多功能车体间外风挡在高速动车组上的适用性研究

doi:10.3969/j.issn.1004-132X.2025.05.023

摘要/Abstract

摘要： 高速动车组为了增强车辆之间的耦合作用，通常在车端安装了车体间纵向减振器，然而它体积大、成本高，与未来高速动车组车端连接系统轻量化、易操作、高可达需求之间的矛盾突出，为此提出了一种多功能车体间外风挡装置，使其不仅具有传统外风挡隔音减阻、抵挡雨雪的功能，同时具备刚度和阻尼特性，可以替代车体间纵向减振器起到车间减振的作用。基于多功能车体间外风挡的工作原理建立了其子单元结构的数值仿真模型，并通过对比子单元与车体间纵向减振器同工况下的动态特性参数，确定了多功能车体间外风挡能够等效车体间纵向减振器减振功能时子单元的数量，最后利用Simulink将多功能车体间外风挡数值仿真模型与高速动车组车辆动力学模型进行联合仿真，对比研究了车辆无车端减振装置和分别安装车体间纵向减振器与多功能车体间外风挡对车辆动力学性能的影响。研究结果表明，相比于车体间纵向减振器，多功能车体间外风挡可以进一步减小车体的摇头角位移振幅和横向振动加速度幅值，能更加高效地抑制车体的摇头振动，并进一步提高车辆运行的横向平稳性。

关键词: 高速动车组, 轻量化, 多功能车体间外风挡, 车体间纵向减振器, 车辆动力学

Abstract: In order to enhance the inter-vehicle coupling, high-speed EMUs were usually equipped with inter-vehicle longitudinal dampers at the car end. However, the large size and high cost of these dampers were in contradiction with the demands for lightweight, easy-to-operate, high-performance and achievable vehicle-end coupling systems in future high-speed EMUs. In response, a multi-functional inter-vehicle external vestibule diaphragm device was proposed, which had the functions of the traditional external vestibule diaphragm to reduce noise and air resistance and to protect against rain and snow as well as had the characteristics of stiffness and damping that might replace the inter-vehicle longitudinal dampers, playing the role of inter-vehicle vibration damping. The numerical simulation model of the sub-unit structure of the multi-functional inter-vehicle external vestibule diaphragm was established based on the operating principle, and the number of the sub-units when the multi-functional inter-vehicle external vestibule diaphragm might be equivalent to the damping function of the inter-vehicle longitudinal dampers was determined by comparing the dynamic characteristics parameters of the sub-units with those of the inter-vehicle longitudinal damper under the same working conditions. Finally, the dynamic co-simulation of the numerical simulation model of the multi-functional inter-vehicle external vestibule diaphragm and the high-speed EMUs dynamic model were carried out by using Simulink. The influences on the dynamic performance of the vehicles without an inter-vehicle damping device, equipped with the inter-vehicle longitudinal dampers and equipped with the multi-functional inter-vehicle external vestibule diaphragm were compared. The results show that compared with the inter-vehicle longitudinal dampers, the multi-functional inter-vehicle external vestibule diaphragm may further reduce the amplitude of yaw angle displacement of the carbody and the amplitude of lateral vibration acceleration of the carbody, suppress the yaw vibration of the carbody more efficiently, and further improve the lateral ride quality of the vehicle running.

Key words: , high-speed electric multiple unit(EMU), lightweight, multi-functional inter-vehicle external vestibule diaphragm, inter-vehicle longitudinal damper, vehicle dynamics

中图分类号:

U270

赵苍鹏, 代亮成, 池茂儒, 郭兆团, 曾鹏程, 孙宝恺. 多功能车体间外风挡在高速动车组上的适用性研究[J]. 中国机械工程, 2025, 36(05): 1111-1122.

ZHAO Cangpeng, DAI Liangcheng, CHI Maoru, GUO Zhaotuan, ZENG Pengcheng, SUN Baokai. Research on Applicability of Multi-functional Inter-vehicle External Vestibule Diaphragm in High-speed EMUs[J]. China Mechanical Engineering, 2025, 36(05): 1111-1122.

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链接本文: https://www.cmemo.org.cn/CN/10.3969/j.issn.1004-132X.2025.05.023

https://www.cmemo.org.cn/CN/Y2025/V36/I05/1111

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