Coal Geology & Exploration
Abstract
The 6th coal seam of the Carboniferous Permian in a coal mine in the Ordos Basin of Inner Mongolia is an extra-thick coal seam with an average minable thickness of 17.0 m. Its floor is threatened by limestone water. Distributed sensing optical fiber technology and cross-hole resistivity CT in situ comprehensive testing technology were used in the field, and the response characteristics of strain field and geoelectric field were obtained successively during mining. Combined with the threshold value of the discriminant parameter for loading deformation and failure of rock samples and detection section of practice, the monitoring data of the floor of four working faces in the mining area are analyzed comprehensively, and the detailed characteristics and evolution distribution law of the floor failure in the area are obtained. The floor failure has obvious zonation in vertical direction. It is believed that the floor failure depth of the working face in the mining area is 7.2-16.5 m, and the main damage layer is in the fine sandstone interval. The destructive disturbance zone is approximately 33 m deep, mainly in the sandy mudstone interval. The failure of the soleplate has a transverse leading stress effect, and the leading influence distance varies from 25 to 60 m. In addition, the damage characteristics of the floor in the study area are similar to a certain extent. The damage degree of floor caused by mining is spatially distributed in shallow areas in the northeast and deep areas in the southwest. The data obtained from the on-site test has a guiding role for the safe mining of the 6th coal seam in the deep part of the area and the prevention of water hazard.
Keywords
extra-thick coal seam, damage of coal seam floor, distributed optical fiber, cross-hole resistivity CT, Ordos Basin
DOI
10.3969/j.issn.1001-1986.2021.01.029
Recommended Citation
ZHANG Pingsong, LIU Chang, OU Yuanchao,
et al.
(2021)
"Comprehensive testing research on floor damage characteristics of mining extra-thick seam in Jungar Coalfield,"
Coal Geology & Exploration: Vol. 49:
Iss.
1, Article 30.
DOI: 10.3969/j.issn.1001-1986.2021.01.029
Available at:
https://cge.researchcommons.org/journal/vol49/iss1/30
Reference
[1] 袁亮,张平松. 煤炭精准开采地质保障技术的发展现状及展望[J]. 煤炭学报,2019,44(8):2277-2284. YUAN Liang,ZHANG Pingsong. Development status and prospect of geological guarantee technology for precise coal mining[J]. Journal of China Coal Society,2019,44(8):2277-2284.
[2] 高延法,李白英. 受奥灰承压水威胁煤层采场底板变形破坏规律研究[J]. 煤炭学报,1992,17(2):32-39. GAO Yanfa,LI Baiying. Investigation of rules of floor rock failure in the workings with risk of Ordovician confined water[J]. Journal of China Coal Society,1992,17(2):32-39.
[3] 段宏飞. 采动过程中煤层底板破坏特征及破坏深度分析[J]. 煤炭科学技术,2014,42(5):17-20. DUAN Hongfei. Analysis on failure features and failure depth of coal seam floor during mining process[J]. Coal Science and Technology,2014,42(5):17-20.
[4] 王连国,毕善军,宋扬. 底板变形破坏规律的数值模拟研究[J]. 矿山压力与顶板管理,2004,21(4):35-37. WANG Lianguo,BI Shanjun,SONG Yang. Numerical simulation of deformation and failure law of floor[J]. Ground Pressure and Strata Control,2004,21(4):35-37.
[5] 王一栋,姜振泉,朱术云,等. 特厚煤层采动底板变形破坏的数值模拟与实测对比[J]. 煤矿安全,2012,43(10):39-41. WANG Yidong,JIANG Zhenquan,ZHU Shuyun,et al. Contrast of numerical simulation and field measurement on deformation and failure in thick seam mining floor[J]. Safety in Coal Mines,2012,43(10):39-41.
[6] 弓培林,胡耀青,赵阳升,等. 带压开采底板变形破坏规律的三维相似模拟研究[J]. 岩石力学与工程学报,2005,24(23):4396-4402. GONG Peilin,HU Yaoqing,ZHAO Yangsheng,et al. Three-dimensional simulation study on law of deformation and breakage of coal floor on mining above aquifer[J]. Chinese Journal of Rock Mechanics and Engineering,2005,24(23):4396-4402.
