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ASTM D3513-02(2007)

(Test Method)

Standard Test Method for Overlength Fiber Content of Manufactured Staple Fiber

Standard Test Method for Overlength Fiber Content of Manufactured Staple Fiber

SCOPE
1.1 This test method covers the determination of the percent by number of overlength or multiple length fibers in a sample of manufactured cut staple. The method is applicable to fiber taken immediately after manufacturing, from the bale, or from partially processed stock. Note 1 - For measurement of length and length distribution of manufactured staple fibers, refer to Test Method D 5103.
1.2 This test method covers procedures using the Fibrosampler Model 335A (inch-pound units), the Fibrosampler Model 335B (SI units), and Fibrosampler combs Model 336.
1.2.1 The Fibrosampler Model 335A is equipped with a sample plate that has 15.8-mm (5/8-in.) diameter sample holes and is recommended for use on blended staple taken from the fiber blender or from a carding machine.
1.2.2 The Fibrosampler Model 335B is equipped with a sample plate that has 10-mm (0.4-in.) diameter sample holes and is recommended for use on unblended staple as may be taken from the fiber cutter or from a bale of staple fiber.
1.3 The values stated in either SI units or inch-pound units are to be regarded separately as the standard. The values stated in each unit are not exact equivalents; therefore, each unit must be used independently of the other.
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 and health practices and determine the applicability of regulatory limitations prior to use.

General Information

Status
Historical
Publication Date
30-Jun-2007
ICS
59.060.20 - Man-made fibres
Technical Committee
D13 - Textiles
Drafting Committee
D13.58 - Yarns and Fibers
Current Stage
Ref Project

Relations

Replaces
ASTM D3513-02 - Standard Test Method for Overlength Fiber Content of Man-Made Staple Fiber
Effective Date
01-Jul-2007
Replaced By
ASTM D3513-02(2012) - Standard Test Method for Overlength Fiber Content of Manufactured Staple Fiber
Effective Date
01-Jul-2012
Referred By
ASTM D4849-21 - Standard Terminology Related to Yarns and Fibers
Effective Date
01-Jul-2007
Referred By
ASTM D5103-07(2018) - Standard Test Method for Length and Length Distribution of Manufactured Staple Fibers (Single-Fiber Test)
Effective Date
01-Jul-2007

