基于盾构管片上浮控制的同步浆液初凝时间研究

周勋; 杨金秋; 韦生达; 曹江涛; 马龙祥

doi:10.20174/j.JUSE.2024.06.25

地下空间与工程学报 >

2024 , Vol. 20 >Issue 6: 1991 - 1999

DOI: https://doi.org/10.20174/j.JUSE.2024.06.25

设计、施工、监测

基于盾构管片上浮控制的同步浆液初凝时间研究

周勋 ,
杨金秋 ,
韦生达 ,
曹江涛 ,
马龙祥

展开

1.中交路桥建设有限公司,北京 100027;
2.成都轨道建设管理有限公司,成都 610041;
3.西南交通大学交通隧道工程教育部重点实验室,成都 610031

周勋(1983—),男,河北唐山人,高级工程师,从事地铁方面的研究与管理工作。E-mail:174600271@qq.com

马龙祥(1988—),男,成都人,博士,副教授,主要从事隧道与地下工程设计、施工、运维理论方向的研究。E-mail:malongxiang_swjtu@163.com

收稿日期: 2024-02-14

网络出版日期: 2025-01-03

基金资助

中交路桥建设有限公司科技项目(R110122H01185)

收起

Study on the Initial Setting Time of Simultaneous Slurry Based on Shield Tunnel Segment Floatation Control

Zhou Xun ,
Yang Jinqiu ,
Wei Shengda ,
Cao Jiangtao ,
Ma Longxiang

Expand

1. CCCC Road and Bridge Construction Co., Ltd., Beijing 100027, P. R. China;
2. Chengdu Railway Construction Management Co., Ltd., Chengdu 610041, P. R. China;
3. MOE Key Laboratory of Transportation Tunnel Engineering, Southwest Jiaotong University, Chengdu 610031, P. R. China

Received date: 2024-02-14

Online published: 2025-01-03

Fold

摘要

目前少有同步浆液初凝时间对盾构施工期管片上浮影响的定量研究,导致较难为各种施工情况提供合理的浆液初凝时间建议。鉴于此,笔者建立了考虑隧道埋深影响的盾构隧道施工上浮纵向解析模型,并基于同步浆液初凝时间与盾构管片纵向受浮力作用区段长度之间的关系,系统研究了中风化泥岩地层中盾构隧道施工期同步浆液合理初凝时间的选择问题,结果表明:浆液初凝时间对盾构隧道施工期的最终累积纵向性态指标有重要影响,表现为浆液初凝时间越长,上浮荷载引起的管片累积上浮量值、纵向弯矩及纵向剪力均越大,且随着浆液初凝时间的等间距增长,相应性态指标的增大量值会有一定幅度的增大;从盾构隧道施工上浮控制的角度看,同步浆液初凝时间与盾构平均掘进速度应具备一定的匹配关系,盾构平均掘进速度越快,合理的浆液初凝时间也应越短;通过配合比设计,将同步浆液初凝时间调整为约5 h后,依托工程施工上浮问题得到了明显改善。

关键词： 盾构隧道; 施工上浮; 同步注浆; 浆液初凝时间

本文引用格式

周勋 , 杨金秋 , 韦生达 , 曹江涛 , 马龙祥 . 基于盾构管片上浮控制的同步浆液初凝时间研究[J]. 地下空间与工程学报, 2024 , 20(6) : 1991 -1999 . DOI: 10.20174/j.JUSE.2024.06.25

Abstract

Currently, there is a little research on the impact of simultaneous slurry initial setting time on the buoyancy of tunnel lining during shield tunneling construction. This makes it difficult to provide reasonable recommendations for slurry initial setting time under various construction conditions. Therefore, a quantitative longitudinal analytical model considering the influence of tunnel depth on shield tunnel construction buoyancy has been established. Based on the relationship between simultaneous slurry initial setting time and the length of the section where the shield tunnel lining is affected by buoyancy, the proper selection of initial setting time for simultaneous slurry during the construction period in moderately weathered clayey formations was systematically studied. The results show that the initial setting time of the slurry has a significant impact on the final cumulative longitudinal behavior of the shield tunnel during the construction period. A longer initial setting time leads to greater cumulative uplift load, longitudinal bending moment, and longitudinal shear caused by buoyancy. Moreover, with an equidistant increase in the initial setting time, the magnitudes of these behavior indicators also increase to a certain extent. From the perspective of controlling buoyancy in shield tunnel construction, there should be a matching relationship between the simultaneous slurry initial setting time and the average excavation speed of the shield. Specifically, as the average excavation speed increases, the reasonable initial setting time should be shorter. By adjusting the simultaneous slurry initial setting time to approximately 5 hours through mix design, a significant improvement in the buoyancy problem during construction has been achieved.

