基于SHPB的岩石动静组合加载试验研究进展
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摘要
随着深部工程不断开发,人类面临的岩石力学问题日益复杂。针对复杂的深部岩石力学问题,基于前人开展的SHPB动静组合加载装置即得的试验研究,从SHPB试验装置改进、力学特性、破坏机理、能量耗散规律和应力波传播规律等方面概述了岩石动静组合加载试验研究现状,总结了相关研究成果,并提出了需要进一步探究的高温、高水压条件下多场耦合作用的相关岩石力学科学问题。
With the increasing development of deep engineering,the problems of rock mechanics are more and more complicated.In view of the complex deep rock mechanics problems,based on the experimental research of SHPB device under static and dynamic loading carried out by many scholars,the research status of rock combined dynamic and static loading test were described from aspects of improvement of SHPB test device,mechanical characteristics,failure mechanism,energy dissipation law,stress wave propagation law and so on.The related research results were summarized,and related scientific problems of rock mechanics which needed further exploration of coupling effect under the condition of high temperature and high water pressure field were put forward.
With the increasing development of deep engineering,the problems of rock mechanics are more and more complicated.In view of the complex deep rock mechanics problems,based on the experimental research of SHPB device under static and dynamic loading carried out by many scholars,the research status of rock combined dynamic and static loading test were described from aspects of improvement of SHPB test device,mechanical characteristics,failure mechanism,energy dissipation law,stress wave propagation law and so on.The related research results were summarized,and related scientific problems of rock mechanics which needed further exploration of coupling effect under the condition of high temperature and high water pressure field were put forward.
引文
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[2]Sun J,Wang S J.Rock mechanics and rock engineering in China:developments and current state-of-the-art[J].International Journal of Rock Mechanics and Mining Science,2000(37):447-465.
[3]朱家锐,常伟华,毛明发.深部复杂岩体特性研究及巷道支护方案设计[J].矿业研究与开发,2017,37(12):28-31.
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[5]刘焕新,王剑波,赵杰,等.深井开采关键技术难题与解决途径初探[J].矿业研究与开发,2018,38(5):1-5.
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[7]谢和平.深部高应力下的资源开采---现状、基础科学问题与展望[C]//香山科学会议.科学前沿与未来(第六集).北京:中国环境科学出版社,2002:179-191.
[8]何满潮.深部开采工程岩石力学的现状及其展望[C]//中国岩石力学与工程学会.第八次全国岩石力学与工程学术大会论文集.北京:科学出版社,2004:88-94.
[9]Diering D H.Ultra-deep level mining:future requirements[J].Journal of the South African Institute of Mining and Metallurgy,1997,97(6):249-255.
[10]Vogel M,Andrast H P.Alp transit-safety in construction as a challenge,health and safety aspects in very deep tunnel construction[J].Tunneling and Underground Space Technology,2000,15(4):481-484.
[11]Gurtunca R G,Keynote L.Mining below 3 000 m and challenges for the South African gold mining industry[C]//In:Proceedings of Mechanics of Jointed and Fractured Rock.Rotterdam:A.A.Balkema,1998:3-10.
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[13]Diering D H.Tunnels under pressurein an ultra-deep Wifwatersrand gold mine[J].Journal of the South African Institute of Mining and Metallurgy,2000,100:319-324.
[14]Johnson R A S.Mining at ultra-depth,evaluation of alternatives[C]//Proceedings of the 2nd North America Rock Mechanics Symposium.Montreal:NARMS96,1996:359-366.
[15]胡社荣,彭纪超,黄灿,等.千米以上深矿井开采研究现状与进展[J].中国矿业,2011,20(7):105-110.
[16]何满潮,谢和平,彭苏萍,等.深部开采岩体力学研究[J].岩石力学与工程学报,2005,24(16):2803-2813.
[17]唐绍辉.深井金属矿山岩爆灾害研究现状[J].矿业研究与开发,2006,26(S1):136-140.
[18]谢和平.“深部岩体力学与开采理论”研究构想与预期成果展望[J].工程科学与技术,2017,49(2):1-16.
[19]赵生才.深部高应力下的资源开采与地下工程---香山会议第175次综述[J].地球科学进展,2002,17(2):295-298.
