新集煤矿远程下保护层开采卸压范围及效果研究
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摘要
作为一种区域性防突措施,一般在条件允许的情况下都把开采保护层作为首选的防突措施。新集煤矿C13-1煤层具有煤与瓦斯突出危险性,在这种情况下,选择首先开采其下方平均间距为65米的不具有突出危险的B11-2煤层,通过采动影响造成C13-1煤层卸压,以降低其突出危险性。
本文在保护层开采理论分析基础上,针对新集矿区煤层赋存地质条件,采用相似材料模拟试验的方法研究了开采过程中随着工作面的推进覆岩移动破坏特征和煤岩体内应力分布规律;利用数值模拟的方法研究了保护层开采影响下覆岩的应力变化和塑性区分布范围以及护巷煤柱对卸压范围的影响等;通过现场实测考察了随工作面的推进被保护层瓦斯压力变化规律、透气性变化规律、被保护层在采动影响下的膨胀变形规律和卸压瓦斯抽放效果等。现场实测结合相似模拟和数值模拟结果得出被保护层卸压范围,下保护层的开采对被保护层的卸压范围沿走向方向卸压角为55°,沿倾斜方向上山卸压角为86°,下山方向卸压角为69°,在保护范围内应力下降,被保护煤层膨胀变形,其变形率最大达20.42%,煤层透气性大大增强,透气性系数相比开采前原始透气性系数增大了近1000倍,保护层开采取得了良好的效果。
Exploitation of the protective layer has been increasing attention as a regional anti-surprise measures, generally, if conditions permitting protective layer mining regarded as the preferred anti-sudden measures. C13-1 coal seam of xin-ji mine with coal and gas outburst danger, in this case, select the B11-2 coal seam as the first exploitation, through the mining-impact caused C13.1 Coal pressure relief to reduce the risk of its prominence.
This paper based on the theoretical analysis of the protection layer exploitation against geological conditions of coal seam of xin-ji mine, through the similar simulation test researched the law of movement-destruction and stress distribution of overlying strata with the advancing of the working face; through numerical Computing researched the stress variation and the plastic zone distribution of the overlying strata in the under-protective B11-2 coal seam mining etc.; through measurement on locale-site reviewed the layer of gas pressure change of protected layer and variation of permeability and pressure relief gas drainage effects with the face of the advancing, and combined field measurement and numerical simulation and similar simulation results obtained the relief angle 55°of protective layer along the direction of advancing and the uphill relief angle 86°and downhill relief angle 69°of the inclined direction, after under-protection layer mining the stress drop in the scope of protection and the protected coal deformed and expanded, its maximum deformation ratio is 20.42%, fully seam permeability after stress-relief greatly enhanced,permeability coefficient of expansion of the nearly 1000 times,the protective-layer mining obtained well effects.
本文在保护层开采理论分析基础上,针对新集矿区煤层赋存地质条件,采用相似材料模拟试验的方法研究了开采过程中随着工作面的推进覆岩移动破坏特征和煤岩体内应力分布规律;利用数值模拟的方法研究了保护层开采影响下覆岩的应力变化和塑性区分布范围以及护巷煤柱对卸压范围的影响等;通过现场实测考察了随工作面的推进被保护层瓦斯压力变化规律、透气性变化规律、被保护层在采动影响下的膨胀变形规律和卸压瓦斯抽放效果等。现场实测结合相似模拟和数值模拟结果得出被保护层卸压范围,下保护层的开采对被保护层的卸压范围沿走向方向卸压角为55°,沿倾斜方向上山卸压角为86°,下山方向卸压角为69°,在保护范围内应力下降,被保护煤层膨胀变形,其变形率最大达20.42%,煤层透气性大大增强,透气性系数相比开采前原始透气性系数增大了近1000倍,保护层开采取得了良好的效果。
Exploitation of the protective layer has been increasing attention as a regional anti-surprise measures, generally, if conditions permitting protective layer mining regarded as the preferred anti-sudden measures. C13-1 coal seam of xin-ji mine with coal and gas outburst danger, in this case, select the B11-2 coal seam as the first exploitation, through the mining-impact caused C13.1 Coal pressure relief to reduce the risk of its prominence.
This paper based on the theoretical analysis of the protection layer exploitation against geological conditions of coal seam of xin-ji mine, through the similar simulation test researched the law of movement-destruction and stress distribution of overlying strata with the advancing of the working face; through numerical Computing researched the stress variation and the plastic zone distribution of the overlying strata in the under-protective B11-2 coal seam mining etc.; through measurement on locale-site reviewed the layer of gas pressure change of protected layer and variation of permeability and pressure relief gas drainage effects with the face of the advancing, and combined field measurement and numerical simulation and similar simulation results obtained the relief angle 55°of protective layer along the direction of advancing and the uphill relief angle 86°and downhill relief angle 69°of the inclined direction, after under-protection layer mining the stress drop in the scope of protection and the protected coal deformed and expanded, its maximum deformation ratio is 20.42%, fully seam permeability after stress-relief greatly enhanced,permeability coefficient of expansion of the nearly 1000 times,the protective-layer mining obtained well effects.
