高渗透压和不对称围压作用下深竖井围岩损伤破裂机理

Mechanism of country rock damage and failure in deep shaft excavation under high pore pressure and asymmetric geostress

  • 摘要: 随着矿产资源开采深度的不断增大,地应力、地温和孔隙水压随之显著增大,岩石的非线性力学行为更加凸显。针对高渗透压和不对称围压作用下深竖井围岩损伤破裂问题,构建了流固损伤耦合效应力学分析模型,分析了流固耦合条件下深竖井开挖围岩有效应力,探讨了孔隙水压及地应力场对围岩损伤破裂演化的作用机制。研究结果表明:孔隙水压及孔隙水压梯度越大围岩损伤破裂区面积越大,围岩损伤破裂区面积随围岩渗透率的减小逐渐增大并趋于稳定;地应力场对围岩破裂形态具有重要控制作用,最大水平主应力与最小水平主应力差异较小时,围岩损伤破裂区集中在最小水平主应力方向,以剪切损伤为主,最大水平主应力与最小水平主应力差异较大时,在最大水平主应力方向上会产生拉伸损伤破裂区。值得关注的是,由于孔隙水压的存在,最大有效水平主应力与最小有效水平主应力之间的比值增大,即围岩发生拉伸破坏的风险增大。本文研究表明,竖井选址和设计过程中应避开构造应力大、孔隙水压大的区域,从而保障井筒施工安全。

     

    Abstract: With the development of the mining industry, a large number of accessible shallow mineral resources are being depleted, and some have now been completely exhausted. The exploitation of the Earth’s deep mineral resources has become the only way to meet the society’s growing demand for minerals. With the increase in mining depth, the geostress, temperature, and pore pressure of water increase significantly, and the nonlinear mechanical behavior of rock becomes prominent. To assess the damage and failure of surrounding rock in deep shaft under high osmotic pressure and asymmetric geostress, a coupled mechanical–hydraulic–damage model was proposed to examine the effective stress of surrounding rock in deep shaft. This approach took into account the maximum tensile stress criterion with shear failure based on the Mohr–Coulomb criterion and was applied to simulate damage evolution in heterogeneous rocks. On this basis, the mechanisms of pore pressure, rock permeability, and geostress and its effects on rock damage evolution and fracture propagation were further investigated. The results indicate that the larger the pore pressure and its gradient are, the larger the damage and failure areas of surrounding rock. With the decrease of permeability of country rock, the damage and failure areas of country rock gradually increase and tend to be stable. The geostress field plays an important role in controlling the failure morphology of surrounding rock. When the ratio between maximum and minimum horizontal principal stresses is small, the damage and failure zones of the surrounding rock are concentrated in the direction of the minimum horizontal principal stress, mainly shear damage. However, if the ratio is large enough, then the tensile damage zone may occur in the direction of the maximum horizontal principal stress. Notably, the ratio of the maximum horizontal principal effective stress to the minimum horizontal principal effective stress increases because of the presence of pore pressure. Therefore, a high pore pressure in the formation could increase the risk of tensile failure of surrounding rocks. The findings of this research can be applied to the optimization of the shaft design to avoid areas with high tectonic stress and high pore pressure and ensure the safety of shaft construction.

     

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