温湿变工况下地铁车辆横向异常晃动机理分析

doi:10.3901/JME.2025.18.278

机械工程学报 ›› 2025, Vol. 61 ›› Issue (18): 278-287.doi: 10.3901/JME.2025.18.278

• 运载工程 • 上一篇

扫码分享

温湿变工况下地铁车辆横向异常晃动机理分析

文永蓬^1,2, 程瑞平^1,2, 钟硕乔^1,2, 宗志祥³, 周慧^1,2

1. 上海工程技术大学城市轨道交通学院上海 201620;
2. 上海市轨道交通振动与噪声控制技术工程研究中心上海 201620;
3. 上海地铁维护保障有限公司车辆分公司上海 200235

收稿日期:2024-09-23 修回日期:2025-03-28 发布日期:2025-11-08
作者简介:文永蓬(通信作者)，男，1979年出生，博士，副教授，硕士研究生导师。主要研究方向为城市轨道车辆系统动力学、城市轨道车辆服役性能演化、轮轨系统智能运维。E-mail：yp_wen@163.com;程瑞平，男，1997年出生，硕士研究生。主要研究方向为城市轨道交通车辆振动与噪声。钟硕乔，女，1989年出生，博士，讲师。主要研究方向为高频域车辆-轨道耦合动力学、轨道车辆减振降噪设备开发等。
基金资助:
国家自然科学基金(52202477)、西南交通大学轨道交通运载系统全国重点实验室开放课题(TPL2103)、上海市轨道交通结构耐久与系统安全重点实验室开放基金(R202204)和上海市自然科学基金(15ZR1419200)资助项目

Mechanism Analysis of Lateral Abnormal Shaking of Subway Vehicles under Ambient Temperature and Humidity Variation

WEN Yongpeng^1,2, CHENG Ruiping^1,2, ZHONG Shuoqiao^1,2, ZONG Zhixiang³, ZHOU Hui^1,2

1. School of Urban Railway Transportation, Shanghai University of Engineering Science, Shanghai 201620;
2. Shanghai Engineering Research Centre for Vibration and Noise Control Technologies in Railway Transportation, Shanghai 201620;
3. Vehicle Branch of Shanghai Metro Maintenance and Guarantee Co., Ltd., Shanghai 200235

Received:2024-09-23 Revised:2025-03-28 Published:2025-11-08

摘要/Abstract

摘要： 我国幅员辽阔气候类型多样，不同地区温湿度差异较大，地铁车辆在长期服役中的轮轨接触状态和环境息息相关，车体横向异常晃动现象时有发生，严重影响车辆运行品质和旅客乘坐舒适性，环境对地铁车辆横向异常晃动影响有待进一步探索。地铁车辆在地面或者高架桥上运行时处于半开放环境，为揭示不同温湿度运行条件下的地铁车辆横向异常晃动机理，首先对我国不同地区的四座城市全年温湿度变化情况进行调研，建立考虑温湿度运行条件的地铁车辆横向动力学模型，模型中根据温湿变运行条件对三种经典蠕滑理论进行选取；然后，研究服役过程中不同等效锥度下温湿度对车辆横向平稳性的影响，分析不同气候典型城市地铁车辆横向平稳性状况；最后，针对温湿度、等效锥度和车速三个影响因素，对发生异常横向晃动的原因进行讨论。结果表明：环境温湿变工况下，较大轮轨蠕滑力、黏滑摩擦状态转换的频繁切换可能是导致地铁车辆横向异常晃动的原因；在高锥度、高运行速度下，极寒地区更易发生横向异常晃动，高温潮湿地区不易发生横向异常晃动；可通过改善轮轨润滑状态、对等效锥度进行科学管理、发生异常晃动区段适当降速运行等方式，减缓地铁车辆横向异常晃动。所做的工作对认识极寒地区地铁车辆横向异常晃动成因具有良好的参考价值。