[20]Stachulak J S,Hensel V.Successful application of DPFsystem at Vale Incos Creighton Mine[C]//The 13th U.S./North American Mine Ventilation Symposium.[S.l.]:[s.n.],2010:123-128.
[21]Diekmeyer P.A supersized combo[J].CIM Magazine,2009,4(2):54-57.
[22]谢和平,高峰,鞠杨.深部岩体力学研究与探索[J].岩石力学与工程学报,2015,34(11):2161-2178.
[23]张维滨,郭树林,姚香,等.中国金属矿山深井通风技术研究现状综述[J].黄金,2009,30(9):26-29.
[24]古德生.金属矿业的前沿领域:深部采矿[R].长沙:中南大学,2010.
[25]王涵,韩晓乐,陈志维,等.千米深井固体充填采煤地表沉陷规律模拟研究[J].矿业研究与开发,2016,36(2):71-75.
[26]晏玉书.我国煤矿软岩巷道围岩控制技术现状及发展趋势[C]//何满潮.中国煤矿软岩巷道支护理论与实践.北京:中国矿业大学出版社,1996:1-17.
[27]Paterson M S.Experimental deformation and faulting in Wombeyanmarble[J].Bull.Geol.Soc.Am,1958,69:465-467.
[28]张春生,周垂一,刘宁.锦屏二级水电站深埋特大引水隧洞关键技术[J].隧道建设(中英文),2017,37(11):1492-1499.
[29]石生明,李长虹,刘娟奇,等.白龙江引水工程深埋长隧洞工程地质问题[J].科学技术与工程,2018,18(12):154-158.
[30]刘树新,鲁思佐,陈阳.基于多重判据的某深部矿区岩爆倾向性研究[J].矿业研究与开发,2017,37(2):9-12.
[31]王初步,谭富生,王宇,等.基于数值模拟的复杂采空区稳定性分析[J].矿业研究与开发,2018,38(1):96-100.
[32]张彦斌,杨永康,康天合,等.采空区煤柱下大采高综放采场围岩应力演化特[J].矿业研究与开发,2017,37(9):59-62.
[33]姜自华,姚兆明,陈军浩.冻融循环和含水率对砂岩单轴抗压强度的影响[J].矿业研究与开发,2017,37(1):85-88.
[34]陈绪新,付厚利,秦哲.干湿循环作用下露天矿边坡岩石损伤能量演化分析[J].科学技术与工程,2016,16(20):247-252.
[35]陈万鹏.酸性饱水对砂岩力学参数的损伤效应[J].矿业研究与开发,2017,37(4):46-49.
[36]宫凤强.动静组合加载下岩石力学特性和动态强度准则的试验研究[D].长沙:中南大学资源与安全工程学院,2010.
[37]李夕兵,古德生.深井坚硬矿岩开采中高应力的灾害控制与破碎诱变[C]//香山第175次科学会议.北京:中国环境科学出版社,2002:101-108.
[38]刘爱华,郑鹏.SHPB在岩石动静组合加载实验中的应用及发展方向[J].爆破,2007,24(S):253-259.
[39]Hopkinson B.Method of measuring the pressure produced in the detonation of high explosives or by the impact of bullets[J].Philos Trans Roy Soc,1914,213(31):437-456.
[40]Kumar A.The effect of strain rate and temperature on strength of basalt and granite[J].Geophysics,1968,33(3):501-510.
[41]李夕兵,古德生.冲击载荷下岩石动态应力应变全图测试中的合理加载波形[J].爆炸与冲击,1993,13(2):125-131.
[42]李夕兵,古德生.岩石冲击动力学[M].长沙:中南工业大学出版社,1994.
[43]Zhao J,Zhou Y X,Hefny A M,et al.Rock dynamics research related to cavern development for ammunition storage[J].Tunneling and Underground Space Technology,1999,14(4):513-526.
[44]Ravichandrn G,Subhash G.Critical Appraisal of limiting strain rates for compression testing of ceramics in a split hopkingson pressure bar[J].America Ceram Soc,1994,77(1):263-267.
[45]Tedesco J W,Ross C A.Strain-rate dependent constitutive equations for concrete[J].Journal of Pressure Vessel Technology,1998,120(4):398-405.
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