摘要
为解决特厚煤层区段煤柱参数留设问题及采动平巷大变形冒顶事故,本文对综放区段煤柱合理参数开展了深入研究,并提出了采动平巷围岩控制技术。结合典型矿井煤柱宽度留设经验及采动平巷变形特征,运用工程类比法提出了5207综放区段煤柱宽度留设及采动平巷支护优化方向;基于煤样三轴压缩试验,建立了区段煤柱稳定性尖点突变模型,推导出煤柱失稳力学条件判据;综合弹性核理论、载荷估算法、经验估算法、数值模拟计算,确定5207综放区段煤柱合理宽度为18m;运用三角模糊算法,结合煤柱稳定性关键影响因素模糊重要度判别原则,确定5207综放区段煤柱稳定性关键影响因素:区段煤柱宽度和区段煤柱高度;基于桁架锚索联接锁紧器发展历程,提出了桁架锚索与单体锚索“交错布置”支护技术,阐述了其围岩控制原理:优势互补、点线结合、共同承载、安全经济;设计了5207采动平巷“交错布置”组合支护方案,运用钻孔应力计测量了区段煤柱支承压力分布规律,并观测了巷道表面位移变化规律。应用实践表明5207综放区段煤柱参数留设和采动平巷支护方案设计安全合理,且取得了良好的社会和经济效益。
In order to solve the problem of coal pillar parameters and frequent roof-fall accidents afterlarge deformation, reasonable pillar parameters is studied in detail and the roadway controllingtechnology is put forward. Combined with the experience of pillar width design and thecharacteristics of roadway deformation in typical coal mine, the optimal direction of pillar width andsupport design of mining roadway at fully-mechanized section NO.5207are proposed byengineering analogy method. Based on triaxial compression test of coal sample, mechanicalcondition criterion of pillar stability is derived by establishing cusp catastrophe model. Incombination with elastic kernel theory, load estimation method, experience estimation method andnumerical simulation method, the reasonable width of coal pillar at fully-mechanized section NO.5207is18m. Combined with triangular fuzzy algorithm and the principle of fuzzy importance, keyinfluence factors to pillar stability are as follows: section pillar width, section pillar height. Based onthe development history of truss connector,“staggered arrangement method”(SAM) supporttechnology containing truss cable and single cable is proposed and its surrounding control principlesare as follows: advantageous complementarities, point-line combination, common carrying andsafety economy. The SAM combined supporting scheme is designed at fully-mechanized section NO.5207, then, the distribution regularities of pillar abutment pressure is measured by borehole stressgauge and the roadway displacement is observed. The research achieves have been applied to5207workface and have brought social and finical benefits promptly.
引文
1.王显政.加强形势认识合理应对挑战提升煤炭工业发展科学化水平[J].中国煤炭工业,2012(3):4~7.
2.孟宪锐,王鸿鹏,刘朝晖,张英.我国厚煤层开采方法的选择原则与发展现状[J].煤炭科学技术,2009,37(1):39~44.
3.王家臣.我国综放开采技术及深层次发展问题探讨[J].煤炭科学技术,2005,33(1):14~17.
4.王家臣.厚煤层开采理论与技术[M].北京,冶金工业出版社,2009.
5.徐永圻.煤矿开采学[M].徐州:中国矿业大学出版社,1999.
6. Rutherford A. Moderately Thick Seam Ming In Australia [C]//WU Jian, WANG Jiachen.Proceedings of1999International Workshop on Underground Thick-Seam Ming. Beijing:China Coal Industry Publishing House,1999:122~135.
7.陈炎光,徐永圻.中国采煤方法[M].徐州,中国矿业大学出版社,1991.
8.徐乃忠.我国厚煤层开采的问题与方向[J].煤炭工程,2008,12:5~7.
9.任传鹏,丁日佳,李上.我国煤炭采出率标准研究[J].煤矿开采,2010,15(3):111~114.
