ASTM D6480-2005(2010) 4375 Standard Test Method for Wipe Sampling of Surfaces Indirect Preparation and Analysis for Asbestos Structure Number Concentration by Transmission Electron.pdf

上传人:testyield361 文档编号:522633 上传时间:2018-12-03 格式:PDF 页数:15 大小:203.46KB
下载 相关 举报
ASTM D6480-2005(2010) 4375 Standard Test Method for Wipe Sampling of Surfaces Indirect Preparation and Analysis for Asbestos Structure Number Concentration by Transmission Electron.pdf_第1页
第1页 / 共15页
ASTM D6480-2005(2010) 4375 Standard Test Method for Wipe Sampling of Surfaces Indirect Preparation and Analysis for Asbestos Structure Number Concentration by Transmission Electron.pdf_第2页
第2页 / 共15页
ASTM D6480-2005(2010) 4375 Standard Test Method for Wipe Sampling of Surfaces Indirect Preparation and Analysis for Asbestos Structure Number Concentration by Transmission Electron.pdf_第3页
第3页 / 共15页
ASTM D6480-2005(2010) 4375 Standard Test Method for Wipe Sampling of Surfaces Indirect Preparation and Analysis for Asbestos Structure Number Concentration by Transmission Electron.pdf_第4页
第4页 / 共15页
ASTM D6480-2005(2010) 4375 Standard Test Method for Wipe Sampling of Surfaces Indirect Preparation and Analysis for Asbestos Structure Number Concentration by Transmission Electron.pdf_第5页
第5页 / 共15页
亲,该文档总共15页,到这儿已超出免费预览范围,如果喜欢就下载吧!
资源描述

1、Designation: D6480 05 (Reapproved 2010)Standard Test Method forWipe Sampling of Surfaces, Indirect Preparation, andAnalysis for Asbestos Structure Number Surface Loadingby Transmission Electron Microscopy1This standard is issued under the fixed designation D6480; the number immediately following the

2、 designation indicates the year oforiginal adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This test method covers a

3、 procedure to identify asbestosin samples wiped from surfaces and to provide an estimate ofthe concentration of asbestos reported as the number ofasbestos structures per unit area of sampled surface. Theprocedure outlined in this test method employs an indirectsample preparation technique. It is int

4、ended to disperse aggre-gated asbestos into fundamental fibrils, fiber bundles, clusters,or matrices. However, as with all indirect sample preparationtechniques, the asbestos observed for quantification may notrepresent the physical form of the asbestos as sampled. Morespecifically, the procedure de

5、scribed neither creates nor de-stroys asbestos, but it may alter the physical form of themineral fiber aggregates.1.2 This test method describes the equipment and proce-dures necessary for wipe sampling of surfaces for levels ofasbestos structures. The sample is collected onto a particle-freewipe ma

6、terial (wipe) from the surface of a sampling area thatmay contain asbestos.1.2.1 The collection efficiency of this wipe sampling tech-nique is unknown and will vary among substrates. Propertiesinfluencing collection efficiency include surface texture, adhe-siveness, and other factors.1.2.2 This test

7、 method is generally applicable for an esti-mate of the surface loading of asbestos structures starting fromapproximately 1000 asbestos structures per square centimetre.1.3 Asbestos identification by transmission electron micros-copy (TEM) is based on morphology, electron diffraction (ED),and energy

8、 dispersive X-ray analysis (EDXA).1.4 This test method allows determination of the type(s) ofasbestos fibers present.1.4.1 This test method cannot always discriminate betweenindividual fibers of the asbestos and nonasbestos analogues ofthe same amphibole mineral.1.4.2 There is no lower limit to the

9、dimensions of asbestosfibers that can be detected. However, in practice, the lowerlimit to the dimensions of asbestos fibers, that can be detected,is variable and dependent on individual microscopists. There-fore, a minimum length of 0.5 m has been defined as theshortest fiber to be incorporated in

10、the reported results.1.5 This test method does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this test method to establishappropriate safety and health practices and determine theapplicability of regulatory limitations prior

