基坑开挖引起下穿交叉隧道变形效应分析

谢强; 马瑗婕; 吴俊; 薛孝强; 涂正楠

doi:10.20174/j.JUSE.2024.05.26

地下空间与工程学报 >

2024 , Vol. 20 >Issue 5: 1695 - 1705

DOI: https://doi.org/10.20174/j.JUSE.2024.05.26

防灾与环境

基坑开挖引起下穿交叉隧道变形效应分析

谢强 ,
马瑗婕 ,
吴俊 ,
薛孝强 ,
涂正楠

展开

1.重庆大学土木工程学院,重庆 400045;
2.库区环境地质灾害防治国家地方联合工程研究中心(重庆),重庆 400045;
3.中电建华东勘测设计研究院(郑州)有限公司,郑州 450003;
4.浙江江南工程管理股份有限公司,杭州 310013

谢强(1975—),男,重庆人,博士,教授,主要从事岩土工程、地下工程等领域的教学与科研工作。E-mail:xieqiang2000@163.com

涂正楠(1998—),男,重庆人,博士生,主要从事岩土工程领域的研究工作。E-mail:tutu98tutu98@gmail.com

收稿日期: 2024-02-07

网络出版日期: 2024-10-31

基金资助

浙江省建设科研项目(2021K121);重庆市地质灾害防治中心科技项目(KJ2021050);重庆市规划和自然资源局科研项目(DK2021Z05null01C)

收起

Analysis of Deformation Effect of Underpass Cross Tunnel Caused by Foundation Pit Excavation

Xie Qiang ,
Ma Yuanjie ,
Wu Jun ,
Xue Xiaoqiang ,
Tu Zhengnan

Expand

1. School of Civil Engineering, Chongqing University, Chongqing 400045, P.R. China;
2. National Joint Engineering Research Center of Geohazards Prevention Areas (Chongqing), Chongqing 400045, P.R. China;
3. Power Construction East China Survey and Design Institute (Zhengzhou) Co., Ltd., Zhengzhou, 450003, P.R. China;
4. Zhejiang Jiangnan Engineering Management Co., Ltd., Hangzhou, 310013, P.R. China

Received date: 2024-02-07

Online published: 2024-10-31

Fold

摘要

以某地铁站换乘大厅工程为例,利用FLAC^3D数值模拟软件,分析总结了上跨深大基坑开挖对不同空间距离和分布形式的下穿立体交叉隧道的变形影响规律,并结合现场监测数据与数值模拟结果进行相互验证,结果表明:(1)基坑开挖卸荷对下穿隧道结构变形的影响主要表现为竖向位移,其变形量与基坑的空间位置和基坑岩土体开挖卸荷量密切相关;(2)1号线左、右线隧道全施工周期监测数据与数值模拟结果吻合较好,验证了数值计算方法对施工活动影响判断的准确性;(3)多种应力状态耦合的叠落隧道竖向位移受叠加效应影响显著,最大竖向位移位于影响因素较多的区域,最大竖向位移值为34.84 mm;(4)埋深较浅隧道对施工扰动比深埋隧道更加敏感,不同位置处的变形离散性更强,变形具有一定的整体性和协同性。

关键词： 基坑开挖; 立体交叉隧道; 数值模拟; 接近施工

本文引用格式

谢强 , 马瑗婕 , 吴俊 , 薛孝强 , 涂正楠 . 基坑开挖引起下穿交叉隧道变形效应分析[J]. 地下空间与工程学报, 2024 , 20(5) : 1695 -1705 . DOI: 10.20174/j.JUSE.2024.05.26

Abstract

Taking the transfer hall project of a subway station as an example, FLAC^3D numerical simulation software was used to analyze and summarize the influence law of the excavation of the deep excavation of the upper span on the deformation of the underpass three-dimensional cross tunnel with different spatial distances and distribution forms. Combined with the field monitoring data and the mutual verification of the numerical simulation results, the results showed that: (1) The effect of excavation unloading on the structural deformation of the tunnel is mainly manifested as vertical displacement, and its deformation is closely related to the spatial position of the foundation pit and the unloading amount of the rock-soil mass of the foundation pit; (2) The monitoring data of the whole construction cycle of the left and right tunnels of Line 1 are in good agreement with the numerical simulation results, which verifies the accuracy of the judgment of the influence of the numerical calculation method on construction activities; (3) The vertical displacement of the cascade tunnel coupled with multiple stress states is significantly affected by superposition effect, and the maximum vertical displacement is located in the area with many influencing factors, and the maximum vertical displacement is 34.84 mm; (4) Tunnels with shallow burial depth are more sensitive to construction disturbance than those with deep burial depth. The deformation dispersion at different locations is stronger, and the deformation has certain integrity and coordination.

