CD A '-' ^- Environmental Protection Agency Industrial Environmental Research
II f^ Office of Research and Dt'vซlonment lahoratnrv
Research Triangle Park, North Carolina 27711
EPA-600/7-77-001
January 1977
PROCEEDINGS: Fine
Particle Emissions
Information System
User Workshop
Interagency
Energy-Environment
Research and Development
Program Report
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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 seven series.
These seven 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 seven series
are:
1. Environmental Health Effects Research
2. Environmental Protection Technology
3. Ecological Research
4. Environmental Monitoring
5. Socioeconomic Environmental Studies
6. Scientific and Technical Assessment Reports (STAR)
7. Interagency Energy-Environment Research and Development
This report has been assigned to the INTERAGENCY ENERGY-ENVIRONMENT
RESEARCH AND DEVELOPMENT series. Reports in this series result from
the effort funded under the 17-agehcy Federal Energy/Environment
Research and Development Program. These studies relate to EPA's
mission to protect the public health and welfare from adverse effects
of pollutants associated with energy systems. The goal of the Program
is to assure the rapid development of domestic energy supplies in an
environmentallycompatible manner by providing the necessary
environmental data and control technology. Investigations include
analyses of the transport of energy-related pollutants and their health
and ecological effects; assessments of, and development of, control
technologies for energy systems; and integrated assessments of a wide
range of energy-related environmental issues.
REVIEW NOTICE
This report has been reviewed by the participating Federal
Agencies, and approved for publication. Approval does not
signify that the contents necessarily reflect the views and
policies of the Government, nor does mention of trade names
or commercial products constitute endorsement or recommen-
dation for use.
This document is available to the public through the National Technical
Information Service, Springfield, Virginia 22161.
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EPA-600/7-77-001
January 1977
PROCEEDINGS:
FINE PARTICLE EMISSIONS
INFORMATION SYSTEM
USER WORKSHOP
M. P. Schrag (Editor)
Midwest Research Institute
425 Volker Boulevard
Kansas City, Missouri 64110
Contract No. 68-02-1324, Task 46
Program Element No. EHE623
EPA Task Officer: Gary L. Johnson
Industrial Environmental Research Laboratory
Office o? 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 report was prepared for EPA/IERL-RTP under Contract No. 68-02-
1324, Task 46. The work was performed in the Environmental and Materials
Sciences Division of Midwest Research Institute. Dr. L. J. Shannon served
as project manager and Mr. M. P. Schrag, Head, Environmental Systems Sec-
tion, was the project leader.
Approved for:
MIDWEST RESEARCH INSTITUTE
a. XVo^-^^-
L. J. Shannon, Director
Environmental and Materials
Sciences Division
January 26, 1977
iii
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FOREWORD
The U.S. Environmental Protection Agency, through the Industrial
Environmental Research Laboratory-RTF, sponsored a User Workshop for the
Fine Particle Emissions Information System. The workshop was held at the
National Environmental Research Center, Research Triangle Park, North
Carolina, on June 15, 1976.
The purpose of the workshop was to introduce the user community to
the Fine Particle Emissions Information System (FPEIS). The FPEIS is a
computerized information system on fine particle emissions from station-
ary sources and may contain source test data including particle size dis-
tribution; chemical, physical and bioassay testing results; design and
performance data on particle control systems; process descriptions; and
descriptions of the sampling equipment and techniques employed.
The workshop opened on Tuesday morning, June 15, 1976, with an offi-
cial welcome by Dr. John 0. Smith, Director of the Office of Program Op-
erations, IERL-RTP after opening remarks by Gary L. Johnson, EPA Project
Officer for the FPEIS.
Following the welcome, Mr. Johnson presented the background and pur-
pose of the FPEIS. M. P. Schrag of Midwest Research Institute concluded
the morning session with a description of the FPEIS data base.
The afternoon session began with a discussion of the FPEIS data input
forms and content by Dr. A. K. Rao of Midwest Research Institute. Mr. G. S.
McMahon of MR! Systems, Inc., and Dr. Rao discussed the data output, includ-
ing both the standard output and several options available to the user. The
workshop was summarized with closing remarks by Mr. Johnson.
This document is, in essence, minutes of the workshop. Although speakers
supplied copies of their remarks, they were not formal papers and should be
used only as minutes of a working seminar. A discussion period followed each
presentation and a summary of each is also given.
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CONTENTS
Page
Summary of Introductory and Welcoming Remarks - Gary L. Johnson,
Project Officer, Special Studies Staff, IERL-RTP; John 0. Smith,
Director, Office of Program Operations, IERL-RTP .... 1
Background and Purpose of the Fine Particle Emissions Information
System - Gary L. Johnson, Project Officer, Special Studies Staff,
IERL-RTP 3
Description of the FPEIS Data Base - M. P. Schrag, Midwest Research
Institute 9
Input, Processing, and Output of FPEIS - A. K. Rao, Midwest Research
Institute. . ซ 23
Data Output - Standard Format and Options - A. K. Rao, Midwest
Research Institute; G. S. McMahon, MRI Systems, Inc 43
Closing Comments to the FPEIS User's Workshop - Gary L. Johnson,
Project Officer, Special Studies Staff, IERL-RTP 67
Workshop Attendees 69
Appendix A - FPEIS Data Element Definitions 71
Appendix B - Source Classification Codes 95
Appendix C - SAROAD Pollutant Codes 113
Appendix D - Sample Completed Data Input Sheets 133
vii
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SUMMARY OF INTRODUCTORY AND WELCOMING REMARKS
Gary L. Johnson
Project Officer
Special Studies Staff
IERL-RTP
John 0. Smith
Director
Office of Program Operations
IERL-RTP
INTRODUCTORY REMARKS
The attendees to the first Fine Particle Emissions Information System
(FPEIS) User's Workshop were greeted by Gary L. Johnson, EPA Project Offi-
cer for the FPEIS. Johnson briefly outlined the agenda for the workshop,
noting in particular that the sessions were to be very informal and that
comments and/or questions from the attendees were welcome during any part
of the program.
WELCOME
The welcoming remarks were made by Dr. John 0. Smith, Director of the
Office of Program Operations at IERL-RTP. Dr. Smith briefly described the
mission of the Industrial Environmental Research Laboratory at RTF and out-
lined lERL's role within EPA1s Office of Research and Development. lERL's
mission is to "develop and demonstrate cost effective technologies to pre-
vent, control, or abate pollution from operations with multimedia environ-
mental impacts associated with the extraction, processing, conversion, and
utilization of energy and mineral resources, as well as with industrial
processing and manufacturing.1' Smith noted that IERL-RTP and its sister
IERL in Cincinnati, Ohio, comprise EPA's Office of Energy, Minerals, and
Industry (OEM!) under the direction of Deputy Assistant Administrator
Stephen Gage.
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The Fine Particle Emissions Information System (FPEIS) represents the
first technical computer data base developed by IERL-RTP. The FPEIS will
be a model for possible future data bases which would store environmental
assessment and other emissions data. It is currently recognized that the
centralized storage of test data will significantly enhance its usability
and lead to a faster solution of today's environmental problems.
In order to disseminate information on the FPEIS to the user community
and to solicit their comments and criticisms, the forum of a User's Workshop
was selected. This is the first FPEIS User's Workshop.
REFERENCES
1. Industrial Environmental Research Laboratory, Annual Report 1975.
Research Triangle Park, North Carolina (January 1976).
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BACKGROUND AND PURPOSE
OF THE
FINE PARTICLE EMISSIONS INFORMATION SYSTEM
Gary L. Johnson
Project Officer
Special Studies Staff
IERL-RTP
INTRODUCTION
The Industrial Environmental Research Laboratory (RTF) has developed
a computerized information system on primary fine particle emissions to
the atmosphere from stationary sources to assist engineers and scientists
engaged in fine particle control technology development.
The Fine Particle Emissions Information System (FPEIS) will contain
source test data including particle size distributions; chemical, physical,
and bioassay testing results performed on particulate samples; design and
performance data on particle control systems applied; process descriptions
of the sources; and descriptions of the sampling equipment and techniques
employed.
The User's Workshop is intended to provide a description of what the
FPEIS is, what data can be stored, what it can do, how it came to be, and
how it may be used.
FPEIS OVERVIEW
The FPEIS is a computerized follow-on of the Fine Particle Emissions
Inventory developed by Midwest Research Institute (MRl) in 1971..I' A plan
to update the 1971 inventory was initiated in July 1974, by the Industrial
Environmental Research Laboratory (IERL) at Research Triangle Park, North
Carolina. By early 1975, the planned update of the Fine Particle Emissions
Inventory was supplanted by the concept of a computerized information sys-
tem on fine particle emissions from stationary sources.
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The MRI Fine Particle Emissions Inventory has become one of the most
widely-quoted reference documents in use by engineers and scientists today
who are engaged in studies of fine particles. Since 1971, several questions
regarding the validity of some of the fine particle data in the inventory
have been raised. Furthermore, advances of fine particle measurement tech-
nology and increased fine particle sampling with determination of the size
distribution1of the particles have led to the formulation of a more relia-
ble set of fine particle emissions data. For these reasons, IERL requested
MRI to undertake a comprehensive revision of the 1971 inventory. Shortly
after the project to update the inventory was initiated, the full magnitude
of the scope of the project became known. Since the number of fine particle
source tests was expected to increase in the years to follow, it became ap-
parent that an automated data system would be needed if the inventory of
fine particle emissions was to be kept current.
The FPEIS was initiated in early 1975 to provide a current, flexible
data base of fine particle emissions data. In addition to containing source
process information and particle size distribution data, the FPEIS scope
was expanded to include design and operating data on applied particulate
control technology, description of the sampling equipment and method used,
and the results of physical, chemical, and biological analysis of the col-
lected samples. To ensure compatability with other EPA data bases, FPEIS
uses the same classification system for sources as NEDS (i.e., the Source
Classification Codes) and uses the SAROAD/SOTDAT chemical ID scheme for the
chemical analysis data. In order to permit effective use of FPEIS by engi-
neers, scientists, and technicians engaged in fine particle control R&D,
a standard protocol for units and terminology has been developed for FPEIS.
This allows data from one source test to be compared with data from other
tests without extensive modifications.
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 being used extensively by EPA
and other government agencies. SYSTEM 2000, which is developed by MRI Sys-
tems, Inc., of Austin, Texas (no relation to Midwest Research Institute),
provides FPEIS users with improved capabilities for data analysis. By uti-
lizing SYSTEM 2000 features, users will be able to sort, compare, and re-
trieve information from FPEIS in any arrangement or manner that they choose.
At present, FPEIS has been implemented on the NCC computer at RTF and
the initial loading of source test data has been completed. To date, MRI
has accumulated source test data from more than 30 source and control de-
vice combinations representing a total of over 700 test runs. FPEIS is now
operational and undergoing testing. User availability is anticipated for
December 1, 1976. Four reports on the FPEIS will be published by IERL.
These include the FPEIS Summary Report, the FPEIS Reference Manual, the
FPEIS User Guide, and the proceedings of this workshop. The FPEIS Summary
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Report will discuss the present loading of data in the data basee It will
contain an analysis and critique of the data, and it will identify any known
shortcomings in the data. The Reference Manual will present a detailed de-
scription of the data base and the various features offered, including the
theory of any calculations performed, definition of data elements, data pro-
tocol, etc. The User Guide will provide detailed instructions to users for
submitting or retrieving data. A catalog of routine sorting and retrieval
commands has been provided for the FPEIS. While it is somewhat limited at
present, this catalog will be expanded to reflect the needs of the user
community.
Following the publication of these reports, it is expected that many
users will have specific requests for data sorting and reporting which will
differ from that provided by the request catalog. Periodic updating of the
User Guide and the Reference Manual will provide users with new techniques
for utilizing the data in the system on a continuing basis. In addition,
the FPEIS data base will be updated with new testing data on a periodic
basis to ensure that the data base is kept current. Summary reports will
be compiled and published for each update. Initially, such updates are ex-
pected on a semi-annual basis.
During the first several years of operation, the FPEIS data base will
undergo several modifications and enhancements. The volume of data entering
the system is expected to increase dramatically during this period, and,
as just mentioned, user needs are also expected to change. The FPEIS has
been developed for the user. Satisfaction of his needs and interests is the
principal objective of this project. IERL is committed to support the evo-
lution of the FPEIS to provide researchers in fine particle measurement and
control technology with a current, accessible compilation of fine particle
emissions data.
This, then, is an overview of the FPEIS. Before proceeding to discuss
the specific features of the FPEIS data base, it is instructive to examine
the background of the project in more detail.
ORIGIN OF THE PROJECT
A national fine particle emissions inventory was published in 1971 by
MRI based upon 1969 to 1970 data then available. In preparing this inven-
tory, MRI acquired and analyzed available data on particle size distribu-
tions from both controlled and uncontrolled sources, typical fractional
efficiency curves for specific control devices, the degree of application
of control equipment to specific sources, and mass emission factors. The
accuracy and precision of the inventory was restricted, however, by the
lack of a generally reliable data base. Extrapolations from larger parti-
cle sizes and use of typical fractional efficiency curves were necessary
since the available data were based upon measurement techniques incapabble
of quantifying particles in the size range below 0.5 M/m. Data collected
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since. 1970 indicate that such extrapolations may have introduced large er-
rors in the data base. Since data from direct measurement of many sources
and collectors by use of recently developed fine particle sizing methods
are now available, it is now possible to develop a more accurate summary :
of fine particle emissions data.
In July 1974, IERL directed MRI to update the 1971 inventory. This re-
quest followed an update sponsored earlier by EPA's Office of, Mr Quality
Planning and Standards. The principal specifications of the task were to
revise and update the existing fine particle emission inventory and to de-
velop program elements for IERL by which the fine particulate data base
would be updated. Several meetings were held with MRI during October,
November,., and December 1974, to review the scope of the project work.
In recognition of the quantity of data involved, development of stan-
dardized data input and output forms was begun and identification of. data
types to be contained in the data base was made on the assumption that; the
earlier scope of work would be modified extensively and that computerization
of the inventory would be an integral part of the revised scope of work. .
Subsequent discussions with MRI resulted in a total redefinition of
the concept of a "fine particle emissions inventory." The plan to revise
the 1971 inventory was replaced by the concept of a computerized Fine Par-
ticle Emissions Information System capable of providing current information
and enabling the continuous updating of the system with new information.
WHY COMPUTERIZATION OF THE DATA?
A computerized information system on fine particle emissions would en-
able persons to access a current source of data. A computerized data base
could process special requests for sorting or editing of data. For example,
it would be a simple task for the computer to print a list .of all sources
in the data base which are controlled by baghouses. To compile such a list
by hand would require hours. A computerized system would also allow for the
almost-continuous updating of new information. EPA test results could be
entered into the system as the testing programs were completed. Then, peri-
odically, a detailed addendum report analyzing the present state of the data
base could be issued. Such a report would contain source prioritizatibns,
evaluations of control technology, identification of data deficiencies,
etc., and could be. used to direct planning efforts for future test programs.
Upon assessing both the magnitude of the quantity of information to
be accumulated and the potential for its use if presented in a convenient
form, the advantages for computerization of the.information far outweighed
the disadvantages. Clearly, there were certain disadvantages: the loss
of previous effort by MRI, the additional effort required for computer data
base development, the need for on-going support, etc. The MRI Fine Particle
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Inventory has in the past been one of the most often referenced documents
in particulate control technology literature. Its role, therefore, in the
development of particulate standards and control technology has been a ma-
jor one. The need to have a current and, more importantly, accurate emis-
sions inventory is obvious. Consequently, the original scope of the project
was changed significantly and an approach has been developed which has re-
sulted in the creation of a useful and usable information system on fine
particle emissions.
REFERENCES
1. Shannon, L. J., P. J. Gorman, and M. Reichel, "Particulate Pollutants
System Study, Volume II: Fine Particle Emissions," Midwest Research
Institute, EPA No. APTD-0744, NTIS No. PB 203-521 (August 1971).
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DESCRIPTION OF THE FPEIS DATA BASE
by
M. P. Schrag
Midwest Research Institute
INTRODUCTION
The Fine Particle Emissions Information System (FPEIS) has been devel-
oped to provide a current, flexible data base containing test data for sta-
tionary source generated fine particle emissions. The scope of informational
and data elements allowed in the data base includes source process informa-
tion, design and operating data on applied particulate control technology,
descriptions of sampling equipment and methods used, results of physical,
chemical and'biological analyses of collected samples and, finally, parti-
cle size distribution data available as mass, number or surface distributions.
A data element is defined as a computer variable corresponding to a
particular source test data item. The data elements of the types just men-
tioned, e..g., process information, etc., are arranged on a test run specific
basis sufficient to provide complete information and data regarding the
source test measurement. The completeness of the information for any given
source test is limited only by the availability of such information as con-
tained in !the test report or original reference from which the FPEIS input
is derived.
To ensure compatibility with other EPA data bases, the FPEIS uses
identical classifications for certain components. The NEDS "Source Classi-
fication Codes" are used for source categorization. Chemical identification
and analysis methods are used as developed for the SAROAD/SOTDAT systems.
A standard; protocol for units (all metric) and terminology has been devel-
oped for the FPEIS.
WLth this brief discussion providing an introduction to the FPEIS, let
us proceed to an in-depth discussion of the structure, organization, content
and current status of the data base system.
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FPfilS STRUCTURE
The fundamental element of the data base system is the test-run, see
Figure 1. A test run is defined as "any test measurement of a 'specific
source for a specified length of time, in a specified location with speci-
fic particle size measuring equipment." The test run is the point on which
the remainder of the matrix is balanced. Associated with this test run data
are the relevant data for source operating characteristics, control device
parameters,test characteristics, sampling conditions and any other perti-
nent information and data which describe the test operation during the per-
iod ofL the feest run. There are provisions for including supplemental infor-
mation such as subsequent chemical analysis or biological testing results
obtained from the collected sample. Assignment of a test run number to a
data set will be on a sequential basis by the encoder when the data are
compiled for entry into the system.
Groups of test runs, that is, repeated measurements for the same; source/
collector combination with the same or common source operating conditions
at the same location, are clustered into a test subseriea. As can be seen
in later discussions, this arrangement allows grouping of simultaneous test
runs such as inlet/outlet pairs or multiple measurement equipment methods,
i.e.,, impactors, diffusion batteries, etc., into a common, coherent time
set. This grouping minimizes repeating of relatively constant data elements
recorded during the subseries such as source operating mode, rate, feed ma-
terial, volumetric flow rate and stack gas velocity. Data which can be con-
sidered or was obtained over the same time period as that for the test sub-
series such as mass train results, Orsat analysis, etc., are also clustered
within the subseries framework. Significant changes in source or collector
operation as part of the testing protocol such as change in source feed ma-
terial, combination of fuels, change in the L/G ratio for scrubbers, change
in air-to-cloth ratio for fabric collectors, etc., define a new subseries.
Test subseries numbers are assigned on an arbitrary basis at the time of
encoding and entry into the system by the encoder.
The uppermost level in the structure is the test series. A test series
is composed of groups of subseries and will usually consist of the informa-
tion contained in a test report, technical journal article, etc., and is
specific to a given source/collector combination. Test programs or reports
which include more than one source/collector combination will, of course,
be separated into different test series. Different test series, in any case,
will be distinguished by assignment of test series numbers from a master
file listing. Test series numbers for the initial data base loading have
been assigned on an arbitrary basis and future additions will be given mas-
ter file numbers as received by the FPEIS administrator.
10
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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
Figure 1 - FPEIS Structure
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Data elements included at the test series level are items such as ref-
erence (report number, etc.) and control device designation, description,
design parameters, typical operating parameters, etc. In summary, those
factors which are common to the lower level subseries and included test
runs are grouped at the series level.
The primary purpose of the stratification into test series, subseries
and run levels is for record-keeping purposes within SYSTEM 2000. Structur-
ing of data elements in this manner ensures that data and information per-
tinent to the associated level can be stored and retrieved as a coherent
unit.
FPEIS ORGANIZATION
FPEIS data are grouped into five general categories of information.
These groupings are discussed in general terms in the following paragraphs.
A tabulation of the FPEIS data elements and their definitions is given in
Appendix A. Specific encoding instruction will be discussed in a later pre-
sentation.
The following tables are an illustration of these five categories:
source and test series related information, control system description, test
characteristics, biological and chemical analyses results, particle size
measurement equipment, and size distribution data.
Source Characteristics (see Table 1)
This group of data elements identifies the source that was tested, the
source and site location and reference information for the test series. An
entry is provided for additional remarks or data pertinent to the test se-
ries. To enable a general grouping of sources to be made, each source test
series is described in terms of the NEDS Source Classification Codes that
are applicable.
The difference between source name and site name as indicated in the
definitions is that the source refers to the specific source whereas the
site refers to the plant, station or company involved. The provision of
these separate elements allows one to distinguish between tests on differ-
ent boilers with an electric generating station, for example.
UTM Zone Locations and coordinates as well as the city/state/zip code
are also included as part of the source location.
Two other elements which are not listed in this table but are worthy
of mention are the identification of the testing group making the measure-
ment and the report reference or journal article from which the information
was acquired.
12
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TABLE 1
FPEIS DATA ELEMENTS
1) SOURCE CHARACTERISTICS:
Source Category (SCC)
Type of Operation (SCC)
Feed Material Class (SCC)
Operating Mode Glass (SCC)
Source Name
Site Name
UTM Zone Location and Coordinates
Source Address (Street, City, State, Zip Code)
2) CONTROL DEVICES:
Generic Device Type
Device Category
Device Commercial Name
Manufacturer
Device Description
Design Specification - Type and Value
Operating Parameter - Type and Value
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Control System Description (see Table!)
This group of elements includes a description of the control system
used (if any) during a specific test series, in addition to pertinent de-
sign specifications and operating parameterso Standard nomenclature is pro-
vided for describing the system and in specifying the minimum information
and data required to adequately characterize the control system, it's design
and the operating conditions during the time of the test.
This group is arranged in a format which will allow maximum flexibil-
ity for cases where multiple devices exist on the same source, e.g., cyclone
and electrostatic precipitator in series, as well as to provide adequate
space for devices where extensive design and operational data are available.
Generic device type refers to the general classification of the control
device (ESP, cyclone, etc.). The device class data element is intended to
designate the state of development as specified in the definition (conven-
tional, novel, prototype, pilot scale). General guidelines for usage of
these latter terms are as follows:
Conventional: Typical, commercial model with modifications only to
suit needed application engineering for installation and usage. Well-
known source/device combinations in conventional or widespread use
are in this category. As an example, application of a cold-side plate
precipitator to a coal-fired utility boiler is in this device class.
Novel; A device utilizing untried or unproven collection mechanisms
or combinations of mechanisms. This device class will usually include
laboratory models or a very small capacity system for demonstration
of proof of principle.
Prototype: A device of modified conventional type, or first in a se-
ries of a new system or class of device. An example of this device
class is the charged droplet scrubber at the Kaiser plant in Fontana,
California.
Pilot Scale: A device with capabilities for handling only a portion
of the source effluent to which it is applied. This device class will
consist principally of conventional equipment applied to a source which
has not been historically controlled with the specified conventional
device. An example of this device class would include use of the EPA
portable pilot fabric filter.
The above guidelines are not completely explicit. However, as further
explanation the concept of a new control device progressing in development
within the above categories through time would be: (a) novel; (b) proto-
type; (c) pilot scale; and (d) conventional. The reason for these designa-
tions is to allow a user to assess the utility of the size data considering
14
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the state of development or breadth of application of a given device to a
given source.
Additional data elements are provided in this grouping for the commer-
cial name of the device, the manufacturer, and additional qualifying infor-
mation.
A device category data element allows a more specific designation of
the generic device. Table A-3 in the Appendix gives specific descriptors
to be used for each generic device type. Only these words or necessary com-
binations are to be entered in the input data form.
Design and operating specifications and parameter values are included
in this grouping. Again, please note that a standard set of nomenclature
is provided (Tables A-4 and A-5). In this case, however, these tables should
be considered as minimum information. Additional specifications or parameters
can be included.
These tables also include standard units that are to be used. Through-
out the FPEIS data ,base all units will be in the metric system, although not
necessarily the SI standard designation. We have attempted to utilize common
practice for. some particular engineering terms, e.g., pressure drop is in
centimeters of water gauge rather than the SI pressure unit of pascals.
Test Characteristics (see Table 2)
This grouping of data identifies the test subseries and operating and
test parameters specific to a cluster of test runs. It is important for sort-
ing purposes that the subseries test date, start time and finish time be
recorded since this mechanism is used to maintain the organization of test
runs within a subseries cluster.
Source operating characteristics are the major components of this
grouping together with so-called one-time measurements that are part of the
test pr.otpcol. Examples of the operating characteristics indicated are oper-
ating rate, operating mode, feed material, etc. Examples of the one-time
measurements include mass-train sampling, Orsat analyses, trace gas sampling,
etc.
Space is also provided for subseries comments to incorporate brief nar-
rative comments or data which may be relevant. The subseries comment cate-
gory, for the present, is also used to enter device operating parameters
and values that are associated with individual test runs. It is important
to note a subtle point regarding device operating parameters and values
and what constitutes a new subseries. The change in source or collector
conditions that are due to expected fluctuations in operation between test
15
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TABLE 2
TEST CHARACTERISTICS
Sub-Series Number
Sub-Series Test Date
Sub-Series Start and Finish Time
Sampling Location and Description
Source Operating Mode
Source Operating Rate
Feed Material Composition
Volumetric Flow Rate
Gas Temperature and Pressure at Sampling Location
Moisture Content
Percent Isokinetic Sampling
Gas Composition
Trace Gases in ppm
Mass Train - Total Mass Concentration
Mass Train - Front Half Mass Concentration
Mass Train Comments
Sub-Series Comments
16
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runs is not cause for definition of a new test subseries. For example,
fluctuations in the volume flow rate to a fabric filter during test runs
will result in a change in the air-to-cloth ratio. These data are important
to note as specific to a test run but do not create a new subseries. When
the volume flow rate and resulting change in the air-to-cloth ratio are
part of test protocol, then the accompanying data are part of a new subse-
ries.
Finally, standard units to be used for all parameters in this group-
ing are indicated in the definitions.
Bioassay Testing and Chemical Analyses (see Table 3)
This group provides for entry of data from biological testing and chem-
ical analyses conducted with the particulate samples collected during the
test subseries. At the present time, the frequency of bioassay testing is
lowj however, it is expected that future test programs will include some
of this type of testing, and space has been provided for future use.
The type of bioassay test which may be entered include cytotoxicity,
mutagenicity, inhalation, skin painting and neonatal. The current defini-
tion is in the form of standard nomenclature and will be modified as appro-
priate in the future. Space is provided for narrative comments regarding
test results.
The chemical analysis group is defined utilizing the coding system
for specific elements and compounds developed for the SAROAD/SOTDAT data
base system. There is also a codification of analysis methods from the
same system.
Where available, the chemical analysis will be reported on a size dis-
tribution basis over five decades from greater than 10 (im down to 0.01 ^m.
For an analysis which required pooling of collected material from several
impactor stages because of the small quantities of material or for tests
where only mass train particulate catch was analyzed, the data element en-
titled "Filter/Total Concentration" is provided.
One can readily see that the decade designations will not agree with
cutoff diameters for any given impactor. However, a curve of chemical con-
centration versus size for a specific test can be used to approximately ap-
portion the concentrations into the specified decades. If more precise in-
formation is required by a user, the original test results are available
in the referenced report.
Particle Size Equipment and Date (see Table 4)
This data grouping provides identification of particle size measuring
equipment, specific test run data and sampling conditions and particle size
17
-------�
TABLE 3
BIOASSAY TESTING AND CHEMICAL ANALYSES
Bioassay Test Type
ซ
Bioassay Test Remarks and Results
SARCAD Chemical ID
Chemical Analysis Method
Concentration in Range Above 10 Jim
Concentration in Range 10 to 1 um
Concentration in Range 1 to 0.1 urn
Concentration in Range 0.1 to 0.01 um
Concentration in Range Below 0.01 um
Filter/Total Concentration
18
-------�
TABLE 4
PARTICLE SIZE EQUIPMENT AND DATA
Run Number
Measurement Equipment Type
Size Range Lower and Upper Limit
Substrate
Sampling Start Time and Duration
Sampling Flow Rate
Dilution Factor
Sampling Train Temperature and Pressure
Percent Moisture
Particle Diameter Basis
Concentration Basis
Upper Diameter Boundary
Density - Value and How Determined
Resistivity - Value and How Determined
Physical Properties Comments
Run Comments
, i
Diameter Boundary
Concentration
19
-------�
data from the particular test run. For discussion purposes this group can
be separated into two basic parts: measurement particulars and particle
size distribution data.
The measurement particulars include data elements defining the measure-
ment equipment type (using standard nomenclature indicated in Table A-7 of
the Appendix); the overall size range limits for this equipment; notation
of the substrate or collection surface used; gas conditions at the measure-
ment location; sampling time; flow rate; and dilution factor, if used. The
specification of gas conditions at the measurement location and dilution
factor are provided for use when ex-situ sampling is performed, e.g., dif-
fusion, battery sampling system. As with the subseries level, the run start
time and run duration are key factors required for run records and cluster-
ing of runs within the test subseries.
Two additional bookkeeping factors which are used for keying the out-
put calculation program include designation of the particle diameter basis
(Aerodynamic or Stokes) and concentration basis (mass or number).
The particle size distribution data include designation of the diame-
ter boundary and associated mass or number data. The diameter boundary in-
dicates the lower class interval boundary point for the specific basis
(Aerodynamic or Stokes) and measurement techniques.