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ASTM D3513-02(2007) - Standard Test Method for Overlength Fiber Content of Manufactured Staple FiberASTM D3513-02(2007) - Standard Test Method for Overlength Fiber Content of Manufactured Staple Fiber
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ASTM D3513-02(2007) - Standard Test Method for Overlength Fiber Content of Manufactured Staple Fiber
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation:D3513–02 (Reapproved 2007)
Standard Test Method for
Overlength Fiber Content of Manufactured Staple Fiber
This standard is issued under the fixed designation D3513; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope Cotton Fibers by Photoelectric Measurement
D2258 Practice for Sampling Yarn for Testing
1.1 This test method covers the determination of the percent
D3333 Practice for Sampling Manufactured Staple Fibers,
by number of overlength or multiple length fibers in a sample
Sliver, or Tow for Testing
of manufactured cut staple. The method is applicable to fiber
D3888 Terminology for Yarn Spinning Systems
taken immediately after manufacturing, from the bale, or from
D3990 Terminology Relating to Fabric Defects
partially processed stock.
D4849 Terminology Related to Yarns and Fibers
NOTE 1—For measurement of length and length distribution of manu-
D5103 Test Method for Length and Length Distribution of
factured staple fibers, refer to Test Method D5103.
Manufactured Staple Fibers (Single-Fiber Test)
1.2 This test method covers procedures using the Fibrosam-
3. Terminology
pler Model 335A (inch-pound units), the Fibrosampler Model
335B (SI units), and Fibrosampler combs Model 336.
3.1 Definitions:
1.2.1 The Fibrosampler Model 335A is equipped with a
3.1.1 For definitions of textile terms used in this test
sample plate that has 15.8-mm ( ⁄8-in.) diameter sample holes
method: fiber beard, staple, overlength staple fibers and
and is recommended for use on blended staple taken from the
multiple-length staple fibers, refer to Terminology D4849.
fiber blender or from a carding machine.
3.1.2 For definitions of other textile terms used in this test
1.2.2 The Fibrosampler Model 335B is equipped with a
method, refer to Terminologies D123, D3888, D3990, and
sample plate that has 10-mm (0.4-in.) diameter sample holes
D4849.
and is recommended for use on unblended staple as may be
4. Summary of Test Method
taken from the fiber cutter or from a bale of staple fiber.
1.3 The values stated in either SI units or inch-pound units
4.1 Fibers are caught randomly on a comb to form a fiber
are to be regarded separately as the standard. The values stated
beard. The probability that a given fiber length group repre-
in each unit are not exact equivalents; therefore, each unit must sented in the original fiber population will appear in the test
be used independently of the other.
specimen is proportional to the ratio of the total length of that
1.4 This standard does not purport to address all of the fiber length group to the total fiber length of the original
safety concerns, if any, associated with its use. It is the
sample. The beard is biased in the favor of long fibers.
responsibility of the user of this standard to establish appro- 4.2 The fiber beard is brushed out and laid on a specimen
priate safety and health practices and determine the applica-
board.The density of the beard of the cut staple tapers to a line
bility of regulatory limitations prior to use. that is parallel to the base of the comb. The overlength fibers
are observed to extend beyond this line and they can be
2. Referenced Documents
identified easily.
2.1 ASTM Standards:
4.3 The noticeably longer fibers are pulled from the fiber
D123 Terminology Relating to Textiles
beard, verified for over- or multiple-length and counted. The
D1447 Test Method for Length and Length Uniformity of
result is then expressed as the percent overlength and percent
multiple-length fiber in the original population.
This test method is under the jurisdiction ofASTM Committee D13 onTextiles 5. Significance and Use
and is the direct responsibility of Subcommittee D13.58 on Yarns and Fibers.
5.1 The existence of overlength fiber in manufactured staple
Current edition approved July 1, 2007. Published August 2007. Originally
can cause serious problems in the spinning of these fibers into
approved in 1976. Last previous edition approved in 2002 as D3513 – 02. DOI:
10.1520/D3513-02R07.
yarn. Overlength fibers may create problems in carding, but
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
more especially high-strength multiple cut fibers may cause
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
cockling in spinning.
Standards volume information, refer to the standard’s Document Summary page on
the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
D3513–02 (2007)
tance. As a minimum, use the samples for such a comparative
teststhatareashomogeneousaspossible,drawnfromthesame
lot of material as the samples that resulted in disparate results
during initial testing and randomly assigned in equal numbers
to each laboratory. The test results from the laboratories
involved should be compared using a statistical test for
unpaired data, a probability level chosen prior to the testing
series. If a bias is found, either its cause must be found and
corrected, or future test results for that material must be
adjusted in consideration of the known bias.
6. Apparatus
6.1 Fibrosampler, Model 335Aof 335B (Fig. 1), equipped
with the following:
6.1.1 Combs, Model 336 (Fig. 2).
6.1.2 Spacing Gage.
6.1.3 Specimen Board, board covered with short pile or
FIG. 1 Fibrosampler
plush surface on one side, for displaying the test specimen.
6.1.4 Brush, for brushing the test specimen.
6.1.5 Tweezers, for removing the long fibers from the
specimen board for verification.
NOTE 2—Fibrosampler Model 192, which is used for sampling cotton,
(Method D1447) has been used successfully with this method, but the
above listed models and combs yield better results because long fibers are
less likely to be pulled from the combs during beard preparation.
6.2 Laboratory Carding Machine or Opener/Blender
Model 338 is needed for use with Fibrosampler Model 335A.
6.3 Analytical Balance, capable of weighing the specimen
to within 0.01 % of its mass.
6.4 Scale, graduated to the nearest 1 mm ( ⁄16-in.).
7. Sampling
7.1 Lot Sampling—As a lot sample for acceptance testing,
FIG. 2 Fibrosampler Combs
take at random the number of shipping containers directed in
the applicable material specification or other agreement be-
tween the purchaser and supplier, such as an agreement to use
5.2 Since the overlength fibers are caused by dull or
Practice D3333 or Practice D2258. Consider shipping contain-
damaged cutting knives or by uneven flow of tow to the staple
ers to be the primary sampling units.
cutter,theirexistencewithinthefiberpopulationisnotuniform
NOTE 3—An adequate specification or other agreement between the
and their occurrence in the population follows a highly skewed
purchaser or supplier requires taking into account the variability between
distribution.
shipping units, between packages, ends or other laboratory sampling unit
5.3 Manual methods of determining overlength fiber require
within a shipping unit if applicable, and within specimens from a single
much more operator time, and the standard deviations of the
package, end or other laboratory sampling unit to provide a sampling plan
test between laboratories and operators are high. Use of the
with a meaningful producer’s risk, consumer’s risk, acceptable quality
Fibrosampler method greatly reduces both operator time and
level, and limiting quantity level.
standard deviation of testing.
7.2 Laboratory Sample—As a laboratory sample for accep-
5.4 In manufacturing it is important to know if fibers are
tance testing, take at random from each shipping container in
overlength due to looping of the tow or multiple length due to
the lot sample the number of laboratory sampling units as
damaged cutters.
directed in an applicable material specification or other agree-
5.5 This method for testing staple fiber for overlength fiber
ment between purchaser and supplier such as an agreement to
is not recommended for acceptance testing (see 13.1).
use Practice D3333 or Practice D2258. Preferably, the same
5.5.1 Insomecasesthepurchaserandthesuppliermayhave
number of laboratory sampling units are taken from each
totestacommercialshipmentofoneormorespecificmaterials
by the best available method, even though the method has not
been recommended for acceptance testing of commercial
The sole source of supply of the apparatus known to the committee at this time
is Special Instruments Laboratory, Inc., 312 W. Vine Ave., P.O. Box 1950,
shipments. If there are differences of practical significance
Knoxville, TN. 37901. If you are aware of alternative suppliers, please provide this
between reported test results for two laboratories (or more),
information to ASTM International Headquarters. Your comments will receive
comparative test should be performed to determine if there is a
careful consideration at a meeting of the responsible technical committee, which
statistical bias between them, using competent statistical assis- you may attend.
D3513–02 (2007)
shipping container in the lot sample. If differing numbers of of the sample plate. Then relax the hand pressure against the
laboratory sampling units are to be taken from shipping plate to prevent fiber damage or breakage.
containers in the lot sample, determine at random which 8.5.4 With the right hand, turn the pivot arm one complete
shippingcontainersaretohaveeachnumberoflaboratoryunits counterclockwise revolution. This carries the comb teeth
drawn. across the face of the protruding test sample and allows a
7.2.1 Take 100-g samples of staple fiber, sliver or top for segment of the fiber beard to form on the comb. See Note 4.
8.5.5 Ease
...