10. Su, Wen H., Peng, Syd S., Hsiung, S. M., Interactions in multiple-seam mining, Soc of MiningEngineers,1986:31~44.
11. Britton, Scott G., Mining Multiple Seams, Coal Mining&Processing,1980,17(12):64~66,68,70.
12. Khare, Saurabh, Rao, Y.V., Murthy, Ch.S.N., etc, Multiple seam mining: a critical reviewJournal of mines, Metals and Fuels,2006,54(12):327~329.
13. Kripakov, Nieholas P., Beckett, Les A., Donato, Douglas A., Loading on underground miningstructures influenced by multiple seam interaction, Soc of Mining Engineers of AIME,1986:225~236.
14. Peng, S.S., Hsiung, S.M., Problems and solutions for multiple seam mining, Colliery Guardian,236(10),1988:371~372.
15. Hill RW, Multi-seam mining in South African Collieries, In, Peng S S, Proceedings of the14thInternational Conference on Ground Control in Mining, Morgantown, WV, West VirginiaUniversity,1995:305~311.
16. Pixler, R, Mining Multiple-seam steeply dipping coal in the Nanna Basin, Society of MiningEngineers of AIME,1986,9.
17.朱银昌,陈庆禄,张铁岗.复杂难采煤层的开采[M],北京:世界图书出版社,1998,1.
18. Chekan, Gregory J., Matetic, Rudy J., Galek, James A., Multiple seam mining problems in theeastern united states information circular-United States, Bureau of Mines,1986:27~43.
19. Chekan, Gregory J., Matetic, Rudy J., Dwyer, David L., Effects of abandoned multiple seamworkings on a long-wall in Virginia, Report of Investigations-United States, Bureau of Mines,9247,1989,19.
20. Hladysz, Z, Analysis of risk in multiple seam mining, Preprint-Society of Mining Engineers ofAIME,1985,12.
21. Dunham, R K, Stace, R L, Interaction Problems in multi-seam mining,19thUS Symposium onRock Mechanics, Stateline, Nevada.1978:174~179.
22. Chekan, Gregory J., Matetic, Rudy J., Galek, James A., Strata interaction in multiple seammining-two studies in Pennsylvania, Report of Investigations–United States, Bureau ofMines,1986,20.
23.张开智.不同宽度区段煤柱巷道围岩结构及变形机理研究[D].青岛:山东科技大学,2004.
24.彭林军.特厚煤层沿空掘巷围岩变形失稳机理及其控制对策[D].北京:中国矿业大学(北京),2012.
25.马其华,王宜泰.深井沿空巷道小煤柱护巷机理及支护技术[J].采矿与安全工程学报,2009,26(4):520~523.
26.钱鸣高,石平五.矿山压力与岩层控制[M].徐州:中国矿业大学出版社,2003.
27.高浩,崔廷锋,张魁等.留小煤柱沿空掘巷技术[J].煤矿安全,2012,43(4):106~109.
28.徐新斌,崔廷锋,杨志远.近浅埋煤层大采高工作面回采巷道护巷煤柱合理宽度研究[J].煤矿安全,2012,43(12):61~64.
29.崔廷锋,张魁,徐新斌.大采高工作面回采巷道护巷煤柱合理宽度研究[J].中国矿业,2012,21(5):88~90.
30.张开智,夏均民,蒋金泉.钻孔煤粉量变化规律在区段煤柱合理参数确定中的应用[J].岩石力学与工程学报,2004,43(8):1307~1310.
31.柏建彪,侯朝炯.沿空掘巷窄煤柱稳定性数值模拟研究[J].岩石力学与工程学报,2004,23(20):3475~3479.
32.邓广哲,江万刚,郝珠成.基于统计损伤的综放区段煤柱变形时间相关性分析[J].采矿与安全工程学报,2009,26(4):413~417.
33.何满潮,袁和生,靖洪文.中国煤矿锚杆支护理论与实践[M].北京:科学出版社,2004.