FPEIS CONTENT AND CURRENT STATUS
The FPEIS has been implemented on the computer here at RTF and the
initial loading of source test data has been completed. The initial data
base loading included 52 test series and over 700 test runs. Data currently
being processed for the first update loading are about equivalent in number.
An assessment of the initial loading of data has been completed and
the result is in a draft summary report.
Also in draft form are a comprehensive Reference Manual and User Guide
for the FPEIS which will be available for user reference. These latter doc-
uments will be periodically updated as the system is expanded and modified
in the future.
DISCUSSION
Q. Is the person responsible for doing the testing to be designated?
A. Yes, the testing organization, company, etc., as appropriate is re-
quired on page 1 of the input form.
20
-------�
Q. Should the FPEIS contain more complete discussion and data of the pro-
cess or source design specifications such as are included in the Energy
Data System?
A. A modification of this type could be incorporated at a later date. A
temporary data element addition to indicate the source; operating con-
dition such as "percent design capacity" can be made until it is de-
cided that more information is necessary.
Q. Should there be more explicit input information required regarding han-
dling, transport and storage of samples for chemical analysis and bio-
assay?
A. Such comments can be added as appropriate in series, subseries or test
remarks.
COMMENTS
Audience - Suggest adding "plate area" and "specific collection area" to
design and operating parameters for electrostatic precipitators.
Response - The group of parameters specified in Table A-4 are defined as
minimum and these additional specifications can be added with
no problem.
Audience - Suggest referring to design efficiency and operating efficiency
as "gross mass design efficiency" and "gross mass operating ef-
ficiency," respectively.
Response-- Good Suggestion. This would minimize confusion with fractional
efficiency.
Audience - I suggest adding more specific information on substrate.
Response - This can be taken care of by adding a data element now. As more
information becomes available on substrate usage an expansion
of this important information can be incorporated by use of the
remarks.
Audience - The decades specified for chemical analysis results are some-
what atypical with respect to current reporting conventions and
it is unlikely that methods will be soon available for such small
sizes.
Some analysis results are not reported nor are they amenable to
mass concentrations.
Response - Both comments are well taken. We can revise the input format so
that the size ranges are to be specified by the investigator
based on the particular system that was used.
21
-------�
INPUT, PROCESSING, AND OUTPUT OF FPEIS
A. K. Rao
Midwest Research Institute
INTRODUCTION
Having heard the FPEIS concept, I shall now discuss topics in Figure
1,, namely, the data input, output, and processing. The success of FPEIS
will depend on how well you, the user,, understand how to input the system
with data, data processing involved, and .standard output of the system.
The presentation will be as follows. First, the system input, proce-
dures will be discussed. For this, constant reference to the information
in the Appendix will be made. Next, the output format will be discussed.
At this time, size distribution plots as drawn by the standard output pack-
age will be explained. As an example, some size distribution plots from the
current data base will be discussed. Finally, the function of the data pro-
cessing programs will be discussed briefly.
i
INPUT
A typical source/collector combination is shown in Figure 2. The FPEIS
is designed to contain: (a) characteristics of sources; (b) characteristics
of control devices; and (of) characteristics of aerosols emitted by various
source/collector combinations. It will also contain:
* Test particulars;
* Particulate mass train data;
* Particulate physical, bioassay, and chemical properties;
* Measurement instrument/method; and
* Particle size distribution data.
23
-------�
INPUT
OUTPUT
Figure 1 -.Topics for Discussion: FPEIS Input, Processing, and Output
-------�
Source
tsJ
Inlet
Slip Stream f "ZZ?
7
Inlet Sampling
Location
Outlet
Control
Device(s)
Cutlet
Sampling
Location
\
- ,' , .-
, i -! -.
ป* . I ""- **
.':*;.-,. '
To Measurement
Instrument/Method
To Measurement
Instrument/Method
Figure 2 - Typical Source/Collector Combination
-------�
It is designed such that one can get information on a:
* Specific test;
* Specific source;
* Specific control device;
* Specific measurement instrument or method; and
* All or a portion of the data.
The sampling log of a hypothetical coal-fired boiler test is shown in
Figure 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 was 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 run 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.
We call each individual measurement a test run--the whole set of runs
a test series. Since the source/collector combination operation was steady
in the morning, we group the two inlet runs, and call it a subseries. Simi-
larly, we group all the outlet runs performed in the morning, and call them
another subseries. Other subseries are designated similarly. The premise
behind the subseries designation is that the aerosol remains the same as
long as the source and control device(s) remain steady. So multiple instru-
ments can be used to cover the wide range of particle size or make multiple
runs with a given instrument.
The organization of the FPEIS is shown in Figure 4. The FPEIS contains
several test series, each of which contains one or more subseries. Each sub-
series consists of one or more runs. The levels of run, subseries, and test
series are shown in Figure 4.
In Appendix D, you will find a set of completed data input sheets. The
set contains five types of data input sheets used for coding the data. The
contents of these data input sheets are shown in Figure 5. Data Sheet No. 1
contains source characteristics and test series remarks. Data Sheet No. 2
contains the control device(s) characteristics. Data Sheet No. 3 contains
the test characteristics, particulate mass train test results, and particu-
late physical properties. Data Sheet No. 4 contains particulate bioassay
and chemical composition data. Data Sheet No. 5 contains measurement in-
strument particulars and particle size distribution. The completed set con-
tains data of two subseries of the hypothetical test described previously
(see Figure 3).
26
-------�
Test Date 12/04/73
Outlet
LLJ
_l
a.
<
on
Inlet
07(
i . i ii. i i
Measurement
Instrument No. & Name
0900 1220
2 Andersen - ฃ y ฃ ^
Impactor 0840 1200
(Run 1) 0941 1231
- 3 Optical Particle J I
Counter 0940 1230
(Run 2) 1100 1335
4 Diffusion Battery/ * y ฃ '
Condensation 1040 1315
Nuclei Counter (Run 3)
I J L J
T T
Subseries 2 .Subseries 4
Subseries 1 Subseries 3
i i
f" i r ^
0845 1050 1230 1315
-1 Brinks s-y ฃ3 ฃ* f-J
Impactor 0830 1030 1215 1300
(Runl) (Run 2)
1 II 1 1 1
DO 0800 0900 1000 1100 1200 1300 14C
TIME, 24-hour clock
Figure 3 - Sampling Log for 10 Runs
-------�
FPEIS
Test Series
Level
Test Series 1
Test Series 2
1-0
CO
Subseries
Level
Subseries 1
Subseries 2
Run
Level
Subseries 3
Subseries 1
Subseries 2
Figure 4 - FPEIS Organization
-------�
DATA INPUT SHEET ORGANIZATION
ID
1
INPUT DATA 1 TEST SERIES LEVEL
SHEET NO. 1
1
1 f SOURCE CHARACTERISTICS
\\
i I L TEST SERIES REMARKS
i
2 1 r CONTROL DEVICE(S) CHA
it
1
|
i
3 '
1
1
1
1
1
i
4
1
1
5
1
I
1
1
SUBSERIES LEVEL 1 RUN LEVEL
1ACTERISTICS
CONTROL
1
1
1
1
i
i
1
DEVICE(S) OPERATING PARAMETERS
1
f TEST CHARACTERISTICS
1
- PARTICULATE MASS TRAIN RESULTS
I
I PARTICULATE PHYSICAL PROPERTIES
{BIO ASSAY
CHEMICAL
1
TEST DATA
1
COMPOSITION
1
rl MEASUREMENT PARTICULARS
Jl
\l PARTICLE SITE DISTRIBUTION DATA
I
1
Figure 5 - Data Input Sheet Organization
-------�
Instructions for filling the data input sheets are given in the fol-
lowing sections.
A-FIELD
This contains source description, name of the testing organization,
and the reference from which the data were obtained.
Test Series Number (Card API. Columns 1 through 5)
This is an arbitrary number representing a group of runs made on one
source/collector combination. The coder can give some number which will be
changed by the FPEIS manager at the time of entering it in the data base.
This as well as subseries number and run number discussed below must be
filled to enable proper identification of data. However, these need to be
filled only on the first card of each field (on A01, B01, C01 cards, etc.).
Columns 1 through 10 of the first card of each field will be duplicated on
other cards of that field at the time of keypunching.
Subseries Number (Card API. Columns 6 through 8)
This is a sequential number representing a group of runs made at a
certain time during which the operating parameters of the source/collector
combination are not changed appreciably.
Run Number (Card API, Columns 9 and 10)
A sequential number given to a test run within a subseries. This run
should be capable of providing particle size distribution data on a por-
tion or whole of particle size range of interest.
Source Classification Code (SCO I through IV. Card API. Columns 16 through
66 and Card A02. Columns 16 through 35)
These codes are source classification codes developed by the National
Emissions Data System (NEDS) for describing the source. These four levels
of identification define a general category, and subcategories within the
general category. The subcategories define classification as to fuel, in-
dustrial processes, products, equipment types used, etc. A new code has
been added to the included NEDS list for laboratory evaluation of the con-
trol device, and some more, codes may be added later. Note also that FPEIS
uses the word description and not the numeric code.
Test Series Start Date and Finish Date (Card API, Columns 67 through 78)
These are start and finish dates for the test series.
30
-------�
UTM Zone (Card API. Columns 79 and 80)
Universal Tranverse Mercator (UTM) Zone location as found on U.S.
Geological Survey maps showing UTM coordinates (see Figure A-l).
Site Name (Card A02. Columns 36 through 75)
Complete and unique name of test site. Abbreviations such as those
shown in Table A-l may be used wherever possible.
Source Name. Street. City. State, and Zip Code (Card A03. Columns 16 through
80. and Card AOW Columns 16 through 2Q1
Name and address of the source tested.
UTM Coordinates (Card A04. Columns 21 through 29)
UTM x and y coordinates for the source as found on USGS maps with
scales less than 1:62,500.
Tested By (Card A04. Columns 31 through 80)
Name of the testing organization.
Reference (Card A05, Columns 16 through 75)
Publication reference in which the data were reported.
B- FIELD
This field contains remarks pertaining to all the test runs, and any
additional information not covered by the data elements.
Columns 1 through 10 are test series numbers, subseries numbers, and
run numbers, as given in A-Field. Columns 16 through 80 contain the test
series remarks.
C- FIELD
This field contains control device description and design and operat-
ing parameters. If more than one control device is used, or if the space
for design and operating parameters is not enough, additional sheets may
be used.
Device No. (Cards CCi. C02. G03. C04. and C05. Column 14)
This is the number of control devices, for example, if a boiler is
equipped with a cyclone, spray tower, and an ESP in that order. Cyclone
is Device No. 1; spray tower is Device No. 2; and ESP is Device No. 3.
31
-------�
Device Category (Card C01. Columns 16 through 48)
Describes control device as in the Table A-3.
Device Class (Card C01. Columns 49 through 60)
States whether the control device is conventional, novel, prototype,
or pilot scale.
Generic Type (Card C01. Columns 61 through 80)
General classification of control device in operation using standard
nomenclature such as ESP, cyclone, wet scrubber, etc.
Commercial Name and Manufacturer (Card C02. Columns 16 through 75)
Commercial or given name of the device and complete manufacturers name.
Device Description (Cards G03 and C04. Columns 16 through 75)
Brief description of the device including physical arrangement, opera-
tional principles or problems, etc.
Control Device(s) Design and Operating Parameters (Card C05)
Column 15 - Letter Code D for design parameters and 0 for operating
parameters.
Columns 16 through 45 - Design or operating parameter specification
(Table A-4).
Columns 46 through 65 - Design or operating parameter value along with
the units used. Do not use English units.
Columns 66 and 67 - Serial number of the design or operating parameter.
The utility of this serial number will be explained later.
D-FIELD
This field contains test characteristics, and remarks and/or additional
subseries information.
Control Device Inlet or Outlet (Card DPI. Column 15)
This indicates the test location by one letter Code-I for inlet, 0 for
outlet.
32
-------�
Subseries Date. Start and Stop Times (Card DPI. Columns 16 through 29)
This contains test date and time, so identifying and comparing data
is facilitated.
Source Operating Mode and Rate (Card DPI. Columns 30 through 79)
This shows the source operating mode and rate at the time of the test
in general terms. The superscript "*" will be explained later when discuss-
ing labor-saving features.
Feed Material and Feed Material Composition (Card PQ2, Columns 16 through 80)
This specified source feed material and composition at the time of test.
Sampling Location Description (Card H03. Columns 16 through 55)
This provides information on physical location of the test. Abbrevia-
tions such as those shown in Table A-l be used.
Sample Condition at Sampling Location (Card D03. Columns 56 through 80 and
Card P04. Columns 16 through 80)
This includes volume flow rate expressed in dry normal (20 C, 1 atm)
cubic meter per second (dnnrVs), flow velocity in meters per second (m/s),
temperature in degrees centigrade, pressure in millimeters of mercury (mm
Hg), water vapor by volume in percent, percent isokinetic rate, Orsat gas
analysis in percent, and any trace gases that are measured in parts per
million (ppm).
Subseries Remarks (Cards D05 to DIP. Columns 16 through 80)
These contain additional information on the subseries not covered by
the data elements. Further, it contains control device operating parameters
for the second and subsequent subseries. The format used here would be like
a text item.
E-FIELD
This contains the particulate mass train results. Front half and total
refer to the particulate concentration determined from the mass collected
on the nozzle, probe, filter and impingers. Mass train comments contain a
description of the mass train and other information.
F-FIELD
This contains particulate physical properties including particle den-
sity and resistivity. Since density and resistivity are important parameters
of aerosol, information on whether these parameters are assumed or measured
is provided by 1 or 0 (1 for assumed, 0 for measured).
33
-------�
G-FIELD
This field contains biological analysis of the particulate collected.
Some biological tests that may be performed are shown on p. 18 of Appendix
A.
H-FIELD
This field contains the chemical composition of the particulates.
Columns 16 through 19 - Chemical element or compound code listed in
Appendix A.
Column 20 - Chemical analysis method code listed in Table A-6 of Ap-
pendix A.
Columns 21 through 80 - Chemical concentration in micrograms per cubic
meter (p,g/m^) (dry normal, i.e., 20 C, 1 atm, basis) in six size ranges,
namely, filter/total, greater than 10 ^m, 10 to 1 |J,m, 1 to 0.1 ^m, 0.1 to
0.01 |j,m, and less than 0.01 (J-m. Filter/total range refers to the analysis
which is performed on mass train filter catch or on the material collected
on all impactor plates.
Chemical analyses often require pooling of impactor catches, either
identical stages of different runs or stages within a given run. The pro-
cedure by which such pooled data are coded is shown by an example below.
Table 1 shows the impactor stage loadings in grams collected at the
inlet of a utility boiler. Similar stages of the impactors for Runs Nos.
2, 3, and 4 were pooled together, and chemical analysis was performed by
atomic absorption spectroscopy on the pooled material. The results were
expressed in ppm by weight as shown in Table 2. The concentration of the
chemicals can be expressed in micrograms per cubic meter Oig/rrH) by
3 ppm x wt of pooled material in g
total flow in m3 at 20 C, 1 atm
The cyclone catch is taken as being in the size range of greater than
10 (im. Stages 1, 2, 3, and 4 catches are taken as being in the 10 to 1 fim
size range. Stage 5 and back-up filter catches are taken as being in the
1.0 to 0.1 |j,m size range. This procedure of pooling results represents some
modification and distortion of the original data, but considerably reduces
the cost of the system.
I-FIELD
This contains the particulars of measuring instrument/method, gas con-
ditions at the measurement locations, and measurement or run remarks.
34
-------�
TABLE 1
PARTICULATE MASS (GRAMS) COLLECTED
u>
(Ji
IN THE PARTICLE SIZE
TRAIN
Weight (%)
Inlet weights (g)
Stage
Cyclone
1
2
3
4
5
Back-up
filter
Total
Run 2
0.09010
0.01200
0.01187
0.00134
0.00023
0.00013
0.00150
Run 3
0.08628
0.01394
0.00561
0.00110
0.00034
0.00009
0.00100
Run 4
0.09790
0.01821
0.00766
0.00224
0.00059
0.00016
0.00140
Total
0.27428
0.04415
0.02514
0.00468
0.00116
0.00038
0.00390
0.35369
All
Stages
77.55
12.48
7.11
1.32
0.33
0.11
1.10
Plates
Only
58.47
33.29
6.20
1.54
0.50
-------�
Pollutant
Trace elements (cations)
Beryllium
Cadmium
Chromium
Cobalt
Copper
Lead
Manganese
Nickel
Tellurium
Thallium
Tin
Vanadium
Zinc
Minor elements (cations)
Calcium
Iron
POLLUTANT
CONCENTRATION
COMPOSITE OF DUST
Cyclone .
> 7.5 urn
6.6
58
381
29
75
13.4
178
450
3.5
1.2
4.0
422
426
23,000
134,000
Stage 1
7.5 to
3.8 urn
5.2
46
251
26
147
14.5
149
460
2.3
1.2
9.3
475
791
20,000
145,000
TABLE 2
(ppm)^ VERSUS PARTICLE
COLLECTOR
Stage 2
3.8 to
2.3 urn
8.7
164
458
30
261
15.5
274
840
2.3
1.4
7.6
818
1,110
35,000
155,000
INLET SAMPLES
Stage 3
2.3 to
1.5 urn
4.7
92
1,080
28
152
29.5
189
690
3.1
2.1
4.3
592
781
20,000
295,000
SIZE
Stage 4
1.5 to
0.79 vim
5.4
135
3,080
58
564
12.1
569
2,460
6.6
4.7
10.3
741
2,670
80,000
121,000
Stage 5
0.79 to
0.41 urn
36.1
447
4,510
75
2,660
18.4
654
689
17.4
28
52
1,550
4,620
81,000
184,000
Back-up
Filter
(<0.41 Jim)
97
571
1,740
66
3,380
10.2
692
1,380
- 41
55
32.8
1,970
4,100
133,000
102,000
a/ Parts per million by weight.
-------�
Measurement Instrument/Method No. (Card 101> Column 14)
This is the serial number of the measuring instrument/method in a
given test series. For example, in the hypothetical test considered here,
the Brinks BMS-II impactor, the Andersen impactor, the optical particle
counter, and the diffusion battery are given numbers 1, 2, 3, and 4, respec-
tively.
Measurement Instrument/Method Name (Card 101, Columns 16 through 45)
Specifies standard name for the measurement equipment used, such as
is listed in Table A-7 of Appendix A.
Size Range and Collection Surface (Card 101. Columns 46 through 75)
Specifies the lower and upper size range the measurement instrument/
method has covered in the test series, and type of collection surface used
if the measuring equipment is an impactor. Specifies the type of adhesive
coating and/or the type of filter used.
Dilution Factor (Card 101, Columns 76 through 80)
This is the factor by which the original aerosol mass or number con-
centration is diluted. Distortion in the size distribution by the diluter,
sampling probes, etc., may be noted in the comments (Cards 102 and 103).
Measurement Start Time (Card 102. Columns 16 through 19)
This contains the measurement start time which is helpful for time-
wise analysis of subseries.
Sampling Period and Aerosol Flow Rate (Card 102. Columns 20 through 30)
Sampling period in minutes and flow rate in liters per minute will pro-
vide the total air flow through the instrumentuseful for determining the
aerosol concentrations.
Gas Conditions at Measurement Location (Card 102. Columns 31 through 42)
In ex-situ sampling, gas conditions at the measurement location can
be different from that at the sampling location. The temperature in degrees
centigrade ( C), pressure in millimeter of mercury (mm Hg), and water vapor
by volume in percent shall be filled.
Comments on the Measurement (Cards 102 and 103)
These are run remarks and any information not covered in run data ele-
ments should be specified.
37
-------�
JrFIELD
This contains the particle size distribution data. Cards J01 through
J03'contain the particle size class boundaries, and Cards J04 through J06
^contain aerosol concentrations.
Column. 14 .of J01 and J04 cards contains the measurement instrument/
method .number. Column 15 of J01 card indicates whether aerodynamic or Stokes
diameter,is used. Columns 16 through 79 shall have class boundaries in micro-
meters (jJi.m)-. The sizes shall be in the decreasing order with first number
corresponding.to the upper boundary of the aerosol that is sensed by the
instrument; This upper boundary is usually not known, but can be estimated.
Also, the last size boundary is usually not known, but can be estimated.
Column 15 of the J04 card specifies whether the concentration speci-
fied is by .mass basis or by number basis (M-g/m3 or No./cc). The concentra-
tions are expressed in scientific notation to avoid the loss of significant
figures.
DATA INPUT SHEET STRUCTURE
Input to the system is prepared by filling five types of data input
sheets; Sheet No. 1 for source description and test series remarks,; Sheet
No. 2 for control device design and operating parameters, .Sheet No. 3 for
test particulars, mass train test results, and particulate physical proper-
ties, Sheet No. 4 particulate bioassay and chemical composition test results,
and Sheet No. 5 for measurement instrument/method description and particle
size distribution data.
In.the discussion above, we covered how each data element gets filled.
Now we shall discuss how to code several runs and subseries of a test series.
As an example, the first two subseries and their runs of the example test
are coded, and completed sheets are shown in the Appendix. Notice that the
first five sheets provide information on the test series, Subseries No. 1,
and Run No. 1. The sixth page is the data input Sheet No. 5 which contains
Run No. 2 of Subseries No. 1. For a moment, let us ignore the blanks in
this and other sheets that follow this sheet. Only Data Input Sheet No. 5
-is needed to code the Run No. 2. To code the second subseries we need only
Data Input Sheet Nos. 3 and 4. In the example, however, Sheet No. 4 was
not used as there were no biological or chemical data. Following Sheet No.
3, the 8th, 9th, and 10th pages provide data pertaining to the first, sec-
ond and third runs of the s;econd subseries. This is how the data sheets
stack up.
LAB0R-SAVING FEATURES
In developing the data input sheets and the data processing programs,
several labor-saving features have been introduced.
38
-------�
These features reduce time, labor, and cost on the part of the coder,
and eliminate keypunching and verifying costs on the part of the data mana-
ger. However, misunderstanding of these features may result in entering er-
roneous data. The labor-saving features are explained below. If the explana-
tion 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. 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 copied. Note, however, if source operating mode for
Subseries 10 through 14 and Subseries 16 through 20 is the same, but for
Subseries 15 is different--it is necessary to code source operating mode
for Subseries 10, Subseries 15, and Subseries 16. For the rest of the sub-
series, information from their preceding subseries will be copied. All the
data elements which will be duplicated this way are marked with a star (*).
The data elements on Data Input Sheet No. 5 marked with ** are asso-
ciated with measurement instrument/method. For these data elements, we need
to code only those data which are new or different from the data for the
measurement instrument/method in consideration.
The labor-saving feature using serial number for control device operat-
ing parameters is withheld temporarily pending some changes in the SYSTEM
2000.
DISCUSSION
Q. Do the SCC codes have to be exactly as in the NEDS system (no spelling
variations)?
A. Yes.
Q. What is the purpose of UTM coordinates?
A. To match up with other EPA data bases; specifically with SOTDAT. Also,
emission modeling people can make use of it.
Q. Wouldn't it be useful to give some more information on the source;
whether or not the source is operating at designed conditions at the
time of test?
A. At present there isn't much data on the sources. If there is more data
it could be given in the test series remarks.
39
-------�
Q. Do you have any chemical composition data in the less than 0.01 fim size
range?
A. At present we do not have any data in this size range, but new techniques
such as ESCA may be used in the near future which can provide the data.
Q. Reformatting the experimental data to conform to your format is a lot
of work, and it would be easier for the contractor to report the data
as taken.
A. To bring the experimental data into the present format requires only
simple calculations.
Q. Why do you propose this six decade arrangment? Why not have various
sizes?
A. This is to minimize the size of the system and reduce cost. Furthermore,
greater emphasis is placed on the particle size data than the chemical
composition data.
Q. Why do we have to report data in M-g/n? Why not report the raw numbers
and let the machine make the calculations?
A. Yes, it is possible to require raw numbers only, and let the computer
convert the raw numbers to fig/nr. However, this requires some front end
programs. Furthermore, many times the individual who collects the data
will be doing some analysis of the collected data. In such situations,
he will be needing aerosol concentrations which can be expressed easily
in Hig/m^. The problem is that aerosol measurements are done by several
different instruments, not just impactors; and test results are reported
in several different ways.. So, the front end programs would be, too numer
ous to handle all possibilities.
Q. Do the figures used for concentrations and particle sizes represent the
number of significant figures?
A. No, we choose three digits after the decimal place for particle size
so that we could report sizes down to 0.001 [i,m. The system is flexible
so as to accept what ever diameters you report. The digits in the out-
put do not represent the number of significant figures -because they are
written with a fixed format. The same is true in the case of concentra-
tions. Here, of course, scientific notation is used to handle the wide
range of concentrations without loss of significant figures.
40
-------�
COMMENTS
Audience - Our experience is that greater mass is right around 1 p, size and
chemical composition for particles larger than 5 M>m is different
from the composition of particles smaller than 5 M-m. Furthermore,
smaller than 3 jim is respirable size range. So instead of last
two size ranges, there can be more ranges in 1 to 10 |j,m.
I guess the point we are trying to make here is that since we
get chemical composition information on eight impactor stages,
and since you got five decades here, last two of which are es-
sentially meaningless, make eight columns for eight impactor
stages and let the user do whatever he wants to do with the data.
Response - We are not disagreeing with you at all. The point is well taken.
As a matter of fact, as the system matures we can actually im-
prove on that. What we are saying is that this format is flexible,
and it can be changed. This is the type of thing we need to know.
Audience - Lots of the time, we don't know what the cut points of impac-
tor are, so keep the stage numbers on the forms.
I guess, what we are telling you right now is that what you have
here is not satisfactory.
I have a couple of comments regarding size distribution data.
The first one is on the cut point of impactors. From some of the
work we did, and from some of work of Dorsey's people have done,
we know that the manufacturer's calibration is faulty. If the
hole diameter and number of holes per stage are known, we can
develop the new calibrations, and rework the data. Therefore,
I strongly suggest that you specify the number of holes per stage
and their diameter so that if we discover a year from now that
the calibrations are off by a factor of 20, all this data can
be reworked and not lost. Some of the data which was taken with
improperly calibrated impactors whose number of holes per stage
and hole diameter is not known, it .can't be corrected now and
the data are useless.
The second.comment is on the way concentrations are reported,
i.e., ug/m . I really think that we should report stage weights
instead of mass concentrations in Ug/m . If we record the stage
loadings, aerosol flow rates and sampling periods, the computer
can calculate the u-g/m . Moreover, a lot of people do not work
in terms of concentrations.
41
-------�
Response - The first comment is good. A good description of the instrument
which in the case of impactors includes the hole diameter and
number of holes per stage can be given as test series remarks.
Regarding impactor cut points, theoretical calculations using
hole dimensions may not be accurate, and we should aim at ob-
taining experimental cut points.
Regarding the second comment, interpretation of the size distri-
bution data is possible only when you express mass, surface or
number per unit volume (e.g., grain loading). Also, if the in-
strument provides number/cc and if we know density in g/cc, then
a simple multiplication gives concentration in Hg/m3.
Audience - I realize that there are some advantages. However, these concen-
trations can be calculated by the machine.
Response - Yes, but to accept raw data requires several types of data input
sheets instead of one data input sheet as we have here. Even
though the bulk of the present data is obtained with impactors,
there are several other types of devices that can be used to col-
lect size distribution data.
Audience - We require now that our contractors provide the filter weight
gains in blank runs.
We need to have a whole set of new cards for reporting the weight
gains of filters in the blank runs. We require this information
from all of our source testing contractors. This is very valuable
information.
Response - We don't need a new set of cards. Blank tests can be treated as
separate runs with pertinent remarks.
42
-------�
DATA OUTPUT - STANDARD FORMAT AND OPTIONS
A. K. Rao
Midwest Research Institute
G. S. McMahon
MRI Systems, Inc.
SYSTEM 2000 provides unlimited capabilities by which the user can sort,
rearrange or compare the FPEIS data. It also provides a standard output for-
mat. This standard output format is the topic of this discussion.
Tables 1 and 2 and Figure 1 show the standard output format. In Table
1, all the descriptive information of the test is shown. In Table 2, the
particle size distribution data are provided. In Figure 1, the three par-
ticle size distributions, namely, the mass, surface, and number distribu-
tions, are plotted.
The descriptive information in Table 1 is arranged under various head-
ings. On the top, the subseries is identified. Following the identification
are the source characteristics; control device(s) characteristics; physical,
biological, and chemical data; measurement equipment and gas conditions;
test subseries and test series remarks.
Table 2 contains particle size distribution data. In this table, the
aerodynamic and Stokes boundary diameters and their geometric midpoints
are given in the first four columns. The mass, surface, and number concen-
tration and distribution function are shown in rest of the columns. On the
bottom of this table, integral parameters of the size distribution, namely,
total concentration in the size ranges above 1 M.m, below 1 (j,m, less than
0.01 p,m, 0.01 to 0.1 n,m, 0.1 to 1 nm, 1 to 10 y,m, and greater than 10 (j,m
in mass, surface and number are presented. Total concentrations are ex-
pressed for mass in |J.g/m^, surface in p,m^/cc, and number in No./cc. The
concentration in various size ranges are expressed as percent of the total
concentration.
43
-------�
TABLE 1
TEST DESCRIPTIVE INFORMATION
STATIONARY POINT SOURCE
FINE PARTICIPATE EMISSION INFORMATION SYSTEM
TEST SERIES NO: 2
TESTED FROM
REFERENCE?
