Volume 39 Issue 3
Jun.  2025
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Article Navigation >  GEOTECHNICAL ENGINEERING TECHNIQUE  > 2025  >  39(3): 331-340
Meng Chenxiang, Lin Houquan, Li Xiang, Zhang Xiaogong, Liu Jiankun. Optimization of flat ratio and selection of construction method for shallow buried super-large section tunnels[J]. GEOTECHNICAL ENGINEERING TECHNIQUE, 2025, 39(3): 331-340. doi: 10.20265/j.cnki.issn.1007-2993.2024-0093
Citation: Meng Chenxiang, Lin Houquan, Li Xiang, Zhang Xiaogong, Liu Jiankun. Optimization of flat ratio and selection of construction method for shallow buried super-large section tunnels[J]. GEOTECHNICAL ENGINEERING TECHNIQUE, 2025, 39(3): 331-340. doi: 10.20265/j.cnki.issn.1007-2993.2024-0093
shu

Optimization of flat ratio and selection of construction method for shallow buried super-large section tunnels

doi: 10.20265/j.cnki.issn.1007-2993.2024-0093
  • 1.

    Shanghai Tunnel Engineering Co., Ltd., Shanghai 200032, China

  • 2.

    School of Civil Engineering, Sun Yat-Sen University, Zhuhai 519000, Guangdong, China

  • Received Date: 2024-03-01
  • Accepted Date: 2024-08-29
  • Rev Recd Date: 2024-05-07
  • Publish Date: 2025-06-09
    Abstract
  • For shallow-buried oversized cross-section flat structure tunnels, reasonable cross-section design and construction method selection are crucial for ensuring tunnel construction safety. In this study, finite difference computation software FLAC 3D was employed to optimize the flat ratio and construction method for Tunnel No.2 of Tonggang Road in the Shenzhen-Shanwei Cooperation Zone. The effects of four different flat ratios and two distinct construction methods on the deformation and stress distribution of the surrounding rock were analyzed, and the entropy weight method was utilized to determine the weights of indicators such as plastic zone area, vault settlement, and ground settlement. Each scheme was evaluated through comprehensive scoring and comparison, leading to the proposal of the optimal flat ratio and construction method for the studied tunnel project. Numerical simulation results indicated that a section design with a flat ratio of 0.65 combined with the double-side drift excavation method represents the optimal solution. The high consistency between field construction monitoring data and numerical simulation results was demonstrated, validating the accuracy of the established numerical model and the feasibility of the proposed optimized construction scheme. The findings provide theoretical support and data references for the construction of shallow buried super-large sections of flat structure tunnels.

     

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