断层条件下的大巷施工与围岩控制技术研究
|
摘要
本论文以淮北袁店二矿大断面巷道群过断层组为工程背景,通过工程物探、数值分析及现场施工与监测的方法,对断层破碎带巷道施工与围岩控制技术进行研究。在深入探测断层区域工程地质条件和模拟分析大型断层带应力场特征的基础上,结合断层破碎带围岩的实际情况,提出了“防患、早测、短进、弱爆、强支、紧封”的施工原则,形成超前物探、超前加固、微震开挖、分步动态支护等综合配套技术;运用分步动态耦合支护的原理对其施工技术和施工过程动态力学性态进行系统研究,分析断层破碎带大巷施工过程中的围岩力学性态以及相互影响;现场进行了工业性试验,对围岩变形进行监控量测,最终大巷安全、快速地通过了断层破碎带。
Taking the roadway groups across fault groups of Yuandian NO.2 coal mine in Huaibei for the engineering background, this thesis studies on roadway construction at fault and fracture zones and control technique of surrouding rock by the way of geophysical prospecting, numerical analysis and locale construction and monitoring.Based on depth exploration on engineering geological condition and simulation analysis on stress field features of huge fault zones,combined with practical situation of surrouding rock at fracture zones,the construction principles of nip in the mud, advanced test, slight burst,reinforced support and tight sealing,was put forward,and integrated technology of Advanced detection, Advanced strengthening, slight shock cutting and substep Dynamic Supporting was formed; Construction technology and Dynamic mechanical properties was researched by the principle of substep Dynamic coupling support, surrounding rock mechanical properties and interaction of was analyzed during the construction process of fault and fracture zones; locale industrial testing was done, Surrounding rock deformation was monitored and measured, eventually,roadway crossed fault and fracture zones safely and rapidly.
Taking the roadway groups across fault groups of Yuandian NO.2 coal mine in Huaibei for the engineering background, this thesis studies on roadway construction at fault and fracture zones and control technique of surrouding rock by the way of geophysical prospecting, numerical analysis and locale construction and monitoring.Based on depth exploration on engineering geological condition and simulation analysis on stress field features of huge fault zones,combined with practical situation of surrouding rock at fracture zones,the construction principles of nip in the mud, advanced test, slight burst,reinforced support and tight sealing,was put forward,and integrated technology of Advanced detection, Advanced strengthening, slight shock cutting and substep Dynamic Supporting was formed; Construction technology and Dynamic mechanical properties was researched by the principle of substep Dynamic coupling support, surrounding rock mechanical properties and interaction of was analyzed during the construction process of fault and fracture zones; locale industrial testing was done, Surrounding rock deformation was monitored and measured, eventually,roadway crossed fault and fracture zones safely and rapidly.
引文
[1]钱凯.淮北桃园矿F2断层泥的分形特征及其工程性质研究[D].合肥:合肥工业大学,2006.1-2.
[2]TSUYOSHI NOHARA,HIDEMI TANAKA,KUNIO WATANABE.In situ hydraulic tests in the active fault survey tunnel, Kamioka Mine, excavated through the active Mozumi-Sukenobu Fault zone and their hydrogeological significance[J].Island Arc,2006,15:537-545.
[3]H. Hadjab-Souag,J.-Fr. Thimus,M.Chabaat.Detecting the fracture process zone in concrete using scanning electron microscopy and numerical modelling using the nonlocal isotropic damage model[J].Ca.n.J.Civ.Eng,2007,34:496-504.
[4]王昆明,唐德高,贺虎成,刘记军,杨夫礼.破碎带对地下坑道动力响应影响的数值分析防灾[J].减灾工程学报,2007,(1):74-78.
[5]孙岩,韩克从.断裂构造岩带的划分[M].北京:科学出版社,1985
[6]孙广忠.岩体结构力学[M].北京:科学出版社,1988
[7]孟召平,彭苏萍.正断层附近煤的物理力学性质变化及其对矿压分布的影响[J].煤炭学报,2001,26(6):561-566
[8]谢和平,高峰,周宏伟,左建平.岩石断裂和破碎的分形研究[J].防灾减灾工程学报,2003,(4):1-8.
[9]张洁,尹宏伟,徐士进.用离散元方法讨论岩石强度对主动底辟盐构造断层分布模式的影响[J].南京大学学报(自然科学),2008,(6):642-650.
