瞬变电磁法在探测永明煤矿地质构造中的应用
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摘要
在以往煤层开采过程中,曾发生多起奥灰水突水事故,其导水通道多为断层、陷落柱等构造。因此,在下组深部煤层开采过程中,查明工作面内部构造的发育情况,对工作面水害治理至关重要。陕西永明煤矿有限公司3311工作面内部断层发育,且矿井其他区域已揭露陷落柱,因此采用瞬变电磁法对工作面进行探查。根据3311工作面瞬变电磁法不同深度电阻率分布图,对比分析其他矿区工作面内部陷落柱发育的电阻率分布图。结果表明:在同一位置并没有出现明显的圆形或椭圆形形态特征,判断3311工作面内部发育陷落柱的可能性不大。
In the past, there have been many water inrush accidents of Ordovician limestone water in the process of coal seam mining, and most of the water passages are faults, collapse pillars and other structures. Therefore, in the process of deep coal seam mining in the lower group, it is necessary to ascertain the development of the internal structure of the working face, which is essential for the management of water damage at the working face. The internal fault of the 3311 working face of Yongming Coal Mine is developed, and the collapsed column has been exposed in other areas of the mine. Therefore, the internal surface of the working face is probed by transient electromagnetic method. According to the different depth resistivity distribution maps of the 3311 working face transient electromagnetics, the resistivity distribution maps of the internal collapse columns in the working faces of other mining areas are compared and analyzed. The results show that there is no obvious circular or elliptical morphological feature in the same position, and it is unlikely that the collapsed column will develop inside the 3311 working face.
In the past, there have been many water inrush accidents of Ordovician limestone water in the process of coal seam mining, and most of the water passages are faults, collapse pillars and other structures. Therefore, in the process of deep coal seam mining in the lower group, it is necessary to ascertain the development of the internal structure of the working face, which is essential for the management of water damage at the working face. The internal fault of the 3311 working face of Yongming Coal Mine is developed, and the collapsed column has been exposed in other areas of the mine. Therefore, the internal surface of the working face is probed by transient electromagnetic method. According to the different depth resistivity distribution maps of the 3311 working face transient electromagnetics, the resistivity distribution maps of the internal collapse columns in the working faces of other mining areas are compared and analyzed. The results show that there is no obvious circular or elliptical morphological feature in the same position, and it is unlikely that the collapsed column will develop inside the 3311 working face.
引文
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[4] 付茂如,张平松,王大设,等.矿井工作面底板水害综合探查技术研究[J].矿业安全与环保,2013,40(2):92-95.
[5] 李云波,李好.矿用瞬变电磁法富水体超前探测原理及应用研究[J].矿业安全与环保,2013,40(2):69-72.
[6] 尹尚先,武强,王尚旭.华北岩溶陷落柱突水的水文地质及力学基础[J].煤炭学报,2004,29(2):182-185.
[7] 许进鹏,梁开武,徐新启.陷落柱形成的力学机理及数值模拟研究[J].采矿与安全工程学报,2008,25(1):82-85.
[8] 贾建称,陈健,柴宏有,等.矿井构造研究现状与发展趋势[J].煤炭科学技术,2008,36(10):72-77.
[9] 任亚平.槽波地震勘探在煤矿大型工作面的应用[J].煤田地质与勘探,2015,43(3):102-104.
[10] 袁桂琴,熊盛青,孟庆敏,等.地球物理勘查技术与应用研究[J].地质学报,2011,85(11):1744-1805.
[11] 李江华,廉玉广,焦阳,等.综合物探技术在工作面导水构造探测中的应用[J].煤矿安全,2018,49(3):129-132.
[12] 悦红军,雷琴琴,李建军,等.矿井瞬变电磁仪,CN202631752U[P],2012.
[13] 许洋铖.地面瞬变电磁勘查煤矿水害的能力分析[J].矿业安全与环保,2014,41(5):43-46
[14] 李好,胡运兵,吴燕清.应用矿井瞬变电磁法超前探测煤矿井下含水体[J].矿业安全与环保,2012,39(5):49-52.
[15] 朱慕谦.矿井瞬变电磁法在工作面顶板水文勘探中的应用[J].煤矿现代化,2015,(6):12-13.
[16] 毛候民.瞬变电磁探水技术在勘探煤矿水中的应用实践[J].煤炭与化工,2015,38(2):17-18.
[17] 李琛,李永军,孙浩,等.综合物探技术在构造突水性探测中的应用[J].华北科技学院学报,2016,13(4):115-119.
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