Strain localization of Mohr-Coulomb soils with non-associated plasticity based on micropolar continuum theory

IF 9.4 1区 工程技术 Q1 ENGINEERING, GEOLOGICAL
Jianbin Tang, Xi Chen, Liusheng Cui, Zongqi Liu
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Abstract

To address the problems of strain localization, the exact Mohr-Coulomb (MC) model is used based on second-order cone programming (mpcFEM-SOCP) in the framework of micropolar continuum finite element method. Using the uniaxial compression test, we focused on the earth pressure problem of rigid wall segment involving non-associated plasticity. The numerical results reveal that when mpcFEM-SOCP is applied, the problems of mesh dependency can be effectively addressed. For geotechnical strain localization analysis involving non-associated MC plasticity, mpcFEM-SOCP in conjunction with the pseudo-time discrete scheme can improve the numerical stability and avoid the unreasonable softening issue in the pressure-displacement curves, which may be encountered in the conventional FEM. It also shows that the pressure-displacement responses calculated by mpcFEM-SOCP with the pseudo-time discrete scheme are higher than those calculated by mpcFEM-SOCP with the Davis scheme. The inclination angle of shear band predicted by mpcFEM-SOCP with the pseudo-time discrete scheme agrees well with the theoretical solution of non-associated MC plasticity.

基于微极连续统理论的非关联塑性Mohr-Coulomb土应变局部化
为了解决应变局部化问题,在微极连续体有限元法的框架下,采用基于二阶锥规划的精确Mohr-Coulomb (MC)模型。利用单轴压缩试验,重点研究了考虑非关联塑性的刚性管段土压力问题。数值结果表明,采用mpcmam - socp方法可以有效地解决网格依赖问题。对于非关联MC塑性的岩土应变局部化分析,mpcFEM-SOCP结合伪时间离散格式可以提高数值稳定性,避免传统有限元方法可能遇到的压力-位移曲线不合理软化问题。采用伪时间离散格式计算的压力-位移响应比采用Davis格式计算的压力-位移响应高。用伪时间离散格式预测的剪切带倾角与非关联MC塑性的理论解吻合较好。
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来源期刊
Journal of Rock Mechanics and Geotechnical Engineering
Journal of Rock Mechanics and Geotechnical Engineering Earth and Planetary Sciences-Geotechnical Engineering and Engineering Geology
CiteScore
11.60
自引率
6.80%
发文量
227
审稿时长
48 days
期刊介绍: The Journal of Rock Mechanics and Geotechnical Engineering (JRMGE), overseen by the Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, is dedicated to the latest advancements in rock mechanics and geotechnical engineering. It serves as a platform for global scholars to stay updated on developments in various related fields including soil mechanics, foundation engineering, civil engineering, mining engineering, hydraulic engineering, petroleum engineering, and engineering geology. With a focus on fostering international academic exchange, JRMGE acts as a conduit between theoretical advancements and practical applications. Topics covered include new theories, technologies, methods, experiences, in-situ and laboratory tests, developments, case studies, and timely reviews within the realm of rock mechanics and geotechnical engineering.
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