An analysis of the detection effect of cross-well electromagnetic wave CT in coal mine goaf
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摘要: 内蒙古呼伦贝尔市某露天煤矿的主采煤层埋深在39~90 m,地下有许多地质资料不详的采空区,给露天开采剥离带来了巨大的安全隐患。为了查明地下采空区的具体位置和连通情况,利用跨孔电磁波CT法对采空区内部进行了详细探测,获得了真实可靠的地球物理数据。经分析,较完整岩层电磁波吸收系数在0.43~0.51 Nper/m之间,未充水的采空区电磁波吸收系数在0.29~0.41 Nper/m之间。根据采空区与围岩电磁波吸收系数的差异,绘制了采空区的形态解释成果图,经与钻孔资料对比,一致性较好。Abstract: In an open-pit coal mine in Hulun Buir of Inner Mongolia, the main mining coal seams are buried in depths ranging from 39m to 90m. Before coal mine integration, predatory mining has left many mined areas with unknown geological data, and the existence of mined-out areas has brought huge safety hazards to open-pit mining stripping. In order to find out the specific location and connectivity of the underground goaf, the authors used the cross-hole electromagnetic wave CT method to probe into the inside of the goaf in detail, and obtained a lot of real and reliable geophysical data. The analytical result shows that relatively complete rock formation electromagnetic wave absorption coefficient is in the range of 0.44~0.51Nper/m, and no water-filled goaf electromagnetic wave absorption coefficient is in the range of 0.29~0.40 Nper/m. According to the difference of electromagnetic wave absorption coefficient between goaf and surrounding rocks, the authors drew the morphological interpretation map of the goaf, and the results are basically consistent with the drilling data.
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Key words:
- electromagnetic wave CT /
- goaf /
- coal mine /
- absorption coefficient
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