关键词: 地铁车辆, 温湿度, 运行平稳性, 横向异常晃动, 等效锥度

Abstract: China boasts a vast territory characterized by diverse climate types, resulting in significant variations in temperature and humidity across different regions. The wheel-rail contact condition of subway vehicles during long-term operation is closely linked to the environment. Occasionally, subway vehicles experience abnormal lateral shaking, which severely impacts vehicle performance and passenger comfort. To obtain a deeper understanding of the mechanisms behind this lateral shaking phenomenon and its relationship with the environment, this study focuses on subway vehicles operating on ground or elevated bridges in semi-open environments, while considering different temperature and humidity conditions. Firstly, the year-round temperature and humidity fluctuations in four cities across various regions of China are investigated. Subsequently, a transverse dynamics model of subway vehicles is established, taking into account the operating conditions influenced by temperature and humidity. Three classical creep theories are selected based on the varying temperature and humidity conditions in the model. The impact of temperature and humidity on the lateral stability of vehicles under different levels of equivalent conicity during service is studied. Additionally, the lateral ride stability of subway vehicles in typical cities with diverse climates was analyzed. Finally, the causes of lateral abnormal shaking are discussed, considering the three influencing factors: temperature and humidity, equivalent conicity, and velocity. The results indicate that the occurrence of lateral abnormal shaking of subway vehicles under changing ambient temperature and humidity conditions may be attributed to the substantial creep force between the wheel-rail interface and the frequent transition between stick and slip friction states. Furthermore, in extremely cold areas, the likelihood of lateral abnormal shaking increases, especially when combined with high conicity and high running speeds. Conversely, such occurrences are less likely in hot and humid regions. To address the issue of lateral abnormal shaking, improvements in the wheel and rail lubrication, effective management of equivalent taper, and appropriate deceleration in sections prone to abnormal shaking are recommended. The work provides valuable insights into understanding the causes of lateral abnormal shaking of subway vehicles, particularly in extremely cold regions.

Key words: subway vehicles, temperature and humidity, running stability, lateral abnormal shaking, equivalent conicity

中图分类号:

U270
O322

文永蓬, 程瑞平, 钟硕乔, 宗志祥, 周慧. 温湿变工况下地铁车辆横向异常晃动机理分析[J]. 机械工程学报, 2025, 61(18): 278-287.

WEN Yongpeng, CHENG Ruiping, ZHONG Shuoqiao, ZONG Zhixiang, ZHOU Hui. Mechanism Analysis of Lateral Abnormal Shaking of Subway Vehicles under Ambient Temperature and Humidity Variation[J]. Journal of Mechanical Engineering, 2025, 61(18): 278-287.

