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跨越走滑断层的大跨度铁路斜拉桥非线性地震响应分析

Nonlinear seismic response analysis of long-span railway cable-stayed bridges crossing strike-slip faults.

作者信息

Zhang Jin, Liu Xiang, Cao Ya-Ting, Chen Ke-Jian, Gao Yu-Feng, Guo Heng

机构信息

School of Environmental and Civil Engineering, Chengdu University of Technology, Chengdu, 610059, Sichuan, China.

China Railway Eryuan Institute Engineering Group Co., Ltd, Chengdu, 610031, Sichuan, China.

出版信息

Sci Rep. 2024 Oct 26;14(1):25479. doi: 10.1038/s41598-024-77135-w.

DOI:10.1038/s41598-024-77135-w
PMID:39462038
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11514047/
Abstract

Active faults along railways in the mountainous regions of western China pose significant challenges to bridge safety. To ensure the safe operation of long-span railway bridges under complex geological conditions, this study investigates the synthesis of artificial ground motions for bridges crossing strike-slip faults and analyzes their nonlinear seismic response. First, we develop a theoretical method for simulating high- and low-frequency seismic motions using a finite fault and an equivalent velocity pulse model. Next, using a specific long-span railway cable-stayed bridge as a case study, we construct a nonlinear finite element model with OpenSees software. Finally, we assess the seismic response of key bridge components considering various crossing angles, seismic amplitudes, fault rupture directivity, and fling-step effects. The results show that the crossing angle significantly influences the seismic response, with longitudinal and transverse responses exhibiting opposite patterns. Additionally, the scaling factor of seismic motion significantly affects bridge response. For bridges crossing strike-slip faults, the longitudinal response exhibits a sudden increase in displacement due to instantaneous velocity pulses, while the transverse response shows notable residual displacement influenced by the fling-step effect. However, the critical section curvatures of bridge towers and piers remain within the elastic range across all crossing angles, indicating that controlling large displacement deformations is crucial for the seismic design of bridges crossing strike-slip faults.

摘要

中国西部山区铁路沿线的活动断层对桥梁安全构成了重大挑战。为确保大跨度铁路桥梁在复杂地质条件下的安全运营,本研究探讨了跨越走滑断层桥梁的人工地震动合成方法,并分析了其非线性地震响应。首先,我们利用有限断层和等效速度脉冲模型开发了一种模拟高频和低频地震动的理论方法。接下来,以一座特定的大跨度铁路斜拉桥为例,我们使用OpenSees软件构建了非线性有限元模型。最后,我们考虑了不同的跨越角度、地震振幅、断层破裂方向性和阶跃效应,评估了桥梁关键部件的地震响应。结果表明,跨越角度对地震响应有显著影响,纵向和横向响应呈现相反的模式。此外,地震动的缩放因子对桥梁响应有显著影响。对于跨越走滑断层的桥梁,纵向响应由于瞬时速度脉冲而出现位移突然增加,而横向响应则受到阶跃效应影响而呈现出明显的残余位移。然而,在所有跨越角度下,桥塔和桥墩的关键截面曲率均保持在弹性范围内,这表明控制大位移变形对于跨越走滑断层桥梁的抗震设计至关重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/184a/11514047/29f5f85f57ea/41598_2024_77135_Fig14a_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/184a/11514047/f0aacf55bcec/41598_2024_77135_Fig10_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/184a/11514047/e041c983a19e/41598_2024_77135_Fig11_HTML.jpg
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