基于井上下微震联合监测技术的矿井防治水应用研究

doi:10.11799/ce202011017

煤炭工程 ›› 2020, Vol. 52 ›› Issue (11): 83-88.doi: 10.11799/ce202011017

基于井上下微震联合监测技术的矿井防治水应用研究

王元杰，路洋波

天地科技股份有限公司

收稿日期:2020-02-13 修回日期:2020-02-21 出版日期:2020-11-16 发布日期:2020-12-16
通讯作者: 路洋波 E-mail:1220042589@qq.com

Study on the Application of Mine Water Prevention and Control based on the joint monitoring technology of well-ground microseism

Received:2020-02-13 Revised:2020-02-21 Online:2020-11-16 Published:2020-12-16

摘要/Abstract

摘要： 基于矿井的地质条件和开采条件，构建井上下一体化微震监测台网，提出了一种井上下微震联合监测技术，对井上下联合微震监测结果在垂直方向的空间分布特征和数量特征进行了分析，并对微震事件分布规律与导水裂隙带发育高度的关系进行了研究。研究结果表明：微震事件在平面位置主要集中在工作面两端，且工作面回风巷侧应力集中程度明显高于运输巷侧，垂直方向上微震事件主要集中在煤层上方0～80m范围内，微震事件数量在顶板以上80m后急剧减少，得出导水裂隙带的最大发育高度在煤层上方80m左右范围内|其中，工作面煤层上方0～20m为垮落带，20～80m为采动裂隙带，微震监测结果与理论计算基本相一致。

关键词: 井上下微震联合监测技术, 微震事件, 定位精度, 导水裂隙带

Abstract: The joint monitoring technique of well-ground microseism for monitoring the development height of water conduction fracture zone in working surface is put forward in this paper. Based on the joint monitoring results of microearthquakes up and down wells, the quantitative and spatial distribution characteristics of microseismic events in vertical direction are analyzed. The relationship between the distribution of microseismic events caused by mining in working face and the development height of water diversion fracture zone is studied. Based on the theoretical calculation results of empirical formula, the development height of water diversion fracture zone is compared and studied. The results show that: The joint monitoring technology of microearthquakes up and down the well has high positioning accuracy. The microseismic events are mainly concentrated at both ends of the working face in the plane position, the stress concentration on the side of return air roadway in working face is obviously higher than that on the side of transportation roadway. The microseismic events in the vertical direction are mainly concentrated in the range of 80m above the coal seam, the number of microseismic events decreased sharply after 80m above the roof. The theoretical calculation results are consistent with the microseismic monitoring results. The research results provide an effective method for monitoring the development height of water diversion fracture zone.

中图分类号:

TD324

王元杰, 路洋波. 基于井上下微震联合监测技术的矿井防治水应用研究[J]. 煤炭工程, 2020, 52(11): 83-88.

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基于井上下微震联合监测技术的矿井防治水应用研究

Study on the Application of Mine Water Prevention and Control based on the joint monitoring technology of well-ground microseism

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