11、 to use.2. Referenced Documents2.1 ASTM Standards:2D1193 Specification for Reagent WaterD1356 Terminology Relating to Sampling and Analysis ofAtmospheresD3670 Guide for Determination of Precision and Bias ofMethods of Committee D222.2 Government Standard:340 CFR 763, USEPA, Asbestos-Containing Mater

12、ials inSchools: Final Rule and Notice,AppendixAto Sub-part E2.3 U.S. Environmental Protection Agency Standards:3EPA600/4-83-043 Analytical Method for the Determinationof Asbestos in WaterEPA 747-R-95-001 USEPA, Residential Sampling for Lead:Protocols for Dust and Soil Sampling: Final Report1This tes

13、t method is under the jurisdiction of ASTM Committee D22 on AirQuality and is the direct responsibility of Subcommittee D22.07 on Sampling andAnalysis of Asbestos.Current edition approved Oct. 1, 2010. Published November 2010. Originallyapproved in 1999. Last previous edition approved in 2005 as D64

14、80 - 05. DOI:10.1520/D6480-05R10.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.3Available from U.S. Governm

15、ent Printing Office Superintendent of Documents,732 N. Capitol St., NW, Mail Stop: SDE, Washington, DC 20401, http:/www.access.gpo.gov.1Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.3. Terminology3.1 DefinitionsFor definitions of ge

16、neral terms used inthis test method, refer to Terminology D1356.3.2 Definitions of Terms Specific to This Standard:3.2.1 amphibole asbestosamphibole in an asbestiformhabit (1).43.2.2 analytical sensitivitythe calculated asbestos struc-ture concentration in asbestos structures/square centimetre,equiv

17、alent to counting of one asbestos structure in the analysiscalculated using Eq 2.3.2.3 asbestosa collective term that describes a group ofnaturally occurring, inorganic, highly fibrous, silicate minerals,that are easily separated into long, thin, flexible, strong fiberswhen crushed or processed (1-3

18、).3.2.3.1 DiscussionIncluded in the definition are the as-bestiform varieties of serpentine (chrysotile), riebeckite (cro-cidolite), grunerite (grunerite asbestos Amosite), anthophyl-lite (anthophyllite asbestos), tremolite (tremolite asbestos), andactinolite (actinolite asbestos). The amphibole min

19、eral compo-sitions are defined in accordance with nomenclature of theInternational Mineralogical Association (3,4).Asbestos Chemical Abstracts Service Registry No.5Chrysotile 12001-29-5Crocidolite 12001-28-4Grunerite Asbestos Amosite 12172-73-5Anthophyllite Asbestos 77536-67-5Tremolite Asbestos 7753

20、6-68-6Actinolite Asbestos 77536-66-43.2.4 asbestos structurea term applied to isolated fibers orto any connected or overlapping grouping of asbestos fibers orbundles, with or without other nonasbestos particles.3.2.5 aspect ratiothe length to width ratio of a particle.3.2.6 bundlea structure compose

21、d of three or more fibersin a parallel arrangement with the fibers closer than one fiberdiameter to each other.3.2.7 camera lengththe equivalent projection length be-tween the specimen and its selection diffraction pattern, in theabsence of lens action.3.2.8 chrysotilea group of fibrous minerals of

22、the serpen-tine group that have the nominal composition Mg3Si2O5(OH)4and have the crystal structure of either clinochrysotile, ortho-chrysotile, or parachrysotile. Most natural chrysotile deviateslittle from this nominal composition. Chrysotile may be par-tially dehydrated or magnesium-leached both

23、in nature and inbuilding materials. In some varieties of chrysotile, minorsubstitution of silicon by Al3+may occur. Chrysotile is themost prevalent type of asbestos.3.2.9 clustera structure with fibers in a random arrange-ment such that all fibers are intermixed and no single fiber isisolated from t

24、he group; groupings of fibers must have morethan two points touching.3.2.10 d-spacing or inter-planar spacingthe perpendicu-lar distance between identical adjacent and parallel planes ofatoms in a crystal.3.2.11 electron diffractiontechniques in electron micros-copy that include selected area electr

