&EPA
United States
Environmental Protection
Agency
Industrial Environmental
Research Laboratory
Research Triangle Park,
NC 27711
EPA-600/8-80-006
January 1980
Research and Development
Environmental Assessment
Data Systems
User Guide
Gaseous
Emissions
Data System
\
EADS GEDS
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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 nine series. These nine broad cate-
gories were established to facilitate further development and application of en-
vironmental technology. Elimination of traditional grouping was consciously
planned to foster technology transfer and a maximum interface in related fields.
The nine 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
8. "Special" Reports
9. Miscellaneous Reports
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-agency 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 sys-
tems. The goal of the Program is to assure the rapid development of domestic
energy supplies in an environmentally compatible manner by providing the nec-
essary environmental data and control technology. Investigations include analy-
ses 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 environ-
mental issues.
EPA 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 recommendation for use.
This document is available to the public through the National Technical Informa-
tion Service, Springfield, Virginia 22161.
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EPA-600/8-80-006
January 1980
Environmental Assessment Data Systems
User Guide:
Gaseous Emissions Data System
R. J. Larkin, Editor
Acurex Corporation
Energy & Environmental Division
485 Clyde Avenue
Mountain View, California 94042
Prepared for
EPA Project Officer — Gary L. Johnson
U.S. Environmental Protection Agency
Office of Research and Development
Industrial Environmental Research Laboratory
Research Triangle Park, NC 27711
Contract No. 68-02-2699
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DISCLAIMER
This report has been reviewed by the Industrial Environmental
Research Laboratory, U.S. Environmental Protection Agency, and approved
for publication. Mention of trade names or commercial products does not
constitute endorsement or recommendation for use.
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This page contains the publication and revision record of the GEDS User
Guide. The current revision status is indicated by the Schedule of
Document Control. As the guide is revised, the affected pages are dated.
Changes and additions to the guide are shown by vertical lines in the
margins. A bar near the page number indicates new pagination rather than
change of content. New pages are indicated by a dot near the page number.
SCHEDULE OF DOCUMENT CONTROL
Revision
Description
May 1980
Original issue.
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PREFACE
In the course of fulfilling its charter, EPA performs multimedia
environmental assessments of stationary sources of pollution and conducts
R&D programs to develop and demonstrate feasible control technology. Such
programs generate voluminous data, often according to different reporting
protocols and sampling and analysis practices. The Environmental Assessment
Data Systems (EADS) have been developed to consolidate the results of these
programs and others into one comprehensive information system. The EADS is
also designed to provide uniformity in reporting protocols and to supply
current information and methods for analyzing data.
The EADS is composed of four waste stream data bases and a number of
reference and support data bases. The waste stream data bases include the
Fine Particle Emissions Information System (FPEIS), the Gaseous Emissions
Data System (GEDS), the Liquid Effluents Data System (LEDS), and the Solid
Discharge Data System (SDDS). The FPEIS was the original data base in EADS,
having become operational in 1977, and is now a mature system containing
data from hundreds of stationary sources and serving the needs of a diverse
user community. The GEDS, LEDS, and SDDS were initiated in 1978 and are now
operational. The original FPEIS has concurrently been redesigned to conform
to the requirements of expanded multimedia testing, although existing data
in FPEIS will continue to be available to the user.
m
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A complete set of EADS documentation includes six publications --
one User Guide for each of. the four waste stream data bases, a Terminology
Reference Manual, and a Systems Overview Manual. This document, the GEDS
User Guide, gives instructions for the encoding of GEDS data sets and
defines procedures for submitting and retrieving data. It also describes
available software packages for analysis of GEDS data.
iv
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TABLE OF CONTENTS
Section Page
1 INTRODUCTION 1.0-1
2 DATA BASE DESCRIPTION . . . . 2.0-1
2.0 GEDS Structure 2.0-1
2.1 GEDS Organization and Contents 2.1-1
2.1.1 -Source and Test Series Related Information . . . 2.1-1
2.1.2 Control Device and Stream Design Conditions . . 2.1-6
2.1.3 Test Operating Conditions 2.1-6
2.1.4 Sampling Activity Information . 2.1-7
3 DATA ACQUISTION AND ORGANIZATION 3.0-1
3.0 Introduction 3.0-1
3.1 How to Build a Test Series 3.1-1
3.2 Data Input Form Structure 3.2-1
3.3 Structure Application Example 3.3-1
3.4 Special Encoding Considerations 3.4-1
3.4.1 Multimedia Test Series 3.4-1
3.4.2 Multiple Control Devices 3.4-2
3.4.3 Parallel or Series Control Devices 3.4-2
3.4.4 Fuels and Feedstocks 3.4-2
3.4.5 Data Accuracy and Quality 3.4-4
3.4.6 Source Assessment Sampling System 3.4-4
3.4.7 Effluent Characteristics 3.4-7
3.4.8 Reporting of Chemical Analysis Results 3.4-9
3.4.9 Reporting of Radionuclide Data 3.4-10
3.4.10 Bioassay Results 3.4-10
4 ENCODING INSTRUCTIONS FOR GEDS DATA INPUT FORMS .... 4.0-1
4.0 General Rules . 4.0-1
4.1 Labor Saving Features 4.1-1
4.1.1 Repetitive Data Feature . . 4.1-1
4.1.2 Control Device and Design Parameters 4.1-4
4.1.3 Operating Parameter Serial Number 4.1-4
4.2 Encoding Instructions ...... 4.2-1
5 DATA SUBMITTAL 5.0-1
5.0 Introduction 5.0-1
5.1 Data Lnput Form Processing 5.1-1
5.2 Submittal Procedures 5.2-1
5.3 Review and Corrective Action Procedures 5.3-1
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TABLE OF CONTENTS (Continued)
Section Page
5.4 EDIT/LOAD Programs 5.4-1
5.4.1 EDIT Program 5.4-1
5.4.2 LOAD Program 5.4-3
6 DATA RETRIEVAL 6.0-1
6.0 Introduction 6.0-1
6.1 Data Retrieval Using the Program Library 6.1-1
6.2 Special Data Retrieval Requests 6.2-1
6.3 Key/Non-key Data Elements 6.3-1
6.4 On-Line Request Procedures ; . . . 6.4-1
6.5 NCC User Qualifications and Services
Registration 6.5-1
6.5.1 Registration Procedures 6.5-]
6.5.2 User ID and Password 6.5-5
6.6 Interactive Terminal Operation .... 6.6-1
6.6.1 Initiating a Demand Processing Session 6.6-4
6.6.2 Terminating a Demand Processing Session .... 6.6-8
6.6.3 Accessing the EADS 6.6-9
6.7 Remote Batch Terminal Operation 6.7-1
6.7.1 Initiating a Remote Batch Processing Session . . 6.7-3
6.7.2 Terminating a Remote Batch Processing
Session 6.7-3
6.8 EADS User Support 6.8-1
7 PROGRAM LIBRARY 7.0-1
7.0 Introduction 7.0-1
7.1 SERIES Report 7.1-1
7.1.1 Applicability 7.1-1
7.1.2 Abstract 7.1-1
7.1.3 User Data Required 7.1-2
7.1.4 Data Qualification Required 7.1-2
7.1.5 Limitations/Restrictions 7.1-2
7.1.6 Functional Description 7.1-2
7.1.7 User Instructions ~ Demand 7.1-2
7.1.8 User Instructions -- Batch 7.1-4
7.1.9 Sample Demand Runs 7.1-5
7.1.10 Sample SERIES Report 7.1-5
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TABLE OF CONTENTS (Continued)
Section Page
7.2 Chemical Search Program (CHEM-SEARCH). ...... 7.2-1
7.2.1 Applicability . 7.2-1
7.2.2 Abstract 7.2-1
7.2.3 User Data Required 7.2-2
7.2.4 Data Qualification Required 7.2-2
7.2.5 Limitations/Restrictions 7.2-2
7.2.6 Functional Description 7.2-2
7.2.7 User Instructions — Demand 7.2-2
7.2.8 User Instructions « Batch 7.2-5
7.2.9 Sample Demand Runs . 7.2-7
7.2.10 Sample Batch Runs 7.2-13
7.3 Series Summary Information Program (SNAP-SHOT) . . 7.3-1
7.3.1 Applicability 7.3-1
7.3.2 Abstract 7.3-1
7.3.3 User Data Required 7.3-2
7.3.4 Data Qualification Required 7.3-3
7.3.5 Limitations/Restrictions 7.3-3
7.3.6 Functional Description 7.3-3
7.3.7 User Instructions -- Demand 7.3-3
7.3.8 User Instructions -- Batch 7.3-6
7.3.9 Sample Demand Runs 7.3-8
7.3.10 Sample Batch Runs 7.3-9
7.3.11 Sample Output 7.3-9
7.4 Biological Search Program (BIO-SEARCH) 7.4-1
7.4.1 Applicability 7.4-1
7.4.2 Abstract 7.4-1
7.4.3 User Data Required 7.4-1
7.4.4 Data Qualification Required 7.4-2
7.4.5 Limitations/Restrictions 7.4-2
7.4.6 Functional Description 7.4-2
7.4.7 User Instructions -- Demand 7.4-2
7.4.8 User Instructions — Batch 7.4-4
7.4.9 Sample Demand Runs 7.4-6
7.4.10 Sample Batch Runs 7.4-9
7.5 Radiological Search Program (RAD-SEARCH) 7.5-1
7.5.1 Applicability 7.5-1
7.5.2 Abstract 7.5-1
7.5.3 User Data Required 7.5-1
7.5.4 Data Qualification Required 7.5-1
7.5.5 Limitations/Restrictions 7.5-2
7.5.6 Functional Description 7.5-2
7.5.7 User Instructions -- Demand 7.5-2
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TABLE OF CONTENTS (Concluded)
Section Page
7.5.8 User Instructions -- Batch 7.5-4
7.5.9 Sample Demand Runs 7.5-6
7.5.10 Sample Batch Runs 7.5-8
7.6 Control Technology Search Program
(CONTROL-SEARCH) 7.6-1
7.6.1 Applicability 7.6-1
7.6.2 Abstract 7.6-1
7.6.3 User Data Required . 7.6-1
7.6.4 Data Qualification Required 7.6-1
7.6.5 Limitations/Restrictions 7.6-2
7.6.6 Functional Description 7.6-2
7.6.7 User Instructions — Demand 7.6-2
7.6.8 User Instructions -- Batch 7.6-5
7.6.9 Sample Demand Runs 7.6-6
7.6.10 Sample Batch Runs 7.6-10
APPENDIX
vm
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LIST OF ILLUSTRATIONS
Figure Page
2-1 EADS Structure 2.0-5
2-2 Waste Stream Data Base Structure 2.1-4
2-3 Organic Extract Summary Table 2.1-9
3-1 Waste Stream Data Base Structure and Contents 3.1-2
3-2 Forms Ordering 3.2-3
3-3 Data Structure — Gasification Plant 3.3-3
3-4 Source Assessment Sampling System 3.4-7
4-1 Repetitive Data Feature Structure . . 4.1-2
5-1 Sample Data Submittal Letter 5.2-2
5-2 Sample Data Submittal Acknowledgement Letter 5.2-3
5-3 QA Procedure 5.3-2
5-4 Sample EDIT Output 5.4-4
6-1 NCC Application 6.5-2
6-2 Request for Batch Terminal Support Form 6.7-2
ix
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LIST OF TABLES
Table Page
2-1 GEDS Data Elements and Their Levels 2.1-2
3-1 • Source Sampling Log -- Gasification Plant 3.3-2
3-2 Response Ranges for Ranking of Various Biotests .... 3.4-12
4-1 Engineering Units 4.2-33
4-2 Conversion Factors to Metric Units 4.2-35
6-1 List of Key Data Elements 6.3-2
6-2 Remote Interface Control Statements 6.6-5
6-3 NCC Demand Access Telephone Numbers 6.6-7
6-4 NCC Remote Batch Access Telephone Numbers 6.7-4
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CONTACTS
EADS Program Manager
EADS Technical Staff
Gaseous Emissions Data
System, Liquid Effluents
Data System
Gary L. Johnson (MD-63)
Industrial Environmental Research Laboratory
U.S. Environmental Protection Agency
Research Triangle Park, North Carolina 27711
919-541-2745
Barbara S. Ballard
Acurex Corporation
485 Clyde Avenue
Mountain View, California 94042
415-964-3200, Extension 3019
Fine Particle Emissions
Information System,
Solid Discharge
Data System
Software
or
Robert J. Lark in
Acurex Corporation
485 Clyde Avenue
Mountain View, California 94042
415-964-3200, Extension 3019
J. Patrick Reider
Midwest Research Institute
425 Volker Boulevard
Kansas City, Missouri 64110
816-753-7600
Nick Young
Acurex Corporation
Route 1, Box 423
Morrisville, North Carolina 27560
919-781-9704
XI
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SECTION 1
INTRODUCTION
The Environmental Assessment Data Systems (EADS) are a group of
independent computerized data bases which are interlinked to provide
common accessibility to data produced by a variety of EPA projects.
EPA-IERL/RTP's Environmental Assessment (EA) programs are expected to be
heavy contributors and users. Accordingly, the EADS has been structured
in a manner such that EA data can easily be. transferred to the input forms.
However, the structure is flexible and comprehensive enough so that data
from virtually any pollutant sampling and analysis protocol could be
included. The EADS is intended to accept data from either energy systems
or industrial processes. Often times these data are multimedia in nature.
Emissions could be fine particles, gases, liquids, solids, or any combination
all coming from the same industrial source. Because pollution controls are
developed on a media-by-media and pollutant-by-pollutant basis, EADS is
composed of media-specific data base systems. They are the Fine Particle
Emissions Information System (FPEIS), the Gaseous Emissions Data System
(GEDS), the Liquid Effluents Data System (LEDS), and the Solid Discharge Data
System (SDDS). This User Guide will instruct in the use of the GEDS. There
are companion User Guides for the other data bases (FPEIS User Guide, EPA
600/8-80-007, January 1980; LEDS User Guide, EPA 600/8-80-008, January 1980;
SDDS User Guide, EPA-600/8-80-009, January 1980).
1.0-1
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While independent, the four data bases are very similar in structure
and are interlinked. Interlinking is necessary to enable a control strategy
analyst or an R&D program planner to select the most environmentally acceptable
control methods on a systems basis. When one considers the objectives and
scope of today's investigative and iterative environmental studies, it is easy
to see why interlinking is necessary. Environmental Assessments, for example,
are intended to determine comprehensive multimedia environmental loadings and
compare them to existing emissions and ambient standards. Resulting health,
ecological and environmental effects, and cross-media impacts and trade-offs
are also assessed. It is necessary and useful to examine and compare emissions
across all media from a specific source.
For example, to evaluate the total environmental impact of a flue gas
scrubber installation on a coal-fired boiler, you would need to sample and
analyze a variety of effluent streams from different media. Among these might
be the boiler bottom ash, the flue gas into and out of the scrubber, and the
liquid slurry produced from the scrubber treatment of the flue gas. These
would be solid, gaseous and liquid effluents, respectively, all. from one
source. The EADS (FPEIS, GEDS, LEDS, and SDDS) is designed to characterize
these emissions by providing data on the factors affecting their generation,
modification, sampling, measurement, and analysis. The data base system is
designed so that one can encode and retrieve information regarding a specific
test, a specific source, a specific control device or treatment process, and a
specific pollutant, as well as a large array of other data elements that may
be of interest to the user.
The EADS can accommodate partial data. The number of parameters
measured in a test depends upon the objectives of the testing program. It is
possible that certain source tests will not have all the data which the EADS
1.0-2
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is designed to contain, nor is the EADS intended to suggest or dictate the
details of a test program. For example, in a given testing program, all
the tests may be made at only the inlet or outlet, and the chemical
analysis or bioassay results may or may not be conducted. It is also
likely that some of the control technology design and operating parameters
may not be reported. Even if there are missing data, the available data
will be of use and should be reported.
Reading this manual may suggest that EADS is bound, even
constricted, by numerous operational rules. In any computerized system
there must be rules; once understood, they facilitate the job of data
encoding. It must be stressed, nevertheless, that flexibility has been
built into EADS. This will be shown in succeeding sections of this User
Guide. ^
Data from sources or sites for which the company name, location,
etc., are or should remain confidential can also be accommodated. The
encoding of data from confidential sources is discussed in Section 4 of
this User Guide and the EADS Systems Overview Manual (EPA-600/8-80-005,
January 1980).
The GEDS system contains industrial or energy process source
emissions test data and related source and control system design and
operating data. It attempts to comprehensively describe the gaseous
emissions at the point from which the gaseous sample is collected from the
gas stream. General groups or categories of information include source
characteristics, discharge stream characteristics, control device or
treatment process information, process conditions, test information,
analyses of the fuels and feedstocks, sampling activity information,
inorganic and organic chemical analyses, radionuclide analyses, and
1.0-3
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bioassay results. Each group of information includes a number of related
data elements, each of which is a unique variable essential for the
description of the source tested.
A uniform protocol for units and terminology has been developed
along with standard data input forms, output report formats and analytical
software. Each data element in the system has been defined in detail for
^
clarity. These standards and definitions will allow all data in the
system to be stored or retrieved on a common basis.
The 6EDS has been implemented at the Environmental Protection Agency
(EPA) National Computer Center (NCC) at Research Triangle Park, on the
UNIVAC 1100 computer, using SYSTEM 2000®. SYSTEM 2000® is a data
base management system developed by the Commercial Systems Division of
INTEL, Inc. It will provide users with a virtually unlimited potential
for data analysis. Features of SYSTEM 2000vv include sorting,
comparing, and retrieving information from the 6EDS data base in a variety
of arrangements.
There are two companion documents to the GEDS User Guide: the EADS
Systems Overview Manual (EPA-600/8-80-005, January 1980) and the EADS
Terminology Reference Manual (EPA-600/8-80-011, February 1980). A
complete set of EADS documentation would include User Guides for the
liquid, fine particle and solid discharge data bases (LEDS, FPEIS and
SDDS, respectively) as well. The EADS Systems Overview Manual contains a
broad-based description of the purposes and scope of the EADS, a discussion
of its organization, and descriptions of the EADS reference data bases and
user software. The EADS Terminology Reference Manual is a general
reference manual on the terminology used to enter and retrieve information
from the EADS waste stream data bases. These manuals are designed with
1.0-4
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discrete segments for major sections and subsections. As changes, additions,
and expansions of the system and the informational capabilities are made,
the manuals will be updated as appropriate.
Section 2 describes the structure, organization and contents of the
GEDS. Section 3 demonstrates an application of a sampling activity to the
GEDS structure and how data should be organized for an encoding effort.
Encoding instructions are given in Section 4. Section 5 describes
procedures required after data has been encoded and is being submitted for
inclusion in the GEDS. Section 6 describes the steps for on- and off-line
data retrievals. User output analysis packages are enumerated in
Section 7 -- Program Library. Users should become thoroughly familiar
with the contents of this document before attempting to encode data.
1.0-5
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SECTION 2
DATA BASE DESCRIPTION
2.0 GEDS STRUCTURE .
The discussion in this section is intended to introduce the new
EADS user to the data base. The main objective is to familiarize the user
with the fundamental structural components of the data base and how they
are assembled to form a structural hierarchy. While this User Guide is
for GEDS only, the user should realize that each of the four data bases
that comprise EADS (GEDS, FPEIS, LEDS and SDDS) are structured in an
identical manner. Naturally, though, certain data elements will be
specific to one media only. Consequently there will be detail differences
between data bases, but not structural differences.
The structure of the GEDS data base presents and organizes a
comprehensive set of data which describes the conduct, techniques,
conditions and results of stationary source emission sampling and analysis
activities. Each variable or bit of data or information concerning the
source test is defined as a data element. The completeness of information
for any given source test within the data base is limited only by the
completeness of the test report or original test data from which the GEDS
input was derived.
Before continuing on in this section, the user should become
familiar with certain terms used throughout the EADS documents. These
t
2.0-1
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terms form the structure upon which all of the EADS waste stream data
bases are based. Many of the terms will probably be familiar, but others
such as "test" may, in the context of EADS, have definitions that are
slightly different from the typical definition. In order to maintain the
integrity of the EADS data, it is imperative that these definitions are
understood and properly used.
media — Used in reference to an effluent stream from a
stationary source. May be either fine particle,
gaseous, liquid, or solid.
source -- A source may be either an industrial or energy
conversion facility. It is the origin of one or more
multimedia effluent streams. An oil refinery and a
coal-fired powerplant would each be examples of a
source.
stream ~ Any multimedia effluent discharging to the environment
from a stationary source.
control device/treatment process — A device or process designed to
remove a specific pollutant or pollutants from an
effluent stream.
control system — Frequently a discharge stream is controlled by a
number of control devices which may be in either a
series or parallel arrangement. The total group of
control devices on that stream is referred to as the
control system.
2.0-2
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level — A data base structural term used to differentiate
groupings of data within the data base. The EADS
contains four structural levels: the test series
level, the stream design level, the test operating
level, and the sample level.
test series — Taken in its broadest context, a test series
designates the sampling activities performed at a
single source over a specified period of time (usually
continuous) with a specific control system employed.
test ~ A set of various types of samples taken to characterize
a source waste stream(s) under one set of source and
control device/treatment process operating conditions.
sample — The measurement or group of measurements taken with a
single measurement method or instrument to describe the
composition of a stream at a given point in time and at
a specific location.
component -- Frequently a measurement instrument can be separated
into two or more components, each of which contains a
sample which may be analyzed separately or combined.
For example, an EPA Method 8 train will collect one
sample (in the EADS context) which can be divided into
two components. The probe, filter, and first impinger
contents would be defined as one component and be
analyzed for sulfuric acid mist. The contents of the
second and third impingers would constitute the second
component and be separately analyzed for sulfur dioxide.
2.0-3
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Several data elements or information items are required to adequately
describe the groups of information which are contained within the GEDS.
These groups are discussed in the EADS Systems Overview Manual and in greater
detail in this section. Also, the reader may wish to refer to the Data Base
Definition (a computer listing of all data elements) and the Data Base Tree
(a graphical presentation of the major groups of information contained in
the data base) in Appendix A.2. From an organizational standpoint, the
various data elements are grouped in one of four levels: the test series
level, the stream design level, the test operating level, and the sample
level. These levels and their relationship are shown in Figure 2-1.
The term "test series level" is used to designate the uppermost level
in the data base structure. This is where source description data are
contained. A single "test series" is composed of all data in the four
structural levels, the first of which has been designated the "test series
level". A test series designates the sampling activities performed at a
single site over a specified period of time (usually continuous) with a
specific control system employed. Each test series is assigned a unique
Test Series Number (TSN) which can always be used to identify that data. It
is possible that certain tests may involve changes to the process which may
make the use of multiple test series more appropriate. This is entirely at
the discretion of the encoder. The encoder should do whatever seems most
convenient and logical. The following examples will illustrate this point.
Suppose a utility boiler is tested under two sets of NO control
A
techniques; one technique is called burners-out-of-service and the other,
biased burner firing. One test is performed using each control technique
individually. The encoder would probably find it most convenient to assign
a unique Test ID Number to each test within one test series, rather than
2.0-4
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Source
Test
Series
Level
Stream
Design
Level
ro
Test
0
in
Testl
1
Sample 1
Sample 2
I
Sample 3
Test 2
Sample 1
Test3
Sample 1
Sample 2
Tesll
I
Sample 1
Sample 2
Operating
Level*
Sample
Samp,e 1 LeVel
'Each test could be at a different process (source) operating condition.
Figure 2-1. EADS structure.
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assigning each test to a separate test series. Because these two control
techniques do not have appreciable design differences, there is no reason to
call them different control systems, and thus assign them to different test
series. Now suppose a utility boiler is equipped with a pilot scale scrubber
which can be altered in the field to become two different generic design
types -- a venturi type and a TCA type scrubber. Because design conditions
of the control system are now different, it would be more appropriate to
assign those control types to two different test series rather than two
tests within one test series.
The level following the test series level is the stream design level.
Here, each waste stream that has been sampled during the test series is fully
described with regard to design parameters. These include control device(s)/
treatment process design parameters as well as stream parameters (i.e.,
flowrate, temperature, pressure, etc.). Being design data, the information
at this level will not change within a test series, barring, of course, any
physical changes to the process, ductwork, or control device. This is a
highly unlikely situation. It is important to keep in mind the meaning of a
control device/treatment process. Fine particle, gaseous, and liquid waste
streams have control devices to reduce emissions. Examples include ESP's,
S02 scrubbers, and waste water clarifiers. Solid discharge streams do not,
however, have control devices per se. They are "controlled" rather by
treatment, storage or recovery processes which in some manner decrease the
pollutant burden on the environment. Hence, the terminology, Control Device/
Treatment/Storage/ Recovery Process.
Following the stream design level is the test operating level. As
the name implies, operating data for each test is defined here. Source
operating data, such as operating mode and feed material rate, and control
2.0-6
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device/treatment process operating data are included. Here also, the fuels
and feedstocks to the process are completely characterized. A test is
broadly defined as a set of various types of samples (e.g., SASS, impactor,
continuous monitor, grab, etc.) taken to characterize a source waste
stream(s) under one set of source and control device/treatment process
operating conditions. Occasionally engineering judgement needs to be used
when, for example, source operating conditions may change during a test. A
decision needs to be made regarding the effect of the change on the emissions
being tested. If it is deemed an insignificant change then the encoder may
designate the test as one test. However, if the source operating change
could appreciably alter the quality or quantity of emissions, then the
encoder should create multiple tests, one for each source condition and each
containing samples taken during that particular operating condition.
The fourth level in the EADS structure is the sample level. All
details for each discrete sample taken during a test are contained here.
This includes measurement equipment particulars, measured stream conditions
at the sampling location, and complete physical, chemical, radionuclide and
bioassay analysis data.
This level contains a "component" feature which enables one to
report data with respect to a measurement instrument component. For
example, the Source Assessment Sampling System (SASS) is a measurement
instrument with multiple components that collect different compounds
simultaneously. The SASS train is the recommended EPA environmental
assessment measurement instrument for gaseous streams which may contain
fine particles. Complete detailed information on the SASS can be found in
"IERL-RTP Procedures Manual: Level 1 Environmental Assessment (Second
Edition)," EPA-600/7-78-201, October 1978. The SASS train has a set of
2.0-7
-------�
three cyclones followed by a filter which classifies fine particles in a
gas stream according to size. Each cyclone and the filter may be analyzed
as a separate component or they may be combined and analyzed in some
combination, depending on the purpose of the test. Simultaneously, other
components collect gaseous organic material and volatile trace elements.
Typically, each SASS component is subjected separately to a variety of
analyses. EADS >s designed to accommodate the data resulting from such an
arrangement. Be sure, however, to encode this data in the correct data
base. Even though the SASS is one sampling train, it produces data on
fine particles and gaseous pollutants. Thus, the fine particle data would
be in FPEIS, with the cyclones and filter being the components, and the
organic and trace element data collected from the organic module and
impinger components would be in GEDS. FPEIS contains fine particle data
and GEDS contains gaseous data. While this procedure may seem confusing
while encoding data, it will facilitate data output requests.
Looking again at Figure 2-1, it is easy to see the flexibility of
the data base structure. Each test series includes information and data
from one stationary source in a given time period with one particular
source/control system. Each source, however, can contain any number of
effluent streams in any media. The data system is capable of accommodating
as many gaseous emissions streams as are tested. In the same manner, each
stream is likely to be tested a number of times under a variety of source
and control device operating conditions. Again, the data system will
accommodate information from any number of tests performed on each
emissions stream. Frequently an emissions stream is sampled with a
variety of measurement methods under each set of source/control operating
conditions. The data system will accommodate information from any number
2.0-8
-------�
of samples obtained during each test on each stream. The EADS will
contain many test series each structured in a similar manner.
When making a decision whether or not to submit data to EADS, the
user should not let the amount of data enter into his or her decision.
EADS will accept a test series of any size, regardless of the number of
effluent streams, tests, or samples. The primary decision criteria should
be the perceived value or usefulness of the data to the user community.
This decision should be a mutual one between the contractor and his
project officer. Guidance may also be sought from the EADS technical
staff.
2.0-9
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2.1 GEDS ORGANIZATION AND CONTENTS
As one can see from the previous discussion, the GEDS data base
structure contains four levels. These levels are simply an organizational
tool — enabling the data to be arranged in a manner which is logical from
the user's viewpoint. Each level contains specific types or groups of
data. Table 2-1 shows the relationship between these general groups of
information and the contents in each group, while the data base structure
is shown in Figure 2-2. The data are grouped into the following general
categories: (a) general source description and related information;
(b) design conditions and parameters of the effluent stream and of the
control device or treatment/storage/recovery process; (c) test operating
information including analyses of any fuels and feedstocks; (d) sampling
activity information including chemical, physical, radionuclide, and
bioassay analysis results.
2.1.1 Source and Test Series Related Information
This group of data elements identifies the stationary source that
was tested, the source location, and the origin of the data which comprise
the test series. To enable a general grouping of sources to be made and to
facilitate computer searches of particular source types, each source is to
be described using appropriate terms from the EADS Source Classification
System. The NEDS Source Classification Codes (SCC) were formerly used
with the FPEIS, but to enhance flexibility, they have been replaced by the
EADS system. The NEDS SCC system had proved to be too cumbersome and
archaic and had contained terminology unfamiliar to users of environmental
data. The EADS system contains more familiar source terminology and, in
addition, contains a reference to the SIC code (Standard Industrial
Classification Manual, Executive Office of the President ~ Office of
2.1-1
-------�
TABLE 2-1. GEDS DATA ELEMENTS AND THEIR LEVELS
Test Series Level
Stream Design Level
Test Operating Level
Sample Level
ro
i
ro
A. Source Description
Source category
Source type
Product/device type
SIC code
Process type
Design process rate and units
Feed material category
Source name
Site name and address
FPEIS, SDDS, and LEDS TSN's
Series start and finish dates
Sponsor organization
Contract number
TO/TD number
Name of sampling group/contractor
Reference title, author, number,
publication date, and NTIS
number
B. Test Series Comments
C. Stream Characteristics (Design)
Flowrate and units
Velocity
Temperature
Pressure
Moisture content
Stack height
Stream name
Comments
Control Device or Treatment
Process
Generic device/process type
Design type
Specific process/device type
Device/process class
Commercial name
Manufacturer
Device/process keywords
Design parameters analysis
E. Test Identification
Date
Start and end times
Operating mode
Percent design capacity
Device operating parameters
Comments
F. Fuels and Feedstocks
Source feed material, feed
rate and units
Sample mass and units
Laboratory name and approval
Feed sample volume and units
Proximate analysis
Ultimate analysis
Physical characteristics
Inorganic and organic
analysis
Comments
H. Sampling Activity Description
Measurement instrument/method
Start time and duration
Measured stream:
Flowrate
Velocity
Temperature
Pressure
Moisture content
Sample volume
Flowrate measurement method
Sample mass and units
Sampling location description
Collection surface/substrate
Comments
K. Component of Sampling Measurement
Method
Component name
Component weight
Chemical analysis laboratory name
Chemical lab approval
Radionuclide lab approval
Component aliquot mass/volume and
units
Effluent characteristics
Parameter
Value and units
Analysis method
Detection limits
Comments
L. Inorganic Analysis/Non-Level 1 or 2
Organic Analysis
Species
Analysis method
Detection limits
Total milligrams recovered
Concentration
Comments
-------�
TABLE 2-1. Concluded
Test Series Level
Stream Design Level
Test Operating Level
Sample Level
ro
M. Level 1 or 2 Organic Analysis
Fraction ID
TCO
Grav
Species
Analysis method
Detection limits
Intensity
Concentration
Comments
R. Radionuclide Data
Radionuclide ID
Analytical method
Detection limits
Concentration
Comments
T. Bioassay Data
Test type
Test name
Duration
Laboratory sample ID
Laboratory name and approval
Test start and end dates
Sample quantity and units
Test organism/strains
Type of value, value, and units
Confidence limits
Maximum applicable dose and units
Level of toxicity
Bacteria mutagenicity response
Minimum effective concentration
and units
Approximate concentration factor
Comments
-------�
Source description
Stream design characteristics
Test identification,
source/process/control device
operating parameters
Sampling activity
description
Sampling
measurement/
method
component
description
Test series level
Control device or treatment/
storage/recovery process
design characteristics
Stream design level
Fuels and feedstocks
characteristics
Test operating level
Inorganic
analysis
Organic
analysis
Radionuclide
analysis
Bioassay
analysis
Sample level
Figure 2-2. Waste stream data base structure.
-------�
Management and Budget, prepared by the Statistical Policy Division, GPO
Stock No. 4101-0066, 1972) for cross-reference to other data systems. The
allowable entries for the EADS Source Classification System are listed in
the EADS Terminology Reference Manual and use four increasingly specific
descriptors to characterize a source.
The name of the testing organization and the reference (report,
journal article, etc.) from which the data have been extracted are
included. Additionally, comments or data may be included which may be
pertinent to the test series, but for which a specific data element is not
available.
An important feature of the GEDS is that it can protect
confidential or proprietary source data, if the source owners so choose.
The GEDS will accept the entry "CONFIDENTIAL" for any source who wishes
their identity (i.e., site name and address) to be anonymous. This
enables the GEDS to store important gaseous data from sources which would
otherwise be unavailable. EPA will have no knowledge whatsoever of the
identity of the source. This feature has already been frequently used
with the original FPEIS and has been a great aid in obtaining data.
Each of the EADS data bases also contains cross references to other
data bases within EADS. For example, suppose a source with multimedia
discharge streams is tested and the gaseous emissions data are to be
reported in the GEDS. The GEDS test series would then contain cross
references (i.e., Test Series Number ~ TSN) to test series in the other
media, either fine particle, liquid, solid or whichever combination was
appropriate, for the same source. In the same manner, test series in the
other media would contain a cross reference (TSN) to the GEDS data base.
2.1-5
-------�
2.1.2 Control Device and Stream Design Conditions
A description of the design conditions of the gaseous emissions
stream at the sampling location is contained within this group. This
information may include data elements such as flowrate, temperature and
pressure. Because this is design information, the values will not change
from test to test, unless of course the control device or stream itself is
altered in some manner.
This grouping of data elements contains design information and
descriptions of the control system tested (if any) for the test series.
Standard nomenclature (see the Terminology Reference Manual) is used to
characterize the device or treatment process by generic device type,
design type, specific process type, and the device class. If this
standard nomenclature is found to be insufficient in describing the
control device, the encoder may include keywords to further describe it.
Commercial name and manufacturer may also be entered.
Control device/treatment process design parameters are indicated by
type and value, where known. A tabulation of suggested minimum specification
types is provided as standard nomenclature in the Terminology Reference
Manual. The units to be used are also given. The EADS uses SI units
throughout, except where noted. A listing of units and useful conversion
factors is located at the end of Section 4.
2.1.3 Test Operating Conditions
Data elements in this group describe actual operating conditions, as
opposed to design conditions, for the test, source, and control devices.
Included here is. such information as test dates and times and operating
conditions of the source. Control device operating parameters are indicated
by type and value, and are described by standard nomenclature with
2.1-6
-------�
appropriate units also given. As with the design parameters, suggested
operating parameters are given for many of the typical gaseous control
devices or treatment processes in use today for a variety of sources. The
user may define and include additional parameters as required, but should,
however, receive approval from the EADS Project Manager beforehand.
This group also contains data describing all fuels and feedstocks that
are inputs to the process being sampled. Up to nine separate fuels or
feedstock materials may be described for each process waste stream sampled in
the test series. The description of the fuel or feedstock includes proximate
and ultimate analysis results, physical characteristics, inorganic and
organic composition, as well as the rate of consumption of the fuel or
feedstock.
2.1.4 Sampling Activity Information
This group of data elements consists of information that describes
individual sampling activities, including actual measured gas stream
conditions at the sampling location, such as temperature, pressure, and
moisture content. In addition the sampling location itself would be
described in such a manner that its location with respect to a control device
or treatment process would be clear.
Frequently, a measurement instrument contains two or more components,
each of which is designed to capture different gaseous species. For example,
an EPA Method 8 train is designed to capture both sulfuric acid mist and
sulfur dioxide, but in different components of the sampling.train. This
group of GEDS data describes not only the instrument itself but also each
component separately and reports the results obtained from the analysis
performed on the sample collected in each component. Chemical, physical,
radionuclide, and bioassay results may be reported. Results are typically
2.1-7
-------�
presented as the identification of the species analyzed and the actual source
concentration as contributed by that component.
An important feature of this group is the quality control/quality
assurance information on the analytical results. Data elements that provide
some measure of quality control and assurance include detection limits of the
analytical method, total amount of sample analyzed, sample aliquot,
identification of the analytical laboratory and reference to any laboratory
quality assurance (QA) audit information. Analytical laboratory audits are
routinely performed by government organizations such as the Environmental
Protection Agency. The results of such audits can be valuable in assessing
the reliability and accuracy of analytical results. The audit information is
contained in a separate reference data base which is accessed through a QA/QC
code reported in GEDS. More information on the audit data base can be found
in the EADS Systems Overview Manual and in Section 3 of this User Guide.
Special provisions have been included to accommodate the organic
species reporting protocol of a Level 1 or 2 environmental assessment
sampling and analysis program. This analysis protocol includes a group of
qualitative and semi-quantitative analytical methods whose results are
suggested to be reported in a manner shown in the example in Figure 2-3
(taken from the "IERL/RTP Procedures Manual: Level 1 Environmental
Assessment (Second Edition)," EPA-600/7-78-201, October 1978). The GEDS is
designed to accommodate this information and, in addition, can report
analytical methods and detection limits as well.
The GEDS is, however, not restricted to accepting Level 1 data only.
It is flexible so that any reporting protocol can be included.
2.1-8
-------�
ORGANIC EXTRACT SUMMARY TABLE
Sample Sorbent Extract—11-3
Total Organic*, mg
TCO. mg
GRAV, mg
LC1
18.2
5.2
13.
LC2
22.3
19.
3.3
LC3
253
73.
180.
LC4
29.7
6.7
23.
LC5
11.0
3.7
7.3
LC6
46.3
5.3
41.
LC7
15.1
0.1
15.
2
390
110
280
Category
Assigned intensity--mg/ (m3, L, or kg)"
Sulfur
Aliphatic HC's
Aroma tics— Benzenes
Fused Arom 216
Fused Arom 216
Heterocyclic S
Heterocyclic N
Carboxylic Acids
Phenols
Esters
100-0.6
10-0.06
10-0.06
100-0.6
10-0.06
10-0.06
100-4
100-4
10-0.4
•Concentration for gas samples = mg/m^, for liquid samples = mg/L, for solid samples = mi
actual n)3, L, or kg value.
* Estimated assuming same relative intensities as LC6, since IR spectra of LC5 and LC6 are
100-0.5
100-0.5
10-0.05
10-0.05
j/kg. Fill in
very siitiil .r.
-0.1 1
-0.1 1
-0.1*
-0.01 f
-0.01 f
100-0.7
10-0.07
100-0.7
10-0.07
10-0.07
10-0.02
100-0.2
10-0.02
10-0.02
0.6
0.06
0.06
5.
5.
0.5
1.
0.3
1.0
01
0.08
ro
•
t-f
to
Figure 2-3. Organic extract summary table.
-------�
The sampling activity information group can also handle
radionuclide data results and bioassay results. The bioassays may be
either health effects or ecological effects tests.
2.1-10
-------�
SECTION 3
DATA ACQUISITION AND ORGANIZATION
3.0 INTRODUCTION
The purpose of this section is to demonstrate how the encoder would
use the structural concepts discussed in Section 2 to prepare a set of
source testing data for encoding into the 6EDS. This will be demonstrated
with a hypothetical example. This section will also discuss some special
problems that may occur while encoding source test data. For example, how
do you encode data from a Source Assessment Sampling System ~ an
instrument which collects samples from two media — fine particles and
gaseous? We cannot forsee all the peculiar situations and special problems
that may occur during the encoding process, but the general guidelines and
techniques given here should greatly facilitate this task. Feel free to
call the EADS Data Base Program Manager or the EADS technical staff listed
on page xi if any questions arise during the encoding process.
3.0-1
-------�
3.1 HOW TO BUILD A TEST SERIES
This section describes the techniques and the thought processes
that the user should employ when encoding source testing data onto the
GEDS data input forms. Using the techniques described here will be of
particular benefit to the user who is not familiar with the EADS system
and underlying concepts. To those who already have some experience with
EADS, possibly through the use of the original Fine Particle Emissions
Information System (FPEIS), these methods may already be familiar to some
degree.
In most cases, the user will have either a test report or perhaps
simply summary tables of results obtained from a source testing effort.
The problem that now confronts the user is how to efficiently and
accurately transfer that morass of data onto the GEDS data input forms.
Experience has shown that the most efficient thing to do is to first
organize the data and information before you -- on paper. The key to this
organization of data is the pyramid structure of the GEDS. All of the
EADS (i.e., GEDS, FPEIS, LEDS, and SDDS) are structured in a similar
manner and the encoding forms and SERIES report are designed to reflect
this structure. Indeed, source testing reports can be thought of as being
arranged in such a manner. Looking at Figure 3-1, the pyramid structure
becomes evident. Data is arranged so that general information, such as
the source description and reference information, is situated at the apex
of the pyramid. The next level down contains design information on the
sources' effluent streams and control devices. The pyramid further
expands into the tests performed on each effluent stream and the operating
conditions of the source and control device(s) during those tests. The
final level in the pyramid contains data on each of the samples taken
3.1-1
-------�
Source description
Stream design characteristics
Test identification,
source/process/control device
operating parameters
Sampling activity
description
Sampling
measurement/
method
component
description
Test series level
Control device or treatment
storage/recovery process
design characteristics
Stream design level
Fuels and feedstocks
characteristics
Test operating level
Inorganic
analysis
Organic
analysis
Radionuclide
analysis
Bioassay
analysis
Sample level
Figure 3-1. Waste stream data base structure and contents.
-------�
during each test. This is the most specific information contained in the
data base. It includes chemical, physical, radionuclide, and bioassay
analytical results. Think of the pyramid structure as descending from the
general to the specific. The source description being general and
analytical results being the most specific.
How then does the user arrange his source testing data into the
pyramid structure? Very simply, the user should lay out a structure on
paper similar to that shown in Figure 3-1. There will be one box at the
test series level to represent the source. The stream design level will
contain as many boxes as there are effluent streams. In a like manner,
the test operating level will contain one box for each test performed on
each stream. And finally, at the sample level, each test will contain as
many boxes as there are samples. The user should then assign appropriate
labels, according to his data, to the source, streams, tests and samples,
and enter those labels in the corresponding boxes of the pyramid. This
approach has two major benefits. One, it forces the user to understand
and organize his data, and two, it structures the data in a manner that
aids tremendously in encoding and proper ordering of the forms. You will
recall that the data forms are organized in a manner similar to the data
base itself. They proceed from the general to the specific.
Section 4 contains detailed encoding instructions which, when used
in conjunction with the above organization methods, make the encoding task
straightforward.
3.1-3
-------�
3.2 DATA INPUT FORM STRUCTURE
The GEDS data elements (see Table 2-1) are entered on eleven data
input forms. The layout of the eleven forms is such that the data elements
in any one test series that are least likely to change, are located on
Form 1, and the most likely to change are on Forms 7 through 11. It
becomes apparent that the input forms are arranged according to the
hierarchical structure (i.e., a pyramid) of the data base as shown in
Figure 3-1.
Forms 1 and 2 (see Section A.4 in the Appendix) include source
description data, stream design characteristics and control device/
treatment process information. Because this is design data, it will noc
change for a given test series on a given source/control device/process
combination. The information on Form 1 is contained in the test series
level while the Form 2 stream/control device/process information is at the
stream design level.
The test operating level is the third level down on the
hierarchical structure and it, as the name implies, contains operating
information — operating in the sense that these are the conditions of the
source, control device/process and fuels and feedstocks during the actual
test. This information is entered on Forms 3 through 5.
The bottom level in the EADS structure is the sample level. This
information is entered on Forms 6 through 11. These forms are expected to
be the most frequently used in that often a number of measurement
instruments, some with two or more components, are used in a given test.
Also a variety of analyses are frequently performed on a collected sample.
Once all data input forms have been encoded, the forms must be put
in a specific order. There are two important reasons for this. One,
3.2-1
-------�
because the repetitive data feature (described in detail in Section 4) is
predicated on correctly ordered input; and two, the computer processing
performs order checks. The rules for ordering input are very
straightforward and can be explained in two different ways.
Look at Figure 3-2, a typical test series. The input forms are
ordered by starting at the top and moving down and left, checking off the
boxes as you encounter them. When you can't go down and left any more,
back up to the first place where you can go down and left again to an
unchecked box. The input forms are ordered in the same way as the boxes
are numbered in Figure 3-2. Remember that each box represents one or more
input forms.
Each input form has multiple lines on it. Each line is identified
by a letter and a number called a card number. Each major grouping of
lines has the same letter and is identified on the input forms, e.g.,
F-fuels and feedstocks. Each line of input also has one or more of these
fields (or data elements) — test series number, stream ID, test ID,
sample number, component number. Suppose that you are encoding a single
test series. The test series number will be the same on all forms
submitted. The first form will be Form 1, containing the source
description and test series comments. All forms for the first stream
follow. The stream characteristics and control devices on one or more
Form 2's are next. Then comes all of the data about the first test on the
stream on Forms 3, 4, and 5. The first sample of this test ID follows on
Form 6. The first component of the sample follows on Forms 7, 8, 9, and
10. Then comes the second component, the third and so on. Then come
bioassay data on the sample on one or more Form ll's. The second sample
of the test comes next followed by its component and bioassay data. Then
3.2-2
-------�
Test. Series Level
Source
to
•
ro
i
to
Stroani design Level _ . __— - — 77
Stream 1 control
device design
parameters
Stream 2 control
device design
parameters
Test Operating Level
Test 1
Test. 3
Source/control device
operating conditions
Source/control device
operating conditions
Source/control device
operating conditions
I
Sample Level
Sample
Sample
Component
Component
Component
10
13
Sample
Sample
Sample
14
16
Component
Component
Component
Component
Test 1
19
Source/control device
operating conditions
Figure 3-2. Forms ordering.
