EPA-600/2-76-172
June 1976
Environmental Protection Technology Series
FINE PARTICLE EMISSIONS
INFORMATION SYSTEM USER GUIDE
: i,.
Industrial Environmental Research Laboratory
Office of Research and Development
U,S. Environmental Protection Agency
^search Triangle Park/North Carolina 27711
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RESEARCH REPORTING SERIES
Research reports of the Office of Research and Development, U.S. Environmental
Protection Agency, have been grouped into five series. These five broad
categories were established to facilitate further development and application of
environmental technology. Elimination of traditional grouping was consciously
planned to foster technology transfer and a maximum interface in related fields.
The five series are:
1. Environmental Health Effects Research
2. Environmental Protection Technology
3. Ecological Research
4. Environmental Monitoring
5. Socioeconomic Environmental Studies
This report has been assigned to the ENVIRONMENTAL PROTECTION
TECHNOLOGY series. This series describes research performed to develop and
demonstrate instrumentation, equipment, and methodology to repair or prevent
environmental degradation from point and non-point sources of pollution. This
work provides the new or improved technology required for the control and
treatment of pollution sources to meet environmental quality standards.
EPA REVIEW NOTICE
This report has been reviewed by the U.S. Environmental
Protection Agency, and approved for publication. Approval
does not signify that the contents necessarily reflect the
views and policy of the Agency, nor does mention of trade
names or commercial products constitute endorsement or
recommendation for use.
This document is available to the public through the National Technical Informa-
tion Service, Springfield, Virginia 22161.
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EPA-600/2-76-172
June 1976
FINE PARTICLE
EMISSIONS INFORMATION SYSTEM
USER GUIDE
by
M. P. Schrag, A.K. Rao, G.S. McMahon,
and G. L. Johnson (EPA)
Midwest Research Institute
425 Volker Boulevard
Kansas City, Missouri 64110
Contract No. 68-02-12J24, Task 47
ROAPNo. 21BJV-023
Program Element No. 1AB012
EPA Task Officer: Gary L. Johnson
Industrial Environmental Research Laboratory
Office of Energy, Minerals, and Industry
Research Triangle Park, NC 27711
Prepared for
U.S. ENVIRONMENTAL PROTECTION AGENCY
Office of Research and Development
Washington, DC 20460
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PREFACE
This document was prepared for EPA/IERL-RTP under Contract No. 68-02-1324,
Task No. 47. The task officer was Mr. Gary L. Johnson.
The work was performed in the Environmental and Materials Sciences Divi-
sion of Midwest Research Institute. Dr. L. J. Shannon served as project
manager and Mr. M. P. Schrag, Head, Environmental Systems Section, was the
project leader.
This document was written by Mr. Schrag and Dr. A. K. Rao with assistance
from Mr. G. S. McMahon of MRI Systems, Inc., and the task officer.
Approved for:
MIDWEST RESEARCH INSTITUTE
L. J. \S
hannon, Director
Environmental and Materials
Sciences Division
December 23, 1976
ii
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CONTENTS
Page
List of Tables. ............. iv
List of Figures ........<> v
Section 1 Introduction. ......... UG-1.0-1
Section 2 Data Input Instructions UG-2.0-0
Section 3 Off-Line Request Procedures UG-3.0-0
Section 4 On-Line Request Procedures. ... UG-4.0-0
Section 5 Catalog of User Request Commands UG-5.0-0
Section 6 Appendix
6.1 Description of National Computer
Center UG-6.1-1
6.2 Description of SYSTEM 2000 UG-6.2-1
6.3 Standard Data Input Forms ...... UG-6.3-1
6.4 FPEIS Standard Report Output UG-6.4-1
6.5 FPEIS Data Base Structure UG-6.5-1
6.6 List of Key/Nonkey Data Ele-
ments UG-6.6-1
6.7 Test Series Numbers and Refer-
ences in the FPEIS. UG-6.7-1
iii
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LIST OF TABLES
Number Title Page
1.0-1 Conversion Factors UG-1.0-4
2.1-1 FPEIS Data Elements and Their Levels UG-2.1.2-3
2.1-2 The Data Input Form Structure UG-2.1.4-3
2.1-3 Data Elements Requiring Standard Nomenclature UG-2.1.8-2
2.1-4 Source Classification Codes . . UG-2.1.8-3
2.1-5 Two-Letter State Abbreviations UG-2.1.8-13
2.1-6 Control Device Description Nomenclature ......... UG-2.1.8-14
2.1-7 Device Category Key Words UG-2.1.8-15
2.1-8 Design Specification Type UG-2.1.8-16
2.1-9 Device Operating Parameter Type UG-2.1.8-18
2.1-10 Bioassay Test Type UG-2.1.8-19
2.1-11 SAROAD Particulate Pollutant Codes. ... UG-2.1.8-20
2.1-12 List of Chemical Analysis Codes UG-2.1.8-25
2.1-13 Standard Nomenclature for Measurement Equipment ..... UG-2.1.8-26
2.2-1 Abbreviations for Street Designators and for Words that
Appear Frequently in Place Names UG-2.2-4
iv
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LIST OF FIGURES
Number Title
2.1-1 Typical Source/Collector Combination UG-2.1.1-3
2.1-2 FPEIS Structure UG-2.1.2-2
2.1-3 Sampling Log for 10 Runs UG-2.1.3-3
2.1-4 Sample Completed Data Input Forms UG-2.1.4-4
2.2-1 FPEIS Standard Data Input Forms UG-2.2-5
2.3-1 UTM Grid Zones in the Contiguous United States. UG-2.3.1-3
2.3-2 Sample Completed A-Cards—Source Description UG-2.3.1-6
2.3-3 Sample Completed B-Cards—Test Series Remarks ...... UG-2.3.2-2
2.3-4 Sample Completed C01-C04 Cards—Control Device(s)
Characteristics UG-2.3.3-3
2.3-5 Sample Completed COS Cards—Control Device(s) Design
Parameters UG-2.3.3-5
2.3-6 Sample Completed D01-D04 Cards—Test Characteristics. . . UG-2.3.4-5
2.3-7 Sample Completed DOS Cards—Control Device(s)
Operating Parameters UG-2.3.4-6
2.3-8 Sample Completed D06-D20 Cards—Subseries Remarks .... UG-2.3.4-7
2.3-9 Sample Completed E-Card—Particulate Mass Train Results . UG-2.3.5-2
2.3-10 Sample Completed F-Card—Particulate Physical Properties. UG-2.3.6-2
2.3-11 Sample Completed G-Cards—Particulate Bioassay Data ... UG-2.3.7-2
2.3-12 Sample Completed H-Cards—Chemical Composition Data . . . UG-2.3.8-4
2.3-13 Sample Completed I-Cards—Measurement Particulars . « . . UG-2.3.9-4
2.3-14 Sample Completed J-Cards—Particulate Size Distribution
Data UG-2.3.10-5
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LIST OF FIGURES (Concluded)
Number Title Page
3.1-1 Sample FPEIS Data Submittal Acknowledgement Memo UG-3.1-3
3.1-2 Sample FPEIS Data Submittal Error Memo UG-3.1-4
3.2-1 System Request Command Form .... UG-3.2-3
vi
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UG-1.0-1
1.0 Introduction
The Fine Particle Emissions Information System (FPEIS) is a computerized
information system containing information on primary fine particle emis-
sions to the atmosphere from stationary point sources and evaluations of
control devices. The purpose of the system is to provide a centralized
source of fine particle measurement information and data for use by engi-
neers and scientists engaged in fine particle control technology develop-
ment.
Contents of the FPEIS include source test data with particle size distri-
butions; chemical, physical, and bioassay testing results from analyses
of particulate samplesj and design and performance data on any particle
control system applied. Also included are process descriptions of the
sources, and descriptions of the sampling equipment and techniques em-
ployed. These data and information items are classified and arranged so
as to ensure some compatibility with other EPA data bases, i.e., NEDS (the
Source Classification Codes)— and the SAROAD/SOTDAT chemical identifica-
2/
tion systems.—'
A uniform protocol for units and terminology has been developed along with
standard input forms and definition of each data element for the system.
The FPEIS uses metric units exclusively, although, for clarity, complete
I/ "Guide for Compiling a Comprehensive Emission Inventory," EPA No. APTD-
1135, NTIS No. PB 212-231, March 1973.
21 "SOTDAT Final Report," EPA No. 450/3-75-070, July 1975.
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UG-1.0-2
adherence to International System of Units (SI) protocol is not maintained^
A list of metric-to-English conversion factors is given in Table 1.0-1.
These standards and definitions will allow all data in the system to be
stored and retrieved on a common basis.
The FPEIS has been implemented at the EPA National Computer Center (NCC)
at Research Triangle Park, on the UNIVAC 1110 computer using SYSTEM 2000,
a flexible data base management system. SYSTEM 2000, developed by MRI Sys-
tems, Inc., of Austin, Texas (no relation to Midwest Research Institute),
will provide users with a virtually unlimited potential for data analysis.
Features of SYSTEM 2000 include sorting, comparing, and retrieving informa-
tion from the FPEIS in a variety of arrangements.
This document constitutes an extensive User Guide to the FPEIS. Detailed
instructions for encoding FPEIS data sets are presented, along with a copy
of the Standard FPEIS data input forms. Both Off-line and On-line Request
procedures for users are explained for direct computer request (for autho-
rized National Computer Center accounts) or for written request to the EPA
project officer. A catalog of pre-defined user request commands is presented
with instructions for its use. The Appendix includes descriptions of the
EPA National Computer Center, the generalized data base management system
used to implement the FPEIS, examples of input and output formats, and lists
of the structure and key data elements in the data base.
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UG-1.0-3
This User Guide is designed with discrete segments for major sections and
subsections. As modifications or additions to the system are made, this
User Guide will be updated as appropriate,
A companion FPEIS Reference Manual—' has been prepared which provides a
general discussion of the FPEIS. It is suggested that users of the FPEIS
read the Reference Manual prior to this document.
J3/ FPEIS Reference Manual, EPA-650/2-76-173, June 1976.
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UG-1.0-4
TABLE 1.0-1. CONVERSION FACTORS
Metric Units
kN/m2
ec
cm3
cm2
joules
kg/m3
km
kW
m3
m3/sec
m
m/sec
mg
m
m2
tons (metric)
W
cm
Multiply by
3.377
(C x 9/5) + 32
6.102 x 10"2
1.550 x 10'1
9.488 x 10 ~4
6.243 x 10"2
6.214 x KT1
3.414 x 103
3.531 x 101
3.531 x 101
3.281
3.281
1.5432 x 10"2
3.937 x 10
1.076 x loj
x
2.205 x 10
3.414
2.54
To Obtain English
Equivalent
in. Hg (at 60° F)
°F
in3
in2
Btu
lb/ft3
miles (statute)
Btu/hr
ft3
ft3/sec
ft
ft/ sec
grains
in.
sq ft
pounds
Btu/hr
in.
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UG-2.0-0
SECTION 2
DATA INPUT INSTRUCTIONS
CONTENTS
S
Number Item Page
List of Tables UG-2.0-2
List of Figures . UG-2.0-3
2.0 Introduction. UG-2.0-4
2.1 Encoding Criteria UG-2.1-1
2.1.1 Objectives and Scope of the FPEIS UG-2.1.1-1
2.1.2 Data Element Grouping and Organization UG-2.1.2-1
2.1.3 Designation Criteria for Test Series, Test
Subseries, and Test Run ..... UG-2.1.3-1
2.1.4 Data Input Form Structure UG-2.1.4-1
2.1.5 Labor Saving Features . UG-2.1.5-1
2.1.6 Standard Nomenclature and Units .... UG-2.1.6-1
2.1.7 Data Preparation. UG-2.1.7-1
2.1.8 Tables of Standard Nomenclature UG-2.1.8-1
2.2 General Instructions for FPEIS Data Input
Forms UG-2.2-1
2.3 Encoding Instructions
2.3.1 Section A - Source Description UG-2.3.1-1
2.3.2 Section B - Test Series Remarks UG-2.3.2-1
2.3.3 Section C - Control Device(s) Characteris-
tics UG-2.3.3-1
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UG-2.0-1
CONTENTS (concluded)
Number Page
2.3.4 Section D - Test Characteristics UG-2.3.4-1
2.3.5 Section E - Mass Train Results UG-2.3.5-1
2.3.6 Section F - Particulate Physical Properties . . . UG-2.3.6-1
2.3.7 Section G - Particulate Bioassay Data UG-2.3.7-1
2.3.8 Section H - Chemical Composition Data UG-2.3.8-1
2.3.9 Section I - Measurement Particulars ....... UG-2.3.9-1
2.3.10 Section J - Particulate Size Distribution
Data UG-2.3.10-1
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UG-2.0-2
SECTION 2.0
LIST OF TABLES
Number Title Page
2.1-1 FPEIS Data Elements and Their Levels UG-2.1.2-3
2.1-2 The Data Input Form Structure .... •.... UG-2.1.4-3
2.1-3 Data Elements Requiring Standard Nomenclature UG-2.1.8-2
2.1-4 Source Classification Codes „ UG-2.1.8-3
2.1-5 Two-Letter State Abbreviations UG-2.1.8-13
2.1-6 Control Device Description Nomenclature ... UG-2.1.8-14
2.1-7 Device Category Key Words UG-2.1.8-15
2.1-8 Design Specification Type ... UG-2.1.8-16
2.1-9 Device Operating Parameter Type UG-2.1.8-18
2.1-10 Bioassay Test Type UG-201.8-19
2.1-11 SAROAD Particulate Pollutant Codes UG-2.1.8-20
2.1-12 List of Chemical Analysis Codes UG-2.1.8-25
2.1-13 Standard Nomenclature for Measurement Equipment UG-2.1.8-26
2.2-1 Abbreviations for Street Designators and for Words
that Appear Frequently in Place Names UG-2.2-4
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UG-2.0-3
SECTION 2
LIST OF FIGURES
Number T itle Page
2.1-1 Typical Source/Collector Combination UG-2.1.1-3
2.1-2 FPEIS Structure UG-2.1.2-2
2.1-3 Sampling Log for 10 Runs UG-2.1.3-3
2.1-4 Sample Completed Data Input Forms .... UG-2.1.4-4
2.2-1 FPEIS Standard Data Input Forms UG-2.2-5
2.3-1 UTM Grid Zones in the Contiguous United States UG-2.3.1-3
2.3-2 Sample Completed A-Cards—Source Description. ...... UG-2.3.1-6
2.3-3 Sample Completed B-Cards—Test Series Remarks UG-2.3.2-2
2.3-4 Sample Completed C01-C04 Cards—Control Device(s)
Characteristics UG-2.3.3-3
2.3-5 Sample Completed 005 Cards—Control Device(s)
Design Parameters . ........ UG-2.3.3-5
2.3-6 Sample Completed D01-D04 Cards—Test Characteristics. . . UG-2.3.4-5
2.3-7 Sample Completed DOS Cards—Control Device(s)
Operating Parameters. ... .... UG-2.3.4-6
2.3-8 Sample Completed D06-D20 Cards—Subseries Remarks .... UG-2.3.4-7
2.3-9 Sample Completed E-Card—Particulate Mass Train Results . UG-2.3.5-2
2.3-10 Sample Completed F-Card—Particulate Physical Properties. UG-2.3.6-2
2.3-11 Sample Completed G-Cards—Particulate Bioassay Data ... UG-2.3.7-2
2.3-12 Sample Completed H-Cards—Chemical Composition Data ... UG-2.3.8-4
2.3-13 Sample Completed I-Cards—Measurement Particulars .... UG-2.3.9-4
2.3-14 Sample Completed J-Cards—Particulate Size Distribution
Data UG-2.3.10-5
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UG-2.0-4
2.0 Introduction
This section on data input instructions is divided into three principal
subsections. The first subsection addresses the encoding criteria for the
FPEIS; that is, why certain data must be encoded in a specific way. Data
requiring the use of standard nomenclature are given along with tables of
allowable entries for those data elements. The standard FFEIS Data Input
Form is introduced and examples of encoding the form are given. The con-
cept of the FPEIS data base structure of series, subseries, and run levels
is discussed. To eliminate redundant data entry, several labor saving tech-
niques have been developed to aid the user, and these techniques are dis-
cussed here.
The second subsection provides general instructions for using the FPEIS
Data Input Forms which apply to all data collection activities.
The third subsection gives detailed, card-by-card encoding instructions
for each Data Input Form.
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UG-2.1-1
2.1 Encoding Criteria
This section provides a general discussion of the encoding criteria for
the FPEIS. An overview of the objectives and scope of the FPEIS, a de-
scription of the data element grouping and organization, and a discussion
of all standard nomenclature and engineering units employed are included.
A description of the FPEIS Data Input Form Structure with sample input,
labor saving features, and miscellaneous data preparation is also given.
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UG-2.1.1-1
2.1.1 Objectives and Scope of the FPEIS
A typical source/collector combination is shown in Figure 2.1-1. Some of
the variations to the typical situation shown may include several sources
combined, several control devices in a control system, systems where all
or only a part of the effluent is controlled, sampling which may be in situ
or etx situ, sampling with or without sample modification, etc.
The Fine Particle Emissions Information System attempts to characterize
the particulate pollutant (aerosol) at the inlet and outlet of a control
system by providing data on all the factors affecting its generation, modifi-
cation, sampling, measurement, and analysis. The FPEIS is designed to con-
tain: (a) characteristics of sources; (b) characteristics of control de-
vices; and (c) characteristics of particulates emitted by various source/
collector combinations. The data base may also contain:
. Test particulars;
. Particulate mass train data;
. Particulate physical, bioassay, and chemical properties;
. Measurement instrument/method; and
. Particle size distribution data.
The data base system is designed such that one can get information with
respect to:
. A specific test;
. A specific source;
. A specific control device;
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UG-2.1.1-2
« A specific measurement instrument or method; and
. All or a portion of the data.
The FPEIS can accommodate partial data. The number of parameters measured
in a test depends upon the objectives of the testing program. It is unlikely
that any source te'sts made will have all the data which the FPEIS is designed
to contain. For example, in a given testing program, all the tests may be
made at only the inlet or outlet, and the chemical analysis or bioassay
may or may not be conducted. It is likely that some of the control device
design and operating parameters may not be reported. Even if there is miss-
ing data, the available data will be of use and should be reported.
Data from sources or sites for which the company name, location, etc., are,
or should, remain confidential can also be accommodated. Arrangements for
such cases should be made with the FPEIS project officer (see Section 3.4).
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Source
Inlet
Slip Stream f—\
Inlet Sampling
Location
\\
I
Outlet
Control
Device(s)
Cutlet
Sampling
Location
I
To Measurement
Instrument/Method
To Measurement
I nstrument/Method
Figure 2.1-1. Typical Source/Collector Combination.
c;
o
I
OJ
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UG-2.1.2-1
201.2 Data Element Grouping and Organization
Presentation of the information described in Section 2.1-1 requires sev-
eral data elements. The definition grouping, and organization of these data
elements as well as the description of the FPEIS system are provided in de-
tail in the FPEIS Reference Manual (EPA-600/2-76-173). From an organizational
standpoint, the various data elements are grouped in one of three levels,
that is, the test series level, the subseries level, and the test run level.
These levels are shown in Figure 2.1-2. In this figure, one can see that
the FPEIS contains several test series, each of which contains one or more
test subseries, which in turn consist of one or more test runs. The data
which are to be contained at each level are shown in Table 2.1-1, FPEIS
Data Elements and Their Levels.
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FPEIS
Test Series
Level
Test Series 1
Test Series 2
Subseries
Level
Subseries 1
Subseries 2
Subseries 3
Subseries 1
Subseries 2
Run
Level
O
I
NJ
Figure 2.1-2. FPEIS Structure.
Ni
to
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TABLE 2.1-1. FPEIS DATA ELEMENTS AND THEIR LEVELS
UG-2.1.2-3
Test Series Level
A. Source Characteristics
Source category (SCC I)
Type of operation (SCC II)
Feed material class (SCC III)
Operating mode class (SCC IV)
Site and source name
Source address (street, city,
state, zip code)
UTM zone location and coordinates
Test series start and finish date
Tested by and reference
B. Test Series Remarks
C. Control Deviee(s) Characteristics
Generic device type •
Device class and category
Device commercial name
Manufacturer
Description
Design parameter type and value
Subseries Level
Run Level
D. Test Characteristics
Test date, start, and finish
time
Source operating mode
Source operating rate
Percent design capacity
Feed material and its composition
Sampling location and its descrip-
tion
Volume flow rate, velocity tempera-
ture and pressure
Percent isokinetic sampling
Orsat gas analysis and trace gas
Composition
Control Device(s) Operating Parameter
and Value Remarks
E. Particulate Mass Train Results
Front half and total mass concen-
tration
Mass train comments
F. Particulate Physical Properties
Density
Resistivity
Others
G. Bioassay Data
Bioassay test type
Test comments
H. Chemical Composition
Particle boundary diameters
Sizing instrument calibrated
or calculated
SAKOAD chemical and analysis
method ID
Concentration In filter/total
Concentration In Ranges 1 through 9
J.
Measurement particulars
Measurement instrument/method name
Size range lower and upper boundary
Collection surface
Dilution factor
Measurement start time and period
Sample flow race
Sample temperature, pressure, and
moisture content
Comments
Particulate Size Distribution
Particle diameter basis
(Aerodynamic or Stokes)
Boundary diameter
Concentration basis (mass or number)
•Concentration
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UG-2.1.3-1
2.1.3 Designation Criteria for Test Series, Test Subseries, and Test
Run
The designation of test series, subseries, and run are illustrated in the
following example.
The sampling log of a hypothetical coal-fired boiler test is shown in Figure
2.1-3. In this test, a Brinks impactor was used at the inlet and an Andersen
impactor, optical particle counter, and a diffusion battery/CNC combination
were used at the outlet for making particle size distribution measurements.
The boiler load was 120 MW in the morning, and 140 MW in the afternoon.
The control device operation was steady throughout the day. In the morning,
two runs were made with the Brinks impactor, one with the Andersen impactor,
one with the optical particle counter, and one with the diffusion battery/
CNC..A similar number of runs were made in the afternoon.
The designation of test series, test subseries, and test run is as follows.
Each individual measurement is designated as a test run—the whole set of
runs a test series. The group of consecutive runs taken at either the inlet
or the outlet of the control device, on a given test date, during the time
in which the source/control device operation has been reasonably steady,
is designated as test subseries. The premise behind the subseries designa-
tion is that the aerosol remains the same as long as the source and control
device(s) remain steady. Multiple instruments then can be used to cover
the wide range of particle size, or multiple runs can be made with a given
instrument. In the example described above (see Figure 2.1-3), the two
Brinks impactor runs made at the inlet in the morning are designated as
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UG-2.1.3-2
a subseries. The measurements made at the outlet with the Andersen sampler,
the optical particle counter, and the diffusion battery/condensation nuclei
counter in the morning are designated as another subseries« Similarly other
runs are grouped into different subseries.
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Test Date 12/04/73
Outlet
LLJ
_J
0.
1/1
Inlet
07
i i i i i I
Measurement
Instrument No. & Name
0900 1220
2 Andersen — £ y £ ^
Impactor 0840 1200
(Run 1) 0941 1231
- 3 Optical Particle — / /
Counter 0940 1230
(Run 2) 1100 1335
4 Diffusion Battery/ — £ T £ T
Condensation 1040 1315
Nuclei Counter (Run 3)
Y T
Subseries 2 Subseries 4
Subseries 1 Subseries 3
i JL
f } i \
0845 1050 1230 1315
Impactor 0830 1030 1215 1300
(Run 1) (Run 2)
1 1 1 1 1 1
00 0800 0900 1000 1100 1200 1300 14(
TIME, 24 -hour clock
Figure 2.1-3. Sampling Log for 10 Runs.
I
hO
UJ
I
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UG-2.1.4-1
2.1.4 Data Input Form Structure
The arrangement of data element groups on various data input forms is shown
in Table 2.1-1. The layout of the six data input forms is such that the
data elements least likely to change are on Form Nos. 1 and 2, and the most
likely to change are on Form No. 6j that is, the data input forms follow
the same hierarchical arrangement as shown in Figure 2.1-2.
The source description group which includes the name of the source test-
ing contractor and test report reference and the test series remarks are
contained on Form No. 1, and control device(s) description and design param-
eters are contained on Form No. 2. The data on Form Nos. 1 and 2 are at
test series level and do not change for a given set of tests on a given
source/collector combination.
The test characteristics, including the source and control device(s) op-
erating parameters, and particulate physical, biological and chemical anal-
yses results are on Form Nos. 3 through 5. These data are at the subseries
level and represent test runs performed for certain continuous time intervals
on a source/control device(s) combination operating at certain operating
conditions, or at a given location.
The measurement particulars, and the particle size distribution data are
contained on Form No. 6. These data are at the test run level. Because more
than one instrument/method may be used to make the size distribution measure-
ment, Form No. 6 is expected to be the most frequently used.
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UG-2.1.4-2
Coding of several runs and subseries of a test series will be clear by ob-
serving the data input form structure for test series described in Section
201.3. The data input form structure for the first two subseries of the
example test is shown in Table 2.1-2. Notice that only forms that are needed
are used. Figure 2.1-4 shows all the completed forms.
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UG-2.1.4-3
TABLE 2.1-2. THE DATA INPUT FORM STRUCTURE
Data Input
Form No. Data Coded
1 Test Series - Source description and test series remarks
2 control device description and design parameters.
3 Subseries 1 - Test characteristics, control device op-
4 erating parameters, mass train results, particle physi-
cal properties.
5 Particulate bioassay and chemical composition data.
6 Subseries 1, Run 1 (Brink impactor data).
6 Subseries 1, Run 2 (Brink impactor data).
3 Subseries 2 - Test characteristics, mass train results.
4
Form No. 5 is not used as there was no biological or chemi-
cal composition data.
6 Subseries 2, Run 1 (Andersen sampler).
6 Subseries 2, Run 2 (Optical particle counter).
6 Subseries 2, Run 3 (Diffusion battery/condensation nuclei
counter).
-------�
STATIONARY POINT SOURCE
Form I 12/76
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STATIONARY (POINT SOURCE
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STATIONARY POINT SOURCE
Form 4 12/76
DATA INPUT FORMS
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20
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23
24
25
26
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30
31
32
33
34
35
36
37
38
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41
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48
49
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Remarks In Text
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
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44
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48
49
50
51
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61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
-
80
E - PARTICULATE MASS TRAIN RESULTS
Test Series
No. '
1
2
3
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65
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67
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69
70
71
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73
74
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76
77
78
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F - PARTICULATE PHYSICAL PROPERTIES
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31
32
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35
36
37
38
39
40
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49
50
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Figure 2.1-4. Continued*
-------�
STATIONARY POINT SOURCE
FormS 12/76
G
- PARTICULATE
Test Series
No.
1
H
2
3
4
5
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
; DATA INiPUT FORMS
BIOASSAY DATA
Sub
Series
No.
6
- CHEMICAL
Test Series
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2
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Figure 2.1-4. Continued.
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FINE PARTICIPATE EMISSIONS INFORMATION SYSTEM
DATlA INPUT FORMS
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Form 6 12/76
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FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DAT!A INPUT FORMS
MEASUREMENT PARTICULARS
Test Seriet
No.
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Series
No.-
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2
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14
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21
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26
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28
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30
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27
28
29
30
31
32
33
14
33
36
37
38
39)40
Comments on the Measurement
16
17
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19
20
21
22
23
24
25
26
27
28
29
30
31
32
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34
35
36
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41
42
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41
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43
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45
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31
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33
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58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
J - PARTICULATE SIZE DISTRIBUTION DATA !
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No.
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Figure 2.1-4. Continued.
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Form 3 12/76
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Test Series
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DATA INlPUT FORMS
— Control Device Inlet or Outlet (I or
Test Sub Series
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14
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18
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20
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30
31
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33
34
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37
38
39
40
41
42
43
44
45
44
47
48
49
50
51
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40
41
42
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47
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32
33
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75
76
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78
79
80
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78
79
80
42
43
44
45
44
47
48
49
70
71
72
73
74
75
74
77
78
79
80
CONTROL DEVICE(S) OPERATING PARAMETERS
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18
19
20
21
22
23
24
25
24
27
28
29
30
31
32
33
34
31
34
37
38
39
40
41
42
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43
44
45
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Figure 2.1-4. Continued.
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STATIONARY POINT SOURCE
Form 4 12/76
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DATA INPUT FORMS
CONTROL DEVICE(S) OPERATING PARAMETERS (confd)
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No.
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2
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5
Sub
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No.
6
7
8
Run
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10
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26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
49
46
47
Form Completed by
Value *
48
49
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51
52
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*
Remarks in Text*
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
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38
39
40
41
42
43
44
45
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47
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50
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56
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59
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65
66
67
68
69
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70
—
71
72
73
74
75
76
77
78
79
80
—
E - PARTICULATE MASS TRAIN RESULTS
Test Series
No. "
1
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3
4
/
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Sub
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No.
6
7
8
£
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Mass Train Comments (Text)
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
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60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
F - PARTICULATE PHYSICAL PROPERTIES
Test Series
No.
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Series
No.
2
Run
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12
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13
1
14
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16
17
18
19
20
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21
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22
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24
25
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26
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Other Physical Properties in Text •
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
c
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Need not be filled if the preceding subseries contains the tame data.
Figure 2.1-4. Continued.
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STATIONARY POINT SOURCE
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INPUT FORMS
MEASUREMENT PARTICULARS
Test Series
No.
1
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No.-
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Run
No.
10
/
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16
17
18
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Upper
21
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23
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26
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27
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28
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26
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55
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58
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59
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60
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Form 6 12/76
Form Completed by
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Temp.
61
62
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63
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64
4
Press .
65
66
67
7
68
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69
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% H2O
70
71
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40
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Comments on the Measurement
16
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Diameter (1 or 0)
24
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26
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Need not be filled if the preceding subseries or run with this Instrument/method contains the same data.
Figure 2.1-4. Continued.
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STATIONARY POINT SOURCE
.Form 6 12/76
I -
MEASUREMENT PARTICULARS
Test Series
No.
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No.
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DATlA INPUT FORMS
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14
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14
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21
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24
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44
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Period **
50
51
52
53
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34
Aerosol
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55
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57
58
7
59
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40
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Form Completed by
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41
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45
44
47
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70
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74
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74
77
78
79
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80
Collection Surface/Substrate and its Specifications
24
27
329
Comments on the Measurement
14
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25
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(.
24
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*
27
4
2
28
,
f
30
31
32
33
34
35
34
37
38
39 40
41
42
43
44
45
44
47
48
49
90
51
32
53
34
53
54
57
38
59
40
41
42
43
44
63
44
47
48
49
70
71
72
73
74
75
74
77
78
79
80
29
7
30
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f
31
R
E
32
&
S
33
34
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35
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34
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37
1
38
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39
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40
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42
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48
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31
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53
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58
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59
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41
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42
k
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47
49
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71
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72
73
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74
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77
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78
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79
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80
^
J - PARTICULATE SIZE DISTRIBUTION DATA i
Test Series
No. |
I
2
3
/
9
Sub
Series
No.
2
Run
No.
10
2
Card
No.
II
J
J
J
12
0
0
0
13
1.
2
3
Card,
No.
II
J
J
J
12
0
0
0
13
4
5
6
I"
14
3
r
14
}
f
15
P
r
15
Q
—Measurement Instrum
— Aerodynamic/Stoke
1*
17
18
19
/
20
•
•
•
21
S
22
23
—Measurement Instrume
— Mass/No. (1 or 0)
±
14
17
2
18
•
•
•
19
7
20
(,
21
22
+
23
2
ent/Method No.
s Diameter (1 or 0)
24
29
2d
27
y
28
•
•
•
29
Q
30
a
31
nt/Method No.
±
1*
25
4
26
•
•
•
27
o
28
C
29
2
30
+
31
3
32
33
34
35
34
•
•
•
37
*
38
«r
39
±
K:
33
/
34
•
•
•
35
o
34
7
37
7
38
»-
39
tf.
Particle
40
41
42
43
44
•
•
•
45
*
44
$
47
Moss/Nur
±
to
41
42
•
•
•
43
44
43
44
47
ize Data**
4*
4*
30
51
52
•
•
•
53
34
55
iber Data
±
«
49
50
•
•
•
51
52
33
34
55
i*
a
58
59
40
•
•
•
41
42
43
±
5*
57
58
•
•
•
59
40
41
42
43
C
64
45
44
47
49
•
•
•
49
70
71
±
«4
45
44
•
•
•
47
49
49
70
71
alib or Cole (1 or 0)-
n
n
74
75
74
•
••
•
77
78
79
±
n
73
74
•
•
•
75
76
77
78
79
1
80
/
8£
** Need not be filled if the preceding subseries or run with this Instrument/method contains the same data.
Figure 2.1-4. Continued.
o
i
rvi
-P-
I
-------�
STATIONARY POINT SOURCE
Form 6 12/76
I-
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATlA INPUT FORMS
MEASUREMENT PARTICULARS'
Test Series
No.
I
2
3
4
/
5
4>
Sub
Series
No.-
6
7
8
^
Run
No.
9
10
5
Card
No.
II
I
12
0
13
1
Card
No.
II
I
12
0
13
2
Card
No.
II
1
I
I
12
0
0
0
13
3
4
5
r
14
4
T4
t*
i
"
IS
M
li
— Measurement Instrument/Method No.
Measurement Instrument/Method Name
16
f.
17
fj
18
19
C
20
4
21
u
22
H
23
7
24
£
25
ff
*•
Measurement Size Range
Lower
16
17
t
18
,0
19
/
20
Upper
21
n
t
23
2
24
25
26
/
27
Jb
28
/
29
P
30
tf
31
.
32
33
e>
34 35
AT
36
7
37
£
38
*
39
y
40
41
42
43
44
45
Meas.
Start Time
46
/
47
0
48
4
49
^
Sampling
Period"
50
31
52
53
i
54
Aerosol
Flow Rate**
35
'36
57
38
A
39
60
Form Completed by
Gas Conditions at
Measurement Location
Temp.
61
62
63
64
Press .
65
66
67
68
69
%H2O
70
71
A
72
73
74
n
Dilution
Factor**
76
77
78
79
A
80
Collection Surface/Substrate and its Specifications
26
27
28
29
30
31
32
33
34)35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
31
32
53
34
35
56
57
38
59
60
61
62
63
64
63
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Comments on the Measurement
16
R
17
e
18
C
19
7
20
/J
21
A/
22
fl
23
f,
24
/
25
4
26
ft
27
28
c
29
/j
30
4
31
A/
32
A/
33
£
34 35
L
36
ft
37
L
38
7
39
7
40
6
41
ff
42
Y
43
44
45
46
47
48
49
30
31
52
33
34
55
56
57
38
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
eo
} - PARTICIPATE SIZE DISTRIBUTION DATA :
Test Series'
No.
1
1
?
Sub
Series
No.
2
Run
No.
3
Card
No.
II
J
J
J
12
0
0
0
13
1
2
3
Card,
No.
II
J
J
J
12
0
0
0
13
4
5
6
r
14
4
i
14
4
r
15
0
—Measurement Instrum
— Aerodynamic/Stoke
16
17
18
r
15
0
—Mass/
l«
17
2
18
•
•
•
19
20
•
•
•
21
1
22
}
23
2
emenl Instrumt
No. (1 or 0)
19
«>
20
21
22
4
23
ft
ent/Method No.
s Diameter (1 or 0)
24
is
26
27
28
•
•
•
29
/
30
P
31
3
ml/Method No.
±
?*
23
4
26
•
•
•
27
i
28
29
30
•f
31
32
33
34
35
36
•
•
•
37
0
38
6
39
*
±
»
33
5
34
•
•
•
35
6
36
37
38
4
39
Particle '
40
41
42
43
44
•
•
•
45
0
46
/
47
-------�
UG-2.1.5-1
2.1.5 Labor Saving Features
In developing the data input forms and the data processing programs, sev-
eral labor saving features have been introduced. These features reduce
time, labor, and cost on the part of the encoder, and eliminate keypunching
and verifying costs on the part of the data manager. However, misunderstand-
ing of these features may result in the entering of erroneous data. The labor
saving features are explained below. If the explanation is not clear, the
safe rule to remember is "if in doubt, fill it out."
The important labor saving feature is "fill in only new information." In
other words, there is no need to code duplicate information if it is not
different from previous runs or subseries. If there are missing data in-
stead of duplicate data, enter "NA" for alphanumeric data and "9" in every
column of numeric data. As an example, suppose the source operating mode
(Card D01, Columns 30 through 59) is the same from Subseries 10 through
20 in a test, then it is sufficient to code source operating mode for the
10th subseries. For Subseries 11 through 20, the information of the 10th
subseries will be copies. Note, however, if source operating mode for Sub-
series 10 through 14 and Subseries 16 through 20 is the same, but for Sub-
series 15 is different — it is necessary to code source operating mode for
Subseries 10, 15, and 16. For the rest of the subseries, information from
their preceding subseries will be copied. All the data elements which are
to be duplicated this way are marked with a star (*) on the input forms.
-------�
UG-2.1.5-2
The data elements on Data Input Form No. 6 marked with '•**'•, associated
with measurement instrument/method, are automatically duplicated by the
input EDIT computer program. For these data elements, only those data are
coded which are new or different from the data for the measurement instrument/
method in consideration.
The serial number for the control device operating parameter is also a labor
saving feature. If all but a few control device operating parameters change
from subseries to subseries, one need to code only the serial numbers of
the operating parameters that changed as given for the first subseries and
the new parameter values. From the serial number, the parameter description
will, be decoded. The parameters that did not vary need not be coded, as
the EDIT program automatically duplicates them for the new subseries. This
feature is quite useful for coding data of concurrent sampling of the inlet
and outlet. An example of this feature is shown in Figure 2.1-4,
-------�
UG-2.1.6-1
2.1.6 Standard Nomenclature and Units
Computerized information systems require that some standardization of data
be present in order for specific data selection to be made. Computers search
for and select data by comparing the selected value to a known value. When
alphanumeric characters are used, such as in the name of a control device,
the known value and the selected value must match exactly. For example,
if a search is made for the value "ESP", all entries in the data base whose
value is "ESP" will be selected; however, entries having the value "ELECTRO-
STATIC PRECIPITATOR" will not although it is technically correct. Insofar
as the computer is concerned, the two data are not equal and the selection
will fail.
To ensure that uniform selection criteria are possible, the FPEIS uses stan-
dard nomenclature for certain data elements. Whenever data from one of these
data elements is requested, it is essential that correct spelling be used
or the request will fail.
Data elements in the FPEIS data base which require the use of standard
nomenclature are given in Table 2.1-4. For these data elements, the encoder
must select terms from a specified list (or menu) to describe the data of
interest. While this list is expandable and will likely be expanded on
a continuing basis, the encoder should use only the list of names provided.
As is the case for any encoding of data, correct spelling is essential.
-------�
UG-2.1.6-2
The allowed data for data elements requiring standard nomenclature are given
in Tables 2.1-4 through 2,1-13. The specific use of each value is discussed
in detail in Section 2.3; however, it is appropriate here to discuss the
general criteria for using standard nomenclature on a group basis.
-------�
UG-2.1.6.1-1
2.1.6.1 Source Description
Of the five data elements shown in Table 2.1-3 requiring standard nomen-
clature, all but one (STATE) require use of the NEDS Source Classification
Codes (SCC). The allowed data values for each data element are given in
Table 2.1-4, NEDS Source Classification Codes. Note that the values to be
used are the word phrases and not the numeric code.
The reason for using the words rather than the numeric code for the SCC
data is twofold. First, the numering scheme within Source Categories is
not unique, that is the Source Category, Type of Operation, and Feed Mate-
rial Class are all interrelated depending upon the Source Category. For
example, the code 1-01-001-xx refers to EXTOOMB BOILER, ELECTRIC GENERATN,
and ANTHRACITE COALj however, if the Source Category is changed to INTERNL
COMBUSTION for ELECTRIC GENERATN, the code 2-01-001-xx means that DISTIL-
LATE OIL is the fuel. This means that unless burdensome qualification was
used, major groups of sources using the same type of fuel could not be iden-
tified. By using the wording for each SCC entry, unique values may be ob-
tained which will enable unqualified sorting of all data. This greatly in-
creases the flexibility and usability of the FPEIS data base.
The data element for STATE requires use of the standard U.S. Postal Service
two-letter abbreviation as given in Table 2.1-5.
-------�
UG-2.1.6.2-1
2.1.6.2 Control Device Characteristics and Design Parameters
Data elements pertaining to fine particle control devices have been grouped
to enable the user to describe the device in treat detail. In order to al-
low for maximum sorting and retrieval flexibility, some data elements that
describe the device have been assigned standard nomenclature. These data
elements are: Device Category, Device Class, and Generic Device Type. The
allowed data for these Device Class and Generic Device Type are given in
Table 2.1-6.
