地铁暗挖车站PBM工法地层及结构变形研究

王子君

doi:10.20265/j.cnki.issn.1007-2993.2025-0042

地铁暗挖车站PBM工法地层及结构变形研究

doi: 10.20265/j.cnki.issn.1007-2993.2025-0042

王子君

北京市勘察设计研究院有限公司，北京　100038

详细信息

作者简介:
王子君，男，1996年生，硕士，工程师。研究方向：隧道与地下空间。E-mail：421981576@qq.com

中图分类号: U455
计量
- 文章访问数: 15
- HTML全文浏览量: 6
- PDF下载量: 6
- 被引次数: 0
出版历程
- 收稿日期: 2025-01-22
- 修回日期: 2025-03-12
- 录用日期: 2025-04-09
- 刊出日期: 2026-02-06

Ground and structural deformation characteristics of metro stations constructed by the PBM method

WANG Zijun

Beijing Survey and Design Institute Co., Ltd., Beijing 100038, China

摘要

摘要: 沈阳某地铁车站采用PBM工法开挖，以该暗挖工程为背景，介绍了PBM工法现场施工关键技术及措施，通过现场监测和数据分析，研究了PBM工法车站开挖过程引起的地表沉降、结构变形和应变的变化规律。研究结果表明：该车站PBM工法施工引起地表最终沉降最大值约25 mm，沉降控制水平较好；整体结构变形及应变处于安全范围，表明PBM工法整体结构布置合理。在负一层的开挖及结构浇筑中，应减小开挖步距和顶板注浆的速度，以减小对上覆管线的扰动；当负一层开挖施工到中部横梁时应适当减缓开挖速度，加强临时支护，从而更好地控制横梁竖向变形。
- 管幕−横梁工法 /
- 地铁暗挖车站 /
- 工程监测 /
- 地表沉降 /
- 结构变形
Abstract: Using the underground excavation section of a metro station in Shenyang as a case study, this research introduces the key technologies and measures for on-site construction of the PBM method. Through on-site monitoring tests, the variation laws of surface settlement, structural deformation and strain caused by the excavation process of the PBM method were studied. The findings demonstrate that the maximum final settlement of the PBM method is about 25 mm, and indicating an acceptable settlement control level. The overall structural deformation and strain are within the safe range, indicating that the overall structural layout of the PBM method station is reasonable. During the excavation and structure pouring of the negative first floor, the excavation step distance and the speed of top plate grouting should be reduced to minimize the disturbance to the overlying pipelines. When the excavation of the negative first floor reaches the central crossbeam, the excavation speed should be appropriately slowed down and temporary support should be strengthened to better control the vertical deformation of the crossbeam.
- pipe-roof beam method /
- underground excavation station of metro /
- engineering monitoring /
- surface settlement /
- structural deformation

HTML全文

图 1 管幕−横梁工法（PBM）车站结构示意图

Figure 1. Schematic diagram of station structure by PBM

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图 2 市府大路站平面布置图

Figure 2. Layout plan of the station

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图 3 市府大路站地下管线分布图

Figure 3. Underground pipeline distribution map

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图 4 市府大路站暗挖段主体结构布置图

Figure 4. Layout diagram of the main structure of the underground section of the metro station

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图 5 地表沉降监测断面布置图

Figure 5. Layout of surface subsidence monitoring sections

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图 6 结构变形监测点分布图

Figure 6. Distribution map of structural deformation monitoring points

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图 7 结构应变监测装置

Figure 7. Structural strain monitoring device

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图 8 地表沉降历时曲线

注：由于点分布较密，图中每5点仅显示1点，其余点跳过，由曲线代替连接。

Figure 8. Time-history curve of ground settlement

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图 9 车站开挖结构断面图^[10]

Figure 9. Structural sectional view of station excavation^[10]

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图 10 地表沉降横断面监测值对比图

Figure 10. Comparison chart of surface subsidence cross-sectional monitoring values

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图 11 地表沉降纵断面监测值分布图

Figure 11. Distribution map of longitudinal section monitoring values of surface subsidence

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图 12 横梁变形监测值对比图

Figure 12. Comparison chart of beam deformation monitoring values

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图 13 中柱沉降监测值对比图

Figure 13. Comparison chart of column settlement monitoring values

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图 14 负一层中跨开挖横梁应变变化图

Figure 14. Strain variation diagram of the excavation crossbeam in the middle span of the basement level

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