-------�
comes the third sample and its component and bioassay data, the fourth
sample, and so on; to complete the data for the first test. Then there is
another set of Forms 3, 4, and 5 describing the second test and sets of
forms for each sample and component following. After all tests on the
first stream have been encoded, then a new Form 2 is used to specify the
second stream. The test, samples, and components of the second stream
follow in the same way as they did for the first stream. Continue in this
way until all streams have been encoded.
Although the stream ID, test ID, sample number and component number
form a defacto page numbering scheme, it is recommended that the pages be
consecutively numbered in the space provided.
3.2-4
-------�
3.3 STRUCTURE APPLICATION EXAMPLE
The techniques for organizing gaseous source sampling data are
demonstrated in the following paragraphs using a hypothetical example.
Table 3-1 shows a sampling log of source tests performed at a low Btu coal
gasification plant. The log shows that two tests were performed at two
sampling locations, the process heater stack gas and the liquor separator
vent. The two tests correspond to two different source operating
conditions where the plant was operating first at 80 percent of capacity
and then at maximum rated capacity. A grab sample and a SASS train were
used at each location under both operating conditions. In addition, a
chemiluminescent analyzer was used to measure NO emissions at both
A
locations, but only during full-load operation.
While the sampling log clearly shows what occurred during the
testing program, it does not display this information in a manner such
that the user can easily visualize how the data should be organized for
encoding purposes. Nor does it provide any information on how the encoded
forms are to be ordered before they are keypunched. At least for the
beginning user, and we believe it's an excellent tool even for the
experienced user, the data should be arranged in the pyramid structure
shown in Figure 3-3. In our hypothetical example, the rearranged sampling
log information would look like Figure 3-3. The gasification plant would
be entered as the source at the test series level and the two sampled
streams would at the next level down. The stream design level can contain
any number of effluent streams. Following down to the test operating
level, you can see that each of the two tests is labeled and entered into
a box. Each stream thus has two tests, one at 80 percent load and one at
full load. The sample level indicates which samples were taken during
3.3-1
-------�
TABLE 3-1. SOURCE SAMPLING LOG — GASIFICATION PLANT
Stream
Test
Sample
1 — Process heater
stack gas
2 — Liquor
separator vent
1 -- 80% load
2 -- full load
1 -- 80% load
2 -- full load
1 ~ Grab sample
2 — SASS
1 —- Grab sample
2 -- SASS
3 - NOX
chemiluminescence analyzer
1 ~ Grab sample
2 -- SASS
1 — Grab sample
2 -- SASS
3 - NOX
chemiluminescence analyzer
3.3-2
-------�
GO
to
Gasi fication
plant
Process heater
stack gas
Liquor
separator vent
Sample 1 Sample 2 Sample
Sample 3 Sample 1 Sample 2 Sample
NOX
chemi1umi nescence
analyzer
Sample 3
NOX
chemiluminescence
analyzer
Sample 2
Sample 2
Test Series Level
Stream Design Level
Test Operating Level'
Sample Level
Figure 3-3. Data structure -- gasification plant.
-------�
each test on each stream. Each box represents one measurement instrument
or sample. The numbers in circles located at the upper left corner of
each box on Figure 3-3 indicate the order in which the encoded data input
forms should be arranged. The rule for ordering of forms is: starting at
the top, move down and left, number the boxes consecutively as they are
encountered. When you can't go down and left anymore, back up to the
first place where you can go down and left again to an unchecked box.
While the forms should be numbered in the manner indicated on Figure 3-3,
recall that each number may represent one or more forms. For example the
box:
80 percent load
test 1
may include forms 3 through 5 which describe the operating conditions
during test 1. The box: •
grab sample
sample 1
may include forms 6, 7, 8, 9, 10 and 11.
3.3-4
-------�
3.4 SPECIAL ENCODING CONSIDERATIONS
The GEDS has a certain amount of flexibility built in and this
enables it to accommodate data from a variety of*sampling protocols and
unusual source situations. The purpose of this section is to discuss some
of these special situations and to familiarize the user with the manner in
which EADS conforms to them. In addition, this section discusses the
rationale for some of the encoding instructions described in Section 4.
3.4.1 Multimedia Test Series
Frequently in source sampling activities, multimedia effluent
samples are collected and analyzed. This is particularly true in
environmental assessment (EA) programs where the contractor is trying to
assess the overall environmental impact of a stationary source. For
example, if a coal-fired utility boiler equipped with NO controls, an
A
electrostatic precipitator, and a flue gas desulfurization system was the
subject of an EA testing program, streams from all media, gas, fine
particle, liquid, and solid, would probably be sampled and analyzed. The
analysis data from each specific media effluent stream would be encoded in
its respective data base (i.e., gas stream analysis results would be
encoded into the GEDS). You might ask yourself how, if data from one
source is entered into four separate data bases in EADS, a user could
benefit from this data. Each data base contains a cross reference to the
other data bases containing data taken from the same source at the same
point in time. This cross reference is in the form of the TSN. Thus, in
our example, the GEDS file would contain the FPEIS, LEDS, and SDDS Test
Series Numbers as cross references. Conversely, LEDS would contain the
GEDS, FPEIS, and SDDS TSN's as cross references. FPEIS and SDDS would
follow in the same manner.
3.4-1
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3.4.2 Multiple Control Devices
The EADS recognizes the fact that an effluent stream may have
multiple control devices.- For example, a gaseous stream may have NO
/\
controls and a flue gas desulfurization unit in series. Up to five
control devices can be accommodated per stream. During the encoding
process, the user is required to assign a number to each control device.
The control device number will be unique for that device in that test
series. The device number is used to identify the set of design and
operating parameters for that particular device in the event that there
are multiple devices.
3.4.3 Parallel or Series Control Devices
Frequently an effluent stream will have two or more control devices
for various pollutants either in a series or parallel arrangement. This
situation is handled in the following way. In a series arrangement, the
control devices are serially assigned unique device numbers 1, 2, 3, ...
etc., to a maximum of five. Each control device will then have a Form 2
and a Form 3 encoded. These forms should be ordered in the same sequence
as they occur in the effluent stream and in addition, group all Form 2's
together and all Form 3's fogether. If the control devices are in
parallel, the convention is to label them as 11, 12, 21, 22, etc. Each
device will again have a Form 2 and a Form 3 and again they should be
ordered in the same sequence that they occur in the effluent stream with
all Form 2's together and all Form 3's together.
3.4.4 Fuels and Feedstocks
Frequently a stationary source of gaseous air pollution will have
one or more fuels and/or material feedstocks as inputs to the process.
These inputs are routinely sampled as part of most testing activities and
3.4-2
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are subsequently analyzed for a variety of parameters and purposes. For
example, material balances around a process are usually performed on
elements (e.g., sulfur) with the intent of validating the data and to
assess the origin and fate of chemical species. The GEDS has two input
forms devoted totally to recording information about the fuels/feedstocks
and any chemical or physical analysis performed. In addition to the
consumption rate and type of fuel/feedstock, the GEDS has data groups
reserved for proximate and ultimate analyses (for fuels only), general
characteristics (usually physical parameters such as viscosity or
pourpoint), and chemical analyses. Information and analyses for up to
nine different fuels and feedstocks from one source may be included in
each test series.
The encoder of data should note that general characteristics may be
entered as either number or text values. Normally such values would be
entered as numbers (e.g., pourpoint, -10°C). However, occasionally
either a range of values needs to be entered or possibly a word descriptor
of some physical characteristic. Here, the entries would be written as
text. More detailed instructions on this point can be found in Section 4,
Group F.
In recognizing the variety of units in which fuels and feedstocks
chemical analyses are reported, the GEDS has left the units selection for
actual concentration open to the discretion of the user. This flexibility
is not the case, however, when reporting actual concentrations of chemical
species in effluent streams (on Forms 8 and 9). These units must be in
yg/m.
3.4-3
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3.4.5 Data Accuracy and Quality
The GEDS contains data elements that assist the user in assessing
data quality, accuracy, and validity. These include identification of the
testing group, analytical laboratories, analysis methods, sampling methods,
high and low detection limits of the analytical methods, total sample
quantities and aliquots, and QA/QC codes. The QA/QC codes are obtained by
the user from the EADS Program Manager at the time the GEDS data input
forms are encoded. Each analytical laboratory that has undergone a
quality assurance/quality control audit will be assigned a unique QA/QC
code. The code refers the user to a reference data base which contains
the results of the audit. These QA/QC audits describe the efficiency and
effectiveness of a particular laboratory in recovering a known
concentration of a chemical species from a spiked sample, thereby giving
the user of the laboratory's services an appraisal of the laboratory's
performance. The QA/QC data base will contain each chemical species
reported and will identify the analysis method used to detect the
chemical. Also, the number of samples submitted, the average percent of
recovery and its standard deviation, and the quality control frequency are
reported for each chemical species or compound in the audit.
In the final analysis, the GEDS QA/QC data elements, however, only
ensure the correctness of the data on an as reported basis. The
responsibility for data validity lies with the people who collect and
input the data.
3.4.6 Source Assessment Sampling System
The Source Assessment Sampling System (SASS) has three or more
components that collect different samples simultaneously. The SASS train
is the recommended EPA EA measurement instrument for gaseous streams which
3.4-4
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may contain fine particles. Complete detailed information on the SASS can
be found in "IERL-RTP Procedures Manual: Level 1 Environmental Assessment
(Second Edition),11 EPA-600/7-78-201, October 1978. The SASS train
(Figure 3-4) has a set of three cyclones (with nominal cut diameters of
10 ym, 3.5 ym, and 1 ym) followed by a filter which classifies fine
particles in a gas stream according to size. Simultaneously, another
component, the organics module, collects gaseous organic material while a
third component, a set of impingers, collects volatile trace elements.
Typically, each SASS component is separately subjected to a variety of
analyses. EADS is designed to accommodate the data resulting from such an
arrangement. Be sure, however, to encode this data in the correct data
base. Even though the SASS is one sampling train, it produces data on
fine particles and gaseous pollutants. Thus, the fine particle data would
be in FPEIS, with the cyclones and filter being the components, and the
organic and trace element data collected form the organic module and
impinger components would be in GEDS.
3.4.7 Effluent Characteristics
This group of data is intended to accommodate any qualitative
measurement of an effluent stream parameter, other than inorganic and
organic chemical species, radionuclide, and bioassay results. This will
typically include physical parameters of the sample such as opacity, odor,
or color. Values may be entered on the forms as either number or text.
For example, opacity would be encoded as a number, say 20 percent, whereas
color would be encoded as a text value, light brown, for example. Space
on the encoding forms is also provided for the analytical method and any
applicable detection limits and their units.
3.4-5
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[EE/S-003e]
Control Module
Trace Element
Impingers
Oven With Cyclones
Gas Cooler &
Organic Module
Sampling Probe
Compressors
Figure 3-4. Source Assessment Sampling System.
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3.4.8 Reporting of Chemical Analysis Results
The EADS input forms have been developed so that a variety of
sampling and analysis protocols can be accommodated. EPA/IERL-RTP's EA
programs are expected to be one of the primary suppliers and users of
data. Thus, in response to the special reporting protocols of EA
programs, EADS has put emphasis in this area, without relegating other
reporting protocols to a lesser position.
Specifically, Form 8 has been designed for all inorganic analysis
results and organic analysis results that do not conform to Level 1
protocols. Form 9, however, is reserved exclusively for reporting organic
analysis results that do conform to Level 1 protocol. Level 1 organic
analyses require special reporting formats due to the mix of qualitative
and semi quantitative results from analyses such as liquid chromatography
fractionation and low resolution mass spectra. The purpose of this type
of analysis is to identify the major classes of organic compounds in a
process effluent stream and to estimate their concentrations. In Level 1
this is done by liquid chromatography which separates a sample into
fractions characterized by a range of boiling points. These are called
fraction ID'S and are labeled LCI through LC7 -- corresponding to groups
of chemical species with successively higher boiling points. Both the
whole sample and the LC fractions are analyzed for TCO and Grav
concentrations. TCO analysis gives volatile organic material and Grav
analysis yields nonvolatile organic material. This data in combination
with qualitative results obtained from infrared analysis, called intensity
values, and information about the source, enables the analyst to identify
the chemical species in a waste stream sample. Occasionally, individual
species are identified in an extension of Level 1 analysis, and their
3.4-9
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concentrations are determined. The GEDS is fully capable of accepting all
this data. In addition, fractions, organic categories, and species are
identified by a MEG number. This is a unique ID for that species and is part
of a system used in EA methodology (Multimedia Environmental Goals for
Environmental Assessment Volumes 1 and 2, EPA-600/7-77-136a, b, November 1977)
for evaluating and ranking pollutants according to environmental impact. The
encoder must use MEG numbers when inputting EA data (i.e., Level 1 or 2).
Either MEG or CAS numbers ("Chemical Abstracts — Chemical Substance Index,"
American Chemical Society) may be used for data obtained by some other
sampling and analysis protocol. When this data is extracted from the data
base as output, it will appear with the preferred chemical name first, then
other less common names.
3.4.9 Reporting of Radionuclide Data
One complete form is devoted to recording radionuclide analysis
results of gaseous samples. Actual source concentrations of radionuclides
are to be recorded in the units, pCi/cubic meter. The isotopes most
likely to be of interest include the following: U-238, Ra-226, Pb-210,
PO-210, U-235, Th-232, Bi-212, Ac-228, and Bi-214. Also, note that space
is available to include metastable isotopes (i.e., Kr-85M).
3.4.10 Bioassay Results
As part of EPA's EA scheme, biological indicators are coupled with
chemical tests to assess the hazard potential of process waste streams.
The Level 1 screening phase uses a series of short-term bioassays to
detect acute biological effects. Bioassays may be either health-related
or ecological tests. While EA methodology has specific recommendations
3.4-10
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for applying bioassays to samples,* it is frequently the case that these
recommendations cannot be followed. For example, EA protocol says that
particulates captured in a SASS train should be divided into two
components— those less than 3 microns and those greater than 3 microns.
Frequently it is the case that neither component separately can meet the
minimum sample quantity requirement for bioassay tests, so the components
must be combined. Consequently Form 11, which records bioassay results,
has no space for component sequence number. The encoder should record in
the comments section which component sample was tested or if component
samples were combined.
While most bioassay data elements on Form 11 pertain to all types
of biotests, some apply to only specific tests. These are listed below:
Data Element Bioassay Test
Type of Value All except the Ames
Bacteria Mutagenicity Response Ames only
"Level of Toxicity" is defined as "a qualitative expression of the
bioassay results based upon a predefined range in LD5Q, EC™ or LC50,
etc." Table 3-3* may be used as an aid in determining the Level of
Toxicity for specific bioassays. Given a certain assay and response
range, the encoder can determine whether the Level of Toxicity is high,
moderate, low, or not detectable.
*Duke, K. M., Davis, M. E., and Dennis, A. J., "IERL-RTP Procedures Manual:
Level 1 Environmental Assessment Biological Tests for Pilot Studies,"
EPA-600/7-77-043, April 1977.
3.4-11
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TABLE 3-2. RESPONSE RANGES FOR RANKING OF VARIOUS BIOTESTS
GO
-P*
RESPONSE RANGES
ASSAY
Health Tests
Ames
RAM, CHO.WI-38
Rodent
Ecological Tests
Algae
Fish
Invertebrate
ACTIVITY MEASURED
Mutagenesis
Lethality (LCsrj)
Lethality (LD5g)
Growth Inhibition (ECgg)
Lethality (LC50)
Lethality (LC50)
MAD
5 mg/plate or
500pL/plate
1,OOOpg/mLor
600pL/mL
10 g/kg or
10 ml/kg
1,OOOmg/Lor
100%
I.OOOmg/Lor
100%
1,000 mg/L or
100%
HIGH
<0.05mgor
<5pL
<10pgor
<6pL
<0.1
<20%or
<200mg
<20%or
<200mg
<20%or
<200mg
MODERATE
0.05-0.5 mg or
5-50 pL
10-100 pg or
6-60 pL
0.1-1.0
20-75% or
200-750 mg
20-75% or
200-750 mg
20-75% or
200-750 mg
LOW
0.5-5 mg or
50-500 pL
100-1,000 pg or
60-600 pL
1-10
75- 100% or
750-1.000 mg
75-100% or
750-1,000 ,;,g
75- 100% or
750-1,000 mg
NOT DETECTABLE
NO at >5mg or
NO at > 500
LCso> 1,000 pg or
LCso>600pL
L050>10
EC50 > 100% or
EC50 > 1,000 mg
LC50 > 100% or
LC5Q> 1,000 mg
LC50>100%or
LC5Q> 1,000 mg
MAO = Maximum Applicable Dose (Technical Limitations)
LD5Q = Calculated Dosage Expected to Kill 50% of Population
LC5Q = Calculated Concentration Expected to Kill 50% of Population
ECso = Calculated Concentration Expected to Produce Effect in 50% of Population
NO = Not Detectable
-------�
SECTION 4
ENCODING INSTRUCTIONS FOR 6EDS DATA INPUT FORMS
This section presents detailed, card-by-card, encoding instructions
for each GEDS data element on the Standard Data Input Forms. The
instructions are separated into 12 groups (identified by the letters A, B,
C, D, E, F, H, K, L, M, R, and T) corresponding to the major groupings of
GEDS data elements. The GEDS Data Input Form number (1 through 11) is
given for each group. While reading these instructions, it would be
beneficial to refer to the blank input forms in Appendix A.4.
4.0 GENERAL RULES
General instructions that apply to data coding include the
following:
• The letter ."0" is to be encoded "0" and zero is encoded "0".
• Zeros are treated as numbers. Blank spaces in a field indicate
either a lack of data, or that the pertinent data have been
coded for the preceding test conditions or sampling activity.
(See the discussion on the repetitive data feature in
Section 4.1.) To blank out a data field, or to prevent data
from being automatically repeated by the EDIT program, encode
9999... in all columns in the field for numeric fields, and NA
in the first two columns of the field for alphanumeric fields.
4.0-1
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• All numeric data shall be right-justified and all alphanumeric
data shall be left-justified, except where noted otherwise.
• Only specified alphabetical or numerical characters and a few
symbols (%, &, #, /, +, -, <, >, and all punctuation marks
except the colon) are allowed to be entered in the columns
where allowed. No unusual marks are to be made in the spaces.
No data field headings are to be changed and only data
appropriate to the field are to be entered. This rule prevents
unnecessary keypunching errors in processing the forms. J^o
colons are permitted anywhere.
• Do not use Greek letters as these cannot be interpreted by the
computer. For example, microgram (yg) is encoded UG. Refer to
Table A-14 in the Terminology Reference Manual or the tables at
the end of this section for the encoding of engineering units.
SI units are used thoughout the EADS, except where otherwise
noted.
• Only the allowed coding values may be entered in columns that
require coding symbols. When + is indicated at the top of the
column, enter either + or -, as appropriate. Also, indicate if
the data being encoded are less than, greater than, or equal to
a value by using the signs <, >, or leaving the space blank, as
noted on the appropriate field heading.
• The small triangle between columns on the forms represents the
decimal point. Enter the fractional decimal digits to the
right of the triangle.
• Leave all the shaded portions on the forms blank.
4.0-2
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t The following identification data elements must be entered on
the first card of every section (data group) where they appear.
Data Element Card Columns Instructions
Test series number 2-6 Enter on all forms.
Stream number 7-8 Enter only on Forms 2 through 11.
Test ID number 9-11 Enter only on Forms 3 through 11.
Sample number 12-13 Enter only on Forms 6 through 11.
Note, that if encoding instructions are not given for card
columns 1 through 15 for any card, the instructions are the
same as those for the previous card.
• In several instances, more cards than allotted on the forms may
be added by the user if needed to encode all the data. The
detailed encoding instructions indicate the corresponding data
elements, and specify a limit to the number of additional cards
0 that may be included.
• Many data elements, identified in the detailed encoding
instructions, require standard nomenclature. The user must use
data from the tables given in the Terminology Reference Manual
to encode these data elements (Tables A-l through A-15). All
standard nomenclature is left-justified.
e Whenever the data exceed the available space on the forms, use
the available space completely, then finish the discussion by
using the comnents section of the appropriate level (i.e., test
series, test, sample, or component, described in Section 2).
» Whenever there are pertinent data for which no data elements
exist, use the comments section of the appropriate level.
4.0-3
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Make the text as brief as possible through the use of
abbreviations, precise words, and elimination of redundant
words. The text should always start at the leftmost column
(i.e., left-justified).
The encoding instructions are designed to apply to the majority
of cases for which data will be reported. But, it is
recognized that unusual situations (source/control system
combinations, for example) may occur. If you have data that do
not correspond with the encoding instructions, make reasonable
assumptions to reflect the actual test data, or contact the
EADS Technical Staff for guidance.
When more than one control device is used, use a separate data
input Form 2 for each control device used. Be sure to give
each control device a unique number within the test series. Up
to five control devices in a test series may be cod§d for a
given source emission stream.
When more than one source is discharging into an effluent
stream, encode the data for one source (usually the dominant
one), and refer to the other source(s) in the test series
comments.
If data are reported for different components of a sampling
instrument separately and combined, define component numbers
for all cases (on Form 7). For example, for the gas components
of a SASS train:
Component number 1 = XAD-2 Resin
Component number 2 = Impinger
Component number 3 = Resin and Impinger, combined.
4.0-4
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If the data from the sampling method are not split into
components, encode the component sequence number = 01, and the
component name as TOTAL SAMPLE (on Form 7).
After all the forms are encoded and put in order (see Section 3
for a discussion of the ordering of the completed forms),
paginate the forms in the indicated spaces to keep them
organized and to prevent loss.
It is critical to include all "zero" cards which start a data
group. Specifically, these cards are AO, CO, DO, EO, FO, HO,
and KO. These cards initialize indices which are used to load
the data into the data base. These indices are the Test Series
Number, the Stream Number, the Device Number, the Test ID
Number, the Feed Material Sequence Number, the Sample Number,
and the Component Sequence Number, respectively for the above
cards, and starred below where they first occur.
The information that is REQUIRED on these cards is as follows:
Card AO ~ *Test Series Number
Source Category
Source Type
Product/Device Type
Card CO — Test Series Number
*Stream Number
Stream Name
Card DO -- Test Series Number
Stream Number
*Device Number
Generic Device/Process Type
(If uncontrolled, enter "NONE". If not known,
enter "NOT SPECIFIED".)
Card EO — Test Series Number
Stream Number
*Test ID Number
4.0-5
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Card FO -- Test Series Number
Stream Number
Test ID Number
*Feed Material Sequence Number
Source Feed Material
(If data are not available, enter "NOT SPECIFIED".)
Card HO — Test Series Number
Stream Number
Test ID Number
*Sample Number
Method Type and Measurement Instrument/Method
(If not known, enter "NOT SPECIFIED".)
Card KO — Test Series Number
Stream Number
Test ID Number
Sample Number
Component Sequence Number
Component Name (If not specified, enter "TOTAL
SAMPLE".)
These cards and data elements must be included even if no other
data are encoded. A "zero" card must be included whenever any
of the indices are reinitialized; that is whenever the encoder
returns to the start of a data group. For example, when a
second sample is taken, the encoder must include another CARD
HO with a new Sample Number.
In addition to the above, the following data elements are also
required to be entered on the forms:
CARD Al — Process Type
Feed Material Category
CARD H2 ~ Sampling Location Code
Sampling Location Description
• Instruct keypunchers not to punch a card unless there are
handwritten data entered on the card.
4.0-6
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4.1 LABOR SAVING FEATURES
In developing the data input forms and the data processing programs,
several labor saving features have been introduced. These features reduce
time, labor, and cost on the part of the encoder. However, misunderstanding
of these features may result in the entering of erroneous data. The labor
saving features are explained below. If the explanation is not clear, the
safe rule to remember is "if in doubt, fill it out."
4.1.1 Repetitive Data Feature
The "Repetitive Data Feature" is an important labor saving device
because it frees the encoder from having to enter repetitive data. In
general, this means that asterisked (*) fields on the input forms need
only be filled out when there is a change in the value of that field.
Putting in additional values or deleting existing values can also be
accommodated by the repetitive data feature.
However, there are limits and conditions. These are shown in
Figure 4-1, the schematic representation of a single test series with
specific groupings. The hierarchical (level) structures of the EADS data
base are also shown. The boxes outlined with dashed lines ( ) show the
limits on the use of the repetitive data feature. For example, at the
sample level, notice that repeating component data can be accommodated in
a single test across component groups, but not across different tests.
Operating conditions data at the test level can be accommodated across
tests but not across streams. In general, the limits can be described by
the following rule. The repetitive data feature operates at the stream,
test, and sample levels of the EADS data base. It only operates across
component groups which have the same data group at the next higher level
4.1-1
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Test Series Level
Test Level
ro
. Source/Process I Source/Process I Source/Process |
Operating Condition!Operating ConditionslOperating Condition
Control Device
| Source/Procpss I
Operating Conditions
Control Device .
I Operating Parameters '
• Control Device •
Operating Parameters '
I Control Device |
Operating Parameters '
mponent Component I Component Component
Figure 4-1. Repetitive data feature structure.
-------�
of the data base. For example, it operates across components at the
sample level until the operating conditions (test level) change.
All the data elements for which the repetitive data feature is
valid are identified by an asterisk (*) on the input forms.
In many instances, a particular data element may not be constant
for all its occurrences. It may have one value for its first few
occurrences, then change values or not be known for other occurrences. In
these situations, the value of the data-element must be reinitialized to
the new value each time the value changes. If the data are not known, the
correct way to reinitialize the value is to enter "NA" in the first two
columns of the field for alphanumeric data or "9" in every card column for
numeric data. Consider the following example.
Suppose that there are 20 samples with the same source/process
operating^conditions. In the first nine samples, SAMPLE TEMPERATURE is
110°C. In the next four it is 120°C; it is unknown for the next
three, and is 150°C for the remainder. In the first sample, enter 110
in columns 58 through 61 of the HO card. The value has now been
initialized. The same field can be left blank for the next eight samples
because they have the same value. For the tenth sample, the value 120 is
entered, reinitializing temperature. The temperature on the next three
samples can be left blank because they are also 120. In sample 14, where
the temperature is unknown, the value 9999 is entered as "null" value,
reinitializing the field. If this were not a numeric field, then "NA"
should be entered as the "null" value. In sample 17, the value 150 would
be entered and then the field would be left blank for samples 18, 19,
and 20.
4.1-3
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In this way, with the repetitive data feature, only four unique
values must be encoded instead of 20. When there are a number of
unchanging values, this feature will save considerable time and effort.
4.1.2 Control Device and Design Parameters
Another example is in the case where two different streams from the
same source each have an identical control device installed. Here, one
should assign the same Device Number (CARD DO) to each. The repetitive
data feature will permit the encoder to fill out the data on all D cards
(DO, Dl, D2, D3, and D4) just once, leaving those for the second control
device blank. All of the data for the second device will automatically
repeat. For example, on CARD D4, once the design parameter data have been
initialized, they remain constant until changed. Be sure to include a
CARD DO with the Device Number on it, to reference the control device.
The only exception to the encoding instructions for an unknown or
"null" value occurs when such a value is needed in the first occurrence.
In that instance, leave the field blank for an unknown or "null" value.
4.1.3 Operating Parameter Serial Number Feature
The Parameter Number (CARD E2, cc 16 and 17) in the control device
operating parameter group is also a labor saving feature. The Control
Device/Treatment Process Operating Parameters as encoded for the first
Test ID Number will be printed in their entirety for succeeding Test ID
Numbers within the same Stream Number unless changed. Operating parameter
names and values which do not change between tests will be duplicated
automatically for subsequent tests provided that only the parameter number
is reentered for the new test.
If operating parameters happen to change between tests, only the
parameter number and its new value need to be encoded. The data which do
4.1-4
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not change do not have to be reencoded. The EDIT program will automatically
reproduce the parameter name.
Be sure to include a CARD El to identify the control device/treatment
process to which the parameters apply.
To null out a previously entered Parameter Name and Value, enter the
parameter number and enter NA for the parameter name. Here again, include a
CARD El.
4.1-5
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4.2 ENCODING INSTRUCTIONS
4.2-1
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GROUP A — SOURCE DESCRIPTION — FORM 1
Card Column
Data Element
Encoding Instructions
CARD AO
1
2-6
Data Base Code
Test Series
Number
7-8
9-11
12-13
14-15
16-35
Stream Number
Test ID Number
Sample Number
Card Number
Source Category
36-55
Source Type
56-75
Product/Device Type
Do not change. Denotes data base. G-GEDS.
Enter as a right-justified integer number
the permanent test series number, assigned by
the EADS Program Manager. If such an
assignment has not been made, enter a nonzero
sequential number for each test series
reported. This number will be used for
preliminary identification purposes only.
Leave blank.
Leave blank.
Leave blank.
Do not change.
Enter the source category as text from
Table A-l.* This is the grouping of major
generic industries or source classes; i.e.,
the broadest description of a source.
Examples include COMBUST-ENERGY, CHEMICAL
MANUFAC, METALS, and NATURAL PRODUCTS. Note
that the list of standard nomenclature is not
complete, but will be added to as needed.
Enter the source type as text from
Table A-l. This identifies the kind of
source within the source category. Examples
include INDUSTRIAL, INORGANIC ACIDS, PRIMARY
FERROUS, and WOOD.
Enter the product or device type as text from
Table A-l. This identifies the general
processes or the specific product. Examples
include BOILER, SULFURIC ACID, STEEL, and
PULP AND PAPER.
*In the Terminology Reference Manual
4.2-2
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GROUP A — SOURCE DESCRIPTION -- FORM 1
Card Column
Data Element
Encoding Instructions
CARD AO (cont.)
76-79 SIC Code
80
CARD Al
16-35
Blank
Process Type
36-41
42-47
48-57
Design Process Rate
Design Process Rate
Units
Feed Material
Category
58-80
Source Name*
Enter as a four-digit integer number the U.S.
Department of Commerce SIC Code for the
source. Use zeroes for unknown trailing
digits; e.g., textile mill products whose SIC
number is 22 would be entered as 2200. (See
the Standard Industrial Classification
Manual, Executive Office of the President --
Office of Management and Budget, prepared by
the Statistical Policy Division, 1972, GPO
Stock No. 4101-0066.)
Leave blank.
Enter the process type as text from
Table A-l. This identifies the unique
process being tested. Examples include
TANGENTIAL, CONTACT PROCESS, BLAST FURNACE,
and SULFATE PULPING.
Enter the design capacity of the process as a
right-justified integer number.
Enter the units of the design process rate
as text from Table A-14. The units should
reflect the type of process tested.
Enter as text from Table A-2 the general
category of the process feed material or
fuel. A detailed description of this is
given at the test data level. Examples
include COAL, OIL, GAS, WOOD, SOLIDWASTE, and
MTL SCRAP.
Enter the name of the source as text.
*Enter CONFIDENTIAL for confidential or proprietary data.
4.2-3
-------�
GROUP A - SOURCE DESCRIPTION -- FORM 1
Card Column
Data Element
Encoding Instructions
CARD A2
16-40
41-60
61-78
79-80
CARD A3
16-20
21-25
26-30
31-35
36-40
41-45
Site Name*
Street/Box Number**
City**
State**
Zip Code**
Country
FPEIS TSN
SDDS TSN
Blank
LEDS TSN
Enter as text the name of the site where the
source is located.
Enter the number and name of the source/site
street address as text.
Enter the name of the city, township or area.
Enter the two-letter code for the state or
Canadian Province in which the source is
located. Use the standard nomenclature in
Table A-3.
Enter the zip code in which the source is
located.
Enter as text an abbreviation for the country
in which the source is located. Use standard
nomenclature provided in Table A-3.
Enter the Fine Particle Emissions Information
System Test Series Number associated with
fine particulate information which was
collected from the same source during the
same sampling program, right-justified. If
none, leave blank.
Enter the Solid Discharge Data System Test
Series Number associated with solid discharge
sample and analysis results obtained from the
same source during the same sampling program,
right-justified. If none, leave blank.
Leave blank.
Enter the Liquid Effluent Data System Test
Series Number associated with liquid effluent
sample and analysis results obtained from the
same source during the same sampling program,
right-justified. If none, leave blank.
*Enter CONFIDENTIAL for confidential or proprietary data.
**Leave blank for confidential or proprietary data.
4.2-4
-------�
GROUP A -- SOURCE DESCRIPTION — FORM 1
Card Column
Data Element
Encoding Instructions
CARD A3 (cont.)
46-54 Blank
55-60 Start Date
61-66
67-80
CARD A4
16-45
46-55
56-58
59-80
Finish Date
Blank
Sponsor
Organization
Contract Number
TO/TD Number
Name of Sampling
Group/Contractor
CARDS A5 AND A6
16-80
CARD A7
16-45
Reference Report
Title*
Reference Report
Author**
Leave blank.
Enter the start date as MM-DD-YY. This is
the starting date of the field sampling.
Enter the finish date as MM-DD-YY. This is
the finishing date of the field sampling.
Leave blank.
Enter the name of the organization who
sponsors the sampling program as text
(e.g., EPA).
Enter the number of the sponsoring
organization contract as text.
Enter the EPA task order or technical
directive number as a right-justified
integer.
Enter the name of the sampling group or
contractor as text. If there is more than
one sampling group, enter additional groups
in test series comments.
Enter as text the title of the report from
which the data are reported. Use both cards
as needed.
Enter the name of the primary author of the
report as last name, first name, and initial
(e.g., Doe, John A.).
*Enter CONFIDENTIAL for confidential or proprietary data.
**Leave blank for confidential or proprietary data.
4.2-5
-------�
GROUP A — SOURCE DESCRIPTION — FORM 1
Card Column
Data Element
Encoding Instructions
CARD A7 (cont.)
46-65
66-80
CARD A8
16-35
36-80
Reference Report
Number**
Reference Report
Publication Date**
Reference Report
NTIS Number
Blank
Enter as text the number, as assigned by the
sponsoring organization, of the article or
report in which the data are reported.
Enter the publication date of the report in
text form as month and year (e.g., July 1979),
Enter the NTIS number of the report as text,
Leave blank.
**Leave blank for confidential or proprietary data.
4.2-6
-------�
GROUP B -- TEST SERIES COMMENTS -- FORM 1
!)ard Column
Data Element
Encoding Instructions
18-80
Line Number
Test Series
Comments
Enter a sequential integer number for each
line of test series comments.
Enter test series comments as text.
Unlimited cards may be added as needed.
4.2-7
-------�
GROUP C — STREAM DESIGN CHARACTERISTICS — FORM 2
Card Column
Data Element
Encoding Instructions
CARD CO
7-8 Stream Number
16-21
22-27
28-31
32-35
36-38
39-41
42-46
47-80
Flowrate
Flowrate Units
Velocity
Temperature
Pressure
Moisture Content
Stack height
Stream Name
CARDS Cl AND C2
16-80 Stream Comments
Enter a sequential, right-justified integer
number for each gas stream sampled at the
source.
Enter as a decimal number the design total
volumetric flowrate of the gas in the sampled
stream at normal maximum operating
conditions. The decimal point is indicated.
Enter the flowrate units as text from Table
A-14 (e.g., m3/s).
Enter as a decimal number the design velocity
of the gas stream in m/sec at normal maximum
operating conditions. The decimal point is
indicated.
Enter as a right-justified integer number
the design temperature of the gas in the
sampled stream at normal maximum operating
conditions in units of degrees Celsius.
Enter as a decimal number the design absolute
pressure, in units of kPa, of the gas stream
at normal maximum operating conditions. The
decimal point is indicated.
Enter as a decimal number the design moisture
content, in percent by volume, of the gas
stream at normal maximum operating
conditions. The decimal point is indicated.
Enter as a decimal number the height of the
stack in meters, relative to ground level.
The decimal point is indicated.
Assign a name for each gas stream sampled at
the source (i.e., process heater flue gas,
boiler flue gas, air preheater gas, etc.) and
enter as text.
Enter stream comments as text. Use both
cards as needed.
4.2-8
-------�
GROUP D - CONTROL DEVICE/TREATMENT PROCESS -- FORM 2
Card Column
Data Element
Encoding Instructions
CARD DO
16-17
18-37
38-70
71-80
CARD PI
16-35
36-47
48-77
78-80
Device Number
Generic Device/
Process Type
Design Type
Blank
Specific Process/
Device Type
Device/Process
Class
Device/Process
Commercial Name
Blank
Enter a serially assigned, right-justified
integer number for each control device and/or
treatment process. This number will remain
unique through the entire test series for a
specific control device/treatment process.
Up to five devices may be included per stream.
Note: Space for one control device/treatment
process is provided on Form 2. If
more than one device is encoded, do
not repeat CARDS CO, Cl, and C2 on
subsequent Form 2's for the same
stream.
Enter the type of generic process as text.
Use standard nomenclature provided in
Table A-4(a). If no control or treatment is
applied, enter "NONE". If not known enter
"NOT SPECIFIED".
Enter the control device/treatment process
design type as text. Use standard
nomenclature provided in Table A-4(a). If
none, leave blank.
Leave blank.
Enter the control device/treatment process
specific type as text. Use standard
nomenclature provided in Table A-4(a). If
none, leave blank.
Enter the device/process class as text. Use
only standard nomenclature given in Table A-5.
Enter the device/process commercial name and
model number (if known) as text.
Leave blank.
4.2-9
-------�
GROUP D -- CONTROL DEVICE/TREATMENT PROCESS -- FORM 2
Card Column
Data Element
Encoding Instructions
CARD D2
16-45
46-80
CARD D3
16-17,
48-49
18-47,
50-79
80
CARD D4
16-17
18-47
48
Manufacturer
Blank
Sequence Number
Device/Process
Keyword
Blank
Design Parameter
Number
Design Parameter
Name
Value Type
If cc 48 contains an N:
49-56 Number Value
57-80
Units
Enter the name of the device/process
manufacturer as text.
Leave blank.
Enter a sequential, right-justified integer
number for each device/process keyword to be
encoded. Enter first two keywords on the
first card (or line), etc. Add four more
cards as necessary.
Enter as text the word or words that best
describe the device/process in greater
detail. The selection of these keywords is
at the discretion of the encoder. Enter two
keywords per card.
Leave blank.
Enter a nonzero, sequential number (starting
from 1, right-justified) for the control
device design specification. Add five more
cards as necessary.
Enter as text the design specification as
standard nomenclature, from Table A-6(a).
Enter T if the parameter is a text parameter,
or N if it has a number value.
Enter the numeric value in the form
nnAnn E +_ nn.
Enter the units of the number value as text,
from Table A-6(a).
4.2-10
-------�
GROUP D — CONTROL DEVICE/TREATMENT PROCESS — FORM 2
Card Column
Data Element
Encoding Instructions
CARD D4 (cont.)
If cc 48 contains a T:
49-56 Blank
57-80 Text Value
Leave blank.
Enter the text value and any associated units.
4.2-1]
-------�
GROUP E -- TEST IDENTIFICATION -- FORM 3
Card Column
Data Element
Encoding Instructions
CARD EO
9-11
16-21
22-25
26-29
30-60
61-64
Test ID Number
65-80
CARD El
16-17
Test Date
Start Time
End Time
Operating Mode
Percent of Design
Capacity
Blank
Device/Process
Number
18-80
Blank
Enter a sequential, right-justified integer
number for each test. A test is defined as a
sample or series of samples at a particular
source/control operating condition at a given
point in time. This number may be serially
assigned by the user at the time the data is
encoded.
Enter the date the test was conducted or begun
as an integer number in the form MM-DD-YY.
Enter the test starting time as a right-
justified integer number, on the basis or a
24-hour day (military time).
Enter the test finish time as a right-
justified integer number, on the basis of a
24-hour day (military time).
Enter the mode of operation of the source at the
time of the test as text. Examples of modes are
batch, continuous, intermittent, cyclic, etc.
Enter the percent of the design capacity at
which the source is operating during the time of
the test as a decimal number. The decimal point
is indicated.
Leave blank.
Enter the unique identifying number for each
control device or treatment process as defined
previously on CARD DO in this test series.
Note: Space for two control device/treatment
processes is provided on Form 3. If more
than two devices are encoded, do not
repeat CARD EO on subsequent Form 3's for
the same Test ID.
Leave blank.
4.2-12
-------�
GROUP E — TEST IDENTIFICATION — FORM 3
Card Column Data Element Encoding Instructions
CARD E2
16-17 Operating Parameter Enter a sequential, right-justified
Number integer number for each of the control
device/treatment process operating
parameters. Twenty-one more cards may be
added as needed, per device.
18-47 Operating Parameter Enter the control device/treatment process
Name operating parameter as text using standard
nomenclature from Table A-6(a).
48 Value Type Enter N if the parameter has a number value,
and T if it 'is a text parameter.
If cc 48 contains an N:
49 > If the value of the parameter is indicated to
be less than or greater than a value, enter
the appropriate sign here. Otherwise, leave
blank.
50-56 Number Value Enter the numeric value in the form
n^nn E +_ nn.
57-80 Units Enter the units of the number value as text,
from Table A-6(a).
If cc 48 contains a T:
49-56 Blank Leave blank.
57-80 Text Value Enter the text value and any associated units.
CARDS E7, E8, and E9
16-80 Comments Enter comments pertaining to the test
operating conditions, as text.
Note: See Section 4.2 for a discussion of the labor saving feature for operating
parameters.
4.2-13
-------�
GROUP F — FUELS AND FEEDSTOCKS - FORM 4
Card Column
Data Element
Encoding Instructions
CARD FO
16-45
46-62
63-67
68-73
74-79
80
CARD Fl
16-55
56-58
59-63
64-70
71-79
80
Source Feed
Material
Feed Material Rate
and Units
Feed Material
Sample Mass
Feed Material
Mass Units
Blank
Feed Material
Sequence Number
Laboratory Name
QA/QC Code
Feed Material
Sample Volume
Volume Units
Blank
Feed Material
Sequence Number
Enter as text the specific name of the source
feed material (e.g., Western PA Bituminous).
If data are not available, enter "NOT
SPECIFIED".
Enter the measured operating (not design)
input rate of the source as text with the
appropriate units.
Enter the mass of the feed material sample as
a decimal number. The decimal point is
indicated.
Enter the appropriate units of the sample
as text, from Table A-14.
Leave blank.
Enter a sequential integer number to identify
each feed material or fuel type used.
Enter the name of the laboratory that
performed the fuels and/or feedstocks
analysis as text. If more than one
laboratory was used and the names do not fit
here, include one name here and the other(s)
in the comments on Form 5.
Enter the laboratory quality assurance/
quality control code, if known.
Enter the feed material sample volume as a
decimal number. The decimal point is
indicated.
Enter the appropriate volume units as text
from Table A-14.
Leave blank.
Same as CARD FO.
4.2-14
-------�
GROUP F — FUELS AND FEEDSTOCKS — FORM 4
Card Column
Data Element
Encoding Instructions
CARD F2
16-31,
43-61
32-38,
62-68
39-42,
69-73
74-79
80
CARD F3
16-25, 31-40
46-55, 61-70
76-79
80
CARD F4
16-27
Proximate Analysis
Parameter
Parameter Value
Units
Blank
Feed Material
Sequence Number
Ultimate Analysis
Parameter
26-30, 41-45 Value
56-60, 71-75
Blank
Feed Material
Sequence Number
Parameter
Name
The parameter associated with a proximate fuel
analysis as per ASTM D3172-73. This is
preprinted on the form.
Enter the value of the proximate analysis
parameter as a decimal number. The decimal
point is indicated.
These are preprinted on the form.
Leave blank.
Same as CARD FO.
The parameter associated with an ultimate
fuel analysis as per ASTM D3176-74. This is
preprinted on the form.
Enter the value of the ultimate analysis
parameter, as a decimal number, in units of
percent by weight. The decimal point is
indicated.
Leave blank.
Same as CARD FO.
28
Value Type
Enter the name of the fuels and feedstocks
parameter analyzed as text. Do not include
inorganic trace elements or organic chemical
species and compounds. Examples are bulk
density, viscosity, pour point, etc.
Enter N if the parameter has a number value
and T if it is a text parameter.
4.2-15
-------�
GROUP F -- FUELS AND FEEDSTOCKS — FORM 4
Card Column
Data Element
Encoding Instructions
CARD F4 (cont.)
If cc 28 contains N:
29 £
30-36
37-54
Number Value
Units
If cc 28 contains T:
29-36 Blank
37-54 Text Value
For both cases (T and N):
55-56 Analytical Method
57-64 High Detection
Limit
65-72 Low Detection Limit
73-79 Detection Limit
Units
80 Feed Material
Sequence Number
If the value of the parameter is indicated to
be less than or greater than a value, enter
the appropriate sign here. Otherwise, leave
blank.
Enter the value of the fuels and feedstocks
parameter analyzed, in the form nAnn E _+ nn.
Enter the units of the parameter analyzed as
text, from Table A-14.
Leave blank.
Enter the text value and any associated units
as text.
Using the standard nomenclature in Table A-8,
enter the two-character code for the chemical
analysis method used.
Enter the upper detection limit of the
analytical method in the form nnjin E +_ nn.