25、on diffraction (SAED) andmicrodiffraction by which the crystal structure of a specimen isexamined.3.2.12 energy dispersive X-ray analysismeasurement ofthe energies and intensities of X-rays by use of a solid statedetector and multichannel analyzer system.3.2.13 eucentricthe condition when the area o

26、f interest ofan object is placed on a tilting axis at the intersection of theelectron beam at that axis and is in the plane of focus.3.2.14 fiberan elongate particle with parallel or steppedsides. For the purposes of this test method, a fiber is defined tohave an aspect ratio equal to or greater tha

27、n 5:1 and a minimumlength of 0.5 m (see 40 CFR 763).3.2.15 fibrila single fiber, that cannot be further separatedlongitudinally into smaller components without losing itsfibrous properties or appearances.3.2.16 fibrous minerala mineral composed of parallel,radiating, or interlaced aggregates of fibe

28、rs from which thefibers are sometimes separable. That is, the crystalline aggre-gate may be referred to as fibrous even if it is not composed ofseparable fibers but has that distinct appearance. The termfibrous is used in a general mineralogical way to describeaggregates of grains that crystallize i

29、n a needle-like habit andappear to be composed of fibers. Fibrous has a much moregeneral meaning than asbestos. While it is correct that allasbestos minerals are fibrous, not all minerals having fibroushabits are asbestos.3.2.17 fibrous structurea fiber, or connected grouping offibers, with or witho

30、ut other particles.3.2.18 field wipe blanka clean, unused, moistened wipefrom the same supply that is used for sampling. Field wipesshall be processed in the same manner used to collect fieldsamples with the exception that no surface is wiped. Each wipedesignated as a field wipe should be removed fr

31、om the bulkpack, moistened, and folded in the same manner as the fieldsamples and placed in a sample container labeled as field wipe.3.2.19 filter blankan unused, unprocessed filter of thetype used for liquid filtration.3.2.20 filtration blanka filter prepared from 250 mL ofwater.3.2.21 habitthe cha

32、racteristic crystal growth form orcombination of these forms of a mineral, including character-istic irregularities.3.2.22 indirect preparationa method in which a samplepasses through one or more intermediate steps prior to finalfiltration. The particles are removed from the original mediumand depos

33、ited on a second filter prior to analysis.3.2.23 limit of detectionthe limit of detection for a mea-surement by this test method is 2.99 multiplied by theanalytical sensitivity for the measurement.3.2.23.1 DiscussionThis limit of detection is based on theassumption that the count resulting from pote

34、ntial filter con-tamination, sample preparation contamination, and other un-controllable background sources is no greater than 0.05 struc-tures per sample. At this time, however, this subcommittee hasno empirical data to confirm this rate.4The boldface numbers in parentheses refer to the list of ref

35、erences at the end ofthis standard.5The nonasbestiform variations of the minerals indicated in 3.2.3.1 havedifferent Chemical Abstract Service (CAS) numbers.D6480 05 (2010)23.2.24 matrixa structure in which one or more fibers, orfiber bundles that are touching, are attached to, or partiallyconcealed

36、 by, a single particle or connected group of nonfi-brous particles. The exposed fiber must meet the fiber defini-tion.3.2.25 process blankan unused wipe (that has not beentaken into the field) processed in accordance with the entirepreparation and analytical procedure.3.2.26 replicate samplingone of

37、 several identical proce-dures or samples.3.2.27 serpentinea group of common rock-forming min-erals having the nominal formula: Mg3Si2O5(OH)4. For furtherinformation see Ref. (4).3.2.28 structurea single fiber, fiber bundle, cluster, ormatrix.3.2.29 structure number concentrationconcentration ex-pre

38、ssed in terms of asbestos structure number per unit ofsurface area.3.2.30 zone-axisthe crystallographic direction of a crystalthat is parallel to the intersecting edges of the crystal facesdefining the crystal zone.3.3 Symbols:eV = electron volth = hourJ = joulekV = kilovoltmin = minute(s)mL = milli