The Device Category data element allows descriptive words to be encoded
as a phrase or string of words to characterize the device. The key words
allowed are given in Table 2.1-7.
/
Specific allowable DESIGN SPECIFICATION TYPE nomenclature is given in Table
2.1-8 along the units to be used to express the value. This list is designed
to be the minimum information list for each device type given. The user
may add more specifications and values if he so chooses up to a maximum
of 20 per device.
-------�
UG-2.1.6.3-1
2.1.6.3 Test Characteristics and Control Device Operating Parameters
The SAMPLING LOCATION data element is identified by its position relative
to the control device as either inlet or outlet. The allowed data to be
encoded are as follows:
I (for inlet)
0 (for outlet)
If the source has no control device applied, then an "I" should be encoded.
The FPEIS also has control device operating parameters and values in addi-
tion to the design specifications and values. Allowed data for the TYPICAL
OPERATING PARAMETER TYPE and the units in which the data values are to ex-
pressed are given in Table 2.1-9. As in the case of the design specifications,
this is a minimum list and the user may add more information up to a maximum
of 20 parameters.
-------�
UG-2.1.6.4-1
2.1.6.4 Particulate Bioassay Data
The results of biological analysis of the collected particulate sample are
given in the FPEIS using standard nomenclature for BIOASSAY TEST TYPEo The
allowed data for this data element are given in Table 2.1-10.
-------�
UG-2.1.6.5-1
2.1.6.5 Particulate Chemical Composition
At present, none of the chemical analyses techniques are _in situ and real-
time. Generally, airborne particulates are collected by means of an inertial
device such as cascade impactor and chemical analyses are performed on the
material collected on each stage. The FPEIS data base provides space for
entry of results of chemical analyses on collected particulate, if such
data are available.
In order to identify the chemical species present in the sample, the FPEIS
uses the identification codes developed for the SAEOAD system. The name
of each chemical compound or element in the SAROAD system and its identifi-
cation code are given in Table 2.1-11. Only these data may be used.
While the input protocol requires that the numeric code be encoded, the
FPEIS Standard Report Output will give the name of the chemical species
found (see Section 6.4).
At present, 22 general types of chemical analysis methods have been iden-
tified for the FPEIS. A standard one-letter alphabetic code will be used
to identify the chemical analysis method used. The allowed data are given
in Table 2.1-12.
As in the case with the SAROAD identification codes, the FPEIS Standard
Report Output will give the complete name of the analysis method and not
the alphabetic code.
-------�
UG-2.1.6.6-1
2.1.6.6 Measurement Particulars
The identification of the particulate measurement instrument or method name
requires the use of standard nomenclature if effective sorting or retrieval
of particle size distribution data are to be accomplished. In Table 2.1-13,
a list of standard names for measurement equipment is provided for seven
classes of equipment. Use only the data provide. Any additional commentary
may be given in the COMMENTS ON THE MEASUREMENT on the data form.
-------�
UG-2.1.6.7-1
2.1.6.7 Engineering Units
As stated previously, the FPEIS uses metric units exclusively. While every ,
attempt has been made to use SI (International System of Units) protocol
whenever possible, some data elements are expressed in the metric equiv-
alent of a more common English unit. The specific required units for each
data element is given in Section 2.3. This is consistent with EPA policy
regarding the use of metric units.
-------�
UG-2.1.7-1
2.1.7 Data Preparation
The FPEIS data as coded on the input forms shown in the Appendix (Section
6.3) require some processing before they can be stored in the data base.
This is necessary in order to re-format the data into SYSTEM 2000 loader
protocol.
Two computer programs, one in FORTRAN and one in COBOL, have been developed
to prepare the data for entry to SYSTEM 2000. The general procedure is as
follows:
Step Process
1 Filling missing cards with blank cards (Program 1)
2 Duplicate necessary information (Program 1)
3 Pre-edit: a. Check for card order (Program 1)
b. Calculation for particle size distributions
(Program 1)
c. Quality assurance check (Program 1)
4 Encode revised deck on magnetic tape
5 Final edit and re-check data fields and load into data
base (Program 2)
In Step 1, the missing cards, i.e., cards not completed at the time of en-
coding, will be replaced by blank cards within the data set. In Step 2,
wherever there is a need for duplicating information such as the sampling
location description or the measurement equipment description, it will be
duplicated by the EDIT program (Program 1). The editing process in Step
3 involves complete calculation of size distribution and total mass and
surface number concentrations.
-------�
UG-2.1.7-2
7 A ^
If the total mass concentration is not within the range of 10 to 10 g/m
2 10
or if the number concentration is not within the range of 10 to 10 par-
o
tides/cm , a keypunching or encoding error is suspected. If all data ap-
pear to be within tolerances set by the EDIT program during the pre-edit
phase, the data are copied to magnetic tape. After quality assurance proce-
dures have been completed, the data are entered into the FPEIS using the
LOADER program. The administrative procedures for submitting new data are
discussed in detail in Section 3.1
-------�
UG-2.1.8-1
2.1.8 Tables of Standard Nomenclature and Units
The following tables, discussed previously include the standard nomenclature
to be used for the FPEIS data base.
-------�
UG-2.1.8-2
TABLE 2.1-3. DATA ELEMENTS REQUIRING STANDARD NOMENCLATURE
Source Description;
Source category
Type of operation
Feed material class
Operating mode class
State
Control Device Characteristics and Design
Parameters;
Device category
Device class
Generic device type
Design specification type
Test Characteristics and Control Device
Operating Parameters;
Sampling location
Typical operating parameter type
Particulate Bioassay Data;
Bioassay test type
Particulate Chemical Composition;
SAROAD chemical ID
Analysis method
Measurement Particulars;
Measurement instrument/method name
-------�
UG-2.1.8-3
TABLE 2.1-4. SOURCE CLASSIFICATION CODES
Column I - Source Category
Column II - Type of Operation
Column III - Feed Material Class
Column IV - Operating Mode Class
-------�
TABLE 2.1-4.
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-4
SCC CATEGORY Nixes
II
III
IV
UNITS
EXTCOM3
EATCONB
EXTCOM8
EXTCOM8
EXTCOMB
EXTCOMB
EITCOMS
EATCOM6
EXTCONB
EXTCOMg
EXTCOM6
EXTCOMB
ExTCOMb
EXTCOMB
EXTCOM8
EXTCOMB
EXTC'JMS
BOILER
BOILER
BUILE>»
BOILED
dOlLEx
HOtLtR
dOILER
BOILEM
BOILER
80ILEU
SOlLEU
BOtLEM
90ILEU
BOILER
EXTC'JMB
EXTCOM8
EXTCOMH
EXTCOM6
BOILEU
HOUER
fO!LE»
BOILED
BOILER
BOILE4
EXTCOM&
EXTCOM8 BOILEM
EXTCOMB BOILER
FXTCOMB BOILER
801LEW
•JOILEP
dOlLE-(
BO!Lt«
HOILtH
401LE"
tATCOMB
KXTCOMb
F.XTCDMb
EXTC1M6
FXTCCM&
EXTC'JMS
EXTCOMfl
EXTC"«8
KXTC'JMB
E»TC'>MS
EXTCOXB
f xrcnMjj
EXTC"X6
EXTCOMB
EXTCUMB
EXTC'JMB 10ILER
EXTCOMB BOILER
HOlLE"
1UIL6-
EXTC'IMH
EXTCOM&
FXICOM6 rtOKEU
BOILED
30ILEK
80ILER
HOILEM
80ILER
BOILER
BOILER
80ILE*
aOILE'
HOILtrl
SOlLtH
dOILER
SOlLER
80UER
BOILER
BOILER
BOILER
EXTCOMB
EXTCOMB
tXTCOMB
EXTC')M8
EXTCOMB
EXTCOHB
EXTCOMB
FXTCUMB
EXTCOHB
EXTCOM9
EXTCONB
EXTCOMB
EXTCOHB
EXTC'JMB
EXTCOMB
EXTCONB
EXTCONB
EXTCOHB
EXTCOXB
EXTCOHB
EXTCOMB
EXTCOMb
EXTCOHB
FXTCOMS
ExTCOMb
EXTCOMB
tXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMS
EXTC'IMB
EXTC'JMb
EXTCOMB
EXTCOMB
EXTCOMB
tXTCOMS
»;«TCUM(j
MKOMB
tXTCQMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
txTC'IMM MOILE1*
EXTO1M& BOILEM
ExTClMB lOILEU
BOILER
90ILEH
HOILEH
TOILER
DOUEri
BOILEM
901LE-I
SOILtR
80ILEM
BOlLEH
SOILEH
bOILf
BOILEH
SENEX4TNUNTMM4CITE CO»L
IELECTHIC &t%EN«INi4NTMJ4CITE CO*L
lELECTxIC SENEHiTNl UNIMJICIIE COAL
lELECTaiC OtNE-ATNl JNTx-aC! TE COAL
liLECTRIC CENExATM ANTHRACITE COAL
IELECTRIC SENEXATNIANTxaACITE COAL
IELECTMIC bENEHATNIANTHHlCITE COAL
IELECTUIC GENE^ATNIBITUMINOUS COAL
IELECTMIC GEN£riATNIBITO»INOUS COAL
lELECTkK 'iENE"ATNIMlTU»tN()US COAL
IELECTMIC 5£NE»ATNIdITU«INOUS COAL
IELECTHIC GENEMATNIBITUMNOUS COAL
IELECTJIC (iENE^ATNlBiruHlNOUS C04L
IELECTUIC SENEkiTNIBITU'INOUS COAL
IELECTMIC uENE^ATNIBITuxINOUS COAL
IELECTUIC 1>ENE->ATNIB!TU»INOUS COAL
lELECI^IC <3ENE*4TNlHITu»INOUS COAL
IELECTUIC GfNEKATNIRITU-INOUS COAL
IELEC1U1C OENE>l>TNIrITENEU»TNH.IGN|TE
IELECTHIC GENE^ATNILIGNITE
lELECTutC ii£NEu»TNILlGN|Tt
IELECTUIC GENEuATNIi. IGNITE
IELECTUIC GfcMEUATNILIGMTE
IELECTUIC GENEUtTNILIGNITE
IELECTUIC GENEUATNILIGNITE
IELECTUIC bENEBATNIuESIOUAL OIL
lELECf-lC GtNEU4TN|uESI1UAL OIL
IELECTUIC
IELECT-IC
lELECTuiC OEME-4TNIOI5TILL4TE OIL
lELECT-IO .,t'.E-4rNIO!STlLL«TE OIL
lELECTuIC GENE>-lTNINATuu4L r.4S
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-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-5
i
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-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-6
SCC CATEGORY NAMES
•••••••••••*•••••*
11 in
UMTS
INOUSTRIAL PROCES i CHEMICAL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INOUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL HROCESICHEMICAL MFS
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PROCESICntMICAL «FS
INDUSTRIAL Phoctsi CHEMICAL MFG
INOUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PHOCESICHEMICAL NFS
INOUSTRIAL HMOCESICMEMICAL HFli
INDUSTRIAL P«OCESICH£NICAL MFG
INOUSTRIAL PROCESICHEMICAL MFG
INOUSTRIAL »HOCESICH£M(CAL MfG
INDUSTRIAL "RDCESICHEMICAL HFG
INOUSTRIAL PROCESICHEMICAL «FS
INOUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL UROCESICHEMICAL NFS
INDUSTRIAL PROCESICHEHICAL »'o
INOUSTRIAL UROCESICHEMICAL >F«
INDUSTRIAL PROCESICHEMICAL MfG
INDUSTRIAL "ROCESICHEMICAL Mfii
INDUSTRIAL PKOCLSICHEMICAL MFS
INDUSTRIAL PROCESICHEHICAL MFS
INDUSTRIAL 'ROCESICHEMICAL Mf»
INDUSTRIAL PaOCESI CHEMICAL MFG
INDUSTRIAL HMOCESICHEMICAL «n>
INDUSTRIAL PMOCESICHEMICAL MFG
INOUSTRIAL pwoctsiCHgwicAL MFG
INDUSTRIAL "HOCESICHEMICAL MFG
INOUSTHIAL HROCESICHENICAL M»S
INDUSTRIAL P««OCESICMENICAL NfG
INDUSTRIAL Raoct Si CHEMICAL »f<5
INOUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL xfcoctsi CHEMICAL "*u
INOUSTHlAL »»f>OCES ICH£MICAL MFt,
INOUSTKUL "MOCESIC-EMtCAL HFij
INDUSTRIAL ••••OCESICHE-ICAL HfG
INDUSTRIAL •"'OCEMCHEMICAL «'«
INDUSTRIAL "HOCKSICHEHICAL MF£
INDUSTRIAL PBQCESICHEHICAL "FG
INDUSTRIAL PHOCESICHEMICAL MfG
INOUSTRIAL PMOCESI CHEMICAL M»S
INDUSTRIAL MOCESI CHEMICAL MFG
INOUSTRIAL vROCESI CHEMICAL MFS
INDUSTRIAL BBOCESICMENIC»L HFG
INDUSTRIAL "HOCi a 1 CHEMICAL MFG
INDUSTRIAL **wOCESlCHf MICAL MFG
INDUSTRIAL "WOCESICHEMICAL MFG
INOUSTHlAL "ROCESICMfMlCiL Nf<»
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INOUSTRIAL PROCESI CHEMICAL MFG
INDUSTRIAL PROCESICHENICAL HFG
INDUSTRIAL PROCESICHEMICAL "F3
INOUSTBIAL ••ROCESICHEMICAL MFG
INDUSTRIAL PROCESICHEMICAL «»s
INDUSTRIAL P«OCESICH«MICAL M*G
INDUSTRIAL PROCES ICHtMlCAL MFS
INDUSTRIAL PROCESI CHEMICAL MFO
INDUSTRIAL KHOCESI CHEMICAL *r<*
INDUSTRIAL PROCtSICH£MICAL MFG
INOUSTRIAL PROCESICHEMICAL Mffe
INDUSTRIAL PROCESICHEMICAL MfG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PWOCESI CHEMICAL MFG
INDUSTRIAL PROCES ICHEMICAL wf«
INDUSTRIAL VROCESI CHEMICAL MF«
INDUSTRIAL PROCESICHEMICAL M»«
INDUSTRIAL PROCESICHEMICAL Mf«
INDUSTRIAL BBOCESICHFMICAL MFG
INDUSTRIAL R«OCE si CHEMICAL MfG
INDUSTRIAL PROCESI CHEMICAL MfG
INOUSTRIAL P«*OCESICH«MIC«L MFG
INDUSTRIAL MOCISICHEMICAL M»O
INDUSTRIAL MROCESICMEMICAL MFG
INOUSTRIAL PROCESI CHEMICAL MF«
INDUSTRIAL PROCESI CHEMICAL MFO
INDUSTRIAL PROCESICHEMtCAL MfG
INDUSTRIAL MROCESICMEMICAL HFG
INDUSTRIAL HBOCESICHEMICAL NF«
INDUSTRIAL PROCESI CHEMICAL MFS
INDUSTRIAL PROCESICHEMICAL HFS
INDUSTRIAL PROCESI CHEMICAL MFO
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL 1--OCESI CHEMICAL Mfs
INOUSTRIAL "OCESICHEMICAL HfG
INDUSTRIAL PROCESICHEMICAL MfG
INDUSTRIAL MMOCESICHEMICAL MfG
INDUSTRIAL PROCISICHEMICAL MFG
INDUSTRIAL PROCES (CHEMICAL MFG
INDUSTRIAL HROCESICH^MICAL MFG
INOUSTMlAL PROCESI CHEMICAL MFG
INOUSTRIAL PKOCESICHEMICAL MFG
INDUSTRIAL PROCES ICnEMUAL MfG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL VHOCESICNEMICAL MfG
INOUSTMIAL PKUCESI CHEMICAL MfG
INOUMTRIAL »HOCESICH»MICAL MfG
INDUSTRIAL "UUCESI CHEMICAL Mf*
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(EXPLOSIVeS-TNT |H*SO* REGtNEHATRI TONS PRODUCED
IEXPt.nSIVCS-TNT (RED «ATCB INCIN (TONS PROUUCED
IEXPLO$IV£S-TNT (OPEN HASTE BURN ITONS BUMMED
ItxPlOSIvES IOTHEB/NOT CLASIFOlTONS PRODUCED
(HYDROCHLORIC ACIOIBYPROOUCTV/OSCRueiTONS FINAL ACIO
1 HYDROCHLORIC ACIDI6YPROOUCT «/SC»U8 1 TONS ri.iAL ACID
IHYQROCHLOMtC ACIOIOTHER/NDT CLASIFDITONS FINAL ACIO
IHYOROFLUOUIC ACIO IROTPYHILN«/SC"U8R| TONS ACIO
IHVONUFLUCRIC ACIOIROT4YKILNI/OSCHUBITONS ACID
InYDROFLUORIC ACIOIGHlNO/ORY FLUOSPRITONS FLUORSPAR,
IHTOIOVLUURIC ACIOIOTHER/NOT CLASIFOlTONS ACIO
INITUIC ACIO lAHMONlAOIIUATNOLOITONS PUME ACIO PRODUCED
INITBIC ACID lAHMONlAOXIUATNNtKITONS PUME ACID PRODUCED
INITMIC ACIO INITACD CONCTR OLD! TONS POHE ACIO PRODUCED
INITBIC ACIO INITACD CUNCTR Nt.lTONi t>uw£ ACIO PRODUCED
(NITRIC ACID-.fA« IUNCONTWOLLED ITONS PUHi ACIO PRODUCED
INITBIC ACIO-VEA* I«/CATYL/COM«USTER|TONS PUME ACIO PRODUCED
INITBIC ACIO-STRNGIUNCONTkOLLCO 1 TONS PU>E ACID PRODUCED
INITBIC ACIO-STRNGK/AaSOUUEI'S ITONS PU»E ACIO PRODUCED
INITC.IC ACIO lOTnta/NOT CLASIFOlTONS PUHE ACIO PRODUCED
(PAINT MFC. (GENERAL ITONS PRODUCED
IPAlNT MFG (PIGMENT KILN ITONS PRODUCT
IPAIMF MfG (OTHER/NOT CLASFO ITONS PROflUCT
IVAUNtSH »FG (BOOTING OIL SfNL ITONS PRODUCED
IVABNISH HFG IOLEORESINOUS GENLITONS PRODUCED
IVAHNISM MfG IALATO RENEWAL ITONS PHOOUCEO
IVABstjH "FO IACNTLIC GENERAL ITONS PRODUCED
I«ABN|SM HfG IOTHfa/NOT CLASFO ITONS PBOOUCcO
IPHOS-ACIl) .tTPJOCIREACTOi-UNCONTLO ITONs PHOSPHATE ROCK
IPHOS-ACIO »eTPBOCiSTPsuM PQNO ITONS PHOSPHATE xocx
IXMOS-ACIO >CTPROCICONOENSB-UNCOkTLaiTONS PHOSPHATE ROCX
IPHOS-ACIO «£TC«OCIOTMJU/vOT CLAS'O ITONS PRODUCED
IPHOi-ACIO THERMAL IStNEBAt. ITONS PHOSPHONOUS 8u*NtO
KMQS-ACtu T-£SHALlOTHta/»OT CLASFD ITONS PROUUCEO
(PLASTICS IPVC-GENERAL ITONS PRODUCED
(PLASTICS IPOLYPROO-4ENERAL ITONS PRCUUCEO
(PLASTICS ISAKf LITE-SENEGAL 1 TONS PRODUCT
IMLASTICS IOTHER/NOT CLASFO ITONS PROOUCe.0
I'HTHALIC AMHYOHIOIUNCONTfcOLLcD-ENTAOItNC-<>ENRL ITONS PRODUCT
ISTNT-ETIC RUBBER IOI«ETHHIPTN£ UENLITONS PRODUCT
ISYNT-fTIC RUHBER IPENTANf-GE>t£BAL ITONS PRODUCT
ISYNT-FTIC RUHBEM IETHANENI TV ILE-GEN ITONS PRODUCT
IXYNTHFTIC RUBBER IACMYLONITRILE-GENITONS PROUUCT
(SYNTHETIC BU88EH IACR.OLEIN-GENEHAL (TONS PRODUCT
ISYNT-'TIC kuHSEU IAUTO TIRES GENEBL ITONS PRODUCT
(SYNTHETIC RUR8EH IOTHER/NOT CLASFO ITONS PRODUCT
IFERTILIZ AHONNITRIPRILTlR-NEUTRLIZRITONS RKOOUCEO
IFfRTILl? AHONNITBIPHlLLINU T0<£« ITONS PROUUCEO
IFIRTILI7 AMONNITRIPMlLTkM-ORTCOOLXSITONS PRODUCED
IFERTILl/ AMONN|1R|GiIEUTLI2MITONS PRUUUCCO
IFERTILIZ AMO^NITMIGWANULATOR ITONS PRODUCED
IFERTKIZ AMO«m|TRiaHAMULAT-0>'YCu
-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2. 1.8-7
SCC CATESOBT NA-ES
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTStAL
I NOUS TB I.,.
INDUSTRIAL
lNOub!HI»L
INDUSTRIAL
INOUSTHUl.
INDUSTRIAL
INDUSTRIAL
INOUSTHIAL
INDUSTRIAL
INOUSTWlAL
INDUSTRIAL
INOUSTHIAL
INCuSTRlAL
INDUSTRIAL
INDUSTRIAL
INOUSTDlAL
INDUSTRIAL
INOU9IRIAL
INDUSTRIAL
INOUSTKIAL
INOUSTHIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHUL
|NOUSTk|AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHIAL
It
PRQCESICHEHICAL HFO
PROCESICMEXICAL XFG
PBOCESICl-£XlC«L MFG
xRoctsiCHtxtciL "f
JBOCtSlCcfcMlCAL »FQ
UMOCESICKXtCAL xFG
*MocESiCHfMicAL HFG
tBOCtilChfHICiL MFG
BHgClSICHEMlCAL NFO
PROCESIC»£x|CAL x»5
*NOCE5IChtMlCAL MFG
»BOCeSIC«EMICAL NFG
HHOCESICHJMICAL XFG
«-80CE5ICc£i4lc»c MfQ
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oaoCESICne-ICil. »«G
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i>ROCESIC»E>*ICiL »'5
fROCESlCHe»[C»--UCt5lCc£«lC«L
IPIOxf NT-INOHGAN
(PI6-- -.T-INOKOiN
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ISOOIUM 8ICAB8
ILITMIUH xrORU' IDE I GENERAL
IfERTlLl/ER U'EA (GENERAL
IAO"ESIVES IGCNL/COHPNO UNION I TONS PHOOUCT
ItCETATE FLAKE IOT»CR/sOT CLASFO ITONS PHUOUCr
nCEinnE ioT»ex/NOT CLASFO ITONS pauouCT •
KALEIC ANNTURIOE I GEN£SAL/OTMgR ITONS WHUOUCT
IPOLVINL PfRiLIOONiaeNERAL/oTxtiR .ITONS PRUOUCT
ISULFQNIC ACIO/ATSI GENEXAL/OT^ER ITONS PMO»UCT
LAST' GAS FLARES IOTH£*/NOT CLASIFOl'ILCION CUBIC FEET 8URNEO
IUT«£a/NOT CLASIFOl SPECIFr IN xEtiAUK I TONS PRODUCT
I TONS PDOOUCT
ITONS PRODUCT
ITONS PRODUCT
I TONS VROOuCT
ITONS PUOOUCT
ITONS PROUUCT
ITONS PROI1UCT
'>IALIALFALFA OEHTOttATN I GENERAL I TONS ME»L P«(lOUCZO
t-WOCtiSlFOOO/AuUICULTUtALIALFALFA OEHVOHATNlOTNEH/NOT CLASFO ITONS PHOOUCT
»<>ocESiFuoo/AaaicuLTUBALicoFFff HOASTINA
•»HOCESIFOOU/»li»lCULTU'»ALlCnFF«f UUASHNO
»«OCESlPuOO/AiiH[CULTu->aocESiFoi}0/A(i>i(cuLTu»en/kOT CLASFO i TUNS PKODUCT
ISBUAT OKIE- I 'ONS liMttN OtANS
IUNLOAOINO FAN i M»L£S CUTTON
ICLtANCo IbALES CDTTON
ISTICK/nUHH «ACfNt IfJALl S CUTTON
IDTHED/NOT CLASFO loALts CllTTON
PflDCESIFOOO/AlHiICULTUNALIFEED/ftriAIN IEB»£L I S«|PINO/BECE IV IN«I TONS l,i(4lN »«OC{SSCO
PBOCES I 'OOG/ •'>•»e'NOI TON* SMAIN f«OCESS£0
V«OCESIFOOU/A(><"tOCESIFoQO/Al»«ICULTu«ALI*fE&/GR4'M CXTUrtlSf^PNa/HiCtlVNS (TONS GRAIN KROCESSEO
r-OCt3lFgnU/Aw«lCULTu«ALl'EEO/«iH»:N CNTHrt I T«ANSFc«/CON»tTNGI TONS MAIN MOCtSSEO
paocEsiFooo/An«icuLTUM»LiFEEo/aa«iN CNTRVCISCREENINS/CLEANMITONS GRAIN PROCESSED
pROCESiFooo/toRtcuLTut>ALirEEO/eRAiN CNTHreiowrtNG ITONS GHAIN PROCESSED
PAOCESlFoOO/AliRICULTURALlFEEtJ/GKAlN IOTHCK/NOT CLASIFOl TONS GdAlN PROCESSED
P«OCESIFOOO/AUHICULTUUALH>RAIN PROCESSING ICORN »CAL ITONS GRAIN WWOCESSEO
HROCESIFOOO/AGRICULTUHALIGRAIN PROCESSING I SOT 8EiN ITONS GRAIN PHOCESSEU
PeOCESIFOOO/AUAtCULTURALIOBAI* PROCESSING ISARLET/'XEATCLEANI TONS GRAIN PROCESSES
p«ocE3iFfiou/«GaicuLTua«i.i3BAi'. PROCESSING INILO CI.EAN£I< ITONS GRAIN BROCESSEO
peoCESIFooo/ASHICULTuaALIoaAI«. PROCESSING I8ARIEYFLOUW »(LL ITONS GRAIN PROCESSED
pRocEsirooo/AGRicuLTURALiGRAtN PROCESSINS I«ET co-~ »!LLINO ITONS OF PRODUCT
PROCESIFOOO/AiiutCULTUBALIGBAI* PROCESSING ImEAT FLDU« HILL I TONS PBbCUCT
»ROCtSIFoOO/A(>HICULTUflALinRA|>l PROCESSING IOTHER/NOT CLASFO ITONS PROCESSED
PBOCESIFOOO/AliBICULTUHALIFEED MANUFACTURE IBARLET FEED-GENL ITONS GRAIN PROCESSED
PROCESIFOOD/A>>MICULTUBALIFEEO MANUFACTURE IOTHER/NOT CLASFO ITONS RRocESato
fdOCESIFOOO/ASRICULTUHALIFEBMCNTATN-eEER I9KAIN HANDLING I TONS GRAIN PROCESSED
»ROCESlFOOO/AGRICULTURALIFERH(i«TATN-eEER IDRTlNO S»NT SHAlNlTflNS GRAIN PROCESSED
PROCES|FOOO/A<>aiCULTURALIFERHENTATION-eEERl BREHI'.G ITMOuSANUS OF GALLONS
>ROCESIFOOO/AG*ICULTURALlFERMtNTAT10N-e£ERIOTMER/NOT CLASFO IGALLONS 'ROOUCT
«-»ocisiFooo/»saicJi.ruMALi'f>— f,TiTioN-9t£aioTHt<»/NOT CLASFO ITONS GRAIN PI>OCESSED
»HOCESiFooo/«>i-iCu(.Tu-.»ui»ja«ft,T«TN-«H|s»TiGBAlN «ANOLIN« ITONS GRAIN PROCESSED
auOCtSIFOOO/AGH(CULTUHALIFERI*eNTATN-«l>tSKTIORTINO SPNT 9BAINITONS GRAIN "BOCESSEO
p«ocEsiFooo/»KULTUfl«LIFe»«tNTArN-.»tS«r|OTB£a/sOT CLASFO IflALLONS PHOOUCT
PdOCESlFOOO/lG»ICULTuaALlF£R»< -t»L ICOO«tBi-»»tS"FIS»ITONJ FIS- »tAL MOOUCEO
PROCESIFOOO/AGHICULTURALIFISH MCAL ICOO«EHS-STALE»IS»ITONS FIS- NC*L p*ooucto
KROCESIFUOD/AGHICULTUMALIFIS» N«AL IORIEBS • ITONS FISH SCHAP
PROCESIFOOO/AliAICULTU-tALIMSM MCAL IOTHEB/MOT CLASIFOITONS PHUCESSED
w»o«siFooo/Aii.»ieuLTu*ALi"f AT sxooiNa isfNtaAt. ITONS HEAT SMOKED
i»OCESlFoOO/»liMICULTU"ALI1TAOCX »FG (GENERAL ITONS STA'CH PHODUCU
vaOCKSIFOOO/ASalCULTURALISUSAk CANE IMQCESIGENCRAL ITONS SUGAR PRODUCED
a-»ocESiFooo/Ai>RicuLTuRALisuOA» CANE PROCES IOTHER/NOT CLASIFOITONS PROCESSED
PROCESIFOOO/AGRICULTURALISUGAa BEET PHOCESIOUTER ONLT ITONS HA. BESTS
pROCESiFooo/>SRlcuLTu»ALiSu6AH MEET PROCISI OTHER/NOT CLASIFOITONS RA> BEETS
PROCESIFOOO/A&RICULTUHALIPCANUT VMOCESSINQ I OIL/NOT CLASFU I TONS PBuOUCT
PBOCESIFOOO/AGHICULTU0ALIPEANUT PROCESS ING I OTHER/NOT CLASFO ITONS PROCESSED
P°OCESIFOOO/iuBICULTUUALIC«NO»/CONFECTNflT IOTHER/NOT CLASFO (TONS PRODUCT
PNOCESIFOOO/AUMICULTUXALI OAIRT punoucTS i»It* SWHAT.ORTEX ITONS PRuOUCT
i»>ocEsiFooo/A6RlcULTu«ALiOAit>r PRODUCTS IOTHEB/NOT CLASFO ITONS PRODUCT
P»OCESiFuou/A(iU|CULTUHALlOTHfc/«ioT CLASIFOI SPECIFY IN BE»AHKITONS PROCESSED
vaocESlFooO/»5rflcuLTua«LioTi<£u/NnT CLASIFOISPECIFV IN -e««H«i TONS HRUOUCEO
>*«1CESIPfl|MA4T Hf.TALS IALU»INU» OBf-MAUIICHUSHING/MANOLlNGlTONS OF OHE
-«0« SIBPIXAWT MCTALS ML aRE-€LECROREDN|PBE9A«E CELLS (TONS ALU-IWJ- POOOUCtO
IAL r-t-€L£C»o«EUNMoaiZbTO SnoE-a»o ITONS ALU«|NOOUC I OVEN CHARGING ITONS COAL CXAVOEO
IIN#UT)
PROCESIPRIHART METALS
PRDCESIPMIMAHf «tTALS
PROCESIPHIMABT
PBOCISIPOIMAKT
PNOCESlPHtMAW M(TALS
WBOCESIBH(M4>>T METALS
HRQCtSIPUIMAMT xfc TALS
-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-8
i
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
INOUSTKUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUS T»UL
INDUSTRIE
INDUSTRIAL
INOUSTBUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
SCC CATEGORY NA«€S
II MI
IV
PHOCESIPRINAWY
PBOCESIPRIMAHf
UROCESIPflMAWT
PBOCESlP«INAHY
MITALS
N£TALS
BROCESIPBIMAMV
»BOCESIPBINA»T
PBOCESIPNIMAwy
**UCtSIP-*|NAi>E OHYER I TONS
(FERROALLOY ILftKCABM C»-"E»C7BI TONS
IF'BBOALLOY IOTMEB/NOT CLASFO I TONS
IFEBALOY S£MCOVFNCIFE»OMA*GAN£SE I TONS
IFCRAI.OY COvO FNC ISENEHAL ITONS
ISLUUCTION IELECT AHC >/LANCElTCNS
ISTEfL PBOOuCTION IELECT ABC NOLiwCEI TONS
PB40UCTION lOTh£a/f,oT CLASFO I TONS
I TONS
I TONS
ITONS
I IKON PBQOUCTION
I|BON PHOUUCTION
I1BON BUOOUCTION
11 BON paoouCTtON
iidOM paooucTiON
I IKON PRODUCTION
IIBOh PHOUUCTION
I I BON auoOuCTION
UNITS
COAL CHARGED
COAL CHARGED
COAL CHARIiEO
COAL CHANGED
COAL CHANGED
COAL CHARGED
CONCENTRATED U»e
CONCENTRATED ONE
CONCENTRATED OWE
COhCENTBATEO ORE
CONCENTHATEO 0ȣ
UF n»E
CONCENTBATEB OHC
pMuouceo
PRODUCED
pRoouceo
paooucto
PBoOUCtO
PHuCESSED
VHnCESSEO
PNliCESStO
PBUOUCEO
UNOOuCEO
P800UCED
vauOuCcD
PMuOUCED
paouucso
UF OB£
PBOCESSED
HANDLED
SANO BAnEO
PRUOUCCO
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IOTH£-/NOT CLASFO
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTBUL
INOUSTHUL
INDUSTRIAL
INOUSTHIAL
INDUSTRIAL
INOUSTMUL
INOUSTUUL
INOXISTUUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTNUL
BT METALS
Mf MtTAL4
»MOC£SlPRT>>Abr METALS
»«QCE SI »"•[«»"•
•"•OCESIPWIHAur MtTALS
P»OCESIP«I"Ati» VETALS
T METALS
T METALS
r MtTALS
T METALS
xROCESIP«IMAi»y METALS
PBOCESH»W|MAMT MfcTiLS
PROCESIPKIMABT MfTALS
ITITlMUM PHUCES
iftOLu
PROCESIPHIMAHT
•RO«S|P»t«A8Y
P80CESISECONOAHY METALS
fROCES i SECONDARY METALS
PROCE 5 1 SECONDARY MfTALS
PBQCESISECONUAKY METALS
PROCESISiCONUARY
POOCE SI SECONDARY
PSOCESIS6CONOAMY
PROCESISECONOAMY
MOCESISECONOAUY
PMOCCSISECONOAMY
BROCISISECONUA-Y
VWOCESISFCONOAUY
PMOCESIStCONOAHY
«<£TAL.S
MJTALS
METALS
MtTALS
"fTALS
M».T»LS
MfTALS
""OCEi I SECOND AM-r METALS
»*OCESISECONOAMY METALS
PROCCSISCCONUARY METALS
PROCESISECONOAHY METALS
P°OCtilSECONO»»Y M»TALS
ILEAO S»£LTE«S
ILEAO SXELTEBS
IMOL'lNU" MINING IGEN6S1L I"UNO1
IMQLT>NUM MILLING IGINEHAL ITONS
IMOLTANUM PMOCES IDTHER/NOT CLASIFOITONS
(TITANIUM PMUCESS IC-L08INAT16N STATITDNS
IDTMCa/NDT CLASIFOITONS
IHINING/PROCiSSlNGITONS
IOHE GutNO ITONS
IREDUCTN* *ILN ITONS
IDNIERS/CALCINEUS ITONS
lOTHEa/'iOT CLASFO ITONS
I GENERAL ITONS
|BOA5TNh/MULl-«"THITONS
ISINTEBINU ITONS
IHOMIZ BETOKTS ITONS
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(ELECTROLYTIC »«OeiTONS
(OTHER/NOT CLASFO I TONS
lOTMEk/NOT CLASFO ISPECIFY IN BEMAKKITONS
I ALUMINUM OPtOATN IS«EATI>lGFUPNACE ITONS
IALUMINU" OPt»ATN ISMELT-CPUCIBLt ITONS
'ALUMINUM OP£aATN ISM£LT*aEVEBB FNC ITONS
(ALUMINUM OPE8ATN ICHLORINATN STtTN I TONS
I ALUMINUM OPEBATN I'OIL BULLING I TUNS
IALUM1WJ" OPEBATN (FOIL CONVF.8TING ITONS
I ALUMINUM OPEBATN I CAN MANUFACTUkE I TONS
IALUMIMJM OPt^ATN IBOLL-0>-««-t«TUUOEI TONS
i «LUM|WM OPES A IN IOTMEB/NOT CLASFU ITONS
M8ASS/8RONZ "ELT (BLAST FNC (TONS
IHUASS/dPONZ MELT IC^UCtBLt FxC ITONS
MELT (CUPOLA FNC I TONS
MELT IELECT INDUCTION ITONS
IHRASS/BHONi MELT lflfv«ag FNC (TONS
IHRASS/BCONZ MELT IUOTABY FNC I TONS
IBDA.SS/R80NJ MCLT IOT-I-/NOT CLASIFOITONS
HRuOUCfO
PRODUCED
XMOOUCEO
paoouceo
PaoOUCED
CONCENTMATEO ONE
COMCENFUATEO ONE
CONCENruATF.O OBE
CO-CENT. ATEO 0»E
'IOS OF TONS MlNtO
PRODUCT
p«ucess{.a
PHOuuCT
*ROfESSED
