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ASTM E1191-03A(2023)e1

(Guide)

Standard Guide for Conducting Life-Cycle Toxicity Tests with Saltwater Mysids

Standard Guide for Conducting Life-Cycle Toxicity Tests with Saltwater Mysids

SIGNIFICANCE AND USE
5.1 Protection of a species requires prevention of unacceptable effects on the number, weight, health, and uses of the individuals of that species. A life-cycle toxicity test is conducted to determine what changes in the numbers and weights of individuals of the test species result from effects of the test material on survival, growth, and reproduction. Information might also be obtained on effects of the material on the health and uses of the species.  
5.2 Results of life-cycle tests with mysids might be used to predict long-term effects likely to occur on mysids in field situations as a result of exposure under comparable conditions.  
5.3 Results of life-cycle tests with mysids might be used to compare the chronic sensitivities of different species and the chronic toxicities of different materials, and also to study the effects of various environmental factors on results of such tests.  
5.4 Results of life-cycle tests with mysids might be an important consideration when assessing the hazards of materials to aquatic organisms (see Guide E1023) or when deriving water quality criteria for aquatic organisms (1).4  
5.5 Results of a life-cycle test with mysids might be useful for predicting the results of chronic tests on the same test material with the same species in another water or with another species in the same or a different water (2). Most such predictions take into account results of acute toxicity tests, and so the usefulness of the results from a life-cycle test with mysids is greatly increased by also reporting the results of an acute toxicity test (see Guide E729) conducted under the same conditions.  
5.6 Results of life-cycle tests with mysids might be useful for studying the biological availability of, and structure-activity relationships between, test materials.  
5.7 Results of life-cycle tests with mysids might be useful for predicting population effects on the same species in another water or with another species in the same or a different...
SCOPE
1.1 This guide describes procedures for obtaining laboratory data concerning the adverse effects of a test material added to dilution water, but not to food, on certain species of saltwater mysids during continuous exposure from immediately after birth until after the beginning of reproduction using the flow-through technique. These procedures will probably be useful for conducting life-cycle toxicity tests with other species of mysids, although modifications might be necessary.  
1.2 Other modifications of these procedures might be justified by special needs or circumstances. Although using appropriate procedures is more important than following prescribed procedures, results of tests conducted using unusual procedures are not likely to be comparable to results of many other tests. Comparison of results obtained using modified and unmodified versions of these procedures might provide useful information on new concepts and procedures for conducting life-cycle toxicity tests with saltwater mysids.  
1.3 These procedures are applicable to all chemicals, either individually or in formulations, commercial products, or known mixtures, that can be measured accurately at the necessary concentrations in water. With appropriate modifications, these procedures can be used to conduct tests on temperature, dissolved oxygen, and pH and on such materials as aqueous effluents (see also Guide E1192), leachates, oils, particulate matter, sediments, and surface waters.  
1.4 This guide is arranged as follows:    
Section  
Referenced Documents  
2  
Terminology  
3  
Summary of Guide  
4  
Significance and Use  
5  
Hazards  
7  
Apparatus  
6  
Facilities  
6.1  
Construction Materials  
6.2  
Metering System  
6.3  
Test Chambers  
6.4  
Cleaning  
6.5  
Acceptability  
6.6  
Dilution Water  
8  
Requirements  
8.1  
Source  
8.2  
Treatment  
8.3  
Characterizat...

General Information

Status
Published
Publication Date
31-Dec-2022
ICS
13.300 - Protection against dangerous goods
Technical Committee
E50 - Environmental Assessment, Risk Management and Corrective Action
Drafting Committee
E50.47 - Biological Effects and Environmental Fate
Current Stage
Ref Project

Relations

Refers
ASTM E943-08 - Standard Terminology Relating to Biological Effects and Environmental Fate
Effective Date
01-Mar-2008
Refers
ASTM E1192-97(2008) - Standard Guide for Conducting Acute Toxicity Tests on Aqueous Ambient Samples and Effluents with Fishes, Macroinvertebrates, and Amphibians
Effective Date
01-Feb-2008
Refers
ASTM E729-96(2007) - Standard Guide for Conducting Acute Toxicity Tests on Test Materials with Fishes, Macroinvertebrates, and Amphibians
Effective Date
01-Oct-2007
Refers
ASTM E1023-84(2007) - Standard Guide for Assessing the Hazard of a Material to Aquatic Organisms and Their Uses
Effective Date
01-Oct-2007

