深埋破碎岩体TBM掘进风险评估与应对

doi:10.13722/j.cnki.jrme.2014.0829

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摘要 TBM具有快速掘进的特点，但在不良地质条件下由于设备和支护能力的限制，其正常掘进受到影响，面临卡机甚至停工的风险。锦屏二级水电站引水隧洞一般埋深超过1 500 m，地质条件复杂，TBM在通过白山组破碎大理岩洞段时，由于围岩破碎、强度较低、自稳能力差，需要对掘进中的风险进行评估。首先利用现场围岩的开挖响应，确定破碎岩体的初始力学参数，之后通过计算对比不同质量岩体的变形和TBM正常掘进所需推力大小，发现在破碎岩体中掘进所需推力已经超过了TBM设备自身能够提供的最大推力，并且围岩变形也很难限制在TBM的扩挖能力范围之内，而围岩在撑靴压力的作用下已经发生破坏，无法提供足够的推进力保证TBM顺利掘进。为此提出了先导洞方案，计算结果表明利用先导洞能缓解释放的变形量，避免卡机风险。最后提出了其他支护优化设计和应对策略。研究成果可为类似的工程施工提供参考。

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关键词 ：隧道工程, 深埋, TBM, 破碎岩体, 风险评估

Abstract：TBM is known for its quick driving，but the normal driving will be affected under the unfavorable geological condition because of the limitation of equipment and the supporting capacity. TBM faces the risk of lock and even shutdown. The general depth of Jinping II diversion tunnel is more than 1 500 m，and the geological condition is very complex. When TBM driving in unfavorable geological period of Baishan group，due to the low strength of broken surrounding rock，and the poor steady ability，the risk of TBM driving need to be evaluated. First the initial mechanical parameters of rock mass were studied by excavation response of field surrounding rock. Then，comparing the displacement of different quality of rock mass and the thrust needed for TBM driving，it was found that the required thrust in the unfavorable geological condition has exceeded the provide maximum thrust，and that the displacement is also hard to limit in the range of TBM expansion. The surrounding rock has been damaged in gripper compression，and cannot provide enough thrust to ensure TBM driving. The pilot tunnel was proposed，and the calculation results show that the pilot tunnel can relieve deformation to avoid lock. Other support optimization designs and coping strategies were presented. The research results can provide good reference for similar engineerings.

Key words： tunnelling engineering deep-buried TBM fractured rock mass risk assessment

引用本文:

刘宁1，2，张春生1，褚卫江1，张传庆3，吴旭敏1. 深埋破碎岩体TBM掘进风险评估与应对[J]. 岩石力学与工程学报, 2015, 34(s1): 3348-3355.
LIU Ning1，2，ZHANG Chunsheng1，CHU Weijiang1，ZHANG Chuanqing3，WU Xumin1. RISK ASSESSMENT AND RESPONSE OF TBM EXCAVATION IN DEEP BURIED FRACTURED ROCK MASS. , 2015, 34(s1): 3348-3355.

链接本文:

http://www.rockmech.org/CN/10.13722/j.cnki.jrme.2014.0829 或 http://www.rockmech.org/CN/Y2015/V34/Is1/3348

