56 OmOG+OO Z0997 G.OD+OO 1 G997 5.4B+00 2 9034 0. -00 10997 0. -OG 20- S03+01 ? GdOO-00 2 0997 4.16-01 2 9035 ol. ..GG .9. 1 -0 2 9036 I.S4-06 49037 3.8-3 19011 1.08@03 3 qos3 6. 5"+0 S 341
3 5ST.GN STEAIA GENERATION O+aO+DO 3 1917 o.GO+OO 3 1917 op.@ 0999 3.4-0 4 M7 3w4O,OO 4 -G-00 3 1917 3@ 02-03 3 1917 3.40+00 4 _oG99 0990 0.00+00 1 1918 -7.34+QO 3-3901- 39Gt 7.93-Di 3 lell 1,96+01 3 39DI 1.9-1 33901 3@43+00 339DI 2.22+02 ..GG.G ;-04 a -3 5.67-02 3 1901 2. 36+GO 3 3 03 -0999 B-01 2910D -tNOO 10997 ..G G91, .99 3 5
36 DISTO DISTRIBUTION 31
3 7PIELN PI-INE G_ .1. .9., .1. .91. G91. Mo GGS. GO,, oll. 0998 1.61-01 3 90. 4.11+GG 1 1.1 1.34- 1 10l. -1-01 3 9038 2.79+OD 3 9"S 13.70-G2 3 903a 8+33100 3 MOO- 0997 6.36+01 2 7DO7 8w46-02 4 3G34 2037 IwOWO 2 2081 3.4-9 3 903 "9 2.S+M I 2on 37
36'
3 9 3 9
40 40
41 41
42 4 2
43 4 3
74 44
45 45
46 46
47 47
48 40
49 49
5 0 so
51 5 1
527
52
53 53
V
5 4 54
5
TABLE 3. ENVIRONMENTAL IMPACTS, EFFICIENCY AND
COST FOR ENVIRONMENTALLY CONTROLLED
OIL SHALE SUPPLY
V-7
7
."1'97
I lSo, 7
+.:
l Go 0
I'lo 7"1 '11' E31"!!
G __G, l .. 0
_GG l lo"
_`U l 2.7
G,
,.oG.oo Go 7
_G '036
o*,o
099,
-Io
Go
�
FTN. 10812002
Footnotes f t Table3
1081 Large scale disasters at strip mines are rarities. As
in auger mining only the failure of the highwall pre-
sents any potential for a disaster.
1082 The potential for large scale disasters qi's'non-existent.
1906 Source 0qU9061,46). 0.166 men per M0qWE is the basis for
the calculation Injury data ate from (190,7,,35). Half
the combined'deaths and permanent injuries are assumed
to be fatal,injuries. Permanent total disabilities are
conideredto represent 6000 days lost while other
:disabilities are estimated as 100 days lost. Man-days
lost are for injuries-only.
1912' A large new power plant is assumed to have a2qheat rate
of'8960 Btu/Kwt11'hr, equivalent to 38P conversion effi-
ciency. The best plants have achieved around 8530-
-10,500
8900, whereas the national average is around
1-.5-6/1-5-7).
@1917 The-basis,or water pollutant calculations is the pro-
posed effluent limitations guidelines and new source
performance standards for the steam electric:power
generating point source category given in (1921q). For
new plants, best available demonstrated control tech-
nology (BADCT) requires effluent pH control in the
range of'6-9. 'Hence,''acids and bases@discharge will
be negligible. BADCT also specifies.total suspended
solids levels no greater than 15 mg/ql for all intermediate
and low volume waste effluents. At this level of con-
trol there will generally be no net increase-inus-
pqended solids in water passing through the power plant
system. organics (oil and grease) must be,controlled
to 10 mg/q1 to meet BADCT standards. Hence, from (19 '21,
2.32) these emissions will amount to 3.02-03 ton/1012
Btu.,, Information on the increase in total dissolved
.solids of water used in Ipower plants is not readily
available,and was synthesized from (1922,6q10,12,20,22).
Based on this data the net-increase in total dissolved
solids' for water used by the power plant is 3.40 ton/
1012 Btu.
1918 Thermalq@discharges are assumed to be completely eliminated
by the use of 'mechanical draft wet co00qoling,towers.
2002 Land impact for pipeline transport of crudeq'oil 6qis
based on 1971 total crude oiltrunk and gathering
line mileage of 1464q2.00q4mi (2001,2) and total crude
Oil traq'n'sportedq'-by pipeline in 1971 "of 36q-.095E9 76qBBL
52qM005,14). Assuming an AV pipeline r2qi0q:ght-of-way of
62.5 ft (2002,14)q'q,q@aboutq'q163.6 A24qC are affected pe0qr 1q.2qOE12
Btu shipped.
16qVq-9
�
�
FTN. 2023 2052
2023 Hydrogen manufacture (steam.reforming)
SCF of natural gas feed equivalent to 1.OE12,Btu is
9.69EO8. (0005,38 and footnote 2000)
Water Pollutants
Thermal gallons.cooling,water/MSCF H2 is 650 and
Delta T is 25F (2005,270)
No other water pollutant information available.
Air Pollutants
The air pollutant sources include steam reformer
and wast 'e heat boiler, blowdown system, pipeline
valves and flanges, vessel relief valves, pump and
compressor seals and process drains. Air pollutant
emis .sion factors from (0002-,1-9,9-3/9-4). Natural
gas was assumed to be the fuel used in the reformer
and boiler.
SCF fuel required in reformer is 4 *947EO8. Based
on (2005,270) and 1031 Btu/SCF (0005,38) Electricity
at 0.4 KWH/1000 SCF fuel required in was@e heat
boiler is 0.0. Boiler uses waste gases from reior-
mer (2005,270).
Air Emissions (tons/yr)
Steam' Waste Heat. Other
Component Reformer Boiler Sources-
Particulates, 4.45E+00
NOX. 5.67E+01
sox 1.4-9E-01
HC 9.89E+00
Co 9.89E-02
NH3 .0.00E+00
Other.Organics 2.48E+00
With a natural gas feed of 1.OE12 Btu/yr, the hydro-
gen plant.can make 1.83E09 SCF H2/yr (2005,270).
A 100000 BPSD refinery uses approximately 100 MMSCFD
H2.
2034 Based on 1971 data for transport of crude oil by
pipeline, 83 disabling work injuries, 2517 man-days
lost, 1 death (0035,4). Total crude oil transported-
by pipeline in 1970 is 5.298EO9 BBL ('0011,561). The
allocation to 1.OE12 Btu/yr is 3.36E-05.
2047 Based on (9022,65) the capital cost of a 10000 BPSD
delayed coker is 8.OE06 dollars andits operating cost is
is 53.5 cents/BBL.
Fixed charge rate is 10P. 1972
dollars. BPSD equivalent to 1.OE12 Btu/yrLis 482.
Based on- (2010,176/182) the capital cost of a 100 MMSCFD
hydrogen plant.is.13.3EO6 dollars.and its operating
cost is 18.25 cents per MSCF H2. Fixed charge rate is
10P. 1972Aollars. SCFD H2 resulting from 1.OE12 Btu/yr
naturalgas-feed is 5.55EO6.
V-10
�
FTN. 20712-29.07.
2072 Based on operating revenues of $6.7EO8 and 5.3EO9
BBLS crude oil transported. 178.000 BBL/yr equivalent
to 1.OE12 Btu/yr.
2079 Based on feed and fuel re
quirements from footnote 20@3.
.2081 Based on (0012,71) 0.00,6P vol. is lost.in.leakage-.
Thus primary efficiency is 99.994P@@ From Footnote 2031@1@
pipeline energy' is 450 Btu/ton-mi. Average pipeline
movement is 300 miles. Tons/yr of crude and product are
26600 and 27,300 (Footnote 2074)..
2087 The major cause-of"all p@peline accidents in 197.0 was
external corrosion at 43P, earth-movin4 equipment
accounted -for 20P.,' personnel errors 4P.-Natural
catastrophes such as land slides, earthquakeslf',.and
floods were of minor magnitude in their effects on
pipelines. Dragging of anchor'lines 'can'rupture an
offshore-pipeline (.2003,Chapter.6)..
2091 Fire and/or explosions' caused by gas' leaks, oil.leaks,
acts of God, or human error. Possible damage to
refinery, personnel, adjacent properties.
2092 Fire and/or explosions caused by sparks and improper
venting. Most refinery firesand explosions are in
the tank farm.
2907 Capital and operating costs for controls are estimated
as follows,:
Control System- Capital Cost- Operating Cost-
$/Kw Ref Mills/Kw-hr Ref
Water Poll-Chemical 1 (1921,233) .05 (1921,234)
Water Poll-Ther'mal 10 (1915) (1920,,111-3)
Total 11 .10
Based on the above, a 60P load factor and a net plant
heat rate of.9053 Btu/Kw-hr (37.7P primary efficien 'cy
from footnote 2908) the incremental capital cost I-S
2.31+04 $/l.OE12 Btu and theIncremental operating
cost is 1. 10+04 $/l. OE12 Btu.' These are in addition
to-the costs given in Footnotes 2906 and 3905. Note
that incremental fuel costs associated with purchasing
a ..6P sulfur residual oil.(for oil fired power plants)
are notincluded in*the above.analysis. Although pro-
perly attributed to air pollution contrpl costs, the.
cost of fuel is not considered in the,operating and
maintenance costs of the uncontrolled case and hence
an incremental,fue 11 cost is not given.for the controlled
case.
V-11
�
FTN. 3901-9001
3901- Air Emission Components (Tons/l.OE12 Btu)
From (9010,1-9)
Particulates sox CO HC. NOx Aldehydes, etc.
7.34 .293 .190 19-.6 191 3.43
3903 See Footnote 1906, using.0.089 men per ME.
3904 Note that 'the only controls utilized are cooling
towers to prevent thermal discharge to water. Ten
acres are needed for the cooling towers with a 1000
ME plant. This is 6.3 percent of the total land use.
Land use@for a 1.OE12 Btu plant (input) has been
-linearly scaled from a 1000 ME plant.
3905 Cost of gas fired power plant at $100/Kw (1914) and (1915).
Operating and maintenance cost exclusive of*fuel cost at
0.51 mills/Kw-hr (1906,45). A .60P load factor is assumed
and the FCR for capital is 10P.
9000 The efficiency for room and pillar underground mining
is 65 percent (.9002,65). This figure is based on
preventing subsidence within'the mine.
9001 Air emissions as particulates are due to the vehicular
traffic and blasting within the mine itself. For a
mine processing 73,700 tons/day particulate emissions
are 25 lb/hr (9000 1, 111-122). For a raw oil shale
heating value of 7.53E+06 Btu/ton particulate emission
due to blasting within the mine is 3.51E-01 ton/l..00E.
+12 Btu input (9013). Using diesel trucks of 100
ton capacity .(gross to tare 2.5/1) and a 1500 ft
average distance between extraction and primary
storage, it takes -X328 round t_"ipsto haul
1.OOE+12 Btu of oil shale. Diesel particulate
emissions based on 7 gal/1000 T-mi are 13 lb/1.009+3
gal. For hauling 1.OOE+12 Btu of oil shale 621,gal are
consumed hence particulate emission.= 2.64E-03 tons.
Total emission is 3.54E-01 tons/1.00E+12 Btu (9010,3.7).
V-12+
�
FTN. 9002-9005
9002 Air emissi ons generated in the mine are generated by
vehicular traffic.- Exhaust fans disperse the pollutants
into the atmosphere Total polutants based-on .1328
round trips/l.OOE8q+12 Btu (see footnote 9001)
are as follows:
SOX 5.47E-0q3-ton
CO 6qA.55E-02 ton
HC 7.74E-03 ton
NOX .7.61E-02 ton
ALD 2p398qE-04 ton
Figures based on -(9010,3.5) and fuel tons8qu4qmption of
621 gqal.
9003 Water pollutants from the underground mining operation
will be negligible. If low quality-mine water with TDS
ranging from 200 to 63,000 PPM is encountered, it will be_,:
used for dust control and spent shale disposal, hence
alleviating the need to draw high quality water from
surface sources (9000).Initially mine water will be of
high quality and could be released tqo nearby streams
if ne cessqa0qry..
9004 :.Fixed land impact for an underground oil shale mine assuming
no subsidence is 10 acres for a 73,700 T/D operation
-(9000 1-111-12). Land is for mine opening, equipment
storage, maintenanc 2qp bldg, etc. The incremental land
impact for waste shale disposal, assuming a combination
of*surface disposal 0qaqn'd-return of theirste to the
underground voids, is 1.93 acre yr/10 Btu from (9000
1-111-1q8). Thus for a-yearly output of.1.82E4q+14 Btu, the
total land impact is 1.97 acre-yr/l.qOqOE4q+12,Btu..input.
9005 only the overburden necessary to open 6qthe-mine is
considered solid waste. For 4 mine,shafts each 25 ft
in diameter & 1500 feet deep, 1.47EqO5 tonof solq@d waste
are produced at an@assumed density of. .05ton/ft 'This
is for a 73,700 TPD oil shale operation (50,000 bbl/d)
so that over the 30 year lifetime of the line the solid
V-13
�
�
FTN. 9006-9009
12
waste amounts to 17.5 ton/10 Btu.
.9006 Occupational health statistics are based on (9000,1-
111-9). Over a 10 year period nonfatal and fatal
accidents for underground mining are 2,919 and 63.93
respectively (9000,1-111-235). For the 10year
operation 1.OOE+16 Btu are extracted from underground
mines. On a 1.OOE+12 Btu in:basis nonfatal accidents
are 1.89E .01 and fatal accidents are,4.14E-03.
9007 Ancillary energy-requirements for the room and.pillar
mining operation consist of 4,200 Xw-h/H (9027).for
operating electrical shovels, etc. This is for a
50,000 BPSD operation (73,60P T/D)'. On a 1.OOE+12
Btu extracted basis, ancillary energy is 6.'20E+08
Btu.'Real energy consumption is 3 times the Btu
equivalent = 1.86E+09 B 'tu. From footnote 9001, 621
gallons.0f.diesel fuel is used with a heating value
of 13Z,690 Btu/gal (9032t269). Total.energy consumption
is 1.2.7E+09 Btu/1.00E+12 Btu input.
9008 Water pollutants for the surface mining operation are
zero (9000,1,1-73). Oil shale is dry and drains well.
Storm water will be directed away-from the surface
mine by piping systems. Water obtained during mine
dewaterihg will-be used for spent shale disposal and
dust control. Excess water of high quality (low in
salinity) will be discharged directly to local streams
andrivers. Highly saline waters may, be disposed of-by
deep well injection or desalted and released
Contamination of ground water reservoirs by.;aline
water is hot quantifiable.
9009 Air pollutants from the surface mining operation
are a result of vehicular traffic. Dust is controlled
by water,sprays and blasting dust generated is not
quantifiable. 15 cy electric shovels are used to
excavate and load the 55 ton diesel (9000) trucks.
It is.asrsumed that the average distance from shovel to
portable crusher and conveying system is 2000 feet..
For-a gross to tare ratio of 2.5/1 and a fuel
consumption of 7 gal/1000T-mi, see footnote 9001, it
takes 819 gals to haul 1.33E+5 tons of oil shale.
In addition to the oil shale haulageloverburden must
be removed. Overburden averaging 450 ft (9 '000, 111,111-
11) and occupying 1.56E-01 acres/1.00E+12 Btu extracted
(see solid waste) weighs 1.52E+05 tons assuming a I
density of 0.05 T/CF. For a haulage distance@of l.-mile
to the disposal site, the fuel consumption is 2494 gal/
1.OOE+12 Btu extracted. Total fuel consumption is 3313
gallons/1.012 Btu out or 2054 gal/1012 Btu in.
V-114
�
FTN. 9010-9014
Air emissions are as follows'(9010,3.7)
Aarticulates .1.33E-02 tons,
sox 2.77E-02 tons
8qC4qo .314qE-01 tons
HC. 3'.79Eq-02 tons
NO4qX 3.79E-01 tons
A0qLD 3. O8qU- 0 3 tons
9010 Solid wastegenerated in the-,mining o
peration consists
of-o0qv0qerburden that must be removed to expose-the oil
shale.; With an average overburden of,450'feet (90001@
III,III-11) and an area of 28.5:cres/2.42E0q+07 ton/y8q;
(9000,1,111-12) 1.56E-01 acres are overturned on a
1.00E8q+12 Btu. Iextracted basis..Heatin6qg value of raw shaleiqn'
7..53E8q+06 Btu/ton. With a density of 0.05 ton/4qQF and,
average overburden of 450 ft, solid waste is 9.42E2q+04
4qton/l.q0q0E2q+12-Btu input. H4qo0qfever after 16 yr (of the 30
yr lifetime) backfilling of overburden begins so that
the solid waste is 5.03EqO4 ton/l.qOE12 Btu input.
9011. The incremental land impact for waste shal e and over-
2qburde4qadisposal, assuming revege8qtatqionof2qthe filled
canyons an8q12 backfill.into the mined-out pit, is 3.99@
acreyr/10, Btu from q(q�q0q0q0,1-1q1q1-q1q5q).
9012 For a qiqO year surface mining operation, fatal accidents
will be 6.2 and non-fatal will be,320 (9000,1.,111-235).
Over the'10 years 3.65E15 Btu will be extracted q(900,0,
1-111-9). Fatal.and non-fatal accidents on a 1.qOqOE2q+12
E-03 and 5' spect0qively.,
Btu input basis are,ql,.06 .'44E-02 re
9013 Efficiency,o8qf the oil shalesurface mining operation
is 62 percent (9000,1q111111-12). This figure assumes
lower grade shale oils (less than 30-gal/ton) are not
processed.
9014 Ancillary energy for a surface' mining operation consists
of energy consumed by the electric shovels and diesel
fuel used inhauling . For a large quarry shovel the
energy consumption is 0q.6 Kwq-64qh/c52qy (9016,439). The
specific volume of shale is 15 CF/T (9002,66). For
excavating 1q.8qO2qOE04q+12 Btu of oil shale, 1.33E08q+05 tons
of oil shale must be handled'. At 0.60 24qKwqjq-q!h/cy energy
consumption, ancillary energy is 9.36E04q+07 Btu/1012q2 Btu
in. Real energy is 3 times this or 6q2q.2q82ql24qE08q+Q2q8Btu. Diesel
fuel consumption isq"2,054 ga0qlq"0q(28qPo08qotnote 9009). At 138,690q*
;Btu/gal'energy consumption is 2q.85E08q+08 Btu/2q1.2q02q0E08q+12
Btu in. Total consumption is 5.6624qE16q+06q8.q,24qRt00qU80q/l40q0l2 Btu in..
24qVq-16q5
�
�
FTN.9015-9022
9015 Ancillary energy required to move 3100 T/H over a
distance of one mile, with arise/fall of 1000 feet
is 4000 HP. This is a 48 inch inclined belt conveyor
system (9033). To transport.qOqOE2q+ '12 Btu energy
consumption is 1.28E8q+05 4qKw-h. Real consumption is 3
times this or 1.3.E8q+09 Btu.
' 1 80q1
9016 Efficiency of the conveying system is 100 percent
based on negligible fugitive dust losses (9000,114q11
q1q1q1-19).
9017 For a conveying system of one mile (from mine t2qo
crushing plant)' and a right 2qof way'f 60 feet,,a 48
inch belt conveyor requires 7.2 acres. For a yearly
output of 1.82E2q+14 Btu, land impacts equal .4.OOE-02
acre-year/l.qOqOE2q+12 Btu.
9018 Air emissions during conveying consist of fugitive
dust. Enclosed conveying system will reduce,dust/
particulates to 20 lb/hr (9000,1,111q-132). For a year
@output of,.82E4q+14 Btu, particulate emissions
4.80E-01 ton/l.qOqO4qE2q+12 Btu.
9019 Air pollutants associated with oqil'shale haulage come
solely from truck exhaust. Dust is controlled by water
sprays. For hauling 1.33E6q+05 ton oil shale,a 100 ton truck'
will make.1330 trips. Assuming a distance of one mile,
gross -to tare ratio of 2.5/1.0, and,fuel consumption of
7 gal/1000 ton-mile, fuel consumption is 2180 gal. Air
pollutants are-as follows (9010,3.7)
Particulates 1.42E-02 tons/l.qOqOE2q+12 Btu
SOX' 2.94E-02 tons/l.qOqOE8q+12 Btu
8qC4qO 2.45E-q01 tons/l.qOqOE4q+12 Btu
4qH8qC 4.04E-02 tons/l.qOqOE4q+12 Btu.
NOqX 4.04E-01 tons/qI.qOqOE4q+12 Btu
A0qLD 3.27E-03 tons/l..OOE4q+12 Btu
Particulate emission from oil shale dust is not
quantifiable and is assumed to be controlled by water
sprays during loading.
9020 Land impact for a roadway one mile long and a 30 foot
00qri
52q%q,80qO52qt of way is 2q.4q00q016qM2q-02 acre-yr/l.8qO8qOE04q+12 Btu based on a
yearly output of 1.82E08q+14 Btu.
9021 Primary efficiency of truck hauling is 1.6qO6qOE12q+00 since
fugitive dust,losses are assumed to be negligible.
9022 From footnote 9019, diesel fuel consumption to haul
1.0qO0qOE16q+12 Btu of oil shale is.2180 gallons. Heating
V-16
�
�
FTN. 9023-9027
value of diesel fuel is 138,690 Btu/galq(10005,38).
Ancillary energy is 3.0q24qE2q+08 Btu/qI.qOqOE2q+12'Btu.
9023 Power requirement for a plant handling 73,600 ton/
day is 20904qKw for:the crushing and sizing operation
(9027q).his i's 0.68.5 Kwh/ton oil shale,. For,1p2ppp4q+05
toqn8q/l.qOqOE8q+12 Btu equivalent, the energy consumption is
3.09E2q+08 Btu.@F0qo'r real '0qconsump Ition ancillary energy is
3 x 3.09E2q+08 Btu q=9.28E2q+08 Btu.
9024 For a crushing 4qgeration handling-3070 t(0qo0qn2q/hr, 40 tons/
hr"are lost*(900 111,111-19). Primary"efficiency
is 9.87E-01.
9025 Air-emiqssi4qon8qg from the ctushing.and"sizing,plant:consist
primarIily of fugitive dust or particulates. These
emissions are-0qemitted to the*atmosphere through the
dust collection system.in the enclosed7crushing,plant
ventilation system. A wet collection system, cyclone
or ve4qhtu8qt i scrubber, will be placed on the primary
crusher and a dry collection device, cyclone or bag
house, placed on'the secondary and tertiary crushers.
Fugitive dust'emissions from these devices will not
exceed..35 lb/hr q(9000,1,1-79). For a yearly plant-
O6qut qmis, 1.00
.put of 1.826qE8q+14tu, particulate e sions,on a
,E8q+122pu basis are 8.40E-01 tons.
9026 Water pollutants.in the crushing activity will be
negligible. Forla 73,600 T/D operation, approximately
325 GPM will be necessary to operate dust control
devices.his wastewater is high in suspended solids
and probably will contain a dust suppress0qantsuch as'
ARXL s0qulqfonate (9000,1,1q-79). The.particuql8qate-and water
mixture will be piped to the spent shale disposal area.
Wastewater from the crushing and retortin6q' plant will be
4q9
conveyed via pipeline to the spent'shale disposal site.
it will be used for-wetting and irrigation of the
spent shale. Excess water from the:sp6qent :shale pile
will'2qbe trapped in' a holding pond andwill,be recycled
as needed. No water pollutants will be discharged from
the plantboundary-.
9027. Solid waste from th0qe crushing operation is aq-8qiesult
of miscellaneous spillage and losses in the system as
well as waste from dust control devices.. From footnote
9024, 960 T/D-q.are lost in the crushingq:opq'eration for04qa
plant processing 73,36q600 T/D. For a yearly6ql0qc4qlut6qi0qput of
1.82E08q+14 Btu,' solid waste in 1737 tons/36q156q6 Btu.
v-1q.7
�
�
.FTN. 9028-9031
9028 Land impact for the crushing operation handling 73,600
T/D with3 days storage is assumed to require 15 acres..
On a 1.00'.E+.12 Btu basis, land impact is 8.24E-02
acre-yrs..
9029 Wastewater generated in the.retorting activity is a
result of. boiler blowdown, steam'ge@erati6n, wet
scrubbing., and process water. Water (2 to 10 gal/ton)
is actually produced during retorting as the organic
matter is released (9000). For a 50,000 BPSD plant,
0.1 MGD of-wastewater is produced (9000). This water
contains 40,000 PPM as CAC03(9018). This process water
will receive chemical treatment,with lime to remove
carbonates, most of the ammonia, and some organic
material,(9018). This wastewater will then be consumed
in the spent.shale disposal system or used for dust
control in the overall plant operation. No effluent will
be discharged to the environment@ (9023) hence water
pollutan@Es are O.'OOE+00.
9030 Although@significant quantities of air pollutants are
generated in'both the Tosco and Gas Combustion retorts,
the tail@'gas is contained in a closed system and fed to
a gas-fiied power'plant. Air pollutants for burning
retort gases will be accounted for under the process of
electrical generation. Air emissions for the Tosco and
Gas Combustion steps will be 0.00+00 tons/1.00E+12 Btu
(9000,9028).'
9031 Air emissions for the Gas Gombustion electrical
generation activity are based on combusting the 100
Btu/SCF (9000) retort gas in a conventional gas-fired
power plant. Ret 'ort gas composition is given in (9028,
14).-Particulate emission is controlled to 0.03 GR/SCF
at the retortplant. 184 lb/hr are emitted for a gas
rate of 713889 SCF/min. For a heating value of 100 Btu/
SCF, particulate emission from the boiler is 2.15E+01
ton/l..OOE+12 Btu. SOX is calculated the same as
particulate, however 85 percent SOX stack gas removal
is requiried to meet the 1.2 lb/1.00E+06 Btu SOX
emission standard. All other emissions are based on
rates in,(9010,1-9). On a Btu input equivalent of
natural ga's to retort gas of 100 Btu/1031 Btu = 0.0971
the emission rates are as follows
CO 0.40 x 0.097 = 3.88E-02 lb/1,00E+06 SCF
HC 40.0 x 0.097 = 3.8$E+00 lb/1.00E+06 SCF
NOX -390.0.x 0.09.7 = 3.78E+01 lb/1.00E+06 SCF
ALD 3.00 x 0.097 = 2.91E-01 lb/1.00E+06 SCF
V-18
�
FTN. 9032-9035
For a 1.954 feed, the air emissions-on a 1.qOqOE2q+.
12 Btu basis are as follows
-01 tons
'2qC8qO .1.94E
l.-94E8q+01 tons
HC
N8qOx 1.89E2q+02 tons
A4qLD 1.46E2q+00' tons
9032 Air emissions.for the Tosco electrical generation
activity are based on.the composition ofthe retort
gas in (9028) and air emissio ns factors in q(9010,1q-9).
Particulate matter will consist of inorganic ash
which8qVill not be combusted in2qheconvenqtional gas-
fired,power4qplant.: The'heating value of theas is 815
Btu/SCF (9000,I-2qJ-18,q) and the output is 32,049. SC8qFM
on a-1.008qE2q+12 Stu basis the emission"of
particulates is 2.62E2q+00 tons. S02 is.based on the
same calculations. So.q@ emission is 5.22E8q+02 ton/1.00
E4q+12.'Th0qe remaining air pollutants are rat2qj4qoed on at,
energy basis to8qthose of natural gas. The,heating value
of Tosco retorq@_ 'gas is 815 Btu/SCF and .that of natural
gas is 1031,4qttu/SCF, hence emission factors are 0.791
of those specified in' (9010). For a 1.q0q0E2q+12 Btu-feed
of 1.23E2q+9 SCF, the air emissions are as follows..
NO0qX 1.90E8q+02 tons
C2qd 1.9q50qE-01 tons,
4qHC 1..95E2q+01 tons
4qA0qLD 1.46E2q+00 tons
9033 water pollution figures are based. on (9015). For a
q10'0,000BPS4qD refinery BOD loading is.100b/D. The
-B8qOD loading.for a total plant Output of q9.53E2q+13 Btu/
yr (2q5.80E2q+06 Btu/BBL)for a q50,000 BPSD refinery is
9.6'1E-02 ton8qs/l.qOqOE6q+12 Btu. In a controlled case an
A2qPI separator,is used to remove 25 perce0qhtO0qD. BOD
is.7.21E-02 tons/l.qOqOE8q+12 Btu (9015q).
9034 Air emission factors are based on a'storag8q6 of 4.734qE2q+
0-BB0qL (2q10 days).of crude oil in one 500 BBL floating
roof storage tank. C air emissions are .based on
30-lb/day breathing l8qoss'(9010).and no working loss.
20qYor aq-'storage,o0qf 2qJq.6qO2qOE12q+12 Btu/yr, the HC emissions
are 5.48E04q+00tons..
9035 For a 50,000 BPSD pl48qint.q,q.40q,ac40qr6qes are re76q464qdire68qd for
crude storage. For a yearly output of 9q.53E12q+12 Btu,
the. landLimpa32qqt 4qiS, 4q.1632qEq-01 acre-y04qr/1q.6q068q012q+12 Btu (9000,
Vq-19
�
�
FTN. 9036-9043
9036 Primary efficiency for crude oil storage is 100
percent'since hydrocarbon.emission'is considered to
be negligible with floating roof storage tanks.
9037 Ancillary energy is based on pumping 472'.6 B8qB8q@/D
q(1.qOqOE2q+12 Btu/yr) 36.5 times a year(10 days qfqitorage)
both into and out of the storage,tank. Assuming a
constant total head of 75 feetp a pumping rate of
2000 GPM through,an 8 inch steel line, and an effi-
ciency of 75 percent, 50 horsepower is required to
pump 12.0q1 hours. Btu equivalent is 1.54E2q+06 Btu.
9038 Ai0qr pollution is based on diesel engine-pump emissions
factors.! To pump 172,500 BB4qL of crude, 3.43E2q+0-9 Btu are
required using 450 Btu/T-mi (9034,7) and 7.03 lb/gal
(9003,588). For distillat0qe'heating value of 5.83E2q+06
Btu/BB2qL-' 6q2.478qF.6q+04 gals are consumed. From (9010.,3-7)
air emissions are
Particulates 1.614qE-01 tons
NO0qX 4.56E2q+00 tons
sox 3 34E-01 tons
HC 4q:56E-01 tons
4qC8qO 2.78E8q+00 tons
'A8qLD, 3.70E-02 tons
9039 To pump 172,500 BB0qL of crude 6q6il 300 miles (9003,2),
3.43E2q+09 Btu are required (see footnote 9038).
Ancillary energy is 3.43E8q+09.
9040 Solid waste is based on data in (9000,III-Iqlqi-q@3). For
every 73,600 tons of oil shaIle processed, 60,000 ton of
..spent oil shale is generated. For a 1.qOqOE8q+12 Btu
equivalent oil shale feed of 1.338qE2q+05 tons, 1.q0q8E2q+05
tons of spent shaleis generated.
9041 The retorting plant itself requires about 5 acres
(9002,94) for a'50,000 bbl/d operation (72,600 ton
shale/6q@q). For a raw shaleheating value of 7.53EqO q12
Btu/ton8qthis is equivalent to 2.78E-02cre yr/10 Btu.
Land impact for spent waste shale is considered in the
extraction footnotes.
9042 occupational health statistics ar16qe based on data in
4q(9000q,4q1,q1111-235). Statistics are based on a 10 year
period., The fatalities and nonfatalities are 1.37Eq-03
and 1.44Eq-01/1.2qO6qOE12 Btu.
9043 Fixed land impact for the Gas Combustion retort plant
is 10 acres for a 50,000q-BPSD plant. on a 1.82E08q+14
V-20
�
�
FTN. 9044-9050
Btu/yr input, fixed land impact is 5.50E02 AC-yr
8qA9002,83). Land impact for.spent waste shale is
considered-the extraction footnotes.
9044 Primary efficiency for the.Gas Comb4qU0qgtj6qo6qni. retort is
67.3 percent@of the standard Fischer'assay based on,
input of 5.470qE8q+11.Btu.and output of 3.680qE8q+11,Btu (9000).
9045 Primary efficiency of theosco II,indirect,.heating
retort-is.77.6 percent of standard Fischer,assay of
the recoverable-organic material (9035,I4qVq-11q). Based
on 4.8q2E2q+ll Btu output and 5.47E8q+ll Btu.input (total
heat b0qalance'of 970qA percent accounted for).
9046 Ancillary'energy is based on data.from'.(902'q7,41). Power
requirements for a.73,600 T/D retorting plant is
27,960 4qKw forretorting,4qAnd 23,610 Kw for solid waste
disposal. For a plant input of 1.qOqOE8q+12 B2qtu/yr, the
power-requirement is7.75E2q+09Btu. Real energy is 3
tqiqjqi6qmqs this or 2.338qE6q+10 Btu.