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ASTM E1191-03A(2023)e1 - Standard Guide for Conducting Life-Cycle Toxicity Tests with Saltwater MysidsASTM E1191-03A(2023)e1 - Standard Guide for Conducting Life-Cycle Toxicity Tests with Saltwater Mysids
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ASTM E1191-03A(2023)e1 - Standard Guide for Conducting Life-Cycle Toxicity Tests with Saltwater Mysids
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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
´1
Designation: E1191 − 03a (Reapproved 2023)
Standard Guide for
Conducting Life-Cycle Toxicity Tests with Saltwater Mysids
This standard is issued under the fixed designation E1191; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
ε NOTE—Section 13.1.11 and References were editorially corrected in January 2023.
1. Scope
Construction Materials 6.2
Metering System 6.3
1.1 Thisguidedescribesproceduresforobtaininglaboratory
Test Chambers 6.4
data concerning the adverse effects of a test material added to Cleaning 6.5
Acceptability 6.6
dilution water, but not to food, on certain species of saltwater
Dilution Water 8
mysids during continuous exposure from immediately after
Requirements 8.1
birth until after the beginning of reproduction using the Source 8.2
Treatment 8.3
flow-through technique. These procedures will probably be
Characterization 8.4
usefulforconductinglife-cycletoxicitytestswithotherspecies
Test Material 9
General 9.1
of mysids, although modifications might be necessary.
Stock Solution 9.2
1.2 Other modifications of these procedures might be justi-
Test Concentration(s) 9.3
Test Organisms 10
fied by special needs or circumstances.Although using appro-
Species 10.1
priate procedures is more important than following prescribed
Age 10.2
procedures,resultsoftestsconductedusingunusualprocedures
Source 10.3
Brood Stock 10.4
are not likely to be comparable to results of many other tests.
Food 10.5
Comparisonofresultsobtainedusingmodifiedandunmodified
Handling 10.6
versions of these procedures might provide useful information
Harvesting Young 10.7
Quality 10.8
on new concepts and procedures for conducting life-cycle
Procedure 11
toxicity tests with saltwater mysids.
Experimental Design 11.1
Dissolved Oxygen 11.2
1.3 These procedures are applicable to all chemicals, either
Temperature 11.3
individually or in formulations, commercial products, or
Beginning the Test 11.4
known mixtures, that can be measured accurately at the Feeding 11.5
Cleaning 11.6
necessary concentrations in water. With appropriate
Duration of Test 11.7
modifications,theseprocedurescanbeusedtoconducttestson
Biological Data 11.8
Other Measurements 11.9
temperature, dissolved oxygen, and pH and on such materials
Analytical Methodology 12
as aqueous effluents (see also Guide E1192), leachates, oils,
Acceptability of Test 13
particulate matter, sediments, and surface waters.
Calculation 14
Documentation 15
1.4 This guide is arranged as follows:
Keywords 16
Appendix
Section
X1. Statistical Guidance
Referenced Documents 2
1.5 This standard does not purport to address all of the
Terminology 3
safety concerns, if any, associated with its use. It is the
Summary of Guide 4
Significance and Use 5
responsibility of the user of this standard to establish appro-
Hazards 7
priate safety, health, and environmental practices and deter-
Apparatus 6
mine the applicability of regulatory limitations prior to use.
Facilities 6.1
Specific hazard statements are given in Section 7.
1.6 This international standard was developed in accor-
dance with internationally recognized principles on standard-
ThisguideisunderthejurisdictionofASTMCommitteeE50onEnvironmental
Assessment,RiskManagementandCorrectiveActionandisthedirectresponsibility
ization established in the Decision on Principles for the
of Subcommittee E50.47 on Biological Effects and Environmental Fate.
Development of International Standards, Guides and Recom-
Current edition approved Jan. 1, 2023. Published January 2023. Originally
mendations issued by the World Trade Organization Technical
approved in 1987. Last previous edition approved in 2008 as E1191–03a(2008).
DOI: 10.1520/E1191-03AR23E01. Barriers to Trade (TBT) Committee.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
´1
E1191 − 03a (2023)
2. Referenced Documents and (2) the basis for interpreting data obtained from the other
2 treatments. In each of the one or more other treatments, the
2.1 ASTM Standards:
mysids are maintained in dilution water to which a selected
E729Guide for Conducting Acute Toxicity Tests on Test
concentrationoftestmaterialhasbeenadded.Specifieddataon
Materials with Fishes, Macroinvertebrates, and Amphib-
theconcentrationoftestmaterial,andthesurvival,growth,and
ians
reproduction of the mysids are obtained and analyzed to
E943Terminology Relating to Biological Effects and Envi-
3 determine the effect(s) of the test material on survival, growth,
