Abstract
Shield recovery in water-rich sand strata is a challenging issue in the field of shield tunnel engineering, especially when the end of the shaft cannot be reinforced by jet grouting or freezing or when the shield cannot be supported with a steel sleeve. Therefore, it is important to develop an effective recovery approach and adopt suitable techniques to control the risks. In this study, a new method based on filling the receiving shaft with water is proposed for the underwater recovery of an earth pressure balance (EPB) shield with zero end reinforcement from a metro tunnel in Tel Aviv, Israel. Several additional techniques are used to ensure safe recovery of the shield, including the design of a concrete cradle, drilling of pressure relief holes, control of excavation parameters, screw conveyor sealing, portal sealing, tail sealing, and grouting. Furthermore, according to the actual situation on site, filling the shaft with water to 1 m above the water level in the strata can prevent the fine sand from percolating into the shaft. Before the cutterhead approaches the underground diaphragm wall, the driving attitude should be strictly controlled, and the edge hob should be inspected for wear. The necessary thrust of shield tunneling in the underground diaphragm wall and shaft is calculated theoretically. In order to ensure the deformation control of the underground diaphragm wall and the smooth tunneling of the shield, the thrust of the shield excavating the underground diaphragm wall will not be larger than 12 000 kN, and the penetration degree will be limited to 3 mm/r. Qualitative observations and measurements of surface subsidence in the metro tunnel indicate that these risk mitigation techniques are effective and suitable for the underwater recovery of EPB shields in water-rich sand strata.
Highlights
Shield tunneling is an advanced technology that has been widely applied to the construction of metro tunnels [1,2,3,4,5]
The complicated lifting operations required to install a steel sleeve cannot be used for shield recovery. erefore, this study proposes a shield recovery method that involves filling the receiving shaft with water. is novel method is superior to both end reinforcement and steel sleeve methods considering the construction restrictions of this project. is study contributes to reducing the risk of underwater shield recovery by proposing a fast and effective control method
Enabling the cutterhead to advance on the thin concrete provided the necessary tolerance for the machine position. e concrete cradle is illustrated in Figure 8. e concrete cradle is a temporary structure for the shield recovery
Summary
Shield tunneling is an advanced technology that has been widely applied to the construction of metro tunnels [1,2,3,4,5]. The shield recovery process will encounter a wide range of rock types, such as loess, mixed, sandy cobble, soft, and water-rich sand strata. A review of previous literature indicates that shield recovery technology in water-rich sandy strata predominantly includes artificial freezing [9], high-pressure rotary jet grouting [10], cement-soil deep mixing [11], and combinations of multiple approaches [12]. Another effective method for shield recovery in water-rich sandy strata involves covering the shield with a steel sleeve [13, 14]. Pan et al [21] carried out a test of shaft end reinforcement for high permeability sandy soil, introduced a construction measure
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