Effective yield strength of a saturated porous medium with a spheroidal meso-pore and spherical micro-pores

Rock Mechanics Bulletin Pub Date : 2024-01-01 DOI:10.1016/j.rockmb.2023.100097

W.Q. Shen

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Abstract

A macroscopic yield criterion has been derived in the present work for a double saturated porous medium with a spheroidal pore at the mesocale and spherical pores at the microscale. These two types of pores are well separated at two different scales. The meso spheroidal pore saturated by a pore pressure which is different from the one in the micro spherical pores. A Drucker-Prager type criterion is adopted for the solid phase at the microscopic scale to describe its asymmetric behavior between tension and compression. The methodology to formulate this criterion is based on the limit analysis approach of a spheroidal volume containing a confocal spheroidal pore subjected to a uniform strain rate boundary conditions. The matrix at the mesoscopic scale obeys to a general elliptic yield criterion. Based on a two-step homogenization step, the influence of meso-pore shape (spherical, prolate or oblate), micro-porosity, meso-porosity and the effect of pore pressures at different scales are taken into account explicitly by this macroscopic yield criterion.

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具有球形中孔和球形微孔的饱和多孔介质的有效屈服强度

本研究针对中尺度为球形孔隙、微尺度为球形孔隙的双饱和多孔介质推导出了宏观屈服准则。这两种孔隙在两个不同尺度上被很好地分开。中层球形孔隙的饱和孔隙压力与微观球形孔隙的压力不同。在微观尺度上，固相采用了德鲁克-普拉格（Drucker-Prager）类型的标准来描述其在拉伸和压缩之间的不对称行为。制定该准则的方法是基于球形体积的极限分析方法，该球形体积包含一个受均匀应变率边界条件影响的共焦球形孔隙。介观尺度的矩阵服从一般椭圆屈服准则。基于两步均质化步骤，该宏观屈服准则明确考虑了中孔形状（球形、扁球形或扁球形）、微孔率、中孔率以及不同尺度孔隙压力的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Rock Mechanics Bulletin

CiteScore

2.40

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0.00%

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