SUB-SERIES NO:
1 INLET
DATE: 9/36/73
FROM 13120 TO 16tl5
09/25/73 TO 09/27/73 BY: CONTROL SYSTEMS LABORATORY,EPAiRTPtNC
STATNICKtRMt EPA-65012-74-111 OCT 74
I. SOURCE CHARACTERISTICS-
NEDS SCC CATEGORY: INDUSTRIAL PROCES
OPERATION CLASSl PRIMARY METALS
FEED MATERIAL CLASS: COPPER SMELTER
OPERATION MODE CLASS: CONVERTING
SPECIFIC OPERATION: CONVERTING
OPERATING KATE: 500 T/DAY
SITE NAME
SOURCE NAME
ADDRESS
TACOHA
UTM ZONE AND X-Y COORDS: 10
FEEDMATERIAL:
FEED MATERIAL COMPOSITION:
AMERICAN SMELTING ป REFINING CO (ASARCO)
COPPER SMELTER CONVERTER
tUA
-0.0
-0.0
II. CONTROL DEVICE(S) CHARACTERISTICS-
UNIT 1
DEVICE CATEGORY:
CLASS:
GENERIC TYPE:
DESCRIPTION:
PARALLEL PLATE
CONVENTIONAL
ESP
DESIGN PARAMETERS
COMMERCIAL NAME>
MANUFACTURERS
ELECTRO STATIC PPTR
RESEARCH COTTREL.NL
OPERATING PARAMETERS
1)VOLUMETRIC GAS FLOW RATE
2)ELECTRODE AREA
3)CORONA CURRENT
4)SPARK RATE
5)VOLUME PER UNIT ELECTRODE AREA 0.0042 M/S
6)CORONA CURRENT DENSITY 0.084 MA/M2
7)TEMPERATURE
61.4 DNM3/S
14813 M2
1243 HA
110 NO/MIN
123 C
III. TEST CHARACTERISTICS
CONTROL DEVICE INLET SAMPLING POINT DESCRIPTION: 3.5X7.3M DUCT IM UPSTREAM OF ESP DUCT * ISOKINETIC: 104
PROCESS CONDITIONS: VOL FLOW= 61.4 DNHB/S VELOCITY* 2.9 M/S T= 123 c P= 770 MHHG WATER VAP *VOL* 5.8
GAS COMPOSITION: ORSAT- co?= .40 % co= o.oo * 02= 20.20 % N2- 79.40 ซ
TRACE GASSES(PPM)-S02=30236> 503=63.8
IV. PARTICULATE MASSTRAIN RESULTS
FRONT HALF= 3.3bOE*06 UG/ONM3 TOTAL= 3.690Eซ06 COMMENTS!
-------�
TABLE 1 (Concluded)
V. PARTICIPATE PHYSICALt BIALOGICAL AND CHEMICAL PROPERTIES
DENSITY= 1.00 GM/CC ASSUMED RESISTIVITY= 5.00E*11 OHM-CM ASSUMED
CHEMICAL COMPOSITION DATA
CHEMICAL AND ANALYSIS METHOD
1) ARSENIC
ATOMIC ABSORPTION
2) CADMIUM
ATOMIC ABSORPTION
-' 3) CHROMIUM
ATOMIC ABSORPTION
4) COPPER
ATOMIC ABSORPTION
5) MERCURY
ATOMIC ABSORPTION
6) LEAD
ATOMIC ABSORPTION
7> ZINC
ATOMIC ABSORPTION
AMOUNT IN UG/DNM3 FOR PARTICLE OIAHETERIUM) RANGE OF
FILTER/TOTAL
616230.0000
40959.0000
262.7300
273.0600
67.5300
321766.0000
227673.0000
OVER .10 10 TO 1
-0.0000
-0.0000
-0.0000
-0.0000
-b.oooo
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
1 TO 0.1 0.
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
1 TO 0.01 UNDER 0.01
-0.0000
-0.0000
-0.0000
-o.pooo
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
-0.0000
VI. MEASUREMENT EQUIPMENT AND GAS CONDITIONS
UNIT 1
1 RUNS
EQUIPMENT NAME: BRINK-MODEL B
SIZE RANGE I .050 TO 10.000 MICRONS
DILUTION FACTOR= 1.0 TEMP= 104 C
COMMENTS: IMKACTOR POSITION VERTICAL
COLLECTION SURFACE/SUBSTRATE: UNCOATED SS CUPS
SAMPLING RATE: 2.ft LPM SAMPLING PERIOD: is.o HIN
PRESSURE= 770 MMHG WATER VAP ปVOL *> 5.8
vn. TEST SUB-SERIES REMARKS-
VIII. TEST SERIES REMARKS-
DUCT VELOCITY WAS OBTAINED AT ONLY ONE LOCATION AND RESULT CAN
BE CONSIDEHED APPROXIMATE
SMOKE STACK HEIGHT 163 M
16% OF THE SMELTER CONVERTER FLUE PASSES THRU AN ACID PLANT (SOX
REMOVAL 96.7*) BEFORE REACHING THE ESP
PARTICLE SIZE DISTRIBUTION DATA REAR FROM GRAPH (AVE OF 3 RUNS)
PARTICLE SIZt BOUNDARIES ARE ARBITRARILY CHOSEN
SAMPLES DRIED 3HR AT 60C DESICCATED ?HR ป WEIGHED ON METTLER H20T
BALANCE
-------�
TABLE 2
PARTICLE SIZE DISTRIBUTION DATA
TEST SERIES NO:
SUB-SERIES NO: 1 INLET DATE! 9/26/73 FROM 13:20 TO 16:15
IX. PARTICLE SIZE DISTRIBUTION DATA
AERODYNAMIC DIA (UM) PARTICLE DIA (UM)
DM
DM/DLDAE
DS
OS/DLDAE
= 1.00
ON
ASSUMED
DN/DLDAE
BNOWY MID PT BNDRY
MID PT
u>
UNIT 1 BRINK-MODEL 8
10.000
5.500
2.500
1.600
.880
.400
.195
.050
INTEGRAL PAR
MASS
SURFACE
NUMBER
10
7.416 5
3.708 2
2.000 1
1.187
.593
.279
.099
(UG/DNM3)
(UM2/CC)
(NO. /CO
.000
.500
.500
.600
.880
.400
.195
.050
3.
6.
2.
7.416
3.708
2.000
1.187
.593
.279
.099
TOTAL
761Eซ06
898Eป06
812O06
1
1
3
3
6
6
5
LT 1.
2.0
12.5
82.3
.890E+06
.100E+06
.850Eป05
.110E*05
.790E*04
.560E+03
.640E*02
0 GT
98
87
17
lUU/Uwnjl
RUNS 1
7.279Eซ06
3.212Eป06
1.986Eซ06
1.198Eซ06
1.983E*05
2.102Eซ04
9.542E*02
1.0 LT
.0 0
.5 0
.7 0
iunซ:/^v,i
1.529Eป06
1.700E+06
1.155Eซ06
1.573Eป06
6.867Eป05
1.409E*05
3.427Eป04
0.01 0.
.0
.0
.0
i
5
5
5
6
2
4
5
01-0
.0
.5
39.8
un
-------�
TEST SERIES NO:
SUR-SERIES NO: 1 INLET
RATE: 9/26/73 FROM 13:20 TO 16:15
PARTICLE DIAMETER (UM)
0.00
SCALES=
NO.niST: 1- 5.6?5E*06
SUP.DIST: 1- I.380E*07
MASS.OIST: 1- 7.522E*06
Figure L - Plot of Particle Size Distribution Data
-------�
, In Figure 1, the differential mass . , _ surface . _ _ and
A log Dae A log Dae
AN
number / , ^ distributions are plotted as a function of aerodynamic
A log Dae
diameters (Dae). The interpretation and usefulness of these plots will be
given in the discussions that follow,,
f
Figure 2 shows the lognormal mass distribution ("X = 1 jJ-m, erg = 3) of
a hypothetical source. The quantity of interest is mass per unit volume
withinia given size range. Since the particle size ranges over four de-
cades, we have to use a log^Q scale on the abscissa. Since there is no
AM
mass concentration associated with a given size, we need to plot
A Io8 Dae
on the ordinate as suggested by the following equation.
1 '' log D I = AM mass within a given range
log ^e & ae
If we divide the above equation by total mass concentration, the right hand
side then represents the fraction of mass within a given size range, and
AM
the distribution function density . , _ ' becomes dimensionless. If we
AM
plot . with linear scale versus aerodynamic diameter with log scale,
** ciC
the area under the curve represents fraction of mass within the size range.
The mode of this curve as well as the percentage mass within a given size
range can be visually estimated and easily interpreted which is the main
purpose of a graph.
Another useful feature of the present plots results from normalization
AM
of ordinate . , by the total mass of the distribution. If we draw in-
A log Dae
let and outlet distributions with one scale (i.e., divide the ordinate with
total inlet mass concentration), the outlet distribution will be usually
very close to the abscissa and cannot reveal all its features (see Figure
3). However, by choosing the total of distribution mass as its scale fac-
tor, the effect of mass concentration on the plots is eliminated, and inlet
and outlet size distribution curves show only relative mass concentrations
within the size ranges. If the control device collection efficiency is in-
dependent of particle size, then inlet and outlet particle size distribution
will be the same. Therefore, normalizing ordinates with total mass concen-
tration makes inlet and outlet particle size distribution curves coincide
with one another. So we find that normalized size distribution curves will
coincide with each other (irrespective of total mass concentration) when
their size distributions are the same, and vice versa.
48
-------�
1.00
0_
Q
o
o
i
Q
0.75
0.50
LO
Q
l/l
0.25
0
\ ( D Log Dp ) = DM Mass Within a
D Lฐ9 DP' Given Size Range
= (M9/m3)
Inlet Mass Distribution
/Log Normal with
V. x = 1/zrn, erg = 3
Fraction of Mass
Within the Size Range
Total Area Under
the Curve Gives the
Total Mass Concentration
0.10
1.00
PARTICLE DIAMETER ( p. M )
Scale: 1 = Total Mass Concentration (/^.g/m3)
Figure 2 - Inlet Mass Distributions of a Hypothetical Source/Collector Combination
10.00
-------�
1.00
0.75
o
o
O 0.50
CD
S
I
1/1
5
to
UO
0.25
Control Device
Fractional Efficiency
Inlet Mass Distribution
/Log Normal withN
\x = 1/im, (Tg = 3 /
Outlet Mass
Distribution
0.10
Scale: Mass Distribution: 1 - 2.000E +
1.00
10.00
PARTICLE DIAMETER
Figure 3 - Inlet and Outlet Mass Distributions of a Hypothetical Source/Collector
Combination Whose Collector has 80% Collection Efficiency
-------�
For summarizing the FPEIS data for each test series, all inlet mass
distributions are plotted on one page, and all the outlet mass distribu-
tions are plotted on another page. However, instead of using total mass of
each distribution as a normalizing factor, twice the average total mass of
all runs in a given plot are used. This type of plot shows variation in to-
tal mass concentration as well as size distribution. For example, Figure 4
shows three inlet size distribution curves whose total mass concentration
is different but whose size distribution is the same. Notice that the shape
of the curves is similar due to same size distribution, but the three curves
do not coincide with each other because the total mass concentration is dif-
ferent. Of course, if both size distribution and total mass concentration
are different for these runs, then the shape as well as the location of plots
would have changed.
SOME FEATURES OF FPEIS DATA
Figures 5 through 10 show the inlet and outlet mass distributions of
three test series which were obtained on different coal-fired boilers; one
equipped with a parallel plate ESP, the other with Nomex baghouse, and the
third with a Venturi scrubber. In these figures, all the data points and
their average (eye-fit) curve are shown. The eye-fit curve represents the
average size distribution. The scale is twice the average total mass con-
centration.
The particle size distribution at the control device inlet is influ-
enced by source only, whereas the outlet is influenced by both the source
and control device. If we just look at the inlet size distributions, i.e.,
Figures 5, 7, and 9, we find that the inlet size distribution as well as
total mass concentration does not change from one source to the other. Coal-
fired boilers emit significantly more super-micron particles. The outlet
size distribution, i.e., Figures 6, 8, and 10, unlike the inlet distribu-
tions, are different from one another due to different types of control de-
vices used. An electrostatic precipitator, which has more or less constant
collection efficiency in the range larger than 1 |im, does not alter the size
distribution (Figures 5 and 6). The baghouse used in test Series 36 (Figures
7 and 8) slightly alters the inlet size distribution. The larger particles
are removed wi'th greater efficiency than 1 urn particles. Venturi scrubbers,
while effectively removing the super-micron particles, are ineffective for
removing submicron particles. This is because inertial impaction is the pri-
mary mechanism of collection.
While coal-fired boilers emit predominantly larger particles, metallur-
gical processes emit primarily submicron particles. This can be seen in Fig-
ures 11 through 16, in which are shown inlet and outlet size distribution
of zinc sintering furnace, open hearth furnace, and aluminum reduction cells
equipped with dry ESP, steam-hydro scrubber, and spray tower/ESP, respect-
ively. Notice here again that ESP's do not alter the size distribution but
scrubbers dp.
51
-------�
1.00
0.75
CL
Q
o
o
Ul
r-o
Z
o
I
CD
oi
CO
Q
CO
CO
0.50
0.25
Total Mass Concentration
6.0 E+ 6
4.0 E + 6
2.0 E + 6
0.10
Scale: Mass Distribution: 1 -4.0E + 6yU.g/m>'
1.00
10.00
PARTICLE DIAMETER
Figure 4 - Three Inlet Mass Distributions of a Hypothetical Source/Collector Combination Drawn
to a Constant Scale--Size Distributions are Same but Total Mass Concentrations Different
-------�
TEST SFPIES NO:
1.00 ..ซซ..ซ..
?H
INLET
DATF:
FROM
TO
1 Cool-Fired Utility Boiler
.75 --
H
A
5
S
0
I
S
T
.50
.35 --
0.00
MM T MM M
1 . 00
ICI F DI AMF TF " HIM)
M
H
Sr AIFs =
: 1- I .4 7',f . n 7
I - S. 7 IMF flfi
OIST: 1- 1 . 11?F '07
Shannon, L. J., ct al., "St. Louis/Union Electric Refuse Firing Demonstration"
Figure 5 - Inlet Size Distribution of Test Series 28
-------�
TEST SEPIES NO:
1.00 ..ปป.ซซ.
OUTLFT
OATF :
FPOM
TO
' J * * ป 4
1
1 ESP
1
' Cool-Fired Utility Boiler
.75-ป--
M
A
S
s
0
I
s
T
V/i
.50
0.00
*
] MM / M | M M
| **yy( M M M | M
) MM 1 M M
.10 1 .on
PAUT1CIF niftMF.TFP UIMI
M 1
1
1
10.00
s =
Figure 6 - Outlet Size Distribution of Test Series 28
-------�
TEST SEPIKS NO:
1.00 .ซ....*ซ
INLET DATF: / /
FROM
TO
M
A
S
S
D
I
.75
.50
(Ji
0.00
1
1 Cool-Fired Boiler
1
. 1"
Kf
1 .on
OIAMFTM* (IIM)
N
jo.no
McKcnna, J. D., et al., "Applying Fabric Filtration to Coal-Fired Industrial Boilers," EPA-650/2-74-058-a
Figure 7 - Inlet Size Distribution of Test Series 36
-------�
TEST SERIES NO:
1.00 .....ปป.
OUTLFT DATF:
FROM I0:ns TO
, | ....*..,*ป....
1
I Nomex Boghouse
1 Cool-Fired Boiler
1
.75 --
M H
M ป
Ol
.50 ซ
0.00
io.no
i-
siiป.HIST :
MASS DIST: 1- ?.*ซปSFป0*
Figure 8 - Outlet Size Distribution of Test Series 36
-------�
TEST SERIES NO:
1.00 ...ซ
51
INLFT
DATE:
FROM
>!ซ**,ซ.ป.*ซป*.
1
I Cool-Fired Boiler
1
.75 ป--
M
A
S
s
D
I
S
T
Ul
.50
0.00
Sr
ปMป i
1 .no
'T ICI.K I'l AMf If IJ (||M)
NO.ni <;T ; 1 - 7 . T. u
1 D.nn
nt<;T: i- /.
Galvert, S., ct al., "Fine Particle Scrubber Performance Tests," EPA-650/2-74-093
Figure 9 - Inlet Size Distribution of Test Series 51
-------�
TEST SERIES NO:
1.00 ซ*..ป*
OUTLET OflTF: / /
FROM
TO
1 ปซ*ซป*
1
1 Venturi Scrubber
1
Coal-Fired Boiler
.75
H
A
S
S
D
I
S
T
.50
00
0.00
"A'M K.'l.f II 1 A Mr- If 0 (IIM )
in.no
Figure 10 - Outlet Size Distribution of Test Series 51
-------�
Ul
VO
TEST SEWIES NO:
1 .00 .ซปซ.ซ.ป<
INLET
n*TF :
FROM
TO
.75
.50
0.00
>!ซ*ซ ป
1
1 Zn Sintering
1
. 1 n
I. no
Pfl'M Id F (H A"F Tf.W HIM)
1
1
I :
10. 00
1 - 7.7 1?f ปn7
Harris, D. B., and D. C. Drehmel, "Fractional Efficiency of
Metal Fume Control as Determined by Brink Imjjactor," EPA/CSL (1973)
Figure 11 - Inlet Size Distribution of Test Series 3
-------�
TEST SERIES NO:
1.00 .........
OUTLF.T nATF: / /
FROM
TO
1 Zn Sintering
1
1 Dry ESP
.75 ป--
H
A
S
s
0
I
s
T
.50 ป
0.00
PAUT1CI.K DIATTFP (IIM)
i o.nn
Nn.n I r,T : 1 - 5. AT7f .07
. n I -, T : I- ?.n47Fซ07
,T:
Figure 12 - Outlet Size Distribution of Test Series 3
-------�
TEST SERIES NO:
1.00 *ปปปปป.
INLET
DATE:
7/73
FROM
TO
.75
H
A
S
s
0
I
s
T
.50
.35
0.00
1 ,
1 Open Hearfh Furnace
1
.10
H
H
H
H
M
M
H
M
M
H
M
M
M
M
H
H
M
l .on
PARTICLE DIAMETER (UM)
10.00
SCALES=
( ./.DIST: 1- 7.641Eซn7
SUR.DIST: 1- 1.1Q?E*07
MASS OIST: 1- 5.ft*REป06
McCain, J. D., and W. B. Smith; :"Lone Star Steel Steam-Hydro Air
Cleaning System Evaluation:;" EPA-650/2-74-028 (1974)
Figure 13 - Inlet Size Distribution of Test Series 8
-------�
TEST SERIES NO:
1.00 ซ*ปป*ป
OUTLET DATE: \z/ 7/73 FROM
TO
1 Open Hearth Furnace
1 Lone Star Steel Steam-Hydro Scrubber
1
.75 *
to
M
A
S
s
0
I
s
T
.50 ซ
.25 *
0.00
1
1
1
l + *
.10
1 .00
PARTICLE DIAMETER (UM)
SCALES^
NO.niST: 1- 8.fll?E*05
SUR.DIST: i-
MASS DIST: 1- 5.flซ4F>03
Figure 14 - Outlet Size Distribution of Test Series 8
-------�
TEST SERIES NO:
1.00 ป*ป**ซปซ.
INLET
DATE: / /
FROM
TO
1 Aluminum Reduction Cells
1
Ui
.75 --
M
A
S
S
0
I
S
T
.50
.85 ซ
0.00
M
M
M
M
M
1
1
1 .00
PARTICLE: DIAMETER
-------�
TEST SERIES NO:
1.00 .ปป+ป*ซ.
34
OUTLET
DATE: 8/33/74 FROM 8:00 TO ?3:00
.75
H
A
S
S
0
I
S
T
.50
.25
0.00
1 'Aluminum Reduction Cells
1
1
1
1
>+l4- + + * + 4
.10
1
1 ESP Preceded by Spray Towers
i .no
PARTICLE DIAMETER (UM)
SCALES=
*' .OIST: 1- S.20f,Eซ04
suR.niST: 1- l.S7?eปr>4
MASS nisT: i- i.7nf,rซni
Figure 16 - Outlet Size Distribution of Test Series 34
-------�
The present data and plots can be valuable to future source testing.
Even though there may be deficiencies in the measurement, the data still
give a good idea of what to expect when sampling similar sources.
DATA PROCESSING
A Fortran program consisting of several subroutines has been developed,
which prepares raw data to a form suitable for entering into SYSTEM 2000.
This preparation involves the following steps.
Step Process
1 Fill Missing Cards with Blank Cards
2 Duplicate Necessary Information
3 Edit: a. Check for Card Order
b. Check for Obvious Errors
4 Punch New Deck or Magnetic Tape
5 Submit to SYSTEM 2000
In Step 1, the missing cards, i.e., cards unfilled at the time of cod-
ing, will be replaced with blank cards within the memory. In Step 2, where-
ever there is a need for duplicating information such as, say, the sampling
location description or the measurement equipment description, will be du-
plicated. In Steps 3 and 4, after editing the deck for card order and obvi-
ous errors, the data are copied onto a magnetic tape. The editing process
involves complete calculation of size distribution and total mass surface
and number concentrations. If the total mass concentration is not within
the range of 10^ to 10ฐ fig/m^ or if the number concentration is not within
the range of 10^ to 10^-0 particles/cc, keypunching or coding error is sus-
pected. All the data are carefully checked before they are copied on the
magnetic tape. In the final step, the data are entered into the SYSTEM 2000,
and a complete listing is obtained which will be sent to the author for his
review. Any comments or changes he suggests will be made before the data
are released for public use.
65
-------�
CLOSING COMMENTS
TO THE
FPEIS USER'S WORKSHOP
Gary L. Johnson
Project Officer
Special Studies Staff
IERL-RTP
The information presented at this workshop today represents the result
of almost 2 years of effort by IERL and its contractors. It does not, how-
ever, represent the end of a project but, in reality, the beginning of one.
The FPEIS must, by its very nature, be a dynamic system responding continu-
ously to the changing needs of the user community. The comments and sugges-
tions offered here today further underscore this point. It must be recog-
nized, however, that the FPEIS cannot be all things to all people, but a
concerted effort can and will be made to incorporate the greatest amount
of user flexibility possible into the FPEIS without degrading seriously the
performance of the system.
As you have seen, the input and basic output formats of the FPEIS are
generally not too difficult to use. We agree that improvements are needed
in both, but there is one further point that the user community must rea-
lize: FPEIS is merely a tool; it cannot do your work for you nor was it
ever intended to do so. Some preprocessing of data will be necessary, but
we do not believe that any testing organization will find it to be burden-
some. Further, we believe that no reputable testing organization would sub-
mit completely raw, unchecked data to FPEIS or anywhere, except under very
extreme circumstances. FPEIS is intended to provide the total user community
with a centralized means of storing data based upon a common protocol. Such
a protocol inherently poses some limitations or restrictions, but much of
the problem with data analysis today stems from the fact that no two test-
ing organizations report data in the same manner or, for that matter, even
report the same data. Comparison of testing results has become a difficult
or, in some cases, an impossible task.
67
-------�
The FPEIS offers the user the opportunity to access a wide spectrum
of fine particle emissions data presented and stored on a common basis. As
the FPEIS is expanded, a large catalog of inquiry routines will be available
to users to interrogate the data base. The possible variations in selection
criteria are many and are limited only by the imagination of the user and
the physical constraints of the computer. We will continue to look to you,
the FPEIS user, for guidance in developing new output modules. From today's
discussion, it is likely that an early program module to be developed will
be one to produce fractional efficiencies for various source and collector
combinations. Another one will be a statistical analysis package. We invite
your suggestions on any new output modules needed.
This, then, is the Fine Particle Emissions Information System. It is
a new approach to an old problem of assimilating data. With your help and
patience, the FPEIS will be a significant asset to continuing fine particle
control technology research and development.
The workshop is adjourned.
68
-------�
WORKSHOP ATTENDEES
J. H. Abbott
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
Dr. Paul E. Fredette
Projects Director
Enviro-Systems and Research, Inc.
Roanoke, Virginia 24016
S. C. Hunter
Manager, Technical Assessment
KVB, Inc.
Tustin, California 92680
Benjamin Linsky
Professor
West Virginia University
Morgantown, West Virginia 26506
Leland Mote
P.O. Box 8
Station B
Systems Analysis Group
Monsanto Research Corporation
Dayton, Ohio 45407
Dr. John Small
Chemist
National Bureau of Standards
Washington, D.C.
L. E. Sparks
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
D. L. Zanders
Monsanto Research Corporation
Research Triangle Park
North Carolina 27711
69
Dennis Drehmel
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
Bill Lipscomb
Enviro-Systems and Research, Inc.
Roanoke, Virginia 24016
Erica Graf-Webster
Mitre Corporation
Greg Hoi ton
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
Joe McSorley
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
Gene Tucker
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
David B. Large
Teknekron, Inc.
4701 Sangamore Road
Washington, D.C. 20016
Bob Bradway
GCA/Technology Division
Burlington Raod
Bedford, Massachusetts 01730
G. Ramsey
EPA
IERL-RTP
Research Triangle Park
North Carolina 27711
-------�
APPENDIX A
FPEIS DATA ELEMENT DEFINITIONS
71
-------�
FPEIS DATA ELEMENT DEFINITIONS
100* Source Category
110* Source Characteristics
120* Type of Operation
130* Operating Mode Class
Source identifier, (See Appendix B,
SCC, Category Name I.)
Example: EXTCOMB BOILER
The principal repeating group in this
data base which includes statements
120 through 270 and repeating group
300, Data are not entered in this cate-
gory but this category is used merely
as an introduction to subcategories.
Specific operation which was tested.
(See Appendix B, SCC, Category Name
II.)
Example: ELECTRIC GENERATION
Size and characteristics of operation,
(See Appendix B, SCC, Category Name
IV.)
Example: LARGER THAN 100 MBTU PULV
DRY
140* Feed Material Class
150* Source Name
200* Site Name
210* UTM-X
220* UTM-Y
Specific type of material used as fuel
feed. (See Appendix B, SCC, Category
Name III.)
Example: BITUMINOUS COAL
Specific source tested within the site
designated in 200,
Example: MERAMEC UNIT 1
Complete and unique name of company
(and, if applicable, plant or station).
Example: UNION ELECTRIC MERAMEC STATION
UTM horizontal coordinate as shown on USGS
maps with scales less than 1:62,500.
Example: 0473
UTM vertical coordinate as shown on USGS
maps with scales less than 1:62,500.
Example: 3921
72
-------�
230* Zone Location
240* Address
250* City
260* State
270* Zip Code
300* Test Series
310* Test Series Number
320* Test Series Reference
330* Name of Testing Group
Universal Transverse Mercator Coordinates
(UTM) zone location as found on United
States Geological Survey (USGS) maps show-
ing UTM coordinates (see Figure A-l).
Example: 12
Street number and street name. (Abbreviate
if- necessary, see Table A-l.)
Example: 1234 RIVER ROAD
City name. (Abbreviate if necessary, see
Table A-l.).
Example: ST. LOUIS
Two letter code for state. (See Table A-2.)
Example: MO
Five digit number designating postal area.
Example: 63102
A repeating group within the principal
repeating group (110). This group defines
a test series and includes statements 310
through 350, statement 1800, and lower
level repeating groups 400 and 700. Data
are not entered in this category but this
category is used as an introduction to sub-
categories.
Numerical identifier for specific test
series for the data to follow. Each test
series will be assigned an identifier from
a master file listing as received.
Example: 14
Reference of the report from which the
data have been extracted.
Example: EPA 650/2-74-031, April 1974
Complete and uniquely identifiable name
of testing group.
Example: MIDWEST RESEARCH INSTITUTE
(not MRI)
73
-------�
120ฐ
114' 108ฐ
78'
Figure A-l. UTM grid zones in the contiguous United States.
-------�
Table A-l. ABBREVIATIONS FOR STREET DESIGNATORS AND FOR WORDS THAT APPEAR FREQUENTLY IN PLACE NAMES
Herd
Acidemy.,
Abbreviation Word
.. AT.AO
MPNT
AJY
AKX
ป/sr.al ................ ...,... ...... AASl
ซ*cr.ut ............... ; ................ WE
3ปyou ................... . ............. 6YU
back....'. ........................... BCH
9<J ............................... . RIO
B.| .................................. BG
B'Kk ................................. BIK
Soultvfrt ............................. BIVO
E:ปf! ........................... ' ....... BLf
3o:iom ................................ erv
5-jnck ................................ HS
Intlt ................................ 8RG
frock ................................ HRK
Bvif .................................. BG
Bypass..... ........................... BYP
Camp ................................. CP
Caซron ....................... . ........ CYN
Cue .............. ................... CPE
Caiircty.., .......................... CWSY
Cr.:t" ............................. CTX
r."< - ............................... CIL
r>i-;ซ .................. ............. CHR
Chants .............................. CHRS
fjii.it .............................. CiR
C.iป ................................ CY
Cie* ................................. CIR
Ci.H ................................ CKS
C'vS .................................. US
Ciiifje ............................... ClG
Co-r-tr ................................ COR
C'ปซrs ............................... CORS
Ctt1 ................................ Cl
CIS
CV
;.: ............... CRU
CRFJ
W.