Enter the lower detection limit of the
analytical method in the form nnjin E + nn.
Enter the upper and lower detection limit
units as text from Table A-14.
Same as CARD FO.
4.2-16
-------�
GROUP F -- FUELS AND FEEDSTOCKS -- FORM 5
Card Column
Data Element
Encoding Instructions
CARD F5
16
17-26
27-28
29-36
37-44
45-52
53-60
61
62-68
69-79
80
Chemical ID
Type
Category/
Species ID
Analytical Method
High Detection
Limit
Low Detection Limit
Detection Limit
Units
Total Milligrams
Recovered
Actual
Concentration
Actual Concentra-
tion Units
Feed Material
Sequence Number
Enter the chemical entry code which
determines the type of chemical ID used.
Enter the letter C for CAS number and M for
MEG number. Unlimited cards may be added as
needed.
Enter the chemical ID for the organic
category or species, from Table A-7.
Enter the two-character code for the chemical
analysis method, from Table A-8.
Enter the upper detection limit of the
analytical method in the form nnAnn E ± nn.
Enter the lower detection limit of the
analytical method in the form nnAnn E + nn.
Enter the upper and lower detection limit
units as text, from Table A-14.
Enter as a decimal number the total
milligrams of the category/species found in
the sample. The decimal point is indicated.
If the actual concentration is indicated to
be less than or greater than a value, enter
the appropriate sign here. Otherwise, leave
blank.
Enter the concentration of the category/species,
in the form nAnn E _+ nn.
Enter units of actual concentration as text,
from Table A-14.
Same as CARD FO.
4.2-17
-------�
GROUP F -- FUELS AND FEEDSTOCKS — FORM 5
Card Column
Data Element
Encoding Instructions
CARDS F7, F8. and F9
16-79 Comments
80
Feed Material
Sequence Number
Enter comments regarding the analysis of the
fuels and feedstocks, starting on CARD F7, as
text.
Same as CARD FO.
4.2-18
-------�
GROUP H — SAMPLING ACTIVITY DESCRIPTION — FORM 6
Card Column
Data Element
Encoding Instructions
CARD HO
12-13
Sample Number
16
17-46
47-50
51-53
54-57
58-61
62-64
65-67
68-71
Blank
Measurement Instru-
ment/Method Name
Sampling Start Time
Sampling Duration
Measured Stream
Velocity
Measured Stream
Temperature
Measured Stream
Pressure
Measured Stream
Moisture Content
Blank
Enter a sequential integer number for each
sample, unique within each test ID. A sample
is defined as the measurement or group of
measurements taken with a single measurement
method to define the composition of a stream
at a given point in time. This number may be
assigned serially at the time the data is
encoded.
Leave blank.
Enter the name of the measurement instrument/
method as text using the standard
nomenclature given in Table A-9(b), and
elaborate in comments if necessary. If not
known, enter "NOT SPECIFIED".
Enter the start time of the sample collection
as a right-justified integer number using
military time.
Enter the duration in minutes of the sample
collection activity as a right-justified
integer number.
Enter as a decimal number the measured
velocity of the gas stream in units of
m/sec. The decimal point is indicated.
Enter as an integer number the measured
temperature of the gas stream in units of
degrees Celsius.
Enter as an integer number the measured
absolute pressure of the gas stream at the
sampling location in units of kPa.
Enter as a decimal number the measured
moisture content of the gas stream at the
sampling location in units of percent by
volume. The decimal point is indicated.
Leave blank.
4.2-19
-------�
GROUP H -- SAMPLING ACTIVITY DESCRIPTION -- FORM 6
Card Column
Data Element
Encoding Instructions
CARD HO (cont.)
72-76 Sample Volume
77-80
CARD HI
16-21
22-27
28-47
48-52
53-54
55-80
CARD H2
16
17-18
Blank
Measured Stream
Flowrate
Flowrate Units
Flowrate Measure-
ment Method
Sample Total Mass
Mass Units
Blank
Sampling Location
Code
Device/Process
Number
Enter as a decimal number the total gas
volume collected for the sample in units of
irr. The decimal point is indicated.
Leave blank.
Enter as a decimal number the measured total
volumetric flowrate of the gas stream at the
sampling location. The decimal point is
indicated.
Enter as text the units of the gas stream
flowrate from Table A-14.
Enter as text the technique or equipment
which was used to determine the gas stream
flowrate using the standard nomenclature
provided in Table A-10.
Enter as a decimal number the total mass of
the sample collected. The decimal point is
indicated.
Enter as text the units of the sample total
mass from Table A-14.
Leave blank.
Enter the code letter for the sampling
location as follows: I, inlet of control
device/treatment process, or 0, outlet of
control device/treatment process. If the
source is uncontrolled, enter I.
Enter the integer number which identifies
to which device or process the sampling
location code refers. (See CARD DO, columns
16-17.)
4.2-20
-------�
GROUP H — SAMPLING ACTIVITY DESCRIPTION — FORM 6
Card Column
Data Element
Encoding Instructions
CARD H2 (cont.)
19-48
Sampling Location
Description
49-80
Blank
Describe the sampling location in terms of
proximity to control devices and discharge
points. Enter as text any information that
affects the sampling and transport of discharges
or emissions. Identify any sources of possible
stratification. Be brief and use abbreviations.
Expand into comments as necessary.
Leave blank.
OMIT CARDS H3 AND H4 ENTIRELY.
CARD H5
16-70
Collection Surface/ Enter as text a description of any surface
Substrate or substrate used for sampling. For
instruments for which no collection surface
is needed, encode NONE.
71-80
Blank
CARDS H6. H7, H8, and H9
16-80 Comments
Leave blank.
Enter as text comments on the sampling
activity.
4.2-21
-------�
GROUP K -- COMPONENT — FORM 7
Card Column
Data Element
Encoding Instructions
CARD KO
16-17
18-29
Component Sequence
Number
Component Name
Enter a sequential integer number for each
component of the measurement method analyzed
starting with the component nearest to the
measurement method inlet.
t
Enter the specific component of the sampling
equipment as text. For example, the XAD-2
Resin in a SASS train could be a component
name; or an impinger. Use abbreviations if
necessary and clarify in comments on Form 6.
If the sample is not split into components,
enter "TOTAL SAMPLE".
30-33
34
35-41
42-80
CARD Kl
16-17
18-20
21-23
Blank
Component
Weight
Chemical Analysis
Laboratory Name
Component Sequence
Number
Chemical Lab QA/QC
Code
Radionuclide
Laboratory QA/QC
Code
Leave blank.
If the component weight is indicated to be
less than or greater than a value, enter the
appropriate sign. Otherwise, leave blank.
Enter the component weight in milligrams,
in the form nAnn E + nn.
Enter the name of the laboratory which
performed the chemical analysis on the gas
samples as text.
Same as CARD KO.
Enter the QA/QC code for the chemical
analysis laboratory, if known.
Enter the QA/QC code for the radionuclide
analysis laboratory, if known.
4.2-22
-------�
GROUP K — COMPONENT — FORM 7
Card Column
Data Element
Encoding Instructions
CARD Kl (cont.)
24-63
64-70
71-75
76-80
CARD K2
16-17
18-29
30
Radiological
Analysis Lab Name
Component Aliquot
Mass/Volume
Aliquot Units
Blank
Component Sequence
Number
Effluent Parameter
Name
Value Type
If cc 30 contains N:
31-35 Number Value
36-43
Value Units
If cc 30 contains T:
31-43 Text Value
Enter the name of the laboratory which
performed the radionuclide analysis on the
gas samples as text.
Enter the mass or volume of the sample
aliquot as a decimal number. The decimal
point is indicated.
Enter the units of the sample aliquot as
text, from Table A-14. These units will
identify the aliquot as mass or volume.
Leave blank.
Same as CARD KO.
Enter the name of the effluent parameter
analyzed as text. This entry is intended to
accommodate any quantitative measurement on
the gas sample with the exception of organic
and inorganic species measurements. Examples
are opacity, alkalinity, pH, etc.
Enter N if the parameter has a number value
and T if it has a text value.
Enter the value of the effluent parameter as
a decimal number. The decimal point is
indicated.
Enter the value units of the effluent
parameter as text, from Table A-14.
Enter the value and any associated units as
text.
4.2-23
-------�
GROUP K — COMPONENT — FORM 7
Card Column
Data Element
Encoding Instructions
CARD K2 (cont.)
For both cases (T and N):
44-45 Analytical Method
46-53 High Detection
Limit
54-60 Low Detection
Limit
61-69 Detection Limit
Units
70-80 Blank
CARDS K3 AND K4
16-17 Component Sequence
Number
18-80 Comments
Enter the two-character code for the analysis
method using the standard nomenclature
provided in Table A-8.
Enter the upper detection limit of the
analytical method in the form nnAnn E + nn.
Enter the lower detection limit of
the analytical method in the form nAnn E _+ nn,
Enter the upper and lower detection limit
units from Table A-14.
Leave blank.
Same as CARD KO.
Enter comments on the effluent
characteristics as text.
4.2-24
-------�
GROUP L — INORGANIC ANALYSIS/NON-LEVEL 1 ORGANIC ANALYSIS — FORM 8
Card Column
Data Element
Encoding Instructions
CARD LO
16-17
18
19-28
29-30
31-38
39-46
47-54
55-62
63
64-70
71-80
Component Sequence
Number
ID Type
Category/
Species ID
Analytical Method
Same as CARD KO.
Enter the chemical entry code which determines
the type of chemical ID used. Enter the
letter C for CAS number and M for MEG number.
Unlimited cards may be added as needed.
Enter as text the inorganic or .non-Level 1
organic species or compound ID for the
appropriate chemical entry code. Use the
standard nomenclature provided in Table A-7.
Enter the two-character code for the
appropriate analysis method using the standard
nomenclature in Table A-8.
High Detection Limit Enter the upper detection limit of the
analytical method in the form nnAnn E + nn.
Low Detection Limit Enter the lower detection limit of the
analytical method in the form nnAnn E j^ nn.
Detection Limit
Units
Total Milligrams
Recovered
Actual Source
Concentration
Blank
Enter as text the upper and lower detection
limit units from Table A-14.
Enter as a decimal number the total milligrams
of the species recovered from the sample
analyzed. The decimal point is indicated.
If the actual source concentration is
indicated to be less than or greater than a
value, enter the appropriate sign here.
Otherwise, leave blank.
Enter the concentration of the species
analyzed for this component in the form
nAnn E +_ nn. Units are yg/m3.
Leave blank.
4.2-25
-------�
GROUP L - INORGANIC ANALYSIS/NON-LEVEL 1 ORGANIC ANALYSIS — FORM 8
Card Column Data Element Encoding Instructions
CARDS LI and L2
16-17 Component Sequence Same as CARD KO.
Number
18-80 Comments Enter inorganic/non-Level 1 organic analysis
comments as text.
4.2-26
-------�
GROUP M — LEVEL 1 ORGANIC ANALYSIS — FORM 9
Card Column
Data Element
Encoding Instructions
CARD MO
16-17
18-20
21-26
27-32
33
34-43
44-45
46-53
54-61
62-69
Component Sequence
Number
Fraction ID
TCO
GRAV
ID Type
Category/
Species ID
Analytical Method
High Detection
Limit
Same as CARD KO.
Enter as text the organic fraction determined
by liquid chromatography per Level 1 analysis
procedures and designated LC1-LC7. Enter TOT
if the sample was not fractionated but TCO
and GRAV were done on the whole sample.
Unlimited cards may be added as needed.
Enter as a decimal number the total
chromatographable organics (TCO) measured for
each LC fraction in units of milligrams. The
decimal point is indicated.
Enter as a decimal number the weight in
milligrams of each LC fraction determined by
gravimetric analysis. The decimal point is
indicated.
The letter M is printed on the form as the
chemical entry code which identifies the type
of chemical ID used. The letter M is for MEG
number.
Enter as text the organic chemical category
or organic chemical species. Enter the
appropriate MEG ID number. Use standard
nomenclature provided in Table A-7.
Enter the two-character code for the
appropriate analysis method using the
standard nomenclature in Table A-8.
Enter the upper detection limit of the
analytical method in the form nnAnn E _+ nn.
Low Detection Limit Enter the lower detection limit of the
analytical method in the form nnAnn E j+ nn.
Detection Limit
Units
Enter as text the upper and lower detection
limit units from Table A-14.
4.2-27
-------�
GROUP M - LEVEL 1 ORGANIC ANALYSIS — FORM 9
Card Column
Data Element
Encoding Instructions
CARD MO (cont.)
70-72 Intensity
73
74-80
Actual Source
Concentration
CARDS Ml and M2
16-17
18-80
Component Sequence
Number
Comments
Enter as a right-justified integer number the
assigned intensity (in essence a weighting
factor) used to indicate relative presence of
chemical categories obtained from either
infrared (IR) or low resolution mass
spectrometry (LRMS) analysis data. Assigned
intensity values, either 100, 10, or 1, are
used to calculate concentration estimates.
An intensity is assigned for each category in
each LC fraction. Units are dimensionless.
If the actual source concentration is
indicated to be less than or greater than a
value, enter the appropriate sign here.
Otherwise, leave blank.
Enter in the form nAnn E +_ nn, the
concentration of each category in each LC
fraction for this component. These values
are calculated from the assigned
intensities. Units are yg/m^.
Same as CARD KO.
Enter comments on the Level 1 Organic
Analysis as text.
4.2-28
-------�
GROUP R -- RADIONUCLIDE DATA. - FORM .10
Card Column
Data Element
Encoding Instructions
CARD RO
16-17
18-25
26-27
28-35
36-43
44-51
52
53-59
Component Sequence
Number
Radionuclide ID
Analytical Method
High Detection
Limit
Low Detection Limit
Detection Limit
Units
Actual Source
Concentration
60-80 Blank
CARDS Rl AND R2
16-17 Component Sequence
Number
18-80 Comments
Same as CARD KO.
Enter the name of the isotope assayed as
text. The name is given as a symbol and mass
number separated by a dash (e.g., RA-226,
U-235, and BI-214). Unlimited cards may be
added as needed.
Enter the two-character code for the name of
the assay (analysis) method as text using
standard nomenclature provided in Table A-8.
Enter the upper detection limit of the assay
method in the form nnAnn E +_ nn.
Enter the lower detection limit of the assay
method in the form nnAnn E +_ nn.
Enter as text the upper and lower detection
limit units from Table A-14.
If the actual source concentration is
indicated to be less than or greater than a
value, enter the appropriate sign here.
Otherwise, leave blank.
Enter the actual source concentration of the
isotope for this component, in the form
nAnn E j^ nn. Units are
Leave blank.
Same as CARD KO.
Enter radionuclide data comments as text,
4.2-29
-------�
GROUP T -- BIOASSAY DATA - FORM 11
Card Column
Data Element
Encoding Instructions
CARD TO
16-40
41-70
Test Type
Test Name
71-76
77-80
CARD Tl
16-56
57-59
60-65
66-71
72-80
CARD T2
Test Duration
Lab Sample ID
Test Lab Name
Bioassay QA/QC
Code
Test Start
Test End
Blank
16-23 Sample Quantity
24-29 Sample Quantity
Units
30-80 Blank
Enter as text the name of the broad category
of bioassay test type using the standard
nomenclature provided in Table A-ll.
Enter as text the exact name of the bioassay
test (a subset of Test Type) using the
standard nomenclature provided in Table A-12.
Enter as a right-justified integer number the
duration of the test in hours.
Enter as a right-justified integer numbe^ the
unique sample ID as assigned by the test lab.
Enter the name of the bioassay testing
laboratory as text.
Enter the bioassay laboratory QA/QC code, if
known.
Enter the start date of the bioassay test as
integer numbers in the form MM-DD-YY.
Enter the end date of the bioassay test as
integer numbers in the form MM-DD-YY.
Leave blank.
Enter as a right-justified integer number the
value indicating the quantity of sample
submitted for analysis.
Enter as text the units of the sample quantity
submitted for analysis, from Table A-14.
Leave blank.
4.2-30
-------�
GROUP T -- BIOASSAY DATA — FORM 11
Card Column
Data Element
Encoding Instructions
CARD T3
16-80
CARD T4
16-19
20-26
27-34
35-41
Test Organisms/
Strains
Type of Value
Value
Value Units
High Confidence
Limit
Enter as text the name of the specific test
organism used. Multiple entries are
permitted for those assays in which more than
one organism is used. For example,
SALMONELLA TYPHIMURIUM TA-1538 and TA-98 may
be used in the same Ames test. Standard
nomenclature is provided in Table A-13.
Unlimited cards may be added as needed.
Enter one organism/strain per card.
Depending on the assay, enter the value type,
such as LD, EC, or LC as text.
Enter the assay results value in the form
nAnn E + nn.
Enter the units of the assay results value as
text from Table A-14.
Enter the upper confidence limit of the
assay results value in the form nAnn E + nn.
42-48
49-56
57-65
66-79
Low Confidence
Limit
Maximum Applicable
Dose (MAD)
80
MAD Units
Level of Toxicity
Blank
Enter the lower confidence limit of the
assay results value in the form nAnn E +_ nn.
Enter the technical limitation on the dose
allowed in a particular assay. The units
will vary according to the assay. For
example, Ames MAD = 5 mg/plate, RAM MAD = 1
mg/ml, RODENT MAD = 10,000 mg/kg. Enter in
the form nAnnn E ^ nn.
Enter the maximum applicable dose units as
text from Table A-14.
Enter HIGH, MODERATE, LOW, or NOT DETECTABLE
as a qualitative expression of the bioassay
results based upon a predefined range in
EC50> or LC50> etc-
Leave blank.
4.2-31
-------�
GROUP T -- BIOASSAY DATA -- FORM 11
Card Column
Data Element
Encoding Instructions
CARD T5
16-29
30-36
37-43
44-60
61-80
CARD T9
16-17
18-80
Bacteria Muta-
genicity Response
Minimum Effective
Concentration (MEC)
Minimum Effective
Concentration Units
Approximate Con-
centration Factor
Blank
Line Number
Comments
Enter POSITIVE or NEGATIVE to indicate the
Ames test response.
Enter the minimum effective concentration
(MEC). If a positive response is obtained
from an Ames test, the MEC is the minimum
concentration that gives a positive
response. Enter in the form nAnn E +_ nn.
Enter the units of the minimum effective
concentration as text from Table A-14.
Enter the factor as text which accounts for
any aliquot taken during the bioassay lab
procedures. It does not refer to the process
stream flow.
Leave blank.
Enter a sequential, right-justified integer
line number (i.e.. 1, 2, 3...). Unlimited
cards may be added as needed.
Enter bioassay comments as text.
4.2-32
-------�
TABLE 4-1. ENGINEERING UNITS
Since computer encoding of units does not allow the use of Greek letters
or lower case letters, the following protocol for the encoding of
engineering
units is defined:
Base Units
Ampere
Curie
Day
Degree Celsius
Hour
Gram
Joule
Liter
Meter
Metric ton
Mho (conductivity)
Minute
Ohm (resistance)
Pascal
Percent
Percent by volume
Percent by weight
Second
Watt
Adapted SI Prefixes
Factor
1018
1012
109
106
103
10-2
ID'3
io-6
10-9
10-12
Special Prefixes
Actual
Dry normal
Normal
Parts per
Prefix
exa
tera
mega
kilo
centi
mi 1 1 i
micro
nano
pico
Encode
A
CI
DAY
C
HR
G
0
L
M
T
MHO
MIN
OHM
PA
%
% VOL
% WT
S
W
SI Symbol
E
T
G
M
k
c
m
y
n
P
Encode
A
DN
N
PP
Encode
E
T
G
M6
K
C
M
U
N
P
4.2-33
-------�
TABLE 4-1. Concluded
Examples of Derived Units Encode
Actual cubic meters AM3
Centimeters CM
Centimeters/second CM/S
Cubic meters/second M3/S
Dry normal cubic meters DNM3
Grams per cubic centimeter (density) G/CM3
Joule per hour J/HR
Kilogram KG
Kilograms of steam per hour KG/HR
Kilojoules/kilogram (heat content) KJ/KG
Kilopascals (kPa) (pressure) KPA
Kilowatt KW
Kilowatt-hour KWH
Liters per second L/S
Liters per minute L/MIN
Megawatt MW
Meters per second M/S
Metric tons per day T/DAY
Micrograms (yg) UG
Microgram per cubic meter UG/M3
Microgram per gram UG/G
Microgram per liter UG/L
Micro mho (conductivity) UMHO
Micron (ym) UM
Milligrams (mg) MG
Milligrams per plate MG/PLATE
Milligrams per mi Hi liter MG/ML
Milligrams per kilogram MG/KG
Mi Hi liter ML
Normal cubic meters per minute NM3/MIN
Parts per billion PPB
Parts per million PPM
Picocurie (pCi) PCI
Picocuries per cubic meter PCI/M3
Picocuries per gram PCI/G
Picocuries per liter PCI/L
Square centimeters (cm2) CM2
Square meters (m2) M2
4.2-34
-------�
TABLE 4-2. CONVERSION FACTORS TO METRIC UNITS
To Convert From:
acre
atmosphere
barrel
Btu
Btu/hour
Btu/pound (mass)
Btu/second
calorie (International Table)
degree Fahrenheit
foot
foot?
foot3
gallon
gallon
grain
grain/foot3
horsepower
(550 foot-pound force/second)
inch
inch
inch2
inch3
inch of mercury (60°F)
inch of water (60°F)
kilocal orie
kilowatt-hour
liter
mil
mile (U.S. Statute)
mile/hour
ounce (mass AVDP)
ounce (U.S. fluid)
To:
meter?
pascal
meter3
joule
watt
kilojoule/kilogram
watt
joule
degree Celsius
meter
meter2
meter3
liter
meter3
milligram
gram/meter3
watt
centimeter
meter
meter2
meter3
pascal
pascal
joule
joule
meter3
meter
meter
meter/second
kilogram
meter3
Multiply By:
4.05
1.01
E +
E +
E -
E +
1.59
1.06
2.93 E -
2.33 E +
1.06 E +
03
05
01
03
01
00
03
4.19 E + 00
(tF-32) 5/9
3.05 E - 01
9.29 E - 02
2.83 E - 02
3.79 E + 00
3.79 E - 03
6.48 E + 01
2.29 E + 00
7.46 E + 02
2.
2.
,54
,54
6.45
1.64
3.38
2.49
E +
E -
E -
E -
E +
E +
4.19 E +
3.60 E +
2.54 E -
1.61 E +
4.47 E -
00
02
04
05
03
02
03
06
1.00 E - 03
2.83
2.96
E -
E -
05
03
01
02
05
4.2-35
-------�
TABLE 4-2. Concluded
To Convert From: To: Multiply By:
pint (U.S. liquid) meter3 4.73 E - 04
pound (mass AVDP) kilogram 4.54 E - 01
pound/million Btu nanogram/joule 4.30 E + 02
pound/inch^ (psi) pascal 6.89 E + 03
pound/foot3 kilogram/meter3 1.60 E + 01
pound (thousands)/hour kilogram/second 1.26 E - 01
quart liter 9.46 E - 01
quart meter3 9.46 E - 04
ton (long = 2240 pounds) kilogram 1.02 E + 03
ton (short = 2000 pounds) kilogram 9.07 E + 02
tonne (metric ton) kilogram 1.00 E + 03
yard meter 9.14 E - 01
-------�
SECTION 5
DATA SUBMITTAL
5.0 INTRODUCTION
The purpose of this section is to provide users of the GEDS with
instructions for submitting new data for entry to the GEDS data base and
to describe the quality assurance and quality control activities which
will be performed on all data submitted. Previous sections in this User
Guide have discussed how the sampling data are to be organized and encoded
on the GEDS Data Input Forms. This section will provide the protocol for
transferring the data from the data sheets to a form that can be read by
the computer. Once this step is completed, instructions are given
regarding to whom the data should be sent and what documentation should be
provided. Next, the review cycle by the EADS Technical Support Staff is
described. The function of the EDIT program and LOADER program is
discussed, and the output of each program is described and interpreted.
5.0-1
-------�
5.1 DATA INPUT FORM PROCESSING
The GEDS data input forms are designed to be entered into the
computer initially as 80-character records either as computer cards or
card images that can be interpreted by the UNI VAC U-1100 computer. It is
the responsibility of the submittor to ensure that the data are keypunched
and verified. The character set to be used should be compatible with the
IBM 029 set.
Cards should be segregated by Test Series Number (TSN) and should
be packaged in boxes (if they are to be mailed). Data may be submitted on
magnetic tape; however, before attempting to do so, the user should
contact the EADS Program Manager for guidance. The manner in which
computer tapes are formatted and read varies widely; thus, each tape
submittal must be handled differently. The EADS Technical Support Staff
will coordinate information between the user and the National Computer
Center staff to ensure that the user's tape will be compatible with the
UNIVAC U-1100. Magnetic tapes to be mailed should be packaged properly in
specially-designed tape containers for shipment. Such containers are
generally available in most data centers.
When the data input forms have been converted into a
machine-readable format for the computer, the submittor should retain the
data forms for reference until the test series has been loaded into the
data base.
5.1-1
-------�
5.2 SUBMITTAL PROCEDURES
All data in machine-readable format (usually cards) should be sent
to the EADS Program Manager accompanied by a cover letter that describes
each test series submitted. A sample cover letter is given in
Figure 5-1. The complete address is as follows:
Gary L. Johnson
EADS Program Manager
Industrial Environmental Research Laboratory
U.S. Environmental Protection Agency
Mail Drop 63
Research Triangle Park, NC 27711
REMINDER: No test series should be submitted until it has been assigned a
unique Test Series Number (TSN) by the EADS Program Manager. As described
in Section 4, the TSN must be encoded in columns 2-6 on each card
submitted. If a permanent TSN has not been assigned, then the encoder
should write or call the EADS Program Manager prior to submitting the data.
Once the data have been received, the encoder will be sent a letter
acknowledging receipt of the data and notifying him that EDIT processing
of the data has commenced. A sample acknowledgement letter is given in
Figure 5-2.
In some cases, EADS users will have the facilities available to
directly submit the test series cards to the National Computer Center.
This is allowed; however, the submitter should contact the EADS Program
Manager for technical guidance prior to doing so.
5.2-1
-------�
Gary L. Johnson
EADS Program Manager
Industrial Environmental Research Laboratory
Mail Drop 63
Research Triangle Park, NC 27711
Dear Mr. Johnson:
Enclosed you will find punched cards for FPEIS Test Series 200, GEDS Test
Series 27, LEDS Test Series 352, and SODS Test Series 14. These test
series represent multimedia sampling performed at a confidential power
plant site as part of EPA Contract No. 68-02-9999.
Very truly yours,
John A. Doe, Ph.D.
Ozone National Laboratory
Enclosure
Figure 5-1. Sample data submittal letter.
5.2-2
-------�
Dr. John A. Doe
Ozone National Laboratory
1234 Anystreet Drive
Hometown, CA 99999
Dear Dr. Doe:
This letter is to acknowledge our receipt of source testing data for
the following data bases and test series: FPEIS TSN 200, GEDS TSN 27,
LEDS TSN 352, and SDDS TSN 14.
In a short time, you will be contacted by the EADS Technical Staff re-
garding any corrections to the data that may be required prior to load-
ing the data into the appropriate media data base.
Thank you very much for your support of the EADS. If you have any ques-
tions, please feel free to call me at (919) 541-2745.
Very truly yours,
Gary L. Johnson
EADS Program Manager (MD-63)
Figure 5-2. Sample data submittal acknowledgement letter.
5.2-3
-------�
5.3 REVIEW AND CORRECTIVE ACTION PROCEDURES
The responsibility for determining the validity of the data
submitted lies with the encoder; however, the EADS Technical Staff will
assist the encoder by identifying errors that must be corrected before the
data can be loaded into the data base.
Upon receipt of the card deck (or decks) submitted by the encoder,
the EADS Program Manager's office will, load the cards into a card-image
file on the UNI VAC U-1100 computer at Research Triangle Park, NC. The
appropriate EADS Technical Staff persons will be notified that a new test
series has been received and that quality assurance (QA) activities may
begin for that test series.
The EADS QA activities are shown schematically in Figure 5-3. The
test series received will be processed through the EADS EDIT program which
will produce a SERIES Report-format listing of the input data, a list of
all errors detected, and a list of all cards contained in the test
series. The EDIT program is described in detail in Section 5.4 which
follows. Initially, the EADS Technical Staff will review the EDIT report
and will identify any obvious errors. These errors will be corrected by
the Technical Staff and a new EDIT report will be produced. It should be
noted that by "obvious errors" we are referring to errors such as
encoding, keypunching, or spelling errors, etc. The Technical Staff
cannot and will not attempt to correct any data with respect to accuracy
or validity, or otherwise pass engineering judgment on the submitted data,
etc. Any errors in measurement data or descriptive data must be
identified and corrected by the encoder of the data.
The corrected EDIT report will be,mailed to. the encoder for his
review. Any changes to the data should be marked legibly on the
5.3-1
-------�
r
Cards
en
ro
Edit
program
Data file
(intermediate
storage)
Loader
in
a>
x
EADS staff
review
Sampling
contractor
review
Error list
Report
(test series
format)
EADS
data
base
Report
Test series
report
Figure 5-3. QA procedure.
-------�
printout. Telephone interaction with the EADS Technical Staff to answer
questions, or to clarify data as they are encoded, is encouraged. The
marked EDIT report with the corrections should be returned to the
Technical Staff promptly. The Technical Staff will implement the
recommended changes and will produce another EDIT report. If no errors
are detected, the EDIT report will be returned to the encoder for final
verification. If the encoder is satisfied that the data are correct (and
valid) as submitted, then he should notify the Technical Staff that the
data are ready to load into the data base. If any errors remain after
review by the encoder, the changes should again be marked on the EDIT
report and it should be returned to the Technical Staff. This corrective
action QA cycle will be repeated until the submittor okays the data for
data base entry. No data will be loaded until encoder approval is
obtained.
Once final approval of the data is received from the submittor, the
test series is processed through the LOAD program, which actually loads
CR)
the sampling activity results into the SYSTEM 2000^-^data base management
structure described in Section 2. The specific details of the LOAD
program are given in Section 5.4, following.
When the test series has been loaded into the data base, a copy of
the SERIES report (see Section 7) will be sent to the submittor to
acknowledge the event. At this point, the contents of the test series are
available to be compared with any other data contained in the data base;
that is, only now will the test series be available for public access.
5.3-3
-------�
5.4 EDIT/LOAD PROGRAMS
5.4.1 EDIT Program
The EADS EDIT program provides three functions on the data being
submitted for entry to the EADS data base. First, it processes and lists
all input cards for a test series, duplicating or filling data fields on
cards as instructed by the Repetitive Data Feature protocol (described in
Section 4). Second, the EDIT program produces a report that is formatted
similarly to the SERIES Report, which allows visual editing to be done in
a format familiar to the user. Third, the program performs values and
range checks on input data fields, such as those fields that require
standard nomenclature, and lists any errors detected. The EDIT program
does not replace actual reviewing of the data by the EADS Technical Staff
or, more importantly, by the submitter of the data.
An example EADS EDIT is given in Figure 5-4. Each page in the
SERIES report format has the form number given in the upper right corner
that identifies the data input form on which the data were encoded. It
should be noted that in the SERIES report format all analytical codes have
been translated into the full description and all chemical ID's have been
expanded to report both the MEG ID and the CAS Number, the chemical
preferred name and any synonyms, and the chemical formula. The EDIT
report reflects the data as they are encoded, that is, the format follows
the pyramid structure form by form. This means that the chemical data
(Non-Level 1 Organic/Inorganic and Level 1 Organic) at the SAMPLE level in
the data base are summarized by COMPONENT. The actual SERIES report
differs from this in that the chemical data are summarized by chemical
species (or Level 1 fraction). The same is true for the radionuclide
5.4-1
-------�
data. The EADS user should refer to Section 7 for more details on the
SERIES report.
Following the listing of the input in the SERIES (EDIT) format, a
summary of administrative data is presented on the TEST SERIES. The
submitter is identified as well as the sponsor, contract number, etc. The
principal milestones in the EDIT review cycle are documented.
After the administrative data, all of the input cards are listed
and numbered sequentially as received. This provides an easy reference to
the card images when errors are found. The EADS Technical Staff will
correct any errors in this card image file using the UNIVAC Text Editor,
which allows on-line changes to be made.
Following the listing of the input data cards, the ERROR file is
printed. The ERROR file contains a list of all of the errors detected by
the EDIT program. For each input card on which an error is found, the
card number and entire card text are printed, the error number is given,
the type of error (F = fatal or W = warning) is given, the data base
component number affected is shown, and the error message is listed. The
complete list of error messages is given in Appendix A.I. The format for
the ERROR file data is shown below:
15 F000110100101K001
No. Type Component Message
163 F C1305 Component Name Missing
The user may refer to the Glossary of Data Elements in Appendix A.3
for a complete description of the component number. It should be noted
that the ERROR file will only identify those fields left out or those
having standard nomenclature to which comparisons may be made. As stated
5.4-2
-------�
previously, the ERROR file does not replace visual checking of the data by
the Technical Staff or validation of the data by the submitter.
5.4.2 LOAD Program
After the data have been reviewed completely and have been approved
for data base entry, the LOAD program is used to enter the test series
into the data base. Loading of the data base is accomplished by the EADS
Technical Staff. The LOAD program has no specific output like the EDIT
program. Verification of data loading is made by the Technical Staff by
checking the data base. Successful completion of the loading process will
be acknowledged to the submitter of the data by his receipt of the SERIES
report print-out.
The operation of the LOAD program is basically simple. The
expanded EDIT-LOAD file is the input file to the LOAD program. The file
is segmented into blocks of data which represent the principal levels of
the data base structure. Using the Test Series Number, Stream Number,
Sample Number, and Component Number as indices, the data are loaded into
fib
the SYSTEM 2000^ pyramid structure through a mechanism called Procedure
fift
Language Interface (PLI), a major feature of SYSTEM 2000-^. The reader
(R)
is referred to the appropriate SYSTEM 2000^-documentation for a
complete discussion of the PLI feature.
5.4-3
-------�
GEDS SERIES REPORT
FORM 1
PAGE 1
DATE 04/02/80
TEST SERIES NO:
101 DESCRIBES SAMPLING AT SITE FROM 08/27/77 TO 09/01/77 BY ACUREX
SPONSOR ORGANIZATION: EPA
CONTRACT NUMBER: 68-02-2160
TASK/DIRECTIVE NUMBER: 123
SOURCE DESCRIPTION-
SOURCE CATEGORY:
SOURCE TYPE:
PRODUCT/DEVICE:
PROCESS TYPE:
DESIGN PROCESS RATE:
FEED MATERIAL CATEGORY:
COMBUST-ENERGY
UTILITY
BOILER
TANGENTIAL
200 MM
COAL
SOURCE NAME:
SITE NAME:
ADDRESS:
NPDES NUMBER:
UNIT A
KINGSTON STEAM PLANT
KINGSTON ,TN
00000
27607 USA
EADS WASTE STREAM DATA BASES-
REFERENCE REPORT-
cn
WASTE STREAM DATA FROM OTHER MEDIA WHICH WERE COLLECTED CONCURRENTLY WITH THIS TEST SERIES
ARE AS FOLLOWSCTEST SERIES NUMBER-TSN):
FPEIS TSN: 00103
LEDS TSN: 00102
GEDS TSN: 00000
SDDS TSN: 00100
TITLE
AUTHOR
SPONSOR REPORT NUMBER
NTIS NUMBER
PUBLICATION DATE
FIELD TESTING OF A TANGENTIAL COAL-FIRED UTILITY BOILER—
EFFECTS OF COMBUSTION MODIFICATION NOX CONTROL ON MULTIMEDIA EMIS
HIGGEBOTHAM E B
ACUREX REPORT 79-337 APRIL 1979
TEST SERIES COMMENTS-
01 LEVEL 1 TESTING FOR EFFECTS DUE TO NOX COMBUSTION MODIFICATIONS
02 TEST tl BASELINE
03 TEST *2 BURNERS OUT OF SERVICE
Oft TEST *3 BIASED FIRING
Figure 5-4. Sample EDIT outnut.
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TEST SERIES NO: 00101
STREAM NO: 01
FORM 2
PAGE 2
DATE 04/02/80
EFFLUENT STREAM DESIGN CHARACTERISTICS-
STREAM NAME: BOILER FLUE GAS
STREAM DESIGN DATA AT SOURCE
MOISTURE CONTENT= 3. 4 PCT MASS/VOLUMETRIC FLOW RATE= 123. 4 M3/SEC VELOCITY'
TEMPERATURE= 100 C PRESSURE= 1.20 KPA STACK HEIGHT= 100.1 METERS
45.6 M/S
COMMENTS:
FLUE GAS INLET TO ID FAN
SIGNIFICANT PITTING NOTED IN ID FAN BLADES.
CONTROL/TREATMENT SYSTEM CHARACTERISTICS
DEVICE 01
cn
in
GENERIC SYSTEM TYPE:
MECHANICAL COLLECTOR
DESIGN TYPE: CYCLONES
SPECIFIC PROCESS/DEVICE: DUSKOLECTOR
DEVICE/PROCESS CATEGORY KEYWORDS: 01
02
03
DEVICE CLASS:
COMMERICAL NAME:
MANUFACTURER:
CONVENTIONAL
DUSKOLECTOR
DUSKOLECTOR,INC.
HIGH PRESSURE
LOW ENERGY
STAINLESS STEEL
DEVICE/PROCESS DESIGN PARAMETERS:
01 PRESSURE DROP
02 DESIGN EFFICIENCY
03 DESIGN TEMPERATURE
04 DESIGN FLOW RATE
05 DESIGN POWER CONSUMPTION
2.60E+00 KPA
9.00E+01 % AT 100 M3
150-250 C
l.OOE+02 M3/S
1.50E+00 KWH
DEVICE 02
GENERIC SYSTEM TYPE:
DESIGN TYPE:
SPECIFIC PROCESS/DEVICE:
ESP
SINGLE STAGE ESP
PLATE
DEVICE/PROCESS CATEGORY KEYWORDS:
01
02
03
DEVICE CLASS:
COMMERICAL NAME:
MANUFACTURER:
HOTSIDE
DRY
HI VOLTAGE
CONVENTIONAL
R/C MODEL 16A
RESEARCH-COTTRELL
DEVICE/PROCESS DESIGN PARAMETERS: 01
PLATE AREA
2.0(lE-t-02 M2
-------�
02 PLATE-PLATE SPACING I.25E+00 CM
03 DESIGN MASS EFFICIENCY 98 %
Oft BULK LINEAR VELOCITY 2.80E + 01 M/S
05 DESIGN PRESSURE DROP 5.49E-01 KPA
CTi
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TEST SERIES NO: 00101
STREAM NO: 01
FORM 2A
PAGE 3
DATE 04/02/80
CONTROL/TREATMENT SYSTEM CHARACTERISTICS
DEVICE 03
GENERIC SYSTEM TYPE:
DESIGN TYPE:
SPECIFIC PROCESS/DEVICE:
LIQUID SCRUBBERS
ABSORPTION PROCESSES
MAGNESIUM OXIDE
DEVICE CLASS:
COMMERICAL NAME:
MANUFACTURER:
PILOT
MAG-OX SCRUBBER
TAKAHASHI ALI, LTD
DEVICE/PROCESS CATEGORY KEYWORDS:
01
02
MECHANICAL AIDED
MOVING BED
DEVICE/PROCESS DESIGN PARAMETERS:
01 DESIGN PRESSURE DROP
02 INLET GAS VELOCITY
03 DESIGN LIQUID LOADING
04 DESIGN EFFICIENCY
5.88E-01 KPA
5.50E+01 M/S
6.50E+01 L/M3
90 %
en
•
i
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TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
FORM 3
PAGE 4
DATE 04/02/80
SOURCE/PROCESS CONDITIONS DATA
TEST CONDITIONS
TEST DATE: 08/30/77 TEST START TIME: 0012 FINISH TIME: 0100
SOURCE OPERATING MODE: CONTINUOUS STEADY STATE PERCENT OF DESIGN CAPACITY= 89.0
CONTROL SYSTEM OPERATING PARAMETERS
DEVICE 01
01
02
POWER CONSUMPTION
PRESSURE DROP
1.25E+00 KWH
8.50E-01 KPA
CONTROL SYSTEM OPERATING PARAMETERS
DEVICE 02
I
CO
01
02
PRESSURE DROP
INLET GAS VELOCITY
4.50E-01 KPA
1.25E+01 M/S
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TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
FORM 4
PAGE 5
DATE 04/02/80
FUELS AND FEEDSTOCKS CHARACTERISTICS
SOURCE FUEL/FEED MATERIAL: COAL FEED MATERIAL RATE: 8.66 KG/SEC
NAME OF ANALYTICAL LABORATORY: COMMERCIAL TESTING AND ENGINEERING CO. QA AUDIT CODE: 026
SAMPLE MASS: 1.50 KG SAMPLE VOLUME: 3.45 M3
PROXIMATE ANALYSIS:
MOISTURE
ASH
VOLATILE MATTER
FIXED CARBON
SULFUR
HEAT CONTENT
2.0 %WT
19.6 5SWT
31.8 %WT
46.5 5JWT
2.2 %WT
36288. J/G
tn
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I
10
ULTIMATE ANALYSIS:
PARAMETER
PERCENT BY WEIGHT
CARBON
HYDROGEN
SULFUR
NITROGEN
ASH
MOISTURE
OXYGEN
63.1
4.3
2.2
1.4
19.6
2.0
7.3
CHARACTERISTICS:
PARAMETER
ANALYTICAL METHOD
HIGH LOW DETECTION
DETECTION DETECTION LIMIT
LIMIT LIMIT UNITS
VALUE
UNITS
DENSITY
PH
COLOR
OTHER(SEE FUEL AND FEEDSTOCK COMMENTS)
WET CHEMICAL ANALYSIS (NOT SPECIFIED)
OTHER(SEE FUEL AND FEEDSTOCK COMMENTS)
1.40E+01 1.50E-01
2.5 G/CM3
8.5
BLACKISH GRAY
-------�
TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
PAGE 6
FORM 5 DATE 04/02/80
FUELS AND FEEDSTOCKS CHARACTERISTICS CONTD
CHEMICAL ANALYSIS.- THE CHEMICAL DATA ARE LISTED IN THE FOLLOWING ORDER
MEG NUMBER CAS NUMBER PREFERRED CHEMICAL NAME
OTHER NAME COMMONLY USED
ANALYTICAL METHOD
EMPIRICAL FORMULA
DETECTION LIMITS
TOTAL CONCEN-
MG TRATION
RECOVERED (UG/M3)
en
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32
37
68
74
72
71
76
07440-39-3 BARIUM- FREE AND COMBINED
BARIUM- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07440-41-7 BERYLLIUM- FREE AND COMBINED
GLUCINIUM
BERYLLIUM- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07440-42-8 BORON- FREE AND COMBINED
BORON- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07440-47-3 CHROMIUM- FREE AND COMBINED
CHROMIUM- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07440-48-4 COBALT- FREE AND COMBINED
COBALT-.FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07439-89-6 IRON- FREE AND COMBINED
IRON- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07439-92-1 LEAD- FREE AND COMBINED
LEAD- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
MANGANESE- FREE AND COMBINED
MANGANESE- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
07440-02-0 NICKEL- FREE AND COMBINED
NICKEL- FREE AND COMBINED
ATOMIC ABSORPTION SPECTROMETRY
BA
3.00E+03 5.00E-04 MG
BE
3.00E+03 5.00E-04 MG
B
CR
CO
FE
PB
MN
NI
12.123 >1.20E+02
11.543 1.40E+00
l.OOE+00
2.60E+01
8.60E+00
6.40E+03
1.40E+01
1.70E+01
6.00E-01
FUELS AND FEEDSTOCKS COMMENTS:
SAMPLE TAKEN 5 METERS ABOVE GROUND LEVEL.
BELOW 5-METER LEVEL WAS FROM DIFFERENT SOURCE.
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TEST SERIES NO: 00101 STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01
PAGE 7
FORM 6 DATE 04/02/80
SAMPLING ACTIVITY DESCRIPTION
MEASUREMENT INSTRUMENT/METHOD NO: 00 NAME: SASS TRAIN WITH/CYCLONES SAMPLING START TIME: 1234 DURATION: 1 MIN
SAMPLING CONDITIONS-- MASS/VOLUMETRIC FLOWRATE= 1.2 L/S FLOWRATE METHOD: PITOT TUBE TEMPERATURE' 45 C
MOISTURE CONTENT= 6.6 PCT VELOCITY= 12.3 M/SEC PRESSURE= 46 KPA
SAMPLE DENSITY= G/CM3 DENSITY DETERMINATION: MEASURED
COMMENTS ON THE SAMPLING ACTIVITY
THE IMPINGERS MERE COMBINED.
tn
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TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01
COMPONENT NO: 01
FORM 7
PAGE 8
DATE 04/02/80
COMPONENT NAME: EAD-2 CARTDG STAGE/FILTER CUT SIZE: UM MASS: 1.23E+01 UG/M3
CHEMICAL LABORATORY QA AUDIT CODE: 024 RADIOLOGICAL LABORATORY QA AUDIT CODE: 019
RADIOLOGICAL ANALYSIS LABORATORY NAME: FONDA NUCLEAR LABS
COMPONENT (ALIQUOT)VOLUME: 1.230 MG
EFFUENT CHARACTERISTIC SUMMARY-
PARAMETER
PH
ANALYTICAL METHOD
WET CHEMICAL ANALYSIS (NOT SPE
HIGH LOW DETECTION
DETECTION DETECTION LIMIT
LIMIT LIMIT UNITS
VALUE
UNITS
5.6-6.3
r\>
COMMENTS: NO WIND SPEED MEASUREMENTS WERE MADE.
