Designation:D3886–99An American National Standard Standard Test Method for
Abrasion Resistance of Textile Fabrics(Inflated Diaphragm Apparatus)1
This standard is issued under thefixed designation D3886;the number immediately following the designation indicates the year of
original adoption or,in the ca of revision,the year of last revision.A number in parenthes indicates the year of last reapproval.A
superscript epsilon(e)indicates an editorial change since the last revision or reapproval.
1.Scope
1.1This test method2covers the determination of the resistance to abrasion of woven and knitted textile fabrics,both conditioned and wet,using the inflated diaphragm tester.This procedure is not applicable tofloor coverings.
N OTE1—Other procedures for measuring the abrasion resistance of textile fabrics are given in Test Methods D3884,D3885,D1175,and AATCC Test Method93.
1.2The values stated in SI units are to be regarded as standard;the values in English units are provided as informa-tion only and are not exact equivalents.
1.3This standard does not purport to address all of the safety concerns,if any,associated with its u.It is the responsibility of the ur of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to u.
2.Referenced Documents
2.1ASTM Standards:
D123Terminology Relating to Textiles3
D1776Practice for Conditioning Textiles for Testing3
D2904Practice for Interlaboratory Testing of a Textile Test Method that Produces Normally Distributed Data3
D2906Practice for Statements on Precision and Bias for Textiles3swing是什么意思
D3884Test Method for Abrasion Resistance of Textile Fabrics(Rotary Platform,Double Head Method)4
D3885Test Method for Abrasion Resistance of Textile Fabrics(Flexing and Abrasion Method)4
D4157Test Method for Abrasion Resistance of Textile Fabrics(Oscillatory Cylinder Method)4
2.2AATCC Standard:
Test Method93Abrasion Resistance of Fabrics:Accelerator Method5
3.Terminology
3.1Definitions:
3.1.1abrasion,n—the wearing away of any part of a material by rubbing against another surface.
3.1.2For definitions of other textile terms ud in this test method,refer to Terminology D123.
4.Summary of Test Method
4.1A specimen is abraded by rubbing either unidirection-ally or multidirectionally against an abradant having specified surface characteristics.A specimen is held in afixed position and supported by an inflated rubber diaphragm which is held under constant pressure.A specimen is abraded by rubbing either unidirectionally or multidirectionally against an abradant having specified surface characteristics.The resistance to abrasion is determined using Option1,the number of cycles to wear a hole in the specimen,or Option2,visual asssment of the specimen surface after a specified number of cycles.
5.Significance and U
5.1The measurement of the resistance to abrasion of textile and other materials is very complex.The resistance to abrasion is affected by many factors,such as the inherent mechanical properties of thefibers;the dimensions of thefibers;the structure of the yarns;the construction of the fabrics;and the type,kind,and amount offinishing material added to thefibers, yarns,or fabric.
the shadow
5.2The resistance to abrasion is also greatly affected by the conditions of the tests,such as the nature of abradant,variable action of the abradant over the area of specimen abraded,the tension of the specimen,the pressure between the specimen and abradant,and the dimensional changes in the specimens.
5.3Abrasion tests are all subject to variation due to changes in the abradant during specific tests.The abradant must accordingly be discarded at frequent intervals or checked periodically against a standard.With disposable abradants,the abradant is ud only once or discarded after limited u.With
1This test method is under the jurisdiction of ASTM Committee D-13on Textiles and is the direct responsibility of Subcommittee D13.60on Fabric Test Methods, Specific.
Current edition approved June10,1999.Published September1999.Originally published as D3886–80.Last previous edition D3886–92.
2This test method is bad upon the development described by R.G.Stoll,in “Improved Multipurpo Abrasion Test and Its Application for the Wear Resistance of Textiles,”Textile Rearch Journal,July1949,p.394.
3Annual Book of ASTM Standards,V ol07.01. 4Annual Book of ASTM Standards,V ol07.02.
5Available from American Association of Textile Chemists and Colorists,P.O.
Box12215,Rearch Triangle Park,NC27709.
1
Copyright©ASTM International,100Barr Harbor Drive,PO Box C700,West Conshohocken,PA19428-2959,United States.