PM
0=0
OIV
OR
(ปl .................................. f
1ปU1M ............................... 1ST
Onปe
Emended .............................. EXI
E (tension ............................. EXI
fall ................................... H
Falls .................................. US
Fjims ........................ (RMS
leir, .................................. FRY
Held ................................. FtO
F,t!0s ...... .- .......................... FIDS
Fills .................................. Ill
Ford ............................. FRO
tixesl ................................. FRSI
foige ................................. (RG
loik .................................. FRR
loiks ................................. FRXS
Fuil .......... ......................... Fl
Fountain: ............................. Flfl
AMirevitlion Wort
EXPY
FURN
CDNS
Galreay .............................. GIWY
Glen .................................. GIN
Grand ................................. GRID
CffJl ................................. GR
Girun ................................ GKt
Cfouml ................................ GRO
Gi(iปt ................................ GRV
Ha-fof ................................ HRfl
Mlven ................................. HVN
Hr<(hU ............................... HIS
Hi|(h ...................... HI
HijhUndS ................ . ............ MCIDS
Hi||fcปir .............................. HWY
Hill ................................... Ill
Hills .................................. HIS
Hollow ................................ IIOIW
Huspttil ............................... I10SP
Hoi ................................... H
House ................................ USE
Inlel .................................. INI!
InitiluK .............................. MSI
IS
.................. IS
Isle .................................. IS
Junction ............................... IC1
Knolls
Undm|
Ukes
KNIS
INDG
IK
IKS
AMmiซtiai Weri
Lne UJ
lii;M ICT
in lie ITl
loil Lf
locks ICKS
loige IDG
IOซB . IWS
M.nor Um
M.aoows MOWS
Mrelmg MIG
Mtmoiial MEM
Middle MOl
Mile : MIE
Mill Ml
Mills MIS
Mines MNS
Mission MSN
Miimd MNO
Miunt MI
Mmntjin MIR
Nihorul NAT
Heck NCK
C.cnird ORCH
Pซlmซ PIUS
Pali PK
Pakปปi.... ; PKY
Piilai PlR
Pniei Pปt$
Phce PI
PI m Wซ
Pl.unt PINS
Pl.iซ PI/
Puil PK1
Pomt PI
Piaiin PR
Bawd RNCH
RJKHO RNCHS
Rljid! RPOS
Resort RESHI
Rest RSt
Ri'lge ROC
Ri u RIV
R:K! RO
Hc:k RK
Rral It
Sปnl S!
SJ.nle SI
SM
Swta
Sfi
. .............. SB
S*
Sthoo) ................................ SCM
Stminry .............................. SMfUTT
Sho*l ................................. SHI
SHU
SHO
SHR
SHRS
Siding ................................. SOG
South ................................. S
Swce Fligtl Ctnltt .................. MC
Spring ................................ SF-6
Spiings ............................... STOS
Soiure ................................ SO
Stale .................................. SI
SUIion ............ , ................... S!A
Strett .......................... ....... 51
Stream ................................ StW
Soiphuf ............................... ana
Summit ............................... SMI
Switch ................................ SWCN
Tannery ................... . ........... (IRK
Itnici
Ton
Tooer
loซn
Trail
H8
IN
TWK
Tซfl
IRl
tRlป
IUปl
Tunnel
TurnpiKt
Upper ............ . .................... UP9
Union ................................. UN
Unuwsity ............................. UซIV
Valley ................................. ซT
Vuduct ............................... VIA
Vieป .................................. Wป
Village ................................ VIG
Villt .................................. VI
Visit .................................. VIS
Water ................................. WTR
Wells ................................. WU
West .................................. W
White ................................. WHT
Works ................................. Wซ
tudj ................................ 1W
-------�
Table A-2. TWO-LETTER STATE ABBREVIATIONS
wwu
(UirtM
a
ซ
GA
HซJJJI
GU
HI
Main
Illinois
tltdijM....
low
Kansas....
Kentucky..
luuisijtu..
Maine
Mat/land..
CA
U
CO
CI
Dฃ
DC
fl Michman...
Minnesota..
Mississippi.,
Missouri....
in
n
IN
IA
KS
KT
IA
M[
MO
MA
Ml
MN
MS
MO
Mofltin*
Nuilh Carolini
Noilh OakoU
Oino
OklatKinu
PlKtlO RlCO
EJT
Nt
NV
NH
NJ
NM
BT
NC
Soปm Cwdira.
Sotrtti Oaijti...
Itnnessn
Utad
Veimwt
Viijini!
HO Virgin Isltntfs..
OH Wnhmgton....
OK West Vngmu.
OS Wiicofljin
PA Wyomini
PR
so
in
ii
in
Vf
V*
n
HA
KV
Ml
HT
-------�
340* Series Start Date
350* Series Finish Date
400* Control Devices
410* Generic Device Type
420* Device Class
430* Device Category
440* Device Commercial Name
450* Manufacturer
Start date for the series in the format
month/day/year.
Example: 05/12/75
Finish date for the test series in the
format month/day/year.
Example: 05/23/75
A repeating group within the repeating
group 300. This group defines the control
device or devices and includes statements
410 through 460 and lower level repeating
groups 500 and 600. Data are not entered
in this, category but this category is used
as -an introduction, to subcategories.
General classification .of control device
in operation during test. The generic de-
vice types will only be from the following
standard nomenclature: ESPi Cyclone, Wet
Scrubber, Fabric Filter, Other, None.
A designation of the state of development
of the control device using only the fol-
lowing standard nomenclature: Conventional,
Novel, Prototype, Pilot Scale (see text
for discussion of these designations).
A more specific definition of the generic
device as noted in 410. Standard nomen-
clature will be used from Table A-3. For
the appropriate generic device, only name
as indicated or combination of words as
indicated in Table A-3, will be used.
Example: GAS ATOMIZED SPRAY SCRUBBER
Commercial or given name of the device.
Example: STEAM-HYDRO SCRUBBER
Complete' name of manufacturer.
Example:. RESEARCH COTTRELL
77
-------�
Table A-3. DEVICE CATEGORY
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
ESP
Wet
Dry
Hotside
Coldside
Plate
Pipe
Hi voltage
Low voltage
Single chamber
Double chamber
Other
Cyclone
1. Single 1.
2. Multiple 2.
3. Recirculating 3.
4. Mech. rotor 4.
5.
6.
7.
8.
9.
10.
11.
Wet scrubber
Plate
Massive packing
Fibrous packing
Preformed spray
Gas atomized spray
Centrifugal
Baffle
Impingement and entrainment
Mechanically aided
Moving bed
Combination
1.
2.
3.
4.
5.
6.
7.
Fabric filter
Continuously cleaned
Intermittently cleaned
Reverse air
Mechanical shake
or vibrate
Hi pressure air
Low pressure air
Other
oo
-------�
460* Device Description
500* Design Specifications
510* Specification Type
520* Specification Value
600* Operating Parameters
Typical
One line qualifier to allow insertion of
additional information for unusual or hy-
brid devices not completely described in
410, 420, 430.
Example: ATOMIZED SPRAY IS SUBJECTED TO
ELECTRICAL FIELD FOR CHARGING OF DROPLETS
A repeating group within the repeating
group 400. This group defines the design
specifications for the; control device and
includes statements 510 and 520. Data are
not entered in this category but this cate-
gory is used as an introduction to subcate-
gories.
Descriptive word for specification, as
appropriate for generic device type (410).
Table A-4 is a tabulation of specifications
which should be entered as a minimum. Addi-
tional specification types required for
more complete characterization of the de-
vice may be included.
Example: DESIGN VOLUME
The numerical value corresponding to the
specification type (510) entered only as
metric units indicated in Table A-4 or as
required for additional types.
Example: 20,000 DNM3/min
A repeating group within the repeating
group 400. This group defines the typi-
cal or average value of the operating
parameters of the device(s) tested. This
group includes statements 610 and 620.
Data are not entered in this category but
the category is used as an introduction
to subcategories.
Note: If there is only one test run in
the test series then data for parameter
type and value should be entered as ap-
propriate in statements 610 and 620. For
test series which include more than one
test run and for which the operating pa-
rameters varied then the values of these
parameters for the second and subsequent
runs should be identified and entered as
text in statement 1700 (subseries remarks).
79
-------�
Table A-4. SPECIFICATION TYPE
oo
o
ESP Units
Design volume DNM /min
Design AP cm WG
Design temperature ฐC
Cyclone
Design volume
Design AP
Design temperature
Units
DNl^/min
cm WG
ฐC
Design efficiency
Design inlet grain
loading
Total power consumption
Bulk linear velocity
Number of sections
Design applied voltage
Aspect ratio
mg/m
kw
m/s
number
volts
dimensionless
Design efficiency
Design inlet grain
loading
Total power consumption
Entrance velocity
Number of tubes
Cyclone diameter
Length/diameter ratio
mg/m
kw
m/s
number
m
dimensionless
-------�
Table A-40 (Concluded)
oo
Scrubber
Design volume
Design AP
Design temperature
Design efficiency
Design inlet grain loading
Total power consumption
Inlet gas velocity
Demister type
Design liquid loading
Units
DNM3/min
cm WG
ฐC
7ป
mg/m3
kw
m/s
text
A/1,000 m3
Fabric filter
Design volume
Design AP
Design temperature
Design efficiency
Design inlet grain loading
Total power consumption
Design air/cloth ratio
Number of compartments
Bag composition
Units
3
DNM /min
cm WG
ฐC
7o
o
mg/m
kw
m-Vm^ min
number
text
Entrainment separator type
text
Bag length
m
-------�
610* Parameter Type
Typical
620* Parameter Value
Typical
700* Test Characteristics
710* Subseries Number
720* Subseries Test Date
730* Subseries Start Time
740* Subseries Stop Time
750* Sampling Location
Descriptive word for parameter as appro-
priate for generic device type (410).
Table A-5 is a tabulation of parameters
which should be entered as a minimum. Ad-
ditional parameter types may be included
as required for more complete description
of device operational characteristics.
Note that some of the operating parameters
and values are included later as data from
the test run.
Example: RAPPING FREQUENCY
The numerical value corresponding to the
parameter type (610) entered only as metric
units indicated in Table A-6 or as required
for additional types.
Example: TWICE PER MINUTE
A repeating group within the repeating
group 300. This group defines the charac-
teristics of each subseries and includes
statements 710 through 930; statement 1700;
lower level repeating group 1000. Data
are not entered in this category but this
category is used as an introduction to
subcategories.
Unique number assigned to the group of
run numbers comprising this subseries.
Example: 14
Date of test in format month/day/year.
Example: 05/15/75
Start time of subseries based on 24 hr
local standard time.
Example: 1230 (Note: no colons)
Stop time of subseries based on 24 hr local
standard time.
Example: 1610 (Note: no colons)
Location of sampling train for this run
relative to the control device, either
inlet or outlet.
Example: DEVICE INLET
82
-------�
Table A-5. DEVICE OPERATING PARAMETER TYPE
ESP
Operating AP
Power consumption
Bulk linear velocity
Applied voltage
Gas pretreatment
Rapping frequency
Spark rate
Current density
Liquid used
oo Liquid loading
Scrubber
Operating AP
Measured efficiency
Total power consumption
Gas pretreatment
Recycle ratio
Liquor recycle characteristics
Effluent liquid treatment
requirement
Scrubbing liquor type
Liquor loading
Units
cm WG
kw
m/s
volts
text
number/min
number/min
nanoamps/cm
text
Z/min
Units
cm WG
%
kw
text
number
text
text
name
Cyclone
Operating AP
Measured efficiency
Gas pretreatment
Fabric filter
Operating AP
Measured efficiency
Total power consumption
Bag composition
Gas pretreatment
Cleaning frequency
Air/cloth ratio
Cloth construction
Cloth weight
Cloth thickness
text
Units
cm WG
7,
kw
text
text
number/min
m /ra^ min
text
. 2
gra/m
cm
-------�
Table A-6. LIST OF 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 lonization 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
84
-------�
760* Sampling Location
Description
A brief description of the sample train
location relative to significant flow dis-
turbances .
Example: TEN DUCT DIAMETERS DOWNSTREAM
FROM 90 DEGREE BEND
770* Source Operating Mode
780* Source Operating Rate
790* Source Feed Material
800* Feed Material Composition
810* Volumetric Flow Rate
820* Gas Velocity at Sampling
Location
Brief description of source operation at
time of run. Most sources will be steady-
state, but for sources with cyclic opera-
tions or specific disturbances, this in-
formation is required. In the case of an
arc furnace such description may include
"oxygen-lancing," "charging," "pouring,"
etc.
Example: OXYGEN-LANGING
Operating rate of source per unit time
in with dimensions of metric ton/hr, mw,
etc.
Example: 10 MT/hr
Specific type of fuel or feed material
used during run.
Example: PULVERIZED BITUMINOUS COAL
Percentage data of feed material for ap-
propriate constituents.
Example: 4.1% S, 10.27= ash
Stack gas flow rate (from EPA Method 1)
in units of DNM^/min.
Example: 1,200
Velocity of gas stream at the sampling
location for this run in units of meters
per second.
Example: 20.4
830* Gas Temperature at Sampling Temperature of gas stream at the sampling
Location location for this run in ฐC.
Example: 61.4
840* Pressure at Sampling
Location
Stack pressure at the sampling location
for this run in cm water gauge.
Example: 11.5
85
-------�
850* Moisture Content
860* Percent Isokinetic
Sampling
870* Gas Composition
880* Trace Gases in PPM
890* Mass Train-Total Mass
Concentration-Mantissa
900* Mass Train-Total Mass
Concent rat ion-Exponent
910* Mass Train-Front Half
Mass Concentration-Mantissa
920* Mass Train-Front Half
Mass Concentration-Exponent
930* Mass Train Comments
Percent moisture by volume (from EPA
Method 4).
Example: 17.4
100 Times the ratio of the average veloc-
ity of the gas entering the sampling noz-
zle to velocity of the flue gas streams
at the sampling point.
Example: 98.7
Percent of 0)3, 02, CO, and N2 by volume
dry (from EPA Method 3).
7ป C02 + 7ป 02 + % CO + 7o N2 = 100%
Example: C02 - 12, 02 - 6, CO - 0.5,
N2 - 81.5
Chemical symbol and measured concentra-
tions for trace gases measured during test
run in parts per million (ppm).
Example: S02 - 300, N02 - 50, Cl - 200
The mantissa for the value of measured
particulate concentration (EPA Method 5)
in units of ug/DNM3.
Example: 4.25
The exponent for the value in 890, includ-
ing positive or negative sign.
Example: + 03
The mantissa for the value of measured
particulate concentration for the front
half of the EPA Method 5 train (particu-
late filter and probe wash) in units of
ug/DNM3.
Example: 1.24
The exponent for the value in 910; includ-
ing positive or negative sign.
Example: +02
Any comments or data not elsewhere reported
which are specifically related to the mass
train data in 890 through 920.
Example: Mass concentration unusually low
due to unexplained train leakage between
filter and meter.
86
-------�
1000* Run Group
1010* Run Number
1020* Density
1030* Density Determination
1040* Resistivity - Mantissa
1050* Resistivity - Exponent
1060* Resistivity
Determination
1070* Physical Properties -
Comments
A repeating group within the repeating
group 700. This group defines the data
and information for each run, and includes
statements 1010 through 1070; 1300 through
1520; statement 1600; and lower level re-
peating groups 1100, 1200 and 1550. Data
are not entered in this category but this
category is used as an introduction to
subcategories.
Unique number assigned to each run within
the test series.
Example: 02
The particle density, in units of grams
per cubic centimeter.
Example: 5.22
An indication of whether the density value
in 930 was determined experimentally or
assumed.
Example: MEASURED
The physical-chemical property of the re-
sistance of the particle based on particle
volume with unit-cross-sectional area and
unit length, in units of ohm-centimeter.
Mantissa for the value.
Example: 5.25
The exponent for the value in 1040, includ-
ing positive or negative sign.
Example: - 11
An indication of whether the resistivity
value in 950 and 960 was determined ex-
perimentally or assumed.
Example: MEASURED
Additional text comments regarding elements
1020 through 1060, or data for other physi-
cal properties such as solubility measure-
ments.
Example: Solubility of particulate in
water is 0.4 g/ml
87
-------�
1100* Bioassay Analysis
1110* Bioassay Test Type
A repeating group within the repeating
group 1000. This group defines the type
of bioassay testing, if done, using the
collected particulate, and includes state-
ments 1110 and 1120. Data are not entered
in this category but this category is used
as an introduction to subcategories.
Indication of biological testing, if done,
with the collected particulate. Entries
will be only from the following:
Cytotoxicity - animal
Cytotoxicity - human
Mutagenicity - (Bacterial strain(s))
Inhalation
Skin painting
Neonatal - mouse
1120* Bioassay Test Remarks
Results of the indicated tests in 1010.
Example: SKIN PAINTING INDICATED NO CHANGE
DUE TO PARTICULATE USED
1200* Chemical Analysis
1210* SAROAD Chemical ID
1200* Analysis Method
1230* Filter/Total
Concentration
A repeating group within the repeating
group 1000. This group includes any chemi-
cal analyses that were performed on the
sample. The group includes statements 1210
through 1280. Data are not entered in this
category but the category is used as an
introduction to subcategories.
The identification number from the SAROAD
System of the specific chemical(s) for which
analysis was performed. (See Appendix C.)
Example: 2322 (for ammonium sulfate)
The identification letter of the specific
analysis method used. (See Table A-6.)
Example: B (for chemiluminescence)
The total concentration of the chemical
listed in 1210 as measured by the filter
or the sum of the discrete size distribu-
tions in 1240 through 1280 in units of
ug/DNM3.
Example: 0047.3156
88
-------�
1240* Concentration Above 10
1250* Concentration 10-1
1260* Concentration 1-0.1
1270* Concentration 0.1-0.01
1280* Concentration Below 0.01
1300* Measurement Equipment
Type
1310* Size Range Lower Limit
1320* Size Range Upper Limit
1330* Substrate
1340* Sampling Start Time
Concentration of the chemical in 1210 with
particle diameter greater than 10 um, in
units of ug/DNM3.
Example: 0.711
Concentration of the chemical in 1210 with
particle diameters in the range from 10
Urn to 1 urn in units of ug/DNM3.
Example: 17.50
Concentration of the chemical in 1210 with
particle diameters in the range from 1 um
to 0.1 Jim in units of ug/DNM3.
Example: 2.37
Concentration of the chemical in 1210 with
particle diameters in the range from 0.1
um to 0.01 um in units of Ug/DNM3.
Example: 4.93
Concentration of the chemical in 1210 with
particle diameter less than 0.01 um, in
units of ug/DNM3.
Example: 0.57
Particle size measuring equipment (includ-
ing model type, if applicable). Only stan-
dard nomenclature will be used from Table
A-7.
Example: ANDERSEN MARK III IMPACTOR
Lower limit of the size range for the equip-
ment/method specified in 1300 in units of
micrometers (um).
Example: 0.40
Upper limit of the size range for the equip-
ment specified in 1300 in units of micro-
meters (um).
Example: 10.00
The substrate acting as the collection medium.
Example: GLASS FIBER FILTER
Start time of run based on 24 hr local stan-
dard time.
Example: 1345 (Note: no colons)
89
-------�
TABLE A-70 STANDARD NOMENCLATURE FOR MEASUREMENT EQUIPMENT
Generic Class Type
BRINKS BMS-11 IMPACTOR
Irapactor
Optical
particle
counter
ANDERSEN MODEL II
IMPACTOR
ANDERSEN MODEL in
IMPACTOR
ANDERSEN MODEL IV
IMPACTOR
UW MARK III IMPACTOR
TAG IMPACTOR
OTHER IMPACTOR
ROYGO MODEL - OPC
CLIMET MODEL - OPC
BAUSCH & LOME MODEL
40-1 - OPC
OTHER - OPC
.Description
Conventional Brinks sampler with
a precyclone having a 7 Mm cut size
Andersen stack sampler with stain-
less steel collection plates
Modified Andersen sampler with
glass fiber filter collection
surface
Modified Andersen sampler "with
glass fiber filter collection
surfaces and a cyclone pre-
collector
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
As necessary
90
-------�
TABLE A-7. (Concluded)
Generic Class
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
of David Sinclair design with
collimated hole structure
WIRE SCREEN DIFF
BATTERY
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
91
-------�
1350* Sampling Duration
1360* Sampling. Flow Rate
1400* Dilution Factor
1410" Sampling Train Temperature
1420* Pressure at Sample Train
Location
1430* Percent Moisture
1500* Particle Diameter Basis
1510* Concentration Basis
1520* Upper Diameter.Boundary
The length of time for the measurement
in minutes.
Example: 45
-3
Sampling flow.rate for'this run in, mi :/miri.
or liters/rain.
Example: 4.5 liters/min
Dilution factor used for sampling methods
which require dilution (ive., diffusion
battery).
Example: 1.0 (no dilution)
65
Temperature maintained- at the sampling
train for the duration of the run in ฐq.
Example: 42.2
The absolute pressure of the gas at the
inlet to the sample train in units of mm
Hg.
Example: 750
The percent, water vapor by volume in, the
gas sampled by the instrument.
Example: 72.5
Indication of the type of diameter specific
for this measurement - Aerodynamic or Stokes.
Example: AERODYNAMIC
Indication of the type of measurement/
calculations used in obtaining concentra-
tion for this.measurement, -. mass or number.
Example: MASS
The upper diameter boundary point in units
of micrometers ( m) for the specific basis
in 1500.
Example: 20.00
92
-------�
1550* Particle Size
Distribution Data
1560* Diameter Boundary
1570* Concentration Value
Mantissa
1580* Concentration Value
Exponent
1600* Test Run Remarks
1700* Subseries Remarks
1800* Test Series Remarks
A repeating group within the repeating
group 1000. This group defines the parti-
cle size distribution and includes state-
ments 1560, 1570 and 1580. Data are not
entered in this category but this category
is used as an introduction to subcategories.
The class interval boundary point (particle
diameter) for the specific basis in 1400.
Units are micrometers (urn).
Example: 13.770
The mantissa of the concentration value
for the measurement with the basis as noted
in 1410 in units of ug/DNM3.
Example: 2.98
The exponent for the concentration value
in 1570 including positive or negative sign.
Example: + 06
Any comments or data not elsewhere reported,
which are specifically related to the run
number designated in statement 1010.
Any comments or data not elsewhere reported,
which are specifically related to the sub-
series designated in statement 310. In addi-
tion, operating parameter types and values
(see 610, 620) for the second and subsequent
test runs in the subseries designated in 310
will be entered here.
Any comments or data not elsewhere reported,
which are specifically related to the test
series designated in statement 310.
To be included in these remarks, specifically
are such physical, and/or chemical properties
which may have been measured as corrosiveness
or solubility which are not included in 1070.
Statements 1(>00, 1700 and 1800 may also be
used to indicate a subjective judgment of
the value of the data, measurement technique,
etc., which may have a bearing on the general
usefulness of a given test run, subseries or
test series and the reliability of the data.
93
-------�
APPENDIX B
SOURCE CLASSIFICATION CODES
95
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
EXTCOMB
ExTCOHB
EXTC')MB
EXTCOHB
EXTCOMB
EXTCOMB
EXTCOMB
ExTCOMB
EXTCOMB
EXTCOMB
tXTCOMb
ExTCOMB
EXTCOMb
EXTCOMB
EXTCOMB
EXTCOMB
EHTCOM8
EXTCOMB
IXTCOMb
ExTCOHB
fXTCOMti
EXTCOMB
EXTC1M6
EXTt'JMB
EXTC'JMB
EXTCOMB
FXTCOMB
EXTCOHh
tXTCOMB
KXTCOMb
F. XTCOMb
EXTCOMB
FXTCGMb
EXTC'JMB
EXTC'JMB
HOtLEB
HOILEB
BOILED
BOlLtft
BOILEH
HOILEB
BOILER
BOILEH
BOlLEB
BOILEH
rtOlLEH
BOILEH
90ILEH
BOILEH
HOILEH
10lLEป
BOILEH
HOILEH
BOILEH
HOILEP
B01LE-)
BOILED
dOILEW
BOILEH
BOILEB
bOlLEH
bOILEX
BOlLF.w
HOILER
dOILE-i
BOILl'H
HOIl.tH
HOILIH
t'XTCDMb hOlLEa
EXTC'IMb
EXTCOMB
ExTCOMfi
tXTCUMB aOlLtH
EXTCOMB 10ILEB
EXTCOMB bOILE"
E * TCOMB lOILLH
EXTC'IMh MOlLEB
F. ซTCOMfc
FXTCf.Mb
IELECTHIC
IELECTHIC
IELECIปIC
ItLECTPIC
IELECTHIC
IEUECTHIC
IELECTHIC
IELECTH1C
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECI-IIC
IELECTHIC
IELEC1HIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELFCTHIC
IELECTHIC
IELECTHIC
IELECTHIC
lELECTuIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECTHIC
IELECT-IC
IELCCT-IC
ItLEC'-IC
IELECTV. 1C
lELECTrK
IELECTHIC
lELECTxIC
IELECI-IC
IELECT-IC
lELECTwIC
IELECTHIC
IELFCT-IC
IELECIHIC
ItLECTHlC
SCC C4TEGOHY N4.ซES
II III
GENEH4TNI4NTHK4CIFE COAL
GENE*t'lE-A IN
GENE^iTN
GENExATN
I.ENERATN
Gt'NEป4TN
FtNEKATN
GENE-4TN
GKNEH4 TN
"FSITUOL OIL
KFSI')U4L OIL
HISIlLLATE OIL
PISTILLATE OIL
DISTILLATE OIL
NAT'J-AL GAS
NATURAL i;4S
PROCESS GAS
JROCt SS f,AS
i-HOCc SS ^.4S
COKt
n4GA^SE
IV UNITS
IMOOMMbTU PULVlZOITONS BUMMED
IMOOMMHTU STOrEHSITONS BUxNED
ll(l-100MMBtu PuLVOITONS HUxNED
I10-100MMBTU STOKBITOMS bUxNED
KIOMM8TU PULVI/EOITONS BUxNEO
K10MMKTU STOKEH I TONS BUHNED
IOTHEH/:gOT CLAS1FOITONS BUH'JEn
I>100MMHTU PULVvET I TONS bUm*ED
I>100MMHTU PULVtlnVITONS BUHNED
IMOOMMHTU CYCLONEITONS BUHNEO
IMOOMMHTU iPOSTKBITONS
I >IOOMHMTU/HH UFSKITONS
110-lOOMMdTU PUL"T|TONS BUuNED
I10-100MM8TU PuLOYITONS BUHNtO
I10-100MMBTU OFSTKITONS BUxNED
I10-100MMBTU UFSTKITONS BUHNEO
KlOMMbTU OFSTuKtRl TONS tiUHNED
K10MMHTU UFSTOKEBI TONS BUfNEO
|<10MMbTU PULV-DHYI TONS HUHNED
IOTHEH/NOT CLASIFDITONS BUHซ:EO
IMOOMH"TU PULVnETI TONS bUHNED
I>100HMHTU PULVOHYITONS BUUNEO
IMOOMMHTU CTCLONEITON3 BUH'vEO
I>100MM^TU OF btซB|TONS bUxNED
I>100MMHTU OF STuHlTONS BUxNED
IMOOMM-1U SPDSTuBlTONS BUHNED
llo-loOMHHTu DYHULITONS BUX-.ED
I10-100UH^TU talPuLITONS bUx>^EO
I 10-100XMHTU OKSTKI TONS BUHNEO
I 10-100HM6TJ U>STKI TONS-bU"ซ.ED
I lO-lOOxxBTUST.STK I TONS BUxNEU
<10MMBTU PULV DxriTONS BUHNED
<10MMbTU OF STOKHlTONi BUxMtO
<10MMBTU UF STO100MMUTU/hH GENLI1000GALLONS BUHNEO
10-100MM8TU/HNGNL I 1 OOOC-ALLONS BURNEO
<10"MBTu/ix GtNL I lOOO^-ALLllNS BUHNED
MUOปMHTu/MH GENL I 10000ALLONS bUHNEO
10-lOOvxBTU/HMGNL F lOOOr-ALLONS HU"NEO
<10MK6TU/Hซ GtNL I 1 OOOC'ALLONS HUHNED
MOOMMซTU/"H MILLION CUBIC FEET BUBNtO
10-100VMHTU/H>. MILLION CUBIC FEET bUHNEO
100MMMTU/"H MILLION CUBIC FEET BUHNEO
in-lOU-MBTU/H- MILLION CUBIC FEET BUHNtO
ซioHM^Tu/-'H MILLION CUHIC FEET
>100MM-TU/-H ITONS dUซNED
I 1 0-1 OOx^dTu/*"-- ITONS BUHNEO
I < 1 0"MBTU/^H ITONS r*UxNฃ0
96
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGOxr NAMES
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCUMB
FXTCOMB
EXTCOHB
EXTCOM9
EKTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EซTCOMB
EXTCOMB
EปTCOM8
EXTCUMb
EXTCOMB
fXTCOMB
EX I COMB
EปTCOMH
tXTCOMB
EKICOMB
txTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMb
EXTCOMB
EXTCOMb
EXTCOMB
f XTCOMB
EXTCOMB
tXICOMB
t nTCUMb
t
HOUE"
HOIl.E-i
t1OOMMRTU/HW ITONS BUxNEO
HATNISOLID WASTE/COAL I 10-1OOMMBTU/Mx ITONS BUXKEO
XATNISOLIO "ASTE/COAL I1OOXKflTU/MX HULVITONS BUkNEO
IANTHOACITE COAL I >IOOMM?TU/IR STKRITONS BUXNEO
COAL I10-100MMBTU MULVOITONS BUHNEO
COAL I10-100MM8TU STuH ITONS BUXNEO
COAL KIOMMHTU/MM PULVDlTONS BUHSED
COAL KlUMMbTU/ซR STKX ITONS BU^ED
COAL !<10MMdTU/MW hNOFRI IONS dUR^EO
IOTHEX/MOT CLAS1FOITONS BUx^EO
I>100MMHIU PULVWET | TONS BUXcMEO
I>IOOMMHTU ปULVU>100MMr.TU PULi'XETlTONS BUxMEO
IMOOMMHTU "ULVDHY I TONS 9UMI.ED
I>100MHซTU CYCLONEITONS BUMPED
I>IOOMMMTU OFSTRH ITONS BUxNED
IMOOMMI.TU UFSTKR ITONS BUXNEO
OlOOMMriTU SPOSTKHITONS BUxNEO
I10-100MMBTU DrPULITONS BUHnEO
Ilu-)OOxMRTU "TWULITONS BUXNEO
I 1 0-1 OOMMRT'J OfSTMTONS HUl-NED
IIO-lOOMMnTU U'STniIONS BU-rwED
I 10-IOOuMHTUSPuSTKITONb DURNEO
KIOMMMTU PULV ORYITON'i hUxNEO
KlOMMhTU OfSTO<" ITONS tiUx'vtO
KlOMMbTU UFSTUKX I TONi HU^tD
K10MMBTU FANOFIME I TONS BUXr-EO
I<10MM8TU SPDSTKU |IONS BURNED
I ANTHRACITE
IANTHRACITE
I ANTHRACITE
I>NTh-ACITE
I ANTHRACITE COAL
IBITu-INOUS COAL
IBITU-INOUS CUAL
IHITUM
IdITU"
IRITu- NOJS COAL
IHITU"
liITUx
IPITU"
IMMUM NOUS CUAL
IRITux
IMITU'
IHITu>
NOUS COAL
NOUS COAL
IrtITU-INOUS COAL
181TUMINCUS COAL
HITU-INOIIS CDAL
II. IGMTf
ll IGNPE
ILIGNITE
ILIGMTE
ILIGNITE
ILIGNITE
ILIGNITE
ILIGNITE
ii. ir.NME
IL IHM TF
ILIGNITE
II !GN|Tt
II IGNITF.