34. P.Willians.The development of rock bolting in UK coal mines[J].Mining Engineering,1994,392(153),307~312.
35. V.V.Nazimko,A.A.Lapteev,V.P.Sazhnev.Rock mass self-supporting effect utilization forenhancement stability of a tunnel[J].International Journal of Rock Mechanics and MiningSciences,1997,34(3),223.e1~223.e11
36. P.Willians.The development of rock bolting in UK coal mines[J].Mining Engineering,1994,392(153),307~312.
37.王焕文,王继良.锚喷支护[M].北京:煤炭工业出版社,1988.
38.杨双锁.回采巷道围岩控制原理及锚固结构的适应性研究[D].徐州:中国矿业大学,2001.
39.袁亮.深井巷道围岩控制理论及淮南矿区工程实践[M].北京:煤炭工业出版社,2006.
40.侯朝炯,郭宏亮.我国煤巷锚杆支护技术的发展方向[J].煤炭学报,1996,21(2),113~118.
41.杨双锁,康立勋.煤矿巷道锚杆支护研究的总结与展望[J].太原理工大学学报,2002,7(4),376~381.
42.康红普.煤巷锚杆支护理论与成套技术[M].北京:煤炭工业出版社,2007.
43. E.Unala,I.Ozkanb,G.Cakmakcia.Modeling the behavior of longwall coal mine gate roadwayssubjected to dynamic loading[J].International Journal of Rock Mechanics and MiningSciences,2001,38(2),181~197.
44.王明恕.全长锚固锚杆机理的探讨[J].煤炭学报,1983,6(1),32~40.
45.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.
46. E Unal,I Ozkan,G Cakmakci.Modeling the behavior of longwall coal mine gate roadwayssubjected to dynamic loading[J].International Journal of Rock Mechanics and MiningSciences,2001,38(2),181~197.
47. Gregory Molinda.Reinforcing coal mine roof with polyurethane injection:4casestudies[J].Geotechnical and Geological Engineering,2008,26(5),553~566.
48.方祖烈.拉压域特征及主次承载区的维护理论.世纪之交软岩工程技术现状与展望[C].北京:煤炭工业出版社,1999:48~51.
49. Chen Shougen,Gu Hua.Numerical simulation of bed separation development and groutinjecting into separations[J].Geotechnical and Geological Engineering,2008,26(3),375~385.
50. S.Lin.Displacement discontinuities and stress changes between roof strata and their influenceon longwall mining under aquifers[J].Geotechnical and Geological Engineering,1993,11(1),37~50.
51.李大伟,侯朝炯,柏建彪.大刚度高强度二次支护巷道控制机理与应用[J].岩土工程学报,2008,30(7),1072~1078.
52. Henryk Gi.The theory of strata mechanics[M].Polish:Polish Scientific Publishers,2001.
53. Santanu Majumder,Swapan Chakrabarty.The vertical stress distribution in a coal side of aroadway—an elastic foundation approach[J].Mining Science and Technology,1991,12(3),233~240.
54. D.N.Bigby.Developments in British rockbolting technology[J].Mining Science andTechnology,1991,12(3),233~240.
55. Huang Qingxiang.Study on roof structure and ground control in shallow seam longwallmining[M].Xuzhou:China University of Mining and Technology Press,2000.
56.马念杰,侯朝炯.采准巷道围岩控制[M].北京:煤炭工业出版社,1996.
57.马念杰,潘玮,李新元.煤巷支护技术与机械化掘进[M].徐州:中国矿业大学出版社,2008.
58.张农,高明仕.煤巷预拉力支护体系及其工程应用[J].矿山压力与顶板管理,2002,6(4),1~6.
59.张农,袁亮.离层破碎型煤巷顶板的控制原理[J].采矿与安全工程学报,2006,6(1),34~38.