参考文献

[1] 孙建锋，池茂儒，吴兴文，等. 基于能量法的轮对蛇行运动稳定性[J]. 交通运输工程学报，2018，18(2)：82-89. SUN Jianfeng，CHI Maoru，WU Xingwen，et al. Hunting motion stability of wheelset based on energy method[J]. Journal of Traffic and Transportation Engineering，2018，18(2)：82-89.
[2] 陈迪来，沈钢，宗聪聪. 基于耦合度的铁道车辆平稳性分析[J]. 同济大学学报(自然科学版)，2018，46(1)：118-124. CHENG Dilai，SHEN Gang，ZONG Congcong. Analysis of ride quality of railway vehicle based on coupling degree[J]. Journal of Tongji University(Natural Science)，2018，46(1)：118-124.
[3] 何成刚，张佩祯，邹港，等. 自然环境条件下轮轨接触黏着特性研究进展[J]. 摩擦学学报，2022，42(3)：642-656. HE Chenggang，ZHANG Peizhen，ZOU Gang，et al. Research progress on wheel-rail contact adhesion characteristic under environmental conditions[J]. Tribology，2022，42(3)：642-656.
[4] POLACH O. Creep forces in simulations of traction vehicles running on adhesion limit[J]. Wear，2005，258(7-8)：992-1000.
[5] 安博洋，王平，徐义新，等. 基于POLACH方法的轮轨蠕滑曲线研究[J]. 机械工程学报，2018，54(4)：124-131. AN Boyang，WANG Ping，XU Yixin，et al. Study on wheel/rail creep curve based on POLACH’s method[J]. Journal of Mechanical Engineering，2018，54(4)：124-131.
[6] ZHU Y，LYU Y，OLOFSSON U，et al. Mapping the friction between railway wheels and rails focusing on environmental conditions[J]. Wear，2015，324-325：122-128.
[7] ZHU Y，OLOFSSON U，HUA CHEN. Friction between wheel and rail：A pin-on-disc study of environmental conditions and iron oxides[J]. Tribol Lett，2013(52)：327-339.
[8] LYU Y，ZHU Y，OLOFSSON U. Wear between wheel and rail：A pin-on-disc study of environmental conditions and iron oxides[J]. Wear，2015，328：277-285.
[9] LYU YEZHE，BERGSETH E，OLOFSSON U. Open system tribology and influence of weather condition[J]. Scientific Reports，2016，6：32455.
[10] SHI L，MA L，GUO J，et al. Influence of low temperature environment on the adhesion characteristics of wheel-rail contact[J]. Tribology International，2018，127：59-68.
[11] 肖乾，方姣，杨逸航，等. 不同温湿度对高速列车车轮磨耗的影响分析[J]. 机械工程学报，2018，54(4)：14-21. XIAO Qian，FANG Jiao，YANG Yihang，et al. Influence analysis of different temperature and humidity on high-speed train wheel wear[J]. Journal of Mechanical Engineering，2018，54(4)：14-21.
[12] 沈明学，秦涛，李圣鑫，等. 宽温域下高速轮轨界面粘着与车轮表面损伤行为[J]. 交通运输工程学报，2021，21(3)：269-278. SHEN Mingxue，QIN Tao，LI Shengxin，et al. High-speed wheel-rail interfacial adhesion and surface damage behavior of wheel in wide temperature range[J]. Journal of Traffic and Transportation Engineering，2021，21(3)：269-278.
[13] 池茂儒，蔡吴斌，梁树林，等. 高速铁路钢轨打磨偏差对车辆动力学性能的影响[J]. 中国机械工程，2019，30(3)：261-265，283. CHI Maoru，CAI Wubin，LIANG Shulin，et al. Infuluences of rail grinding deviations on vehicle dynamics performances of high speed railways.[J]. China Mechanical Engineering，2019，30(3)：261-265，283.
[14] 李国栋，曾京，池茂儒，等. 高速列车轮轨匹配关系改进研究[J]. 机械工程学报，2018，54(4)：93-100. LI Guodong，ZENG Jing，CHI Maoru，et al. Study on the improvement of wheel-rail matching relationship for high speed train[J]. Journal of Mechanical Engineering， 2018，54(4)：93-100.
[15] 李晓峰，李国栋，宋春元，等. 动车组车辆低频横向晃动分析及改进措施[J]. 城市轨道交通研究，2019，22(2)：66-69，73. LI Xiaofeng，LI Guodong，SONG Chunyuan，et al. Analysis of EMU vehicle low-frequency lateral swaying and improvement measures[J]. Urban Mass Transit， 2019，22(2)：66-69，73.
[16] 张斌，关庆华，李伟，等. 轨道不平顺与轮轨匹配对地铁车辆晃动的影响[J]. 浙江大学学报(工学版)，2022，56(9)：1772-1779. ZHANG Bin，GUAN Qinghua，LI Wei，et al. Influence of track irregularity and wheel-rail profile compatibility on metro vehicle sway[J]. Journal of Zhejiang University (Engineering Science)， 2022， 56(9)：1772-1779.
[17] 中国天气网[EB/OL].[2022-12-02] http://www.weather. com.cn. China Weather Web[EB/OL]. [2022-12-02] http://www. weather.com.cn.
[18] 肖乾，黄碧坤，杨逸航，等. 摩擦系数对高速轮轨磨耗的影响研究[J]. 铁道学报，2016(4)：39-43. XIAO Qian，HUANG Bikun，YANG Yihang，et al. Influence of friction coefficient on wheel-rail wear of high speed rail system[J]. Journal of the China Railway Society，2016(4)：39-43.
[19] 翟婉明. 车辆-轨道耦合动力学[M]. 4版，北京：科学出版社，2015. ZHAI Wanming. Vehicle-track coupled dynamics[M]. 4th edition，Beijing：Science Press，2015.
[20] 罗仁，石怀龙. 高速列车系统动力学[M]. 成都：西南交通大学出版社，2019. LUO Ren，SHI Huailong. High-speed train system dynamics[M]. Chengdu：Southwest Jiaotong University Press，2019.
[21] 吴俊汉，文永蓬，宗志祥，等. 服役条件下提速地铁车辆的横向运动稳定性研究[J]. 振动与冲击，2023，42(3)：304-312. WU Junhan，WEN Yongpeng，ZONG Zhixiang，et al. Study on lateral motion stability of speed-up metro vehicles under service conditions[J]. Journal of Vibration and Shock，2023，42(3)：304-312.
[22] 金学松，刘启跃. 轮轨摩擦学[M]. 北京：中国铁道出版社，2004. JIN Xuesong，LIU Qiyue. Tribology of wheel and rail[M]. Beijing：China Railway Publishing House，2004.
[23] 董昊亮，文永蓬，王向阳，等. 多种接触状态下地铁车辆蛇行运动的稳定性演化[J]. 振动与冲击，2022，41(18)：94-103. DONG Haoliang，WEN Yongpeng，WANG Xiangyang，et al. Stability evolution of metro vehicle serpentine motion under multiple contact conditions[J]. Journal of Vibration and Shock，2022，41(18)：94-103.

