A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation
This study proposes a simplified analysis method that couples the bridge and train-track subsystem in a weak form to facilitate the dynamic analysis of the train-track-bridge coupled system (TTBS) under earthquakes. The method includes three main steps: (i) performing dynamic analysis of the bridge...
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sg-ntu-dr.10356-1802142024-09-24T04:38:21Z A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation Zhu, Zhihui Gong, Wei Zhou, Gaoyang Yang, Yaowen Jiang, Lizhong School of Civil and Environmental Engineering Engineering Simplified analysis method Weak coupling form This study proposes a simplified analysis method that couples the bridge and train-track subsystem in a weak form to facilitate the dynamic analysis of the train-track-bridge coupled system (TTBS) under earthquakes. The method includes three main steps: (i) performing dynamic analysis of the bridge under seismic conditions to obtain the response of the bridge deck; (ii) interpolating the bridge displacement beneath each wheelset based on the train's velocity, departure time, and the initial positions of the wheelsets; and (iii) assessing the running safety of the train by incorporating the interpolated bridge response as track irregularity into the train-track coupled system. Steps (i) and (iii) can be analyzed separately using finite element and multibody dynamics software, eliminating the need to create a complex TTBS model that is challenging to achieve within a single software platform. Additionally, based on the method's assumptions, the earthquake excitation on the train can be separated into the seismic inertial effect and seismic-induced bridge deformation, enabling a quantitative analysis of the impact of these two types of excitations on train safety. Taking a 10-span simply supported bridge and a long-span cable-stayed bridge as examples, the proposed method's assumptions are verified by comparing its results with those obtained from a complex TTBS model. Furthermore, the impact characteristics of inertial effects and seismic-induced bridge deformation on train safety for these two types of bridges are analyzed. The proposed method offers robust support for seismic design of bridges and facilitates a comprehensive analysis of the mechanisms through which seismic excitations affect train safety. This work was supported by the National Natural Science Foundation of China [Grant No. 52078498], the National Key R&D Program “Transportation Infrastructure” “Reveal the list and take command” project [2022YFB2603301], the Natural Science Foundation of Hunan Province of China [Grant number: 2022JJ30745], the Hunan Provincial Science and Technology Promotion Talent Project [Grant number: 2020TJ-Q19], the Frontier Cross Research Project of Central South University [Grant number: 2023QYJC006], and the Science and Technology Research and Development Program Project of China Railway Group Limited [Major Special Project, No.: 2021-Special-04-2]. 2024-09-24T04:38:21Z 2024-09-24T04:38:21Z 2024 Journal Article Zhu, Z., Gong, W., Zhou, G., Yang, Y. & Jiang, L. (2024). A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation. Engineering Structures, 309, 118072-. https://dx.doi.org/10.1016/j.engstruct.2024.118072 0141-0296 https://hdl.handle.net/10356/180214 10.1016/j.engstruct.2024.118072 2-s2.0-85191352822 309 118072 en Engineering Structures © 2024 Elsevier Ltd. All rights reserved. |
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Engineering Simplified analysis method Weak coupling form |
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Engineering Simplified analysis method Weak coupling form Zhu, Zhihui Gong, Wei Zhou, Gaoyang Yang, Yaowen Jiang, Lizhong A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
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This study proposes a simplified analysis method that couples the bridge and train-track subsystem in a weak form to facilitate the dynamic analysis of the train-track-bridge coupled system (TTBS) under earthquakes. The method includes three main steps: (i) performing dynamic analysis of the bridge under seismic conditions to obtain the response of the bridge deck; (ii) interpolating the bridge displacement beneath each wheelset based on the train's velocity, departure time, and the initial positions of the wheelsets; and (iii) assessing the running safety of the train by incorporating the interpolated bridge response as track irregularity into the train-track coupled system. Steps (i) and (iii) can be analyzed separately using finite element and multibody dynamics software, eliminating the need to create a complex TTBS model that is challenging to achieve within a single software platform. Additionally, based on the method's assumptions, the earthquake excitation on the train can be separated into the seismic inertial effect and seismic-induced bridge deformation, enabling a quantitative analysis of the impact of these two types of excitations on train safety. Taking a 10-span simply supported bridge and a long-span cable-stayed bridge as examples, the proposed method's assumptions are verified by comparing its results with those obtained from a complex TTBS model. Furthermore, the impact characteristics of inertial effects and seismic-induced bridge deformation on train safety for these two types of bridges are analyzed. The proposed method offers robust support for seismic design of bridges and facilitates a comprehensive analysis of the mechanisms through which seismic excitations affect train safety. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Zhu, Zhihui Gong, Wei Zhou, Gaoyang Yang, Yaowen Jiang, Lizhong |
| format |
Article |
| author |
Zhu, Zhihui Gong, Wei Zhou, Gaoyang Yang, Yaowen Jiang, Lizhong |
| author_sort |
Zhu, Zhihui |
| title |
A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
| title_short |
A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
| title_full |
A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
| title_fullStr |
A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
| title_full_unstemmed |
A simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
| title_sort |
simplified weak coupling dynamic analysis method for running safety evaluation of train on bridges under earthquake excitation |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180214 |
| _version_ |
1814047237160828928 |