permanent abradants that u hardened metal or equivalent surfaces,it is assumed that the abradant will not change appreciably in a specific ries of tests.Similar abradants ud in different laboratories will not change at the same rate,due to differences in usage.Permanent abradants may also change due to pick up of finishing or other material from test fabrics and must accordingly be cleaned at frequent intervals.The mea-surement of the relative amount of abrasion may also be affected by the method of evaluation and may be influenced by the judgment of the operator.5.4The resistance of textile materials to abrasion as mea-sured on a testing machine in the laboratory is generally only one of veral factors contributing to wear performance or durability as experienced in
the actual u of the material.While “abrasion resistance”(often stated in terms of the number of cycles on a specified machine,using a specified technique to produce a specified degree or amount of abrasion)and “durability”(defined as the ability to withstand deteriora-tion or wearing out in u,including the effects of abrasion)are frequently related,the relationship varies with different end us,and different factors may be necessary in any calculation of predicted durability from specific abrasion data.Laboratory tests may be reliable as an indication of relative end-u performance in cas where the difference in abrasion resis-tance of various materials is large,but they should not be relied upon where differences in laboratory test findings are small.In general,they should not be relied upon for prediction of actual wear-life in specific end us unless there are data showing the specific relationship between laboratory abrasion tests and actual wear in the intended end-u.
5.5The general obrvations apply to all types of fabrics,including woven,nonwoven,and knit apparel fabrics,hou-hold fabrics,industrial fabrics,and floor coverings.It is not surprising,therefore,to find that there are many different types of abrasion testing machines,abradants,testing conditions,testing procedures,methods of evaluation of abrasion resis-tance and interpretation of results.
5.6All the test methods and instruments so far developed for measuring abrasion resistance may sh
后会有期的意思
ow a high degree of variability in results obtained by different operators and in different laboratories;however,they reprent the test methods now most widely in u.
5.7Becau there is a definite need for measuring the relative resistance to abrasion,standardized test methods are needed and uful and may clarify the problem and lesn the confusion.
广州甜品培训
5.8Becau of the conditions mentioned above,technicians frequently fail to get good agreement between results obtained on the same type of testing instrument both within and between laboratories,and the precision of the test methods is uncer-tain.
5.9Test Method D 3886is not recommended for acceptance testing of commercial shipment becau of the poor between-laboratory precision.
5.9.1In cas of a dispute arising from differences in reported test results when using this test method for acceptance testing of commercial shipments,the purchar and the sup-plier should conduct comparative tests to determine if there is a statistical bias between their laboratories.Competent statis-tical assistance is recommended for the investigation of bias.As a minimum,the two parties should take a group of test specimens which are as homogeneous as possible and which are from a lot of material of the type in question.The test specimens should then
be randomly assigned in equal
numbers
FIG.1Schematic Diagram of Inflated Diaphragm Abrasion
Testerimperative
to each laboratory for testing.The average results from the two laboratories should be compared using appropriate statistical analysis for unpaired data and an acceptable probability level chon by the two parties before the testing begins.If a bias is found,either its cau must be found and corrected or the purchar and the supplier must agree to interpret future test results in the light of the known bias.
6.Apparatus
6.1Inflated Diaphragm Abrasion Tester ,shown in Fig.16and Fig.2with the following esntial parts:
6.1.1Surface Abrasion Head —The specimen is mounted in a circular clamp over a rubber diaphragm by means of a clamping ring and a tightening collar.The circular opening of the clamping ring is 94.061.3mm (3.7060.05in.)in diameter and that of the collar 95.3mm (3.75in.)or more.The hei
ght from the surface of the clamped-in specimen to the upper edge of the tightening collar shall not exceed 9.5mm (3⁄8in.).The clamping area of the body of the clamp and the ring should have gripping surfaces to prevent slipping of the specimen and leakage of air pressure during the test.Means should be provided for supplying air pressure to the body of the clamp so that the pressure under the diaphragm can be controlled between 0and 41kPa (0and 6psi)with an accuracy of 65%of range.
6.1.2Diaphragm —The rubber diaphragm should be 1.4060.25mm (0.05560.010in.)in thickness.A metallic contact pin 3.2mm (1⁄8in.)in diameter is aled into the center of the diaphragm flush with the diaphragm surface.Provision should be made for a flexible electrical connection from this contact pin to the ground of the machine.The strain distribution on the diaphragm must be uniform so that when inflated without the specimen,it assumes the shape of a ction of a sphere.Pressure can be controlled from 0to 41kPa (0to 6psi).6.1.3Driving Mechanism —The design of the driving mechanism is such that the circular clamp makes a reciprocal motion of 115615double strokes per minute of 25-mm (1-in.)stroke length.Provision shall be made for rotation of the clamp in addition to the reciprocating motion so that one revolution can be completed in 100610double strokes.6.1.4Balance Head and Abradant Plate —The abradant is mounted upon a plate,which is rigidly supported by a double-lever asmbly to provide for free movement in a direction perpendicular to the plane of the r
eciprocating specimen clamp.The abradant plate asmbly should be well balanced to maintain a vertical pressure equivalent to a mass of 0to 2.2kg (0to 5lb)by means of dead weights.Provision should be made to mount different abradants such as abrasive paper,fabrics,etc.,on this plate,and to stretch them into an even position.An electrically insulated contact pin,adjustable to the thickness of the abradant is mounted into this plate on the length axis at one of the turning points of the center of the clamp.
