Probabilistic analysis of geomembrane puncture from granular material under liquid pressure

Xiao-zhen Jiang; Yi-ming Shu; Jun-gao Zhu

doi:10.1007/s11771-013-1849-4

Journal of Central South University ›› 2013, Vol. 20 ›› Issue (11) : 3256 -3264. DOI: 10.1007/s11771-013-1849-4

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Probabilistic analysis of geomembrane puncture from granular material under liquid pressure

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Abstract

A simplified probabilistic analysis of geomembrane punctures from granular material was presented when subjected to liquid pressure. The probability distribution of contact force between geomembrane and granular material was obtained based on the principle of equal probability and assumptions that grains are spheres with constant size. A particle flow code PFC^3D was employed to simulate the contact process which indicates a good agreement with the theoretical probabilistic analysis. The odds of geomembrane puncture from grains of constant size were obtained by evaluating the puncture force which should not exceed the puncture resistance of geomembrane. The effects of grain radius, grain rigidity and liquid pressure were studied in more detail and displayed in graphs. Both high-level of liquid pressure and large grain can result in high risk of geomembrane puncture. The influence of grain rigidity on the geomembrane puncture odds is significant. For granular material with a grain size distribution, the geomembrane puncture odds can be estimated by the grain size distribution, served as weight function and it is a cautious design if the largest grain is chosen as the design grain size.

Keywords

geomembrane puncture / probability distribution / contact force

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Xiao-zhen Jiang, Yi-ming Shu, Jun-gao Zhu. Probabilistic analysis of geomembrane puncture from granular material under liquid pressure. Journal of Central South University, 2013, 20(11): 3256-3264 DOI:10.1007/s11771-013-1849-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	ScueroA M, VaschettiG L. A new geomembrane system in construction of fill dams: Concepts and two case histories [C]. Proceedings of the 15th Conference of the British Dam Society, 2008LondonTlaomas Telford392-403

[2]	DanielP, LaurentP, PatriceM. Feedback and guidelines for geomembrane lining systems of mountain reservoirs in france [J]. Geotextiles and Geomembrane, 2010, 29: 415-424

[3]	RichardW T, KoernerR M. Advances in HDPE barrier walls [J]. Geotextiles and Geomembranes, 1996, 14: 393-408

[4]	BobL W. Geomembrane application for an RCC dam [J]. Geotextiles and Geomembrane, 1996, 14: 253-264

[5]	Commission of manuals of geosynthetics applications.. Manuals of geosynthetics applications [M]. Beijing: China Architecture & Building Press, 2000201-202

[6]	GudinaS, BrachmanR W I. Physical response of geomembrane wrinkles overlying compacted clay [J]. ASCE Journal of Geotechnical and Geoenvironmental Engineering, 2006, 132(10): 1346-1353

[7]	DickinsonS, BrachmanR W I. Assessment of alternative protection layers for a geomembrane/geosynthetic clay liner (GM/GCL) composite liner [J]. Canadian Geotechnical Journal, 2008, 45(11): 1594-1610

[8]	BrachmanR W I, GudinaS. Gravel contacts and geomembrane strains for a GM/GCL composite liner [J]. Geotextiles and Geomembranes, 2008, 26(6): 448-459

[9]	BrachmanR W I, SabirA. Geomembrane puncture and strains from stones in an underlying clay layer [J]. Geotextiles and Geomembranes, 2010, 28: 335-343

[10]	MüllerWHDPE geomembranes in geotechnics [M], 2007BerlinSpringer-Verlag144-147

[11]	Wilson-FahmyR F, NarejoD, KoernerR M. Puncture protection of geomembrane, Part I: Theory [J]. Geosynthetics International, 1996, 3(5): 605-628

[12]	NarejoD, KoernerR M, Wilson-fahmyR F. Puncture protection of geomembranes, Part II: Experimental [J]. Geosynthetics International, 1996, 3(5): 629-653

[13]	KoernerR M, Wilson-fahmyR F, NarejoD. Puncture protection of geomembranes Part III: Examples [J]. Geosynthetics International, 1996, 3(5): 655-675