II. IGMTF
ILIGMTE
ILKiNITE
IRLSIOUAL OIL
I "ESI'JUAL OIL
iRfSinuปL OIL
lOISTILLATf OIL
IDISTILLAtE OIL
I MOO
I lll-l
I <10MMHTU/'1R
I > 100Mป
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NA-ES
EXTCOMfJ
EXTCOMB
EXtCOMB
EซTCOMB
EXTCOMB
ExTCOMb
EXTC'JMB
FxTCriMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCOMB
EXTCliMB
EXTCOMB
fXTCOMB
EXTCOMB
EปTCOMB
EXTCOMB
EXTCOM&
EXTCOMfl
EXTCOMB
EXTCOMB
EXTCONB
EXTCDM8
EXTCOMB
EXTCOMB
EXTC'JMB
EXTCOMB
I
BOILER
BOILER
BOILER
BOILER
BOILER
BOILER
MOILER
BOILEH
BOILER
BOILER
TOILER
BOILER
BOILER
BOILER
HOILER
BUILEN
BOILED
BUILER
BOILER
BOILER
HOILER
BOILER
BOILER
BOILER
80ILEH
BOILER
BOILER
BOILEA
BOILIR
F.ITCOMB HOILER
EXTCOMB BOILER
EXTCOM8 BOILER
FXTCOMB nOlLER
riTCOMB BOILER
F < FC'IMB BOH tR
EXTC'IMB nOIutR
f xTcriMB
tXTCOMB
t < rc>>MR
EXTC'IMB
EXTO'iซB MUlLlR
EXTC'JMB oOlLER
EXTCOMB BOILER
EXTCOMB
II
iINDUSTRIAL
lINDUSTRIAL
lINDUSTRIAL
III
l INDUSTRIAL
IINOUSTHUL
l INDUSTRIAL
l INDUSTMUL
l INDUSTRIAL
I INDUSTRIAL
(INDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
l INDUSTRIAL
I INOUSTHIAL
i INDUSTRIAL
I INDUSTRIAL
IINOUSTXIAL
ICOMME^CL-INSTUTNLI ANTM-ACITE COAL
ICOMMEwCL-INSTUTNLUNTHOaCITE COAL
ICOMMERCL-INSTUTNLUNTHUACITE COAL
ICOMMERCL-INSTUTNLUNTHU4CITE COAL
ICOMMEHCL-INSTUTNLUNTMi-ACITE C'JAL
ICOMME*CL-INSTUTNL IANTHJACITE OML
I COMMERCL- I NSTUTNL I ANTHRACITE t')AL
ICOMMERCL- I NSTUTNL I ฐITUMINOUS C'ML
ICOMMt'KCL-INSTUTNLIHITU"INOUS COAL
ICOMMERCL-1NSTUTNLIMITU-INOUS COAL
ICOMMEKCL-INSTUTNL IBITU"INOJS COAL
ICOMMEXCL-INSTUTNL IHITUซINOUS COAL
ICOMME-ICL-INSTUTNL I HI Tu" INDUS COAL
ICOMMExCL-INSTUTNLI^ITU-INOUS COAL
ICOMMtRCL-INSTUTNL I MITU"INOUS COAL
ICOMMEHCL-INSTUTNL I HI Tux I NOUS COAL
ICOMMEWCL-INSTUTNLI"ITUMINOJS COAL
ICOMMEHCL-l'-'STUTNLIHITu-INOUS COAL
ICOMMtปCL-|NSTUT.\L 1L I6MI TE
ICUMME-CL-INSTHTNL II IGNI TE
ICOMMtVCL-INSlUTNLILIGM TE
IV
UNITS
IOISTILL4TE OIL
(NATURAL r,AS
INATu^AL GAS
1 NATURAL 'JAS
(PROCESS liAS
(PROCESS GAS
(PROCESS GAS
<10MMBTU/Hb
>100MMtiTU/KR
10-100MMBTU/HR
<10MMBTU/ซ'<
>100MMMTU/HM
10-100MM8TU/MH
<10MM8TU/HH
ICOKf | 10-100MMBTU/MK
(COKE KlOMHdTU/HR
1 1000 GALLONS
(MILLION CUBIC
(MILLION CUBIC
(MILLION CUBIC
(MILLION CUBIC
(MILLION CUBIC
(MILLION CUBIC
(TONS BURNED
(TONS BURIED
BURNED
FEET BURNED
FEET HUHNCO
FEET UURNEO
FtET BURNED
FEET BUBNEO
FEET BURNED
1*000 (MOOD WASTE 60ILERITONS BURNED
(MOOD (SHALL HANOFIHE
ITONb BURNED
I1000GALLONS BURNED
IIOOOGALLONS BURNED
I TONS BURNED
(TONS BURNED
ICOMMtRtL-lN'.TUTM. IL IGMTE
ICOMfE^CL- INSTUTNL II. IGNI TE
ICOMMExCL-l'.STuTNl. IL I&MTE
ICOMMtxCL-INSTuTNL IL IGNI TE
ICOMMtHCL-INSTUINLILlGM TE
ICOMMExCL-JNSTulNLlLlGNITE
EXTCOM9 iOH t'M
EXTCOMB BOILER
KXTt'lMb rlOILE"
. I "".SI'JUAL
ICOMMERCL-INSTuTNLI-ESnilAi.
(CuMMERCL-INSTurivLI'JIbTILLATE
ILIO PETROLEUM GASI10-1OOMMBTU/HR
ILIO PETROLEUM GASl<1OMM8TU/HR
IRAGASSE I10-100MMBTU/HR
IBAGASSE KIOMMBTU/Mk
(OTHtu/NOT CLASIFOISPECIFV IN MEMAHKIMILLION CUBIC FEET BUHNEO
IOTHER/NHT CLASIFDISPEC1FV IN REMARKI1000 GALLON BURNED (LIQUID)
(OlhER NOT CLASIFOISPECIFT IN REMARKITONS BURNED (SOLID)
110-100-MBTU PUL*T|TONS BURNED
110-lOOxMBTu PULDYITONS BURNED
I 10-IOOMMBTUSPOSTKI TONS BURNED
K10MMBTU PULVIZEOlTONS BURNED
K10MMBTU STOKER ITONS BURIED
KlOMMbTU SPOSTOnRITONS BURMED
IOTHER/NOT CLASIFUITONS BURNED
I10-100MM8TU PULซTITONS BUhNED
I10-100MM8TU PULDYITONS BURNED
I 10-lOOMMflTU Ol-'STKITONS BURNED
110-100-HBTj UFSTKITONS BURNED
I 10-100"MdTUSPl>STKI TONS BURNED
I 10-100-MBTU M4NFRITONS BURNED
K10MMBTU OFSTOKERI TONS bUR^EO
K10MMBTU JFSTOXERI TONS bURr100MMfTU/MR I 1000 GALLON^ BURNED
OIL I1D-1OOMMBTU/M- 11000 GALLONS BUHNEO
OIL K10MMBTU/KR 11000 bALLONb BURNED
J/-R (1000 GALLONS BURNED
98
-------�
NATIONAL EMISSIONS, DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NAMES
11
III
SITCOMS 1BOILEM
EปTCOM8
ICOMMEWCL-INSTuTHlllllSTILLA'E
IC'JMWEdCL-INSTuTNLIDISTILLATE
NSTuTNL INATUJAL GAS
NSTUTNLIiNATU-JAL .,AS
ICOMMEHCL- NSTUTNLINATU-AL uปS
ICOMMEKCL-
ICOMMEHCL-
ICOMME-CL-
ICOMME^CL-
ICOMMESCL-
ICOMMEcCL-
ICOMMEWLL-
ICOMMEiCL-
NSTUTNLIปOOD
IV
I10-100MMBTU/MK
I <10MM8TU/H>-
I>100MMhTU/fซ
IlO-lOOMMBTU/H-
I<10MMBTU/Hk
K10HMBTU/nU
UNITS
I 1000 GALLONS BU&NEO
I 1000 GALLONS 6UPNEO
(MILLION CUBIC FEET bURNEO
IMILLION CUBIC FEET HUBNIO
MILLION CUBIC FEET HUHNKO
I TONS BUKNED
11000 GALLON:, BURNED
I 1000 GALLONS BUBNED
EXTCOM6'BOILER.
EXTCOMB'lOlLER
E*TCOM8 BOILEH
EXTCOMB,,f)OlLEH
EXTCOMB I90UER
EXTCOMB.'BOILEH
EXTCUMB 30ILEH
EXTCOMB HOILEB
INTEBNLCDHBUSTIONIELECTHIC GENEVA T HI DIST ILL ATE OIL |TulซBlNF 11000 GALLONS BURNED
iNTc-NLCOMttUSTlONIELECT-IC GENECATNINATu-AL PAS I TUB'S INK IMILLION CUBIC FEET
]NTE"NLCOMRUST10NIELECTWIC oENERATNIDIESFL IRECIPHOCATING (THOUSANDS Of GALLONS
INTE-JNLCOMBUSTIONIELECTRIC GEsEHATNI OTHER/NOT CLAS IFO I SPECIF 1 IN REMARK I MILLION CUBIC FEET BURNfO
C GENExATNIOTHE^/NOT CLASIFOI SPECIFY IN MEMAOKI1000 GALLONS BURNED
NSTuTNLILIO "ETwOLEUM 0ซSI 10-1OOMM8IU/MJ
NSTUTNLILIO PFTUULEUM GaSI<1OMMBTU/HH
NSTUTNLI'lTHEu/NOT CL'SIFO I SPEC IFY IN REซซซซK I M ILL ION CUB 1C FEET BURNfO
NSTUTML IDTME^/NOT-CLASIFOISOEClFy IN KEMAKKHOOO GALLON BU-NEO ILIOUIO)
NSTUTNL IOTHE-/NOT1 'CL'AS IFD I S^EC IF T IN REMARK I IONS BUWNED ISOLtO)
INTfxNLCOMBUSTIONI INOUSTMIAL
INTEBNLCOMHUSTIONI INOUSTHIAL
INTt^NLCUHHUSTIONI INOUSIMIAL
INTE-NLCOMBUSTIONI INDUSTUIAL
I NT EซNL COMBUST ION|:INDUSTWIAL
INTEWNLCOMHUSTIONI iNOUSTi-IAL
I INUUS!-'HUSTIUNlCCMME.'/NOT CL ASI'.O I S^EC IFY IN REMARKIlOOO UALLONS BURNED
IRCwAFT ITUHBOJET 'ITHOUSANOS OF GALLON/FUEL
O.IHC ACID PHOU IGE'NERAl -CYCLO-Ex ITONS PRODUCED
PIPIC ซCIO PROD IOT^ฃB/>OT CLAilFOITONS PPOOUCEO
UST10NI5NGINE TESTING
INDUSTRIAL PHUCESICHEMRAL MH,
INDUSTRIAL KBOCEMCMt'MICAL MFG
INDUSTRIAL ^HOCESlC^<^MIC4L Mf (,
INDUSTRIAL PHOCtSICMfMlciL "FG
INDUSTRIAL PHOCtSICHFXICoL MFG
INDUSTRIAL "ROCESICMFMICAL MFG
INDUSTRIAL PROCEblCHtMlf.nL MFG
INDUSTRIAL PROCESICHEMKaL MFG
INOUiTHlAL MMOCES ICMtMKiL MFU
INDUSTRIAL OMOCdSlCHFMlCiL MFG'
INHUSTHUL I'PUCESICMEMICaL MFG
INDUSTRIAL PPOCEi ICHfMICAL "-MOClSICff MICiL MFG
INDUSTRIAL "HOCESICHEMICOI MFG,
INDUSTRIAL "ROCESICMEMICAL MFG
INDUSTRIAL PBOCESICwEHICAL MfG
INDUSTRIAL HPOCESICHEMIC4L UFG
INDUSTRIAL PHOCesiCHEMICJL "FG
INDUSTKML HKOCฃSICMEMICซL ปft>
INDUSTRIAL (-HGCESICHF.M1C1L Hfr'
G'S
ITONi PRODUCED
I TON-) PBOOUCED
I TONS PHO'JUCtD
I TONS PHOOUCtD
I TONS PMOOUCED
MMO'JI-A ซ/MET
MMO^IA ซ/MET
MMOMIA ซ/COปBS'
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
5CC CATE3ORY NAMES
I
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSIRUL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTMIAL
INDUSTRIAL
INDUSTRIAL
INDUSTUI AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSlHl AL
INOU-.IHI AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
11
PROCESICHEMICAL MFG
PROCESICHEMICAL MFO
P&OCESICHEMICAL MFC
fROCESIC^EMICAL
PROCESICHEMICAL
PROCESICMEMICAL
PhOCESICHEMICAL
PROCESICHEMICAL
PHOCESICHENICAL
-ROCESICHEMICAL
PROCE.'ICnEMlCAL
PROCESICHEMICAL
*ซUCLSICnEMlCAL
fROCESICHEMICAL
PROCESICHEMICAL
PROCESICHEMICAL
PROCESICHEMICAL
tROCEslCHEMICAL
PROCESICMEMICAL
VROCESICHEMICAL
PROCESICHEMICAL
HHOCESICHEMKAL
PROCESICMEMICAL
PROCESICHEM1CJL
PROCESICHEMICAL
PPOCESIChEHlCAL
1-rtOCESICnEMlCAL
PHOCESICHEMICAL
PHOCtSICMEMICAL
HROCESI CHEMICAL
PPOCESICMEMICAL
PhOCESICHEMICAL
PMOCF.SICHEMKAL
PROCESIClEMICAl.
HkOCESICnEMlCii.
mOCES IChEMICAu
fwOCESIOEMICAL
HWUCESICHEMICAL
t-MOCESICHEMICOL
PHOCESICHEMICAL
PCOCESICMEMICAL
PHOCESIOEMICAL
PROCtSICMEMlCAL
*-ซOCESICMEMICAL
HROCESIChEMICAL
PROCESICMEMICAL
"KOCEsI CHEMICAL
PROCESlCiFHICAL
t"HOCtSICMFM|CAL
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MFC
MfG
MFG
MF6
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MFo
MFO
Ml-G
MFG
MKG
MFG
MfG
Mf G
MKG
MFG
ซf G
>-FO
fftj
MFG
MFC,
MfG
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MFG
MfG
MF(,
III IV UNITS
ICHLO"-ALKALI (LOADING T NKC Art VNT 1 1 00 TONS CHLORINE LIQUEFIED
ICHLOU-ALKALI (LOADING STGTNKVNTl 100 TONS CHLORINE LIQUEFIED
ICHLOR- ALKALI lAIR-BlO* MC 6WINEI100 TONS CHLOHINE LIUUEFIEO
ICHLOU-ALKALl IOTHER/NOT CLASIFDI100
ICLEANING CHEMICLSIS04P/DET SPMYDRYR I TONS
ICLEANINO CMEMICLSISPECIALTY CLEA.4RSI TONS
ICLEANING CHEMlCLSIOTHERS/NOT CLASFOITONS
IEXPIOSIVES-TNT (NITRATION HEACTHSITONS
IEซPLOSIVES-TNT IHNOS CONCTRTMS ITONS
(EXPLOSIVfS-TNT IHXSO* REGtNERATR 1 TONS
IEซPinSIVF.S-TNT IREO dATEH INCIN ITONS
IEXPLOSIVฃS-TNT (OPEN HASTE BURN ITONS
IMPlOSIVES IOTHER/NOT CLASIFOITONS
1 HYDROCHLORIC ACIOIBYPRODUCTtt/OSCRUB 1 TONS
iHYDkucHLORic ACIDIBYPROOUCT ซ/scซua ITONS
IHYDROCHLONIC ACIDIOTHER/NOT CLASIFOITONS
IHYOROFLUOH1C ACIOIROTRYKlLN'/SCuUBRl TONS
IHYDRUFLUOHIC ACIDIROTRYKILND/OSCRUBITONS
IHYORUFLUORIC ACIOIG^IND/DRY FLUOSPRITONS
IHYDCOFLUORIC ACIOIOTMEH/NOT CLASIFOIIONS
INITUIC ACID 1 AMMONI AOKIUATNOLDI TONS
INITPIC ACID 1 AMMONlAOXIUATNNtMl TONS
INITHlC ACID INITACD CONCTR OLDITONS
INITBIC ACID INITACD CONCTR NE.IIONS
INITR1C ACIO-ซEAH lUNCONTuOLLED P TONS
INITRIC ACID-KEAK Ib/CATYL/COMBUSTERI TONS
INITUIC ACIO-STRNGIUNCONTWOLLEO ITONS
INITRIC ACIO-STRNGIU/A8SOUBEHS ITONS
INITtIC ACID lOTtiER/NOT CLปSIFD|TONS
IปAINT MFR (GENERAL ITONS
IPAINT MFG IPIGMENT KILN ITONS
IPAINT MFG IOIMEf>/NOT CL4SFD ITONS
IVAUMSH MFG laoOrlNb OIL Gb'NL ITONS
IVARNISH "FG IOLEOHESINOUS GENLITONS
IVAHNISH "FG IALKYO RENEWAL ITONS
lYAHMIiH MFG IACRYLIC GENERAL ITONS
IVAWNISH MFC lOTMtR/NOT CLAbFO ITONS
IPH05-1CIU ปtTPr)OC|REACTO--UNCONTLD ITONS
IPHOS-ACID nETPROCIGYPSUM PONn (TONS
Ih'HOS-aCIfl ซETPHOC 1 CONOENSfi-UNCOKTLO 1 TONS
IPHns-ACIO ซETPROCIOTHER/".OT CL'SFO ITONS
iPMOs-tcin THERMAL iGtNERAi. ITONS
IPHOS-ACIU TnERMALlOTHtR/NOT CLASFD ITONS
IPLASMCS IPVC-GENERAL ITONS
IPLASTICS IPOLYPHOD-GENEWAL ITONS
IPLASTICS IBAKELITE-GENERAL ITONS
ELASTICS lOTMER/'lOT CLปSFO ITONS
MHTHALIC ANMYDHIOIUNCONTkOLLtO-'iENLI TONS
(PRINTING INK 1 COOK) NO-GENERAL ITONS
IPRINMNG INK ICOO" INli-OILS ITONS
TONS CHLOMINE LIOUEFIEO
PRODUCED
PRODUCT
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
BUHNED
PRODUCED
FINAL ACID
FINAL ACID
FINAL ACID
ACID
ACID
FLUORSPAR
ACIO
PUKE ACIO
PUME ACIO
POME ACID
PUUE ACIO
PUMt ACID
PUKE ACID
PUME ACID
PUwE ACID
PURE ACID
PRODUCED
PRODUCT
PRODUCT
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PHOSPHATE
PHOSPHATE
PHOSPHATE
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
PRODUCED
ROCK
MOCK
ROCK
PHOSPHOxOUS BUKNED
PRODUCED
PRODUCED
PRODUCED
PRODUCT
PRODUCtO
PRD3UCEU
PRoOUCtO
Pซ0')UCcD
100
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)'"
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NAMES
1 II
INDUSTRIAL PROCESICMEMICAL MFG
INDUSTRIAL PP.OCESICHEMICAL MFG
INDUSTRIAL PROCESICHEHICAL MFG
INDUSTRIAL PROCESICHEMIC4L MFG
INDUSTRIAL PROCESICHEM1CAL MFG
INDUSTRIAL PMOCEMCHFMICAL MFG
INDUSTRIAL PHOCtSICHEMICAL Mf G
INDUSTRIAL PHOCESICHEMICAL MFG
INDUSTRIAL PROCESICHtMlCAL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL ^HOCfMCHEMKAL *F(,
INOUS,THIAL HROCESICHEMICAL MFG
INDUSTRIAL PROCE.S (CHEMICAL Mf(, .
INDUSTRIAL PROCESICMEMICAL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PWOCESICHEMICAL MFQ
INDUSTRIAL PROCESICHEHICAL MFG
INDUSTRIAL MROCESICHEM1CAL MFQ
INDUSTRIAL PHOCESICHEMICAL Mf G
INUUSTRIAL PROCESICMEMICAL MFQ
INOUSTHUL PROCESICHF.MICIIL *FG
INDUSTRIAL, PWOCESICHEMICAL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PROCESICHEMIC4L MFG
INDUSTRIAL t-rfOCESlCHEMicปL H'G
INDUSTRIAL H&OCESICHEMICAL MFG
INDUSTRIAL PROCEilCl-EHICaL MFG
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PKOCESICHEMICAL MFG
INDUSTRIAL PHOCESICHEMICAL CFG
INDUSTRIAL HROCESICHEMICAL M^G
INDUSTRIAL PROCESICHEMICAL MFG
INDUSTRIAL PROCESICHEMICAL HFG
INDUSTRIAL PPOCE.SICHEMICHL MFG
INDUSTRIAL PROCESICHEMICSL MFG
INDUSTRIAL l-HOCESICMEMICoi. MFG
INDUSTRIAL ฐROCESICKEMICAL M>G
INDU-ilRIAL PROCESICMEMICAL MFG
INOUSTHIAL PROCESICMEMICAL MFG
INDUSTRIAL pMOCEsic^EMiciL HFG
INDUSTRIAL PROCtSICMEMlCAL MFG
INDUSTRIAL >-PbCEsic>-FMiCiL MFG
INDUSTRIAL PROCESICMEMICAL MFG
INDUSTRIAL PHOCESICM.EMICAL "FG
INDUSTRIAL PROCESICMEMICAL MFG
INDUSTRIAL PROCtSICHEMICAL MF(i
INDUSTRIAL ^HOCESICMEMICAL MFG
INDUSTRIAL HซUCtSICHEMICAL MFG
INDUSTRIAL "Roctsicnt M.ICซL MFG
INDUSTRIAL "WUCESICMEMKAL MFr,
III IV UNITS
IPRINTING INK ICOOKING-OLEORESINITONS PRODUCED
1 PRINTING INK ICOOKINn-ALKYDS 1 TONS PRODUCED
IPRINTING INK (PIGMENT MI * INGGENI TONS PIGMENT
IPRINTING INK (OTHER/NOT CLASFD ITONS PRODUCED
ISODIU". CARBONATE (AMMONIA RECOVERY ITONS PRODUCED
ISODIUM CARBONATE (HANDLING ITONS PRODUCED
ISODIUM CAMdONATE (OTHER/NOT CLASFD ITONS PRODUCED
IHJSO* -CHAMBER (GENERAL ITONS PURE ACID PRODUCED
IHZSO'-CONTACT 199.7 CONVERSION ITONS PUrtE ACID PRODUCED
IH2S04-CONTACT 199. i CONVERSION (TONS PUME ACID PRODUCED
IH2SOป-CONTACT 19;. 3 CONVERSION ITONS PUHE ACID PRODUCED
|M2Sbป-CONTACT I9%.0 CONVERSION ITONS PURE ACID PRODUCED
IHJS04-CONTACT 197.0 CONVERSION ITONS PURE ACID PRODUCED
IHaSOo-COHTACT 196.0 CONVERSION ITONS PUxE ACID PRODUCED
IH2SOป-CONTปCT 195.0 CONVERSION ITONS PURE ACID PRODUCED
IHZS04-CONTACT 194.0 CONVERSION (TONS PUMF ACID PRODUCED
IH2S04-CONTACT (93.0 CONVERSION 1 TONS PURE ACID PSOOUCEO
IHZSOป-CONTACT IOTHER/NOT CLAbFD ITONS PROOUCtD
(SYNTHETIC FIBERS INrLON GENERAL ITONS FIBER
ISYNTHFTIC FIBERS (OACRON GENERAL ITONS FIBER
tSYNTHETIC FIBERS IOHLON ITONS PRODUCT
i SYNTHETIC FIBERS IELASTIC ITONS PRODUCT
I5YNTHETIC FIBERS (TEFLON ITONS PRODUCT
(SYNTHETIC FIBERS (POLYESTER ITONS PRODUCT
ISYNTHFTIC FIBERS INCHEX ITONS PRUUUCT
(SYNTHETIC FIBERS (ACRYLIC ITONS PRODUCT
ISYNTnETIC FIBERS ITYVEX ITONS PRODUCT
HYN'T-ETIC HBERS IOLEFINS ITONS PRODUCT
(SYNTHETIC FIHERS IOTHERS/NOT CLซSFOITONS PRODUCED
ISEHISYNTHTICFI8R IRAYON GENERAL ITONS FIBER
ISEMISYNTHTICFIBR (ACETATE ITONS PRODUCED
ISEMISYNTHETICFIBRIVISCOSE ITONS PRODUCED
ISEMISYNTHTICFIBW IOTHERS/NOT CLASFOITONS PRODUCED
i SYNTHETIC RUHBER (BUTADIENE-RENTAL ITONS PROHUCT
(SYNTHETIC RUH8ER 1 ME THYLPPOPENE-GNL 1 TONS PHOUUC t
(SYNTHETIC RUBBER IBUTYNE GENEHAL ITONS PRODUCT
(SYNTHETIC RUHBER IPENTADIENE-GENUL ITONS PRODUCT
ISYNT-ETIC RUBBER 1 0 I"E THMtPTNE GENL 1 TONS PRODUCT
ISYNTHFTIC SUH8ER 1 PENT ANF-GE NERAL ITONS PHOPUCT
ISYNT-FTIC RUBBER 1 ETHANENI TRILE-GEN 1 TONS PRODUCT
ISYNTHFTIC RUBBER IACRYLONITR1LE-GENITONS PROUUCT
1 SYNTHETIC. RUBBER 1 ACROLE IN-GENERAL ITONS PRODUCT
|SYNTHFTIC.>UHBER IAJTO TIRES GENERL 1 TONS .PRODUCT
(SYNTHETIC RURBEH (OTHER/NOT CLASFO ITONS PRODUCT
IFERTILU AMONNITRIPRILTซR-NEUTRLIZRITONS PRODUCED
IFERTlLl? AMONNITRIPRILLING TOปE" 1 TONS .PRODUCED
IFERTILI7 AMONNITRIPMlLTxw-OR'COULRSI TONS PRODUCED
IFERTlLlf AMONNIlHIGrfANULAT-NEUTLUWITONS PROUUCtO
IFER'TILIZ AMONNITRIGWANULATOH ITONS PRODUCED
IFERTHIZ AMONNITRIGRANULAT-DtrCiiOLUI TONS PRODUCED
101
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NA-ES
I
INDUSTRIAL
INOUSTHIAL
INOUSTHIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOuSlRlAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHIAL
INDUSTRIAL
INDUSTRIAL
INOUsIRIAL
INDUSTRIAL
INUUSTM)AL
INDUSTRIAL
INOli~>TRI AL
INDUSTRIAL
INOUSTHIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTHIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
II
PROCESICHEMICAL MFG
PROCESICHEMICAL MFG
PROCESIOEMICAL "fS
PROCESICHEMICAL ซF(i
pROCESICnEMICAL MM;
PROCtSICntMICAL MFG
WROCESICHEMICAL MFG
k-cocts I CHEMICAL MFG
PROCtSICHEMICAL MFG
pwuCESicnEMiCAL MFG
PROCESICHEMICAL MFG
"ROCF.5 I CHEMICAL MFG
PHOCtilCHEMICAL MFG
PRUCCSICHEMICAL MFG
I-ROCESICMEMICAL MFG
PHOCESICHEMICAL MFG
PROCESICHEMICAL MFG
PROCESICHEMICAL MFG
HHocEsiCnEMicsL MFG
PROCESICHEMICAL MFG
PROCESICHEMICAL MKG
PROCESICHEMICAL MFii
PWOCESICHEMICAL MFC
PSOCESICHFMICAL MFC
PROCEblCnEMICAL MFG
PROCESIChEMICAL MFG
^ROCESICMEMICAL MFC
Ml IV
IFERTILIZ-NSUPPMOSIGRINO-DHY
IFFRTILI7-NSUPPHOSMA1N STACK
IFERfiLli-TRPSPMOSlRUN OF PILE
IFFHT1LI7-TRPSPHOSIGRANULAR
iFEWTILlZ-OlAMPMOSIORYER-COOLtHS
UNITS
I TONS PRODUCED
I TONS PRODUCED
I TONS PRODUCED
I TONS PRODUCED
I TONS PRODUCED
IFEHTILIZ-OIAMPHOSUMONIAT-GRANULATEITONS PRODUCE0
IFERT1LI?ER IOTHEH/NOT CLAblFOI TONS PRODUCED
|TfPE"THALIC ACIO IHN03ซPARปXrLENGENITONS PRODUCED
ITEREPTHALlC ACIO IOTMEH/NOT CLASIFOITONS PRODUCED
ISULFUBlfLEMtNTAL)IMOO-CLAUS 2STAGE I TONS PRODUCT
IbULFURIELEMENTAL) IHOD-CLAUS 3STAGE I TONS PRODUCT
ISULFUHtELEMENTALIIXOO-CLAUS ปSTAGE I TONS CHUOUCT
ISULFUR
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS) .
