Dynamic response of cable fracture of long span road-rail cable-stayed suspension bridge

doi:10.3785/j.issn.1008-973X.2024.09.012

Journal of ZheJiang University (Engineering Science)

2024, Vol. 58

Issue (9): 1874-1885 DOI: 10.3785/j.issn.1008-973X.2024.09.012

Dynamic response of cable fracture of long span road-rail cable-stayed suspension bridge

Xingbiao ZHANG1(

),Tao WANG1,*(

),Sen YAO2,Huawen YE3,Lu WANG1,Lunhua BAI4

1. School of Civil Engineering and Architecture, Southwest University of Science and Technology, Mianyang 621010, China
2. China Railway Major Bridge Engineering Group Co. Ltd, Wuhan 430050, China
3. School of Civil Engineering, Southwest Jiaotong University, Chengdu 610031, China
4. School of Transportation, Civil Engineering and Architecture, Foshan University, Foshan 528225, China

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Abstract

Taking the G3 Tongling road-rail bridge as the research object, a finite element calculation model of bridge was established, in order to investigate the dynamic response of the bridge structure and the train on the bridge when the cables were fracturing under extreme action in long span road-rail cable-stayed suspension bridge. Firstly, the dynamic response of the bridge structure after stayed cables or suspender cable fracture was studied. Then, the dynamic response of the bridge and the train under the cable fracture conditions of the train-bridge coupling vibration was studied. Results showed that the cable-stayed suspension bridge had high structural stiffness and safety redundancy. After a single stayed cable or suspender cable fractured, the train could be maintained. Continuous cable fracture might occur when more than four cables were fracturing in one side of the suspender cables area of the bridge. Continuous cable fracture would not occur when eight cables were fracturing in one side of the stayed and suspender cables alternating region and the stayed cables region. Setting the dynamic amplification factor of cable fracture equal to 2.0 was reasonable, but they had engineering application value only for the remaining suspender cables and stayed cables near the fracture cables. When the cable was fracturing, if the train was passing by, the vertical acceleration of the train would change abruptly, but the acceleration was within the safe range. The stress increase of residual stayed cables and suspender cables was mainly due to the action of main girder, and the proportion of train action was less than 13%.

Key words： cable-stayed suspension bridge finite element method cable fracture dynamic response train-bridge coupled vibration

Received: 11 December 2023 Published: 30 August 2024

CLC:

U 448

Fund: 国家自然科学基金资助项目（51708468，52278219）；四川省自然科学基金资助项目（2023NSFSC0891）；西南科技大学自然科学基金资助项目（20zx7125）.

Corresponding Authors: Tao WANG E-mail: zhangxb1981@126.com;7015294@qq.com

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Cite this article:

Xingbiao ZHANG,Tao WANG,Sen YAO,Huawen YE,Lu WANG,Lunhua BAI. Dynamic response of cable fracture of long span road-rail cable-stayed suspension bridge. Journal of ZheJiang University (Engineering Science), 2024, 58(9): 1874-1885.

URL:

https://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2024.09.012 OR https://www.zjujournals.com/eng/Y2024/V58/I9/1874

大跨度公铁两用斜拉-悬索协作体系桥断索动力响应

研究大跨度公铁两用斜拉-悬索协作体系桥在极端作用下发生断索时桥梁结构及桥上列车的动力响应，以G3铜陵长江公铁大桥为研究对象，建立全桥有限元模型；研究各个位置斜拉索、吊索断裂后桥梁结构的动力响应；研究在列车-桥梁耦合振动作用下，各断索组合工况中桥梁及列车的动力响应. 结果表明：斜拉-悬索协作体系桥具有较高的结构刚度及安全冗余；在单根斜拉索、吊索断索后，可保持列车通行；在吊索区域单侧发生4根以上断索，可导致连续断索破坏；在斜拉索-吊索交替及斜拉索区域，单侧断索达到8根也不会发生连续断索破坏；断索动力放大系数取2.0合理，但仅对断索位置附近剩余吊索和斜拉索具有工程应用价值；当断索发生时，若列车经过，列车竖向加速度会发生突变，但仍在安全范围内；剩余斜拉索与吊索动应力增加主要来自于主梁作用，列车作用占比不超过13%.

关键词： 斜拉-悬索协作体系桥, 有限元方法, 断索, 动力响应, 列车-桥梁耦合振动

Fig.1 FEM model of simple cable-beam structure

Tab.1 Setting of cable fracture conditions

Fig.2 Displacement and cable force dynamic response of simple cable-beam model under different cable fracture conditions

Fig.3 General arrangement and FEM model diagram of cable-stayed suspension bridge

Fig.4 Dynamic response of bridge structure after fracture of outside suspender cable 50#

Fig.5 Dynamic response of bridge structure after outside stayed cable 38# fracture

Fig.6 Maximum stress of other stayed cables and suspender cables with cable fracture at each position

Fig.7 Maximum stress of cable fracture in different regions of cable-stayed suspension bridge

Tab.2 Table of calculation conditions with cable breaking occurring under train action

Fig.8 1/2 point displacement response of middle span of main beam under working condition 1 and 2

Fig.9 1/2 point displacement response of middle span of main beam under working condition 3 and 4

Fig.10 Train dynamic response in working condition 3 and 4

Fig.11 Dynamic response of bridge and train in working condition 5

Fig.12 Dynamic response of bridge and train in working condition 6

Fig.13 Acceleration response of main girder in working condition 1,4 and 6

Tab.3 Train action ratio in each working condition of suspender cable 50# fracture

Fig.14 Dynamic response of bridge and train in working condition 7

Fig.15 Dynamic response of bridge and train in working condition 8 and 9


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