ronmental Fate (Withdrawn 2023)
and reproduction of the test organisms.
E1023Guide for Assessing the Hazard of a Material to
Aquatic Organisms and Their Uses
5. Significance and Use
E1192Guide for ConductingAcute Toxicity Tests onAque-
5.1 Protection of a species requires prevention of unaccept-
ous Ambient Samples and Effluents with Fishes,
able effects on the number, weight, health, and uses of the
Macroinvertebrates, and Amphibians
individuals of that species. A life-cycle toxicity test is con-
E1203Practice for Using Brine Shrimp Nauplii as Food for
ducted to determine what changes in the numbers and weights
Test Animals in Aquatic Toxicology (Withdrawn 2013)
of individuals of the test species result from effects of the test
IEEE/ASTM SI 10American National Standard for Use of
material on survival, growth, and reproduction. Information
theInternationalSystemofUnits(SI):TheModernMetric
might also be obtained on effects of the material on the health
System
and uses of the species.
3. Terminology
5.2 Results of life-cycle tests with mysids might be used to
predict long-term effects likely to occur on mysids in field
3.1 Thewords“must,”“should,”“may,”“can,”and“might”
have very specific meanings in this guide. situationsasaresultofexposureundercomparableconditions.
3.1.1 “Must” is used to express an absolute requirement,
5.3 Results of life-cycle tests with mysids might be used to
that is, to state that the test ought to be designed to satisfy the
compare the chronic sensitivities of different species and the
specified condition, unless the purpose of the test requires a
chronic toxicities of different materials, and also to study the
differentdesign.“Must”isonlyusedinconnectionwithfactors
effectsofvariousenvironmentalfactorsonresultsofsuchtests.
that directly relate to the acceptability of the test (see 13.1).
5.4 Results of life-cycle tests with mysids might be an
3.1.2 “Should”isusedtostatethatthespecifiedconditionis
important consideration when assessing the hazards of materi-
recommended and ought to be met if possible. Although
als to aquatic organisms (see Guide E1023) or when deriving
violationofone“should”israrelyaseriousmatter,violationof
water quality criteria for aquatic organisms (1).
several will often render the results questionable. Terms such
as“isdesirable,”“isoftendesirable,”and“mightbedesirable” 5.5 Results of a life-cycle test with mysids might be useful
are used in connection with less important factors. for predicting the results of chronic tests on the same test
3.1.3 “May” is used to mean “is (are) allowed to,” “can” is materialwiththesamespeciesinanotherwaterorwithanother
used to mean “is (are) able to,” and “might” is used to mean species in the same or a different water (2). Most such
“could possibly.” Therefore, the classic distinction between predictionstakeintoaccountresultsofacutetoxicitytests,and
may and can is preserved, and might is never used as a so the usefulness of the results from a life-cycle test with
synonym for either may or can. mysids is greatly increased by also reporting the results of an
acute toxicity test (see Guide E729) conducted under the same
3.2 Fordefinitionsofothertermsusedinthisguide,referto
conditions.
Guide E729, Terminology E943, and Guide E1023. For an
explanation of units and symbols, refer to IEEE/ASTM SI 10. 5.6 Results of life-cycle tests with mysids might be useful
for studying the biological availability of, and structure-
4. Summary of Guide
activity relationships between, test materials.
4.1 In each of two or more treatments, saltwater mysids of
5.7 Results of life-cycle tests with mysids might be useful
one species are maintained in two or more test chambers from
forpredictingpopulationeffectsonthesamespeciesinanother
immediately after birth until after the beginning of reproduc-
water or with another species in the same or a different water
tion in a flow-through system. In each of the one or more
(3).
controltreatments,themysidsaremaintainedindilutionwater,
to which no test material has been added, in order to provide 6. Apparatus
(1) a measure of the acceptability of the test by giving an
6.1 Facilities—Flow-through or recirculating brood-stock
indicationofthequalityofthemysidsandthesuitabilityofthe
tanks and flow-through, but not recirculating, test chambers
dilution water, food, test conditions, and handling procedures
should be maintained in constant-temperature areas or recircu-
lating water baths.An elevated headbox might be desirable so
dilutionwatercanbegravity-fedintobrood-stocktanksandthe
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
metering system (see 6.3), which mixes and delivers test
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Standards volume information, refer to the standard’s Document Summary page on
the ASTM website.
3 4
The last approved version of this historical standard is referenced on Theboldfacenumbersinparenthesesrefertothelistofreferencesattheendof