[10]汪吉林,李耀民,杨靖.基于断层信息维的矿井构造定量评价[J].煤炭科技,2009,(3):29-35.
[11]黎良杰,钱鸣高,李树刚.断层突水机理分析[J].煤炭学报,1996,(2):119-123.
[12]万斌,赵全富,吴祥.利用井下钻探方法分析判定断层位置及导水性[J].山东煤炭科技,2004,6:30-31.
[13]武强,周英杰,刘金韬,钟亚平,殷作如,李建民,洪益清.煤层底板断层滞后型突水时效机理的力学试验研究[J].煤炭学报,2003(6):561-565.
[14]李连崇,唐春安,梁正召,马天辉,张永彬.含断层煤层底板突水通道形成过程的仿真分析[J].岩石力学与工程学报,2009,(2):290-296.
[15]王强,曹代勇.皖北刘桥一矿边界断层富导水性及其成因机制[J].煤炭工程,2009,(2):72-74.
[16]孙家应,谢长仑,黄平,谢焰.淮南板集煤矿F512断层导水性分析及地面注浆加固[J].中国煤炭地质,2010,(7):31-35.
[17]李青锋,王卫军,朱川曲,彭文庆.基于隔水关键层原理的断层突水机理分析[J].采矿与安全工程学报,2009,(1):87-90.
[18]关宝树.隧道工程施工要点集[M].北京:人民交通出版社,2003.
[19]重庆建筑工程学院,同济大学编.岩体力学[M].北京:中国建筑工业出版社,1981,153-164
[20]高磊.矿山岩体力学[M].北京:机械工业出版社,1988
[21]HKastner. Osterreich Bauzeitischrift[J].Vol.10(11),1947。
[22]韩瑞庚.地下工程新奥法[M].北京:科学出版社,1987
[23]L.米勒.新奥法支护理论[M].地下工程,1980(6)
[24]P John D Lambshead, Caroline J Brown, Timothy J Ferrero.Biodiversity of nematode assemblages from the region of the Clarion-Clipperton Fracture Zone, an area of commercial mining interest[J].BMC Ecology,2003,1:1-12.
[25]Fulvio Celico,Emma Petrellal,Pietro Celico.Hydrogeological behaviour of some fault zones in a carbonate aquifer of Southern Italy:an experimentally based model [J].Terra Nova,2006,18:308-313.
[26]郑颖人等.地下工程锚喷支护设计指南[M].北京:中国铁道出版社,1988
[27]何满潮.软岩巷道工程概论[M].徐州:中国矿业大学出版社,1993
[28]方祖烈.拉压域特征及主次承载区的维护理论[M].世纪之交软岩工程技术现状与展望.北京:煤炭工业出版社,1999
[29]董方庭.巷道围岩松动圈支护理论及应用技术[M].北京:煤炭工业出版社,2001
[30]何满潮等.软岩工程力学[M].北京:科学出版社,2002
[31]朱昌星.综放工作面开切眼与停采线大断面巷道支护技术研究[D].泰安:山东科技大学2004,5.
[32]于长友.软岩巷道联合支护可靠性分析[D].沈阳:辽宁工程技术大学,2005,5.
[33]李东.基于可靠性的锚杆支护设计理论与应用研究[D].沈阳:辽宁工程技术大学,2005,6.
[34]付存仓,温森.断层对巷道附近塑性区的影响[J].采矿技术,2006(6):31-32.
[35]周跃峰,王金安,胡建军.基于灰色模糊理论的巷道锚网支护设计与优化[J].北京科技大学学报,2007,(12):1177-1181.
[36]冯超.高应力软岩返修巷道支护技术与监测结果分析[J].煤矿安全,2010,4:123-125
[37]Zhengxin Lu, D. J. Reddish and L. R. Stace.Uncertainty analysis in a numerical modelling context-an example application on a coal mine roadway design[J].Mining Technology (Trans. Inst. Min. Metall. A),2005,114:231-240.
[38]侯朝炯等.煤巷锚杆支护[M].徐州:中国矿业大学出版社,1999
[39]陈炎光,陆士良.中国煤矿巷道围岩控制[M].徐州:中国矿业大学出版社,1994
[40]刘长武,褚秀生著.软岩巷道锚注加固原理与应用[M].中国矿业大学出版社,2000
[41]王悦汉等.巷道支架壁后充填技术[M].北京:煤炭工业出版社,1995,8
[42]张柯.大跨度高地压破碎煤巷支护及机理研究[D].西安:西安科技大学,2003,5
[43]伍佑伦.基于岩体断裂力学的巷道稳定性与锚喷支护机理研究[D].上海:华中科技大学,2004,11.