Key words： shield tunnel; construction uplift; simultaneous grouting; initial setting time of slurry

参考文献

[1] 王新强, 晏启祥, 孙明辉, 等. 盾构隧道同步注浆对管片上浮的影响分析[J]. 铁道建筑, 2022, 62(2):118-122. (Wang Xinqiang, Yan Qixiang, Sun Minghui, et al. Influence of synchronous grouting on segment floating in shield tunnel[J]. Railway Construction, 2022, 62 (2): 118-122.(in Chinese))
[2] 李明宇, 吴龙骥, 赵世永, 等.盾构管片上浮量变化规律及简化算法研究[J]. 公路, 2021, 66(3): 337-341. (Li Mingyu, Wu Longji, Zhao Shiyong, et al. Research on the simplified calculation method of segment uplift of shield tunnel[J]. Highway, 2021, 66 (3): 337-341.(in Chinese))
[3] 肖明清, 封坤, 周子扬, 等. 盾构隧道施工期管片错台影响因素研究[J]. 岩土工程学报, 2022, 45(7): 1347-1356. (Xiao Mingqing, Feng Kun, Zhou Ziyang, et al. Study on the influencing factors for segment dislocation during shield tunnelling[J]. Chinese Journal of Geotechnical Engineering, 2022, 45(7): 1347-1356.(in Chinese))
[4] 付艳斌, 梅超, 卞跃威, 等. 考虑注浆填充率的大直径盾构管片上浮解析解与应用[J]. 中国公路学报, 2022, 35(11):171-179. (Fu Yanbin, Mei Chao, Bian Yuewei, et al. Analytical solution and application of large- diameter shield segment uplift considering the filling rate of grouting[J]. China Journal of Highway Transportation, 2022, 35 (11): 171-179.(in Chinese))
[5] 傅鹤林, 史越, 陈俐光, 等. 盾构隧道施工期管片上浮机理数值模拟研究[J]. 中外公路, 2019, 39(1):174-179.(Fu Helin, Shi Yue, Chen Liguang, et al. Numerical simulation study on the floating mechanism of segment during shield tunnel construction[J]. Journal of China & Foreign Highway, 2019, 39 (1): 174-179.(in Chinese))
[6] 胡辉, 张恒, 刘晓迪, 等. 泥岩地层盾构隧道施工管片上浮影响因素分析[J]. 公路, 2018, 63(12):312-318.(Hu Hui, Zhang Heng, Liu Xiaodi, et al. Analysis on influencing factors of segment floating in construction of shield tunnel in mudstone stratum[J]. Highway, 2018, 63 (12): 312-318.(in Chinese))
[7] 董赛帅, 杨平, 姜春阳, 等. 盾构隧道管片上浮机理与控制分析[J]. 地下空间与工程学报, 2016, 12(1):49-54.(Dong Saishuai, Yang Ping, Jiang Chunyang, et al. Analysis of mechanism and controls of segment floating of shield tunnels[J]. Chinese Journal of Underground Space and Engineering, 2016, 12 (1): 49-54.(in Chinese))
[8] 杨志勇, 杨星, 张长旺,等. 盾构管片上浮量理论计算模型及上浮控制措施研究[J]. 矿业科学学报, 2021, 6(5):591-597, 605.(Yang Zhiyong, Yang Xing, Zhang Changwang, et al. Research on theoretical calculation model of shield segments floating amount and floating control measures[J]. Journal of Mining Science and Technology, 2021, 6 (5): 591-597, 605.(in Chinese))
[9] 陈仁朋, 刘源, 刘声向,等. 盾构隧道管片施工期上浮特性[J]. 浙江大学学报:工学版, 2014, 48(6):1068-1074.(Chen Renpeng, Liu Yuan, Liu Shengxiang, et al. Characteristics of upward moving for lining during shield tunnelling construction[J]. Journal of Zhejiang University (Engineering Science), 2014, 48 (6): 1068-1074.(in Chinese))
[10] 吕乾乾, 周建军, 杨振兴, 等. 基于地基回弹因素的盾构隧道管片上浮预测[J].隧道建设(中英文), 2017, 37(增2):87-93.(Lü Qianqian, Zhou Jianjun, Yang Zhenxing, et al. Prediction of shield tunnel segment up-floating caused by formation rebound[J]. Tunnel Construction, 2017, 37 (Supp.2): 87-93.(in Chinese))