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lilNC SMELTING
SMELTING
SMfLTINO
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""OCfSISeCONU.-'Y
PROCES i SECONDARY METALS
»«OCE» I SECONDARY METALS
»OOCESISECONO«»T METALS
"OCESISECONUAHY -«tTALS
•MOCEilSECOiOA-Y
MinCtSISECONOAHY
"•OCtSISfCONOAHY
»"UCtSI itCONUl-'
BOQCESIStCONOAMY
»ROCEs I SECONDARY METALS
PHOCES I SECONDARY MtTALS
«BOCE-> I SECONDARY «tT.LS
""OCESIStCONu.-'Y MtTALS
I GRAY [JON
ir.BAY IdON
inaiY IRON
I CM AY IRON
ISBAY IRON
IPBAT IHON
(GRAY IRON
(LEAD SMELT SIC
ILEAO SMELT .sec
ILEAO SMELT sec
ILE>» SMELT SEC
ILF.AO SMFLT SEC
ILEAO SMELT SEC
ILEAO BATTERY
ILEAI/ BATTE4Y
|M«Gx«SIUM SEC
I-AON4SIU" SIC
ISTtEL FOUNUMY
ISTE1L FOUNUfcY
(STEEL FnUNOMY
I STEEL FOUNOMY
I STEE'. FOUNDRY
ISTEEI FOUNOxr
UINC SEC
i CUPOLA ITONS
iREVERB FNC iTONS
ICLECT INDUCTION iTONS
(ANNEALING OBE>-ATNlTONS
IMISC CAST-FABCTN iTONS
10« I NO I NO-CUE'NINO I TONS
IDTHEA/NOT CUASIFOITONS
(POT FuuNACt ITONS
(REVERB FNC ITONS
(BLAST/CUPOLA FNC ITONS
IRUTABY BEVER8 FNCI'ON'i
ILEAO 0L pooouceo
paonucT
PBOOUCEO
PHbOUCEO
PBUOUCEO
paoouceo
cMAi-oe
CHAUGC
CHi-QE
CHANGE
CHANGE
CHA-OE
PROOUCEO
METAL CMA»<3E
METAL CHARGE
METAL CHAB«E
METAL CHAHGC
P-
-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-9
sec
t ti
INDUSTRIAL BBOCESIStCONOAHY METALS
INOUSTHIAL PHOCESISECONUAHY METALS
INDUSTRIAL PHOCESISECONOAHY M£T»LS
INOUSTRIAL kHOCEsI SECONDARY NETALS
INDUSTRIAL ^HOCESI SECONDARY METALS
INOUSTMlAL PHOCESISECONOA-Y METALS
INDUSTRIAL PHOCESI SECONDARY METALS
INDUSTRIAL XROCESISECONUAHY METALS
iNCiUSTHUL HHOCESI SECONDARY NeTiLb
INDUSTRIAL PBOCESISECONUA-V MjTALS
INDUSTRIAL PHOCESI SECONDARY M£TALS
INOOSTRIAL PHOCESISJCDNOilHY METALS
INDUSTRIAL PHOCESI SECOND»HY M£TALS
INDUSTRIAL PBOCtSISECONOAHY «tTi|.S
INDUSTRIAL BROCESIStCONOABY "ETALS
INDUSTRIAL PHOCESISiCONOAHY
INDUSTRIAL PHOCESISECONOAUY
INQUSTUIAL PUOCESISKCONUiHY "ETAcS
INDUSTRIAL HuocEsistcoNO*«Y METALS
INDUSTRIAL PROCESISECONiUHY »ETALS
INDUSTRIAL PHOCESI SECONDARY METALS
INOUSTHIAL PBOCESININEHAL PRODUCTS
INDUSTRIAL PROCESI MINERAL PNOJUCTS
INDUSTRIAL BHOCISI MINERAL PwOOOCTS
INDUSTRIAL OHOCESININEMAC PHOOUCTS
INDUSTRIAL PSOCESIMlnESAL P"'iOUCTS
INDUSTRIAL »HOCtS|MlNEJAC P-OOUCTS
INDUSTRIAL HBOCESIMINERAL PRODUCTS
INDUSTRIAL PROCESIMlNESAL PxOUUCTS
INDUSTRIAL MHQCESI MINERAL PRODUCTS
INOuSTMlAL »HOCESIH|N£HAL PHOOUCTS
INDUSTRIAL PROCESIMI^ESAL PRODUCTS
INOUSTHIAL PHOCE.SIMIS.EBAL PNOOUCTS
INOUSTHIAL PROCISIMINERAL PI-OOUCTS
INDUSTRIAL PHOCESIMINERAL PRODUCTS
INDUSTRIAL PHOCtSIM|«.£RAC PKOOUCTS
INDUSTRIAL HUUCE^ININESAL PHOOUCTS
INDUSTRIAL mociiiMiNESAL PHOOUCTS
INDUSTRIAL PHOCESIMINERAL PRODUCTS
INDUSTRIAL PMOCESIHtxiSAL PHOuUCTS
INDUSTRIAL VHOCESIMINEHAL PaoouCTS
INOUSTHIAL FMOCESIM[*E«AL PMOOUCTS
INOUSTHIAL PUOCtai »[NflL PHOUUCTS
INOUSTHIAL PMUCEalMINEriiL PRODUCTS
INDUSTRIAL »OOCESIMINERAL PHOUUCTS
INOUiTHIAL vHOCCSlMINEaAL HxOOUCTS
INDUSTRIAL wiOCEsI MINERAL PRODUCTS
INOUf.THUL ^"OCESlMlhEWAL P»OOUCTS
INOUiTHlAL »ROCCilMINtMAL PUOUUCTS
INDUSTRIAL mociiiMiNCHAL RUOOUCT*
INDUSTRIAL PBOCESIMINERAl. PNOOUCTS
INDUSTRIAL PHOCESIMlNCiUL PCOOUCTS
INOUS TRIAL PSOCESIMIXEXAL POQOUCTS
INDUSTRIAL PROCESIM1NERAL PMOOUCTS
INDUSTRIAL fBOCES I MI»£«»(. PHOOUCTS
INDUSTRIAL I-ROCESININEAAL PRODUCTS
INDUSTRIAL k«oC£SiMINERAL PROUUCTS
INDUSTRIAL P«OCESIMIN£HAL PNOOUCTS
INOUSTHIAL PHOCESiMINERAL PHOOUCTS
INCUSTRIAL PDOCCSI MINERAL PRODUCTS
INOUSTHIAL PHOCCSIHINERAl PUOOUCTS
INDUSTRIAL *>ROct si MINERAL PRODUCTS
INDUSTRIAL PROCESI MINERAL PAOOUCTS
INDUSTRIAL KDOCtSIHINCRAL PUOOUCTS
INDUSTRIAL POOCESIMINEHAL PROUUCTS
INDUSTRIAL PROCESIHINERAL PRODUCTS
INDUSTRIAL PMOCESIMINERAL PAOOUCTS
INDUSTRIAL PHOCE-SIHINEMAL PXOOUCTS
INOUSTHUL PHOCESiMINERAL PUOOUCTS
INDUSTRIAL fHOCtsI MINERAL PUOUUCTS
INOUSTBIAL PROCESIM|Nt«AL PHOOUCTS
INDUSTRIAL P«OCISIMINERAL PUOOUCTS
INOUSTHIAL PHOCtSIMlNEMAL PUOOUCTS
INDUSTRIAL PUOCESI MINERAL PHOOUCTS
INDUSTRIAL f«ocESittNEH*L PRODUCTS
INDUSTRIAL »«OCEilMINERAL PUOUUCTS
INOUSTRIAL K«OCtil«|NEaAL PHUOUCTS
INDUSTRIAL PHOCESIMINEHAL PVOOUCTS
INDUSTRIAL POOCESIMINEHAL PNOOUCTS
INOUSTHIAL P«OCESIMINEHAL PRODUCTS
INOUSTHIAL H-OCESII-1NEHAL PUOOUCTS
INOUSTRIAL PDOCESIMINEMAL PHUOUCTS
INUUSTHtAL PHOCESI MINERAL PUOOUCTS
INOUSTHIAL xaoc£sI MINIMAL PHOOUCTS
INDUSTRIAL PUOCISIMINERAL PRODUCTS
INOUSTHIAL HHOCESIMINCHAL PUOOUCTS
INDUSTRIAL PROCESIHINEHAL PUOOUCTS
INDUSTRIAL ^UOCESIMINEHAL PUODUCTS
INOUSTMIAL PUOCtilMIHEXAL PHOOUCTS
INDUSTRIAL MAOCKSIMINCHAL PUOOUCTS
INOUSTHIAL -KOCESIMINtHAL PRODUCTS
INOUSTHIAL PUOCtiI MINERAL PHUOUCTS
INOUSTHIAL w*ocEbiniNt««L PUUOUCTS
INDUSTRIAL WOCESI MINERAL PHOUUCTS
INOUSTHIAL IXIOCtMMlNEMAL PMOOUCTS
INOUSTRIAL PAOCEblMINEKAL P-OOUCTS
INOUbTHIAL KMOCCSIMINtKAL PUOOUCTS
INDUSTRIAL PUOCESIMINCHAL PMOOUCTS
INDUSTRIAL PUOCSSIMINEHAL PUOOUCTS
INDUSTRIAL UTOCESIMINEHAL PUOOUCTS
III
IV
UNITS
IZINC SEC
I ZINC SEC
IZINC SCC
IZINC SEC
IZINC SEC
IZINC StC
IZINC SEC
IZINC SEC
i«ALLEAdLt IRON
IMALL!ABL£ I»ON
INIC'FL
INIC'EL
IZIHCONIUM
IXBIC<
I»«IC<
lofl[C<
IttBIC"
IB81O
iMOBiz MUFFLE FNC iTONS PRODUCED
I POT FUHNACE ITONS PBQOUCtO
IKETTLE-S.EAT FNC ITONS PRODUCED
iGALVANtztNG KETTLITONS PROOUCCO
ICALCINING «ILN ITONS PRODUCED
ICUNCENTRATE OHYERifONS PRUCESSEO
IBEVEJH-S.tAT FnC I TONS PRUOUCEU
IOTME6/NOT CLASIFOITONS PROCESSED
IANNEALING OPE*Af.NI TONS METAL CHARGE
IOTH£B/.<,OT CLASIFOITONS METAL CHARGE
IFLUA FuBNACt ITONS PROCESSED
IOT»ER/»OT CLASIFOITONS PROCESSED
I OX IDE «ILN ITDNS PHOCESSEO
IOTHER/NOT CLASirOITDNS PROCESSED
(FURNACE ELECTRODEICALCINATION ITONS PROCESSED
I FURNACE ELECTBOOf INUING i TONS PROCESSED
IFUHNACE tLECTROOEIPITCH TH£ATINS ITONS PBQCESSEO
(FURNACE ELECTRODE I SAKE FUHNACtS ITONS PUOCESSEO
(FURNACE ELECTROOEIOTifB/NOT CLASIFOITONS PHOCESSEO
IMISC CAST^ABHCTNISHECIFY IN HE-AHKITONS PHOOUCEO
IOTHt»/NQT CLASIFOISPEC1FY IN »£HASKI TONS PRUCESSEO
IASPKALT HOOFING I8LOHINI-, OPE»ATI ON I TONS SATURATED FELT PHOOUCEO
(ASP-ALT BOOKING (DIPPING DNct ITONS SATURATbO FELT PROOUCED
(ASPHALT HOOFING ^"HAYING ONLY ITONS SATURATED FELT PRDOUCEO
KSPMAcT BOOFING ion>p[N'>/SPuAY[Nii i TONS SATUHATEO FELT PRODUCED
lASPtALT HOOFING IOTHER/NOT CLASIFOITONS SATUHATEO FELT PHOOUCEO
IASPUALTIC CONCRETlROTAPY GHYE* ITONS "ByCUCEO
IASPMALTIC CONCRETIOTHEH SOUHCES ITONS PuOOuCEO
CUNCH£TIOT»£B/NOT CLASIFOITONS PRODUCED
NUFACTUREIOHYING-aA* MTL I TON) PRODUCED
NuFACTUMEIGxlNOIlG-HA* >TL ITONS KBOUUCEO
.NUFACTuu£(ST3HtGt-4A> MTL ITONS PHOOUCEO
.NUFACTUHEICUHING UAS M-EO ITONS PHUOUCED
,NUFACTu«E (CURING OIL FIxEO ITONS PROOUCEO
NUFACTUHEICUPINb COAL M-£01 TONS PBOOUCEO
NUFACTUHEIOTHEH/MOT CtASIFOITONS PRODUCED
(CALCIUM CAR8IDE (ELECTRIC FNC ITONS PRODUCED
ICALCItlM CAR8IOE ICU«E OUYER I TONS ""OOuCEO
ICALCIUM CAR8IDE IFNC BOOM VENTS I TONS BBUOUCEO
ICALCIUM CABol&E IOTHEH/NOT CLASIFOITONS XSOCESSEO
ICASTit>L£ HEFRACTYIRAkMATL DHY£>> I TONi FEED MATERIAL
ICASTARLf HEFSACTYiai.MATL CSUSf/WHClTONS 'EtO MATEHIAL
ICASTAqLE aEFBAClYlEuEITHIC AUC -ELTITONJ F£tt) MATEHIAL
ICASTAHLE "EtMACTYICUMNG OVEN I TONS FEED MATERIAL
ICASTA6LE HFFaACTYlMOLO/SHAKEOUT ITONS FEED MATERIAL
ICASTA8LE REFRACTYIOTHER/NOT CLASIFOITONS FEfO MATERIAL
ICEUENT MFG UHY IKILNS (BARRELS CEMENT PRODUCED
IOHYEHS/GMIw.'.EreidABu£LS CE»t»T HBOOUCEO
'IKILNS-OIL n»m 'TONS CEMENT >>MOOUCEO
I«ILN$-<|AS «-IMta ITOXS CEMENT PADOUCEO
I KILNS-COAL FINED ITONS CEMENT PHOOUCEO
(OTHER/NOT CLASIFOITONS CEMENT PAOOUCEO
IKILNS I8AAHELS CEMENT PAOOUCEO
IDHYEHS/OBINOEHETCIBABHELS CEMENT PAOOUCEO
IKILNS-OIL FIREO ITONS CEMENT PHOOUCEO
IKILNS GAS FIRED ITONS CEMENT PRODUCED
(KILNS-COAL FUEO ITONS CEMENT PROOUCEO
IOTHER/NOT CLASIFOITONS CEMENT PRODUCED
ITONS INPUT TO PROCESS
ITON» INPUT TO PROCESS
Mrs ISTOBAGE ITONS INPUT TO PROCESS
(CERAMIC/CLAY Mrs (OTHER/NOT CLASIFOITONS PROOUCEO
ICLAY/FLTASMSINTEAirLYASH ITONS FINISHED PRODUCT
ICLAY/rLTASMSINTEAICLAT/COKE ITONS FINISHED PAOOUCT
ICLAY/FLTASHSINTEAINATUAAL CLAY ITONS FINISHED PRODUCT
ICLAY/rLYASHSINTERIOTHER/NOT CLASIFOITONS PAOOUCEO
(COAL CLEANING ITHEMM/rLUID BED ITONS COAL OHIEO
ICOAL CLEANING |THERM/FLASH ITONS COAL OHIEO
ICOAL CLEANING ITHEHN/MULTILOUVAOITONS COAL OHIEO
ICOAL CLEANING IOTHER/NOT CL.AS JFOI TONS COAL CLEANED
I CONCRETE 8ATCNIN4ISENEAAL ICUS1C TAMOS CONCRETE PAOOUCEO
(CONCRETE 8ATCXIN8IAS8EST/CEMNT lH)TSITONS PAOOUCT
ICONC-ETE BATCMINSIOTMER/NOT CLASfO ITONS PAOOUCT
iriBEP«LASS MTS IHEVERbrNC-RESENEXITONS MATERIAL PROCESSED
IHtVEHbFNC--£CUi>EllIONS MATERIAL PBO«sS£D
(ELECTRIC INO FNC ITONS MATERIAL PROCESSED
IFOHMING LINE ITONS MA-TERIAL PHOCESSEO
ICUHINO OVEN ITONi MATEHIAL PROCESSED
IOTNER/NOT CLASIFOITONS >»UUC£SSEU
IHOTAHY FNC GENL ITONS CHANGE
IOTHER/NOT CLASIFOITONS CNAHGEO
ISOOALIMC SENL FNCITONS GLASS PAOOUCEO
(RAM MAT uEC/STOHSITONS PUOCESSEO
I8ATCMING/WUINS (TONS PROCESSED
IMOLTEN HOLD TANKSITONS PAuCtSSEO
lOTMER/NOT CLASIFOITONS MBOUUCtO
I A* MTL OHYtH ITONS THkOUGHPUT
IPtttMARY GRINUtM ITONS THhOUbxPUT
ICALCINEH ITONS TMHOUGMHUT
(CONVEYING ITONS TH»OUGlPUT
IOTHEH/NOT CLASIFOITONS THkOUGHduT
IPHlMAHr CHUSMINO ITONS PMUCESSED
ISECNOBY CHUSHIN« ITONS PHOCESSEO
ICALCINNG-vtHTnlLNITON-j PROCESSED
ICALCINN6-HOTTH1LNITONS KROCESSEO
(OTHER/MOT CLASIFOITONS PROCESSED
(CUPOLA ITONS CHA^«C
IHEVERB FNC ITONS CHAXGE
ISkOu CHAMaEH ITONS CHAHSE
ICUHING OVEN ITONS CHAHfcE
ICEME-.T M«S 4v'
IC£M£,«T Mr« uHT
(CEMENT MTS OAT
ICCMENT MPS DRY
ICEMENT Mrs «ET
I CEMENT MTS i£T
ICEMENT Mrs «ET
ICEMENT Mrs «£T
ICEMENT MTS «ET
(CEMENT MTS nET
ICERAMIC/CL.AT NTS IOMTINS
ICERAMIC/CLAT MTG ISAINOINS
IFIBE««LASS •*$
IFI8EO(ILASS M»3
IFI8E>GLASS MTS
IFiat-OLASS MTS
IFBIT M^O
IFRIT MT«
(GLASS *TO
(GLASS MTS
(GLASS MTO
(GLASS NTS
(GLASS MF5
ISVPSUM NTS
KiTPfux Mrs
ISTPSUM MFS
ISTPiuM »fd
liiYPSUM MFIi
1C I ME *fv
(LIME NTS
(LIME MFO
I LIME MTO.
(LIME Mrs
IMINtHAL «OOL
I MINI "AC «OOL
IMINEHAL »OOL
IMINEHAL »OOL
-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-10
SCCCATEGOMY
i
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTM1AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTRIAL
INUUSTRIAL
INDUSTRIAL
INUUSTRIAL
INDUSTRIAL
INUUSTRIAL
INCUSTRUL
INDUSTRIAL
INDUSTRIAL
INOUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INOUSTHUL
INCUS TRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTRIAL
INOUSTRIAL
INOUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTRIAL
INDUSTRIAL
INOUSTRIAL
INOUSTHUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTRIAL
INOUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INOUSTRIAL
INOUSTHUL
INDUSTRIAL
INOUSTHUL
INDUSTRIAL
INOUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTRIAL
INOUSTRIAL
II
III
IV
UNITS
PROCESIMINERAL PHOOUCTS (MINERAL *OOL
PROCESIMINERAL PRODUCTS (MINERAL *OOL
PROCEslMINEHAL PRODUCTS IPERLHE MFG
PHOCESIMINERAL PHOOUCTS IPERLlTE MFG
PROCESIMINERAL PHOOUCTS (PHOSPHATE ROCK
PROCESIMINERAL PHOOUCTS IPHOSPHATE ROCK
PROCESIMINERAL PRODUCTS IPHOSPHATE ROCK
PROCESIMINERAL PRODUCTS IPHOSPNATt ROCK
PROCESIMINERAL PRODUCTS (PHOSPHATE ROCK
PROCtSIHINERAL PHOOUCTS ISTONt QUAMY/PHQC
(COOLER ITONS CHARGE
(OTHER/NOT CLASIFOITONS PROCESSED
(VERTICAL FNC GEN I TONS CHARGE
(OTHER/NOT CLASIFOITONS PROCESSED
(ORYINS (TONS PHOSPHATE ROCK
IGRINOING ITONS PHOSPHATE ROCK
I TRANSFER/STORAGE I TONS PHOSPHATE ROCK
(OPEN STOHAbE (TONS PMoSPHATt ROCK
(OTHER/NOT CLASIFOITONS PROCESSED
I PR IRART CRUSHING (TONS HA* MATERIAL
PROCcaiMINERAL PRODUCTS (STONE QUAHV/PHOC (SEC CRUSH/SCREEN (TONS RA* MATERIAL
PROCESIMINERAL PHOOUCTS ISTONE OUARY/PROC ITERT CRUSH/SCREEN(TONS HA* MATERIAL
PROCESIMINERAL PROOUCTS ISTONt OUARY/PHQC IRECRUSM/SCHEENlNGITONS HA* MATERIAL
frROCESIMINERAL PHOOUCTS (STONE QUARY/PROC (FINES MILL ITONS RA* MATEMUL
PROCESIMINERAL PROOUCTS (STONE OUARY/PHQC ISCREEN/CONVY/HNOLITONS PRODUCT
PROCES(NINERAL PROOUCTS (STONE QUAAY/PROC (OPEN STOHAUE ITONS PRODUCT STORED
PHOCES(MINERAL PHOOUCTS ISTONE OUAflflT PROCICUT STONE-«£NERALITONS PROCESSED
PHOCESIMINERAL PHUOUCTS ISTONE QUARRY PHOCIBLASTIMi-uENERAL I TONS PROCESSED
PHOCESI MINERAL PRODUCTS ISTONt OUAflHY PROCI OTHER/NOT CLASIFOITONS PROCESSED
PROCESIMINERAL PRODUCTS (SALT MINING (GENERAL ITONS MINED
PHOCESiMINERAL PRODUCTS IPOT«S» PROOUCTIONIMINE-GRINO/OHY ITONS ORE
PBOCESIMINtRAL PRODUCTS (POTASH PHOOUCTJONIOTHER/MOT CLASIFOITONS PROCESSED
(MINING/PROCESSINGITONS PRODUCT
PROCEslMINEHAL PROOUCTS (CALCIUM BOHATE
PROCESIHlNERAL PRODUCTS (CALCIUM BOBATE
*ROCEsiMINERAL PRODUCTS IMG CARBONATE
PROCEblMlNERAL PROOUCTS IMG CARBONATE
PROCESiMINERAL PRUOUCTS I$ANO/GRA»EL
PBOCESININERAL PRODUCTS ISANO/ORAVEc
PRODUCTS iGUTOMACoustRTH
(OTHER/NOT CLASIFOITONS PROCESSED
|M|Nc/Pl»OCEsS ITONS PROOUCT
IOTHER/NOT CLASIFOITONS PROCESSED
iCRUSHtMii/SCPElNlNITONS PRuOOCT
(OTHER/NOT CLASIFOITONS PROCESSED
(HANDLING ITONS PRODUCT
PHOCESlHINERAL PROOUCTS luIATOMACOUS tiflTMlOfHt«/NOT CLASIFOITONS PROCESSED
pRUCtslRINEHAL PRODUCTS (CERAMIC ELECT PTSIOTHER/NOT CLASlFOItONS PROCESSED
PHOCESIMlsERAi. PROOUCTS (OTHEH/NOT CLAS1FOI SPECIFY IN REMARK I TONS PROOUCT
PHOCESI PETROLEUM INOBT
PHOCEblPETROLEUM INOHT
PRUCESI PETROLEUM INOHY
P-AsTE .ATf
1000 BARRELS *ASTE .ATER
1000 BARRELS VACUUM alSTILLATIOM
11000 BARRELS VACUUM DISTILLATION
(MILLION r.ALLONS COOLING «ATER
IPIPE/VALVE-FLANGEIIOO.) BARRELS REFINERY CAPACITY
IvtSL RELIEF VALUEI1000 BARRELS REFINERY CAPACITY
(PUMP SEALS llOOg BAHMELS BEFINERT CAPACITY
ICUMPRESM SEALS I 1000 BARRELS REFINERT CAPACITY
IOTHE«-«tNL 11000 BARRELS HtFlNEHT CAPACITY
(NATURAL GAS (MILLIONS OF CUBIC FEET
(OTHfR/NOT CLASIFOIMlLLlONS OF CUBIC FEET
(GENERAL ITONS PROCESSES
ASPHALT OXIDIZES IGENERAL ITONS PROCESSED
ASPHALT OX1DIZER (OTHER/NOT CLAsIFOlTONS PROCESSED
(FLUID COKING (GENERAL 11000 BAkfcELS "ESH FEED
(OTHER/NOT CLASIFOISPECIFY IN REMAHK(TONs PROCESSED
IOTHER/NOT CLASIFOISPECIFY IN REMARK(BARRELS-PROCESSED
IBLOOTNK ICCURULTRIAIR-ORT TONS UNBLEACMEO PULP
I*ASHHS/SCREENS IAIR-ORY TONS UNBLEACHED PULP
IMULT-EFFtCT EVAP IAIR-ORY TONS UNBLEACMEO PULP
IRECVY BOLR/OCEVAPlAIR-ORY TONS UNBLEACHED PULP
(SMELT OISSOLV TNKIAlM-ORY TONS UNBLEACHED PULP
ILIME KILNS i»IB-OPT TONS UNBLEACHED PULF>
(TURPENTINE CONOSRIAIR-OMY TQNS UNBLEACHED PULP
IFLUI08EO CALCINERIAIR-ORY TONS UNBLEACHED PULP
ILIOUOH 01ION TOVRIAIR-ORY TONS UNBLEACHED PULP
IOTHEM/NOT CLAslFOlAIR-OMY TONS UNBLEACHED PULP
ILIOUOH RECOVERY IAIR-OPV TONS UNBLEACMEO PULP
ISULFITE TO*ER (AtR-OHY TONS UNBLEACHED PULP
IOI6ESTEH UIR-OHY TONS UNBLEACHED PULP
(SMELT TANK lAlB-OMY TONS UNBLEACHED PULP
(EVAPORATORS IAIR-ORY TONS UNBLEACHED PULP
(PULP DIGESTER (TONS A IK DRY PULP
(OTHER/NOT CLASIFOITONS AIM DRY PULP
IPAPER80ABO-6EN ITONs FINISHED POOOUCT
IFIBER80AHO-GEN I TONS FINISHED PROOUCT
(OTHER/NOT CLASIFOITONS FINISHED PROOUCT
(PRESSURE TRtATIMSICMEOSOTE I TONS OF *OOU TREATED
(PRESSURE TREATINGIOTHER/VOT CLASUOITONS OF .000 TREATED
ITALLOIL/HOSIN (GENERAL I TONS OF PROOUCT
IPLY*000/PARTBOAROIVENEER OMYtR ITONS PROCESSED
IPLYlOOO/PAHTaOAkOISANOlNO I TONS PROCESSED
|PLY*300/PARTaOAROIOTH(«/<«OT CLASIFOITONS PROCESSED
ISA.RILL OPEHATNS (OTHER/NOT CLASIFOITONS PROCESSED
(EICtLSlnk HFG lOTHtR/NOT CLASIFOITONS PROCESSED
(CORK PROCESSING (OTHER/NOT CLAsIFOlTONS PkoCtSSEO
(FURNITURE MFC (OTHER/NOT CLASIFOITONS PROCESSED
IOTMta/NOT CLASIFDISPECIFY IN REMARKITONS PROCESSED
IHISC HAROCAHE ITONS OF PRObUCT
IFARM MACHINERY iTONS OF PROOUCT
ISULFATC PULPNO
ISULFtTE
ISULFATE
ISULFATf PULPNIi
(SULFATE PULPNG
ISULFATE PULPNG
ISULFATl PULPNS
ISULFATE PULPNO
ISULFATE PULPING
ISULFATt PULPING
ISULFITE PULPING
ISULFITE PULPING
ISULFITE PULPING
ISULFtTE PULPING
ISULFITE PULPING
ISULFITE PULPlNa
ISULFITE PULPING
IPULPOOARO .MFG
IPULPSOAPO MFG
IPULP90ARO MFG
MROCeSINETAL FAHHICATIONIIRON/STEEL (OTHER/NOT CLASIFOITONS PROCESSED
PHOCtSIMtTAL FABriICATICN(PLATlN6 OPtRATONSIOTHEM/NOT CLASUOlTONS PLATED
PROCESIMtTAL FA8M1CATIOHICAN RAKING OPHNS (OTHER/NOT CLASIFOITONS PRODUCT
PROCESIMtTAL FAHHICATIONIOTht>/NOT CLASIFOISPECIFT IN R£MAHKI TONS PROCESSED
MIOCEilLEATHti, PRODUCTS lOTHta/NOT CLASIFOI SPECIFY IN HEMARKiTONS PROCESSED
PHOCEslUiTILC M»'G IwENtRAL FABHICS IYAHN PhEP/BLEACH (TONS PHoCESSED
PROCESlTEltlut MO ItiENCUAL '•"AbHICS (OTHER/NOT SPECIFOITONS PHuCESSEO
PHOCESlTtATIii MFG (BUBERIZEO FABHICSIOTMER/NOT SPECIFOITONS PRwCEsstO
PROCESITE»TlL« MFG (CARPET OPCRATNS (OTnCR/NOT SPECIFOITONS PROCESSED
-------�
TABLE 2.1-4. (Continued)
NATIONAL EMISSIONS DATA SYSTEM (NEDS;
SOURCE CLASSIFICATION CODE (SCC) REPORT
UG-2.1.8-11
SCC CATC60HY NAMES
i
tt
INDUSTRIAL PHOCESIINPflOCESS FuEL
INOUSTRUL PHOCEillNPWOCiSS FUEL
INDUSTRIAL pHuCEsiiNPMOciss FUEL
INDUSTRIAL PNOCCbllNPHOCESS FUEL
INDUSTRIAL .»flOCE»IINPBOCESS FUEL
INDUSTRIAL KNOClM 1NPBOCESS FUEL
INDUSTRIAL PHOCESIlNPMOCESS FUEL
INOUSTRUL PROCESUNPWOCESS FUEL
INOUSTRUL pRoctsiiNPHuCEaS FUEL
INOUSTRUL PRUCESIINPHOCESS FUEL
INOUSTRUL PWOCtSltNPMOCtSS FUEL
INOUSTRUL pROCE»iiNPRocci» FUEL
INOUSTHltL PROCE*IINPROCESS FUEL
INOUSTRUL PROCESIINPHOCESS FUEL
INDUSTRIAL PNOCEslINPROCESi FUEL
INOUSTRUL PNOCEX INPROCESS FUEL
INOUVTRUL PHOCfc&IINPMOCESS FUEL
INDUSTRIAL PNOCKSI1NPMUCESS FUEL
INDUSTRIAL PROCESI INPMOCESS FUEL
INOUSTRUL PROCESIlNPHOCESS FUEL
INDUSTRIAL PBOCEsllNPROCEiS FutL
INDUSTRIAL PMOCESI iNPBoctSS FUEL
INOUSTRUL I-MUCESIINHKOCESS
INDUSTRIAL xfcOCESI iNpflOCESS FuEL
INOUSTRUL PROCESI INPBOCESS FUEL
INDUSTRIAL CROCESI iNpaoctii FUEL
INOUSTRUL fMocEbi i»paoc£ss FUEL
INDUSTRIAL mocESiiNPNOcfcSS FUEL
INCuSTHUL PSOCESI iNiMOCESS FuEL
INDUSTRIAL K«OCE»I:>PHOCESS FUEL
INDUSTRIAL PiocEiiiNpaocESS FUEL
INOUSTRUL pRoctsiiNpaociSS FUEL
INDUSTRIAL PSOCESI INPBOCSCSS FUEL
INOUSTRUL •*«OCESIINP«OCESS FUEL
INOUSTRUL P9UCESIINPROCESS FuEL
III
(ANTHRACITE COAL
(BITUMINOUS COAL
I BITUMINOUS COAL
I BITUMINOUS COAL
I*ITU«|NOUS COAL
IOITU-4INOUS COAL
IMESIOUAL OIL
IKES I DUAL OIL
IMESIOUAL OIL
!>>ESIDUAL OIL
IMES19UAL OIL
IrfESlOUAL OIL
(RESIDUAL OIL
(NESIDUAL OIL
IOISTILLATE OIL
IOISTILLATE OIL
IOISTILLATE OIL
•DISTILLATE OIL
•DISTILLATE OIL
IOISTILLATE OIL
IOISTILLATE OIL
IDISTILLATE OIL
INATU3AL liAS
(NATURAL GAS
INATUBAL liAS
INATUMAL GAS
I NATURAL GAS
I NATURAL SAS
INATUMAL <>AS
INATUUAL UAS
(PBOCSSS GAS
I COKE
1*000
IV
UNITS
(OTHER/NOT CLASIFOITONS SUNNED
ICENENT KILN I TONS aUHNEO
(•»!« KILN/ORY I TONS aUMNED
(GfPSUM KILN/ETC (TONS aURNEO
(COAL DRYERS I TONS BUHNEO
CLASIFOITONS BURNED
(ASPHALT
•ICE«ENT KILN
ILIME KILN
IKAOL1N KILN
IKETM. MELTINS
I8R1CX KlLN/ORT
15TPSUM KILN/ETC
uooo GALLONS BURNED
11000 GALLONS BUHNEO
11000 GALLONS BUWNEO
I 1000 GALLONS buUNED
UOOO GALLONS 8URMEO
I 1000 GALLONS 6U>,OT CLA&IFOI»(LLldN CUBIC FEET auRNEO
lOTntR/NOT CLAMFOlTONi
lOTnER/xOT CLASIFOlTONa BUNNED
IOT»£-/NOT CLASIFOISPECIFf IN HE»AB
POINT SC l»AI»
POINT SC EVAP
POINT SC EV.P
POINT sc tVAC
POINT SC EVAP
PU|"T SC
POINT SC CVAP
POINT SC EVAP
POINT sc EV.P
POINT sc EVAP
POINT sc EVAC
POINT SC EVAP
POINT SC IVAP
POINT sc EVAP
POINT SC EVAP
POINT sc EVAP
SOLID »SU
SOLID »ASTE
SOLID IASTE
SOLID IASTC
SOLID 1A-.TE
SOLID HASTE
SOLID «ASTE
SOLID HASTE
SOLID HASTE
SOLID »AST£
SOLID HASTE
SOLID HASTC
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID >»STE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HAS IE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID H*STE
SOLID H.STC
SOLID HASTC
SOLID IASTE
SOLID HASTE
SOLIU HASTE
SOLID HASTE
SOLID HA»TC
SOLID «A!>JE
bOLIO HASTE
SOL 10 HASTE
ICLEANI-,6
(CLEANING
I CLEANING SOLVENT
(CLEANING SOLVENT
ICLE'NING SOLVENT
I SU>>'ACE COATIN6
ISUBFACE COATINO
(SURFACE COATING
(SURFACE CUATING
lSUBF«ti COAT INo
(SURFACE CUAT!M>
IPETIMLEUM STG
IPtTUULEuN ST6
(PETROLEUM ST8
IPETROLEg» ST9
(PETROLEUM STS
I PETROLEUM ST9
(PETROLEUM STS
(PETROLEUM ST8
(PETROLEUM STS
IO»»CLf »N|M»
iU«TC,.EiNlN6
IPAINT
IVARNISH/SHCLLAC
ILAQU'U
ItNAMEL
IMISC MC EVAP
I GOVERNMENT
IGOVEHNMENT
(GOVERNMENT
I6UVEHNMENT
I GOVERNMENT
(«OVERNM«.NT
laOVCRNHENT
(GOVERNMENT
I80VEANMENT
IOOVE<*NM£NT
I80VEHNMCNT
IMVCRNM(NT
IGOV£-(N»ENT
I TONS PHuCESitO
|PENC"LORETHTLEN€ tTONi CLOT»E» CLEANED
ISTuOOArfO ITON5 CuO'-ta CLEANED
ISTOOOAOO I TONS SOLVENT USED
IUESMEiSI»G IOTn£d/NOT CLAblFOlTONS SOLVENT uSEO
lor»t-i/NOT CLASIFOISPECIFT IN AEHAHKlTONi SOLVENT USEO
I TONS COATING
(TONS COATlNfe
(TONS COATING
ITONi COATING
(TONS COATING
IN NE«AH« I TONS COAT INI,
GALLON* STORAGE CAPACITY
IBHEATHINO CMUUC UOOO GALLONS STORAM CAPACITY
iHORKING-PRODUCT uooo GALLONS THROUGHPUT
IHORKINIi CPUUE UOOO GALLONS THROUGHPUT
(BREATHING PHOOUCTUOOO GALLONS STORAGE CAPACITY
I.OBKINO-PHOOUCT UOOO GALLONS TMUQUGHPgT
IBxEATHING-ChUUi UOOO GALLONS STORAUt, CAPtCITT
IHORKlNii-CHUUE UOOO GALLONS THROUGHPUT
IN MEMAIHI1000 GAL STORED
IN REMARK I TONS STOHEO-
I TONS SOLVENT
(GENERAL
IGENEAAk
IGENtHAL
IGENEHAL
(GENERAL
IOTn«u/NOT CLASIFCI SPECIFY
I FIXED rfOOF
IFUEj HOOF
IFIIEO ROOF
IFIHO AOOF
I FLOATING ROOF
IFLOATINO ROOF
i FLOAT ING ROOF
i FLOAT ING ROOF
IOTH&B/NOT CLASIFOISPECIFT
IMISC ORGANIC STQRIOTHEB/NOT CLASIFOISPECIFY
IPMINTIN8 PRESS lOBYfJS I8CNEHAL
I8OVEHNMENT
ICOMM-INST
ICO""-tNST
ICOMM-IHST
ICOMM-INST
ICOMN-INST
(CONM-INST
IOTHEB/NOT CLASIFOISPECIF-r IN REMAMKKONS PROCESSED
(MUNICIPAL INCIN (MULTIPLE CHAMBCH I TONS 8UI"»ED
'MUNICIPAL INCIN (SINGLE CHANHCM I TONS BUHNEO
I OPEN BURNING DUMP I GENERAL I TONS BUMNEO
(OPEN 8UHNIN8 OUMPILANOSCAPE/PDUNIMITONS BUMNED
(OPEN BURNING OUMPIJET FUEL IMUNOMEOS Of GALLONS
IINCINE<)ATOR (PATHOLOGICAL I TONS BUUNEO
IINCINERATON (SLUDGE I TONS DRY SLUOGC
(INCINERATOR (CONICAL I TONS BUMMED
IINCINFRATON (OTHER/NOT CLA4IFOITOMS BUMNED
UU».FUEL/NO EMSNSI RESIDUAL OIL (1000 3ALLONS
IAUX.FUEL/NO tMSNSIOISTILLATE Oik UOOO GALLONS
I »UX.FUEL/NO EMSNSINATUMAL 8A& (MILLION CUBIC F«T
lAUI.FUEL/NO EMSNSILP* I 1000 GALLONS
IAUI.FUEL/NO E«SNS I OTHER/NOT CLASIF.OIMILLlDN CUBIC FEET
i tut. FUEL/NO E«SNS i OTHER/NOT CLASIFOUOOO GALLONS
IAUX.FUEL/NO EMSNSiOTHER/NOT CLASIFOITONS
IINCINEHATOH GEN (MULTIPLE CHAMBER (TONS SUMt.EO
ICOMN-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICuwi-inST
I com- 1 MS T
ICUMM-OST
I INCINERATOR GEN
IINCINEHATOK GEN
I INCINERATOR GEN
(INCINERATOR GEN
(OPEN BURNING
(APARTMENT INCIN
(APARTMENT INCIN
iINCINERATOR
I INCINERATOR
I INCINERATOR
I INOUSTMUL
I INOUSTMUL
I INDUSTRIAL
IINOUSTHUL
(INDUSTRIAL
i INOUSTMUL
(SINGLE CMAMBEM (TONS BUMNCO
(CONTROLLED AIR (TONS DIMMED
(CONICAL FEFUSE I TONS 8UHNEO
ICONICAL HOOD iTONS BURNED
(HOOD (TONS BUMMED
I FLUE FED (TONS BUMNED
(FLUE FEO-MQOiriCOITONS BURNED
(PATHOLOGICAL I TONS BUHNfO
ISLUOGC I TONS DRY SLUOGC
(OTHER/NOT CLAblFOlTONS OU»~EO
IAUX.FUEL/NO EMSNSIRESIOUAL OIL UOOO GALLONS
IAUX.FUEL/NO EMSNSIOISTILLATE OIL UOOO GALLONS
IAUX.FUEL/NO EMSNSINATURAL 3AS (MILLION CUBIC FEET
IAUX.FUEL/NO tMSNSiLPG uooo GALLONS
IAUX.FUEL/NO EMSNSIOTNEK/NOT CLASIFOIMILLION CUBIC FEET
UUX.FUEL/NO CNSNSIOTHtR/NOT CLAblFOI IOOU UALLONS
IAUX.FUEL/NO CMSNSI OTHER/NOT CLASIFOITONS
I INCINERATOR (MULTIPLE CHAMHEM I TONS MUMNED
(INCINERATOR (SINGLE CHAMBER I TONS BUMN£0
(INCINERATOR (CONTROLLED At* ITONi BUMNCO
IINCINERATON ICONICAL REFUSE I TONS BUDNEO
IINCIXCRATOM ICONICAL HOOD (TONS HUMNEO
(INCINEMATOH lOHtN PIT (TONS OF HASTE
-------�
UG-2.1.8-12
TABLE 2.1-4. (Concluded)
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGURt NA-ES
SOLID
SOLID
SOLID
SOLID
SOLID
SOL 10
SOLID
SOLID
SOLID
SOLID
SOLID
SOLID
SOLID
SOLID
SOLID
SOLID
• ASTE
»ASTE
• ASTE
• AiTE
• »STE
»«STE
• A»T£
»ASH
•ASTE
• ASIt
HASTE
Other
11
1 INDUSTRIAL
1 INDUSTRIAL
1 INDUSTRIAL
1 INDUSTRIAL
1 INDUSTRIAL
1 INDUSTRIAL
i INDUSTRIAL
i INPUSTRIAL
1 INDUSTRIAL
i INDUSTRIAL
i INDUSTRIAL
i INDUSTRIAL
1 INDUSTRIAL
{INDUSTRIAL
1 INDUSTRIAL
I INDUSTRIAL
Lab (
Analysis
III I» UNITS
OPEN BURNING HOOD ITQNi BUxMEO
OPEN i.ru£L/NO EHSMSlfRUCtSS uAb MILLION CUbIC FEET
AUI. FUEL/NO EHSNSIL P H iiooo GALLONS
AUA. FuEL/NO EHSNSIOTHER/NOT CLASIKOIHILLION CUBIC FEET
AUX. FUEL/NO EMSNSIOTrtER/NOT CLASIFDIlOOO liALLONs
AUX. FUEL/NO EMSNSI OTHER/NOT CLASIFQITONS
)ther Not Specify in Remarks
Classified
-------�
TABLE 2.1-5. TWO-LETTER STATE ABBREVIATIONS
UG-2.1.8-13
Alabama
Alaska
Arizona
Arkansas
California
Canal Zone
Colorado
Connecticut
Delaware
District of Columbia
Florida
Georgia
Guam
Hawaii
Idaho
Illinois
Indiana
Iowa
Kansas
Kentucky
Louisiana
Maine
Maryland
Massachusetts
Michigan
Minnesota
Mississippi
AL
AK
AZ
AR
CA
CZ
CO
CT
DE
DC
FL
GA
GU
HI
ID
IL
IN
IA
KS
KY
LA
ME
MD
MA
MI
MN
MS
Missouri
Montana
Nebraska
Nevada
New Hampshire
New Jersey
New Mexico
New York
North Carolina
North Dakota
Ohio
Oklahoma
Oregon
Pennsylvania
Puerto Rico
Rhode Island
South Carolina
South Dakota
Tennessee
Texas
Utah
Vermont
Virginia
Virgin Islands
Washington
West Virginia
Wisconsin
Wyoming
MO
MT
NE
NV
NH
NJ
NM
NY
NC
ND
OH
OK
OR
PA
PR
RI
SC
SD
TN
TX
UT
VT
VA
VI
WA
WV
WI
WY
-------�
UG-2.1.8-14
TABLE 2.1-6. CONTEOL DEVICE DESCRIPTION NOMENCLATURE
Generic Type;
Cyclone
ESP
Wet scrubber
Fabric filter
Other
None
Device Class;