[44]李和林,杨本生,孙利辉.深井地应力对巷道支护设计的影响[J].煤炭工程,2009,(3):28-31.
[45]Katja Essen,Thomas Bohlen.Modelling of Rayleigh-type seam waves in disturbed coal seams and around a coal mine roadway[J].Geophys.J.Int.2007,170:511-526.
[46]徐颖,张安临.断层破碎带巷道掘进技术[J].金属矿山,2001(8):15-16.
[47]于景泉.通过高压力、宽破碎带导水断层的施工技术[J].建井技术,2007(6):6-9.
[48]鲍胜芳,王斌.五沟煤矿轨道大巷注浆法过断层施工技术[J].能源技术与管理,2008(6):45-47.
[49]蔡东红,吴义泉.断层应力影响区巷道支护技术与实践[J].煤炭工程,2009(2):41-42.
[50]孙茂贵,陈柯.用注浆管幕法通过大涌水断层破碎带的施工技术[J].采矿技术,2009(6):32-35.
[51]高明中,韩磊,高新亚.巷道群过断层围岩控制技术研究,安徽理工大学学报(自然科学版)[J].2010(9):17-22.
[52]高明中.袁店二矿大巷组过断层组综合保障及支护技术研究报告[R].淮南:安徽理工大学,2010.
[2]TSUYOSHI NOHARA,HIDEMI TANAKA,KUNIO WATANABE.In situ hydraulic tests in the active fault survey tunnel, Kamioka Mine, excavated through the active Mozumi-Sukenobu Fault zone and their hydrogeological significance[J].Island Arc,2006,15:537-545.
[3]H. Hadjab-Souag,J.-Fr. Thimus,M.Chabaat.Detecting the fracture process zone in concrete using scanning electron microscopy and numerical modelling using the nonlocal isotropic damage model[J].Ca.n.J.Civ.Eng,2007,34:496-504.
[4]王昆明,唐德高,贺虎成,刘记军,杨夫礼.破碎带对地下坑道动力响应影响的数值分析防灾[J].减灾工程学报,2007,(1):74-78.
[5]孙岩,韩克从.断裂构造岩带的划分[M].北京:科学出版社,1985
[6]孙广忠.岩体结构力学[M].北京:科学出版社,1988
[7]孟召平,彭苏萍.正断层附近煤的物理力学性质变化及其对矿压分布的影响[J].煤炭学报,2001,26(6):561-566
[8]谢和平,高峰,周宏伟,左建平.岩石断裂和破碎的分形研究[J].防灾减灾工程学报,2003,(4):1-8.
[9]张洁,尹宏伟,徐士进.用离散元方法讨论岩石强度对主动底辟盐构造断层分布模式的影响[J].南京大学学报(自然科学),2008,(6):642-650.
[10]汪吉林,李耀民,杨靖.基于断层信息维的矿井构造定量评价[J].煤炭科技,2009,(3):29-35.
[11]黎良杰,钱鸣高,李树刚.断层突水机理分析[J].煤炭学报,1996,(2):119-123.
[12]万斌,赵全富,吴祥.利用井下钻探方法分析判定断层位置及导水性[J].山东煤炭科技,2004,6:30-31.
[13]武强,周英杰,刘金韬,钟亚平,殷作如,李建民,洪益清.煤层底板断层滞后型突水时效机理的力学试验研究[J].煤炭学报,2003(6):561-565.
[14]李连崇,唐春安,梁正召,马天辉,张永彬.含断层煤层底板突水通道形成过程的仿真分析[J].岩石力学与工程学报,2009,(2):290-296.
[15]王强,曹代勇.皖北刘桥一矿边界断层富导水性及其成因机制[J].煤炭工程,2009,(2):72-74.
[16]孙家应,谢长仑,黄平,谢焰.淮南板集煤矿F512断层导水性分析及地面注浆加固[J].中国煤炭地质,2010,(7):31-35.
[17]李青锋,王卫军,朱川曲,彭文庆.基于隔水关键层原理的断层突水机理分析[J].采矿与安全工程学报,2009,(1):87-90.
[18]关宝树.隧道工程施工要点集[M].北京:人民交通出版社,2003.