6
The Stoll-Quartermaster has been found suitable and is available from Custom Scientific Instrument,Inc.,13Wing Drive,Whippany,NJ
07981.
FIG.2One Type of Commercial Inflated Diaphragm Abrasion
Tester
6.1.5Some testers can also be equipped with a continuous changing abradant head which is optional.
N OTE2—The machine manufacturer does not provide adequate instruc-tions for the u of the continuous changing abradant head.Work is being done with the manufacturer to write a t of instructions.
6.1.6Machine Stopping Mechanism—Contact between the adjustable pin on the lower side of the abradant plate and the contact pin inrted into the center of the diaphragm clos a low-voltage circuit and stops the machine.
6.1.7Indicators—Means should be provided for indicating the diaphragm pressure,and the number of abrasion cycles(1 cycle=1double stroke).
6.1.8Fig.2shows a commercially available machine that conforms to the requirements of this method.
7.Sampling
7.1Lot Sample—As a lot sample for acceptance testing, take at random the number of rolls of fabric directed in an applicable material specification or other agreement between the purchar and the supplier.Consider rolls of fabric to be the primary sampling unit.
N OTE3—An adequate specification or other agreement between the purchar and the supplier requires taking into account the variability between rolls of fabric and between test specimens from a swatch from a roll of fabric to produce a sampling plan with a meaningful producer’s risk,consumer’s risk,acceptable quality level,and limiting quality level.
7.2Laboratory Sample—Take a laboratory sample from each roll or piece of fabric in the lot sample.The laboratory sample should be full width and at least50cm(approximately 20in.)long and should not be taken any clor to the end of the roll or piece of fabric than1m(1yd).
7.3Test Specimens—Testfive specimens from each labora-tory sampling unit.Cut the specimens112mm(43⁄8in.)in diameter and space them on a diagonal to reprent different machine and cross-machine direction areas of the laboratory sampling units.Take no specimen within one tenth of the fabric width from the edges.
8.Conditioning
8.1Precondition and condition samples or specimens as directed in Practice D1776.Consider equilibruim to have been reached when the increa in mass of the specimen in succes-sive weighings made at intervals of not less than2h does not exceed0.1%of the mass of the specimen.
9.Procedure
9.1Test the specimen in the standard atmosphere for testing textiles,which is7062°F(2161°C)and6562%relative humidity.
9.2Place the specimen over the rubber diaphragm in a smooth condition,clamp the specimen in place without dis-torting it.
9.3Place the abrasive paper or other abradant on the abradant plate under sufficient tension to be held smooth and in such a position that the contact pin,reaching through a hole in the abradant,is even with the surface of the abradant.No.0 emery polishing paper is the standard abradant.The method may be modified to u other abradants but this information should be included in thefinal report.
N OTE4—If the continuous changing abradant head is ud,it should be noted that,although the weight of the head is counter-balanced,the balance changes during u as the paper pass from the back roll to the front roll unless the continuous changing abradant head is ud.
N OTE5—Unless the continuous changing abradant head is ud,it is recommended that the abradant paper be changed at some regular frequency,such as every100to300cycles.As this frequency is dependent upon the type of fabric being tested,the task group is working on devising
a more extensive system.
9.4Set the air pressure under the diaphragm and force on the abradant plate.The air pressure should be28kPa(4psi) and the load on the abradant should be454g(1lb).Be sure that the air pressure control and contact between inflated specimen and loaded abradant is in a state of equilibrium before abrasion is started.To ensure consistent inflation of the diaphragm,inflate to a higher air pressure(25%)and then reduce to testing pressure.
9.5Direction of Abrasion:
9.5.1Standard Multidirection—Engage the rotation mecha-nism of the specimen clamp.
9.5.2Unidirection—When this is ud,dingage the rota-tion mechanism of the specimen clamp and bring the specimen into the desired direction by turning and tting the clamp after the diaphragm has been inflated.Include this information in the final report.
9.6Remove pills of mattedfibers interfering with proper contact between the specimen and abradant during the test if they cau a marked vibration of the abradant plate.
9.7If the specimen slips in the clamp or the air pressure does not remain constant during the test or an anomalous wear pattern is obtained,discard such individual measurements and test an additional specimen.
9.8This table is intended as a guide for visual asssment:
oz/yd2asss@cycle#
under3oz.1000
3-5oz.3000
over5oz.5000
9.9If abrasion of wet specimens is desired,cover the dry clamped-in specimen with10ml of distilled water at a temperature of2062°C(7062°F).
10.Interpretation of Results
10.1Determine the end point by one of the following methods as specified by the requesting individual.
