邻近地铁深大基坑开挖变形与控制措施研究
引用文献:
俞强. 邻近地铁深大基坑开挖变形与控制措施研究[J]. 建筑结构,2022,48(12):127-133.
YU Qiang. Study on deformation characteristics and control measures of deep and large foundation pit excavation neighboring metro[J]. Building Structure,2022,48(12):127-133.
摘要:以邻近运营地铁隧道的福州正祥广场深大基坑为实例,结合基坑开挖过程中围护结构侧向位移、周围土体沉降和地铁隧道水平及竖直位移的现场实测数据,系统分析了不同施工阶段基坑围护结构、周边土体以及地铁隧道的变形特性,讨论了采用围护结构刚度优化、支撑体系优化以及开挖工序优化等变形控制措施的合理性。结果表明:基坑淤泥层开挖所引发的侧向位移约占总侧向位移的50%~60%;受开挖方式和支护方式的影响,基坑东侧(邻近地铁隧道)与西侧围护结构的最大侧移位移平均值分别为0.128%H和0.228%H(H为基坑开挖深度),最大侧向位移所在深度约为0.25H~H;地铁隧道的位移曲线与基坑周围土层、围护结构的位移曲线的发展趋势具有良好的一致性,均表现出显著的空间效应。
关键词:深大基坑;基坑开挖;运营地铁隧道;变形特性;控制措施;空间效应
基金:福建省科技计划引导性项目(2021H0032)。
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[11] 张治国,白乔木,姜蕴娟,等.邻近隧道及周围地层受深基坑开挖影响的现场监测研究[J].现代隧道技术,2017,54(2):177-184.
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[14] 杨德春,刘建国.地铁隧道附近软土深基坑设计与施工关键技术分析[J].建筑结构,2012,42(7):109-114.
[15] 陈仁朋,孟凡衍,李忠超,等.邻近深基坑地铁隧道过大位移及保护措施[J].浙江大学学报(工学版),2016,50(5):856-863.
[16] MOORMANN C.Analysis of wall and ground movements due to deep excavations in soft soil based on a new worldwide database[J].Soils and Foundations,2004,44(1):87-98.
[17] OU C Y,HSIEH P G,CHIOU D C.Characteristics of ground surface settlement during excavation[J].Canadian Geotechnical Journal,1993,30(5):758-767.
[18] 王卫东,徐中华,王建华.上海地区深基坑周边地表变形性状实测统计分析[J].岩土工程学报,2011,33(11):1659-1666.
[19] 黄军华,周志健,刘鑫坤,等.邻近运营地铁的深基坑开挖风险及控制措施[J].施工技术(中英文),2021,50(24):35-39.
[2] 秦前波,方引晴.基坑开挖及上盖荷载对下卧隧道结构的影响分析[J].建筑结构,2012,42(6):107-111.
[3] 闫静雅.邻近运营地铁隧道的深基坑设计施工浅谈[J].岩土工程学报,2010,32(S1):234-237.
[4] 郭永发,杨翔,叶林,等.某基坑支护方案对相邻地铁区间的影响分析[J].地下空间与工程学报,2015,11(3):726-731.
[5] 胡琦,许四法,陈仁朋,等.深基坑开挖土体扰动及其对邻近地铁隧道的影响分析[J].岩土工程学报,2013,35(S2):537-541.
[6] 史江伟,陈丽.圆形基坑开挖引起下卧隧道三维变形机理研究[J].地下空间与工程学报,2018,14(4):1083-1090.
[7] 王定军,王婉婷,段罗,等.基坑开挖对下卧地铁隧道的施工影响分析[J].地下空间与工程学报,2017,13(S1):223-232.
[8] 丁智,张霄,金杰克,等.基坑全过程开挖及邻近地铁隧道变形实测分析[J].岩土力学,2019,40(S1):415-423.
[9] 贾夫子,王立峰,逯武全,等.基坑开挖对近邻地铁车站和隧道的影响[J].岩土力学,2016,37(S2):673-678.
[10] 刘念武,陈奕天,龚晓南,等.软土深开挖致地铁车站基坑及邻近建筑变形特性研究[J].岩土力学,2019,40(4):1515-1525.
[11] 张治国,白乔木,姜蕴娟,等.邻近隧道及周围地层受深基坑开挖影响的现场监测研究[J].现代隧道技术,2017,54(2):177-184.
[12] LEE F H,YONG K,QUAN K C N,et al.Effect of corners in strutted excavations:field monitoring and case histories[J].Journal of Geotechnical & Geoenvironmental Engineering,1998,124(4):339-349.
[13] 张思峰,周健,贾敏才,等.深基坑施工的现场监测及其时空效应分析[J].建筑结构,2007,37(6):53-55.
[14] 杨德春,刘建国.地铁隧道附近软土深基坑设计与施工关键技术分析[J].建筑结构,2012,42(7):109-114.
[15] 陈仁朋,孟凡衍,李忠超,等.邻近深基坑地铁隧道过大位移及保护措施[J].浙江大学学报(工学版),2016,50(5):856-863.
[16] MOORMANN C.Analysis of wall and ground movements due to deep excavations in soft soil based on a new worldwide database[J].Soils and Foundations,2004,44(1):87-98.
[17] OU C Y,HSIEH P G,CHIOU D C.Characteristics of ground surface settlement during excavation[J].Canadian Geotechnical Journal,1993,30(5):758-767.
[18] 王卫东,徐中华,王建华.上海地区深基坑周边地表变形性状实测统计分析[J].岩土工程学报,2011,33(11):1659-1666.
[19] 黄军华,周志健,刘鑫坤,等.邻近运营地铁的深基坑开挖风险及控制措施[J].施工技术(中英文),2021,50(24):35-39.
Study on deformation characteristics and control measures of deep and large foundation pit excavation neighboring metro
Abstract: Taking the deep and large foundation pit of Fuzhou Zhengxiang Square adjacent to the operating subway tunnel as an example, combined with the on-site measured data of the lateral displacement of the enclosure structure, the surrounding soil settlement and the horizontal and vertical displacement of the subway tunnel during the excavation process of the foundation pit, a systematic analysis was carried out on the deformation characteristics of the foundation pit envelope, surrounding soil and subway tunnels in different construction stages, and the rationality of the deformation control measures such as the optimization of the envelope structure stiffness, the optimization of the support system and the optimization of the excavation process were discussed. The results show that the lateral displacement caused by the excavation of the silt layer of the foundation pit accounts for about 50%~60% of the total lateral displacement. The average maximum lateral displacement of the side enclosure structure is 0.128%H and 0.228%H respectively, which influenced by the excavation method and support method.(H is the excavation depth of the foundation pit), and the depth of the maximum lateral displacement is about 0.25H~H. The displacement curve of the subway tunnel has a good consistency with the development trend of the displacement curve of the soil layer around the foundation pit and the envelope structure, and both show significant spatial effects.
Keywords: deep and large foundation pit; foundation pit excavation; operating subway tunnel; deformation characteristic; control measure; spatial effect
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