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本文(ASTM E2399-2011 Standard Test Method for Maximum Media Density for Dead Load Analysis of Vegetative (Green) Roof Systems《生长植物的(绿色)屋顶系统静载荷分析用最大介质密度的标准试验方法》.pdf)为本站会员(medalangle361)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASTM E2399-2011 Standard Test Method for Maximum Media Density for Dead Load Analysis of Vegetative (Green) Roof Systems《生长植物的(绿色)屋顶系统静载荷分析用最大介质密度的标准试验方法》.pdf

1、Designation: E2399 11Standard Test Method forMaximum Media Density for Dead Load Analysis ofVegitative (Green) Roof Systems1This standard is issued under the fixed designation E2399; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision,

2、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 procedure for determining themaximum media density for purposes of estimating th

3、e maxi-mum dead load for green roof assemblies. The method alsoprovides a measure of the moisture content, the air-filledporosity, and the water permeability measured at the maximummedia density.1.2 This procedure is suitable for green roof media thatcontain no more than 30 % organic material as mea

4、sured usingthe loss on ignition, as described in Test Methods E177, TestMethod C. The test specimen should be a bulk oven-driedsample prepared according to Test Methods E177, Test MethodA.1.3 The maximum media density and associated moisturecontent measured in this procedure applies to drained condi

5、-tions near the saturation point.1.4 The test method is intended to emulate vertical perco-lation rates for water in green roofs.1.5 The values stated in inch-pound units are to be regardedas standard. The values given in parentheses are mathematicalconversions to SI units that are provided for info

6、rmation onlyand are not considered standard.1.6 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and to determine theapplicability of regula

7、tory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:2D698 Test Methods for Laboratory Compaction Character-istics of Soil Using Standard Effort (12 400 ft-lbf/ft3(600kN-m/m3)D2216 Test Methods for Laboratory Determination of Wa-ter (Moisture) Content of Soil and Rock by MassD2325

8、 Test Method for Capillary-Moisture Relationshipsfor Coarse- and Medium-Textured Soils by Porous-PlateApparatus3D2947 Test Method for Screen Analysis of Asbestos FibersE11 Specification for Woven Wire Test Sieve Cloth and TestSievesE177 Practice for Use of the Terms Precision and Bias inASTM Test Me

9、thodsE631 Terminology of Building ConstructionsE691 Practice for Conducting an Interlaboratory Study toDetermine the Precision of a Test MethodE2114 Terminology for Sustainability Relative to the Per-formance of Buildings3. Terminology3.1 Definitions:3.1.1 For terms related to building construction,

10、 refer toTerminology E631.3.1.2 For terms related to sustainability relative to theperformance of buildings, refer to Terminology E2114.3.2 Definitions of Terms Specific to This Standard:3.2.1 air-filled porositythe air-filled porosity, also knownas void ratio or non-capillary porosity, is a measure

11、 of the airvolume remaining in a sample after it has been compacted tothe maximum media density and when the moisture contentequals the maximum media water retention. In this method, theair-filled porosity does not include closed-cell particle porosityor porosity that is unavailable to be filled by

12、water when thesample is immersed.3.2.1.1 DiscussionThis property has two important appli-cations:(1) It is an indicator of the viability of media to support plantswhen it is wet. Materials with low air-filled porosity may tendtoward anoxic conditions when wet, and(2) This is the volume available for

13、 water to fill after themaximum media water retention is satisfied. This volume ofwater may contribute to the live load of the green roof system.1This test method is under the jurisdiction of ASTM Committee E60 onSustainability and is the direct responsibility of Subcommittee E60.01 on Buildingsand

14、Construction.Current edition approved April 1, 2011. Published May 2011. Originallyapproved in 2005. Last previously approved in 2010 as E2399 10. DOI: 10.1520/E2399-11.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annua

15、l Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.3Withdrawn. The last approved version of this historical standard is referencedon www.astm.org.1Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-29

16、59, United States.3.2.2 maximum media densitythe density of a mixedmedia material determined after it has been subjected to aspecific amount of compaction and hydrated by immersion tosimulate prolonged exposure to both foot traffic and rainfall.3.2.2.1 DiscussionThe maximum media density appliesto d

17、rained conditions.3.2.3 maximum media water retentionthe quantity ofwater held in a media at the maximum media density, measuredin volume percent.3.2.3.1 DiscussionThis is useful measure of the capacityof a media to hold water under drained conditions.3.2.4 saturation pointthe moisture content at wh

18、ich thesoil tension in the mixed media is zero, but a free water surfacehas not developed.3.2.4.1 DiscussionThe saturation point represents thetheoretical maximum moisture content that a material cancontain in a drained state.3.2.5 water permeabilitythe coefficient, which when mul-tiplied by the hyd

