应力作用下软硬互层岩石破裂过程的细观模拟

doi:10.13722/j.cnki.jrme.2014.0387

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摘要采用数值模拟方法研究软硬互层岩石材料在不同围压条件下的压缩破坏过程。利用改进刚体弹簧方法，模拟细观裂隙的起裂和扩展过程。界面破坏准则结合莫尔–库仑准则和抗拉强度准则，能同时考虑拉裂和剪切2种破坏模式。岩石材料由以Voronoi图形为基础的块体集合表征为显式模拟结构面，提出一种分步插点的计算网格自动生成算法。对已有的典型实验进行计算，模拟得到不同围压下不同倾角数值试件的破坏模式和抗压强度。与实验结果的对比表明，改进刚体弹簧方法能够定性和定量地描述由于软硬互层结构引起的抗压强度各向异性，不同围压条件下得到的破坏模式也与实验结果吻合良好。

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关键词 ：岩石力学, 裂隙扩展, 软硬互层, 各向异性, 刚体弹簧方法

Abstract：The failure process of interlayered rocks at different confining pressures was numerical simulated. A modified rigid body spring method(RBSM) was proposed to simulate the initiation and propagation of micro cracks. Both tensile and shear failures were considered with a failure criterion combining Mohr-Coulumb criterion and the tensile strength criterion. The rock material was represented by an equivalent discrete assembly of rigid blocks based on the Voronoi diagram. In order to explicitly account for the structural planes，a multi-step node insertion scheme was proposed for mesh generation. The proposed method was applied to an anisotropic artificial rock containing interlayered structures. Various failure modes and strengths were obtained with regards to the different orientations of structural planes. Simulation results indicated that the proposed model had the capacity to describe the anisotropic behaviors of strength and the failure modes in both qualitative and quantitative manner.

Key words： rock mechanics crack propagation interlayered rock anisotropy rigid body spring method(RBSM)

收稿日期: 2014-03-31

引用本文:

姚池1，李瑶2，姜清辉1，2，周创兵1，2. 应力作用下软硬互层岩石破裂过程的细观模拟[J]. 岩石力学与工程学报, 2015, 34(08): 1542-1551.
YAO Chi1，LI Yao2，JIANG Qinghui1，2，ZHOU Chuangbing1，2. MESOSCOPIC MODEL OF FAILURE PROCESS OF INTERLAYERED ROCK UNDER COMPRESSION. , 2015, 34(08): 1542-1551.

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http://www.rockmech.org/CN/10.13722/j.cnki.jrme.2014.0387 或 http://www.rockmech.org/CN/Y2015/V34/I08/1542

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