[7] 高召宁,孟祥瑞. 采动条件下煤层底板变形破坏特征研究[J]. 矿业安全与环保,2010,37(3):17-20. GAO Zhaoning,MENG Xiangrui. Study on deformation and failuring characteristics of seam floor under mining influence[J]. Mining Safety & Environmental Protection,2010,37(3):17-20.
[8] 付宝杰,涂敏,程桦. 承压水上厚煤层底板变形破坏特征实验研究[J]. 地下空间与工程学报,2017,13(增刊1):107-112. FU Baojie,TU Min,CHENG Hua. Deformation and failure characteristics research on thick seam mining floor above confined water[J]. Chinese Journal of Underground Space and Engineering,2017,13(Sup.1):107-112.
[9] 许延春,杨扬. 大埋深煤层底板破坏深度统计公式及适用性分析[J]. 煤炭科学技术,2013,41(9):129-132. XU Yanchun,YANG Yang. Applicability analysis on statistical formula for failure depth of coal seam floor in deep mine[J]. Coal Science and Technology,2013,41(9):129-132.
[10] 段宏飞,姜振泉,张蕊,等. 杨村煤矿综采条件下薄煤层底板破坏深度的实测与模拟研究[J]. 煤炭学报,2011,36(增刊1):13-17. DUAN Hongfei,JIANG Zhenquan,ZHANG Rui,et al. Field measurement and simulation research on failure depth of fully mechanized thin coal seam floor in Yangcun Coal Mine[J]. Journal of China Coal Society,2011,36(Sup.1):13-17.
[11] 朱术云,曹丁涛,岳尊彩,等. 特厚煤层综放采动底板变形破坏规律的综合实测[J]. 岩土工程学报,2012,34(10):1931-1938. ZHU Shuyun,CAO Dingtao,YUE Zuncai,et al. Comprehensive measurement of characteristics of deformation and failure of extra-thick coal seam floor induced by fully mechanized top-coal mining[J]. Chinese Journal of Geotechnical Engineering,2012,34(10):1931-1938.
[12] 段宏飞,姜振泉,朱术云,等. 综采薄煤层采动底板变形破坏规律实测分析[J]. 采矿与安全工程学报,2011,28(3):407-414. DUAN Hongfei,JIANG Zhenquan,ZHU Shuyun,et al. Measurement of mining-induced floor failure regularity for thin coal seams using fully mechanized coal caving[J]. Journal of Mining and Safety Engineering,2011,28(3):407-414.
[13] 张蕊,姜振泉,岳尊彩,等. 采动条件下厚煤层底板破坏规律动态监测及数值模拟研究[J]. 采矿与安全工程学报,2012,29(5):625-630. ZHANG Rui,JIANG Zhenquan,YUE Zuncai,et al. In-situ dynamic observation and numerical analysis of thick coal seam floor's failure law under the mining[J]. Journal of Mining and Safety Engineering,2012,29(5):625-630.
[14] 朱术云,鞠远江,赵振中,等. 超化煤矿"三软"煤层采动底板变形破坏的实测研究[J]. 岩土工程学报,2009,31(4):639-642. ZHU Shuyun,JU Yuanjiang,ZHAO Zhenzhong,et al. Field measurement study on deformation and destruction of "three-soft" coal seam floor of Chaohua Coal Mine[J]. Chinese Journal of Geotechnical Engineering,2009,31(4):639-642.
[15] 程学丰,刘盛东,刘登宪. 煤层采后围岩破坏规律的声波CT探测[J]. 煤炭学报,2001,26(2):153-155. CHENG Xuefeng,LIU Shengdong,LIU Dengxian. Sound-wave CT detection for failure patterns of surrounding rock after mining[J]. Journal of China Coal Society,2001,26(2):153-155.
[16] 高召宁,孟祥瑞,赵光明. 煤层底板变形与破坏规律直流电阻率CT探测[J]. 重庆大学学报(自然科学版),2011,34(8):90-96. GAO Zhaoning,MENG Xiangrui,ZHAO Guangming. DC electrical resistivity CT survey of deformation and damage law of coal floor[J]. Journal of Chongqing University(Natural Science Edition),2011,34(8):90-96.