www.astm.org. this guide.
´1
E1191 − 03a (2023)
solutionstothetestchambers.Strainersandairtrapsshouldbe valves have been used successfully to control the concentra-
included in the water supply system. Headboxes and brood- tionsoftestmaterialin,andtheflowratesof,testsolutions(see
stock tanks should be equipped for temperature control and Guide E729).
aeration (see 8.3). Air used for aeration should be free of
6.3.2 The metering system should be calibrated before the
fumes, oil, and water; filters to remove oil and water are
testbydeterminingtheflowratethrougheachtestchamberand
desirable. Filtration of air through a 0.22-µm bacterial filter
measuring either the concentration of test material in each test
might be desirable. The facility should be well ventilated and
chamber or the volume of solution used in each portion of the
free of fumes. To further reduce the possibility of contamina-
meteringsystem.Thegeneraloperationofthemeteringsystem
tion by test materials and other substances, especially volatile
should be visually checked twice daily, in the morning and
ones, the brood-stock tanks should not be in a room in which
afternoon, throughout the test. The metering system should be
toxicitytestsareconducted,stocksolutionsortestsolutionsare
adjusted during the test if necessary and any malfunction or
prepared, or equipment is cleaned. During culture and testing, adjustment should be noted in the study records.
organisms should be shielded from disturbances with curtains
6.3.3 The flow rate through each test chamber should be at
or partitions to prevent unnecessary stress. A timing device
least five volume additions per 24 h. It is usually desirable to
should be used to provide either a 14-h light and 10-h dark or
construct the metering system to provide at least ten volume
a 16-h light and 8-h dark photoperiod. A 15 to 30-min
additionsper24hincasethereisrapidlossoftestmaterialdue
transition period (4) should be provided whenever lights go on
to microbial degradation, hydrolysis, oxidation, photolysis,
or off to reduce the possibility of mysids being stressed by
reduction, sorption, or volatilization (see 11.4.2). At any
instantaneous changes in light intensity. In the natural
particular time during the test, the flow rates through any two
environment, the normal vertical migration of mysids allows
test chambers should not differ by more than 10%. Flow rates
gradual acclimation to light intensity. Under artificial labora-
through all test chambers may be equally changed simultane-
tory conditions, some mysids exhibit an escape response to
ously during the test as long as the test temperature (see 11.3)
sudden increases or decreases in light intensity resulting in
and the concentrations of dissolved oxygen and test material
jumping and impingement on the sides of test chambers or
(see 11.4.1 and 11.9.3) remain acceptable (see 11.3, 11.9, and
compartments.
13).
6.2 Construction Materials—Equipment and facilities that
6.4 Test Chambers:
contact stock solutions, test solutions, or any water into which
6.4.1 Inatoxicitytestwithaquaticorganisms,testchambers
mysidswillbeplacedshouldnotcontainsubstancesthatcanbe
are defined as the smallest physical units between which there
leached or dissolved by aqueous solutions in amounts that
are no water connections. However, screens and cups may be
adversely affect mysids. In addition, equipment and facilities
usedtocreatetwoormorecompartmentswithineachchamber.
that contact stock solutions or test solutions should be chosen
Therefore, test solution can flow from one compartment to
to minimize sorption of test materials from water. Glass, Type
another within a test chamber, but, by definition, cannot flow
316 stainless steel, nylon, Teflon, and fluorocarbon plastics
from one chamber to another. Because solution can flow from
should be used whenever possible to minimize dissolution,
one compartment to another in the same test chamber, the
leaching, and sorption. Stainless steel should not be used for
temperature, concentration of test material, and levels of
tests on metals. Concrete and rigid plastics may be used for
pathogens and extraneous contaminants are likely to be more
brood-stock tanks and in the water supply, but they should be
similar between compartments in the same test chamber than
soaked, preferably in flowing dilution water, for a week or
between compartments in different test chambers in the same
morebeforeuse (5).Castironpipeshouldnotbeusedwithsalt
treatment.Chambersshouldbecoveredtokeepoutextraneous
water. Specially designed systems are usually necessary to
contaminantsandtoreduceevaporationoftestsolutionandtest
obtainsaltwaterfromanaturalwatersource(seeGuideE729).
material. All chambers and compartments in a test must be
Brass, copper, lead, galvanized metal, and natural rubber
identical.
should not contact dilution w
...