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Standard Test Methods for Breaking Tenacity of Manufactured Textile Fibers in Loop or Knot Configurations

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Standard Test Method for Overlength Fiber Content of Manufactured Staple Fiber

SIGNIFICANCE AND USE
5.1 The existence of overlength fiber in manufactured staple can cause serious problems in the spinning of these fibers into yarn. Overlength fibers may create problems in carding, but more especially high-strength multiple cut fibers may cause cockling in spinning.  
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1.2.1 The Fibrosampler Model 335A is equipped with a sample plate that has 15.8-mm (5/8-in.) diameter sample holes and is recommended for use on blended staple taken from the fiber blender or from a carding machine.  
1.2.2 The Fibrosampler Model 335B is equipped with a sample plate that has 10-mm (0.4-in.) diameter sample holes and is recommended for use on unblended staple as may be taken from the fiber cutter or from a bale of staple fiber.  
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ABSTRACT
This specification covers polyolefin monofilament yarn materials, and test methods for standard polyolefin monofilaments. The direct yarn number in tex or in denier, tensile properties in terms of breaking force, breaking tenacity, elongation at break and initial modulus shall be determined from a sample material. The width, thickness, gloss, hot water shrinkage, resistance to ultraviolet radiation, stability to thermal oxidation and cleanliness of the material shall also be analyzed.
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SIGNIFICANCE AND USE
5.1 This test method for the determination of crimp frequency of manufactured staple fibers may be used for the acceptance testing of commercial shipments but caution is advised since between-laboratory precision is known to be poor. Comparative tests conducted as directed in 5.1.1 may be advisable.  
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ASTM D3333-07(2018)(Practice)
Standard Practice for Sampling Manufactured Staple Fibers, Sliver, or Tow for Testing

