ASTM D4823-1995(2014) Standard Guide for Core Sampling Submerged Unconsolidated Sediments《水下松散沉积物心部抽样的标准指南》.pdf

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1、Designation: D4823 95 (Reapproved 2014)Standard Guide forCore Sampling Submerged, Unconsolidated Sediments1This standard is issued under the fixed designation D4823; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the year of last

2、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 guide covers core-sampling terminology, advan-tages and disadvantages of different types of core samplers,core-distort

3、ions that may occur during sampling, techniquesfor detecting and minimizing core distortions, and methods fordissecting and preserving sediment cores.1.2 In this guide, sampling procedures and equipment aredivided into the following categories based on water depth:sampling in depths shallower than 0

4、.5 m, sampling in depthsbetween 0.5 m and 10 m, and sampling in depths exceeding 10m. Each category is divided into two sections: equipment forcollecting short cores and equipment for collecting long cores.1.3 This guide emphasizes general principles. Only in a fewinstances are step-by-step instruct

5、ions given. Because coresampling is a field-based operation, methods and equipmentmust usually be modified to suit local conditions. This modi-fication process requires two essential ingredients: operatorskill and judgment. Neither can be replaced by written rules.1.4 Drawings of samplers are includ

6、ed to show sizes andproportions. These samplers are offered primarily as examples(or generic representations) of equipment that can be purchasedcommercially or built from plans in technical journals.1.5 This guide is a brief summary of published scientificarticles and engineering reports. These refe

7、rences are listed inthis guide. These documents provide operational details thatare not given in this guide but are nevertheless essential to thesuccessful planning and completion of core sampling projects.1.6 The values stated in SI units are to be regarded asstandard. No other units of measurement

8、 are included in thisstandard.1.7 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 determine the applica-bility of regulatory limitation

9、s prior to use. For specificwarning statements, see 6.3 and 11.5.2. Referenced Documents2.1 ASTM Standards:2D420 Guide to Site Characterization for Engineering Designand Construction Purposes (Withdrawn 2011)3D1129 Terminology Relating to WaterD1452 Practice for Soil Exploration and Sampling by Auge

10、rBoringsD1586 Test Method for Penetration Test (SPT) and Split-Barrel Sampling of SoilsD1587 Practice for Thin-Walled Tube Sampling of Soils forGeotechnical PurposesD4220 Practices for Preserving and Transporting SoilSamplesD4410 Terminology for Fluvial Sediment3. Terminology3.1 DefinitionsFor defin

11、itions of terms used in this guide,refer to Terminology D1129 and Terminology D4410.3.2 Definitions of Terms Specific to This Standard:3.2.1 check valvea device (see Fig. 1)4mounted atop anopen-barrel core sampler. As the sampler moves down throughwater and sediment, the valve remains open to allow

12、water toflow up through the barrel. When downward motion stops, thevalve closes. During retrieval, the valve remains closed andcreates suction that holds the core inside the barrel.3.2.2 corea vertical column of sediment cut from a parentdeposit.3.2.3 core catchera device (see Fig. 2) that grips and

13、supports the core while the sampler is being pulled from thesediment and hoisted to the water surface.3.2.4 core conveyora device (see Fig. 3) for reducingfriction between a core and the inside surface of a core barrel.3.2.5 core-barrel linera rigid, thin-wall tube mountedinside the barrel of a core

14、 sampler. During the core-cuttingprocess, sediment moves up inside the liner.1This guide is under the jurisdiction of ASTM Committee D19 on Water and isthe direct responsibility of Subcommittee D19.07 on Sediments, Geomorphology,and Open-Channel Flow.Current edition approved Jan. 1, 2014. Published

15、March 2014. Originallyapproved in 1988. Last previous edition approved in 2008 as D4823 95 (2008).DOI: 10.1520/D4823-95R14.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, re

16、fer to the standards Document Summary page onthe ASTM website.3The last approved version of this historical standard is referenced onwww.astm.org.4The boldface numbers in parentheses refer to the list of references at the end ofthis guide.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C

17、700, West Conshohocken, PA 19428-2959. United States13.2.6 core sampleran instrument for collecting cores.3.2.7 extrudeThe act of pushing a core from a core barrelor a core-barrel liner.3.2.8 open-barrel samplerin simplest form, a straighttube open at both ends. More elaborate open-barrel samplersha

18、ve core catchers and check valves.3.2.9 piston immobilizera special coupling (see Fig. 4)that protects a core from disruptive forces that arise duringsampler pull-out. Piston immobilizers are also called splitpistons or break-away pistons.3.2.10 piston samplera core sampler (see Fig. 5) with asolid