39、litre (103litre)L = microlitre (106litre)mm = millimetre (103metre)m = micrometre (106metre)nm = nanometre (109metre)s = second(s)W = wattPa = pascals3.4 Acronyms:DMF = dimethyl formamideED = electron diffractionEDXA = energy dispersive X-ray analysisFWHM = full width, half maximumHEPA = High Effici

40、ency Particulate AirMCE = mixed cellulose ester and also refers to purecellulose nitrate filtersPC = polycarbonateTEM = transmission electron microscope4. Summary of Test Method4.1 Wiping a surface of known area with a wipe materialcollects a sample. The sample is transferred from the wipematerial t

41、o an aqueous suspension of known volume. Aliquotsof the suspension are then filtered through a membrane filter.Asection of the membrane filter is prepared and transferred to aTEM grid, using the direct transfer method. The asbestiformstructures are identified, sized, and counted by TEM, using EDand

42、EDXA at a magnification from 15 000 to 20 000 3.5. Significance and Use5.1 This wipe sampling and indirect analysis test method isused for the general testing of surfaces for asbestos. It is usedto assist in the evaluation of surfaces in buildings, such asceiling tiles, shelving, electrical componen

43、ts, duct work, and soforth. This test method provides an index of the concentrationof asbestos structures per unit area sampled as derived from aquantitative measure of the number of asbestos structuresdetected during analysis.5.1.1 This test method does not describe procedures ortechniques required

44、 for the evaluation of the safety or habit-ability of buildings with asbestos-containing materials, orcompliance with federal, state, or local regulations or statutes.It is the users responsibility to make these determinations.5.1.2 At present, a single direct relationship between asbes-tos sampled

45、from a surface and potential human exposure doesnot exist. Accordingly, the user should consider these data inrelationship to other available information (for example, airsampling data) in their evaluation.5.2 One or more large asbestos-containing particles dis-persed during sample preparation may r

46、esult in large asbestossurface loading results in the TEM analyses of that sample. Itis, therefore, recommended that multiple replicate independentsamples be secured in the same area, and that a minimum ofthree such samples be analyzed by the entire procedure.6. Interferences6.1 The following materi

47、als have properties (that is, chemi-cal composition or crystalline structure) that are very similar toasbestos minerals and may interfere with the analysis bycausing a false positive to be recorded during the test.Therefore, literature references for these materials shall bemaintained in the laborat

48、ory for comparison with asbestosminerals so that they are not misidentified as asbestos minerals.6.1.1 Antigorite,6.1.2 Fibrous talc,6.1.3 Halloysite,6.1.4 Hornblende and other amphiboles,6.1.5 Palygorskite (attapulgite),6.1.6 Pyroxenes,6.1.7 Sepiolite, and6.1.8 Vermiculite scrolls.7. Apparatus7.1 E

49、quipment and Materials for Sampling:7.1.1 Disposable Wet Towels.7.1.2 Masking Tape.7.1.3 Measuring Tape.7.1.4 Powderless, Rubber Gloves.7.1.5 Sample Container, clean, sealable, used for transport-ing the sample to the laboratory.7.1.6 Template to Delineate Sampling Area, a reusable ordisposable template of nonparticle-shedding material, such asaluminum, plastic, or nonshedding cardboard. A variety ofshapes (for example, square, rectangular) are acceptable. Alltemplates shall have accurately known inside dimensions.Templates should be thi