9047 For a 73.,600 T/D underground mine the fixed capital
costincluding deferred capital and interest during-
construction is 2.q17E8q+07 dollars (9000,1). Fora
mine producing 1.82E8q+14 B0qtu/yr (24.2EqO6 tp8qy) -the cost
allotted to 1.qOqOE2q+12 Btu, with a 10 percent fixed'
charge rate is 7.74E8q+03 dollars. Operating cost
including payroll ' supplies, labor, taxes', and
insurance is 2.22E4q+07 dollars. 'On a 1.qOqOE8q+12 Btu
basis, operating cost equals 7.93E8q+04 dollars.,
9048'* For a 147,q@00 T/D surface mine (3 64E14 Btu/yr), the' fixed
capital.cost including deferred [email protected] interest during
mine 'development is 4.96E8q+07 dollars. on a 1.OE2q+12
basis and at.a fixed charge rate of 14q6 percent, fixed
cost is8.43E2q+03 dollars (9000,Iq)@. Operating cost is
1.78E8q+07 dollars (9000,1). On,a 1.qOqOE8q+12 Btu 6qVasis,
operating cost is 3.03E2q+04 dollars.
9049 For an'inc -lined belt conveyor systemhandling 3100
T/hr (1.84E8q+14. Bt8qu/yr) the capital and operating cost
are 2.75E8q+06 and 2.69E8q+04 dollars/0qyr.:0qOn a 1.qOqOE8q+12
.Btu basis the capital cost is 1.49E8q+03 and annual
operating cost is 1.46E12q+02 dollars/yr (9038q3).
9050 Capital'q,c24qost for truck haulage is basedq.6qon,the cost
of 2 road graders, 2 water trucksq,q.and 50 q- 100 ton.
dump trucks. Total capital.cost is 4q.68E08q+06q- dollars
for hauling l.'82E08q+14 Btu/yr.-At a 10 percent fixed
charge rate, capital cost 2.46E12q+03 $/1q.00E08q+12
(9029,7/26)[email protected] cost based on.(9016,583). using
Vq-21
�
�
FTN. 9051-9054
1.56E+02 $/hr as operating cost toaul 1.828qE2q+14 Btu/
yr. Operating cost is 6.74E+03 $/l.'OOE8q+12 Btu.
0qp 0
9051 Capital cost for a 73,600.T/D crushing operation (1.82E2q+14
4qUtu/yr).i0qs 1.23E2q+07 dollars-q(90qD0.JIIq).pt a 10 percent
fixedcharge rate, fixed cost is 6.67E8q+03 $/1.q0q0E8q+12Bt4qu.
Operating cost is based-on energy consumption only. For
a requirem nt of.2090 Kw (Footnote 9023), operating cost
at 0.01q5 $/0qKw-h is 1.36E-8q+qOqj $-6q/1.q0q04qr8q+12 Btu.
9052 For an.input of 72,600 T/D (1.86E8q+14 Btu/yr) of oil shale,
the capital cost for a retorting plant is 1.16Eq+08 d0q4l4qarq3
(9027,37). On a 1.qOqOE2q+12 Btu/yr basis and a fixed rate of
0 percent, the fixed cost is 6.44E8q+04 dollars. Operation
cost for a 72,600 T/D plant is.1.87E8q+07 dollars. On a
q1.q0q0E8q+12 Btu/y'4qr basis, the annual operating cost is
I.. 048qEq78q0.5 :doql0ql8qarq4.
9053 Crude oil shale storage cost is based upon a
throughput of 172,500 BBL/yr and a 10 day storage
capacity. Equivalent tank size would:be 4720 BB8qL.
Capital or fixed cost for a 16,200 BBL tank is :
124,000 dollars. At fixed charge rate of 10 percent,,
fixed cost of a 5000 BBL tank is.3.83E2q+03 $/1.q0q08qE2q+12
Btu (9024,138).
Operating post is approximately 7 percent (9036,162/
168q). Operating cost are 2.68E8q+02 $/1.q0q0E2q+12 Btu.
9054 For atmospheric distillation.-, process water pollutants
are based on (9015) and an 4qan8qnual.BBL feed of
172,500. All wastewater requires primary or physical
treatment and secondary treatment in the form of.
an activated sludge plant. Removal efficiencies for
BOD, Phenols, '-Sulfides, and TDS are 90, 95, 95, , I
80 percent respectively. Pollutants for distillation
are as follows (9015, Table 5):
BOD 1.73E-03 tons/1.q0q0E2q+12 Btu
Phenol 4.30E4q+00 tons/1.q0q0E4q+12 Btu
Sulfide 4.304qE-03 tons/1.q0q0E4q+12 Btu
TDS 6.040qE-01-tons/l.qOqOE4q+12 Btu
For a 1.qOqOE8q+12 Btu/yr distillation process, power
required is 1.91E04q+10 Btu (9022 32). This includes
electrical at 6,qp92qOE-01 HP-Hr/B32qL1 and fuel (steam) at
1.07E08q+05 Btu/28qBB20qL. Cooling water is 3.74E08q+07 gal/
1.2qO2qOE08q+12 Btu. Wastewater is 10 gal/B72qB24qL feed (9020).
Miscellaneous HC emissions are based on (9010,9-4)
utilizing cooling water, wastewater, and 272q15 of
refinery capacity. HC 2.73E08q+00 tonq.96q/1.0024qE04q+12 Btu.
�
�
FTN. 9055-9059
9055 Cooling water for a 1.00+12-Btu/yr refinery
utilizing 'a'hyqd6qko0qgein'0qp0qla4qnt' is 1.71E2q+09 gal/yr. All
thermal pollution may,0qbe eliminated by utilizing a
mechanical draft wet cooling tower.
9056 Air emission for the discreet refinery.activ4qities
are a result of boiler and process heaters. Sufficient
low Btu fuel gas is. generated in the retortqiqn4q4.'steps.
to supply the re6qfineries'needs. To process 1.,OOE2q+12
Btu of shale oil 9.068qE8q+10 Btu2p fuel is required and
3.54E8q+10 Btu of,.2qd-electrical power is required, based
on 50i,0qKw and 40 percent efficiency. To process 172,500
BB4qt of shale oil requires 82.8 hours and retort gas
produced is 1.76E8q+qlql Btu (9028) Since the oil shale
upgrading plant Will be an [email protected] ofthe total
shale oil process, the fuel gas produced will be used
within a centrally located power plant which will
produce all electrical, fuel and steam requirements
for the'operatqion. Air pollutants produced by burning
fuel gas are accounted for in the power generation
process. Except for miscellaneous HC emissions
(footnote 9054)ll emissions are qO.qOqOE8q+00.
9057 capital and operating cost Isfor -a 10000.BPSD'atmospheric
distillation column are 15.97E2q+06 do llars (Footnote 2043)
a0qnd 14. 2 cent0qs/BBL (9022) respectively. 'Based on a 1.qOqOE8q+12
s
Btu/yr input, equivalent to 473 BPSD,.the capitalost i
7.55E2q+03 dollars. Operating cost is 2.45E8q+04.dollars/1 'OOE8q+12
Btu/yr Cost oqf wastewater treatment is attributed to the
distillation process. For a wastewater flow of 6144.gal/D
for processing 1.qOqOE4q+12 Btu/yr, wastewater treatment costs
are.4.3q!E8q+02 dollar capital and 4.1pE8q+02 dollars operating
cost. Cost figures are based on footnote 2102 scaled down
to-handle 614q44'gal/D. Total costs for distillation are
9. 05E8q+ 03 dollars capital and 2.51E8q+04 dollars operating.
9058 Water pollutants are,.based on feed of 159000 BB6qL fo8qr
the d6qelayed-coker. Wastewater treatment efficiencies
are stated,in footnote 9054. Pollutants areased-on
(902q6). Water' pollutants after waste treatment are as
qf qoql2qlcqk0qwqa
Non-De40qg64qradable Organics 2.47Eq-q-q;02q:tonqs
COD 1.02E08q+00 tons
TDS 4.77-01 tons
9059 Air 'emissions for process a36qnd boiler,fee40qd are given
in (9031) and (9032). Miscellaneous HC emissions from
pipelines, val52q*esqy flanges# pump seals are 71 6qlb/1.00
V- 23
�
�
FTN.,9060-9066
E+03 BBL refinery. Of the four major processes, the
coker throughput is 1/5 of total refinery throughput.
HC emissions directly associated with coker are
2.13E+00 ton/1.0q0E2q+12 Btu/yr (9010,9-4).
9060 Ancillary energy for the delayed coker'is 4.68E2q+05 Btu/
BBL based-on a fuel requirement of 4.65E8q+05 Btu/BBL and
electrical requirement of 2.74E8q+03 Btu/BBL (9022,65).
For a1.qOqO8qE8q+12 Btu/yr feed of159,000 BBL, energy is
7.44E8q+10 Btu.
9061 Operating cost based on 40 cents/BB0qL (9022,65). Escala-
ted 60 percent (9037) to reflect 1972 cost on.1.q0q0E8q+12
Btu/yr basis,. operating cost.is .37E8q+04 dollars.
9062 Air emissions based solely on HC emissions from
cooling water. No other information available. Cool-
_-Lag. water required for a 5.55E2q+06 SCF/D H2 plant
q(1.qOqOE8q+12 Btu/yr gas'feed) is 900 gal/MSCF H2
(902q2,183). From (9010) HC emissions are 6 lb/
1.qOqOE8q+06 gallon cooling water. HC emissions are
4.92E8q+00 tons/l.qOqOE4q+12.Btu/y-0qr.
9064 Water pollutants are based on (9020,11) for the
hydrotreating Unit with a 1.qOqO8qE8q+12:Btu/yr throughput
of 172,q@00 BBL. All wastewater receives primary and
secondary .treatment. Removal e qfficiencies given in footnote
(9054). Water pollut8qants'are as follows:
BOD 8.63E-02 tons
COD 1.72E8q+0q6 tons
Non-Degradable Organics 7.33E-01 tons
TDS 6.04E-01 tons
9065 Ancillary energy consists of process fuel@q(steam
boiler feed) and electric power. From (9022194)
fuel requirement is 60,06qMBt8qd6q/BB0qL and electrical
and compression-is 5247 Btu/BBL. For a 1.qOqOE4q+12
Btu feed of 172,500 8qBB0qL, energy is 1.130qE4q+10 Btu.
9066 operating cost for a hydrotreating unit is 28.10 cents/
BBL,0qdn2qCluding a 60 percent escalation cost (9022,94).
For a 172,500 BBL'fe0qed, operating costs are 4.85E8q+04
dollars. From (Footnote 2044) a 40,000 BPSD h20qydrotreating
unit costs 3.20E08q+06 dollars., For a feedq'of 172,500
BBL equivalent to 1012 Btu (521 BPSD)q,q@ at fixed rate
of 10 percent, fixed cost is 4.17E8qO3 dollars.
V-24
�
�
9067-9074
9067. Ancillary energy for the-'@T0qo4qz@co power generation
activity is qO.qOqOE4q+00.' Tdqs8qdo II retort gases will
produce the fuel and steam within the upgrading
facility..,
q�068 Ancillary energy for-theGas Combustion power genera-
tion activity is 0.00+00. Gas'produced in retorting
will'be used to produce steam for the upgrading
facility.
906 Land impact for in situ drqi1ing,and restoration is
based on the time average land i0qmpact-fo2qithe@
Colorado, Utah, and Wyoming tracts.8qAveraging the
land.impacts gives 1088 acres over a 30'year period.
For a crude value of.80E8q+06 Btu/BBL, and output of
50.000 BPSD, i 9.53E8q+13*Btu are produced. 6qOn a 1.qOqOE8q+12
Bt6qunput basis, land impact equals-6.47 ac-yr (9000,
9070 Occupationalhealth statistics are based on (9000,1,
111-235). On a 1.qOqOE8q+12'tu input basis, deaths are
3.64-03 and injuries are 5.69-01.
9071 Water pollutants for the g4qas treating facility are
- .-zero based on'steaqm-stripping of H2S and NH3
from sour refinery tail4qgaqs. Based on (9038,98) water.
from treatment facility is of sufficient quality
for reuse. Total water effluent is 4.31E4q+08 gal/yr/
1.OE2q+12 Btu0q/yr input.
9072 Air pollutants from the gas processing activity
consistlofo 2 fromlaus recovery system. With a 99
.percent efficient Claus plant with stack@0qqas cleaning,
so emissions are. 4.3E-01 T/D H S for a 2.39E4q+10 Btu/D
fe2qidq-(9000,IIIq)2po2pa q1.002qt8q+12 2Btu/yr feed the SO
emissions are 33. tons/yr. All other emissions a0qie
0.004q+00 si.qnce,gases are recycled to hydrogen plant.
9073 Solid waste for the gas treatingacility is 0.008q+00
since elemental sulfur and ammonia have a market
value (9038,9'9).
9074 Land impact forq.68qa 2.39E04q+09 Btu/Dq"gas treating facility
isq' assumed to occupy 2.0q'08qacresq. On a 8qi.OOE28q+12 Btu
basis, land impacts ar28qe 2.55E08q+00 A-yrs.
V-25
�
�
FTN.9075-9078
9075 Primary efficiency for-the gas treating facility is
100 percent based on (9000,111-111-26).
9076 For a gas treating plant for steam stripping, sour
water stripping, sulfur recovery.(0qClaus),, and ammonia
recovery, the capital costs ate:
(9038) Gas q+Water Stripping.q1.35E2q+06 dollar/40 T/D NH3
(9039) Claus Plant 3.q5-OE4q+05-dol.qlar/50 T/D S
To process 143 T/D NH3 and 43 T6qlb s q(5q0,0q00 BPSD plant),
using a 0.6 scale factor,@total capital cost is 2.90E
q+06 dollars. The gas feed equivalent is 2.39E8q+09 Btu/
D. using -a q1..qOqOE2q+q1-q2 Btu/yr basi 's, at 10 percent fixed
rat0qe,capital cost is 3.32E8q+05 dollars. Operating cost
is 1.21E2q+06,dollars/yr (9038) for stripping-and
1.qOqOE8q+05 dollar/yr for Claus recovery (9039), using a
8ql4qe'factor. On a 1.qOqOE2q+12 Btu/yr basis,
0.6.sca
operating cost is 1.50E2q+06 dollars/yr. For a 1.qOqO0qE2q+1.q2
Btu/yr feedl 49300 ton of NH3 and 27000 ton of S qi0qWeql
produced. At 40 dollars/ton NH3 and 15 dollars/ton S,,
annual credit for gas by-product recovery is 1.99E2q+06
dollars/yr. Operation cost is qO.qOqOE2q+00 dollars.
9077 Capital cost for a 50,000 BPSD.In Situ retorting plant,
using recovery .plant and co6qWpresson and initial
wells,. i2q@ 94.7E8q+06 dollars for processing 1. 68E8q+14Btu/yr
input. Annual 'ized capital cost q(8q10 PC FCR) for 1.008q9+q12
Btu/Yr input is 5.64E8q+04 dollars, plus l.59E8q+03 (from
Footnote 9079) for a total of 5.78E2q+04 dollars.
9078 Air emissions for the In Situ retorting activity are
based on flaring the low Btu product gas., A 50,000 1 - II
BPSD plant will produce 1.49E8q+09 SCF/CD q(9000'q1q1q1'q1q1q1q-
29) of low Btu gas, 30 Btu/8qS8qC4qF (9008,15) which is
flared after particulate removal'to 0.03 gr/SCF.
Assuming 90 percent combustion,control on CO & HC,
emissions are q(90-28):
Particulates 1.16E8q+03 ton/yr
POX 4.90E8q+04
4qN0qOqX NA
HC 2.82E4q+q04
24qC28qO 2.12E04q+2q63
Based on a retorting efficiency of 56.7 percent and a
50,000 bbl/d operation the air pollutants are:
V-26'
�
�
FTN. 9079-9083
ton/l.OE12 Btu
Particulates
sox 2 62E2q+02/
2qC2qo 1.13E2q+q01
4qH8qC 1.50q1'4qE2q+02
9079 Water pollutants from In situ ret6qbrt-qing,are q0.q0q0E2q+q00
since the water generated is treatedq:with lime, carbon
absorption, and ion exchange resins (9018). For a
plant producing 50,000 BPSD,.560,000 aal/D-are
generated (9000q0,111). After,waste treatment the waste-
-water contains 1890 PPM'which'is suitable for cooling.
tower makeup water (9018). For a 1 MGD treatment system
the costs are:
Process Capital 02eratin6qg
Lime Treatment 4.6lE4-04 4.61E8q+03 -(9041)
Ion Exchange- 2.10E2q+06 .2.10E2q+05 (9041)
Carbon Absorption, 5.36E2q+05 6.qOqOEq4-04 (9040)
Lime and ion exchange operation Costs are assumed to
be 10 peqicent of capital cost. For a plant processing
1.qOqOE8q+12 Btu/yr costs aria (retorting efficiency is'
5,6.7 percent)q;
Capital. 1.59E4q+03 dollars
Operation 1.64E8q+03 dollars
9081 Miscellaneous HC emissions based'on process drains,
cooling water, pipes, valves, flanges, and pumps -
(9010). For a hydrotre6qating unit processing 172,500
BPSD,.cooling water is 3.86E2q+07 gal, wastewater is
1 gal/BBL, and hydrotreating throughput.is 2/5 of,
total refin4q6qry,capacity. For a 1.qOqOE8q+12 Btu/yr
refinery misc. HC emissions are 2.59E8q+00 tons.
9082 Waste water will be treated and recycled for use within
the plant boundaries. It is assumed that no water
pollutants will be discharged (900q6,IIqIOI0qV-80).
9083 Air pollutants for processing 18q40E8q+12 4qBtu/yr occur in
the retorting, dis8qtillationqt.delayed coking, H2.
manufacture, hydrotreating, gas treating, and power
generation activities.For each process ,pollutant on
a 1 q*OOE08q+l2q@ B76qtu/yr basis s16qee individual,p20qtocesses and
respective footnotes and references. q.To process
1q.2qO6qOE12q+12 Btu/yr, the respective feeds-and pollutants
.are:
Vq-27
�
�
FTN. 9084-9085
Process Feed Part. NOx SOx HC CO 4qLD
Retort 13300OT/Y
Dist. 97900BPY 1.71
Coking 48950BPY 0.62
H2 Manu.., 779000SCF/YR 2.10
Hydrot. 89016BPY 1.32
Gas Trt., 4.378qE2q+10B4qTU/YR 1.5
Storage 91486 BPY 21p.
Power q1.q8q82qE2q+11BT4qU/YR 4.04 35.5 29.1, 3.65 .0365 .275
Total 0qT-4q74q66qT q-35q-.0qT TO q-.6 3 4qMq-6-4q9
Total pollutants to process 1.qOqO4qE8q+12 Btu are q8.28E
6q+01 tons.
9084 Air pollutants for processing.qOqOE2q+12 Btu/yr occur
in the retorting, distillation, delayed coking, H2
manufacture, hydrotreating, gas treating, and power
generation activities.or each process pollutant
on a 1.0qOE2q+12 Btu/yr basis see the individual
processes and their respective footnotes and references.
To process 1.qOqOE2q+12 Btu/yr of oil'shale, the unit
feed and pollutants are:.
Process 4qF0q6ed Part. NO4qX q!q!C 8qC8qO ALDI
Retort 13300qOT/Y
Dist. 122000BPY 2.16
Coking 61000BPY 0.777
H2 Manu. 97206q60SC ,F/YR 2.63
Hydrot. q1q1q1000BPY 1.86 1.66
Gas Trt. 5.4,q8E8q+10BT4qU/YR
qSItorage 114500BPY 3.64
Power 6.83E8q+10BTqU/YR 0.178 12.9 35.5 1.33 0.0133 0.099
Total .0.178 12.9 37.4 6qiq-q2q-.q2 -2q6-.q-0q133 0qTq-6qMq-9
Total air pollutants for processing J.qOqOE6q+12 Btu are
q6.28E2q+01 tons.
9085 Air pollutants for processing 1.qOqOE2q+12 Btu/yr occur in
the retorting', distillation, delayed cokings, H
4qn0qianufacturing, hydrotreating, gas treatingqr an0qi power
generationq'activities.q'For the pollutants fo24qk each process,
on a 1.2qO2qOE4q4q-12 Btu/yr.basis, see the individual-processes
and the respective footnotes and references. To process
1q.6qO6qOE16q+12 Btu/yr of oil shale, the unit feed and
pollutants are:
V-28
�
�
FTN. 9086-9090
Process Feed Part NOX SOx, HC CO ALD
Retort 1724OObPY 6.22, 262.0 1512qA 11.3
Dist., 97900BPY, 1.71
Coking 48950BPY 0.62
H2 Manu. 779000SCF/Y4qR, 2.10
Hydrot. 89016BPY 1.32
Gas Trt. 4.8q3q7E8q+10B0qTU/YR 1.5
Storage 914q86BPY 2,8q91
Steam * 3904q+10.BTU/YR .286 7.5 .011 ..76 .007 .134
Total 51 8qT8q68qT-_8q3q7q_ql8qZ8qVq_-4qTq_ 8qT8qrq-.6q7q-q- .134
Total' pollutants for processing 6ql.q0q0E8q+12 Btu are
4.49E4q+02, tons..
9086 Primary efficiency -for qIqn -2qSq! tu oil shale retorting
is assumed to be 56.7 percent. For nuclear
fracturing and retorting, efficiency 0qmay be as high
as 70 percent.(9001,,12q-9).. For an input of 172,400
BBL/yr (ql.,OO8qE2q+12 Btu/yr), 97900 BBL/yr are produced.
9087 Land impact for processing 1.qOqOE4q+12 Btu utilizing'
the gas2pomb0qustion method is based on 320 acres fixed'
land for surface facilities and o0qffsitqbs from (9000,
1-111-12) for a 72,700 T6qPD shale oil operation (50,000
bbl/d).
9088 Land impact for processing 1.qOqOE8q+12 Btu utilizing the
Tosco.IIprocess is based on 320 acres fixed land for
surface facilties and offsites from (9000,1-111-12) for.
a 72,700,TP6qD shaleil operation (50,000 bbl/d).
9089 Land impacts.'for conventional In Situ processing of
oil shale is' based on 230 acres fixed land foqr,:surface
facilities*and offsites from (90q00,I7III-12)f6r a
50,000 bbl/2qd operation plusthat land required in the
retorting process from footnote 9069 for a total of
7.84 acre yr/l.qOE12 Btu.
9090 occupational health statistics are based on retorting
and power generation only. No other information is
-the
available. For individual processes, refer to
respective fQot16qhotesq,a52qnd references. Toprocess 1.8qO2qOE08q+
12 Btu/yr theq.impa6qct4qs are:
Process Deaths Injuries Man-Days
Gas Combusti on 1.48Eq-03 1. 5520qE-6q088q1 4.44E-01
Tosco II 1.41Eq-03 1.48E-01 q.1.49E-01
In Situ 3q, 66E-q-q;q-03q- 5.71E-01 9q..28q0,28qE8q-02
V-29
�
�
FTN. 9091-9098
9091 Primary efficiency of@the delayed coking process is
89.7 percent based on an input of 1.55E+ll Btu/D
(hydrogen and product) and an output of 1.39E+ll
Btu/D (fuel gas and product) (9000,111).
9092 Primary efficiency of the hydrotreating process is
96.8 percent based on an input of 3.13E+ll Btu/D
(hydrogen and product) and an output of 3.02E+ll
Btu/D (fuel gas and product) (�000,III).
9093 Primary efficiency is based on the assumption that
53500 B/D of crude oil will be produced by retorting
72600 T/D of 7.53E+06 Btu/T oil.shale. Recovery
efficiency is 56.7 percent due to.migration and
drift of underground shale oil.
9094 Waste water will be treated and recycled for use
within the plant boundaries. It is assumed that no water
pollutants will be discharged (9000,III-IV-80).
9095 Overall primary efficiency is based on an input of.
1.33E+05 ton/yr (1.OOE+12 Btu/yr) and an output of
91486 BBL/yr (5.31E+ll Btu/yr) (ROOO,III).
9096 Overall efficiency of a Tosco II oil shale plant is
based on an.input of 133000 ton/yr (1.00.E+12 Btu/yr)
and an output of 114,500 BBL/yr (6.67E+ll Btu/yr).
9097 Ancillary energy for a Gas C-ombustion oil shale
processing plant is O.OOE+00 Btu/yr. A plant processing
72,600 T/D requires 50 MW (9031), hence a plant
processing 133,000 T/yr requires 250 Kw. Total
electrical energy for the.plant will require an input
of 2.09E+10 Btu/yr and a fuel/steam requirement of
3.90E+10 Btu/yr (9022). Total-energy required to
process 1.OOE+12 Btu/yr (133,000 T/yr) is 6.23E+10
Btu/yr. Fuel gas produced in retorting is 1.11E+ll
Btu/yr (9000,111).
9698 Ancillary* energy to process 133,000 T/yr (1.OOE+12
Btu/yr) utilizing the Tosco II method-is O.OOE+00
Btu/yr. Electrical requirements for retorting and
upgrading will.be 250 Kw-hr/h (1.97E+10 Btu/yr) and 1.2B*09
Btu/yr (9022) respectively. Fuel/steam requ irement for
upgrading is 4.83E+10 Btu/yr. Total energy required is
6.92E+1-0.Btu/yr. Fuel gas from.,retorting as a result
of processing 133,000 T/yr is equal to 6.92E+10 Btu/yr
(9028), hence a Tosco II plant will be self-sufficient.
v-3o
�
FTN 9099-9102
9099 Ancillary energy for the In Situ oil shale processing
plant is 5.99E8q+1.0 Btu/yr. Electric power'required to
process 133,q000 T/D by in situ,retorting, And upgrading
the resulting.97,900 B/D, is 2.09E8q+10Btu/yr. This
assumes total plant electrical requirement is the same
as the equivalent gas combustion planti-250 q]qKw-hr/h. Fuel/
steam for the upgrading facility requires 3.90E6q+10
Btu/yr(9022). Total-energy required is 5.9q98qE8q+10 Btu/
yr. Gas produced,for in situ.reto0qrting (29.2 Btu/SCF)
is too low@qin heating value for economic use
hence it is flared. All energy will be purchased, 2.09
E8q+10 Btu/yr electrical-energy and 3.90E4q+10 Btu/yr fuel
gas. Natural,gas will be4qused to firea0qheavy industrial
boiler to produce steam for upgrading.'
9100 Efficiency of a heavy industrial boiler is q8q8.0
percent (9041,19-6).
9101 Total annual capital and operating cost qfor processing
133000 T/y4qr q(1.qOqOE8q+12 Btu/yr) utilizing the gas
combustion retorting method is given below. For
references and footnotes, refer to individual
processes. Cost figures are in'dollar6qs.
Annualized Operating Total"
Process. Feed Ca8q2ital Cost Costs. Costs
Retorting 1.33E8q+05T/Y 5.82E8q+04 9.38E8q+04 q1.52E0q+qbq5
Distillation 9.79E8q+04BPY 4.28E4q+03 1.40E8q+05 1.44E8q+05
D. Coking, 4.90E8q+044qBPY 1.10E8q+04 1.95E8q+04 3.05E8q+04
H2 Manuf.- 7.79E8q+05SCF/YR 1.04E4q+04 5.19E8q+04 6.23E8q+04
Hydrotrmt 8.90E8q+040qBPY 1.95E+04 2.q50E4q+04 4.45E8q+04
Gas Trmt 4.37E8q+q1q0B6qT.U/YR 1.q28E8q+04 qO.qOE8q+00 1.28E8q+04
Storage 9.15E4q+04BPY 2.02E4q+03 1.41E4q+03 .43E8q+03
Power Plt 1.11E4q+11B6qTU/YR 3.96E8q+04
I.18E8q+05 3.32E8q+ 2qT.q-6qU6qTEq-4qT0qUqS'
9102 Total annual capital and operating cost for processing
T/Y q(1.qOqOE8q+12 Btu/yr) utilizing the Tosco II
method is given below.. For references,and.footnotes
see individual activities.
Vq-31
�
�
FTN. 9103-9105
Annualized operating Total
Process Feed Ca2ital Cost Costs Costs
Retorting 1.33E+05T/Y
DiIstillation 1.22E+05BPY 5.33E+03 1.75E+05 1.80E+05
D. Coking 6-10E+04BPY 1.37E+04 2.4'4E+04 3.81E+04
H2 Manuf. 9:72E+05SCF/YR 1.30E+04 6.49E+'04 7.79E+04
Hydrotrmt l..11E+05BPY 2.43E+04 3.13E+04 5.56E+04
Gas Trmt' 5.48E+10BTU/YR 1.61E+04- 7.58E+.04 9.19E+04
Storage 1.15E+05BPY 2.53E+03 1.76E+'03 4.29E+03
Power Pit 6.91E+10BTU/YR --- 3.96E+04
7'.50E+04 3.73E+05 4.87E+05
9103 Total annual capital and operating cost for an In Situ
oil shale operation processing 133000 T/Y.(56'.7 percent.
efficiency) or 97900 B/Y are given below. For individual
refere''nces and footnotes see the respective individual
activities.
Annualized, Operating Total
Process Feed@ Capital Cost Costs Costs
Retorting 1.33E+05T/Y. .5.12E+04 --- 5.12E+04
Distillation 9.79E+04BPY 4.28E+03' 1'.40E+05 1.44E+05
D. Coking, 4.9bE+04BPY 1.10E+04 1.95E+04 3.05E+04
H2 Manuf. 7.79E+05SCF/YR 1.04E+04 5.19E+04 6.23E+04
Hydrotrmt 8.90E+04BPY 1.95E+04 2.50E+04 4.45E+04
Gas Trmt 4.37E+10BTU/YR 1.28E+03 6.06E+04 7.34E+04
Storage 9.15E+04BPY 2.02E+03 1.41E+03 3.43E+03
Steam Plant 3.90E+10BTU/YR
1.11E+05 2.98E+05 4.09E+05
9104 Disasters (a-single accident resulting in 5 or more
deaths) occur frequently in underground mines. In the
past 40 years"@bnly 6 calendar years went without a'
disaster occurring.
9105 Primary efficiency is defined as 1 minus the fractio'n of
the primary fu *el input attributable to physical losses
minus the fraction of the primary fuel input used in the
processas fuel and/or steam. By equation, the primary
.efficiency equz
as (1-(Y 1,OE12)-(Z/1.OE12)) x 100P, where
Z is the Btu of physical losses and Y is the Btu of in-
put feed used as fuel and/or steam. All of the refinery
processes would use fuel gas as the primary fuel; thus
Y equals 0 and the primary efficiency approaches 1 except
for physical losses such as. those due to.evaporation-and
wastewater contaminants. This procedure results in a
high ancillary fuel requirement. It can be shown that
V-32
�
the overall process efficiency will be the same as.that
if Y were large and the ancillary demand low. All
e ies are o w
fficienc' n a Btu basis. It as further
assumed that oil lost to wastewaterwould have the
same heat content as crude.oil and that hydrocarbon
losses to the atmosphere would have a heating.value
of 200 Btu/lb.
V@33
�
VI. FLUIDIZED BED BOILER COMBUSTION
A., Introduction
The environmental impacts, efficiencies and costs of Fluidized
Bed Boiler Combdstion of coal in a power plant cycle are given in
Table 4 of this, report. All line entries in the. table are '$pro-
cesses" according to the,homenclature adopted and defined on page
II-1.2he fluidized'bed process. using coal is intended to be inte-
grated-with the-more complete set of coal data on extraction. con-
version,. transportation, etc. already' published in Volume I of
this'report. Fluidized bed combustion is.pa,rt of,th,e power'
plant conversion activity.
Entries in the'table are based on an energy input.of 1012 Ptu/
yr into each power@plant utilizing the"fluidized combustion''process.
All of the cost data shown in Table 4 is based on.a 75 percent
plant load factor, or 274-6pe-rating days/yr. The values
presented in this table are based on data accumulated during
the early months of 1974. Entries assume.controlled emissions
in all.cases. Entries in.the table reflect the combustion of a
.high sulfur central reg'ion,coal, a medium sulfur Northern
Appalachian coal and a low sulfur Northwestern coal in each
of two proposed fluidized bed boiler power plant systems.
These systems are:
The 635 Mw Westinghouse Pressurized Fluidized Bed-
Boiler Power Plant, Westingl@ou'se Research Labora-
tories, Pittsburgh, PA.
(2) The 30 Mw Pope, Evans and Robbins Atmospheric
Pressure.Fluidized Bed Boiler Power Plant, Pope,
Evans and Robbins, Inc., Alexandria, VA.
The concept of'fluidized bed combustion has.long been known
and used in the petrol Ieum industry. Its advantages for coal com-.,
bustion have begun to be.explored for several reasons,.* .The basic
justification for developing fluidized bed boilers is their ability.
to burn high sulfur coal.with low S02 and NOx emissions. Further,
the fluid bed's inherently high'heat release and heat transfer
coefficients can drastically reduce the boiler's size, weight, and
cost.