温湿变工况下地铁车辆横向异常晃动机理分析

Mechanism Analysis of Lateral Abnormal Shaking of Subway Vehicles under Ambient Temperature and Humidity Variation

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	文永蓬, 董昊亮, 徐祖翰, 周月, 吴俊汉. 考虑温湿变的地铁曲线啸叫噪声形成机理分析[J]. 机械工程学报, 2025, 61(6): 217-227.
[2]	王泽根, 宫岛, 周劲松, 刘广宇. 基于车轮踏面凹磨演化控制的动车组运行稳定性优化研究[J]. 机械工程学报, 2025, 61(16): 283-292.
[3]	石怀龙, 曾京. 基于二系横向主动悬挂的高速列车晃车控制[J]. 机械工程学报, 2024, 60(22): 340-350.
[4]	李牧皛, 刘鹏飞. 复杂轮轨摩擦条件下驱动方式对地铁轮轨动态相互作用影响研究[J]. 机械工程学报, 2024, 60(14): 215-226.
[5]	杨云帆, 凌亮, 张涛, 王开云, 翟婉明. 牵引/制动载荷和复杂黏着条件对地铁轮轨动态相互作用影响研究[J]. 机械工程学报, 2023, 59(12): 284-296.
[6]	胡帛茹, 赵春发, 蔡文锋, 龚俊虎, 冯洋. 两种中低速磁浮车辆动力学性能仿真对比分析[J]. 机械工程学报, 2023, 59(10): 311-322.
[7]	谢晨希, 陶功权, 温泽峰. 地铁车辆制动管路动应力分析及结构优化[J]. 机械工程学报, 2021, 57(10): 118-125.
[8]	肖国放, 陶功权, 刘孟奇, 任德祥, 温泽峰, 周小江, 陆文教. 地铁车辆车轮偏磨原因分析与对策研究[J]. 机械工程学报, 2020, 56(22): 247-255.
[9]	石怀龙, 王建斌, 戴焕云, 邬平波. 地铁车辆轴箱吊耳断裂机理和试验研究[J]. 机械工程学报, 2019, 55(6): 122-128.
[10]	李国栋, 曾京, 池茂儒, 宋春元, 干锋. 高速列车轮轨匹配关系改进研究[J]. 机械工程学报, 2018, 54(4): 93-100.
[11]	肖乾, 方姣, 杨逸航, 昌超. 不同温湿度对高速列车车轮磨耗的影响分析[J]. 机械工程学报, 2018, 54(4): 14-21.
[12]	田师峤, 罗湘萍, 任利惠, 宫岛, 孙煜. 基于地铁车辆二系回转角的主动径向研究[J]. 机械工程学报, 2018, 54(24): 147-153.
[13]	孙煜, 宫岛, 周劲松, 孙文静, 夏张辉. 低地板有轨电车准零刚度二系悬挂系统研究[J]. 机械工程学报, 2017, 53(8): 132-137.
[14]	熊嘉阳, 曹亚博, 肖新标, 温泽峰, 金学松. 曲线轨道参数对直线电动机地铁车辆曲线通过性能的影响[J]. 机械工程学报, 2017, 53(18): 131-137.
[15]	丁杰,张平. 地铁车辆牵引逆变器IGBT模块的结温与疲劳寿命计算[J]. 电气工程学报, 2017, 12(10): 9-18.