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| KARST WATER INRUSH MECHANISM AND RISK MITIGATION OF TUNNEL HOSTED IN CARBONATE OF NAPPE STRUCTURE BELTS |
| XU Ying1,ZUO Changqun1,CHEN Zhichao1,2,FANG Xiaorui3 |
(1. Faculty of Engineering,China University of Geosciences,Wuhan,Hubei 430074,China;
2. Fujian Key Laboratory of Geohazard Prevention,Fuzhou,Fujian 350002,China;
3. Hubei Province Guzhu Expressway Construction Command,Shiyan,Hubei 442100,China) |
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Abstract In this paper,the similarities and differences of numbers of water inrush in Dapingshan tunnel have been comprehensively studied in combination with site-specific geological tectonic environment,rock lithology,and hydrogeological environment in Wudang nappe structure belts. The effect of nappe belts on water inrush,the controlling effect on reservoir structure,and the hydrogeological environment associated with construction condition have been considered to analyze the mechanism of karst water inrush. On basis of the conclusion,a risk assessment model has been established considering five risk-evaluation geological factors. Fuzzy optimum theory was used to screen the optimum combination of geo-environments which are most dominant factors to potentially inducing karst water inrush. In addition,the risk mitigation method in terms of the key point of geo-environmental risk assessment associated with comprehensive geophysical method was put forward,and the site-specific construction conditions on working face were used to verify its rationality. Results show that the risk prediction method proposed can play an important role in risk mitigation in karst tunnel. In addition,the conclusion mentioned above also shows that geological analysis as the core in comprehensive geophysical prospecting method is the main focus of geological forecast in terms of risk mitigation.
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Received: 20 May 2013
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| [1] 刘新荣,张旭东,黄 明,等. 深埋隧道填充型溶腔溃水机制及风险识别[J]. 重庆大学学报,2012,35(7):28–34.(LIU Xinrong,ZHANG Xudong,HUANG Ming,et al. Feature and risk identification of super karst water burst in deeply buried karst tunnel[J]. Journal of Chongqing University,2012,35(7):28–34.(in Chinese))
[2] 刘招伟,何满潮,王树仁. 圆梁山隧道岩溶突水机制及防治对策研究[J]. 岩土力学,2006,27(2):228–232.(LIU Zhaowei,HE Manchao,WANG Shuren. Study on karst water inrush mechanism and prevention countermeasures in Yuanliangshan tunnel[J]. Rock and Soil Mechanics,2006,27(2):228–232.(in Chinese))
[3] 戎 凯,曹大明,王荣劲. 长凼子隧道岩溶突水、突泥特征及控制因素分析[J]. 现代隧道技术,2010,47(5):26–31.(RONG Kai,CAO Daming,WANG Rongjin. Analysis of control factors for water inrush and mud gushing in Changdangzi karst tunnel[J]. Modern Tunnelling Technology,2010,47(5):26–31.(in Chinese))
[4] 匡 星,白明洲,王成亮,等. 基于模糊评价方法的隧道岩溶突水地质灾害综合预警方法[J]. 公路交通科技,2010,27(11):100–103. (KUANG Xing,BAI Mingzhou,WANG Chengliang,et al. Research of comprehensive warning of water inrush hazards in karst tunnel based on fuzzy evaluation method[J]. Journal of Highway and Transportation Research and Development,2010,27(11):100–103.(in Chinese))
[5] 蒋国云. 深埋隧道岩溶突水安全风险评价模型研究[J]. 地下空间与工程学报,2012,8(2):274–279.(JIANG Guoyun. Study on the security risk assessment model of karst water burst in deep buried tunnel[J]. Chinese Journal of Underground Space and Engineering,2012,8(2):274–279.(in Chinese))
[6] 周宗青,李术才,李利平,等. 岩溶隧道突涌水危险性评价的属性识别模型及其工程应用[J]. 岩土力学,2013,34(3):818–826. (ZHOU Zongqing,LI Shucai,LI Liping,et al. Attribute recognition model of fatalness assessment of water inrush in karst tunnels and its application[J]. Rock and Soil Mechanics,2013,34(3):818–826.(in Chinese))
[7] 薛翊国,李术才,苏茂鑫,等. 隧道施工期超前地质预报实施方法研究[J]. 岩土力学,2011,32(8):2 416–2 422.(XUE Yiguo,LI Shucai,SU Maoxin,et al. Study of geological prediction implementation method in tunnel construction[J]. Rock and Soil Mechanics,2011,32(8):2 416–2 422.(in Chinese))
[8] 葛颜慧,李术才,张庆松,等. 基于风险评价的岩溶隧道综合超前地质预报技术研究[J]. 岩土工程学报,2010,32(7):1 124–1 130. (GE Yanhui,LI Shucai,ZHANG Qingsong,et al. Comprehensive geological prediction based on risk evaluation during tunneling in karst area[J]. Chinese Journal of Geotechnical Engineering,2010,32(7):1 124–1 130.(in Chinese))
[9] 白名洲,许兆义,王连俊,等. 深埋隧道岩溶突水灾害的地质条件研究[J]. 铁道工程学报,2006,6(3):21–24.(BAI Mingzhou,XU Zhaoyi,WANG Lianjun,et al. Research on the geological condition of karst water bursting disaster in the course of tunnel caving[J]. Journal of Railway Engineering Society,2006,6(3):21–24.(in Chinese))
[10] 湖北省交通规划设计院. 大坪山隧道施工设计图[R]. 武汉:湖北省交通规划设计院,2010.(Hubei Communications Planning and Design Institute. Design drawings of Dapingshan tunnel[R]. Wuhan:Hubei Communications Planning and Design Institute,2010.(in Chinese))
[11] 王树仁,何满潮,刘招伟. 岩溶隧道突水灾变过程分析及控制技术[J]. 北京科技大学学报,2006,28(7):613–618.(WANG Shuren,HE Manchao,LIU Zhaowei. Analysis of the process of water inrush catastrophe and its prevention countermeasures in a karst tunnel[J]. Journal of Beijing University of Science and Technology,2006,28(7):613–618.(in Chinese))
[12] 中国科学院武汉岩土力学研究所. 麻竹高速V8电法探测解译报告[R]. 武汉:中国科学院武汉岩土力学研究所,2008.(Institute of rock and soil mechanics,Chinese academy of sciences: V8 electrical method detection report interpretation of Macheng—Zhuxi high way[R]. Wuhan:Institute of rock and soil mechanics,Chinese Academy of Sciences,2008.(in Chinese))
[13] 杨 兵. 宜万铁路马鹿箐隧道岩溶灾害的工程处治技术[J]. 地下空间与工程学报,2011,7(3):581–586.(YANG Bing. Treatment techniques for karst disaster of Maluqing tunnel on Yichang—Wanzhou Railway[J]. Chinese Journal of Underground Space and Engineering,2011,7(3):581–586.(in Chinese)) |
| [1] |
MAO Yuting1, 2, HE Manchao1, 2, LIU Fangzhou3, BAI Xing4, YANG Xiaojie1, 2, TAO Zhigang1, 2*. Development and application of a large-scale physical model system for tunnel creep testing[J]. , 2026, 45(6): 1627-1638. |
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2014, Vol. 33 