Instead of burning coal in a large-furnace where only the
furnace envelope absorbs-heat., crushed coal is burned in a fluidized
bed composed of,1/16 in. - 1/8 in. particles of limestone or dolomite
-which absorbs the sulfur in'the-coal.,to form,CaS04- The heat trans.-
fer surfaces or boiler tubes can be embedded in the fluidized bed.
directly because combustion takes place at temperatures-(@- 15000F)
which will-not damage-the tubes. Heat release rates of 200,060
Btu/ft3-hr have been attained in fluidized bed boilers'as compared
to 17,000 Btu/ft3-hr in.conventionial boi .lers. High heat release
results in the fluidized bed boiler being more compact than,a
V1_1
�
conventional boiler. Because of this., fluidized bed boilers can be
built as factory-assembled, packaged units, shipped to site and
arrayed as required. This reduces construction time for a new power
plant considerably.
The Westinghouse Pressurized Fluidized Bed Boiler,developed
for EPA, consists of four modules (Figure 21). Each module in-.
cludes four primary fluidized bed combustors stacked vertically.
Each module also contains- a separate fluidized carbon burn-up cell
to complete combustion ot carbon elutriAted from the primary beds.
Almost all the boiler heat transfer surface is immersed in the beds.
The beds are pressurized to 10 atmospheres and fluidization
.is carried out with air at 8-15 fps. After particulate removal,
the high pressure, high temperature gases leaving the combustor
pass directly into a gas turbine which expands them to atmospheric
pressure. Stack gas coolers recover sensible heat to' preheat
feedwater.
Coal combustion takes place in a dolomite bed to absorb
sulfur. The spent dolomite is regenerated in a two.-step.reduc-
t-ion/steam-C02 oxidation reaction, and recycled. The H2S released
during this process is recovered as sulfur. Make-up dolomite is
fed with the coakl.
The feedwater is preheated in the water walls enclosing the beds
and then saturated steam is generated in the boilertubes submersed
in the fluidized bed.' Saturated steam then flows through superheater
beds to the high@pressure steam turbine. The steam returns to the
reheat bed between the hiah and low pre.ssure.steam turbines.
The proposed Pope, Evans and Robbins Atmospheric Pressure
Fluidized Bed Boiler Power Plant, developed for OCR, consists of
a single-bed-level arrangement of four open-space modular cells
augmented by an open ro%4 of "seibel" water-containing tubes ex-
tending out from the integral wall dividers (Figure 22). Fluidi-
zati6n of the bed is carried out at 12-14.fps. The integral 2000OF
b,ed limestone regenerator and carbon burn-up cells (CBC) are water-
cooled. Offgases from both boiler and auxiliary cells are cooled
to 715OF by an integral economizer section. Boiler and regenerator
cell flyash are fed to the CBC.' Sulfated limestone is pneumatically
transported from the front of the boiler bed to the regeneration cell
where, under high t@emperature reducing conditions, CaS04 is converted
to CaO and.-S02 from which sulfur is recoveredi CaO is returned to
the'main boiler bed. One percent sodium chloride is added to the
boiler.along with the make-up limestone. This enhances sulfur ab7
sorption by the limestone and reduces carbon losses.
vi-@
�
TAIL GAS 300OF
STACK
SULFUR
PLANT
S
2
COAL DOLOMITE ------- PARTICULATE
REGENER REMOVAL
IR ATOR p SOLID
WASTE
REGENERATED
2000OF
DOLOMITE
CARBON
PRESSURIZED BURNUP SOLID,
AIR
FLUIDIZED BED WASTE
AIR
BOILER
1750OF
L-SPENT 10 atm. STEAM STEAM
TURBINE
DOLOMITE ERATOR
FLUE. GAS'
TURBINE
COAL a
MAKEUP
DOLOMITE
PREHEATED R
HEAT
Figure 21. Pressurized Fluidized Bed Boiler Power Plant RECOVERY
@
All
TU UR B
COOLING
WATER IN
�
DUST REMOVAL
TURBINE
GENERATOR
FAN
STEAM WIN STACK
PLANT
DUST L- ----- 6-1
LIMESTONE __SOLID
8 SALT WASTE
TAIL
GAS
U1 E12 - BED BOILER
2OW OF! L
15009F REGENERATOR
F"MMW CARSON BURN- CELL3
BOLEN UP CELLS
FT"! I
- - - - - - - - - - - - - - - - - -
AIR
Figure 22. Atmos"pheric Pressure Fluidized Bed Boiler Power Plant
FAN
I
@ID
AYL T
E@
�
B. IMPACT.DATA TABLE AND FOOT140TES
VI-5
�
CONTROLLED CASE 1 2 3 4 5 6 7 9 10 It 12 13 14 15 Is 17 is 19 20 21 22 03
FUEL REGION 24 25 26 27 26 29 30
COAL AS INDICATED WATER POLLUTANTS (TONS/ 1012 STU, EX. COL,.12) AIR POLLUTANTS (TONS/ld' STU) OCOUPATIONAL HEALTH POTENTIAL COST(DOLLARS/I
ROW MNE_ PROCESS DISSOLVED SOLIDS SUSPENDED TOTAL SOD coo THERMAL PARTIC NO, sox KYDRO- CO ALDEHYDES SOLIDS LAND DEATHS1 INJURIES MAN-DAYS LARGE PRIMARY ANCILLARY -
ACIDS BASES No, OTHER SOLIDS COL'S 6,7,8 Il ULATES CAR13ONS ETC. TOTAL TONS/ (ACRE-YRN SCALE EFFICIENCY ENERGY FIXED OPERATING TOTAL
w4k 170TAL(OS) ORGANICS (9TU/IO STIA 1012STU Vi-- - - - c
P04 OUI STU) 07 _I toil STU L-/d'B- DISASTER mIdlemo COST
CENTRAL REGION
2
PRF PRESS. FLUlDIZED BED COMBUSTION 0-00 3 9200 @.-0 1 0990 0999 1.82+01 4 9200 1.82+01 4 0.00+00 3 9200 3. 02- 03 3 9200 1.82+01 4 09.9 0099 0.00-00 1 9201 9-00 1 9202 6.73-01 1 97D2 4.41,02 1 12.2 -- 1 1103 '0.0-0 1 9103 0.0-0 1 92.3 @.14- 1 6.7-3 2 no 4.19+002 9205 0999 om 0"9 3.55-011 9206 C -. 7 007 3* 66+05 3 9207 1.28+05 3 U07 4.92+05 3
3 POWER PLANT CYCLE
3
4 ATFBB ATMOSPHERIC FLUIDIZED BED ...-0 3 9209 0. -00 3 92091 0999 0999 1.82+01 4 9209 .1. 82.01 4 0,00+00 3 I20q,3A2-G3 L82101 4 B999 0999 0-00 1 9201 1!73+01 1 9211.7AMI 1 9211 3.71+02 1 9211.2.-02 2 9211 2. 5-0 2 9211 D. D&O0 1 0997, 7.04+02 2 6.@03 2 921214.28@f)D @ 12113 0- 3.68-01 1 9214 0-0 2 OL972.35+05 2 921 1.34+05 3 9215 3,69+05@ 3
5 -STION POWER PLANT CYCLE
5
6 -ERN @UGHIA REGION
PRFB8 PRESSURIZED FLUIDIZED BED 0.0-0 2 9200 0-00 3 9200 0- 0999 1.32+01 4 9200 1.82+01 4 0-00 3 9200 3.0-1 -2.01 4 .991` 0999 0-00 1 9201 1.23+01 2 9221 C73-01 1 9221 2-2 1 -1 0.0-0 1 9203 0. -00 1 2203 0-00 1 92 3 249-2 1 5.79-03 2 9222 3.78+00 2 NL3 D9i 0919 0- 3-55-01 1 920 0.0000 2 -7 3- 60-05 3 1207 1. 19+05 3 9224 4. a5+05 3 7
COMBUSTION POWER PUNT CYCLE
ATFBB ATMOSPRERIC FLUIDIZED BED I IN, 0.- 1 12.1 0999 0999 1.82,01 4 9201 1.8-1 4 QmO@00 3 9209 1--03 91.9 '._-01 4 0999 0999 0.0@0 I VOI fl@IS2... 1 -1 7.0.. 1 -6 1.57+02 1 9726 -2-.42+02 2 -9226 2. 5-0 Z 1221 0-0 1 U97 4-02 2 5.88@03 2 9227 3.82,001-922A 01 11 0- ... 3.68-01 1 . 4 0-0 2 0997 2.35+05, - 1.23+053 1--- 3.5 8+05 9
10 COMBUSTION POWER PUNT Cycm- to
if NORTHWEST REGION
12 PRFB8 PRESSURIZED FLUIDIZED RED 0- @ 1- .-0 1 1 0999 0999 1.82.01 4 9200 1' "' a' 4
0-0 3 glog 3.02-03 3 9200 1482+01 4 0999 0999 1.110@ 1 11.1 1.1.... 2 12111 1 9216 7.78+01 1 9216 0.0(1+00 1 9203 0m(I(I+()d 1 $203 0A.00 1 9203 !A@Q 1 3.95+03 2 9217 3-0@002 .1. 011. 11. 3.56- 1 11 O.WOO 2 0997 2.56+05 3 9 1- 15+05 3 -9 4.81+05 1
56+05
COMBUSTION POWER PU, CYCLE
14 ATFBB ATMOSPKERIC FLUIDIZED BED 0-00 3 9209 0-00 3 9209 0999 0299 1. 02+01 4 9209 1.82+01 4 0. 00+00 3 9209 3.02-03 A 9209 L62+01 4 @9% 0999 0.00-00 1 9201 5,31+00 2 9230 7.0- 1 9230 5,68+01 1 9230 2.42-02 2 9230 2aSWO 2 92300w()@OO 1 0997 3.76.02 2 3. 9- 2 9231 3. 1@00 Z .... 0999 .11, .1. 09" 3.68-01 1 2 0997 2.35+05Z 121 1 3.51+05 3
15 COMBUSTION POWER PUNT CYCLE
to
to _.ML REGION
17 PFURIB PRESSURUED FLUIDIZED BED 0-0 3 9234 0-0 3 9234 0999 0999 1. 82+01 4 9234 11. 8-1 4 _L0- 3 9- 3.0-3 3 9234 1. 82+01 4 0999 0- %00 1 -4 1.04+01 2 9234 6.7-1- 1 1- 2.41+02 1 9234 A(I+00 I 92M 0-00 1 92L4 L.0- 1 9234 3.1- 1 53- Z I- @. 69.00 Z 1- 0999 02" 0"9 em 9234 0.6- 2 0997 3.66 4*86+05 3 I-,,_
18 COMBUSTION POWER PUNT CYCLE
to
19 ATFBBI ATMOS-RIC FLUIDIZED BED 0-0 3 9234 0-00 3 9234 .999 0999 1. 82.01 4 9214 1. 82+01 4 0-0. 3 923413.02-03 3 9234 1. 924 01 4 .9S, 0999 1 -4 ..3.+0. 2 923@1 1.00+ 1 1 9234 2.0-2 1 9234 2+42+02 2 9734 2-00 2 9234 Ow00- 2 9234 S.- 2 5.5-3 2 9234 3.73+002 9234 OJI .11, .19, 0"9 3-58-01 1 923 OvO()+00 2 0997 34 3.59+05 3
- 2. 35+05 2 1234 1.24+05 1 22
20 COMBUSTION POWER PUNT CYCILE 2;)
21
2 2
2 1
23 23
2 4
24
25
2 5
26 26
27 9
28 2
29
30
30
3 1 37
32 3 2
33 3 3
34 3 4
3i
3 5
36 38]
37 37
38 3
39 3 9
40 49,
41 41
42 2
43 431
44 4 4
45 45
46
46
47
49 48
4 9
50
51 Sol
5 1
5 2 32
5 3 53'
54
55 _L4
TABLE 4. ENVIRONMENTAL IMPACTS, EFFICIE14CY AND
COST FOR ENVIRONMENTALLY CONTROLLED
NATIONAL AND REGIONAL FLUIDIZED BED
BOILER COMBUSTION POWER PLANTS
V I - 7
�
FTN. 9200-9202
Footnotes for Table 4
920.0 Entries in the table .are based on an energy inp!@t to each
process of 1.OOE12 Btu/yr. Water pollutants are assumed
to be the same as those,from a controlled conventional
coal-fired boiler since many of.the unit process opera-
tions are the"game. Thus from footnote 1908.organic
emissions are 3.02-03 ton/1012 Btu and.dissolved solids
amount to 18.2, ton/1012 Btu'.while'incre ,ase in-suspended
solids is negligible. Capital cost for,control is esti-
mated at $ 1/Kw and operating cost is taken at .05 mills/
Kw-hr, (9221, 233,1 234).
9201 Thermal-pollution is controlled by use of a mechanical
draft wet.cooling tower system at a cost of $10/Kw (9221).
Cooling tower-operating cost is estimated.at 0.05 mills/
Kw-hr (9209,111-3). First generation fluidized bed
boiler plants will produce 10 percent.less waste heat
than conventional plants , and second generation plants
will produce 25 percent less waste heat (9200,274)..
9202 Air emissions for the 635 Mw pressurized fluidized bed
boiler plant which are given in (9200,272) are based on
a plant with a heat rate of 8892-Btu/Kw-hr and a full
load plant efficiency of 38.4 percent,(9200,272).
However, by this report's definition oflefficiency
(see explanatory section prefacing report), the additional'
coal used in the dolomite regeneration s,ystem.must also
be included as part of the primary energy input. From
(9200,274*) fuel for regeneration amounts to 0.31'mills/
Kw-hr. Dividing.by total fuel costs of 4.35 mills/Kw-hr,
7.12 percent is the fraction of total coal used for the
regeneration system. On this premise, the'heat rate of
the plant then. becomes 8892+(0.0712x8892) Btu/Kw-hr or
9.525 Btu/Kw-hr, and plant efficiency is thus reduced to
35.8 percent., From (9221,234,446) electrical-energy re-
5"022 Mwe or 1%
quirements for a, 500 Mwe plant amount to
for thermal and chemical water pollution'control. Hence
the overall plant efficiency is reduced.to 35.5 percent..
The plant operates at 10 atmospheres pressure with
bed temperatures of 1300 to 1750 degrees F. Air
emissions are based onthe fluidization of a 4.3
percent sulf ur Central region. coal with dolomite absorbent
added to-that portion of it in the boilerl:.(93.percent) to
a net
give a calcium/sulfur ratio'of 6/1. The coal has
,heating value of 12500 Btu/lb and an ash content of
8.5percent. Air emissions given in the table are based
on those given in (9200,272), but adjusted as stated
above to reflect the additional coal considered as primary-
energy input'.. Thus for a l.0El'XBtu ihpxit, 7.12 percent
or 7.12E10,Btugoes to th.e.regener ,ator and.92.88 perc ent.
or 0.93E12 Btu is combusted in the boiler.Particulate
emissions are derived,from the boiler plant (includes -
boiler and coal drying.but not fugitive-dust)-0.0186 to
0.149 lb/l.OE06 Btu. The upper limit of this range is
VI-9
�
FTN. M3-9204
for the case where no particulate control on the stack
is used in addition to the'four 90 percent efficient
cyclone collectors and two 97 percent efficient Tornado
collectors presently planned for each boiler,module
(9200,271). (Each module includes 4 primary fluidized
bed combustors-one bed for the pre-evaporator, 2 beds
for the superheater and one bed-for the reheater). The
lower end of the particulate rangewhich is used in the
table,assumes one additional 90 percent efficient
secondary cyclone. NOX emissions derive from the boiler
plant and range from 0.065-0.204 lb/l.OE06 Btu. Under
combustion conditions of 1500 degrees F, a-sulfated bed
(which promotes-reduction,of NOX (9206,18)),.limitation
of excess air to the bed and maintenance of high pressurer
NOx emissions can be controlled within this range. This
is well belbw the EPA emission standard of 0.7 lb N02/
1.OE06 Btu (9207,19). SOX emissions derive from the
boiler plant (0.65 lb/l.OE06 Btu), dolomite regeneration
(0.093 lb/l.OE06 Btu),and sulfur recovery (0.093-0.186
lb/l.OE06 Btu). Total SOX emissions are 0.836-0.929-lb/
1.OE06 Btu, well below the.,EPA emission standard of 1 '.2
lb/-l.OEO.6 Btu. Emissions shown in the table are, except
for particulates, calculated*from the'average between
the high and low values for each pollutant as given
above.
..Air emissions summary for a 635 [email protected]
bed boiler in tons/l.OE12 Btu
Particulates 9.3
Sulfur Oxides (as S02) 441.2
Nitrogen Oxides 67.3
Total 517.8
9203 Under the design conditions of operation given in (9200,.
269),i.e'. 10 Atm Pressure, 10 percent excess air in the
primary beds and@30 percent excess air in the carbon
burn-up cell, it is assumed that there are no gaseous
carbon c ompounds produced which are-not fully oxidized
to C02(9205).
9204 Footnote 9202 states that the coal contains 8.5-percent
ash which amounts to 3400 tons/l.OE12 Btu. Ref. (9204,
147) states that 10 percent of the sorbent is rejected
during'regeneration and 3 percent is elutriated from
the bed. From the material balance diagram shown in
Ref. (9204,H-1.00) it can be seen that the dolomite
make-up.rate is- 10.6 percent of the dolomite in the
boiler. Thus, this is the amount discarded to solid
VI-10
�
FTN. 9206-9207
waste and amounts to 3354.82 tons dolomite/l.OE12 Btu.
Therefore total solid waste (subtracting particulates)
is 6755.3 tons/l.OE12 Btu.' Sulfur recovered not included.
9205@. From the site plan of the 635 Mw-plant'shown in Ref.
(9207,105) the fixed land impact for the plant, including
coal storage and.ash and dolomite storage, is 59.8 acres.
Using the plant heat rate calculated in footnote 9202
of 9621 Btu/Kw-hr, and a 75 percent load factor, Btu's/
yr going into the plant were calculated as 40.1E12
Btu. Scaling down linearly to 1.OE12 Btu/yr input, fixed
land impact was determined as 1.49 acres.. From (.9222,
45) cooling towers ate estimated to occupy 10 acres.for
a 1000 Mwe plant oi:'..130 .ac-yr/1012 Btu. Hence the total.
fixed land use is 1.62.ac-yr/1012 Btu. Based on
6755.3 tons solid waste with an average density of 60.45
lb/CF (see footnote 9213), and waste banks'36-ft high,
the annual incremental land use due to solid waste is
0.171 acres. Time averaged over.a. 30 yr plant lifetime
and added to fixed land gives a total land impact of 4.19
acre-yr/l.OE12 Btu.
9@06. The' literature value of efficiency, 38.4 percent (see
footnote 5202 for efficiency value adjusted for coal
input into regenerator)@assumes a back pressure of 1-1/2
inches mercury, a boiler efficiency of 88.6 percent
and pressure losses in the gas turbine combustor loop
of 7.5 percent.
9207 Fixed costs were.determined from (9200,273) for a,
regenerative pressurized fluidized bed boiler power
cycle of 635 MWe producing 4.17EO9 Kw-hr/yr at a
load factor of 75 percent and a heat rate of 9621 Btu/
Kw-hr (see footnote 9202)..No adjustment has been made
in the dollars/Kw value to reflect the use of-a 75
L:)errent load-factor instead of the 7Q percent used in
(9200,273). Construction costs escalated to $220.36/Kw
from (9208,162). Total fixed cost does not include the
cost of coal (49 cents/million Btu (9200,273)), but does
include water pollution control costs (see footnote 9200
& 9201). Total fixed cost is thus 3.49E+06-dollars +
1.74E+05 dollars..per 1.OE12 Btu. At a fixed charge rate
of 10 percent, annual fixed cost is 3.66E,05 dollars/l. OE12
Btu.. Operating costs of 0.98 mills/Kw-hr are from (9200,
274) updated to-1972 prices (9208,162). Operating costs
*also include cost of water:pollution1control at 0.1 mills/
Kw-hr (see footnote.,9200 and 9201) and the cost of dolomite-
limestone absorbent at 4.38 dollars/ton (9200.,,274) to give
a total operating cost of 1.26EO5 doll,ars/l.OE12 Btu. No
credit has been taken-for. 'sulfur recovery.
�
FTN. 9209-9211
9209 Entries in the table are based on energy input to each
process of l.'OOE12 Btu/yr. Entries for water pollutants
are assumed to be the same as those from a controlled
conventional coal-fired boiler since many of the unit
process operations are the 'same. Thus from footnote
12
1908 organic emissions are 3.02-03'ton/10 Btu. Dissolved
solids amount to 18.2 iton/1012 Btu while increase in
suspended solids is nlegligible. Capital cost for control
is estimated at $ 1/Kw and operating cost is taken at
0.05 mills/Kw-hr (9221,233,234).- The efficiency of
the Pope, Evans and Robbins plant has been stated to
be 37.2.percent with a plant he 'at rate of 9187 Btu/Kw-hr
(9218). By taking the data from (9210,48) for a plant
with an annual coal input of 106,000 tons and annual out-
put of 271,000 Mw-hr, and using a heating value for the
.coal of 11,640 Btu/lb .(9211,7), these values.can be cal-
culated approximately.
9211 Emission-factors in the table were calculated assuming
a Central region coal with a net caloric heating value
of 12,500 Btu/lb, a sulfur.content of 4.3 percent and
an ash content of 8.5 percent. They apply to a 30 Mw
single-lev'el atmospheric pressure fluidized bed
boiler power plant with a , heat rate of 9187
Btu/Kw-hr and an-overall plant efficiency of 36.8 percent
(see footnote 9214). The plant operates at a temperature
of 1500-1600 degrees F in the boiler and 12-14 FPS flue
gas velocity-with the integral carbon burn-up cell and
regenerator bed sections operating at 1900-2050 degreesF
(9212-130). One-e-ighth inch particle size 1*estone is
added to the coal to give.a calcium/sulfur ratio of 2/1-with
limestone makeup added to account for a bed blowdown of
about 10 percent. One percent sodium chloride is added
with the limestone to enhance sulfur absorption '(9212,
31 and 9211,5)..Particulate emissions derive from the
primary, carbon burn-up, and regenerator cells of the
system. Each stream is cleaned with a high efficiency
cyclone (eff.=85 percent), and the first two streams
are further cleaned with an electrostatic precipitator
(eff."99+ percent). The tail gas of the regenerator
effluent is recycled to the boiler (9212,5-6). From
(9211,14), 12.1 percent of the ash in the coal appears
.in the flue gasbefore the electrostatic precipitator
.or,411.4 ton coal ash/1.00E12 Btu for an 8.5 percent
ash coal. Also, from (9211,14) and (9213,8).which
states that 10 percent of the flyash is,,calcium sulfate
and 40 percent calciumoxide, one percent of the calcium
in the boiler appears-as calcium sulfate in the flyash
and 9.6.percent of the calcium in the boiler appears as
calcium oxide,in the flyash. Accordingly, for the 4.3
percent sulfur coal.requiring 22.165 lb limestone/1-0E
6 Btu for a 2/1 Ca/S ratio, 0.686 lb of calcium-appears
in the flyash as 0.28 lb Ca'S04/1-OE6 Btu, and 0.826 lb
VI-12
�
FTN. 9212
Ca appear in the flyash as 1.156 lb CaqO/l.qOE6 Btu. These
amounts together with the ash amount to 1129.4 tons/l.qOE
12 Btu before the electrostatic precipitator which reduces
6qp
articulates to 11.3,ton/l2pp12 Btu. Sulfur emissions
derive from the boiler where about 80 percent of the
qs
ulfur in the coal is absorbed by the limestone. Ten
Percent of the sulfur in.the coal appears in the solid
waste,and 10 percent is e'mittedt0q6 the atmosphere (9213,
7). No sulfur emissions ate expected from.sulfur recovery
from regenerator effluent since the stripped tail gas
is recycled to the-0qIncoming boiler air..Fo8qrqa 4.3 percent
sulfur coal, 12,500 Btu/lb*heat content, the sulfur
emitted.to the.atmosphere would be -189.2 to0qn2q/l.qOqOE12.
Btu.or 378.4 ton S02/1-qOE12 Btu.O0qX emissions derive from
the boiler plant and-amount to an average of 0.14 lb N4qOx/
l.qOqOE6 Btu or 70 ton/6qI.qOqOE12 Btu (9211,0q10q). Hydrocarbons
and ACO are present in the flue gas in.amounts on the order
of 1000 PPM .q(vol0qume-basis) and 0.2-q0. volume percent
respectively, with 3 percent excess oxygen the boiler
outlet (9214q) The coal producing these emissions on
@combqustion in the Pope, Evans and Robbins fluidized bed
boiler is a 4.6 percent sulfur,12,34qd Btu/lb, 15.8
percent ash coal. It is assumed that its combustion
characteristics are similar to the 1250.0 Btu/lb, 4.3
percent sulfur coal used to compute other emissions.
Therefore,'CO and hydrocarbons were calculated using
data given in (9211,14), Moles of-flue gas/l.qOE6 Btu
were calculated as 13763.8 moles or 5.2.87 liters/mole. Hydro-
carbons were calculated'as methane to be .484@l6qb2q/l.qOEq6
Btu, 242-ton/l.qOqOE12 Btu. Using a density of .0738 lb/CF
(9215,1936) for C4qOat 0 degrees C and 760 mm,pressure,
CO was.found to-be 0,005 lb/l.qOE6 Btu or 2.5 t2q6n/l.qOqOE12
Btu.
Air emissions summary for a 3qQ MW atmospheric pressure,,
qsin6q4le-level fluidized bed boiler plant in.tons/l.qOqOE12'
B4qtu
Particulates 11.3
Sulfur Oxides (as S02) 378.0
Nitrogen'Oxides 32q70.0
242.
Hydrocarbons 6q@qLs CH04q@
Carbon Monoxide 2.5
703.q,8
Total
9212 The amountq.q-of ash issuing from the combus48qtionof 1.2qOE12
Btuq,8.5 percent coal would be 3400ton. Makeup limestone
is added at the rate of 3 times the weight of sulfur in
the coal (9213,4). For a4.3 percent coal, this would
VIq-13
�
�
FTN. 9213-9215
amount to $160 ton limestone or 2002 ton Ca/l..OE12 Btu
discarded from the system (limestone assumed to contain
97 percent calcium carbonate by weight). From (9213,8)
four-fifths of the calcium in the waste is present as
calcium oxide and one-fifth as calcium sulfate. This
amounts to 1361.36 tons calcium sulfate and 2242.24
tons calcium oxide. Thus,' subtracting particulate
emissions of 11.3 ton/l.OE12 Btu, solid waste amounts to
6992.3 ton/l.OE12 Btu. Sulfur recovered not included.
9213 Fixed land impact for the atmospheric,pressure
fluidized bed boiler was taken as that given in footnote
9205 for the pressurized plant--l.62 acre-yr/1-OOE12 Btu.
From footnote 9212, solid waste is 6992.3 ton/lAOE12 Btu,
with a flyash,component of 3393.9 tons and.a CaS04-CaO
component of 3598.4tons (appropriate proportions of
the particulate emissions subtracted). From (.9216.,4),
the average bulk density of coal flyash is 1 gm/cc or
62.4 lb/CF.'From (,9213,13) the calcium in the solid
waste is present mostly as calcium oxide which has a
bulk density of 53-64 lb/CF (9217,6-8). Thus an
average density for the,solid waste of 60.45 lb/CF
was used. Assuming waste banks 30 ft high, the
annual incremental land-use due to solid waste was
determined to be 0.177.acre-yr/1.0t12 Btu. Time-averdged
over a 30 yr plant lifetime,.total land impact is thus
4.'28 acre-yr/l.OE12 Btu.
9214 Primary efficiency is given as 37.2 percent. (See footnote
9219)0. From (9221,23.4,446) electrical energy requirements
.for a 500 MWe plant amount to.5.022 MWe or one percent for
thermal an.d chemical water pollution control. Hence the
overall plant efficiency is reduced to 36.8 percent.
9215 (9212,32) states that.a plant 'cost of 37 million
dollars or 125 dollars/Kw is anticipated for a 300 MW
atmospheric fluidized bed boiler plant (1972 figures).
Referring to (9210,58) this estimate is seen to
include land, structures, boiler plant'eq-dipment,
turbine, electrical equipment and.miscellaneous. Adding
a 6 percent contingency fund (7.44 dollars/Kw) and
water pollution control.costs (See footnotes 9200,9201)
the,cost becomes 143.44 dollars/Kw. For a,plant with a
heat rate.of 9280 B.tu/Kw-hr, the fixed cost for an annual
input of 1.OE12 Btu/yr, at a 10 PC fixed charge rate,
is 2.35EO5,dollars/l.OE12 Btu input. Coal costs at 49
cents/l.OE6 Btu are not included in operating costs
(9200,273)-. Limestone costs of 4.35 dollars/ton delivered
(9200,274) are updated to 1972 costs from (9208,162) for
an input of 5160. ton/l.OE12 Btu input. Water pol-lution
control costs are.0.10 mills/Kw-hr .(see footnotes*9200,9201).
VI-14
�
FTN 9216-9217
Operating and maintenance costs for an atmospheric
plant-were taken,from (9207,132) on the,assumption that
-these costs would be similar whether the plant has
single-level beds or'stacked beds. Updated,-to 1972 costs
from(92q68,6q162_q) this-amounts to 0.94' millqs/Kw-hr.'
Tot6qal.operating cost',, not including credit for sulfur
recovered fly0qash sold, is 1.34EqO5 dollars/qI.qO8qEq12
Btu. Plant load factor is75.percent.
9216 Emissionfactors in the table are based on anin6qp0qut of
2q16qAE12 Btu of -,Northwest region. coal with a q0.5 percent
sulfur,.6 percent ash and heating value of 8800Btu/
lb. The cal8qcul0qations,are made on the sameq'ases as set
out-in footnote 9202,'i.e,92.8q9 percent of 'the,input
coal goes tohe boiler and 7.1 percent goes to the coal
combustor of the regenerator system,. Thus, there are 113.6
lb coai/1'.qOE06 Btu producing 6.82 lb ash. The portion that
is combustedn the boilercontains 0.53 lb sulfur
requiring the addition of 10,46 lb-doomite fora 6/1
Ca/S ratio. The absorbent in this case is not actually
necessary in order for sulfur-emissions tomeet EPA
standards (1.2 lb S02/1.qOE06 Btu), but is assumed added
in, the above@proportions-in order to have standardized
data for a high, low, and medium -sulfur coal. Using
the mass.balance diagram in (9204,100q),t'was determined
that 0.306qpercen2qt of the-ash in the coal and 0.0050
percent of the dolomite added to the coal appeai -s
particulate emissions. T 'hereis an additional 9u percent
efficient cyclone for flue gas clean up (seefootnotiqj
.9202q).-0qUsing these.rati8q6s, particulate emissions for this
coalere determined as 0_0194 lb/1.q0E06 Btu or 97,ton/
1.qOE12Btu. N8qOxemissions were assumed to be at the.same
low levels st6qated.inf4qootnote 9202, 67.3 ton/l.qOE12 Btu,
since they.are primarily dependent on boiler temperature
and restriction of 'excess air to the bed. Sox was
determined by calculating from (5200,2q12) that 86q6.4
percent'of the 'sulfur in the coal is removed. Thus,
J
for this coal,1.8 tons S8qOx are emitted/ qOE2 Btu.
Summary of air emissions f4qor a, 'q635 Mw.pressuqr'ized fluidized
4qPed boiler power plant in tons/l.qOE12 Btu,
q@Pa00qrticulates 9.2q1
Sulfur Oxidesq.6q(aq' S 71.8
s 02
Nitro en Oxides 6 32q7q. 3
32q9
Total 148.8
9217 Footnote 9216 state0qgq.that the coal contains 6 percent
ash which amounts to 3409 t24qons/l.6qOE12 Btu. Using the same
basisasq,in footnote 9204 and (9204,Hq-q.100), the dolomite
VIq-15
�
�
FTN. 9218-9222
discarded:to solid waste is 554..38 ton/l.OE12 Btu.
Therefore? totalsolid waste is 3953.68 tons/l.OE12
Btu (particulate emissions subtracted).
From footnote 9205, fixed land impact for a 1.OE12 Btu/
yr plant is 1.62acres. Weighting the solid waste load
from footnote 9217 according to the densities given
in footnote 9213 gives an overall.densityof 61.85
lb/CF. Assuming waste banks 30 ft high, the annual
incremental land use due to solid waste is 0. 0978 acres.
Time-averaged over a 30-yr plant lifetime, total land
impact is 1. 4 7 acres-yr/l. OE12 Btu.
9219 From footnote 9207., operating costs*include 0.98 mills/
Kw-hr, water pollution control costs at 0.10 mills/Kw-hr,
and the cost of dolomite-limestone absorbent at 4.38 dollars/
ton or 2430.79 dollars/l.OE12 Btu. Total operating costs
are thus 1.15EO5 dollars/l.OE12 Btu.. No credit taken,for
sulfur recovery.
