|Table of Contents|

Numerical simulation study of rapid dewatering technology in excavation leakage emergency rescue(PDF)

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:
2026年02期
Page:
185-195
Research Field:
岩土工程
Publishing date:

Info

Title:
Numerical simulation study of rapid dewatering technology in excavation leakage emergency rescue
Author(s):
CHENG Xuesong1 QIU Jun1 LI Qinghan1 SHI Jiancheng1 NIU Qi2 YANG Chengwei2 SONG Zhanwei2
(1. Department of Civil Engineering, Tianjin University, Tianjin 300350, China; 2. China Railway Construction Bridge Engineering Bureau Group Co., Ltd., Tianjin 300200, China))
Keywords:
excavation leakage emergency rescue rapid dewatering groundwater recharge settlement
PACS:
TU463
DOI:
10.19815/j.jace.2024.11110
Abstract:
Based on an excavation waterproof curtain leakage project in Tianjin, the effects of leakage gap size and soil layer permeability on leakage volume and fluctuations in aquifer water levels were analyzed using a fluid-solid coupling numerical model. The effects of various precipitation conditions such as single wells placed at different distances and multiple evenly distributed wells on the reduction of leakage and the settlement of surrounding ground surface were discussed. The influence of different recharge well configurations and activation strategies in controlling settlement was also investigated. The results show that in water-rich soft soil regions, leakage through a confined aquifer can reach up to 81 m3·d-1 through a 30 cm diameter seam in the diaphragm wall. The primary factors affecting leakage volume are the size of the leakage gap and the soil's permeability at the leakage point. When the leakage occurs in the excavation waterproof curtain, rapid dewatering techniques can reduce aquifer pressure, decreasing leakage flow by 23% to 46%, thus creating favorable conditions for remediation methods like grouting. Rapid dewatering may also cause surface settlement near the excavation. After 3 d of continuous dewatering, surface settlement at 57.5 m from the excavation reaches 6 mm, and it exceeds 10 mm after 10 d. Groundwater recharge can effectively mitigate surface settlement around the excavation while maintaining the benefits of rapid dewatering in reducing leakage flow.

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Last Update: 2026-04-01