Abstract
Water is one of the major risk sources in the excavation of deep-large foundation pits in a water-rich area. The presence of intrusive broken diorite porphyrite in the stratum aggravates the risk level of deep foundation pits. Based on a geological survey report and design documents of parameter information, MIDAS/GTS software was used to perform the numerical simulation of an engineering example of a deep foundation pit project of ultradeep and water-rich intrusion into the broken rock station of subway line 4 in a city. The simulation results show the characteristics of seepage path evolution, seepage aggregation areas and points, and the effect of seepage on the deformation of a deep foundation pit during the whole construction of this deep foundation pit. The results show that with the precipitation-excavation of the deep foundation pit, the pore water pressure at the bottom of the foundation pit follows a distribution of three “concave” shapes. High-permeability pressure zones are found around the foundation pit, intruding broken diorite porphyrite zones, and middle coarse sand zones. With further excavation of the foundation pit, the seepage pressure in the middle part of the foundation pit gradually decreases, and the two “concave” distributions in the middle gradually merge together. After excavation to the bottom of the pit, the pore water pressure at the bottom is distributed in two asymmetrical “concave” shapes, and the maximum peak of pore water pressure is found at the intrusion of fractured porphyrites prone to water inrush. The four corners of the foundation pit are prone to form seepage accumulation zones; therefore, suffosion and piping zones are formed. The surface settlement caused by excavation is found to be the largest along the longitudinal axis of the deep foundation pit, whereas the largest deformation is found near the foundation pit side in the horizontal axis direction of the foundation pit. With the excavation of the deep foundation pit, the diaphragm wall converges to the foundation pit with the maximum deformation reaching about 25 mm. After the first precipitation-excavation of the deep foundation pit to the silty clay and the bottom of the pit with the largest uplift, with further precipitation-excavation of the deep foundation pit, the uplift at the bottom of the deep foundation pit changes only slightly.
Highlights
Disasters of deep foundation pits are mostly related to the improper control of groundwater
Water problems are encountered as the foundation pit continues to deepen; in particular, groundwater control is the focus of research in some deep foundation pit projects when located in water-rich fractured rock areas
MIDAS/GTS software was used for simulation analysis, and the geotechnical parameters and material properties used in the simulation were provided from the design file of the deep foundation pit, so that the simulation results can reflect the seepage and deformation characteristics of the deep foundation pit under the design of the deep foundation pit and better guide the design
Summary
Disasters of deep foundation pits are mostly related to the improper control of groundwater. Water problems are encountered as the foundation pit continues to deepen; in particular, groundwater control is the focus of research in some deep foundation pit projects when located in water-rich fractured rock areas. Both the abovementioned methods require a water seepage path and evolution trend along with excavation to obtain accurate information about the design to ensure project safety. In the bottom layer of foundation pit excavation under seepage condition, the soil around the pile will rebound due to water pressure. The seepage and deformation evolution trends of deep foundation pit in the whole construction process were studied through a numerical simulation for the excavation of a deep foundation pit of a 37 m deep city subway station with water-rich and locally broken intrusive rocks. The research results provide a reference for the excavation design and construction of deep foundation pits with water-rich and locally invaded broken diorite porphyritic stratum
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