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NAMES
1
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTHI'AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRjAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOJSTR1AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
II
III
IV
UNITS
PROCESIFOqO/AliRICULTUWALIFEED/GRAlN CNTHYEISCREENING/CLEANNGI TONS GRAIN PROCESSED
pROCESlFooD/AURicuLTURALiFEEO/eRAiN CNTRYEIDHYING ITONS GRAIN PROCESSED
PROCESIFOOD/AGHICULTUPALlFEEp/GRAlN' IOTHER/NOT CLASIFOI TONS GRAIN PROCESSED
PROCESIFOOD/AGRICULTURALliiRAIN PROCESSING ICORN MfAL I TONS GRAIN PROCESSED
PHOCESIFOOD/AGRICULTUKALIGRAIN PROCESSING ISOY BEAN I TONS GRAIN PROCESSED
PROCESIFOOD/AURICULTURALrGRAIN. PROCESSING IBARLEY/*MEATCLEAN I TONS GRAIN PROCESSED
PROCESIFnOO/AGซICULTUซALIGHAIป. PROCES'SING' IMRO CLEANER I TONS GRAIN PROCESSED
PRpCESIFOOD/AGWICULTURALIGRAIN PROCESSING IBARLEYFLOUK MILL I TONS GRAIN PROCESSED
"ROCESIFOOD/AGRICULTURALIGRMN PROCESSING IKET CO"N BILLING I TONS OF PRODUCT
PROCESIFOOO/AuRICULTURALIGRAlK: PROCESSING IKMEAT FLOUR MILL (TONS PRODUCT
PROCiSIFOOQ/AttRICULTURALI'iHAHl PROCESSING (OTHER/NOT CLASFO I TONS PROCESSED
PROCESIFOOb/AtiHICULTUKALIFEED MANUFACTURE IBARLEY FEEO-GENL
PROCESI FOOD/AGRI CULTURAL I FEED MANUFACTURE
PROCESI FOOD/AGRI CULTURAL I FERMENTATN-BEER'
"ROCESI FOOD/AGRICULTURAL I FERMENTATN-BEER
PHOCESIFOOD/A'JRICULTURALIF.ERMENTATION-BEERI BREYI'-G I THOUSANDS OF GALLONS
PROCESIFOOD/AGRICULTURALIFERMENTATION-BEERI OTHER/NOT CLASFO IGALLONS PRODUCT
MROCtSIFOOD/ftGRICULTUWALIFFRMtNTATION-BEERIOTMlR/NOT CLASFD I TONS GRAIN PROCESSED
PHOCESIFOOO/A'iMICULTy^llL iFERMENTATN-llMlSnYIGRAIN HANDLING I TONS GRAIN PROCESSED
PROCtSIFOOO/AGwlCULTUWsLIFERMENTAfN-ilHISKYIORYING SPNT GHA1NITONS GRAIN PROCESSED
MRpCEilFOOO/aGHlCULTUdAL.IFEHMENTATN-iMfSnYIAGING ITONS GRAIN PROCESSED
t'ROCES'l FOOD/AGRICULTURAL I FERMENTATN-liHISKY I OTHER/NOT CLASFO IRALLONS PRODUCT
PROCES|FOOD/AGRICULTURAL'lFERซฃNTATN-ปiNE IGENERAL I GALLONS'PROUUCT
ITONS GRAIN PROCESSED
I OTHER/NOT CLASFO ITONS PHOCESStD
IGRAIN HANDLING ITONS GRi'IN PROCESSED
IDRYING SPNT GUAINITONS GRAIN PROCESSED
PROCESiFOOD/AGRICULTURALiFISH MEAL
PROCESI FOOD/AGRICULTURAL I FISH MEAL
CROCESIFOOO/AGRICULTUrfALIFISH MEAL
.PROCESIFOOO/AljSICULTUXALIKISH MEAL .
PROCE S I FOOD/0'iR I CULTURAL I "FAT SMOMNG
PROCESI FOOD/AGR[CULTURALISTAPCH MFC
ICOORERS-FMESHFISHITONS Fisf MEAL PRODUCED
ICOOKEHS-STALEFISMITONS FIS- MEAL PRODUCED
IDRIERS ITONS MSx SCRAP
lOTHER/rgOT CLASIFDITONS PRUCESSEO
ITONS MEAT S"OKED
ITONS STA"CH PKOOUCEO
ITONS SUi5AH PRODUCED
IGENERAL
IGENERAL
PROCESIFOOD/AGRICULTURALISUGAI'. CANE PROCES I GENERAL
PHOCESiFOOD/AGRICULTURALiSUGA" CANE PROCESIOTMER/MOT CLASIFOITONS PROCESSED
PHOCESIFpOO/AGRICULTUHALISUGAO BEET PROCESIOHYER ONLY ITONS RAป BEETS
('ROCESIFOOO/AGRICULTUMALISUGAH BEET PRQCtS I OTHER/NOT CLAblFD I TONS RAซ BEETS
PROCESIFOOp/AliRICULTURALIPEANUT PROCESSING I OIL/NOT CLASFU (TONS PRuDUCT
PHOCES I FOOD/AC.H I CULTURAL I PEANUT PROCESSINGIOTMER/NOT CLASFD ITONS PROCESSED
PROCESIFOOU/AljRICULTURAL ICANDY/CONFECTNHY lOTHER/NOT CLASFO I TONS PRODUCT
P.HOCESIFOOO/AuRICyLTU^AL.IJAIRY PRIIDUCTS IMILK SHRAY-ORYER ITONS PRuDUCT
't'OCEilFOOD/AGHicULTU'iAL IDAI&Y PRODUCTS IOTHER/NOT CLASFO ITONS PRODUCT
PMOCESIFOOU/AGMICULTUHALIOTMFI.VNUT CLASIFO I SPEC IF Y IN REMARK I TONS PROCKSSEO IINPUT)
MROCESIFOOD/A'jRICUl. TUUAL.I OTMt "/NOT CLAS IFD I SPEC IFY IN RE"AHKITONS PRODUCED (FINISHED)
I ALUMINUM OME-BAUHICRUSHING/HANDLINGITONS OF ORE
UL: nBE-ELECROREDN|PHEBAซE CELLS I TONS ALUMINUM PRODUCED
IAL 0-E-ELECRUREONIHORIZSTO SOOEHBRGI TONS ALUMINUM PRODUCED
IAL OME-ELECROREONIVERTSTD SODERBERGI TONS ALUMINUM PRODUCED
IAL ORF.-ELECRpREDNIMATERIALS HANULNGI TONS ALUMINUM PRODUCED
IAL OaE-ELECROREUNIANOOE BAKF. FU"NCE I TONS ALUMINUM PRODUCED
I ALUUINUM OP.tRATN IOTHER/NOT CLASFU ITONS ALUMINUM PRODUCED
IAL 0^-f-CALC ALHYOIGLNERAl ITONS ALU-INUM PRODUCED
ICOKF MET aYPROUUClTGENERAL ITON1 COAL CHARGED
ICOKf.-ปET BYPRODUCIOWEN CHARGING ITONS COAL CHARGED
fROCfSIPPIMAur MtTALS
t-ROCf.SIPHIMARr MtTALS
PROCESIPRIMARr MKTALS
PROCESIPRIMAhY MtTALS
"ROCESIPRIMAttV MtTJLS
PROCESIPRlMA^f MtTALJ.
PROCt'SIPHIMAHf MfTALS
MA^f M>TซLS
SIPRIMAUY MtTALS
103
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY Nซ-ES
1 II
INDUSTRIAL PHOCESIPR1MARY METALS
INDUSTRIAL PHOCESIPRJHARr METALS
INDUSTRIAL PROCESIPRIHAkY METALS
INDUSTRIAL PROCESIPR1MAWY HLTALS
INDUSTRIAL PROCESIPRIHAWY MtlALS
INDUSTRIAL PROCESIPR1HAPY HETALS
INDUSTRIAL PHOCESIPRIMAR* METALS
INDUSTRIAL PHOCEblPNIMARr PETALS
INDUSTRIAL huctsiP-'iMAWY MITELS
INDUSTRIAL PROCESIPMHARY METALS
INDUSTRIAL PROCLilPซIHAWY METALS
INDUSTRIAL PROC^SIPRIHAHY HETALS
INDUSTRIAL PROCESIP&IHAUY HETALS
INDUSTRIAL PROCESIPRIMAMY HETALS
INDUSTRIAL PHOCESIPRIHAMY HETALS
INDUSTRIAL PROCESIPWIHARY HETALS
INDUSTRIAL PROCESIPHIHARY MITALS
INDUSTRIAL PROCESIPRIHAMY HETALS
INDUSTRIAL HHOCESIPRIMAHY HETALS
INDUSTRIAL PROCESIPHlMARY HETALS
INDUSTRIAL PROCESIPHIHARY HETALS
INOUS1HIAL PROCESIPRIHARY MtTALS
tNDUSTHUL PMOCESIPRIHAHt HtTALS
INDUSTRIAL PROCESIPRIHAWY HLTALS
INDUSTRIAL I-HOCESIPRIHARY MMALS
INDUSTRIAL ppocEMPRlHARv M^TALS
INDUSTRIAL PROCESS* MAHr MtTALS
INDUSTRIAL PROCLSIPR HAH* METALS
INDUSTRIAL PROCESIP- Haur HETALS
INDUSTRIAL PHOCESIP" MAMf HETALS
INDUSTRIAL ^HOCESIP.W HAWY HETOLS
INOD^TBIAL PWUCLSIHW MAW* HLTILS
[IMUUSTHIAL PKOCt SIPMIMAHY "fcTALS
INDUSTRIAL l-HOCLS|PH|M;fcr MtltLb
INOI/sTMIAL HซOCt:5 IPHIMnl. MITALS
INDUSTRIAL -'HOCE'; II'KIMAH < METALS
INDUSTRIAL CMOCEsifwiMAm Mf.Tm.s
INOUlTHIAL f-KUCt SIPWIMAS* MtTALS
INOUSTWIAL ""OCESIPMIMAHY MtTil.--
|NIIUSTป;1AL i^ROCESIVWIMAPr "t'TซLS
INnu^TRIAL PPOCESIPRIMoHv MI.TAL'I
IMnUMKllou >-HOCrSIPKlMAHY MtTALS
INDUSTRIAL ChOCESlPnIHAH MtTALS
INDUSTRIAL PROCESIPHIHAH MtTALS
INDUSTRIAL (-HOCES|PR|MAN MLTALS
INDUSTRIAL PMOCES 1 PN IMAH MtTALS
INOUSTHlnL ^UOCtSIPWlHAH MtTALS
INDUSTRIAL 'MUCESIPHIMAN Ht.TALS
INDUSTRIAL PHOCESIPWIMAH METALS
III IV UNITS
ICOKE-MET BYPROOUCIOVEN PUSHING ITONS COAL CrtAHGEO
ICOKt'-MET 6YPROOUCI QUENCHING ITONS COAL CHARGED
ICOKK-MET BYPHQUUCIUNLOAOING 1 TONS CH&L CHARGED
ICOKE-MET RYPROOUCIUNDERF IHING 1 TONS COAL CHARGED
ICOKE-"ET BYPPODUCIOTHER/NOT CLป5FO ITONS COAL CHARGED
ICOKF MET-BEEHIVE (GENERAL ITONS COAL CHARGED
icoppe" SMELTER ITOTAL/(.ENฃWAL ITONS CONCENTRATED ORE
(COPPER SHELTER IROASTING ITONS CONCENTRATED OWE
ICnpPFv SHELTER ISHELTlNG ITONS CONCENTRATED ORE
ICOPPER SMELTER (CONVERTING ITONS CONCENTRATED ORE
iCOPPf SMELTER (REFINING ITONS CONCENTRATED ORE
ICOPPtrt MINE (ORE DRYER ITONS OF ORE
ICnPPER SHELTER lOTHER/NQT CLASFO 1 TONS CONCENTRATED OWE
IFERALLOY OPEN FNCI50* FEsI 1 TONS PRODUCED
IFERALLOY OPEN FNC 1 Taป FESI ITONS PRODUCEO-
IFERALLOV OPEN FNCI4Uซ FESI ITONS PRODUCED
IFEHALLOY OPEN FNCISILICON HETAL ITONS PRODUCED
IFERALLOY OPEN FNCISILICOHANGANESE ITONS PRODUCED
IFERRdALLOY ISCREENING ITONS PROCESSED
IFERRUALLOY IORE DRYER ITONS PROCESSED
(FERROALLOY (LOWCAซH CR-ซEปCTR 1 TONS PROCESSED
IFERHlULLOY IOTHER/NOT CLASFO ITONS PRODUCED
IFEHALOY SEHCOVFNCIFEHOHANGANESE ITONS PRODUCED
IFERALOY COVO FNC IGENERAL ITONS PRODUCED
1 IRON PRODUCTION IBLAST FNC-OHECHG ITONS PRdDUCEO
MOON PROJUCTION IBLAST FNC-AGLCป6 ITONS PRuOUCED
linos PRODUCTION (SINTERING GENEMALlTONS PRODUCED
IIBON PRODUCTION IOME-CRUSM/HANOLE 1 TONi OF ORE
MhON PRODUCTION ISCARFINU ITONS PROCESSED
II WON PRODUCTION ISAND HANDLING OPNITONS HANDLED
1 I^ON PRODUCTION IHOLO OVENS 1 TONS SAND BAKED
MWON PRODUCTION IOTnER/^OT CLASFD ITONS PRODUCED
I^TFKL PRODUCTION lOPNHEAfcTH DXLANCE 1 TONS PROOUCtO
1 STEEL PRODUCTION IOPNMEARTH NOXLNCE 1 TONS PRODUCED
ISTEEl. PRODUCTION IBOF-GENERAL 1 TONS PRODUCED
ISTEEL PRODUCTION IELECT ARC K/LANCElTONS PRODUCED
ISTEfL PRODUCTION IELECT ARC MOLaNCE 1 TONS PRODUCED
IsTEtL PRODUCTION lOThER/NOT CLASFD ITONS PRODUCED
iLfAn SMFLTEXS isiNTEซ/CRUbniw; ITONS CONCENTMATED ORE
ILEAO SHELTEHS IBLAST fuซNACE 1 TONi CONCEN1KATEO OHE
ILF.AR SMFLTEwS IREVt'RB FUMMCE ITONS CONCENTRATED .ORE
ILf.AO SMFLTERS IOTnEw/>;or CLAiFO I TOli CONCENfMATED ORE
IMOLYiNU" MINING IGENERAL lMUND"tDS OF TONS MINED
IMOLY^NUM HILLING IGtNEHAL ITONS PRODUCT
IHOLYHNUM PHOCES IOIHER/NOT CLASIFOlTONS PROCESSED
ITITt.MIUM PROCESS ICซLORINATION sTATlTONi PHOUUCT
ITITtNIUH PRuCES lOTMta/NOT CLASIFOlTONS HRurESsED
ir.OLO IHIMNG/PSOCtSSINGITOSS ORt
IH4RIU",, i-JOrtE GRIND ITONS PHOCESSEO
MARuiM IHEODCTN' HILN ITONS PROCESSED
104
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
scc CATEGORY NAMES
I
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRI AL
INDUSTRIAL
INDUSTRIAL
INDUSTRI OL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
1NOUSTBI AL
INDUSTRIAL
INDUSTRIAL
I NOUS TU I AL
INDUSTRIAL
INDUSTRI AL
II
PROCESIPHIMARY METALS
PROCESIPRIMARY METALS
PROCESIPRIMARf METALS
PROCESIPRIMARY METALS
PROCESIPRIMARY METALS
PROCESIPRIMARY MtTALS
PROCESIPRIMAUY MFTALS
f-ROCtSIPRIMAHY MtTALS
PROCESIPMIMAHY METALS
PROCESIPRIMARY MC.TALS
PROCESISECONOARY METALS
PHOCLSISECONDARY METALS
PHOCESISECONDAR MFTALS
PROCESISECONOAR METALS
PROCESIStCONljAH METALS
PHOCf SISECONIJAR METALS
PROCESISECONOAR MfTALS
PROCESISECONUaR METALS
PROCESISECOMIARY METALS
pROCESistcoNOAHY MFTALS
PBOCESI SECONDLY "F.TALS
PROCES 1 SE CONUARY MKTALS
SROCESISECONOAR< METALS
PROCES1SECONOAPY MtTALS
PROCESI SECONDARY MtTALS
PROCtS.'SECONOARY MtTALS
PROCEil SECONDARY MtTALS
PROCES ISECONDAWY MfTALS
PHOCtilSECONUaRY MtTALS
pROCEsisf CONUARY MF.ULS
PBOCts 1 'jECONUawr MP-TALS
pBoct si sf COMOซWY METALS
moCFSI Sf CONOซJY METALS
PPOCEilSECONOJRY MfTALS
PROCESI St CHNOaRY METALS
PROCES p SECONDARY METALS
PMOCES i sE cONijaRY METALS
PBOCESISECONUAHY <( TILS
"wnCEilSECONjaJY MMtLS
PMOCt S 1 SECONJilR Y *^ETtLS
PCOCE S 1 SF CONU L>^Y MtTALS
""OCtSlSt CDNDAHY "tTซLS
^ROCESIitCONUa-ป MLT4LS
PROCESI StCONUArfY METiLS
pROCEsiSEGONOinY METALS
PROCESISECONOAHY MtTALS
PROCEblSECONUARY MtToLS
PROCt s 1 Sc'CO-MUJ WY FETfcLS
PwOCESl SECON()'"Jป "tTALS
PMOCEM SECONDARY ^ETtLS
III
IBARIUM
IRARIUM
IZINC SMELTING
IZINC SMELTING
IZINC SMFLTING
I/INC SMELTING
I/INC SMELTING
l/INr SMELTING
IZINC SMELTING
IOTMEI./MOT CLASFD
IALOM NUM OPERATN
IALUM NUM OPERATN
IALUM NUM OPEฐATN
IALUM NUM OPERATN
ALUM MUM OPERATN
ALUM NUM OPERATN
ALUMINUM OPERATN
OLUMIป.UM OPE^ATN
ALUMINUM OPERATN
HBASS/HRONZ MELT
IHRASS/UHONZ MELT
IHHASS/HBUNZ MELT
IHRASS/PPONZ MELT
IHPASS/BWONZ MELT
IMBASS/BPONZ MJLT
IBRASS/HBONZ MELT
IGRAY [RON
MtRAY I"ON
ir.Qir IRON
If.RAY IRON
IGRAY IRON
1 C-RA Y I kfON
IGPAY IRON
ILEAO SMELT SEC
ILEAO SMELT SEC
ILFAD SMELT SEC
ILEAO SMELT SEC
ILFAD SMFLT SEC
ILEAIi SMFLT SEC
II.FAI.I BATTERY
ILEAT, BATTERY
|MAGซI'SIIPM SEC
IMAONJSIU" StC
1 STtf L FCUHUR
ISUfL FOUNUR
ISIEEL FOUMIH
1 STEEL FOUNDx
I^TEE1, FOUNOR
ISTEEl FOUNOR
i/ INC SEC
IV
IORIERS/CALCINERS PTONS
lOTnER/'iOT CLASFO I TONS
(GENERAL I TONS
IRclASTNfVNULl-MRTHI TONS
ISINTEHINli ITONS
IMORIZ PETOurs ITONS
ivtRT RETORTS ITONS
IELECTROLYT1C PROCITONS
POTriER/NOT CLASFO ITONS
ISRECIFY IN BEMAHKITONS
IS-EATINGFUBNACE ITONS
ISMELT-CRUCIBLl ITONS
ISMELT-REVERB FNC ITONS
ICMLOHINATN ST1.TN ITONS
(FOIL HULLI"G I TUNS
(FOIL CONVERTING ITONS
ICAN MANUFACTURE ITONS
IHOLL-DRAป-EปTRUOEI TONS
IOTMER/MOT CLASFU ITONS
IBLAST FNC ITONS
IC-iUCIRLE FNC I TONS
ICUPOLA FNC I TONS
IELECT INDUCTION iTONS
IHtVFHB FNC ITONS
I ROTARY fNC I TONS
IOTMER/NOT CLAsIFOlTQNS
ICUROLA I IONS
IRtvERB FNC I TONS
IELECT INDUCTION iTONS
(ANNEALING OPEปATNITONS
IMISC CซST-l-ABCTN I TONS
I G-J INDIGO-CLEANING I TONS
lOTMER/NOT CLASIFDI10NS
IPOT FU"NACE ITONS
IREVEHB FNC I TONS
IBLAST/CUPOLA FNC ITONS
IROTARY REVERB FNCITONj
ILEAD 0> IDE uFr, I TONS
IOTMER./NOT CLASIFDITONS
IGENERAL ITONS
lOTMER/K'OT CLASIFOITONS
IPOT FU>-'NACF ITONS
IOTMLR/NOT CLAilFOlIONS
IELECTWIC ARC FNC I TONS
IOREN HtARTM FNC ITONS
IOREN HEARTH LANCDMONS
IHEAT-TwEAT FNC I TONS
I INDUCTION FURNACE I TONS
IOTH1P/NOT CLASIFOITONS
IRt10ซT FNC I'QMS
UNITS
PROCESSED
RROCESSEO
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PRODUCED
RROOUCEO
METAL PRODUCED
METtL PRODUCED
METAL PRODUCED
PRODUCT
PRODUCED
PRODUCED
PRODUCED
PRODUCED
CHARGE
CHANGE
CHARGE
CHANGE
CHANGE
CHANGE
RROOUCED
METAL CHAซGE
METAL CHARGE
METOL CHARGE
METAL CHARGE
PROCESSED
PROCESSED
METAL CHARGE
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PMUCESSED
PRuCESStO
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
PROCESSED
105
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NAMES
I II
INDUSTRIAL PHOCESI SECONDARY METALS
INDUSTRIAL PROCESI SECONDARY METALS
INDUSTRIAL PROCESIStCONDAHY METALS
INDUSTRIAL ^OCES I SECONDARY METALS
INDUSTRIAL PROCESI SECONDARY METALS
INDUS TRIAL PROCESI SECONDARY MLTALS
INDUSTRIAL PROCESI SECONDARY "ETALS
INOUSTPIAL TRUCES I SECONDARY METALS
INDUSTRIAL PROCESI SECONDARY -METALS
INDUSTRIAL PROCESISECONOAXY METALS
INDUSTRIAL PHOCESISECONOAHY METALS
INDUSTRIAL PROCES(SECONDARY METALS
INDUSTRIAL PHOCES I SECONDARY' METALS
INDUSTRIAL PROCtlSl'SECONOAHY METiLS
INDUSTRIAL PROCESI SECONDARY METALS
INDUSTRIAL PROCESISECONDARY MtTALS
INDUSTRIAL PROCESI SECONDARY MtTALS
INDUSTRIAL PROCES(SECONDARY METALS
INDUSTRIAL PROCESISECONDAHY METALS
INDUSTRIAL PROCeSISECONOAHY METALS
INDUSTRIAL PROCESI SECONDARY MtTALS
INDUSTRIAL PROCESIMINERAL PRODUCTS
INDUSTRIAL PBOCESIMlNt'RAL PRODUCTS
INDUSTRIAL PROCESIHINERAL PRODUCTS
INDUSTRIAL "ROCESI MINERAL PRODUCTS
INDUSTRIAL PROCESIMIMERAL 'PRODUCTS
INDUSTRIAL wROCtsiMtNEnoL PRODUCTS
INDUSTRIAL PROCESIMINERAL PRODUCTS
INDUSTRIAL PROCESIMlNEHAL PRODUCTS
INDUSTRIAL PHOCESIMINEMAL PRODUCTS
INDUSTRIAL PHOCESIM1NERAL PRODUCTS
INDUSTRIAL PROCESIMINERAL PROUUCTS
INDUSTRIAL PROCtSIMIMERAL PHOUUCTS
INDUSTRIAL PROCISIMINERAL PRODUCTS
INDUSTRIAL PWOCESMINERAL PRODUCTS
INDUSTRIAL f-ROCESIMINEhAL PRODUCTS
INDUSTRIAL PROCEblMINERAL PRODUCTS
INDUSTRIAL ^HOCESIMINENAL PRODUCTS
INDUSTRIAL PHOCESIMiMERAL PRODUCTS
INDUSTRIAL PROCESIN1NERAL PRODUCTS
INDUSTRIAL PHOCESIMINERAL PHOOUCTS
INDUSTRIAL PROCKSIMINtWflL PRODUCTS
INDUSTRIAL PROCtSI MINERAL PRODUCTS
INDUSTRIAL PRUCESIM1NERAL PnODUCIS
INDUSTRIAL PROCtS(MlNtt.AL PRODUCTS
INDUSTRIAL PROCESIMINERAL PRODUCTS
INDUSTRIAL RHOCESIMINERAL PKOOUCTS
INDUSTRIAL ^ROCESIMINERAL PDUOUCTS
INDUSTRIAL MROCESIMINEHAL PRODUCTS
INDUSTRIAL >-ROCtiiMINERAL PRODUCT^
in
IV
UNITS
i ZINC SEC
IZINC SEC
IZINC SEC
IZINC SEC
IZINC SEC
IZINC SEC
IZINC SEC
IZINC SEC
IMALLEAHLE
(MALLEARLE
INICซFL
INIC'EL
(ZIRCONIUM.
(ZIRCONIUM
(MORI/ MUFFLE FNC ITONS PRODUCED
I POT FURNACE ITONS PRODUCED
IKETTLE-SHEAT FNC ITONS PRODUCED.