Conventional
Novel
Prototype
Pilot scale
-------�
TABLE 2.1-7. DEVICE CATEGORY KEY WORDS
ESP
1. Wet
2. Dry
3. Hotside
4. Coldside
5. Plate
6. Pipe
7. Hi voltage
8. Low voltage
9. Single chamber
10. Double chamber
11. Other
Cyclone
1. Single
2. Multiple
3. Recirculating
4. Mech. rotor
Wet Scrubber
1. Plate 1.
2. Massive packing 2.
3. Fibrous packing 3.
4. Preformed spray 4.
5. Gas atomized spray
6. Centrifugal 5.
7. Baffle 6.
8. Impingement and entrainment 7.
9. Mechanically aided
10. Moving bed
11. Combination
Fabric Filter
Continuously cleaned
Intermittently cleaned
Reverse air
Mechanical shake
or vibrate
Hi pressure air
Low pressure air
Other
o
to
OO
t-'
(Jl
-------�
TABLE 2.1-8. DESIGN SPECIFICATION TYPE
ESP
Design volume flow rate
Design AP
Design temperature
Units
D*3/s.C
cm WG
°C
Cyclone
Design volume flow rate
Design AP
Design temperature
Units
DNm3/sec
cm WG
°C
Gross mass design
efficiency
Design inlet grain
loading
Total power consumption
Bulk linear velocity
Number of sections
Design applied voltage
Aspect ratio
Specific collecting area
Plate area
ug/m
kWh
m/s
number
volts
dimensionless
2, 3
m /m
m2
Gross mass design
efficiency
Design inlet grain
loading
Total power consumption
Entrance velocity
Number of tubes
Cyclone diameter
Length/diameter ratio
ug/mj
kWh
m/s
number
m
dimensionless
o
I
ho
cx>
I
-------�
TABLE 2.1-8. (Concluded)
Scrubber
Design volume flow rate
Design AP
Design temperature
Gross mass design efficiency
Design inlet grain loading
Total power consumption
Inlet gas velocity
Demister type
Design liquid loading
Entrainment separator type
Units
o
DNnr/sec
cm WG
°C
%
o
ug/mj
kWh
m/s
text
A/m3
text
Fabric Filter
Design volume flow rate
Design AP
Design temperature
Gross mass design efficiency
Design inlet grain loading
Total power consumption
Design air/cloth ratio
Number of compartments
Bag composition
Bag length
Units
DNm3/sec
cm WG
°C
%
3
Hg/m
kWh
o f\
m /m min
number
text
m
o
i
Oo
I
-------�
TABLE 2.1-9. DEVICE OPERATING PARAMETER TYPE
ESP Units
Operating AP cm WG
Gross mass operating efficiency %
Power consumption kwh
Bulk linear velocity m/s
Applied voltage volts
Gas pretreatment text
Rapping frequency number/min
Spark rate number/min
Current density (nA/cnr)
Liquid used text
Liquid loading £/min
Cyclone
Operating AP
Gross mass operating efficiency
Power consumption
Gas pretreatment
text
Scrubber
Units
Fabric filter
Units
Operating AP cm WG
Gross mass operating efficiency %
Total power consumption kwh
Gas pretreatment text
Recycle ratio number
Liquor recycle characteristics text
Effluent liquid treatment text
requirement
Scrubbing liquor type name
Liquor loading jfc/m
Operating AP
Gross mass operating efficiency
Total power consumption
Bag composition
gas pretreatment
Cleaning frequency
Air/cloth ratio
Cloth construction
Cloth weight
Cloth thickness
cm WG
kwh
text
text
number/min
nr/nr min
text
f\
gm/mz
cm
i
to
00
I
00
-------�
UG-2.1.8-19
TABLE 2.1-10. BIOASSAY TEST TYPE
The following data may be used for Bioassay Test Type:
CYTOTOXICITY - ANIMAL
CYTOTOXICITY - HUMAN
MUTAGENICITY - (BACTERIAL STRAIN)
INHALATION
SKIN PAINTING
NEONATAL - MOUSE
-------�
TABLE 2.1-H. SAROAD PARTICULATE POLLUTANT CODES
Code-' Chemical Pollutant
General
Fartlculate (total)
Organic (total) fraction
Benezene soluble organic fraction
Polynuclear hydrocarbons (heterocycllc)
Water soluble organlcs
Aliphatic fraction
Aromatic fraction
Inorganic fraction
Hydrocarbon fraction
Aldehyde fraction
Organic acid fraction
Inorganic
Total element (free and combined)
Aluminum
Antimony
Arsenic
Argon
Beryllium
Bismuth
Barium
Boron
at These codes are Identical to the last four
SAROAD PARAMETER CODING MANUAL (APTD-0633)
1
1101
1102
1103
1104
1105
1110
1111
1113
1114
1115
1116
2
21
2101
2102
2103
2104
2105
2106
2107
2108
digits
•
Bromine
Cadmium
Ca Ic lum
Chromium
Cobalt
Copper
Chlorine
Carbon
Cerium
Cesium
Dysprosium
Erbium
Europium
Fluorine
Gadolinium
S—
Gallium
Germanium
Iron
Hafnium
Lead
Holmlum
Hydrogen
of the SAROAD pollutant
Code
2109
2110
2111
2112
2113
2114
2115
2116
2117
2118
2119
2120
2121
2122
2123
2124
2125
2126
2127
2128
2129
2130
codes for
Chemical Pollutant
Ind lum
Manganese
Irldlum
Molybdenum
Krypton
Nickel
Helium
Lithium
Lutetlum
Magnesium
Iodine
Mercury
Gold
Neodymlum
Neon
Lanthanum
Niobium
Nitrogen
Osmium
Oxygen
Pa 1 lad lum
Phosphorus
suspended, respirable,
Code Chemical Pollutant
2131
2132
2133
2134
2135
2136
2137
2138
2139
2140
2141
2142
2143
2144
2145
2146
2147
2148
2149
2150
2151
2152
and settled |
Platinum
Selenium
Praseodymium
Protactinium
Radium
Rhenium
Rhodium
Tin
Titanium
Samarium
Scandium
Vanadium
Silicon
Sliver
Zinc
Strontium
Sulfur
Tantalum
Tellurium
Terbium
Thallium
Thor lum
articulates, found
Code
2153
2154
2155
2156
2157
2158
2159
2160
2161
2162
2163
2164
2165
2166
2167
2168
2169
2170
2171
2172
2173
2174
In the
Chemical Pollutant
Thu 1 lum
Rubidium
Ruthenium
Tungsten
Uranium
Potassium
Xenon
Ytterbium
Yttrium
Sodium
Zirconium
Group VII Compounds
and Ions
Bromide Ion
Fluoride Ion
Chloride Ion
Iodide Ion
Chlorate Ion
Perchlorate Ion
Bromate ion
Sodium chloride
Potassium chloride
Code
2175
2176
2177
2178
2179
2180
2181
2182
2183
2184
2185
22
2201
2202
2203
2204
2205
2206
2207
2210
2211
d
o
i
to
•
t-«
•
CO
Ni
O
-------�
TABLE 2.1-11. (Continued)
Chemical Pollutant
Calcium chloride
Ammonium chloride
Aluminum chloride
Sodium bromide
Potassium bromide
Sodium iodide
Potassium iodide
Potassium fluoride
Sodium fluoride
Sodium fluorosillcate
Calcium fluorosillcate
Group V Compounds and
Ions
Ammonium ion
Cyanide ion
Nitrate ion
Nitrite ion
llydrazlne
Hydrazolc acid
Ammonium chloride
Ammonium nitrate
Ammonium sulfate
Phosphoric acid
Calcium phosphate
Phosphorous penta-
sulflde
Code
2212
2213
2214
2230
2231
2250
2251
2270
2271
2275
2276
23
2301
2304
2306
2309
2310
2311
2320
2321
2322
2340
2341
2342
Chemical Pollutant
Phosphorus pentoxlde
Phosphate ion
Hydrogen phosphate ion
Dlhydrogen phosphate
ion
Group VI Compounds and
Ions
Sulfide ion
Sulfurlc acid
Sulfate Ion
Thlosulfate Ion
Sulflte ion
Ferrous sulfide
Ferric sulfide
Ferrous sulfate
Ferric sulfate
Barium sulfate
Chromium trioxide
Sodium dlchromate
Zinc oxide
Aluminum oxide
Water
Group IV Compounds and
Ions
Carbonate ion
Code
2343
2345
2346
2347
24
2401
2402
2403
2404
2410
2411
2412
2413
2414
2415
2417
2418
2430
2431
2450
25
2501
Chemical Pollutant
Bicarbonate ion
Carbon boride
Silicon carbide
Silicate Ion
Silicon dioxide
Acids and Bases
Total acidity H+
Hydrogen ion con-
centration pH
Nitric acid
Hydrochloric acid
Total alkalinity
Hydroxide Ion con-
centration
Calcium hydroxide
Organo -Metal lie Com-
pounds and tons
Miscellaneous
Aliphatic Compounds
Gross hydrocarbons
Hydrocarbons
Heptane
Octane
Nonane
Code
2502
2510
2511
2550
2551
26
2601
2602
2605
2606
2650
2651
2653
27
28
6
61
62
6201
6202
6203
Chemical Pollutant
Decane
Undecane
Dodecane
Tridecane
Tetradecane
Pentadecane
llexadecane
Heptadecane
Octadecane
Nonadecane
Elcosane
Hemelcosane
Docosane
Trlcosane
Tetracosane
Pentacosane
Hexacosane
Heptacosane
Octacosane
Cyclohexane
Cycloheptane
Cyclooctane
Heptene-1
Octene-1
Code
6204
6205
6206
6207
6208
6209
6210
6211
6212
6213
6214
6215
6216
6217
6218
6219
6220
6221
6222
6223
6224
6225
6226
6227
Chemical Pollutant
Alcohols and Ethers
Butyl alcohol
lap-Butyl alcohol
sec-Butyl alcohol
tert -Butyl alcohol
n-Arnyl alcohol
iso-Amyl alcohol
tert-Amyl alcohol
n-Hexyl alcohol
Cyclohexanol
n-Octyl alcohol
Capryl alcohol
(octanol-2)
Decyl alcohol
Laiiryl alcohol
Hyrlstyl alcohol
Cetyl alcohol
Stearyl alcohol
Dl-n-butyl ether
Di-n-arayl ether
Di-lso-amyl ether
Di-n-Uexyl ether
Di-chloromethyl
ether
Code
63
6301
6302
6303
6304
6305
6306
6307
6308
6309
6310
6311
6312
6313
6314
6315
6316
6340
6341
6342
6343
6344 S
ro
i-1
00
NJ
-------�
TABLE 2.1-11. (Continued)
Chemical Pollutant
Dl-O-chloroethyl)
ether
Ethylene glycol
dimethyl ether
Dlvlnyl ether
Dlallyl ether
Carboxyllc Acids and
Esters
Proplonlc acid
N-Butyrlc acid
Iso-Bytyrlc acid
n-Valerlc acid
Trlmethylacetlc acid
Ca prole acid
n-Heptyllc acid
Ca pry lie acid
Pelargonlc acid
Fluoroacetlc acid
Cliloroacetlc acid
Bromoacetlc acid
lodoacetlc acid
Dlchloroacetlc acid
Trlchloroacetlc acid
QT-Chloroproplonlc acid
B-Chloroproplonlc acid
Code
6346
6347
6348
6349
64
6401
6402
6403
6404
6405
6406
6407
6408
6409
6410
6411
6412
6413
6414
6415
6416
6417
Chemical Pollutant
Glycoilc acid
Lactic acid
Hethoxyacetlc acid
ThloglycoHc acid
Cyanoacetlc acid
Glyoxyllc acid
Acrylic acid
Vlnylacetlc acid
Pheynlacetlc acid
Formic acid
Acetic acid
Crotonlc acid
Oxalic acid
Ha Ionic acid
Succlnlc acid
Glutarlc acid
Adlplc acid
Plmellc acid
Suberic acid
Azelalc acid
Sebaclc acid
Aldehydes and Ketonea
Caproa Idehyde
Code
6418
6419
6420
6421
6422
6423
6425
6426
6427
6428
6429
6430
6431
6432
6433
6434
6435
6436
6437
6438
6439
65
6501
Chemical Pollutant
Heptaldehyde
Hexanone-2
Hexanone-3
Dl-n-propyl ketone
Dl-lso-propyl ketone
Dl-lso-butyl ketone
Dl-n-amyl ketone
Stearone
Chloroacetone
Dlchloroacetone
Acetylacetone
Hesltyl oxide
Phorone
Cyc lohexanone
Acroleln
Other Oxygen Compounds
Nitrogen Compounds
Trl-n-propy lamlne
Hexylamlne
Laury lamlne
Trlmethylenedlamlne
Tetrame thy lened lamlne
Pent amethy lened lamlne
Code
6502
6504
6505
6506
6507
6508
6509
6510
6511
6512
6513
6514
6515
6516
6517
66
67
6701
6702
6703
6704
6705
6706
Chemical Pollutant
Hexanethylenedlamlne
Ethano lamlne
Dlethanolaralne
Trlethano lamlne
Acrylonltrlle
Halogen Compounds
He thy lene Iodide
Bromoform
Carbon tetrabromlde
Ethylene dlbroraide
1,1-Dlbromoe thane
1.1,2,2-Tetrachloro-
Hexachloroe thane
1 , 3 -Dlbromopropane
1 ,4-Dlbromobutane
1,5 -Dlbroraopentane
1 ,6-Dlbromohexane
Miscellaneous
Aromatic Compounds
Simple and gross
hydrocarbons
Benzene
Toluene
Code
6707
6708
6709
6710
6711
68
6801
6802
6803
6804
6805
6806
6807
6808
6809
6810
6811
69
"
7
71
7101
7102
Chemical Pollutant
Ethy Ibenzene
n- Propy Ibenzene
tso-Propy Ibenzene
n-Buty Ibenzene
sec-Buty Ibenzene
tert-Buty Ibenzene
Styrene
Allylbenzene
o-Xy lene
m-Xylene
j>-Xy lene
p_-Ethyltoluene
m-Ettiyl toluene
£-Ethyltoluene
j>-Cymene
o-Dle thy Ibenzene
m-Dlethy Ibenzene
£-Dlethy Ibenzene
1,2,3-Trlmethyl-
benzene (hemi-
mellltene)
1,2,4-Trimethyl-
benzene (pseudo-
cumene)
Code
7103
7104
7105
7106
7107
7108
7109
7110
7111
7112
7113
7114
7115
7116
7117
7118
7119
7120
7121
7122
a.
o
!-•
co
i
ro
-------�
TABLE 2.1-11. (Continued)
Chemical Pollutant
1,3,5-Trlmethyl-
benzene (mesltylene)
1,2,3,4-Tetramethyl-
benzene (prehnltene)
1,2,3,5-Tetramethyl-
benzene (laodurene)
1,2,4,5-Tetramethyl-
benzene (durene)
Pentamethylbenzene
Hexaraethylbenzene
1,3,5-Triethyl-
benzene
Dipheny line thane
Tripheny Imethane
Tetraphenylmethane
Stllbene
1 , 1 -Dipheny lethane
1 ,2 -Dipheny lethane
Diphenyl
£-Terphenyl
£-Quaterpheny 1
1, 3, 5 -Trlpheny 1-
benzene
Naphtalene
a-Methylnaphthalene
B-Methylnaphtha lene
Code
7123
7124
7125
7126
7127
7128
7129
7131
7132
7133
7134
7135
7136
7137
7138
7139
7140
7141
7142
7143
Chemical Pollutant
Indene
Azulene
Acenaphthene
Acenaphthalene
Fluorene
Phenanthrene
Anthracene
2 -Methy lanthracene
Complex Hydrocarbons
Fluoranthcne
8-Methylf luoranthese
Pyrene
1-Methylpyrene
4-Methylpyrene
2 ,7-Dlmethylpyrene
Chrysene
Anthanthrene
Coronene
Perylene
Naphthacene
Benzo(£) phenanthrene
Benzo(a) anthracene
ll-h Benzo(b_)£luorene
Code
7145
7146
7147
7148
7149
7150
7151
7152
72
7201
7202
7204
7205
7206
7207
7208
7210
7211
7212
7213
7214
7215
7216
Chemical Pollutant
ll-h Benzo(a)f luorene
7-h Benzo(c)f luorene
Dlbenzo(a , i)f luorene
Benzo(b ) f luoranthrene
Benzo(g,h,l)-
£ luoranthene
Benzo( j) f luoranthene
Benzo(k)f luoranthene
Benzo(e) pyrene
Na phtho( 2 , 3-a ) pyrene
Dibenzo (a, e) pyrene
Dlbenzo(a , i) pyrene
Dibenzo( a (h) pyrene
Dlbenzo(b,h)phen-
anthrene
Dlbenzo(a.h)-
anthracene
Tr ibenzo(a ,c ,h) -
anthracene
Benzo(a)naphthacene
Dlbenzo(a,l)-
naphthacene
Dibenzo(a.J)-
naphthacene
Dibenzo(a.c)-
naphthacene
Code
7217
7218
7219
7220
7221
7222
7223
7224
7226
7227
7228
7229
7230
7231
7232
7233
7234
7235
7236
Chemical Pollutant
8enzo(g9h,i}-
pcrylene
Dlbenzo(b , p ,g , r) -
perylene
Benzo(a) pyrene
Phenols and Ethers
o-Cresol
m-Cresol
£-Cresol
o-Chlorophenol
m-Chlorophenol
£-Chlorophenol
o-Bromophenol
m-Bromo phenol
£-Bromophenol
o-Nltrophenol
m-Nltrophenol
£-Nltrophenol
2,4-Dlnltrophenol
3,5-Dlnitrophenol
Reaorcinol
Hydroqulnone
Catechol
Pyrogallol
Code
7237
7238
7242
73
7301
7302
7303
7304
7305
7306
7307
7308
7309
7310 „
7311
7312
7313
7314
7315
7316
7317
7318
Chemical Pollutant
Phlorogluclnol
Anisole
Phenetole
Diphenyl ether
(D-anialdine
£-Anlsidlne
Carboxyllc Acids and
Esters
Aldehydes and Ketones
Xanthen-9-one
7h-Benzo(d,e)-
anthracene-7-one-
(benzanthrone)
Phenalen-1-one
Other Oxygen Compounds
Nitrogen Compounds
Aniline
o-Phenylenediamlne
m-Phenylenediamine
£-Phenylenediamine
o-Anisidlne
£-Anlsldine
o-Ch lor oani line
m-Ch loroan 1 1 Ine
Code
7319
7340
7341
7342
7343
7344
74
75
7501
7502
7503
76
77
7701
7702
7703
7704
7705
7706
7707
7708
C
1
to
CO
1
to
-------�
TABLE 2.1-11. (Concluded)
Chemical Pollutant
j>-Chloroanlllne
o-Toluldlne
m-Toluldlne
ji-Toluldlne
Diphenylamlne
Trlpheny lamine
Benzldlne
Halogen Compounds
Miscellaneous
Heterocycllc Compounds
Nitrogen Compounds
Pyrldlne
or-Plcollne
B-Plcollne
Y-Picollne
Qulnollne
Isoqu Incline
Qulnaldlne
Indole
Acrid Ine
Carbazole
Benzo(f )qulnollne
Benzo(h)qulnollne
Phenanthr Id Ine
Code
7709
7710
7711
7712
7713
7714
7715
78
79
8
81
8101
8102
8103
8104
8105
8106
8107
8108
8109
8110
8111
8112
8113
Chemical Pollutant
Benz(a)acrldlne
Benz(c)acrldlne
llh-Benzo(a)carbazole
5li-benzo(h)carbazole
7h-Benzo(b)carbazole
Dlbenz(a ,h)acrldlne
Dlbenz (a , j)acrld Ine
Benzo( l,ra,n)phen-
anthridlne
lndeno(l, 2,3-1, J)-
laoqulnollne
9-Acrldanone
Oxygen Compounds
Benzofuran
Dlbenzofuran
Furfural
Sulfur Compounds
Nitrogen and Oxygen
Compounds
Sulfur and Oxygen
Compounds
Sulfur and Nitrogen
Compounds
Other
Code
8114
8115
8116
8117
8118
8119
8120
8121
8122
8123
82
8201
8202
8203
83
84
85
86
87
o
i
to
CO
-------�
UG-2.1.8-25
TABLE 2.1-12. LIST OF CHEMICAL ANALYSIS CODES
Analysis Method Alphabetic Code
1. Atomic absorption (flame or flameless) A
2. Chemiluminescence B
3. Conductametric method (specify in comments) C
4. Colorimetric method (specify in comments) D
5. Electrometric method (coulometry, potentiometry,
etc.) E
6. Flame ionization F
7. Gravimetric method (specify in comments) G
8. Infrared absorption (IR) I
9. Nondispersive infrared absorption J
10. Gas chromatography K
11. Thin-layer chromatography L
12. Nuclear magnetic resonance (NMR) M
13. Neutron activation method N
14. Photometric method (e.g., "flame;" specify in
comments) P
15. Beta gauge (Carbon-12) Q
16. Mass spectrographic method (e.g., "spark-source;"
specify in comments) R
17. Emission spectrographic method (e.g., muffle
furnace; specify in comments) S
18. Titrimetric (specify in comments) T
19. Turbidimetric (e.g., pH meter; specify in comments) . U
20. "Wet Chemistry" method (e.g., Jacobs Method;
specify in comments) W
21. Optical evaluation method (e.g., reflectance,
transmittance; specify in comments) X
22. Other (specify in comments) Z
-------�
UG-2.1.8-26
TABLE 2.1-13. STANDARD NOMENCLATURE FOR MEASUREMENT EQUIPMENT
Generic Class Type
Impactor BRINKS BMS-11 IMPACTOR
ANDERSEN MODEL II
IMPACTOR
ANDERSEN MODEL III
IMPACTOR
Description
Conventional Brinks sampler with
a precyclone having a 7 H-m cut size
Andersen stack sampler with stain-
less steel collection plates
Modified Andersen sampler with
glass fiber filter collection
surface
Optical
particle
counter
ANDERSEN MODEL IV
IMPACTOR
UW MARK III IMPACTOR
TAG IMPACTOR
OTHER IMPACTOR
ROYCO MODEL - OPC.
CLIMET MODEL - OPC
BAUSCH & LOMB MODEL
40-1 - OPC
Modified Andersen sampler with
glass fiber filter collection
surfaces and a cyclone pre-
co Hector
University of Washington cascade
impactor manufactured by Pollu-
tion Control Systems, Inc.
Multiple slit cascade impactor
manufactured by Environmental
Research Corporation or Sierra
Instruments, Inc.
Any other impactor, including
modified versions of the above
Manufactured by Royco Instruments,
Inc., Menlo Park, California
Manufactured by Climet Instruments,
Inc., Sunnyvale, California
Manufactured by Bausch & Lomb,
Rochester, New York
OTHER - OPC
As necessary
-------�
UG-2.1.8-27
TABLE 2.1-13. (Concluded)
Generic Glass
Type
Condensation GENERAL ELECTRIC - CNC
nuclei counter
RICH 100 - CNC
Description
Manufactured by General Electric,
Pittsfield, Massachusetts
Diffusion
battery
OTHER - CNC
CLUSTER TUBE - DIFF
BATTERY
RECTANGULAR TUBE -
DIFF BATTERY
CHS - DIFF BATTERY
WIRE SCREEN DIFF
BATTERY
of David Sinclair design with
collimated hole structure
Manufactured by Thermo-Systems, Inc.
Electrical
analyzer
WHITBY ELECTRICAL
ANALYZER, MODEL
3030
Manufactured by Thermo-Systems, Inc.
Miscellaneous MOBILITY ANALYZER
CYCLONES
COULTER COUNTER
ELECTRON MICROSCOPE
OPTICAL MICROSCOPE
Other
Measuring equipment not otherwise
classified
-------�
UG-2.2-1
2.2 General Instructions for FPEIS Data Input Forms
The FPEIS Standard Data Input forms are given in Figure 2.2-1. Certain in-
structions that apply to data coding include the following:
• Zeros are treated as numbers. Blank spaces in a field indicate either
a lack of data or that the pertinent data have been coded for the
preceding test subseries or test run. All numeric data shall be
right-justified and all alphanumeric data shall be left-justified,
except where noted otherwise.
• Only specified alphabetical or numerical characters are allowed
to be entered in the columns. No unusual marks are to be made in
the spaces. No data field headings are to be changed and only data
appropriate to the field are to be entered. This rule prevents
unnecessary keypunching errors in processing the forms.
• Only the allowed coding values may be entered in columns that re-
quire coding symbols.
• Instructions for filling out each card on the form are quite spe-
cific and were designed to apply to the large majority of source/con-
trol system combinations. Nevertheless, it is recognized that assump-
tions must occasionally be made to reflect the real, physical situa-
tion for an unusual source/control system combination. Care should
be taken to make reasonable assumptions that most nearly correspond
to the true circumstances for the source/control system combination
tested.
-------�
UG-2.2-2
• If there are more than one source emitting into a control system,
the description of one should be given and other data should be
indicated in the test series remarks. The criteria is to note the
source parameters which affect the physical, chemical, and biologi-
cal nature of the particulate rather than quantity of particulate.
• When more than one control device is used, use a separate data in-
put Form No. 2 for each control device used. Be sure to give the
control device number. Up to three (3) control devices in series
may be coded for a given source gas stream.
• When more than one test run was made, use a separate data input
Form No, 6 for each run. Be sure to indicate the measurement in-
strument/method number.
• Whenever the data exceeds the available space, it can be given in
the remarks or comments of the appropriate level (i.e., test series,
subseries, or run remarks). In such cases, however, both the data
element and its value should be given and not just the data ele-
ment value.
• Whenever there are pertinent data for which no data element exists,
such data can be given in the remarks of the appropriate level.
-------�
UG-2.2-3
• Whenever text items are being completed, care should be exercised
to leave np_ blank cards between completed cards. Also, try to make
the text as brief as possible through the use of abbreviations,
precise words, and elimination of redundant words. The text should
always start at the left most column (i.e., left-justified). Table
2.2-1 gives a list of commonly accepted abbreviations which may
be used.
• The small triangle between columns represents the decimal point.
Enter the fractional decimal digits to the right of the triangle.
When + is indicated at the top of the column, enter either + or
- as appropriate.
• Leave all the hatched-out portions blank.
• The following identification data elements must be filled on first
card of every section (data group). There may be no blanks.
Data Element Card Columns Instructions
Test series number 1-5 Enter on all forms.
Subseries number 6-8 Enter on Forms Nos. 4 through 6.
Blank on Forms Nos. 1 and 2.
Run number 9-10 Enter only on Form No. 6. Blank
on Forms Nos. 1 through 5.
Detailed instructions are given in Section 2.3 for completing each card
in the input forms.
-------�
TABLE 2.2-1. ABBREVIATIONS FOR STREET DESIGNATORS AND FOR WORDS THAT APPEAR FREQUENTLY IN PLACE NAMES
Word
Audemy '.,.,....
Agentf
Affport... „.;.;;..
Afley
Awiei .,
Arc»Je , ;;;....
Awial
Aver**
Bayou
back.../.
Box!
BUtk
Boulevard
B:«n
Bortom
B'anch
Bodge
Bowk
Bypass....:
Cannon
Cw
CMitmv
Cf>'c* *
r.n.i.t\
fK'?;h .
CK.it nts . ,.
Oile
Clear
Chit ; . ..
Cwfeje
Oner
Carers
Ccyl
Courts .
Cove
Creek ,,..-
Crescent „....
C'nsifti ...
Caif
D*f
Cf pul
Divide
Out
(ail
UUtM
ACAO
AGKCY
ARPKI
AIY
ANX
ASC
..;: AftSl
. AVi
BYU
BCH
BUD
BG
BIK
81VO
BLF
Bra
BR
BRG
BRK
BG
8YP
CP
CYN
CPf
CWSt
CIH
cn
CHR
CHRS
CIR
CY
cm
ClfS
CtB
CIG
......... COR
CURS
CI
CIS
cv
..... CRK
CRFS
XiHG
W.
PM
OPO
orv
wt
t
......... tsi
Word
C«prnswty
(•tended .. .
Eitension
fall
falls
fjims
feiry
Field
fields \
flats
foid
forest
foige
Fork
Foiks
Fort
Fountain:
Fr«»jy
furnace
GaicNs
Gateway
Glen
Grand
Grwt
Gimn
Gcountl....,
Grove
Hartof
Hiven
H»i«ht»
High
Highlands
Hi«h«i|
Hill
Hills
Hollow
• Hospital
Hot
House
Inlel
Institute
Island
Isle
Junction
Key
' Knolls
Undinf
like
Like;
Abbreviation
IXt
CXI
fl
FIS
FRMS
FRY
flO
FIDS
Fll
FRO
IRSI
FRG
IRK
IRKS
fl
flit
rwr
FUKN
GDNS
GIWY
GIN
GRND
GR :
CKfl
GRD
CRV
HBR
HVN
HIS
HI
HCIDS
HWY
Ill
HIS
HOIW
HOSP
H
USE
Mil
INSI
IS
IS
IS
ICI
KY
KNIS
INDG
Ill
IKS
Uw
lilht
little
1 ml
locks
lolge
loiter :
Minor
Miadows
Meeting
Memorial
Middle
Mile :
Mill
Mills
Mines
Mission
Miund
Mtunt
Maintain
NlllOMl
Neck
New
Moith ,
C,ch«<
Palms
Prk
Pakway
Filial
Pmei
Plxe
run
Pl,nns
Rin
Pun
Poml
Pun is ,
SiXh ,
RiKhei
Ri^ids
Resort
Rest
Rrlge
Rrer
R;>d
Reck
Real ,. . .
Sinl ,
Sa.ntl
IN
LCI
in
If
ICKS
IOC
IWS
MNR
MOWS
MIC
MEM
MM.
Mlf
Ml
MIS
MNS
MSN
UNO
MI
, MIN
, NAI
, NCX
N
OUCH
PLMS
PK
PKY
PIR
PNfS
PI
PIN
PINS
PtZ
PKl
P!
PR
BiCH
RNCHJ
WOS
RtSRI
RSI
ROD
RIV
RD
,. RK
R
SI
SI
Wort
Saa
Santa
S»nto ,
School ,
Seminary
Shoal ,
Shoals ,
Shofc
Shore
Shot}
Sidinf
South
Space flight Carter
Sprinf
Spungs
Square
Slate
Station ,
Sliett
Stream
Sulphur
Summit
Switch
teiitci »
Ion
lower
lown
Irail
tunnel
turnpike
Upper /
Union
University
Valley
Viaduct
View
Village
Ville ...
Vista
Watet
WelU
West
White
Works
Yafds
SN
S»
M
SCM
suwrr
SHI
SHIS
SHO
SHR
SWB
SOG
S
SIC
SPC
SPGS
so
SI
SIA
SI
SIR*
SIP*
, SMI
SWCH
TNRY
IVHN
: :.. im
IN
fw»
, i lYOI
IRl
tm»
IUNI
UN
UNIV
. VtY
VIA
vw
«G
n
VIS
fffR
WLS
w
WHT
. .. WKS
. YDS
O
N)
.
to
-------�
STATIONARY POINT SOURCE
Form 1 12/76
A
- SOURCE
Test Series
No.
1
2
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INPUT FORMS
DESCRIPTION
Seties,
No.
Run
No,
ID
Card
No.
II
A
12
0
13
1
Card
No.
II
A
12
A
13
2
Card
No.
II
A
12
0
13
3
Card
No.
II
A
12
0
13
4
Card
No.
II
A
12
0
13
5
14
U
14
14
M
n
»
IS
14
15
SCC 1 (Source Category)
16
17
It
19
20
21
22
23
24
25
24
27
28
29
30
31
32
SCC II (Type of Operation)
33
34
35
SCC IV (Operating Mode Class)
16
17
18
19
20
21
22
23
24
29
24
27
28
29
30
31
32
33
34
35
34
37
38
39
(0
41
42
43
44
45
44
47
48
49
Form Completed by
SCC III (Feed Material Class)
50
91
92
53
54
55
54
57
58
59
40
61
42
43
44
45
66
Test Series
Start Dote
Mo
47
68
Da
49
70
Yr
71
72
Finish Dale
Mo
73
74
Da
79
Site Name
34
37
38
39
40
Source Name
16
17
Zip
16
17
18
19
20
18
19
20
21
22
23
24
29
24
27
28
29
UTM Coords
X
21
22
23
24
Y
29
24
27
28
29
30
»
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45
44
47
48
49
50
91
92
53
54
55
54
57
58
59
60
Street
41
42
43
44
45
46
47
4t
49
50
91
52
53
54
55
54
57
58
59
40
61
42
43
64
45
44
47
48
49
70
71
72
73
74
75
76
Yr
77
78
UTM
Zone
79
80
>*
77
78
City
61
42
43
44
49
46
47
48
49
70
71
72
73
74
75
76
77
78
7»
80
State
7?
80
Tested By
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45
46
47
48
49
50
91
52
53
54
59
54
57
5t
59
40
41
42
63
44
49
44
47
48
49
70
71
72
73
74
75
Reference '.
14
17
It
19
20
11
22
23
24
29
24
27
28
29
30
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45
46
47
48
49
50
91
92
53
54
95
54
57
58
59
60
41
42
43
44
49
64
47
68
49
70
71
72
73
74
75
76
77
78
79
to
tt
77
n
77
80
B - TEST SERIES REMARKS
Test Series
No. i
1
2
3
\
4
5
Sot '
Serifti
Ho.
6
7
8
Sun
N6.
9
\(
Cord
No.
II
B
B
B
B
B
B
B
B
B
B
12
0
0
0
0
0
0
0
0
0
1
13
1
2
3
4
5
6
7
8
9
0
M
15
Remarks in Text '
14
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45
44
47
48
49
50
51
52
53
94
55
54
57
98
59
40
41
42
43
44
45
46
47
68
69
70
71
72
73
74
75
76
77
78
79
80
Figure 2.2-1. FPEIS Standard Data Input Forms.
o
ro
i
Ol
-------�
STATIONARY POINT SOURCE
Form 2 12/76
C - CONTROL
Test Series
No.
I
1
3
4
3
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INPUT FORMS
DEVICE(S) CHARACTERISTICS
Sub
Series
Ms.
6
t
ft
Run
No.
*
(«
Card
No.
II
C
12
0
13
\
Card
No.
II
C
12
0
13
2
Card
No.
II
C
12
0
13
3
Card
No.
II
C
12
0
13
4
[
t
14
»*
\4
14
—
H
*
1*
-Device No. (1,2 or 3)
Device Category
16
17
IB
1?
20
21
22
23
24
29
26
27
26
29
30
31
32
33
34
39
36
37
38
39
40
41
42
43
44
45
Commercial Name
16
17
18
19
20
21
22
23
24
29
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
Device Class
49
50
51
52
93
94
55
56
57
58
59
60
Form Completed by
Generic Type
61
62
63
64
U
66
67
68
69
70
71
72
73
74
75
Manufacturer
46
47
48
49
90
51
92
93
94
55
56
57
51
59
60
61
62
63
44
65
66
67
68
69
70
71
72
73
74
75
J.
Device Description
16
15
17
1*
19
20
21
22
23
24
29
26
27
38
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
91
52
93
94
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
Device Description (continued)
16
17
U
19
20
21
22
23
24
29
26
27
21
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
91
53
93
54
95
96
57
98
99
60
61
62
61
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
SO
«
77
ft
if
84
It
n
n
TV
to
H
77
ft
7»
to
CONTROL DEVICE(S) DESIGN PARAMETERS
Test Series
No.
I
2
3
4
5
Sub
S«rtw
Ntt. =
6
7
8
Run
No.
»
10
Card
No.
II
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
13
5
5
5
5
5
5
5
5
5
5
5'
5
3
5
5
5
5
5
5
5
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14
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Si
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16
17
-Device No. (1.2 or 3)
Specifications
18
19
20
21
22
23
24
29
26
27
28
29
30
31
32
33
34
35
16
37
38
39
40
41
42
43
44
45
46
47
Value
48
49
50
51
92
93
94
55
96
97
98
99
60
61
62
63
64
65
66
67
-------�
STATIONARY JpOINT SOURCE
Form 3 12/76
D •
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INJPUT .FORMS
- TEST CHARACTERISTICS
Teil Series
No. ;
l
2
3
4
'
3
Sub
Series
No.
4
7
1
fiyn
No.
*
to
Card
No.
II
D
12
0
13
1
Card
No.
II
D
12
0
13
2
Card
No.,
II
D
12
0
13
3
Card
No.:
II
D
12
0
13
4
t«
t*
14
\t
r
13
t*
15
1*
— Control Device Inlet or Outlet (1 or
Test Sub Series
Date
Ma
14
17
Da
18
19
Yr
20
21
Start
Time
22
23
24
25
Stop
Time
24
27
28
2?
0)
Source Operating Mode'
30
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45
44
47
48
49
30
51
52
53
34
55
54
57
38
59
Form Completed by
Source Operating Rate*
40
41
42
43
44
43
44
47
48
49
70
71
72
n
74
75
74
% Design
Capacity
77
78
79
80
Feed Material * [Feed Material Composition*
14
17
16
19
20
21
22
23
24
25
24
27
2B
29
30
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45| 44
J
47
48
49
50
31
52
53
34
55
Sampling Location Description*
14
17
16
19
C02*<
14
17
IS
19
20
21
22
23
co*;
20
21
22
23
24
23
24
27
02*
24
23
24
27
28
29
30
31
N2*
28
29
30
31
32
33
34
33
34
37
38
39
40
41
42
43
44
49
44
47
48
49
30
31
32
33
34
35
54
37
58
59
40
41
Volume
Flow Rate*
54
37
56
59
40
t
41
42
43
44
45
Velocity*
42
43
44
45
44
47
48
49
Temp*
44
47
48
49
70
71
72
73
74
Press.*
70
71
72
73
74
75
74
77
% H2O
75
n
77
78
79
80
% Iso .
Kinetic
76
79
80
Trace Gases in ppm (Text)
32
33
34
33
34
37
38
39
40
41
42
43
44
45
44
47
48
49
50
51
52
53
34
55
54
57
58
59
40
41
42
43
44
45
46
47
48
49
70
71
72
73
74
75
74
77
76
79
60
CONTROL DEVICE(S) OPERATING PARAMETERS
Test Series
No.
1
Sub
Series
No.
ftun
No.
w
Card
No.
II
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
13
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
r
14
**
'iff
:$:
:£x
•*£
:8
Hi;
is
::::::
:Xv
:•:•:•
•:-:•:
::::::
::::;:
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%?•
HS
*K
If
14
17
-Device No. (1.2 or 3)
Specification *
16
19
20
21
22
23
24
25
24
27
28
-
29
30
31
32
33
34
35
34
37
38
39
40
41
42
43
44
45
44
47
Value*
48
49
5C
51
52
53
34
55
34
57
38
59
40
41
42
43
—
44
—
45
44
47
4»
W
m
71
72
7J
74
—
7i
74
77
71
79
60
Need not be filled if the preceding subseries contains the same data.
Figure 2.2-1. Continued.
o
to
i
-------�
STATIONARY POINT SOURCE
Form 4 12/76
rilNC I-MK 1 1 V.ULM 1 C C IV\ 1 i S 1
m
Other Physical Properties in Text ';
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
30
51
52
53
34
55
54
57
58
59
60
61
42
43
44
45
44
47
48
49
70
71
72
73
74
75
74
77
78
79
80
O
to
I
00
* Need not be filled if the preceding subseries contains the same data.
Figure 2.2-1. Continued.
-------�
STATIONARY POINT SOURCE
FormS 12/76
G
- PARTICULATE
Test Series
No.
1
H
2
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
• . DATA INiPUT FORMS
BIOASSAY DATA
Sub
Series
No.
- CHEMICAL
Test Series
No.
1
2
to*
Mo,
10
Card
No.
II
G
G
G
G
G
12
0
0
0
0
0
13
.
14
t*
Bloassay Test Type
16
17
18
COMPOSITION !
Sub
Series
No.
Run
No.
16
Card
No.
II
H
12
0
13
1
Cord
No.