9221 Air emissions given in the table are for a Northern
Appalachian coal containing 2 percent sulfur, 10 percent
ash and having a heating value of.12000 Btu/Ib.
Emissions are calculated on the same basis as those in
footnote 9202, i4e.,92.88 percent of the input coal goes
to the boiler and 7.12 percent goes to the coal
combustor portion of the regenerator-system. Thus, there
are 83.33 lb coal/l..OE06 Btu, producing 8.33 lb ash. The
portion combusted in the boiler contains 1.55 lb sulfur
requiring 30.67 lb dolomite for a calcium/sulfur ratio of
6/1. A lower Ca/S ratio may suffice for adequate sulfur
removal from the emissions of this coal. Using the same
bases as in footnote 9216, particulate emissions were
determined as [email protected] tons/l.OE12 Btu * Nox emissions were
assumed at 67.3 tons/l.OE12-Btu (see footnote 9.216).
Sox was determined as 210.8 tons/l.OE12 Btu..
Summary of air emissions for a 635 Mw pressurized fluidized
bed power plant in tons/l.OE12 Btu
Particulates 12.3
Nitrogen Oxides
Sulfur. 'Oxides Jas, S02)@ 210.8
Total 290.4
From footnote 9221, 1.0E12 Btu of coal produce 4165 ton ash.
From footnotes 9204 and 92@1,-dolomite discarded-from the
system amounts t6 1625.5-tdns/l.DE12 Btu. Thus, totalsolid.
VI-16
�
FTN9223-9226
waste is 778.2 ton/l.qOE12 Btu -(particulates subtracted).
9223 From footnote 9205, fixed land impact for a.l.qOE12 Btu/
y0qr plant isl. q68q2, acres. Weighting t6qhe solid waste
loading from footnote 922q2 according to densities given
i2qn footnote 9213 gives a4qn.average density for the solid
waste of 61.3 lb/CF. Assuming waste banks 30 ft high,
the.annual incremental land useu*4qe to solid waste is-
0 - 144 acres. Time-averaged over a 3 0 yr plant lif etime,
total land impact is 3.78 acreq"yr/1'.qOE12 Btu.
9224 From footnote 9206q7, operating costs include 0.98 mills/
Kw-hr, water pollution control costs at0.10 mills/
Kw-hr, and the cost of dolomite-limestone 0qaqlo@sorbent at
4.38 dollars/ton or 7119.4 dolqlars/l.qOE12 Btu. Total
operating.cost.are.thus 1.19EqO5 dollars/l.qOE12 Btu.
No credit taken for'sulfur recovery.
9226 The emissions a 're calculated assuming'a Northern
Appalachqinoalontai4qniqn'g 2 percent sulfur, 10 percent
Ash a0qnd having aheating 'Value of 12000 Btu/.lb.
Emission factors in the, 'table a0qre based on the operation
of a 30 2qMW singql0qe-level atmospheric pressure fluidized
bed power plant with a.heat rate 6qof 9187 Btu/0qKw-hr and
an over-all plan4qt'efficiency 36.'8 per'
cent. (See footnote
.9209). Plant operation'and methods of calculation are
as.given in footnote 9211. This coal produces 8.33 lb
ash/l.qOE6 6qBtu. There are 1.67 lb sulfu0qr/l.qOE6 Btu coal
requiring 10.74 lb limestone qJ97 percent calcium
carbonate) for a 2/1 calcium/sulfur ratio in the boiler.
Thus, from footnote 9211,@.135 lb calcium.sulfate and
0.56 lb calcium'oxide/l.qOE6 2qB4qt0qu appear in the flyash to
the electrostatic precipitator.. In addition 12.1 percent
of the ash in'the"coal 'also -appears inhe flyash, or 1.01
qlb/l.qO4qE6tu.*0qApplying Ithe final particulate control
gives particulate emissions of 8.515 tons/l.qOE12 Btu.
From*q(.9213o7) 10-.perqc'ent of the sulfur in the coal is.
emitted to the atmosphere, Thus? for this coal, this
amounts to 0.334-lb S4qOx/l.qO8qE6 Btu, calculated as S02,
emitted,.-This is4qwell below the EPA standard of 1.2 lb
S02/q1-qOEq6 Btu. NOqX@emisqsions are Ia function of excess air
in the boiler and bed temperature. So long as these are
q@kep2qtt within the limits described in footnote 9211,.NO
6qx
was assumed constant forall the coals 60 escribed.,Thus,
N28qo6qx emissions amount to 70 ton/l.8qO52qE12 Btu. Hydrocarbon
q'd
and carbon m04qonoxi e emissions are also,qc2qiqsq's40qu6qmed to remain'
constant from coal to coal as long as combustion conditions
remain the same. This,,q-hydrocarbon emissions are 242 ton/
VIq-17
�
�
FTN. 9227-9230
I.OE12 Btu and Co is 2.5 ton/l.OE12 Btu. (See footnote
9211).
Summary of air emissons for a 30 Mw atmospheric pressur e
single-level fluidized bed boiler power plant in tons/
1.OE12 Btu
Particulates 8.6
Sulfur Oxides (as S02) 167.0
Nitrogen Oxides 70.0
Hydrocarbons (as CH 4) 242.0
Carbon Monoxide 2.5'
Total 490.1
9227 The amount of ash produced by the.combustion..of 1.OE12
Btu, 10 percent ash coal with a heating value of 12000
Btu/lb is 4166 tons. Makeup limestone is added at the
-rate of 3,times the weight of sulfur in the coal (9213,
4). Thus,'2505 tons limestone containing 971.94 tons
calcium are discarded from the system. From (9213,8),
80 percent of the calcium.in the waste is present as.
calcium oxide or 1088.6 tons. 20 percent of the calcium
in the waste is,present as callcium'sulfate or 631.8 ton/
1."OE12 Btu. Thus, subtracting particulate emissions,
total solid waste is 5877.8 ton solid waste/l.OE12 Btu.
9228 From footnote 9213, fixed land impact for a 1.OE12 Btu/
yr plant is 1.62 acre.-The ash component of*the solid
waste is 4161.7 tons and the CaO-CaSO4 component is
1716.1 tons (appropriate proportions of particulate
emissions subtracted). From footnote 9213, the bulk
density of the fly ash is 62.4 lb/CF and the average
density of the@qalcjum fraction is 58.5 lb/CF. Assuming
waste banks 30 ft high, the annual incremental land
use due to solid waste is 0.147 acres. Time-averaged
over a 30 yr plant lifetime, the totAl land impact is
3.82 acre@-yr/l.OE12 Btu..
9229 Included in operating costs are'limestone costs at
4.35 dollars/ton or 10896.75 dollars/1012 Btu (9200,
274 and 5208 '162)-,, water pollution control costs at.
0.16 Millis/Kiw-hr,(see footnotes 9200,'9201) and operating
.and maintenance costs of 0.94 mills/Kw-hr (footnote
9215). Thus, total operating cost is,1.23EO5 dollars/
1.OE12 Btu.
Emission factors in the table are for a Northwest region
coal containing 0.5-percent sulfur, 6 percent ash and
having a heating value of 8800 Btu/lb. They are derived -
on the same bases as are stated in footnotes 9209 and 9211.
VI-18
�
FTN 9231-9232
Thus, for this coal there are 0.568 lb sulfur/l.OE6 Btu.
the sulfur content of this'coal is
low,enough to meqet.4qEPA
emission standards-of,1.2,l6qb S02/1-qOE6 Btu without the use
of any-,absorbent.over, it will, be assumed th8qAtlime-
stonein a 2/1 calciu0qm/s8qulfur ratio is added to standardize
the results on all coa8qls,used. Thus, this Amount of,
sulfur would require 3.66 lb limestone'as absorbent
containing 1.42 l0qb calcium. 6.82 lb ash/l.qOE6 Btu are also
produced4 From-footnote 9211,-0.825 lb ash, 0.046 l.
calciumsulfate.and 0.191b calcium oxide appear in the
flue gas/l.qOE6 Btu before the 99 percent efficien2qt@'
electrostatic precipitator. Applying final particulate
control, particulate emissions are found to be 5.31 tons/
1.qOE12 Btu. Sulfur oxides (calculated as So ) are 56.8
tons/l.qOE12 Btu. Nitrogen oxides are 70 ton2q@l.,qOE12 Btu:
Hydrocarbons (as CH4),are 242.0 ton/l.qOE12 Btu and CO is
2.5 ton/l.qOE12 Btu. See footnote 9211.
Summary oqf air emissions for a 30 Mw atmospheric pressure
single-level fluidize0qd'bedpower plant in tons/l.qOE12 Btu
Particulates 5.3
Nitrogen Oxides 70.0
Sulfur Oxides (as S02) 56.8.
Hydrocarbons*q(as CH4) 242.0
Carbon Monoxide 2.5
Total 376.
9231 The amount of ash produced by 1.qOE12 Btu of a 6 4qper cent
ash coal with 'A heating value of q8q800 Btu/lb is q34,09 tons.
Makeup,lim0qestone is added at a rate ofhree@times the
weight of sulfur i6qn the coal. Thus 852 tons limestone
containing 330.576 tons calcium is discarded from the
system. From q@92q13,8),80 percent of the calcium is presen t
in the waste as Ca8qO or 370.25 tons Cao. Twenty percent of
the calcium is present as CaqS8q04 or 214.87 tons CaS8qO 4- Thus,
subtracting particulate emissions, total solid wast4qd'load
is 3988.8 tons/q!.qOE12 Btu.
9232 From footnote 9213, fixed land impact fora1.'qOE12Btu/yr
atmospheric plant is 1,62acres. From footnote 9231, the
ash component of the solid waste is 3406.35 tons' and the
4.1
20qC2qa.24qOq-24qC6qa0qS20qO4 component is 582.47 tons (appropriate proportions
of particulates subtracted). From footnote 9213, the bulk
density of the flyash is 62.4 lb/CF and that of calcium
oxide-calcium sulfate is an 44qAverag04qe-of 58.5 lb/CF.
Assuming waste banks 30 ft hi08qqh, the annual incremental
land use due to solid waste is 0 q- 0988 acres- q* Ti6qmq'e-averaged
over a 3 0 yr plant lif eti6qmq@ e, the total land impact is 3. 10
acre-yr/l.6qOE12 Btu.
vi-19.
�
�
FTN. 9233-9234
9233, Included in operating costs are the cost of limestone to
the boiler at 4.35 dollars/ton (9200,274), or 3706.210
dollars/l.OE12 Btu, water pollution control costs at.
0.10 mills/Kw-hr(footnotes 9200,9201), and operating and
maintenance costs of 0.94 mills/Kw-hr (footnote 9213).
Thus,, tot.al operating costs are 1.16EOS dollars/l.OE12
Btu.
9234 All the national average impacts-are arithmetic averages
of the data given for the Central, NorthernAppalachia,
and Northwest :pegions.
VI-20
�
VII SOLVENT REFINED COAL
A. Introduction
The environmental..impacts, cost,-and,efficiency for the
activities and processes associated with solvent refined coal
are shown in Table.5 of this report. Data have been developed
for two regional coals: high sulfur Central and medium sulfur
Northern Appalachia. The characteristics of the regional coal
,utilized are contained in the-footnotes. Data are @or an environ-'
mentally "controlled" condition.. All of the cost data shown in
Table 5 is based on a 90 percent plant load factor, or 328 operating
days/yr. 'Thevalues presented in this table are based on data
accumulated,during the Spring of 1974.
Each data entry is based upon an energy input of coal
equivalent to 1012 Btu/yr., The Solvent Refined Coal process
should be considered an integral part of the fossil fuel supply-,
trajectory. Compared to the coal processing entries.in.the
Phase -1 report, (HIT-593, Volume I), the environmental impacts have
changed considerably in the distribution and power g6neration activi-
ties since the heating values, sulfur, and ash content of the SRC
productare different. On the other hand, 'the coal extraction
activities in the Phase I report may be usedto complemept or
c(Mplete the total fossil fuel supply chain.
The Solvent Refined Coal process developed by the Pit@,tsburgh
ArA Midway Coal,Mining Company is the basis for,the energy
environmental data developed in this report. Although generally,
referred to as the coal-de-ashing process, both ash and sulfur
are removed., Figure 23 illustrates the process.
The process itself consists of six distinct operations des-
cribed below:
1. Coal Preparation and SlurEy. In this area the
run-of-mine coal is crushed to less than 1/8-
inch by 0 and then dried with thermal.flash
dryers to approximately 3% moisture. The coal
particles are then mixed with a hot aromatic slurry
azid directed to-.the dissolvers.
2. Dissolving. The coal-slurry mixture is next
hyar9genated under elevated temperature and
pressure. The coal-slurry mixture has a con-
tact time of approximately 15 minutes., although
during actualloperation this may va3@y somewhat.
3. Filtration. The dissolved cdal-sblvent solution
is next passed through a rotary pr6coat type
filter where undissolved coal and ash are sep-
arated from the solution. This material is then
sent to the Mineral Residue processing area in
the form of a "filter cake" whereas the coal
solution is further processed.
VII-1
�
M ACID
TREATMENT
COAL VENT GAS 8 SULFUR PLAPFr
COAL FUJRA7E
PREPARATION DISSOLVER 'FILTRATION SOLVENT
ak . SOLUTION SOLUTION RECOIVERY
SLURRY
RE-CYCLE RASH LIQUID
SOINENT
-CONDENSM RECYCLE SMVeff
L SOUAEN'r
STACK GAS FIEFINED
TO SULFUR PLANT COAL
MINERAL,
BOTTOMS
CRE CS RESIDUE SOLIDIFICA- FROM
DISTILLATION PROCESSING TION SOLVENT
LIGHT OILS ASH RECOVERY
do
JRMYCLE SOLVENT
SOLVENT COAL
.41
SOLVENT SOLVENT SOUR
MIXING EXTRACT SOtJR - WATER CLAR I F1 ERS
STRIPPER WATER
SOLVENT
SLUOK
Figure. 23. Sol At kofinet":0*1 Process
PHENOLS1
SyiEcs:]
*7LVENT@@
(11. 930)
�
4. Mineral Residue Processing. The filter cake contain-
ing mosF of-the coal ash and minor portions of"undissolved
..carbon,is dried and burned. The filter cake has a
heating value of approximately 4220 Btu/lb and provides
a significant portion of the energy needed for opera-
tion of the plant.
.5. Solvent RecoveEZ. The coal-solvent solution is then
flashed and further distilled to remove the solvent
from the "liquid.coal." The solvent is recycled to
theslukry step.
6. Solidification. The coal product is soli ified by
use of flaking drums.and stored,as a solill-de-ashed
coal ready for shipment.
VII-3
�
B. Impact Data Table and Footnotes
VII-4
�
@LVENT REFINED COAL 3 4 5 6 7 8 9 10 If it 13 14 15 16 17 Ii 19 20 21 22 23 24 25 26 27 20 29
FUEL REGION 30
COAL A5 INDICATED WATER POLLUTANTS (TONW 10'2 STU. EX. COL.12) AIR POLLUTANTS (TONS/1012 M) OCCUP@ fTIONAL HEALTH POTENTIAL COST (DOLLARS/1012m)
NNE - I DISSOLVED SOLIDS SUSPENDED TOTAL THERMAL PARTIC- HYORO- ALDEHYDES S LIDS LAND -jA-N ARGE PRIMARY ANCILLARY
ROM ACTIVITY PROCESS BOD COD : NOX so, CID TOTAL TONS/ ACRE-YR) DEATHS INJURIES DAYS L EFFICIENCY ENERGY FIXED OPERATING TOTAL
MON. SOLIDS Cous 6,7,8 /totaTIA ULATES CARBONS ETC. 7 SCALE ROW
ACIDS BASES P04 N03 OTHER TOTAL(DS) ORGANICS BTU 012 BTU 101, BTU LOSTAOP29Tt DISASTER (BTU/I&BTU COST COST COST
1.
2 TRN@ TRANSPORTATION
T_
TRUCK .19. .1. .11. .1. .11. o", o". o9o o998 3.34-o 4 23oo 9.51-01 4 2300 6-02 4 91do 2.51-021 4 93QO S.7-1 4 13oo 7.71-0 4 93co I.-oo 4 7.4-1 3 11ol .11, o9" 0992 I-D 1 9302 1.1-19 3 9301 4.04,03 930J I. DI.04 3 2.3@@N 1 3
4CON- CONVERSION I 1 14
SAMC -C o", W. -t!LLI!@ 1 1- -.-02 o -4 -1- 1 1.0-02 1@o@ 1--@ 130. .117 --1 3 0.1 2m!1@01 3 230112.42101 3 9305 -4-00 3 9305 4.84-02 3 930S 3.62-01 3 93dS 6.W01 3 3-03 2 9106 ZmW00 3 93D7 0999 7.68-01 19366T 7.66,lo 2 93og 1. - 2.2-S 2 5
6 o". moil 0-5 2-9310 1 TA- 2 931G
7
--- - 2.,D.ox 3 0400+D0 2 9315 3.4341 4 9314 6.10-02 2 9316 51.6-1 1"1" 5.11.1 @ 316 "99 1. woo 2'312 6. 8i,04 3 @D317 7. 0404 3 8
_ffR UNIT TRAIN .1. .11. .19. .11. .1. .9. o9go - o". .99's o". o- .1. 1. 361@1 3 1311 3.20@0() 3 9311 2.111003 111, 2412*003 9311 2.97,00 3 2311 1. ?o_oj 3 9311_
9RIIARG RIVER BARGE o998 o998 o'98 oloo 099. G. 0+00 3 0997 D.D0100 3 0997 0-00 0.0040 3 0997 D,W(10 30997 O.-H-3 ....... . .... 1.4-0 3 9319 1.52- 1 s- gw!@01 3 9319 1w27+00 3 9319 7.06-01 3 9319 2.4MI I o"8 .1. o999 o..' o"9 1.0.0. 11311 L'59-10 3 932o 3.91+01 3 9122 2.16-1 1 S322 3m25@ 3 9
10 PFC- EUCTRIC ER 10
I I - D.00+0 3 1908 13. 02-03 3 190o 1.82401 09. mo I.. o0N00 3 9325 2.53-01 3 9323 2.84+02 3 9323 5.71.02 3 9323 4.74+00 3 9323 I.S6 1-01 3 9323 7.86-o2. 132) 19.01+02 3 6.-oo 2 1326 6o27+00 3 9330 1 --(Il o9- -
`-EN -R GENERATION 0-6 3 1908111-0 3 1908 og.2 1.82.01 -jI.8201 -11-033 9327 11@-Ql 1 9327 4,41+00-1 -9127 3 0997 1-- 1 -9 JWA@s 3 9,29 6.7245 3
12
13 CENTRAL IS
14 TRNSP TRANS@RTATION @K
TRUNK TRUCK o". o9" -1 .90 o998 0998 1.75-02 3 0331 4.98-01 3 9331 3.63-02 3 �331 4.15-07 3 933T 3+03-01 3 933L 4.o4-o3 3 9331 1.09-01 A 0"t 4*01@01 o 933Z ......... III" .19s 1.00,00 2 9U3 3.7"1 3 9332 3.79-633 9334 1.16-3 9334 1.534043
Co- CO-N-N -
17 CCSRC _c o"o . 0999 3.21-01 4 9335 0919 5.221. 9335 S.22-02 4 1.40+00 5 9335 2.7-1 o 1- 1 6.7-3 5 9335 8.62 03 5 933S 0.0-0 2 D997 1+72+01 3 9336 1.9-1 3 oggs al., .-01 1 9339 6.81+16 2 934C 1.22+01 @ 9341 19.M- 2 - 2,oo.1 2 17
Is
20 WITR UNIT TRAIN o9gs o995 o". o998 o9's o19. 0- .2L. oos. oggg 1.36+013 9342 2.881003 1342 2,49+003 1042 1. U2+0o 3 9342 2- 68-00 3 9342 1-50-01 3 9342 2.37@01 1 9316 S.95-01 293161 019, 3-83E+0i3Q347 5.01E+04 3 9347 6.39E+.4 3 20
P1 RDARC RIVER BARGE 0998 Qp0D+DD 3 0997 0-o 3 0997 O,Oo+oo 3 - 0-011,997 0-00 3-1- 0-00 3 0997 134401 3 9142 -I-ol 3 9449 5mfi@()! 1 2344 L41@01 3 9349 CS"I 3 9349 2.65-02 3 .349 1.53+01 3 o"s o2a -9 .1.. 1- 2 W51 4.30-89 3 9346 1.9-3 3 935o 2.86+0 3 9350 3.75-1 3 21
22
FUCTRIC MWER 22
23 m- -FRA'.. 0-0 3 I9Q8 0.0-D 3 19D81 og.o 0999 1.82+01 4 190f 1.82101 4 '0-00 3 looa 3.o2-o3 3 go -oz, I] O.GI+023
1.8-1 Mo. oM (1.00+00 39325 2,53- 3 9323 2.84,02 m.. 1.--- 1 9323 14-00 3 9323 1,58-01 3 932317.86 6.30+00 2 -1 6. 27+.Q 1 1,. 1.-.3 3 ID@7 1108-01 3 9327 4.41+00 39327 1.97-01 3 9328 COMo I QM 2-0% 1 9125 4.14@S 1 .11 -2- 3 23
24 24
25
26 26
27 27
28
29 29
30
32 31
33 33
34 34
35
35
36 36
37 37
39 38
39 39
40
_LO
41
42
49
43 43
44 44
45
45
46
47 47
48
49 49
50 so
51
_i2 Taal
53
154.
TABLE5 ENVIRONMENTAL IMPACTS, EFFICIENCY AND
COSTFOR ENVIRONMENTALLY CONTROLLED
NATIONAL AND REGIONAL SOLVENT REFINED
COAL SUPPLY
26
2
5
7
3 ...
13 1311
12 H11
2@_
.33o
1 3
3.
�
FTN.19089300
Footnotes for Table.5
1908 The basis for water pollutant calculations is the pro-
posedeffluent limitations guidelines and new source
performance standards for-the steam electric power
generating point source category given in (1921). For
new plants, best available demonstrated control tech-
nology (BADCT) requires effluent pH control in-the'
range of 6-9. Hence*6qdcids and bases discharge,will be
negligible. BADCT also specifies total suspended
solids levels no greater than 15 qm8qg/q1 for all inter-
-mediate and low volume waste effluents. At this level
of control there will'generally be no net increase-in
suspended solids in water 'passing through the power plant
system. Organics (oil and grease) must be.controlled
to 10 mg/q1 to6qpeet BADCT standards. Hence fqr om (1921,
232) these emissions-will amount to .0736 ton organics/
106 ton coal or 3.02-03 ton/1012 Btu.' Information on
the increase in total dissolved solids*of water used
in power plants is not readily available and was syn-
thesized from (1922,10,12,20,22). Based on this,data
the net increase in total dissolved solids for water
used by the power plant is 18.2 ton/1012 Btu.
9300 Table entries-for N. Appalachian Coal transportation
are based on the haulage of 1.qOqOE8q+12q2 Btu/yr of coal
(4.17E2q+04 T/yr).The average'distance from mine
tipple to,.prep plant-is 7.3 mile's and the average
truck.,capacity is 22 tons (9314j344). The-average
fuel consumption of diesel trucks is 7.0 gal/1000
T2qHI (9303). To haul 1.qOqO8qE2q+12 Btu/yrf coal, 1896
round-trips are required* For a,plant processing
1.qOqOE2q+12 Btu/yr, 3q200 T/yr of ash is produced (see
SR6qbq-Solid Waste). This requires 146 full load trips
back to mine.-Assuming a gross to tare of 2q5 5.14+
E6q+03 gallons'are consumed..4qFrom (9303) the..air
pollutants are
Particulates 3.34qEqi-02T/l.q0q0E8q+l2tu
sox 6.94Eq-'0q26qT/1.qOqOE4q+1'2 Btu
8qC4qO .5.76q8Eq-0lT/l.q0q0E8q+l2 Btu
HC 9.-514qE-026qT/1.qOqOE0q+12 Btu
NO4qX 9.514qEq-qOqJ0qT/1.qOqOE8q+12 Btu
A24qLD 7.71E-03T/1q-6q02q0E08q+12q-Btu
Road dust is assumed to be controlled by water sprays.
VII-7
�
�
FTN. 9301-9304
9301 For a heating value of 5.83E8q+06 Btu/BBL and a fuel
consumption of 5143 gal, ancillary energy for truck
haulage is 7.14E4q+08 Btu. Land impact for truck
haulage is based on a,60 ft rdwy, 'a mine to' plant
distance'6f 7.3 miles (9314,344), and a lacre settling
pond per mile. For a plant processing 10,0,00 tpd,
the fixed land impact is 60'.lac. For a plant processing
q1.qOqOE0q+12'Btu/yr, the fixed land impact is .763 ac-yr/
1.qOqOE2q+12 Btu.
9302 Coal loss during transportation is assumed to be
controlled by water sprays, Primary eqfficiency is
1.qOqOE6q+00.
9303 Capital cost for truck haulage consists of the. following
1p316,7/26):
Road Grader 1.35E8q+05
Dump Truckq@q(5) 9.68E0q+05
Water Truck 2.20E4q+04
Settling Pondsq(7) -q1.40E4q+04
Coal Trucks(20) 8.OOE4q+05
Total 1.94E4q+06 dollars for 2MMT/yr mine
Operating costs.rebased on (931.2,583,586). At 40,'000
dollars/truck and a fuel consumption,of 5143 gal,
operating cost(including 720 dollars/l.qOE8q+12 Btu for
fuel, 13140,dollars/l.qOE8q+12 Btu for labor, and 5256
dollars/l.qOE8q+1q2 Btu for maintenance) is l.-91E8q+04 dollars/
1.qOqOE2q+12 Btu. At 10 percent fixed charge rate, capital
cost is 4.04E4q+03 dollaqrs/l.qOqOE8q+12 Btu.
9304 Impacts for the solvent refined coal process are
based on energy and material balances in (9300).
A Northern Appalachian coal having the following
proximate aqnialysis was used:
Moisture 3.40 percent
Ash 7.70 percent
Sulfur 1.80 percent
FC4q+VMA 89.90 percent.
Heating value 12,000 32qt,tu/lb
In order to maintain continuity in product and
by-product streams, the fixed carbon and volatile
matter is fixed. For a Northern Appalachian coal,
equivalent feed is 8.42E12q+05 lb/hr. From (9300)
wastewater stream from the dissolvers is 95,471
lb/hr and the probable composition is (9318q3,9300):
VII-8
�
�
FTN. 9304 (Cont)
Phenol 300.lb/hr
NH3 157 lb/hr
TDS 765 lb/hr
S/S 5o lb/hr
CN/SCN 27 lb/hr'
Oil 3lb/hr
H2S is assumed at 158 2qlb/hr to keep overall plant
sulfur balance at 96.7 percent figure. No condensate
from coal drying Will be formed since coal is
approximately 3 percent moisture and most water will-be
driven off as vapor. Sanitary waste is based on 100
gallon/day per employee and consist.of (9301):
Flow 4843 lb/hr
BOD 1.1 lb/hr
.COD 1.4 2qlb/hr
S/S 1.3 lb/hr
Total plant blowdown (makeup water) is 1.45E4q+06 lb/
hr (9300) and will have the following analysis.(9317):,'
TDS 11,043 lb/hr
PO
4 7.3 lb/hr
25 lb/hr
Blowdown is held in a holding or cooling pond and
is then released (9300). The wastewater 'treatment
system consists of the following units (9301,9304,
9305,9311)-phenol solvent extraction, sour water
-stripping, primary clarification,,activated sludge,
and secondary clarification. Removal effitiencies
are given in references. To process 1.qOqOE8q+12 Btu/
yr of 12000 Btu/lb N. Appalachian coal, the scale
factor is 1.26E-02 times figures given in (9300) and
using 8.42E8q+02q5 lb/hr fixed carbon and vo2q1itile matter
-feed.6qat"er pollutants based on discharging 4qof
dissolver waste, sanitary waste, and cooling tower
blowdown-6qaft+er treatment are (on a 1.qOqOE4q+1q2 Btu/yr basis).,.-
Effluent@
Ton/Yr PPM
Oil 1.49E-02 1.94E-01
CN2qISCNq. 1.35E-01 1.76E4q+00
NH3 2q.50Eq-02 3.25E-01q'
H2S 1.15Eq-02 8q1. 2q5020qE-8q02q1
Phenol 1.49Eq-02 1 94E-01
S/S 1.59E08q+00 28q:07E04q+8q01
BOD 1.8qO8qOEq-02 1.30E-01
COD 1.2qO2qOEq-02 1.3024qE-01
TDS 5q.90E08q+02 7.67E08q+03
P04 3.65E-01 4.7520qE08q+00
H20 7.70E08q+04
VII-9
�
�
FTN. 9305
9305 Air pollutants associated with the solvent refining
process primarily consist of emissions from fuel
gas combustion.. Claus plant tail gas, and coal
preparation plant.
Claus Plant
S02 emissions are based on.the total available sulfur
in the input coal. For processing 8.42E+05 lb/hr of
N. Appalachian coal with 1.8 percent sulfur content,
11,95-1 lb/hr of.sulfur is recovered of which 146 lb/
hr is generated as H2S in the sour water.stripping
operation, 4410 lb/hr is recovered from a Wellman-
Lord scrubber as S02 resulting in filter cake
burning, and the remaining 7407 lb/hr H2S is
recovered as H2S in acid gas treating. Assuming a 95
percent removal efficiency of the Wellman-Lor*d
scrubber, 232 lb/hr S is emitted (9318). The Claus
plant recovers.99.9 percent of-input sulfur. 0.1
percent is emitted to the atmosphere as S02 (9319,
127).
S02 emissions are:
Filter Cake Combustion Stack Gas 1829 T/yr-464 lb/hr@
'Claus Plant Taill Gas @94 T/yr- 24 lb/hr
..Fuel Gas Combustion
Combustionof the fuel.gas produced (868 Btu/SCF)
is based on the fuel requirements and distribution
given in (9300). The following is a list of
combustion sources:
Thermal Driers (from dissolvers)1309E+06 Btu/hr
Mineral Residue Processing 50E+06 Btu/hr
Solvent Recovery .630E+06 Btu/hr
Hydrogen Plant 502E+06 B
tu/hr
Sulfur incinerator 52E+06 Btu/hr
Air emissions are based on combusting a total of
2.54E+09-Btu/hr (9303,2/72), and the heating value
ratio of. 868 Btu/SCF to that of natural gas 1050
Btu/SCF. Preparation of coal in flash dryer .s
accounts for additional particulate emissions (9303,
8/10). Processing 8.39E+05 lb/hr of coal .(at 3
percent moisture) particulate emissions are 1413
T/yr using 95 percent efficient cyclone. Total air
pollutants are (tons/yr),:
VII-10
�
FTN. 9306-9309
Area Part. SO CO .11C No ALD
Coal Prep. 1413.00 1.97 197 @861 14.716
Mineral Proc. 3.40 1829 0,08 7.52 _32.9 0.56
Solvent Ext. 42 6 - .0.95 94.@80 414.8 7.11
H2 Plant 33:94 - 0.76 75.60 330.8 5.67
Claus Plant 3.50 94 0.08 7.80 34.0 0.59
1496.40 1923 3.:84 .382.72 1673.5 28.69
These data are based,on processing-8.42E+05 lb/hr.
To process 1.OOE+12 Btu/yr of 12000 Btu/lb N.
.Appalachian coal, the scale factor is 0.0126..
9306 Solid waste from the solvent refining process results
primarily from ash removal in the mineral residue
processing area. As the filter cake is combusted,
the ash is produced. For an SRC plant processing
8.42E+05 lb/hr of N. Appalachian coal with a. 7.71
percent ash content, 64,867 lb/hr of ash will be
produced (9300). To process 1.OOE+12 Btu/yr, 3.20E+03
ton/yk df ash will.be produced. The ash will not have
a land impact since it is assumed to be.returned to
the mine for burial.
9307 A 10,000 T/D SRC plant,is assumed to occupy 200 -
acres. For a-plant processing 1.OOE+12 Btu/yr (127
T/D) land impact is 2.51 Ac-yr.'
9308 Primary efficiency Is based on the'input of..8.42E+05
lb/hr of-1.20E+04 Btu/lb N. Appalachian coal and.an
output of 4.88E+05 lb/hr of 1.59E+04 Btu/lb solvent
refined coal. Primary thermal efficiency 'is 76.8
percent. The thermal efficiency would be higher if
input of hydrogen'and output of'light oils is
considered (9300).
9309 Ancillary energy for a 10,000 T/D solvent refined
coal plant is,approximately 7.71E+08 Btu/hr of-
natural gas (9300,5-11). Of the 3.14E+09.Btu/hr
fuel gas required, 2.37E+09 Btu/hr is supplied by
the production of high Btu refinery gas. The
additional gas (natural gas) must be purchased-It
is anticipated that a solvent refined coal plant
will make use of a considerable amount ofwaste
heat and will actually export 32 MW of electrical
power.