19、cylinder (piston) that seals against the inside walls of thecore barrel. The piston remains fixed at the bed-surfaceelevation while the core barrel cuts down through the sediment.3.2.11 recovery ratiothe ratio A/B where “A” (see Fig. 1)is the distance from the top of the sediment core to the bottomo

20、f the cutting bit and “B” is the distance from the surface of theparent deposit to the bottom of the cutting bit.3.2.12 repenetrationa mishap that occurs when a coresampler collects two or more cores during one pass.3.2.13 surface samplera device for collecting sedimentfrom the surface of a submerge

21、d deposit. Surface samplers aresometimes referred to as grab samplers.3.2.14 trip releasea mechanism (see Fig. 5 and Fig. 6(b)that releases a core sampler from its suspension cable andNOTE 1Dark bands represent stiff sediments; light bands representplastic sediments. As coring proceeds, sediment bel

22、ow the barrel moveslaterally away from the cutting edge and plastic sediments inside the barrelare compressed. “A” is the cores length and “B” is the barrelspenetration depth.FIG. 1 Deformations Caused by Open-Barrel Core Samplers (1)NOTE 1(a) The leaves separate during penetration and then closedur

23、ing retrieval. Strips of gauze can be woven around the leaves toprovide additional support. (2) (b) The lever trips down during retrieval torelease the spring and twist the fabric sleeve shut. (3) (c) The cupped platedrops during retrieval to block the entrance and support the core. (3) (d)The lever

24、 releases the spring-loaded blade which pivots downward to holdthe core. (3)FIG. 2 Core CatchersNOTE 1(a) Strips of metal foil slide up through the core barrel as thecutting edge advances downward. (4) (b) The plastic sleeve unfolds frompleats stored near the cutting edge. This sleeve surrounds the

25、core as thebarrel moves down. (3)FIG. 3 Core ConveyorsNOTE 1During penetration the shear pins break but the flow-restricting orifice holds the clevis and piston together. During retrieval,water in the top chamber flows through the orifice and allows the pistonand clevis to separate. Cable tension pu

26、lls the clevis up against the stopbut friction locks the piston and core barrel together.FIG. 4 Piston Immobilizer (5)D4823 95 (2014)2allows the sampler to freely fall a predetermined distancebefore striking the bed.3.2.15 undisturbed samplesediment particles that havenot been rearranged relative to

27、 one another by the process usedto cut and isolate the particles from their parent deposit. Allcore samples are disturbed to some degree because raising thecores to the water surface causes pore water and trapped gasesto expand (10). In common usage, the term “undisturbedsample” describes particles

28、that have been rearranged but onlyto a slight degree.4. Critical Dimensions of Open-Barrel and PistonSamplers4.1 Dimensions of a samplers cutting bit, core tube, andcore-tube liner (see Fig. 7) are critical in applications requiringundisturbed samples. These dimensions control the amount ofdistortio

29、n in recovered cores. The recommendations in thissection were developed from tests on open-barrel core sam-plers (11); however, the recommendations are usually extendedto cover piston-type core samplers.4.2 Cutting-Bit AngleThe angle “b” on the cutting bit (seeFig. 7) should be less than about 10; t

30、he optimum angle isabout 5. If the angle is smaller than about 2, the bit cutsefficiently but its edge chips and dulls easily.4.3 Core-Liner Diameter, Ds(see Fig. 7)Dsshould belarger than about 5 cm; however, the upper limit for Dsisdifficult to establish. As Dsincreases, the amount of corecompactio

31、n decreases but the sampler becomes heavier andlarger. A survey of existing samplers shows that 10 cm is apractical upper limit. A few samplers have barrels larger than10 cm but these are used only for special applications (12).4.4 Inside Friction FactorThe dimensions Dsand De(seeFig. 7) set the ins

32、ide friction factor defined as Ci=(DsDe)100/De. For a barrel without a core conveyor, the optimumCivalue depends mainly on the barrels length. Cishould besmaller than 0.5 if the barrel is shorter than about 2 m. If thebarrel is longer than about 2 m, Cishould fall between 0.75 and1.5. For a barrel w

33、ith a core conveyor, Cishould be smallerthan 0.5 regardless of the barrels length. Notice that in allinstances Dsis lightly greater than De. The small expansionabove the cutting bit minimizes friction where the outside ofthe core contacts the inside of the barrel or liner. Frictiondistorts the cores

34、 strata by bending horizontal layers intocurved, bowl-shaped surfaces shown on the upper part of Fig.8. Friction also causes overall end-to-end compaction of thecore and thereby reduces recovery ratios. If friction becomesvery large, sediment fails to enter the cutting bit. Instead,sediment moves as