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5.1 HACCP is a proactive management tool that serves to reduce hazards potentially expressed as adverse biological or environmental effects, for example, associated with chemical releases, changes in natural resource or engineering practices and their related impacts, and accidental or intentional releases of biological stressors such as invasive species.  
5.2 Sequential implementation of HACCP and feedback in the iterative HACCP process allows for technically-based judgments concerning, for example, natural resources or the use of natural resources. Implementing the HACCP process serves to reduce adverse effects potentially associated with a particular material or process, and provides guidance for testing and evaluation of products or processes, through a pre-emptive procedure focused on information most pertinent to a system’s characterization. For example, identification of CCPs assure that processes and practices can be managed to achieve hazard reduction. For different processes and situations, HA may be based on substantially different amounts and kinds of, for example, biological, chemical, physical, and toxicological data, but the identification of CCPs serving to reduce hazard is key to successful implementation of HACCP.  
5.3 HACCP should never be considered complete for all time, and continuing reassessment is a characteristic of HACCP evaluations, especially if there should be changes in, for example, production volumes of a material, or its use or disposal increases, new uses are discovered, or new information on biological, chemical, physical, or toxicological properties becomes available. Similarly, HACCP should be considered an ongoing process serving as a key component in engineering practices, for example, related to construction activities and land-use changes, and natural resource management practices, for example, related to habitat use, enhancement, and species introductions such as fish-stocking programs. Periodic review of a system’s per...
SCOPE
1.1 This guide describes a stepwise procedure for using existing information, and if available, supporting field and laboratory data concerning a process, materials, or products potentially linked to adverse effects likely to occur in the environment as a result of an event associated with a process such as the dispersal of a potentially invasive species or the release of material (for example, a chemical or a physical substance) or its derivative products to the environment. Hazard Analysis-Critical Control Point (HACCP) evaluations were historically linked to food safety (Hulebak and Schlosser W. 2002 (1);2 Mortimer and Wallace 2013 (2)), but the process has increasingly found application in planning processes such as those occurring in health sciences ; Quattrin et al. 2008 (3); Hjarno et al. 2007 (4); Griffith 2006 (5) or; Noordhuizen and Welpelo 1996 (6)), in natural resource management (US Forest Service 2014 a,b,c (7, 8, 9), (US EPA, 2006 (10); see also    
http://www.waterboards.ca.gov/water_issues/programs/swamp/ais/prevention_planning.shtml; (last accessed October 16, 2023)
or in supporting field operations wherein worker health and natural resource management issues intersect.  
1.2 HACCP evaluation is a simple linear process or a network of linear processes that represents the structure of any event; the hazard analysis (HA) depends on the data quality and data quantity available for the evaluation process, especially as that relates to critical control points (CCPs) characterized in completing HACCP. Control measures target CCPs and serve as limiting factors or control steps in a process that reduce or eliminate the hazards that initiated the HACCP evaluation. The main reason for implementing HACCP is to prevent problems associated with a specific process, practice, material, or product.  
1.3 This guide assumes that the reader is knowledgeable in specific resource management or engineering practices us...