60. Song Guo,Stankus J.Control mechanism of a tensioned bolt system in the laminated roof witha large horizontal stress[A].16th Int.Conf.on Ground Control in Mining[C].Morgantown,West Virginia,1997,93~98.
61.刘波,李先炜,陶龙光.锚拉支架中锚杆横向效应分析[J].岩土工程学报,1998,20(4),36~39.
62. He Fulian,Yin Dongpin,Yan Hong,etc.Study on the coupling system of high prestress cabletruss and surrounding rock on a coal roadway[A].The5th International Symposium on In-situRock Stress[C]. Beijing: CRC Press,2010,643~646.
63. Li Jianping,He Fulian,Yan Hong,et al.The caving and sliding control of surrounding rockson large coal roadways affected by abutment pressure[J].Safety Science,2012,50(4),773~777.
64. He Fulian,Yin Dongpin,Yan Hong,etc.The control of thick compound roof caving on a coalroadway[A].International Conference on Mine Hazards Prevention and Control[C]. Qingdao:Atlantis Press,2010,717~721.
65.赵洪亮,姚精明,何富连等.大断面煤巷预应力桁架锚索的理论与实践[J].煤炭学报,2007,32(10),1061~1065.
66.阚甲广,张农,李桂臣,等.深井大跨度切眼施工方式研究[J].采矿与安全工程学报,2009,26(2),163~167.
67.康立勋,杨双锁.全煤巷道拱形整体锚固结构稳定性分析[J].矿山压力与顶板管理,2002,6(3),19~21.
68.杨双锁,康立勋.煤矿巷道锚杆支护研究的总结与展望[J].太原理工大学学报,2002,33(4),376~381.
69.周志利.厚煤层大断面巷道围岩稳定与掘锚一体化研究[D].北京:中国矿业大学(北京),2011.
70.翟英达.多裂隙围岩中锚固结构形成的力学机理[J].煤炭学报,2011,36(9):1435~1439.
71.战玉宝,毕宣可,尤春安.预应力锚索锚固段应力分布影响因素分析[J].土木工程学报,2007,40(6):49~53.
72.朱颖彦,唐寿高,崔鹏.岩土数值模拟:方法论的思考[J].岩石力学与工程学报,2005,42(增2):5919~5925.
73.严红.特厚煤层巷道顶板变形机理与控制技术[D].北京:中国矿业大学(北京),2013.
74.孟宪锐,周昌兴,王鸿鹏等.千米深部大倾角特厚煤层综放回采巷道矿压显现规律研究[J].煤,2008,17(11),1~4.
75.鞠文君.急倾斜特厚煤层水平分层开采巷道冲击地压成因与防治技术研究[D].北京:北京交通大学,2009.
76.许建聪.碎石土滑坡变形解体破坏机理及稳定性研究[D].杭州:浙江大学,2005.
77.张业民.突变理论在岩土与结构工程中的若干应用[D].大连:大连理工大学,2008.
78.聂珊利.基于尖点突变理论的摩擦桩竖向承载力分析[D].乌鲁木齐:新疆农业大学,2010.
79.宋扬,缪协兴.基于尖点突变模型的煤层底板突水预测研究[J].岩石力学与工程学报,2003,22(4),573~577.
80.王旭春,黄福昌,张怀新等.A. H.威尔逊煤柱设计公式探讨及改进[J].煤炭学报,2002,27(6):604~608.
81.郭文兵,邓喀中,邹友峰.走向条带煤柱破坏失稳的尖点突变模型[J].岩石力学与工程学报,2004,23(12),1996~2000.
82.钱鸣高,石平五.矿山压力与岩层控制[M].徐州:中国矿业大学出版社,2003.
83.高浩,崔廷锋,张魁等.留小煤柱沿空掘巷技术[J].煤矿安全,2012,43(4):106~109.
84.徐新斌,崔廷锋,杨志远.近浅埋煤层大采高工作面回采巷道护巷煤柱合理宽度研究[J].煤矿安全,2012,43(12):61~64.