For a plant processing 1.OOE+12 Btu/yr, ancillary
energy is 7.66E+10 Btu/yr.
VII-11
�
FTN. 9310-9312
9310 Capital cost for a 10,000 T/D solvent refined coal
plant is based on data from (9300). The process is
utilizing 8.33E+05 lb/hr and a Northern Appalachian
coal wil1require-8.42E+05.lb/hr. Cost for coal
prep, processing, filtration, and sulfur recovery have
been linearly adjusted to refle 'ct difference in coal
input rates (lb/hr). Additionally, another 1.63E+06
dollars has been added to cover the cost of sour water
strippers and activated sludge units. Costs have been
adjusted to 1972 dollars using 4 12 percent increase
(from 1969). Total annualized cost is 8.34E+06 dollars
at 10 percent fixed charge rate. For a plant processing
1.OOE+12 Btu/yr, the total capital cost is 1.05E+05
dollars. Plant load factor is. 90 percent.
Operatinq cost is based on 9.58E+06 dollars/yr and a
by-product credit of 1.16E+06 dollars/yr. Total cost
is scalediup 12 percent to reflect 1972 cost'(9300).
9311 In a study conducted by the Bureau of-Mines (9320)
the average haulage distance from mines in this
region is'about 320 miles. Energy consumption by
freight trains is assumed to apply to unit and
mixed.trains (9335). Trains-are assumed to have a.
gross to tare ratio of 4 and consist of 3 locomo-
tives. It is further assumed that SRC.is transported
in solid form and that it presents no unusual diffi-
culties in handling.-To haul 1.OOE+12 Btu/yk, the
total weight of a unit train is 41982 tons. To haul
320 miles, a total of 6.72E+04 gal of diesel fuel is
consumed by the 3 locomotives. Return trip requires
1.68E+04 gal. Air pollutants for diesel consumption
and loading and unloading are given as follows
(9303,3-7,7-4):
Locomotive Loadinq/Unloadinq
Lb/1000 Gal T/1.OOE+12 Btu T/l.DOE+12 Btu
Particulates 25 l.U4+UU 12.60+00
sox 65 2.76+00
CO 70 2.97+00
HC 50 2.12+00
NOX 75 3.20+00
ALD 4 1.70-01
9312 Ancillary energy for haulage of 1.OOE+12 Btu/yr is
l.-17E+10 Btu. Figure is based on consumption of
8.40E+04 gallons of diesel fuel with a heating value
of 5.83E+06 Btu/bbl (Footnote 9311).
VII-12
�
FTN 9313-9319
9313 Primary efficiency is 1.00E+00 percent. It is
assumed that miscellaneous losses due to spillage
are negligible.
9314 Land impacts associated with the distribution of
SRC are assumed to consist of a 320 mile rail
line, footnoote 9311, with a R/W of 60 ft. This
line would serve a 10,000 T/D SRC plant producing
6.80E+13 Btu/yr. Land impact for shipping 1.00E+12
Btu/yr is 3.43+01 A-yr.
9315 Solid waster for SRC haulage by rail assuming
negligible losses is 0.000E+00 ton/yr.
9316 For the period from 1969 to 1970, shipment of coal
accounted for 27 percent of the total tons of freight
shipped by rail (9321,559). Of the total coal shipped,
1.00E+12 Btu/yr of SRC would account for 0.01
percent (total 330 MMT). During the same period an
average of 2255 fatalities occurred and 21,666 person
were injured in rail accidents (9322). These figures
include all accidents. Injuries to employees on duty
average 16,250 persons and 93 man-days were lost per
injury (9322). Hence, for every 1.00E+12 Btu/yr
hauled, there are 0.061 fatal injuries, 0.585 non-
fatal injuries, and 59.5 man-days lost.
9317 Freight charges for haulage by unit train are
0.0061 dollars/TMI (9322,10) in 1969 cost. ICC im-
posed an 8P and 6P freight rate increase in 1970 and
1971, respectively, to 0.00070 $/TMI. Haulage of 3.15E+04
ton of SRC, equivalent to 1.00E+12 Btu, a distance of
320 miles is 7.04E+04 dollars totoal costa. From (9323,
67/70 fixed cost (depreciation only) is about 6 percent
of total annual cost. Hence, fixed cost is 4.22E+03
$ and annual operating cost is 6.62E+04 $.
9319 The average capacity of a barge is 25000 tons (9326,
35), and the average haul distance is assumed to be
800 miles (approximate distance from Erie,Pa. to
Chicago via Great Lakes). Air emmissions are based
on (9303,3-11). To haul 1.00E+12 Btu of SRC 1.26
round trips must be made. Pollutants are:
VII-13
�
FTN. 9320-9323
Lb/Mi T/1.OOE+12 Btu
Particulates 2 2.02E+00
sox 1.5 1.52E+00
CO 1.2 1.22E+00
HC 0.9 9.10E-01
.NOX 1.4 1.42E+00
.ALD 0.07 7.06E-02
From (9303,7-4) an additional 12.6 tons of
particulates are emitted when loading and unloading
SRC.
9320 Ancillary energy is based on a fuel consumption of
378 Btu/TMI (9325), a capacity of 25000 tons (9326,
35), and distance of 800 miles. Assuming a gross
to tare ratio of 4 and that barges return empty to
their origin, -energy required isl.59E+10 Btu:for
the 1.26 round-trips.
9321 Neglectin4 miscellaneous transportation losses,
primary efficiency is 100 percent.
9322 The cost for shipping coal..(SRC) in 1971 by barge
was 0.97 dollars/ton (9327,37) of which 12 percent
(inclusive of insurance and depreciation) is fixed
cost. This agrees with data in (9328,18). Cost to
haul 3.15E+04 tons of SRC would be 2.86E+04 dollars
operating and 3.91E+03 dollars fixed. Cost is
escalated 6 percent to reflect 1972 cost.
9323 Air pollutants'for power generation are based on,
an SRC input of 1.OOE+12 Btu/yr or 31,446 tons/yr.
SRC composition will have a sulfur content not
greater than 0.95 percent and a heating value of
approximately 15,900 Btu/lb. Ash content will be
less than 0.1-percent. It is assumed that pulverized
SRC will perform similar to typical coals and will.
present no unusual combustion difficulties. All
pollutant figures are.based on (9303) utilizing the
appropriate ash and sulfur content. Pollutants are
as follows:
Lb/Ton SRC Ton/1.00E+12 Btu
Particulates 16(Ash) 2.53E+01
sox 5.71E+02
CO 1.0 1.58E+01
HC 0.3 4.74E+00
NOX 18.0 2.84E+02
ALD .005 7.86E-02
Total 9.01E+02
VII-14
�
FTN 9325-9331
9325 By use of mechanical draft wet cooling towers, thermal
pollution may be virtually eliminated.
9326 From (9300) the ash content of solvent refined coal
is 0.1 percent. For a SRC feed of 31,446 ton/yr
(1.00E+12 Btu), 31.5 tons of ash are available as
solid waste. In practice, however, 80 percent of
this material is emitted as particulates during
combustion. The remaining 20 percent results in ash
or solid waste. Soldi waste is 6.30 ton/1.00E+12 Btu.
9327 Occupational health statistics are based on reference
(9330,46). 0.166 men per MWE is the basis for the
calculation. Injury data is from (9331,35). Half the
combined deaths and permanent injuries are assumed
to be fatal injuries. Permanent total disabilities
are considered to represent 6000 days lost while
other disabilities are estimated as 100 days lost.
Man-days lost are for injuries only.
9328 Power plant efficiency is based on 60.3 percent heat
rejection rate. One-sixth of this is emitted through
the stack gas. It is assumed the boiler and turbine
efficiency is similar to conventional fossil fired
plants (9333), however in actuality they will be
somewhat higher due to the reduced ash content and
higher heating value of the solvent refined coal.
No actual tests have been performed. From (9330)
turbine heat rate is 7750 Btu/Kw-hr resulting in a
turbine efficiency of 44 percent, and steam
generator efficiency of 90.1 percent (9300,5-6).
Total plant efficiency is 39.7 percent.
9329 Capital and operating cost are based on (9300).
Capital cost for a power plant with an input of
5.70E+13 Btu/yr is 1.31E+08 dollars. At a fixed charge
rate of 10 percent, capital cost on a 1.0E+12 Btu input
basis is 2.58E+05 dollars (1972). Operating cost is
4.14E+05 dollars including fuel, interest, taxes, in-
surance, and depreciation.
9330 A typical size for a 3000 MWE plant with flyash controls
is 1200 acres, including 350 for ash storage and 40 for
coal storage from (9332,11,14). For a solvent refined
coal plant, ash storage will not be required, hence
fixed land impact is 6.27 acres/1.00E+12 Btu input.
9331 Tables entries for Central coal transportation are
based on the haulage of 1.00E+12 Btu/yr or 4.17E+04
ton/yr of coal. The average distance from mine
tipple to prep plant is 3.8 miles (9314,344). The
average truck haul capacity is 59 tons (9314,344).
The average truck diesel fuel comsumption is 7 gal/
1000 TMI (9303). To haul 1.00E+12 Btu/yr, 707
VII-15
�
FTN. 9332-9334
round trips are required of which 67 return trips
are full loads (haul solid waste, ash, back to the
mine, see solid waste). Assuming a gross to tare
of 2.5, a total of 2693 gallons of diesel fuel is
consumed. From (9303.3-7)air pollutants are as follows:
Lb/1000 Gal T/1.00E+12 Btu
Particulates 13 1.75E-02
SOx 27 3.63E-02
CO 225 3.03E-01
HC 37 4.98E-02
NOx 370 4.98E-01
ALD 3 4.04E-03
9332 For a heating value of 5.83E+06 Btu/BBL and a totoal
fuel consumption of 2693 gallons, ancillary energy
for truck haulage is 3.74E+08 Btu. Land impact for
truck haulage is based on a 60 ft R/W, a mine to
plant distance of 3.8 miles (9314,344), and a 1
acre settling pond per mile (control of sediment).
For a plant processing 10,000 tons/day, the fixed
land impact is 31.6 acres. For a plant processing
1.00E+12 Btu/yr, the fixed land impact is 0.401
A-yr/1.00E+12 Btu.
9333 Coal loss during transportation is assumed to be
negligible. Dust control is accomplished by water
sprays. Primary efficiency is 100 percent.
9334 Capital and operating cost are based on (9316,7/26).
For truck haulage capital cost are as follows:
Road Grader (2) 1.32E+05 dollars
Dump Trucks (5) 9.68E+05 dollars
Water Truck 2.20E+04 dollars
Settling Pond (4) 8.00E+03 dollars
Coal Trucks (10) 6.90E+05 dollars
1.82E+06 dollars for 2MMT/hr
mine
For a truck haulage of 1.00E+12 Btu/yr at 10 percent
fixed charge rate, costs are 3.79E+03 dollars.
Operating costs are based on (9312,586). At 69,000
dollars/truck and a fuel consumptionof 2693 gallons,
operating cost (4.54E+03 dollars for maintenance,
3.77E+02 dollars for fuel, and 6.56E+03 dollars for
labor, on a 1.00E+12 Btu/yr basis) is 1.15E+04 dollars/
1.0E+12 Btu.
VII-16
�
FTN. 9335
9335 Impacts for the solvent refined coal process are
based on energy and material balances in .(9300).*A
Central coal:having the following proximate analysis
was used:
Moisture 11.20 percent
Ash .9.40'perc&nt
Sulfur 3.50 percent
FC+VMA 79.40 percent
Heating value 12,00'0 Btu/lb,
In order to,maintain continuity in product and
by-product streams- the fixed carbon and volitile
matter is'fixed. For a Central coal, th'e'equivalent
feed is 8.64E+05 lb/hr at 3.0 percent moisture as
in reference (9300). From (9300) the wastewater
stream from the dissolver is 96,.599 lb/hr and the
probable composition is (9313,9300):
Phenol 3000 lb/hr
NH3- @,160 lb/hr
TDS .8125 lb/hr
S/S 51 lb/hr.
CN/SCN. @27 lb/hr
Oil .3 lb/hr
H2S islassumed at 3*491b/hr to keep.the overall
plant sulfur balance'at 96.5 percent. Condensate
from the coal prep plant is approximately.11,379
lb/hr with about 10 percent oil and solvent content.
This waste streain is genera-Led during thermal drying.
Sanitary waste is based.on 100 gal/day/employee and
consists of' (-9301)-:'
Flow' 4843 lb/hr
BOD 1.1 lb/hr.
COD 1.4 lb/hr
S/S 1.3 lblhk
Total boiler and. 'cooling water makeup is.1.45E+06
lb/hr (93 00).,Blowdown will consist of the
'-following pollutants (9317):
TDS lb/hr
PO,4 7.3'lb/hr
S/S 25 lb/hr
VII-17
�
FTN. 9336
This blowdown will be held in a holding or cooling
pond and is periodically released (9300). The waste
water treatment system consists of the following
units (9301,9304,9305,9311): phenol solvent
extraction, sour water stripping, primary
clarification, activated sludge, and secondary clari-
fication. Removal efficiencies are given in
references. To process 1.00E+12 Btu/yr of 12,000
Btu/lb Central coal, the scale factor is 1.12E-02
times figures given in (9300) and using 8.64E+05
lb/hr feed (FC+VMA fixed). Water pollutants are based
on discharing of dissolver waste, coal prep waste,
sanitary waste, and blowdown waste after treatment.
Effluent
Ton/Yr PPM
Phenol 1.33E-02 1.95E-01
H2S 1.10E-02 1.62E-01
S7S 1.49E+00 2.06E+01
NH 2.20E-02 3.23E-01
CN/SCN 1.19E-01 1.75E+00
TDS 5.22E+02 7.67E+03
Oil 2.64E-01 3.88E+00
BOD 6.78E-03 9.97E-02
COD 8.62E-03 1.27E-01
PO4 3.21E-01 4.27E+00
H20 6.83E+04
9336 Air emissions associated with the solvent refining
process primarily consist of emissions from fuel
gas combustion, Claus plant tail gas, and coal
preparation plant.
CLaus-Plant
SO2 emissions are based on the total available
sulfur in the input coal. For processing 9.43E+05
lb/hr of 3.5 percent sulfur coal, 26,410 lb/hr of
sulfur is recovered in the Claus plant. 324 lb/hr
of this sulfur is recovered in sour water stripping
and 9734 lb/hr is recovered via a Wellman-Lord
scrubber system on filter cake burning process. The
remaining sulfur is recovered in acid gas recovery
of fuel gases. Assuming a 95 percent removal
efficiency of the Wellman-Lord system (9318), 1025
lb/hr of SOx is emitted. The Claus plant recovers
99.9 percent of the input sulfur. 0.1 percent is
emitted as S02 (9319,127). SO2 emissionis as follows:
VII-18
�
FTN. 9337
Filter Cake Combustion Stack Gas 4041 T/Yr-1025 lb/hr
Claus Plant Tail Gas 205 T/Yr- 53 lb/hr
Fuel Gas Combustion
Combusti on of the fuel gas produced (.868 Btu/SCF)
is based on the fuel requirements and distribution
given in (9300). The following is a list of
combustion sources:
Thermal Driers (from dissolvers) 1309E+06 Btu/hr
Mineral Residue'Processing 50t+06-Btu/hr
Solvent Recovery 630E+06 Btu/hr
Hydrogen Plant' 502E+06 Btu/hr
Sulfur Plant Incinerator 52E+06 Btu/hr
Air emissions are based on combustion of-the total
2.54E+09 Btu/hr (9303,12/72), and the-heating value
@ratio of 868 Btu/SCF to that@of natural.gas, 1050
Btu/SCF..Preparation of coal in flash driers
accounts for additional particulate emissions (9303,
8/10). Processing 8.64E+05 lb/hr of coal (3.0 percent
moisture) particulate emissions are 1362 T/yr using
a 95 percent efficient cyclone,system. Total
pollutants a re (tons/yr):
Part. sox CO HC NOX ALD
Coal P'rep. 1451.00 - 1.97 197.00 861.00 1T.76
Mineral Proc. 3.38 4041 0.08 7.52 32.90 0.56
Solvent Ext. 42.59 - 0.95 94 * 80 414.75 7.11
H2 Plant 33.94 - 0.76 75.60 303.75 5.67
Claus Plant 3.50 '204 0.08 7.80 34.00 0.59
1534.41 4245 3.84 382.72 1673.40 28
These figures are based on processing 8.64E+05 lb/hr.
To process 1.OOE+12 Btu/yr of 12000 Btu/lb Central
coal, the scale factor is 0.0112.
9337. Solid waste from the solvent refining process is.
a result of combustion of the filter c.ake,being used
as supplementary fuel. This ash is generated in the
mineral processing step. For processing 9.43E+05
ton/hr-of Central coal having an ash'content of-9.4
percent, 88,663 lb/hr of ash is generated in the
fluidized bed boiler. For a SRC plant processing
1.OOE+12 Btu/lb of Central coal (HV=12000 Btu/lb),
ash or solid waste is 3.92E+03.ton/yr. This solid
waste will have no land impact since it will be
transported back to the mine for ultimate disposal -(9300).
VII-19
�
FTN. 9338-9341-
9338 impacts have been interpolated from (9334,7).
It is assum6d that a solvent refining operation
will occupy 200 acres since product distillation,
upgrading, and pipeline gas production will not
be required. on a 1.OOE+12 Btu/yr,basis, land.
impact is.2.24- A-yr.
9339 Primary efficiency is based on the input of 9.43E+05
lb/hr.of 12000 Btu/lb Central coal. Since fixed
carbon.and volatile matter-is fixed with that,of
the coal in (9300), the product streams are consistant
with!that in (9300). Primary thermal efficiency
accounts for only primary coal-input and SRC output.
For a SRC heating value of 15,900 Btu/lb, product
is 4.88E+05'lb/hr, and primary efficiency is 68.6
percent. If by-product streams are consiaeredl,
efficiepcy would be somewhat-higher.
9340 Ancillary energy for a 10,000,T/D solvent. refined
coal'plant is approximately 7.71E+08 lb/hr of
natural gas (9300,5-11). Of the 3'.14E+09 Btu/yr.'
fuel'gas required, 2.37E+09 Btu/hr is supplied by
the production of high Btu refinery fuel gas. The
additional gas (natural gas) must be imported. It
is anticipated that a solvent refined coal plant will
make use of a considerable amount of waste heat,
and will be able to utilize this heat to produce
electricity. Approximately 32 MW may be exported.
'Ancillary energy for a plant processing 1.OOE+12
Btu/yr is'6.,81E+10 Btu/yr.
9341 Capital cost for a 10,'000 ton/day SRC plant is
based on figures in*reference (9300). Since the
processing.6f Central coal will require a larger
feed the cost of coal preparation, dissol 'ving,_
filtration, and'sulfur recovery have been scaled to
.reflect the differences in throughput. Additionally,
another 1.63E+06 dollars have been added to,cover
the cost of sour water strippers and activated
sludge units. Cost has been escalated from 1969 to
1972 $ using a straight 12 percent increase. Total
annualized cost is 8,85E+06 dollars 'at a 10 percent
fixed charge'-rate. For a plant processing 1.00E+12,
Btu/yr', capital cost is 1.22E.+05 dollars. Plant load
factor is 90 percent.
VII-20
�
FTN. 9342-9343
Operating cost is based on 9.58E+06 dollars and
a by-product credit consisting of the following:
Sulfur 1.04E=06 dollars
CO2 2.65E+05 dollars
Lt Oil 5.13E+04 dollars
Phenol 1.10E+05 dollars
Power 1.18E+05 dollars
Total 2.05E+06 dollars
Costs have been escalated (from 1969) 12 percent to re-
flect 1972 cost. For a plant processing 1.00E+12 Btu/yr of
Central coal, Operating costs are 9.44E+04 dollars
(9300).
9342 The average haul distance in the Central region is
assumed to be 290 miles and the fuel consumption
is 0.005 gal/TMI. (9335). To haul 1.00E+12 Btu/yr
(31500 ton/yr) of SRC, 6.09E+04 gallons are
consumed by the 3 locomotives. This assumes a
gross to tare weight ratio of 4 to 1. The empty
return trip requires 1.52E+04 gallons of diesel
fule. Total fuel comsumption to haul 1.00E+12 Btu/
yr is 7.61E+04 gallons. Exhaust gases from the
three locomotives are as follows (9303,3-7):
Lb/1000 Gal Tons/Yr
Particulates 25 0.95
SOx 65 2.49
CO 70 2.68
HC 50 1.92
NOx 75 2.88
ALD 4 0.15
In addition, another 12.64 tons/yr or particulates
are emitted during loading and unloading (9303,7-2).
9343 Land impacts are based on 290 miles and a 60 foot
railway right of way, for a plant processing 10,000
ton/day. The land impact for hauling 6.80E+13 Btu/
yr is 2109 acres. For an SRC plant producing
1.00E+12 Btu/yr, the land impact is 31.0 acres.
�
FTN. 9345-9350
9345 Primary efficiency for solvent refined coal
percent, assuming negligible losses
during transportation.
9346 Ancillaryfuel consumption for unit and mixed train
haulage is 1. Q6E+10 Btu/1. OOE+12 Btu hauled. From
footnote 9342, 7.61E+04 gallons of diesel fuel are
consumed. For a heating value-of 5.83E+06 Btu/BBL,
total energy required is 1.06E+10 Btu.
9347 Freight charges for haulage by unit train are 0.0061
$/TMI (9322,10) in 1969 cos 't. ICC imposed an 8P and
6P freight rate increase in.1970 and.1971, respectively,
to 0.0070 $/TMI. Haulage of 3.15E+04 tons of SRC,
equivalent to 1.OOE+12 Btu, a distance of 290 miles
is 6.:39E+04 $ total cost. From (9323,67/70) fixed cost
(depr eciation.only) is about 6P of total annual cost.
Hence, fixed cost is 3.83E+03 $ and operat.11ng cost is
6.01E+04 $.
9349 Th@average capacity of a barge.is 25000 tons'(9326.
35),and the average 1haul distance is assumed to be
300 miles (the approximate dis@tance from the
southern coal fields of Illinois to Chicago Via the
Illinois River). Air emissions are based on (9303.
3-11)'. To haul 1.OOE+12 Btu of SRC, 1.26 round trips
must be.made. Air pollutants-are as follows:'
Lb/Mi T/1.OOE+12 Btu
Particulates 7.58E-01
sox 1.5 5.69E-01
CO 1.2 4.55E-01
HC 0.,9 3.41E-01
NOX 1.4 5.31E-01
ALD 0.07 2.65E-02
These pollutants are based on a fuel consumption of
378 Btu per TMI (9325). Another 12.6 tons of
particulates are emitted during loading and
unloading (9303,7-4).
9350 The cost for shipping coal (SRC) in 1971 by barge
was 0.97 dollars per ton (9327,37) of which 12
percent Unclusive of insurance and depreciation) is
fixed cost. This agrees with data in (9328,18). Cost
Ito haul 3.15E+04 tons of SRC would be 2.86E+04
dollars operating and 3.91E+03 dollars fixed. Cost
is escalated 6 percent to reflect a 1972 base.
VII-22
�
VIII. COAL LIQUEFACTION
A. Introduction
The environmental impacts, efficiencies-, and costs,for the
production of low sulfur, liquid fuels from coal.-..are given in'Table
6 of this report. . Data-weredevelopedfor thiree regional coals:,
a high sulfur Cehtral.coal,-medium-sulfur Northern Appalachia coal,
and a low sulfur.-Northwe,st coal.. In addition, a National average__
case was synthesized from theregional data. Thecharacteristics''
of the coal [email protected] content,are' specified in the'first foot-
note for each regional case,.
Each data entry is based on an energy input of coal equiva-
lent to 1012 Btu and has-been derived for.a 11con'trolled" environ-
mental condition. The nature and magnitude of coal liquefaction
operations is suchthat stringent environmental control must be
practiced. A new entry,has been included for the truck transportation
of coal from the mine to the liquefaction plant. Since the solid
waste produced by 'the liquefaction plant.is assumed to be disposed of
by returning it to the-mine for bur-ial.,,@@,.thetruck.is no longer
empty on-its return trip. Hence.there is. an increased:con.sumption
of diesel fuel with a-corresponding increase.in air@ppllutants.
All of the cost data shown in;[email protected] based-on I a90 percent
Y
ant load factor, or 328 operating days/yr. -The.valueS' DrespntpH-
n' this table are based-on data accumu'lated..during. the Spring
of 1974.
TWO processes were considered,for the production of low
sulfur liquid fuels from.coal, These are the CSF (Consol Syn-
thetic Fuel) and SRC (Solvent Refined Coal) processes. Although
other processes are being developed, thesetwo represent the most
advanced for which data,are readily available. The COED process,
although sufficiently 'advanced, was not considered in this studv
because, with over half of the output Btu in the form of
6har or SNG, the process is not set up primarily for.the produc-'
tion of liquid fuels."
Table entries.have been made both at the process and activity
1, evels for coal liquefaction. The process lev.el.entries ar e re-
presentative of the environmental impacts for the CSF and SRC pro-
cesses, while the activit entry is an average of the process level
y
impacts. An activity level entry was made.so as to'minimize the
differences in pr .ocess design assumptions, (arising from limited
pilot plant data), the degree of completeness, and time periods
over which.the processes were investigated.
The following sections are brief descriptions of the individual
coal conversion processes considered.
VIII-1
�
CSF Process
The CSF process (Figure 24) features extraction of the coal by
hydrogenated solvents derived from the coal to produce a liquid-
solid slurry. After hydroclave separationrthe liquid extract is
fractionated in a vacuum still to produce a light fuel oil produdtand
a heavier bottom extract. This extract then passes to a hydro-
distillation column@from which is,taken a naphtha.cut and a heavy
product fuel oil. The solid residue from the separation stepi
containing ash.plus residual carbon, passes to a carbonization
section to remove the remaining solvent.' The' resulting char from
the carbonizer is gasified-in a Bigas u'n'it to manufacture the hydro-
.gen required for the entire plant.
2. SRC Process
In the SRC.process (Figure 25) coal is dissolved in a recycled
solventunder a reducing atmosphere., The" resulting liquid-solid phases.
are separated by means of filtration and the solid phase, contain-
ing ash and residual carbonaceous material, is gasified in a Bigas
unit to produce the hydrogen required in the hydrotreating units
throughout the plant. The liquid.phase filtrate passes to.c-i dis-
tillation column where it.is fractionated to p3;oduce a naphtha
stream, a distillate, and a residual-fuel oil.;.-' The naphtha and
distillate fractions are subsequently hydrotreated to reduce the
sulfur and nitrogen.levels of these fuels.
VIII-2
�
RAW FUEL GAS HpS TO
RAW COAL
SULFUR
-PREHEATED PLANT
COAL
COAL EXTRACT SOLVENT
FEED ------- 40 EXTRACTION SOLVENT DISTILLATE
,SOLVENT
PREPARA- RECOVERY FUEL
TION WASH
OVER- 'RESIDUE GAS 40 GAS FUEL-
FLOW
SEPARA- PLANT
TION LIQUOR EXTRACT GAS
LIQUOR TO WATER'
des- __w
TO - I ' TREATMENT.
WASH,
LOW
WATER UNDER-,-
Btu TREATMENT FLOW EXTRACT
GAS HYDROGEN
HYDRO H 8k
FOR SOLVENT LIGHT GENATION LET-
COAL DOWN
OIL
DRY-
TAR SOLVENT GAS
ING BUTANE
RECYCLE
SOLVENT
TAR TAR DISTILLATE FUEL
DISTILLATION-
LETDOWN
-IA-R:: LTC Ek - GAS
(CARBONIZER)
WASH
CHAR ABSORPTION
UNDER-
H?S TO
ULFUR AIR- LIQUOR
Colp PLANT SULFUR RECYCLE
TO WATER SOLVENT
ZeHAR STEAM TREATMENT H2 Ek BUTANE
LET-
STEAM DOWN
BCR H2 Hp HYDRO- GAS
MANUFAC- H2 0. COM_ DISTI LL_ NAPTHA
F
P
D 19S
'ArT@
FR I-
LATION@-11
OR
'Q.U
VATER
4
TMENT
TURE PRESSION HYDROGEN ATION HYDRORESIDUE TO PLA@j FUEL
------------------- Joe 02
Figure 24. CSF Coal Liquefaction Process (Ref. 9400)
�
WATER CO WATER
STEAM
WATER GASIFICATIO14 SYN- ACID GAS G SHIFT GAS C02
OXYGEN UNIT GAS REMO\AL CONVERSION REMOVAL
J
SLAG
COAL
TO DISPOSAL GAS FROM C L L.LQUEFACTION
T I METHANATION
COAL DISSOLVER FUEL GAS
PREPARATION ACID GAS@ SULFUR Hp GAS
PLANT
REMOVAL REMOVAL
FUEL GAS
OFFGAS
WET FILTER OFFGAS OFFGAS-__
CAKE
COAL COAL A COAL FUELOIL 0.2%,S
SLURRYING a LIQUEFACTION FILTR LIQUEFACTIO HYDROGENA- FUEL OIL
PUMPING 1% P11 T.ATION PRODUCT TION
DISTIL ATION
LIG _JNAPTHA
RIECYCLE LIQUID 0.5%S
PHENOLIC BOTTOMS
WATER BOILER
I f f H GAS FROM FUEL OIL
WAT
ACID GAS TO WATER RECOVERED-7 NAPTHA METHANATION
SULFGR RECOVE TREATMENT PHENOLICS HYDROGENA- NAPTHA PRODUTCT
TION
Figure 25. -Modified SRC Liquefaction Process (Ref. 9401)
WA,TER
N
ER
�
B.' Impact Data Table and Footnotes
VIII-5
�
CONTROLLED 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Is 17 to 19 20 21 22 Z3 24 25 26 27 28 29 30
FUEL REGION
COAL A5 INDICATED WATER POLLUTANTS (TONS/ Ida BTU, EX. COL. 12) AIR POLLUTANTS (TONS/Ida BTU) Ul ATIONAL HEALTH POTENTIAL COST (I)OLLARS/IOP*M)
SOLIDS LAND OCC LARGE PRIMARY ANCILLARY
MNE: - DISSOLVED SOLIDS SUSPENDED TOTAL T14ERMAL PARTIC- YDRO_ ALDEHYDES ) DEAiHS INJURIES MAN-DAYS ENERGY FIXED OPERATING TOTAL'
ROM ACTIVITY PROCESS GOD COD NO,. sox co TOTAL TONS/ (ICRE.-TR - $CAL EFFICIENCY COST COST COST R
Mott SOLIDS ORGANICS COUS 6.7,8 ATU/IO`*BTU) ULATES CARBONS ETC.' 1012STU, Ida . 70.2 BTU _10'28TU LOSTfdlBTU DISASTER (STuldlum
ACIDS BASES P04 N05 OTHER TOTAL(DS) 10 BTU
7 -PACE I
THNISJ TRANS@R TATION 2
3TRUK TRUCK o298 o9go .110 o9ge .... 1 1- 1-1 o9se D993 2.08-02 3 5-01 3 9457 4.33-G2 3 %57 5-02 3 9457 3.61-01 3 94S] 9.64-03 3 9457 160@@D 3 Oll. lm3g@Ot 3 1.57 09P9 .111 .11, 1082 1-00 1 P57 COD- 3 94S7 2.68,03 3 9457 7.67.63 3 057 1- 3 3
-4 UQFC LIQUEFAMON D1191 Oll, Ml .1. L@28@@72@1 19.4@56 A-3 5 94S6 1.67-03 5 9456 3.-.1 o- ... 9 o...... 2A ... D . . ....... . 9. -0-01 4 9456 2.2910D 4 945612.60-01 4 9456 9.52-04 4 4-03 2 9456 3.7-0 3945 61 -1 1 .191 20911 6.58-01 3 94S6 O.OQ- 2 945612. -05 3 906 1.9- 3.5. 41
6CSFPR CSF PROCE5S o.91 ol. Oll, 0999 4 , 1 59450 34-Oy 5 945D 1.23-03 5 9450 -4-61 5 D- D999 0-00 2 9451 2.56QO . 1- 1.1-1 0149446 3AS-01 4 9446 2.1-0. 4 9446 2.20-01 4 - 7,94-01 4 4.09,03 2 9447 -o 3"481 DO. o999 .11 mg, ...... . ... 0. 0040 2 5"51 I-OS 39441 1.3-5 3- 2.12.05 3 5
D.9 00.