-------�
TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01 COMPONENT NO: 01
LEVEL 1 ORGANIC EXTRACTION SUMMARY
THE EXTENDED CHEMICAL DATA ARE GIVEN IN FOLLOWING ORDER:
MEG NUMBER CATEGORY/SPECIES NAME
ANALYTICAL METHOD
HIGH/LOW DETECTION LIMITS AND UNITS
FRACTION
ID
INTENSITY
PAGE , 9
FORM 9 DATE 04/02/80
ESTIMATED
CONCENTRATION
(UM/M3)
01
08
tn
CO
16
11
18
ALIPHATIC HYDROCARBONS
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-06 MG
CARBOXYLIC ACIDS AND DERIVATIVES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
NITROSAMINES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-06 MG
HALOGENATED AROMATIC COMPOUNDS
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
1.OOE+05 l.OOE-04 MG
AZO COMPOUNDS, HYDRAZINE DERIVATIVES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
SULFONIC ACIDS AND ESTERS, SULFOXIDES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-06 MG
PHENOLS
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
LCI
LC2
LC3
LC4
LC5
LC6
LC7
10
10
100
10
10
100
100
l.OOE-06
<1.22E-04
1.02E-01
<1.22E-0
-------�
TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01
COMPONENT NO: 01
FORM 10
PAGE 10
DATE 04/02/80
RADIONUCLIDE DATA SUMMARY-
RADIOHUCLIDE
KR-85
XE-133M
XE-133
XE-135
CONCENTRATION
(PCI/M3)
<1 .33E-05
ft . 32E-02
<5.00E-05
ft. 32E-02
ANALYTICAL METHOD
NEUTRON ACTIVATION ANALYSIS
NEUTRON ACTIVATION ANALYSIS
NEUTRON ACTIVATION ANALYSIS
ATOMIC ABSORPTION SPECTROMETRY
HIGH
DETECTION
LIMIT
1 .OOE+10
1. OOE + 10
1. OOE+10
l.OOE+10
LOW
DETECTION
LIMIT
l.OOE-05
1 .OOE-05
1 .OOE-05
l.OOE-05
DETECTION
LIMIT
UNITS
PCI/M3
PCI/M3
PCI/M3
PCI/M3
COMMENTS:
KR CONCENTRATION MAY BE ARTIFICIALLY HIGH.
en
I
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-------�
TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01 COMPONENT NO: 02
COMPONENT NAME: IMPINGERS STAGE/FILTER CUT SIZE: UM MASS: 1.13E+02 UG/M3
CHEMICAL LABORATORY QA AUDIT CODE: 024 RADIOLOGICAL LABORATORY QA AUDIT CODE: 019
RADIOLOGICAL ANALYSIS LABORATORY NAME: FONDA NUCLEAR LABS
COMPONENT (ALIQUOT)VOLUME: 1.230 M6
EFFUENT CHARACTERISTIC SUMMARY-
FORM 7
PAGE 11
DATE 04/02/80
PARAMETER
PH
ANALYTICAL METHOD
WET CHEMICAL ANALYSIS (NOT SPF.
HIGH LOU DETECTION
DETECTION DETECTION LIMIT
LIMIT LIMIT UNITS VALUE
UNITS
5.6-6.3
en
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I
cn
COMMENTS: NO MIND SPEED MEASUREMENTS MERE MADE.
-------�
TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01
COMPONENT NO: 02
LEVEL 1 ORGANIC EXTRACTION SUMMARY
THE EXTENDED CHEMICAL DATA ARE GIVEN IN FOLLOWING ORDER:
MEG NUMBER CATEGORY/SPECIES NAME
ANALYTICAL METHOD
HIGH/LOW DETECTION LIMITS AND UNITS
FRACTION
ID
INTENSITY
PAGE 12
FORM 9 DATE 04/02/80
ESTIMATED
CONCENTRATION
(UM/M3)
01
08
12
01
16
11
18
ALIPHATIC HYDROCARBONS
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-06 MG
CARBOXYLIC ACIDS AND DERIVATIVES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
NITROSAMINES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-06 MG
HALOGENATED AROMATIC COMPOUNDS
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
AZO COMPOUNDS, HYDRAZINE DERIVATIVES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
SULFONIC ACIDS AND ESTERS. SULFOXIDES
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-06 MG
PHENOLS
GAS CHROMATOGRAPHY/MASS SPECTROMETRY
l.OOE+05 l.OOE-04 MG
LCI
LC2
LC3
LC4
LC5
LC6
LC7
10
10
100
10
10
100
100
l.OOE-06
.22E-04
1.02E-01
<1.22E-04
1.47E-02
1.29E-01
1.36E-04
TOTAL ORGANICS (MG)
TCO (MG)
GRAV (MG)
LCI
LC2
LC3
LC4
LC5
LC6
LC7
SUM
2.5
1 .2
1 .3
2.6
1.2
1.4
3.0
1.7
1.3
2.6
1.2
1.4
2.7
1.2
1 .5
2.9
1.2
1 .7
2.9
1.2
1.7
38.4
17.8
20.6
COMMENTS:
REPLICATE SETS RUN ON ALL FRACTIONS.
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TEST SERIES NO: 00101
STREAM NO: 01
TEST ID NO: 001
SAMPLE NO: 01
COMPONENT NO: 02
RADIONUCLIDE DATA SUMMARY-
FORM 10
PAGE 13
DATE 04/02/80
RADIONUCLIDE
KR-85
XE-133M
XE-133
XE-135
CONCENTRATION
(PCI/M3)
<1.33E-05
4.32E-02
<5. OOE-05
4.32E-02
ANALYTICAL METHOD
NEUTRON
NEUTRON
NEUTRON
NEUTRON
ACTIVATION
ACTIVATION
ACTIVATION
ACTIVATION
ANALYSIS
ANALYSIS
ANALYSIS
ANALYSIS
HIGH
DETECTION
LIMIT
1
1
1
1
.OOE+10
.OOE+10
.OOE+10
.OOE+10
LOW
DETECTION
LIMIT
1 .OOE-05
1 .OOE-05
1. OOE-05
1. OOE-05
DETECTION
LIMIT
UNITS
PCI/M3
PCI/M3
PCI/M3
PCI/M3
COMMENTS:
KR CONCENTRATION MAY BE ARTIFICIALLY HIGH.
I
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TEST SERIES NO: 00101 STREAM NO: 01 TEST ID NO: 001 SAMPLE NO: 01 PAGE
FORM 11 DATE
BIOASSAY SUMMARY DATA
TYPE OF ASSAY: MUTAGENICITY NAME OF TESTING LAB: LOVE CANAL ANALYTICAL LAB
TEST NAME: AMES QA AUDIT CODE: 034 TEST START DATE: 12/31/78
FINISH DATE; 01/01/79
ASSAY SAMPLE NO: 234 TEST DURATION: 1000 MRS. ASSAY SAMPLE QUANTITY= 100 MG
TEST ORGANISMS/STRAINS USED:
SALMONELLA TYPHIMURIUM TA-98
SALMONELLA TYPHIMURIUM TA-1535
SALMONELLA TYPHIMURIUM TA-1537
ASSAY RESULTS:
LD50 = 1.23E-01MG/M3 CONFIDENCE LIMITS- HIGH= 1.34E+05 -LOW= 1.45E-03
*** LEVEL OF TOXICITY= HIGH *** MAXIMUM APPLICABLE DOSE= 1.56E-01 MG/M3
AMES TEST RESPONSE' POSITIVE MINIMUM EFFECTIVE CONCENTRATION= 1.23E-02 HG/M3
i*1 APPROXIMATE CONCENTRATION FACTOR= 1.25
-P«
00 COMMENTS ON THE BIOASSAY:
REPLICATES MERE RUN ON ALL SAMPLES.
COMBINED SASS TRAIN CATCH MAS ANALYZED.
TOTAL CARDS = 00120
TOTAL FATAL ERRORS = 00011
TOTAL WARNING ERRORS = 00000
-------�
0000
ADMINISTRATION SECTION
00000
SERIES STATUS-
DATA BASE: GEDS
TSN: 00101
SPONSOR:
SPONSOR PROJECT OFFICER:
CONTRACTOR CONTACT:
CONTRACTOR PHONE:
CONTRACT NUMBER:
NUMBER OF CARDS RECEIVED: 120
DATA CARDS RECEIVED: 04/02/80
TEST SERIES ASSIGNED:
TASK/TD NO.
EDIT PHASE-
DATE STARTED: 04/02/80
NUMBER OF RUNS: 1
DATE ENCODED:
DATE RECEIVED:
DATE APPROVAL:
DATE LAST RUN:
NUMBER OF FATAL ERRORS: 11
NUMBER OF WARNING ERRORS:
LOAD PHASE-
DATE LOADED;
CYCLE NO.:
SERIES PHASE
DATE LAST RUN:
NUMBER OF RUNS:
00000
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FPEIS*GLJ(1).INGEDS
1 G 101 AOCOMBUST-ENERGY UTILITY BOILER
2 G 101 A1TANGENTIAL 200 MW COAL UNIT A
3 G 101 A2KINGSTON STEAM PLANT KINGSTON TN
4 G 101 A327607USA 103 100 102 082777090177
5 G 101 A4EPA 68-02-2160123ACUREX
6 G 101 A5FIELD TESTING OF A TANGENTIAL COAL-FIRED UTILITY BOILER—
7 G 101 A6EFFECTS OF COMBUSTION MODIFICATION NOX CONTROL ON MULTIMEDIA EMIS
8 G 101 A7HIGGEBOTHAM E B ACUREX REPORT 79-337APRIL 1979
9 G 101 BO 1LEVEL 1 TESTING FOR EFFECTS DUE TO NOX COMBUSTION MODIFICATIONS
10 G 101 BO 2TEST tl BASELINE
11 G 101 BO 3TEST *2 BURNERS OUT OF SERVICE
12 G 101 BO 4TEST *3 BIASED FIRING
13 G 101 1 CO 1234M3/SEC 456 100 12 3401001BOILER FLUE GAS
14 G 101 1 C1FLUE GAS INLET TO ID FAN
15 G 101 1 C2SIGNIFICANT PITTING NOTED IN ID FAN BLADES.
16 G 101 1 D001MECHANICAL COLLECTORCYCLONES
17 G 101 1 D1DUSKOLECTOR CONVENTIONALDUSKOLECTOR
18 G 101 1 D2DUSKOLECTOR.INC.
19 G 101 1 D301HIGH PRESSURE 02LOW ENERGY
20 G 101 1 D303STAINLESS STEEL
21 G 101 1 D401PRESSURE DROP 2.60E+00 KPA
22 G 101 1 D402DESIGN EFFICIENCY 9.00E+01 X AT 100 M3/S
23 G 101 1 D403DESIGN TEMPERATURE 150-250 C
tn 24 G 101 1 D404DESIGN FLOW RATE l.OOE+02 M3/S
' 25 G 101 1 D405DESIGN POWER CONSUMPTION 1.50E+00 KMH
i 26 G 101 1 D002ESP SINGLE STAGE ESP
g 27 G 101 1 D1PLATE CONVENTIONALR/C MODEL 16A
28 G 101 1 D2RESEARCH-COTTRELL
29 G 101 1 D301HOTSIDE 02DRY
30 G 101 1 D303HI VOLTAGE
31 G 101 1 D401PLATE AREA 2.00E+02 M2
32 G 101 1 D402PLATE-PLATE SPACING 1.25E+00 CM
33 G 101 1 D403DESIGN MASS EFFICIENCY 98 '/.
34 G 101 1 D404BULK LINEAR VELOCITY 2.80E+01 M/S
35 G 101 1 D405DESIGN PRESSURE DROP 5.49E-01 KPA
36 G 101 1 D003LIQUID SCRUBBERS ABSORPTION PROCESSES
37 G 101 1 D1MAGNESIUM OXIDE PILOT MAG-OX SCRUBBER
38 G 101 1 D2TAKAHASHI ALI, LTD
39 G 101 1 D301MECHANICAL AIDED 02MOVING BED
40 G 101 1 D401DESIGN PRESSURE DROP 5.88E-01 KPA
41 G 101 1 D402INLET GAS VELOCITY 5.50E+01 M/S
42 G 101 1 D403DESIGN LIQUID LOADING 6.50E+01 L/M3
43 G 101 1 D404DESIGN EFFICIENCY 90 X
44 G 101 1 1 E008307700120100CONTINUOUS STEADY STATE 890
45 G 101 1 1 E101
46 G 101 1 1 E201POWER CONSUMPTION 1.25E+00 KWH
47 G 101 1 1 E202PRESSURE DROP 8.50E-01 KPA
48 G 101 1 1 E102
49 G 101 1 1 E201PRESSURE DROP 4.50E-01 KPA
50 G 101 1 1 E202INLET GAS VELOCITY 1.25E+01 M/S
51 G 101 1 1 FOCOAL 8.66 KG/SEC 15 KG
52 G 101 1 1 F1COMMERCIAL TESTING AND ENGINEERING CO. 026 345M3
53 G 101 1 1 F2MOISTURE 2.0 XWT ASH 19.6 XWT
54 G 101 1 1 F2VOLATILE MATTER 31.8 %WT FIXED CARBON 46.5 %WT
55 G 101 1 1 F2SULFUR 2.2 %WT HEAT CONTENT 36288. J/G
56 G 101 1 1 F3CARBON 63.1 HYDROGEN 4.3 SULFUR 2.2 NITROGEN 1.4
-------�
tn
ro
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
101
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
F3ASH 19.6 CHLORINE MOISTURE 2.0 OXYGEN
F4DENSITY N 25 G/CH3 ZZ
7.3
F4PH N 85 . WC1 . 40E + 01 1 . 50E-01
F'.COIOR TBLACKISH GRAY ZZ
F5M36 AA3.00E+035.00E-04MG 1 2 . 1 2 3>120E + 02
F5M32 AA3.00E+035.00E-04MG 11.543 140E+00
F5M37 AA 100E+00
F5M68 AA 260E+01
F5M74 AA 860E+00
F5M72 AA 640E+03
F5M46 AA 140E+01
F5M71 AA 170E+01
F5M76 AA 600E-01
F7SAMPLE TAKEN 5 METERS ABOVE GROUND LEVEL.
F8BELOW 5-METER LEVEL WAS FROM DIFFERENT SOURCE.
1HO SASS TRAIN WITH/CYCLONES 1234001 123 45 46 66
1H1 12L/S PITOT TUBE 10000MG
1H203.5 M FROM SCRUBBER OUTLET 80 5 52
1H5NONE
1H6THE IMPINGERS MERE COMBINED.
1K001EAD-2 CARTDG 1 . 23E + 0 1WOLFPACK TESTING SERVICE
1K101024019FONDA NUCLEAR LABS 123
1K2 1PH T 5.6-6.3 WC
1K301NO MIND SPEED MEASUREMENTS MERE MADE.
1M001LC1 1.2 1.3M01 GS1 . OOE+051 . OOE-06MG
1M001LC2 1.2 1.4M08 GS1 . OOE+051 . OOE-04MG
1M001LC3 1.7 1.3M12 GS1 . OOE+051 . OOE-06MG
1M001LC4 1.2 1.4M16 GS1 . OOE+051 . OOE-04MG
1M001LC5 1.2 1.5M11 GS1 . OOE+051 . OOE-04MG
1M001LC6 1.2 1.7M14 GS 1 . OOE+051 . OOE-06MG
1M001LC7 1.2 1.7M18 GS1 . OOE+051 . OOE-04MG
1M101REPLICATE SETS RUN ON ALL FRACTIONS.
1R001KR-85 NA1. OOE + 101 . OOE-05PC I/M3 <133E-05
1R001XE-133M NA1. OOE+101. OOE-05PCI/M3 432E-02
1R001XE-133 NA1.00E+101 . OOE-05PCI/M3 <500E-05
1R001XE-135 AA1 .OOE+101 . OOE-05PCI/M3 432E-02
1R101KR CONCENTRATION MAY BE ARTIFICIALLY HIGH.
1K002IMPINGERS 1 . 1 3E+02MOLFPACK TESTING SERVICE
1K102024019FONDA NUCLEAR LABS 123
1K2 2PH T 5.6-6.3 MC
1K302NO MIND SPEED MEASUREMENTS MERE MADE.
1M002LC1 1.2 1.3M01 GS1 . OOE+051 . OOE-06MG
1M002LC2 1.2 1.4M08 GS1 . OOE+051 . OOE-04MG
1M002LC3 1.7 1.3M12 GS1 . OOE+051 . OOE-06MG
1M002LC4 1.2 1.4M16 GS1 . OOE+051 . OOE-04MG
1M002LC5 1.2 1.5M11 GS1 . OOE+051 . OOE-04MG
1M002LC6 1.2 1.7M14 GS1 . OOE+051 . OOE-06MG
1M002LC7 1.2 1.7M18 GS1 . OOE+051 . OOE-04MG
1M102REPLICATE SETS RUN ON ALL FRACTIONS.
1R002KR-85 NA1 . OOE+1 01 . OOE-05PCI/M3 <133E-05
1R002XE-133M NA1 . OOE+1 01 . OOE-05PC I/M3 432E-02
1R002XE-133 NA1 .OOE+101 . OOE-05PC I/M3 <500E-05
1R002XE-135 NA1 .OOE+101 . OOE-05PC I/M3 432E-02
1R102KR CONCENTRATION MAY BE ARTIFICIALLY HIGH.
1TOMUTAGENICITY AMES
12
MG
10 100E-06
10<122E-04
100 102E-01
10<122E-04
10 147E-02
100 129E-01
100 136E-04
MG
10 100E-06
10<122E-04
100 102E-01
10<122E-04
10 147E-02
100 129E-01
100 136E-04
0010000234
1T1LOVE CANAL ANALYTICAL LAB 034123178010179
1T2 100MG
-------�
114
115
116
117
118
119
120
G
G
G
G
G
G
G
101 1
101 1
101 1
101 1
101 1
101 1
101 1
1
1
1
1
1
1
1
1T3SALMONELIA TYPHIMURIUM TA-98
1T3SALMONELLA TYPHIMURIUM TA-1535
1T3SALMONELLA TYPHIMURIUM TA-1537
1T4LD50123E-01MG/M3 1 34E + 05145E-03 156E-01MG/M3
1T5POSITIVE 123E-02MG/M3 1.25
1T901REPLICATES MERE RUN ON ALL SAMPLES.
1T902COMBINED SASS TRAIN CATCH WAS ANALYZED.
HIGH
3FREE FNY.
READY
3BRKPT PRINTS
ro
ro
-------�
G 101 AOCOMBUST-ENERGY UTILITY BOILER
NO. TYPE COMPONENT MESSAGE
154 F TEST SERIES NUMBER NOT IN STATUS FILE
19
20
27
G 101 1
NO. TYPE
126 F
126 F
G 101 1
NO. TYPE
126 F
G 101 1
NO. TYPE
F
D301HIGH PRESSURE 02LOW ENERGY
COMPONENT MESSAGE
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
D303STAINLESS STEEL
COMPONENT MESSAGE
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
D1PLATE CONVENTIONALR/C MODEL 16A
COMPONENT MESSAGE
INVALID CONTROL SYSTEM TABLE MATCH
cn
PO
oo
30
37
39
120
G 101 1
NO. TYPE
126 F
126 F
G 101 1
NO. TYPE
126 F
G 101 1
NO. TYPE
125 F
G 101 1
NO. TYPE
126 F
126 F
G 101 1
NO. TYPE
155 F
156 F
D301HOTSIDE 02DRY
COMPONENT MESSAGE
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
D303HI VOLTAGE
COMPONENT MESSAGE
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
PILOT
MAG-OX SCRUBBER
D1MAGNESIUM OXIDE
COMPONENT MESSAGE
INVALID DEVICE/PROCESS CLASS TABLE MATCH
D301MECHANICAL AIDED 02MOVING BED
COMPONENT MESSAGE
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
INVALID DEVICE/PROCESS KEYWORD TABLE. MATCH
1 1T902COMBINED SASS TRAIN CATCH WAS ANALYZED.
COMPONENT MESSAGE
STATUS FILE MODIFY DID NOT WORK
C1845 NON-NUMERIC TOTAL MG RECOVERED
-------�
SECTION 6
DATA RETRIEVAL
6.0 INTRODUCTION
The purpose of this section is to provide users with instructions for
submitting new data for entry to the EADS and for retrieving existing data
from the EADS. In particular, Section 6 discusses direct interactions with
the computer and procedures for those users who do not have direct access
to the EPA National Computer Center (NCC) at Research Triangle Park,
North Carolina.
It is likely that many users of the EADS will have neither the time
nor the inclination to pursue the direct access methods. Since Federal
regulations do not permit the sale of computer services by government data
centers like the NCC, most users will not be authorized to access the NCC
unless they are under EPA contract. For this reason, procedures have been
established which will enable those "off-line" users to retrieve
information by written or telephone request instead.
It should be noted that there is no charge for "off-line" data
retrieval; however, EPA makes no guarantee regarding the completeness of
the data or the promptness of the response. In all likelihood, simple
data requests will be processed quickly, but the staff response will
depend upon their current workload and on the complexity of the request.
Special data requests which require computer program development will take
longer. Requesters will be appraised of any expected delays.
6.0-1
-------�
6.1 DATA RETRIEVAL USING THE PROGRAM LIBRARY
The simplest method of retrieving data for an off-line user is to
request a program from the Program Library. Section 7 presents the
programs available which may be utilized to retrieve EADS data in a
specified manner. Each program is described separately and has its own
requirements for data input or qualification by the user.
Programs may be requested by off-line users by telephone or in
writing. The requester should supply all information in accordance with
the requirements of the program and send the completed request to the
following address:
EADS Program Manager
Special Studies Staff (MD-63)
Industrial Environmental Research Laboratory
U.S. Environmental Protection Agency
Research Triangle Park, North Carolina 27711
Users should send separate requests for different runs even if the
same program is being used repeatedly. For example, if a user wishes to
interrogate the data base according to a specific access criteria, any
change to that criteria must be shown in a separate request. Receipt of
the request will be acknowledged to the requester in writing. If there
are any errors in the request or some information is missing, the
requester will be contacted to clarify the problem. When the request has
been processed, the output will be sent to the requester for verification.
6.1-1
-------�
6.2 SPECIAL DATA RETRIEVAL REQUESTS
It is recognized at the outset that the Program Library is not
likely to be diverse enough to satisfy all user needs for data. For this
reason, a special data retrieval request category was established. There
is no specific form to be used for special requests; there is merely a set
of general guidelines to follow in preparing the request. These guidelines
are as follows:
1. Be explicit. Be thoroughly familiar with the GEDS data base
structure. Identify each data base element to be sorted and/or
retrieved by name. Should additional work on the request be
required, consultation with the requester will be initiated,
and, upon completion, the printout will be sent to the
requester for verification.
2. Plan the request: Be sure that the access criteria applies to the
proper type of data element. Remember that only key values may be
retrieved directly and that non-key values must be qualified for
data access (see Section 6.3). Specify all needed qualifications
and identify all input data for comparative evaluation.
3. Define the output: Determine how you wish the data to be displayed
on output. Identify how data elements are to be ordered. Specify
column headings. Define any calculations to be performed on the
accessed data.
The completed definition of the request should be sent to the EADS
Program Manager at IERL-RTP. The user should be sure to include his own
telephone number with the request. If there are any problems encountered
with the request, the user will be contacted by telephone to resolve the
problem.
6.2-1
-------�
When the request has been received, a letter of acknowledgement
will be sent to the requester. The letter will include a preliminary
estimate of the length of time required to process the request. As
emphasized previously, the length of time needed to process a special
request will depend upon the complexity of the request.
If no problems are encountered that require consultation with the
requester, the results will be sent to the requester when the processing
is completed. The requester should review the output to verify that it
satisfies the request. If it does not, the printout should be returned
with corrections to IERL for reworking. If the printout is satisfactory,
the requester should notify the EADS Program Manager of his acceptance.
6.2-2
-------�
6.3 KEY/NON-KEY DATA ELEMENTS
Data elements in a SYSTEM 2000data base may be either KEY or
NON-KEY. This designation determines whether a particular data element
may be accessed directly or must be qualified by including additional
information. KEY elements may be selected directly; NON-KEY elements
require qualification by a KEY element. For example, the data element
GENERIC DEVICE/PROCESS TYPE is KEY and may be used to directly access the
data of interest, such as in the following:
PRINT 6EDS TEST SERIES NUMBER WHERE GENERIC DEVICE/PROCESS TYPE EQ
ESP:
If, however, the data element is NON-KEY, as in the case of SERIES
START DATE, then qualification will be required:
IF SERIES START DATE GT 1/1/80 THEN PRINT GEDS TEST SERIES NUMBER
WHERE NAME OF SAMPLING GROUP EQ XYZ LABORATORY:
In this case, the KEY element, NAME OF SAMPLING GROUP, is used to qualify
the request regarding a NON-KEY data element.
Table 6-1 lists the KEY data elements, along with their
SYSTEM 2000^ component numbers.
6.3-1
-------�
TABLE 6-1. LIST OF KEY DATA ELEMENTS
101* FPEIS TEST SERIES NUMBER 905*
102* GEDS TEST SERIES NUMBER 923*
103* LEDS TEST SERIES NUMBER 926*
104* SDDS TEST SERIES NUMBER 945*
105* TEST SERIES KEY 946*
106* DB KEY 947*
110* SOURCE CATEGORY 950*
120* SOURCE TYPE 1010*
125* PRODUCT/DEVICE 1060*
130* PROCESS TYPE 1203*
140* DESIGN PROCESS RATE , 1206*
145* DESIGN PROCESS RATE UNITS 1209*
150* FEED MATERIAL CATEGORY 1221*
155* SPONSOR ORGANIZATION 1245*
160* SPONSOR ORGANIZATION CONTRACT NUMBER 1247*
170* T.O./TD NUMBER 1276*
180* SOURCE NAME 1278*
190* SITE NAME 1303*
210* CITY 1305*
220* STATE 1310*
230* ZIP CODE 1320*
232* COUNTRY 1321*
235* FPEIS TSN CROSS REFERENCE 1324*
240* SDDS TSN CROSS REFERENCE 1325*
250* GEDS TSN CROSS REFERENCE 1420*
260* LEDS TSN CROSS REFERENCE 1425*
270* SIC CODE 1830*
300* NPDES NUMBER 1835*
330* NAME OF SAMPLING GROUP 1840*
355* DATE OF ENTRY 1836*
370* SITE LATITUDE 2530*
372* SITE LONGITUDE 2580*
374* FRACTION DESIGN RATE IND ORIGIN 2582*
378* CONTRIBUTING INDUSTRIAL CATEGORY NUMBER 2583*
380* INDUSTRY-COMMERICAL SIC NUMBER 2585*
382* CATEGORY FLOW CONTRIBUTION 3025*
384* NUMBER OF ESTABLISHMENTS 3030*
410* STREAM NUMBER 3205*
420* STREAM NAME 3210*
475* STACK HEIGHT 3225*
505* DEVICE/PROCESS NO 3226*
510* GENERIC DEVICE/PROCESS TYPE 3280*
515* DESIGN TYPE 3315*
520* SPECIFIC PROCESS/DEVICE TYPE 3320*
530* DEVICE/PROCESS CLASS 3255*
540* DEVICE/PROCESS COMMERCIAL NAME
550* MANUFACTURER
585* DEVICE/PROCESS CATEGORY SEQ NUMBER
590* DEVICE/PROCESS CATEGORY KEYWORD
610* DES-PARAMETER NUMBER
810* TEST-ID-NUMBER
869* FF-SEQUENCE NUMBER
870* FF-SOURCE FEED MATERIAL
877* FF-LABORATORY NAME
878* FF-QA-QC CODE
885* FF-PA-PARAMETER
FF-UA-PARAMETER
FF-PARAMETER
FF-ANALYSIS METHOD
FF-C-CATEGORY/SPECIES
FF-C-CS-TYPE
FF-C-CS-PRIORITY
FF-C-ANALYSIS METHOD
OP-DEVICE NUMBER
OPERATING PARAMETER NUMBER
SMPL-NUMBER
MEASUREMENT INST/METHOD TYPE
MEASUREMENT INST/METHOD NAME
SMPL-FLOWRATE MEASUREMENT METHOD
SAMPLING LOCATION CODE
SAMPLING LOCATION DEVICE NUMBER
PARTICLE DIAMETER BASIS
PARTICLE CONCENTRATION BASIS
COMPONENT SEQUENCE NO
SAMPLING EQUIPMENT COMPONENT NAME
STAGE/FILTER CUT SIZE
CHEMICAL ANALYSIS LAB NAME
CHEMICAL QA-QC CODE
RADIONUCLIDE ANALYSIS LAB NAME
RAD-QA-QC CODE
EC-PARAMETER
EC-ANALYSIS METHOD
IA-SPECIES-ID-TYPE
IA-SPECIES-ID
IA-ANALYSIS-METHOD
IA-SPECIES-PRIORITY
L10A-FRACTION-ID
L10AFED-CATEGORY/SPECIES TYPE
L10AFED-CATEGORY/SPECIES
L10AFED-CATEGORY/SPECIES-PRIORITY
L10AFED-ANALYSIS METHOD
RN-RADIONUCLIDE ID
RN-ANALYSIS METHOD
BIO-TEST TYPE
BIO-TEST NAME
BIO-TEST LAB NAME
BIO-TEST QA-QC
BIO-VALUE TYPE
BIO-LEVEL OF TOXICITY
BIO-BACT. MUTAGEN RESPONSE
BIO-ORGANISMS/STRAINS
6.3-2
-------�
6.4 ON-LINE REQUEST PROCEDURES
The phrase "on-line request" implies that the user intends to
establish direct communication with the EADS data base through some type
of terminal-to-computer link. The procedure described in this section may
be used by a qualified user of EPA1s NCC to access the EADS directly
through an interactive data communications (demand) terminal or a remote
job entry terminal. The specific qualifications for NCC user access are
discussed in Section 6.5.
On-line users of the EADS are presumed to have a reasonably working
knowledge of UNIVAC 1100 series computers and, in some cases, of
(IT)
SYSTEM 2000vli/natural language. Special data retrieval procedures (see
Section 7) have been developed to minimize the data processing knowledge
required to use the EADS. Any user unsure of his familiarity with the
UNIVAC or SYSTEM 2000^ is urged to request information through the
off-line procedures described previously in this section.
On-line users are granted READ-ONLY access to the EADS data base.
No updating of data is permitted. New data must be submitted through the
EPA project officer. In the READ-ONLY mode, the user may retrieve, for
sorting and evaluation, any data stored in the system. The user may take
advantage of the wide array of features offered by SYSTEM 2000^for
data sorting and retrieval.
6.4-1
-------�
6.5 NCC USER QUALIFICATIONS AND SERVICES REGISTRATION
Qualified users are defined as those who have valid accounts with
the NCC at Research Triangle Park, North Carolina. In most cases, NCC
users are either EPA personnel or contractors who are under EPA contract.
The NCC is not available to public subscribers. Federal regulations
prohibit the marketing of computer time by government data centers which
may be in competition with commercial computer services vendors. Thus, it
is not usually possible for EADS users who are not under EPA contract to
obtain account numbers in order to access the NCC directly. Exceptions to
this may be found with user.access through interagency agreements or
grants. The qualifications of a potential NCC user are determined by
EPA's Management Information and Data Systems Division (MIDSD).
Any questions regarding the qualification of a user should be
addressed to:
MIDSD TSSMS Office
U.S. Environmental Protection Agency
National Computer Center (MD-34B)
Research Triangle Park, North Carolina 27711
or by telephone to 919/541-3629 (FTS: 629-3629).
6.5.1 Registration Procedures
All users of the NCC UNI VAC 1100 must be registered for accounting
and security purposes. Application for NCC services is made by submitting a
completed EPA Form 2800-3 (Figure 6-1) to the appropriate Automated Data
Processing (ADP) coordinator for approval and signature. Each EPA office or
laboratory which uses the NCC or other computing facilities has a designated
person (or persons) who serves as the ADP coordinator. All procedural
matters pertaining to the use of the NCC should be directed to the ADP
coordinator. The MIDSD Time Sharing Services Management System (TSSMS)
6.5-1
-------�
SERVICE (Check one)
O TIMESHARING
(-•TECHNICAL
u ASSISTANCE
n OTHER
EDP SERVICES REGIS!
(Please Print or Tyf
SUPPLIER (Specify)
[RATION
e)
SOURCE OF FUN OS
O U.S. EPA
QREIMBURSIBLE
Q SPONSORED
MIDSD USE ONLY
DATE RECEIVED
PROJECT
CODE
ENVIRONMENTAL
SYSTEM IDENTIFI-
CATION NUMBER
PROJECT TITLE (Limit: 60 characters, Including spaces)
PROJECT DESCRIPTION
ORGANIZATION
PROGRAM ELEMENT TITLE
DOLLAR AMOUNT DATE
PROJECT MANAGER
MAIL COOE (or room)
ORGANIZATION CODE
PROGRAM ELEMENT CODE
TO BEGIN DURATION
NAME (Lift, First, M.I.)
OFFICE OR LOCATION
AODRESS (Strut or P.O. Box) CITV
USER |NAME (Last, Pint, M.I.)
MAIL CODE (or room)
OFFICE OR LOCATION
ADDRESS (Street or P.O. Box) CITV
USER 1 NAME (Lift. Pint, M
MAIL CODE (or room)
1.)
OFFICE OR LOCATION
ADDRESS (Street or P.O. Box) CITV
TO:
U.S. Environmental Protec
MIDSD TSSMS Office
National Computer Center
MD-34B (Km. HI Micnau
Research Triangle Park, t
POSTED
ORIGINATED
I ion Anem-J CONCURREN
(CS277U*J CONCURREN
SVSTEM DAILY
Q RETRIEVAL ONLY STORAGE
O FULL ACCESS
PHONE (Include area code)
STATE ZIP CODE
PHONE (Include area code)
STATE ZIP CODE
PHONE (Include area Code)
STATE ZIP CODE
BY DATE
:E (Funding) DATE
:E (Otner) DATE
MIDSD USE ONLY
UPDATED
PROOFED
DISTANCE
CODE
MAI
M[
P
F
DISTANCE
CODE
MA
M[
P r
c [
F [
DISTANCE
CODE
MA
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REFER- LOGON
ENCE
INITIALS
LING LIST CODE
3 sD
3 SB
3 .NO
REFER- LOGON
ENCE
INITIALS
LING LIST CODE
3 SD
D TO
3 "D
3 NQ
REFER- LOGON
ENCE
INITIALS
LING LIST CODE
3 SD
3 TO
3 "O
3 NO
MAILING LIST KEY
M — MANAGEMENT PANEL
P — PROPERTY
C — CONTRACTOR
F — FEDERAL NON-EPA
S — ST
U — U
N - SI
ATE OR LOCAL GOVT
RMINAL CONTACT
DIVERSITY
STEM NEWS
EPA Form 2800-3 (Rev. 6-78)
PREVIOUS EDITION IS OBSOLETE
(continued on bock)
Figure 6-1. NCC application.
6.5-2
-------�
PLEASE PRINT OR TYPE
(Additional users)
USERl NAME (l_att. First, M.I.
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
PHONE (Include area code)
OFFICE OH LOCATION
jJSERJ NAME (Last, First, M.I.)
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
USEH|NAME (L8St' Flr"< "•'•
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
USER|NAME "-*"• F|r". M-'->
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
USER [NAME (Last, First, M.I.;
MAI L CODE (or room)
ADDRESS (Street or P.O. Box)
USER [NAME (Last, First, M.I.)
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
USER INAME (Last. First, M.I.)
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
USERJ NAME (Last, First. M.I.
MAIL CODE (or room)
ADDRESS (Street or P.O. Box)
CITY
STATE
ZIP CODE
OFFICE OR LOCATION
CITY
STATE
ZIP CODE
PHONE (Include area code)
OFFICE OR LOCATION
CITY
STATE
ZIP CODE
PHONE (Include area code)
OFFICE OR LOCATION
CITY
STATE
ZIP CODE
PHONE (Include area code)
OFFICE OR LOCATION
CITY
STATE
ZIP CODE
PHONE (Include area code)
OFFICE OH LOCATION
CITY
STATE
PHONE (
ZIP CODE
nclude area code)
OFFICE OR LOCATION
CITY
STATE
ZIP CODE
PHONE (Include area code)
OFFICE OR LOCATION
evert*)
CITY
STATE
ZIP CODE
CODE
ENCE
INITIALS
MAILING LIST CODE
M Q S D
P D T D
c D u D
F D N D
DISTANCE
CODE
REFER-
ENCE
INITIALS
LOGON
MAILING LIST CODE
M D S D
" O T Q
CQ " D
F n N n
DISTANCE
CODE
REFER-
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INITIALS
LOGON
MAILING LIST CODE
M Q S D
P D T D
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F D N D
DISTANCE
CODE
REFER-
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MAILING LIST CODE
M Q S Q
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F n N n
DISTANCE
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DISTANCE
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LING LIST CODE
D s D
: T D
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REFER-
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] S D
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Figure 6-1. Concluded.
6.5-3
-------�
Office is located at the National Computer Center. Requests for EPA user
account modifications processed through the ADP coordinators to authorize
new accounts or add new users to existing accounts, normally submitted
using the EPA Form 2800-3, should then be forwarded to the following
address:
MIDSD TSSMS Office
U.S. Environmental Protection Agency
National Computer Center (MD-34B)
Research Triangle Park, North Carolina 27711
In instances where a user organization requires immediate access to
computer facilities, temporary authorization can be achieved by telephone
contact with the TSSMS Office. Requests for temporary authorization
should be directed to 919/541-3629 (FTS: 629-3629). Upon receiving
temporary authorization, a completed Form 2800-3 must be forwarded to the
TSSMS Office. The temporary authorization obtained by telephone is valid
for a 2-week period pending receipt of the Form 2800-3 for processing
permanent authorization. Users must specify an EPA employee as Project
Manager who, in all cases, becomes responsible for the utilization of the
account. Requests for cancellation of specific users authorized under a
given account or changes in user address/telephone numbers will be
processed by telephone using the TSSMS telephone number listed above.
Non-EPA users (e.g., contractors, grantees, etc.) should submit all
required forms to their EPA project officer, who in turn will forward the
information to the ADP coordinator. Account authorizations/modifications
for Interagency Agreement User Accounts (non-EPA users) should be
forwarded for approval to:
W. G. Allen, Computer Specialist
U.S. Environmental Protection Agency
National Computer Center (MD-34)'
Research Triangle Park, North Carolina 27711
6.5-4
-------�
Upon approval of Interagency requests, the TSSMS Office will
complete implementation of the authorization and notify the respective
project manager. Any questions concerning the above should be directed to
the TSSMS Office at 919/541-3641 (FTS: 629-3641). Please note that, in
regard to EPA Form 2800-3, the organization titles and codes and the EPA
DIPS organization titles and codes, and the program element titles and
codes are assigned by the Office of Planning and Programming. The account
number will be assigned to the user by MIDSD and must appear on all
transactions attempted with the NCC UNI VAC 1100.
5.5.2 User ID and Password
The NCC UNIVAC 1100 has a comprehensive, multi-level security system
which is designed to prohibit unauthorized use of the computer. A feature
of this security system is the TSSMS which requires that all users be
identified by a unique USERID and PASSWORD before access to the computer
is granted. The USERID/PASSWORD must appear on all demand and batch job
requests. This will be discussed in detail later in Sections 6.6 and 6.7,
respectively.
The USERID/PASSWORD is assigned to each individual user of the NCC
by MIDSD. Requests for a USERID/PASSWORD should be submitted to the
appropriate ADP coordinator (through the EPA project officer, if
necessary) for approval and signature.
6.5-5
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6.6 INTERACTIVE TERMINAL OPERATION
Demand processing or interactive terminal operation, is defined as
a mode of operation in which processing is dependent on manual interface
with the central processor during processing. Basically, it is a
conversational mode of operation requiring a demand and response type of
activity. Conversational operation via a remote terminal causes the
Executive System, a demand processor, or an active program to immediately
react and respond. Demand processing terminals are generally thought of
as being remote from the computer site and as having a printer or a
cathode-ray tube and keyboard. An example of a demand terminal is the
teletype-writer keyboard and printer.
The distinction between batch-mode processing and demand processing
lies in the frequent interaction with the user that occurs during demand
processing. The terminal user is considered to be in conversation with
the Executive System, special demand function, user programs, or the batch
functions of the Executive System on a unit basis.
Tasks executed by the demand terminal user normally have frequent but
short bursts of computation. To process a substantial amount of computation
may require a long period of time. Access to computation is a percentage of
the total computing facility and is scheduled in small increments of time at
frequent intervals to provide immediate responses. This action gives the
appearance of total system control to the user and the impression of being the
only user currently running. The more a user is required to interact with a
demand program the shorter the bursts of computation required to service a
given request. The bursts of computation are time-shared within the Executive
System to provide an apparent immediate response, with the program placed in a
dormant mode during idle periods awaiting response from the user.
6.6-1
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While a demand program is in a dormant mode, it may be necessary to
swap the program from main storage. Normally, this transfer happens only
when main storage is full and another program currently on mass storage
has work to do.
The demand has three distinct modes of operation. They are
described below:
t Terminal Inactive Mode — The initial mode of the terminal
following the sign-on procedure. The terminal will return to
this mode at the completion of the other two modes.
« Demand Run Mode ~ This mode is achieved by submitting a @RUN
control statement (see Section 6.6.1) from the primary input
device; that is, the keyboard. The terminal operator must wait
until the date and time message is displayed at the terminal
before submitting the run stream data. In demand mode, the
input will be solicited when input is desired by the Executive
System. The terminal is returned to the inactive mode by
submitting a @FIN control statement (see Section 6.6.2).
• Batch Mode — The demand terminal may be switched from demand
mode to batch mode for input or output. The "B" sub-option on
the @RUN control statement (@RUN,/B) will place the terminal in
batch input mode. Input will not be solicited as in demand run
mode. The terminal will be returned to the terminal inactive
mode following a @FIN control statement. Another @RUN control
statement will be accepted while in the remote batch run
whether it contains a 'B1 option or not. Output files
generated by the batch run, as well as those SYM'd (via @SYM)
to the terminal can be displayed at the terminal by entering
6.6-2
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the statement, @@SEND. The terminal is returned to the
inactive mode when the output process of the file is complete.
Interactive (or demand) processing with the NCC UNIVAC 1100 is
supported for a variety of low-speed data communications terminals.
Generally speaking, most 30 character/second (CPS) terminals which have
ASCII character sets will be able to access the NCC. The NCC does not
support any terminals which operate at 10 CPS or 15.5 CPS. Also, the NCC
does not support IBM 2741 or similar EBCIDIC code set terminals.
A partial list of terminals supported by the NCC for demand
processing include the following:
Anderson-Jacob son Models 630, 840, 830, and 832
UNIVAC UNI SCOPE 100
UNIVAC DCT 500 or equivalent
Texas Instruments Silent 700 series
Hazeltine (most models)
LA36 DECwriter II
If you are uncertain about the compatability of a particular
terminal with the NCC UNIVAC 1100, you should contact the following:
NCC User Services
919/541-3649
FTS: 629-3649
All UNIVAC supported demand terminals use a common interface (device
routines providing the user interface with unit record peripherals) for
input and output processing. This provides several controls and features
to all demand terminals in a uniform manner. Control of remote symbionts
is regulated by control statements prefixed with a double master space
(@@). These control statements do not require the input solicitation.
6.6-3
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They may be entered after an output interrupt (break-key) or any other
time the terminal operator finds the need. The control statements are
given in Table 6-2.
For more details on demand processing, the user should refer to the
National Computer Center User Reference Manual. This manual may be
obtained from NCC User Services at the telephone numbers listed above.
The remainder of this section will address demand processing as it applies
to the EADS.
6.6.1 Initiating a Demand Processing Session
Communications are established with the NCC UNI VAC 1100 through
data communication modems or couplers over voice-grade telephone lines.
Users should follow the steps given in the equipment user manual for their
terminal in order to establish the data link to the computer. A list of
nationwide telephone access numbers for the NCC is given in Table 6-3.
Once the data link is established, the following sequence of commands
should be entered (for clarity, the information printed by the computer is
shown in capital letters; the input required from the user in small
letters).
Note that the pound sign (#) denotes a carriage return:
Command Descriptton
#nccdemd# This identifies the NCC to the communications
network.
READY TO NCC ON 9E Response indicates that communication is
established on Port 9E.
ENTER USERID/PASSWORD Enter the approved USERID and PASSWORD
>xxx/xxxxxx# following the input solicitation symbols (>).
*DESTROY USERID/PASSWORD
ENTRY
(continued on page 6.6-8)
6.6-4
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TABLE 6-2. REMOTE INTERFACE CONTROL STATEMENTS
Statement
Mode
Description
TIOC
(?@SEND
(JERQUE
(3I9CONT
Demand Run
Demand Run
Demand Run
Demand Run
Demand Run
Terminal
Inactive
Remote Batch
All
Demand Run
(3(3 INQ
All
The @@X statement directs the Executive
System to take action on any or all of the
four possible action parameters. The @@X
defaults to @?X 0.
T -r- terminate the demand run's present
execution.
I -- discard all backed-up input.
0 -- discard all backed-up output.
C — generate a '3RK' contingency.
Ship n lines of output where n is a value of
0 to 63. The SKIP may be reset by a
@(3SKIP 0. The @@SKIP n defaults to @(aSKIP 0.