Key words： foundation pit excavation; three-dimensional cross tunnel; numerical simulation; approaching construction

参考文献

[1] 王明年, 胡萧越, 唐雄俊, 等. 大直径盾构铁路隧道火灾温度荷载及结构内力特性研究[J]. 现代隧道技术, 2021, 58(1): 1-9. (Wang Mingnian, Hu Xiaoyue, Tang Xiongjun, et al. Research on fire temperature loading and structural internal force characteristics of large diameter shield railroad tunnel[J]. Modern Tunneling Technology, 2021, 58(1): 1-9. (in Chinese))
[2] 袁运涛, 李苏春. 临近地铁车站深基坑开挖综合控制研究[J]. 地下空间与工程学报, 2013, 9(4): 843-847. (Yuan Yuntao, Li Suchun. Research on comprehensive control of deep foundation pit excavation near subway station[J]. Journal of Underground Space and Engineering, 2013, 9(4): 843-847. (in Chinese))
[3] 沈雯, 沈蓉, 孙廉威. 超深基坑分区开挖对侧方地铁影响的实测分析[J]. 地下空间与工程学报, 2019, 15(增1): 354-360. (Shen Wen, Shen Rong, Sun Lianwei. Measured analysis of the impact of ultra-deep foundation pit zoned excavation on lateral subway[J]. Journal of Underground Space and Engineering, 2019, 15(Supp.1): 354-360. (in Chinese))
[4] Sun H, Wu J, Zhang J, et al. Deformation analysis of a new subway transfer channel closely undercrossing an existing station[J]. Advances in Civil Engineering, 2023, 2023: 5668254.
[5] Yang M, Li H, Li N, et al. Influence of utility tunnel on the lower part of the existing double-track shield tunnel in loess soil[J]. Advances in Materials Science and Engineering, 2021, 2021: 9927245.
[6] Zeng L, Zhang D, Lian C, et al. Study on the influence of an under-crossing parallel double-line shield tunnel on the existing tunnel structure[J]. Mathematics, 2023, 11(14): 3125.
[7] 刘英男, 雷华阳, 马长远, 等. 近接既有隧道盾构开挖面三维稳定性分析[J]. 岩土工程学报, 2023, 45(7): 1374-1383. (Liu Yingnan, Lei Huayang, Ma Changyuan, et al. Three-dimensional stability analysis of shield excavation face in near-existing tunnels[J]. Journal of Geotechnical Engineering, 2023, 45(7): 1374-1383. (in Chinese))
[8] 邓旭, 郑虹, 宋昭煌, 等. 邻近新建地铁车站的深基坑工程的变形分析[J]. 地下空间与工程学报, 2018, 14(增1): 270-277. (Deng Xu, Zheng Hong, Song Zhaohuang, et al. Deformation analysis of deep foundation pit works adjacent to a new subway station[J]. Journal of Underground Space and Engineering, 2018, 14(Supp.1): 270-277. (in Chinese))
[9] Liang R, Xia T, Hong Y, et al. Effects of above-crossing tunnelling on the existing shield tunnels[J]. Tunnelling and Underground Space Technology, 2016, 58: 159-176.
[10] Liu B, Yu Z, Han Y, et al. Analytical solution for the response of an existing tunnel induced by above-crossing shield tunneling[J]. Computers and Geotechnics, 2020, 124: 103624.
[11] Zhang D M, Xie X C, Li Z L, et al. Simplified analysis method for predicting the influence of deep excavation on existing tunnels[J]. Computers and Geotechnics, 2020, 121: 103477.
[12] Meng F Y, Chen R P, Xie S W, et al. Excavation-induced arching effect below base level and responses of long-collinear underlying existing tunnel[J]. Tunnelling and Underground Space Technology, 2022, 123: 104417.
[13] 金雪峰. 某紧临地铁车站土岩基坑设计与变形规律研究[J]. 地下空间与工程学报, 2021, 17(3): 815-824, 871. (Jin Xuefeng. Research on the design and deformation pattern of soil and rock foundation pit in a subway station immediately adjacent to the subway[J]. Journal of Underground Space and Engineering, 2021, 17(3): 815-824, 871. (in Chinese))