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ASTM
ASTM E1445-08(2023)(Terminology)
Standard Terminology Relating to Hazard Potential of Chemicals

SCOPE
1.1 This standard is a compilation of terminology used in the area of hazard potential of chemicals. Terms that are generally understood or adequately defined in other readily available sources are not included.  
1.2 Although some of these definitions are general in nature, many must be used in the context of the standards in which they appear. The pertinent standard number is given in parentheses after the definition.  
1.3 In the interest of common understanding and standardization, consistent word usage is encouraged to help eliminate the major barrier to effective technical communication.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM D8134-18(2023)(Guide)
Standard Guide for Conducting Internal Hydrostatic Pressure Tests on United Nations (UN) IBC Design Types

SIGNIFICANCE AND USE
4.1 Dangerous goods (hazardous materials) regulations require performance tests to be conducted on packaging or IBC designs before being authorized for use. The regulations do not include standardized procedures for conducting performance tests and, because of this, may result in a non-uniform approach and differences in test results between testing facilities.  
4.2 The purpose of this standard is to provide guidance and to establish a set of common practices for conducting hydrostatic pressure tests on IBC designs subjected to UN certification testing.  
4.3 Intermediate bulk container designs are required to be tested in a sequence. This guide focuses on conducting the hydrostatic pressure test, which is preceded in the test sequence by the leakproofness test. The fittings and adaptors applied to the container for the hydrostatic pressure test may also be used for the leakproofness test.
SCOPE
1.1 This guide is intended to provide a standardized method and a set of basic instructions for performing hydrostatic pressure testing on Intermediate Bulk Containers (IBCs) designs as required by the United States Department of Transportation Title 49 Code of Federal Regulations (CFR) and the United Nations Recommendations on the Transport of Dangerous Goods (UN).  
1.2 This guide focuses on composite and rigid plastic IBCs and is suitable for testing IBCs of any design or material type.  
1.3 This guide provides information to help clarify various terms used as part of the United Nations (UN) certification process that may assist in determining the applicable test.  
1.4 This guide provides the suggested minimum information that should be documented when conducting pressure testing.  
1.5 This guide provides information for recommended equipment and fittings for conducting pressure tests.  
1.6 This guide is based on the current information contained in 49 CFR 178.814.  
1.7 When testing packaging designs intended for hazardous materials (dangerous goods), the user of this guide shall be trained in accordance with 49 CFR 172.700 and other applicable hazardous materials regulations such as the International Civil Aviation Organization (ICAO) Technical Instructions for the Safe Transport of Dangerous Goods by Air, the International Maritime Dangerous Goods Code (IMDG Code), and carrier rules such as the International Air Transport Association (IATA) Dangerous Goods Regulations.  
1.8 Units—”The values stated in SI units are to be regarded as the standard. No other units of measurement are included in this guide.  
1.9 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.10 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E681-09(2023)(Test Method)
Standard Test Method for Concentration Limits of Flammability of Chemicals (Vapors and Gases)