Send a queued batch output file to the
terminal.
Stop the present batch output file and
requeue it for a later @@SEND request.
Return to terminal inactive mode.
Directs the symbiont to continue. Useful
after a BRK-KEY when no action is desired.
Circumvent input solicitation requirement.
Allow several input images to be buffered in
memory before the terminal is placed in the
wait condition.
Directs the Executive System to buffer all
input to mass storage until the @@END
control statement is received. If the @@INQ
statement is entered in terminal inactive
mode, the next input should be a @RUN
statement. All @RUN statements entered
while in @@INQ mode will be considered
remote batch and not demand.
6.6-5
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TABLE 6-2. Concluded
Statement
Mode
Description
@(a END
All
(3@ ESC
Demand Run
@@TERM
All
(3(3TTY W,n All
Terminates special input mode, i.e., @@CQUE
or (3(3INQ. The @@END returns the terminal to
demand run from @@CQUE and will process the
mass storage buffered input of @@INQ.
Allows the input to be passed to the
requester unaltered from the format of which
it was entered; that is, all communication
envelope characters are not removed nor is
the image translated.
Directs the Executive System to terminate
the terminal. It is recommended that the
remote Operator enter @@TERM only while in
the terminal inactive mode. However, if
entered while a run is active, the run and
terminal will be terminated. @@TERM is
equivalent to sign off.
Changes the maximum character width of page
from the default 80 characters to n
characters wide. In most cases, the maximum
page width should be set to 132.
6.6-6
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TABLE 6-3. NCC DEMAND ACCESS TELEPHONE NUMBERS
State
Alabama
California
Colorado
Connecticut
District of Columbia
Georgia
Illinois
Louisiana
Massachusetts
Michigan
Minnesota
Missouri
Nevada
New York
North Carolina
Ohio
Pennsylvania
South Carolina
Tennessee
Texas
Washington
All other locations
(toll free)
City
Montgomery
San Francisco
Denver
Wethersfield
Washington
Athens
Atlanta
Chicago
New Orleans
Boston
Grosse He
Lansing
Minneapolis
Kansas City
Las Vegas
New York
Raleigh/Durham
Cincinnati
Philadelphia
Columbia
Nashville
Dallas
Seattle
Telephone
205/277-9390
415/546-1395
303/837-0843
203/529-3378
202/966-9510
404/549-3882
404/873-6431
312/663-1640
504/566-0041
617/742-0420
313/675-8936
517/485-3220
612/861-7451
816/474-3540
702/736-1988
212/233-1604
919/541-2000
513/751-5800
215/925-4407
803/256-1018
615/244-8020
214/651-1723
206/682-6456
800/424-3690
6.6-7
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C*UNIVAC 1100 OPERATING This header message is usually followed by
SYSTEM VER. several lines of text indicating special news
33R0030-315A(RSI)* which can be obtained. When the solicitation
symbol (>) is received you are ready to enter a
valid @RUN card.
>@@tty w,nnn# where nnn = the maximum width of the page in
characters (usually 132). This command may be
omitted if terminal is limited to 80 characters.
-@@ COMPLETE Indicates that the @@TTY corrmand has been
executed.
>@run nnxxx,account
number,eads,15# where nnxxx = the RUNID. Usually this begins
with a number that designates an output
receiving bin at the NCC followed by the user's
initials. Please consult the NCC User
Reference Manual or call User Services for more
information.
account no. = the NCC account number as given.
eads = the project code which enables access to
the GEDS data base and software. No other
project code may be used.
DATE: 011580 TIME: 135248 This is the system response if a valid @RUN
> card has been entered, followed by the >.
NOTE: If your terminal can print more than 80
characters across the page, you may wish to
expand the page width as shown above.
At this point, the computer is ready to receive instruction for
accessing the data base or for executing EADS retrieval or analytical software.
For users who are knowledgeable in SYSTEM 2000^natural language,
Section 6.6.3 describes the accessing procedure.
6.6.2 Terminating a Demand Processing Session
Two commands are required to end a demand processing session -- the
@FIN and the @@TERM. The (PFIN command ends the run and results in the
printing of summary usage and accounting data, and places the terminal in the
inactive mode. The @@TERM command ends the session by disconnecting the
terminal from the computer.
6.6-8
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A typical sequence is as follows (# denotes carriage return):
>@fin#
RUNID:
TIME:
XXXXX
ACCT:
TOTAL:
CAU:
CC/ER:
SRC: PS =
SRUS: 00:01:41.027 COST:
IMAGES READ: 78 PAGES:
START: 13:52:47 JANUARY 15, 1980
*TERMINAL INACTIVE*
>@@term#
xxxxxxxxxx
00:00:35.510
00:00:00.177
00:00:26.509
000130352
$005.05
3
FIN:
(Enter the @FIN command)
PROJECT: EADS
CBSUPS: 001854139
I/O: 00:00:08.822
WAIT: 00:02:36.079
ES = 000276035
13:57:50 JANUARY 15, 1980
(Enter the @@ TERM command)
6.6.3 Accessing the EADS
Read-only access to the data base is granted to users of the EADS
who use this procedure. Users are cautioned not to attempt to use this
(?)
procedure unless they are familiar with SYSTEM 2000v^natural language.
The sequence is as follows (# denotes carriage return):
>@add eads.startf (Enter the @ADD command.)
01/15/80 17:09:07 BEGIN SYSTEM 2000 VERSION 2.SOD
-556- ASSIGNED...EADS-EADS 12 28443 01/15/80 11:44:14
At this point, the system is ready to accept valid SYSTEM 2000
commands. The session may be ended by using the EXIT: command, which
produces the trailer banner and returns to control mode with the input
solicitation character (>) given.
exit:#
01/15/80
17:14:52
END
SYSTEM 2000 VERSION 2.SOD
6.6-9
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The demand processing session may be terminated by using the
procedure given in Section 6.6.2.
Any attempts to change or modify the data base in any way will
result in the following diagnostic message:
-864- COMMAND NOT AVAILABLE IN SHARED MODE -
6.6-10
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6.7 REMOTE BATCH TERMINAL OPERATION
Batch processing, whether remote or local submittal, implies that
discrete jobs are submitted to the NCC UNIVAC 1100 from cards or some
similar form. If local, card decks are submitted to the I/O Control Clerk
and then loaded into the computer; if remote, cards are read into the
computer through a high-speed remote job entry (ROE) terminal which has
been connected to the computer via telephone data link.
Remote batch terminal operation with the NCC UNIVAC 1100 is
currently supported under the UNIVAC 1004 and NTR (9000 Remote) terminal
protocols. This means that a variety of commercial ROE terminals which
are capable of emulating (or looking like) a U-1004 or NTR terminal may be
used to access the NCC UNIVAC 1100. A partial list of RJE terminals which
satisfy one or more of these conditions includes the following:
DATA 100 Models 74, 76, and 78
COPE RJE Terminals
Harris RJE Terminals
UNIVAC 1004
UNIVAC 9200 NTR
If you are uncertain regarding the compatibility of a particular
terminal with the NCC UNIVAC 1100, you should contact the following:
NCC User Services
919/541-3649
FTS: 629-3649
All RJE terminals are identified to the NCC UNIVAC 1100 by a unique
SITE ID which is assigned by the MIDSD TSSMS Office at Research Triangle
Park, North Carolina. Figure 6-2 gives an example of the form required
for batch terminal support. The completed form is submitted to the
appropriate ADP coordinator (through the EPA project officer if required)
for approval and signature.
6.7-1
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Organization:
Terminal manufacturer § model number:
If programmable, what UNIVAC terminal does the terminal emulate?
Hours of Operation: From To EOT
Person responsible:
Name '
Title
Mailing Address
Telephone -- FTS . Ext,
-- Commercial . Ext.
Comments:
ADP Coordinator Date
THE FOLLOWING TO BE COMPLETED BY NCC
SITE-ID Central Computer Operations:
Day:
Telephone numbers to use:
FTS Night:
Mailing Address:
National Computer Center
Commercial U.S. EPA
Research Triangle Park
North Carolina 27711
Contacts: User Services Hours available for operation:
FTS 629-3649 Weekdays: to EOT
919/541-3649 Saturday: to EOT
Sunday: to EOT
Holidays: to EOT
Comments:
Figure 6-2. Request for Batch Terminal Support Form.
6.7-2
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The batch SITE ID is of the form DATAXX and must be transmitted to
the NCC UNI VAC 1100 at sign-on before any processing can be initiated.
6.7.1 Initiating a Remote Batch Processing Session
Communications are established with the NCC UNIVAC 1100 through
data communication modems over voice-grade telephone lines. The NCC
UNIVAC 1100 will support RJE processing only at 4800 bits/second (BPS)
transmission rate. A list of nationwide RJE telephone access numbers for
the NCC is given in Table 6-4.
Batch processing through an RJE terminal essentially means that the
terminal-to-computer data link must be established and the computer card
deck must be read into the computer in a prescribed manner. Since this
procedure varies dramatically among terminal vendors, the user should
refer to his terminal hardware operating manual for the appropriate
procedure. If any problems or questions arise, the user should contact
NCC User Services.
6.7.2 Terminating a Remote Batch Processing Session
The termination of a remote batch processing session depends upon
which UNIVAC RJE terminal is being used (or emulated). The user should
consult his terminal hardware operations manual for the correct procedure.
6.7-3
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TABLE 6-4. NCC REMOTE BATCH ACCESS TELEPHONE NUMBERS
Location Transmission Rate (BPS) Telephone
Continental U.S. 4800 919/541-2094
(toll outside RTP) (3 lines)
Continental U.S. (except NC) 4800 800/334-9761
(toll free) (8 lines)
NOTE: 4800 BPS transmission requires Bell 208B dataset or equivalent.
6.7-4
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6.8 EADS USER SUPPORT
IERL/RTP is committed to the on-going support of the EADS and its
associated software. The administrative functions relative to the EADS
are provided by the Special Studies Staff in IERL. Technical development
and maintenance is provided by the EADS Support Staff, which is composed
of government contractors under the direction of the EADS Program Manager.
The EADS Technical Support Staff has the responsibility for conducting the
data QA program, updating documentation, developing analytical software
specifications, conducting information transfer activities, etc. This
function is being provided by Acurex Corporation in Mountain View,
California, and Midwest Research Institute in Kansas City, Missouri. Data
processing activities are also performed by Acurex Corporation in its
offices located at Research Triangle Park, North Carolina.
Any questions regarding the EADS should be directed to the EADS
Program Manager or the EADS Technical Support Staff. Their names,
addresses, and phone numbers are listed on page xi.
Problems relating to the operation of the NCC UNIVAC 1100, to data
communications, etc., are not the responsibility of the EADS Technical
Support Staff. These questions should be addressed to:
User Services
National Computer Center (MD-34B)
U.S. Environmental Protection Agency
Research Triangle Park, North Carolina 27711
FTS: 629-3649
Commercial: 919/541-3649
6.8-1
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SECTION 7
PROGRAM LIBRARY
7.0 INTRODUCTION
The usefulness and usability of industrial discharge data which
have been compiled into a computerized information system is limited if
the data cannot be retrieved and utilized to answer questions that a user
-------�
applicable to one or more of the waste stream data bases contained in the
EADS.
Each entry in the program library is described by a brief abstract
which identifies in general terms the input required from the user and the
output to be expected. Some programs will be applicable to both demand
(interactive) processing and batch processing, and step-by-step
instructions for executing the program in both modes are given when
appropriate. For demand processing, it is assumed that the user has
successfully established communications with the UNI VAC U-1100 computer as
described in Section 6 of this user guide. In like manner, batch users
are assumed to have established communications with the UNIVAC U-1100
through a remote terminal device or have the capability of submitting run
requests locally at the EPA National Computer Center at Research Triangle
Park, NC. All input requirements for each program are listed and a sample
(or representative) output is provided. Any comments pertaining to the
use of the program which may be helpful to the user are also given.
As new user programs are developed and made available to the EADS
user community, this section will be expanded.
7.0-2
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7.1 SERIES REPORT
7.1.1 Applicability: FPEIS, GEDS, LEDS, SODS
7.1.2 Abstract
The SERIES Report is the basic report for the EADS waste stream
data bases. This report lists all of the data contained in the test
series by stream, test operating level, and sample. The length of the
SERIES Report will depend upon the quantity of data contained in the test
series.
The format of the SERIES Report follows the structure of the EADS
data base. The first page of the report describes the source that was
sampled, identifies the sponsor of the testing and the organization which
did the actual testing, and provides any commentary on the test series
which was included. Beginning with the second page, the Report describes
the effluent stream level, including the control/treatment technology
design parameters. Following this, the test operating level is reported
which includes the control/treatment technology operating parameters and
the description of the source fuel or feed material. Next, the sample
level and any subsequent components are described. These data include the
chemical, radiological, and biological analysis results. The chemical
data may include Level 1 Environmental Assessment data as well as
compound-specific data for inorganics and organics. The chemical and
radiological data for various sampling components are summarized by
chemical/radiological species (or Level 1 fraction).
For the FPEIS, the SERIES Report provides calculated particle size
distributions for impaction-type sampling equipment including cumulative
mass concentrations, geometric mean diameters, etc. Where other types of
samples are used, the mass or number concentration is provided. The data
7.1-1
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are given as a function of particle size; that is, as a function of
components of the sampling system.
The SERIES Report may be run by inputting the TSN and the data base
name. The Report may be initiated only through a "demand" terminal
session although the SERIES program is only executed as a batch job. The
demand session gives complete instructions for using the SERIES Report
program.
7.1.3 User Data Required
• EADS Data Base Name (FPEIS, LEDS, GEDS, and/or SDDS)
• Valid TSN (or range of TSN's)
7.1.4 Data Qualification Required
None
7.1.5 Limitations/Restrictions
The SERIES Report program user has several printing options
available, including the NCC local printers, remote high-speed terminal
printers, and low-speed time-sharing (demand) terminals. Because of the
length of the SERIES Report for most of the test series, it is recommended
that the low-speed terminal option be avoided where possible.
7.1.6 Functional Description
Using the EADS waste stream data base name and the TSN, the
selected test series is retrieved and printed in its entirety. Multiple
SERIES Reports may be initiated during one session.
7.1.7 User Instructions — Demand File name: EADS.SERIES
The SERIES Report program may be accessed through a "demand", or
time-sharing, terminal (see Section 6.6), which can access the U-1100
computer. User access through the demand terminal allows the program to be
7.1-2
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executed as a batch job. The user should initiate the demand session by
following the procedures outlined in Section 6.6.1. When the session is
completed, the demand session may be ended by following the instructions
given in Section 6.6.2.
(In the following computer-generated instructions, the response by
the user is underlined.)
>@ADD EADS.SERIES (Enter the file name)
CIS 6R1 16:21:01
THE ASSUMED MODE IS FIELDATA
DO YOU NEED INSTRUCTIONS?> YES (Enter YES or NO)
THIS MODULE IS DESIGNED TO RUN THE SERIES REPORT FOR ANY VALID TEST SERIES
NUMBER AND DATA BASE NAME ENTERED. INFORMATION REQUIRED TO RUN THIS
ROUTINE WILL BE ENTERED BY THE USER AS PROMPTED BY THIS MODULE.
(If the answer to the preceding question had been NO, the above
statements would be skipped.)
ENTER YOUR ACCOUNT NUMBER:> (Enter a valid NCC Account Number)
ENTER THE DATA BASE NAME (Enter the data base name)
(FPEIS, LEDS, GEDS, OR SDDS):>
IS THE SERIES NUMBER IN A RANGE (YES OR N0)?> YES
YOUR REQUEST IS A CONTINUOUS RANGE
ENTER THE FIRST SERIES NUMBER:> (Enter the first TSN)
ENTER THE LAST SERIES NUMBER:> (Enter the last TSN)
(If the response to the range question is NO, the above statements
are skipped. The computer will prompt the user with the following
question.)
7.1-3
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ENTER THE TEST SERIES NUMBER:> (Enter the TSN)
ENTER THE NUMBER OF COPIES (Enter the number of copies wanted)
IF 1, JUST PRESS RETURN:>
DO YOU REQUIRE SPECIAL FORMS?> NO (Enter YES or NO)
(If YES had been entered, the program would request the forms ID.
Please consult the NCC User Reference Manual or the EADS Program Manager
before attempting to use this feature. The NO response means that
standard, one-part computer paper will be used.)
ENTER THE PRINT DESTINATION IF IT IS
TO BE OTHER THAN THE MAIN PRINTER:>
(If there is no preference, press the return key. If the output is
to be a remote high-speed terminal, enter the site ID of the terminal. If
a user demand terminal is to receive the output, enter the user ID for
that terminal user.)
ARE YOU FINISHED (YES OR N0)?> (Enter YES or NO)
(If additional selections are to be made, enter NO and the program
will prompt for the data base name selection. If YES, there will be a
normal exit.)
Please refer to Section 7.1.9 for sample runs of the demand SERIES
Report program. An example of the SERIES Report is given in
Section 7.1.10.
7.1.8 User Instructions — Batch
Batch (card input) processing of the SERIES Report program is not
available.
7.1-4
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7.1.9 Sample Demand Runs
(To be added later.)
7.1.10 Sample SERIES Report
(To be added later.)
7.1-5
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7.2 CHEMICAL SEARCH PROGRAM (CHEM-SEARCH')
7.2.1 Applicability: FPEIS, GEDS, LEDS, SDDS
7.2.2 Abstract
The Chemical Search Program (CHEM-SEARCH) enables the user to .
search all or part of the EADS waste stream data bases to determine the
presence of a particular chemical species. The user may identify the
chemical species by its Chemical Abstracts Services (CAS) Number, its
Multimedia Environmental Goals (MEG) Number, or its empirical formula. If
a search is to be made of part of a data base, the data base name must be
given and the range of TSN's must be specified. Both demand and batch
versions of the program are available to the user. The demand version
provides complete instructions on the use of the program through an
interactive interface with the user. A "Help" command is also available
to users who encounter problems.
The output from the CHEM-SEARCH program provides additional
information on the chemical species selected, including the MEG ID Number,
CAS Number, empirical formula, preferred name, molecular weight, other
names by which the chemical is known, and whether or not the chemical is
designated as a priority pollutant, hazardous pollutant, or both. For
each data base scanned, the TSN is listed for those test series in which
the chemical of interest is reported. The program does not report the
concentration of the chemical species. The selection criteria requires
only that the chemical species be found once in a given test series even
though multiple occurrences of the chemical may be present. It is
recommended that the user request the SERIES Report for each test series
identified in order to get more information.
7.2-1
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7.2.3 User Data Required
• Valid Chemical ID Code (MEG ID or CAS Number) or Empirical
Formula
t EADS Data Base Name (FPEIS, LEDS, 6EDS, and/or SDDS)
• Range of TSN's (optional)
7.2.4 Data Qualification Required
None
7.2.5 Limitations/Restrictions
The user is cautioned to use care when selecting the empirical
formula format option for organic compounds. Since several organic
compounds of the same class may have the same formula (e.g., isomers), it
would likely be safer to search on the basis of the MEG ID or the CAS
Number.
7.2.6 Functional Description
Using the user-supplied data on a particular chemical species, the
CHEM-SEARCH program initially checks the EADS Chemical Data Table (CDT) to
verify that a valid species has been requested. If so, both the MEG ID
and CAS Number are retrieved. The program next scans all of the data
bases specified using both the MEG ID and the CAS Number to search for the
chemical. If at least one occurrence of the species is found within a
test series, that test series is listed in the output. If no data are
found in the entire data base, this fact is also listed in the output.
7.2.7 User Instructions — Demand File name: EADS.RUN/CHEM-SEARCH
The CHEM-SEARCH program may be accessed through a "demand," or
time-sharing, terminal (see Section 6.6), which can access the U-1100
computer. User access in demand mode enables the program to be run in
"real time"; that is, the results are returned directly to the user.
7.2-2
-------�
The user shall initiate a demand session by following the
procedures outlined in Section 6.6.1. When the session is completed, the
session may be ended by following the procedures given in Section 6.6.2.
(In the following computer-generated instructions, the response by
the user is underlined.)
>@ADD EADS.RUN/CHEM-SEARCH (Enter the file name)
DO YOU NEED INSTRUCTIONS? (Enter YES or NO)
>YES
INSTRUCTIONS WILL BE LISTED SEVERAL LINES AT A TIME AND THEN STOP. TO
CONTINUE DEPRESS CARRIAGE RETURN.
THIS PROGRAM WILL LIST TEST SERIES NUMBERS FROM THE EADS DATA BASE WHICH
HAVE USER SPECIFIED CHEMICALS REPORTED IN THEIR ANALYSIS DATA. THE USER
MUST IDENTIFY THIS CHEMICAL TO THE PROGRAM BY USING MEG, CAS ID NUMBERS OR
EMPIRICAL FORMULA.
>(CR)
THE FORMAT USED IS:
M/MMMMMM - FOR THE MEG NUMBER — OR -
C/CCCCC-CC-C - FOR THE CAS NUMBER — OR -
F/XXXXXXX... - FOR THE EMPIRICAL FORMULA.
>(CR)
THE USER HAS THE OPTION OF SPECIFYING WHICH DATA BASE SERIES ARE TO BE
LISTED (FPEIS, GEDS, LEDS, OR SDDS). ADDITIONALLY, THE USER MAY LIMIT THE
LIST TO SPECIFIC RANGES, ONE PER DATA BASE.
TO SPECIFY A RANGE FOR ANY DB, THE USER MUST SELECT A "PARTICULAR" DATA
BASE WHEN QUERIED. "STOP" AND "HELP" MAY BE ENTERED AT ANY TIME. "STOP"
WILL EXIT THE PROGRAM. "HELP" WILL BRIEFLY LIST THE MAJOR QUERY RESPONSE
FORMATS. (IMPORTANT ~ ANY QUERY LISTED PRIOR TO A "HELP" REQUEST WILL
NOT BE SHOWN AG'AIN AFTER THE "HELP" RESPONSE FROM THE PROGRAM.)
>(CR)
7.2-3
-------�
(If the reply to the above question is NO, the preceding statements
are skipped.)
ENTER THE CODE/CHEMICAL ID (FORMULA) (Use the format described above)
>C/00067-66-3
DO YOU WISH A PARTICULAR DATA BASE? (Enter YES or NO)
>YES
ENTER THE DATA BASE TO BE SELECTED (Enter LEDS, GEDS, SDDS, or FPEIS)
>LEDS
DO YOU WISH TO SELECT WITHIN A (Enter YES or NO)
RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE (Enter the TSN)
RANGE
ENTER THE MAXIMUM NUMBER IN THE RANGE
>1P_
(If no particular data base is named, CHEM-SEARCH will scan all
entries in all four data bases. This is a lengthy sort and it is better
to request each data base separately. When the data base is specified,
the user may restrict the search to only a portion of the data base as
shown. If a range is not requested by the user, the last two queries are
skipped, and the entire data base is scanned.)
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A PREVIOUS
ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
7.2-4
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(If a data base name is entered, the program will again ask if a
range is requested and the ensuing steps are repeated. If END is entered,
the program starts to execute. Typical output is as follows.)
CHLOROFORM (TRICHLOROMETHANE)
MEG: 02A100 CAS: 00067-66-3 FORMULA: CHCL3
MOLECULAR WEIGHT: 119.38 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
OTHER NAMES: METHANE TRICHLORIDE
TRICHLOROMETHANE
LEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
*** NORMAL END ***
At this point, the terminal is returned to the Control Mode; that is, the
program has finished and the user may now enter additional commands.
The CHEM-SEARCH program is very flexible and has a number of
options available to users. This flexibility is best seen through the
sample demand runs given in Section 7.2.9. Use of the "HELP" option is
also shown there.
7.2.8 User Instructions — Batch
The CHEM-SEARCH program may also be executed as a batch job on the
UNIVAC U-1100 using punched card input. It is assumed that the user has
card input access to the U-1100 computer either through "across the
counter" submitted at Research Triangle Park, NC, or through a remote
batch terminal.
7.2-5
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In order to run the CHEM-SEARCH program in batch mode, the user
should submit the following cards:
@RUN,R/RS Run ID,Account Number,EADS,5,50/50
@ASG,A EADS.
@XQT,BHZ EADS.CHEM-SEARCH
. . . parameter cards . . .
@FIN
There are three types of parameter cards defined for CHEM-SEARCH
and they are used to drive the program. The Type 1 Parameter Card
identifies the chemical to be requested in terms of its MEG ID Number, CAS
Number, or empirical formula. The Type 2 Parameter Card identifies the
data base to be selected and specifies the range of TSN's to be searched.
The Type 3 Parameter Card is the END card which indicates to the program
that the input data have been completed.
The formats for the parameter cards are as follows:
Card Col. 12345678
Type 1: M/AAAAAA
or C/BBBBB-BB-B
or F/DDDDD...
where all data begin in column 1 of the card and:
M identifies the MEG Number AAAAAA;
C identifies the CAS Number BBBBB-BB-B; and
F identifies the Empirical Formula DDDD....
1 2
Type 2: Card Col. 12345678901234567890
DBDBD MINXX-MAXZZ
where DBDBD identifies the data base name beginning in
column 1 (choose FPEIS, GEDS, LEDS, or SDDS),
7.2-6
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MINXX is the starting TSN in the range of TSN's to be
specified. The TSN should be entered as a right-justified
integer number in card columns 7-11,
(enter a dash in card column 12)
MAXZZ is the last TSN in the range of TSN's to be specified.
The TSN should be entered as a right-justified integer
number in card columns 13-17.
*Note* If no range of TSN's is requested (that is, if the entire data
base is to be searched), leave card columns 7-17 blank.
Also, if one end of the TSN's range is entered, the other is
required also. A Type 2 parameter card must be included for each data
base requested. The order of the Type 2 cards is not important.
Type 3: Card Col. 123
END
This card signifies the end of the data. It should be the last
parameter card included in the card deck.
*Caution* The parameter cards must be entered into the card deck in the
following order:
Type 1
All Type 2
Type 3
Sample print-outs from CHEM-SEARCH are included in Section 7.2.10.
7.2.9 Sample Demand Runs
(1) MEG ID Number Format:
>@ADD EADS.RUN/CHEM-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE CODE/CHEMICAL ID (FORMULA)
>M/02A065
7.2-7
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CHEMICAL DATA NOT FOUND FOR: M/02A065
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE CODE/CHEMICAL ID (FORMULA)
>M/02A100
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DO~YftJ WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
CHLOROFORM (TRICHLOROMETHANE)
MEG: 02A100 CAS: 00067-66-3 FORMULA: CHCL3
MOLECULAR WEIGHT: 119.38 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
OTHER NAMES: METHANE TRICHLORIDE
TRICHLOROMETHANE
LEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
00011
00143
00144
00145
00147
00148
00150
00151
00152
00153
*** NORMAL END ***
7.2-8
-------�
(2) Chemical Formula Format:
Caution: Be careful using this format for organic chemicals
where isomers may be encountered.
>@ADD EADS.RUN/CHEM-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE CODE/CHEMICAL ID (FORMULA)
>F/CHCL3
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>01
ENTER THE MAXIMUM NUMBER IN THE RANGE
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>FPEIS
DO YOU WISH TO SELECT WITHIN A RANGE OF FPEIS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
CHLOROFORM (TRICHLOROMETHANE)
MEG: 02A100 CAS: 00067-66-3 FORMULA: CHCL3
MOLECULAR WEIGHT: 119.38 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
OTHER NAMES: METHANE TRICHLORIDE
TRICHLOROMETHANE
LEDS
00001
00002
00003
00004
00005
7.2-9
-------�
NO FPEIS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
>
(3) Use of HELP Command:
>@ADD EADS.RUN/CHEM-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE CODE/CHEMICAL ID (FORMULA)
>F/C2CL4
DO YOU WISH A PARTICULAR DATA BASE?
>HELP
"STOP" WILL EXIT PROGRAM
"M/MMM..,C/CCCCC-CC-C,F/XXXXX...
WILL SEARCH BY CHEMICAL
"FPEIS", "GEDS", "LEDS" or "SDDS" WILL SELECT A DATA BASE,
"END" MEANS END OF SOLICITATION FOR A DATA BASE.
>YES
ENTER THE DATA BASE TO BE SELECTED
>FPEIS
DO YOU WISH TO SELECT WITHIN A RANGE OF FPEIS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>1
ENTER THE MAXIMUM NUMBER IN THE RANGE
>5
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>^
ENTER THE MAXIMUM NUMBER IN THE RANGE
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
TETRACHLOROETHENE
MEG: 02B080 CAS: 00127-1S-4 FORMULA: C2CL4
MOLECULAR WEIGHT: 165.83 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
7.2-10
-------�
OTHER NAMES: ETHYLENE TETRACHLORIDE
PERCHLOROETHYLENE
TETRACHLORO ETHYLENE
LEDS
00005
00006
00007
00008
00009
00010
NO FPEIS SERIES FOUND BETWEEN SERIES 00001 and 00005
*** NORMAL END ***
(4) CAS Number Format:
>@ADD EADS.RUN/CHEM-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE CODE/CHEMICAL ID (FORMULA)
>C/00127-18-4
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>2!9
ENTER THE MAXIMUM NUMBER IN THE RANGE
>39
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
TETRACHLOROETHENE
MEG: 02B080 CAS: 00127-18-4 FORMULA: C2CL4
MOLECULAR WEIGHT: 165.83 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
OTHER NAMES: ETHYLENE TETRACHLORIDE
PERCHLOROETHYLENE
TETRACHLORO ETHYLENE
7.2-11
-------�
NO LEDS SERIES FOUND BETWEEN SERIES 00029 AND 00039
*** NORMAL END ***
>
(5) Example of User Aborted Run:
>@ADD EADS.RUN/CHEM-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE CODE/CHEMICAL ID (FORMULA)
>M/02P101
CHEMICAL DATA NOT FOUND FOR: M/02P101
WOULD YOU LIKE TO TRY AGAIN?
>NO
(6) Invalid Data Format/Data Not Found:
>@ADD EADS.RUN/CHEM-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE CODE/CHEMICAL ID (FORMULA)
>C/01A001
INVALID CAS FORMAT (01A001 )
CHEMICAL DATA NOT FOUND FOR: C/01A001
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE CODE/CHEMICAL ID (FORMULA)
>M/001A001
CHEMICAL DATA NOT FOUND FOR: M/001A001
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE CODE/CHEMICAL ID (FORMULA)
>M/01A100
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
7.2-12
-------�
PENTANES
MEG: 01A100 CAS: FORMULA: C5H12
MOLECULAR WEIGHT: 72.15
NO LEDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
7.2.10 Sample Batch Runs
The sample batch run outputs demonstrate the flexibility of the
CHEM-SEARCH program in satisfying user needs. The user input cards (which
are listed in the output) are underlined.
(1) MEG ID Format:
@RUN.D/RS Run ID,Account Number,EADS.10.20
@ASG.A EADS.
@XQT.BHZ EADS.CHEM-SEARCH
ENTER THE CODE/CHEMICAL ID
M/48A100
ENTER THE DATA BASE TO BE SELECTED
GEDS
ENTER THE DATA BASE TO BE SELECTED
LEDS 00001-00100
ENTER THE DATA BASE TO BE SELECTED
END
ELEMENTAL PHOSPHORUS
MEG: 48A100 CAS: 07723-14-0 FORMULA: P
MOLECULAR WEIGHT: 30.97 HAZARDOUS POLLUTANT
OTHER NAMES: BLACK PHOSPHORUS
RED PHOSPHORUS
WHITE PHOSPHORUS
YELLOW PHOSPHORUS
LEDS
00083
00089
00092
00093
7.2-13
-------�
00094
00095
00096
NO GEDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
@FIN
(2) CAS Number Format:
@RUN,R/RS Run ID,Account Number,EADS,8.10
(3ASG.A EADS.
FAC WARNING 040000100000
@XQT EADS.CHEM-SEARCH
ENTER THE CODE/CHEMICAL ID (FORMULA)
0/00076-44-8
ENTER THE DATA BASE TO BE SELECTED
LEDS
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
FPEIS
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
END
HEPTACHLOR
MEG: 16PN03 CAS: 00076-44-8 FORMULA: C10H5CL7
MOLECULAR WEIGHT: 373.35 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
OTHER NAMES: DRINOX
HEPTAGRAN
VELSICOL-104
LEDS
00058
00074
00076
00082
00089
00103
00113
00115
00116
00134
00140
7.2-14
-------�
NO FPEIS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
@FIN
(3) Empirical Formula Format:
@RUN,R/RS Run ID.Account Number,EADS-,8,10
(3ASG.A EADS.
FAC WARNING 040000100000
@XQT EADS.CHEM-SEARCH
ENTER THE CODE/CHEMICAL ID (FORMULA)
F/C10H5CL7
ENTER THE DATA BASE TO BE SELECTED
LEDS
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/11 END" OR CARRIAGE RETURN IF COMPLETE:
FPEIS
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
END
HEPTACHLOR
MEG: 16PN03 CAS: 00076-44-8 FORMULA: C10H5CL7
MOLECULAR WEIGHT: 373.35 PRIORITY POLLUTANT
HAZARDOUS POLLUTANT
OTHER NAMES: DRINOX
HEPTAGRAN
VELSICOL-104
LEDS
00058
00074
00076
00082
00089
00103
00113
00115
00116
00134
00140
7.2-15
-------�
NO FPEIS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
@FIN
(4) Invalid Data/Input Error Format:
(3RUN.R/RS Run ID,Account Number.EADS.8,10
@ASG.A EADS.
@XQT EADS.CHEM-SEARCH
ENTER THE CODE/CHEMICAL ID (FORMULA)
C/00076-44-8
ENTER THE DATA BASE TO BE SELECTED
LEDS
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
FPEIS
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
1104A NO DATA AVAILABLE ON ACCEPT (Missing END Card)
ERROR ADDR: 015514 BDI: 000013
EXECS ERROR: CONTINGENCY TYPE-12 ERROR TYPE-03 CODE-00 AT PROG
ADD 012165
BDI'S: M-1=000013 M-D=000012 U-I=000000 U-D=000000
-800- SYSTEM ERROR CODE 816 xll = 007255-
**** PLEASE NOTIFY DATA BASE ADMINISTRATOR ****
7.2-16
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7.3 SERIES SUMMARY INFORMATION PROGRAM (SNAP-SHOT)
7.3.1 Applicability: FPEIS, GEDS, LEDS, SDDS
7.3.2 Abstract
The Series Surrmary Information Program (SNAP-SHOT) is a brief
report which summarizes the contents of an EADS test series. The report
o
gives an indication of "what" is contained in the test series without
getting into details. It will provide the user with an overview of the
test series in a brief format that would ordinarily require the obtaining
of a more detailed and lengthy SERIES Report (see Section 7.1).
The formation of the SNAP-SHOT Report follows the SERIES Report
very closely; it is as if a "snap-shot" had been made of the SERIES
Report. The first page of the SNAP-SHOT Report is the same as the first
page of the SERIES Report; that is, the source that was sampled is
described in terms of its industrial categorization and location (if
available); the sponsor of the testing and the organization which
performed the work are identified; and any comments on the test series are
provided. Any EADS test series which contain data from other media that
were collected at the same time are identified and a list of references
pertaining to the test series is provided. Next, a summary of the data to
be found in the test series is given, including the type of waste or
product streams reported, the type of control technology applied (if any),
the number of discrete samples collected and whether they were collected
from a control system inlet or outlet, and whether or not data are present
for the sample on the results of inorganic/non-Level 1 organic analysis,
Level 1 organic analysis, radionuclide analysis, and bioassay. Finally,
the total number of effluent or product streams is given along with the
total number of samples reported.
7.3-1
-------�
The SNAP-SHOT program may be qualified by any combination of five
parameters to select several test series, or a specific range of test
series may be specified by the user. The five parameters which may be
chosen are as follows:
Source Category
Source Type
Product/Device
Process Type
Feed Material Category
Acceptable data for these parameters may be found in the
Terminology Reference Manual in Table A-l for the first four parameters
and in Table A-2 for the Feed Material Category. The user may specify any
combination of these parameters to retrieve summary information from a
particular data base. For example, a user may request SNAP-SHOT reports
for all test series where the Source Type equals UTILITY, Product/Device
equals BOILER, and Feed Material Category equals COAL; that is, the user
wants to identify all test series on coal-fired, utility boilers. The
user is not required to utilize this parameter option. He may instead
specify a single TSN or a range of TSN's.
The SNAP-SHOT program may be initiated either through a "demand"
(time-sharing) session or through submitting a batch job. The demand
version of the program prompts the user with complete instructions for its
use.
7.3.3 User Data Required
t EADS Data Base Name (FPEIS, LEDS, GEDS, or SDDS)
t Valid TSN (or range of TSN's) or
t Source Category, Source Type, Product/Device, Process Type,
and/or Feed Material Category
7.3-2
-------�
7.3.4 Data Qualification Required
If the Parameters Option is selected, the user may qualify the
search for particular test series by inputting data for any combination of
the parameters chosen. The acceptable data are combined in the
Terminology Reference Manual in Table A-l and Table A-2. This
qualification is best shown by illustration in sections to follow.
7.3.5 Limitations/Restrictions
The SNAP-SHOT program user has several printing options available
including the NCC local printers, remote high-speed terminal printers, and
low-speed time-sharing (demand) terminals. While the SNAP-SHOT Report
itself is not long (usually two to three pages), the volume of output
could become voluminous, particularly if the Parameters Option is selected
and the subsequent retrieval involves many test series. Unless the user
is selecting a specific test series, it is recommended that the low-speed
terminal option be avoided where possible.
7.3.6 Functional Description
Using the EADS waste stream data base name and the TSN(s) (or the
source categorization parameters), the selected test series is (are)
retrieved from the data base and the summary information is printed.
7.3.7 User Instructions -- Demand File name: EADS.RUN/SNAP-SHOT
The SNAP-SHOT program may be accessed through a "demand", or
time-sharing, terminal (see Section 6.6), which can access the U-1100
computer. User access through the demand terminal allows the program to
be executed as a batch job. The user should initiate the demand session
by following the procedures outlined in Section 6.6.1. When the session
is completed, the demand session may be ended by following the
instructions given in Section 6.6.2.
7.3-3
-------�
(In the following computer-generated instructions, the response by
the user is underlined.)
>@ADD EADS.RUN/SNAP-SHOT (Enter the file name)
CIS 6R1 16:21:01
THE ASSUME MODE IS FIELDATA
DO YOU NEED INSTRUCTIONS:> YES (Enter YES or NO)
THIS MODULE IS DESIGNED TO RUN THE SNAP-SHOT REPORT FOR ANY VALID TEST
SERIES NUMBER AND DATA BASE NAME ENTERED. INFORMATION REQUIRED TO RUN
THIS ROUTINE WILL BE ENTERED BY THE USER AS PROMPTED BY THIS MODULE.
THE PARAMETERS OPTION ALLOWS THE USER TO SEARCH THE ENTIRE DATA BASE FOR
ALL TEST SERIES WHICH SATISFY THE SELECTION CRITERIA.
>(Press carriage return to continue)
THE PARAMETERS FOR WHICH VALUES MAY BE ENTERED ARE AS FOLLOWS:
SOURCE CATEGORY
SOURCE TYPE
PRODUCT/DEVICE
PROCESS TYPE
FEED MATERIAL CATEGORY
>(Press carriage return to continue)
OTHERWISE, THE USER MAY ENTER A SINGLE TEST SERIES NUMBER OR A RANGE OF
TEST SERIES NUMBERS.
>(Press carriage return to continue)
(If the answer to the instructions question was NO, the above statements
would be skipped.)
ENTER YOUR ACCOUNT NUMBER:> (Enter a valid NCC Account Number)
ENTER THE DATA BASE NAME (Enter the data base name)
(FPEIS, LEDS, GEDS, or SDDS):>
DO YOU WISH TO SELECT THE PARAMETERS OPTION?
>YES (Enter YES or NO)
ENTER THE VALUE FOR THE PARAMETER AS PROMPTED.
IF NO DATA TO BE INPUT FOR THIS PARAMETER, PRESS RETURN.
SOURCE CATEGORY:> (CR) (Enter value from Table A-l,
Terminology Reference Manual, or
press return.)
7.3-4
-------�
SOURCE TYPE:> UTILITY
PRODUCT/DEVICE:> BOILER
PROCESS TYPE:> (CR)
FEED MATERIAL CATEGORY:> COAL (Enter value from Table A-2,
Terminology Reference Manual, or
press return.)
ENTER THE NUMBER OF COPIES (Enter the number of copies wanted)
IF 1, JUST PRESS RETURN:> (CR)
DO YOU REQUIRE SPECIAL FORMS?> NO (Enter YES.or NO)
(If YES had been entered, the program would request the forms ID.
Please consult the NCC User Reference Manual or the EADS Program Manager
before attempting to use this feature. The NO response means that
standard, one-part computer paper will be used.)
ENTER THE PRINT DESTINATION IF IT IS TO BE OTHER THAN THE MAIN
PRINTER:> (CR)
(If there is no preference, press the return key. If the output is
to be a remote high-speed terminal, enter the site ID of the terminal. If
a user demand terminal is to receive the output, enter the user ID for
that terminal user.)
ARE YOU FINISHED (YES OR N0)?> (Enter YES or NO)
(If additional selections are to be made, enter NO and the program
will prompt for the data base name selection. If YES, there will be a
normal exit.)
Please refer to Section 7.3.9 for sample runs of the demand
SNAP-SHOT program. An example of the SNAP-SHOT Report is given in
Section 7.3.11.
7.3-5
-------�
It should be emphasized that SNAP-SHOT does not actually execute as
a demand (time-sharing) job. The demand routine creates a job stream
which is processed as a batch job by the U-1100.
7.3.8 User Instructions -- Batch
The SNAP-SHOT program may also be executed as a batch job on the
UNIVAC U-1100 using punched card input. It is assumed that the user has
card input access to the U-1100 computer either through "across the
counter" submitted at Research Triangle Park, NC, or through a remote
batch terminal.
In order to run the SNAP-SHOT program in batch mode, the user
should submit the following cards:
@RUN,R/RS RUN ID,Account Number,EADS,5,50/50
(9ASG,A EADS.
@XQT,BHZ EADS.SNAP-SHOT
. . . parameter cards . . .
@FIN
Three types of parameter cards are used to identify the options
selected and to drive the program. If the user wishes to print the
SNAP-SHOT report for a specific TSN (or range of TSN's), the following
Type 1 parameter card is used:
1 2
Type 1: Card Col. 12345678901234567890
DBDBD MINXX-MAXZZ
where DBDBD identifies the data base name beginning in column 1
(choose FPEIS, 6EDS, LEDS, or SDDS),
MINXX is the starting TSN in the range of TSN's to be
specified. The TSN should be entered as a right-justified
integer number in card columns 7-11,
(enter a dash in card column 12)
7.3-6
-------�
MAXZZ is the last TSN in the range of TSN's to be specified.
The TSN should be entered as a right-justified integer
number in card columns 13-17.
*Note* If no range of TSN's is requested (that is, if a single test
series is selected), leave card columns 12-17 blank.
If the user wishes to select the Parameters Option, then the Type 2
parameter cards should be used. Any or all of the following cards may be
included in any order:
1234
Type 2 Card Col. 1234567890123456789012345678901234567890
SOURCE CATEGORY VVVV V '
SOURCE TYPE VVVV- V
PRODUCT/DEVICE VVVV - V
PROCESS TYPE VVVV V
FEED MATERIAL VVVV V
where VVVV V is the valid value from Table A-l or Table A-2 in the
Terminology Reference Manual beginning in column 21,
and not exceeding 20 characters in length.
Following the Type 1 or Type 2 cards, the Type 3 card is entered to
indicate the end of the data. It should be the last parameter card in the
deck before the @FIN card. The card has the following format:
Type 3: Card Col. 123
END
*Caution* The parameter cards must be entered into the card deck in the
following order:
Type 1 or Type 2
Type 3
Examples of batch runs of SNAP-SHOT are given in Section 7.3.10.
7.3-7
-------�
7.3.9 Sample Demand Runs
(1) SNAP-SHOT for a Specific TSN:
>@ADD EADS. RUN/SNAP-SHOT
DO YOU NEED INSTRUCTIONS?
>NO
ENTER YOUR ACCOUNT NUMBER: > Account Number
ENTER THE DATA BASE NAME
(FPEIS, LEDS, GEDS, OR SDDS):> FPEIS
DO YOU WISH TO SELECT THE PARAMETERS OPTION?
>NO
DO YOU WISH TO SELECT WITHIN A RANGE OF TEST SERIES?
>NO
ENTER THE TEST SERIES NUMBER: > 225
ENTER THE NUMBER OF COPIES
IF 1, JUST PRESS RETURN: > 2
DO YOU REQUIRE SPECIAL FORMS? :> NO
ENTER THE PRINT DESTINATION IF IT IS TO BE OTHER THAN THE MAIN
PRINTER:> (CR)
ARE YOU FINISHED (YES OR N0)?> YES
*** NORMAL EXIT ***
(2) SNAP-SHOT for a Range of TSN's:
>@ADD EADS. RUN/SNAP-SHOT
DO YOU NEED INSTRUCTIONS?
>NO
ENTER YOUR ACCOUNT NUMBER :> Account Number
ENTER THE DATA BASE NAME
(FPEIS, LEDS, GEDS, OR SDDS):> FPEIS
DO YOU WISH TO SELECT THE PARAMETERS OPTION?