19、raulic gradient will yield the apparentvelocity with which water, at 68F (20C) will move through across-section of media.3.2.5.1 DiscussionThe conditions created in this methodapply to freely-drained media where the free water surface islevel with the upper surface of the media layer (such as,impend

20、ing accumulation of water above the surface of themedia).4. Summary of Test Method4.1 This test method involves compressing a moist sampleof a media into a perforated mold using specified compactiondeveloped using a Proctor hammer. The sample is subsequentlyimmersed in a water bath for 24 hours to p

21、romote fullhydration of the material. After allowing the sample to drainbriefly, its density and moisture content are determined usingstandard gravimetric procedures. This procedure also includesa method for estimating the water permeability using apseudo-constant head procedure and the air-filled p

22、orosity.4.2 This test method involves measuring the density of themedia after the sample has been allowed to drain for 2 h. Thismeasurement is the maximum media density. The 2-h measure-ment is valuable to the green roof designer, since it is directlycomparable to media densities determined using th

23、e mostcommon international procedures for establishing green roofdead load values.5. Significance and Use5.1 This test method describes simple laboratory methodsthat provide reproducible measurements of critical mediaproperties, and permit direct comparisons to be made betweendifferent media materia

24、ls.5.2 The density of mixed media materials will vary depend-ing on the degree to which they are subjected to compactionand the length of time that the material is allowed to hydrateand subsequently drain. Most green roof media materials havea large capacity to absorb and retain moisture. Furthermor

25、e,moisture will drain gradually from the media following ahydration cycle. The maximum media density measured in thisprocedure approaches the density at the theoretical saturationpoint.5.3 Existing methods for measuring the capillary-moisturerelationship for soils (Test Method D2325) rely on samplep

26、reparation procedures (Test Methods D698) that are notconsistent with the conditions associated with the placement ofgreen roof media materials. This procedure is intended toprovide a reproducible laboratory procedure for predicting themaximum media density, moisture content, air-filled porosity,and

27、 water permeability under conditions that more closelyreplicate field conditions on green roofs.5.4 The value of this test method to the green roof designeris that it provides an objective measure of maximum probablemedia density (under drained conditions) for estimating struc-tural loads. It also p

28、rovides a method for estimating the lowerlimit for the water permeability of the in-place media. Thislatter value is important when considering drainage conditionsin green roofs. Finally, the maximum media water retention hasbeen shown to be a useful indicator of the moisture retentionproperties of

29、green roof media.6. Apparatus6.1 Apparatuscontains the following:6.1.1 Cylindrical stainless steel container: inside dimen-sions 6.5 in. (16.5 cm) high with a 6-in. (15.2 cm) insidediameter and 125316-in. (4.75-mm) perforations in the bottom.The hole pattern is not significant, provided the holes ar

30、edistributed evenly across the bottom of the cylinder. Thetolerance for the cylinder dimensions shall be plus or minus 0.1in. (2.5 mm).6.1.2 U.S. #30 (0.6 mm) sieve disc, 5.8-in. (14.7-cm)diameter.6.1.3 Steel disk plate, 5.8-in. (14.7-cm) diameter.6.1.4 Proctor hammer: 10 lb (4.54 kg), with fall hei

31、ght of 18in. (45.7 cm).6.1.5 Scale, accurate to 0.0035 oz (0.1 g) and capacity of atleast 11 lbs (5 kg).6.1.6 Drying dish.6.1.7 Plastic water immersion bath with minimum immer-sion depth of 8 in. (20.3 cm).6.1.8 Drain stand.6.1.9 Filter fabric disk, 5.8-in. (14.7-cm) diameter, forcovering the upper

32、surface of the sample within the testcylinder.6.1.10 4-in. (10-cm) concrete cubes (for use as weights).6.1.11 Measuring scale, supported by a circular wire stand,with marks at 1.5 and 2.0 in. (3.8 and 5.0 cm).6.1.12 Thermometer.6.1.13 Calibrated 8 fluid oz (250 ml) volumetric flask withwide neck.6.1

33、.14 Hot plate.6.1.15 Hot mitts.7. Conditioning7.1 The procedure requires a damp sample. If the sample isreceived in a dry condition, it must be moistened. The initialmoisture content, Mi, of the sample shall be not less than 10 %and not more than 25 %, by weight.7.2 Determine the as-received moistur

34、e content of thesample according to Test Method E691.E2399 1127.3 If the as-received moisture content of the sample is lessthan 10% moisture content by weight, adjust by adding waterand incorporate by gently mixing. If the as-received moisturecontent of the sample is greater than 25 % moisture conte