SIGNIFICANCE AND USE
5.1 The LFL and UFL of gases and vapors define the range of flammable concentrations in air.  
5.2 This method measures the LFL and UFL for upward (and partially outward) flame propagation. The limits for downward flame propagation are narrower.  
5.3 Limits of flammability may be used to determine guidelines for the safe handling of volatile chemicals. They are used particularly in assessing ventilation requirements for the handling of gases and vapors. NFPA 69 provides guidance for the practical use of flammability limit data, including the appropriate safety margins to use.  
5.4 As discussed in Brandes and Ural,4 there is a fundamental difference between the ASTM and European methods for flammability determination. The ASTM methods aim to produce the best representation of flammability parameters, and rely upon the safety margins imposed by the application standards, such as NFPA 69. On the other hand, European test methods aim to result in a conservative representation of flammability parameters. For example, in this standard, LFL is the calculated average of the lowest go and highest no-go concentrations while the European test methods report the LFL as the minimum of the five highest no-go concentrations.
Note 2: For hydrocarbons, the break point between nonflammability and flammability occurs over a narrow concentration range at the lower flammability limit, but the break point is less distinct at the upper limit. For materials found to be non-reproducible per 13.1.1 that are likely to have large quenching distances and may be difficult to ignite, such as ammonia and certain halogenated hydrocarbon, the lower and upper limits of these materials may both be less distinct. That is, a wider range exists between flammable and nonflammable concentrations (see Annex A1).
SCOPE
1.1 This test method covers the determination of the lower and upper concentration limits of flammability of chemicals having sufficient vapor pressure to form flammable mixtures in air at atmospheric pressure at the test temperature. This test method may be used to determine these limits in the presence of inert dilution gases. No oxidant stronger than air should be used.  
Note 1: The lower flammability limit (LFL) and upper flammability limit (UFL) are sometimes referred to as the lower explosive limit (LEL) and the upper explosive limit (UEL), respectively. However, since the terms LEL and UEL are also used to denote concentrations other than the limits defined in this test method, one must examine the definitions closely when LEL and UEL values are reported or used.  
1.2 This test method is based on electrical ignition and visual observations of flame propagation. Users may experience problems if the flames are difficult to observe (for example, irregular propagation or insufficient luminescence in the visible spectrum), if the test material requires large ignition energy, or if the material has large quenching distances.  
1.3 Annex A1 provides a modified test method for materials (such as certain amines, halogenated materials, and the like) with large quenching distances which may be difficult to ignite.  
1.4 In other situations where strong ignition sources (such as direct flame ignition) is considered credible, the use of a test method employing higher energy ignition source in a sufficiently large pressure chamber (analogous, for example, to the methods in Test Method E2079 for measuring limiting oxygen concentration) may be more appropriate. In this case, expert advice may be necessary.  
1.5 The flammability limits depend on the test temperature and pressure. This test method is limited to an initial pressure of the local ambient or less, with a practical lower pressure limit of approximately 13 kPa (100 mm Hg). The maximum practical operating temperature of this equipment is approximately 150 °C.  
1.6 The values stated in SI units are to be regarded as standard. No other units of measuremen...

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ASTM E1382-97(2023)(Test Method)
Standard Test Methods for Determining Average Grain Size Using Semiautomatic and Automatic Image Analysis

SIGNIFICANCE AND USE
5.1 These test methods cover procedures for determining the mean grain size, and the distribution of grain intercept lengths or grain areas, for polycrystalline metals and nonmetallic materials with equiaxed or deformed grain shapes, with uniform or duplex grain size distributions, and for single phase or multiphase grain structures.  
5.2 The measurements are performed using semiautomatic digitizing tablet image analyzers or automatic image analyzers. These devices relieve much of the tedium associated with manual measurements, thus permitting collection of a larger amount of data and more extensive sampling which will produce better statistical definition of the grain size than by manual methods.  
5.3 The precision and relative accuracy of the test results depend on the representativeness of the specimen or specimens, quality of specimen preparation, clarity of the grain boundaries (etch technique and etchant used), the number of grains measured or the measurement area, errors in detecting grain boundaries or grain interiors, errors due to detecting other features (carbides, inclusions, twin boundaries, and so forth), the representativeness of the fields measured, and programming errors.  
5.4 Results from these test methods may be used to qualify material for shipment in accordance with guidelines agreed upon between purchaser and manufacturer, to compare different manufacturing processes or process variations, or to provide data for structure-property-behavior studies.
SCOPE
1.1 These test methods are used to determine grain size from measurements of grain intercept lengths, intercept counts, intersection counts, grain boundary length, and grain areas.  
1.2 These measurements are made with a semiautomatic digitizing tablet or by automatic image analysis using an image of the grain structure produced by a microscope.  
1.3 These test methods are applicable to any type of grain structure or grain size distribution as long as the grain boundaries can be clearly delineated by etching and subsequent image processing, if necessary.  
1.4 These test methods are applicable to measurement of other grain-like microstructures, such as cell structures.  
1.5 This standard deals only with the recommended test methods and nothing in it should be construed as defining or establishing limits of acceptability or fitness for purpose of the materials tested.  
1.6 The sections appear in the following order:    
Section  
Section  
Scope  
1  
Referenced Documents  
2  
Terminology  
3  
Definitions  
3.1  
Definitions of Terms Specific to This Standard  
3.2  
Symbols  
3.3  
Summary of Test Method  
4  
Significance and Use  
5  
Interferences  
6  
Apparatus  
7  
Sampling  
8  
Test Specimens  
9  
Specimen Preparation  
10  
Calibration  
11  
Procedure:  
Semiautomatic Digitizing Tablet  
12  
Intercept Lengths  
12.3  
Intercept and Intersection Counts  
12.4  
Grain Counts  
12.5  
Grain Areas  
12.6  
ALA Grain Size  
12.6.1  
Two-Phase Grain Structures  
12.7  
Procedure:  
Automatic Image Analysis  
13  
Grain Boundary Length  
13.5  
Intersection Counts  
13.6  
Mean Chord (Intercept) Length/Field  
13.7.2  
Individual Chord (Intercept) Lengths  
13.7.4  
Grain Counts  
13.8  
Mean Grain Area/Field  
13.9  
Individual Grain Areas  
13.9.4  
ALA Grain Size  
13.9.8  
Two-Phase Grain Structures  
13.10  
Calculation of Results  
14  
Test Report  
15  
Precision and Bias  
16  
Grain Size of Non-Equiaxed Grain Structure Specimens  
Annex A1  
Examples of Proper and Improper Grain Boundary Delineation  
Annex A2  
1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental pra...