6SRCPH sRc PRocEss .119 o999 Q999 3. 4-1 S945G @. 11-0 1 -D 2.1-3 51- 1.4- 1 o999 0999 O.OPOO 2 9451 3.35+DD 4 9446 5.82.01 4 9446 1.6-1 4 9446 2w9S 01 4 ME 2-OD 4 944t 2.99-DI 4* -6 1.17-02 4 4.3103 2 9447 4.34+00 39449 o999 .119 og" ZQ91 C25-01 3 9445 4. @D 2 @5 2oS@DS 29449 2.41AS 39U9 SA-5 3 6
-7 NO RTN@EST
0TRNW TRANS@ORTATION
9TRUK TRUCK -s .11. o9l. D- o...oo I's D19. 0998 S.31-03 3 9443 2.65-DI 3 940 1.93-02 3 9443 2.65-02 3 9443 1.61-01 3 9- 4. 30-D3 39443 4.85-01 3 DODO 3.03-01 31233 O.O-D I 12N 2. lo-02 1 l2o2 6m 74@01 1 1202 1 .2 DO- 1 22 3*25+03 3 9452 SaO@3 394S2 t.23+D4 3 9
-10 UQFC LIQUEFACTION o.-OO 2 945. 0-00 2 9458, 0-00 2 94SB 0.0-0 2 M . ..... DO -. D.D-D -. .. -D. I- D.OD+DD 11411 D.O-O 2 0.00+0 2 9458, Q.00-DO 2 9458 0. -OD 2 -8 1 2.. -D_ 4 9453 7.49+01 4 9458 4q 6@00 4 9458 7.9-1 4 9458 2-DO 4 "59 2.32 01 49459 , -3+01 4 331- 2 5.11... 3 941. o9ll .11, .11, 2.1 1. -1 1 -1 Oa 2 9458 2-.1 1- LA1.5 394", 3.- 1 10
CSFPRI CSF PRoc.s O-D@ 2 1-1 D.0.0 I I . 2 9436 o.oolOO 2 9 I'll .191 2091 6.21-01 3 94311 0.. 1.33+05 39435r_,-5 3
o...O. @ - .1 D.-D 2-9- O--D 02 9436 D. -OD 29436 O.OOIDQ 2 0.0&00 2 9436 0.0- 2 943@ 0.0- 2 9413 2.3-0 4 9432 6-101 4 9432 4.4B+OO 4 9432 3-01 4 9432: 2.08+00 4 o32 1.12-01 .-2 7.87.01 -1- 9031 D. Ol- 0. D", 1 01 101 1-- 39435 11-
12 -C-1 SRC -OUS O.OODO 2 9442 D.-OD 2 9442 O.WOD 2 442 0.0-0 2 9442 0. -00 2 9442 0-0 2 9442 D.-O 2 -2 d-00 29442 0. -00 2 D.-O 9442 0,00+OD @442 0-0 2 9413 3.491DO 4 1- -1- 4 2438 4.91-00 4 943B @-- 4 - -1- 1- -1-0 11.38 9.9-1 3:46+03 29439 6.22+OD 39440 o999 o9911 2.11 ..11-0 1 9.11 "37 2 W05 29441 2.4- 3-1 _F2
13 C.-RAL 13
14 TRNSPI TRANSPORTATION 14
Is TRUK I TRU@K ..8 .11 M. Oll. .11. D....OO 1 1- D11O D. DO... 2- .11. Oll. D998 1.95- 3 94141 5.Sfi-Ot 3 9414 4.05-02 3 9414 5,56-02 3 9414 3.38-Ol 3 9414 -1-0 1-4 1-1.0 3 ..D. 13sf D... 091 1082 1.00+00 1 109. 4+17- 3 94S% 2. 77.0 3 IM 13- 9455 1. ol+" 15
LW. I LIOVE-CTI.. -1 .11, mg ..91 0999 $.eo.ol 5 9459 1.27-Ol 1 1- -9-01 59459 5.8- 5 .9 -1 @ D,DD.O. .4@2 Dj49459 2.69-01 4 9459 4 Ml -1AD D 05912.11-Ol -1 LORID2 . Sj!4+D3 2 9459 3a!6+OG 3 9459 o999 .11, 2091 6.5-1 2 9459 ..O@00 1 $459 2.11+05 3 9459 IA8@05 39459 4-5 3
17 CSFPR CSF PROCM .919 - Oll. o- 0999 6.36+01 5 9- D-1 1 9401 1.84-D3 59406 .36-Ol 1 1 M, -. Z 10 +D,494DI L43+01 4 94D2 3.18-01 4 9402 2.12,00 4 9AD2 2A.-Ol 902 1 9.1-1 5.01-03 2 9403 2-100 3 9104 0." .111 .11. 2.1 2 1.1 O.OQ+OO 2 9401 1.621GS 3 9DOS 1.2@0 3940S 2AL,05 3 17
5RCPR SRC PROCESS -9 .91 nq 0999 5.23+01 5 9412 1.74 Ol 1 -1 14-03 59472 5.2-1 5 0"9 o.2 MOOD 7 94i3 .-I 1 1.0 1. -.1 . 904 2.1-1 Ml @.-DD @ 2- --l 1.2-1 1+11.1 1 -1 @-o 3 1- Oll, o"I'l 1 14.1 2.11.1 @ I- 'Al- 39411
19 NORTHERN APPA@CHIA 191
20 THNsF TRAN@RTATION 20
21 TRUK TRUCK .11. Oll. M. Oll. ..DDIDD 3 1- 0998 OAD'oo 3 .198 .91. - --2 1 .1. 1-- @ 1.1 --2 @ W8 9.1-2 3 942. 5.84-01 3 9428 1.56-02 39426 _1+76+00 3 aggg 1. 14+GO 3 1472 o999 D911 .11 1002 1-00 1 1093 7.24@ 3 9429 2.63+031 -_ 1.12,03 3 .13 9.25+03 3 21
22 IoFc ,qu,AcTlow .11, D119
.119 G999 oggg I.-W wo --2 @ -0 -0- S 946o @.-o .11, 0999 0-00 2 9450 2.94+00 4 9460 7.46+01 4 9460 I.-Ol 4 94R -2--ol 4 9460 2.2-0 4 9460 Ml@Ol 49460 9d22+01 4 4.11.03 2 9460 3-00 3 9- .11, .11, 2091 5.58-01 2 9460 O.OO+oo 2 946o 26045 i 946o ias- 3 -D 4.0-s 1 22
23 jC5FPR I CSF PR E@S o999 o999 o9gs am .111 -741 1 1- -03 5 94211 1.84-03 5 9421 6.37+01 5 1.0-DI 2 111. D.00+06 2 2416 1.- 3 94201 1.31- 3 -26 2.0@0 3
21 8.01 1 DO, 0999 IO.DD+0O 2 9413 2.6-0 4 9417 01- @ -1 1.11+01 4 9417 2@97-01 4 9417 _2.0+00 4 9417 2.2-1 49417 7m54+Dl 4 4wO0*O3 2 941. 2-+00 3 9419 - o919 Mg 23
24 sncpR] sRC mocEss .91, .... .11, D999 Sm24+01 5 9427 1,7-2 1 -7 3AI-Ol 1 9427 S.24-01 5 D911 0999 o@ I - 4 1- Sa82+01 4 9423 1.43+01 4 942: 2-01 4 9423 2.SO.00 1 9.23 3.02-01 49423 1.0-2 4 cz,- 3 - DID 2.1 k-Ol 2 1.21 D.DO+OO 2 94M 2-S 2 9426 2.4-5 3 -6 5-5 3 24
25 25
26 26
27 27
28 28
29 R 29
30 30
3 1 3 1
32 3 2
33
34 34
35 3
36 36
3 7 37
38 38
3 9 39
40 40,
4 1 41
42 42
43 43
441 1 44
45 4 5
46 46
47 j47
48 481
49 491
50 so
51
5 2 52
V3
31 54
:4
55 W5
TABLE 6. ENVIRONMENTAL IMPACTS, EFFICIENCY AND
COST FOR ENVIRONMENTALLY CONTROLLED
NATIONAL AND REGIONAL COAL LIQUEFACTION
V I I 1 7
3
4
T'"S'
T
$4
U' !'C
CE 1* h1l 2
7
RNW
TRUK
I'D
2 94.
--o . . ...
@
5
4
47
4G
49
50
51
�
FTN. 1082-1233
Footnotes for Table 6
1082 The potential for large scale disasters is non-existent.
1098 Coal losse's during haulagd,from.mine to tipple are assumed
to be negligible.
120*2. The.'haulage' statistics published in (1206) through (1210)
were employed here. Haulage encompasses a broad category
which includes the following transportation modes for the
coal-U) from an underground mine to the surface by rail
and (2) from the surface to,the coal preparation plants
by truck. No-fatalities for-hauling coal strip mined
in the states of Montana and Wyoming were reported over
the years 1964-19,66, 1968 and 1.969. An average of 0.473
non-fatal injuries/l.OE06 tons production was computed
.for coal haulage, occurring primarily in Wyoming,. An
approximate average of 25 work-days lost per injury is
assumed'foi transport following strip mining. This
quantity results from averaging.the work-days lost/injury
for Montana and Wyoming.; The basic statistics on average
severities were comprised of contributions due to strip
mining and haulage.. The.Felative contribution of each
cannot be isolated.
1213' No coal is assumed lost between mine'and tipple.
123V To control sedimentation, the runoff from the haul roads is
diverted to settling ponds placed at intervals along the
roadway (1100). Since the road is relatively short (1.5
mile, footnote 1204) only one settling basin is,.assumed to
be needed.. Because of,the low rainfall, the settling pond
is,assumed adequate to contain all.,the runoff .(footnote
1233). The contained water can be utilized for dust
suppression of-the haul roads or allowed to evaporate.
1233 The haul road land.impact is 0.274 AC-yr/l.OE12 Btu
(footnote 1204). The settling pond is assumed-to have a-
surface area of 1 AC, which for a depth of 5 feet has a
storage capacity,of 1.6 MMgal. Thus, the land impact for
the settling pond is'0.0285 AC-yr/l.OE12 Btu (2 MMT/yr hauled
on roads). The.total land impact is 0.303 AC-yr/l.OE12 Btu.
VII 1-9
�
FrPN. 1358-9401
1358 To control siltation, the runoff.from.the haul roads.'is
diverted to settling.ponds placed along the roadway (1100).
@It is assumed that all the sediment is removed.
1359 It is assumed that a settling pond is required,for each
mile.of road and.that-each pond..us.es an.acre of land.
Thus, 4 AC are utilized for the settling pond (the haul
road is 3.8 mile long, footnote 1,312). The land impact is
0.0945. AC-yr/l.OE12 Btu., This is,in addition tolthe land
impacted,by the road, ..0..584 AC-yr/l.OE12 Btu (footnote
1311),
1455 Sediment runoff from coal haulage roads can be controlled
by-ditching.alongside the roads and diverting the runoff
to small settling-ponds.
1472 it is as,sumed that a settling pond is required for each
mile of road and that each pond uses one acre. Thus seven
acres are utilized for the settling ponds (the haul road
is 7.3 mile in length, footnote 1415). The land impact
is.0.148'AC--yr/l.OE12 Btu. This is in addition to theland
impacted by the road 0. 990 AC-yr/l. OE12 Btu, (footnote 1415)
2091 Fire and/or explosions caused by gas'.leaks, oil leaks,
act of God, or human er 'ror. Possible damage@to refinery,
personnel, adjacent properties.
9400 The-central coal used in this study has the'following
n' -of-mine basis
composition 0 a.run
Proximate Ahalysis-WT PC
Btu/lb 10820 Ash 11. 3
S-WT PC 3.70, Water 14.4.
Vol. Mat. 33.4
Fixed C 40.9
For this coal 46,200 ton of coal is equivalent to 1.OE12
Btu.
9401 From (9400,13), a plant processing 23364 TPD of ROM coal
produces.298.3EO9 Btu/D of fuel oil and 62.5EO9 Btu/D
naphtha-or 360..8EO9 Btu/D total liquid fuels. The total
plant heat demand is 106AE09 Btu/D, based on (9400,13)
plus an additional 14.7EO9 Btu/D for previously purchased
electricity (61150 Kw). This heat demand is provided by
the combustion of fuel gases (89.8EO9 Btu/D) and coal-
(16.6EO9 Btu/D). Thus a total of 24,133 TPD coal (522.2EO9
Btu/D from footnote 9400). is required to produce the
360.8EO9 Btu/D of liquid fuels for a primary.effic,iency
of .691. The ancillary energy is zero because the plant
is self-sustaining with all power and steam requirements
generated on-site.,
VIII-10
�
FTN. 9402.
9402 Th e principal quantifiable air pollution sources are
as follows
TPD
Part Sox CO HC NOX other
Fuels combustion 1.40 8.91 11-11 .*157. 32.5 .00192
sulfur recovery.
plant 3.80
Storage-and misc. .009 .128
Fuels Combustion
Based on air emissions factors in (8301,1,.1-3,1.4-2)
and the combustion of 769 TPD I:coal and 89.8EO9 Btu/D
U of gases (containing 0.4 PC of the S in the process feed
9
coal from (9400)). Particulates from,the coal fired
boiler were reduced 99.5 PC by the use of an ESP and
FQ_ a Wellman Lord wet scrub. S02 emissions from the coal
fired boiler were-reduced 95 PC by the Wellman-Lord
unit. Particulate.emissions from the coal thermal
dryers are based.on (8301,8.9-1). These emissions are
'reduced 85 PC by the use of multiple cyclones and then
99 PC by'a baghouse,before entering the atmosphere.
Sulfur Recovery Plant
Based on the amind and Rectisol acid.gas removal sys-
tems' in (9400), the.Claus plant receives a 55 MOL PC
H2S feed.- From (,2022,103) thi's Claus unit can recover
95.5 PC of the in'coming S. The inc'oming S 'for recovery
is based.on 23364 TPD process feed coal, 3.70 PC S, and
91.4 PC of the-feed S as H2S to Claus for recovery (the
balance-of the' S is in the liquid fuel products (3.0
PC) and produced as byproduct S (5.2 PC)) from (9400).@
Based, furthermore, on complete recycle to Claus of
all.the S02 recovered in the Wellman Lord scrubbing
units on the boiler flue'gases and Claus tailgases,
8521.2-TPD S is the Claus feed. Thus 813.9 TPD S is
recovered from Claus plus 44.3 TPD S from the iron oxide
towers for a.total of 858.2 TPD S or 1643 ton/l.OE12
Btu. 38.3 TPD S passes to the-tailgas unit so that 1.9
TPD S.or 3.8 TPD S02'exits the stack.
Storage and Misc.
Based on 23364. TPD of process feed coal and 1.1 PC N2
in the coal (9400,12) and-40 PC of the N2 as NH3'(9400
13), 128 TPD NH3 is produced and recovered. From (8301,
.5.2-2) controlled,storage and loading operations emit
two lb NH3/ton NH3. Thus .128 TPD NH3 are released into
the atmosphere. From J9400,13) 12,200 BBL/D of naphtha
are pro 'duced. Assuming two weeks storage capacity under
new tank conditions and emission factors from (9302,4.j-8),
.009.TPD HC are@emitted.
Conversion to tons/l.OE12 Btu is.based on a total coal
throughput of 24,133 TPD and 46,200 ton coal/l.OE12 Btu.
VIII-11
�
FTN. 9403-9405
9403 Based on 23,364 TPD process feed coal with 11.3 PC
ash, 2645 TPD ash are produced. 95 pc of this is solid
waste for disposal with the balance in the products or
deposited on catalysts (9400,13). Based on the combus-
tion of 769 TPD coal and .4 TPD of emitted particulates,
86.7 TPD of solid waste is produced. Based on 10.660
GPM net makeup H20 (9400,51,66) and an assumed 500 PPM
suspended solids which is completely removed by lime
treatment and clarification, an additional 32 TPD of
solid waste is generated. The sum total solid waste
produced is thus 2616 TPD or 5007 ton/1.0E12 Btu.
9404 Fixed land requirements are estimated at 500 acres from
(9401,7). Since coal liquefaction is considered a mine-
mouth activity, all solid waste (Footnote 9403) produced is
assumed to be returned to the mine for burial. There is,
therefore, no incremental land impact due to solid waste
production. Thus a total of 500 acres is required for a
24,133 TPD coal liquefaction operation. With a 90 PC
operating factor this is equivalent to 2.91 acre-yr/1.0E12 Btu.
9405 Capital and operating costs were developed as follows:
Capital Costs-1972 $-Plant Basis-24,100 TPD, 90 P LF
From (9400,19), escalated from 1971 $ to 1972 $ at 5 PC,
costs for coal preparation, extraction, separation, sol-
vent recovery, low temperature carbonization, tar distilla-
tion, extract hydroconversion, hydroletdown and absorption,
hydrodistillation, gas plant, H2 manufacture, H2 com-
pression, and support serviced total 233.6E06 $. Power
generation costs were estimated at 121,80E06 $ (8323,
42), ESP costs at .16E06 $ from (9402,133), Claus plant
costs at 3.70E06 $ from (8303, AI-25), Wellman Lord SO2
removal costs on coal boiler flue gases at 3.80E06 $ and
on Claus tailgases at 3.90E06 $ from (8303, AI-26), and
water pollution control costs at 1.8E06 $ from (9400,
102) and (2013,VII-4,VII-5). To the subtotal was added
a 7 PC development contingency to arrive at a total plant
investment of 278E06 $. Based of a FCR of 10 PC/yr and
7.93 TPY coal, this is equivalent to 1.62E05 $/1.0E12
Btu.
Operating costs-1972 $-Plant Basis-24,100 TPD, 90 P LF
From (9400,32), costs for catalyst and chemicals, raw
water ash disposal maintenance material and labor,
operating labor; supervision, and payroll and general
overhead to 23.64E06 $/year. Operating and main-
tenance costs on the power boiler were estimated at
.19E06 $/year from (1918,46), ESP costs at 5E03 $/year
from (9402,135), SGC costs on coal boiler flue gases at
.86E06 $/year and on Claus tailgases at .92E06 $/year
from (9403,18/27), and water pollution control costs at
45E03 $/year from (2013,VII-4,VII-5). The total gross
operating cost is thus 25.66E06 $/year. Byproducts
VIII-12
�
FTN. 9406-9408
were cre dited at $10/LTS (761 LTS/D) and,$25/T NH3
(128 TPD, NH3) from (8103,AI-5). The total net operating
cost is thus 22-11E06 $/year or, for 7.93EO6 tPY coal
input, 1.29EO5 $/l.OE12 Btu.
9406 Process wastewater pollutants were derived from (9400)
and (9404) and include phenols, cyanide, NH3, sulfide,
oil, and suspended solids.' Dissolved solids are contri-
buted by boiler and.cooling tower blowdowns and deminerali-
zation regenerations.. Wastewater treatment includes oil-
water separation, dissolved air flotation, ammonia stills#
equalization, activated sludge plus clarification, and
activated carbon polish.- Removal efficiencies were de-
veloped from (8318, Table 7 (8313,609.1618), (8312,207.),
(2013,IV-3), and (8316,172). Organics
(9.6E-04TPD) comprise phenols and oil,.while total
-dissolved solids includes cyanide .(2.2E-03 TPD NH3
(.13 TPD)', sulfide (9.6E-04 TPD) and.other dissolved solids
(33.1 TPD). Suspended solids total 4.2E-03 TPD-and the
processwastewater discharge is 1193 TPD. Conversion to
tons/l.OE12 Btu is'ba-sed on a total 'coal throughput of
24,133 TPD knd 46,,200 ton coal/I.OE12 Btu.
9407 From (94 .01,31) a plant processing 1.0,000 TPD coal (250.
8EO9 Btu/D) produces 156.7EO9 Btu/D.of liquid fuel pro-
ducts for a.primary efficiency of .625. Although this is
for a different coal, it is assumed that this efficiency
holds a's well'for the central coal*(footnote 94 '00) used
in this analysis. Thus, a total of 11,585 TPD of coal is
required for the production of 156.7EO9 Btu/D of liquid
fuels. Thetotal plant heat demand is 76.3EO9 Btu/D
which is provided for by the combustion of 70EO9-Btu/D of
fuel gases and 6.3EO9 Btu/D of product heavy fuel'oil.
The ancillary energy is zero because the plant is self@
sustaining with all power and steam requirements, generated
on-site.
9408 The principal quantifiable air pollution sources are as,
follows:-
TPD
Part SOX CO HC NOx Other
Fuels combustion .832 2.40 .626 ..0725, 22.1 .0196
sulfur recovery
plant 5.0
storage and misc. .0014 .062
Fuels Combustion
Based on air emi ssions factor's in (8301,1.3-2,1.-4-2). and
the combustion of 6.25EO9 Btu/D of heavy fuel oil (con-
taining .28 PC of the S in the process feed,coal from
VIII-13
�
FTN. 9409-9410
(9405,11)) and 70EO9 Btu/d fuel gases (containing negii-
gible S from (9405,11)). Particulate emissions-from
the coal thermal dryers are based on (8301,8.9-1).
These emissions are reduced 85 percent by the use of
multiple cyclones and then 99 percent by a Venturi
scrub before entering the atmosphere.
Sulfur Recovery Plant''.
Based on the.amine acid gas removal system in (9405',11,
16,19,21), the Claus plant receives a 10 Mol- percent
H S feed. From (8303,AI-25) this-Claus unit can
2
recover 89 percent of the 'incoming S., The incoming
S for recovery is based on 11585 TPD process feed coal,
3.7 percent-S, and 94..6 percent of the feed S as H2S to
Claus for recovery (the balance of the S is in the
liquid fuel products (5.4 percent)) from (9405,11.).
Based, fuAhermore, on complete recycle to Claus.of the
so2 recovered in the Wellman Lord.scrubbing unjt on the
Claus tailgases, 452.8 TPD S is the Claus feed. Thus
403 TPD S is recovered for sale.or 1607 ton/l.OE12
Btu. Since 49.8 TPD S passes to the Wellman Lord tailgas
scrubbing unit, 2.5 TPD S or 5.0 TPD SO2 exits to the
atmosphere.
Storage and misc.
Based on 11585 TPD of process feed coal,and 1.1 percent
N2 in the coalandthe assumption that 40 percent of the
N2 forms NH (9400,13), 61.9, TPD NH. is produced and
recovered. @rom (8301.,5.2-2) controlled storage and
loading operations emit 2 lb NH3/ton NH . Thus .062 TPD
NH are released into the atmosphere. ?rom (94'05,11) 2011
BB2/D of naphtha are produced. Assuming 2 weeks storage-
capacity under new tank conditions and emission factors
from (8302,4.3-8), .001 TPD HC are emitted.
Conversion.to tons/l.OE12 Btu is based on a total coal
throughput of 11585 TPD and 46200 ton coal/l.OE12 Btu.
9409 Based on 11585 TPD process feed coal with 11.3,percent
ash, 1311 TPD ash are produced. Based on 3626.gpm*net
makeup H 0, (9401,27) and an assumed 500 ppm suspended
.Solids wAillch is completely removed by lime treatment
and clarification, an additional 11 TPD of solid waste
is generated. The sum total solid waste produced is
thus 1322 TPD or 5272 ton/l.OE12 Btu.
9410 Fixed land requirements are estimated at 280 acres
from (9405,48). Since,coal liquefaction is considered
a mine-mouth activity,.all solid waste (Footnote 94.09)
produced is a'ssumed to be returned to,the mine for burial.
There is, -therefore, no incremental land impact due to solid
VIII-14
�
FTN. 9411-9412
waste production. Thus a total of 280 acres is required
for a 11585 TPD coal liquefaction operation. With a 90
percent operating factor this is equivalent to 3.40
acre-yr/1.0E12 Btu.
9411 Capital and operating costs were developed as follows:
Capital Costs-1972 $-Plant Basis-11,600 TPD, 90 P LF
From (9401,57), deescalated from 1973 to 1972 $ at 5
percent, costs for coal preparation, coal slurring and
pumping, coal liquefaction and filtration, dissolver
acid gas removal, coal liquefaction product distillation,
fuel oil hydrogenation, naphtha hydrogenation, fuel
gas sulfur removal, gasification, acid gas removal, shift
conversion, CO2 removal, methanation, 02 plant, instru-
ment and plant air, raw H2O treatment, process waste H2O
treatment, power generation, product storage, slaq
removal system, steam generation, general facilities,
and home office engineering total 207E06 $. Claus plant
costs were estimated at 3.3E06 $ from (8303,AI-25),
Wellman Lord SO2 removal costs on Claus tailgases at
4.5E06 $ from (8303,AI-26), carbon absorption for
wastewater costs at .25E06 $ from (2013,VII-4), and a
Venturi for particulate removal on the thermal dryer at
.40E06 $ from (1080,64). The total plant investment is
thus 215.5E06 $. Based on a FCR of 10 percent/yr and
3.81E06 TPY coal this is equivalent to 2.61E05 $/1.0E12
Btu.
Operating Costs-1972 $-Plant Basis-11,600 TPD, 90 P LF
From (9406) the preliminary estimated operating costs of a
10,000 T/D plant are 50E06 $/yr based on $9/ton coal. Assuming
a 90 percent operating factor this would give 29.6E06 $/yr
for coal cost and 20.4E06 $/yr for other operating
expenses. Based on 20.4 E06 $/yr and 3.81E06 TPY coal
this becomes 2.47E05 $/1.0E12 Btu.
9412 Process waste water pollutants were derived from (9300)
and (9313,61) and included phenols, cyanide, NH3,
sulfide, oil, and suspended solids. Dissolved solids are
contributed by boiler and cooling tower bowdowns and
demineralization regenerations. Waste water treatment
includes oil-H2O separation, phenol solvent, extraction,
sour H2O stripping, primary clarification, activated
slude, secondary clarification, and activated carbon
polish. Removal efficiencies were developed from (8318,
Table 7), (9301), (8322), (9305), and (9311).
Organics (7.9E-04 TPD) comprise phenols
and oil, while total dissolved solids includes cyanide
(1.1E-02 TPD), NH3 (.01 TPD), sulfide (3E-03 TPD) and
VIII-15
�
FTN. 9413-9416
other dissolved,solids (13.1 TPD). Suspended solids
total 4.4E-03 TPD and the process waste H 20 discharge.
is 208 TPD. Conversion to tons/l.OE12 Btu is based
on a total coal throughput of 11585 TPD and 46200 ton
coal/l.OE12 Btu.
9413 Thermal discharges can be completely eliminated.by
the use of 'mechanical draft wet cooling towers.
9414 In 1969 the.average truck capacity for this region
was'59 T and the average haulage distance from mine
to tipple was 3.8 mi (0001,344). The fuel consumption
rate is assumed to be 7 gal/1000 TMI.(0002,377) and the
gross to tare weight ratio of the trucks is assumed to
be 2.5 to 1. Based on 46200 ton coal/l.OE12 Btu, 783
round trips are required to deliver 1.OE12 Btu. From
footnotes 9403 and 9409 the liquefaction plant produces
an average,,of 5140 ton solid waste, so that 6.6 ton of
solid waste/return trip goes back to the mine. Thus a
round trip is 548 ton miles and 3003 gal of diesel fuel
are consumed/l.OE12 Btu. Emissions from a diesel powered
truck are given in (0002,3-7). Dusting,from haulage
roads is controlled by'watering downf oiling, or some
other method.
9415 The Northern.Appalachian coal used in this study has
the following composition on a run-of-mine basis
Proximate Analysis-Wt. PC.
Btu/lb 12000 Ash 10.0
S-Wt PC @2.0 Water- 5.0
Vol.Mat.and
Fixed C. 85.0
For this coal 41700 ton,.'of coal is equivalent 'to 1.OE12
Btu.
9416 From (9400,,13) a plant processing 23364 TPD of ROM coal
produces 360.8EO9 Btu/d liquid fuel products. The total
plant heat demand is'106.4EO9 Btu/d. based'on (9400,13.)
plus an additional 14.7EO9 Btu/d for previously purchased
electricity (61150 Kw). This heat demand is provided by
the combustion of fuel gases (89AE09 Btu/d) and coal
(16.6,EO9 Btu/d). Thus a'total of 24133 TPD coal is
required to produce the 360.8EO9 Btu/d of liquid-fuels
for a primary efficiency of .691. Although this is for
adifferent coal, it is assumed that this efficiency
holds as well for the Northern Appalachian coal (foot-
note 9415),used in-this analysis. Thus 21067 TPD coal
is required for process feed and 692 TPD coal is used
in boilers.for a total of 21759 TPD coal. The
ancillary energy is zero.because the plant is self-
sustaining with all power and steam requirements generated
VIII-16
�
FTN. 9417
on site.
9417 The principal quanitfiable air pollution sources are as
follows
TPD
Part SOx CO HC NOx Other
Fuels Combustion 1.37 2.84 1.07 .146 31.8 .00173
Sulfur Recovery Plant 2.0
Storage and Misc. .009 .113
Fuels Combustion
Based on air emissions factors in (8301,1.1-3,1.4-2) and
the combustion of 692 TPD coal and 89.7E09 Btu/d of gases
(containing 0.4 percent of the S in the process feed coal
from (9400)). Particulates from the coal fired boiler were
reduced 99.5 percent by the use of an ESP and a Wellman
Lord wet scrub. SO2 emissions from the coal-fired boiler
were reduced 95 percent by the Wellman Lord unit.
Particulate emissions from the coal thermal dryers are
based on (8301,8.9-1). These emissions are reduced 85
percent by the use of multiple cyclones and the 99 percent
by a bag house before entering the atmosphere.
Sulfur Recovery Plant
Based on the amine and Rectisol acid gas removal systems
in (9400), the Claus plant receives a 43 Mol percent H2S
feed. From (2022,103) this Claus unit can recover 94.9
percent of the incoling S. The incoling S for recovery
is based on 21067 TPD process feed coal, 2.0 percent S,
and 91.4 percent of the feed S as H2S to Claus for
recovery (the balance of the S is in the liquid fuel
products (3.0 percent) and produced as by-product S
(5.2 percent)) from (9400). Based, futhermore, on
complete recycle to Claus of all the SO2 recovered in
the Wellman Lord scrubbing units on the boiler flue
gases and Claus Tailgases, 413.1 TPD S is the Claus feed.
Thus 392 TPD S is recovered from Claus plus 21.9 TPD S
from the iron oxide towers for a total of 414 TPD S or
793 ton/1.0E12 Btu. Since 21.1 TPD S passes to the
Wellman Lord tailgas scrubbing unit, 1.0 TPD S or 2.0
TPD SO2 exits the stack.
Storage and Misc.
Bases on 21067 TPD of process feed coal and 1.1 percent
N2 in the coal and 40 percent of the N2 and NH3 (9400,13),
1I3 TPD NH3 is produced and recovered. From (8301,5.2-2)
controlled storage and loading operations emit 2 lb NH3/
ton NH3. Thus .113 TPD NH3 are released into the atmos-
VIII-17
�
FTN. 9418-9420
phere. From (9400,13) 12200 BBL/d Of naphtha are
produced. Assuming 2 weeks storage capacity under new
tank conditions and emission factors from (8302,4.3-8),
.009 TPD HC'are emitted.
Conversion to tons/l.OE12 Btu is based on a total coal
throughput of 21759 TPD and 41700 ton coal/l.OE12 Btu.-
9418 Based on 21067 TPD process feed coal with 10-percent
ash, 2107 TPD ash are produced. 95 percent of this is
solid waste for disposal with the balance in the.
products or deposited on catalysts (9400,13). Based on
the combustion of 692 TPD coal and .4 TPD of emitted
particulates, 68.8 TPD of solid waste'is produced. Based
on 10660 gpm 'net makeu 'p H20 (9400,51,66) and an assumed
500 ppm suspended solids which is completely removed
by lime treatment and clarification, an additional 32
TPD of solid Waste is generated. The sum total solid
waste produced is thus 2090 TPD or 4004 ton/I.OE12 Btu.
9419 Fixed land tequirements are estimated.at 500 acres from
(9401,7). Since coal liquefaction is considered a mine@-
mouth activity, all solid waste (Footnote 9418) produced
is assumed"to be r 'eturned to the mine for.burial. There is,
therefore,'no'incremental,land impact due to solid waste
production. Thus a total of @00. acres is required for a
21759 TPD coal-liquefaction operation. With a 90 percent
operating factor this is equivalent to 2.92 acre-yr/l.OE12 Btu
9420 Capital and -operating costs were developed as follows:
Capital Costs-1972 $-Plant Basis-21,800 TPD, 90 P LF
From (9400,19),.escalated from 1,971 $ to 1972 $ at 5
percent, costs for coal preparation, extraction, separ-
ation, solvent recovery., low temperature carbonization,
tar distillation, extract hydroconversion, hydroletdown'
and absorption, hydrodistillation,@gas plant? H manu-
2
facture, H 2 compression, and support services total
233.6EO6 $. Power generation costs were estimated at
12.8EO6 $ from (8323,42), ESP costs at .16EO6 $ from
(9402,133),,Claus plant costs at 2.3EO6 $ from (8303,
AI-25), Wellman Lord S02 removal costs on coal boiler
flue gases'at 2.8EO6 $ and on Claus tailgases at 2.8EO6
$ from (830'3,AI-26),,I and H20 pollution control costs at
1.8EO6 $ from (9400,102) and (2013,VII-4,VII-5). To the
subtotal was added a Tpercent development contingency
to arrive at a total plant investment of 274.3EO6
Based on a FCR of 10 percent/yr and 7.15EO6 TPY-coal
this.is equivalent to 1.60EO5 $/l.OE12 Btu.