>NO
DO~~YOU WISH TO SELECT WITHIN A RANGE OF TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
ENTER THE MAXIMUM NUMBER IN THE RANGE
>39
ENTER THE NUMBER OF COPIES
IF 1, JUST PRESS RETURN:> 2
DO YOU REQUIRE SPECIAL FORMS? :> NO
7.3-8
-------�
ENTER THE PRINT DESTINATION IF IT IS TO BE OTHER THAN THE MAIN
PRINTER:> (CR)
ARE YOU FINISHED (YES OR N0)?> YES
*** NORMAL EXIT ***
7.3.10 Sample Batch Runs
(To be added later.)
7.3.11 Sample Output
(To be added later.)
7.3-9
-------�
7.4 BIOLOGICAL SEARCH PROGRAM (BIO-SEARCH)
7.4.1 Applicability: FPEIS, GEDS, LEDS, SODS
7.4.2 Abstract
The Biological Search Program (BIO-SEARCH) enables the user to
search all or part of the EADS waste stream data bases to determine the
presence of the results of a particular bioassay test. The user may
identify the bioassay results either by specifying the type of bioassay or
the specific test name as found in the EADS Terminology Reference Manual
Tables A-ll and A-12, respectively. If a search is to be made of part of
a data base, the data base name must be given and the range of TSN's must
be specified. Both demand and batch versions of the program are available
to the user. The demand version provides complete instructions on the use
of the program through an interactive interface with the user. A "Help"
command is also available to users who encounter problems.
For each data base scanned, the TSN is listed for those test series
in which the bioassay of interest is reported. The program does not
report the results of the biological tests. The selection criteria
requires only that the bioassay be found once in a given test series even
though multiple occurrences of the assay may be present. It is
recommended that the user request the SERIES Report for each test series
identified in order to get more information.
7.4.3 User Data Required
• Valid Bioassay Test Type or Bioassay Test Name
• EADS Data Base Name (FPEIS, LEDS, GEDS, and/or SODS)
• Range of TSN's (optional)
7.4-1
-------�
7.4.4 Data Qualification Required
None
7.4.5 Limitations/Restrictions
None
7.4.6 Functional Description
Using the user-supplied data on a particular bioassay test type or
test name, the BIO-SEARCH program initially checks the data to verify that
a valid bioassay test type or name has been requested. The program next
scans all of the data bases specified using either the test type or the
test name. If at least one occurrence of the assay is found within a test
series, that test series is listed in the output. If no data are found in
the entire data base, this fact is also listed in the output.
7.4.7 User Instructions — Demand File name: EADS.RUN/BIO-SEARCH
The BIO-SEARCH program may be accessed through a "demand", or
time-sharing, terminal (see Section 6.6), which can access the U-1100
computer. User access in demand mode enables the program to be run in
"real time"; that is, the results are returned directly to the user.
The user shall initiate a demand session by following the
procedures outlined in Section 6.6.1. When the session is completed, the
session may be ended by following the procedures given in Section 6.6.2.
(In the following computer-generated instructions, the response by
the user is underlined.)
>6>ADD EADS.RUN/BIO-SEARCH (Enter the file name)
DO YOU NEED INSTRUCTIONS? (Enter YES or NO)
>YES
INSTRUCTIONS WILL BE LISTED SEVERAL LINES AT A TIME AND THEN STOP.
TO CONTINUE DEPRESS CARRIAGE RETURN.
7.4-2
-------�
THIS PROGRAM WILL LIST TEST SERIES NUMBERS FROM THE EADS DATA BASE WHICH
HAVE USER SPECIFIED BIOASSAYS REPORTED IN THEIR ANALYSIS DATA. THE USER
MUST IDENTIFY THIS BIOASSAY TO THE PROGRAM BY USING THE BIOASSAY TEST TYPE
OR TEST NAME.
>(CR)
THE FORMAT USED IS:
A/TESTTYPE - FOR THE BIOASSAY TEST TYPE
B/TESTTYPE - FOR THE BIOASSAY TEST TYPE
>(CR)
THE USER HAS THE OPTION OF SPECIFYING WHICH DATA BASE SERIES ARE TO BE
LISTED (FPEIS, GEDS, LEDS, OR SDDS). ADDITIONALLY, THE USER MAY LIMIT THE
LIST TO SPECIFIC RANGES, ONE PER DATA BASE.
TO SPECIFY A RANGE FOR ANY DB, THE USER MUST SELECT A "PARTICULAR" DATA
BASE WHEN QUERIED. "STOP" AND "HELP" MAY BE ENTERED AT ANY TIME. "STOP"
WILL EXIT THE PROGRAM. "HELP" WILL BRIEFLY LIST THE MAJOR QUERY RESPONSE
FORMATS. (IMPORTANT - ANY QUERY LISTED PRIOR TO A "HELP" REQUEST WILL NOT
BE SHOWN AGAIN AFTER THE HELP RESPONSE FROM THE PROGRAM.)
>(CR)
(If the reply to the above question is NO, the preceding statements
are skipped.)
ENTER THE BIOASSAY TEST TYPE/NAME (Use the format described above)
>A/CYTOTOXICITY
DO YOU WISH A PARTICULAR DATA BASE? (Enter YES or NO)
>YES
(Enter LEDS, GEDS, SDDS, or FPEIS)
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DO YOU WISH TO SELECT WITHIN A
RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE
RANGE
(Enter YES or NO)
(Enter the TSN)
ENTER THE MAXIMUM NUMBER IN THE
RANGE
(If no particular data base is named, BIO-SEARCH will scan all
entries in all four data bases. This is a lengthy sort and it is better
to request each data base separately. When the data base is specified,
7.4-3
-------�
the user may restrict the search to only a portion of the data base as
shown. If a range is not requested by the user, the last two queries are
skipped, and the entire data base is scanned.)
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A PREVIOUS
ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
(If a data base name is entered, the program will again ask if a
range is requested and the ensuing steps are repeated. If END is entered,
the program starts to execute. Typical output is as follows.)
BIOASSAY TEST TYPE: CYTOTOXICITY
LEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
*** NORMAL END ***
>
At this point, the terminal is returned to the Control Mode; that is, the
program has finished and the user may now enter additional commands.
The BIO-SEARCH program is very flexible and has a number of options
available to users. This flexibility is best seen through the sample
demand runs given in Section 7.4.9. Use of the "HELP" option is also
shown there.
7.4.8 User Instructions -- Batch
The BIO-SEARCH program may also be executed as a batch job on the
UNIVAC U-1100 using punched card input. It is assumed that the user has
7.4-4
-------�
card input access to the U-1100 computer either through "across the
counter" submitted at Research Triangle Park, NC, or through a remote
batch terminal.
In order to run the BIO-SEARCH program in batch mode, the user
should submit the following cards:
@RUN,R/RS Run ID,Account Number,EADS,5,50/50
G>ASG,A EADS.
@XQT,BHZ EADS.BIO-SEARCH
. . . parameter cards ...
@FIN
Three types of parameter cards are defined for BIO-SEARCH and they
are used to drive the program. The Type 1 Parameter Card identifies the
assay to be requested in terms of its test type or test name. The Type 2
Parameter Card identifies the data base to be selected and specifies the
range of TSN's to be searched. The Type 3 Parameter Card is the END card
which indicates to the program that the input data have been completed.
The formats for the parameter cards are as follows:
Type 1: Card Col. 12345678...
A/TESTTYPE
or B/TESTNAME
where all data begin in column 1 of the card and:
A identifies the bioassay test type TESTTYPE; and
B identifies the bioassay test name TESTNAME.
1 2
Type 2: Card Col. 12345678901234567890
DBDBD MINXX-MAXZZ
where DBDBD identifies the data base name beginning in column 1
(choose FPEIS, GEDS, LEDS, or SDDS),
MINXX is the starting TSN in the range of TSN's to be
specified. The TSN should be entered as a
right-justified integer number in card columns 7-11,
7.4-5
-------�
(enter a dash in card column 12)
MAXZZ is the last TSN in the range of TSN's to be
specified. The TSN should be entered as a
right-justified integer number in card
columns 13-17.
*Note* If no range of TSN's is requested (that is, if the
entire data base is to be searched), leave card columns
7-17 blank.
Also if one end of the TSN's range is entered, the
other is required also. A Type 2 parameter card must
be included for each data base requested. The order of
the Type 2 cards is not important.
Type 3; Card Col. 123
END
This card signifies the end of the data. It should be the last
parameter card included in the card deck.
*Caution* The parameter cards must be entered into the card deck
in the following order:
Type 1
All Type 2
Type 3
Sample print-outs from BIO-SEARCH are included in Section 7.4.10.
7.4.9 Sample Demand Runs
(1) Test Name Format:
>gADD EADS.RUN/BIO-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE BIOASSAY TEST TYPE/NAME
>B/CHOV
BIOASSAY DATA NOT FOUND FOR: B/CHOV
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE BIOASSAY TEST TYPE/NAME
>B/CHO
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
7.4-6
-------�
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
BIOASSAY TEST NAME: CHO
LEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
00011
00143
00144
00145
00147
00148
00150
00151
00152
00153
*** NORMAL END ***
(2) Use of HELP Command:
>G>ADD EADS.RUN/BIO-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
EFTER THE BIOASSAY TEST TYPE/NAME
>A/MUTAGENICITY
DO YOU WISH A PARTICULAR DATA BASE?
>HELP
"STOP" WILL EXIT PROGRAM
"A/TESTTYPE", "B/TESTNAME"
WILL SEARCH BY TEST TYPE OR NAME
"FPEIS", "GEDS", "LEDS", OR "SDDS" WILL SELECT A DATA BASE,
"END" MEANS END OF SOLICITATION FOR A DATA BASE.
>YES
7.4-7
-------�
ENTER THE DATA BASE TO BE SELECTED
>FPEIS
DO YOU WISH TO SELECT WITHIN A RANGE OF FPEIS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>_!
ENTER THE MAXIMUM NUMBER IN THE RANGE
M
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>!
ENTER THE MAXIMUM NUMBER IN THE RANGE
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
BIOASSAY TEST TYPE: MUTAGENICITY
LEDS
00005
00006
00007
00008
00009
00010
NO FPEIS SERIES FOUND BETWEEN SERIES 00001 AND 00005
*** NORMAL END ***
(3) Example of User Aborted Run:
>@ADD EADS. RUN/BIO-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE BIOASSAY TEST TYPE/NAME
>A/AMES
BIOASSAY DATA NOT FOUND FOR: A/AMES
WOULD YOU LIKE TO TRY AGAIN:
>NO
7.4-8
-------�
(4) Invalid Data Format/Data Not Found:
>@ADD EADS. RUN/BIO-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE BIOASSAY TEST TYPE/NAME
>B/CYTOTOXICITY
0 BIOASSAY DATA NOT FOUND FOR: B/CYTOTOXICITY
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE CODE/CHEMICAL ID (FORMULA)
>A/CYTOTOXICITY
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTTR THE DATA BASE TO BE SELECTED
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
BIOASSAY TEST TYPE: CYTOTOXICITY
NO LEDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
7.4.10 Sample Batch Runs
The sample batch run outputs demonstrate the flexibility of the
BIO-SEARCH program in satisfying user needs. The user input cards (which
are listed in the output) are underlined.
(1) Use of Bioassay Test Name:
(PRUN.D/RS Run ID, Account Number. EADS ,10, 20
0ASG.A EADS.
G>XQT,BHZ EADS. BIO-SEARCH
ENTER THE BIOASSAY TEST TYPE/NAME
B/RAM
7.4-9
-------�
ENTER THE DATA BASE TO BE SELECTED
6EDS
ENTER THE DATA BASE TO BE SELECTED
LEDS 00001-001QO
ENTER THE DATA BASE TO BE SELECTED
END
BIOASSAY TEST NAME: RAM
LEDS
00083
00089
00092
00093
00094
00095
00096
NO 6EDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
@FIN
7.4-10
-------�
7.5 RADIOLOGICAL SEARCH PROGRAM (RAD-SEARCH)
7.5.1 Applicability: FPEIS, GEDS, LEDS, SDDS
7.5.2 Abstract
The Radiological Search Program (RAD-SEARCH) enables the user to
search all or part of the EADS waste stream data bases to determine the
presence of a particular radionuclide. The user may identify the
radionuclide by its chemical symbol and isotope (mass) number in the form
XX-NNN. If a search is to be made of part of a data base, the data base
name must be given and the range of TSN's must be specified. Both demand
and batch versions of the program are available to the user. The demand
version provides complete instructions on the use of the program through
an interactive interface with the user. A "Help" command is also
available to users who encounter problems.
For each data base scanned, the TSN is listed for those test series
in which the radionuclide of interest is reported. The program does not
report the concentration of the radionuclide species. The selection
criteria require only that the radionuclide species be found once in a
given test series even though multiple occurrences of the radionuclide may
be present. It is recommended that the user request the SERIES Report for
each test series identified in order to get more information.
7.5.3 User Data Required
• Valid Radionuclide .Chemical Symbol and Isotope Number
• EADS Data Base Name (FPEIS, LEDS, GEDS, and/or SDDS)
• Range of TSN's (optional)
7.5.4 Data Qualification Required
None
7.5-1
-------�
7.5.5 Limitations/Restrictions
None
7.5.6 Functional Description
Using the user-supplied data on a particular radionuclide species,
the RAD-SEARCH program scans all of the data bases specified to search for
the radionuclide. If at least one occurrence of the species is found
within a test series, that test series is listed in the output. If no
data are found in the entire data base, this fact is also listed in the
output.
7.5.7 User Instructions -- Demand File name: EADS.RUN/RAD-SEARCH
The RAD-SEARCH program may be accessed through a "demand", or
time-sharing, terminal (see Section 6.6), which can access the U-1100
computer. User access in demand mode enables the program to be run in
"real time"; that is, the results are. returned directly to the user.
The user shall initiate a demand session by following the
procedures outlined in Section 6.6.1. When the session is completed, the
session may be ended by following the procedures given in Section 6.6.2.
(In the following computer-generated instructions, the response by
the user is underlined.)
>@ADD EADS.RUN/RAD-SEARCH (Enter the file name)
DO YOU NEED INSTRUCTIONS? (Enter YES or NO)
>YES
INSTRUCTIONS WILL BE LISTED SEVERAL LINES AT A TIME AND THEN STOP. TO
CONTINUE DEPRESS CARRIAGE RETURN.
THIS PROGRAM WILL LIST TEST SERIES NUMBERS FROM THE EADS DATA BASE WHICH
HAVE USER SPECIFIED RADIONUCLIDES REPORTED IN THEIR ANALYSIS DATA. THE
USER MUST IDENTIFY THIS RADIONUCLIDE TO THE PROGRAM BY USING THE CHEMICAL
SYMBOL AND ISOTOPE (MASS) NUMBER.
>(CR)
7.5-2
-------�
THE FORMAT USED IS: XX-NNN
WHERE XX = THE CHEMICAL SYMBOL
NNN = THE ISOTOPE (MASS) NUMBER
>(CR)
THE USER HAS THE OPTION OF SPECIFYING WHICH DATA BASE SERIES ARE TO BE
LISTED (FPEIS, GEDS, LEDS, OR SDDS). ADDITIONALLY, THE USER MAY LIMIT THE
LIST TO SPECIFIC RANGES, ONE PER DATA BASE.
TO SPECIFY A RANGE FOR ANY DB, THE USER MUST SELECT A "PARTICULAR" DATA
BASE WHEN QUERIED. "STOP" AND "HELP" MAY BE ENTERED AT ANY TIME. "STOP"
WILL EXIT THE PROGRAM. "HELP" WILL BRIEFLY LIST THE MAJOR QUERY RESPONSE
FORMATS. (IMPORTANT.- ANY QUERY LISTED PRIOR TO A "HELP" REQUEST WILL NOT
BE SHOWN AGAIN AFTER THE HELP RESPONSE FROM THE PROGRAM.)
>(CR)
(If the reply to the above question is NO, the preceding statements
are skipped.)
ENTER THE RADIONUCLIDE ID (Use the format described above)
>RN-220
DO YOU WISH A PARTICULAR DATA BASE? (Enter YES or NO)
>YES
ENTER THE DATA BASE TO BE SELECTED (Enter LEDS, GEDS, SDDS, or FPEIS)
>GEDS
DO YOU WISH TO SELECT WITHIN A (Enter YES or NO)
RANGE OF GEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE (Enter the TSN)
RANGE
ENTER THE MAXIMUM NUMBER IN THE
RANGE
(If no particular data base is named, RAD-SEARCH will scan all
entries in all four data bases. This is a lengthy sort and it is better
to request each data base separately. When the data base is specified,
the user may restrict the search to only a portion of the data base as
shown. If a range is not requested, by the user, the last two queries are
skipped, and the entire data base is scanned.)
7.5-3
-------�
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A PREVIOUS
ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
(If a data base name is entered, the.program will again ask if a
range is requested and the ensuing steps are repeated. If END is entered,
the program starts to execute. Typical output is as follows.)
RADIONUCLIDE: RN-220
GEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
*** NORMAL END ***
>
At this point, the terminal is returned to the Control Mode; that is, the
program has finished and the user may now enter additional commands.
The RAD-SEARCH program is very flexible and this flexibility is
best seen through the sample demand runs given in Section 7.5.9. Use of
the "HELP" option is also shown there.
7.5.8 User Instructions -- Batch
The RAD-SEARCH program may also be executed as a batch job on the
UNIVAC U-1100 using punched card input. It is assumed that the user has
card input access to the U-1100 computer either through "across the
counter" submitted at Research Triangle Park, NC, or through a remote
batch terminal.
In order to run the RAD-SEARCH program in batch mode, the user
should submit the following cards:
7.5-4
-------�
@RUN,R/RS Run ID, Account Number, EADS,5,50/50
(?ASG,A EADS.
@XQT,BHZ EADS.RAD-SEARCH
. . . parameter cards . . .
Three types of parameter cards are defined for RAD-SEARCH and they
are used to drive the program. The Type 1 Parameter Card identifies the
radionuclide to be requested in terms of its chemical symbol and isotope
(mass) number. The Type 2 Parameter Card identifies the data base to be
selected and specifies the range of TSN's to be searched. The Type 3
Parameter Card is the END card which indicates to the program that the
input data have been completed.
The formats for the parameter cards are as follows:
Type 1; Card Col. 12345678
XX-NNN
where all data begin in column 1 of the card and:
XX = the chemical symbol, and
NNN = the isotope (mass) number.
1 2
Type 2: Card Col. 12345678901234567890
DBDBD MINXX-MAXZZ
where DBDBD identifies the data base name beginning in column 1
(choose FPEIS, GEDS, LEDS, or SDDS),
MINXX is the starting TSN in the range of TSN's to be
specified. The TSN should be. entered as a
right-justified integer number in card columns 7-11,
(enter a dash in card column 12)
MAXZZ is the last TSN in the range of TSN's to be
specified. The TSN should be entered as a
right-justified integer number in card
columns 13-17.
7.5-5
-------�
*Note* If no range of TSN's is requested (that is, if the entire
data base is to be searched), leave card columns 7-17 blank.
Also, if one end of the TSN range is entered, the other is
required also. A Type 2 parameter card must be included
for each data base requested. The order of the Type 2
cards is not important.
Type 3: Card Col. 123
END
This card signifies the end of the data. It should be the
last parameter card included in the card deck.
*Caution* The parameter cards must be entered into the card deck
in the following order:
Type 1
All Type 2
Type 3
Sample print-outs from RAD-SEARCH are included in Section 7.2.10.
7.5.9 Sample Demand Runs
(1) Radionuclide with Full Data Base Scan:
>@ADD EADS.RUN/RAD-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE RADIONUCLIDE ID
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DOTOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>FPEIS
DO YOU WISH TO SELECT WITHIN A RANGE OF FPEIS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
7.5-6
-------�
RADIONUCLIDE: 1-131
LEDS
00001
00002
00003
00004
00005
NO FPEIS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
>
(2) Use of HELP Command:
>@ADD EADS.RUN/RAD-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE RADIONUCLIDE ID
>U-238
DOOTJ WISH A PARTICULAR DATA BASE?
>HELP
"STOP" WILL EXIT PROGRAM
XX-NNN FOR RADIONUCLIDE FORMAT WILL SEARCH BY RADIONUCLIDE
"FPEIS", "GEDS", "LEDS" OR "SDDS" WILL SELECT A DATA BASE,
"END" MEANS END OF SOLICITATION FOR A DATA BASE.
>YES
ENTER THE DATA BASE TO BE SELECTED
>FPEIS
DO YOU WISH TO SELECT WITHIN A RANGE OF FPEIS TEST SERIES?
>YES
ENTTR THE MINIMUM NUMBER IN THE RANGE
>l
ENTER THE MAXIMUM NUMBER IN THE RANGE
>!
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>5
ENTER THE MAXIMUM NUMBER IN THE RANGE
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
7.5-7
-------�
>END
RADIONUCLIDE: U-238
LEDS
00005
00006
00007
00008
00009
00010
NO FPEIS SERIES FOUND BETWEEN SERIES 00001 AND 00005
*** NORMAL END ***
>
(3) Example of User Aborted Run:
>@ADD EADS.RUN/RAD-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE RADIONUCLIDE ID (FORMULA)
>KR-85M
DO YOU WISH A PARTICULAR DATA BASE?
>STOP
7.5.10 Sample Batch Runs
The sample batch run outputs demonstrate the flexibility of the
RAD-SEARCH program in satisfying user needs. The user input cards (which
are listed in the output) are underlined.
(1) Multiple Data Base Selection:
(3RUN.D/RS Run ID.Account Number. EADS.10.20
EASG.A EADS.
0XQT.BHZ EADS.RAD-SEARCH
ENTER THE RADIONUCLIDE ID
KR-85
ENTER THE DATA BASE TO BE SELECTED
GEDS
7.5-8
-------�
ENTER THE DATA BASE TO BE SELECTED
LEDS 00001-00100
ENTER THE DATA BASE TO BE SELECTED
END
RADIONUCLIDE: KR-85
LEDS
00083
00089
00092
00093
00094
00095
00096
NO GEDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
@FIN
7.5-9
-------�
7.6 CONTROL TECHNOLOGY SEARCH PROGRAM (CONTROL-SEARCH)
7.6.1 Applicability: FPEIS, GEDS, LEDS, SDDS
7.6.2 Abstract
The Control Technology Search Program (CONTROL-SEARCH) enables the
user to search all or part of the EADS waste stream data bases to
determine the presence of a particular control technology. The user may
identify the control technology by specifying either the generic device
type or the design type as given in Table A-4 of the EADS Terminology
Reference Manual. If a search is to be made of part of a data base, the
data base name must be given and the range of TSN's must be specified.
Both demand and batch versions of the program are available to the user.
The demand version provides complete instructions on the use of the
program through an interactive interface with the user. A "Help" command
is also available to users who encounter problems.
For each data base scanned, the TSN is listed for those test series
in which the control technology of interest is reported. The selection
criteria require only that the control technology generic type or design
type be found once in a given test series. It is recommended that the
user request the SERIES Report for each test series identified in order to
get more information.
7.6.3 User Data Required
t Valid Control Technology Generic Device Type or Design Type
• EADS Data Base Name (FPEIS, LEDS, GEDS, and/or SDDS)
• Range of TSN's (optional)
7.6.4 Data Qualification Required
None
7.6-1
-------�
7.6.5 Limitations/Restrictions
The user is cautioned to use care when selecting the Design Type
option for control technology. Since several generic control system types
have the same or similar design types, it would likely be safer to search
on the basis of the generic type only, or thoroughly check the Terminology
Reference Manual to be certain of the correct Design Type value.
7.6.6 Functional Description
Using the user-supplied data on a particular control technology,
the CONTROL-SEARCH program initially checks to verify that a valid Generic
Device Type or Design Type has been requested. The program next scans all
of the data bases specified. If at least one occurrence of the generic
type or design type is found within a test series, that test series is
listed in the output. If no data are found in the entire data base, this
fact is also listed in the output.
7.6.7 User Instructions — Demand File name: EADS.RUN/CONTROL-SEARCH
The CONTROL-SEARCH program may be accessed through a "demand", or
time-sharing, terminal (see Section 6.6), which can access the U-1100
computer. User access in demand mode enables the program to be run in
"real time"; that is, the results are returned directly to the user.
The user shall initiate a demand session by following the
procedures outlined in Section 6.6.1. When the session is completed, the
session may be ended by the following the procedures given in
Section 6.6.2.
(In the following computer-generated instructions, the response by
the user is underlined.)
>@ADD EADS.RUN/CONTROL-SEARCH (Enter the file name)
DO YOU NEED INSTRUCTIONS? (Enter YES or NO)
>YES
7.6-2
-------�
INSTRUCTIONS WILL BE LISTED SEVERAL LINES AT A.TIME AND THEN STOP. TO
CONTINUE DEPRESS CARRIAGE RETURN.
THIS PROGRAM WILL LIST TEST SERIES NUMBERS FROM THE EADS DATA BASE WHICH
HAVE USER SPECIFIED CONTROL TECHNOLOGY REPORTED IN THEIR ANALYSIS DATA.
THE USER MUST IDENTIFY THIS CONTROL TECHNOLOGY TO THE PROGRAM BY USING THE
GENERIC DEVICE TYPE OR DESIGN TYPE.
>(CR)
THE FORMAT USED IS:
G/GENERICTYPE FOR THE GENERIC TYPE — OR --
D/DESIGNTYPE FOR THE DESIGN TYPE.
>(CR)
THE USER HAS THE OPTION OF SPECIFYING WHICH DATA BASE SERIES ARE TO BE
LISTED (FPEIS, GEDS, LEDS, OR SDDS). ADDITIONALLY, THE USER MAY LIMIT THE
LIST TO SPECIFIC RANGES, ONE PER DATA BASE. TO SPECIFY A RANGE FOR ANY
DB, THE USER MUST SELECT A "PARTICULAR" DATA BASE WHEN QUERIED. "STOP"
AND "HELP" MAY BE ENTERED AT ANY TIME. "STOP" WILL EXIT THE PROGRAM.
"HELP" WILL BRIEFLY LIST THE MAJOR QUERY RESPONSE FORMATS. (IMPORTANT -
ANY QUERY LISTED PRIOR TO A "HELP" REQUEST WILL NOT BE SHOWN AGAIN AFTER
THE HELP RESPONSE FROM THE PROGRAM.)
>(CR)
(If the reply to the above question is NO, the preceding statements
are skipped.)
ENTER THE GENERIC/DESIGN TYPE (Use the format described above)
>6/BIOLOGICAL PROCESSES
DO YOU WISH A PARTICULAR DATA BASE? (Enter YES or NO)
>YES
•
ENTER THE DATA BASE TO BE SELECTED (Enter LEDS, GEDS, SDDS, or FPEIS)
>LEDS
DO YOU WISH TO SELECT WITHIN A (Enter YES or NO)
RANGE OF LEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE (Enter the TSN)
RANGE
ENTER THE MAXIMUM NUMBER IN THE
RANGE
(If no particular data base is named, CONTROL-SEARCH will scan all
entries in all four data bases. This is a lengthy sort and it is better
7.6-3
-------�
to request each data base separately. When the data base is specified,
the user may restrict the search to only a portion of the data base as
shown. If a range is not requested by the user, the last two queries are
skipped, and the entire data base is scanned.)
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A PREVIOUS
ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
(If a data base name is entered, the program will again ask if a
range is requested and the ensuing steps are repeated. If END is entered,
the program starts to execute. Typical output is as follows.)
CONTROL TECHNOLOGY GENERIC TYPE: BIOLOGICAL PROCESSES
LEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
*** NORMAL END ***
>
At this point, the terminal is returned to the Control Mode; that
is, the program has finished and the user may now enter additional
commands.
The CONTROL-SEARCH program is very flexible and has a number of
options available to users. This flexibility is best seen through the
sample demand runs given in Section 7.6.9. Use of the "HELP" option is
also shown there.
7.6-4
-------�
7.6.8 User Instructions -- Batch
The CONTROL-SEARCH program may also be executed as a batch job on
the UNIVAC U-1100 using punched card input. It is assumed that the user
has card input access to the U-1100 computer either through "across the
counter" submitted at Research Triangle Park, NC, or through a remote
batch terminal.
In order to run the CONTROL-SEARCH program in batch mode, the user
should submit the following cards:
@RUN/RS Run ID,Account Number,EADS,5,50/50
@ASG,A EADS.
@XQT,BHZ EADS.CONTROL-SEARCH
. . . parameter cards . . .
@FIN
Three types of parameter cards are defined for CONTROL-SEARCH and
they are used to drive the program. The Type 1 Parameter Card identifies
the control technology to be requested in terms of its generic type or
design type. The Type 2 Parameter Card identifies the data base to be
selected and specifies the range of TSN's to be searched. The Type 3
Parameter Card is the END card which indicates to the program that the
input data have been completed.
The formats for the parameter cards are as follows:
1 2 3
Type 1: Card Col. 123456789012345678901234567890123456
G/AAAAAAAA AA
or D/BBBBBBBBBB BB
where all data begin in column 1 of the card and:
G identifies the Generic Type AAAA....; and
D identifies the Design Type BBBB
1 2
Type 2: Card Col. 12345678901234567890
DBDBD MINXX-MAXZZ
7.6-5
-------�
where DBDBD identifies the data base name beginning in column 1
(choose FPEIS, GEDS, LEDS, or SDDS),
MINXX is the starting TSN in the range of TSN's to be
specified. The TSN should be entered as a
right-justified integer number in card columns 7-11,
(enter a dash in card column 12)
MAXZZ is the last TSN in the range of TSN's to be
specified. The TSN should be entered as a
right-justified integer number in card columns
13-17.
*Note* If no range of TSN's is requested (that is, if the entire
data base is to be searched), leave card columns 7-17 blank.
Also, if one end of the TSN range is entered, the other is
required also. A Type 2 parameter card must be included
for each data base requested. The order of the Type 2
cards is not important.
Type 3: Card Col. 123
END
This card signifies the end of the data. It should be the
last parameter card included in the card deck.
*Caution* The parameter cards must be entered into the card deck
in the following order:
Type 1
All Type 2
Type 3
Sample print-outs from CONTROL-SEARCH are included in Section 7.6.10.
7.6.9 Sample Demand Runs
(1) Device Type Format:
>@ADD EADS.RUN/CONTROL-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE GENERIC/DESIGN TYPE
>D/ACTIVATED SLUGE
CONTROL DATA NOT FOUND FOR: D/ACTIVATED SLUGE
WOULD YOU LIKE TO TRY AGAIN?
>YES
7.6-6
-------�
ENTER THE GENERIC/DESIGN TYPE
>D/ACTIVATED SLUDGE
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>LEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF LEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
CONTROL TECHNOLOGY DESIGN TYPE: ACTIVATED SLUDGE
LEDS
00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
00011
00143
00144
00145
00147
00148
00150
00151
00152
00153
*** NORMAL END ***
(2) Use of HELP Command:
>@ADD EADS.RUN/CONTROL-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE GENERIC/DESIGN TYPE
>G/ESP
DUTOTJ WISH A PARTICULAR DATA BASE?
>HELP
7.6-7
-------�
"STOP" WILL EXIT PROGRAM
"G/AAA...", "D/BBB..."
WILL SEARCH BY GENERIC/DEVICE TYPE,
"FPEIS", "GEDS", "LEDS" OR "SDDS" WILL SELECT A DATA BASE,
"END" MEANS END OF SOLICITATION FOR A DATA BASE.
>YES
ENTER THE DATA BASE TO BE SELECTED
>FPEIS
DO YOU WISH TO SELECT WITHIN A RANGE OF FPEIS TEST SERIES?
>YES
ENTTR THE MINIMUM NUMBER IN THE RANGE
>!
ENTER THE MAXIMUM NUMBER IN THE RANGE
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>GEDS
DO YOU WISH TO SELECT WITHIN A RANGE OF GEDS TEST SERIES?
>YES
ENTER THE MINIMUM NUMBER IN THE RANGE
>5
ENTER THE MAXIMUM NUMBER IN THE RANGE
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
CONTROL TECHNOLOGY GENERIC TYPE: ESP
FPEIS
00005
00006
00007
00008
00009
00010
NO GEDS SERIES FOUND BETWEEN SERIES 00001 AND 00005
*** NORMAL END ***
(3) Example of User Aborted Run:
>@ADD EADS.RUN/CONTROL-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
7.6-8
-------�
ENTER THE GENERIC/DESIGN TYPE
>D/MULTICLONE
CONTROL DATA NOT FOUND FOR: D/MULTICLONE
WOULD YOU LIKE TO TRY AGAIN?
>NO
(4) Invalid Data Format/Data Not Found:
>G>ADD EADS.RUN/CONTROL-SEARCH
DO YOU NEED INSTRUCTIONS?
>NO
ENTER THE GENERIC/DESIGN TYPE
>C/ESP
iNVATn) FORMAT (C/ESP)
CONTROL DATA NOT FOUND FOR: C/ESP
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE GENERIC/DESIGN TYPE
>G/ESPS
CONTROL DATA NOT FOUND FOR: G/ESPS
WOULD YOU LIKE TO TRY AGAIN?
>YES
ENTER THE GENERIC/DESIGN TYPE
>G/ESP
DO YOU WISH A PARTICULAR DATA BASE?
>YES
ENTER THE DATA BASE TO BE SELECTED
>GEDS
DO~YO~U WISH TO SELECT WITHIN A RANGE OF GEDS TEST SERIES?
>NO
ENTER THE ADDITIONAL DATA BASE TO BE SELECTED/CORRECT A
PREVIOUS ENTRY/"END" OR CARRIAGE RETURN IF COMPLETE:
>END
CONTROL TECHNOLOGY GENERIC TYPE: ESP
NO GEDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
7.6-9
-------�
7.6.10 Sample Batch Runs
The sample batch run outputs demonstrate the flexibility of the
CONTROL-SEARCH program in satisfying user needs. The user input cards
(which are listed in the output) are underlined.
(1) Design Type Format:
@RUN.D/RS Run ID.Account Number.EADS.10.20
@AS6.A EAD"ST
0XQT.BHZ EADS.CONTROL-SEARCH
ENTER THE GENERIC/DESIGN TYPE
D/ACTIVATED CARBON
ENTER THE DATA BASE TO BE SELECTED
SODS
ENTER THE DATA BASE TO BE SELECTED
LEDS 00001-00100
ENTER THE DATA BASE TO BE SELECTED
END
LEDS
00083
00089
00092
00093
00094
00095
00096
NO SDDS SERIES FOUND IN ENTIRE DATA BASE
*** NORMAL END ***
0FIN
7.6-10
-------�
APPENDIX A.I
LIST OF ERROR MESSAGES
-------�
TERM-012
CODE DATA BASE
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
TYPE
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
f
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
. F
F
F
F
F
F
F
F
F
F
F
COMPONENT
C110
C120
C125
C270
C130
C140
C145
C150
C230
C235
C240
C250
C260
C300
C340
C350
C155
C160
C170
C330
C361
C410
C430
C440
C450
C460
C470
C475
C505
C505
C585
C610
C810
C820
C830
C840
C860
C1010
C1010
C1010
C1060
C874
C876
C930
C931
C955
C955
C960
C965
EADS PAGE
ERROR LIST DATE 05/
MESSAGE
MISSING SOURCE CATEGORY
MISSING SOURCE TYPE
MISSING PRODUCT/DEVICE TYPE
NON-NUMERIC SIC CODE
MISSING PROCESS RATE
NON-NUMERIC DESIGN PROCESS RATE
MISSING PROCESS RATE UNITS
MISSING FEED MATERIAL CATEGORY
NON-NUMERIC ZIP CODE
NON-NUMERIC FPEIS TSN
NON-NUMERIC SDDS TSN
NON-NUMERIC GEDS TSN
NON-NUMERIC LEDS TSN
NON-NUMERIC NPDES NUMBER
INVALID START DATE
INVALID FINISH DATE
MISSING SPONSOR ORGANIZATION
MISSING CONTRACT NUMBER
NON-NUMERIC TO/TD NUMBER
MISSING NAME OF SAMPLING GROUP
NON-NUMERIC COMMENT LINE NUMBER
NON-NUMERIC STREAM NUMBER
NON-NUMERIC FLOMRATE
NON-NUMERIC VELOCITY
NON-NUMERIC TEMPERATURE
NON-NUMERIC PRESSURE
NON-NUMERIC MOISTURE CONTENT
NON-NUMERIC STACK HEIGHT
NON-NUMERIC/MUST BE 01 , 02 , 03 , 04 , OR 05
DEVICE NUMBER MISSING OFF OF DO CARD
NON-NUMERIC SEQ NO OR GREATER THAN 14
NON-NUMERIC PARAMETER NO.
NON-NUMERIC TEST ID NO
INVALID TEST DATE
NON-NUMERIC START TIME
NON-NUMERIC END TIME
NON-NUMERIC DESIGN CAPACITY
NON-NUMERIC DEVICE/PROCESS NUMBER
NO MATCH WITH DEVICE SET UP ON DO CARD
DEVICE/PROCESS NUMBER MISSING OFF El
NON-NUMERIC/ONLY 30 PARAMETERS PER DEVICE
NON-NUMERIC FEED MATERIAL SAMPLE MASS
NON-NUMERIC FEED MATERIAL SAMPLE VOLUME
INVALID VALUE TYPE NOT T OR N
NON-NUMERIC PARAMETER VALUE
NON-NUMERIC TOTAL MG RECOVERED
NON-NUMERIC TOTAL MG RECOVERED
INVALID ACTUAL SOURCE SYMBOL
NON-NUMERIC ACTUAL CONCENTRATION MANTISSA
-------�
I
ro
TERM-012
CODE DATA BASE
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
TYPE
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
COMPONENT
C967
C1203
C1206
C1212
C1215
C1224
C1227
C1230
C1233
C1236
C1239
C1248
C1218
C1251
C1245
C1243
C1244
C1246
C1257
C1260
C1262
C1264
C1266
C1270
C1276
C1278
C1280
C1282
C1303
C1313
C1316
C1303
C1330
C1429
C1430
C1847
C1850
C1852
C2540
C2540
C2550
C2550
C2590
C2595
C2600
C2605
C3034
EAD5 PAGE
ERROR LIST DATE 05/
MESSAGE
NON-NUMERIC ACTUAL CONCENTRATION EXPONENT
NON-NUMERIC SAMPLE NUMBER
NON-NUMERIC METHOD TYPE
NON-NUMERIC/LESS THAN ZERO SAMPLE START TIME
NON-NUMERIC/LESS THAN ZERO SAMPLE DURATION
NON-NUMERIC SAMPLE VELOCITY
NON-NUMERIC SAMPLE TEMPERATURE
NON-NUMERIC SAMPLE PRESSURE
NON-NUMERIC MOISTURE CONTENT
NON-NUMERIC DENSITY
NON-NUMERIC DENSITY DETERMINATION
NON-NUMERIC VOLUME
NON-NUMERIC FLOWRATE
NON-NUMERIC TOTAL MASS
INVALID CODE NOT 0 OR I
NON-NUMERIC INSTRUMENT TEMPERATURE
NON-NUMERIC INSTRUMENT PRESSURE
NON-NUMERIC INSTRUMENT FLOWRATE
NON-NUMERIC Y. ISOKINETIC
NON-NUMERIC C02
NON-NUMERIC CO
NON-NUMERIC 02
NON-NUMERIC N2
NON-NUMERIC DILUTION FACTOR
NON-NUMERIC PARTICLE DIAMETER BASIS
NON-NUMERIC PARTICLE CONCENTRATION BASIS
NON-NUMERIC UPPER BOUNDARY DIAMETER
NON-NUMERIC CALIBRATION/CALCULATION
NON-NUMERIC COMPONENT SEQ NO.
NON-NUMERIC CONCENTRATION MANTISSA
NON-NUMERIC CONCENTRATION EXPONENT
INVALID COMPONENT SEQUENCE NUMBER MATCH
NON-NUMERIC COMPONENT (ALIQUOT) MASS/VOLUME
NO SPACE IN EFFLUENT CHARACTERISTICS TABLE
INVALID VALUE TYPE NOT T OR N
NON-NUMERIC EFFLUENT CHARACTERISTICS VALUE
INVALID TOTAL MILLIGRAMS SYMBOL
NON-NUMERIC TOTAL MG RECOVERED MANTISSA
NON-NUMERIC TOTAL MG RECOVERED EXPONENT
NON-NUMERIC TCO
NON-NUMERIC TCO
NON-NUMERIC GRAV.
NON-NUMERIC GRAV.
TCO COUNT GREATER THAN 7 FORM 9
NON-NUMERIC INTENSITY
INVALID ACTUAL SOURCE SYMBOL
NON-NUMERIC ACTUAL SOURCE CONCENTRATION MANTISSA
NON-NUMERIC ACTUAL SOURCE CONCENTRATION EXPONENT
INVALID ACTUAL CONCENTRATION SYMBOL
-------�
I
oo
TERM-012
CODE DATA BASE
106
107
106
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
ALL
TYPE
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
COMPONENT
C3035
C3040
C3215
C3220
C3230
C3235
C3240
C3285
C3286
C3295
C3296
C3305
C3306
C3325
C3326
C3365
C926
C946
C945
C3851
C3851
C950
C1425
C1425
C3830
C5835
C3851
C3851
C3840
C2582
C2585
C2585
C3030
C3210
C3205
C3300
C3301
EADS PAGE
ERROR LIST DATE 05/
MESSAGE
NON-NUMERIC ACTUAL SOURCE CONCENTRATION MANTISSA
NON-NUMERIC ACTUAL SOURCE CONCENTRATION EXPONENT
NON-NUMERIC TEST DURATION
NON-NUMERIC SAMPLE NUMBER
INVALID TEST START DATE
INVALID TEST FINISH DATE
NON-NUMERIC SAMPLE QUANTITY
NON-NUMERIC VALUE MANTISSA
NON-NUMERIC VALUE EXPONENT
NON-NUMERIC HIGH CONFIDENCE VALUE MANTISSA
NON-NUMERIC HIGH CONFIDENCE VALUE EXPONENT
NON-NUMERIC MAXIUM APPLICABLE DOSE MANTISSA
NON-NUMERIC MAXIUM APPLICABLE DOSE EXPONENT
NON-NUMERIC MINIMUN EFFECTIVE CONCENTRATION MANTISSA
NON-NUMERIC MINIMUN EFFECTIVE CONCENTRATION EXPONENT
NON-NUMERIC LINE NO.
INVALID SOURCE CATEGORY TABLE MATCH
INVALID FEED MATERIAL CATEGORY TABLE MATCH
INVALID CONTROL SYSTEM TABLE MATCH
INVALID DEVICE/PROCESS CLASS TABLE MATCH
INVALID DEVICE/PROCESS KEYWORD TABLE MATCH
INVALID ANALYTICAL CODE TABLE MATCH
INVALID CHEMICAL ID TYPECNOT S,C,M)
INVALID CHEMICAL CATEGORY/SPECIES
INVALID RETURN CODE (CALL PROGRAMMER)
INVALID RETURN CODE (CALL PROGRAMMER)
INVALID ANALYTICAL CODE TABLE MATCH
INVALID ANALYTICAL CODE
INVALID ANALYTICAL CODE TABLE MATCH
INVALID CHEMICAL ID TYPE(NOT S.C,M)
INVALID CHEMICAL CATEGORY/SPECIES
INVALID RETURN CODE (CALL PROGRAMMER)
INVALID RETURN CODE (CALL PROGRAMMER)
INVALID ANALYTICAL CODE TABLE MATCH
INVALID CHEMICAL ID TYPE(NOT S.C.M)
INVALID CHEMICAL CATEGORY/SPECIES
INVALID ANALYTICAL CODE TABLE MATCH
INVALID ANALYTICAL CODE TABLE MATCH
INVALID BIO-TEST NAME TABLE MATCH
INVALID BIO-TEST TYPE TABLE MATCH
NON-NUMERIC TEST SERIES NUMBER
INVALID DATA BASE TYPE (NOT F,G,L,S)
MISSING CARD ID
INVALID CARD NUMBER
NON-NUMERIC LOW CONFIDENCE LIMIT MANTISSA
NON-NUMERIC LOW CONFIDENCE LIMIT EXPONENT
SERIES NUMBER INVALID OR MISSING AO CARD
DATA BASE TYPE IS INVALID
TEST SERIES NUMBER NOT IN STATUS FILE
-------�
3>
•
I
TERM-012
CODE DATA BASE
155
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TERM-012 EADS PAGE 5
ERROR LIST DATE 05/12/80
CODE DATA BASE TYPE COMPONENT MESSAGE
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210
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LEDS
LEDS
LEDS
LEDS
LEDS
LEDS
F
F
F
F
F
F
C370
C372
C374
C378
C382
C384
NON-NUMERIC
NON-NUMERIC
NON-NUMERIC
NON-NUMERIC
NON-NUMERIC
NON-NUMERIC
SITE LATITUDE
SITE LONGITUDE
FRACTION DESIGN RATE OF INDUSTRIAL ORIGIN
CONTRIBUTING INDUSTRIAL CATEGORY NO
CATEGORY FLOW CONTRIBUTION
NUMBER OF ESTAB.
I
CJ1
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APPENDIX A.2
DATA BASE DEFINITION
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C»40 CNOHUL
MWltSIt
CMO MOlllMTf
MM.TSIS
cm ULTIMATE
MM.TSIS
c«?o
CMARACKRISTICS
C1050 WE DAI IK
MBAMHRS
C1NO COMWIITS
CI4IO CrriUCNT
UMMCTemsucs
C18?0 IHOSGMIC
MMTSIS
C3IOO IIMSVIT
MH
CJO?0 RAD10-
•JCLIOC SPECKS
C37M 110-
NISMS
CJMO 110-
COMIENTS
Figure A.2-1. EADS data base tree.