引文
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[23]吴教锟等.大湾煤矿保护层开采数值模拟研究[J].矿业安全与环保,2007,34(1):6-10
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[29]李青松等.潘二矿上保护层开采保护效果及参数考察研究[J].煤炭工程,2007,(5):46-48
[30]高松,孙波.潘三矿远距离下保护层开采技术的实践[J].煤矿安全,2003,34(5):23-25
[31]李万峰.淮南矿区保护层开采的探讨[J].煤炭科技.
[32]周德永,甘林堂.淮南矿区瓦斯区域性治理—保护层开采的成果与展望[J].矿业安全与环保,2005,32(2):37-39
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[35]Qian Minggao. A Study of the Behaviour of Overlying Strata in Longwall Mining and Its Application to Strata Control. Proceedings of the Symposium on Strata Mechanics. Elsevier Scientific Publishing Company.1982:13-17
[36]蒋金泉.采场围岩应力与运动[M].北京:煤炭工业社,1993
[37]D.L.Hopkins. The implications of joint-deformation in analyzing the properties and behavior of fractured rock masses, underground excavation and faults. International Journal of Rock Mechanics and Mining Sciences. Vol.37 No 1/2 Jan/Feb 2000
[38]W.J.Gale Strata Control Dtillising Rock Reinforcement Techniques and Stress Control Methods in Australia Coal Mines, Mining Engineering 1991(1)
[39]陈祥恩,李德海,勾攀峰.巨厚松散层下开采及地表移动[M].徐州:中国矿业大学出版社,2001
[40]邹友峰,邓喀中,马伟民.矿山开采沉陷工程[M].徐州:中国矿业大学出版社,2003
[41]Peng, S. S. Surface Subsidence Engineering, Society for Mining Metallurgy and Exploration Inc.,1992
[42]S.C.Blair, N.G.W.Cook,1998, Analysis of compressive fracture in rock using statistical techniques:part Ⅱ. Effect of microscale heterogeneity on macroscopic deformation, Int. J. Rock Mech. Min. Sci., Vol.35, No.7,pp.849-861
[43]麻凤海.岩层移动及动力学过程的理论与实践[M].北京:煤炭工业出版社,1997
[44]林海飞.采动裂隙椭抛带中瓦斯运移规律及其应用分析[D].西安科技大学,2004
[45]国家安全生产监督管理总局.防治煤与瓦斯突出规定[M].北京:煤炭工业出版社,2009
[46]余华中.巨厚松散层下开采地表移动研究[D].河南理工大学,2004
[47]张东明.南桐矿区开采沉陷基本规律的研究[D].重庆大学,2000
[48]李鸿昌.矿山压力的相似模拟试验[M].徐州:中国矿业大学出版社,1988
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[2]崔兆华.2001—2008年我国煤矿瓦斯事故统计及原因分析[J].科技情报开发与经济,2009,19(21):140-141
[3]煤炭工业部安全司.中国煤矿伤亡事故统计分析资料汇编(1949-1995)[M].北京:煤炭工业出版社,1998
[4]赵铁锤等.瓦斯灾害防治技术[M].北京:煤炭工业出版社,2007
[5]何学秋.中国煤矿灾害防治理论与技术[M].徐州:中国矿业大学出版社,2006
[6]于不凡,王佑安.煤矿瓦斯灾害防治及利用技术手册[M].北京:煤炭工业出版社,2000
[7]俞启香.矿井瓦斯防治[M].徐州:中国矿业大学出版社,1992
[8]王兆丰.邻近层瓦斯涌出量预测(D).煤炭科学研究总院抚顺分院,1988
[9]钱鸣高等.岩层控制的关键层理论[M].中国矿业大学出版社,2003.
