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高应力软岩巷道变形破坏与控制机理数值模拟研究

Numerical simulation study on deformation, failure and controlmechanism of high stress soft rock roadway

  • 摘要: 针对高应力软岩巷道支护难题,以新集口孜东煤矿北翼轨道石门为工程背景,采用离散元数值模拟方法,建立了不同支护条件下的高应力软岩巷道模型,研究高应力软岩巷道变形破坏的机理,以及不同支护方式对高应力软岩巷道的支护加固机理,探求高应力软岩巷道控制技术措施。研究表明:口孜东矿高应力软岩巷道的变形破坏主要集中于巷道的顶板和底板。在巷道底板,高水平应力促使底板砂质泥岩沿层理面张开、滑动、并逐步向巷道内凸起,形成倒V形挤压式底鼓。浅部直接底隆起后,为深部底板泥岩提供了变形空间,泥岩也开始向上弯曲变形。巷道顶板在高水平应力作用下,沿层理面张开、滑动、并逐步向巷道内凸起,形成V形挤压式变形破坏。拉伸破坏在整个顶板和底板围岩的破坏模式中发挥主导作用。U型钢可缩支架壁后充填加锚网索支护,可以在维持较大支护力的情况下抵抗较多巷道变形,从而使巷道保持稳定。

     

    Abstract: In view of the difficult problems of high stress soft rock roadway support, the high-stress soft rock roadway model under different supporting conditions was established by using discrete element numerical simulation method to study the high stress of the north wing transportation roadway of Kouzidong Coal Mine. The mechanism of deformation and failure of soft rock roadway and the support and reinforcement mechanism of different support methods for high stress soft rock roadway, and the technical measures for high stress soft rock roadway control were also investigated. The numerical result shows that the deformation and failure of the high-stress soft rock roadway in the Kouzidong Coal Mine was mainly concentrated on the roof and bottom of the roadway. In the floor, the sandy mud stone fails by means of opening and sliding along the bedding planes and gradually protrudes into the roadway to form an inverted V-shaped extruded floor heave. After the shallow immediate floor directly bulges, it provides a deformation space for the deep floor mud stone, which also begins to bend upward and deform. Under the action of high horizontal stress, the roof of the roadway expands and slides along the bedding plane and gradually protrudes into the roadway to form a V-shaped extrusion deformation failure. It is found that tensile failure plays a dominate role in the failure mode of the surrounding rock of the roof and floor. A support system consisting of rock bolts and cables, U-shaped yielding steel arches and back fill can successfully maintain the stability of roadway excavated in high-stressed soft rock due to its intrinsic feature of providing high support pressure after large deformations.

     

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