废弃矿井软岩-煤体在循环动力荷载作用下的破坏机理试验研究

Dong Wang , Yujing Jiang , Bin Liang , Zhijie Wen , Jianlong Wang
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引用次数: 0

摘要

在废弃矿井抽水蓄能电站的建设和运行过程中,由顶板和残留煤柱组成的软岩煤体结构会遇到以循环荷载为特征的复杂应力环境。研究其在循环动荷载作用下的破坏机理,对于保证废弃矿井抽水蓄能电站的安全和稳定具有重要的理论和现实意义。本文以不同成岩率的 "顶板-残留煤柱 "软岩-煤组合为研究对象,通过循环动荷载实验研究其力学性能、破坏机理、能量演化特征和声发射分布特征。实验结果表明(1) 弱循环动荷载和高岩石百分率都能增强软岩-煤组合的抗变形能力。在低扰动水平循环加载下,其峰值强度和弹性模量随岩石百分率的增加而增加。(2) 在低扰动水平循环荷载下,随着岩石比例的增加,组合的平均总应变能密度、耗散能密度和弹性能密度呈上升趋势。(3) 在低扰动水平循环荷载作用下,随着软岩-煤组合中岩石比例的增加,岩体部分的破坏程度逐渐加剧,而煤部分的破坏程度逐渐减弱。(4)在煤岩组合失稳和破坏的瞬间产生大量声发射信号,主要以煤体破坏产生的信号为主。关键点 N2 的声发射计数和绝对能量随着岩石比例的增加而减少。b 值主要分布在循环动态加载阶段和破坏阶段,均呈现出 b 值突然增加和突然减少的区域。
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Experimental study on failure mechanism of soft rock-coal bodies in abandoned mines under cyclic dynamic loading

During the construction and operation of a pumped storage power station in an abandoned mine, the soft rock-coal body structure, comprising the roof and the residual coal pillars, encounters a complex stress environment characterized by cyclic loads. The study of its failure mechanism under cyclic dynamic loading holds significant theoretical and practical importance to stay the safety and stability of the abandoned mine pumped storage power station. In this paper, we take “roof-residual coal pillar” soft rock-coal combinations with different percentages of rock as the research object, and study their mechanical properties, failure mechanism, energy evolution characteristics and acoustic emission distribution characteristics through cyclic dynamic loading experiments. The results of the experiment indicate that: (1) Both weak cyclic dynamic loading and high rock percentage enhance the deformation resistance of soft rock-coal combinations. Under low-disturbance horizontal cyclic loading, its peak strength and modulus of elasticity increase with increasing rock percentage. (2) Under low-disturbance horizontal cyclic loading, an increasing trend is observed in the average total strain energy density, dissipation energy density, and elastic energy density of the combinations as the percentage of rock increases. (3) Under low-disturbance horizontal cyclic loading, as the percentage of rock increases in the soft rock-coal combinations, the degree of failure in the rock body part progressively intensifies, while the destruction of the coal portion progressively decreases. (4) The large number of acoustic emission signals are generated at the instant of destabilization and destruction of the coal-rock combinations, mainly dominated by the signals generated by the destruction of the coal body. Acoustic emission counts and absolute energy at key point N2 decrease as the percentage of rock increases. The b value is primarily distributed in the cyclic dynamic loading stage and the failure stage, both displaying zones of sudden increase and sudden decrease in b value.

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