[10]高祥.保护层开采的保护范围和效果的研究[J].煤炭技术,2004,23(9)
[11]刘林,程远平.开采远距离下保护层卸压保护角的相似模拟研究[J].矿业安全与环保,2006,33(6):7-9
[12]王岩等.保护层开采后周围煤岩体采动裂隙分布规律的研究[J].煤矿安全,2008,(1):11-14
[13]王岩等.红菱煤矿开采保护层对煤岩体透气性的数值模拟[J].地球科学与环境学报,2008,30(2):161-164
[14]王路军等.红菱煤矿开采保护层后煤岩体采动裂隙分布的数值模拟研究[J].矿业安全与环保,2008,35(5):1-6
[15]朱栓成等.保护层开采条件下煤层残余瓦斯含量预测方法研究[J].中国煤炭,2008,34(6):17-18
[16]石必明,俞启香.远距离保护层开采煤岩移动变形特性的试验研究[J].煤炭科学技术,2005,33(2):39-41
[17]石必明等.保护层开采远距离煤岩破裂变形数值模拟[J].中国矿业大学学报,2004,33(3):259-262
[18]石必明等.远程保护层开采上覆煤层透气性动态演化规律试验研究[J].岩石力学与工程学报,2006,25(9):1917-1920
[19]钱鸣高,许家林.覆岩采动裂隙分布的“0”形圈特征研究[J].煤炭学报,1998,23(5):466-469
[20]余国峰等.远距离保护层开采卸压机理数值模拟分析[J].煤矿安全,2007,(11):5-8
[21]涂敏等.远程下保护层开采被保护煤层变形规律研究[J].采矿与安全工程学报,2006,23(3):254-257
[22]马占国,涂敏,马继刚等.远距离下保护层开采煤岩体变形特征[J].采矿与安全工程学报,2008,25(3):253-257
[23]吴教锟等.大湾煤矿保护层开采数值模拟研究[J].矿业安全与环保,2007,34(1):6-10
[24]张家文,马其祥.基于煤层瓦斯基本参数的保护层开采效果检验[J].采矿技术,2008,8(4):25-26
[25]刘树国.下保护层开采在薛村矿的实践效果[J].煤矿开采,1995,(4):16-17
[26]贾天让等.近距离保护层开采技术在平煤五矿的实践[J].煤炭科学技术,2006,34(12):23-25
[27]刘德贵.急倾斜近距离复杂煤层保护层开采的实践[J].矿业安全与环保,2005,32(1):66-67
[28]信锁林等.牛儿庄矿开采保护层初探[J].河北煤炭,2007,(3):9-10
[29]李青松等.潘二矿上保护层开采保护效果及参数考察研究[J].煤炭工程,2007,(5):46-48
[30]高松,孙波.潘三矿远距离下保护层开采技术的实践[J].煤矿安全,2003,34(5):23-25
[31]李万峰.淮南矿区保护层开采的探讨[J].煤炭科技.
[32]周德永,甘林堂.淮南矿区瓦斯区域性治理—保护层开采的成果与展望[J].矿业安全与环保,2005,32(2):37-39
[33]何国清,杨伦,凌赓娣.矿山开采沉陷学[M].徐州:中国矿业大学出版社,1994
[34]钱鸣高,石平五等.矿山压力与岩层控制[M].徐州:中国矿业大学出版社,2003
[35]Qian Minggao. A Study of the Behaviour of Overlying Strata in Longwall Mining and Its Application to Strata Control. Proceedings of the Symposium on Strata Mechanics. Elsevier Scientific Publishing Company.1982:13-17
[36]蒋金泉.采场围岩应力与运动[M].北京:煤炭工业社,1993
[37]D.L.Hopkins. The implications of joint-deformation in analyzing the properties and behavior of fractured rock masses, underground excavation and faults. International Journal of Rock Mechanics and Mining Sciences. Vol.37 No 1/2 Jan/Feb 2000
[38]W.J.Gale Strata Control Dtillising Rock Reinforcement Techniques and Stress Control Methods in Australia Coal Mines, Mining Engineering 1991(1)
[39]陈祥恩,李德海,勾攀峰.巨厚松散层下开采及地表移动[M].徐州:中国矿业大学出版社,2001
[40]邹友峰,邓喀中,马伟民.矿山开采沉陷工程[M].徐州:中国矿业大学出版社,2003
[41]Peng, S. S. Surface Subsidence Engineering, Society for Mining Metallurgy and Exploration Inc.,1992
[42]S.C.Blair, N.G.W.Cook,1998, Analysis of compressive fracture in rock using statistical techniques:part Ⅱ. Effect of microscale heterogeneity on macroscopic deformation, Int. J. Rock Mech. Min. Sci., Vol.35, No.7,pp.849-861
[43]麻凤海.岩层移动及动力学过程的理论与实践[M].北京:煤炭工业出版社,1997
[44]林海飞.采动裂隙椭抛带中瓦斯运移规律及其应用分析[D].西安科技大学,2004
[45]国家安全生产监督管理总局.防治煤与瓦斯突出规定[M].北京:煤炭工业出版社,2009
[46]余华中.巨厚松散层下开采地表移动研究[D].河南理工大学,2004
[47]张东明.南桐矿区开采沉陷基本规律的研究[D].重庆大学,2000
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