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SYSTEM RELEASE NUMBER 2. SOD
DATA BASE NAME IS EADS-EADS
DEFINITION NUMBER 6
DATA BASE CYCLE 273
10* EADS (NAME XXXX)
50* TEST SERIES (RG)
101* FPEIS TEST SERIES NUMBER (INTEGER NUMBER 9(5) IN 50)
GEDS TEST SERIES NUMBER (INTEGER NUMBER 9(5) IN 50)
LEDS TEST SERIES NUMBER (INTEGER NUMBER 9(5) IN 50)
SDDS TEST SERIES NUMBER (INTEGER NUMBER 9(5) IN 50)
SOURCE CATEGORY (NAME X(20) IN 50)
SOURCE TYPE (NAME X(20) IN 50)
PRODUCT/DEVICE (NAME X(20) IN 50)
PROCESS TYPE (NAME X(20) IN 50)
DESIGN PROCESS RATE (INTEGER NUMBER 9(6) IN 50)
DESIGN PROCESS RATE UNITS (NAME X(6) IN 50)
FEED MATERIAL CATEGORY (NAME X(10) IN 50)
SPONSOR ORGANIZATION (NAME X(30) IN 50)
SPONSOR ORGANIZATION CONTRACT NUMBER (NAME X(10) IN 50)
T.O./TD NUMBER (INTEGER NUMBER 999 IN 50)
SOURCE NAME (NAME X(23) IN 50)
SITE NAME (NAME X(25) IN 50)
ADDRESS (NON-KEY NAME X(20) IN 50)
CITY (NAME X(18) IN 50)
STATE (NAME XX IN 50)
ZIP CODE (INTEGER NUMBER 9(5) IN 50)
COUNTRY (NAME X(5) IN 50)
FPEIS TSN CROSS REFERENCE (INTEGER NUMBER 9(5) IN 50)
SDDS TSN CROSS REFERENCE (INTEGER NUMBER 9(5) IN 50)
GEDS TSN CROSS REFERENCE (INTEGER NUMBER 9(5) IN 50)
LEDS TSN CROSS REFERENCE (INTEGER NUMBER 9(5) IN 50)
SIC CODE (INTEGER NUMBER 9999 IN 50)
NPDES NUMBER (NAME X(9) IN 50)
102*
103*
104*
110*
120*
125*
130*
140*
145*
150*
155*
160*
170*
180*
190*
200*
210*
220*
230*
232*
235*
240*
250*
260*
270*
300*
320*
321*
322*
323*
324*
325*
330*
340*
350*
355*
370*
372*
374*
TITLE-1 (NON-KEY
TITLE-2 (NON-KEY
AUTHOR (NON-KEY
NUMBER (NON-KEY
NAME X(65) IN 50)
NAME X(65) IN 50)
NAME X(30) IN 50)
NAME X(20) IN 50)
NTIS NUMBER (NON-KEY NAME
PUBLICATION DATE (NON-KEY
X(20) IN 50)
NAME X(15) IN
REFERENCE REPORT
REFERENCE REPORT
REFERENCE REPORT
REFERENCE REPORT
REFERENCE REPORT
REFERENCE REPORT
50)
NAME OF SAMPLING GROUP (NAME X(22) IN 50)
SERIES START DATE (NON-KEY DATE IN 50)
SERIES FINISH DATE (NON-KEY DATE IN 50)
DATE OF ENTRY (DATE IN 50)
SITE LATITUDE (DECIMAL NUMBER 99.99 IN 50)
SITE LONGITUDE (DECIMAL NUMBER 999.99 IN 50)
FRACTION DESIGN RATE IND ORIGIN (DECIMAL NUMBER 9.9999 IN 50
105* TEST SERIES KEY (NAME X(6) IN 50)
106* DB KEY (NAME X IN 50)
360* TEST SERIES COMMENTS ( RG IN 50)
361* TSC-LINE NUMBER (NON-KEY INTEGER NUMBER 99 IN 360)
362* TEST SERIES COMMENT (NON-KEY TEXT X(63) IN 360)
376* CONTRIBUTING INDUSTRIES (RG IN 50)
378* CONTRIBUTING INDUSTRIAL CATEGORY NUMBER (INTEGER NUMBER 9(
5) IN 376)
-------�
380* INDUSTRY-COMMERICAL SIC NUMBER (INTEGER NUMBER 9999 IN 376
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co
382* CATEGORY FLOW CONTRIBUTION (DECIMAL NUMBER 9.999 IN 376)
384* NUMBER OF ESTABLISHMENTS (INTEGER NUMBER 9999 IN 376)
400* STREAM (RG IN 50)
410* STREAM NUMBER (INTEGER NUMBER 99 IN 400)
420* STREAM NAME (NAME X(34) IN 400)
430* MASS/VOLUMETRIC FLOH RATE (NON-KEY DECIMAL NUMBER 9(5). 9
IN 400)
432* FLOW RATE UNITS (NON-KEY NAME X(6) IN 400)
440* VELOCITY-SAMPLING LOCATION (NON-KEY DECIMAL NUMBER 999.9
IN 400)
450* TEMPERATURE-SAMPLING LOCATION (NON-KEY INTEGER NUMBER 999
9 IN 400)
460* PRESSURE-SAMPLING LOCATION (NON-KEY DECIMAL NUMBER 99.9 I
N 400)
470* MOISTURE CONTENT (NON-KEY DECIMAL NUMBER 99.9 IN 400)
475* STACK HEIGHT (DECIMAL NUMBER 9999.9 IN 400)
480* STREAM-COMMENTS 1 (NON-KEY TEXT X(65) IN 400)
481* STREAM COMMENTS 2 (NON-KEY TEXT X(65) IN 400)
500* CONTROL DEVICE/TREATMENT/STORAGE/RECOVERY PROCESS (RG IN 4
00)
505* DEVICE/PROCESS NO (INTEGER NUMBER 99 IN 500)
510* GENERIC DEVICE/PROCESS TYPE (NAME X(20) IN 500)
515* DESIGN TYPE (NAME X(33) IN 500)
520* SPECIFIC PROCESS/DEVICE TYPE (NAME X(20) IN 500)
530* DEVICE/PROCESS CLASS (NAME X(12) IN 500)
540* DEVICE/PROCESS COMMERCIAL NAME (NAME X(30) IN 500)
550* MANUFACTURER (NAME X(30) IN 500)
580* DEVICE/PROCESS CATEGORY (RG IN 500)
585* DEVICE/PROCESS CATEGORY SEQ NUMBER (INTEGER NUMBER 99
IN 580)
590* DEVICE/PROCESS CATEGORY KEYWORD (NAME X(30) IN 580)
600* DESIGN PARAMETER ( RG IN 500)
610* DES-PARAMETER NUMBER (INTEGER NUMBER 99 IN *00)
620* DES-PARAMETER NAMF (NON-KEY NAME X(30) IN 600)
621* DES-PARAMETER TYPE (NON-KEY NAME X IN 600)
622* DES-PARAMETER VALUE MAN (NON-KEY
IN 600)
623* DES-PARAMETER VALUE EXP (NON-KEY
600)
624* DES-PARAMETER VALUE UNITS (NON-KEY
DECIMAL NUMBER 99.99
INTEGER NUMBER 99 IN
NAME X(24) IN 600)
630* DES-PARAMETER TEXT VALUE (NON-KEY NAME X(24) IN 600)
800* SOURCE/PROCESS CONDITIONS DATA (RG IN 400)
810* TEST-ID-NUMBER (INTEGER NUMBER 999 IN 800)
820* TEST-DATE (NON-KEY DATE IN 800)
830* TEST-START TIME (NON-KEY INTEGER NUMBER 9999 IN 800)
840* TEST-STOP TIME (NON-KEY INTEGER NUMBER 9999 IN 800)
850* OPERATING MODE (NON-KEY TEXT X(31) IN 800)
860* PERCENT OF DESIGN CAPACITY (NON-KEY
9 IN 800)
861* TEST-COMMENT-1 (NON-KEY TEXT X(65)
862* TEST-COMMENT-2 (NON-KEY TEXT X(65)
863* TEST-COMMENT-3 (NON-KEY TEXT X(65)
865* FUELS-N-FEEDSTOCKS (RG IN 800)
869* FF-SEQUENCE NUMBER (INTEGER NUMBER 9 IN 865)
DECIMA1 NUMBER 999.
IN 800)
IN 800)
IN 800)
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870* FF-SOURCE FEED MATERIAL (TEXT X(30) IN 865)
873* FF-FEED MATERIAL RATE (NON-KEY TEXT X(17) IN 865)
874* FF-SAMPLE MASS (NON-KEY DECIMAL NUMBER 999.99 IN 865)
875* FF-SAMPLE MASS UNITS (NON-KEY TEXT X(6) IN 865)
876* FF-SAMPLE VOLUME (NON-KEY DECIMAL NUMBER 999.99 IN 86
5)
877* FF-LABORATORY NAME (NAME X(40) IN 865)
878* FF-QA-QC CODE (NAME XXX IN 865)
879* FF-SAMPLE VOLUME UNITS (NON-KEY TEXT X(7) IN 865)
970* FF-COMMENT 1 (NON-KEY TEXT X(65) IN 865)
971* FF-COMMENT 2 (NON-KEY TEXT X(65) IN 865)
972* FF-COMMENT 3 (NON-KEY TEXT X(65) IN 865)
880* FF-PROXIMATE ANALYSIS (RG IN 865)
885* FF-PA-PARAMETER (NAME X(I6) IN 880)
890* FF-PA-PARAMETER VALUE (NON-KEY DECIMAL NUMBER 9(7).
99 IN 880)
895* FF-PA-PARAMETER-UNITS (NON-KEY NAME X(5) IN 880)
900* FF-ULTIMATE ANALYSIS (RG IN 865)
905* FF-UA-PARAMETER (NAME X(10) IN 900)
910* FF-UA-PARAMETER VALUE (NON-KEY DECIMAL NUMBER 999.9
9 IN 900)
920* FF-CHARACTERISTICS (RG IN 865)
923* FF-PARAMETER (NAME X(12) IN 920)
924* FF-DETECTION LIMIT-HIGH MAN (NON-KEY DECIMAL NUMBER
99.99 IN 920)
925* FF-DETECTION LIMIT-HIGH EXP (NON-KEY INTEGER NUMBER
99 IN 920)
926* FF-ANALYSIS METHOD (NAME XX IN 920)
927* FF-DETECTION LIMIT - LOW MAN (NON-KEY DECIMAL NUMBE
R 99.99 IN 920)
928* FF-DETECTION LIMIT - LOW EXP (NON-KEY INTEGER NUMBE
R 99 IN 920)
929* FF-DETECTION LIMIT - UNITS (NON-KEY NAME X(7) IN 92
0)
930* FF-VALUE TYPE (NON-KEY NAME X IN 920)
931* FF-PARAMETER VALUE MAN (NON-KEY DECIMAL NUMBER 99.9
9 IN 920)
932* FF-VALUE UNITS (NON-KEY NAME X(18) IN 920)
933* FF-TEXT VALUE (NON-KEY NAME X(18) IN 920)
934* FF-PARAMETER VALUE EXP (NON-KEY INTEGER NUMBER 99 I
N 920)
935* FF-PARAMETER VALUE HIGH-LOW (NON-KEY NAME X IN 920)
940* FF-CHEMICAL ANALYSIS (RG IN 865)
945* FF-C-CATEGORY/SPECIES (NAME X(10) IN 940)
946* FF-C-CS-TYPE (NAME X IN 940)
947* FF-C-CS-PRIORITY (NAME X IN 940)
948* FF-C-DETECTION LIMIT-HIGH MAN (NON-KEY DECIMAL NUMB
ER 99.99 IN 940)
949* FF-C-DETECTION LIMIT-HIGH EXP (NON-KEY INTEGER NUMB
ER 99 IN 940)
950* FF-C-ANALYSIS METHOD (NAME XX IN 940)
951* FF-C-DETECTION LIMIT LOW-EXP (NON-KEY INTEGER NUMBE
R 99 IN 940)
952* FF-C-DETECTION LIMIT UNIT (NON-KEY NAME X(8) IN 940
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953* FF-C-DETECTION LIMIT LOW-MAN (NON-KEY DECIMAL NUMBE
R 99.99 IN 940)
955* FF-C-TOTAL MG RECOVERED (NON-KEY DECIMAL NUMBER 9(5
j.999 IN 940)
964* FF-C-CONCENTRATION-HIGH-LOW (NON-KEY NAME X IN 940)
965* FF-C-CATEGORY/SPECIES CONCENTRATION MAN (NON-KEY DE
CIMAL NUMBER 9.99 IN 940)
967* FF-C-CATEGORY/SPECIES CONCENTRATION EXP (NON-KEY IN
TEGER NUMBER 99 IN 940)
969* FF-C-CONCENTRATION UNITS (NON-KEY NAME X(ll) IN 940
)
1000* CONTROL DEVICE/TREATMENT PROCESS OPERATING PARAMETERS (R
G IN 800)
1010* OP-DEVICE NUMBER (INTEGER NUMBER 99 IN 1000)
1050* OPERATING PARAMETERS (RG IN 1000)
1060* OPERATING PARAMETER NUMBER (INTEGER NUMBER 99 IN 105
0)
1064* OPERATING PARAMETER HIGH-LOW (NON-KEY NAME X IN 105
0)
1065* OPERATING PARAMETER NAME (NON-KEY NAME X(30) IN 105
0)
1066* OPERATING PARAMETER TYPE (NON-KEY NAME
1067* OPERATING PARAMETER VALUE MAN (NON-KEY
ER 9.99 IN 1050)
1065* OPERATING PARAMETER VALUE EXP (NON-KEY
ER 99 IN 1050)
1069* OPERATING PARAMETER VALUE UNITS (NON-KEY
IN 1050)
1070* OPERATING PARAMETER TEXT VALUE (NON-KEY
IN 1050)
1100* RECEPTOR OPERATING DATA (RG IN 800)
1200* SAMPLE GROUP (RG IN 800)
1203* SMPL-NUMBER (INTEGER NUMBER 99 IN 1200)
1206* MEASUREMENT INST/METHOD TYPE (NAME X IN 1200)
1209* MEASUREMENT INST/MTTHOD NAME (NAME X(30) IN 1200)
1212* SMPL-START TIME (NON-KEY INTEGER NUMBER 9999 IN 1200)
X IN 1050)
DECIMAL NUMB
INTEGER NUMB
NAME X(24)
NAME X(24)
1215* SMPL-DURATION (NON-KEY INTEGER NUMBER 999 IN 1200)
1218* SMPL-MASS/VOLUMETRIC FLOWRATE (NON-KEY DECIMAL NUMBER
9(5).9 IN 1200)
1219* SMPL-FLOWRATE UNITS (NON-KEY NAME X(6) IN 1200)
1221* SMPL-FLOWRATE MEASUREMENT METHOD (NAME X(20) IN 1200)
1224* SMPL-VELOCITY (NON-KEY DECIMAL NUMBER 999.9 IN 1200)
1227* SMPL-TEMPERATURE (NON-KEY INTEGER NUMBER 9999 IN 1200
)
1230* SMPL-PRESSURE (NON-KEY INTEGER NUMBER 999 IN 1200)
1233* SMPL-MOISTURE CONTENT (NON-KEY DECIMAL NUMBER 99.9 IN
1200)
1236* SMPL-DENSITY (NON-KEY DECIMAL NUMBER 99.9 IN 1200)
1239* SMPL-DENSITY DETERMINATION (NON-KEY INTEGER NUMBER 9
IN 1200)
1242* SAMPLING LOCATION DESCRIPTION (NON-KEY NAME X(30) IN
1200)
1243* INSTRUMENT TEMPERATURE (NON-KEY INTEGER NUMBER 9999 I
N 1200)
1244* INSTRUMENT PRESSURE (NON-KEY INTEGER NUMBER 999 IN 12
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1245*
1246*
1247*
1248*
1251*
1254*
1257*
1260*
1262*
1264*
1266*
1268*
1270*
1274*
1276*
1278*
1280*
1282*
1290*
1291*
1292*
1293*
1300*
1303*
1305*
1310*
1312*
1313*
1316*
1320*
1321*
1324*
1325*
1330*
1335*
1349*
1350*
1351*
1352*
1353*
00)
SAMPLING LOCATION CODE (NAME X IN 1200)
INSTRUMENT FLOWRATE (NON-KEY DECIMAL NUMBER 9999.9 IN
1200)
SAMPLING LOCATION DEVICE NUMBER (INTEGER NUMBER 99 IN
1200)
VOLUME OF SAMPLE (NON-KEY DECIMAL NUMBER 999.99 IN 12
00)
TOTAL MASS (NON-KEY DECIMAL NUMBER 999.99 IN 1200)
MASS UNITS (NON-KEY NAME XX IN 1200)
PERCENT ISOKINETIC SAMPLING (NON-KEY INTEGER NUMBER 9
99 IN 1200)
CO-2 (NON-KEY DECIMAL NUMBER 99.99 IN 1200)
CO (NON-KEY DECIMAL NUMBER 99.99 IN 1200)
0-2 (NON-KEY DECIMAL NUMBER 99.99 IN 1200)
N-2 (NON-KEY DECIMAL NUMBER 99.99 IN 1200)
TRACE GASES IN PPM (NON-KEY TEXT X(65) IN 1200)
DILUTION FACTOR (NON-KEY DECIMAL NUMBER 9999.9 IN 120
0)
COLLECTION SURFACE/SUBSTRATE (NON-KEY TEXT X(55) IN 1
200)
PARTICLE DIAMETER BASIS (INTEGER NUMBER 9 IN 1200)
PARTICLE CONCENTRATION BASIS (INTEGER NUMBER 9 IN 1200
UPPER BOUNDARY DIAMETER (NON-KEY
9 IN 1200)
CALIBRATION/CALCULATION (NON-KEY
1200)
SMPL-COMMENTS 1
SMPL-COMMENTS 2
DECIMAL NUMBER 999.9
INTEGER NUMBER 9 IN
SMPL-COMMENTS
TEXT X(65) IN 1200)
TEXT X(65) IN 1200)
TEXT X(65) IN 1200)
TEXT X(65) IN 1200)
(NON-KEY
(NON-KEY
3 (NON-KEY
SMPL-COMMENTS 4 (NON-KEY
COMPONENT (RG IN 1200)
COMPONENT SEQUENCE NO (INTEGER NUMBER 99 IN 1300)
SAMPLING EQUIPMENT COMPONENT NAME (NAME X(12) IN 130
0)
STAGE/FILTER CUT SIZE (DECIMAL NUMBER 99.99 IN 1300)
MASS HIGH-LOW (NON-KEY NAME X IN 1300)
MASS MAN (NON-KEY DECIMAL NUMBER 9.99 IN 1300)
MASS EXP (NON-KEY INTEGER NUMBER 99 IN 1300)
CHEMICAL ANALYSIS LAB NAME (NAME X(39) IN 1300)
CHEMICAL QA-QC CODE (NAME XXX IN 1300)
RADIONUCLIDE ANALYSIS LAB NAME (NAME X(40) IN 1300)
RAD-QA-QC CODE (NAME XXX IN 1300)
COMPONENT ALIQUOT MASS-VOL (NON-KEY DECIMAL NUMBER
9999.999 IN 1300)
COMPONENT ALIQUOT UNITS (NON-KEY NAME X(5) IN 1300)
UG CONCENTRATION HIGH-LOW (NON-KEY NAME X IN 1300)
UG-DNCM-STAGE-MAN (NON-KEY DECIMAL NUMBER 9.99 IN 1
300)
UG-DNCM-STAGE-EXP (NON-KEY INTEGER NUMBER 99 IN 130
0)
CUM-PCT-LESS THAN D50 (NON-KEY DECIMAL NUMBER 999.9
9 IN 1300)
CUM-UG-ACM LESS THAN D50 MAN (NON-KEY DECIMAL NUMBE
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1354*
1355*
1356*
1357*
1358*
1359*
1360*
1361*
1362*
1363*
1364*
1365*
INTEGER NUMBE
DECIMAL NUMB
INTEGER NUMB
R 9.99 IN 1300)
CUM-UG-ACM LESS THAN D50 EXP (NON-KEY
R 99 IN 1300)
CUM-UG-DNCM LESS THAN D50 MAN (NON-KEY
ER 9.99 IN 1300)
CUM-UG-DNCM LESS THAN D50 EXP (NON-KEY
ER 99 IN 1300)
GEOMETRIC MEAN DIAM-MAN (NON-KEY DECIMAL NUMBER 9.9
9 IN 1300)
GEOMETRIC MEAN DIAM-EXP (NON-KEY INTEGER NUMBER 99
IN 1300)
DECIMAL NUMBER 9.99 IN 1300)
INTEGER NUMBER 99 IN 1300)
DECIMAL NUMBER 9.99 IN 1300)
INTEGER NUMBER 99 IN 1300)
DECIMAL NUMBER 9.99 IN 1
INTEGER NUMBER 99 IN 130
DM-DLOG-MAN (NON-KEY
DM-DLOG-EXP (NON-KEY
DN-DLOG-MAN (NON-KEY
DN-DLOG-EXP (NON-KEY
NO-DNCM-STAGE MAN (NON-KEY
300)
NO-DNCM-STAGE EXP (NON-KEY
0)
NO-DNCM-HIGH-LOW (NON-KEY NAME X IN 1300)
EC-COMMENT 1 (NON-KEY TEXT X(63) IN 1300)
1450* EC-COMMENT 2 (NON-KEY TEXT X(63) IN 1300)
1860* IA-COMMENT-1 (NON-KEY TEXT X(63) IN 1300)
1870* IA-COMMENT-2 (NON-KEY TEXT X(63) IN 1300)
2610* L10A-COMMENT-1 (NON-KEY TEXT X(63) IN 1300)
2620* L10A-COMMENT-2 (NON-KEY TEXT X(63) IN 1300)
3050* RN-COMMENT 1 (NON-KEY TEXT X(63) IN 1300)
3051* RN-COMMENT 2 (NON-KEY TEXT X(63) IN 1300)
1410* EFFLUENT CHARACTERISTICS (RG IN 1300)
1420* EC-PARAMETER (NAME X(12) IN 1410)
1423* EC-DETECTION LIMIT-HIGH-MAN (NON-KEY
ER 99.99 IN 1410)
1424* EC-DETECTION LIMIT-HIGH-EXP (NON-KEY
ER 99 IN 1410)
1425* EC-ANALYSIS METHOD (NAME XX IN 1410)
1426* EC-DETECTION LIMIT -LOW MAN (NON-KEY
ER 9.99 IN 1410)
1427* EC-DETECTION LIMIT -LOW EXP (NON-KEY
ER 99 IN 1410)
1428* EC-DETECTION LIMIT - UNITS (NON-KEY
1410)
1429* EC-VALUE TYPE (NON-KEY NAME X IN 1410)
1430* EC-VALUE (NON-KEY DECIMAL NUMBER 9999.9 IN 1410)
1431* EC-VALUE UNITS (NON-KEY NAME X(8) IN 1410)
1432* EC-TEXT VALUE (NON-KEY NAME X(13) IN 1410)
1820* INORGANIC ANALYSIS/NON-LEVEL 1 ORGANIC SPECIES (RG I
N 1300)
1830* IA-SPECIES-ID-TYPE (NAME X IN 1820)
1835* IA-SPECIES-ID (NAME X(10) IN 1820)
1840* IA-ANALYSIS-METHOD (NAME XX IN 1820)
1841* IA-DETECTION LIMIT-HIGH-MAN (NON-KEY
ER 99.99 IN 1820)
1842* IA-DETECTION LIMIT-HIGH-EXP (NON-KEY
ER 99 IN 1820)
1843* IA-DETECTION LIMIT-LOW-MAN (NON-KEY
R 99.99 IN 1820)
1844* IA-DETECTION LIMIT-LOW-EXP (NON-KEY
DECIMAL NUMB
INTEGER NUMB
DECIMAL NUMB
INTEGER NUMB
NAME X(9) IN
DECIMAL NUMB
INTEGER NUMB
DECIMAL NUMBE
INTEGER NUMBE
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R 99 IN 1820)
1845* IA-DETECTION UNIT (NON-KEY NAME X(8) IN 1820)
1850* IA-CONCENTRATION MAN (NON-KEY DECIMAL NUMBER 9.99
IN 1820)
1852* IA-CONCENTRATION EXP (NON-KEY INTEGER NUMBER 99 I
N 1820)
1846* IA-TOTAL MG RECOVERED (NON-KEY DECIMAL NUMBER 9(5
).999 IN 1820)
1847* IA-HIGH-LOW (NON-KEY NAME X IN 1820)
1836* IA-SPECIES-PRIORITY (NAME X IN 1820)
2520* LEVEL 1 ORGANIC ANALYSIS (RG IN 1300)
2530* L10A-FRACTION-ID (NAME XXX IN 2520)
2540* L10A-FRACTION-TCO (NON-KEY DECIMAL NUMBER 9999.99
IN 2520)
2550* L10A-FRACTION-GRAV (NON-KEY DECIMAL NUMBER 9999.9
9 IN 2520)
2560* L10A-FRACTION-TOTAL (NON-KEY DECIMAL NUMBER 9999.
99 IN 2520)
2570* L10A-FRACTION-EXTENDED-DATA (RG IN 2520)
2580* L10AFED-CATEGORY/SPECIES TYPE (NAME X IN 2570)
2582* L10AFED-CATEGORY/SPECIES (NAME X(10) IN 2570)
2583* L10AFED-CATEGORY/SPECIES-PRIORITY (NAME X IN 257
0)
2585* L10AFED-ANALYSIS METHOD (NAME XX IN 2570)
2586* L10AFED-DETECTION LIMIT-HIGH MAN (NON-KEY
AL NUMBER 99.99 IN 2570)
2587* L10AFED-DETECTION LIMIT - HIGH EXP (NON-KEY
EGER NUMBER 99 IN 2570)
2588* L10AFED-DETECTION LIMIT - UNITS (NON-KEY
(8) IN 2570)
2590* L10AFED-INTENSITY (NON-KEY
N 2570)
2595* L10AFED-HIGH-LOW (NON-KEY NAME X IN 2570)
2600* L10AFED-CONCENTRATION MAN (NON-KEY DECIMAL NUMB
ER 9.99 IN 2570)
2605* L10AFED-CONCENTRATION EXP (NON-KEY INTEGER NUMB
ER 99 IN 2570)
2608* L10AFED-DETECTION LIMIT-LOW-MAN (NON-KEY DECIMA
L NUMBER 99.99 IN 2570)
2609* L10AFED-DETECTION LIMIT-LOW EXP (NON-KEY INTEGE
R NUMBER 99 IN 2570)
3020* RADIONUCLIDE-SPECIES CONCENTRATION (RG IN 1300)
3025* RN-RADIONUCLIDE ID (NAME X(8) IN 3020)
3028* RN-DETECTION LIMIT-HIGH MAN (NON-KEY DECIMAL NUMB
ER 99.99 IN 3020)
3029* RN-DETECTION LIMIT-HIGH EXP (NON-KEY
ER 99 IN 3020)
3030* RN-ANALYSIS METHOD (NAME XX IN 3020)
3031* RN-DETECTION LIMIT-LOW-MAN (NON-KEY
R 99.99 IN 3020)
3032* RN-DETECTION LIMIT -LOW EXP (NON-KEY
ER 99 IN 3020)
3033* RN-DETECTION LIMIT - UNITS (NON-KEY
3020)
3034* RN-CONCENTRATION HIGH-LOW (NON-KEY
DECIM
INT
NAME X
INTEGER NUMBER 999 I
INTEGER NUMB
DECIMAL NUMBE
INTEGER NUMB
NAME X(8) IN
NAME X IN 3020
3035* RN-CONCENTRATION MAN (NON-KEY DECIMAL NUMBER 9.99
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i
IN 3030)
3040* RN-CONCENTRATION EXP (NON-KEY INTEGER NUMBER 99 I
N 3020)
3200* BIOASSAY DATA (RG IN 1200)
3205* BIO-TEST TYPE (NAME X(25) IN 3200)
3210* BIO-TEST NAME (NAME X(30) IN 3200)
3215* BIO-TEST DURATION (NON-KEY INTEGER NUMBER 9(6) IN 3
200)
3220* BIO-SAMPLE ID (NON-KEY NAME XXXX IN 3200)
3225* BIO-TEST LAB NAME (NAME X(41) IN 3200)
3226* BIO-TEST QA-QC (NAME XXX IN 3200)
3230* BIO-TEST START (NON-KEY DATE IN 3200)
3235* BIO-TEST END (NON-KEY DATE IN 3200)
3240* BIO-TEST SAMPLE QUANTITY (NON-KEY INTEGER NUMBER 9(
8) IN 3200)
3245* BIO-TEST SAMPLE UNITS (NON-KEY NAME X(6) IN 3200)
3280* BIO-VALUE TYPE (NAME XXXX IN 3200)
3285* BIO-VALUE-MAN (NON-KEY DECIMAL NUMBER 9.99 IN 3200)
3286* BIO-VALUE-EXP (NON-KEY INTEGER NUMBER 99 IN 3200)
3290* BIO-VALUE UNITS (NON-KEY NAME X(8) IN 3200)
3295* BIO-HI-CONF-LIMIT-MAN (NON-KEY DECIMAL NUMBER 9.99
IN 3200)
3296* BIO-HI-CONF-LIMIT-EXP (NON-KEY
3200)
3300* BIO-LOW-CONF-LIMIT-MAN (NON-KEY
IN 3200)
3301* BIO-LOW-CONF-LIMIT-EXP (NON-KEY
N 3200)
3305* BIO-MAX-APPLICABLE-DOSE-MAN (NON-KEY
9.999 IN 3200)
3306* BIO-MAX-APPLICABLE-DOSE-EXP (NON-KEY INTEGER NUMBER
99 IN 3200)
3310* BIO-M-A-D-UNITS (NON-KEY NAME X(9) IN 3200)
3315* BIO-LEVEL OF TOXICITY (NAME X(14) IN 3200)
3320* BIO-BACT. MUTAGEN RESPONSE (NAME X(14) IN 3200)
3325* BIO-MIN-EFF-CONC-MAN (NON-KEY DECIMAL NUMBER 9.99 I
N 3200)
3326* BIO-MIN-EFF-CONC-EXP (NON-KEY INTEGER NUMBER 99 IN
3200)
3330* BIO-MIN EFFECTIVE CONCEN. UNITS (NON-KEY NAME X(7)
IN 3200)
3335* BIO-APPROX-CONCENTRATION-FACTOR (NON-KEY NAME X(17)
IN 3200)
3250* BIO-ORGANISMS (RG IN 3200)
3255* BIO-ORGANISMS/STRAINS (NAME X(65) IN 3250)
3360* BIO-COMMENTS SUMMARY (RG IN 3200)
3365* BIO-COMMENT LINE NUMBER (NON-KEY INTEGER NUMBER 9
9 IN 3360)
3370* BIO-COMMENT (NON-KEY TEXT X(63) IN 3360)
INTEGER NUMBER 99 IN
DECIMAL NUMBER 9.99
INTEGER NUMBER 99 I
DECIMAL NUMBER
-------�
APPENDIX A.3
GLOSSARY
-------�
The following table is a glossary of the data elements in the EADS
waste stream data bases. While this encompasses all the data elements in
EADS, note that no single data system (fine particles, gaseous, liquids,
or solids) contains all of the data elements. As an example, data element
C300 is the NPDES number which occurs only in the Liquid Effluents Data
System.
The table lists the name of the data element (in the order it
appears on the input forms), the data base variable name (as it is defined
in the data base definition), the corresponding component number(s) and
field size or format (from the data base definition), and a description of
the data element. For further clarification on these definitions, refer
to Section 4, the detailed encoding instructions.
In the field size or format, X(20) means an alphanumeric field
20 characters long. The format 9(5) means an integer field, five numbers
long, and 9(3).9(2) represents a decimal number field with three numbers
before the decimal point and two after.
The exponential format requires two data elements, a decimal number
for the mantissa, and an integer number for the exponent. In the
description of the data element, the exponential format is written
nn.nn E + nn.
A.3-1
-------�
FORM 1 — Source Description
Data Element Name
Data Base
Component
Data Base Variable Name Numbers
Field Size/Format
Description
co
ro
FPEIS Test Series Number FPEIS TEST SERIES NUMBER C101
GEDS Test Series Number GEDS TEST SERIES NUMBER C102
LEDS Test Series Number LEDS TEST SERIES NUMBER C103
SDDS Test Series Number SDDS TEST SERIES NUMBER C104
(Not on Form) TEST SERIES KEY C105
(Not on Form) DB KEY C106
Source Category SOURCE CATEGORY C110
Integer 9(5)
Integer 9(5)
Integer 9(5)
Integer 9(5)
Name X(6)
Name X
Name X(20)
The permanent, unique number assigned by the EADS
Program Manager to each test series in the Fine
Particle Emissions Information System.
The permanent, unique number assigned by the EADS
Program Manager to each test series in the Gaseous
Emissions Data System.
The permanent, unique number assigned by the EADS
Program Manager to each test series in the Liquid
Effluents Data System.
The permanent, unique number assigned by the EADS
Program Manager to each test series in the Solid
Discharge Data System.
The code letter which identifies the data base (F, G,
L, or S) and the Test Series Number for data retrieval
purposes.
The code letter which identifies the data base (F, G,
L, or S), for data retrieval purposes.
The grouping of major generic industries or source
Source Type
Product/Device Type
SIC Code
Process Type
Design Process Rate
Process Rate Units
Feed Material Category
Source Name
Site Name
SOURCE TYPE C120
PRODUCT/DEVICE C125
SIC CODE C270
PROCESS TYPE C130
DESIGN PROCESS RATE C140
DESIGN PROCESS RATE UNITS C145
FEED MATERIAL CATEGORY C150
SOURCE NAME C180
SITE NAME C190
Name X(20)
Name X(20)
Integer 9999
Name X(20)
Integer 9(6)
Name X(6)
Name X(10)
Name X(23)
Name X(25)
classes; i.e., the broadest description of a source
(e.g., COMBUST-ENERGY, CHEMICAL MANUFAC, METALS, and
NATURAL PRODUCTS).
The kind of source within a source category (e.g.,
INDUSTRIAL, INORGANIC ACIDS, PRIMARY FERROUS, and
WOOD).
The general device or specific product (e.g., BOILER,
SULFURIC ACID, STEEL, and PULP AND PAPER).
The U.S. Department of Commerce Standard Industrial
Classification code.
The unique process being tested (e.g., TANGENTIAL,
CONTACT PROCESS, BLAST FURNACE, and SULFATE PULPING).
The design capacity of the process.
The design process rate units, reflecting the type of
process tested.
The general category of the process feed material or
fuel (e.g., COAL, OIL, GAS, WOOD, SOLIDWASTE, and MTL
SCRAP).
The name of the source.
The name of site where the source is located.
-------�
FORM 1 — Continued
CO
I
CO
Data Element Name
Street/Box Number
City
State
Zip Code
Country
Data Base Variable Name
ADDRESS
CITY
STATE
ZIP CODE
COUNTRY
Data Base
Component
Numbers
C200
C210
C220
C230
C232
Field Size/Format
Name X(20)
Name X(18)
Name XX
Integer 9(5)
Name X(5)
Description
The number and name of the street address of
The name of the city, township, or area.
The two-letter code for the state or Canadian
The zip code for the address of the site.
The abbreviation for the country in which the
the site.
province.
source is
FPEIS Test Series Number
SCDS Test Series Number
GEDS Test Series Number
LEDS Test Series Number
NPDES Number
Start Date
Finish Date
(Not on Form)
FPEIS TSN CROSS REFERENCE
C235
SDDS TSN CROSS REFERENCE C240
GEDS TSN CROSS REFERENCE C250
LEDS TSN CROSS REFERENCE C260
NPDES NUMBER
SERIES START DATE
SERIES FINISH DATE
DATE OF ENTRY
C300
C340
C350
C355
Integer 9(5)
Integer 9(5)
Integer 9(5)
Integer 9(5)
Name X(9)
Date
Date
Date
located.
The Fine Particle Emissions Information System Test
Series Number associated with the fine particulate
information which was collected from the same source
and at the same time as the data for the test series
currently being encoded.
The Solid Discharge Data System Test Series Number
associated with the solid discharge information which
was collected from the same source and at the same time
as the data for the test series currently being encoded.
The Gaseous Emissions Data System Test Series Number
associated with the gaseous information which was
collected from the same source and at the same time as
the data for the test series currently being encoded.
The Liquid Effluents Data System Test Series Number
associated with the liquid effluent information which
was collected from the same source and at the same time
as the data for the test series currently being encoded.
The National Pollutant Discharge Elimination System
number assigned by Permit Sections of the State or EPA
Regional Offices.
The starting date of the sampling activity.
The finishing date of the sampling activity.
The date indicating when the test series data were
loaded into the data base, used for internal records.
-------�
FORM 1 ~ Concluded
Data Element Name
Sponsor Organization
Contract Number
TO/TD Number
Name of Sampling Group/
Contractor
Reference Report Title
Reference Report Author
Reference Report Number
• Reference Report
-------�
FORM 1A -- Wastewater Collection System Effluent Identification
GO
I
en
Data Element Name
Site Latitude
Site Longitude
Fraction Design Rate of
Industrial Origin
Contributing Industrial
Category Number
I ndu s try/Coronerc i a 1
SIC Number
Category Flow Contribution
Number of Establishments
Data Base Variable Name
SITE LATITUDE
SITE LONGITUDE
FRACTION DESIGN RATE IND
ORIGIN
CONTRIBUTING INDUSTRIAL
CATEGORY NUMBER
INDUSTRY -COMMERCIAL SIC
NUMBER
CATEGORY FLOW CONTRIBUTION
NUMBER OF ESTABLISHMENTS
Data Base
Component
Numbers
C370
C372
C374
C378
C380
C382
C384
Field Size/Format
Decimal 99.99
Decimal 999.99
Decimal 9.9999
Integer 9(5)
Integer 9999
Decimal 9.999
Integer 9999
Description
The site latitude in units of degrees North.
The site longitude in units of degrees West.
The fraction of the influent stream that is from
industrial sources.
The sequential number for the category of industry or
commercial activity that contributes waste flow to the
source.
The U.S. Department of Commerce Standard Industrial
Classification code.
The fraction of flow contributed by the industry or
commercial activity.
The number of establishments in the service area.
-------�
FORM 2 —• Stream Design Characteristics and Control Device/Treatment Process Data
Data Element Name
Stream Number
Flowrate
Flowrate Units
Velocity
Temperature
Pressure
Moisture Content
W Stack Height
en
Stream Name
Stream Comments as Text
Device Number
Generic Device/Process Type
Design Type
Specific Process/
Device Type
Device/Process Class
Device/Process
Commercial Name
Data Base Variable Name
STREAM NUMBER
MASS/VOLUMETRIC FLOWRATE
FLOW RATE UNITS
VELOCITY-SAMPLING LOCATION
TEMPERATURE-SAMPLING
LOCATION
PRESSURE-SAMPLING LOCATION
MOISTURE CONTENT
STACK HEIGHT
STREAM NAME
STREAM-COMMENTS 1; 2
DEVICE/PROCESS NO
GENERIC DEVICE/PROCESS TYPE
DESIGN TYPE
SPECIFIC PROCESS/
DEVICE TYPE
DEVICE/PROCESS CLASS
DEVICE/PROCESS
COMMERCIAL NAME
Data Base
Component
Numbers
C410
C430
C432
C440
C450
C460
C470
C475
C420
C480;
C481
C505
C510
C515
C520
C530
C540
Field Size/Format
Integer 99
Decimal 9(5). 9
Name X(6)
Decimal 999.9
Integer 9999
Decimal 99.9
Decimal 99.9
Decimal 9999.9
Name X(34)
Text X(65);
Text X(65)
Integer 99
Name X(20)
Name X(33)
Name X(20)
Name X(12)
Name X(30)
Description
The sequential number assigned to each effluent stream
sampled at the source.
The design total mass or volumetric flowrate of the
effluent in the sampled stream at normal maximum
operating conditions.
The appropriate units of the stream flowrate.
The design velocity of the effluent stream in m/sec at
normal maximum operating conditions.
The design temperature of the effluent stream in
degrees Celsius at normal maximum operating conditions.
The design absolute pressure in units of kPa of the
effluent stream at normal maximum operating conditions.
The design moisture content in percent by volume of the
effluent stream at normal maximum operating conditions.
The height of the stack in meters, relative to ground
level.
The name of the effluent stream sampled at the source
(e.g., boiler flue gas, process wastewater, bottom ash,
etc.).
The comments on the stream data.
The number assigned to each control device or
treatment, storage, or recovery process, unique within
a test series.
The type of generic control device or treatment process.
The control device/treatment process design type.
The control device/treatment process specific type.
The device/process class.
The comnercial name and model number of the
device/process.
-------�
FORM 2 — Concluded
Data Element Name
Data Base Variable Name
Data Base
Component
Numbers
Field Size/Format
Description
CO
Manufacturer
Sequence Number
Device/Process Keyword
Parameter Number
Design Parameter Name
Value Type
Parameter Value
Parameter Value
Text/Units
MANUFACTURER C550
DEVICE/PROCESS CATEGORY C585
SEQ NUMBER
DEVICE/PROCESS CATEGORY C590
KEYWORD
DES-PARAMETER NUMBER C610
DES-PARAMETER NAME C620
DES-PARAMETER TYPE C621
DES-PARAMETER VALUE C622;
MAN; EXP C623
DES-PARAMETER TEXT VALUE; C630;
VALUE UNITS C624
Name X(30)
Integer 99
Name X(30)
Integer 99
Name X(30)
Name X
Decimal 99.99;
Integer 99
Name X(24);
Name X(24)
The name of the device/process manufacturer.
The sequential number assigned to each device/
process keyword.
The word that best describe the control device/
treatment process in greater detail.
The sequential number for the design parameter.
The name of the design parameter.
The code letter for the type of parameter value; T for
text or N for number.
The numeric value of the design parameter, in
exponential format, nn.nn E + nn.
The text value of the design parameter, or the units
of the numeric value of the design parameter.
-------�
FORM 3 -- Test Identification and Control Device/Treatment Process Operating Parameters
CO
CO
Data Element Name
Test ID Number
Test Date
Start Time
End Time
Operating Mode
Percent of Design Capacity
Device/Process Number
Operating Parameter Number
Operating Parameter Name
Value Type
Less Than/Greater Than Sign
Parameter Value
Operating Parameter
Text/Units
Comments as Text
Data Base Variable Name
TEST- ID- NUMBER
TEST -DATE
TEST -START TIME
TEST-STOP TIME
OPERATING MODE
PERCENT OF DESIGN CAPACITY
OP-DEVICE NUMBER
OPERATING PARAMETER NUMBER
OPERATING PARAMETER NAME
OPERATING PARAMETER TYPE
OPERATING PARAMETER
HIGH-LOW
OPERATING PARAMETER VALUE
MAN; EXP
OPERATING PARAMETER TEXT
VALUE; VALUE UNITS
TEST-COMMENT-1; -2; -3
Data Base
Component
Numbers
C810
C820
C830
C840
C850
C860
CIO 10
C1060
C1065
C1066
C1064
C1067;
C1068
C1070;
C1069
C861;
C862;
C863
Field Size/Format
Integer 999
Date
Integer 9999
Integer 9999
Text X(31)
Decimal 999.9
Integer 99
Integer 99
Name X(30)
Name X
Name X
Decimal 9.99;
Integer 99
Name X(24);
Name X(24)
Text X(65);
Text X(65);
Text X(65)
Description
The sequential number for each test. A test is defined
as a sample or series of samples at a given point in
time for a particular source/control operating
condition.
The date the test was conducted or begun.
The test starting time on the basis of a 24-hour day.
The test finish time on the basis of a 24-hour day.
The mode of operation of the source at the time of the
test (e.g., batch, continuous, cyclic, etc.).
The percent of the design capacity at which the source
is operating during the test.
The unique number previously assigned to each control
device/treatment process.
The sequential number for each control device operating
parameter.
The name of the operating parameter.
The code letter for the type of parameter value; T for
text or N for number.
The appropriate sign indicating if the data are less
than or greater than a value.
The numeric value of the operating parameter, in
exponential format, n.nn E + nn.
The text value of the operating parameter, or the units
of the numeric value of the operating parameter.
The comments on the test operating conditions.
-------�
FORM 4 -- Fuels and Feedstocks
CO
Data Element Name
Source Feed Material
Feed Material Rate and Units
Feed Material Sample Mass
Feed Material Mass Units
Sequence Number
Laboratory Name
QA/QC Code
Feed Material Sample Volume
Volume Units
Proximate Analysis Parameter
Value
Units
Ultimate Analysis Parameter
Value
Parameter Name
Value Type
Less Than/Greater Than Sign
Data Base Variable Name
FF -SOURCE FEED MATERIAL
FF-FEED MATERIAL RATE
FF-SAMPLE MASS
FF-SAMPLE MASS UNITS
FF-SEqUENCE NUMBER
FF-LABORATORY NAME
FF-QA-qC CODE
FF-SAMPLE VOLUME
FF-SAMPLE VOLUME UNITS
FF -PA-PARAMETER
FF-PA-PARAMETER VALUE
FF -PA-PARAMETER-UNITS
FF-UA-PARAMETER
FF-UA-PARAMETER VALUE
FF -PARAMETER
FF-VALUE TYPE
FF-PARAMETER VALUE HIGH-LOW
Data Base
Component
Numbers
C870
C873
C874
C875
C869
C877
C878
C876
C879
C885
C890
CP95
C905
C910
C923
C930
C935
Field Size/Format
Text X(30)
Text X(17)
Decimal 999.99
Text X(6)
Integer 9
Name X(40)
Name XXX
Decimal 999.99
Text X(7)
Name X(16)
Decimal 9(7). 99
Name X(5)
Name X(10)
Decimal 999.99
Name X(12)
Name X
Name X
Description
The specific name of the source feed material (e.g.,
Western PA Bituminous, Kraft Pulp, etc.).