(GALVANIZING KETTLITONS PRODUCED
(CALCINING KILN ITONS PRODUCED
(CONCENTRATE ORYERIIONS PROCESSED
IREVERH-SMEAT FNC ITONS PRODUCED,
IOTMER/^OT CLASIFDITONS PROCESSED
IRON (ANNEALING OPEHATNITONS MtTAL CHARGE
IxON (OTHER/NOT CLASIFDITONS METAL CHARGE
IFLUA FiiUNACE ( TONS PROCESSED
{OTHER/NOT CLASIFDITONS PROCESSED
IOXIOE KILN . ITONS .PROCESSED
(OTHER/NOT CLASIFOITONS PROCESSED
IFURNtCC ELECTROOEICALClhATION ITONS PROCESSED
IFURNACE ELECTRODE IMIKING ITONS PROCESSED
(FURNfld ELECTRODEIPITCH TREATING ITONS PROCESSED
(FURNACE ELECTRODE I8AHE FURNACES ITONS PROCESSED
IFUHNlTE ELECTRODE lOTHfR/NOT CLASIFOITONS PROCESSED
I "ISC CASTt,FABRCTNlSPECIFY IN REMARK I TONS PRODUCED
lOIHEu/NOT CLASIFOISPEC1FY IN REMARKITONS PRUCESSEO
(ASPHALT ROOFING IBLOHlNr, OPERAT ION I TONS SATURATED FELT PRODUCED
IASPHALT ROOFING IDIPPINf, ONLY I TONS SATURATED FELT PRODUCED
lASPiALT ROOFING (SPRAYING ONLY ITONS SATURATED FELT PRODUCED
I ASPHALT ROOFING IDIPP|N',/SPRAY|SU I TONS . SA TUHA1 ED FELT PRODUCED
I ASPHALT ROOFING (OTHER/NOT CLASIFOITONS SATURATED FELT PRODUCED
IASPMALTIC CONCRETIROTARY ORปEn ITONS PRODUCED
IASPHALTIC CONCRETIOTHER bOURCES ITONS PRODUCED
IASPMALTIC CONCHET (OTHER/NOT CLASIFOITONS PRODUCED
IriRIC* MANUFACTURE IDRYING-RAH MIL ITONb PRODUCED
IHUIC< MANUFACTURE IGUINOING-RA* HTL ITONS PRODUCED
IHR1C* MANUFACTUHEISTORAGE-RA* MTL ITONS PRODUCED
IriRICK MANUFACTUREICuRlNG UAS F HED ITONS PRODUCED
IdRICK MANUFACTURE (CURING OIL F1ซEO I TONS PRODUCED
IHBIO MANUFACTUREICURINU COAL F1REOITONS PRODUCED
I8RICK MANUFACTUREIOTHER/NOT CLASIFDITONS PRODUCED
ICALCIUM CARBIDE (ELECTRIC FNC ITONS PRODUCED
ICALCIIIM CARBIDE ICOKE DRYER ITONS HHOnuCEO
ICALCIOM CARBIDE IFNC ROOM VtNTS IIONb PRUUUCED
ICALCIUM CARBIDE lOTHtR/NOT CLASIFOITONS PROCESSED
ICASTARLE REFRACTYIRAkHATL OHYE^ ITONS FEED MATERIAL
ICflSToHLf HEFAACTYIRAkMATL CRUSH/f RC I TONS FEED MATERIAL
ICASTARLt REFRACI Y IELECTRIC AMC MELTITONi FEtO MATERIAL
iCASItHLE HEIRACTYICUhING OvfEN I TONS FEED MATERIAL
ICASTABLF REFRACTYIMOLD/SMAKEOUT i TONS FEED MATERIAL
ICASTABLE HEFRACTYIOTHER/NOT CLASIFDITONS FEfO MATERIAL
ICEMENT MFG URY (KILNS IHARRELS CEMENT PRODUCED
ICEME'iT MFG i)R\; .1 DRYENS/GRI ซ-r-c>ETC I BARRELS CEMENT PRODUCED
ICEHENT MFG i\.' VKILNS-OIL. f IRI'I) "ITONS CEMENT PRODUCED
(CEMENT MFG'' OUT IKRNS-GAS -FIRtU (TONS CEMENT PRODUCED
106
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATf.GO"Y NAMES
I
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
II
PROCESIMINERAL
PHOCESIMINERAL
PROCESIMINERAL'
PROCESIMINERAL
PROCESIMINERAL
t-ROCESIMINERAL
fRUCES MINERAL
PROCESIMINEHAL
PROCESIMINERAL
PHOCESIMINERAL
FROCESIMINERAL
PROHSIHINERAL
PROCtSIMINERAL
HROCESIMINERAL
PROCESIMINERAL
PROCESIMINERAL
PROCESIMINERAL'
PROCESIMINEHAL
PROCESIMINERAL
PROCtSIMINERAL
PROCES(MlNtซAL
PROCtSIMINEHAL
PROCtSIMlNEHAL
PROCESIMINERAL
PROCEil MINERAL
PROCESIMINERAL
PROCtSIMINERAL
PROCESIMINERAL
PROCEblMINERAL
PROCESIMINERAL
I-KOCESIM1NEHAL
PROCESIMINERAL
PROCISI MINERAL
PROCESIMINERAL
PROCESIMINERAL
PROCESIMINEHAL
PROCESIMINERAL
t-ROCt'si MINERAL
PHOCtSIMINEHAL
PROCtilMINEHAL
PROCESI MINERAL
PROCKSIMINERAL
PROCESIMINtRซL
PROCESIMINEHAL
PROCESIMINERAL
PROCESIMINEHAL
PROCESIMINEHAL
PHOCESIMINERAL
PROCESIMINERAL
PROCESIMINEHAL
PRODUCTS
PRODUCT'S
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PROUUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PROUUCTS
PMODUCTS
PRODUCTS
PRODUCT*
PRODUCTS
PRODUCTS
PROUUCTS
PRODUCTS
PRODUCTS
PKOOUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PWOOUL'TS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
PROUUCTS
PRODUCTS
PRODUCTS
PHODUCTS
PRODUCTS
PRODUCTS
PRODUCTS
III
ICEMENT MFG DRY
ICEMENT MFG DRY
ICEMENT MFG ปET
ICEMENT MFG HET
(CEMENT MFtt ปET
ICEMENT MFG ปET
ICEMENT MFG *ET
ICEMENT MFG ซET
ICERAMIC/CLAY MFG
ICERAMC/CLAY MFG
ICERAMIC/CLAY MFG
ICERAMIC/CLAY MFG
IV
1 KILNS-COAL FIRED ITONS
(OTHER/NOT CLASIFOITONS
UNITS
CEMENT PRODUCED
CEMENT PRODUCED
1 KILNS 1 BARRELS CEMENT PRODUCED
IDRYERS/GRINOERETCIOARHELS CEMENT PRODUCED
IKILNS-OIL TIRED ITONS
(KILNS GAS FIRED ITONS
IKILNS-COAL' FIRED ITONS
(OTHER/NOT CLASIFOITONS
(DRYING ITONS
(GRINDING ITONS
(STORAGE ITONS
(OTHER/NOT CLASIFDITONS
ICLAY/FLYASHSINTERIFLYASM ITONS
ICLAY/FLYASHSINTERICLAY/COKE ITONS
ICLAY/FLYASHSINTERINATURAL CLAY ITONS
.ICL A Y/FLYASHSINTEHI OTHER/NOT CLASIFOITONS
ICOAL CLEANING
ICOAL CLEANING
ICOAL CLEANING
ICOAL CLEANING
(THERM/FLUID BED (TONS
ITHtRH/FLASM ITONS
1 TMEHM/MULT ILOUVRD I TONS
IOTMER/NOT CLASIFDITONS
CEMENT PRODUCED
CEMENT PRODUCED
CEHENT PRODUCED
CEMENT PRODUCED
INPUT TO PROCESS
INPUT TO PROCESS
INPUT TO PROCESS
PRODUCED
FINISHED PRODUCT
FINISHED PRODUCT
FINISHED PRODUCT
PRODUCED
COAL DRIED
COAL DRIED
COAL DRIED
COAL CLEANED
(CONCRETE BATCHINGIGENEHAL ICU8IC YA"OS CONCRETE PRODUCED
ICONCRCTE RA1CHINGIASBEST/CEMNT PDTSITQNS
ICONCrfETE BATCHINGIOTHER/HOT CLASFD ITONS
IFIBEBGLASS MFC
IFI6ERGLASS MfK
IFI8ERGLASS MFG
IFIBET-LASS MFG
IF IHf a'GLASS MFG
IFIBMGLASS MFG
IFHIT MFO
IFRIT MFG
(GLASS MFU
IGLASS MFG
(GLASS MFG
IGLASS MFG
IGLASS MFG
IGYPSUM MFG
IliYPSUH MFG
IGYPSUM ป
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY MIMES
I
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL.
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
1NUUSTRIAL
INIlUSTRIAL
INuUSTHlAL
I M,USTRI AL
I NUU-J TRIAL
INCUSTH1AL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INOUSTRluL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
II
PROCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PHOCEblMlNEHAL PRODUCTS
FRUCESI MINERAL PRODUCTS
PROCtSIMlNERAL PRODUCTS
HROCES i MINERAL PRODUCTS
PMOCL5IMINEHAL PRODUCTS
PROCtSIMlNERAL PRODUCTS
PHOCESIMINERAL PRODUCTS
PROCtSIMlNERAL PRODUCTS
PHOCtSIMlNEHAL PRODUCTS
PROCESiMINERAL PRODUCTS
PROCESIMINEHAL PRODUCTS
PHOCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PHOCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PROCESIMlNtRAL PRODUCTS
PHOCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PROCESIMINlfiAL PRODUCTS
PHOCESIMINERAL PRODUCTS
PROCESIMINtRAL PRODUCTS
PROCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PROCESIMINERAL PRODUCTS
PRuCEblMlNEHAL PRODUCTS
PROCE5IMINEHAL PRODUCTS
RHUCtSIMlNERAL PRODUCTS
PROCESiMINERAL PRODUCTS
PROCESI PETROLEUM INOR
PHOCESIPETROLEUM NDR
PrlUCE S I PE TROi. LUM NDR
P'tOCLSIPETROmUM NDR
RROCtS I Pr'.TROLtuM
PROCEalPETROLdUM
PRUCtbIPE TROL.C.UM NOR
PROCES i PETROLEUM
NOR
NDR
NDR
NDI-
III
IV
UNITS
{MINERAL ซOOL
IMINERAL MOOL
IPERLITE MF6
IPERLITE MFG
(PHOSPHATE HOCK
(PHOSPHATE ROCK
(PHOSPHATE ROCK
IPHOSPHATt HOCK
IPHOSPHAlE ROCK
fHOCEalPtTROLtUM
fROCESIPtTROLtUM
PROCEblftTROLtUM
RHOCESIPtTRULEUM NDR
PROCESIPtTROLEUM
PHOCtilPr.TROLtUM
PMOCESIPtTROLEUM
NDR
NDR
NDx
PROCESIPETrtOLEUM INDR
*>ROCESIPLTROLtUM INDR
ICOOLER I TONS CHARGE
IOTMER/NOT CLAS1FDITONS PROCESSED
(VERTICAL FNC GEN I TONS CHARGE
IOTHER/NOT CLASIFOITONS PROCESSED
IDHTING (TONS PHOSPHATE ROCK
IGRINDING I TONS PHOSPHATE ROCK
I TRANSFER/STORAGE I TONS PHOSPHATE MOCK
I OPEN STORAGE (TONS PHuSPHATt HOCK
IOTHER/NOT CLASIFOITONS PROCESSED
ISTONL OUAHY/PROC (PRIMARY CRUSHING I TONS RA. MATERIAL
(STONE OUAHY/PROC (SEC CHUSH/SCREL'N I TONS RA* MATERIAL
(STONE OUAHY/PHOC ITERT CRUSH/SCREEN I TONS HA* MATERIAL
ISTONt OUARY/PROC IRECRUSH/SCREENINGITONS RAo MATERIAL
ISTONL' OUAHY/PROC (FINES MILL I TONS RAb MATERIAL
ISTONF. OUARY/PHOC ISCREEN/CONVY/HNDL I TONS PRODUCT
(STONE OUARY/PROC (OPEN STORAGE I TONS PRODUCT STORED
ISTONE OUAHRY PROCICUT STONE-GENERAL I TONS PROCESSED
(STONE QUARRY PHOCIBLASTlNG-uENERAL I TONS PROCESSED
ISTONt OUARRY PROCIOTHER/NOT CLASIFDITONS PROCESSED
ISALT MINING (GtlNERAL (TONS MINED
IPOTASh PROOUCTIONIMINE-GRIND/ORY (TONS ORE
IPOTASH PRODUCTIONIOTMER/UOT CLASIFOITONS PROCESSED
ICALCIUM BORATt IMINING/PROCESSINGITONS PRODUCT
(OTHER/NOT CLASIFOITONS PROCESSED
(MINE/PROCESS (TONS PRODUCT
(OTHER/NOT CLASIFOITONS PROCESSED
ICRUSMlNU/SCREENlNITONS PRODUCT
(OTHER/NOT CLASIFOITONS PROCESSED
(HANDLING I TONS PRODUCT
IUIATOMACUUS LAHTHIOTHER/NOT CLASIFOITONS PROCESSED
ICERAMIC ELECT PTSIOTMER/NOT CLASIFOITONS PROCESSED
IOTHER/NOT CLASIFOISPECIFY IN RECARKiTONS PRODUCT
(CALCIUM BORATE
IMG CARbONATt
IMG CARBONATE
ISANO/GRAVEL
ISAND/GRAVEL
(OlATOMACOUitRTM
PROCESS HEATER
PROCESS HEATER
PROCESS HEATER
RROCtSS HEATER
I-'LUIO CRACKERS
IOIL
IGAS
IOIL
IGAS
IGENEBAL
(FCC)
Moi/-ntD CAT-CHACK IGENERAL ITCCI
nLUซ-DOซN SYSTM IK/CUNTuOLS
dLOw-00ATER
iiooo BARRELS VACUUM DISTILLATION
IIOOO BARRELS VACUUM DISTILLATION
I IMILLION GALLONS COOLING WATER
IPIPE/VALVE-FLANGEi1000 BAHRELS REFINERY CAPACITY
IVLSL RELIEF VALUEI1000 BARRELS REFINERY CAPACITY
I PUMP SEALS IIOOU BARRELS REFINERY CAPACITY
ICUMPRESR SfALS IIOOO BAHxELb REFINERY CAPACITY
IOTHER-(.
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NAMES
I
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INUUbTRlAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
INDUSTRIAL
II
III
IV
UNITS
PNOCESIPETROLEUM INOMY
PROCESIPETROLEUM INORT
PHOCEilPETROLEUM INDRT
PROCESIPETROLEUM INDRY
PROCEslPETHOLEUM 1NORY
PROCESIPETHOLEUM INOHY
PROCESIPETROLEUM INDRY
PHOCESIPETROLEUM INORY
pNOCEsnooD PRODUCTS
PHOCESIป000 PRODUCTS
PHOCESIHOpO PRODUCTS
PROCESIKUOO PRODUCTS
PHOCESKIOOD PRODUCTS
PROCES1*000 PRODUCTS
PROCESIBOOO PRUOUCTS
PROCESIWOOD PRODUCTS
PROCESIปOOD PRODUCTS
PHOCES1X000 PRODUCTS
PROCEslHOOO PRODUCTS
PROCESIKOpD PRODUCTS
PHOCESI WOOD PRODUCTS
RHOCESISOOO PRUOUCTS
PROCESI*OOD PRODUCTS
PROCEslซOOD PRODUCTS
PROCEilป000 PRODUCTS
PROCESIHOOO PRODUCTS
RHOCEsl.OOD PRODUCTS
PROCESIKOOQ PRODUCTS
PROCESIkUOO PRODUCTS
PROCESIซ000 PRODUCTS
KRDCtSItOUD PRODUCTS
PRUCESIHOOD PRODUCTS
PSOCESIlfUOD PRODUCTS
RROCEblBOOO PRODUCTS
PROCESKOOD PRODUCTS
PROCESUOOD PRODUCTS
PMOCESIWOOD PRODUCTS
RROCEblBOOU PRODUCTS
PROCEalปUOO PRUOUCTS
PROCESI METAL FABRICATION I IRON/STEEL
PHOCEalHETAL FABRIC AT ION IIRON/STtEL
IFLARES (NATURAL GAS (MILLIONS Of CUBIC FEET
IFLAHES IOTMEH/NOT CLASIFOI MILL IONS OF CUBIC FEET
I SLUDGE CONVERTER I GENERAL I TONS PROCESSED
IASPHALT OX1UIZEH (GENERAL I TONS PROCESSED
IASPHAL.T OXIDIZER IOTMER/NOT CLASIFDITONS PROCESSED
IFLUID COKING (GENERAL 11000 bARt-ELS FRESH FEED
IOTMER/NOT CLASIFDISPECIFY IN REMAHKITONS PRuCESSED
IOTHER/NOT CLASIFDJSMECIFY IN REMARK I BARRELS-PROCESSED
IBLOXTNK ACCUMULTRIAIR-DHY TONS UNBLEACHED
IMAShRS/SCREENS IAIR-DRY TONS UNBLEACHED
IMULT-EFFECT EVAP IAIH-DRY TONS UNBLEACHED
IRECVY BOLR'PCฃVAPIAlR-ORr TONS UNBLEACHED
ISMELT DISSOLV TNKIAlrt-DRY TONS UNBLEACHED
ILIME KILNS IAIR-DRY TONS UNBLEACHED
I TURPENTINE CONDSRIAIR-DHT TONS UNBLEACHED
IFLUIOBED CALCINERlAIR-ORป TONS UNBLEACHED
(LIQUOR OXIDN TOซRI AIR-DP.V TONS UNBLEACHED
IOTHER/NOT CLASIFOIAIR-DRY TONS UNBLEACHED
IL10UOR RECOVERY I AIR-ORY . TONS UNBLEACHED
ISULFITE TuซER IAIR-ORV TONS UNBLEACHED
lOIGESUR IAIR-ORY TONS UNBLEACHED
ISMELT TANK IAIR-OHY TONS UNBLEACHED
IEVAPOHATORS IAIR-ORY TONS UNBLEACHED
IPULP DIGESTER I TONS AIK DRY PULP
IOTMER/NOT CLASIFOITONS AIR DHY PULP
IPAPERBOARD-GEN I TONS FINISHED PRODUCT
IF1BEHBOซRO-GEN I TONS FINlSHtD PRODUCT
IOTMER/MOT CLASIFDITONS FINISHED PRODUCT
PRESSURE TRtATINGICREOSOTE I TONS OF HOOD TREATED
(PRESSURE TREATIN6IOTMER/MOT CLASIfDITONS OF .ODD TREATED
ITALL01L/ROS1N IGENERAL I TONS OF PRODUCT
IPLYKOOD/PARTBOARDIVENEER ORYtH I TONS PROCESSED
|PLYปOOD/PARTdOAi
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NAMES
I II
INDUSTRIAL PHOCESI INPROCESS FUEL
INDUSTRIAL PROCESI INPHOCtSS FUEL
IN&USTH1AL PHUCESI INPHOCtSS FUEL
INDUSTHUL PHOCESI INPHOCESS FUEL
INDUSTRIAL HROCEsI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPHOCESS FUEL
INDUSTRIAL PHOCtSI INPRUCESS FUEL
INDUSTRIAL TRUCES 1 INPHOCESS FUEL
INDUSTRIAL PHUCESI INPHOCtSS FUEL
INDUSTRIAL PROCESI INPHOCtSS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL HROCESi INPHOCESS FUEL
INDUSTRIAL PkOCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPROCESS FUEL
INDUSTRIAL PROCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCLSS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPROCESS FUEL
INDUSTRIAL PHOCE5I INPHOCESS FUEL
INDUSTRIAL PROCESI INPROCESS FUEL
INDUSTRIAL PROCESI INPHOCtSS FUEL
INDUSTRIAL HHOCESI INPHOCtSS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPHOCtSS FULL
INDUSTRIAL PROCESI INPROCESS FUEL
INDUSTRIAL HHOCESI INPHOCESS FUEL
INDUSTRIAL PROCESI INPROCESS FUEL
III IV . UNITS
IANTHHACITE COAL (OTHER/NOT CLASIFDITONS BURNED
(BITUMINOUS COAL (CEMENT KILN ITONS 6UMNEO
IBITUMINOUS COAL I6HICK KILN/DRY ITONS bUMNEO
IHITUX1NOUS COAL IGTPSUM KILN/ETC ITONS bUHNEO
(BITUMINOUS COAL ICOAL DRYERS ITONS bUHNEO
(BITUMINOUS COAL (OTHER/NOT CLASIFOITONS BURNED
IHESIOUAL OIL (ASPHALT DRYER 11000 GALLONS BURNED
(RESIDUAL OIL -ICEMENT KILN 11000 GALLONS BUHNEO
IHESIJUAL OIL ILIME KILN 11000 GALLONS BUHNEO
IHESIDUAL OIL (KAOLIN KILN 11000 GALLONS bUHNEO
(RESIDUAL OIL IMETAL MELTING (1000 GALLONS BURNED
IHESIDUAL OIL (BRICK MLN/ORY 11000 GALLONS BURNED
IRESIOUAL OIL (GYPSUM KILN/ETC 11000 GALLONS BUHNEO
IHESIDUAL OIL (OTHER/NOT CLAS1FDIIOOO GALLONS BURNED
(DISTILLATE OIL (ASPHALT DRYER 11000 GALLONS BURNED
(DISTILLATE OIL ICEMENT KILN 11000 GALLONS BURNED
DISTILLATE OIL ILIME KILN 11000 GALLONS BURNED
IUISTILLATE OIL IKAOLIN KILN 11000 GALLONS bURNED
IOISTILLATE OIL 1 METAL MELTING 11000 GALLONS BURNED
(DISTILLATE OIL IBHICK KILN/DRY 11000 GALLONS BURNED
IOISTILLATE OIL 1 GYPSUM KILN/ETC 11000 GALLONS BURNED
(DISTILLATE OIL (OTHER/NOT CLASIFD'1000 GALLONS BURNED
(NATURAL GAS (ASPHALT OHYEH (MILLION CUBIC FEET BURNED
INATUUAL GAS ICEMENT KILN (MILLION CUBIC FEET BURNED
(NATURAL GAS ILIME KILN (MILLION CUBIC FEET bUHNEO
INATUUAL GAS IKAOLIN KILN (MILLION CUBIC FEET BURNED
INATUUAL GAS (METAL MELTING IMILLION CUBIC FEET UUfiNtO
INATUHAL GAS IBHICK KILN/UHYS IMlLLlON CUBIC FEET BURNED
INATUUAL GAS IGYPSUM KILN ETC (MILLION CUBIC FEET bUHNED
INATUUAL GAS (OTHER/NOT CLASIFDIMILHON CUBIC FEET BURNED
IPROCESS GAS (OTHER/NOT CLASIFO 1 M ILL I ON CUBIC FEET bUHNEO
ICOKE (OTHER/NOT CLASIFOITONS
IซOOU (OTHER/NOT CLASIFOITONS bUHNEO
IOTHEU/NOT CLASIFDISPECIFY IN REMARK IMILLION CUBIC FEET BURNED
IOTHER/NOT CLASIFDISPECIFY IN HEMAHKIIOOO GALLONS BUHNEO
IOTHEA/NOT CLASIFD I SPECIFY IN HEMAHKITONS BUHNED
INDUSTRIAL PHOCESIOTHEH/NOT CLASIFDISPECIFY IN kEMAHK 1 ITONS PROCESSED
POINT SC EVAP ICLEANING SOLVENT
POINT SC EVAP (CLEANING SOLVENT
POINT SC EVAP (CLEANING SOLVENT
POINT St EV*P (CLEANING SOLVENT
POINT SC EVAP (CLEANING SOLVENT
POINT SC EVAP (SURFACE COATING
POINT SC EVAP (SURFACE COATING
POINT SC EVAP (SURFACE COATING
POINT SC EVif (SURFACE COATING
POINT SL EVAP (SURFACE COATING
POINT SC EVAP ISURFACE CuATINb
PUlNT SC IV4K (PETROLEUM ST6
POINT SC EVAP (PETROLEUM STG
IDRYCLFANING IPEHCMLORETHYLENE ITONi CLOTMEs CLEANED
IDRYCLEANING ISTUDDAHD ITONS CLOTnES CLEANED
IUEGUEASING ISTODDAtO ITONS SOLVENT USED
lUEGUEtSING IOTHER/NOT CLASIFOITONS SOLVENT USED
ll-TMEH/NOT CLASIFOISPECIFY IN HEMAHKITONS SOLVENT USED
(PAINT IGENEHAL ITONS COATING
(VARNISH/SHELLAC IGENEAAL ITONS COATING
ILAQU?U IGENEHAL ITONS COATING
ItNAMEL IGENEHAL ITONS COATING
li^HIMEH (GENERAL ITONS COATING
(UTriEu/NOT CLASIFOISPECIFY IN HEMAHKITONS COATING
(FIXED HOOF IBHEAThlNG-PMODUCTl 1000 GALLONS STOHAGE CAPAC
IFIXEu HOOF (BREATHING CHUOE 11000 GALLONS STOHAGE CAPAC
110
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCCCATEGORY NAMES
I
POINT SC EVAP
POINT SC EVAP
POINT SC EVAP
POINT sc EVAP
POINT SC EVAP
POINT SC EVAP
POINT SC EVAP
POINT sc EVAP
POINT SC EVAP
POINT SC EVAP
SOL III HASTE
SOLID HASTE
SOLID HASTE
SOLI'J HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOL 10 HASTE
SOL10 HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOL 10 HASTE
SOLID kASTE
SOLID HASTE
SOLID HASTE
SOLID BASTE
50LIO HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID HASTE
SOLID H^STE
SOLID HuSTE
SOLID HASTE
SOLID >ASTE
SOLID HASTE-
50LIU BASTE
SOL'IO HASTE
SOLID HAbTE
SOLID HASTE
SOLID kASTE
SOLID HASTE
II
1 PETROLEUM ST6
1 PETROLEUM ST6
IPETROLtUM ST6
IPETROLEOM STG
(PETROLEUM SIC
IPETHOLKUM SIG
IPETHOLtUM STG
IMISC ORGANIC
III IV UNITS
1 FIXED ROOF IHORKING-PROOUtT 11000 GALLONS THROUGHPUT
IF1XEO ROOF IHORKINb CRUDE 11000 GALLONS THROUGHPUT
(FLOATING ROOF (BREATHING PRODUCT! 1000 GALLONS STORAGE CAPACITY
(FLOATING ROOF IHORKING-PHODUCT i loco. GALLONS THROUGHPUT
(FLOATING ROOF IBREATMlNG-ChUUi ( 1000 GALLONS STORAtit CAPACITY
(FLOATING ROOF IHORnlNo-CHuUE 11000 GALLONS THMOUGHPUT
IOTMf/NOT CLASIFDISPECIFY IN REMAMKI1000 GAL STORED
STORIOTHER/NOT CLASIFO 1 SPEC IF Y IN HEMARKITONS STOWED
(PRINTING PHESS IORYEHS (GENERAL 1 TONS SOLVENT
IMISC MC EVAP
(GOVERNMENT
(GOVERNMENT
IGOVEHNMENT
(GOVERNMENT
(GOVERNMENT
(GOVERNMENT
IGOVEHNMENT
IGOVEHNMENT
(GOVERNMENT
(GOVERNMENT
(GOVERNMENT
(GOVERNMENT
(GOVERNMENT
(GOVERNMENT
(GOVERNMENT
IGOVEHNMENT
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-INST
ICOMM-I'NST
ICOMM-INST
ICOMM-INST
1 INDUSTRIAL
1 INDUSTRIAL
IINDUSTHIAL
(INDUSTRIAL
1 INDUSTRIAL
1 INDUSTRIAL
lOTHER/NOT CLASIFOISPECIFV IN REMAHKITONS PROCESSED
(MUNICIPAL INCIN (MULTIPLE CHAMBER 1 TONS, BUhNED
(MUNICIPAL INCIN (SINGLE CHAMBER (TONS BUHNEO
IOPCN BURNING DUMPIGENEHAL 1 TONS UUMNEO
IOPEN BURNING DUMPILANDSCAPE/PRUNlNGITONS BURNED
(OPEN BURNING DUMPIJET FUEL IHUNDHEDS OF GALLONS
(INCINERATOR (PATHOLOGICAL (TONS BUHNEO
.1 INCINERATOR (SLUDGE (TONS DRY SLUDGE
(INCINERATOR (CONICAL ITONS BUHNEO
IINCINFRATOR (OTHER/NOT CLAMFOITONS BURNED
IAUX. FUEL/NO EMSNSIRESIOUAL OIL 11003 GALLONS
IAUX. FUEL/NO EMSNSIOISTILLATE OIL 11000 GALLONS
ItUX. FUEL/NO EMSNSINATUHAL GAS (MILLION CUBIC FEET
(AUK. FUEL/NO EMSNSILPO 11000 GALLONS
IAUX. FUEL/NO EMSNSIOTMER/NOT CLASIF.OIMlLLION CUBIC FEET
IAUX.FUCL/NO^EMSNSIOTHER/~OT CLASIFOIIOOO GALLONS
IAUX. FUEL/NO EMSNSIOTr
-------�
NATIONAL EMISSIONS DATA SYSTEM (NEDS)
SOURCE CLASSIFICATION CODE (SCC) REPORT
SCC CATEGORY NA*ES
SOLID
SOLID
SOLID
SOLID
SOLID
SOL 10
SOLID
SOL 10
SOL 10
SOLIO
SOLIO
SOL 10
SOLID
SOLID
SOLIO
SOLID
I
ASTE
HASTE
BASTE
HASTE
HAbTE
ASTE
KซSTE
KAbTE
ปASTE
ASTE
ASTE
ASTE
AsTE
BASTE
ASTE
II
IINDUSTRIAL
IINDUSTRIAL
I INDUSTRIAL
IINOUSrCIAL
I INDUSTRIAL
IINDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
IINDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
I INDUSTRIAL
III
IV
UNITS
I AJTuS BURNED
IAUTOS BURNEJ
ICARS BURNED
I TONS DRY SLUDGE
IOPEN BURNING IMOOO I TONS BURNED
IOPEN BURNING IHtFUSE ITONi bURNED
IOPEN HUWMNG IAUTO BOOY COปPTS I IONS BUซNEO
IAUTO BODY INCINATIV/O AFTERBURNER
IAUTO BOUY INCINATI*/
RAIL CAR BURNING IOPEN
INCINERATOR ISLUUOE
INClNfRAfOR IOTnEH/NOT
AUX.FUEL/NO EMSNSIRESIDUAL OIL
AUX.HJEL/NO LMSNSIDISTlLLATE OIL
AUX.FUEL/NO LMSNSINATURAL GAS
AUX.FUEL/NO EMSNSIRRULtSS GAS
IAUX.FUEL/NO EMSNSIL P G
IAUX.FUEL/NO EMSNSIOTMES/NOT CLASIKDPMILL ION CUBIC FEET
IAUX.FUEL/NO EMSNSIOTHER/NOT CLASIFOIIOOO GALLON^
IAUX.FUEL/NO EMSNSIOThEH/NOT CLASIFQITONS
11000 GALLONS
I 1000 GALLONS
IM1LLIO* CUBIC
IHILLION CUBIC FEET
I100U GALLONS
FEIT
Other
Lab
Analysis
Other
Not
Classified
Specify in Remarks
112
-------�
APPENDIX C
SAROAD POLLUTANT CODES
113
-------�
CODE**
General 1
Participate (total) 1101
Organic (total) fraction 1102
Benezehe soluble organic fraction 1103
Polynuclear hydrocarbons (heterocyclic) 1104
Water soluble organics 1105
Aliphatic fraction 1110
Aromatic fraction 1111
Inorganic fraction 1113
Hydrocarbon fraction 1114
Aldehyde fraction 1115
Organic acid fraction 1116
Inorganic 2
Total Element (free and combined) 21
Aluminum 2101
Antimony 2102
Arsenic 2103
Argon 2104
Beryllium 2105
Bismuth 2106
Barium 2107
Boron 2108
**These codes are identical to the last 4 digits of the SAROAD pollutant
codes for suspended, respirable, and settled particulates, found in the
SAROAD PARAMETER CODING MANUAL (APTD-0633).