II
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
a
13
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
\4
U
tf
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©
27
26
v>
•
30
31
32
±
27
28
•
•
•
•
•
•
•
•
•
•
•
*
•
•
•
•
•
•
•
•
•
•
•
•
•
29
30
31
32
©
33
34
35
•
36
37
38
©
±
33
34
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
35
36
37
38
Particle Bout*
39
40
41
•
42
43
44
®
±
39
40
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
41
42
43
44
dary Diameter *
45
46
47
•
46
49
50
Chemica
©
±
45
46
•
•
•
•
•
•
•
•
*
•
•
•
*
•
•
•
•
•
•
•
•
•
•
•
•
47
46
49
50
(D
51
52
53
•
54
55
56
Concentration i
±
51
52
•
•
•
•
•
•
•
•
•
»
•
•
•
•
•
•
*
•
•
•
•
•
•
•
•
53
54
55
56
©
57
58
5»
•
60
61
62
/ig/m3)
±
57
SB
•
•
•
*
•
•
•
•
•
•
•
•
*
•
•
•
•
•
•
•
•
•
•
•
•
59
60
61
62
©
63
64
65
•
66
67
68
©
±
63
64
*
•
•
•
•
•
•
•
•
*
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
65
66
67
66
®
69
70
71
•
72
73
74
±
69
70
•
•
•
•
•
»
•
•
•
*
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
71
72
73
74
®
75
76
77
•
78
79
80
®
±
75
76
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
*
*
*
•
•
77
78
79
80
Need not be filled if the preceding subserles contains the same data.
Fig.ure 2.2-1. Continued.
o
fo
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-------�
STATIONARY POINT SOURCE
Form 6 J2/76
I-
FINE PARTICIPATE EMISSIONS INFORMATION SYSTEM
DATlA INPUT FORMS
MEASUREMENT PARTICULARS
Test Ser
No.
1
2
l
es
4
5
Sub
Series
No.-
4
1
»
Run
No.
9
10
Card
No.
II
I
12
0
13
1
Card
No.
II
I
12
0
13
2
Card
No.
II
I
I
I
12
0
0
0
13
3
4
5
I"
M
M
t*
1
'
"™
IS
'
U
I>
—Measurement Instrument/Method No.
Measurement Instrument/Method Name
16
17
18
19
20
21
22
23
24
25
•*
Measurement Size Range
Lower
16
17
18
IV
20
Upper
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
Meas.
Start Time
46
47
46
49
Sampling
Period**
50
51
52
53
1
S4
Aerosol
Flow Rote**
ss
56
57
58
A
59
60
Form Completed by
Gas Conditions at tt
Measurement Location
Temp.
61
63
63
64
Press.
65
66
67
68
69
%H2O
70
71
A
72
73:
M
?!
Dilution
Factor**
76
77
78
79
.
80
Collection Surface/Substrate and its Specifications*
26
27
28
29
30
31
32
33
34
35
36
37
38
39)40
41
42
43
44
45
46
47
48
49
50
51
52
S3
S4
55
36
57
58
59
60
61
a
63
M
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Comments on the Measurement
16
17
18
1*
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
SO
51
52
S3
S4
SS
56
57
58
59
60
61
a
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
J - PARTICULATE SIZE DISTRIBUTION DATA i
Test Series
No. :
l
2
3
Sub
Series
No.
Run
No.
10
Card
No.
II
J
J
J
12
0
0
0
13
1
2
3
Card,
No.
II
J
J
J
12
0
0
0
13
4
5
6
r
14
r
14
r
15
<
r
15
—Measurement Instrum
— Aerodynamic/Stoke
is
17
IB
19
20
•
•
•
21
22
23
—Measurement Instrumc
—Mass/No. (1 or 0)
±
M
17
18
•
•
•
19
20
21
22
23
ant/Method No.
l Diameter (1 or 0)
24
is
26
27
28
•
•
•
29
30
31
mt/Method No.
t
r*
25
26
•
•
•
27
28
29
30
31
32
33
34
35
36
•
•
•
37
38
39
±
K
33
34
•
•
•
35
36
37
38
39
Particle '.
4
-------�
UG-2.3-1
2.3 Encoding Instructions
This section presents detailed, card-by-card encoding instructions for each
FPEIS data element. The discussion is separated into ten groups correspond-
ing to the major data groupings of FPEIS data. The FPEIS Data Input Form
number is given for each group, and an example completed form is shown for
each group of data.
Each card type has been designated REQUIRED CARD or CARD NOT REQUIRED. This
pertains to the minimum data set requirement. Some data, such as, control
device design and operating parameters, bioassay or chemical analysis,
may not be available, and consequently, there would be no data to enter.
These cards as well as those pertaining to comments are not required to be
part of the minimum data set. Other cards may or may not be required depend-
ing upon a previous card. For example, the C01 card describes the applied
control device. If there is no applied device (i.e., an uncontrolled source),
then cards CO2-COS and D05 are not needed. Otherwise, all of these cards
must be present.
-------�
UG-2.3.1-1
2.3.1 Section A - Source Description - Form 1
Card Columns
Data Element
CARD A01 (REQUIRED CARD)
1-5 Test Series Number
6-8
9-10
11-13
14-15
16-32
Subseries Number
Run Number
Card Letter and
Number
Special Code
SCC I
33-49
50-66
67-72
SCC II
SCC III
Test Series Start
Data
Encoding Instructions
Enter a nonzero, sequential number
for each test series reported, right-
justified. This number will be used
for preliminary identification pur-
poses only. A permanent FPEIS test
series number will be assigned by
the FPEIS data base administrator
when the data are entered into the
FPEIS.
Leave blank.
Leave blank.
Do not change.
Leave blank.
Enter Source Classification Code
I description (source category) as
text beginning in Column 16 (see
Table 2.1-4). A new code has been
added to the NEDS codes for laboratory
evaluation of control device, and
more codes may be added later. Note
also that FPEIS requires the word
description of NEDS codes rather than
numeric codes. Use the exact wording
given in Table 2.1-4, left-justified.
As above for SCC II (type of opera-
tion). Exact spelling required.
As above for SCC III (feed material
class). Exact spelling required.
Enter integer date as MM-DD-YY. This
is the source/control device or field/
laboratory test starting date.
-------�
UG-2.3.1-2
Card Columns
CARD API
(cont'd)
73-78
79-80
Data Element
Encoding Instructions
Test Series Finish
Date
UTM Zone
As above for the fieId/laboratory
test finish date. Enter as integer
date as MM-DD-YY.
The Universal Transverse Mercator
(UTM) is another means of identi-
fying the location of the source.
The UTM Zone number, which is in-
dicated on each USGS map, must be
cited to locate the coordinates
properly. Figure 2.3-1 indicates
that Zones 10 through 19 encompass
the 48 contiguous states; Zones 1
through 9, Alaska; Zones 19 and 20,
Puerto Rico and the Virgin Islands;
and Zones 1 through 5, Hawaii. For
a complete description of the Uni-
versal Transverse Mercator (UTM) sys-
tem, see the references below.1-3/
_!/ "Universal Transverse Mercator Grid," U.S. Department of the Army,
Washington, D.C., Publication No. TM5-241-8, July 1958.
"2J "Universal Transverse Mercator Grid, Zone-to-Zone Transformation Tables,"
U.S. Department of the Army, Washington, D.C., Publication No. TM5-
241-2, June 1957.
2/ Dietz, C. H., and D. S. Adams, "Elements of Map Projection," U.S. Depart-
ment of Commerce, Washington, D.C., Special Publication No. 68 (1945).
-------�
120*
114'
108*
114 '
Figure 2.3-1. UTM Grid Zones in the Contiguous United States.
O
l
OJ
.
I-1
I
-------�
UG-2.3.1-4
Card Columns
Data Element
CARD A02 (REQUIRED CARD)*
1-10 Data Identification
11-13
14-15
16-35
36-75
41-60
61-78
79-80
Card Number
Special Codes
SCC IV
Site Name
76-80 Blank
CARD A03 (REQUIRED CARD)**
16-40 Source Name
Street Address
City
State
Encoding Instructions
Leave Blank. While punching the cards,
the keypuncher will duplicate the
first 10 columns of A01 card.
No not change.
Leave blank.
Source Classification Code IV de-
scription (operating mode class)
as text beginning Column 16 (see
Table 2.1-4).
The name of the site where the source
is located. Enter as text, beginning
in Column 36.
Leave blank.
Name of the source in text.
Number and name of the street ad-
dress in text (beginning in Column
41.
Name of the city, township, or area,
beginning in Column 61.
Two-letter code for state in which
source is located (see Table 2.1-
5).
* Enter NA for data not available.
** Enter CONFIDENTIAL for confidential data.
-------�
UG-2.3.1-5
Card Columns
Data Element
CARD A04 (REQUIRED CARD)
16-20 Zip Code
21-24
25-29
30
31-80
UTM Coords-X
UTM Coords-Y
Blank
Tested by
CARD A05 (REQUIRED CARD)**
16-75 Reference
Encoding Instructions
Enter the zip code of source loca-
tion.
The Universal Transverse Mercator
X-coordinate for the test site. The
UTM coordinates are found on USGS
maps with scales less than 1:250,000.
The 1:24,000 scale is necessary to
locate the point source adequately.
The decimal point is indicated by
the small triangle.*
Enter the Y-coordinate as above.*
Leave blank.
Enter the name of the testing group
or company as text.
Enter report number, date, or cite
the journal from which the data was
derived as text data beginning in
card Column 16.
* See references at bottom of page UG-2.3.1-2.
** Enter CONFIDENTIAL for classified documents.
-------�
Form 1 12/76
A
- SOURCE
Test Series
No.
1
f
*J
DESCRIPTION
Sub
No.
Rtm
Ho,
19
Card
No.
U
A^
12
0
13
1
Cord
No.
II
A
12
A
13
2
Cord
No.
II
A
12
0
13
3
Card
No.
II
A
12
0
13
4
Cord
No.
n
A
12
0
13
5
14
14
14
14
14
15
15
15
15
15
SCC
16
E
17
X
(Source Category)
18
r
19
c
20
21
M
22
£
23
24
fi
25
4
24
/
27
L
28
£
29
R
30
31
32
SCC II (Type of Operation)
33
£
34
35
£
SCC IV (Operating Mode Class)
16
i
17
,
16
7
19
20
21
/
22
O
Source Name
16
S
17
«
16
/
19
L
20
e
Zip!
16
6
17
3
18
/
19
2.
20
0
21
ft
22
23
O
24
M
25
M
24
6
27
r
26
U
29
30
31
32
33
34
35
36
C
37
7
38
ft
39
/
(0
C
41
42
<5
43
44
A/
45
e
46
£
47|4e
^r
49
A/
Form Completed by
SCC III (Feed Material Class)
50
£
51
4
52
L
53
/
54
£>
55
54
*v
57
/?
58
5
59
r
60
£
41
/
62
C
63
4
64
4
65
L
66
Test Series
Start Date
Mo
67
/
68
P
Da
69
C
70
«
Yr
71
7
72
5
Finish Date
Mo
73
/
74
2.
Da
75
/
Site Name
36
M
37
e
38
R
39
A
40
M
23
f
24
V
25
/
26
T
27
26
/
29
UTM Coords
X
21
7
22
2
Reference
16
S
17
H
18
A
i?
N
20
47
U
68
1
69
^
70
71
72
73
74
75
76
77
78
79 «0
State
79 IRQ
Mtf
Tested By
31
M
32
/
33
D
34
A/
35
£
34
S
37
r
36
39
R
40
E
41
5
42
E
43
4
44
(?
45
C
44
^
47
48
/
49
rf
50
S
51
r
52
S3
54
55
K
54
4
57
fj
58
S
59
ft
60
s
61
42
C
63
I
64
T
45
Y
64
.
67
68
M
69
70
71
72
73
74
75
23
.
24
25
L
24
.
27
J
28
.
29
30
31
£
32
T
33
34
f\
35
I
36
37
.
38
39
£
40
P
41
/)
42
-
43
f>
44
5
42
o
44
/
47
2
48
-
49
7
50
-------�
UG-2.3.2-1
2.3.2 Section B - Test Series Remarks - Form 1
Card Columns
Data Element
CARD B01 (CARD NOT REQUIRED)
1-10 Data Identification
11-13 Card Identification
14-15
16-80
CARD B02-B10
16-80
Special Codes
Remarks
(CARDS NOT REQUIRED)
Remarks
Encoding Instructions
Same as Card A01.
Do not change.
Leave blank.
Enter test series remarks as text,
Test series remarks continued from
Card B01.
-------�
B - TEST SERIES REMARKS
Test Series
No.
I
2
3
4
/
5
^
Sub ,
Serin
No.
»
7
8
Run
No.
9
10
Cord
No.
11
B
B
B
B
B
B
B
B
B
B
12
0
0
0
0
0
0
0
0
0
\
13
1
2
3
4
5
6
7
8
9
0
\4
li
Remarks in Texr
16
/
17
M
18
P
If
fl
20
c
21
T
22
t
23
R
24
25
r
26
/;
27
T
28
29
P
30
31
/
32
rf
33
T
34
s
35
36
c
37
44
45
F
46
*?
47
0
4B
M
49
30
K
51
A
n
N
53
£
54
-
55
a
56
AJ
57
£>
58
-
59
*/
60
0
61
A/
A3
6
63
64
T
65
H
66
£
67
68
#
69
y
70
71
72
73
74
75
76
77
78
79
BO
Figure 2,3-3. Sample Completed B-Cards—Test Series Remarks.
o
I
to
CO
to
-------�
UG-2.3.3-1
2.3.3 Section C - Control Device(s) Characteristics - Form 2
Card Columns Data Element Encoding Instructions
CARD C01 (REQUIRED CARD)
1-10 Data Identification Same as on Card A01.
11-13
14
15
16-48
49-60
61-80
Card Designation
Device Number
Special Code
Device Category
Device Class
Generic Type
Do not change.
Enter sequence number (1, 2, or 3)
given to the control device. For
example, if a control system consists
of a cyclone and a spray tower fol-
lowed by an ESP, there are three
control devices in the system. The
cyclone is Device No. 1, the spray
tower is Device No. 2, and the ESP
is Device No. 3. Multiple devices
are riumbered seqentially from the
source.
Blank.
Enter a descriptive definition of
the generic device in text form
beginning in Column 16. Use stan-
dard nomenclature given in Table
2.1-7.
Enter device class as text using
standard nomenclature given in Table
2.1-6, beginning in Card Column 48.
Enter the type ,of generic control
device as text beginning in card
Column 61. Use only standard nomen-
clature as given in Table 2.1-6.
-------�
UG-2.3.3-2
Card Column
Data Element
CARD C02 (REQUIRED CARD)*
16-45 Commercial Name
46-75
76-80
Manufacturer
76-80 Blank
CARD C03 (REQUIRED CARD)*
16-75 Device Description
Blank
CARD C04 (REQUIRED CARD)*
Encoding Instructions
Enter the commercial name (and model
number) of the control device as
text beginning in card Column 16.
Enter the name of the device manu-
facturer as text beginning in card
Column 46.
Leave blank.
Enter a brief description of the
device as text which can include
the principle of operation, size,
shape, modifications to a standard
unit, etc. Use abbreviations as much
as possible beginning in card Column
16.
Leave blank.
The instructions for this card are
the same as for Card C03.
* Not required if entry for GENERIC TYPE (C01, CC61-80) is "NONE."
-------�
Form 2 12/76
c
- CONTROL
Teit Series
No.
1
/
1
DEVICE(S) CHARACTERISTICS
Sub
S«rl«
No.
Run:
No,
10
Cord
No.
II
C
12
0
1]
1
Card
No.
II
C
12
0
13
2
Card
No.
II
C
1]
0
13
3
Card
No.
II
C
12
0
13
4
f
M
/
14
t4
14
tj
-Device No. (1.2 or 3)
Device Category
16
t>
17
A
18
R
19
A
20
L
21
L
22
£
23
K
24
25
F
26
t
27
A
21
T
29
E
30
31
£
32
S
33
P
34
35
36
37
38
39
40
41
42
43
44
45
1 Commercial Name
15] U
J^S
15
13
17
L
18
£
19
C
20
7
21
/?
22
a
23
S
24
r
25
A
26
T
27
/
21
C
2?
30
?
31
R
32
S
33
C
34
/
35
P
56
/
37
T
38
A
39
7
40
<2
41
R
42
43
44
45
46
47
48
Device Class
49
c
50
19
N
20
/
21
T
22
s
23
24
/
25
H
26
27
P
2B
A
29
r?
30
A
31
L
32
L
33
6
34
I
35
36
H
37
/
38
7
39 [40
H(
41
C
42
Gt
43
M
44
A
45
a
46
AJ
47
48
/
49
Af
50
L
Device Description (continued)
14
/
17
f:
18
7
19
20
fi
21
(J
22
c
23
7
24
5
25
.
26
27
n
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
52
C
53
H
54
55
C
56
4
57
7
58
7
59
R
60
<5
61
£
62
L
63
64
65
66
67
68
69
70
71
72
73
74
75
51
e
52
7
53
54
^
55
0
56
C
57
7
58
59
4
60
Ar1
61
b
a
63
64
e
65
P
66
X)
67
*
68
^
69
7
70
e
71
72
-------�
UG-2.3.3-4
Card Columns
Data Element
CARD C05 - Control Device Design P
1-10 Data Identificatior
11-13
14
15
16-17
18-47
Card Designation
Control Device
Number
Special Code
Serial Number
Design Par
Specificat
rds.
card),
.umber
.control
• /format the
. tdard nomen-
3 beginning
48-67
68-80
Design Parameter
Value
Blank
a design par am-
i text using
the standard uo. ature in Table
2.1-8. Separate the value and units
by two (2) blanks. Begin entry of
value in card Column 48.
Leave blank.
* Not required if entry for GENERIC TYPE (C01, CC61-80) is "NONE."
-------�
CONTROL DEVICE(S) DESIGN PARAMETERS
Test Ser
No.
1
2
3
iei
4
/
S
?
Stfc
Series'
No.
4
*
«
Rort
No.
*
16
Cord
No.
iT
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
13
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
r
14
/
/
/
IS
SB
o .
Jl
16
17
/
2
3
-Device No. (1.2 or 3)
Specifications
it
£
C
p
19
(,
$
L
20
£
R
A
21
C
$
T
22
7
N
e
23
K
A
14
$
T
25
£
W
*
26
e
i
27
R
f
28
XJ
F
L
29
R
4
30
f
D
r
31
»
/
e
32
4
33
.
3
34
F"
35
A
)4
C
37
/
38
/tf
39
<=
40
41
42
43
44
45
46
47
Value
48
5
,*
^
49
/
,
fl
50
7
$
H
SI
4
52
V
M
53
f
fi>
n
54
55
W
M
^
57
58
59
40
61
62
63
64
65
66
67
«8
W
70
-
-
71
n
73
74
74
TO
n
n
n
K
Figure 2.3-5. Sample Completed COS Cards—Control Device(s) Design Parameters.
-------�
UG-2.3.4-1
2.3.4 Section D - Test Characteristics - Form 3, Form 4
Card Columns Data Element Encoding Instructions
CARD DPI (REQUIRED CARD)
1-5 Test Series Number
6-8
9-10
11-13
14
15
16-21
22-25
26-29
30-59
60-76
Test Subseries
Number
Blank
Card Designation
Blank
Control Device
Inlet or Outlet
Date
Start Time
Stop Time
Source Operating
Mode
Source Operating
Rate
As on Card A01.
Enter the integer number of the
subseries within this test series.
Leave blank.
Do not change.
Leave blank.
Enter the letter Code I for inlet or
0 for outlet. When there is no control
device, indicate NONE on Card C01,
Columns 61 through 64, and enter
I in this column.
Test subseries starting date entered
as integer MM-DD-YY.
Test subseries start time on the
basis of 24-hr day (military time).
Test subseries finish time expressed
as above.
Specify the source operating con-
ditions at the time of the test as
text beginning in card Column 30.
If the operation of the source is
cyclical, then specify the operating
mode at the time of test.
Enter the measured (not designed)
operating output rate of the source
and the appropriate units as text
beginning in card Column 60. Separate
the value and unit by one blank.
-------�
UG-2.3.4-2
Card Columns
CARD DPI
(cont'd)
77-80
Data Element
Encoding Instructions
46-80
16-55
56-61
62-65
66-69
Percent Design
Capacity
CARD DO2 (CARD NOT REQUIRED)
16-45 Feed Material
Feed Material
Composition
CARD DO3 (CARD NOT REQUIRED)
Sampling Location
Description
Volume Flow Rate
Velocity
Temperature
Specify the percent of the design
capacity at which the source is
operating during the time of test.
The decimal point is represented
by the triangle between Columns 79
and 80.
Specify in text (alphanumeric) begin-
ning in card Column 16 the type of
source material.
Specify briefly the major constitu-
ents of the feed material as text
beginning card Column 46.
Describe the sampling location in
terms of duct diameter or meters from the
the nearest obstruction or bent. Enter
any information that affects the sam-
pling and transport of aerosol. Be
brief and use abbreviations.
Enter the total volume flow rate
of effluent gas at the sampling
location as a decimal number in
units of dry normal m^/s. The
decimal point is implied between
Columns 60 and 61.
Enter the velocity of gas at the
sampling location as a decimal num-
ber in units of m/s. The decimal
point is implied between Columns 64
and 65.
Enter the temperature of the gas
at sampling location as an integer
number in units of degree Celsius.
Right-justify entry to Column 69.
-------�
UG-2.3.4-3
Card Columns
CARD D03
(Cont'd)
70-74
Data Element
Encoding Instructions
Pressure
75-77
Percent
78-80
Percent Isokinetic
CARD D04 (CARD NOT REQUIRED)
16-19 C02
20-23
CO
24-27
28-31
N2
32-80
Trace Gases in PPM
Enter the absolute static pressure
at the sampling location as an integer
number in units of mm Hg. Right-justify
entry to Column 74.
Enter the percent by volume of water
vapor at the sampling location as a
decimal number. The decimal point
is implied between Columns 76 and
77.
Enter the percent isokinetic sampling
achieved at the sampling location
as an integer number right-justified
to card Column 80.
Enter the percent of total gas of
C02 as determined by Orsat gas anal-
ysis as a decimal number, the decimal
point is implied between card Columns
17 and 18.
Enter the percent of total gas of
CO as determined by Orsat gas analysis
as a decimal number. The decimal point
is implied between card Columns 21 and
22.
Enter the percent of total gas of
02 as determined by Orsat gas analysis
as a decimal number. The decimal point
is implied between card Columns 25 and
26.
Enter the percent of total gas of N2
as determined by Orsat gas analysis
as a decimal number. The decimal
point is implied between card Columns
29 and 30.
Enter the results of trace gas anal-
ysis as text beginning in card Column
32. Enter the chemical symbol fol-
lowed by a dash and the value in parts
per million (ppm). Separate multiple
entries by commas. Use subseries re-
marks for overflow space.
-------�
UG-2.3.4-4
Card Columns
Data Element
Encoding Instructions
CARD DOS - Control Device Operating Parameters (CARD NOT REQUIRED)
1-10 Data Identification Encode same as on D01 card.
11-13
14
15
16-17
18-47
48-67
68-80
CARD D06
1-10
16-80
Card Designation
Device Number
Special Code
Serial Number
Specification
Value
Blank
Do not change.
Enter the control device number as
defined on Card C01.
Leave blank.
When encoding the first subseries,
enter the serial number for each
of the control device operating
parameters. For the second and sub-
subsequent subseries enter the serial
number of operating parameter being
entered as given for the first sub-
series.
Enter the control device operating
parameter as text using standard
nomenclature from Table 2.1-9 beginning
in card Column 18. For second and sub-
sequent subseries utilize the labor
saving feature explained on page
UG-2.1.5-2.
Enter the value of control device
operating parameter and units using
standard nomenclature from Table
2.1-9 as text beginning in card Column
48. The value and units should be
separated by two blank spaces.
Leave blank.
Subseries Remarks (CARD NOT REQUIRED)
Data Identification Same as D05 card.
Remarks
Enter subseries remarks as text begin-
ning in card Column 16.
-------�
Form 3 12/76
D - TEST CHARACTERISTICS
Test -Series
No.
1
1
f
d
Sub
Series
No.
I
ftgn
No,
io
Card
No.
II
D
12
0
13
1
Card
No.
II
D
12
0
13
2
Card
No.
II
D
12
0
13
3
Card
No.
II
D
12
0
13
4
U
M
14
14
f
15
I
\i
15
15
— Control Device nlet or Outlet (I or
Test Sub Series
Date
Mo
14
^
17
2
Do
18
0
19
4
Yr
20
7
21
^
Start
Time
22
0
23
S
24
3
23
O
Stop
Time
24
/
27
/
28 29
00
0)
Source Operating Mode
30
C
31
*
32
4
33
i.
34
4
33
R
34
F
37
f
38
(/
39
X
40
f
41
42
ft
43
U
44
K
45
/v1
44
/
47
W
48
/^
49
30
51
52
53
34
55
34
37
38
59
Form Completed by
Source Operating Rale*
40
/
41
2
42
o
43
44
if
43
M
44
47
48
49
70
71
7J
n
74
75
74
% Design
Capacity
77
1
78
0
79
0
80
Feed Material * (Feed Material Composition*
14
s£
17
R
18
/
19
s
20
W
21
7
n
23
6
24
23
C
24
0
27
A
28 29
L
30
A
31
A/
32
h
33
34
M
33
tV
34
rV
37
.
38
39
4
40
f
41
F
42
C/
43
,5
44
?
4!
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47
48
49
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Sampling Location Description*
14
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,
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d)
33
54
37
58
59
40
41
Volume
Flow Rate*
54
37
58
/
59
£
40
9
41
42
43
44
43
Velocity*
42
43
^
44
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43
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44
47
48
49
Temp.
44
47
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48
6
49
4
70
71
77
73
74
Frets.*
70
71
77
7
73
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75
74
% H2
75
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77
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1
78
79
90
% ho .
Kinetic
78
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Trace Gases in ppm (Text)*
32
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=:
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y
37
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38
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40
41
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42
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48
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=
31
2
32
2
33
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54
55
34
57
58
59
40
41
42
43
44
43
44
47
49
49
70
71
77
73
74
75
74
77
78
79'
80
Figure 2.3-6. Sample Completed D01-D04 Cards—Test Characteristics.
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-------�
CONTROL DEVICE(S) OPERATING PARAMETERS
Test Series
No.
1
2
/
i
Sub
Series
No.
/
Ryri:
No-
ll!
Cord
No.
II
D
D
D
D
D
D
D
D
D
0
D
D
D
D
D
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D
D
D
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0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1]
5
5
5
5
5
5
5
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iff.
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16
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3
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5
-Device No. (1.2 or 3)
Specification *
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39
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41
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74
77
71
79
K
Need not be filled if the preceding subseries contains the same data.
Form 4 12/76
CONTROL DEVICE(S) OPERATING PARAMETERS (cont'd)
Test Series
No.
Sub
Series
No.
Run
No,
~
Card
No.
D
D
D
n
D
D
D
D
D
D
0
0
0
n
0
0
0
0
0
0
5
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5
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5
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5
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$
a
Jl
—Device No. (1.2 or 3)
Specification
Value *
48 io V) SI
52 51 54 55
58 59 40
61
A?
43 44
65
Form Completed by
Aft
41 40
.71
77
n
...
74
7$ ?* 77 78 7» M
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Figure 2.3-7. Sample Completed DOS Cards—Control Device(s) Operating Parameters.
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-------�
SUBSERIES REMARKS
Test Serin
No. .
1
2
/
V
Sub
Seriet
No.
r
/
Run
No,
10
Card
No.
11
D
D
D
D
0
0
D
0
D
D
D
D
D
D
D
12
0
0
0
0
2
ID
6
7
8
9
0
1
2
3
A
5
6
7
8
9
0
u
IS
Remarks In Text*
16
/
*
17
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K
18
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A
19
ft
20
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21
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22
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29
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31
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32133
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35
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36
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37
38
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45
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46
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48
49
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52
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54
7
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56
57
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58
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59
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60
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62
63
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64
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65
66
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67
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70
/
71
^
72
f\
73
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74
75
76
77
78
TV
SO
Figure 2.3-8. Sample Completed D06-D20 Cards—Subseries Remarks.
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-------�
UG-2.3.5-1
2.3.5 Section E - Mass Train Test Results - Form 4
Card Columns Data Element Encoding Instructions
CARD E01 (CARD NOT REQUIRED)
1-8 Data Identification Same as D01 card.
16-25
Front Half
26-35
Total
36-80
Mass Train Comments
Enter the mass train front half con-
centration in scientific notation
in units of p-g per dry normal m •
The exponent shall be right-justified
in card Column 25. The decimal point
is specified in card Column 18. (This
data includes the mass collected in
the nozzle and probe wash and the
filter.)*
Enter the total mass concentration
as the sum of the front half mass
and the impinger. Enter the value
in scientific notation in units of
|J-g per dry normal m-^. The exponent
shall be right-justified in card
Column 35. The decimal point is
specified in card Column 28.*
Enter any brief comments on the mass
train as text beginning in card
Column 36.
Note that these values are to be entered as exponential numbers with
exponents following the "+" in Columns 24, 25, and 34, 35.
-------�
E - PARTICULATE MASS TRAIN RESULTS
Test Series
No. "
l
1
1
9
Sub
No.
/
Ron
Nr,
10
Card
No.
11
E
12
0
13
1
14
13
Front Hair
16
17
ff
18
•
19
2
20
/
21
J2
E
23
+
24
0
25
?
Total
26
27
4
28
29
7
30
tf
31
32
E
33
+
34
O
35
6
Mass Train Comments7Texf)
36
£
37
A
38
/)
39
40
^
41
£
42
7
43
H
44
0
45
£
46
47
5
48
49
7
50
?
51
4
52
(
53
/V
54
55
56
57
58
S9
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79 80
Figure 2.3-9. Sample Completed E-Card—Particulate Mass Train Results.
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I
-------�
UG-2.3.6-1
2.3.6 Section F - Particulate Physical Properties - Form 4
Card Columns Data Element Encoding Instructions
CARD F01 (REQUIRED CARD FOR FIRST SUBSERIES)
1-8 Data Identification Same as D01
16-19
20
21-27
28
29-30
31-90
Density
Density Determina-
tion
Resisitivity
Resistivity
Determination
Blank
Other Physical
Properties
Enter density as a decimal number
in units of g/cm^. The decimal point
is implied between card Columns 17
and 18.
Enter the integer 1 for "measured,"
0 for "assumed."
Enter resistivity in scientific nota-
tion in units of ohm-cm. The exponent
shall be right-justified in card
Column 27. The decimal point is speci-
field in card Column 22.
Enter the integer 1 for "measured,"
0 for "assumed."
Leave blank.
Enter as text beginning in card
Column 31 any additional physical
properties, values, and units to
be reported.
-------�
F - PARTICULATE PHYSICAL PROPERTIES
Test Scries
No.
I
2
3
/
i
Sub
Series
No.
/
Run
No
l(
Cord
No.
II
F
12
0
1}
1
14
15
Density*
16
17
2
IS
2
19
7
20
£
— Determination —
Resistivity*
21
2
22
•
23
3
24
25
+
26
/
27
/
T
\
28
o
»
36
Other Physical Properties in Text i
31
32
33
34
35
36
37
38
39
40
41
42
43
44
4}
46
47
48
49
50
51
52
S3
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
77
eo
Need not be filled if the preceding subseries contains the same data.
Figure 2.3-10. Sample Completed F-Card—Particulate Physical Properties.
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-------�
UG-2.3.7-1
2.3.7 Section G - Particulate Bioassay Data - Form 5
Card Columns
Data Element
CARD G01 (CARD NOT REQUIRED)
1-8 Data Identification
16-35
36-80
Bioassay Test Type
Bioassay Comments
Encoding Instructions
Same as DOl.
Enter the bioassay test type per-
formed on the sample as text using
standard nomenclature given in Table
2.1-10, beginning in card Column
16. Correct spelling is essential.
Enter results of the indicated test
as above as .text beginning in card
Column 36.
-------�
FofitiS 12/76
G
- PARTICULATE
Test Series
No.
1
/
v
BIOASSAY DATA'
Sub
Seriei
No.
/
Run
No.
f
10
Card
No.
II
G
G
G
G
G
12
0
0
0
0
0
13
1
1
1
1
1
14
11
Bioassay Test Type
16
5
17
k
18
1
\1
N
20
21
P
22
A
23
/
24
A/
23
7
26
/
27
fJ
28
fi
29
30
31
32
33
34
35
Form Completed by
Bioossoy Comments
36
s
T>
37
K
A
38
/
K
39
rV
7
40
/
41
P
c
42
/T
I/
43
/
t.
44
Kl
A
45
7
7
46
/
f
47
V
48
6
d
49
fi
SO
/
P
51
,v
7>
52
I
53
/
54
f
55
/)
56
f
57
£
58
f>
59
60
»V
61
^
62
63
c
64
//
65
A
66
fl
a
68
f
69
70
5
71
(/
72
?
73
74
7
75
$
76
77
7)
79
80
Figure 203-11. Sample Completed G-Cards—Farticulate Bioassay Data.
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-------�
UG-2.3.8-1
2.3.8 Section H - Chemical Composition Data - Form 5
Card Columns
Data Element
Encoding Instructions
CARD HOI (CARD NOT REQUIRED)
1-8 Data Identification Same as D01 card.
16-18
19
20
21-26
27-32
33-38
39-44
45-50
51-56
57-62
63-68
69-74
75-80
Blank
Aerodynamic/Stokes
Diameter
Calibrated or
Calculated
Upper Boundary
Diameter
Particle Boundary
Diameter-lst Stage
Particle Boundary
Diameter-2nd Stage
Particle Boundary
Diameter-3rd Stage
Particle Boundary
Diameter-4th stage
Particle Boundary
Diameter-5th Stage
Particle Boundary
Diameter-6th Stage
Particle Boundary
Diameter-7th Stage
Particle Boundary
Diameter-8th Stage
Particle Boundary
Diameter-9th Stage
Leave blank.
Enter the integer 1 for "aerodynamic"
particle diameter, 0 for "Stokes"
particle diameter.
Enter the integer 1 for "calibrated"
instrument cut diameters, 0 for "cal-
culated" instrument cut diameters.
Enter the upper boundary diameter
value as a decimal number in units
of |im. The decimal point is specified
in card Column 23.
Enter the particle boundary diameter
value as a decimal number in units
of p-rn. The decimal point is specified.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
-------�
UG-2.3.8-2
Card Columns
Data Element
CARD HO2 (CARD NOT REQUIRED)
16-19 Chemical ID
20
21-26
27-32
33-38
39-44
45-50
51-56
Analysis ID
Mass Train Filter/
Fooled Stages
Chemical Concentra-
tion-lst Stage
Chemical
tion-2nd
Chemical
tion-3rd
Chemical
tion-4th
Chemical
tion-5th
Concentra-
Stage
Concentra-
Stage
Concentra-
Stage
Concentra-
Stage
Encoding Instructions
Enter the integer code number for
the chemical element or compound
using the SAROAD standard nomen-
clature given in Table 2.1-11.
Enter the code letter for the chemi-
cal analysis performed using the
standard nomenclature given in Table
2.1-12.
Enter the chemical concentration
as a decimal number in units of
jig/dry normal m^ for the mass train
filter or the pooled stages. The
decimal point is specified in card
Column 22.
Enter in scientific notation in
units of M-g/dry normal m^« The
decimal point is specified in the
second column in the field. The sign
of the exponent (+ or -) shall be
entered in the fifth column, and
the value of the exponent as an
integer in the seventh column.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
-------�
UG-2.3.8-3
Card Columns Data Element
CARD HO 2
Encoding Instructions
(Cont'd)
57-62
63-68
69-74
75-80
Chemical
tion-6th
Chemical
tion-7th
Chemical
tion-8th
Chemical
tion-9th
Concentra-
Stage
Concentra-
Stage
Concentra-
Stage
Concentra-
Stage
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
Same as 1st stage.
-------�
H •
- CHEMICAL
Test Series
No.
1
2
/
A
»A
*A
?fl
M
•7)
A
>A
>4
ffl
M
A
>/)
Upper
Boundary
Diameter
21
1_
22
T
23
•
24
25
26
Mass Train
Filter or
Pooled Stages
21
22
23
24
25
26
©
27
28
7
v>
•
30
5
}>
92
±
27
2
1
1
\
3
/
/
3
i
/
4
28
2»
/
£
21
^
i
4
i
%
d
\
2
3
5
<§
b
£
/
I
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42
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9
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5
43
4-
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4-
+
t]
4-
t
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*
4-
+
t
44
0
2
2
1
2
0
0
P
2
1
Jary Diameter *
©
49
46
/
47
•
48
s
49
so
Chemica
©
±
45
i
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k
t
6
2
1
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£
Z
46
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
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•
•
47
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7
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6
48
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52
53
•
34
55
?
56
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±
51
*
4
4
?
5
2
c
4
1
/
52
•
•
•
*
•
1*
•
•
•
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54
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i
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0
5
©
37
56
59
•
60
4
61
/
62
[MaM
©
±
37
1
2
3
3
a
^
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7
i
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7
58
•
•
•
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•
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•
•
•
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59
7
2
2
-
j1
2
4
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3
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7
2
1
60
i
2
4
2
^
5
3
6
i
i
Q
5
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64
65
I
0
4
o
7
^
7
9
o
66
/
3
«
3
7
4
1,
^
3
i
67
?
*
+•
4-
V
4-
4-
4,
•«•
t
±
+
4
68
0
J
0
i
1
1
1
c
D
0
f
2
3
3
. ®
69
70
71
•
72
73
74
®
±
69
70
71
72
73
74
(D
75
76
77
•
78
79
80
±
75
76
77
78
79
80
Need not be Riled if the preceding subseries contains the same data.
Note: The stages (or catches) are arranged sequentially in decreasing order of cut diameter sizes for up
to a maximum of nine stages. The successive stages may be cyclone, impactor, final filter, etc.,
depending upon the configuration of the sampling train.
Figure 2.3-12. Sample Completed H-Cards—Chemical Composition Data.
o
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00
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-------�
UG-2.3.9-1
2,3.9 Section I - Measurement Particulars - Form 6
Card Columns
Data Element
CARD 101 (REQUIRED CARD)
1-5 Test Series Number
6-8
9-10
11-13
14
15
16-45
46-49
50-54
55-60
Subseries Number
Run Number
Card Designation
Measurement Instru-
ment/Method Number
Blank
Measurement Instru-
ment/Method Name
Measurement Start-
Time
Sampling Period
Aerosol Flow Rate
Encoding Instructions
Same as on Card A01.
Same as Card D01.
Enter the nonzero, sequential integer
number of the run.
Do not change.
Each of the measurement instrument/
method used for making particle size
distribution measurements of a test
series is given a nonzero, sequential
number. Enter the number of measurement
instrument/method here.
Leave blank.
Enter the name of the measurement
instrument/method as text using the
standard nomenclature as given in
Table 2.1-14 beginning in Column
16.
Enter the integer starting time of
measurement with this particular
instrument. Use 24-hr clock (military
time).
Enter the measurement duration (sam-
pling period) for this instrument
as a decimal number in minutes. The
decimal point is implied between
card Columns 53 and 54.
Enter the sample flow rate as a
decimal number in units of liters/
minute for this instrument/method.
The decimal point is implied between
card Columns 58 and 59.
-------�
UG-2.3.9-2
Card Columns
CARD 101
(Cont'd)
61-64
Data Element
Encoding Instructions
Temperature
65-69
Pressure
70-72
Percent
73-75
76-80
Blank
Dilution Factor
Enter the gas temperature at the
measurement location (the measure-
ment location may be the sampling
location for _in situ sampling) as
an integer number in units of degree
Celsius.
Enter the gas pressure at the mea-
surement location (the sampling and
measurement locations will be the
same for j.n situ sampling) as an
integer number in units of mm Hg,
right-justified to Column 69.
Enter the percent by volume of water
vapor as a decimal number. The decimal
point is specified between card Columns
71 and 72.
Leave blank.
Enter the ratio of aerosol concen-
tration (either on mass basis or
number basis) in the original gas
stream to that of measured sample
as a decimal number. Enter 1 in card
Column 79 if the aerosol is not diluted
as is the usual case when sampling
with impactors. Distortions in par-
ticle size distribution due to the
dilution system should be reported
in the appropriate remarks. The
decimal point is implied between
card Columns 79 and 80.
-------�
UG-2.3.9-3
Card Columns
Data Element
CARD 102 (CARD NOT REQUIRED)
16-20
Measurement Size
Range (Lower)
21-25
Measurement Size
Range (Upper)
26-80
Collection Surface/
Substrate and Its
Specifications
CARD 103-105 (CARDS NOT REQUIRED)
16-80
Comments on the
Measurement
Encoding Instructions
Enter the lower diameter range of the
measurement instrument /method as a
decimal number in units of M-m. The
decimal point is implied between
card Columns 17 and 18.
Enter the upper diameter range of the
measurement instrument /method as a
decimal number in units of y,m. The
decimal point is implied between card
Columns 22 and 23.
Enter as text a description of adhesive
coating used for impactor sampling, begin-
ning in card Column 26. For instruments
for which no collection surface is
needed, leave blank.
