考虑支护要素承载特性的围岩变形控制研究

姚志雄; 周岐窗; 郑国文

doi:10.20174/j.JUSE.2025.01.26

地下空间与工程学报 >

2025 , Vol. 21 >Issue 1: 236 - 246

DOI: https://doi.org/10.20174/j.JUSE.2025.01.26

设计、施工、监测

考虑支护要素承载特性的围岩变形控制研究

姚志雄 ,
周岐窗 ,
郑国文

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1.地下工程福建省高校重点实验室,福州 350118;
2.福建省土木工程新技术与信息化重点实验室, 福州 350118;
3.中建一局集团第一建筑有限公司,上海 201210;
4.中铁二十四局集团福建铁路建设有限公司,福州 351111

姚志雄(1978—),男,福建莆田人,博士,教授、硕士生导师,主要从事隧道及地下岩土工程等领域的教学与科研工作。E-mail:3113993@qq.com

收稿日期: 2024-07-15

网络出版日期: 2025-03-12

基金资助

国家自然科学基金(51504070);福建省自然科学基金(2021J011061);中铁二十四局集团有限公司重点科研项目(GY-H-23213)

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Research on Deformation Control of Surrounding Rock Considering the Bearing Characteristics of Supporting Elements

Yao Zhixiong ,
Zhou Qichuang ,
Zheng Guowen

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1. Key Laboratory of Underground Engineering, Fujian University of Technology, Fuzhou 350118, P.R. China;
2. Fujian Provincial Key Laboratory of Advanced Technology and Informatization in Civil Engineering, Fuzhou 350118, P.R. China;
3. The First Construction Co., Ltd., China Construction First Group, Shanghai 201210, P.R. China;
4. China Railway 24th Bureau Group Fujian Railway Construction Co., Ltd., Fuzhou 351111, P.R. China

Received date: 2024-07-15

Online published: 2025-03-12

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摘要

为探讨支护承载及变形控制特性,基于综合考虑钢拱架、喷射混凝土、超前加固等支护承载特性的支护-围岩耦合作用力学模型,构建了5种计算类型共35种工况,并结合某工程算例详尽分析不同支护形式、支护刚度及支护时机等对围岩变形的影响规律。结果表明:隧道支护对掌子面前后方围岩变形具有较好控制作用,超前支护+初期支护的联合支护效果更佳,且这种控制具有空间效应;单一支护或多种支护协调的联合支护均可达到相同的变形控制效果,这取决于各支护要素的刚度匹配;钢拱架作为一种刚性的能立即、主动承担荷载的支护结构,在分担压力、控制变形方面较喷射混凝土更具优势,超前支护+钢拱架的联合支护效率更高。支护越早施作,围岩变形越早进入可控状态,效果越佳;有超前支护作用,围岩变形对支护时机的敏感性相对较低,因此针对复杂隧道工程,提前施作超前支护是弥补初期支护施作不到位、降低施工风险的重要措施。本研究从理论上阐明了支护结构之间合理的刚度匹配性是应力协调、围岩稳定的关键。

关键词： 隧道工程; 钢拱架; 围岩变形特性; 联合支护; 支护时机

本文引用格式

姚志雄 , 周岐窗 , 郑国文 . 考虑支护要素承载特性的围岩变形控制研究[J]. 地下空间与工程学报, 2025 , 21(1) : 236 -246 . DOI: 10.20174/j.JUSE.2025.01.26

Abstract

To explore the characteristics of support bearing and deformation control, a mechanical model for the coupling effect of support and surrounding rock was constructed based on comprehensive consideration of support bearing characteristics such as steel arch frame, sprayed concrete, and advanced reinforcement. A total of 35 working conditions were constructed for 5 calculation types, and the influence of different support forms, support stiffness, and support timing on the deformation of surrounding rock was detailed analyzed based on a certain engineering example. The results showed tunnel support has a good control effect on the deformation of the surrounding rock in front of and behind the palm, and the combined support effect of advanced support and initial support is better, and this control has a spatial effect. A single support or a coordinated combination of multiple supports can achieve the same deformation control effect, depending on the stiffness matching of each support element. Steel arch frame, as a rigid support structure that can immediately and actively bear loads, has more advantages than sprayed concrete in bearing loads and controlling deformation. The combined support efficiency of advanced support and steel arch frame is higher. The earlier the support is applied, the earlier the deformation of the surrounding rock enters a controllable state, and the better the effect. With advanced support, the sensitivity of surrounding rock deformation to support timing is relatively low. Therefore, for complex tunnel projects, early implementation of advanced support is an important measure to compensate for inadequate initial support and reduce construction risks. This study theoretically clarified that reasonable stiffness matching between supporting structures is the key to achieve stress coordination and tunnel structure stability.

