Affiliation:
1. School of Civil Engineering, Chang’an University, Xi’an 710064, China
2. School of Civil and Transportation Engineering, Ningbo University of Technology, Ningbo 315211, China
3. School of Faculty of Architectural, Civil Engineering and Environment, Ningbo University, Ningbo 315211, China
Abstract
Shield tunnels assembled with general ring segments are widely used in urban areas. Segment assembly methods and widths cause changes in the mechanical properties of the structure and influence the seismic response of shield tunnels. To investigate the influence of the assembly method and width of the general ring segment on the seismic performance of a shield tunnel, a three-dimensional refined soil–structure dynamic interaction finite element model of the shield tunnel was established based on ABAQUS, and the mechanical response and joint deformation of the general ring lining under seismic loads were studied. The simulation results show the following: (i) The overall deformation of the tunnel lining is not significantly affected by the assembly method, and the difference is only 5.24% under a 0.4 g earthquake. (ii) The seismic responses of general ring tunnels with different assembly methods are quite different, and the mechanical properties of the shield tunnel assembled with the straight assembly method are better than those of the shield tunnel assembled with staggered joints, but the deformation of the structure is larger. Under the action of a 0.1 g earthquake, the radial force, circumferential force, and bending moment of the staggered 90° assembly tunnel are respectively reduced by 13.6%, 11.1%, and 17.8% compared with the staggered 45° assembly structure, but the maximum intra-opening deformation increases by 0.19, 0.58, and 2.4 mm, respectively. (iii) The internal force distribution of the bolts is controlled by the deformation of the joint; compared with the CF90 and TF assembled tunnels, the mechanical properties and deformation characteristics of the CF45 and CF90 assembled tunnels are more reasonable. (iv) The extrados and intrados joint opening deformation and shear dislocation of the 1.2 m wide general ring segment under the staggered assembly increase by 1.2 mm and 1.03 mm, respectively, compared with the 1.5 m wide segment, while the radial force, circumferential force, and bending moment are reduced by 24.4%, 36.5%, and 41.7%, respectively, indicating that the seismic performance of the shield tunnel with a segment width of 1.5 m is better than that of the shield tunnel with a width of 1.2 m.
Funder
Systematic Project of Key Laboratory of New Technology for Construction of Cities in Mountain Area
Systematic Project of Guangxi Key Laboratory of Disaster Prevention and Structural Safety
Ningbo Natural Science Foundation
Ningbo Public Welfare Science and Technology Planning Project
Subject
Building and Construction,Civil and Structural Engineering,Architecture
Reference34 articles.
1. Sbd-k-medoids-based long-term settlement analysis of shield tunnel;Shen;Transp. Geotech.,2023
2. Study on Dynamic Response of Soil Layer at the Bottom of Subway Shield Tunnel under Seismic Action;Xu;Geotech. Geol. Eng.,2022
3. Masanori, H. (2014). Dynamic Behaviors of Underground Structures during Earthquakes and Earthquake-Resistant Design, Springer.
4. Causal Analyses of Different Degree of Earthquake Damage Occurred on Daikai Subway Station and Its Running Tunnels during Kobe Earthquake;Yang;J. Disaster Prev. Mitig. Eng.,2020
5. Review of Earthquake Damage Prediction for Underground Structures;Liu;China Earthq. Eng. J.,2020
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