Experimental study on the effect of flexible joints of a deep-buried tunnel across an active fault under high in-situ stress conditions

IF 8.2 1区 工程技术 Q1 ENGINEERING, CIVIL Underground Space Pub Date : 2024-05-31 DOI:10.1016/j.undsp.2024.02.005
Jiawei Zhang , Zhen Cui , Qian Sheng , Wanhua Zhao , Liang Song
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Abstract

During dislocation, a tunnel crossing the active fault will be damaged to varying degrees due to its permanent stratum displacement. Most previous studies did not consider the influence of the tunnel’s deep burial and the high in-situ stress, so the results were not entirely practical. In this paper, the necessity of solving the anti-dislocation problem of deep-buried tunnels is systemically discussed. Through the model test of tunnels across active faults, the differences in failures between deep-buried tunnels and shallow-buried tunnels were compared, and the dislocation test of deep-buried segmental tunnels was carried out to analyze the external stress change, lining strain, and failure mode of tunnels. The results are as follows: (1) The overall deformation of deep-buried and shallow-buried tunnels is both S-shaped. The failure mode of deep-buried tunnels is primarily characterized by shear and tensile failure, resulting in significant compressive deformation and a larger damaged area. In contrast, shallow-buried tunnels mainly experience shear failure, with the tunnel being sheared apart at the fault crossing, leading to more severe damage. (2) After the segmental structure design of the deep-buried tunnel, the “S” deformation pattern is transformed into a “ladder” pattern, and the strain of the tunnel and the peak stress of the external rock mass are reduced; therefore, damages are significantly mitigated. (3) Through the analysis of the distribution of cracks in the tunnel lining, it is found that the tunnel without a segmental structure design has suffered from penetrating failure and that cracks affect the entire lining. The cracks in a flexible segmental tunnel affect about 66.6% of the entire length of the tunnel, and cracks in a tunnel with a short segmental tunnel only affect about 33.3% of the entire length of the tunnel. Therefore, a deep-buried tunnel with a short segmental tunnel can yield a better anti-dislocation effect. (4) By comparing the shallow-buried segmental tunnel in previous studies, it is concluded that the shallow-buried segmental tunnel will also suffer from deformation outside the fault zone, while the damages to the deep-buried segmental tunnel are concentrated in the fault zone, so the anti-dislocation protection measures of the deep-buried tunnel shall be provided mainly in the fault zone. The results of the above study can provide theoretical reference and technical support for the design and reinforcement measures of the tunnel crossing active fault under high in-situ stress conditions.

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高原位应力条件下穿越活动断层的深埋隧道柔性接头效应的实验研究
在变位过程中,穿越活动断层的隧道会因地层永久位移而受到不同程度的破坏。以往的研究大多没有考虑隧道深埋和高原位应力的影响,因此研究结果并不完全切合实际。本文系统论述了解决深埋隧道抗位移问题的必要性。通过对穿越活动断层隧道的模型试验,比较了深埋隧道与浅埋隧道在破坏方面的差异,并对深埋节段隧道进行了抗错位试验,分析了隧道的外应力变化、衬砌应变和破坏模式。结果如下(1)深埋隧道和浅埋隧道的整体变形均呈 "S "形。深埋隧道的破坏模式主要表现为剪切破坏和拉伸破坏,因此压缩变形较大,破坏面积也较大。相比之下,浅埋隧道主要是剪切破坏,隧道在断层交汇处被剪开,导致更严重的破坏。(2)深埋隧道采用分段结构设计后,"S "型变形模式转变为 "阶梯 "型,隧道应变和外部岩体峰值应力降低,破坏程度明显减轻。(3) 通过对隧道衬砌裂缝分布的分析,发现未采用分段结构设计的隧道存在贯穿性破坏,裂缝影响整个衬砌。柔性分段隧道的裂缝约占整个隧道长度的 66.6%,而短分段隧道的裂缝仅占整个隧道长度的 33.3%。因此,采用短节段隧道的深埋隧道能产生更好的抗位移效果。(4)通过对比以往研究中的浅埋节理隧道,得出浅埋节理隧道在断层带外也会发生变形,而深埋节理隧道的破坏集中在断层带内,因此深埋隧道的抗脱位保护措施应主要在断层带内进行。上述研究结果可为高原位应力条件下隧道穿越活动断层的设计和加固措施提供理论参考和技术支持。
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来源期刊
Underground Space
Underground Space ENGINEERING, CIVIL-
CiteScore
10.20
自引率
14.10%
发文量
71
审稿时长
63 days
期刊介绍: Underground Space is an open access international journal without article processing charges (APC) committed to serving as a scientific forum for researchers and practitioners in the field of underground engineering. The journal welcomes manuscripts that deal with original theories, methods, technologies, and important applications throughout the life-cycle of underground projects, including planning, design, operation and maintenance, disaster prevention, and demolition. The journal is particularly interested in manuscripts related to the latest development of smart underground engineering from the perspectives of resilience, resources saving, environmental friendliness, humanity, and artificial intelligence. The manuscripts are expected to have significant innovation and potential impact in the field of underground engineering, and should have clear association with or application in underground projects.
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