[14]	KoernerR M, HsuanY G, KoernerG R, DavidG. Ten year creep puncture study of HDPE geomembrane protected by needle-punched nonwoven geotextiles [J]. Geotextiles and Geomembrane, 2010, 28: 503-513

[15]	NarejoD B. A comparison of puncture behavior of smooth and textured HDPE geomebranes [J]. Geosynthetics International, 1995, 2(4): 699-706

[16]	StarkT D, BoermanT R, ConnorC J. Puncture resistance of PVC geomembranes using the truncated cone test [J]. Geosynthetics International, 2008, 15(6): 480-486

[17]	AlyssaK, MichaelH. Evaluation of geomebrane puncture potential and hydraulic performance in mining applications [C]. Tailings and Mine Waste 08, London, 2009343-349

[18]	ChanS H, NganA H W. 2005. Statistical distribution of contact forces in packings of deformable spheres [J]. Mechanics of Materials, 2005, 37: 493-506

[19]	NganA H W. Mechanical analog of temperature for the description of force distribution in static granular packings [J]. Phys Rev E, 2003, 68: 1-10

[20]	EriksonJ M, NathanW M, HeinrichM J, SidneyR N. Force distributions in three dimensional compressible granular packs [J]. Phys Rev E, 2002, 66(4): 233-238

[21]	WangD M, ZhouY H. Statistics of contact force network in dense granular matter [J]. Particuology, 2010, 8: 133-140

[22]	MÜLLERM, StefanL, ThorstenP. Force statistics and correlations in dense granular packings [J]. Chemical Physics, 2010, 375: 600-605

[23]	AbbasS, BehroozF. Three dimensional discrete element modeling of granular media under cyclic constant volume loading: A micromechanical perspective [J]. Powder Technology, 2011, 212: 1-16

[24]	WilliamFAn introduction to probability theory and its applications third ed [M], 1968New YorkJohn Wiley & Sons, Inc78-86

[25]	SuR-kengStatistical physics [M], 2003BeijingHigher Education Press402-405

[26]	YoshiokaDStatistical physics: An introduction [M], 2005BerlinSpringer-Verlag176-180

[27]	BagiK. Statistical analysis of contact force components in random granular assemblies [J]. Granular Matter, 2003, 5: 45-54

[28]	ZhangGangResearches on Meso-scale mechanism of piping failure by means of model test and pfc numerical simulation [D], 2007ShanghaiTongji University

[29]	CundallP A, StrackO D L. A discrete numerical model for granular assemblies [J]. Geotechnique, 1979, 29: 47-65

[30]	Itasa Consulting Group Inc.. PFC3D (Particle Flow Code in 3 Dimensions) version 3.0 [M]. Minneapolis: Itasca, 200377-80

[31]	GiroudJ P, Badu-tweneboahK, SodermanK L. Theoretical analysis of geomembrane puncture [J]. Geosynthetics International, 1995, 2: 1019-1048

[32]	JohnsonK L. One hundred years of hertz contact [C]. Proc. Instn. Of Mech. Engrs, 196, Institution of Mechanical Engineers, 1982LondonIMECHE363-378

[33]	JohnsomK LSinglerI L, PollockH M. Introduction to contact mechanics: A summary of principle formulae [C]. Fundamentals of friction: Macroscopic and Microscopic Processes, 1992Dordrecht, The NetherlandsKluwer589-603

[34]	LuM, McdowellG R. The importance of modelling ballast particle shape in the discrete element method [J]. Granular Matter, 2007, 9(1/2): 69-80

[35]	RothenburgL, BathurstR J. Micromechanical features of granular assemblies with planar elliptical particles [J]. Geotechnique, 1992, 42(1): 79-95

[36]	RothenburgL, BathurstR J. Influence of particle eccentricity on micromechanical behavior of granular materials [J]. Mechanics of Materials, 1993, 16(1/2): 141-152

[37]	FernandoA, WangY-can. An effcient algorithm for granular dynamics simulations with complex-shaped objects [J]. Granular Matter, 2009, 11: 317-329

[38]	YanY, CuiJ-z, HanFei. An effective computer generation method for the composites with random distribution of large numbers of heterogeneous grains [J]. Composites Science and Technology, 2008, 68: 2543-2550