Coal Geology & Exploration
Abstract
The mud and sand inrush disaster during the mining of deep-buried coal seam is caused by the disintegration of the mudstone in the coal seam roof when meeting water. It is a comprehensive disaster due to concentrated underground mud and sand gush under mine pressure. The occurrence of such disaster is affected by many factors, such as aquifer, mine pressure, and geological structure, etc. This paper took Zhaojin coal mine in Huanglong coalfield as the study area, and discussed the mechanism of the disaster. Then the main controlling factors were identified, including water yield property of Luohe Formation aquifer, distance between coal roof and Luohe Formation aquifer, thickness of conglomerate in Yijun Formation, thickness of variegated mudstone above the coal seam, distance between coal roof and variegated mudstone, fault density, distribution of fold, coal seam thickness. The analytic hierarchy process was used to determine the weights of the main controlling factors, and the mathematical model for the risk assessment of the mud and sand inrush disaster in the coal seam roof was constructed. Then the thematic map of the main control factors was drawn. Based on the information fusion method, the factors were superimposed, and finally the disaster integrated zoning method of multi-source information fusion was formed. The research results show that the risk of disaster occurrence of ZF202 working face is high, which is in conformity to the 4·25” major disaster, indicating that the risk assessment model is reasonable, and the zoning results can be used to guide mining of Zhaojin coal mine and prevention and control of mud and sand inrush disaster.
Keywords
deep-buried coal seam, mud and sand inrush, multi-source information fusion, main controlling factors, evaluation method, Jurassic coalfield, Zhaojin coal mine
DOI
10.3969/j.issn.1001986.2020.01.015
Recommended Citation
GUO Xiaoming, GUO Kang, LIU Yingfeng,
et al.
(2020)
"Multi-source information evaluation of mud and sand inrush disaster during the mining of deep-buried coal seam,"
Coal Geology & Exploration: Vol. 48:
Iss.
1, Article 16.
DOI: 10.3969/j.issn.1001986.2020.01.015
Available at:
https://cge.researchcommons.org/journal/vol48/iss1/16
Reference
[1] 魏秉亮. 神府矿区突水溃砂地质灾害研究[J]. 中国煤田地质,1996,8(2):28-30. WEI Bingliang. Study on geological harm of blowing out water and bursting sand in Shenfu coal mining area[J]. Coal Geology of China,1996,8(2):28-30.
[2] 范立民,马雄德,蒋辉,等. 西部生态脆弱矿区矿井突水溃沙危险性分区[J]. 煤炭学报,2016,41(3):531-536. FAN Limin,MA Xiongde,JIANG Hui,et al. Risk evaluation on water and sand inrush in ecologically fragile coal mine[J]. Journal of China Coal Society,2016,41(3):531-536.
[3] 范立民,马雄德. 浅埋煤层矿井突水溃沙灾害研究进展[J]. 煤炭科学技术,2016,44(1):8-12. FAN Limin,MA Xiongde. Research progress of water inrush hazard in shallow buried coal seam mine[J]. Coal Science and Technology,2016,44(1):8-12.
[4] 王子河. 西部侏罗系聚煤区榆林谷地茆-大西沟剖面潜在突水溃沙沙层沉积规律研究[D]. 徐州:中国矿业大学,2014. WANG Zihe. Sedimentary characterization of potential quick sand layers of Gudimao-Daxigou cross section in Jurassic coalfield of western China[D]. Xuzhou:China University of Mining and Technology,2014.
[5] 隋旺华,蔡光桃,董青红. 近松散层采煤覆岩采动裂缝水砂突涌临界水力坡度试验[J]. 岩石力学与工程学报,2007,26(10):2084-2091. SUI Wanghua,CAI Guangtao,DONG Qinghong. Experimental research on critical percolation gradient of quicksand across overburden fissures due to coal mining near unconsolidated soil layers[J]. Chinese Journal of Rock Mechanics and Engineering,2007,26(10):2084-2091.
[6] 隋旺华,董青红. 近松散层开采孔隙水压力变化及其对水砂突涌的前兆意义[J]. 岩石力学与工程学报,2008,27(9):1908-1916. SUI Wanghua,DONG Qinghong. Variation of pore water pressure and its precursor significance for quicksand disasters due to mining near unconsolidated formations[J]. Chinese Journal of Rock Mechanics and Engineering,2008,27(9):1908-1916.
[7] 杨斌,杨天鸿,徐曾和,等. 中国西部矿区厚松散层的溃沙临界流速与水沙流动特征[J]. 东北大学学报(自然科学版),2018,39(11):1648-1652. YANG Bin,YANG Tianhong,XU Zenghe,et al. Critical velocity of sand inrush and flow characteristics of water-sand in thick unconsolidated formations of mine in western China[J]. Journal of Northeastern University(Natural Science),2018,39(11):1648-1652.
[8] 杨鑫,徐曾和,杨天鸿,等. 西部典型矿区风积沙含水层突水溃沙的起动条件与运移特征[J]. 岩土力学,2018,39(1):21-28. YANG Xin,XU Zenghe,YANG Tianhong,et al. Incipience condition and migration characteristics of aeolian-sand aquifer in a typical western mine[J]. Rock and Soil Mechanics,2018,39(1):21-28.