[17] 张平松,胡雄武,吴荣新. 岩层变形与破坏电法测试系统研究[J]. 岩土力学,2012,33(3):952-956. ZHANG Pingsong,HU Xiongwu,WU Rongxin. Study of detection system of distortion and collapsing of top rock by resistivity method in working face[J]. Rock and Soil Mechanics,2012,33(3):952-956.
[18] 张平松,刘盛东,吴荣新,等. 采煤面覆岩变形与破坏立体电法动态测试[J]. 岩石力学与工程学报,2009,28(9):1870-1875. ZHANG Pingsong,LIU Shengdong,WU Rongxin,et al. Dynamic detection of overburden deformation and failure in mining workface by 3D resistivity method[J]. Chinese Journal of Rock Mechanics and Engineering,2009,28(9):1870-1875.
[19] 张平松,鲁海峰,韩必武,等. 采动条件下断层构造的变形特征实测与分析[J]. 采矿与安全工程学报,2019,36(2):351-356. ZHANG Pingsong,LU Haifeng,HAN Biwu,et al. Monitoring and analysis of deformation characteristics of fault structure under mining condition[J]. Journal of Mining and Safety Engineering,2019,36(2):351-356.
[20] 张平松,许时昂,郭立全,等. 采场围岩变形与破坏监测技术研究进展及展望[J]. 煤炭科学技术,2020,48(3):14-35. ZHANG Pingsong,XU Shi'ang,GUO Liquan,et al. Prospect and progress of deformation and failure monitoring technology of surrounding rock in stope[J]. Coal Science and Technology,2020,48(3):14-35.
[21] 程爱民,孔皖军. 定向钻进技术在唐家会矿水害防治中的应用[J]. 煤炭与化工,2019,42(5):56-59. CHENG Aimin,KONG Wanjun. Application of directional drilling technology in prevention and control of water disaster in Tangjiahui Mine[J]. Coal and Chemical Industry,2019,42(5):56-59.
[22] 张平松,翟恩发,程爱民,等. 深厚煤层开采底板变形特征的光纤监测研究[J]. 地下空间与工程学报,2019,15(4):1197-1203. ZHANG Pingsong,ZHAI Enfa,CHENG Aimin,et al. Optical fiber monitoring study on characteristics of deformation in floor of deep and thick coal seam during mining[J]. Chinese Journal of Underground Space and Engineering,2019,15(4):1197-1203.
[23] 陈磊,詹跃东,田庆生. 基于BOTDR分布式传感系统的研究[J]. 仪表技术与传感器,2019(6):96-100. CHEN Lei,ZHAN Yuedong,TIAN Qingsheng. Research on BOTDR distributed sensing system[J]. Instrument Technique and Sensor,2019(6):96-100.
[24] XU Shi'ang,WANG Shuangming,ZHANG Pingsong,et al. Study on strain characterization and failure location of rock fracture process using distributed optical fiber under uniaxial compression[J]. Sensors,2020,20(14):3853.
[25] 刘盛东,张平松. 分布式并行智能电极电位差信号采集方法和系统:ZL200410014020.0[P]. 2005-05-18. LIU Shengdong,ZHANG Pingsong. Distributed parallel intelligent electrode potential difference signal acquisition method and system:ZL200410014020.0[P]. 2005-05-18.
[26] 郑晓亮,刘盛东. 基于双处理器的并行采集网络电法仪器的设计[J]. 煤炭科学技术,2008,36(4):85-88. ZHENG Xiaoliang,LIU Shengdong. Design on parallel collection network electrical instrument base on double processorss[J]. Coal Science and Technology,2008,36(4):85-88.
[27] 刘盛东,刘静,戚俊,等. 矿井并行电法技术体系与新进展[J]. 煤炭学报,2019,44(8):2336-2345. LIU Shengdong,LIU Jing,QI Jun,et al. Applied technologies and new advances of parallel electrical method in mining geophysics[J]. Journal of China Coal Society,2019,44(8):2336-2345.
[28] 钱鸣高,石平武,许家林.矿山压力与岩层控制[M].徐州:中国矿业大学出版社,2010:188-190. QIAN Minggao,SHI Pingwu,XU Jialin. Mining pressure and strata control[M].Xuzhou:China University of Mining and Technology Press,2010:188-190.
Included in
Earth Sciences Commons, Mining Engineering Commons, Oil, Gas, and Energy Commons, Sustainability Commons