Analysis of the Response Law of Station Buried Depth Change to Subway Station Under Vibration Load
DOI:
https://doi.org/10.70693/cjst.v1i2.1036Keywords:
Subway stations; V-column structure; Earthquake response rule; Station buried depth; Elastoplastic analysis;Numerical simulationAbstract
In the period of rapid development of urban rail transit, the traditional transportation hub has become increasingly unable to meet the needs of people 's travel due to the lack of rationality and efficiency of land use, the monotonous structure and other reasons, resulting in a series of new three-dimensional transportation hub. The Huangmugang comprehensive transportation hub in Shenzhen is a complex four-story underground station with different spans. The station adopts a large-diameter and large-angle V-column structure system. In this paper, a simplified seismic analysis method suitable for the V-pillar structure of subway station is proposed, and the two-dimensional finite element model and dynamic time history analysis of subway station are completed in combination with practical engineering cases. The influence of buried depth change of station on the response law of subway station is studied. The seismic response results of station under three different buried depths are analyzed, and the stress and deformation law of key components such as V-pillar, side wall and station floor of station structure are compared and analyzed.The main conclusions are as follows : with the increase of the buried depth of the station, the constraint effect of the surrounding soil on the station structure is obviously enhanced, which is manifested by the increase of the constraint effect of the soil on the side wall of the station and the decrease of the displacement of the side wall. However, with the further increase of the buried depth of the station, the constraint effect of the surrounding soil on the station tends to be stable. At the same time, due to the increase of the thickness of the overlying soil, the self-weight stress transmitted by the soil of the station increases, which makes the deformation of the side wall of the station increase.
References
Japanese Architectural Society.Calculation standard and explanation of steel reinforced concrete structure. Feng Naiqian, Ye Lieping. Beijing : Energy Press, 1998:(36-39).
State Construction Committee of the Soviet Union. Soviet Guide for the Design of Rigid Reinforced Concrete Structures . Translated by Liu Chunpu. Compilation of Technical Information Room, General Institute of Building Research, Ministry of Metallurgical Industry (Reference Materials for Metallurgical Buildings. 8302), 1983 (N3-78)..
Suwen Chen, Pei Wu. Analytical model for predicting axial compressive behavior of steel reinforced concrete column[J]. Journal of Constructional Steel Research, 2017(318):135-136.(in Chinese) DOI: https://doi.org/10.1016/j.jcsr.2016.10.001
Hui Ma, Jian Yang Xue, Xi Cheng Zhang, Zong Ping Chen. Experimental Study on Seismic Perfor- mance of Steel Reinforced Concrete Column with Recycled Coarse Aggregate[J]. Applied Mechan-ics and Materials,2013, (256): 215-216.(in Chinese) DOI: https://doi.org/10.4028/www.scientific.net/AMM.256-259.2063
Piotr Lacki, Anna Derlatka, Przemyslaw Kasza. Comparison of steel‒concrete composite column and steel column. Composite Structures [J]. Composite Structures, 2017:125-128. DOI: https://doi.org/10.1016/j.compstruct.2017.11.055
Hu Ruiqing. Influence of soil-structure contact interface on lateral seismic response characteristics of lining structures under different surrounding rock and buried depth [J]. Tunnel construction (Chinese and English), 2018, 38(12): 1957-1965.(in Chinese)
Dong Zhengfang, Zhu Hongyun, CAI Baozhan, Yan Chao. Seismic internal force variation of underground structures in soil sites with different buried depths [J]. Earthquake Resistance and Reinforcement Engineering, 2017, 39(05): 143-148.(in Chinese)
Wang B. Dynamic response analysis and parametric study of subway stations under earthquake action [D]. Chang 'an University, 2023.(in Chinese)
XU Zigang, Xu Chengshun, Du Xiuli, Wu Ye. Research on seismic damage of Dakai station and section tunnel based on pseudo-static napper analysis [J]. Chinese Journal of Geotechnical Engineering, 2021, 43(07): 1182-1191+1373.(in Chinese)
Haiyang Zhuang, Jiawei Ren, Yu Miao, et al. Seismic Performance Levels of a Large Underground Subway Station in Different Soil Foundations, Journal of Earthquake Engineering, 2019:56-59.(in Chinese) DOI: https://doi.org/10.1080/13632469.2019.1651423
HAN Runbo, Xu Chengshun, Xu Zigang, Jiang Jiawei, Du Xiuli. Boundary forced response displacement method for seismic Analysis of symmetric underground structures [J]. Engineering Mechanics, 2021,38(05):50-60.(in Chinese)
Du Xiuli, Qiao Lei, Xu Zigang, Yin Mengsha. Comparative study on solving methods of foundation spring stiffness coefficient in response displacement method [J]. Journal of Disaster Prevention and Reduction Engineering, 201,41(02):246-254. (in Chinese)
LIU Jingbo, Wang Wenhui, Zhao Dongdong, Zhang Xiaobo. Integrated response displacement method for seismic response analysis of underground structures with complex sections [J]. Journal of Civil Engineering, 2014, 47(01): 134-142.(in Chinese)
XU Zigang, Du Xiuli, Xu Chengshun, Han Runbo, QIAO Lei. Study on generalized response displacement method for seismic response analysis of underground structures with complex sections [J]. Rock and Soil Mechanics, 2019, 40(08): 3247-3254.(in Chinese)
ZHAO Mi, Guo Mengyuan, Zhong Zilan, Du Xiuli. Variation of optimal ground motion peak index for underground structure with buried depth [J]. Acta Seismologica Sinica, 2022, 44(01): 15-25.(in Chinese)
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2025 Chao Lin, Jiansheng Li, Yuehui Shen, Tao Liu, Baofeng Zhao, Zhenjun Liao, Lumeng Zhou, Qishan Huang, Gehong Wang, Jiaxin Chen, Zhipeng Gao
This work is licensed under a Creative Commons Attribution 4.0 International License.