[9] 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]. 煤炭学报,2000,25(1):62-67. WU Qiang,HUANG Xiaoling,DONG Donglin,et al. "Three maps-two predictions" method to evaluate water bursting conditions on roof coal[J]. Journal of China Coal Society,2000,25(1):62-67.
[10] 武强,樊振丽,刘守强,等. 基于GIS的信息融合型含水层富水性评价方法:富水性指数法[J]. 煤炭学报,2011,36(7):1124-1128. WU Qiang,FAN Zhenli,LIU Shouqiang,et al. Water-richness evaluation method of water-filled aquifer based on the principle of information fusion with GIS:Water-richness index method[J]. Journal of China Coal Society,2011,36(7):1124-1128.
[11] 郭小铭,董书宁,刘英锋,等. 深埋煤层开采顶板泥砂溃涌灾害形成机理[J]. 采矿与安全工程学报,2019,36(5):889-897. GUO Xiaoming,DONG Shuning,LIU Yingfeng,et al. Formation mechanism of mud and sand inrush disaster during the mining of deep-buried coal seam[J]. Journal of Mining and Safety Engineering,2019,36(5):889-897.
[12] 武谋达. 彬长矿区复合煤层联合开采区涌水特征[J]. 煤田地质与勘探,2019,47(1):133-137. WU Mouda. Analysis on water burst characteristics during united mining of multiple coal seams in Binchang mining area[J]. Coal Geology & Exploration,2019,47(1):133-137.
[13] 王东东,邵龙义,李智学,等. 陕西省中侏罗统延安组层序地层格架与煤层形成[J]. 中国煤炭地质,2011,23(8):22-27. WANG Dongdong,SHAO Longyi,LI Zhixue,et al. Middle Jurassic Series Yan'an Formation sequence stratigraphic framework and coal seam formation in Shaanxi Province[J]. Coal Geology of China,2011,23(8):22-27.
[14] 陈绍杰,夏治国,郭惟嘉,等. 断层影响下岩体采动灾变响应研究现状与展望[J]. 煤炭科学技术,2018,46(1):20-27. CHEN Shaojie,XIA Zhiguo,GUO Weijia,et al. Research status and prospect of mining catastrophic response of rock mass under the influence of fault[J]. Coal Science and Technology,2018,46(1):20-27.
[15] 王双美. 导水裂隙带高度研究方法概述[J]. 水文地质工程地质,2006,39(5):126-128. WANG Shuangmei. A brief review of the methods determining the height of permeable fracture zone[J]. Hydrogeology & Engineering Geology,2006,39(5):126-128.
[16] 张通,赵毅鑫,朱广沛,等. 神东浅埋工作面矿压显现规律的多因素耦合分析[J]. 煤炭学报,2016,41(增刊2):287-296. ZHANG Tong,ZHAO Yixin,ZHU Guangpei,et al.A multi-coupling analysis of mining-induced pressure characteristics of shallow-depth coal face in Shendong mining area[J]. Journal of China Coal Society,2016,41(S2):287-296.
[17] 郭金玉,张忠彬,孙庆云. 层次分析法的研究与应用[J]. 中国安全科学学报,2008,18(5):148-153. GUO Jinyu,ZHANG Zhongbin,SUN Qingyun. Study and applications of analytic hierarchy process[J]. China Safety Science Journal,2008,18(5):148-153.
[18] 熊立,梁樑,王国华. 层次分析法中数字标度的选择与评价方法研究[J]. 系统工程理论与实践,2005,25(3):72-79. XIONG Li,LIANG Liang,WANG Guohua. Method research on selection and valuation of numeric scale in analytic hierarchy process[J]. System Engineering Theory and Practice,2005,25(3):72-79.
[19] 张艳博,梁鹏,刘祥鑫,等. 基于多参量归一化的花岗岩巷道岩爆预测试验研究[J]. 岩土力学,2016,37(1):96-104. ZHANG Yanbo,LIANG Peng,LIU Xiangxin. An experimental study of predicting rock burst in granitic roadway based on multi-parameter normalization[J]. Rock and Soil Mechanics,2016,37(1):96-104.
[20] WU Qiang,GUO Xiaoming,SHEN Jianjun,et al. Risk assessment of water inrush from aquifers underlying the Gushuyuan coal mine,China[J]. Mine Water and the Environment,2017,36(1):96-103.
[21] 武强,许珂,张维. 再论煤层顶板涌(突)水危险性预测评价的"三图-双预测法"[J]. 煤炭学报,2016,41(6):1341-1347. WU Qiang,XU Ke,ZHANG Wei. Further research on "three maps-two predictions" method for prediction on coal seam roof water bursting risk[J]. Journal of China Coal Society,2016,41(6):1341-1347.
Click below to download English version.
Multi-source information evaluation of mud and sand inrush disaster during the mining of deep-buried coal seam.PDF (3635 kB)Included in
Earth Sciences Commons, Mining Engineering Commons, Oil, Gas, and Energy Commons, Sustainability Commons