Key words： tunneling; steel arch frame; deformation characteristics of surrounding rock; combined support; supporting time

参考文献

[1] 张顶立.隧道及地下工程的基本问题及其研究进展[J]. 力学学报,2017,49(1):3-21. (Zhang Dingli. Essential issues and their research progress in tunnel and underground engineering[J]. Chinese Journal of Theoretical and Applied Mechanics,2017,49(1):3-21. (in Chinese))
[2] 周辉,高阳,张传庆,等.考虑围岩衬砌相互作用的钢筋混凝土衬砌数值模拟[J]. 水利学报,2016,47(6):763-771. (Zhou Hui, Gao Yang, Zhang Chuanqing, et al. Numerical simulation of reinforced concrete lining considering the interaction with the surrounding rock[J]. Journal of Hydraulic Engineering, 2016,47(6):763-771. (in Chinese))
[3] 王永刚,丁文其,刘志强,等.木寨岭隧道大变形分级标准与支护时机研究[J]. 地下空间与工程学报,2020,16(4):1116-1122. (Wang Yonggang, Ding Wenqi, Liu Zhiqiang, et al. Classification standard of large deformation and construction time of second lining in muzhailing tunnel [J]. Chinese Journal of Underground Space and Engineering,2020,16(4):1116-1122. (in Chinese))
[4] 田大鹏.杨林隧道围岩支护相互作用时效性规律研究[J]. 地下空间与工程学报,2021,17(增2):616-622.( Tian Dapeng. Study on the aging law of the interaction of surrounding rock and support in yanglin tunnel [J]. Chinese Journal of Underground Space and Engineering,2021,17(Supp.2):616-622. (in Chinese))
[5] 于丽,蔡闽金.郑万高铁隧道大型机械化配套全断面法施工围岩-支护结构相互作用力学特性研究[J]. 隧道建设(中英文),2018,38(8):1316-1323.( Yu Li, Cai Minjin. Study of mechanical properties of interaction between surrounding rock and supporting structure of Zhengzhou-Wanzhou high-speed railway tunnel constructed by full-section method with large-scale machinery[J]. Tunnel Construction,2018,38(8):1316-1323. (in Chinese))
[6] 杜建明,房倩,程荔琼,等.围岩-支护结构时效性共同作用下运营隧道服役特性[J]. 中南大学学报(自然科学版),2022,53(10):4001-4011.( Du Jianming, Fang Qian, Cheng Liqiong, et al. Service characteristics of operational tunnel under combined action of time effects of surrounding rock and supporting structure[J]. Journal of Central South University (Science and Technology),2022,53(10):4001-4011. (in Chinese))
[7] 张顶立,孙振宇.复杂隧道围岩结构稳定性及其控制[J]. 水力发电学报,2018,37(2):1-11.( Zhang Dingli, Sun Zhenyu. Structural stability of complex tunnel surrounding rock and its control [J]. Journal of Hydroelectric Engineering, 2018,37(2):1-11. (in Chinese))
[8] 孙振宇,张顶立,房倩,等.隧道初期支护与围岩相互作用的时空演化特性[J]. 岩石力学与工程学报,2017,36(增2):3943-3956.( Sun Zhenyu, Zhang Dingli, Fang Qian, et al. Spatial and temporal evolution characteristics of interaction between primary support and tunnel surrounding rock[J]. Chinese Journal of Rock Mechanics and Engineering,2017,36(Supp.2):3943-3956. (in Chinese))
[9] 王志龙,王明年,严志伟,等.考虑超前支护作用效应的围岩-支护相互作用机制研究[J]. 隧道建设(中英文),2021,41(10): 1748-1755.( Wang Zhilong, Wang Mingnian, Yan Zhiwei, et al. Surrounding rock-support interaction mechanism considering effect of tunnel advance supports[J]. Tunnel Construction, 2021,41(10):1748-1755. (in Chinese))
[10] 董建华,徐斌,吴晓磊,等.隧道分级让压支护作用下围岩弹塑性变形全过程解析[J]. 岩土力学,2022,43(8):2123-2135. (Dong Jianhua, Xu Bin, Wu Xiaolei, et al. Elastic-plastic deformation of surrounding rocks under graded yielding support of tunnel[J]. Rock and Soil Mechanics,2022,43(8):2123-2135. (in Chinese))
[11] 保其长,彭守拙,钟建文,等.均质围岩灌浆锚杆应力的近似解析解[J]. 水力发电学报,2019,38(11):102-111. (Bao Qichang, Peng Shouzhuo, Zhong Jianwen, et al. Approximate analytical solution of grouted bolt stress in homogeneous rock mass[J]. Journal of Hydroelectric Engineering,2019,38(11):102-111. (in Chinese))
[12] 夏才初,徐晨,杜时贵.考虑应力路径的深埋隧道黏弹-塑性围岩与支护相互作用[J]. 岩石力学与工程学报,2021,40(9):1789-1802. (Xia Caichu, Xu Chen, Du Shigui. Interaction between viscoelastic-plastic surrounding rock and support structure in deep tunnels considering stress path[J]. Chinese Journal of Rock Mechanics and Engineering,2021,40(9):1789-1802. (in Chinese))
