| Citation: | CHENG Hao, CHEN Hui, ZHANG Shu, JIA Hanying. Investigations into ground surface settlement characteristics of excavation under dewatering and excavating conditions using the response surface experimental design method[J]. Bulletin of Geological Science and Technology, 2024, 43(5): 181-196. doi: 10.19509/j.cnki.dzkq.tb20230294
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The soil surrounding an excavation experiences continuous ground settlement due to the combined effects of dewatering and excavation, which significantly impacts both the stability of the excavation and its surrounding environment.
To elucidate the key factors governing ground settlement during the dewatering and excavation process, as well as to establish an empirical model based on these findings, this study systematically investigated a deep metro station excavation in Hangzhou, situated on a typical river terrace with a dual-layered geological structure.
Firstly, a numerical analysis method for settlement in braced excavations was proposed by incorporating a hybrid Mohr-Coulomb (MC)-Modified Cambridge (MMC) constitutive model, derived from the deformation mechanism of excavation soil and a comparison with actual monitoring data. Subsequently, the response surface method (RSM) was employed, to establish an empirical model for ground settlement caused by dewatering and excavation under dual-layer geological structure conditions in the study area, accounting for various operational factors and their interactions, and to analyze the zoning characteristics of ground settlement.
The findings suggest that the drawdown of the groundwater table,
This study not only presents an empirical model for excavation engineering under similar geological conditions but also provides a practical framework for excavation design, construction, and monitoring. These contributions are crucial for effectively managing settlement deformation in excavations and their surrounding environments.
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