展开阅读全文
相关资源
猜你喜欢
  • AECMA PREN 3745-703-2000 Aerospace Series Fibres and Cables Optical Aircraft Use Test Methods Part 703 Durability of Manufacturer's Marking Edition P 1《航空航空航天系列  航空用光缆和光纤 试验方法.第703.pdf AECMA PREN 3745-703-2000 Aerospace Series Fibres and Cables Optical Aircraft Use Test Methods Part 703 Durability of Manufacturer's Marking Edition P 1《航空航空航天系列  航空用光缆和光纤 试验方法.第703.pdf
  • AECMA PREN 3745-705-2006 Aerospace series Fibres and cables optical aircraft use Test methods Part 705 Contrast measurement Edition P 1《航空航空航天系列  航空用光缆和光纤 试验方法.第705部分 对比测量》.pdf AECMA PREN 3745-705-2006 Aerospace series Fibres and cables optical aircraft use Test methods Part 705 Contrast measurement Edition P 1《航空航空航天系列  航空用光缆和光纤 试验方法.第705部分 对比测量》.pdf
  • AECMA PREN 3746-1994 Aerospace Series O-Rings in Fluorosilicone Rubber (FVMQ) Hardness 80 IRHD Edition P 1《航空航天系列.硬度 80 IRHD 氟硅橡胶(FVMQ)O形环》.pdf AECMA PREN 3746-1994 Aerospace Series O-Rings in Fluorosilicone Rubber (FVMQ) Hardness 80 IRHD Edition P 1《航空航天系列.硬度 80 IRHD 氟硅橡胶(FVMQ)O形环》.pdf
  • AECMA PREN 3747-1994 Aerospace Series O-Rings in Fluorosilicone Rubber (FVMQ) Technical Specification Edition P 1《航空航天系列.氟硅橡胶(FVMQ)O形环 技术规范》.pdf AECMA PREN 3747-1994 Aerospace Series O-Rings in Fluorosilicone Rubber (FVMQ) Technical Specification Edition P 1《航空航天系列.氟硅橡胶(FVMQ)O形环 技术规范》.pdf
  • AECMA PREN 3748-2000 Aerospace Series O-Ring Grooves Dimensions Edition P 1《航空航天系列O形环尺寸.P1版》.pdf AECMA PREN 3748-2000 Aerospace Series O-Ring Grooves Dimensions Edition P 1《航空航天系列O形环尺寸.P1版》.pdf
  • AECMA PREN 3750-1993 Aerospace Series Nuts Anchor Self-Locking Fixed 90 Degree Corner Reduced Series with Counterbore in Heat Resisting Steel MoS2 Lubricated Classification 1 100 M.pdf AECMA PREN 3750-1993 Aerospace Series Nuts Anchor Self-Locking Fixed 90 Degree Corner Reduced Series with Counterbore in Heat Resisting Steel MoS2 Lubricated Classification 1 100 M.pdf
  • AECMA PREN 3751-1996 Aerospace Series Nuts Anchor Self-Locking Fixed Closed Corner Reduced Series with Counterbore in Heat Resisting Steel MoS2 Lubricated Classification  1 100 MPa.pdf AECMA PREN 3751-1996 Aerospace Series Nuts Anchor Self-Locking Fixed Closed Corner Reduced Series with Counterbore in Heat Resisting Steel MoS2 Lubricated Classification 1 100 MPa.pdf
  • AECMA PREN 3752-1994 Aerospace Series Nuts Self-Locking MJ Threads in Heat Resisting Steel FE-PA92HT (A286) MoS2 Coated Classification 1 100 MPa (at Ambient Temperature) 425 Degree.pdf AECMA PREN 3752-1994 Aerospace Series Nuts Self-Locking MJ Threads in Heat Resisting Steel FE-PA92HT (A286) MoS2 Coated Classification 1 100 MPa (at Ambient Temperature) 425 Degree.pdf
  • AECMA PREN 3753-1993 Aerospace Series Nuts Anchor Self-Locking Fixed 60 Degree Corner with Counterbore in Alloy Steel Cadmium Plated MoS2 Lubricated Classification 1 100 MPa (at Am.pdf AECMA PREN 3753-1993 Aerospace Series Nuts Anchor Self-Locking Fixed 60 Degree Corner with Counterbore in Alloy Steel Cadmium Plated MoS2 Lubricated Classification 1 100 MPa (at Am.pdf
  • 相关搜索

    当前位置:首页 > 标准规范 > 国际标准 > ASTM

    copyright@ 2008-2019 麦多课文库(www.mydoc123.com)网站版权所有
    备案/许可证编号:苏ICP备17064731号-1