35、ide as the bit penetrates downward. Thislateral motion, commonly referred to as “staking,” preventsdeep-lying strata from being sampled. It is important toobserve upper limits on Cibecause too large an expansioncauses another form of distortion, the core slumps against thewalls as the sediment slide

36、s up into the barrel.NOTE 1(a) The sampler is lowered slowly through the water. (b) Thesampler falls free when the trip weight contacts the bed. (c) The corebarrel cuts downward but the piston remains stationary.FIG. 5 Operation of a Piston-Type Core Sampler (6)NOTE 1(a) The messenger weight strikes

37、 the hook and releases thestring holding the check valve. (7) (b) The trip weight strikes the sedimentand unhooks the sampler. (8) (c) The cable slackens and allows thespring-loaded hook to open. (9)FIG. 6 Release MechanismFIG. 7 Critical Dimensions for Cutting Bits and Core Barrels (11)D4823 95 (20

38、14)34.5 Outside Friction FactorThe dimensions Dwand Dt(see Fig. 7) set the outside friction factor defined as Co=(Dw Dt)100/Dt. Coshould be zero for barrels used in cohesionlesssediments; but Coshould be between 1.0 and about 3.0 forbarrels used in cohesive sediments. Notice that in all instancesDwi

39、s larger than Dt. The small contraction above the bitreduces friction at the outside surface of the barrel and makesit easier to push the core barrel into the bed. On a long barrel,friction can be reduced by installing one or more sleeves (seeFig. 7). The sleeves not only plough a path for the barre

40、l butthey also serve as clamps to hold barrel sections together.4.6 Area FactorThe dimensions Dwand Deset the areafactor defined as Ca=(Dw2) 100/De2. Cashould be less than10 or possibly 15. Notice that Cais proportional to the area ofsediment displaced by the bit divided by the area of the bitsentra

41、nce; therefore, Cais an index of disturbance at the cuttingedge. A sampler with too large an area factor tends tooversample during early stages of penetration when frictionalong the inner wall of the barrel is low. Oversampling occursbecause sediment laying below and outside the bit shift inwardas t

42、he bit cuts downward.4.7 Core-Barrel LengthA samplers core barrel should beslightly longer than L, the longest core that can be collectedwithout causing significant compaction. L and Ds(see Fig. 7)set the core-length factor defined as Lf= L/Ds. Lfshould beless than 5.0 (or possibly 10) for a sampler

43、 used in cohesivesediments, but Lfshould be less than 10 (or possibly 20) for asampler used in cohesionless sediments.The constant factors 5,10, and 20 apply to slow-penetrating, open-barrel samplers.Studies suggest that all of these factors can be increased byraising the samplers penetration speed

44、or using a pistonsampler instead of an open-barrel sampler.4.8 Barrel SurfacesAll surfaces contacting the coreshould be smooth and free of protruding edges to reduceinternal friction and minimize core distortion. The surfacesshould also be clean and chemically inert if the core is to beanalyzed for

45、contaminants or if the core is to be stored in itsliner for long periods of time.4.9 Chemical Composition of Sampler PartsSampler partsmust not contain substances that interfere with chemicalanalysis of the cores. For example, barrels, pistons, and corecatchers made of plastic should not be used if

46、tests includephthalate concentrations. Misleading data will result fromplasticizer contamination of the sediments.5. Open-Barrel Samplers Versus Piston Samplers5.1 Users sometimes face difficult decisions in choosingbetween an open-barrel sampler and a piston sampler. Thedecision frequently depends

47、not only upon characteristics ofthe two samplers but also upon other factors such as hoisting-equipment capabilities, working platform stability, waterdepth, operator experience, and the purpose for collecting thecores.This section covers factors to consider before making thefinal choice.5.2 Depth o

48、f PenetrationMost open-barrel samplers andmost piston samplers rely on momentum to drive their barrelsinto sediment deposits. Momentum-driven samplers are re-leased at a predetermined point so as to acquire momentumwhile falling toward the bed. A momentum-driven pistonsampler generally penetrates de

49、eper than a momentum-drivenopen-barrel sampler provided the two samplers have equalweights, equal barrel-diameters, and equal fall-distances (6).5.3 Core CompactionWhen compared under equal testconditions (see 5.2), a piston sampler causes less core com-paction than an open-barrel sampler. However, the piston mustbe held motionless at the bed-surface elevation while the barrelpenetrates downward. If the piston is allowed to shift downwith the barrel, the core undergoes serious compaction.5.4 Flow-in DistortionFlow-in distortion is ca