SIGNIFICANCE AND USE
5.1 Assigning a value to any property of the material in a container or in a lot, consignment, or delivery involves a measurement process that includes both sampling and testing procedures. The correctness of the value assigned depends upon the variability due to testing. Even when the variability due to testing is minimized by carefully developed procedures, correct and consistent estimates of the true value of the property are possible only when the sampling procedure avoids systematic bias, minimizes variations due to sampling, and provides a laboratory sample of adequate size.  
5.2 This practice may not give the most efficient sampling plan that might be devised in special situations but it does present a general procedure that gives satisfactory precision with an economical amount of sampling and one which does not require elaborate statistical computation based on previous knowledge of the amount of variation between lot samples, between laboratory samples, and between test specimens.  
5.3 The smallest number of specimens required for a given variability in the average result will usually be obtained by (1) minimizing the number of shipping units in the lot sample, (2) taking one of the shipping units in the laboratory sample, and (3) taking the prescribed specimen(s) from the selected laboratory sample shipping unit. (See 7.3 and 7.4.)  
5.4 To minimize the cost of sampling a lot of material, it is necessary to agree on the required variance for the reported average for a lot of material:  
5.4.1 Estimate the variance due to lot samples, the variance due to laboratory samples, and the variance due to test specimens.  
5.4.2 Calculate the total variance for the average test results for several combinations of the number of lot samples, the number of laboratory samples per lot sample, and the number of test specimens per laboratory sample.  
5.4.3 Calculate the cost of performing each of the sampling schemes considered in 5.4.2.  
5.4.4 Select the samp...
SCOPE
1.1 This practice covers a procedure for the division of shipments of manufactured staple fiber, sliver (or top) or tow into lots and the sampling of such lots for testing.  
Note 1: For sampling yarns, refer to Practice D2258.
Note 2: This practice differs from BISFA2 rules for staple fibers in the lot sampling, by the elimination of separate sampling of outer versus inner container areas, in the reduction of number of strata from 6 to 5, and by the elimination of compositing to obtain a single laboratory sample for the lot when testing properties which do not depend on as-received moisture content.  
1.2 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.  
1.3 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 D7138-16(Test Method)
Standard Test Method to Determine Melting Temperature of Synthetic Fibers

SIGNIFICANCE AND USE
5.1 Either of these two test methods is used to determine the temperature at which a synthetic fiber specimen changes from a solid to a liquid-like state.  
5.1.1 Synthetic fibers may be either amorphous or semi-crystalline thermoplastics or thermosets. Synthetic fibers may change from the solid to a liquid-like state on heating because of the glass transition of amorphous polymers, the melting of crystalline regions of semi-crystalline polymers, or at the onset of degradation. Thermoplastic fibers consist of crystalline and amorphous regions and may be manufactured with a range of molecular weights. The amorphous and crystalline fiber structure and variable molecular weight can lead to a melting temperature range instead of a discreet melting point (see Table X1.1).  
5.2 This test method is considered satisfactory for acceptance testing of commercial shipments.  
5.2.1 If there are differences of practical significance between reported test results for two or more laboratories, perform comparative testing to determine if there is a statistical bias between them, using competent statistical assistance. As a minimum, use the samples for such a comparative test that are as homogeneous as possible, drawn from the same lot of material as the samples that resulted in disparate results during initial testing and randomly assigned in equal numbers to each laboratory. Compare the test results from the laboratories involved using a statistical test for unpaired data, at a probability level chosen prior to the testing series. If bias is found, either its cause must be found and corrected, or future test results for that material must be adjusted in consideration of the known bias.  
5.3 This test method is suitable for quality control testing of synthetic fibers and product comparisons of different fibers by manufacturers, retailers, and users.  
5.4 If the test method is used to identify fiber material type, it is important to test a known reference material at the s...
SCOPE
1.1 Either of two test methods are used to determine the melting temperature of thermoplastic fibers, yarns, or threads.  
1.2 Method 1 can be used to determine melting temperatures for blends of multiple fiber material types. Method 2 can only be used to determine the melting temperature of a single fiber material type.  
1.2.1 Method 1, Differential Scanning Calorimetry (DSC), measures changes in heat capacity and will detect the glass transition, the crystalline melting and endothermic thermal degradation.  
1.2.2 Method 2, a visual determination of melting, determines any change that visually appears as a transition from a solid to a liquid state.  
1.2.3 Due to the differences in what each test method measures, the results from Method 1 and Method 2 cannot be compared.  
1.3 The values stated in either SI units or other units are to be regarded separately. The values stated in each system are not exact equivalents; therefore, each system shall be used independently without combining values.  
1.4 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 and health practices and determine the applicability of regulatory limitations prior to use.

