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| Study on floor failure law of large buried depth gently inclined thick coal seam based on microseismic monitoring |
| Li Xinwang1,2,3, Hao Yunde1, Cheng Lichao1,2,3, Lu Bing1 |
| 1. School of Mining Geomatics Engineering, Hebei University of Engineering, Handan 056038, China; 2. Coal Resources Development and Construcyion Application Technology Research Center of Universities in Hebei Province, Hebei University of Engineering, Handan 056038, China; 3. Handan Coal-based Solid Waste Scale Utilization Technology Innovation Center, Hebei University of Engineering, Handan 056038, China |
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Abstract Based on the background of Jiulong Mine, the long-term dynamic real-time monitoring of the No.15249S Face of the mine was carried out by using the microseismic monitoring technology. The correlation analysis of floor microseismic events frequency, cumulative energy, advancing distance and failure depth was carried out. The spatial distribution characteristics of the floor failure zone were revealed, and the failure depth and failure range of the floor were determined. The results showed that the microseismic events were mainly weak and near coal seam, the number of floor events was greater than that of roof events, and the number of floor events of upper roadway was greater than that of lower roadway. Affected by mining disturbance, the damage degree of the floor of No.15249S Face gradually deepened, and finally two failure zones were formed, which were distributed in the influence of ' inverted double peak ' along the strike. The failure depth of floor was generally positively correlated with frequency and cumulative energy of microseismic events. The maximum failure depth of the floor was 25 m, and there was no risk of water outburst. The research results provided support for the on-site safety production of Jiulong Mine and provided reference for the mining of similar large buried depth and gently inclined coal seams.
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| [ 1 ] 许家林. 煤矿绿色开采20年研究及进展[ J ]. 煤炭科学技术,2020,48( 9 ):1 - 15.
[ 2 ] 缪协兴,钱鸣高. 中国煤炭资源绿色开采研究现状与展望[ J ]. 采矿与安全工程学报,2009,26( 1 ):1 - 14.
[ 3 ] 武 强. 我国矿井水防控与资源化利用的研究进展、问题和展望[ J ]. 煤炭学报,2014,39( 5 ):795 - 805.
[ 4 ] 谢和平,高 峰,鞠 杨. 深部岩体力学研究与探索[ J ]. 岩石力学与工程学报,2015,34( 11 ):2 161 - 2 178.
[ 5 ] 何满潮,谢和平,彭苏萍,等. 深部开采岩体力学研究[ J ]. 岩石力学与工程学报,2005( 16 ):2 803 - 2 813.
[ 6 ] 赵庆彪,赵昕楠,武 强,等. 华北型煤田深部开采底板“分时段分带突破”突水机理[ J ]. 煤炭学报,2015,40( 7 ):1 601 - 1 607.
[ 7 ] 施龙青,曲兴玥,韩 进,等. 多模型融合评价煤层底板灰岩岩溶突水危险性[ J ]. 煤炭学报,2019,44( 8 ):2 484 - 2 493.
[ 8 ] 鲍莱茨基,M. 胡戴克,于振海. 矿山岩体力学[ M ]. 北京:煤炭工业出版社,1985.
[ 9 ] N·A·多尔恰尼诺夫. 构造应力与井巷工程稳定性[ M ]. 北京:煤炭工业出版社,1984.
[ 10 ] 张金才,刘天泉. 论煤层底板采动裂隙带的深度及分布特征[ J ]. 煤炭学报,1990( 2 ):46 - 55.
[ 11 ] 李白英. 预防矿井底板突水的“下三带”理论及其发展与应用[ J ]. 山东矿业学院学报(自然科学版),1999( 4 ):11 - 18.
[ 12 ] 钱鸣高,缪协兴,黎良杰. 采场底板岩层破断规律的理论研究[ J ]. 岩土工程学报,1995( 6 ):55 - 62.
[ 13 ] 施龙青,徐东晶,邱 梅,等. 采场底板破坏深度计算公式的改进[ J ]. 煤炭学报,2013,38( S2 ):299 - 303.
[ 14 ] 董书宁,王 皓,张文忠. 华北型煤田奥灰顶部利用与改造判别准则及底板破坏深度[ J ]. 煤炭学报,2019,44( 7 ):2 216 - 2 226.
[ 15 ] 刘伟韬,穆殿瑞,杨 利,等. 倾斜煤层底板破坏深度计算方法及主控因素敏感性分析[ J ]. 煤炭学报,2017,42( 4 ):849 - 859.
[ 16 ] 董书宁,王 皓,张文忠. 华北型煤田奥灰顶部利用与改造判别准则及底板破坏深度[ J ]. 煤炭学报,2019,44( 7 ):2 216 - 2 226.
[ 17 ] 王进尚,姚多喜. 承压水上含隐伏断层突水动态监测物理模拟研究[ J ]. 地下空间与工程学报,2022,18( 2 ):681 - 689.
[ 18 ] 张文泉,张红日,徐方军,等. 大采深倾斜薄煤层底板采动破坏形态的连续探测[ J ]. 煤田地质与勘探,2000( 2 ):39 - 42.
[ 19 ] 张平松,吴基文,刘盛东. 煤层采动底板破坏规律动态观测研究[ J ]. 岩石力学与工程学报,2006( S1 ):3 009 - 3 013.
[ 20 ] 许延春,谢小锋,董检平,等. 在相似模拟试验中利用超声波检测技术探测底板破坏深度[ J ]. 煤矿开采,2016,21( 1 ):7 - 11.
[ 21 ] 刘伟韬,穆殿瑞,谢祥祥,等. 倾斜煤层底板采动应力分布规律及破坏特征[ J ]. 采矿与安全工程学报,2018,35( 4 ):756 - 764.
[ 22 ] 姜福兴. 微震监测技术在矿井岩层破裂监测中的应用[ J ]. 岩土工程学报,2002( 2 ):147 - 149.
[ 23 ] 靳德武,赵春虎,段建华,等. 煤层底板水害三维监测与智能预警系统研究[ J ]. 煤炭学报,2020,45( 6 ):2 256 - 2 264.
[ 24 ] 王进尚,郭 俊,辛崇伟,等. 基于高精度微震监测技术的底板破坏深度预测研究[ J ]. 煤炭技术,2020,39( 4 ):67 - 70. |
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