大采高工作面煤壁破坏机制研究

doi:10.13722/j.cnki.jrme.2016.0874

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摘要

针对大采高工作面煤壁易发生片帮、冒顶这一难题，以王庄矿8101工作面为背景，构建“顶板–煤壁–支架”系统力学模型，对煤壁稳定性影响因素进行敏感度分析；设计煤壁稳定性控制实验台对煤壁稳定性与采高、支架工作阻力、煤壁压力及煤体强度的关系进行模拟实验；采用UDEC数值软件对不同采高、黏聚力、支护强度、推进距离下煤壁变形情况进行模拟。研究得到：煤壁处的顶板压力是煤壁发生破坏的主要因素，煤体强度决定着煤壁所能承受的顶板压力；采高越大、煤壁发生破坏时的临界压力越小，煤壁越不稳定；支架的支护强度越大，作用在煤壁处的压力就越小，煤壁越稳定，但提高支护强度对于控制煤壁破坏的作用是有限的；支架护帮板在控制塑性区煤体继续破坏起的作用不大。煤壁破坏前，煤体具有较大的变形量，且煤壁破坏位置多发生在煤壁中上部，为采高的60%～70%。研究成果为煤壁片帮的防治提供了基础。

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	孔德中1
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关键词 ：采矿工程, 大采高工作面, 煤壁稳定性, 影响因素, 实验台, 数值模拟

Abstract：

In response to the condition that coal face spalling and roof-fall occurring frequently in the large-cutting-height mining face，taking panel 8101 of Wangzhuang coal mine as background，the“roof-coal face-support”system mechanical model has been established to conduct the influence factors sensitivity analysis of coal face stability. Experimental test for coal face stability study has been designed to conduct similarity simulation test in order to study the relations between coal face stability and influence factors such as mining height，support working resistance，coal face pressure and coal strength. UDEC numerical simulation was used to simulate the coal face deformation in changing mining height，cohesion，support capacity and advancing length. The study shows that coal face pressure and coal strength are the main reason that causing coal face failure. The larger is the mining height，the smaller is the limited coal face failure pressure. The larger is the support capacity，the smaller is the coal face pressure. However，improving of support capacity only has limit impact on coal wall failure controlling. Guard board of support can prevent the fractured coal face from sliding down effectively but has little impact on coal face failure controlling. There is a large deformation in coal body before the coal face failure. The coal face failure position locates as the upper part of coal face，usually 60%–70% of mining height. These results provide a foundation for coal face spalling prevention.

Key words： mining engineering large-cutting-height mining face coal face stability affecting factors experimental frame numerical simulation

引用本文:

孔德中1，2，刘洋1，刘勤志1. 大采高工作面煤壁破坏机制研究[J]. 岩石力学与工程学报, 2018, 37(S1): 3458-3469.
KONG Dezhong1，2，LIU Yang1，LIU Qinzhi1. Study of coal face failure mechanism of a large-cutting-height mining face. , 2018, 37(S1): 3458-3469.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.13722/j.cnki.jrme.2016.0874 或 https://rockmech.whrsm.ac.cn/CN/Y2018/V37/IS1/3458

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