10.1.1Option1,Failure—Abrade the specimen until all fibers in the center of the abrasion area are worn off so that the contact pin in the abradant plate comes in contact with the pin in the diaphragm,actuating an electrical relay and stopping the machine.
10.1.2Option2,Visual Rating—Abrade the specimen a specified number of cycles and then evaluate visually for the effect of the abrasion on luster,color,or fabric structure as follows:
Abrasion Asssment
Grade Description
5No,or esntially no luster,color,or fabric structure change
4Slight change in color with no broken threads
3Moderate change in color with visual fraying
2Substantial change in color with2or less broken threads
1Severe change in color with more than2broken threads
N OTE6—Unless the continuous changing abradant head is ud,it
is
recommended that the abradant paper be changed at some regular frequency,such as every100to300cycles.As this frequency is dependent upon the type of fabric being tested,the task group is working on devising
a more extensive system.
11.Report
11.1State that the specimens were tested as directed in Test Method D3886.Describe the material or product sampled and the method of sampling ud.
awkwardly11.2Report the following information:
11.2.1Type of abradant,
11.2.2Frequency with which abradant paper was changed, 11.2.3Air pressure under the diaphragm and load on the abradant plate,
11.2.4Type of abrasion(unidirectional or multidirectional), 11.2.5Number of cycles to reach the end point as deter-mined by electrical contact,
11.2.6Effect of abrasion on luster,color,and fabric struc-ture at a specified number of cycles recorded by qualitative or
服装行业
comparative ranking,and
11.2.7Any deviations from the standard test procedure.
12.Precision and Bias
12.1Summary—Bad upon limited information from two laboratories,the single-operator,within-laboratory,and between-laboratory components of variation and critical dif-ferences shown in Tables1and2are approximate.The tables are constructed to illustrate what two laboratories found when all the obrvations are taken by well-trained operators using specimens randomly drawn from the sample of material.For the laboratories,in comparing two averages,it was found that differences should not exceed the single-operator precision values shown in Table2for the respective number of tests in95 out of100cas.Differences for other laboratories may be larger or smaller.
12.2Single-laboratory Test Data7—A two-laboratory test was run in1997in which randomly drawn samples of three materials were tested.Two operators in each laboratory each tested ten specimens(five on each of two days)from each fabric material using the cycles to failure procedure in Test Method D3886.Analysis of the data was conducted using Practices D2904and D2906and the Adjunct“Tex-Pac.”The components of variance for inflated diaphragm abrasion ex-presd as standard deviations were calculated to be the values listed in Table1.
12.3Precision—Becau tests were conducted in only two laboratories,estimates of between laborat
ory precision may be either underestimated or overestimated to a considerable extent and should be ud with special caution.Before a meaningful statement can be made about two specific laboratories,the amount of statistical bias,if any,between them must be established,with each comparison being bad on recent data obtained on specimens taken from a lot of material of the type being evaluated so as to be as nearly homogeneous as possible and then randomly assigned in equal numbers to each of the laboratories.However,when agreed upon between the contrac-tual parties,for the approximate components of variance reported in Table1,two averages of obrved values may be considered significantly different at the95%probability level if the difference equals or exceeds the critical differences listed in Table2,for inflated diaphragm abrasion cycles to failure. Tex-Pac grouped materials into two perate groups,therefore, the components of variance and the critical differences are reported parately.Conquently no multi-material compari-sons were made.
12.4Bias—The value of inflated diaphragm abrasion cycles to failure of textile fabrics can only be defined in terms of a test method.Within this limitation,Test Method D3886has no known bias.
13.Keywords
13.1abrasion;woven fabric;and knitted fabric
7A copy is available from ASTM Headquarters,100Barr Harbor Drive,West Conshohocken,PA19428-2959.
TABLE1Grand Average and Components of Variance A
Expresd as Standard Deviations for Inflated Diaphragm
Abrasion Cycles to Failure
Grand Average
and Component
Material1Material2Material3
Grand average45101585309
Single-operator component47522676 Within-laboratory component029068 Between-laboratory component57300医院英文
A The square roots of the components of variance are being reported to express the variability in the
appropriate units of measure rather than as the squares of tho units of measure.
TABLE2Critical Differences for Inflated Diaphragm Abrasion Cycles to Failure for the Conditions Noted A
Materials
Number of
Obrvations in
Each Average
Single-
Operator
Precision
Within-
Laboratory
Precision
Between-
Laboratory
Precision 11131613162061四六级考试时间安排
29309301841
55885881694
104164161642
2162610181018
2443917917
5280850850
10198827827 31212284284
2150241241
595212212
1067201201选择题答题技巧
A The critical differences were calculated using t=1.960,which is bad on infinite degrees of
freedom.
