Preliminary investigation on parameter inversion for three-dimensional distinct element modeling of methane hydrate

JIANG Ming-jing; HE Jie; SHEN Zhi-fu

doi:10.11779/CJGE201404019

Volume 36 Issue 4

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Chinese Journal of Geotechnical Engineering > 2014 > 36(4): 736-744. > DOI: 10.11779/CJGE201404019

JIANG Ming-jing, HE Jie, SHEN Zhi-fu. Preliminary investigation on parameter inversion for three-dimensional distinct element modeling of methane hydrate[J]. Chinese Journal of Geotechnical Engineering, 2014, 36(4): 736-744. DOI: 10.11779/CJGE201404019

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Preliminary investigation on parameter inversion for three-dimensional distinct element modeling of methane hydrate

JIANG Ming-jing^{1, 2, 3},
HE Jie^{1, 2, 3},
SHEN Zhi-fu^{1, 2, 3}

1. Department of Geotechnical Engineering, College of Civil Engineering, Tongji University, Shanghai 200092, China; 2. Key Laboratory of Geotechnical & Underground Engineering of Ministry of Education, Tongji University, Shanghai 200092, China; 3. State Key Laboratory of Disaster Reduction in Civil Engineering, Tongji University, Shanghai 200092, China

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Received Date: July 02, 2013
Published Date: April 21, 2014

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Abstract

Abstract

Marine sandy sediments containing pore-filling type methane hydrate particles can be considered as a class of special granular materials which present apparent discontinuity characteristics. To numerically simulate such materials, the distinct element method (DEM) can be used by modeling methane hydrate particles as groups of spheres cemented together and filled into the pores of soil skeleton. The model parameters for inter-particle bonds within an individual hydrate particle are investigated through parameter inversion against the existing laboratory triaxial compression (TC) test results of methane hydrate blocks under various confining pressures. The results indicate that a loose packing with low inter-particle friction needs to be used for the simulated methane hydrate block. When the inter-particle friction coefficient is equal to or less than 0.0, the friction angle obtained from the unbounded sample is less than that of the experimental tests. The bond stiffness varying in a very small range can adequately capture the elastic behavior of methane hydrate under different confining pressures at the same temperature. Because the interaction between stiffness parameters and bond strength parameters is small, it is assumed that the two types of parameters should be independent. The relationships between micro bond strength parameters and macro parameters (internal friction angle and cohesion) are established by conducting TC tests on choosing different micro bond strength parameters. The methane hydrate shows volume contraction, then dilatancy. And the characteristic dilatancy increases with the decrease of the confining pressure. With the increase of the axial strain, the grain contact direction deflects
- methane hydrate,
- DEM,
- parameter inversion,
- bond model,
- anisotropy,
- percentage of intact bonds