[19]重庆建筑工程学院,同济大学编.岩体力学[M].北京:中国建筑工业出版社,1981,153-164
[20]高磊.矿山岩体力学[M].北京:机械工业出版社,1988
[21]HKastner. Osterreich Bauzeitischrift[J].Vol.10(11),1947。
[22]韩瑞庚.地下工程新奥法[M].北京:科学出版社,1987
[23]L.米勒.新奥法支护理论[M].地下工程,1980(6)
[24]P John D Lambshead, Caroline J Brown, Timothy J Ferrero.Biodiversity of nematode assemblages from the region of the Clarion-Clipperton Fracture Zone, an area of commercial mining interest[J].BMC Ecology,2003,1:1-12.
[25]Fulvio Celico,Emma Petrellal,Pietro Celico.Hydrogeological behaviour of some fault zones in a carbonate aquifer of Southern Italy:an experimentally based model [J].Terra Nova,2006,18:308-313.
[26]郑颖人等.地下工程锚喷支护设计指南[M].北京:中国铁道出版社,1988
[27]何满潮.软岩巷道工程概论[M].徐州:中国矿业大学出版社,1993
[28]方祖烈.拉压域特征及主次承载区的维护理论[M].世纪之交软岩工程技术现状与展望.北京:煤炭工业出版社,1999
[29]董方庭.巷道围岩松动圈支护理论及应用技术[M].北京:煤炭工业出版社,2001
[30]何满潮等.软岩工程力学[M].北京:科学出版社,2002
[31]朱昌星.综放工作面开切眼与停采线大断面巷道支护技术研究[D].泰安:山东科技大学2004,5.
[32]于长友.软岩巷道联合支护可靠性分析[D].沈阳:辽宁工程技术大学,2005,5.
[33]李东.基于可靠性的锚杆支护设计理论与应用研究[D].沈阳:辽宁工程技术大学,2005,6.
[34]付存仓,温森.断层对巷道附近塑性区的影响[J].采矿技术,2006(6):31-32.
[35]周跃峰,王金安,胡建军.基于灰色模糊理论的巷道锚网支护设计与优化[J].北京科技大学学报,2007,(12):1177-1181.
[36]冯超.高应力软岩返修巷道支护技术与监测结果分析[J].煤矿安全,2010,4:123-125
[37]Zhengxin Lu, D. J. Reddish and L. R. Stace.Uncertainty analysis in a numerical modelling context-an example application on a coal mine roadway design[J].Mining Technology (Trans. Inst. Min. Metall. A),2005,114:231-240.
[38]侯朝炯等.煤巷锚杆支护[M].徐州:中国矿业大学出版社,1999
[39]陈炎光,陆士良.中国煤矿巷道围岩控制[M].徐州:中国矿业大学出版社,1994
[40]刘长武,褚秀生著.软岩巷道锚注加固原理与应用[M].中国矿业大学出版社,2000
[41]王悦汉等.巷道支架壁后充填技术[M].北京:煤炭工业出版社,1995,8
[42]张柯.大跨度高地压破碎煤巷支护及机理研究[D].西安:西安科技大学,2003,5
[43]伍佑伦.基于岩体断裂力学的巷道稳定性与锚喷支护机理研究[D].上海:华中科技大学,2004,11.
[44]李和林,杨本生,孙利辉.深井地应力对巷道支护设计的影响[J].煤炭工程,2009,(3):28-31.
[45]Katja Essen,Thomas Bohlen.Modelling of Rayleigh-type seam waves in disturbed coal seams and around a coal mine roadway[J].Geophys.J.Int.2007,170:511-526.
[46]徐颖,张安临.断层破碎带巷道掘进技术[J].金属矿山,2001(8):15-16.
[47]于景泉.通过高压力、宽破碎带导水断层的施工技术[J].建井技术,2007(6):6-9.
[48]鲍胜芳,王斌.五沟煤矿轨道大巷注浆法过断层施工技术[J].能源技术与管理,2008(6):45-47.
[49]蔡东红,吴义泉.断层应力影响区巷道支护技术与实践[J].煤炭工程,2009(2):41-42.
[50]孙茂贵,陈柯.用注浆管幕法通过大涌水断层破碎带的施工技术[J].采矿技术,2009(6):32-35.
[51]高明中,韩磊,高新亚.巷道群过断层围岩控制技术研究,安徽理工大学学报(自然科学版)[J].2010(9):17-22.
[52]高明中.袁店二矿大巷组过断层组综合保障及支护技术研究报告[R].淮南:安徽理工大学,2010.