Development and application of a model test device for active fault tunnel crossing complex fault under high in-situ stress environment
CUI Zhen1,ZHANG Jiawei1,2,SHENG Qian1,MA Yalina1,3,ZHOU Guangxin1,4,YAN Tianyou5,LI Jianhe5
(1. State Key Laboratory of Geomechanics and Geotechnical Engineering,Institute of Rock and Soil Mechanics,Chinese Academy of Sciences,Wuhan,Hubei 430071,China;2. School of Civil Engineering and Architecture,Wuhan Polytechnic University,Wuhan,Hubei 430023,China;3. CCCC Second Highway Consultant Co.,Ltd.,Wuhan,Hubei 430056,China;5. Nanchang Water Authority,Nanchang,Jiangxi 330000,China;5. Changjiang Institute of Survey,Planning,Design and Research Co.,Ltd.,
Wuhan,Hubei 430010,China)
Abstract:When active faults experience tectonic movements,tunnels crossing these active faults will undergo varying degrees of structural damage and failure. Existing experimental setups that simulate the fault displacement of tunnels crossing active faults are mostly designed for shallow-buried tunnels and do not consider deep-seated stress conditions. This limitation has impacted the applicability of their test results to deep-buried,high-stress tunnel projects. Given this,the development of an experimental apparatus capable of simulating complex fault-displacement mechanisms under high in-situ stress conditions becomes a crucial component. This study,in conjunction with the characteristics of large lifeline projects crossing active faults in the strong seismic zone of western China,determined the parameters required for the experimental apparatus. We have successfully developed this apparatus and utilized it to investigate the differences in lining damage characteristics between deep-buried and shallow-buried tunnels.The results show that:(1) tunnel structures crossing active fault zones in the strong seismic regions of western China exhibit features such as significant burial depth,high in-situ stress,and complex fault displacement. Consequently,the design parameters for the experimental apparatus were determined,including a confinement pressure of 0.8 MPa,a horizontal fault offset of 20 cm,and a vertical fault offset of 10 cm. (2) By conducting free-field and tunnel model fault-displacement experiments,it was confirmed that the equipment can effectively simulate pure strike-slip,dip-slip,and strike-slip/dip-slip-coupled fault movements. Moreover,it was observed that the confining pressure remains stable during the fault movement process,thereby achieving the objectives of this research and equipment development. (3) The tunnel fault-displacement tests yielded the following outcomes:Deep-buried tunnels exhibited significant compressive deformation,resulting in larger areas of damage. Shallow-buried tunnels,on the other hand,experienced shearing at the fault zone,leading to more severe structural damage. Moreover,when the fault was oriented at a small angle to the tunnel axis,the level of damage to the tunnel increased. The development of this equipment provides a crucial foundation for investigating the impact of complex fault mechanisms on tunnels crossing active faults in high-stress environments.
崔 臻1,张佳威1,2,盛 谦1,马亚丽娜1,3,周光新1,4,颜天佑5,李建贺5. 高应力环境下复杂错断机制隧道模型试验装置的研制与应用[J]. 岩石力学与工程学报, 0, (): 811-811.
CUI Zhen1,ZHANG Jiawei1,2,SHENG Qian1,MA Yalina1,3,ZHOU Guangxin1,4,YAN Tianyou5,LI Jianhe5. Development and application of a model test device for active fault tunnel crossing complex fault under high in-situ stress environment. , 0, (): 811-811.