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[1]	BIRCHWOOD R, DAI J, SHELANDER D, et al. Developments in gas hydrates[J]. Oilfield Review, 2010, 22(1): 18-33.
[2]	KVENVOLDEN K A, LORENSON T D. The global occurrence of natural gas hydrate[M]// Natural Gas Hydrates: Occurrence, Distribution, and Detection. Washington:American Geophysical Union, 2001.
[3]	BRUGADA J, CHENG Y P, SOGA K, et al. Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution[J]. Granular Matter, 2010, 12(5): 517-525.
[4]	HACISALIHOGLU B, DEMIRBAS A H, HACISALIHOGLU S. Hydrogen from gas hydrate and hydrogen sulfide in the black sea[J]. Energy Education Science and Technology, 2008, 21(1/2): 108.
[5]	Committee on Assessment of the Department of Energy's Methane Hydrate Research and Development Program: Evaluating Methane Hydrate as a Future Energy Resource. Committee on Earth Resources. Board on Earth Sciences and Resources. Division on Earth and Life Studies. National Research Council of the National Academies. Realizing the energy potential of methane hydrate for the United States[R]. Washington: the National Academies Press, 2010.
[6]	NIXON M F, GROZIC J L H. Submarine slope failure due to hydrate dissociation: a preliminary quantification[J]. Canadian Geotechnical Journal, 2007, 44(3): 314-325.
[7]	SOGA K, LEE S L, NG M Y A, et al. Characterisation and engineering properties of methane hydrate soils[J]. Characterisation and Engineering Properties of Natural Soils, 2007, 3: 2591-642.
[8]	WAITE W F, SANTAMARINA J C, CORTES D D, et al. Physical properties of hydrate-bearing sediments[J]. Reviews of Geophysics, 2009, 47(4): RG4003.
[9]	UCHIDA S, SOGA K, YAMAMOTO K. Critical state soil constitutive model for methane hydrate soil[J]. Journal of Geophysical Research, 2012, 117(B3): B03209.
[10]	WAITE W F, WINTERS W J, MASON D H. Methane hydrate formation in partially water-saturated Ottawa sand[J]. American Mineralogist, 2004, 89(8/9): 1202-1207.
[11]	HYODO M, NAKATA Y, YOSHIMOTO N, et al. Basic research on the mechanical behavior of methane hydrate-sediments mixture[J]. Japanese Geotechnical Society, 2005, 45(1): 75-85.
[12]	WINTERS W J, PECHER I A, WAITE W F, et al. Physical properties and rock physics models of sediment containing natural and laboratory-formed methane gas hydrate[J]. American Mineralogist, 2004, 89(8/9): 1221-1227.
[13]	MIYAZAKI K, MASUI A, SAKAMOTO Y, et al. Triaxial Compressive properties of artificial methane-hydrate-bearing sediment[J]. Journal of Geophysical Research, 2011, 116, B06102.
[14]	张旭辉, 王淑云, 李清平, 等. 天然气水合物沉积物力学性质试验研究[J]. 岩土力学, 2010, 31(10): 3069-3074. (ZHANG Xu-hui, WANG Shu-yun, LI Qing-ping, et al. Experimental study of mechanical properties of gas hydrate deposits[J]. Rock and Soil Mechanics, 2011, 31(10): 3069-3074. (in Chinese))
[15]	张旭辉, 王淑云, 李清平, 等. 天然气水合物沉积物力学性质的试验研究[J]. 岩土力学, 2010, 31(10): 3069-3074. (ZHANG Xu-hui, WANG Shu-yun, LI Qing-ping, et al. Experimental study of mechanical properties of gas hydrate deposits[J]. Rock and Soil Mechanics, 2010, 31(10): 3069-3074. (in Chinese))
[16]	颜荣涛, 韦昌富, 魏厚振, 等. 水合物形成对含水合物砂土强度影响[J]. 岩土工程学报. 2012, 34(7): 1234-1240. (YAN Rong-tao, WEI Chang-fu, WEI Hou-zhen, et al. Effect of hydrate formation on mechanical strength of hydrate-bearing sand[J], Chinese Journal of Geotechnical Engineering , 2012, 34(7): 1234-1240. (in Chinese))
[17]	CUNDALL P A, STRACK O D L. The discrete numerical model for granular assemblies[J]. Géotechnique, 1979, 29(1): 47-65.
[18]	JIANG M J, SUN Y G, YANG Q J. A simple distinct element modeling of the mechanical behavior of methane hydrate-bearing sediments in deep seabed[J]. Granular Matter, 2013, 15(2): 209-220.
[19]	蒋明镜, 肖俞, 朱方园. 深海能源土宏观力学性质离散元数值模拟分析[J].岩土工程学报, 2013, 35(1): 157-163. (JIANG Ming-jing, XIAO Yu, ZHU Fang-yuan. Numerical simulation of macro-mechanical properties of deep-sea methane hydrate bearing soils by DEM[J]. Chinese Journal of Geotechnical Engineering, 2013, 35(1): 157-163. (in Chinese))
[20]	SONG Y C, YU F, LI Y H, et al. Mechanical property of artificial methane hydrate under triaxial compression[J]. Journal of Natural Gas Chemistry, 2010, 19: 246-50.
[21]	YU F, SONG Y C, LIU W G, et al. Analyses of stress strain behavior and constitutive model of artificial methane hydrate[J]. Journal of Petroleum Science and Engineering, 2011, 77(2): 183-188.
[22]	Itasca Consulting Group Inc. PFC3D (Particle Flow Code in 3 Dimensions)[M]. Version 3.0. Minneapolis, MN: ICG; 2002.
[23]	POTYONDY D, CUNDALL P. A bonded-particle model for rock[J]. International Journal of Rock Mechanics and Mining Sciences, 2004, 41(8): 1329-1364.
[24]	WANG J, YAN H. DEM analysis of energy dissipation in crushable soils[J]. Soils and Foundations, 2012, 52(4): 644-657.
[25]	JIANG M J, KONRAD J M, LEROUEIL S. An efficient technique for generating homogeneous specimens for DEM studies[J]. Computers and Geotechnics, 2003, 30(7): 579-597.
[26]	ODA M, IWASHITA K. Mechanics of granular materials[M]. Netherlands: A A Balkema, 1999: 1-80.
[27]	NABESHIMA Y, TAKAI Y, KOMAI T. Compressive strength and density of methane hydrate[C]// Proceedings of the Sixth ISOPE Ocean Mining Symposium. Changsha, 2005.

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