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ASTM
ASTM D3217/D3217M-20(Test Method)
Standard Test Methods for Breaking Tenacity of Manufactured Textile Fibers in Loop or Knot Configurations

SIGNIFICANCE AND USE
5.1 Both the loop breaking tenacity and the knot breaking tenacity, calculated from the breaking force measured under the conditions specified herein and the linear density of the fiber, are fundamental properties that are used to establish limitations on fiber-processing and upon their end-use applications. Physical properties, such as brittleness, not well defined by tests for breaking force and elongation can be estimated from the ratio of breaking tenacity measured in loop or knot tests, or both, and the normal tenacity as measured by Test Method D3822 provided both methods use the same gauge length and strain rate.  
5.2 This test method is not recommended for acceptance testing of commercial shipments in the absence of reliable information on between-laboratory precision (see Note 3). In some cases the purchaser and the supplier may have to test a commercial shipment of one or more specific materials by the best available method, even though the method has not been recommended for acceptance testing of commercial shipments. In such a case, if there is a disagreement arising from differences in values reported by the purchaser and the supplier when using this test method for acceptance testing, the statistical bias, if any, between the laboratory of the purchaser and the laboratory of the supplier should be determined with each comparison being based on testing specimens randomly drawn from one sample of material of the type being evaluated.
SCOPE
1.1 These test methods cover the measurement of the breaking tenacity of manufactured textile fibers taken from filament yarns, staple, or tow fiber, either crimped or uncrimped, and tested in either a double loop or as a strand formed into a single overhand knot.  
1.2 Methods for measuring the breaking tenacity of conditioned and wet (immersed) fibers in loop and knot form are included.  
1.3 Elongation in loop or knot tests has no known significance, and is usually not recorded.  
1.4 The basic distinction between the procedures described in these test methods and those included in Test Methods D2101 is the configuration of the specimen, that is, either as a double loop or in the configuration of a single overhand knot.  
1.5 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system are not necessarily exact equivalents; therefore, to ensure conformance with the standard, each system shall be used independently of the other, and values from the two systems shall not be combined.  
1.6 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.  
1.7 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
ASTM E2058-19(Test Method)
Standard Test Methods for Measurement of Material Flammability Using a Fire Propagation Apparatus (FPA)

SIGNIFICANCE AND USE
5.1 These test methods are an integral part of existing test standards for cable fire propagation and clean room material flammability, as well as, in an approval standard for conveyor belting (1-3).3 Refs (1-3) use these test methods because fire-test-response results obtained from the test methods correlate with fire behavior during real-scale fire propagation tests, as discussed in X1.4.  
5.2 The Ignition, Combustion, or Fire Propagation test method, or a combination thereof, have been performed with materials and products containing a wide range of polymer compositions and structures, as described in X1.7.  
5.3 The Fire Propagation test method is different from the test methods in the ASTM standards listed in 2.1 by virtue of producing laboratory measurements of the chemical heat release rate during upward fire propagation and burning on a vertical test specimen in normal air, oxygen-enriched air, or in oxygen-vitiated air. Test methods from other standards, for example, Test Method E1321, which yields measurements during lateral/horizontal or downward flame spread on materials and Test Methods E906, E1354, and E1623, which yield measurements of the rate of heat release from materials fully involved in flaming combustion, generally use an external radiant flux, rather than the flames from the burning material itself, to characterize fire behavior.  
5.4 These test methods are not intended to be routine quality control tests. They are intended for evaluation of specific flammability characteristics of materials. Materials to be analyzed consist of specimens from an end-use product or the various components used in the end-use product. Results from the laboratory procedures provide input to fire propagation and fire growth models, risk analysis studies, building and product designs, and materials research and development.
SCOPE
1.1 This fire-test-response standard determines and quantifies material flammability characteristics, related to the propensity of materials to support fire propagation, by means of a fire propagation apparatus (FPA). Material flammability characteristics that are quantified include time to ignition (tign), chemical ( Q˙chem), and convective ( Q˙c) heat release rates, mass loss rate ( m˙) and effective heat of combustion (EHC).  
1.2 The following test methods, capable of being performed separately and independently, are included herein:  
1.2.1 Ignition Test, to determine tign  for a horizontal specimen;  
1.2.2 Combustion Test, to determine  Q˙chem,  Q˙c,  m˙, and EHC from burning of a horizontal specimen; and,  
1.2.3 Fire Propagation Test, to determine  Q˙chem  from burning of a vertical specimen.  
1.3 Distinguishing features of the FPA include tungsten-quartz external, isolated heaters to provide a radiant flux of up to 110 kW/m2 to the test specimen, which remains constant whether the surface regresses or expands; provision for combustion or upward fire propagation in prescribed flows of normal air, air enriched with up to 40 % oxygen, air oxygen vitiated, pure nitrogen or mixtures of gaseous suppression agents with the preceding air mixtures; and, the capability of measuring heat release rates and exhaust product flows generated during upward fire propagation on a vertical test specimen 0.305 m high.  
1.4 The FPA is used to evaluate the flammability of materials and products. It is also designed to obtain the transient response of such materials and products to prescribed heat fluxes in specified inert or oxidizing environments and to obtain laboratory measurements of generation rates of fire products (CO2, CO, and, if desired, gaseous hydrocarbons) for use in fire safety engineering.  
1.5 Ignition of the specimen is by means of a pilot flame at a prescribed location with respect to the specimen surface.  
1.6 The Fire Propagation test of vertical specimens is not suitable for materials that, on heating, melt sufficiently to form a liquid pool...

