煤层导水裂缝带电各向异性特征研究

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摘要水害是煤矿五大自然灾害之一，严重威胁着煤矿工人的生命安全，其主要原因是煤层导水裂缝带诱发透水事故。由于导水裂隙带电各向异性严重，利用传统的电阻率方法探测的电阻率信息将会导致错误的水文地质结论。本文以煤层导水裂缝带为地质基础，建立地电模型，研究煤层导水裂隙带电各向异性特征。分别讨论了裂隙带地层水电导率、基质孔隙度、基质电阻率、裂缝密度，裂缝表面粗糙度，围岩地层压力大小以及裂缝倾角的对导水裂隙带电各向异性的影响。通过数值模拟，定性分析了各因素对电各向异性的影响以及地表视电阻分布形态与导水裂隙带特征之间的关系，初步探讨了利用导水裂隙带的电各向异性研究裂缝走向以及倾向方法。

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关键词：煤层导水裂缝带电各向异性表面粗糙度地层水电导率围压

Abstract： Water flooding disasters are one of the five natural coal-mining disasters that threaten the lives of coal miners. The main causes of this flooding are water-conducting fractured zones within coal seams. However, when resistivity methods are used to detect water-conducting fractured zones in coal seams, incorrect conclusions can be drawn because of electrical anisotropy within the water-conducting fractured zones. We present, in this paper, a new geo–electrical model based on the geology of water-conducting fractured zones in coal seams. Factors that influence electrical anisotropy were analyzed, including formation water resistivity, porosity, fracture density, and fracture surface roughness, pressure, and dip angle. Numerical simulation was used to evaluate the proposed electrical method. The results demonstrate a closed relationship between the shape of apparent resistivity and the strike and dip of a fracture. Hence, the findings of this paper provide a practical resistivity method for coal-mining production.

Key words： water-conducting fractured zones in coal seams coalfield goaf electrical anisotropy surface roughness formation water resistivity formation pressure

收稿日期: 2016-07-18;

基金资助:

本研究由江苏高校优势学科建设工程、中央高校基本业务基金（编号：2014QNA88）和国家自然基金（编号：41674133）联合资助。

引用本文:

. 煤层导水裂缝带电各向异性特征研究[J]. 应用地球物理, 2017, 14(2): 216-224.

. Research of the electrical anisotropic characteristics of water-conducting fractured zones in coal seams[J]. APPLIED GEOPHYSICS, 2017, 14(2): 216-224.

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