The measured operating (not design) input rate of the
source with the appropriate units.
The mass of the feed material sample.
The units of the feed material sample mass.
The sequential number that identifies each feed
material or fuel type used.
The name of the laboratory that performed the fuels and
feedstocks analysis.
The quality assurance/quality control code for the
laboratory.
The volume of the feed material sample.
The units of the feed material sample volume.
The parameter associated with the proximate fuel
analysis, as per ASTM D3172-73.
The value of the proximate analysis parameter.
The units of the proximate analysis parameter value.
The parameter associated with the ultimate fuel
analysis, as per ASTM D3176-74.
The value of the ultimate analysis parameter in units
of percent by weight.
The name of the fuels and feedstocks parameter analyzed
(e.g., bulk density, viscosity, pour point, etc.),
excluding inorganic trace elements and organic chemical
species and compounds.
The code letter for the type of parameter value; T for
text or N for number.
The appropriate sign indicating if the data are less
than or greater than a value.
-------�
FORM 4 — Concluded
Data Element Name
Value
Units
Analytical Method
High Detection Limit
Low Detection Limit
Detection Limit Units
Data Base Variable Name
FF-PARAMETER VALUE
MAN; EXP
FF-VALUE UNITS;
FF-TEXT VALUE
FF-ANALYSIS METHOD
FF-DETECTION LIMIT-HIGH
MAN; EXP
FF-DETECTION LIMIT -
LOU MAN; EXP
FF-DETECTION LIMIT - UNITS
Data Base
Component
Numbers
C931;
C934
C932;
C933
C926
C924;
C925
C927;
C928
C929
Field Size/Format
Decimal 9.99;
Integer 99
Name X(18);
Name X(18)
Name XX
Decimal 99.99;
Integer 99
Decimal 99.99;
Integer 99
Name X(7)
Description
The value of the parameter, in exponential format
n.nn E +_ nn.
The text value of the parameter, or the units of the
numeric value of the parameter.
The two-character code for the chemical analysis method
used.
The upper detection limit, in exponential format,
nn.nn E +_ nn.
The lower detection limit, in exponential format,
nn.nn E + nn.
The units of the upper and lower detection limits.
co
i
-------�
FORM 5 — Fuels and Feedstocks — Chemical Analysis
OJ
Data Element Name
Chemical ID Type
Category/Species ID
Species Priority/
Hazardous Pollutant
Designation
(Not on Form)
Analytical Method
High Detection Limit
Low Detection Limit
Detection Limit Units
Total Milligrams Recovered
Less Than/Greater Than Sign
Actual Concentration
Actual Concentration Units
Comments as Text
Data Base Variable Name
FF-C-CS-TYPE
FF-C -CATEGORY/SPECIES
FF-C-CS-PRIORITY
FF-C-ANALYSIS METHOD
FF-C-DETECTION LIMIT
HIGH MAN; EXP
FF-C-DETECTION LIMIT
LOW-MAN; -EXP
FF-C-DETECTION LIMIT
UNIT
FF-C-TOTAL MG RECOVERED
FF-C-CONCENTRATION-HIGH-LOW
FF-C-CATEGORY/SPECIES
CONCENTRATION MAN; EXP
FF-C -CONCENTRATION UNITS
FF -COMMENT 1; 2; 3
Data Base
Component
Numbers
C946
C945
C947
C950
C948;
C949
C953;
C951
C952
C955
C964
C965;
C967
C969
C970;
C971;
C972
Field Size/Format
Name X
Name X(10)
Name X
Name XX
Decimal 99.99;
Integer 99
Decimal 99.99;
Integer 99
Name X(8)
Decimal 9(5). 999
Name X
Decimal 9.99
Integer 99
Name X(ll)
Text X(65);
Text X(65);
Text X(65)
Description
The chemical entry code which determines the type of
chemical ID used (C for CAS number or M for MEG number).
The chemical ID for the organic category or species, or
the inorganic species.
Identification of whether the chemical species is a
NRDC Consent Decree Priority Pollutant or a Section 311
Hazardous Pollutant, or both.
The two-character code for the chemical analysis method
used.
The upper detection limit, in exponential format,
nn.nn E + nn.
The lower detection limit, in exponential format,
nn.nn E + nn.
The units of the upper and lower detection limits.
The total milligrams of the category/species found in
the sample.
The appropriate sign indicating if the data are less
than or greater than a value.
The actual concentration of the category/species, in
exponential format, n.nn E + nn.
The units of the actual concentration.
The conments on the analysis of the fuels and
feedstocks.
-------�
FORM 6 -- Sampling Activity Description
GO
Data Element Name
Sample Number
Method Type
Measurement Instrument/
Method Name
Sampling Start Time
Sampling Duration
Measured Stream Velocity
Measured Stream Temperature
Data Base Variable Name
SMPL-NUMBER
MEASUREMENT INST/
METHOD TYPE
MEASUREMENT INST/
METHOD NAME
SMPL-START TIME
SMPL -DURATION
SMPL- VELOCITY
SMPL-TEMPERATURE
Data Base
Component
Numbers
C1203
C1206
C1209
C1212
C1215
C1224
C1227
Field Size/Format
Integer 99
Name X
Name X(30)
Integer 9999
Integer 999
Decimal 999.9
Integer 9999
Description
The sequential number for each sample, unique within a
Test ID. A sample is the measurement or group of
measurements taken with a single measurement method to
define the composition of a stream at a given point in
time.
The code letter for the type of measurement instrument/
method; I for inertial impaction (e.g., impactor,
SASS), or X for other.
The name of the measurement instrument/method.
The start time of the sample collection on the basis of
a 24-hour day.
The duration of the sample collection activity in
minutes.
The measured velocity of the effluent stream in m/sec.
The measured temperature of the effluent stream in
Measured Stream Pressure
Measured Stream Moisture
Content
Density
Density Determination
Sample Volume
Measured Stream Flowrate
Flowrate Units
SMPL-PRESSURE C1230
SMPL-MOISTURE CONTENT C1233
SMPL-DENSITY C1236
SMPL-DENSITY DETERMINATION C1239
VOLUME OF SAMPLE C1248
C1218
SMPL-MASS/VOLUMETRIC
FLOWRATE
SMPL-FLOWRATE UNITS
Flowrate Measurement Method SMPL-FLOWRATE MEASUREMENT
METHOD
C1219
C1221
Integer 999
Decimal 99.9
Decimal 99.9
Integer 9
Decimal 999.99
Decimal 9(5). 9
Name X(6)
Name X(20)
units of degrees Celsius.
The measured absolute pressure of the effluent stream
at the sampling location, in units of kPa.
The measured moisture content of the effluent stream at
the sampling location, in units of percent by volume.
The particle density of a particulate laden gas stream,
or the bulk density of a solid discharge stream, in
The number 1 for measured density, or 0 for assumed
density.
The total volume collected for the sample in units of
m3 (or liters for a liquid sample).
The measured total mass or volumetric flowrate of the
effluent stream at the sampling location.
The units of the effluent stream flowrate.
The technique or equipment used to determine the
effluent stream flowrate.
-------�
FORM 6 — Continued
co
i
Data Element Name
Sample Total Mass
Mass Units
Sampling Location Code
Device/Process Number
Sampling Location Description
Instrument Temperature
Instrument Pressure
Instrument Flowrate
Percent Isokinetic
CO 2
CO
02
N2
Dilution Factor
Data Base Variable Name
TOTAL MASS
MASS UNITS
SAMPLING LOCATION CODE
SAMPLING LOCATION DEVICE
NUMBER
SAMPLING LOCATION
DESCRIPTION
INSTRUMENT TEMPERATURE
INSTRUMENT PRESSURE
INSTRUMENT FLOWRATE
PERCENT ISOKINETIC SAMPLING
CO- 2
CO
0-2
N-2
DILUTION FACTOR
Data Base
Component
Numbers
C1251
C1254
C1245
C1247
C1242
C1243
C1244
C1246
C1257
C1260
C1262
C1264
C1266
C1270
Field Size/Format
Decimal 999.99
Name XX
Name X
Integer 99
Name X(30)
Integer 9999
Integer 999
Decimal 9999.9
Integer 999
Decimal 99.99
Decimal 99.99
Decimal 99.99
Decimal 99.99
Decimal 9999.9
Description
The total mass of the sample collected.
The units of the sample mass.
The code letter for the sampling location; I for inlet
of control device/treatment process or for uncontrolled/
untreated, 0 for outlet of control device/treatment
process, G for treatment plant inlet, H for treatment
plant outlet, or S for final sludge disposal outlet.
The number which identifies to which device or process
the sampling location code refers.
The sampling location description in terms of proximity
to control devices and discharge points, including any
information that affects the sampling and transport of
discharges or emissions.
The temperature of the sampling instrument in degrees
Celsius.
The inlet absolute pressure of the sampling instrument
in kPa.
The instrument flowrate in liters/minute.
The percent isokinetic sampling achieved at the
sampling location.
The amount of C02 as a percent of total gas on a dry
basis as determined by gas analysis.
The amount of CO as a percent of total gas on a dry
basis as determined by gas analysis.
The amount of 02 as a percent of total gas on a dry
basis as determined by gas analysis.
The amount of N2 as a percent of total gas on a dry
basis as determined by gas analysis.
The ratio of aerosol concentration (on either a mass or
number basis) in the original gas stream to that of the
measured sample. The number 1 if the aerosol is not
diluted, as is the usual case when sampling with
impactors.
-------�
FORM 6 — Concluded
co
i
Data Element Name
Particle Diameter Basis
Particle Concentration Basis
Upper Boundary Diameter
Calibration/Calculation
Trace Gases in PPM
Collection Surface/
Substrate'
Couments as Text
Data Base Variable Name
PARTICLE DIAMETER BASIS
PARTICLE CONCENTRATION BASIS
UPPER BOUNDARY DIAMETER
CALIBRATION/CALCULATION
TRACE GASES IN PPM
COLLECTION SURFACE/
SUBSTRATE
SMPL -COMMENTS 1; 2;
3; 4
Data Base
Component
Numbers
C1276
C1278
C1280
C1282
C1268
C1274
C1290;
C1291;
C1292;
C1293
Field Size/Format
Integer 9
Integer 9
Decimal 999.99
Integer 9
Text X(65)
Text X(55)
Text X(65);
Text X(65);
Text X(65);
Text X(65)
Description
The number 0 for Stokes particle diameter, 1 for
classic aerodynamic particle diameter, or 2 for
aerodynamic impaction particle diameter.
The number 1 if the instrument/method measures mass, or
0 if it measures the number of particles.
The upper boundary diameter in units of microns.
The number 1 for calibrated instrument cut diameters,
or 0 for calculated instrument cut diameters.
The results of trace gas analysis, with the chemical
symbol followed by a dash and the value in parts per
million (e.g., S02-15).
The description of any surface or substrate used for
sampling.
The comments on the sampling activity.
-------�
FORM 7 or 7A — Component Data and Effluent Characteristics
J>
•
CO
Data Element Name
Component Sequence Number
Component Name
Stage/Filter Cut Size
Less Than/Greater Than Sign
Stage Weight/
Component Mass/
Concentration
Mass Concentration/Stage
(Not on Form)
Number Concentration/Stage
(Not on Form)
Cumulative Mass Percent
Less Than Stage Size
(Not on Form)
Cumulative Mass/Actual
Cubic Meter Less than
Stage Size
(Not on Form)
Cumulative Mass/
Dry Normal Cubic Meter
Less Than Stage Size
(Not on Form)
Geometric Mean
Diameter/Stage
(Not on Form)
Data Base Variable Name
COMPONENT SEQUENCE NO
SAMPLING EQUIPMENT
COMPONENT NAME
STAGE/FILTER CUT SIZE
MASS HIGH-LOW;
UG CONCENTRATION HIGH-LOW;
NO-DNCM-HIGH-LOW
MASS MAN;
EXP
UG-DNCM-STAGE-MAN;
-EXP
NO-DNCM- STAGE MAN;
EXP
CUM-PCT-LESS THAN D50
CUM-UG-ACM LESS THAN
050 MAN; EXP
CUM-UG-DNCM LESS THAN
D50 MAN; EXP
GEOMETRIC MEAN
DIAM-MAN; -EXP
Data Base
Component
Numbers
C1303
C1305
C1310
C1312;
C1349;
C1365
C1313;
C1316
C1350;
C1351
C1363;
C1364
C1352
C1353;
C1354
C1355;
C1356
C1357;
C1358
Field Size/Format
Integer 99
Name X(12)
Decimal 99.99
Name X;
Name X;
Name X
Decimal 9.99;
Integer 99
Decimal 9.99;
Integer 99
Decimal 9.99;
Integer 99
Decimal 999.99
Decimal 9.99;
Integer 99
Decimal 9.99;
Integer 99
Decimal 9.99;
Integer 99
Description
The sequential number for each component of the
measurement instrument/method analyzed.
The specific component of the sampling equipment (e.g.,
the 10 micron cyclone of a SASS train, the filtrate of
a liquid sample, etc.).
The particle boundary diameter in units of microns.
The appropriate sign indicating if the data are less
than or greater than a value.
The stage weight (FPEIS), component weight (GEDS, LEDS),
or mass (SODS) in milligrams; or the mass concentration
(FPEIS) in micrograms/dry normal cubic meter; or the
number concentration (FPEIS) in number of particles/dry
normal cubic meter, for the sampling system component,
in exponential format, n.nn E *• nn.
FPEIS Only: The calculated mass concentration per stage
in micrograms/dry normal cubic meter, in exponential
format, n.nn E + nn.
FPEIS Only: The calculated number concentration per
stage in number of particles per dry normal cubic
meter, in exponential format, n.nn E + nn.
FPEIS Only: The calculated cumulative percent of the
total mass less than the stage size (d50).
FPEIS Only: The calculated cumulative mass concentra-
tion in micrograms per actual cubic meter, in expo-
nential format, n.nn E + nn.
FPEIS Only: The calculated cumulative mass concentra-
tion in micrograms per dry normal cubic meter, in expo-
nential format, n.nn E +_ nn.
FPEIS Onl_y_: The calculated average of the logarithms
of the maximum and minimum particle sizes found on the
stage, in exponential format, n.nn E + nn.
-------�
FORM 7 or 7A — Concluded
Data Element Name
Differential Mass
Concentration/Stage
(Not on Form)
Differential Number
Concentration/Stage
(Not on Form)
Chemical Analysis
Laboratory Name
Chemical QA/QC Code
Radiological QA/QC Code
Radiological Analysis
Laboratory Name
Component (Aliquot)
Mass/Volume
Mass/Volume Units
, Effluent Parameter Name
i— »
Value Type
Value
Value Units
Analytical Method
High Detection Limit
Low Detection Limit
Detection Limit Units
Comments as Text
Data Base Variable Name
OM-DLOG-MAN; -EXP
DN-DLOG-MAN;
-EXP
CHEMICAL ANALYSIS
LAB NAME
CHEMICAL QA-QC CODE
RAD-QA-QC CODE
RADIONUCLIDE ANALYSIS
LAB NAME
COMPONENT ALIQUOT
MASS-VOL
COMPONENT ALIQUOT
UNITS
EC-PARAMETER
EC-VALUE TYPE
EC-VALUE;
EC-TEXT VALUE
EC-VALUE UNITS
EC-ANALYSIS METHOD
EC-DETECTION LIMIT-HIGH-
MAN; -EXP
EC-DETECTION LIMIT -LOW
MAN; EXP
EC-DETECTION LIMIT - UNITS
EC-COMMENT 1; 2
Data Base
Component
Numbers
C1359;
C1360
C1361;
C1362
C1320
C1321
C1325
C1324
C1330
C1335
C1420
C1429
C1430;
C1432
C1431
C1425
C1423;
C1424
C1426;
C1427
C1428
C1440;
C1450
Field Size/Format
Decimal 9.99;
Integer 99
Decimal 9.99;
Integer 99
Name X(39)
Name XXX
Name XXX
Name X(40)
Decimal 9999.999
Name X(5)
Name X(12)
Name X
Decimal 9999.9;
Name X(13)
Name X(8)
Name XX
Decimal 99.99;
Integer 99
Decimal 9.99;
Integer 99
Name X(9)
Text X(63);
Text X(63)
Description
FPEIS Only: The calculated change in mass concentra-
tion due to particles caught on this stage (DM/DlogD),
in exponential format, n.nn E +_ nn.
FPEIS Only: The calculated change in number concentra-
tion due to particles caught on this stage (DN/DlogD),
in exponential format, n.nn E + nn.
The name of the laboratory which performed the
chemical analysis on the samples.
The QA/QC code for the chemical analysis laboratory.
The QA/QC code for the radionuclide analysis laboratory.
The name of the laboratory which performed the
radionuclide analysis on the samples.
The mass or volume of the sample aliquot.
The appropriate units of the sample aliquot.
The name of the effluent parameter (e.g., opacity, pH,
oil and grease, odor, etc.), excluding organic and
inorganic species measurements.
The code letter for the type of parameter value; T for
text or N for number.
The numeric or text value of the effluent parameter.
The units of the numeric value of the parameter.
The two-character code for the chemical analysis method
used.
The lower detection limit, in exponential format,
nn.nn E + nn.
The lower detection limit, in exponential format,
n.nn E + nn.
The units of the upper and lower detection limits.
The comments on the effluent characteristics.
-------�
FORM 8 -- Inorganic Analysis/Non-Level i Organic Analysis
CO
I
Data Element Name
ID Type
Category/Species ID
Species Priority/
Hazardous Pollutant
Designation
(Not on Form)
Analytical Method
High Detection Limit
Low Detection Limit
Detection Limit Units
Total Milligrams
Recovered
Less Than/Greater Than Sign
Actual Source Concentration
torments as Text
Data Base Variable Name
IA-SPECIES- ID-TYPE
IA-SPECIES-ID
IA-SPECIES-PRIORITY
IA-ANALYSIS-METHOD
IA-DETECTION LIMIT-
HIGH-MAN; -EXP
IA-DETECTION LIMIT-
LOW-MAN; -EXP
IA-DETECTION UNIT
IA-TOTAL MG RECOVERED
IA-HIGH-LOU
IA-CONCENTRATION MAN;
EXP
IA-COMMENT-1; -2
Data Base
Component
Numbers
C1830
C1835
C1836
C1840
C1841;
C1842
C1843;
C1844
C1845
C1846
C1847
C1850;
C1852
C1860;
C1870
Field Size/Format
Name X
Name X(10)
Name X
Name XX
Decimal 99.99;
Integer 99
Decimal 99.99;
Integer 99
Name X(8)
Decimal 9(5). 999
Name X
Decimal 9.99;
Integer 99
Text X(63);
Text X(63)
Description
The chemical entry code which determines the type of
chemical ID used (C for CAS number or M for MEG number).
The chemical ID for the organic category or species, or
the inorganic species.
Identification of whether the chemical species is a
NRDC Consent Degree Priority Pollutant or a Section 311
Hazardous Pollutant, or both.
The two-character code for the chemical analysis method
used.
The upper detection limit, in exponential format,
nn.nn E + nn.
The lower detection limit, in exponential format,
nn.nn E + nn.
The units of the upper and lower detection limits.
The total milligrams of the category/species found in
the sample.
The appropriate sign indicating if the data are less
than or greater than a value.
The actual source concentration for this component of
the category/species, in exponential format,
n.nn E + nn; in micrograms per cubic meter (FPEIS and
GEDS), per liter (LEDS), or per gram (SDDS).
The comments on the inorgan ic/non-Level 1 organic
analysis data.
-------�
FORM 9 — Level 1 Organic Analysis
CO
I—"
00
Data Element Name
Fraction ID
TCO
Grav.
(Calculated Data - Not
On Form)
ID Type
Category/Species ID
Species Priority/
Hazardous Pollutant
Designation
(Not on Form)
Analytical Method
High Detection Limit
Low Detection Limit
Detection Limit Units
Intensity
Less Than/Greater Than Sign
Actual Source Concentration
Comments as Text
•
Data Base Variable Name
L10A-FR ACTION-ID
L10A-FRACTION-TCO
L10A-FRACTION-GRAV
L10A-FRACTION-TOTAL
L10AFED-CATEGORY/
SPECIES TYPE
L10AFED-CATEGORY/SPECIES
L 10AFED-CATEGORY/SPEC I ES-
PRIORITY
L10AFED-ANALYSIS METHOD
L10AFED-DETECTION LIMIT-
HIGH MAN; EXP
L10AFED-DETECTION LIMIT-
LOW-MAN; EXP
L10AFED-DETECTION LIMIT -
UNITS
L10AFED- INTENSITY
L10AFED-HIGH-LOW
L10AFED-CONCENTRATION
MAN; EXP
L10A-COMMENT-1; -2
Data Base
Component
Numbers
C2530
C2540
C2550
C2560
C2580
C2582
C2583
C2585
C2586;
C2587
C2608;
C2609
C2588
C2590
C2595
C2600;
C2605
C2610;
C2620
Field Size/Format
Name XXX
Decimal 9999.99
Decimal 9999.99
Decimal 9999.99
Name X
Name X(10)
Name X
Name XX
Decimal 99.99;
Integer 99
Decimal 99.99;
Integer 99
Name X(8)
Integer 999
Name X
Decimal 9.99;
Integer 99
Text X(63);
Text X(63)
Description
The organic fraction determined by liquid
chromatography per Level 1 analysis procedures and
designated LC1-LC7, or TOT if the sample was not
fractionated.
The total chromatographable organics (TCO) measured for
each LC fraction, in milligrams.
The weight in milligrams of each LC fraction determined
by gravimetric analysis.
The sum of TCO and GRAV for each LC fraction.
The chemical entry code letter M for MEG number, the
type of chemical ID used.
The MEG ID number for the organic chemical category or
species.
Identification of whether the chemical species is a
NRDC Consent Decree Priority Pollutant or a Section 311
Hazardous Pollutant, or both.
The two-character code for the chemical analysis method
used.
The upper detection limit, in exponential format,
nn.nn E +_ nn.
The lower detection limit, in exponential format,
nn.nn E + nn.
The units of the upper and lower detection limits.
The assigned intensity (in essence a weighting factor)
used to indicate relative presence of chemical
categories obtained from either infrared (IR) or low
resolution mass spec trome try (LRMS) analysis data.
Values are 100, 10 or 1 and are used to calculate
concentration estimates.
The appropriate sign indicating if the data are less
than or greater than a value.
The actual source concentration for this component of
the category/species, in exponential format,
n.nn E + nn, in micrograms per cubic meter (FPEIS and
GEDS), per liter (LEDS), or per gram (SDDS).
The coranents on the Level 1 organic analysis.
-------�
FORM 10 — Radionuclide Data
CO
I
Data Element Name
Radionuclide ID
Analytical Method
High Detection Limit
Low Detection Limit
Detection Limit Units
Less Than/Greater Than Sign
Actual Source Concentration
Comments as Text
Data Base Variable Name
RN-RADIONUCLIDE ID
RN-ANALYSIS METHOD
RN-DETECTION LIMIT-HIGH
MAN; EXP
RN-OETECTION LIMIT
-LOW-MAN; EXP
RN-DETECTION LIMIT - UNITS
RN-CONCENTRATION HIGH-LOW
RN -CONCENTRATION MAN;
EXP
RN -COMMENT 1; 2
Data Base
Component
Numbers
C3025
C3030
C3028;
C3029
C3031;
C3032
C3033
C3034
C3035;
C3040
C3050;
C3051
Field Size/Format
Name X(6)
Name XX
Decimal 99.99;
Integer 99
Decimal 99.99;
Integer 99
Name X(8)
Name X
Decimal 9.99;
Integer 99
Text X(63);
Text X(63)
Description
The name of the isotope assayed, as a symbol followed
by a dash and the mass number (e.g., RA-226, U-235,
etc.).
The two-character code for the assay (analysis) method
used.
The upper detection limit, in exponential format,
nn.nn E +_ nn.
The lower detection limit, in exponential format,
nn.nn E + nn.
The units of the upper and lower detection limits.
The appropriate sign indicating if data are less than
or greater than a value.
The actual source concentration for this component of
the isotope, in exponential format, n.nn E + nn, in pCi
per cubic meter (FPEIS and GEDS), per liter (LEDS), or
per gram (SODS).
The comments on the radionuclide data.
-------�
FORM 11 — Bioassay Data
u>
I
8
Data Element Name
Test Type
Test Name
Test Duration
Lab Sample 10
Test Laboratory Name
Lab QA/QC Code
Test Start
Test End
Sample Quantity
Sample Quantity Units
Test Organisms/Strains
Type of Value
Value
Value Units
High Confidence Limit
Low Confidence Limit
Maximum Applicable Dose
Maximum Applicable Dose
Data Base Variable Name
BIO-TEST TYPE
BIO-TEST NAME
BIO-TEST DURATION
BIO-SAMPLE ID
BIO- TEST LAB NAME
BIO- TEST QA-QC
BIO- TEST START
BIO-TEST END
BIO-TEST SAMPLE QUANTITY
BIO-TEST SAMPLE UNITS
BIO-ORGANISMS/STRAINS
BIO-VALUE TYPE
BIO-VALUE-MAN; -EXP
BIO-VALUE UNITS
BIO-HI-CONF-LIMIT-
MAN; -EXP
BIO-LOH-CONF-LIMIT-
MAN; -EXP
BIO-MAX-APPLICABLE-
DOSE-MAN; -EXP
BIO-M-A-D-UNITS
Data Base
Component
Numbers
C3205
C3210
C3215
C3220
C3225
C3226
C3230
C3235
C3240
C3245
C3255
C3280
C3285;
C3286
C3290
C3295;
C3296
C3300;
C3301
C3305;
C3306
C3310
Field Size/Format
Name X(25)
Name X(30)
Integer 9(6)
Name XXXX
Name X(41)
Name XXX
Date
Date
Integer 9(8)
Name X(6)
Name X(65)
Name XXXX
Decimal 9.99;
Integer 99
Name X(8)
Decimal 9.99;
Integer 99
Decimal 9.99;
Integer 99
Decimal 9.999;
Integer 99
Name X(9)
Description
The name of the broad category of bioassay test type.
The exact name of the bioassay test (a subset of Test
Type).
The duration of the test in hours.
The unique sample ID assigned by the test laboratory.
The name of the bioassay testing laboratory.
The bioassay laboratory QA/QC code.
The start date of the bioassay test.
The end date of the bioassay test.
The quantity of sample submitted for analysis.
The units of the sample quantity.
The name of the specific test organism used (e.g.,
SALMONELLA TYPHIMURIUM TA-1538 or TA-98, etc.).
The value type (e.g., LD50, LC50, EC 50, etc.) depending
on the assay.
The value of the assay results, in exponential format,
n.nn E + nn.
The units of the assay results value.
The upper confidence limit of the assay results value,
in exponential format, n.nn E ^ nn.
The lower confidence limit of the assay results value,
in exponential format, n.nn E ± nn.
The technical limitation on the dose allowed in a
particular assay, in exponential format, n.nnn E + nn.
The units of the maximum applicable dose.
Units
-------�
FORM 11 — Concluded
CO
I
ro
Data Element Name
Level of Toxicity
Bacteria Mutagenicity
Response
Minimum Effective
Concentration
Minimum Effective
Concentration Units
Approximate Concentration
Factor
Line Number
Comments as Text
Data Base Variable Name
Data Base
Component
Numbers
Field Size/Format
BIO-LEVEL OF TOXICITY C3315 NameX(il)
BIO-BACT. MUTAGEN RESPONSE C3320 Name X(14)
BIO-MIN-EFF-CONC-MAN; C3325; Decimal 9.99;
-EXP C3326 Integer 99
BIO-MIN-EFFECTIVE CONCEN. C3330 Name X(7)
UNITS
BIO-APPROX-CONCENTRATION- C3335 Name X(17)
FACTOR
BIO-COMMENT LINE NUMBER C3365 Integer 99
BIO-COMMENT C3370 Text X(63)
Description
The qualitative bioassay result, as HIGH, MODERATE,
LOW, or NOT DETECTABLE.
The Ames test response, as POSITIVE or NEGATIVE.
The minimum effective concentration, in exponential
format n.nn E *_ nn.
The units of the minimum effective concentration.
The factor which accounts for any aliquot taken during
the bioassay lab procedures; not the process stream
flow.
The line number for the bioassay comments.
The comments on the bioassay data.
-------�
APPENDIX A.4
6EDS DATA INPUT FORMS
-------�
vvEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Triangle Park, N.C. 27711
GASEOUS EMISSIONS DATA SYSTEM
DATA INPUT FORMS
FORM 1
2/80
A - SOURCE DESCRIPTION
Form Completed by
Test
Series
1 2
y
No.
10
M
II
n
Card
No.
u
A
15
0
Card
No.
14
A
15
1
Card
No.
"
A
15
2
Card
No.
»
|A
15
3
Card
[No^
14
JA
15
4
Card
No.
)4
A
A
15
5
1.
Card
No.
«
IA
15
7
tard
No.
M
A
15
a
Source Category
16
17
16
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
Process Type
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
3!
32
33
34
35
Source Type
36
37
38
39
40
41
Design
Process Rate
36
37
38
39
40
Site Name
16
7
16
19
20
21
22
23
24
25
Zip Code 1 Country
6
17
16
19
20|JI
r
a
23
24
IS
26
27
28
29
30
31
32
33
34
35
FPEIS 1 SDDS
TSN | TSN
26
27
28
29
30J3I
32
33
34
35
34
37
38
39
40
41
42
43
44
45
46
47
Process
Rate Units
42
43
44
45
46
47
46
49
50
51
52
53
54
V
Product/ Device Type
54
57i
58
59
60
41
62
63
44
65
66
67
6B]69
70
71
72
73
74
75
SIC Cod.
76
77 71
" i
Feed Material 1
Category | Source Name
46
49
50
51
52
Street/ Box Number
41
42
43
44
45
46
47
46
49
50
51
52
53 54
U
53
5;
56
57)58
59
40
41
62
63
44
65
44
67
68
49
70
71
72
73
74
75
76
77 TBj
State
ICi.y
14
GEDS 1 LEDS I NPOES
TSN 1 TSN 1 Number
3*
J7
319
4QJ41
42
43
44
45J*5
1
47
41
4»
SO
51
52
S3
M
55
56
Stc
Mo
55
Sponsor Organization (Contract Number
16
17
18
19
20
21
22
23
24
25
24
27
28
29
30J 31
32
33
34
35
36
37
38
?*
40
41
42
43
44
45J 46
47
48
49
50
51
52
53
54
55
56
57
58
irt DC
Da
57
58
TO/TD
Number
56
57
58
59
40J4I |42|63|44|65|44
te
Yr
59
LLLLL.
1 Finish Date
Mo Da Y
60J6I
62
63
44
65
47
68
69
70
71
72
73
74
75
76
77 n
79 80
1
TV 8(
J
<4t?
1
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«i«i7il7i1nf7»|w
n 11 1 1
M!«|M
,
Name of Sampling Group/Contractor
59
60
61
62
43
44
65
66
47
68
49
70
71
72
73
74
75
74
77 78
79 «
Reference Report Tit e
16
17
18
19
20
21
22
23
24
25
26
27
21
29
30
31
3?
33
34
35
36
37
38
39
40
41
42
43
44
45
44
47
46
49
50
51
52
53
54
55
54
57
58
59
60
61
62
63
64
65
Reference Report Author 1 Reference Report Number
6
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
36
39
40
45^46
50
51
52
53
54
55
54
57
58
59
40
61
62
63
64
65
66J67
1
68
49
70
71
72
73
74
75
74
77 78
79 80
Reference Report Publication Date
66
67
69
49
70
71
77
73
74
75
76
77 7i
T» *
Reference Report I
NTI5 Number I
16
17
16
19
20
21
22
23
24
25
24
27
28
29
30
31
32
33
34
35 IM
r
"Pi'T6
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18
19
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Page of_
-------�
4VEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Triangle Park. N.C. 27711
GASEOUS EMISSIONS DATA SYSTEM
FORM 2
2/80
C - STREAM
Test
Series
1 2
C
DESIGN CHARACTERISTICS
r-Stream No.
No.
I
1 f
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Card
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14
C
15
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14
C
C
15
1
2
DATA
Flowrate*
16
17
IS
1
19
20
21
Flowrate
Units'
22
23
24
25
26
27
Velocity*
28
29
30
31
Temper-
ature*
32
33
34
35
Pres-
sure*
36
37
38
NPUT FORMS
Moist.
Con.*
39
40
41
Stack
Height*
12
43
44
45
46
Stream
47
48
Name*
49T50
Stream Comments as Text*
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
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62
63
64
65
66
67
68
69
70
71
72
73
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75
76
77
78
79
80
D -CONTROL DEVICE/TREATMENT PROCESS
Test
Series No.
G
1
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1
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Card
No.
D
0
Card
No.
D
1
Card
No.
D
2
Card
No.
14
D
D
D
15
3
3
3
De-
vice
No.
Generic Device/ Process Type
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
Specific Process /Device Type
20
21
22
23
24
25
26
27
282,
30
31
32
33
34
35
36
37
Design Type
38
39
40
41
42
43
44
45
46
47
Device/ Process Class
36
37
38
39
40
41
42
43
44
45
Manufacturer
Seq.
No.
6
17
20
21
22
23
2425
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
Device/ Process Commerc
48
49
50
51
52
53
54
55
56
57
58
59
69
61
62
63
64
65
66
67
68
69
70
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58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75J76
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42
Device/ Process Keyword
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
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42
43
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63
64
65
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66
67
68
69
70
71
72
73
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75
76
77
78
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Test
Series No.
G
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Card
No.
14
D
D
D
D
D
D
D
15
4
4
4
4
4
4
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16
17
— Parameter No .
Design Parameter Name
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
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42
43
44
45
46
47
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50
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51
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54
55
56
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Parameter Value Text/Units
57
58
59
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60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
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Page of_
-------�
EPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research triangle Park, N.C. 27711
GASEOUS EMISSIONS DATA SYSTEM
FORM 3
2/80
E-TEST IDENTIFICATION
rStreom No.
1
|« wj^4* ig|7if7i>?*i|24tnl7*[r7ii> fan
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No.
9
10 III
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a In
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14
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15
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2
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2
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16
17
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17
14
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Operating Parameter Name*
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
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46
49
50
51
52
53
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55
56
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49
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8
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17
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19
20
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a
23
24
25
26
27
21
29
10
31
32
33
34
35
36
37
31
39
40
41
42
43
44
45
46
47
[
40
Value Type
Parameter Value
$ ±
49
50
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52
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54
55
56
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57
58
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70
71
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76
77
71
79
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16
17
10
19
20
21
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23
24
25
26
27
28
19
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
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Page of_
-------�
wEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Mangle Park. N.C. 27711
GASEOUS EMISSIONS DATA SYSTEM
FORM 4
2/80
F - FUELS AND FEEDSTOCKS
(—Stream No.
Test
Series No.
G
456
1
1
Test
ID.
No.
10
11
9
a
Card
No.
14
^
15
0
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No.
I'4
f
15
1
Source Feed Material *
16
17
18
19
20
21
22
"|
23J24
1
Laboratory Name *
16
17
18
19
20
21
22
23
25
26
27
28
29
30
31
32
33
24
25
26
27
28
29
30
31
32
33
DATA NPUT FORMS
34
35
36
37
38
39 40 41 42 43
44
45
Feed Material Rate & Units*
46 47 48 49 50 51 52 53 54 55 5*1
57
58
QV
QC
| Code
34
35
36
37
38
39 40 41 42 43
44
45
46 47 48 49 50 51 52 53 54 55156
±
57
58
59 I
0 61
62
Form- Completed by
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Sample Mass*
63
Feed Material
Sample
Volume*
59 6
0 61
,
62
63
64
65
66
67
Feed
Material
Mass Units*
68
a
Volume
Units*
64
65
66
67
68
69
70
J
70
71
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71
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±::±±
F - FUELS AND FEEDSTOCKS — PROXIMATE ANALYSIS
Test
Series
1 2
B
«
No
Test
ID.
No.
|
4*
1
,
Card
No.
F
F
^
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15
2
2
2
2
Proximate Analysis
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16
M
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26
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27
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28
T
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29
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1
30
R
T
31
Y
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32
33
34
35
16
37
38
Units
39
%
%
%
40
W
w
W
41
T
T
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42
Proximate Analysis
Parameter
43
A
F
H
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45
H
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A
46
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47
D
48
C
49
C
0
50
A
N
51
R
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52
B
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53
0
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54
N
T
55
56
57
58
59
60
61
Value*
62
63
64
65
66
67
68
Units
69
%
%
K
70
W
W
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71
T
T
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72
K
73
G
Seq. No
M
ra
w
77
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71
1
80
>
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I
F - FUELS AND FEEDSTOCKS — ULTIMATE ANALYSIS
Test
Scric
9
» No.
-stream NO.
Test
ID.
No.
Card
No.
F
r
3
3
Ultimate Analysis
Parameter
C
A
A
S
R
H
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0
N
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Ultimate Analysis
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M
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F
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0
1
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G
0
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G
N
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N
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beq
N
H
3 30
F - FUELS AND FEEDSTOCKS — CHARACTERISTICS
Test
Series No.
l 2
S
3
1
p Stream No.
Test
ID.
No.
10
11
ufn
Card
No.
F
F
F
F
F
F
F
•4
4
4
4
4
4
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4
4
4
4
4
Parameter Name
20
21
22
23
24
25
26
27
r
28
Value Type*
Value*
$ t
?9I
30
(
(
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31
32
33
E
E
E
E
E
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E
E
E
E
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35
36
Analytical Method*
Units*
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
High Detection
Limit • ±
57
68
(
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59
60
61
E
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E
E
E
E
E
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62
63
64
Low Detection
Limit * j
65
66
(
(
67
68
69
E
E
E
E
E
E
E
E
E
t
E
E
70
71
72
Seq. No.-,
Detection
Limit Units" 4
73
74
75
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77
78
79 SO
* Denotes Repetitive Data Feature at Test Level
NOTE: When encoding data, use a^ for alpha character and 0 for numeric zero.
Poae_
of
-------�
vvEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Triangle Park, N.C. 277II
GASEOUS EMISSIONS DATA SYSTEM
FORM 5
2/80
DATA INPUT FORMS
F - FUELS AND FEEDSTOCKS - CHEMICAL ANALYSIS
r- Stream No.
Test
Series No.
1 1
x
Test
ID.
No.
10
n
w|w
lard
No.
14
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
r
F
15
5
5
5
5
5
5
b
5
5
5
5
5
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5
5
5
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5
5
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[
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Ihemical ID Type
Category/Species ID
17
18
19
20
21
22
23
24
25
26
27
-A
21
nalytical Method
High Detection
Limit +
29
30
i
31
32
33
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
34
35
36
Low Detection
Limit +
37
38
i
39
40
41
E
E
E
E
E
E
E
E
E
E
E
E
E
E
E
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E
E
E
E
E
E
E
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E
E
E
E
E
E
E
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42 [43
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|
44
-
Detection
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45
-
46J47
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_
—
—
;
i
48
49
T "
i
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—
solsi
—
52
-
Total Milligrams
Recovered
53J54
55
-
56
57
— i
58
59
60
Form Completed by
Actual
Concentration
$ ±
61
62
U
64
45
E
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E
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b
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66
67
M
Seq. No.-i
Actual
Concentration Units 1
<*
n
n
71
n
M
75
7*
rr
7*
7* I
en
F - FUELS AND FEEDSTOCKS - COMMENTS
Test
Series No.
G
G
G
— Mream No.
Test
ID.
No.
Card
Mo.
F
F
F
7
8
9
Comments as Text *
_.
—
j
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1
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" ~|-"
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Seq. No.-,
i
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NOTE: When encoding data, use a % for alpha character and 0 for numeric zero.
Page_
of
-------�
wEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Triangle Park, N.C. 27711
GASEOUS EMISSIONS DATA SYSTEM
FORM 6
2/80
H - SAMPLING ACTIVITY DESCRIPTION
[—Stream No.
Test
Series No.
G
,
Test
ID.
No.
10
n
Smpl.
No.
12
13
Card
No.
14
H
15
0
Card
No.
14
H
15
I
Card
No.
H
2
Card
No.
14
H
IS
3
u
DATA INPUT FORMS
,- Sampling .Duration* (Min)
Measurement Instrument/Method
Name*
17
18
19
20
21
Meas. Stream
Flowrate*
16
[
17
18
ampl
r
*
% bo-
Mltf
11
19
20
22
23
24
25
26
27
Flowrate
Units *
21)22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
Sampling
Start
Time
47
Flowrate Measurement Method*
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
46
49
50
1
SI
52
Sample
Total Mass*
48
49
50
5!
52
53
Meas.
Stream
Velocity*
54
Mass
Units
53
54
55
56
57
Meas.
Stream
Temp.*
56
59
60
61
Meas.
Stream
Pressure
62
63
64
Form Completed by
Meas. S
Moist.
Con.*
65
66J67
I
tream
Density
•>
6V
70
I
n
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Sample
Volume
72
73
74
75
76
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19
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21
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23
24
25
26
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27
28
29
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31
32
33
34
article Oia
N2*
31
31
30
M
35
36
37
38
39
neter Basis *-
Dilution
Factor*
35
M
32
38
39
40
I
40
41
I
4T
42
43
44
45
46
[Particle Con
Upper
Diameter
Boundary*
42
43
44
45
44
47
4.U
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50
51
52
53
54
55
56
57
SI
59
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Page of_
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vvEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
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GASEOUS EMISSIONS DATA SYSTEM
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Page of_
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vv EPA EADS
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Page.
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vvEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Triangle Park. N.C. 27711
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FORM 9
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Page of _
-------�
wEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCY
IERL-RTP Research Triangle Park. N.C. 27711
GASEOUS EMISSIONS DATA SYSTEM
FORM 10
2/80
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Page of _
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vVEPA EADS
U.S. ENVIRONMENTAL PROTECTION AGENCT
IERL-RTP Research Triangle Park. N.C. 27711
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19
20
21
22
23
Sample
Quantity
16
17
18
19
20
21
22
23
24
25
26
27
28
29
Sample
Quan. Units
24
25
26
27
26
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
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60
61
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61
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71
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16
17
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20
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23
24
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24
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26
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28
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30
31
32
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27
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20
21
22
23
24
25
26
27
28
29
30
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33
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37
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39
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35
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Effective Cone.
30
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39
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42
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Effective
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37
38
39
40
41
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43
44
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46
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49
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57
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59
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19
20
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24
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28
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30
31
32
13
34
35
36
37
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40
41
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47
48
49
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NOTE: When encoding data, use a fl for alpha character and 0 for numeric zero.
Page of.
-------�
TECHNICAL REPORT DATA
(Please read Instructions on the reverse before completing!
1. REPORT NO.
EPA-600/8-80-006
2.
3. RECIPIENT'S ACCESSIOf*NO.
4. TITLE AND SUBTITLE
Environmental Assessment Data Systems User Guide:
Gaseous Emissions Data System
5. REPORT DATE
January 1980
6. PERFORMING ORGANIZATION CODE
7. AUTHOR(S)
R. J. Larkin, Editor
8. PERFORMING ORGANIZATION REPORT NO.
9. PERFORMING ORGANIZATION NAME AND ADDRESS
Acurex Corporation
Energy & Environmental Division
485 Clyde Avenue
Mountain View, California 94042
10. PROGRAM ELEMENT NO.
EHE624
11. CONTRACT/GRANT NO.
68-02-2699
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
9/78 - 9/79
14. SPONSORING AGENCY CODE
EPA/600/13
15. SUPPLEMENTARY NOTES
IERL-RTP project officer is Gary L. Johnson, Mail Drop 63, 919/541-2745.
16. ABSTRACT
The report is a user guide to the Gaseous Emissions Data System (GEDS),
a computerized data base on gaseous emissions from stationary point sources. GEDS
is one of four waste stream data bases which are components of the Environmental
Assessment Data Systems (EADS). The EADS concept has been designed to aid
researchers in environmental assessment, emissions characterization, and control
technology development. GEDS contains data from source sampling which may include:
design and typical operating data on control technology applied to the gaseous
effluent stream; analysis of any fuel or feedstock to the process producing the
effluent stream; results of chemical, physical, radiological, and biological/eco-
logical tests of gaseous samples; process descriptions of the sources; and descrip-
tions of the sampling equipment and techniques employed. The GEDS protocol is
consistent with Level 1 and 2 reporting requirements. The guide gives detailed
instructions for encoding GEDS data sets, defines procedures for submitting and
retrieving data, and contains standard nomenclature to facilitate data encoding.
The guide also includes a program library that describes analytical software
available to the user and provides instructions for its use. The guide also dis-
cusses procedures which will allow its users to access GEDS directly by computer
or through the EPA project officer.
KEY WORDS AND DOCUMENT ANALYSIS
DESCRIPTORS
b.IDENTIFIERS/OPEN ENDED TERMS
COS AT i Held'Group
Pollution
Assessments
Exhaust Gases
Data Storage
Pollution Control
Stationary Sources
Gaseous Emissions Data
System (GEDS)
Environmental Assessment
Data Systems
EADS
13B
14B
218
098
18. DISTRIBUTION STATEMENT
Release to Public
19. SECURITY CLASS (This Reportj
Unclassified
21. NO. OF PAGES
304
20. SECURITY CLASS (Thispage)
Unclassified
22. PRICE
EPA Form 2220-1 (9-73)
-------� |