VIII-18
�
FTN. 9421-9422
Operating Costs-1972 $-Plant Basis-21,800 TPD, 90 P LF
From (9400,32) costs for catalyst and chemicals, raw
H2O, ash disposal, maint. mat. and labor, operating
labor, supv., and payroll and gen. overhead total
23.33E06 $/Yr. Operating and maintenance costs on the
power boiler were estimated at.19E06 $/yr from (1918,
46), ESP costs at 5E03 $/yr from (9402,135), SGC costs
on coal boiler flue gases at .63E06 $/yr and on Claus
tailgases at .66E06 $.yr from (9403,18.27), and H2O
pollution control costs at 45E03 $/yr from (2013, VII-4,
VII-5). The total gross operating cost is thus 24.86E06
$/yr. By-products were credited at $10/LTS (369 LTS?D)
and $25/T NH3 (113 TPD NH3) from (8303),AI-5). The total
net operating cost is thus 22.73E06 $/yr or, for 7.15E06
TPY coal input, 1.33E05 $/1.0E12 Btu.
9421 Process waste water pollutants were derived from (9400)
and (9404) and included phenols, cyanide, NH3, sulfide,
oil, and suspended solids. Dissolved solids are con-
tributed by boiler and cooling tower blowdowns and
demineralization regenerations. Waste H2O treatment
includes oil-H2O separation, dissolved air flotation,
ammonia stills, equalization, activated sludge plus
clarification, and activated carbon polish. Removal
efficiencies were developed from (8318,Table 7), (8313,
609,618), (8312,207), (2013,IV-3), and (8316,172).
Organics (9.6E-04 TPD) comprise phenols
(2.2E-03 TPD), NH3 (.13 TPD), sulfide (9.6E-04 TPD) and
other dissolved solids (33.1 TPD). Suspended solids
total 4.2E-03 TPD and the process waste H2O discharge is
1193 TPD. Conversion to tons/1.0E12 Btu is based on a
total coal thoughput of 21759 TPD and 41700 ton coal/
1.0E12 Btu.
9422 From (9401,31) a plant processing 10000 TPD coal
(250.9E09 But/D) produces 156.7E09 Btu/D of liquid
fuel products for a primary efficiency of .625.
Although this is for a differenct coal, it is assumed
that this efficiency holds as well for the N.
Appalachian coal (footnote 9415) used in this analysis.
Thus a total of 10446 TPD of coal is required for the
production of 156.7E09 Btu/D of liquid fuels. The total
plant heat demand is 76.3E09 Btu/D whic is provided
for by the combustion of 70E09 Btu/D of fuel gases and
6.3E09 Btu/D of product heavy fuel oil. The ancillary
energy is zero because the plant is self-sustaining with
all power and steam requirements generated on-site.
VIII-19
�
FTN. 9423
9423 The principal quantifiable air- pollution sources are as
follows:
TPD
Part. so CO HC NO Other
'X x
Fuels Combustion .815 1.17 .626* .0725 22.1 .0196
Sulfur Recovery Plant 2.4
Storage and Misc. .0014. .056
Fuels Combustion-
Based on air emissions factors in (8301,1.3-2,1.4-2) and
the combustion of 6.25EO9 Btu/D of heavy fuel oil
(containing .28 percent of the S in 'the process feed
coal from (9405,11)) and 70EO9 Btu/D of fuel gases
(containing negligible S from (9405,11)). Particulate
emissions from the coal thermal dryers are based on
(8301,8.9-1 ). These emissions are reduced-85 percent by
the use of multiple'cyclones and then 99 percent by a.
Ve-nturi,scrub before entering the atmosphere.
Sulfur Recovery Plant
Based on the amine acid gas*removal system in (9405,11,
16,19,21), the Claus plant receives'a 10 Mol percent H 2S
feed. From (8303,AI-.25) this Claus -unit can recover 89,
percent of the incoming S. The incoming S for recovery
is based,on.10446 TPD process feed coal, 2A percent S,
and 94.6 percent of the feed S as H S to Claus for
recovery (the balance of the S is iA the liquid fuel products
(5.4 percent)) from (9405,11). Based, furthermore, on
complete recycle to Claus of the SO recovered in the
Wellman Lord scrubbing unit on the.Laus tailgases, 220.6
TPD S is the Claus feed.,.Thus 196.3 TPD S is recovered
for sale, or 783 ton/l.OE12 Btu. Since 24.3 TPD S passes
to the Wellman Lord tailgas scrubbing unit, 1.2 TPD S or
2.4 TPD SO 2' exits to the atmosphere..
Storage and Misc.
Based on 10446 TPD of process feed coal and 1.1 percent
Ng in the coal and the assumption that 40 percent of
t e N forms NH (9400,13), 55.8 TPD NH is produced and
2 3 3
recovered. From (8301,5.2-2) controlled storage and
loading operations emit 2 lb NH /ton NH 3. Thus .056 TPD
NH are released into the atmoslhere..From (9405,11) 2'011
BBZ/d of naphtha are produced. Assuming 2 weeks storage
capacity under new tank conditions and emission factors
from (8302,4.3-8), .001 TPD HC are emitted.
Conversion to tons/l.OE12 Btu is based on a total coal
throughput of 10446 TPD and 41700 ton coal/l.OE12 Btu.
VIII-20
�
FTN. 9424-9427
9424 Based on 10466 TPD process feed coal with 10.0 percent ash,
1045 TPD ash are produced. Based on 3626:gpm,ne'-t makeup H 20
9401,27) and an assumed 500 ppm suspended solids which
is completely removed by lime treatment and'clarification,
an additional 11 TPD,of solid waste is generated. The
sum total solid waste-produced -is thus 1056 TPD or '4214 ton/1.0
E12 Btu.
9425 Fixed land requirements are estimated at 280 acres from
(9405,48). Since coalliquefaction 'is considered a,mine-
mouth activity', all solid waste (Footnote 9424):produced is
assumed to be returned to the mine for burial., There:is,
therefore, no incremental land impact'due to solid waste pro-
duction. Thus a total of 280 acres,is'requir'ed for a 10446 TPD
coal liquefaction-operation.. With a 90 percent operating
factor this-is equivalent to .3.40 acre-yr/l.OE12 Btu.,
9426 Capital and operating costs were develo ped as follows:
.Capital Costs-1972@$-Plant Basis-10,400'TPDi 90 P LF
,.From (.9401,5,7), de-escalated from 1973 to 1972 $ at 5
percent, costs for coal preparation, coal. slurrying and
pumping, coal liquefacti6n and filtration,, dissolver
acid gas'removal, coal liquefaction product distillation,
fuel oil hydrogenation,.naphtha hydrogenation,.fuel.cjas.
sulfur removal, gasification, acid gas removal, shift,
conversion, CO removal, methanation, 0 plant, instrument
2 2.
and plant air, raw H 20 treatment, process waste H 20
treatment, power generation,.product@storage, slag
removal system, steam generation, general facilities, and
home office engineering total 207EO6'$. Claus plant costs
were estimated at 1.9EO6 $ from (8303-,AI-25),.Wellman
Lord SO removal costs on Claus tai Igases at 3.2EO6 $
from (8303,AI-26), carbon.absorpti'on for' wastewater@costs
at .25EO6 $ from (2.013,VII-4), and a,Venturi for
particulate removal on the thermal dryer-at .40EO6*$
from (1080,64). The total plant investment is-thus
212.7EO6 $. Based on a FCR of 10 percent/yr and-3.43EO6
TPY coal this is equivalent to 2.59EO5 $/l.OE12 Btu.
Operating Costs-1972 $-Plant Basis-10,40O.TPD, 90 P LF
From (9406) the preliminary estimated operating costs.
are 50EO6 $/yr bas,ed on $9/ton coal. Assuming a 90
percent operating factor this would give 29.6EO6 $/yr-
for coal cost and 20.4EM$/yr'for other operating
expenses. Based on 20AE06 $/yr and 3.43E06 TPY,coal.
this becomes 2.48EO5 $/l.OE12 Btu.
9427 Process waste water pollutants were derived from (9300)
and-(9313,61) and included phenols,:cyanide, NH V sulfide,
VIII-21
�
FTN. 9428-9431
oil, and suspended solids. Dissolved solids are
contributed by boiler and cooling tower blowdowns and
demineralization regenerations. Waste water treatment
includes oil-H 9 separation, phenol solvent extraction,
2
sour H 20 stripping, primary clarification, activated
sludge, secondary clarification, and activated carbon
.polish. Removal efficiencies were developed fr 'om (831R.
Table 7), (9301), (8322), (9305), and (9311).
Organics (7.9E-04 TPD) comprise phenols and
oil, while total dissolved solids includes cyanide
(1.lE-02 TPD), NH 3 (.01 TPD), sulfide (3E-03 TPD). and
other dissolved solids (13.1 rPPD).. Suspended solids
total 4.4E-03 TPD and the process waste H 20 discharge
is 208 TPD. Conversion to tons/l.OE12 Btu is'based
on a total-coal throughput of 10446 TPD and 41700 ton
coal/l.OE12 Btu.
9428 In 1969 the average truck capacity for this region was
22T and the average haulage distance from mine- to
tipple.was 7.3 mi (0001,344). The fuel consumption rate
is assumed t6 be 7 gal/1000 TMI(0002,3-7) and the gross
to tare weight ratio of the trucks is assumed to be
2.5 to 1. Based on 41700 ton coal/l.OE12 Btu, 1895 round
trips are,required to deliver 1.OE12 Btu. From footnotes
9418 and 9424, the liquefaction plant produces an
average of 4110 ton solid wast@, so that 2.2 ton of solid
.,waste/return trip goes.back to the mine. Thus a round'
trip is 391 ton-miles and 5191 gal of diesel fuel are
consumed/l.OE12 Btu. Emissions from 6 diesel'powered
truck are,given in (0002,3-7). Dusting from haulage roads
is controlled by-watering down, oiling, or some other
method.
9429 Fuel consumption by the haulage trucks amounts to 5191
gal diesel fuel/l.OE12 Btu (footnote 9428). For 5.83EO6
Btu/BBL diesel fuel this.is equivalent to 7.21EO8 Btu/
1.OE12 Btu.
9430- The Northwest coal used in this study has th.e.following.
composition on a run-of-mine basis
Proximate Analysis-Wt.Pc.
Btu/lb 8806 Ash 6.0.
S-Wt.Pc. 0.5 H 0 22.0
@621.Mat. 29.4
Fixed C. 42.6
For thi's coal 57000 ton of coal is equivalent to 1.OE12
Btu.
'9431 From (9400,13) a plant processing 23364 TPD of ROM coal
produces 360.8EO9 Btu/D liquid fuel products. The total
plant heat demand is 106AE09 Btu/D, based on (9400,.13)
VIII-22
�
FTN.9432
plus an additional 14.7EO9 Btu/D.for previously purchased
electricity (61150 Kw)'. This heat demand is provided
by the.combustion of fuel gases (8-9.8EO9 Btu/D),and
coal (16.6EO9 Btu/D).. Thus a total of @4133 TPD.coaI
is required to produce .the.360.8EO9 Btu/D of liquid fuels
for a primary efficiency of .691. Although this is.for,.
a different coal; it is assumed that this efficiency holds
as well for the subbituminous Northwest coal (footnote'
9430) used in this analysis.. Thus 28696 TPD;coal is
required for process feed and 949 TPD coal is used in-
boilers for a total of 29645 TPD coal. The ancillary
energy is zero because the plant is self-sustaining,with
all power and steam requirements generated on-site.
9432 The principal quantifiable airpollution sou rces are as
follows:
TPD
Part. so CO HC NO' Other
x x
Fuels Combustion 1.24 1.53. 1.08. .147 .31.9 .001.74
SuILfur Recovery Plant 0.80
Storage and Mis.c. @.009 .099
Fuels Combustion
Based on air emission factors in (8301,1.1-3,1.4-2) and
the combustion of-696 equivalent TPD coal and,89.7EO9
Btu/D of gases..(containing 0.4 percentof the Sin the
process feed coal from (9400)). Particulates from the;
coal fired boiler were reduced 99.5 percent by the use
of an ESP and a Wellman.Lord wet scrub. S'O emissions:
from the coal fired boiler were reduced 95 2percent by
the Wellman Lord unit. Particulate emissions from the.
coal thermal dryers are based on (8301,8.9-1). These
emissions are reduced 85 percent by the use of multiple
cyclones and then'99 percent by a bag house before
entering the atmosphere.
Sulfur Recovery Plant
Based on the amine and Rectisol acid gas removal systems
S
in (9400), the Claus plant receives a 35 Mol percent H
2
feed. From (2022,103) this-Claus unit can recover 94.6
percent of the incoming S. The incomi .ng S for recovery is
based on 28696 TPD process feed coal, 0.5 percent S, and
91.4 percent of the feed S as H 2S to Claus for recovery
(the balance of the S is-in the liquid fuel products
(3.0 percent) and produced as by-product S (5.2 Percent))
from (9400). Based, furthermore, on complete recycle to
Claus of all the SO recovered in the Wel.lman:Lord
scrubbing units on ihe boiler flue gases and Claus tail-
VIII-23
�
FTN. 0,433-9435
gases, '141.4 TPD S is the Claus feed. Thus 133.8 TPD S is
,recovered from Claus plus 8 TPD S from the iron Oxide'
towers for a total of 142 TPD S or 273 ton/l.OE12 Btu.
'Since 7.6 TPD S passes to the Wellman Lor-d tailgas
scrubbing unit, 0.4 TPD 5 or 0.8 TPD SO exits the stack.
.2
Storage and Misc.
..,Based on .28696 TPD of process feed coal and 0.7 percent
N2 in the coal and 40 percent of the N 2 as NH (9400,13),
97.5 TPD NH 3 is produced and recovered. From 18301,5.-2-2)
controlled storage and loading operations emit 2 lb
NH3/ton NH 3* Thus .098 TPD NH are released into the
atmosphere. From (9400,13) 12300 BBL/D of naphtha are
produced. Assuming 2 weeks storage capacity under new
tank conditions and emission factors.from (.8302,463-8),
.009 TPD HC are emitted.
Conversion to tons/l.OE12 Btu is based on a total*coal
throughput of 29645 TPD and 57000.ton coal/l.OE12 Btu.
9433 Based-on 28696 TPD process feed coal with 6 percent ash,
1722 TPD ash are produced. 95 percent of this is solid
waste for disposal with the balance in the products or
deposited on catalysts (9400,13). Based on the combustion
of 949 TPD coal and .2 TPD of emitted particulates, 56.7.
.TPD of solid waste is produced. Based on the assumption
that H 0 requirements for this,plant can be cut in half
througA theuse of air cooling, 5330 gpm net makeup H 20
would be required-' Assuming 500 ppm suspended solids in
this H 20 and complete removal by lime treatment and
clarification,.an additional 16 TPD of solid waste is
generated. The sum total solid waste produced is thus
1698 TPDbr 3264 ton/l.OE12 Btu.
9434 Fixed land requirements are estimate d at 500 acres for
coal storage, preparation, and liquefaction plant
facilities,from (9401,7) and at 265 acres for evaporation
ponds to handle the concentrated dissolved solids ' '
streams. Since coal liquefaction is considered.a mine-
mouth activity, all solid waste (Footnote 9433) produced is
assumed to be returned to the mine for burial. There is,
therefore# no incremental land impact due'to solid waste produc.
tion. Thus a total of 765 acres is required for a 29645 TPD
coal'liquefaction operation. With a 90 percent,operating fac-
tor this, is equivalent to 4.48 acre-yr/l.OE12 Btu.
9435 Capital And operating costs were developed'a,s follows:
Capita 1 C.osts-1972 $-Plant Basis-29,600 TPD','90 p LF
From (9400,19), escalated from 1971 $ to 1972 $ at 5
percent, costs for coal preparation, extracti on, separation,
VIII-24
�
FTN. 9436-9437
solvent, recovery, low temperature carbonization, tar
distillation, extract dyroconversion, hydroletdown and
absorption, hydrodistillation, gas plant,H2 manufacture,
H2 compression, and support services total 233.6E06 $.
Power generation costs were estimated at 12.8E06 $ from
(8323,42), ESP costs at .16E06 $ from (9402,133), Claus
plant costs at 1.0E06 $ from (8303,AI-25), Wellman Lord
SO2 removal costs on coal boiler flue gases at 1.9E06
$ and on Claus tailgases at 1.5E06 $ from (8303,AI-26),
and H2O pollution control costs at 1.8E06 $ from
(9400,102) and (2013,VII-4,VII-5). To the subtotal was
added a 7 percent development contigency to arrive at
a total plant investment of 270.7E06 $. Based on a FCR
of 10 percent/yr and 9.74E06 TPY coal this is equivalent
to 1.58E05 $/1.0E12 Btu.
Operating Costs-1972 $-Plant Basis 29,600 TPD, 90 P LF
From (9400,32) costs for catalyst and chemicals, raw
H2O, ash disposal, maint. mat. and labor, operating
labor, super., and payroll and general overhead total
22.85E06 $/yr: Operating and maintenance costs on the
power boiler were estimated at .19E06 $/yr from (1918,
46), ESP costs at 5E03 $.yr from (9402,135), SGC costs
on coal boiler flue gases at .49E06 $/yr and on Claus
tailgases at.42E06 $/yr from (9403,18/27), and H2O
pollution control costs at 45E03 $/yr from (2013,VII-4,
VII-5). The total gross operating cost is thus 23.99E06
$/yr. By-products were credited at $10/LTS (126 LTS/D)
and $25/T Nh3 (98 TPD NH3) from (8303,AI-5). The total
net operating cost is thus 22.78E06 $/yr for 9.74E06
TPY coal input, 1.33E05 $/1.0E12 Btu.
9436 Water pollutants are zero because there is no aqueous
discharge from the boundaries of the plant operation. All
process waste H2O and impounded runoff is treated and used
for cooling tower makeup, while all blowdown streams
are collected and sent to lined evaporative ponds for disposal.
9437 From (9401,31) a plant processing 10000 TPD coal
(250.8E09 Btu/D) produces 156.7E09 Btu/D of liquid
fuel products for a primary efficiency of .625, Although
this is for a difference coal, it is assumed that this
efficiency holds as well for Northwest coal (footnote
9430) used in this analysis. Thus a total of 14235 TPD
of coal is required for the production of 156.7E09 Btu/
D of liquid fuels. The total plant heat demand is 76.3E09
Btu/D which is provided for by the combustion of 70E09
Btu/D of fuel gases and 6.3E09 Btu/D or product heavy
fuel oil. The ancillary energy is zero because the plant
is self-sustaining with all power and stream requirements
VIII-25
�
FTN. 9438
generated on-site.
9438 The principal quantifiable air pollution sources are as
follows:
TPD
Part. SOx CO HC NOx Other
Fuels Combustion .872 0.40 .626 .0725 22.1 .0196
Sulfur Recovery Plant 0.80
Storage and Misc .0014 .048
Fuels Combustion
Based on air emissions factros in (8301,1.3,1.4-2)
and the combustion of 6.25E09 Btu/D of heavy fuel oil
(containing .28 percent of the S in the process feed
coal from (9405,11)) and 70E09 Btu/D fuel gases
(containing negligible S from (9405,11)). Particulate
emissions from the coal thermal dryers are based on
(8301,8.9-1). These emissions are reduced 85 percent by
the use of multiple cyclones and then 99 percent by a
Venturi scrub before entering the atmosphere.
Sulfur Recovery Plant
Bases on the amine acid gas removal system in (9405,11,
16,19,21), the Claus plant receives a 10 Mol percent
H2S feed. From (8303,AI-25) this Claus unit can recover
89 percent of the incoming S. The incoming S for
recovery is based on 14235 TPD process feed coal, 0.5
percent S, and 94.6 percent of the feed S as H2S to
Claus for recovery (the balance of the S is in the liquid
fuel products (5.4 percent) from (9405,11). Based
furthermore, on complete recycle to Claus of the SO2
recovered in the Wellman Lord scrubbing unit on the Claus
tailgases, 75.3 TPD S is the Claus feed. Thus 67.0 TPD
S is recovered for sale or 268 ton/1.0E12 Btu. Since
8.3 TPD S passes to the Wellman Lord tailgas scrubbing
unit, 0.4 TPD S or 0.8 TPD SO2 exits to the atmosphere.
Storage and Misc.
Based on 14235 TPD of process feed coal and 0.7 percent
N2 in the coal, and the assumption that 40 percent of
the N2 forms NH3 (9400,13), 48.4 TPD NH3 is produced and
recovered. From (8301,5.2-2) controlled storage and
loading operations emit 2 lb NH3/ton NH3. Thus .048 TPD
NH3 are released into the atmosphere. From (9405,11)
2011 BBL/D of naphtha are produced. Assuming 2 weeks
storage capacity under new tank conditions and emission
VIII-26
�
-9441
TN. 9439
F
factors from -8), .001 TPD,HC are emitted.
8302,4.3
Conversion to tons/l.OE12 Btu is based on a total coal
throughput.of 14235 TPD and 57000 ton coal/I.OE12 Btu.'
9439 Based on 14235 TPD process feed coal with 6.0 percent ash,
854 TPD ash are produced. Based on 3626 gpm net,makeup
H 0 (9401,27) and an assumed. 500 ppm suspended solids
wKch is completely removed.by lime.,treatment and
clarification, an additional 11 TPD of-solid waste is
generated. The sum total solid waste'produced is thus
.865 TPD or 3464 ton/I.OE12 Btu.,
9440 Fixed land requirements are es timated at 280 acres
for coal storage, preparation, and liquefaction plant
facilities from' (9405,48) and at 230 acres for evaporation
ponds to handle the concentrated dissolved solids streams.,
Since coalliquefaction is considered a mine-mouth activity,
all solid waste (Footnote 9439) is assumed to b6-returned to
the mine for burial. There is, therefore, no incremental
land impact due to solid waste production. Thtis a total of.
510 acres,is.required for a.14235.TPD.co.al.l,iquefaction
operation. With a 90 percent operating factor this is
equivalent to 6.22 acre-yr/l..OE12 Btu.
9441. Capital and operating costs were developed as follows:
Capital Costs-1972 $-Plant Basis-14,*200 TPD, 90 P. LF
From '(9401,57), de-escalated from 1973 to 1972*$ at 5
percent, costs for.coai preparation, coal slurrying
and pumping', coal liquefaction'and fi.itration,.dissolver
acid gas removal, coal liquefaction product distillation,.
fuel oil hydrogenation', naphtha hydrogenation, fuel gas
sulfur removal, gasification, acid gas removal, shift
conversion?'CO removal, methanation,.O plant,
2 2'
instrument and plant air,. raw H 20 treatment, process
waste H 2O,treatmqnt, power generation, product storage,
slag removal system steam generation, general facilities,
and home office engineering total 207EO6 $. Claus plant
costs were estimated at .87EO6 $ from (8303F-AI-25),
Wellman Lord.SO removal costs on Claus tailgases at
2.OE06 $ from (h03,AI-2'6), carbon absorption for waste.
*water costs at .25EO6 $ from (2013,VI,I-4.), and a Venturi
for particulate removal on the thermal dryer at AOE06
$ from (1080,64).,The total plant investment is thus
210.5EP6 $.-Based on a FCR of 10 percent/yr and 4.68EO6@
_TPY'.coal this is equivalent [email protected]@$/I.OE12 Btu.
VIII-27
�
FTN.9442-9448@@
't @TPD, 90 P LF,
Operaing,Costs-1972 $-Plant Basis-14,200'
From (9406) the preliminary estimated operating costs
are 50E06 $/yr basedon $9/ton coal. Assuming a .90 percent
operating factor this wouldgive 29.6EO6 $/yr for coal
cost and 20AE06 $/yr-'for other operating expenses. Based
on 20AE06 $/yr and 4.68EO6 TPY.coal this becomes 2.48EO5
$/l.OE12 Btu.
9442 Water pollutants are zero because there is.no aqueous
discharge from the boundaries of the plant operation.
All process waste H 0 and impounded runoff is treated
2
and used for cooling tower makeup, while all blowdown
streams are.collected and sent to lined evaporative
ponds for disposal.
Based on the use of'100.T truck capacity and an average
haulage distance from mine to tipple of 1.5 miles'(0001,
344),* The fuel consumption rate is assumed to be 7 gal/
1000 TMI (0002,3-7) and the-gross-to tare weight ratio
of the trucks'is assumed to be 2-.5 to 1. Based on 57000
ton coal/l.OE12 Btu, 570 round trips are required to
deliver 1.OE12 Btu. From footnotes 9433 and 9439 the
liquefaction plant produces an average of 3360 T solid
waste, so that 5.@9 T of solid waste/return trip goes
..back to the-mine. Thus a round trip,is 359 ton miles
and 1432 gal of diesel fuel are.consumed/l.OE12 Btu.
Emissions from a,diesel powered truck ate given in
-0092,3-7). Dusting from haulage roads is controlled
by.watering !down, oiling, or some other method.
9444 Fuel consumption by the haulage trucks amounts to 1432,
gal diesel fuel/l.OE12'Btu (footnote 9443). For 5 '.83EO6
Btu/BBL diesel fuel this is equivalent.to 1.99EOB,Btu/
1.OE12 Btu.
The primary efficiehdy'and ancillary energy for this
process are the arithmetic'average of the primary
efficiency and ancillary energy for the Northern
Appalachian, Central, and Northwest regions.
9446 Air pollutants for this process are.the arithmetic
averIage of the air pollutants f or the Northern
Appalachian, Central, and Northwest regions.
9447 Solid waste for this process is the.akithmetic average
of the solid waste produced in'the Northern Appalachian,
Central, and Northwest regions.
9448 Land utilized by this process is the arithmetic average
of the land used in the Northern Appalachian,.Central,
and Northwest regions.,,
VIII-28
�
FTN. 9449-9455
9449 Capital and operating costs for this process are the
arithmetic average of the capital.and operating costs
for the Northern Appalachian, Central, and-Northwest
regions.
9450 Water pollutants for this process a 're the arithmetic
average of the water pollutants for the Northern
Appalachian, Central, and Northwest.regions.-
9451, Thermal discharges for this process are the,arithmetic
average of thermal discharges for the Northern Appalachian,
Central, and Northwest regions.
9452, From footnote 1046 the capital cost of.transportation
equipment for a,2E.06 TPY mine is 1.123EO6 $.-Sediment
runoff from coal haulage roads can be controlled bv the
use of small, settling ponds at a cost. of $20000/pond (Footnote
1135). Assuming that a settling pond is requirea tor
each mile of road, 1 settlinq pond is required.-Thus
the total'capital cost is, 1.14EO6 $ or 1.14EO5 $/yr
at 10 'percent FqR. Based.on a 2EO6 TPY coal operation
and 57000.T/1.OE12 Btu ,this is equivalent to 3250 $/l.OE12
Btu. The operating costs is taken as $3175,80/yr from
footnote 1046. Thus for a 2E.06 TPY coal ope'ration.and
57000 T/1.OE12,Btu this is equivalent to 9051 $/l.OE12 Btu..
9453 From footnote 1046 the capital cost for transportatio n
equipment for a 2EO6 TPY mine is 1.12EO6 $. Sediment,
runoff from coal haulage roads can be controlled by the
use of settling ponds at a cost of $20000/pond (Footnote 1135).
Assuming that.a settling pond is required tor each mile
of road, 7 -settling Ponds are required. Thus-the total
capital cost is 1.26EO6 $ or 1.26EO5 $/yr at 1 '0 percent,
FCR. Based on a 2EO6 TPY coal 'operation-and 41700 T/
1.OE12 Btu this is equivalent to 2630 $/l,.OE12 Btu. The
operating cost is taken as $317580/yr from footnote 1046.
Thus for a 2EO6 TPY coal operation and 41,700 T/l.OE12 Btu
this is equivalent to 6622 $/l.OE12 Btu.
9454. Fuel consumption by..the haulage trucks amounts to 3'003
gal diesel fuel/l.OE12 Btu (footnote 94-14). For 5.83EO6
Btu/BBL diesel fuel this is equivalent to'4.17EO8 Btu/
1.OE12 Btu.
9455 From footnote 1046 the capital cost for,transportation'
equipment for a 2EO6 TPY mine is 1.12EO6 $. Sediment '
runoff from coal haulage roads can be controlled bv the
use' of small settling ponds at a cost of $20000/pond (Footnote
.1135). Assuming that a settling pond is required for each mile
of road, 4 settling. ponds are required. Thus.the total
capital cost, is 1.20EO6 $ -or 120 E05 $/yr at 10
percent FCR. Based on a 2EO6 TPY coal operation and 4620.6
VIII-29
�
FTN. 9456-94,60
T/l-OE12 Btu this is equiv
alent to 2770 OE12 Btu.
rating-cost is taken as $317580/yr from footnote
The ope,
1046. Thus for a 2EO6 TPY coal operation and 46200 T/
1.OE12 Btu this is equivalent to.7336 $/l.OE12 Btu.
9456 An arithmetic average of the CSF.and SRC processes for
the National Average case.
9457 @.An arithmetic average oftransportation numbers for the
Northern Appalachian, Central, and Northwest regions.
9458 An arithmetic average of the CSF and SRC processes for
the Northwest region.
9459 An arithmetic average of the CSF and SRC process for the
Central@region.
9460 An arithmetic average of the CSF 'and SRC processes for
the Northern Appalachian-rdgion.
VIII-3.0
�
IX. REFERENCES
REFERENCES FROM VOLUME I
0001 Minerals Yearbrook-1969, U.S. Department of the
Interior, Bureua of Mines, 1971.
0002 "Compilation of Air Pollutant Factors," Environmental
Protection Agency, Research Triangle Park, North
Carolina, February 1972.
0005 "Crude Petroleum, Petroleum Products, and Natural
Gas Liquids-1971," Min. Ind. Surv., USDI Bu Mines,
December 20, 1972.
0011 "Statistical Abstract of the US-1972," Bu Census,
Washington, DC 1972.
0012 "Environmental Conservation, The Oil and Gas Indus-
tries-Vol. One," Natl. Petr. Coun., June 1971.
0035 "Annual Summary of Disabling Work Injuries in the
Petroleum Industry for 1971,"API, Washington, D.C.,
April 1972.
1080 Jones, L.G., "Section Vi-Economics of Emission Control
Systems," an unpublished draft report, Environmental
Protection Agency, Research Triangle Park, North
Carolina, 1972.
1100 Grim, E. (Environmental Protection Agency, Cincinnati),
Personal Communication, June 1973.
1119 "Interim Effluent Limitations Guidance and Technical
Documentation for the Steel Industry", Office of
Permit Programs, EPA, Washington, D.C., March 1973.
1121 "Technical Report on the Coal Preparation Industry",
A draft report, Environmental Protection Agency,
Research Triangle Park, North Carolina, 1972.
1900 Aynsley, Eric and Meryl R. Jackson, "Industrial Waste
Studies-Steam Generating Plants", an unpublished study
in draft form prepared for The Environmental Protection
Agency, Water Quality Office, May 1971.
1906 Olmstead, Leonard M., "17th Annual Steam Station Cost
Survey", Electrical World, November 1, 1971.
1907 National Safety Council, Accident Facts - 1971 Edition,
N.S.C., Chicago, 1971.
1913 Federal Power Commission, The 1970 National Power
Survey - Part I, U.S.G.P.O., Washington, D.C., 1972.
XI-1
�
191.5 "Hydroelectric-@PowEir 'Evaluation, Supplement No. 1"..
Washington, D.'C., G.P.O.,
1917 Feaeral Power-Commission, Bureau of Power, "Feb. 1973
Monthly Report Of Cost and Quality of Fuels for Steam
Electric Plant," Washington,'.D.C. FPC.
1918 "17th,Steam S tation Cost Survey", Electrical Worldf
Nov. 1,-.1971.
1919 Federal Power Commission, "Problems in Disposal of
Waste Heat from Steam-Electric Plant",. Staff Study
Supporting 1970 National Power.Survey.
1920 "'Possible Impact '.of Costs of Selected Pollution Control
Equipment on the Electric Utility Industry & Certain
Power'Intensive Consumer Industries", Nera 1972.'
2001 "Crude Oil and Refined Products.Pipeline Mileag i
e in
the U;S.-Jan. 1971," Mineral Industry Survey, 'U.S.
,Bureau of.Mines, Dec. 3, 1971.
2002 :"A Primer of Pipeline Construction," Petroleum Extension
Service and Pipeline Contractors Association, Austin,
Texas', 1966.
2003 "Environmental Conservation-The Oil-and Gas-Industries-
Volume Two," National Petroleum Council, Feb. 1972.
2013, "Petroleum Refining Guidelines and Technical
Documentation", Office of Permit Programs, EPA,
Washington, D.C., March 7, 1973.