85.朱松岭,周平,韩毅,杨海成.基于模糊层次分析法的风险量化研究[J].计算机集成制造系统,2004,10(8),980~984.
86.李青,陆廷金,李宁萍,,张玉柱.三角模糊数的模糊故障树分析及其应用[J].中国矿业大学学报,2000,29(01),56~59.
87.贾智伟,景国勋,张强,段振伟.基于三角模糊数的矿井火灾事故树分析[J].安全与环境学报,2004,4(6),62~65.
88.司书宾,孙树栋,韩光臣,王军强.基于三角模糊数的综合保障评价指标权重分析[J].西北工业大学学报,2004,22(6),689~694.
89.伍爱友,施式亮,王从陆.基于事故树方法与三角模糊理论耦合的城市火灾风险分析[J].中国安全科学学报,2009,19(7),31~36.
90.赵艳萍,贡文伟.模糊故障树分析及其应用研究[J].中国安全科学学报,2001,11(6),31~35.
91.刘仁辉,张劲强,韩喜双.三角模糊数的工程项目风险识别[J].哈尔滨工业大学学报,2008,40(10),1617~1620.
92.张发明,赵维炳,刘宁.预应力锚索锚固荷载的变化规律及预测模型[J].岩石力学与工程学报,2004,23(1):39~43.
93.翟英达.多裂隙围岩中锚固结构形成的力学机理[J].煤炭学报,2011,36(9):1435~1439.
94.战玉宝,毕宣可,尤春安.预应力锚索锚固段应力分布影响因素分析[J].土木工程学报,2007,40(6):49~53.
95.翟英达.锚杆预紧力在巷道围岩中的力学效应[J].煤炭学报,2008,33(8):856~859.
96.周永江,何思明,杨雪莲.预应力锚索的预应力损失机理研究[J].岩土力学,2006,27(8):1353~1356.
97.尤春安,战玉宝.预应力锚索锚固段的应力分布规律及分析[J].岩石力学与工程学报,2005,24(6):925~929.
98.王艳芬.预应力锚索加固岩体的机理分析和数值计算[D].武汉:华中科技大学岩土工程专业,2007:20~8.
99.吴家龙.弹性力学[M].上海:同济大学出版社,1993:45~56.
100.翁明月,殷帅峰,李其敏.桁架锚索与单体锚索不同支护结构研究及应用[J].煤炭工程,2013,(4):100~103.
101.梁运培,孙东玲.岩层移动的组合岩梁理论及其应用研究[J].岩石力学与工程学报,2002,21(5):654~657.
102.康希良,赵鸿铁,薛建阳.钢管混凝土套箍机理及组合弹性模量的理论分析[J].工程力学,2007,24(11):121~125.
103.赵洪亮,姚精明,何富连.大断面煤巷预应力桁架锚索的理论与实践[J].煤炭学报,2007,32(10):1061~1065.
104.翁明月,殷帅峰,李其敏.桁架锚索与单体锚索不同支护结构研究及应用[J].煤炭工程,2013,(4):100~103.
105.梁运培,孙东玲.岩层移动的组合岩梁理论及其应用研究[J].岩石力学与工程学报,2002,21(5):654~657.
106.康希良,赵鸿铁,薛建阳.钢管混凝土套箍机理及组合弹性模量的理论分析[J].工程力学,2007,24(11):121~125.
107.严红,何富连,徐腾飞.深井大断面煤巷双锚索桁架控制系统的研究与实践[J].岩石力学与工程学报,2012,31(11):2248~2257.
108.赵洪亮,姚精明,何富连.大断面煤巷预应力桁架锚索的理论与实践[J].煤炭学报,2007,32(10):1061~1065.
109.王艳芬.预应力锚索加固岩体的机理分析和数值计算[D].武汉:华中科技大学岩土工程专业,2007:20~28.
110.吴家龙.弹性力学[M].上海:同济大学出版社,1993.