大采高综采覆岩两带发育高度特征研究

doi:10.16265/j.cnki.issn1003-3033.2022.S2.0178

摘要/Abstract

摘要：

覆岩两带发育高度是矿井水害防治和实施保水采煤的一个基本参数。为揭示西部宁东煤炭基地大采高综采覆岩移动破坏特征,以红柳煤矿1121综采面为研究对象,采用钻探、数值模拟和综合分析相结合的方法研究覆岩两带发育高度及其破坏特征。结果表明:1121综采面开采后覆岩两带发育高度为81.66 m,裂采比15.47,垮落带高度为42.76 m,垮采比8.10;综采面回采过程中,上覆岩层主要发生剪切和拉张塑性破坏,分别对应压应力释放和拉应力释放过程;压应力主要集中在工作面切眼和回采前方的煤壁处,拉应力主要集中在采空区上方;覆岩两带发育可划分为孕育、发育、缓增、突增和稳定5个阶段,发育稳定后整体呈现稍倾斜的“马鞍型”且发育高度与开采距离之间满足正相关的指数关系。

关键词: 大采高综采, 覆岩两带, 发育高度, 数值模拟, 冲洗液消耗量

Abstract:

The development height of two zones of overburden was a basic parameter for preventing and controlling mine water hazards and implementing water-preserved coal mining. In order to reveal the movement and failure law of the overburden, which was caused by fully mechanized mining with large mining height in the Ningdong Coal Base in western China, the 1121 fully mechanized mining face of Hongliu Coal Mine was taken as the research object. The development height and failure law of the two zones of overburden were studied by means of drilling, numerical simulation, and comprehensive analysis. The results show that the development height of the two zones of overburden after mining in the 1121 fully mechanized mining face is 81.66 m. The fracture-height ratio is 15.47. In addition, the height of the caving zone is 42.76 m, and the caving-height ratio is 8.10. In the mining process of the fully mechanized mining face, the overlying strata mainly undergo shear and tensile plastic failure, which correspond to the release of compressive stress and tensile stress, respectively. The compressive stress is mainly concentrated in the cut hole of the working face and the coal wall in front of the mining. The tensile stress is mainly concentrated above the goaf. The development of the two zones of overburden can be divided into five stages: incubation, development, slow increase, sudden increase, and stability. Once the development is stable, a slightly inclined saddle shape is shown. Furthermore, there is a positive exponential correlation between development height and mining distance.

Key words: large mining height, two zones of overburden, developemt height, numerical simulation, flushing fluid consumption

郭维. 大采高综采覆岩两带发育高度特征研究[J]. 中国安全科学学报, 2022, 32(S2): 142-147.

GUO Weiqiang. Study on characteristics of height of two zones of overburden caused by fully mechanized mining with large mining height[J]. China Safety Science Journal, 2022, 32(S2): 142-147.

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