[14] 魏宁, 姚爱军, 李鹏, 等. 超近距离基坑施工对交叠地铁的影响及响应[J]. 地下空间与工程学报, 2018, 14(4): 1056-1063. (Wei Ning, Yao Aijun, Li Peng, et al. Impact and response of ultra-close pit construction on overlapping subways[J]. Journal of Underground Space and Engineering, 2018, 14(4): 1056-1063. (in Chinese))
[15] 张宏伟, 李洋. 深圳地铁11号线土压平衡盾构近距离上跨既有1号线影响分析[J]. 铁道科学与工程学报, 2017, 14(3): 560-567. (Zhang Hongwei, Li Yang. Analysis of the impact of soil-pressure balanced shield close to crossing the existing Line 1 on Shenzhen Metro Line 11[J]. Journal of Railway Science and Engineering, 2017, 14(3): 560-567. (in Chinese))
[16] Lai H, Zheng H, Chen R, et al. Settlement behaviors of existing tunnel caused by obliquely under-crossing shield tunneling in close proximity with small intersection angle[J]. Tunnelling and Underground Space Technology, 2020, 97: 103258.
[17] 安永林, 李佳豪, 周进, 等. 上下立交隧道施工优化与动态近接分区[J]. 铁道科学与工程学报, 2022, 19(2): 470-479. (An Yonglin, Li Jiahao, Zhou Jin, et al. Construction optimization and dynamic proximity zoning of up-and-down overpass tunnels[J]. Journal of Railway Science and Engineering, 2022, 19(2): 470-479. (in Chinese))
[18] 沈良帅, 贺少辉. 复杂环境条件上跨下穿同一既有地铁隧道的变形控制分析及施工方案优化[J]. 岩石力学与工程学报, 2008(增1): 2893-2900. (Shen Liangshuai, He Shaohui. Deformation control analysis and construction scheme optimization of an existing subway tunnel under complex environmental conditions[J]. Journal of Rock Mechanics and Engineering, 2008(Supp.1): 2893-2900. (in Chinese))
[19] Wang P, Wu J, Song D, et al. A general framework for the impact of shield tunnel construction on existing tunnel in soil[J]. Sustainability, 2023, 15(12): 9226.
[20] Zhang Y, Tao L, Liu J, et al. Construction techniques and mechanical behavior of newly-built large-span tunnel ultra-short distance up-crossing the existing shield tunnel with oblique angle[J]. Tunnelling and Underground Space Technology, 2023, 138: 105162.
[21] 王威. 大断面隧道小净距上跨既有隧道施工方案优化[J]. 铁道建筑, 2023, 63(9): 85-90. (Wang Wei. Optimization of construction scheme for large section tunnel with small clear distance across existing tunnel[J]. Railway Construction, 2023, 63(9): 85-90. (in Chinese))
[22] 马凯伦, 董明礼, 曹义, 等. 两侧双基坑开挖对密贴地铁车站的影响研究[J]. 地下空间与工程学报, 2022, 18(增2): 1043-1048. (Ma Kailun, Dong Mingli, Cao Yi, et al. Study on the effect of double pit excavation on both sides on close-packed subway station[J]. Journal of Underground Space and Engineering, 2022, 18(Supp.2): 1043-1048. (in Chinese))
[23] 邢慧堂, 徐前卫, 刘浩, 等. 盾构近距离上跨既有隧道施工影响及控制研究[J]. 铁道工程学报, 2021, 38(9): 61-67. (Xing Huitang, Xu Qianwei, Liu Hao, et al. Study on the impact and control of shield tunnel construction in close proximity to and across existing tunnels[J]. Journal of Railway Engineering, 2021, 38(9): 61-67. (in Chinese))
[24] Yin M, Jiang H, Jiang Y, et al. Effect of the excavation clearance of an under-crossing shield tunnel on existing shield tunnels[J]. Tunnelling and Underground Space Technology, 2018, 78: 245-258.

Options

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献