Enter as text beginning in card Column
16 all the run level comments. Be
brief and use abbreviations where
ever possible. These comments will
not be applicable to any other runs.
If there are comments regarding a
measuring instrument which will ap-
ply to all runs enter such comments
in subseries remarks.
-------�
Form 6 12/ 76
1-
MEASUREMENT PARTICULARS
Test Series
No.
1
/
1
Sub
Series
No.-
1
Run
No.
10
1
Card
No.
n
I
12
0
13
1
Cord
No.
II
JJ
1]
0
13
2
Card
No.
II
I
I
I
12
0
0
0
13
3
4
5
f
14
1
14
U
"
IS
IS
IS
—Measurement Instrument/Method No.
Measurement Instrument/Method Name
16
£
17
f?
18
/
IV
A/
20
rV
21
s
22
23
ft
24
M
25
^
• *
Measurement Size Range
Lower
16
17
t
18
,/
If
20
Upper
21
/
22
<5
23
24
25
26
.
27
I
28
T
2?
30
31
32
33
14
35
36
37
38
39
40
41
42
43
44
45
Meas.
Start Time
46
0
47
R
48
*
49
0
Sampling
Period**
50
51
52
/
53
S
54
Aerosol
Flow Rate
55
56
57
58
/
5»
8
60
7
Form Completed by
Gas Conditions at
Measurement Location**
Temp.
41
62
/
63
6
64
U
Press .
65
66
67
7
68
/>
69
0
%H2O
70
71
y
72
7
n
74
75
Dilution
t- *•
Factor
76
77
78
79
/
80
Collection Surface/Substrate and its Specifications*
26
s
27
7
28
A
29
/
30
N
31
L
32
£
33
s
34
5
35
36
37
38
e
39
€
40
L
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
to
61
a
63
64
65
66
67
68
69
70
r\
72
n
74
75
76
77
78
79
80
Comments on the Measurement
16
/
17
M
18
P
19
f)
20
c
21
T
22
$
23
«
24
25
rV
26
A
27
?
n
29
P
30
f?
31
£
32
rV
33
6
34
fl
35
T
36
f
37
5
38
39
F
40
41
ft
42
43
/
44
/
45
2
46
47
H
48
R
49
50
/
51
N
52
53
7
54
H
55
£
56
57
£>
58
-------�
UG-2.3.10-1
2.3.10 Section J - Particulate Size Distribution Data - Form 6
Card Columns
Data Element
CARD J01 (REQUIRED CARD)*
1-10 Data Identification
14
15
16
24-25
32-33
40-41
48-49
56-57
64-65
72-73
17-23
26-31
34-39
42-47
50-55
58-63
66-71
74-79
Measuremet Instru-
ment/Method Number
Aerodynamic/Stokes
Diameter
Blank
Particle Size Data
Encoding Instructions
Enter test series, test subseries,
and test run numbers as on Card 101.
Enter the same integer as on Card
101, Column 14.
Enter the integer 1 for "aerodynamic"
particle diameter, 0 for "Stokes"
particle diameter.
Leave blank
Enter the boundary particle diam-
eters as decimal numbers in units
of p,m in order of decreasing par-
ticle diameter. The decimal points
are specified in the fourth column
of each seven-column field. The
number of digits reported should
be able to represent the precision
of the measurement. The diameters
are in decreasing order of size.
The first diameter is the upper
boundary diameter of the aerosol
which depends upon the aerosol and
on the sampling train and is usually
estimated.
* At least for the first run of each measurement instrument/method.
-------�
UG-2.3.10-2
Card Go limns
Data Element
Encoding Instructions
CARD J01
(Cont«d)
80
Calibrated or Cal-
culated
Enter the integer 1 for "calibrated"
boundary diameters, 0 for "calculated"
boundary diameters.
CARDS JO2 and JO3 (REQUIRED CARDS)*
14-17
24-25
32-33
40-41
48-49
56-57
64-65
72-73
80
Blank
Leave blank
17-23 Particle Size Data
26-31
34-39
42-47
50-55
58-63
66-71
74-79
Continuation of data fields from
J01 card. Same encoding instructions
apply.
CARD J04 (REQUIRED CARD)
14
15
Measurement Instru-
ment/Method Number
Mass/Number
Enter the same integer as on 101
and J01, card Column 14.
Enter the integer 1 for "mass" or
0 for "number" depending upon which
the instrument/method measures.
* At least for the first run of each measurement instrument/method.
-------�
UG-2.3.10-3
Card Columns
Data Element
Encoding Instructions
CARD J04
(Cont'd)
16
24
32
40
48
56
64
72
80
Blank
Leave blank.
17-23
25-31
33-39
41-47
49-55
57-63
65-71
73-79
Mass/Number Data
CARDS J05, J06 (REQUIRED CARDS)
14-16
24
32
40
48
56
64
72
80
Blank
Enter the particle concentration
in order of decreasing particle
size boundary in scientific nota-
tion in the seven column field.
The decimal point is specified
in the second column of each field.
The sign of exponent (either + or -)
shall be entered in the fifth column
and the exponent as an integer in the
seventh column. Mass concentration
shall be expressed in units of Hg/dry
normal m^. Number concentration
shall be expressed in units of num-
ber/en^. The mass concentration is
calculated for each stage by dividing
the mass by the total volume in dry
normal w~ sampled by the instrument.
Leave blank.
-------�
UG-2.3.10-4
Card Columns Data Element Encoding Instructions
CARDS J05t J06
(Cont'd)
17-32 Continuation of data fields from
25-31 J04 card. Same encoding instructions
33-39 apply.
41-47
49-55
57-63
65-71
73-80
-------�
J - PARTICULATE SIZE DISTRIBUTION DATA
Test Seriet
No.
1
f
4
Sub
Seriet
No.
/
Run
No.
10
1
Card
No.
it
1
J
J
12
0
0
0
13
1
2
3
Card
No.
II
J
J
J
12
0
0
0
13
4
5
6
r
14
/
r
14
/
r
IS
1
r
15
/
— Measurement Instrum
— Aerodynamic/Stoke
U
17
18
/
\t
s
70
•
•
•
21
22
23
-Measurement •Initrurm
—Mass/No. (1 or 0)
16
17
i
it
•
•
•
19
9
20
?
21
«?
22
f
23
«?
ent/Method No.
s Diameter (1 or 0)
24
13
26
27
7
28
•
•
•
29
41
4
42
•
•
•
43
5
44
?
45
4.
46
+
47
4
ize Data**
<6
Vx:
4«
30
51
/
52
•
•
•
53
*?
54
4
55
«i
nber Data
+
4*
49
2
50
•
•
•
SI
7
52
S
53
/
54
f
55
4
56
-
37
58
59
to
•
•
•
61
7
62
?
63
±
S«
37
s
58
•
•
•
59
2
60
0
61
2
62
i
63
3
c
64
45
66
67
68
•
•
•
69
V
70
O
71
f
±
**
63
66
•
•
•
67
6?
66
69
70
71
^
alib or Calc (1 or 0)-
n
n
74
75
74
•
•
•
77
/
78
79
±
n
73
74
•
•
•
75
76
77
71
77
1
80
0
so
Need not be filled IF the preceding subteries or run with this Instrument/method contains the same data.
Figure 2.3-14. Sample Completed J-Cards—Particulate Size Distribution Data.
o
i
ro
O
61
-------�
UG-3.0-0
SECTION 3
OFF-LINE REQUEST PROCEDURE
CONTENTS
Number Item
List of Figures 3.0-1
3.0 Introduction 3.0-2
3.1 Submittal of New Data 3.1-1
3.2 Use of Request Command Catalog ............ 3.2-1
3.3 Special Data Retrieval Requests 3.3-1
3.4 FPEIS User Support 3.4-1
-------�
UG-3.0-1
SECTION 3
LIST OF FIGURES
Number Page
3.1-1 Sample FPEIS Data Submittal Acknowledgment
Memo UG-3.1-3
3.1-2 Sample FPEIS Data Submittal Error Memo UG-3.1-4
3.2-1 System Request Command Form UG-3.2-3
-------�
UG-3.0-2
3.0 Introduction
The purpose of this section and the section to follow is to provide users
with instructions for submitting new test data and for retrieving existing
data from the FPEIS data base* This section addresses data submittal and
retrieval procedures for those users who do not have access to the EPA
National Computer Center at Research Triangle Park, North Carolina. Such
users will submit requests in writing to the EPA project officer for ac-
tion. The response by IERL will depend largely upon the nature of the re-
quest. Routine data updates or retrieval requests from the FPEIS Catalog
of Request Commands will be handled promptly. Special data retrieval re-
quests which require program development work will take longer. The length
of time required to respond to such requests will be a function of the com-
plexity of the requests.
-------�
UG-3.1-1
3.1 Submittal of New Data
All new source testing data for the FPEIS should be sent to the EPA proj-
ect officer, IERL-RTP, for input to the data base. These data must be en-
coded on the FPEIS data input forms in accordance with the data input instruc-
tions described previously. The user shall also send a cover letter identify-
ing each test series, subseries, and run in the data set submitted. Remember;
unique test series numbers will be assigned to each series by the FPEIS
data base administrator from a master file listing. It is not necessary
for the user to encode a series number on the data form; however, subseries
and run numbers must be encoded sequentially on the form.
Data for input to the FPEIS data base should be sent to the following address:
FPEIS Project Officer
U.S. Environmental Protection Agency
Special Studies Staff (MD-63)
Industrial Environmental Research Laboratory
Research Triangle Park, North Carolina 27711
When the data set has been received by IERL-RTP, a letter of acknowledge-
ment will be sent to the submitter (see Figure 3.1-1). The letter will also
identify the unique series number(s) assigned to his data set.
The user is requested to use quality data control in preparing data forms
to be submitted. Incomplete (e.g., less than minimum) or illegible data
forms will be returned to the user for correction (see Figure 3.1-2).
-------�
UG-3.1-2
As soon as the data submitted has been processed by the EDIT program, a
listing of the data will be sent to the submitter for verification of the
data* This listing will include calculations of particle size distributions.
Any data errors found should be noted, and corrections should be sent in
writing to the FPEIS project officer. A letter of verification will be
sent to the submitter and will be followed by a listing of the corrected
data set for the submitter's use. If no errors are found, the submitter
should acknowledge this in writing to the FPEIS project officer. When all
quality assurance procedures have been satisfied, the complete data set
will be entered into the FPEIS data base.
-------�
UG-3.1-3
Dr. John A. Doe
Ozone National Laboratory
1234 Anystreet Drive
Hometown, PA 12345
Dear Dr. Doe:
This letter is to acknowledge our receipt of source testing data
from you for the Fine Particle Emissions Information System (FPEIS).
The data forms have been examined and several omissions of key data were
noted. We are returning the data forms to you for correction. The
omitted data items have been noted on the data forms.
If you have any questions regarding the data forms, please feel free
to call me. Thank you very much for your support of the FPEIS.
Sincerely,
FPEIS Project Officer
Special Studies Staff
Figure 3.1-1. Sample FPEIS Data Submittal Acknowledgement Memo,
-------�
UG-3.1-4
Dr. John A. Doe
Ozone National Laboratory
1234 Anystreet Drive
Hometown, PA 12345
Dear Dr. Doe:
This letter is to acknowledge our receipt of source testing data for the
Fine Particle Emissions Information System (FPEIS) from you. The data forms
have been examined and have been found to be acceptable for input to the
FPEIS database.
In a short time, we will return to you a print-out containing the data
which you have submitted for your review and comment. The test series
numbers which have been assigned to your data are: 61, 62, 63, and 64.
Thank you very much for your support of the FPEIS. Please feel free to
call me if you have any questions.
Sincerely,
FPEIS Project Officer
Special Studies Staff
Figure 3.1-2. Sample FPEIS Data Submittal Error Memo.
-------�
UG-3.2-1
3.2 Use of Request Command Catalog
Section 5.0 contains a catalog of System Request Commands (SRC) which may
be utilized to retrieve FPEIS data in a specified manner. Each request
command is described separately and has its own requirements for data in-
put or qualification by the user. To simplify their use, the request com-
mands have been numbered sequentially beginning with C3000. In this way,
the user needs only to identify the command number in order to request a
certain procedure.
FPEIS System Request Commands should be requested by off-line users by the
standard request form shown in Figure 3.2-1. The requestor should complete
this form in accordance with the requirements of the request system com-
mand and send the completed form to the following address:
FPEIS Project Officer
U.S. Environmental Protection Agency
Special Studies Staff (MD-63)
Industrial Environmental Research Laboratory
Research Triangle Park, North Carolina 27711
Users must use separate request forms for different runs even if the same
command is being used repeatedly* For example, if a user wishes to inter-
rogate the data base according to a specific access criteria, any change
to that criteria must be shown on a separate request form. Receipt of re-
quest forms will be acknowledged to the requestor in writing. If there are
any errors in the request or some information is missing, the form will
be returned to the requestor for correction and resubmittal. When the request
has been processed, the output will be sent to the requestor for verification.
-------�
UG-3.2-2
The System Request Command Form Shown in Figure 3.2-1 may be duplicated
by the user from this document.
-------�
UG-3.2-3
REQUESTED BY:
(Street/P.O. Box)
(City)[State][TTpT
(Phone)
SYSTEM COMMAND NUMBER:
DATE SUBMITTED: DATE NEEDED:
COMMAND INPUT AND/OR QUALIFICATION DATA (List as required by Command Input
Instructions):
(Attach Additional Sheets If Needed)
Figure 3.2-1. System Request Command Form.
-------�
UG-3.3-1
3.3 Special Data Retrieval Requests
It is recognized at the outset that the System Request Commands are not
likely to be diverse enough to satisfy all user needs for data. For this
reason, a special data retrieval request category was established. There
is no specific form to be used for special requests; there is merely a set
of general guidelines to follow in preparing the request. These guidelines
are as follows:
1. Be explicit: Be thoroughly familiar with the FPEIS data base struc-
ture. Identify each data base element to be sorted and/or retrieved
by name. Should additional work on the request be required, consultation
with the requestor will be initiated, and, upon correction, the print-
out will be returned to the requestor for verification.
2. Plan the request; Be sure that the access criteria applies to
the proper type of data element. Remember that only key values may
be retrieved directly and that nonkey values must be qualified for
data access (see Section 6.6). Specify all needed qualifications and
identify all input data for comparative evaluation.
30 Define the output; Determine how you wish the data to be displayed
on output. Identify how data elements are to be ordered. Specify column
headings. Define any calculations to be performed on the accessed data.
-------�
UG-3.3-2
The completed definition of the request should be sent to the FPEIS proj-
ect officer at IERL-RTP. The user should be sure to include his telephone
number with the request. If there are any problems encountered with the
request, the user will be contacted by telephone to resolve the problem.
When the request has been received, a letter of acknowledgement will be
sent to the requestor. The letter will include a preliminary estimate of
the length of time required to process the request. As emphasized previ-
ously, the length of time needed to process a special request will depend
upon the complexity of the request. The simpler the request, the faster
it can be processed.
If no problems are encountered that require consultation with the requestor,
the results will be sent to the requestor when the processing is completed.
The requestor should review the output to verify that it satisfies the re-
quest. If it does not, the printout should be returned with corrections
to IERL for reworking. If the printout is satisfactory, the requestor should
notify the FPEIS project officer of his acceptance.
-------�
UG-3.4-1
3.4 FPEIS User Support
The FPEIS is supported by IERL-RTP. The administrative functions relative
to the FPEIS are provided by the Special Studies Staff in IERL. Develop-
mental work on new concepts for sorting and retrieval programs is performed
by government contractors under direction of the FPEIS project officer in
the Special Studies Staff.
Any questions regarding the FPEIS should be directed in writing to the fol-
lowing address:
FPEIS Project Officer
U.S. Environmental Protection Agency
Special Studies Staff (MD-63)
Industrial Environmental Research Laboratory
Research Triangle Park, North Carolina 27711
or by telephone to:
FTS 629-2745
Commercial 919-549-8411, Extension 2745
-------�
UG-4.0-0
SECTION 4
ON-LINE REQUEST PROCEDURE
CONTENTS
Number Item Page
4.0 Introduction. ........ ..... UG-4.0-1
4.1. Interactive Terminal Operation. . . UG-4.1-1
4.2 Remote Batch Terminal Operation UG-4.2-1
4.2.1 Accessing the FPEIS Data Base UG-4.2.1-1
4.2.2 Invoking FPEIS System Request Commands UG-4.2.2-1
4.3 Summary UG-4.3-1
4.4 FPEIS User Support UG-4.4-1
-------�
UG-4.0-1
4.0 Introduction
The procedure described in this section may be used by qualified NCC users
to access the FPEIS data base directly through an interactive data communi-
cations terminal or a remote batch terminal. Qualified users are defined
as those who have valid account numbers and site identification codes as
specified by NGC User Services at Research Triangle Park, North Carolina.
For information regarding User Services, the user is directed to Section
6.1.4.
On-line users of the FPEIS are assumed to have a working knowledge of
UNIVAC demand processing and SYSTEM 2000 natural language. Any user not
thoroughly accustomed to them is urged to request information through the
off-line procedures route described in the previous section.
On-line users are granted READ-ONLY access to the FPEIS data base. No up-
dating of data are permitted. New data input must be submitted through the
EPA project officer. In the READ-ONLY mode, the user may retrieve for sort-
ing and evaluation any data stored in the system. The user may take advantage
of the wide array of features offered by SYSTEM 2000 for data sorting and
retrieval. A general description of SYSTEM 2000 is included in Section
6.2. For reference purposes, the FPEIS data base definition is given in
Section 6.5, and lists of key and nonkey data elements are given in Sec-
tion 6.6.
-------�
UG-4.1-1
4.1 Interactive Terminal Operation
(To be added at a later date)
-------�
UG-4.2-1
4.2 Remote Batch Terminal Operation
Since the NCC UNIVAC 1110 computer supports a variety of remote batch (KJE)
computer terminals, the user is directed to the operating guide of his par-
ticular terminal for specific instructions for establishing communications
with the NCC. A list of RJE terminals currently supported by the NCC is
given in Section 6.1.4.
Telephone access numbers to the NCC may be obtained from NCC User Services
(see Section 6.1.4).
-------�
UG-4.2.1-1
4.2.1 Accessing the FPEIS Data Base
In order to access the FPEIS data base in the batch mode, the user must
either use a cataloged FPEIS System Request Command procedure or enter the
data base in SYSTEM 2000 Queue Access mode. Use of the SRC in batch mode
is discussed in the next section. The use of Queue Access will require the
following general computer card arrangement:
Card Column 1 8
©RUN,a account number,qualifier, parameters
©ADD FPEIS*FPEIS.START
QUEUE:
(SYSTEM 2000 commands on cards in the order in which they are to be
processed.)
TERMINATE:
EXIT:
©FIN
Details on use of the Queue Access module may be found in the SYSTEM 2000
I/
Reference Manual.
I/ SYSTEM 2000 Reference Manual, MRI Systems Corporation (August 1974).
-------�
UG-4.2.2-1
4.2«2 Invoking FPEIS Request Commands
Section 5 of this document contains a list (or catalog) of standardized
user request procedures, called System Request Commands (SRC), which may
be utilized to retrieve data in a certain manner. The specific instructions
for using the commands are given in Section 5. Many of these commands utilize
the STRING Command feature of SYSTEM 2000. In essence, the string commands
are a compact, uniquely-identified list of SYSTEM 2000 instructions which
may be initiated by a single command.
Batch users of the FPEIS may invoke the System Request Commands by follow-
ing the procedure given in the USER PROCEDURE for batch mode. It should
be noted that several SRC's are designed specifically for use in batch
processing mode only. In most cases, any SRC which is executable in the
demand processing mode is also executable in the batch mode.
-------�
UG-4.3-1
4,3 Summary
(To be added at a later date)
-------�
UG-4.4-1
4.4 FPEIS User Support
The FPEIS is supported by IERL-RTP. The administrative functions relative
to the FPEIS are provided by the Special Studies Staff in IERL. Develop-
mental work on new concepts for sorting and retrieval programs is performed
by government contractors under direction of the FPEIS project officer in
the Special Studies Staff.
Any questions regarding the FPEIS should be directed in writing to the fol-
lowing address:
FPEIS Project Officer
U.S. Environmental Protection Agency
Special Studies Staff (MD-63)
Industrial Environmental.Research Laboratory
Research Triangle Park, North Carolina 27711
or by telephone to:
FTS 629-2745
Commercial 919-549-8411, Extension 2745
-------�
UG-5.0-0
SECTION 5
CATALOG OF SYSTEM REQUEST COMMANDS
CONTENTS
Number * Page
5.0 Introduction 5.0-1
C3000 FPEIS Summary Report - Complete C3000-1
-------�
UG-5.0-1
5.0 Introduction
In order to aid users in the use of the FPEIS, a catalog of pre-defined
(or "canned") sorting and retrieval procedures has been developed for the
FPEIS. These procedures are called System Request Command, or SRC's. Each
SRC has a unique indentifier beginning with the prefix "C3." For some SRC's
which utilize the SYSTEM 2000 STRING command feature, the SRC number or
identifier will have a special significance that will be discussed in the
user instructions for that SRC. In general, the SRC number is a convenient
way of identifying the specific procedures.
Each entry in the SRC catalog is identified by the SRC number and the title
for the procedure. A brief abstract on the nature of the SRC is given, and
any input data required from the user are identified. Also, any qualification
needed for NONKEY data elements is given, A step-by-step procedure for execut-
ing the procedure is given both for demand users and for batch users. A
sample output produced by the SRC is included as well as any comments which
may be helpful to the user in executing the command.
As additional SRC's are added to the catalog, this section will be updated.
-------�
UG-C3000-1
SYSTEM REQUEST COMMAND NUMBER; C3000
TITLE; FPEIS SUMMARY REPORT - COMPLETE
ABSTRACT;
This SRC produces a complete listing of the contents of the FPEIS data base»
The data are listed in the standard FPEIS Summary Report format. The data
are in order of source category, then by series, subseries, and run. This
SRC produces several thousand pages of output and is available only to batch
users.
INPUT DATA REQUIRED;
None
DATA ELEMENT QUALIFICATION REQUIRED;
None
INTERACTIVE TERMINAL PROCEDURE;
Not available to demand users.
BATCH PROCESSING PROCEDURE
The complete FPEIS Summary Report may be obtained by submitting the fol-
lowing sequence of control cards;
(Valid ©RUN card)*
@ADDbbFPEIS*FPEIS.REPORT
©FIN
where b denotes one blank card column.
* The ©RUN card contains job priority, run time limit, accounting data.
This information must be supplied by the user. Refer to "NCC User's Refer-
ence Manual," U.S. Environmental Protection Agency, Data Systems Division,
National Computer Center, Research Triangle Park, North Carolina, April
1974 (revised).
-------�
UG-C3000-2
COMMENT;
Implementation of this procedure will result in the printing of a large
volume of computer paper (several THOUSAND pages). Users are urged to sub-
mit an "off-line" request so that the printing may be done locally at
Research Triangle Park, North Carolina. The output would be shipped to the
user.
SAMPLE OUTPUT;
A sample output of one test series is given on the following pages.
-------�
FINF PARTICIPATE EMISSIONS INFORMATION SYSTEM
FPFIS SUMMARY REPORT
TEST SERIF.S MO:
TFST Sl-RtES AT SITF FROM l?/()4/73 TO 13/14/73 BY: MIDWEST RESEARCH INST., KANSAS CITY. MO.
CF: SHANNON. L.J.. E.T AL . • FPA-ftS(»/i?-74-0 73. AUG. 74
SOURCE CHARACTFHISIICS
NKDS SCC CAftf-i
ORF. HA
f ttO
CLASS:
L CLASS:
MUllf
EXTTOMM Hr>II..FH
ELECTRIC fif'NFHATN
SOLID WASTF/COAl
G.T. 100MMHTU/HP
SITF NAME MFRAMEC PLANT
SOURCE NAME BOILER UNIT 1
ADDRESS H200 FINE ROAD
ST. LOUIS
UTM 70NE AND X-Y COORDS: 15
MO 63120
725.0 475.0
CONTROL OtVICF(S) CHARACTER ISTICS-
COMMFRCIAL NAME: ELECTROSTATIC PRECIPITATOR
MANUFACTURER: RESEARCH COTTRELL
UN I T I
01: VICE GtNf.KIC TYPF: ESP
CATt.GOWY: PftPflLI FR PLATE ESP
CLASS: coNvFK'T IOMBL
DF.SCRIPTION: ?-UNITS IN PARALLEL WITH COMMON INLET DUCT AND SEPARATE OUT-
LET DUCTS.
CONTROL OtVlCF(S) IJFSIGN PARAMETERS - -
1 1 ELFCTWOnF AREA
?) CORONA WIRF 01 A.
3) PLATE TO PLATF SPACING
M?
?.H MM
?38 MM
TEST SERIES REMARKS
IMPflCTOK CUT RUINT1' CO^PUTFC) FROM RANZ AND WONG THEORY
O
CO
O
O
O
u>
-------�
TEST SERIHS NO:
MO: 1
IMLFT
TEST DATE: 12/04/73 FROM oa:3o TO 11:00 HOUR
TEST CHARACTERISTICS
SOUMCE OPERATING Moot: COAI. *REFUSE HIIRNING SOURCE OPERATING RATE: 1?0 MW PCT DESIGN C APACI TV: 100.
FEED MATE*ML: ORIFNT 6 COAL AND MIJN. REFUSE FEED MATERIAL COMPOSITION: 99, REFUSE
CONTROL DEVICE INLFT SAMPLINR POINT DESCRIPTION: ABOUT 2M FROM REND (RAD. OF CIJRV.=2.3M) % ISOKINETIC: 100
PROCESS CONDITIONS: VOL FLOW = 169.0 DNM3/S VELOCITY= 20.* M/S T= 164 C P= 760 MMHG WATER VAP %VOL= 8.5
GAS COMPOSITION: ONSAT- co?= i4.sn % co= .01 % o?= 6.50 * N2= 79.00 «
TRACE GASSESIPPMl-SO2=900, 503=0. N0=220
CONTROL OEVICF(S) OPERATING PAR/1MFTFMS
1) VOL'IMFTRTC FLOW HATF ?30.1 M3/S
?) APPI I En VOLTAGE 32 KV
3) CORONA CII^PFNT ?53 MAMP
4) POWFR H KW
S) SPAPK RATE 115/MiN
PARTICULATE MASSTHAIN RESULTS
FRONT HALF= S./^10E*05 UG/DNM3 TOTAL= 4.7flOE+06 COMMENTS: EPA METHOD 5 TRAIN
PARTICULATF PHYSICAL PROPEMflh'S
OENSITY= ?.?7 tiM/CC ASSUMED RESISTIVITY= ^.3flF+H OHM-CM ASSUMED
CHEMICAL COMPOSITION DATA
PARTICULATt SAM^LFP UNCALIRRATFD
SAMPLFW STAGE CUT POINTS (UM)
01214S67H9
7.S T.H 2.3 1.5 .7<* .41
IS.
,1
CHEMICAL
ANALYSIS MKTHOI!
CHFMICAL CONCENTRATION IN (UM/DNM3)
Tf'N STAGE STAGE. STAGE STAGE STAGE STAGE STAGE STAGE
/POOI.I) 1 2 1 4 "S 6 7 8
STAGE
9
1)
ATOMIC.
?) CAIlMIIII'
A HIM It UHSO^PII UN
3) CHPOMHIM
ATOMIC AHSOHPTlUN
*) COMALT
ATf>"lL ABSORPTION
S) COOPf.M
AT'>K'IL ftHSO^PT ) ON
2.1 »1 4.6 «() 7.6 »n 4.1 +0 4.7 »0 1.79*0 4.fll + 0
l.H »? 1.0 »l 1.^3*2 H.O *1 1.17*2 2.22*1 2.83*1
l.?l*3 2.1^*2 3.^9*2 9.40*2 2.68*3 2.24*2 8.63*1
4.? *) 2.2 *1 2.S «1 2.4 *1 4.9 «1 3.7 *0 3.3 *0
?.'• »? 1.2R*2 2.27*2 1.32*2 4.91*2 1.32*2 1.68*2
O
O
O
O
-------�
t>) l.t.AO
ATOMIC ABSORPTION
7) MANGANFSt
ATOMIC ArtSOHPTION
8) NICKtL
ATOMIC ABSORPTION
9) TELLURIUM
ATOMIC ABSORPTION
10) THALLIUM
ATOMIC AHSOPPIIlJN
11) TIN
ATOMIC ABSORPTION
1?) VANAO1HM
ATOMIC ABSORPTION
13) ZINC
ATO'MC AMSOPPT10N
14) CALCIUM
ATOMIC ABSORPTION
15) IWON
ATOMIC AHSORPTION
4.2h*l 1.^6*1
S.66+2 1.30*?
1.43+3 4. + 2
1.1+1 1.9+0
3. H »0 1 . +0
1.3*1 H.I +0
1.43*3 4.14*?
1.35*3 6.89+? 9.66+2
7.3 +4' 1.68+4 2.94*4
2.39+?
7.31+2
1.9 +0
1.2 +0
6.6 +0
2.57+1 1.05+1 9.14-1 5.06-1
1.65+2 4.96+2 3.25+1 3.43+1
6. +2 2.14+3 3.43+1 6.87+1
2.6 +0 5.5 +0
-1.8+0 4.1 +0
9. +0
3.7*0
7.13+2 5.16+2
6.80+2
1 .68 + 4
8.64-1 2.04+0
1.38+0 2.71+0
1.63+0
9.79+1
2.3 +0
6.46+2 7.71*1
2.32*3 2.29*2 2.03*2
6.71*4 4.20*3 6.90*3
4.?6+5 1.26*5 1.35*5 2.57*5 1.05*5 9.14*3 5.06*3
SUHSFHJES PfMARKS-
O
O
Co
O
O
O
I
Ol
-------�
TFST SFHIFS NO:
sU"SKP(f:S 'in:
PUN NO: l
OEVICF INLET
MF.ASUHFMFNT PAPf
'•'FAS. INST/METHOO: i HPIMKS MMS-IT
COLLECTION SIJKFACF/SUHSTWATF: STAINLESS STEEL
"FAS. START T I "IK : -T.'-IO SAMPLING PFUIOD: IS.O MTN
r,AS SAMPLING rONDTTIONS: TF«P =
ON Trtfc. MFASUPFnfNT:
(ONCALIUHATFO) SIZF HANGF
SAMPLING WATF.: 1.87 LPM
= 7f>0 MMHH VATFD VAP
.100 TO IS. 000 UM
DILUTION FACTOR:
= 9.7
1.0
PAPTICLF. SI7F nlSTHlHUTIOM OATA
AKROnv.MAM 1C
HNO^Y
IS. 000
7.500
3. H<> 7
/?.?t»4
1 .S45
.790
.409
.100
1)1 A
MIO
10
S
;?
1
1
(UM)
PT
.607
.343
.9SH
.(IMS
. 10S
,b*H
.?.()?.
PARTICLE OIA HIM)
HNOMY ^'TD PT
9.S(^3ft
1.000 l.??S
.SOO .707
.?SO . 3S4
,OS4 . 1 l*i
DM
fii/* / n M M ~j i
(lllT/lirjMJI
p cj ocjp
1.130E
q. 343E
4 .Sf>4F
?.7fllF
H.?0?K
1.HS4F
*05
»OS
404
»04
+ 04
«03
«04
OM/OLOAF.
IMP /f^KIMII
1 ll'7/ U(Nrl J >
9.9fS?E»OS
3.837F.»05
4.?'iSE»05
2.644E*05
9.547E»04
2.869E»04
3.031F. + 04
h*«K
ns
/IIMO/ffl
( 11" ** /*-*L 1
i
8
1
q
1
b
4
.1 31E+OS
.4H9E+04
.?75E»05
.fS!E»04
.039E+05
.132E»04
.?37E»05
1 H-Lt Ur.lNSl 1
OS/OLOAE
| i i|u| -y / f f* \
1 UM/* f Li, 7
3.7S6F. + 05
2.8R3F+OS
5.8??E*05
5.707E+05
3.5f.8E»05
2.145E+05
6.926E+05
T= C*CI «"/V,l
ON
IMA / r r \
\ riu . / v-v. i
7.321E»02
2.183E+03
1.082E+04
2.091E*04
6.613E+04
1.562E+05
1.008E»07
DN/DLDAE
f Ml*» /f*P 4
i IMU • / V.L. /
2.432E«03
7.413E+03
4.942E+04
1.211E»OS
2.270E+05
5.463E»05
1.648E+07
CUM M
TOTAL MASS COMC= 6.06SF*OS
TOTAL SIIHF CONC= 1.013F + 06
TOTAL NUM CONC= 1.03«E*07
O
O
LO
O
O
O
-------�
TEST bFRTF.S MO:
I-i
NO:
NO:
CONTROL DEVICE INLFT
MEASUREMENT MARriCUl
(UMCAL1HRATEO)
SUE RANGE: .100 TO 15.000 DM
MK«S. lNST/"if THOP: 1 HRINKS HMS-I!
COLLFCTIUN SU^FACF/SUHSTRATF : STAINLESS STFFL
Mf-AS. START TIMt: 1030 SAMPIING I'ERIOO: ?0.0 MIN SAMPLING »ATE: l.«7 LPM DILUTION FACTOR: 1.0
GAS SAMPLING COMOITIDNS: TFMP=
COMMENTS ON T1-^
760 MMH«
WATER VAP ""iVOL = 9.0
PAHTICLE SI/E 0 ISTH1HUTIOM D«T«
MNflRY
lb.000
7. SOO
3.H07
2.?99
1 .S4U>
.790
.'.09
.100
C 01A (IJM) PARTICLE
Mill PT HNdRY
9.929
10.6I)/ A.'JSl
i>.3<« i ?.SnO
?.9bH 1 .SUO
1 .Hr(S ) .OUO
I.IOS .SUO
•bhH .?bO
.20? .OS4
01 A HIM)
MID (JT
7.011
3. SI B
1.93*
1 . P2S
.707
. TS'i
.1 1*
[IM
(IIG/DNM3)
A.7M3E+OH
»03
0.
« . 7 4'. E * 0 3
OM/OLOAE
(IJG/ONM3)
PARTICLE nENSITY= 2.37 GM/CC
DS
(UM?/CO
DS/DLDAF
(UM?/CO
ON
(NO./CO
?.010E»05 3.2H5E»05 4.782E*06
DN/DLDAE
(NO./CO
H.29SE+06
1.6?4E«06
6.70hE*05
2.43HE*OS
1 . 1R*E«04
0.
9.413F«05
3.SC>3E*OS
?.005E+OB
9.0H?E+04
1 .?91F»04
0.
3.1?7E»06
1.220F+06
9. 1S4E»05
5.26?E»05
4.432E«04
0.
6.095E»03
9.240E*03
1.702E«04
1.928E»04
8.21ftE»03
0.
?.025E«04
3.13BE+04
7.770E«04
1.117E*05
?.821E*04
0.
7.817E»06
CUM M
(*)
TOTAL MASS CONC= 3.177F+06
TOTAL SURF CONC= l.«06E*06
TOTAL NUM CONC= 4.84?E»06
o
OJ
o
o
o
I
-------�
TEST
OIITLFT
TEST DATE: 12/04/73 FROM oe:«o TO 11:00 HOUR
TEST CHARACTF'"ISTICb
SOIIPCE OPERATING MODI-: : COAI »WFFUSF MllPMJNn SOURCE OPERATING RATE: 120 MW PCT DESIGN CAPACIT Y: 100.
FEF.O MATERIAL: OWIFMT * COAI /VNO MUN. i>EFUc.t FEED MATFRIftl. COMPOSITION:
O
O
O
I
00
-------�
TEST SERIES no:
NO:
MO: 1
CONTROL OFVICF OUTI.FT
MEAS, INST/Hh Imin: >> ANOFPSFN MOI.IFI. IV
COLLECTION SU*HACF/SUHST4ATF: GL«SS FIMFR FILTER
MF.AS. START TIMF: 840 SAMf'l.TNR PERIOD: PO.O MIN
(iAS SAMPLING CONDITION* : TFMP =
COMMENTS UN T^t. MF (.SI.IHKMFNT :•
If.'. C.
(IINCALIRRATF.m SI7F RANGF: .100 TO IS.000 UM
SAMPLING PATF: ?0.22 LPM DILUTION FACTOR:
PMF.SSURfc'= 7*0 MMHG WATFP VAP %VOL = fl.5
1.0
PA>3F»03
P.397K+03
4.7ciOE + 03
/ 1 Ki / rtMM 1 1
\ \ t\j / i IINH 1 1
1.279F. + 05
6.7KOE+04
9.334E+04
5.454E»04
7.406E»04
5.009E*04
2.00?E*04
1 .414E+04
7.3fl?E+03
KOK 1 11
OS C
/ 1 IM p / C" r* i
\\.)~r/\j\^t
4.4H9E+03
6.107E+03 ,
1.074E*04 (
9.1P5E+03 5
2. 18RE*04
4.1 17E+04
2.136E*04
1 .9()9E + 04
1.044E»05
-Ut UCW1 1 1 1
)S/OLOAE
1 IM5 /f C \
U ™ < f \f \* 9
J.fl^lE+OA
•*»t^M5F*-04
>»337E*04
J.470E+04
.131F+05
.36BE*05
,006E«05
. 126E»05
.623E+05
r= e»ei »n/ui
DN
i Kin /cr \
inu./l-*-l
1 .S92E + 01
5.393E*01
2.255E*02
4.183E+02
2.323E*03
1.398E*04
2.45
O
O
O
vD
-------�
TFST SFR1KS Mfi:
MUM Mil: ? CONTROL OEVICF OUTLFT
( CAL IHPATHI1)
SI7F RANG^: .hSO TO l.SOO UM
MKAS. INST/MI- Inn'.): .T CLIMFt Mollf I. CI.-PM* OPC
COLLFCTION Sil^F'ACF/SUHSTI'AT^ :
"KAS. STAKF Tli-lk: 'MO SAMPLING P(-oiO|): 1.0 MIN SAMPLING RATE: 7.0fl LPM DILUTION FACTOR: 1.0
(>AS SAMPLING COMDl f 1 OM1;: TFMP= ?S r
OW THt MFASHPfi
PPFSSURE= 760 MMHfi
WATER VAP %VOL = 12.0
PARTICLE M/F MIST" IHI.IT 10* OATA
AFUOOYNAMIC DIA (U'") PAPTICLF
MMI.lRY M[l) PT MNilwr
?.?49 1.SI10
l.syo i.^i? i.njo
1.319 I ,44<( .ftSd
1.017 1.1^M
Ml")
ri PT
UM/OLOAF
(UG/nNM.3)
8..100K
PARTICLE OENSITY= a.27 GM/CC
ns
(IJM?/CC)
OS/OLOAF
((IMP/CO
ON
(NO. /CO
DN/DLOAF
(NO. /CO
3.93SF»03 1.340E»03 8.368E»03 2.760E»02 1.724E*03
1.101E+04 1.3S3E*05 4.002E*03 4.919E+04
^4 1.6S4E*05 I.077E»04 9.530E+04
CUM M
(*)
TOTAL MASS CONC= Q.7HCfF
TOTAL SURF CONC= 3.104F*04
TOTAL NUM CONC= l.b05E»04
o
o
o
o
i
-------�
TFST SFMIKS NO:
NO:
HUM WO:
CONTHUL OEVICF OUTLF_T
MF
MtAS. INST/MHTHfi'i: a CM COHNIF K/UIKF. HVTTFHY
COLl FCT ION SU'-h ACF/SUIIS T'> A TF' :
MF. AS. STftWT T1MF: |0 1.4?HF»03
1 ,7H^F.«01 2.VS6E + 01
1.97?F.-ni t
PARTICLE DENSITY= 2.27
OS DS/DLDAF ON
l.S76F»03
2.610E+03
2.143F+02
2.500E«05
4.?OOE»05
5.600E+05
1.400E«05
DN/DLOAF
(NO./
2.244E»06
9.273E»05
6.089E»05
CUM M
(%)
TOTAL
Cl)Mr= 9.HSOF»0?
