深倾斜煤层沿走向长壁底板顶板开采应力分布及破坏特征

Q3 Engineering

International Journal of Mining and Mineral Engineering Pub Date : 2020-12-16 DOI:10.1504/ijmme.2020.10034280

Fengda Zhang, Baohong Shen, Wenyan Guo

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引用次数: 2

摘要

通过算例分析，结合数值模拟、理论计算和现场实测结果，介绍了深倾斜煤层和沿走向长壁架空开采的应力分布特征和塑性区分布特征。结果表明，该结构是由顶板、互连和主闸门组成的。垂直锥形结构由地板、面部和尾门组成。垂直锥形结构的作用使其运动和变形相互制约，导致垂直应力和最大剪应力的应力集中。最大失效深度为20m，失效区主要集中在互连和工作面附近。通过理论计算，煤层底板的最大破坏深度为21.32m，通过现场试验，最大破坏深度在18.19m至20.24m之间。

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Stress distribution and failure characteristics of deep inclined seam and overhead mining along strike longwall floor

Based on a case study, this paper presents the stress distribution characteristics and plastic zone distribution characteristics of a deep inclined seam and overhead mining along strike longwall (ICMSL) floor by considering the results from numerical simulations, theoretical calculations, and field measurements. The results show that the vertical taper structure is formed by the roof, the interconnection, and the maingate. The vertical taper structure is formed by the floor, the face, and tailgate. The movement and deformation are mutually restricted by the vertical taper structure, which leads to the stress concentration of vertical stress and maximum shear stress. The maximum failure depth is 20 m, and the failure zone is mainly concentrated in the vicinity of the interconnection and face. The maximum failure depth of the coal seam floor is 21.32 m by theoretical calculation, and between 18.19 m and 20.24 m by in situ field tests.

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来源期刊

International Journal of Mining and Mineral Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

1.90

自引率

0.00%

发文量