隧道围岩压力缓释理念与减阻耗能支护控制研究——以巧家隧道为例

doi:10.3973/j.issn.2096-4498.2025.S2.027

隧道建设（中英文） ›› 2025, Vol. 45 ›› Issue (S2): 302-312.DOI: 10.3973/j.issn.2096-4498.2025.S2.027

隧道围岩压力缓释理念与减阻耗能支护控制研究——以巧家隧道为例

康剑锋¹，李守仁^{2， *}，谢雄耀²

（1. 中铁第四勘察设计院集团有限公司，湖北武汉 430063； 2. 同济大学地下建筑与工程系, 上海 200092）

出版日期:2025-12-20 发布日期:2025-12-20
作者简介:康剑锋（1981—），男，湖南新化人，2005年毕业于中南大学，土木工程专业，本科，正高级工程师，主要从事工程经济工作。E-mail： 50288516@qq.com。*通信作者：李守仁， E-mail： 15801760042@163.com。

Gradual-Pressure-Relief Concept for Tunnel Surrounding Rock and Resistance-Reducing Energy-Dissipating Support Control: A Case Study of Qiaojia Tunnel

KANG Jianfeng¹, LI Shouren^{2, *}, XIE Xiongyao²

(1. China Railway Siyuan Survey and Design Group Co., Ltd., Wuhan 430063, Hubei, China; 2. Department of Geotechnical Engineering, Tongji University, Shanghai 200092, China)

Online:2025-12-20 Published:2025-12-20

摘要/Abstract

摘要： 为解决隧道穿越高地应力软弱破碎岩层时易发生的大变形灾害，提出一种以收敛-约束法为核心的压力缓释控制理念进行针对性控制，设计具备“刚—缓释—刚”力学特性的减阻耗能支护结构，采用室内试验、现场监测和现场试验等多种研究手段对巧家隧道缓倾偏压大变形灾害开展综合研究。主要结论如下： 1）压力缓释控制理念既赋予了支护结构较高的延性，又确保了变形过程中围岩的径向不平衡力始终较低、能够起到减缓围岩变形速率的目的，有利于减弱开挖支护对深层围岩的扰动； 2）减阻耗能元件通过折线形钢板的弯折屈服来吸收外部能量，单轴压缩试验结果表明该结构具备良好的变形能力和“缓释”力学性能，通过调整折线形钢板的厚度与间距即可满足不同隧道支护力需求； 3）减阻耗能支护施作后，隧道左、右拱肩差异变形量减小66.7%，左拱肩、拱顶、右拱肩的峰值围岩压力相较于刚性支护分别减少28.8%、13.8%、54.5%，左、右拱肩峰值围岩压力差减少72.6%，围岩偏压大变形问题得到了有效的控制。

关键词: 隧道工程, 压力缓释控制, 减阻耗能支护, 偏压地层

Abstract: Weak and fractured rock masses with high in-situ stress are prone to large deformation when tunnels pass through. To address this issue, a gradual-pressure-relief control concept, centering on the convergence-confinement method, is proposed. A resistance-reducing energy-dissipating support structure with a "stiff-gradual relief-stiff" mechanical characteristic is designed. A comprehensive study on the large deformation disaster of the Qiaojia tunnel under gently inclined and asymmetrical pressure is conducted using multiple research methods, including laboratory tests, field monitoring, and in-situ tests. Conclusions are drawn as follows: (1) The gradual-pressure-relief control concept not only endows the support structure with high ductility, but also ensures consistently low radial unbalanced forces within the surrounding rock during deformation. This effectively slows down the deformation rate, reduces disturbances to the deeper surrounding rock caused by excavation and support operations, and enhances overall stability. (2) The resistance-reduction and energy-dissipation components absorbs external energy through the bending yield of corrugated steel plates. Uniaxial compression tests demonstrate that the structure possesses excellent deformation capacity and gradual-relief mechanical performance. By adjusting the thickness and spacing of the zigzag-shaped steel plates, the support system can meet varying requirements for tunnel support resistance. (3) After implementing the resistance-reducing and energy-dissipating support system, the difference deformation of left and right arch shoulders in the tunnel is reduced by 66.7%, the peak surrounding rock pressures at the left arch shoulder, crown, and right arch shoulder decrease by 28.8%, 13.8%, and 54.5%, respectively, compared to rigid support. Additionally, the difference in peak pressures between the left and right arch shoulders is reduced by 72.6%. These demonstrate that the large deformation of asymmetrical-pressurized rock has been effectively controlled.

Key words: tunnel engineering, gradual-pressure-relief control, resistance-reducing energy-dissipating support, asymmetrical-pressurized strata

康剑锋, 李守仁, 谢雄耀. 隧道围岩压力缓释理念与减阻耗能支护控制研究——以巧家隧道为例[J]. 隧道建设, 2025, 45(S2): 302-312.

KANG Jianfeng, LI Shouren, XIE Xiongyao. Gradual-Pressure-Relief Concept for Tunnel Surrounding Rock and Resistance-Reducing Energy-Dissipating Support Control: A Case Study of Qiaojia Tunnel[J]. Tunnel Construction, 2025, 45(S2): 302-312.

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隧道围岩压力缓释理念与减阻耗能支护控制研究——以巧家隧道为例

Gradual-Pressure-Relief Concept for Tunnel Surrounding Rock and Resistance-Reducing Energy-Dissipating Support Control: A Case Study of Qiaojia Tunnel

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