TOTAL SURF COMC= 2.4P4F+04
TOTAL NUM CONC= 1.370E»06
O
O
U)
O
O
O
I
-------�
UG-6.0-0
SECTION 6
APPENDIX
CONTENTS
Number item Page
6.1 Description of National Computer Center. ....... UG-6.1-1
6.2 Description of SYSTEM 2000 UG-6.2-1
6.3 Standard Data Input Forms UG-6.3-1
6.4 FPEIS Standard Report Output UG-6.4-1
6.5 FFEIS Data Base Structure UG-6.5-1
6.6 List of Key/Nonkey Data Elements UG-6.6-1
6.7 Test Series Numbers and References in the FPEIS. . . . UG-6.7-1
-------�
UG-6.1-1
SECTION 6.1
DESCRIPTION OF EPA NATIONAL COMPUTER CENTER
CONTENTS
Number Item Page
6.1.1 Introduction. .......... .... UG-6.1.1-1
6.1.2 NCC Computer System Description UG-6.1.2-1
6.1.3 Summary of NCC Software Capabilities . UG-601.3-1
6.1.4 NCC User Services UG-6.1.4-1
6.1.5 Summary of References and Documentation UG-6.1.5-1
-------�
UG-6.1.1-1
6.1.1 Introduction
The Fine Particle Emissions Information System (FPEIS) is resident on EPA's
National Computer Center (NCC) system at Research Triangle Park, North
Carolina. The NCC is a general purpose data center, supporting both scienti-
fic and administrative application areas, and provides interactive as well
as batch capabilities. Remote users have access to the NCC via a national
system of low speed and high speed data communication lines. Since some
FPEIS users may be qualified to access the NCC, and in so doing access
the FPEIS data base directly, this section has been added to the report
to acquaint users or potential users of the FPEIS with some of the capabili-
ties of the NCC.
The National Computer Center is organizationally structured under the Manage-
ment Information and Data Systems Division, of the Office of Administration,
EPA headquarters in Washington. NCC services are provided by two branches:
the Analysis and Support Branch and the Computer Systems Branch. The Analysis
and Support Branch provides ADP support service to the user community while
the Computer Systems Branch is responsible for maintaining the computing
>
utility. The NCC staff is augmented by a facility operations contractor
who provides technical support in the areas of machine operations, system
programming, and user support services. Sperry-Univac, the computer system
vendor, maintains a resident staff of hardware engineers for data preparation
services and data base management consultation.
-------�
UG-6.1.1-2
In the following sections, descriptions have been enclosed of the NCC com-
puter hardware, available computer software, user support services, and
pertinent references. Users are cautioned that the information contained
in these discussions is of a summary nature and is not intended to provide
reference-level details on the NCC system. Furthermore, as enhancements
to the NCC are made, parts of the discussion material in this report may
be subject to change. To ensure the accuracy of the descriptions presented
here, the user is requested to contact NCC User Services at Research Tri-
angle Park. This is discussed in greater detail in paragraph 6.1.4.
-------�
UG-6.1.2-1
6.1.2 NCC System Hardware! Configuration^'
The National Computer Center data processing hardware consists of memory,
processors, mass storage, magnetic tape, unit record equipment, and com-
munications equipment. The base system is the UNIVAC 1110 computer.
Processors, Memory
o Processor Model Number - UNIVAC 1110 3023-99
o Basic 2x2 configuration consisting of two Command/Arithmetic
Units (CAU) and two Input/Output Access Units (IOAU) each. A single
IOAU has 16 I/O channels available.
o Main memory has a capacity of 935,936 36-bit words. This represents
3,743,733 bytes.
Mass Storage
o FH-432 Drum
Number
Average Access Time
Transfer Rate (Maximum)
Capacity (Total)
4.3 milliseconds
240,000 words/sec
1.57 million words
o FH-1782 Drum
Number
Average Access Time
Transfer Rate (Maximum)
Capacity (Total)
o 8440 Disc (Removable)
Number
Average Seek Time
Average Access Time
(Latency)
Transfer Rate
Capacity (Total)
17 milliseconds
240,000 words/sec
4.2 million words
32 (4 subsystems)
30 milliseconds
12.5 milliseconds
138,666 words/sec
640.24 million words
(about 232 positions/disc.)
_!/ National Computer Center, "IM 370 to UNIVAC 1110 Conversion Guide I:
General Overview," March 1976.
-------�
UG-6.1.2-2
Mass Storage Space Units
o 1 Word = 36 bites
= 6 characters
= 4 bytes
o 1 Sector = 28 words = 168 characters
= 112 bytes
o 1 Track = 64 sectors = 1,792 words = 10,752 characters
= 7,168 bytes
o 1 Position = 64 tracks = 4,096 sectors = 114,688 words =
688,128 characters
= 485,752 bytes
o Random Storage Prepping = 4 sectors = 112 words = 672 characters
= 448 bytes
Magnetic Tape Units (Uniservo - 16 tape drives)
o Dual Density, 9-track
Number
Density
Transfer Rate
Speed
o Multiple Density, 7-track
Number
Density
Transfer Rate
Speed
o 9-track
800,1600 bpi
96,000-192,000 frames/sec
305 cm/sec (120 in/sec)
200,556,800 bpi
24,000-96,000 frames/sec
305 cm/sec (120 in/sec)
Number
Density
Transfer Rate
Speed
20
1600 bpi
192,000 frames/sec
305 cm/sec (120 in/sec)
-------�
UG-6.1.2-3
System Control Consoles
o Two consoles, each consisting of one Uniscope 100 CRT display and
keyboard with a DCT 500 hardcopy printer.
Communications Equipment
o Two Communications Terminal Module Control (CTMC) units which offer
transmission speeds from 300 to 50,000 bits/sec. There are 64 total
parts available.
Plotting Equipment
o One CalComp Model 1136 drum plotter with 4,096 words of 9 bit core
storage. The plotter is driven by a 1600 pbi, 9-track tape drive.
There are three pens per plot head. The plotting speed is 23.4 cm/sec
(9.2 in/sec).
Remote Communications Terminals Supported
o Interactive (Demand) Processing
UNIVAC Uniscope 100 terminal
UNIVAC DCT-500
Teletype Models 33, 35, 37, and 38 (KSR/ASR)
Friden Model 7100
Anderson-Jacobsen Models 630 and 830
Tektronix Models 4051 and 4010
o Remote Batch Processing
UNIVAC U-9200 II RJE terminal
UNIVAC 1004 RJE terminal and 1004 emulation (e.g., Data 100/78)
-------�
UG-6.1.3-1
6.1.3 Summary of NCC Software Capabilities-!:7
The EPA National Computer Center offers a wide selection of business, scien-
tific, special purpose (including utilities), language processors, and miscel-
laneous software. The following is a brief description of some of the soft-
ware offered:
Language Processors
o FORTRAN V
o ASCII COBOL
o ASSEMBLER
o ASCII FORTRAN
The FORTRAN V language has all of the features
of the proposed American National Standard
(ANSI) FORTRAN IV language and has many extensions
which increase the power and flexibility of
the language, particularly in the area of data
handling.
The COBOL language available is the American
National Standard (ASCII) COBOL. This language
is used primarily for business-related applica-
tions.
The 1110 ASSEMBLER language is a powerful user
tool designed to facilitate the preparations,
editing, and debugging of machine level pro-
grams for execution instead of procedure level
programs.
This is a new system on the 1110 that offers
certain features not available from FORTRAN
V. It conforms to the ANSI FORTRAN standard
and encompasses revisions to the standard which
were expected to be approved during 1975.
II National Computer Center, "IBM 370 to UNIVAC 1110 Conversion Guide
I: General Overview," March 1976.
-------�
UG-6.1.3-2
Scientific Software
The following is a brief discussion of a few of the scientific software
packages available on the NCC. For a complete list of scientific software
available on the UNIVAC 1110 which may or may not be supported by the NCC,
please contact NCC User Services (see paragraph 6.1.4).
o SYMAP
o STAT PAK
o MATH PAK
o SPSS
o FMPS
o TSL
A graphics system designed for making visual aids
for presentations to nontechnical audiences.
A comprehensive library of 91 fundamental statis-
tical subprograms coded in FORTRAN V, including
Chi-square tests, regression analysis, time series
analysis, etc.
A comprehensive library of 84 fundamental mathe-
matical subprograms coded in FORTRAN V, including
numerical integration, curve fitting, matrix
manipulation, etc.
Statistical Package for the Social Sciences, and
integrated system of programs for analysis of social
science data.
Functional Mathematical Programming System, an
advanced mathematical programming language, which
may be used to solve difficult mathematical problems.
Time Sharing Library, a series of interactive statis-
tical analysis programs which provide a comprehensive
and unified resource for performing many different
types of data analysis expeditiously.
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UG-6.1.3-3
o OMNITAB - A highly user-oriented system of programs for
simple and complex numerical, statistical, and
data analysis. It was developed by the National
Bureau of Standards and is intended for a non-
programmer audience.
o SAS - Statistical Analysis System, a uniform, simple
language in which to state the analysis to be
performed.
Business Software
Business software available on the NCC includes the following:
o SORT/MERGE - A file manipulation package available in two ver-
sions: a stand-alone parameter driver proces-
sor for use with COBOL and a SORT/MERGE subroutine
that must be invoked through an assembler lan-
guage interface.
o PERT - Project Evaluation and Review Technique, a gen-
eralized applications program for project/plan-
ning and control. The modular design of PERT al-
lows separate processing of the time networks
and cost structure while simultaneously provid-
ing for time and cost reporting.
Data Base Management Software
o SYSTEM 2000 - A generalized data base management system which
(S2K) allows users to define new data bases, modify
the definition of existing data bases, retrieve
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UG-6.1.3-4
and update values into data bases, and perform
data base maintenance functions. The English-like
command language of S2K enables the user to per-
form the above activities in either interactive
or batch modes* In addition, the Procedural Lan-
guage Interface feature permits the user to access
a data base through a COBOL or FORTRAN program.
S2K is developed by MRI Systems, Inc., Austin,
Texas.
Time Sharing Software
o GTS - Conversational Time Sharing, a subsystem of the
UNIVAC 1100 Executive System. GTS provides a con-
versational time sharing interface to the 1110
computer system for simplified demand processing.
Miscellaneous Software
o SSG - Symbolic Stream Generator, a processor which
produces a stream of data and/or control cards
(PROC's).
o SYMSTREAM - A processor language that is the syntax directed
coding that gives directions to SSG.
o CPDMPH - A utility processor which may be used to dump,
punch, and copy tape or mass storage files,
o CalComp Soft- - A package of basic plotter subroutines for use
ware with FORTRAN programs. The package includes
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UG-6.1.3-5
PLOT, SYMBOL, WHERE, PLOTS, NUMBER, SCALE, AXIS,
FACTOR, NEWPEN, and LINE.
o COPIE - A file manipulation utility which will accept
as input COBOL or FORTRAN created data files
residing on tape or mass storage and card files.
COPIES produces as output COBOL or FORTRAN com-
patible data files. COPIE can also be used to
convert or create IBM EBCDIC tape files.
o Concatenation - A utility routine which may be used with ASCII
Routine COBOL, FORTRAN, and ASSEMBLER routines to pro-
vide for the concatenation of multifile reels
and multireel files into a single file.
UNIVAC File Utility Routines (FURPUR)
The FURPUR processor consists of a set of file maintenance routines for
manipulation of catalogued or temporary files containing data or program
statements. There is a set of control statements recognized by the Execu-
tive as calls to FURPUR. Whenever the Executive encounters a FURPUR con-
trol statement, the FURPUR processor will be loaded into core. FURPUR con-
tinues to process control statements until signaled by the Executive that
the next statement is not a FURPUR control statement, at which time FURPUR
is terminated* Some of the FURPUR control statements available are:
o @CHG - Changes element name, version name, read key,
write key, and mode of a file.
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UG-6.1.3-6
o ©CLOSE - Writes two hardware EOF (end of file) marks on
a magnetic tape and rewinds the tape.
o ©GOPIN - Copies elements from an element file located on
magnetic tape into a program file on FASTRAND -
formatted mass storage.
o ©COPOUT - Copies a program file, or selected elements of
a program file, located on FASTRAND - formatted
mass storage onto a magnetic tape file in ele-
ment file format.
o ©DELETE - Drops catalogued files or marks elements in a
program file as deleted.
o ©FIND - Locates an element in a magnetic tape file (which
must be in element file format) and positions
the file before the element's label block.
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UG-6. 1.4-1
6.1.4 NCC User
User Services is part of the Data Systems Division at Research Triangle
Park, North Carolina, and was established to provide a central source of
information and problem solving support related to NCC UNIVAC 1110 processing^
This function consists of assistance in debugging problem runs, passing solu-
tions, etc., on to other users in the user community, as well as assisting
the IEM user converting to the UNIVAC system.
User Services may be reached as follows:
U.S. Environmental Protection Agency
Data Systems Division
User Services
MD-34
Research Triangle Park, North Carolina 27711
FTS 629-2804
Commercial 919-549-8411, Extension 2804
In addition to handling problems, User Services also provides an adminis-
trative interface user community. Requests for remote batch or demand
processing support are directed to User Services. All users of the NCC must
be registered for accounting and security purposes. Registration of qualified
users will be handled by User Services. The required forms may be obtained
from User Services.
II National Computer Center, "IEM 370 to UNIVAC 1110 Conversion Guide I:
General Overview," March 1976.
27 NCC USER'S REFERENCE MANUAL, U.S. EPA, Data Systems Division, National
Computer Center, april 1974 (revised).
-------�
UG-6.1.5-1
6.1.5 Summary of References and Documentation
(1) NCC USER'S REFERENCE MANUAL, U.S. Environmental Protection Agency,
Data Systems Division, National Computer Center, Research Triangle
Park, North Carolina (April 1974), revised.
(2) UNIVAC 1100 Series FORTRAN V Programmer Reference Manual, Sperry-
Univac Computer Systems, UP-4060, Rev. 2 (March 1973).
(3) UNIVAC 1100 Series Operating System Programmer Reference Manual, Sperry-
Univac Computer Systems, UP-4144, Rev. 3 (1973).
(4) USER'S MANUAL FOR EPA SCIENTIFIC APPLICATIONS SOFTWARE, Management
Information and Data Systems Division, Washington, D.C. (July 1975).
(5) UNIVAC 1100 Series Introduction to Time Sharing for GTS Users, Sperry-
Univac Computer Systems, UP-8117 (1975).
(6) UNIVAC 1100 Series American National Standard COBOL (ASCII) Manual,
Sperry-Univac Computer Systems, Up-7923, Rev. 1 (1974).
-------�
UG-6.2-1
SECTION 6.2
DESCRIPTION OF SYSTEM 2000
CONTENTS
Number Item
6.2.1 Introduction. ................. UG-6.2.1-1
6.2.2 SYSTEM 2000 Overview ' UG-6.2.2-1
6.2.3 SYSTEM 2000 References and Documentation. . . . UG-6.2.3-1
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UG-6.2.1-1
6.2.1 Introduction
The Fine Particle Emissions Information System (FPEIS) data base has been
implemented by use of the SYSTEM 2000* data base management system. SYSTEM
2000 has been used extensively to create management and technical informa-
tion data bases for government and nongovernment users. SYSTEM 2000 was
developed by MRI Systems Corporation of Austin, Texas, and was selected
as the method of implementation for the FPEIS because of its unique fea-
tures and flexibility.
Since many users of the FPEIS may not be computer system oriented, the authors
felt it advisable to include a brief discussion of SYSTEM 2000 in this report
to enable such users to gain a clearer understanding of SYSTEM 2000 and its
relevance to any user of the FPEIS. This is needed for several reasons.
First of all, the FPEIS is structured in such a way as to maximize the
utilization of SYSTEM 2000's unique features. This structure in turn will
dictate which data are to be entered, what constitutes a minimum data set,
etc. Secondly, the manner in which information is sorted and retrieved also
utilizes unique SYSTEM 2000 features. While many users will never request
data through direct interaction with the computer, it is important that
such users understand why data are arranged in a particular fashion or why
data retrieval must meet certain criteria. The key to understanding the
FPEIS data base is through an understanding of how SYSTEM 2000 works. Clearly,
it is not possible here to present a complete tutorial on SYSTEM 2000. A
more detailed discussion of SYSTEM 2000 may be obtained from the extensive
documentation available from MRI Systems Corporation, Austin, Texas.
* SYSTEM 2000 is the registered trademark of MRI Systems Corporation, Austin,
Texas.
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UG-6.2.2-1
6.2.2 SYSTEM 2000 Overview^/
SYSTEM 2000 is a generalized data base management system that operates on
IBM 360 and 370 series, UNIVAC 1100 series, and GDC 6000 and CYBER 70 series
computers. The Basic SYSTEM 2000, with selected optional features, provides
the basis for developing information systems tailored to the requirements
of the application and the user. The following is a brief overview of SYSTEM
2000 and its capabilities.
THE USER VIEW
Self-Contained Capabilities
(1) Simplicity—The SYSTEM 2000 self-contained languages are of a form
that was devised over many years of use. As an example, several key words
have three variations, e.g., HAS, HAVE, and HAVING. Whenever a modifica-
tion to the SYSTEM 2000 languages are made, care is taken to ensure "gram-
matical" correctness. In addition to being simple to use and easy to under-
stand, most SYSTEM 2000 commands have abbreviations. This simplicity was
also extended to data; that is, a user may specify a component's name or
numeric .identifier whenever the component is used in a command. For example,
C100 or SOURCE CATEGORY. Taken together, the command language and the data
components can in most cases self-document the query. For example:
II Gorman, M. M., and E. A. Wallish, "SYSTEM 2000 Capabilities," MRI Sys-
tems Corporation (1974).
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UG-6.2.2-2
PRINT SOURCE CATEGORY, SOURCE NAME WHERE STATE
G EQ KS:
or
PR C100, C100 WH C170 EQ KS:
(2) Data Independence—One of the cardinal principles that permeates SYSTEM
2000 is that the user's logical view of the data structure is free from
the restrictive conventions of data processing hardware. Thus a user per-
ceives only a natural hierarchical or linear view of his data organization.
The computer, however, has its own view of the data; thus single values,
multiple values, or global values can be changed, added, deleted, or re-
trieved without the user being aware of processes involved. In addition
to a single user view of the data structure, passwords may be employed
to present a subset of the structure, or the appearance of an entirely
different structure.
(3) Multi-Record, Multi-File Capabilities—SYSTEM 2000's qualification
clause in the Queue or Immediate languages allows for complex data selec-
tion for either retrieval or change. SYSTEM 2000 also allows definitions
of multi-record structures which may be linked by a single higher key ele-
ment for network type retrievals.
(4) Interactive—SYSTEM 2000 is designed as an interactive system. In its
original conception—some 20 years ago—there was provided a well engineered
foundation on which all its features are now built. The user may envoke
a command echo function which echos for the user all commands that were
-------�
UG-6.2.2-3
received. There is a large variety of diagnostic messages, and because of
the basic design of the system, all commands received the most immediate
response possible*
(5) Batch--SYSTEM 2000 has multiple methods for data base interrogation.
All of these query languages may be transmitted to the computer in either
the batch mode or the interactive mode.
(6) Maintenance and Query Data Editing—SYSTEM 2000 supports three types
of data editing. The first is automatic and consists of data type check-
ing and rudimentary field size checking. The second type is user coded and
is supported by the advanced TP monitor. The third type is "hindsight" check-
ing. That is, a user is easily able to check for illegal data values, ranges,
etc., with SYSTEM 2000 natural language commands once the data are loaded.
(7) Arithmetic—SYSTEM 2000 is able to perform arithmetic computation on
data that has been selected for either retrieval or for storage back into
the data base. SYSTEM 2000 is also able to "hold" the results of data searches
for use in another query. The conditional clauses can contain Boolean op-
erators, relational operators (GE, LT, etc.), range searches, and nested
conditions*
(8) Report Formatting Report--First, there exists in the Immediate lan-
guage the ability to place multiple retrieval commands in an invokable Macro.
These stored commands can cause the production of headers, trailers, re-
port dates, sorted columnar data with titles, subtotals, and totals. The
-------�
UG-6.2.2-4
arithmetic functions include COUNT, SUM, MIN, MAX, AVG, and SIGMA. A second
method is through a fully developed Report Writer.
(9) Linkage to Procedural Capabilities—SYSTEM 2000's advanced TP Moni-
tor is able to direct a transaction to SYSTEM 2000, a procedural program,
or to a procedural program which utilizes SYSTEM 2000 for data selection
and retrieval. Within the procedural languages, simple English-like state-
ments provide for security, data base management, data selection for re-
trieval or maintenance, audit trail creation, and damaged data base recovery.
These procedural capabilities are currently available in FORTRAN, COBOL,
and assembly languages.
(10) Mixed Views of Data—SYSTEM 2000 offers simple to use methods of
"creating" different views of a data structure. This is accomplished through
the use of passwords. SYSTEM 2000's passwords are independent of each other;
thus, each password is able to have described to it a logical subset of
the hierarchical structure. For each such logical subset description the
user may have retrieval, update, and qualification authorities for any or
all of the elements. Through the English-like password definition language,
these subsets can be dynamically created or discarded. A SYSTEM 2000 data
structure may be designed to contain one entry type or multiple entry types.
The password definition language may be used to shield one entry type's
description from the other*
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UG- 6.2.2-5
(11) Schema Modification--SYSTEM 2000 allows the user to change the data
base definition. The changes may be administrative in nature, i.e., pass-
word redefinition, component name changing, component number changing, and
data type redesignation. The changes may also be structural, i.e., adding
to the definition of a new element, deleting an element's definition, adding
a repeating group, etc. For some classes of changes, the modification re-
quires no change to existing stored data, and for others, the user is not
aware of the required stored data changes. All structure modification is
password controlled.
(12) Input Record Definition—SYSTEM 2000 utilizes the entry as the load
vehicle. An entry is a collection of related data sets and a data set is
the value occurrence for a particular element set. Because the entry is
variable in length--in terms pf the quantity of data sets loaded—the for-
mats for load transactions are user definable. The definition process may
be "real-time," a stored macro, or a formatted screen through a CRT input.
For complex entry creation, a procedural language program can be written
that selects, edits, and merges data from a single or multiple automated
files. These programs may be invoked in a batch or TP environment depending
upon the TP employed.
(13) Geographical Facilities—SYSTEM 2000 currently does not contain the
automatic facilities for standard geographic coordinates. SYSTEM 2000 does,
however, contain all the processing features that would enable this fea-
ture to be implemented easily. For example, data values are currently
-------�
UG-6.2.2-6
translated to a computable format. SYSTEM 2000 also contains a range de-
termination condition. An example, therefore, of how the geographic coordinate
system grammar would appear would be: PRINT COUNT SITE NAME WHERE UTM-X
SPANS < UTM-X min > * < UTM-X max > AND UTM-Y SPANS < UTM-Y min > * < UTM-Y
max > :.
(14) Extracting—SYSTEM 2000 has the capability of "dumping" whole entries,
part of entries, or computational results. These data may be then used for
input to another data base, for qualification data in subsequent queries,
and for use in other non-SYSTEM 2000 processing programs.
Procedural Capabilities
(1) New or Extensions of Existing Languages—MRI Systems Corporation feels
that existing procedural oriented languages (POL), i.e., COBOL or FORTRAN,
are so widely accepted that to develop an additional procedural-oriented
language would be counter-productive to a policy of standardization. MRI,
therefore, brought to these languages—in simple English-like phrases—many
of the natural language data selection and retrieval commands, many of
the data base maintenance and control commands, the data base audit trail
retention and data base recovery commands, etc. The results achieved are
procedural programs that have their data base management commands written
in a language that is machine independent.
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UG-6.2.2-7
(2) Self-Contained Facilities in Procedural Languages—Many of the SYSTEM
2000 data base control statements are "1 for 1" available in the procedural
oriented language. Much of the WHERE clause logic is also available in the
procedural oriented languages available in the POL. The data selection
logic is different in form, but very similar in logic to that of the SYSTEM
2000 natural languages. Therefore, since the concepts are similar, the
"retaining" necessary is minimal. Once learned, users state that their POL
programs are easier to design, program, debug, and maintain.
(3) Nature of the Language Extension—MRI, in keeping with its principle
of increasing user throughput, has designed its POL extensions to be sim-
ple English-like statements. For example: LOCATE MANUFACTURER WHERE GENERIC
DEVICE TYPE EQ ESP. The results of this command would be an array of pointers
to those data sets containing qualified manufacturers. MRI in keeping also
with its principle of increasing computer throughput, contains a precompiler
which translates these English-like statements into "hard" calls to sub-
routines. The user, therefore, has both the simplicity of command definition
and the swiftness of command execution.
(4) Data Independence—SYSTEM 2000 POL extensions are such that changes
to the data structure definition do not impact the POL program--providing
of course that the data elements to be retrieved have not been removed.
The user, therefore, has a high degree of independence from structure modifi-
cation.
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UG-6.2.2-8
PERFORMANCE
Interactive Mode
(1) Response Time—While response performance is certainly a function of
particular fields queried by the user, the nature of the query (e.g., multi-
entry or single entry conditioning), and the number of users, number of
entries retrieved or updated, and data base parameters (entry length, data
base organization, etc.), SYSTEM 2000's storage structure, query processor,
buffer management routines, easily enable the average response time to be
less than 10 sec.
(2) Storage Requirements
Disk—SYSTEM 2000 data bases are able to process from either tape or
mass storage requirements, that is, there is a Sequential File Process-
ing feature (tape) and a standard processing capability (disk). The
storage structure for SYSTEM 2000 data on disk is very sophisticated
as the system was designed to be interactive.
Core--SYSTEM 2000 currently occupies 25 to 30K words on CDC and UNIVAC
computers, and 120 to 300K bytes on IBM computers. The size of core
available directly affects processing speeds.
(3) Degradation and Recovery—SYSTEM 2000 has very sophisticated capabili-
ties for garbage collecting and reuse. In addition, there exists capabilities
to reorganize—on a selective basis—the tables that comprise a SYSTEM 2000
data base. Index table reorganization tends to greatly enhance the query
throughput.
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UG-6.2.2-9
Batch Mode
Processing in batch is similar to the response above with the following
exception. SYSTEM 2000 has Queue Mode processing. That is, a selection of
natural language commands and the commands in a POL program are able to
be "batch" processed. Basically, all the queued commands are analyzed to
determine the largest single subset of data that is needed to satisfy the
"action-clause" part of a query command. The action-clauses are then serially
processed against the subset.
Procedural Capabilities
All SYSTEM 2000 POL commands are compilable into "hard" code. This means
that SYSTEM 2000 POL commands are executed directly rather than interpreted
then executed. Savings are therefore significant.
NETWORK CAPABILITIES
While the SYSTEM 2000 data structure is hierarchical in nature, certain
network structures can be achieved through the natural languages, through
LINK commands, and through the establishment of higher level elements which
contain network relationship values.
SECURITY
SYSTEM 2000 offers very comprehensive security capabilities. In general,
security is divided into system use protection, entry use protection, and
element use protection. System use protection in SYSTEM 2000 is either a
function of its advanced TP monitor or the TP monitor under which SYSTEM
2000 is functioning. Under the SYSTEM 2000 TP monitor, there exists posi-
tive terminal ID security, user security, and transaction security.
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UG-6.2.2-10
Data base use protection in SYSTEM 2000 is achieved through a password.
If the user has the correct password for the correct data base, access to
the data base is granted.
Entry use protection in SYSTEM 2000 is achieved through an element that
has been declared as the entry key and that has a unique value for each
entry.
Element use security is achieved in SYSTEM 2000 through a password. For
each password, explicit permissions must be given for each element over
which the password is to have control. The permissions allow data retrieval,
data updating, data element use in a qualification clause for a retrieval
action, and data element use in a qualification clause for an update ac-
tion. Of singular importance in any secure system is the ability to dynami-
cally change all security permissions.
DATA AND PROGRAM RELIABILITY
(1) Recovery and Back-Up Procedures—SYSTEM 2000 provides an efficient
and easy to use mechanism for data base recovery from systems failures with
an acceptable level of data loss. This process involves the periodic dumping
of complete data bases onto off-line storage and the continual recording
of parsed update transactions as they occur from any update source in order
to repeat all or selectively those update operations which are not reflected
on a back-up copy.
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UG-6.2.2-11
(2) Access Controls and Data Integrity—SYSTEM 2000 has controls which
protect the data base from unrecognized damage. At the beginning of every
update, the data base is flagged "damaged" and only after every data change
has been written back onto the disk is the flag turned off. SYSTEM 2000
also traps all POL program errors to assure proper data base close outs
before returning to the host computer's operating system.
The security as described above provides supplemental control for file
protection.
Finally, file protection is additionally achieved through file lock-out
at the moment data or indices are about to be changed. This means that the
lock-out is achieved on a command by command basis rather than the 'update-
job1 basis.
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UG-6.2.3-1
6.2.3 SYSTEM 2000 References and Documentation
(1) SYSTEM 2000 REFERENCE MANUAL, MRI Systems Corporation, Austin, Texas
(1974).
(2) SYSTEM 2000 PROCEDURAL LANGAUGE FEATURE - FORTRAN, MRI Systems Corpora-
tion, Austin, Texas (July 1973).
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UG-6.3-1
SECTION 603
STANDARD DATA INPUT FORMS
CONTENTS
Number Item Page
6.3.1 Introduction UG-6.3.1-1
6.3.2 FPEIS Data Input Forms „ . . . UG-6.3.2-1
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UG-6.3.1-1
6.3.1 Introduction
Standard data input forms for the FPEIS may be found following this dis-
cussion. There are six forms in all. These forms may be reproduced for use
in encoding emissions testing data. Specific encoding instructions are given
in Section 2.
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STATIONARY POINT SOURCE
Form 1 12/76
A
- SOURCE
Test Series
No.
1
2
3
4
5
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INPUT FORMS
DESCRIPTION
5
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STATIONARY POINT SOURCE
Form 2 12/76
C - CONTROL
Test Series
No.
I
2
3
4
9
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INPUT FORMS
DEVICE(S) CHARACTERISTICS
Sub
Serle*
Mo.
4
t
ft
*v
n
No.
*
rt
Card
No.
II
C
12
0
13
1
Card
No.
II
C
12
0
13
2
Card
No.
II
C
12
0
13
3
r
j
14
14
u
M
Card 1
No. 1
II
C
12
0
I3H
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STATIONARY IPOINT SOURCE
Form 3 12/76
D •
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA IN)PUT .FORMS
- TEST CHARACTERISTICS
Test -Series
No.
1
2
3
4
i
Sub
Series
No.
6
1
8
Ryn
NO-
*
10
Card
No.
II
0
12
0
13
1
Card
No.
II
D
12
0
13
2
Card
No.
II
D
12
0
13
3
Cord
No.
II
D
12
0
13
4
14
t<
»
(*
r
15
14
13
IS
—Control Device
Test Sub Series
Date
Mo
14
17
Da
18
19
Yr
20
21
nlet or Outlet (I or
Start
Time
22
23
24
25
Stop
Time
26
27
2B
29
0)
Source Operating Mode
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
Feed Material *
16
17
It
l»
20
21
22
23
24
U
26
27
26
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
4!
46
47
48
49
50
51
52
53
54
55
56
57
58
59
Form Completed by
Source Operating Rate*
60
41
42
43
44
45
64
67
48
49
70
71
72
73
74
75
76
% Design
Capacity
77
78
79
i
80
Feed Material Composition*
46
47
41
49
50
51
52
53
54
55
Sampling Location Description*
14
17
It
19
C02',!
16
17
It
19
20
21
22
23
co*;
20
21
22
23
24
is
26
27
02*
24
25
26
27
28
29
30
31
N2*
2t
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
43
46
47
41
49
50
51
52
53
54
55
56
57
58
59
40
61
Volume
Flow Rate*
56
57
58
59
60
61
62
63
44
45
Velocity*
42
43
44
45
46
47
48
49
Temp*
66
47
68
49
70
71
72
73
74
Press.*
70
7)
72
73
74
75
74
77
% H2O
75
It
77
78
79
80
% Iso „
Kinetic
78
79
80
Trace Gases in ppm (Text)
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
40
61
42
43
44
45
66
47
48
69
70
71
72
73
74
75
76
77
78
79
80
CONTROL DEVICE(S) OPERATING PARAMETERS
Test Series
No.
I
2
3
4
5
Sub
Series
No.
6
7
8
ftu*
N0.
•)
u
Card
No.
II
D
D
D
D
D
D
D
D
D
D
U
D
D
D
D
D
D
D
D
D
12
0
0
0
0
0
0
0
0
0
0
U
0
0
0
0
0
0
0
0
0
13
5
5
5
5
5
5
5
5
5
5
i
5
5
5
5
5
5
5
5
5
f
14
H
a
M
14
17
-Device No. (1.2 or 3)
Specification *
IB
19
20
11
22
23
24
23
24
27
28
29
30
31
32
33
34
35
34
37
38
39
40
41
42
43
44
-
45
44
47
Value*
48
49
--
50
51
52
53
54
55
56
57
58
59
40
61
42
43
44
-
65
66
67
48
a
M
71
n
n
74
73
7*
n
71
7*
to
Need not be filled if the preceding subseries contains the same data.
O
I
Co
-------�
STATIONARY POINT SOURCE
Form 4 12/76
DATA INPUT FORMS
CONTROL DEVICE(S) OPERATING PARAMETERS (confd)
Test Series
No.
1
13
1
Sub
Series
No.
Run
No.
10
Card
No.
II
D
D
D
D
D
D
D
D
D
D
12
0
0
0
0
0
0
0
0
0
0
13
5
5
5
5
5
5
5
5
5
5
r
u
ft
™;
*£
is
;:>;:
':•:•:
:•:•:-
a.
If
14
17
—Device No. (1. 2 or 3)
Specification
18
19
20
21
22
23
24
29
26
27
28
29
10
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
Form Completed by
Value •
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
41
«
70
OM
n
w
14
ft
n
rt
78
•n
80
SUBSERIES REMARKS
Test Series
No.
1
2
Sub
Series
No.
Run
N0,
10
Card
No.
II
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
12
0
0
0
0
2
13
6
7
8
9
0
1
2
3
4
5
6
7
8
9
0
*4
IB
Remarks in Text
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
5*
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
E - PARTICULATE MASS TRAIN RESULTS '
Test Series
No. "
I
Sub
Series
No.
7
8
Kurt
No,
f
W
Card
No.
II
£
12
0
13
1
14
is:
Front Half
16
17
IB
•
19
20
21
22
E
23
+
24
25
Total
26
27
28
•
29
30
31
32
E
33
+
34
35
Mass Train Comments (Text)
36
37
38
39
40
41
42
43
44
45|46
1
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
F - PARTICULATE PHYSICAL PROPERTIES
Test Series
No.
1
Sub
Series
No. '
Rgn
N*,
W
Card
No.
II
F
12
0
13
1
14
1?
Density*
16
17
18
19
20
— Determination —
Resistivity*
21
22
•
23
24
25
+
26
27
T
t
28
r>
3d
Other Physical Properties in Text i
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
o
I
CO
•
t-'
I
Need not be filled if the preceding subseries contains the same data.
-------�
STATIONARY POINT SOURCE
FormS 12/76
FINE PARTICULATE EMISSIONS INFORMATION SYSTEM
DATA INiPUT FORMS
G - PARTICULATE BIOASSAY DATA
Test Series
No.
12343
Sub Sufc.
Series tto,
No.
47 a I t<>
Cord
No.1
II
G
G
G
G
G
12
0
0
0
0
0
13
»4
M
Bioassay Test Type
16
17
It 1
H - CHEMICAL COMPOSITION
Test Series
No.
Sub Sad
Series Ma,
No.
Cord
No.
II
H
12
0
13
1
Card
No.
II
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
13
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
t4
M
IS
15
(4
I*
\t 1
Analysis 1
Chemical
I.D.
16
17
18 1
9 20
» 20
.D.
1
9 20
21
22
23
24
23
24
27
— Aerodynamic/ Sto
-Caliber Calc (1 c
Upper
Boundary
Diameter
21
22
23
•
24
25
26
Mass Train
Filter or
Pooled1 Stages
21
22
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
23
24
23
26
28
29
30
31
32
33
34
33
Form Completed by
Bioassay Comments
36
37
38
39
10
41
42
43
44
45
46
47
48
4»
30
31
52
53
54
55
56
57
58
39
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
BO
;et Diameter ( 1 or 0)
>rO)
©
27
28
V>
•
30
31
32
±
27
28
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
29
30
31
32
®
33
34
33
•
36
37
38
©
±
33
34
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
*
*
•
33
36
37
38
Particle Boun
39
40
41
•
42
43
44
®
±
39
40
•
•
*
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
4)
42
43
44
lory Diameter*
®
43
46
47
«
48
49
30
Chemica
©
±
45
46
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
47
48
49
30
31
52
53
•
54
53
56
Concentration i
®
±
31
52
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
53
54
55
56
75
76
77
•
78
79
80
±
75
76
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
77
78
79
80
Need not be filled if the preceding subseries contains the same data.
O
I
a*
u>
-------�
STATIONARY POINT SOURCE
Form 6 12/76
I-
FINE PARTICIPATE EMISSIONS INFORMATION SYSTEM
DATlA INPUT FORMS
MEASUREMENT PARTICULARS
Test Serin
No.
1
Sub
Series
No.-
Run
No.
10
Cord
No.
II
1
12
0
13
1
Card
No.
II
I
12
0
13
2
Card
No.
II
I
I
I
12
0
0
0
13
3
4
5
r
14
M
1*
i
"
15
15
19
— Measurement Instrument/Method No.
Measurement Instrument/Method Name
16
17
IS
IV
20
21
22
23
24
25
**
Measurement Size Range
Lower
16
17
18
If
20
Upper
21
22
23
24
23
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
Meas.
Start Time
46
47
48
49
Sampling
Period**
SO
51
52
53
54
Aerosol
Flow Rate**
55
56
57
58
59
60
Form Completed by
Gas Conditions at
Measurement Location**
•Temp.
61
62
63
64
Press .
65
66
67
68
69
%H2O
70
71
J
72
73
74
n
Oi
Fa
76
ution
cto,**
771
78
79
,
80
Collection Surface/Substrate and its Specifications
26
27
28
29
30
31
32
33
34
39
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
63
66
67
49
69
70
71
72
73
74
75
76
77
78
79
80
Comments on the Measurement
16
17
18
19
20
21
22
23
24
23
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
J - PARTICULATE SIZE DISTRIBUTION DATA
Test Ser
No.
1
2
es
Sub :
Series
No.
Run
No.
10
Card
No.
II
J
J
J
12
0
0
0
13
1
2
3
Card,
No.
II
J
J
J
12
0
0
0
13
4
5
6
r
14
r
14
r
15
15
—Measurement Instrum
— Aerodynamic/Stoke
«
17
18
19
20
•
•
•
21
22
23
-Measurement Instrum
—Mass/No. (1 or 0)
±
!«
17
It
•
•
•
19
20
21
22
23
lent/Method No.
s Diameter (1 or 0)
M
J»
26
27
28
•
•
•
29
30
31
ml/Method No.
±
7*
m
25
26
•
•
•
27
28
29
30
31
32
33
34
35
36
•
•
•
37
38
39
±
37
33
34
•
•
•
35
36
37
38
39
Particle '
40
41
42
43
44
•
•
•
45
46
47
Mass/Nui
±
40
41
42
•
•
•
43
44
45
46
47
ize Data**
48
49
50
51
52
•
•
•
53
54
55
nber Data
±
4»
49
50
•
•
•
51
52
53
54
55
56
57
58
59
60
•
•
•
61
62
63
±
$4
57
58
•
•
•
59
60
61
62
63
M
AS:
,
66
67
68
•
•
•
69
70
71
±
M
65
66
•
•
•
67
68
69
70
71
jlib or Calc (1 or 0)-
72
n
74
75
76
•
•
•
77
78
79
±
7J
73
74
•
•
•
75
76
77
78
79
1
80
80
Need not be filled if the preceding subseries or run with this Instrument/method contains the same data.
§
-------�
UG-6.4-1
SECTION 6.4
FPEIS STANDARD REPORT OUTPUT
-------�
FINE PARMCUI ATF. EMISSIONS INFORMATION SYSTFM
FPFIS SUMMARY REPORT
TEST SFRIKS NO:
HST SKRTFS AT SI IK FW Of,/?]/73 TO 0*/?l/73 BY: JACKO.R.B. F.T AL.« PURDUE UNIVERSITY
YOST, K.J. ^T AL . . .PRO'^HE SS RFPOHT NSFIM4NN) GI-3S106
SOURCE CHARACTFRISTICS-
MF'ns sec CATKGO^Y: INDUSTRIAL PROCF.S
DERATION CLASS: PHIMAPY MFTALS
FKFD MATERIAL CLASS: ZINC SMELTING
TION MliDF CLASS: COKING
NEW JERSEY ZINC CO.
COKER NO.6
SITE NAME
SOURCE NAME
ADDRESS
PALMERTON
UTM ZONE AND X-Y COORDS: 18
PA
-0.0
-0.0
CONTROL OF.VICE(S) CH AK ACT FR 1 ST ICS
IINCONTPOLLED SOIIITE
TEST SFRIUS RfMARKS-
O
-------�
TEST SERIF.? NO:
•*.)
SU"Sf.P.TFS NO: 1
INLET
TEST DATF: 06/21/73 FROM 13:00 TO 15:00 HOUR'
TEST CHARACTERISTICS
SOI.MCE OPF..'ATIM<:, MODE: COKING SOURCE OPERATING RATE: 46«o KG/HR PCT OESIGN CAPACITY: 80.