[11] 舒瑶, 季昌, 周顺华, 等. 考虑地层渗透性的盾构隧道施工期管片上浮预测[J]. 岩石力学与工程学报, 2017, 36(增1):3516-3524.(Shu Yao, Ji Chang, Zhou Shunhua, et al. Prediction for shield tunnel segment uplift considering the effect of stratum permeability[J]. Chinese Journal of Rock Mechanics and Engineering, 2017, 36 (Supp.1): 3516-3524.(in Chinese))
[12] 贾少东, 马杲宇, 王士民, 等. 考虑注浆压力的泥岩地层管片上浮特性与控制[J]. 铁道标准设计, 2022, 66(2):72-78.(Jia Shaodong, Ma Gaoyu, Wang Shimin, et al. Floating properties and control of segments in mudstone stratum considering grouting pressure[J]. Railway Standard Design, 2022, 66(2):72-78. (in Chinese))
[13] 施有志, 阮建凑, 林树枝, 等. 海底盾构隧道管片上浮分析及控制研究[J]. 地下空间与工程学报, 2022, 18(5):1665-1677.(Shi Youzhi, Ruan Jiancou, Lin Shuzhi, et al. Floating analysis and control of subsea shield tunnel segment[J]. Chinese Journal of Underground Space and Engineering, 2022, 18 (5): 1665-1677. (in Chinese))
[14] 叶飞. 软土盾构隧道施工期上浮机理分析及控制研究[D].上海:同济大学,2007.(Ye Fei. Analysis and control for upward movement of shield tunnel during construction[D]. Shanghai: Tongji University, 2007.(in Chinese))
[15] 李培楠,英旭,石来,等.基于CFD的盾构同步注浆填充扩散运动力学分析[J].地下空间与工程学报,2021,17(增1):126-132.(Li Pennan,Ying Xu,Shi Lai,et al.Hydrodynamics analysis on fill diffusion in shield synchronous grouting based on CFD[J].Chinese Journal of Underground Space and Engineering,2021,17(Supp.1):126-132.(in Chinese))
[16] 李涛,王颖轶,黄醒春.基于冲击映像法盾构同步注浆效果检测与评价[J].地下空间与工程学报,2022,18(6):1962-1967,1978.(Li Tao,Wang Yingyi,Huang Xingchun,et al.Detection and evaluation of shield synchronous grouting effect based on impact image metho[J].Chinese Journal of Underground Space and Engineering,2022,18(6):1962-1967,1978.(in Chinese))
[17] 王涵. 大直径盾构隧道管片上浮机理与施工控制研究[D]. 济南:山东大学, 2022.(Wang Han. Study on segment uplifting displacement mechanism and control measures of large diameter shield tunnel[D]. Jinan: Shandong University, 2022.(in Chinese))
[18] Tananashi H. Formulas for an infinitely long bernoulli-euler beam on the pasternak model[J]. Journal of the Japanese Geotechnical Society, 2004, 44(5): 109-118.
[19] Liang R, Wu W, Yu F, et al. Simplified method for evaluating shield tunnel deformation due to adjacent excavation[J]. Tunnelling and Underground Space Technology, 2018, 71: 94-105.
[20] Yu J, Zhang C, Huang M. Soil-pipe interaction due totunnelling: Assessment of winkler modulus for underground pipelines[J]. Computers and Geotechnics,2013, 50:17-28.
[21] 徐凌.软土盾构隧道纵向沉降研究[D].上海:同济大学, 2005. (Xu Ling. Research on longitudinal settlement of soft soil shield tunnels[D]. Shanghai: Tongji University, 2005.(in Chinese))
[22] 徐凯. 砂卵石地层叠线小净距盾构隧道管片结构受力特征与松动土压力计算方法研究[D]. 成都:西南交通大学, 2021.(Xu Kai. Study on mechanical characteristics of segment structure and calculation method of loose earth pressure of shield tunnel with small spacing in sand cobble stratum[D]. Chengdu: Southwest Jiaotong University, 2021.(in Chinese))

Options

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献