35、nt byweight, allow the sample to air-dry until the moisture contentis reduced to within the appropriate range. After moistening orair-drying, allow the sample to stand in an airtight container for3 hours before continuing the procedure. Re-measure thepercent moisture content (Test Method E691) to co

36、nfirm thatthe appropriate moisture range has been achieved and record asMi.8. Procedure8.1 General:8.1.1 Place one of the sieve discs inside the cylinder tocover the perforations. Weigh the cylinder and disc together,and record. Fill the cylinder with the sample material to aheight of 4.75 to 5.5 in

37、. (12 to 14 cm). The quantity of materialadded should be sufficient to produce a sample height ofapproximately 4 in. (10 cm) after being compressed.8.1.2 Cover the contained material with the steel plate andcompress with 6 blows of the Proctor hammer. Remove thesteel plate. Determine the sample thic

38、kness, Hi, by measuringthe height from the top of the upper cylinder edge to the uppersurface of the sample and subtracting this from the insidecylinder height. If the sample surface is not level, fourcross-wise measurements of the sample height should be takenand averaged. Compute the initial sampl

39、e volume, Vi.8.1.3 Determine the weight of the container together withthe contained sample. Compute the initial sample weight, Wi,by subtracting the combined weight of the container andbottom sieve (see above).8.1.4 The sample volume and the sample weight must beestablished initially, before the sam

40、ple is immersed. Anychange in sample volume during subsequent immersion shouldbe reported with the test results. A determination of the sampledensity in the dry condition is undertaken after determinationof the maximum media density capacity8.1.5 Cover the upper surface of the sample with the filter

41、fabric disc. Cover the fabric with the sieve disc and place thestone weights on top in order to minimize swelling of thesample during immersion.8.1.6 Place the cylinder in the immersion bath and slowlyfill with water to a depth of 0.5 in. (1.25 cm) over the top of thesample. As required, fill to mai

42、ntain the water level. Maintainthe temperature of the bath at 68F 6 5F (20 6 2.75C).8.1.7 Remove the cylinder after 24 hours of immersion.Place on the drain stand and allow to drain for 120 min. Wipethe outside of the container dry and remove the blocks andupper sieve disc. Do not remove the fabric.

43、 Weigh the cylinderwith the contained sample.8.1.8 Compute the sample weight, W120, by subtracting thecombined weight of the container and bottom sieve disc. Checkthe final sample thickness, H, and record changes from theinitial height. This thickness will be used in the subsequentdetermination of w

44、ater permeability and maximum mediadensity. Compute the final sample volume, V, and record.8.1.9 Return the cylinder to the drain stand. Place themeasuring scale on the upper surface of the sample.8.1.10 Using water from the bath, at a temperature of 68 65F (20 6 2.75C), fill the cylinder so that th

45、e water stands toa depth of 0.5 to 1 in. (1.25 to 2.50 cm) over the top of thesample. Add water continually to keep the water level approxi-mately constant.8.1.11 Begin the measurement as soon as a steady flow ofwater issues from the holes at the bottom of the cylinder. Fillthe cylinder to a depth g

46、reater than the upper mark (2.0-in.(5.0-cm) mark). As the water level declines, note the time thatat which the water level first reaches the 2.0-in. (5.0-cm) mark.Determine the elapsed time, T, in seconds, required for thewater level to fall to the final water level (1.5-in. (3.8-cm)mark). Repeat 3

47、times and average the results. Record thetemperature of the water that is collected from the bottom ofthe cylinder.8.1.12 Place the sample in a drying dish of known weightand dry at 220 fi 5o F (104 6 2.75C) for four hours. Weighthe drying dish and sample. Continue drying until subsequentmeasurement

48、s made 15 min apart differ by 2 %, or less.Compute the weight of the dry sample, Wdry, by subtracting theweight of the dish.8.1.13 Weigh clean dry volumetric flask, Wa.8.1.14 Add 0.1 to 0.22 lbs (50 to 100 g) of the conditionedsample to the flask and weigh. Record as Ws.8.1.15 Fill the flask with ap

49、proximately 5 fluid oz (150 ml)of distilled water, taking care to rinse sample particles into thesuspension.8.1.16 To remove entrapped air, place the flask on a hotplate and boil gently for 3 min. Agitate content, as necessary,to avoid foaming and sample loss. Remove the flask from thehot plate and cool to room temperature. Room temperature is68F (20C), plus or minus 5F (2.75C).8.1.17 Fill the flask to the 8 fluid oz (250 ml) calibration linewith boiled distilled water at room temperature. Weigh theflask and contents. Record as Wsw.8.1.18 Remove the conten

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