FEFO MftTKHlAL: FEED MATERIAL COMPOSITION:
CONTROL DEVICE IMLtT SAMPLING POINT DESCRIPTION: \? DIA ONSTPEAM FLOW DISTURBANCE * ISOKINETIC: 100
PHOCFSS CON01I IONS: VOL FI.OW= .1.1 DNM.^/S VF|OCITY= fl.4 M/S T= 900 C P = 760 MMH6 WATER VAP *VOL= 11.3
GAS COMPOSITION: OPSAT- C0^= 7.30 <*, CO= 0.00 % Q?= 11.30 % N3= B1.50 «
TPACF GASSFS(PPM)-
CONTROL OtVICFISI IJHF>ATIMG PftRftMF.TFPS
PARTICULATE MASSIHAIN "hStlLTS
F^ONT HALF= ^. J30F»0(. IJG/ONM3 TOTA|. = -0. COMMENTS: tPA MF.THOO B
PARTICULATF PHYSICAL P»OPEMTIES
DFNS1TY= 1.00 liM/CC ASSUMED fvFSISTIVTTY= l.SOF»ll OHM-CM ASSI/MEO
CHEMICAI COMPOSITION DATA
PAUTTCML ATb SA'tPLFw UNCAL 1 R"'» TFI)
CHI-'MJCAI NAMh
flMM YSIS METHOD
n
311.
MAS T»'N
/POOI.D
SAMPLER STAGF CUT POINTS (UM)
23456
1S.1 10. 7. 4.6 2.4
7
1.4
8
.9
I
CHFMIC.AL CONCENTRATION IN (UM/DNM3)
STAGE STAGE STAGF STAGE STAGE STAGE STAGF STAGE
234^6789
1) CADMIUM
ATOMIC AiJSORPT ll'N
?) IF.10
ATOHIC AHSOUPTfON
3) /IMC
ATO"IC AHSOPPTION
<> ) COPPF ^
AT(J"1C AH SOUP T FI.IN
4.1'< + ? l.H4*3 1.3?»3 1.0?*3 1.63*3 6.06*3 1.45*4
0. 1.^*3 9.67*? 5.76*2 8.20*2 2.63*3 5.57*3
4.*?*3 !.?()*» 7.'-)3*3 6.11*3 4.16*3 9.13*3 3.10*4 6.5B*4
4.0M*1 0. 4.0H*1 3,?^«1 0. 0. 4.H9*1 7.69*1
O
OJ
SIIHSFPIKS Ht MARKS-
-------�
TFST SFHIF.S
43
SUBSFPIFS NO:
MUM MD:
MEASIIRFME-MT PflMT I C.UL tfcS-
MFBS. |NST/!: 1 «i>iltF"<;FM MOOFl. Til
COLLECTION SUWFCCF /SUHSTW« TF : GLASS
Ml: as. STAHI TIMM 13I I |I.IN<;: TFMP=
COMMtNTS OH THt MF/VSIJMFMFNT:
CONTKOL DEVICE INLFT
(UNCALIHHAIEfM SI7E RANGE: .900 TO 30.000 IIM
?.0 M|N SAMPLING PATE: 1H.40 LPM DILUTION FACTOR: 1.0
I>PF"SSUNE.= 7f>0 MMHG WATER VAP %VOL = 11.3
PAHT1CLF SI7F I>I STI^ I HUT I ON DATA
HNPHY
10.000
24 .200
is. i on
10.000
7.oo (i
4 .ftOO
2.400
1 .400
.100
C OlA (DM) PARTICLE DI» <()M>
MID HI HNDPY Min PT
10.000
?f>.944 24.200 Ph.Q^A
|9. 1 lh IS. 1(10 10. 1 If,
12. ?H* 10.000 12.28fl
H.J».7 7.000 M.1h7
S.h7S 4. ft 00 5 . ft 7 S
3.323 2.400 3.323
1 . H .n 1.400 ] . R 3 1
1.122 . rv(IO 1.122
OM
l i if* y i IMM 1 \
~~
3.HOOE+04
2.990F+04
3.260E+04
2.4SOE«04
2. 170E»04
3.530E»04
7..140E + 04
1 ,bHOF*05
OM/OLOAf
/ I ifi y riKIM 1 )
I U '3 / 1 1 l9?E*04
1 .7S7E+04
2.294E+04
ft.374E*04
2.403E*OS
8.445E»05
i i i-i_r ut n"^ i i
DS/DLOAE
I i |M r> / CC \
\ \jr*r f \*\* 1
9.0ft9E»04
4.582F»04
8.894E»04
1.114E»05
1 .25HF»05
2.256E»05
1.076E+06
4.401E»06
T- l.uu wn/r\,\
ON
i wn /cc \
\ 'Vl.t m r \*\* I
3.710E+00
8.17SE»00
3.355E*01
7.989E»01
2.26RE+02
1.838E+03
2.276E»04
2.134E»05
ON/OLOAE CUM M
t un /cc \ i * i
I nv • / v*v» i * v> /
3.976E»01
3.991E+01
1.875E+02
5.158E»02
1.244E+03
6.505E«03
9.723E+04
1.112E»06
TOTAL
COMC-
TOTAL SI.IKF COMC= 1.223E + 06
TOTAL NUM CONC= 2.383F+OS
s
-------�
UG-6.5-1
SECTION 6.5
FPEIS DATA BASE STRUCTURE
CONTENTS
Number Item Page
6.5.1 Introduction UG-6.5.1-1
6.5.2 SYSTEM 2000 Data Base Definition UG-6.5.2-1
-------�
UG-6.5.1-1
6.5.1 Introduction
Direct access to the FPEIS requires that the user have a working knowledge
of the SYSTEM 2000 Data Base Management System. The key to the sorting and
retrieval of data is the data base definition. This is a list of all of the
data elements which are identified by unique component numbers and which
are arranged in a hierarchical structure. Section 6.5.2, which follows,
gives the SYSTEM 2000 data base definition for the FPEIS.
-------�
UG-6.5.2-1
6.5.2 SYSTEM 2000 Data Base Structure
10* FPEIS (name X (5))
50* Category (RG)
100* Source category (name X (17) in 50)
110* Source characteristics (RG in 50)
120* Type of operation (name X (17) in 110)
130* Feed material class (name X (17) in 110)
140* Operating mode class (name X (20) in 110)
150* Source name (name X (25) in 110)
160* Site name (name X (40) in 110)
170* Zone location (number 99 in 110)
180* UTM-X (decimal number 999.9 in 110)
190* UTM-Y (decimal number 9999.9 in 110)
200* Address (nonkey name X (20) in 110)
210* City (name X (18) in 110)
220* State (name XX in 110)
230* Zip code (nonkey integer number 9(5) in 110)
300* Test series (RG in 110)
310* Test series number (integer number 9(5) in 300)
320* Test series reference (name X (60) in 300)
330* Name of testing group (name X (50) in 300)
340* Series start date (nonkey date in 300)
350* Series finish date (nonkey date in 300)
355* Date FPEIS entry (date in 300)
-------�
UG-6.5.2-2
360* Test series remark 1 (nonkey text X (65) in 300)
361* Test series remark 2 (nonkey text X (65) in 300)
362* Test series remark 3 (nonkey text X (65) in 300)
363* Test series remark 4 (nonkey text X (65) in 300)
364* Test series remark 5 (nonkey text X (65) in 300)
365* Test series remark 6 (nonkey text X (65) in 300)
366* Test series remark 7 (nonkey text X (65) in 300)
367* Test series remark 8 (nonkey text X (65) in 300)
368* Test series remark 9 (nonkey text X (65) in 300)
369* Test series remark 10 (nonkey text X (65) in 300)
400* Control devices (RG in 300)
410* Generic device type (name X (20) in 400)
420* Device class (name X (12) in 400)
430* Device category (nonkey text X (33) in 400)
440* Device commercial name (name X (30) in 400)
450* Manufacturer (name X (30) in 400)
460* Device description 1 (nonkey text X (60) in 400)
461* Device description 2 (nonkey text X (60) in 400)
500* Design specification (RG in 400)
510* Device number (integer number 9 in 500)
520* Specification number 2 (integer number 99 in 500)
530* Specification type (nonkey name X (30) in 500)
540* Specification value (nonkey name X (20) in 500)
600* Test characteristics (RG in 300)
610* Subseries number (integer number 999 in 600)
-------�
UG-6.5.2-3
620* Subseries test date (nonkey date in 600J
630* Subseries start time (nonkey integer number 9(4) in
600)
640* Subseries finish time (nonkey integer number 9(4)
in 600)
650* Sampling location (name X in 600)
660* Sampling location description (name X (40)
in 600
670* Source operating mode (nonkey text X (30) in 600)
680* Source operating rate (nonkey text X (17) in 600)
690* Percent design capacity (nonkey text X (17) in 600)
700* Source feed material (nonkey text X (30) in 600)
710* Feed material composition (nonkey text X (35) in
600)
720* Volumetric flow rate (nonkey decimal number 9(5).9
in 600)
730* Gas velocity sampling location (nonkey decimal number
999.9 in 600)
740* Gas temperature sampling location (nonkey integer number
9999 in 600)
750* Pressure sampling location (nonkey integer number
9(5) in 600)
760* Moisture content (nonkey decimal number 99.9 in 600)
770* Percent isokinetic sampling (nonkey integer number
999 in 600)
780* CO-2 (decimal number 99.99 in 600)
781* CO (decimal number 99.99 in 600)
782* 0-2 (decimal number 99.99 in 600)
783* N-2 (decimal number 99.99 in 600)
-------�
UG-6.5.2-4
790* Trace gases in PPM (nonkey text X (49) in 600)
800* Mass train - total mass concentration mantissa (nonkey
decimal number 99.999 in 600)
810* Mass train - total mass concentration exponent -•
(nonkey integer number 99 in 600)
820* Mass train - front half mass concentration mantissa
(nonkey decimal number 99.999 in 600)
830* Mass train - front half mass concentration exponent
(nonkey integer number 99 in 600)
840* Mass train comments (nonkey text X (45) in 600)
850* Density (nonkey decimal number 99.99 in 600)
860* Density determination (nonkey text X in 600)
870* Resistivity-mantissa (nonkey decimal number 9.99 in
600)
880* Resistivity-exponent (nonkey integer number 99 in 600)
890* Resistivity determination (nonkey text X in 600)
900* Physical properties comments (nonkey text X (50) in
600)
910* Subseries remark-1 (nonkey text X (65) in 600)
911* Subseries remark-2(nonkey text X (65) in 600)
912* Subseries remark-3 (nonkey text X (65) in 600)
913* Subseries remark-4 (nonkey text X (65) in 600)
914* Subseries remark-5 (nonkey text X (65) in 600)
915* Subseries remark-6 (nonkey text X (65) in 600)
916* Subseries remark-7 (nonkey text X (65) in 600)
917* Subseries remark-8 (nonkey text X (65) in 600)
918* Subseries remark-9 (nonkey text X (65) in 600)
-------�
UG-6.5.2-5
919* Subseries remark-10 (nonkey text X (65) in 600)
920* Subseries remark-11 (nonkey text X (65) in 600)
921* Subseries remark-12 (nonkey text X (65) in 600)
922* Subseries remark-13 (nonkey text X (65) in 600)
923* Subseries remark-14 (nonkey text X (65) in 600)
924* Subseries remark-15 (nonkey text X (65) in 600)
1000* Control device operating parameters (EG in 600)
1010* Control Device number (integer number 9 in 1000)
1020* Parameter number 2 (integer number 99 in 1000)
1030* Parameter type (nonkey name X (50) in 1000)
1040* Parameter value (nonkey name X (20) in 1000)
1100* Bioassay analysis (RG in 600)
1110* Bioassay test type (name X (20) in 1100)
1120* Bioassay test remarks (nonkey name X (45) in 1100)
1200* Chemical calibration/calculation (integer number
9 in 600)
1205* Diameter basis (integer number 9 in 600)
1210* Upper boundary limit (nonkey decimal number 99.999
in 600)
1220* Stage-1 limit (nonkey decimal number 99.999 in 600)
1230* Stage-2 limit (nonkey decimal number 99.999 in 600)
1240* Stage-3 limit (nonkey decimal number 99.999 in 600)
1250* Stage-4 limit (nonkey decimal number 99.999 in 600)
1260* Stage-5 limit (nonkey decimal number 99.999 in 600)
1270* Stage-6 limit (nonkey decimal number 99.999 in 600)
1280* Stage-7 limit (nonkey decimal number 99.999 in 600)
-------�
UG-6.5.2-6
1290* Stage-8 limit (nonkey decimal number 99.999 in 600)
1300* Stage-9 limit (nonkey decimal number 99.999 in 600)
1400* Chemical analysis (RG in 600)
1410* SASDAD chemical ID (integer number 9999 in 1400)
1420* Analysis method (name X in 1400)
1430* Filter/total (nonkey text X (6) in 1400)
1432* Stage-1 (nonkey text X (6) in 1400)
1434* Stage-2 (nonkey text X (6) in 1400)
1436* Stage-3 (nonkey text X (6) in 1400)
1438* Stage-4 (nonkey text X (6) in 1400)
1440* Stage-5 (nonkey text X (6) in 1400)
1442* Stage-6 (nonkey text X (6) in 1400)
1444* Stage-7 (nonkey text X (6) in 1400)
1446* Stage-8 (nonkey text X (6) in 1400)
1448* Stage-9 (nonkey text X (6) in 1400)
1500* Run group (RG in 600)
1505* Run number (integer number 99 in 1500)
1510* Measurement instrument/method number (integer number
9 in 1500)
1520* Measurement instrument/method name (name X (30) in
1500)
1530* Measurement start time (nonkey integer number 9999
in 1500)
1540* Sampling period duration (nonkey decimal number
9999.9 in 1500)
1550* Sampling flow rate (nonkey decimal number 9999.99
in 1500)
-------�
UG-6.5.2-7
1560* Sampling train temperature (nonkey integer number
9(4) in 1500)
1570* Sampling train pressure (nonkey integer number 9(5)
in 1500)
1580* Percent moisture (nonkey decimal number 99.9 in
1500)
1590* Dilution factor (nonkey decimal number 9(4).9 in
1500)
1600* Measurement size range - lower limit (decimal number
99.999 in 1500)
1610* Measurement size range - upper limit (decimal num-
ber 99.999 in 1500)
1620* Collection surface/substrate (nonkey text X (55)
in 1500)
1630* Run remark-1 (nonkey text X (65) in 1500)
1631* Run remark-2 (nonkey text X (65) in 1500)
1632* Run remark-3 (nonkey text X (65) in 1500)
1640* Particle diameter basis (integer number 9 in 1500)
1645* Concentration basis (integer number in 1500)
1650* Upper diameter boundary (nonkey decimal number
9(3).9(3) in 1500)
1700* Particle size distribution date (RG in 1500)
1710* Diameter boundary (nonkey decimal number 9(2).9(3)
in 1700)
1715* Calibration/calculation (nonkey integer number 9
in 1700)
1720* Concentration value - mantissa (nonkey decimal
number 9.999 in 1700)
1730* Concentration value - exponent (nonkey integer
number 99 in 1700)
-------�
UG-6.5.2-8
1800* SARDAD table (RG)
1810* SAROAD number (integer number 9(4) in 1800)
1820* SAROAD chemical name (name X (27) in 1800)
1900* Chemical analysis type table (RG)
1910* Chemical analysis code (name X in 1900)
1920* Chemical analysis method (name X (75) in 1700)
-------�
UG-6.6-1
SECTION 6.6
LIST OF KEY/NONKEY DATA ELEMENTS
CONTENTS
Number Item Page
6.6.1 Introduction. .......... .. UG-6.6.1-L
6.6.2 KEY Data Elements ...... UG-6.6.2-1
6.6.3 MONKEY Data Elements UG-6.6.3-1
-------�
UG-6.6.1-1
6.6.1 Introduction
Data elements in a SYSTEM 2000 data base may be either KEY or NDNKEY. This
designation determines whether a particular data element may be accessed
directly or must be qualified by including additional information. KEY
elements may be selected directly; NONKEY elements require qualification (
by a KEY element. For example, the data element GENERIC DEVICE TYPE is KEY
and may be used to directly access the data of interest, such as in the
fo1lowing:
PRINT TEST SERIES NUMBER WHERE GENERIC DEVICE TYPE EQ ESP:
If, however, the data element is NONKEY as in the case of SERIES START DATE,
then qualification will be required:
IF SERIES START DATE GT 1/1/76 THEN PRINT TEST SERIES NUMBER WHERE
NAME OF TESTING GROUP EQ XYZ LABORATORY:
In this case, the KEY element, NAME OF TESTING GROUP, is used to qualify
the request regarding a NONKEY element.
Sections 6.6.2 and 6.6.3 which follow list the KEY and NONKEY data elements,
respectively, along with their SYSTEM 2000 component numbers.
-------�
UG-6.6.2-1
6.6.2 KEY Data Elements
Component Number
100
120
130
140
150
160
170
180
190
210
220
310
320
330
355
410
420
440
450
.510
520
610
650
660
780
781
782
783
1010
1020
1110
Data Element
Source Category
Type of Operation
Feed Material Class
Operating Mode Class
Source Name
Site Name
Zone Location
UTM-X
UTM-Y
City
State
Test Series Number
Test Series Reference
Name of Testing Group
Date FPEIS Entry
Generic Device Type
Device Class
Device Commercial Name
Manufacturer
Device Number
Specification Number 2
Subseries Number
Sampling Location
Sampling Location Description
CO-2
CO
0-2
N-2
Control Device Number
Parameter Number 2
Bioassay Test Type
-------�
UG-6.6.2-2
Component Number Data Element
1200 Chemical Calibration/Calculation
1205 Diameter Basis
1410 SAROAD Chemical ID
1420 Analysis Method
1505 Run Number
1510 Measurement Instrument/Method Number
1520 Measurement Instrument/Method Name
1600 Measurement Size Range - Lower Limit
1610 Measurement Size Range - Upper Limit
1640 Particle Diameter Basis
1645 Concentration Basis
-------�
UG-6.6.3-1
6.6.3 NOMKEY Data Elements
Component Number
200
230
340
350
360-369
430
460-461
530
540
620
630
640
670
680
690
700
710
720
730
740
750
760
770
790
800
810
820
830
Data Element
Address
Zip Code
Series Start Date
Series Finish Date
Test Series Remark 1-10
Device Category
Device Description 1 and 2
Specification Type
Specification Value
Subseries Test Date
Subseries Start Time
Subseries Finish Time
Source Operating Mode
Source Operating Rate
Percent Design Capacity
Source Feed Material
Feed Material Composition
Volumetric Flow Rate
Gas Velocity Sampling Location
Gas Temperature Sampling Location
Pressure Sampling Location
Moisture Content
Percent Isokinetic Sampling
Trace Gases in PPM
Mass Train - Total Mass Concentration
Mantissa
Mass Train - Total Mass Concentration
Exponent
Mass Train - Front Half Mass Concentra-
tion Mantissa
Mass Train - Front Half Mass Concentra-
tion Exponent
-------�
UG-6.6.3-2
Component Number Data Element
840 Mass Train Comments
850 Density
860 Density Determination
870 Resistivity - Mantissa
880 Resistivity - Exponent
890 Resistivity Determination
900 Physical Properties Comments
910-924 Subseries Remark 1-15
1030 Parameter Type
1040 Parameter Value
1120 Bioassay Test Remarks
1210 Upper Boundary Limit
1220 Stage - 1 Limit
1230 Stage - 2 Limit
1240 Stage - 3 Limit
1250 Stage - 4 Limit
1260 Stage - 5 Limit
1270 Stage - 6 Limit
1280 Stage - 7 Limit
1290 Stage - 8 Limit
1300 Stage - 9 Limit
1430 Filter/Total
1432 Stage - 1
1434 Stage - 2
1436 Stage - 3
1438 Stage - 4
1440 Stage - 5
1442 Stage - 6
1444 Stage - 7
1446 Stage - 8
-------�
UG-6.6.3-3
Component Number Data Element
1448 Stage - 9
1530 Measurement Start Time
1540 Sampling Period Duration
1550 Sampling Flow Rate
1560 Sampling Train Temperature
1570 Sampling Train Pressure
1580 Percent Moisture
1620 Collection Surface/Substrate
1630-1632 Run Remark 1, 2, and 3
1650 Upper Diameter Boundary
1710 Diameter Boundary
1715 Calibration/Calculation
1720 Concentration Value - Mantissa
1730 Concentration Value - Exponent
-------�
UG-6.7-1
6.7 Test Series Numbers and Refernces in the FPEIS
This section provides a master listing of test series numbers and refer-
ences for the data in the FPEIS data base. As new testing results are added
to the FPEIS, this master listing will be updated.
-------�
Teat Scries
No.
Report's Author and Name
Testing Equipment
Control Equipment
No. of ffuna
Harris, 0. B., and D. C.
Drehmel, "Fractional Effi-
ciency of Metal Fume Con-
trol as Determined by
Brink Impactor." EPA/CSL
(1973).
Harris, D. B. , and D. C.
Drehmel, "fractional Effi-
ciency of Metal Fume Con-
trol as Determined by
Brink Inpactor," EPA/CSL
(1973).
Harris, D. B., and D. C.
Drehmel, "Fractional Effi-
ciency of Metal Fume Con-
trol as Determined by
Brink Impactor," EFA/CSL
(1973).
Harris, D. B., and D. C.
Drehmel, "Fractional Effi-
ciency of Metal Fume Con-
trol as Determined by
Brink Impactor," EFA/CSL
(1973).
Harris, D. B., and D. C.
Drehnel, "Fractional Effi-
ciency of Metal Fume Con-
trol as Determined by
Brink Impactor," EPA/CSL
(1973).
Statnlck, R. M., "Measurement
of S02, Paniculate, and
Trace Elements In a Copper
Smelter Converter and
Roaster/Reverberatory Gas
Streams," EFA/CSL
Brink Iropactor Model B, 5-stage.
Gelmnn type "A" final filter
flow rate •* 2.83 1pm
Ap " 10"Hg
Brink Impactor Model B, 5-stage,
Gelman type "A" final filter
flow rate - 2.83 Ipm
Ap - 10'llg
Brink Impactor Model B, 5-stage,
Gelman type "A" final filter
flow rate - 2.83 Ipn
Ap - 10"Hg
Brink Impactor Model B, 5-stage,
Gelman Type "A" final filter
flow rate • 2.83 Ipm
Ap - IO"Hg
Brink Impactor Model B, 5-Btage,
Gelman type "A" final filter
flow rate = 2.83 Ipm
Ap - 10"Hg
Brink Impactor (Model R) at
Inlets, Andersen Sampler
(Mark III) at outlets
Brink flow rate - 2.R3 1pm
Andersen flow rate • 23.8 1pm
Zn Roaster
Wet ESP
Cu Converter
Wet ESP
Zn Sintering
Dry F.SP
Pb Sintering
Baghouse (Orion)
Pb Blast Furnace
Baghouse (wool felt)
Cu Roaater and
Reverneratory Furnace
(ASARCO)
Dry ESP (pipe) and
parallel type ESP
rO
-------�
Test Series
Report's Author and Name
Testing _E_qulpment__
Source
Control Equipment
_Ho. of ..Run_s_
7 Statnlck, R. M., "Measurement
of SOj, Participate, and
Trace Elements In a Copper
Smelter Converter and
Roaster/Keverheratory Gas
Streams," EPA/CSL
B McCain, J. D. , and VI. B.
Smith. "Lone Star Steel
Steam-Hydro Air Cleaning
System Evaluation," EPA-
650/2-74-028 (197/*).
9 Cooper, D. W., and D. P.
Andersen, "Dynactor Scrub-
ber Evaluation," CCA Cor-
poration (1976)
10 Harris, D. B., "Tests Per-
formed at Celotex Corpora-
tion, Coldsborn, North
Carolina
11 Harris. D. R., and J. A.
Turner, "Partlculate and
SOj/SO.* Measurement; Around
an Anthracite Steam Genera-
tor Baghouse." EPA/CSL (1973)
12 McKenna, J. D., "Applying
Fabric Filtration tnCn.il-
Flred Industrial Bollers:
A Preliminary Pilot Scale
Investigation," Envi ro-
Syatems and Research, Inc.
(1974)
13 Cowherd, 0., et a I., "Hazard-
ous Emission Characterization
of Utility Boilers." F.PA-650/
2-75-066
Brink Impactor (Model B) at
inlets, Andersen Sampler
(Kirk III) at onttfits
Brink (low rate « 2.R1 1pm
Andersen fli>w r.ite c 23.8 I pin
Brink Impactor at Inlet and
Andersen Sampler at outlet.
Optical particle counter
and diffusion battery.
Method 5 technique.
Andersen (Mark III) 14 1pm
PI I at Impactor
Brink Impactor
f 1 ow rate 3 4.7 I pen
Ap - 10'llR
Anderaen Sampler
Brink Impat'tor
Cu Converter
Open Hearth Furnace
Test Aerosol from
Oust Feeder
Asphalt Roofing
Pulverized Coal-Fired
Roller (anthracite)
Pennsylvania Power
and Light Company
Con 1 -FI red Ind u s t rIa 1
Roller Korr Industries.
Concord, North Carolina
Utility Boiler
Plate type ESP
Lone Star Steel Stea
Hydro Scrubber
Uynactor Scruhber
Afterburner
Baghouse
bulked weave, glass
fiber bags with a
Teflon finish
Notncx
Baghnuse
38
50
Cyclone
-------�
Test Series
No.
Report's Author and Name
TestinR Equipment
Source
Control Equipment
Bo. of Runs
15
16
17
18
19
Stntnlck, R. M. . and D. C.
Drehmel, "Fine Partlculate
Control Using SO Scrubber*,"
EPA (1974).
Statnlck, R. H. , and D. C.
Drehmel, "Fine Participate
Control Using SO, Scrubbers,"
EPA (1974).
Statnlck, R. M. , and D. C.
Drehmel, "Fine Partlculate
Control Using S02 Scrubbers,"
EPA (1974).
Riggenbach, J. D. , E. D.
Johnson and H. K. Ramlln,
"Measurement of Partlculate
Grain Loadings, Particle Sice
Distribution, and Sulfur Gas
Concentrations at Hoerner
Waldorf's Pulp and Papermlll
No. 3 Recovery System, Vols.
I, II, and III, Environmental
Science and Engineering, Inc.
Shannon, L- J., et al.,
"St. Loula/Unlon Electric
Refuse Firing Demonstration
Air Pollution Test Report."
Brink Impactor and Andersen
Sampler. Total Partlculates
using EPA Method S.
Brink Impactor and Andersen
Sampler. Total Partlculates
using EPA Method 5.
Brink Impactor and Andersen
Sampler. Total Partlculates
using EPA Method 5.
Brink Impactor
Total Mass by EPA Method 5
Brink Impactor and Andersen
Sampler
Coal-Fired Power Boiler
(TVA, Shawnee)
Coal-Fired Power Boiler
(TVA, Shawnee)
No. 6 Fuel Oil Flrod
Power Boiler (Mystic)
Pulp and Papermill Re-
covery Bller
TCA Scrubber
Venturi Scrubber
Venturl HgO Scrubber
F.SP
38
Coal-Fired Utility
Boiler Refuse Firing
Demonntration,
St. Louis/Union Electric
ESP
2«
20 McCain, J. D. , "Evaluation of
Aronetlcs Two-Phase Jet
Scrubber," EPA-650/2-74-129
Brink Impactor, Andersen
Sampler Method 5, Optical
Particle Counter, Diffu-
sion Battery + CNC
Ferro-Alloy Electric Arc
Furnace
Aronetlcs Two-Phase
Jet Scrubber
41
21
Bosch, J. C., M. J. Ftlat,
and B. F. Hrutflord, "Site
Distribution of Aerosols
From a Kraft Mill Recovery
Furnace," Tappl S4(ll):1871
(1971).
Pllat Impactor
Kraft Mill Recovery
Furnace
ESP
o
Test Series Nos. 14 and 47 has missing or invalid data and will be coded when test data are available,
-------�
Test Series
No.
Report's Author and Name
Testing Equipment
Control Equipment
No. of Runs
22 McGarry, F. J., and C. J.
Gregory, "A Comparison of
the Site Distribution of
Partlculates Emitted From
Air, Mechanical, and Steam
Atomized Oil-Fired Burners,"
JAPCA. 22(8):636 (1972).
Andersen Sampler
Air Atomized Oil-Fired
Boiler
ESP
23 McCarry. F. J., and C. J.
Gregory, "A Comparison of
the Size Distribution of
Partlculates Emitted From
Air, Mechanical, and Steam
Atomized Oll-Flred Burners,
JAPCA, 22(8):636 (1972).
Andersen Sampler
Mechanical Atomized Oll-
Flred Boiler
Andersen Sampler
24 McGarry, F. J., and C. J.
Gregory, "A Comparison of
the Size Distribution of
Partlculales Emitted From
Air, Mechanical, and Steam
Atomized Oll-Flred Burners,"
JAPCA. 22(8):636 (1972).
25 Lee, R. E. . Jr., H. L. Crist, IW MarV lit Sampler
A. E. Rlley, and K. E. M.icLeod,
"Concentration and Size of
Trace Metal Emissions From a
Power Plant, a Steel Plant,
and a Cotton Gin," Env. Set.
and Tech.. 9(7):643 (1975).
26 Lee, R. E. , Jr., II. L. Crist, UW Mark III Sampler
A. E. Rlley, and K. E. M.icLeod,
"Concentration and Size of
Trace Metal Emissions From a
Power Plant, a Steel Plant,
and a Cotton Gin," Env. Scl.
and Tech., 9(7):643 (1975).
Steam Atomized Oll-Flred
Boiler
ESP
Emissions from a Power
Plant
Emissions from a Steel
Plant
Raghouse
o
I
Ul
-------�
Test Series
No.
27
28
29
30
31
32
33
Testing Equipment
IV Mark III Sampler
Report's Author and Name
Let, R. E., Jr., 11. L. Crist,
A. F.. Rtley, and K. E.
MacLeod, "Concentration and
Size of Trace Metal Emissions
from a Power Plant, a Steel
Plant, and a Cotton Cln," Env.
Scl. and Tech.. 9(7)643 (1975).
"St. Louis-Union Electric Refuse Brink and Andersen Impactors
Fuel Project," MRI Project
No. 3821-C(4), January 1975
"St. Louis-Union Electric Refuse Brink and Andersen Impactors
Fuel Project," HR1 Project
No. 4033-C, Monthly Report
No. 1
"Test and Evaluation Program
for St. Louis-Union Electric
Refuse Fuel Project," MRI
Project No. 4033-C, Monthly
Report No. 4
"Test and Evaluation Program
for St. Louis-Union Electric
Refuse Fuel Project." MRI
Project No. 4033-C, Monthly
Report No. 11
Toca, F. M., "Lead and Cadmium
Distribution In the Partlcu-
late Effluent from a Coal-
Flred Boiler," Ph.D. Thesis,
University of lova, Ames,
Iova, July 1972
Baladl, E., "Particle Sice Dis-
tribution Tests for Beker
Industries Corporation," MRI
Project No. 5-1379-C
Brink and Andersen Impactors
Brink and Andersen Impactors
Andersen Ambient Sampler
Brinks Impactor
Source
Emissions from a Cotton
Gin
Control Equipment
Ho. of Runs
Coal-Fired Utility Boiler
Refuse Firing Demonstra-
tion
Coal-Fired Utility Boiler
Refuse Firing Demonstra-
tion
Coal-Fired Utility Boiler
Refuse Firing Demonstra-
tion
Coal-Fired Boiler
Phosphate Rock Calclner
Wet Scnihber
ESP
ESP
Coal-Fired Utility Boiler ESP
Refuse Firing Demonstra-
tion
ESP
ESP
67
12
19
Venturl Scrubber
-------�
Test Series
Ho, Report's Auilior ami Name Testing Equipment Sotirce Control Equipment Ho. of Runs
34 Roocll, J. P.. ami J. D. McCain, Brink Andersen Samplers Optical Aluralnirm Reduction Colls ESP Preceded by Spray 17
"Partlculate Collection Ef- Particle Counter, Diffusion Towers
ffclency Mcatuiremonta on a Battery anil CN Counter
Wet Electrontatlc preclpl-
tator." EPA-650/2-75-OJ3
35 Bradway, K. H. , and R. U. Andnrnen Impactor Coal-Fired Boiler Bugbouae 86
Caso, "Fractional Efficiency
of a Utility Duller Bag-
liouse," EPA-600/2-75-OI3-a
36 HcKcnna, J. D., .). C. Hylock, Amletacn Impactor Conl-Flreil Boiler Nimpx Bagliouae 28
and U. O. I.I pftcomli, "Apply-
ing Fabric Filtration to
Coal-Fired I mliial r In I Boll-
era," KPA-650/2-74-05B-a
37 McKcimn, J. D., J. C. Hylock, Andersen Imp.ictnr Coal-Fired llollor Teflon Felt (Style 1) 7
and W. O. Mpacomh, "Apply- Baghouae
Ing Fabric Fl I tr.it Inn to
Coal-Ftred Industrial Dot I-
era," EPA-6'.0/2-7'i-OS8-a
38 McKenna, J. D., J. C. My lock, Andersen Impactor Coal-Fired Boiler Teflon Frit (Style 2) 5
and W. O. Llpscomb. "Apply- IL.gl.ouso
Ing Fabric Filtration to
Coal-Fired Industrial Boil-
ers," EPA-650/2-74-058-a
39 McKenna, J. I)., .1. C. Mylock, Andnrnen Impnctor Coal-Fired Holler Core-Tex/Ntmcx Bagliuune II
and U. O. Llpacnnib, "Apply-
ing Fabric Filtration to
Coal-Fired Industrial Boil-
ers," KPA-650/2-7/,-058-a
/,0 McKenna. J. D. , J. C. Hylock, Andernen Impactor Coal-Fired Boiler Dralon Raghousc 7
and W. O. l.lpscomh, "Apply-
ing Fabric Flltr.illon to
Coal-Fired Industrial Boil-
ers," EPA-650/2-74-058-a
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Teat Series
Mo. Report's Author and Name Testing Equipment Source Control Equipment Mo. of Runs
41 McCain, j. D., "Evaluation of Brinks Andersen Tmpactort Dlf- Asphalt Dryer Burning I. Coarse Cyclone 31
Centrifieli] Scrubber," EPA- fusional. Optical and Klectrl- No. 2 Fuel Oil 2. Secondary Collector
650/2-74-129-a cal Methods 3. Scrubber
42 Cooper, D. W., "Pentapure In- Andersen In-Stack Impactor Gray Iron Foundry Pentapure Implnger 12
pinger Evaluation," EPA-
650/2-75-024-a
43 Yost, K. J. et al., **The En- Andersen Impactor Zinc Coker Plant - 1
vironmental Flow of Cadmium
and Other Trace Metals,"
Progress Report NSF (RANN)
Grant GI-35106, Purdue Uni-
versity, West Lafayette,
Indiana
44 Yost, K. J. et al., "The En- Andersen Impactor Zinc Vertical Retort Baghouse 3
vironmental Flow of Cadmium
and Other Trace Metals,"
Progress Report NSF (RANN)
Grant GI-35106, Purdue Unl-
veralty, West Lafayette,
Indiana
45 Yost, K. J. et al., "The En- Andersen Impactor Steel Mill Open Hearth ESP 6
vironmental Flow of Cadmium Furnace
and Other Trace Metals,"
Progress Report NSF (RANN)
Grant GI-35106, Purdue Uni-
versity, West Lafayette,
Indiana
46 Yost, K. J. et al., "The En- Andersen Impactor Municipal Incinerator Scrubber 1
vlrontnental Flow of Cadmium
and Other Trace Metals,"
Progress Report NSF (RANN)
Grant GI-35106, Purdue Uni-
versity, West Lafayette,
I nd la na
48 Calvert, S., N. J. Jhaveri, IW Mark II and Andersen Urea Prilling Tower Valve Tray 12
and S. YunR, "Fine Particle Impactors
Scrubber Performance Tests," 5
EPA-650/2-74-093 I
CT>
•
I
CO
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Test Series
No.
Report's Author and Name
Testing Equipment
Source
Control Equipment
No. of Runs
49 Culvert, S., M. J. Jhaverl,
and S. Yung, "Fine Parti-
cle Scrubber Performance
Tests," EPA-650/2-74-093
UU Mark III and Andersen
Impactors
Potash Dryer
Scrubber
17
SO Calvert. S., N. J. Jhaverl,
and S, Yung, "Fine Parti-
cle Scrubber Performance
Tests." EPA-650/2-74-093
UU Hark III and Andersen
Irapactors
Coal-Fired Boiler
TCA Scrubber
51 Calvert, S., N. J. Jhaverl,
and S. Yung, "Fine Parti-
cle Scrubber Performance
Tests," EPA-650/2-74-093
IIW Hark III and Andersen
Impactors
Coal-Fired Boiler
Venturl Scrubber
52 Calvert, S. , N. J. Jhaverl,
and S. Yung, "Fine Parti-
cle Scrubber Performance
Tests," EPA-650/2-74-093
UW Mark III and Anderacn
Impactors
Salt Dryer
Wetted Fiber Scrubber
16
53 Calvert, S., N. J. Jhaverl,
and S. Yung, "Fine Parti-
cle Scrubber Performance
Tests," EPA-650/2-74-093
UU Hark III and Andersen
Impactors
Salt Dryer
Impingment Plate
Scrubber
12
54
Calvert, S., N. J. Jhaverl,
and S. Yung, "Fine Parti-
cle Scrubber Performance
Tests," EPA-650/2-74-093
UU Hark III and Andersen
Impactors
Iron Wetting Cupola
Venturl Rod Scrubber
IB
S
I
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TECHNICAL REPORT DATA
(Please read Instructions on the reverse before completing)
1. REPORT NO.
EPA-600/2-76-172
3. RECIPIENT'S ACCESSION NO.
4. TITLE AND SUBTITLE
Fine Particle Emissions Information System
User Guide
5. REPORT DATE
June 1976
6. PERFORMING ORGANIZATION CODE
7. AUTHOR(S)
8. PERFORMING ORGANIZATION REPORT NO.
M. P.Schrag, A.K.Rao, G. S.McMahon, and
G L. Johnson
9. PERFORMING ORGANIZATION NAME AND ADDRESS
Midwest Research Institute
425 Volker Boulevard
Kansas City, Missouri 64110
10. PROGRAM ELEMENT NO.
1AB012; ROAP 21BJV-023
11. CONTRACT/GRANT NO.
68-02-1324, Task 47
12. SPONSORING AGENCY NAME AND ADDRESS
EPA, Office of Research and Development
Industrial Environmental Research Laboratory
Research Triangle Park, NC 27711
13. TYPE OF REPORT AND PERIOD COVERED
Guide: 3-5/76
14. SPONSORING AGENCY CODE
EPA-ORD
15. SUPPLEMENTARY NOTES
919/549-8411, ext 2815.
for this report is G.L.Johnson, Mail Drop 63,
16. ABSTRACT
The report is an extensive user guide to the Fine Particle Emissions Infor-
mation System (FPEIS), a computerized database on primary fine particle emissions
to the atmosphere from stationary sources, designed to assist engineers and scien-
tists engaged in fine particle control technology development. The FPEIS will contain
source test data including particle size distributions; chemical, physical, and bio.-
assay testing results performed on particulate samples; design and typical operating
data on particle control systems applied; process descriptions of the sources; and
descriptions of the sampling equipment and techniques employed. The FPEIS, a
successor to the MRI Fine Particle Inventory developed in 1971, gives detailed instru-
ctions for encoding FPEIS datasets, along with a copy of the FPEIS data input form.
It discusses procedures which will provide users with access to the FPEIS either by
direct computer request for authorized National Computer Center (NCC) accounts or
by written request to the EPA project officer. It gives a list of standard data inquiry
and retrieval requests, with instructions for their use. The appendix describes
EPA's NCC and the generalized database management system used to implement the
FPEIS.
17.
KEY WORDS AND DOCUMENT ANALYSIS
DESCRIPTORS
b.lDENTIFIERS/OPEN ENDED TERMS
c. COSATl Field/Croup
Air Pollution
Instructions
Dust
Data Storage
Sampling
Size Determination
Environmental
Biology
Air Pollution Control
Stationary Sources
User Guide
Fine Particle Emissions
Information System
FPEB
Fine Particulate
13B
11G
09B,05B
14B
06F
18. DISTRIBUTION STATEMENT
Unlimited
19. SECURITY CLASS (This Report)
Unclassified
21. NO. OF PAGES
232
20. SECURITY CLASS (Thispage)
Unclassified
22. PRICE
6PA Form 2220-1 (9-73)
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