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ASTM
ASTM D3218-07(2018)(Specification)
Standard Specification for Polyolefin Monofilaments

ABSTRACT
This specification covers polyolefin monofilament yarn materials, and test methods for standard polyolefin monofilaments. The direct yarn number in tex or in denier, tensile properties in terms of breaking force, breaking tenacity, elongation at break and initial modulus shall be determined from a sample material. The width, thickness, gloss, hot water shrinkage, resistance to ultraviolet radiation, stability to thermal oxidation and cleanliness of the material shall also be analyzed.
SIGNIFICANCE AND USE
6.1 Acceptance Testing—The test methods in Specification D3218 for the determination of the properties of polyolefin monofilaments are considered satisfactory for acceptance testing of commercial shipments of polyolefin monofilaments, unless specified in the individual test method. These test methods are the best available and are used extensively in the trade.  
6.1.1 If there are differences or practical significance between reported test results for two laboratories (or more) comparative test should be performed to determine if there is a statistical bias between them, using competent statistical assistance. As a minimum, test samples that are as homogeneous as possible, drawn from the material from which the disparate test results were obtained, and randomly assigned in equal numbers to each laboratory for testing. The test results from the two laboratories should be compared using a statistical test for unpaired data, at a probability level chosen prior to the testing series. If a bias is found either its cause must be found and corrected or future test results for that material must be adjusted in consideration of the known bias.
SCOPE
1.1 This specification covers polyolefin monofilament yarn materials, and test methods for standard polyolefin monofilaments. While designed primarily for testing standard polyolefin monofilaments, many of the procedures can be used, with little or no modification, for other polyolefin monofilaments. However, testing on non-standard polyolefin monofilaments should be conducted with caution. See 3.1 for a definition of standard polyolefin monofilament.  
1.2 Only on condition that interlaboratory precision data are available for the specific procedure is any test method described, or referenced in this specification, recommended for acceptance testing of commercial shipments of polyolefin monofilaments.  
1.3 The specification for polyolefin raw materials appears in Section 4.  
1.4 The test methods for individual properties appear in the following sections:    
Property  
Section  
Breaking Force  
10    
Breaking Tenacity  
10    
Elongation  
10    
Gloss  
13    
Hot Water Shrinkage  
14    
Initial Modulus  
10    
Polyolefin-Material Cleanliness  
17    
Resistance to Ultraviolet Radiation  
15    
Stability to Thermal Oxidation  
16    
Tensile Properties  
10    
Thickness  
12    
Width  
11    
Yarn Number  
9
Note 1: In most instances, the suitability of these procedures for polymeric yarns in general, and polyolefin monofilaments in particular, is already accepted in commercial transactions (see 6.1).  
1.5 The values stated in SI units are to be regarded as standard; the values in English units are provided as information only and are not exact equivalents.  
1.6 The following safety hazards caveat pertains only to the test methods described in this specification: This standard may involve hazardous materials, operations, and equipment. This standard does not purport to address all of the safety problems, 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.  
1.7 This international standard was developed in accordance with internationally recognized principles on ...

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