Anisotropic characteristics of granular materials under simple shear 被引量：5

Anisotropic characteristics of granular materials under simple shear

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摘要 The discrete element method was used to investigate the microscopic characteristics of granular materials under simple shear loading conditions. A series of simple tests on photo-elastic materials were used as a benchmark. With respect to the original experimental observations, average micro-variables such as the shear stress, shear strain and the volumetric dilatancy were extracted to illustrate the performance of the DEM simulation. The change of anisotropic density distributions of contact normals and contact forces was demonstrated during the course of simple shear. On the basis of microscopic characteristics, an analytical approach was further used to explore the macroscopic behaviors involving anisotropic shear strength and anisotropic stress-dilatancy. This results show that under simple shear loading, anisotropic shear strength arises primarily due to the difference between principal directions of the stress and the fabric. In addition, non-coaxiality, referring to the difference between principal directions of the strain rate and the stress, generates less stress-dilatancy. In particular, the anisotropic hardening and anisotropic stress-dilatancy will reduce to the isotropic hardening and the classical Taylor’s stress-dilatancy under proportional loading. The discrete element method was used to investigate the microscopic characteristics of granular materials under simple shear loading conditions. A series of simple tests on photo-elastic materials were used as a benchmark. With respect to the original experimental observations, average micro-variables such as the shear stress, shear strain and the volumetric dilatancy were extracted to illustrate the performance of the DEM simulation. The change of anisotropic density distributions of contact normals and contact forces was demonstrated during the course of simple shear. On the basis of microscopic characteristics, an analytical approach was further used to explore the macroscopic behaviors involving anisotropic shear strength and anisotropic stress-dilatancy. This results show that under simple shear loading, anisotropic shear strength arises primarily due to the difference between principal directions of the stress and the fabric. In addition, non-coaxiality, referring to the difference between principal directions of the strain rate and the stress, generates less stress-dilatancy. In particular, the anisotropic hardening and anisotropic stress-dilatancy will reduce to the isotropic hardening and the classical Taylor＇s stress-dilatancy under proportional loading.

作者 QIAN Jian-gu YOU Zi-pei HUANG Mao-song

机构地区 Key Laboratory of Geotechnical and Underground Engineering of Ministry of Education (Tongji University) Department of Geotechnical Engineering

出处《Journal of Central South University》 SCIE EI CAS 2013年第8期2275-2284,共10页 中南大学学报（英文版）

基金 Foundation item： Projects（10972159, 41272291, 51238009） supported by the National Natural Science Foundation of China Project supported by the Fundamental Research Funds of the central Universities

关键词 simple shear discrete element method ANISOTROPY NON-COAXIALITY simple shear discrete element method anisotropy non-coaxiality

分类号 TU457 [建筑科学—岩土工程] O343.8 [建筑科学—土工工程]

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