弱胶结覆岩采动全过程导水裂隙带发育特征研究

doi:10.19286/j.cnki.cci.2025.04.012

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Abstract

The study on the development characteristics and height of water conduction fracture zone is of great significance for the safe production of coal and the protection of groundwater resources in the western ecologically fragile mining area. The traditional field measurement methods such as borehole TV and flushing fluid leakage observation can not monitor the development characteristics of water conduction fracture zone in the whole mining process. In view of this, considering the particularity of medium-large buried depth, thick coal seam and thick and weak cemented roof in the western Jurassic coalfield, the development law of the whole mining process of the water conduction fracture zone in No.2 coal seam of Xiaojihan Coal Mine was studied by using the underground advanced inclined hole monitoring method. At the same time, the development process and spatial form of the water conduction fracture zone were supplemented and explained by the auxiliary synchronous monitoring of the mining height, rockburst microseism and mining speed.It was found that the water conduction fracture zone was generally developed in advance during the mining of No.2 coal seam, and the advance distance was 104~150 m. The water conduction fracture zone gradually increased from the transport roadway to the inside of the working face, and the fracture development height in the middle of the working face reached the maximum value of monitoring, and it was inferred that the water conduction fracture zone was an asymmetric form with low west and high east in the tendency of the working face. When the height of the water conduction fracture zone was 50 ~ 80 m, the water conductivity was the strongest. And when the vertical height above 100 m, it was a weak water conduction fracture. The research results could provide theoretical guidance and reference for the characterization of the development characteristics of the water conduction fracture zone in similar mines.

Key words： western coal mining area water conduction fracture zone overburden rock destruction advanced oblique hole monitaring method empiyical formula

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	Articles by authors
	Yin Wenbin
	Bo Tao
	Yang Jiangfeng
	Jiang Wenbing

Cite this article:

Yin Wenbin,Bo Tao,Yang Jiangfeng等. Study on the development characteristics of water conduction fracture zone in the whole mining process of weakly cemented overburden rock[J]. CCI, 2025, 48(4): 55-61.

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http://www.mtyhg.com.cn/EN/10.19286/j.cnki.cci.2025.04.012 OR http://www.mtyhg.com.cn/EN/Y2025/V48/I4/55

[ 1 ]       范立民，迟宝锁，王宏科，等. 鄂尔多斯盆地北部直罗组含水层研究进展与水害防治建议[ J ]. 煤炭学报，2022（ 47 ）：3 535 - 3 546.
[ 2 ]       武    强，赵苏启，孙文洁，等. 中国煤矿水文地质类型划分与特征分析[ J ]. 煤炭学报，2013（ 38 ）：901 - 905.
[ 3 ]       曾一凡，武    强，赵苏启，等. 我国煤矿水害事故特征、致因与防治对策[ J ]. 煤炭科学技术，2023（ 51 ）：1 - 14.
[ 4 ]       邬飞龙. 仰孔注水测漏法在磁窑沟13102工作面防治水的应用研究[ J ]. 煤炭与化工，2022，45（ 2 ）：58 - 61.
[ 5 ]       张    彬，牟    义，张俊英，等. 瞬变电磁法在导水裂隙带高度探测中的研究应用[ J ]. 煤炭工程，2011（ 3 ）：44 - 46.
[ 6 ]       unjin L, Jinpeng X, Qiang L, et al. Research on the development law of water-conducting fracture zone in the combined mining of jurassic and carboniferous coal seams[ J ]. Applied Sciences, 2022, 12( 21 ).
[ 7 ]       Yi T, Han X, Weitao Y, et al. Development law of water-conducti
ng fracture zone in the fully mechanized caving face of gob-side entry driving: a case study[ J ]. Minerals, 2022, 12( 5 ).
[ 8 ]       段江飞，刘凡凡，杜超杰. 安山煤矿浅埋煤层覆岩导水裂隙带发育高度实测研究[ J ]. 煤炭与化工，2024，47（ 2 ）：69 - 72，77.
[ 9 ]       许家林，朱卫兵，王晓振. 基于关键层位置的导水裂隙带高度预计方法[ J ]. 煤炭学报，2012，37（ 5 ）：762 - 769.
[ 10 ]     许延春，李俊成，刘世奇，等. 综放开采覆岩“两带”高度的计算公式及适用性分析[ J ]. 煤矿开采，2011（ 16 ）：4 - 7，11.
[ 11 ]     张    军，王建鹏. 采动覆岩“三带”高度相似模拟及实证研究[ J ]. 采矿与安全工程学报，2014，31（ 2 ）：249 - 254.
[ 12 ]     Xicai G, Shuai L, Tengfei M, et al. A prediction method for height of water flowing fractured zone based on sparrow search algorithm-Elman neural network in northwest mining area[ J ]. Applied Sciences, 2023, 13( 2 ).
[ 13 ]     Yanbo H, Qiqing W, Wenping L, et al. Predicting the height of the water-conducting fractured zone in fully mechanized top coal caving longwall mining of very thick jurassic coal seams in western China based on the NNBR model[ J ]. Mine Water and the Environment, 2023, 42( 1 ).
[ 14 ]     郭    斌. 采空区下近距离煤层开采导水裂隙带发育规律研究[ J ]. 煤炭与化工，2024，47（ 3 ）：74 - 76，80.
[ 15 ]     王    旭，尹尚先，徐    斌，等. 综采工作条件下覆岩导水裂隙带高度预测模型优化[ J ]. 煤炭科学技术，2023，51（ S1 ）：284 - 297.
[ 16 ]     Huan L, Haobin D, Jian G, et al. An overview of sensing platform-
technological aspects for vector magnetic measurement: A case study of the application in different scenarios[ J ]. Measurement, 2022, 187.
[ 17 ]     张平松，李    洁. 我国煤矿井下钻孔物探技术发展与分析[ J ]. 地球物理学进展，2023，38（ 4 ）：1 885 - 1 897.
[ 18 ]     吴铁卫. 内蒙古门克庆煤矿导水裂隙带高度探测及发育规律[ J ]. 中国煤炭地质，2022，34（ 5 ）：55 - 58，65.
[ 19 ]     徐智敏，韩宇航，陈天赐，等. 侏罗系弱胶结顶板采动破坏规律与发育高度预测[ J ]. 工程地质学报，2023（ 31 ）：1 474 - 1 485.
[ 20 ]     徐树媛，张永波，时    红，等. 采动覆岩导水裂隙带发育高度研究进展[ J ]. 科学技术与工程，2018（ 18 ）：139 - 148.
[ 21 ]     郭兵兵，孙文标，刘长武. 煤层开采导水裂隙带发育高度研究综述[ J ]. 科学技术与工程，2015，15（ 17 ）：100 - 108.
[ 22 ]     武    强，黄晓玲，董东林，等. 评价煤层顶板涌(突)水条件的“三图-双预测法”[ J ].