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ASTM G125-00(2023)(Test Method)
Standard Test Method for Measuring Liquid and Solid Material Fire Limits in Gaseous Oxidants

SIGNIFICANCE AND USE
5.1 This test method provides for measuring of the minimum conditions of a range of parameters (concentration of oxidant in a flowing mixture of oxidant and diluent, pressure, temperature) that will just support sustained propagation of combustion. For materials that exhibit flaming combustion, this is a flammability limit similar to the lower flammability limit, upper flammability limit, and minimum oxidant for combustion of gases (1).4 However, unlike flammability limits for gases, in two-phase systems, the concept of upper and lower flame limits is not meaningful. However, limits can typically be determined for variations in other parameters such as the minimum oxidant for combustion (the oxidant index), the pressure limit, the temperature limit, and others. Measurement and use of these data are analogous to the measurement and use of the corresponding data for gaseous systems. That is, the limits apply to systems likely to experience complete propagations (equilibrium combustion). Successful ignition and combustion below the measured limits at other conditions or of a transient nature are not precluded below the threshold. Flammability limits measured at one set of conditions are not necessarily the lowest thresholds at which combustion can occur. Therefore direct correlation of these data with the burning characteristics under actual use conditions is not implied.
SCOPE
1.1 This test method covers a procedure for measuring the threshold-limit conditions to allow equilibrium of combustion of materials in various oxidant gases under specific test conditions of pressure, temperature, flow condition, fire-propagation directions, and various other geometrical features of common systems.  
1.2 This test method is patterned after Test Method D2863-95 and incorporates its procedure for measuring the limit as a function of oxidant concentration for the most commonly used test conditions. Sections 8, 9, 10, 11, 13, and  for the basic oxidant limit (oxygen index) procedure are quoted directly from Test Method D2863-95. Oxygen index data reported in accordance with Test Method D2863-95 are acceptable substitutes for data collected with this standard under similar conditions.  
1.3 This test method has been found applicable to testing and ranking various forms of materials. It has also found limited usefulness for surmising the prospect that materials will prove “oxygen compatible” in actual systems. However, its results do not necessarily apply to any condition that does not faithfully reproduce the conditions during test. The fire limit is a measurement of a behavioral property and not a physical property. Uses of these data are addressed in Guides G63 and G94.  
Note 1: Although this test method has been found applicable for testing a range of materials in a range of oxidants with a range of diluents, the accuracy has not been determined for many of these combinations and conditions of specimen geometry, outside those of the basic procedure as applied to plastics.
Note 2: Test Method D2863-95 has been revised and the revised Test Method has been issued as D2863-97. The major changes involve sample dimensions, burning criteria and the method for determining the oxygen index. The aim of the revisions was to align Test Method D2863 with ISO 4589-2. Six laboratories conducted comparison round robin testing on self-supporting plastics and cellular materials using D2863-95 and D2863-97. The results indicate that there is no difference between the means provided y the two methods at the 95 % confidence level. No comparison tests were conducted on thin films. The majority of ASTM Committee G4 favors maintaining the D2863-95 as the backbone of G125 until comprehensive comparison data become available.  
1.4 One very specific set of test conditions for measuring the fire limits of metals in oxygen has been codified in Test Method G124. Test Method G124 measures the minimum pressure limit in oxygen fo...

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