[13] 田四明,吴克非,刘大刚,等.软弱围岩隧道变形控制主动支护理念及技术[J]. 铁道学报,2021,43(6):158-164. (Tian Siming, Wu Kefei, Liu Dagang, et al. Study on active support technology for deformation control of tunnels in soft surrounding rock[J]. Journal of the China Railway Society,2021,43(6):158-164. (in Chinese))
[14] 张顶立,孙振宇,陶伟明. 隧道围岩大变形灾害特点与主动控制方法[J]. 铁道标准设计, 2023, 67(1):1-9. (Zhang Dingli, Sun Zhenyu, Tao Weiming. Characteristics and active control methods of large deformation disaster of tunnel surrounding rock[J]. Railway Standard Design, 2023, 67(1):1-9. (in Chinese))
[15] 孟陆波,黄意霖,李天斌,等.高地应力层状软岩隧道非对称挤压大变形分级修正方法研究[J]. 岩石力学与工程学报,2022,41(1):147-156. (Meng Lubo, Huang Yilin, Li Tianbin, et al. An improved classification method of asymmetrical squeezing large deformation of layered soft rock tunnels under high geo-stresses[J]. Chinese Journal of Rock Mechanics and Engineering, 2022,41(1):147-156. (in Chinese))
[16] Tao Z, Cao J, Yang L, et al. Study on deformation mechanism and support measures of soft surrounding rock in Muzhailing deep tunnel[J]. Advances in Civil Engineering, 2020, 2:1-14.
[17] 潘文韬,何川,吴枋胤,等.层状软岩隧道超前支护及锚杆定向预加固研究[J]. 地下空间与工程学报, 2023, 19(2): 571-585. (Pan Wentao, He Chuan, Wu Fangyin, et al. Study on advanced support and anchor directional prerein for cement of layered soft rock tunnel[J]. Chinese Journal of Underground Space and Engineering, 2023, 19(2): 571-585. (in Chinese))
[18] 姚志雄,刘耀星,张忠星,等.四孔小净距隧道浅埋下穿高速公路施工力学特性[J]. 地下空间与工程学报,2022,18(6):2052-2061. (Yao Zhixiong,Liu Yaoxing,Zhang Zhongxing, et al. Study on mechanical characteristics of shallow buried four-hole tunnel with small distance through expressway[J]. Chinese Journal of Underground Space and engineering,2022,18(6):2052-2061. (in Chinese))
[19] 孙钧. 岩石流变力学及其工程应用研究的若干进展[J]. 岩石力学与工程学报, 2007, 26(6):1081-1106.( Sun Jun. Rock rheological mechanics and its advance in engineering applications[J]. Chinese Journal of Rock Mechanics and Engineering, 2007, 26(6): 1081-1106. (in Chinese))
[20] Kargar A R, Haghgouei H, Babanouri N. Time-dependent analysis of stress components around lined tunnels with circular configuration considering tunnel advancing rate effects[J]. International Journal of Rock Mechanics and Mining Sciences, 2020, 133: 104422.
[21] Kargar A R, Haghgouei H. An analytical solution for time-dependent stress field of lined circular tunnels using complex potential functions in a stepwise procedure[J]. Applied Mathematical Modelling, 2020, 77: 1625-1642.
[22] Lin L B, Lu Y P, Chen F Q, et al. Complex variable solutions for twin tunnelling at great depth in viscoelastic geomaterial considering the three-dimensional effects of tunnel faces[J]. Applied Mathematical Modelling, 2021, 89: 919-951.
[23] Carranza-Torres C, Fairhurst C. The elasto-plastic response of underground excavations in rock masses that satisfy the Hoke-Brown failure criterion [J]. International Journal of Rock Mechanics and Mining Sciences, 1999, 36 (6): 777-809.
[24] Chern J C, Shiao F Y, Yu C W. An empirical safety criterion for tunnel construction[A]//In: Regional Symposium on Sedimentary Rock Engineering[C]. Taiwan, China, 1998: 222-227.
[25] 侯公羽.基于开挖面空间效应的围岩-支护相互作用机制[J]. 岩石力学与工程学报,2011,30(增1):2871-2877.( Hou Gongyu. Interaction mechanism between surrounding rock and support based on spatial effect of excavation face[J]. Chinese Journal of Rock Mechanics and Engineering,2011,30(Supp.1):2871-2877. (in Chinese))
[26] Ranjbarnia M, Rahimpour N, Oreste P. A simple analytical approach to simulate the arch umbrella supporting system in deep tunnels based on convergence confinement method[J]. Tunnelling and Underground Space Technology incorporating Trenchless Technology Research, 2018, 82: 39-49.

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