114
-------�
SAROAD POLLUTANT CODES
CHEMICAL POLLUTANT CODE
Bromine 2109
Cadmium 2110
Calcium 2111
Chromium 2112
Cobalt 2113
Copper 2114
Chlorine 2115
Carbon 2116
Cerium 2117
Cesium 2118.
Dysprosium 2119
Erbium 2120
Europium 2121
Fluorine 2122
Gadolinium 2123
Gallium 2124
Germanium 2125
Iron 2126
Hafnium 2127
Lead 2128
Hoimiurn 2129
Hydrogen 2130
Indium 2131
Manganese 2132
Iridium 2133
Molybdenum 2134
115
-------�
Krypton 2135
Nickel 2136
Helium 2137
Lithium 2138
Lutetiurn 2139
Magnesium 2140
Iodine 2141
Mercury 2142
Gold 2143
Neodymium .2144
Neon 2145
Lanthanum 2146
Niobium .2147
Nitrogen 214.8
Osmium 2149
Oxygen 2150
Palladium .2.151
Phosphorus 2152
Platinum 2153
Selenium 2154
Praseodymium .2155
Protactinium 2156
Radium .2157
Rhenium 2158
Rhodium .2159
116
-------�
Tin 2160
Titanium .2161
Samarium ฃ,162'
Scandium 2163
Vanadium 2164
Silicon 2165
' i: >"
Silver 2166
Zinc 2167
Strontium 2168
Sulfur 2169
Tantalum 2170
Tellurium 2171
Terbium 2172
Thallium 2173
Thorium 2174
Thulium 2175
Rubidium 2176
Ruthenium 2177
Tungsten 2178
Uranium 2179
Potassium 2180
Xenon 2181
Ytterbium 2182
Yttrium 2183
Sodium 2184
Zirconium 2185
117
-------�
Group VII Compounds and Ions 22
Bromide ion 2201
Fluoride ion 2202
Chloride ion 2203
Iodide ion 2204
Chlorate ion 2205
Perch!orate ion 2206
Brornate ion 2207
Sodium chloride 2210
Potassium chloride 2211
Calcium chloride 2212
Ammonium chloride 2213
Aluminum chloride 2214
Sodium bromide 2230
Potassium bromide 2231
Sodium iodide 2250
Potassium iodide 2251
Potassium fluoride 2270
Sodium fluoride 2271
Sodium fluorosilicate 2275
Calcium fluorosilicate 2276
Group V Compounds and Ions 23
Ammonium ion 2301
Cyanide ion 2304
Nitrate ion 2306
Nitrite ion 2309
118
-------�
Hydrazine 2310
Hydrazoic acid 2311
Ammonium chloride 2320
Ammonium nitrate 2321
Ammonium sulfate 2322
Phosphoric acid 2340
Calcium phosphate 2341
Phosphorous pentasulfide 2342
Phosphorus pentoxide 2343
Phosphate ion 2345
Hydrogen phosphate ion 2346
Dihydrogen phosphate ion 2347
Group VI Compounds and Ions 24
Sulfide ion 2401
Sulfuric acid 2402
Sulfate ion 2403
fhiosulfate ion 2404
Sulfite ion 2410
Ferrous sulfide 2411
Ferric sulfide 2412
Ferrous sulfate 2413
Ferric sulfate 2414
Barium sulfate 2415
Chromium trioxide 2417
Sodium dichromate 2418
Zinc oxide 2430
Aluminum oxide 2431
Water 2450
119
-------�
Group IV Compounds and Ions 25
Carbonate Ion 2501
Bicarbonate ion 2502
Carbon boride 2510
Silicon carbide 2511
Silicate ion 2550
Silicon dioxide 2551
Ac ids .and Bases 26
Total acidity H+ 2601
Hydrogen ion concentration pH 2602
Nitric acid 2605
Hydrochloric acid 2606
Total alkalinity 2650
Hydroxide ion concentration 2651
Calcium hydroxide 2653
Organo-Metallic Compounds and Ions 27
Miscellaneous 28
Aliphatic Compounds 6
Gross Hydrocarbons . 61
Hydrocarbons 62
Heptane 6201
Octane 6202
Nonane 6203
Decane . 6204
Undecane 6205
Dodecane 6206
120
-------�
Tridecane 6207
Tetradecane 6208
Pentadecane 6209
Hexadecane 6210
Heptadecane 6211
Octadecane 6212
Nonadecane 6213
Eicosane 6214
' Hemeicosane 6215
Docosane 6216
Tricosane 6217
Tetracosane 6218
Pentacosane 6219
Hexacosane 6220
Heptacosane 6221
Octacosane 6222
Cyclohexane . 6223
Cycloheptane 6224
Cyclooctane 6225
Heptene-1 6226
Octene-1 6227
Alcohols and Ethers 63
Butyl alcohol . 6301
jso^-butyl alcohol 6302
sec_-butyl alcohol 6303
tert-butyl alcohol 6304
121
-------�
jv-amyl alcohol 6305
JStOj-amyl alcohol 6306
tert-amyl alcohol 6307
n.-hexyl alcohol 6308
Cyclohexanol 6309
rv-octyl alcohol > 6310
Capryl alcohol (octanol-2) 6311
Decyl alcohol 6312
Lauryl alcohol 6313
Myristyl alcohol ;6314
Cetyl alcohol 6315
Stearyl alcohol 6316
Di-nrbutyl ether 6340
D1-jv-amy1 ether 6341
Di-jjjฃ-amyl ether .6342
Di-iv-hexyl ether 343
Di-chloromethyl .ether 6344
Di-(3-chloroethyl) ether :6346
Ethylene glycol dimethyl ether ฃ347
Divinyl ether ฃ348
Diallyl ether ฃ349
Carboxylic Acids and Esters -64
Prooionic acid ฃ401
N-butyric acid ฃ402
jso_-bytyric acid ' ฃ403
rv-valeric acid . ฃ404
122
-------�
Trimethylacetic add 6405
Caproic acid 6406
jl-heptylic acid $407
Caprylic acid <6408
Pelargonic acid 6409
Fluoroacetic acid ฃ410
Chloroacetic acid ฃ411
Bromoacetic acid 6412
lodoacetic acid 6413
Dichloroacetic acid ' 6414
Trichloroacetic acid 6415
o-chloropropionic acid 6416
3-chloropropionic acid 6417
Glycolic acid 6418
.Lactic acid 6419
Methoxyacetic acid 6420
.Thioglycolic acid 6421
Cyanoacetic acid 6422
Glyoxylic acid 6423
Acrylic acid 6425
Vinylacetic acid 6426
Pheynlacetic acid 6427
Formic acid 6428
Acetic acid 6429
Crotonic acid 6430
Oxalic acid 6431
123
-------�
Malonic acid 6432
Succinic add 6433
Glutaric acid 6434
Adi pic add 6435
Pimelic add 6436
Suberic acid 6437
Azelaic acid 6438
Sebacic acid 6439
Aldehydes and Ketones 65
Caproaldehyde 6501
Heptaldehyde 6502
Hexanone-2 6504
Hexanone-3 6505
Di-jv-propyl ketone 6506
Di-^so_-propyl ketone 6507
Di-jjsp_-butyl ketone 6508
Di-n^amyl ketone 6509
Stearone 6510
Chloroacetone 6511
Dichloroacetone 6512
Acetylacetone 6513
Mesityl oxide 6514
Phorone 6515
Cyclohexanone 6516
Acrolein 6517
124
-------�
Other Oxygen Compounds 66
Nitrogen Compounds 67
Tri-rv-propylamine 6701
Hexylamine 6702
Laurylamine 6703
Trimethylenediamlne 6704
Tetramethylenediamine 6705
Pentamethylenediamine 6706
Hexamethylenediamine 6707
Ethanolamine 6708
Diethanolamine 6709
Triethanolamine 6710
Acrylonitrile 6711
Halogen Compounds 68
Methylene Iodide 6801
Bromoform 6802
Carbon tetrabromide 6803
Ethylene d1bromide 6804
1,1-d1bromoethane 6805
1,1,2,2-tetrachloroethane 6806
Hexachloroethane 6807
l,3-d1bromopropane 6808
1,4-d1bromobutane 6809
1,5-dibromopentane 6810
l,6-d1bromohexane 6811
125
-------�
Miscellaneous 69
Aromatic Compounds 7
Simple and Gross Hydrocarbons 71
Benzene 7101
Toluene 7102
Ethyl benzene 7103
n-propylbenzene 7104
j_sp_-propyl benzene 7105
iv-butyl benzene 7106
sec_-butyl benzene 7107
tejrt-butyl benzene 7108
Styrene 7109
Ally!benzene 7110
p_-xylene 7111
rn-xylene 7112
ฃ-xylene 7113
p_-ethyl toluene 7114
nv-ethyl toluene 7115
ฃ-ethyltoluene 7116
p_-cymene 7117
Oj-di ethyl benzene 7118
m_-di ethyl benzene 7119
ฃ-diethyl benzene 7120
lป2,3-trimethylbenzene (hemimellitene) 7121
1,2,4-trimethylbenzene (pseudocumene) 7122
1,3D5-trimethylbenzene (mesitylene) 7123
126
-------�
1,2,3,4-tetramethylbenzene (prehnltene) 71E4
1,2,3,5-tetramethylbenzene (Isodurene) 7125
1,2,4,5-tetramethylbenzene (durene) 7126
Pentamethylbenzene 7127
Hexamethylbenzene 7128
1,3,5-triethyl benzene 7129
Diphenylmethane 7131
Triphenylmethane 7132
Tetraphenylmethane 7133
Stilbene 7134
1,1-diphenylethane 7135
T,2-diphenylethane 7136
Diphenyl 7137
ฃ-terphenyl 7138
ฃ-quaterphenyl 7139
1,3,5-triphenylbenzene 7140
Naphtalene 7141
o-methylnaphthalene 7142
B-methylnaphthalene 7143
Indene 7145
Azulene 7146
Acenaphthene 7147
Acenaphthalene 7148
Fljorene 7149
Phenanthrene 7150
Anthracene 7151
2-methylanthracene 7152
127
-------�
Complex Hydrocarbons 72
Fluoranthene 7201
8-methylfluoranthese 7202
Pyrene 7204
1-methylpyrene 7205
4-methylpyrene 7206
2,7-dimethylpyrene 7207
Chrysene 7208
Anthanthrene 7210
Coronene^ 7211
Perylene 7212
Naphthacene 7213
Benzo(c)phenanthrene 7214
Benzo(a)anthracene 7215
11-h Benzo(b)fluorene 7216
11-h Benzo(a)fluorene 7217
7-h Benzo(c)fluorene . 7218
Dibenzo(a,i)fluorene 7219
Benzo(b)fluoranthene 7220
Benzo(g,h,i)fluoranthene 7221
Benzo(j)fluoranthene 7222
Benzo(k)fluoranthene 7223
Benzo(e)pyrene 7224
Naphtho(2,3-a)pyrene 7226
D1benzo(a,e)pyrene 7227
D1benzo(a,i)pyrene 7228
128
-------�
Dibenzo(a,h)pyrene 7229
Dibenzo(b,h)phenanthrene 7230
D1benzo(a,h)anthracene 7231
Tribenzo(a,c,h)anthracene 7232
Benzo(a)naphthacene 7233
Dibenzo(a J)naphthacene 7234
Dibenzo(a,j)naphthacene 7235
Dibenzo(a,c)naphthacene 7236
Benzo(g,h,i)perylene 7237
Dibenzo(b,p,g,r)perylene 7238
Benzo(a)pyrene 7242
Phenols and Ethers 73
ฃ-cresol 7301
m-cresol 7302
ฃ-cresol 7303
ฃ-chlorophenol 7304
m-chlorophenol 7305
ฃ-chlorophenol 7306
ฃ-bromophenol 7307
in-bromophenol 7308
ฃ-bromophenol 7309
ฃ-nitrophenol 7310
jn-nitrophenol . 7311
ฃ-m'trophenol 7312
2,4-dinitrophenol 7313
3,5-dinitrophenol 7314
129
-------�
Resorcinol 7315
Hydroquinone 7316
Catechol 7317
Pyrogallol 7318
Phloroglucinol 7319
Anisole 7340
Phenetole 7341
Diphenyl ether 7342
p_-anisidine 7343
ฃ-anisidine 7344
Carboxylic Acids and Esters 74
Aldehydes and Ketones 75:
Xanthen-9-one 7501
7h-benzo(d,e)anthracene-7-one(benzanthrone) 7502
Phenalen-1-one 7503
Other Oxygen Compounds 76 .
Nitrogen Compounds 77
Aniline 7701
p_-phenylenediamine 7702
m_-pheny1enediamirie 7703
ฃ-phenylenediamine 7704
p_-anisidine 7705
ฃ-anisidine 770$
pj-chloroaniline 7797
m-chloroaniline 7708
ฃ-chloroaniline 7709
130
-------�
Oj-tolu1dine 7710
jn-toluidine 7711
ฃ-toluidine 7712
Dlphenylamine 7713
Trlphenylamine .7714
Benzidine 7715
Halogen Compounds 78
Miscellaneous 79
Heterpcycllc Compounds ' 8
Nitrogen Compounds 81
Pyridine 8101
ce-picoline 8102
e-picoline 8103
Y-picoline 8104
Quincline 8105
Isoquinoline 8106
Quinaldine 8107
Indole 8108
Acridine 8109
Carbazole 8110
Benzo(f)quinoline 8111
Benzo(h)quinoline 811?
Phenanthridine 8113
131
-------�
Benz(a)acr1d1ne 8114
Benz(c)acr1d1ne 8115
llh-benzo(a)carbazole 8116
5h-benzo(b)carbazole 8117
7h-benzo(b)carbazole 8118
D1benz(a,b)acr1d1ne 8119
D1benz(a,j)acr1d1ne 8120
Benzo(l,m,n)phenanthr1d1ne 8121
Indeno(l ,2,3-1 ,J)isoquinol1ne 8122.
9-acridanone 8123
Oxygen Compounds '82
Benzofuran 8201
Dibenzofuran 8202
Furfural 8203
Sulfur Compounds 83
Nitrogen and Oxygen Compounds 84
Sulfur and Oxygen Compounds 85
Sulfur and Nitrogen Compounds 86
Other 87
132
-------�
APPENDIX D
SAMPLE COMPLETED
DATA INPUT -SHEETS
133
-------�
STATIONARY POINT SOURCE
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-------�
STATIONARY POINT SOURCE
Page 1 of .5
h-1
CO
in
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Test Series
No.
1
(
y
FINE PARTICULATE EMISSION INFORMATION SYSTEM
DEV,CE(S) CHARACTER.STICS ' ฐATA 'NPUT FฐRMS
Sub
Series
No.
/
Run
No.
It
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Test Ser
No.
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16
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STATIONARY POINT SOURCE
Page 3 of 5.
D -
FINE PARTICULATE EMISSION INFORMATION SYSTEM
DATA INPUT FORMS
- TEST CHARACTERISTICS
Test Ser
No.
,
'es
/
O
Sub
Series
No.
/
Run
No.
10
/
Cord
No.
II
D
12
0
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No.
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D
12
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No.
11
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No.
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12
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5
6
7
8
9
0
14
14
14
14
14
r
15
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15
15
15
15
Control Device nlet or Outlet (1 or
Test Sub Series
Date
Mo
16
/
17
2
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IB
0
19
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16
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22
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26J27
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28
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60
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65
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66
67
68
69
70
71
72
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46
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50
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61
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56
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59
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60
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62
63
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32
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39
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-------�
STATIONARY POINT SOURCE
Poge 4 of 'j_
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FIMC PARTICULAR EMISSION 1 N F O F ,'.', A II O N SYSTEM iForm Prepored by
DATA IN PUT FORMS
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-------�
STATIONARY POINT SOURCE
Page 5 of 1
I -
MEASUREMENT
Test Series
No.
1
/
*i
PARTICULARS
Sub
Series
No.
I
Run
No.
10
/
J
Card
No.
11
I
12
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1
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M
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12
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II
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12
13
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14
15
15
F
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Measurement Instrument/Method No
Measurement Instrument/Method Name
/3
A
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16
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20J2I
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Time
18
19
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20|21
22| 23
i |/j51
Comments on
16
17
IB
19
20
24
26
27
28
111
PARTICULATE EMISSION INFORMATION
D*TA INPUT FORMS
**
29J30 31 32 33J34 I35J36
|
Aerosol ^JL.
Flow Rote
25J26
i
the Measurement
21
22
23
24
25
26
27
28
/
29
^
30
7
1 :
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Meps,
Temp .
3IJ32b3|34
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37
38
39
40
41
42
.onditions at
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35
Press.
36 1 37138
7'6
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40
41
42
?A7
43
44
45
43|44
I
45
SYSTEM
Size Range
Lower
46 47 48 49 5
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0 51
52
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53
54
55
Collection
56
57)58
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60
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61
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64
Form Prepared by
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65 A6i67J68
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67
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Dilution,^
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76 77J78 r* K
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Comments on the Measurement
Idi 47|48i49lso|5l IS2J53J54
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55
56
57
58
59
WlelJ
62
63J64 65l66J67<68|69l7oi7li73
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1
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74J75 76 77|78 IM 9C
i ! 1 '
{continued}
27
28
29
30
31 32 33J34
!
35
36
37
38
39
40
41
42
43
44
45
46 47 48 49 5
0 51
52
53
54
55
56
57
58
59
60
61 !a2|63 164 |65
66
67I6B
69
70|71 J72
73
74
75
76 J77 78 |7"ec-
1 1
] - PARTICULATE SIZE DISTRIBUTION DATA
Test Series
No.
1 j 2 i 3J 4| 5
1 | \i\a
Sub
Serie*
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6
7
8
^
Run
No.
9
10
/
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1
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15
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21
22
23
Mass/Number (1 or
16
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21
\
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24
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25
26
27
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28J29I30J31
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24
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26
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31
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48
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50
52
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-------�
STATIONARY POINT SOURCE
Poge 1 of 5
I - MEASUREMENT PARTICULARS
h-1
UJ
Test Series
No.
'! 2 | 3l 4' S
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Sub
Series
No.
6! 7| 8
i /
Run
No.
9 [ 10
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1 1
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12
0
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1
12
0
13
3
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14
14
14
"
15
15
15
FINE
PARTICULATE EMISSION INFORMATION SYSTEM Form Prepared by
DATA INPUT FORMS
Measurement Instrument/Method No.
Measurement Instrument/Method Nome
16
17
Meas.
Start T
16
L
17
0.
8 19
> me
8 19
to
20
21(22
23
24i:s|26
Period
20
21
22! 23
24
27
Aerosol
Flow Rate
25
26
Comments on the Measurement
16
17
8 19|20
21
22
J3
24
25
26
27
28
**
11
i
(cont
27
28
: ; i
431 44
Gas Conditions at
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31 32J33
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29
30
31 32
33
34 :ซ 36 |37
i1 :
34 35 36 37
. ** % H2'6
28 39 40 41
tffA
42
L
43J44
45
Size Range
Lower
ซ[49 50
i
1
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51 1 52 | 53 54 | 55
Collection Surface/Substrate Factor
5615758 59 60 61 62J63I64.&5 66!ป7 68,1)7 70| 7; \ 7?!73 '74 . 7; ~t 77 'S :-y.
i i i ; ! : . , ; : A
Comments on the Measurement
46
47
38 39 40 41
42
43
44
45
44
47
48
49
44
49
50
51 52
50
51 52
53(54 55
54 57 58 59 60 61 62 63 64J65 ซ'6?| 66 69 70; 71 ' 77 73 74 75 76 ' 77 78 79 8C
III ! : :
53 54 55
56 57 58 59 40 61 62 63 64 65 64 47 6S 49 70|7I 77173 !?4 7! !?6 '77(78 79 -1C
! ! ! i i :
J - PARTICULATE SIZE DISTRIBUTION DATA
Test Series
No.
_!_
2 1 3 U! 5
Sub
Series
No.
i7
Run
No.
2
Card
No.
J
J
J
12| 13
oi i
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2
3
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No.
11
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14
7
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r
15
7
16
Aerodynamic/Stoke
17
18 19
20
.
.
21
23
Mass/Number (1 or
!
2
IB; 19
r
-------�
D - TEST CHARACTERISTICS
STATIONARY POINT SOURCE
FINE PARTICULATE EMISSION INFORMATION SYSTEM
DATA INPUT FORMS
Poge 3 of .5
Form Prepared by
Test Series
No.
l
2
3
4
1
5
v
Sub
Series
No.
6
7
B
2
Run
No.
9
10
f
Card
No.
tl
D
12
0
13
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Card
No.
II
D
12
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13
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1 1
15"
12
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3
Card
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11
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12
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D
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16
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17
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18
V
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20
7
Feed Materio
16
17
18
19
20
21
M
21
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22
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23
$
24
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Slop
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26
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27
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28
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30
3,
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33
34
35
36
28
29
30
31
32
33
34
35
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37
37
38
38
39
40
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51
52
53
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56
59
Source Operating Rote;
60
61
62
63
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49
50
51
52
53
54
55
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17
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19
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35|36
35
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37
38
39
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55
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57
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59
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62
63
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63
64
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66
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66
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68
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69
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54
55
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56
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60
61
67
63
64
65
-
66
-
67
68
69
70
71
77
73
74
75
76
77
7ซ
79>80
E - PARTICULATE MASS TRAIN RESULTS
Test Series
No.
1
7
3-
4
/
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i
Sub
Series
No.
6
7
8
2,
Run
No.
9
10
/
Cord
No.
II
E
12
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13
1
14
15
Front Half
16
17
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18
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19
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20
4
21
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I
73
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25
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Total
26
27
2
28
79
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30
6
31
7
32
E
33
+
34p5
Moss Train Comments (Text)
.16
37
38
39
40
41
47
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
74J 75
1
76
77 78 7?!tO
I
F - PARTICULATE PHYSICAL PROPERTIES
Test Series
No.
1
2
3
4
/
5
i
Sub
Series
No.
6
7
8
2
Run
No.
9
10
/
Card
No.
u
F
12
0
13
1
14
15
,v
Density
16
17
18
19
20
Determination
-V
Resistivity
21
2
22
23
4
24
25
+
26
f
27
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29)30
*
Other Physical Properties in Text
31
32
33
34
35
.16
37
38
39J40
|
4IJ42 |43
44
45
46
47
48
49
50
51J52
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66
67
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-------�
STATIONARY POINT SOURCE
Page 1 of 1
I -
MEASUREMENT PARTICULARS
Test Ser
No.
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Series
No.
2
Run
No.
J
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Measurement
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MzJJfi,
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San
Per
FINE PARTICULATE EMISSION INFORMATION
DATA 1 NPUT FORMS
Instrument/Method No.
njrrument/Method Name
A/
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Aerosol
Flow Rate
Comments on the Measurement
!ซ 17 18J19
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29
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53
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56
57 58 59 60161 62 63 j 64 65 64J67 A
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1 ! : i
} - PARTICULATE SIZE DISTRIBUTION DATA
Test Series
No.
I
? 3 4 | 5
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6
7
8
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No.
9 llO
Jy.
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-------�
STATIONARY POINT SOURCE
Page 5 of 5
to
I -
MEASUREMENT PARTICULARS
Test Ser
No.
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No.
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Run
No.
10
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1
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PARTICULATE EMISSION INFORMATION SYSTEM
DATA INPUT FORMS
**
29J30I3I 32T33
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31 32 33
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46
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47 4.
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8 49
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51
52
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54
55
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56 57 58 59 60 61 62
63
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46
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6 77 78 .79'eO
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6 77178 79-80
} - PARTICULATE SIZE DISTRIBUTION DATA
Test Series
No.
l
2
3
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Sub
Series
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10
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11
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24
25
26
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+
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35
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33
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37
7
38
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40
41
42
43
44
4546
65
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Mass/Nun
+
140
41
42
o
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43
44
45
46
'47
**
ize Data
48
49
50
51
52
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53
54
55
riber Data
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48
49
50
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51
52
53
54 55
56
57
58
59
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61
62
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56
57
58
59
60
61 ;62
63
64
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66|67|6Blซ9
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-------�
STATIONARY POINT SOURCE
Poge 1 of 1
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I - MEASUREMENT PARTICULARS
Test Ser
No.
1 1 2
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Sub
Series
No.
1
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No.
9 [lO
[3
Cord
No.
II
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12
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12
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No.
II
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12
0'
3
f
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14
ฃ
15
15
FINE
PARTICULATE EMISSION INFORMATION SYSTEM
' DATA INPUT FORMS
Measurement Instrument/Method No.
Measurement Instrument/Method Nome
16
C
M
SI
16
t
17
V
COS
art
17
o
18
19
20|2I
CL ft
Time
IB
4
19
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22
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23|24|25
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Sampling
Period**
20
Comments on
20
21
22
23 24
26J27
/L^
28
/
29l30J3l!32|33l34!3
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Aerosol
Flow Rate *"
25
26
1
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21
22
13 24
25
26
27
28
(cont
27
2B
29
30
5i36 3?|38
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Gos Conditior
Temp.*'^
31 32 33 34 3
39|40
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Press.**
S 36 371
38
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29
30
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36 37
38
39
40
41
42
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O
42
43 44
45
43
44
45
Form Prepared by
Size Range**
Lower
46
47
Com
46
47
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42
43
44
45
46
47
48
4,
50
Upper
51 52
A
53 5-
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55
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Collection Surface/Substrate Factor -
56 57 58 .591 60 61 62J63 44 65 1 66J67 | 68|69 70J 71 77|?3 74 75 76|77|78 -TV'.X
i i 1 1 i 1 ! - ' /A
nentj on the Measurement
46
C
48
49
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49
50
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5i Is;! 53(54
50
[51^52
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53 it
5S|54 575859 60 61 i 62 63 J64 65 66 6?| 6ซ|69 | 7ol 71 1 73>73 l?4 !,'! |76 i 77I7J :79'8C
rtk CHAMeL 8AT\7C^r i : : ! ~
55
56 57 58 59 60 61 42 63 44 65 64 67 j 48 \69 70 j 71 77 73 1 74 75 l?6 ! 77 178 1 79 '80
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-'
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No.
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Series
No.
6
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Run
No.
9
10
Cord
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Aerodynomic/Stoke
16
17
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16
17
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21
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24
25
26
27
28
29
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30 31
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27
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28
29
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32
33
34
35
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39
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34135
6
36
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37
39
L.
39
5
Particle '
40
41
42
43
44
45
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46
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47
4
Mass/Nur
*
40
41
f
42
43
4-
44
45
44
f
47
ฃฃ
ize Data**
48
49
50
51
52
53|54
no
55
V
nber Data
48
49
50
51
52
53
54
55
54
57
58
59
60
6,
1
!
54
57
58
59
60
42
43
61
62163
64J65J44
64
67
6B|49
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4-
65 ^66l67;4e!49!70!7l
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77
78 179
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75 176 '77 781-
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**/ Need not be filled if the preceding subseries or run with this instrument contains the same data.
/o
-------�
TECHNICAL REPORT DATA
(Please read Inancrions on the reverse before completing!
1. REPORT NO.
EPA-60Q/7-77-001
2.
3. RECIPIENT'S ACCESSION NO.
4. TITLE AND SUBTITLE
Proceedings: Fine Particle Emissions Information
System User Workshop
5. REPORT DATE
January 1977
6. PERFORMING ORGANIZATION CODE
7. AUTHOR(S)
M. P. Schrag (Editor)
8. PERFORMING ORGANIZATION REPORT NO.
9. PERFORMING ORGANIZATION NAME AND ADDRESS
Midwest Research Institute
425 Volker Boulevard
Kansas City, Missouri 64110
10. PROGRAM ELEMENT NO.
EHE623
11. CONTRACT/GRANT NO.
68-02-1324, Task 46
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
Proceedings; 2-8/76
14. SPONSORING AGENCY CODE
EPA-ORD
15. SUPPLEMENTARY NOTES iERL_RTP Task officer for this document is G. L. Johnson, 919/
549-8411 Ext 2745, Mail Drop 63.
16. ABSTRACT
proceedings document a User Workshop for the Fine Particle Emissions
Information System (FPEIS), sponsored by EPA's Industrial Environmental Research
Laboratory (DSRL-RTP) and held June 15, 1976, at EPA's Environmental Research
Center, Research Triangle Park, NC. Purpose of the Workshop was to introduce the
user community to FPEIS. FPEIS is a computerized information system on fine
particle emissions from stationary sources and may contain source test data including
particle size distribution; chemical, physical, and bioassay testing results; design and
performance data on particle control systems; process descriptions; and descriptions
of the sampling equipment and techniques employed. The Proceedings contain the
text of the Workshop presentations, as well as that of the discussion period following
each presentation. The Workshop consisted of sessions on the background and pur-
pose of FPEIS, the database structure, the input data requirements, and the output
formats.
17.
KEY WORDS AND DOCUMENT ANALYSIS
DESCRIPTORS
b.IDENTIFIERS/OPEN ENDED TERMS
c. COSATI Field/Group
Air Pollution Size Determination
Aerosols Chemical Tests
Dust Physical Tests
Information Systems Sampling
Computer Programs
Tests Bioassay
Air Pollution Control
Stationary Sources
FPEIS
Particulate
Fine Particles
Source Test Data
13B
07D
11G
09B,05B
14 B
06A
18. DISTRIBUTION STATEMENT
Unlimited
19. SECURITY CLASS (This Report)
Unclassified
21. NO. OF PAGES
149
20. SECURITY CLASS (This page)
Unclassified
22. PRICE
EPA Form 2220-1 (9-73)
145
-------� |