[1]	吴世勇，王鸽，徐劲松，等. 锦屏二级水电站TBM选型及施工关键技术研究[J]. 岩石力学与工程学报，2008，27(10)：2 000-2 009. (WU Shiyong，WANG Ge，XU Jinsong，et al. Research on TBM type-selection and key construction technology for Jinping II hydropower station[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(10)：2 000-2 009.(in Chinese)) " target="_blank">
[5]	苏华友，张继春，史丽华. TBM通过不良地质地段的施工技术[J]. 岩石力学与工程学报，2005，25(9)：1 635-1 637.(SU Huayou，ZHANG Jichun，SHI Lihua. Construction technology of TBM excavating through section of unfavorable geological condition[J]. Chinese Journal of Rock Mechanics and Engineering，2005，25(9)：1 635- 1 637.(in Chinese)) " target="_blank">
[6]	王梦恕，李典璜，张镜剑，等. 岩石隧道掘进机(TBM)施工及工程实例[M]. 北京：中国铁道出版社，2004：13-78.(WANG Mengshu，LI Dianhuang，ZHANG Jingjian，et al. Tunnelling with rock TBM andrelated case studies[M]. Beijing：China Railway Publishing House，2004：13-78.(in Chinese)) " target="_blank">
[11]	HOEK E. Tunnel support in weak rock[C]// Keynote Address Symposium of Sedimentary Rock Engineering. Taipei：[s. n. ]，1998： 1-12. " target="_blank">
[13]	瑞士安伯格工程咨询公司. 锦屏二级长引水隧洞采用TBM 施工可行性咨询报告[R]. 瑞士：安伯格工程咨询公司，2006.(Amberg Technologis Ltd.. Feasibility consultation report on TBM working for Jinping Cascade-II Hydropower Station with long diversion tunnel[R]. Switzerland：Am Berg Technologies Ltd.，2006. (in Chinese)) " target="_blank">
[2]	钱七虎，李朝甫，傅德明. 全断面掘进机在中国地下工程中的应用现状及前景展望[J]. 建筑机械，2002，(5)：28-35.(QIAN Qihu，LI Chaofu，FU Deming. Application situation and outlook of TBM in underground project in China[J]. Construction Machinery，2002，(5)：28-35.(in Chinese)) " target="_blank">
[3]	张镜剑. TBM 的应用及其有关问题和展望[J]. 岩石力学与工程学报，1999，18(3)：363-367.(ZHANG Jingjian. The application and some problems of TBM and its prospects[J]. Chinese Journal of Rock Mechanics and Engineering，1999，18(3)：363-367.(in Chinese))
[4]	刘冀山，肖晓春，杨洪杰，等. 超长隧洞TBM 施工关键技术研究[J]. 现代隧道技术，2005，42(4)：37-43.(LIU Jishan，XIAO Xiaochun，YANG Hongjie，et al. A study on key construction techniques for tunnel boring machines adopted in super-long tunnels[J]. Modern Tunnelling Technology，2005，42(4)：37-43.(in Chinese)) " target="_blank">
[9]	WENNER D，WANNENMACHER H. Alborz Service tunnel in iran：TBM tunnelling in difficult ground conditions and its solutions[C]// 1st Regional and 8th Iranian Tunneling Conference. Tehran，Iran：[s. n.]，2009：29-31. " target="_blank">
[10]	中国水电顾问集团华东勘测设计研究院. 锦屏二级电站可行性研究报告[R]. 杭州：中国水电顾问集团华东勘测设计研究院，2005. (Feasibility study report on Jinping II Hydropower Station[R]. Hangzhou：HydroChina Huadong Engineering Corporation，2005.(in Chinese)) " target="_blank">
[7]	杨智国. 围岩坍塌地段TBM处理措施研究[J]. 铁道工程学报，2005，(2)：51-54.(YANG Zhiguo. Research on treatment measures for TBM working in collapsed section of surrounding rock[J]. Journal of railway Engineering Society，2005，(2)：51-54.(in Chinese)) " target="_blank">
[8]	刘大军，张益忠. TBM在不良地质洞条件下的施工技术[J]. 探矿工程：岩体钻掘工程，2008，(10)：60-65.(LIU Dajun，ZHANG Yizhong. Construction technology of TBM in unfavorable geological tunnel section[J]. Exploration Enginnering：Rock and Drilling Tunnelling，2008，(10)：60-65.(in Chinese)) " target="_blank">
[12]	AMBERG F. Tunnelling in high overburden with reference to deep tunnels in Switzerland[J]. Tunnelling and Underground Space Technology，2004，19(4)：308. " target="_blank">