2022 H@dr6carbon Proce-ssinE. Volume 51, No. 4, April
1972,,,Gulf Publishing Co.,, houston, Texas.
IX-2
�
REFERENCES FOR LOW BTU GASIFICATIQN
@8000. Agosta, J. Illiant H.F., Lundberg, R.m. and Tranby,
O.G., "Status of Low Btu Gas as a Strategy for Power
Station Emission Control", Am.Ins.Chem.Eng. 65th Annual
Meeting, Nov. 1972.
8001. Jain, L.K., and Hixson, T.J., "Applicability Study, Coal
Gasification Process", Catalytic, Inc., Contract No.
68-02-0241 EPA March 1972.
8002. U.S. Dept. Int., "OCR 1973 Annual Report: Clean Energy
From Coal - A National. Priority", Calendar year 1972,
GPO Wash DC Feb 1973, pg. 37-42.
8003 Air Products and Chemicals, Inc., "Sulfur.Removal from
Low-Btu Gas Using A Fixed Hot Bed of Dolomite", OCR
1973 Annual Report: Clean Energy from*.Coal - A National
Priority,.Calendar year 1972, GPO Wash DC Feb 1973,
pg. 37-38.
8004 Lemezis, S. and Archer, D.H., "Coal Gasification for
Electrical Power Generation", Westinghouse Eng., Vol. 33
No. 4, July 1973.
8005 Hottel, H.C. and Howard, J.B., New Energy Technology
Some Facts and Assessments, The MIT Press, 1971, pg.
144-161.
8006 Leonard, J.W. and,Mitchell, D.R., Coal Preparation
AIME, The Seeley.W. Mudd Series, New York 1968.
8007 Mills, G.A., Gas From@Coal Fuel of the Future,
Environmental Science and Technoloay, Vol. 5, 12,
Dec. 1971.
8008 Shurr, Sam-H., Energy Research Needs,-Section on
"Production of Zflean Low-Btu Gas from Coal", RFF Inc.,
Wash DC, Oct 1971, pg. V29-V49.
8009 Wen, C.Y., "Optimization of Coal Gasification Processes"
Dept. Chem. Eng. WVU, prepared for OCR US Dept. Int.,
Research and Development Report No. 66, Interim Report'
No. 2, Contract No. 14-01-0001-497, Wash DC.
8010 Katell, S., Lewis, P.S. and Wellman, P.,'"'The
Economics of Producing Gas at Atmospheric and
Elevated Pressures", presented at the American Assoc.'
of Cost Eng. Annual Meeting, St. Louis,'Mo., June 18-20#
1973.
8011 Final Report, "The Supply-Technical Advisory Task-
Fo rcerSynthetic Gas-poal", prepared by Synthetic Gas-
Coal Task Force for Supply-Technical Advisory Comm.,
NGS, FPC, April 1973.
IX-3
�
8012 "Application of El Paso Natural Gas Co. At Docket
No. CP73-131 for a Certificate of Public Convenience
and Necessity", filed before the Federal Power
Commission, Nov 15, 1972, pursuant to Section 7 (c) of
the Natural Gas Act, Vol. I, Vol II, Vol. III, El Paso
Gas Co., Nov 7, 1972.
8013 Robson, F.L., et al., "Technological and Economic
Feasibility of Advanced Power Cycles and Methods of
Producing Nonpolluting Fuels for Utility Power
Stations", United Aircraft Res. Lab., prepared for
NAPCA, USDHEW, Durha, N.C., Dec 1970.
8014 Lewis, P.S., Liberatore, A.J., and McGee, J.P.,
Strongly Caking Coal Gasified in a Stirred-Bed Producer,
US Bur. of Mines, RI 7644, US Dept. Int., Bur. Mines,
Wash. DC 1972.
8015 Applies Tech, Corp. "SO2 Free Two-State Coal Combustion
Process", EPA-R2-72-035, for EPA, August 1972.
8016 Personal Communication with Morgantown Energy Research
Center, Morgantown, W.V., Sept. 1973.
8017 Gas Generator Research and Development - Phase II -
"Process and Equipment Development", OCR R&D Report
No. 20 - Final Report by Bitum. Coal Res., 1970.
8018 Karnavas, J.A., and Larosa, P.J. and Pelczarski, E.A.,
Two-Stage Coal Combustion Process, Chem. Eng. Progress,
Vol. 69, No. 3, March 1973, pp. 54-55.
8019 Karnavas, J. A., Larosa, P.J., and Pelczarski, E.A.,
Atgas-Molten Iron Coal Gasification, Applied Technology
Corp, presented at 1972 AGA Synthetic Pipeline Gas
Symp., Chicago, Ill., October 30, 1972.
8020 Lurgi Quick Information )0 1007/10.71), "Clean Fuel
Gas from Coal", Lurgi Mineraloltechnik GMBH, Fuel
Technology Division, obtained Aug. 1973 from American
Lurgi Corp, 5 East 42nd Street, New York, N.Y. 10017.
8021 Lurgi Quick Information (0 1008/10/71), "New Fossil-
Fueled Power Plant Process Based on Lurgi Pressure
Gasification of Coal", Paul F.H. Rudolph, Lurgi
Gesellschaft Fur Warme-Und Chemo-Technik MBH,
paper presented by Joint Conference of the Chem.
Institute of Canada with Amer. Chem. Soc. 25th Annual
Conf., May 26, 1970.
8022 Applied Tech. Corp., "SO2 Free Two-State Combustion
Process", Phase II, draft report to EPA, Appendix to
EPA-R2-72-035.
IX-4
�
@8023 Kop ers Eng.-andCo., Confidential Information
p
Supplied on "Pollution Aspects of Coal Gasification",
Sept. 24, 1973.,
8024. Farnsworth, F.J., Leonard, H.F., Mitsak, D.M., and
Wintrell, R., The Production of Gas from Coal Through
A Commercially Proven Process, Koppers Co.,,Inc., Aug
1973.
.8025 Personal Communication with Paul J. Larosa, Director
R&D, Applied Technology Corp..,,Pittsburgh, Pa.?
10/8/73.
8026 The Pennsylvania State Universityi College of Earth
and Mineral Sciences, Coal Research Section,
Proximate and Ultimate Analysis of Various U.S. Coals",
Collected and analyzed under contract to OCR, Wash DC
1973.
8027 Sullivan, D.A.,. "Design-Considerations for Low-Btu
Fuels", SOA-10-73 paper presented at the l8th GE Gas
Turbine State of-theArt-Engineering Seminar, June
11, 12, 13,1973..
8028 General Electric Company, Gas Turbine Products.
Division, "Gas Turbine Environmental Factors, GER.
2486B", Schenectady, New York 1572..
8029 ATC Two-Stage Combustor, Design Calculations,
Applied Technology Corp., Pittsburgh, Pa., 1973.
8030 "Design Calculations of BOM-Atmospheric.and
BOM-Pressurized Systems", supplied by BOM Morgantown
Research Center, Morgantown, West Virginia, Sept,1973.
8031 Second Supplement to"'Application of-El Paso Natural
Gas,Company for a-Certificate of Public Convenience
and Necessity", Docket No. CP73-1314 El Pas 'o Natural
Gas'Company, October 8, 1973,,Filed : October 9.01 1973.
8032 Personal Communication with Paul Lewis'of the BOM''
Research Center, Morgantown,, West Virginiao" Dec..1973.
8033 "The @1970 NationalPower Survey , Federal'Power
Commission, Part ll", The Federal Power Commission-#,
GPO,,Wash DC, Dec 1971..
8034 Carlson,.H.A., The Stag Cycle, USOA-4-72, paper
given at the GE State of the Art Seminar.on. Electric
utility Gas Turbine,Applications, Sept 24-27, 1972.
8035, Technical Report,on "The Coal Preparation Industry", a
draft report,EnvironImental Protection Agency, Research
Triangle Park, 1972.
�
REFERENCES FOR HIGH BTU GASIFICATION
8300 "FPC National Gas Survey-Synthetic Gas-Coal Section",
April, 1973 (FPC Files).
8301 --"Compilation of Air Pollutant Emission Factors" (Second
Edition). EPA, Research Triangle Park, North Carolina,
April 1973.
8302 "Supplement No@,Ifor Compilation of Air Pollutant
Emission Factors,'!,., Second Edition, EPA, Research
Triangle Park, North Carolina, July 1973..
8303 "Final Report - The Supply-Technical Advisory Task-
Force-Syhthetic Gas-Coal", Federal Power Commission
,National,'Gas Survey., April 197-3.
8304 "An Econ 6mic Evaluation of Waste Water Treatment for a
250 MM SCFD.Synthane Plant", Report No. 73-22, Bureau of
Mines, April 1973.
8305@ "Engineering Study and Technical Evaluation of
the Bituminous Coal Research, Inc., Two*-Stage Super
Pressurd.Gasification Process'" Research and
Development Report No. 60, Office of Coal'Research,,
Department of the Interior, Washington, D.C.
8306 Metcalff J. (Stearns-Roger,Inc. Denver, Colorado),'
Personal@Com'munication, October 1973.
8307 "Pollution Aspects of the Synthane Process", Bureau of
-Mines, Technical.Progress Report, U.S. Department of
the Interior.
8308 Schora, F.C., and C.W. Matthews, "Analysis of a Hygas
Coal Gasification Plant Design", paper presented at
AIChE 65th Annual Meeting, New'York, Nov. 27"30
1972.
8309 Katell,"S., P. Wellman, and W. Morel, "An Economic
Evaluation of Synthane Gasification for the Production
of Pipeline Gas from Coal", Process Evaluation Group,
Bureau of Mines, Morgantown, West Virginia.
.8310 "El,Paso.Na'tural Gas.Co. - Second Supplementto
Application of El Paso Natural Gas Co. for a
Certificate of Public Convenien ceIand Necessity",'
October 9,* 1973.
8311 'iDetailed Envik-ohmdnta 1 Analysis Concerning a Proposed
Coal Gasification Plant for Transwestern Coal
Gasificati.on,,,Co--,',.,Pacific Coal Gasification Co., and.
Western Gasification Co.", submitted before the Federal
Power Commission, "February 1, 1973.
IX-6
�
8312 Kostenba .der, P.D., and J.W. Flecksteiners" IlBiological
Oxidation of Coke Plant Weak Ammonia Liquor", Journal
Water Pollution Control Federation, Vol. 41, Nbo 2,
Part 1, FeEruary 1969.
8313 Cousins, W.G. and A'B. Mindler, Tertiary Treatment of
Weak Ammonia Liquor., Journal Water Pollution-Control
Federation, Vol. 44, No. 4, April 1972.
8314 Forney, A. (Bureau of Mines,- Pittsburgh,,Pa.),
Personal Communication, September 1973.
8315 Hertwig, W., .(Amoco,Oil Co.,.Whitingj Indiana) Personal
Communication, October 18, 1973.
8316 Pattersong,,J.W..11 et al., "Wastewater Treatment
Technology", National Technical Information Service
PB204521, August 1971.
Porterp J.W.p et al., "Zero Discharge of Wastewater from
Petroleum Refineries", National Conference on Complete
Water Reuse, Washington, D.C., April 1573.
8318 "Petroleum,Refining Effluent Guidelines", A draft report
@Programs
by,Roy'F. Weston for EPA,Office.of Water'
Washington, D.C., September-1, 1971.
8319 "Transwestern Coal Gasification Co.., Pacific Coal
G*asification Co.,.'Western Gasification Co., Joint
Application for Certificate 'of Public Convenience
and Necessity", Filed with.the Federal,Power Commission,
February 1, 1973.1
8320 "Volumes I, II, III' 'Application of El Paso Natural Gas
Co. at Docket@No. CP73-131 for,a Certificate of Public
Convenience and-Necessity filed with the Federal Power
.Commission, November 15, 1972.
8321. Ellington, E.E., et al.,' "Phase III and Phase IV-A Design
and Construction of the CSG Pilot Plant", R and D Report
No. 16-Interim Report No. 5" Office of Coal Research,
Washington, D.C.
8322 Wurm, Hans J., "The Treatment of Phenolic Wastes
.23rd Industrial Waste Con'ferdnce-Part Two, Purdue
University, 1968.
8323 Roe, Kenneth A., And William H. Young" "Trendd@In
Capital Costs of Generating Plants", Power Engineering,
June 1972.
8324 Chemical Engineerin2 Progress, Vol. 690, No. 3, March 11973,
3 7.
IX-7
�
REFERENCES FOR OIL SHALE
9000 "Final Environmental Statement for the Prototype Oil
Shale Leasing Program, USDI, Volume I and III, 1973.
9001 Schurr, Sam H., "Energy Research Needs," Resources
for the Future, Inc., NTIS, Washington D.C.
9002 "Report on Economics of Environmental Protection for
the Federal Oil Shale Leasing Program," State of
Colorado, January 1971.
9003 "Petroleum Facts and Figures," American Petroleum
Institute, 1971.
9004 Weichman, B. E., "Oil Shale, Coal, and the Energy
Crisis," Chemical Engineering Progress, Volume 69,
No. 5, May 1973.
9005 "Water Use in the Petroleum and Natural Gas Industries,"
BOM, USDI, 1966.
9006 East, J.H., JR., E.D. Gardner, "Oil Shale Mining,"
Rifle, Colorado, 1944-56, Bulletin 611, USDI, 1964.
9007 Katell, Sidney, Paul Wellman, "Mining and Conversion
of Oil Shale in a Gas Combustion Retort," BOM
Technical Progress Report No. 44, USDI, October 1971.
9008 Burwell, E.L., H.C. Carpenter, and H.W. Sohns,
"Experimental IN SITU Retorting of Oil Shale at Rock
Springs, Wyoming," BOM Technical Progress Report #16,
USDI, June 1969.
9009 "Water Pollution Potential of Spent Oil Shale Residues,"
U.S. Environmental Protection Agency, December 1971.
9010 "Compilation of Air Pollutant Emission Factors,"
U.S. Environmental Protection Agency, Research Triangle
Park, North Carolina, February 1972.
9011 Burwell, E.L., T.E. Sterner, and H.C. Carpenter,
"In Situ Retorting of Oil Shale, "USDI, Report of
Investigations 7783, 1973.
9012 Ruark, J.R., H.W. Sohns, H.C. Carpenter, "Gas
Combustion Retorting of Oil Shale Under the Anvil
Points Lease Agreement: Stage II," USDI, Report of
Investigations 7540, July 1971
IX-8
�
9013 "Hydrocarbons form Oil Shale, Oil Sands, and Coal,"
AICHE Series 54, Volume 61, 1965.
9014 Wise, R.L., R.C. Miller, and H.W. Sohns, "Heat
Contents of Some Green River Oil Shales," USDI,
Report of Investigations 7482, March 1971.
9015 "Cost of Clean Water," Volume III, Industrial Waste
Profile No. 5, Petroleum Refining, FWPCA, USDI,
November 1967.
9016 Pfleider, Eugene P., "Surface Mining," The American
Institute of Mining, Metallurgical, and Petroleum
Engineers, Inc., New York 1968
9017 Ward, J.C., G.A. Margheim, G.O.G. Lof, "Water
Pollution Potential of Spent Oil Shale Residues
From Aboveground Retorting," American Chemical Society,
Division of Fuel Chemistry, Volume 15, No. 1, March 29-
April 2, 1971.
9018 Hubbard, Arnold B., "Method for Reclaiming Waste Water
from Oil Shale Processing," American Chemical Society,
Division of Fuel Chemistry, Volume 15, No. 1, March 29-
April 2, 1971.
9019 "Hydrocarbon Processing," Volume 51, No. 9, Gulf
Publishing Company, Houston, Texas, September 1972.
9020 Carnes, Billy A., Davis L. Ford, and Sidney G. Brady,
"Treatment of Refinery Wastewaters for Reuse,"
Presented at the National Conference of Complete
Water Reuse, Washington, D.C., April, 1973.
9021 Hydrocarbon Processing, Volume 49, No. 9, Gulf
Publishing Company, Houston, Texas, September 1970.
9022 Nelson, N.C., "Guide to Refinery Operating Cost,"
Petroleum Publication Company. Tulsa, Oklahoma, June
1970.
9023 Hutchins, John S., Warren W. Krech, and Max W.
Legatski, "The Environmental Aspects of a Commercial
Oil Shale Operation, " Paper Number EQC25, American
Institute of Mining, Metallurgical, and Petroleum
Engineers, New York, New York, 1971.
IX-9
�
9024 Oil and Gas Journal Volume 69, No. 25, Petroleum
Publishing Company, Tulsa, Oklahoma, June 21, 1971.
9025 "Oil Shale-A Stateside Answer to the Petroleum
Shortage," Mining Engineering, Society of Mining
Engineers of AIME, October 1972.
9026 Aires, Robert S., and Robert S. Newton, "Chemical
Engineering Cost Estimating, "McGraw-Hill, New York,
New York 1955.
9027 "An Economic Evaluation Using 30 Gal/Ton Shale and
Producing 50,000 BBL per Calendar Day of Shale Oil,"
Report NO. 74-13, Process Evaluation Group, Bureau
of Mines, USDI, Morgantown, West Virginia, Publication
Expected April 1974.
9028 "Impact on Air Quality from Oil Shale Development,
Engineering-Science, Inc., McLean, Virginia, January
1973.
9029 "Cost Analyses of Model Mines for Strip Mining of
Coal in the United States," BOM Information Circular
IC 8535, USDI, 1972.
9030 "Annual Summary of Disabling Work Injuries in the
Petroleum Industry for 1971," API Washington, D.C.,
1972.
9031 Prine, Charles H., John J. Schanz, Jr., and Richard
K. Doran, "Profile of Development of an Oil Shale
Industry in Colorado," Working Paper #2, University of
Denver Research Institute, February 1973.
9032 Obert, Edward F., Internal Combustion Engines, Inter-
national Textbook Company, Scranton, Pennsylvania,
November 1956.
9033 Personal Communication with Mr. F. D. Dietiker, Letter
dated 12/13/73, Barber-Green Company, Aurora, Illinois.
9034 Rice, R.A., "System Energy as a Factor in Considering
Future Transportation," ASME Paper 70-WA/Ener 8, 1971.
9035 "Energy Research Needs," Resources for the Future, Inc.,
Prepared for the National Science Foundation, Contract
NSF-C644, October 1971.
IX-10
�
9036 "Cost of Process Equipment," Chemical Engineering,
McGraw-Hill, March 16, 1964.
9037 Nelson, W.L., "Latest Research Indexes and Pro-
ductivities," Oil and Gas Journal, January 1974.
9038 Hydrocarbon Processing, Volume 51, No. 10, October
1972, Gulf Publishing Company, Houston, Texas,
pp. 97-99.
9039 Hydrocarbon Processing, Volume 51, No. 4, April 1972,
Gulf Publishing Company, Houston, Texas, pp. 102-106.
9040 "Petroleum Refining Guidelines and Technical
Documentation," Office of Permit Programs, EPA,
Washington, D.C., March 7, 1973.
9041 Fryling, G.R., Combustion Engineering, The Riverside
Press, Cambridge, Massachusetts, 1966, 19-6.
IX-11
�
REFERENCES FOR FLUIDIZED BED COMBUSTION
9200 Keairns, D.L., "Design of a Pressurized Fluidized Bed
Boiler Power Plant," AICHE Symposium Series, NO. 126,
Vol. 68, 1972.
9201 Aynsley, Eric and Meryl R. Jackson, "Industrial Waste
Studies-Steam Generating Plants," an unpublished study
in draft form prepared for The Environmental Protection
Agency, Water Quality Office, May 1971.
9203 Archer, D.H., "Evaluation of the Fluidized Bed
Combustion Process, Vol. III, " Westinghouse Research
Laboratories, Nov. 1971.
9205 Personal communication from Mr. P. Turner, Environmental
Protection Agency, Durham, North Carolina, January 1974.
9206 Hammons, G.A., et al., "Studies of NOx and SOx Control
Techniques in a Regenerative Limestone Fluidized Bed
Coal Combustion process," Esso Research and Eng. Co.,
Interim Report to Division of Process Control Eng.,
Office of Air Programs, EPA, for period January 1, 1971-
June 1, 1971.
9207 "Evaluation of the Fluidized Bed Combustioin Process.
Vol. I Summary Report," Submitted to Office of Air
Programs, EPA, by Westinghouse Research Labs, Pittsburgh,
Pennsylvania, for period November 15, 1969-November 15,
1971.
9208 "Economic Indicators," Chemical Engineering, Vol. 81,
No. 1, January 7, 1974, P. 162.
9209 "Possible Impact of Costs of Selected Pollution Control
Equipment on the Electric Utility Industry and Certain
Power Intensive Consumer Industries," NERA, 1972.
9210 "Development of Coal Fired Fluidized Bed Boilers. Final
Report," Vol. II, Research and Development Report No.
36, USDOI, Office of Coal Research, February 1971-
February 1972.
9211 Demski, R.J., et al., "Final Report. Bureau of Mines
Test of Fluidized-Bed Combustor of Pope, Evans and
Robbins," USDOI, Pittsburgh Energy Research Center,
Pittsburgh, Pennsylvania, March 1973.
IX-12
�
9212 "Fluidized Bed Boiler Cuts Pollutants," Elec. World,
January 15, 1973.''..
9'213 "Proposed Multi-Cell Fluidized Bed.Bo.i.ler.at
Rivesville, West Virginia," Draft Environmental State-
ment prepared by Office of Coal Research, DOI, March
1973.
9214 Personal communication from Pope, Evans and Robbins Co.,
Alexandria, Virginia, January 1974.
9215 Handbook of Chemistry 'and Physics,.42nd Edition, Chemical
Rubber Publishing Co., Cleveland, Ohio, 19.604
9216 Adams, L.M.., et al., "Reclamation of.Acidic Coal-Mine
Spoil With Flyash," R17504, USDOI, April 1971.
9217 Baumeister, S., Editor, Standard Handbook for Mechanical
Engineers, 7th Edition, McGraw-HT-31 Book Co.,, New York,
1967.
9218 Personal communication.from G. Weth, office of Coal
Research, Washington, D.C., March 1974.
9219 Bagnulo, A.H., et al. "Final Report, Volume 1,
Development of Coal-Fired Fluidize -d Bed Boilers,
Prepared for Office of Coal Rese 'arch, DOI, Washingtong
D.C., June 1965-February 1970.
9220 Engineering News Record, Vol. 188, No. 26, June 29,. 1972.'
9221 U.S. Environmental Protection Agency, "Development
Document for Proposed Effluent Limitations Guidelines
and New Source Performance Standards for the Steam
.,Electric Power Generating Point Source category,"
EPA 440/1-73/029, March 1974.
9222 council on Environmental Quality, "Energy,a.nd the
Environment-Electric.Power," U.S. Government Printing
office, August 1973.
IX-13
�
FINED COAL
REFERENCES FOR SOLVENT RE
9300 ##Economic Evaluation of a Process to Produce Ashless,
Low Sulfur Fuel from Coal," R&D No. 53, Interim
Report No. 1, Office of Coal R6search, June 1970.
9301 Seelye., E.E., "Design, Data Book for Civil Engineers,"
Vol. I, John Wiley and Son, Inc., New York 1960.
9302 "cost Of Clean Water," Volume III, Indust;rial Waste
Profile No. 5, Petroleum Refinin' USDI, November
9!
1@67.
9303 "Compilation of Air Pollutant Emission Factors,"
USEPA, Research Triangle Park, North Carolina,
February 1972.
9.304 Wurm, Hans*J.., "Treatment of Phenolic Waste,"
@presented at 23kd Industrial Waste.Conf.erence,
Part Two, Purdue University, 1968.
9305 Gas Engineers Handbook, Industrial Press, Inc.,
New York,-New York,,1969.
9306 "Hydrogen Plants," The Oil and Gas Journal, Vol. 69
No.. 25, June .21, 1971.
9,307 Nelson, [email protected]., "Guide to Refinery Operating Cost,",
The Petroleum Publishing Company, Tulsa, Oklahoma,
.1970.
93 0 8 Bryant, H.S., ",Environment," The Oil and,Gas
Journal, March 2:6, 1973.-
.93.09 "Gases, Solids, Liquids," Power Magazine, June 1971.
Perry, R.H., Cecil H. Chelton, Chemical-Engineers
Handbook, Fifth Edition,.McGraw_-_H=i 'Book Companyt
New-York, 1973.
9311 Klett, Robert, "Treat 'Sour,Water for Profit,
Hydrocarbon Processing, October 1972.
9312 Pfleid er, E.P., Surface Mining, American Society
of Mining, Metallurgical, and Petroleum Engineers,
Inc., New York, 1968, Reprinted 1.9.72, Maple..Prbss,
York, Pa.
ix-14
�
9313 Environmental Studies Institute, Carnegie-Mellon
Institute, Sub-Contract No. 7, Pittsburgh and Midway
Coal Mining Co., "Solvent Refined Coal," November 1,
1973.
9314 Minerals Yearbook-1969, USDI, Bureau of Mines, 1971.
9315 Westerstrom, Leonard, US Bureau of Mines, Personal
Communication, February 1973.
9316 Bureau of Mines, "Cost Analysis of Model Mines for
Strip Mining of Coal in US," USDI, IC8535, 1972.
9317 Carnes, Billy A., D.L. Ford, Sidney O. Brady,
"Treatment of Refinery Wastewaters for Reuse,"
Paper presented at National Conference for Complete
Water Reuse, AICHE, April 23-27, 1973.
9318 "FPC National Gas Survey-Synthetic Gas-Coal Section,"
April 1973.
9319 "Take Sulfur out of Waste Gases," Hydrocarbon
Processing, October 1972.
9320 Glover, T.O., M.E. Hinkle, and H.L. Riley,
"Unit Train Transportation of Coal," USDI, Bur. of
Mines, IC 8444, 1970.
9321 "Statistical Abstract of the US-1972," Bureau of
Census, Washington D.C., 1972.
9322 "Accident Bulletin No. 140, Summary and Analysis of
Accidents on Railroads in the US-1971," DOT,
Federal RR Admin., Washington D.C. 1972.
9323 "Bur of Accounts, Railroads, Trans. Statistics in
The U.S.," 1971 ICC, 1972.
9324 "Mineral Industry Surveys, Coal-Bituminous and
Lignite in 1971," USDI Bur. of Mines, September
1972.
9325 Unpublished US Coast Guard data obtained from John
Milton, USCG.
9326 "Bituminous Coal Facts, 1968," National Coal
Association, 1968.
IX-15
�
9327 Bur of Accou nts, "Carriers@by Water, Trans.
Statistics in the U.S.," 1971, ICC, 1972.
9328, Fulkerson, F.B., "Transportation-of Mineral
Composites on Inland Waterways of SoUth-Central
States," USDI,@Bur@. of Mines., IC 8431, 1969.
9329 Aynsley j, Eric, and Meryl R. Jackson, "Industrial'
Waste Studies-Steam Generating Plants," An
unpublished study in draft form prepared for the
'Environmental Protection Agency, Water Quality
Office, May@_1971.
9330 Olmstead, Leonard M., "17th:Arinual Steam Station.
Cost Survey," Electrical World, November 1, 1971.
9331 "National Safety CouncilY Accident Facts-1971
Edition,." N.S.C., Chicago, 1971...
.9332 'Office of"'Science.and Technology, Energy Policy
Staff, "Considerations Eff'ecting Steam Power
Plant Site'Selection," USGPO, Washington, D.C.,
1968.
9333 Delson, J4rome K. and Richard J. Frankel, "Residuals
Management in the Coal Energy Industry," A soon to
be 'Published study by Resources'for,the Future,
Inc., Washington, D.C.
9334 "Demonstration Plant, Clean Boiler Fuels from Coal,
Preliminary Design and Capital Cost Estimate, R and*
D Report No..82-Interim Report No. 1, Volume I, OCR,
USi)l,,Sept. 1973.
9335 "Summary of'National Transportation Statistics," DOT,
Washington D.C., 1972.
�
REFERENCES FOR COAL LIQUEFACTION
9400 "Engineering Evaluation and Review of Consol Synthetic
Fuel Process," Research and Development Report No. 70,
Office of Coal Research, Department of the Interior,
Washington, D.C.
9401 IoDemonstration Plant Clean. Boiler Fuels From Coal-Prelimi-
nary Design/Capital Cost Estimate," Research and Develop-
ment Report No. 82-Interim'Report N6.-1-Volume 1, office
of Coal Research, Department of the-Interiol,r, Washington,
D.C.,
9402 Con trol of Air Pollution From Fossi 1 Fuel.-Fired Steam
Generators Greater Than 250 Million Btu Per Hour Heat
Input," U.S. Environmental Protection Agency, Durham,
A North Carolina.
9403 Burchard, John K, et al,'"Some General -Economic Con.si-
derations of Flue Gas Scrubbing for Utilities," Control
Systems Division, Environmental Protection Agency,
..Research Triaiigle Park, North Carolina.
9404 "Final Environmental.Statement-Proposed Process' and Equip-
ment Revisions to the Synthetic Fuels Process Pilot Plant,
Cresap, West Virginia," office of Coal Research, Department
of the.Interior, Washington,.D.C.
9405' "Demonstration Plant Clean Boiler Fuels From Coal-Pre-
liminary Design/Capital Cost Estimate.," Research and
Development Report No. 82-Interim Report No. 1-Vol. II,
office of Coal Research, Department, of the Interior,.
Washington, D.C.,
9406 O'Hara, 'James (The,Ralph M. Pa rsons.Co.,'Los Angeles,
California),, Personal Communication, April 1974.
IX-17
�
APPENDIX A
LIST OF ABBREVIATIONS
A-1
�
APPENDIX A
LIST OF ABBREVIATIONS
Ash
A
AC Acre
A/C Air Conditioner
ALD Aldehydes
AMNT Amount
AV Average
BAAPCD San Francisco Bay Area Air
Pollution Control District
BADCT Best Available Demonstrated
Control Technology
BBL. Barrel(s)
BCF Billion Cubic Feet (Standard)
BOD Biological Oxygen Demand
BPH' Barrels per Hour
BPSD Barrels per Stream Day
BPY Bartels per Year
BTU, British Thermal Unit
BTUH BTU per Hour
B-T-X Benzene Toluene Xylene
C Cents
CO Carbon Monoxide-
CAP Capacity
CD Calendar Day
CF Cubic Feet
CNISCN Cyanide and Thiocyanates
CY Cubic Yard
D Day
DIST or DSTL Distillate
DOT Department of Transportation
DS Dissolved Solids
.DSCF Dry Standard Cubit Feet
DSCFM Dry Standard Cubic Feet per.
Minute
DWT Deadweight
E Equivalent
ELECT Electricity
EPA Environmental Protection Agency
ESP Electrostatic Precipitator
F Fahrenheit
FC Fixed Carbon
FCR Fixed Charge Rate'
FF and following pages . . .
FT Foot (Feet)
Fps. Feet Per Sejo*nd'
GAL Gallon
,GAS Natural Gas
@rGASO Gasoline.
GM Gram
.GPD Gallons per Day
A-2
�
GPM Gallons per Minute
G.k Grains
HEW U.S. Department of Health,
Education and Welfare
HP Horsepower
Hour
IN Inch
KW Kilowatt
KWH Kilowatt Hour (Electrical)
L Liter
LB Pound
LF Load Factor
LIRR Long Island Railroad
LNG Liquefied.Natural Gas
LPG Liquefied Petroleum Gas
LT Long Ton
LTS Long Ton Sulfur,
M thousand
MCF Thousand Cubic Feet (Standard)
MEA Monoethanolomine
MF Moisture Free
MG Milligram
MGD Million Gallons per Day
MI Mile(s)
MIBK Methylisobutyl. Ketone
MM Million
MMCF Million Cubic Feet (Standard)
MMCFD Million Cubic Feet per Day
MOL Mole'
MPG Miles per Gallon
MW Megawatts
NDO Nondegradable Organics
NGL Natural Gas Liquids
NMI Nautical Miles
NO Number
ODS. Other Dissolved Solids
OST Office of.Science and Technology
P or PC Percent
PE Primary Efficiency
PHS Public Health Service
PLF Plant Load Factor
PM Passenger Mile
PPM Parts per Million
PSIA
Pounds per Square Inch Absolute
PSIG Pounds per Square Inch Gage
RESID or RF0 Residual fuel oil
ROM Run of Mine'
Sulfur
SCF Standard Cubic.Feet
SF Square Foot (Feet)
SGC Stack Gas Cleaning
SH Short
SI Square Inch(es
A-3
�
SNG Synthetic Natural'Gas
SRC Solvent Refined Coal',
S/S Suspended Solids
T Tons(s)
TDS Total Di.ssolved Solids
TM or TMI Ton Mile
TPD Tons per Day
TPY Tons per Year
.TS Total Solids (Dissolved + Suspended)
USDI U.S. Department of the Interior
VM Vehicle Mile-
VMA Volatile Matter
W or"WT Weight
WAL Weak Ammonia Liquor
YR Year
A@4
GPO 9.03-045
�
I
! 5710
