JZUS - Journal of Zhejiang University SCIENCE

Journal of Zhejiang University SCIENCE A 2025 Vol.26 No.5 P.438-455

Aerodynamics and countermeasures of train-tail swaying inside single-line tunnels

Author(s): Yadong SONG, Yanpeng ZOU, Yuan YAO, Ting QIN, Longjiang SHEN
Affiliation(s): State Key Laboratory of Rail Transit Vehicle System, Southwest Jiaotong University, Chengdu 610031, China; more
Corresponding email(s): yyuan8848@163.com
Key Words: Train-tail swaying, Vortex-induced vibration (VIV), Wake flow field, Train aerodynamics, Vehicle dynamics

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Abstract: In recent years, train-tail swaying of 160 km/h electric multiple units (EMUs) inside single-line tunnels has been heavily researched, because the issue needs to be solved urgently. In this paper, a co-simulation model of vortex-induced vibration (VIV) of the tail car body is established, and the aerodynamics of train-tail swaying is studied. The simulation results were confirmed through a field test of operating EMUs. Furthermore, the influence mechanism of train-tail swaying on the wake flow field is studied in detail through a wind-tunnel experiment and a simulation of a reduced-scaled train model. The results demonstrate that the aerodynamic force frequency (i.‍e., vortex-induced frequency) of the train tail increases linearly with train speed. When the train runs at 130 km/h, with a small amplitude of train-tail swaying (within 10 mm), the vortex-induced frequency is 1.7 Hz, which primarily depends on the nose shape of the train tail. After the tail car body nose is extended, the vortex-induced frequency is decreased. As the swaying amplitude of the train tail increases (exceeding 25 mm), the separation point of the high-intensity vortex in the train wake shifts downstream to the nose tip, and the vortex-induced frequency shifts from 1.7 Hz to the nearby car body hunting (i.‍e., the primary hunting) frequency of 1.3 Hz, which leads to the frequency-locking phenomenon of VIV, and the resonance intensifies train-tail swaying. For the motor vehicle of the train tail, optimization of the yaw damper to improve its primary hunting stability can effectively alleviate train-tail swaying inside single-line tunnels. Optimization of the tail car body nose shape reduces the amplitude of the vortex-induced force, thereby weakening the aerodynamic effect and solving the problem of train-tail swaying inside the single-line tunnels.

单线隧道内列尾晃车的空气动力学及对策研究

作者：宋亚东¹，邹延鹏²，姚远^1,3，秦汀¹，沈龙江³
机构：¹西南交通大学，轨道交通运载系统全国重点实验室，中国成都，610031；²中国中车长客股份有限公司基础服务部，中国长春，130062；³中国中车株洲电力机车有限公司重载、高速大功率电力机车国家重点实验室，中国株洲，412000
目的：近年来，正在运营的160 km/h动力集中动车组在单线隧道内的列尾晃车问题突出，亟待解决。本文旨在通过仿真与试验分析，研究列尾晃车的机理及气动特征，并提出有效的解决措施。
创新点：1.建立尾车流固耦合振动的仿真模型，复现单线隧道内列尾的气动晃车现象，并对其气动特征展开了研究；2.通过现场试验和比例模型的风洞实验，验证列尾晃车的涡激共振机理。
方法：1.通过现场试验，测得该实际运营的动车组通过单线隧道时列尾的晃车频率；2.通过尾车流固耦合振动的仿真分析，阐明列尾的气动晃车机理及影响因素，并提出缓解措施；3.通过列车比例模型的风洞实验与仿真分析，再次验证列尾涡激共振的晃车机理。
结论：1.列尾脱涡力频率与尾鼻外型及列车运行速度有关，且随着列车速度的增加而线性增大。2.对于该动力集中动车组，在130 km/h速度下运行时，列尾的气动脱涡力频率为1.7 Hz；随着列尾晃车幅值的增加，脱涡力频率变为1.3 Hz附近的车体蛇行频率，这表明出现了涡激振动的锁频特性；涡激共振导致了列尾的剧烈晃车现象。3.对于列尾动力车，通过改进抗蛇行减振器或优化尾鼻外型，两种措施均可有效改善列尾在单线隧道内的气动晃车问题。

关键词：列尾晃车；涡激振动；列车尾流；列车空气动力学；车辆系统动力学

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