主动径向与迫导向转向架曲线通过性能差异化研究

doi:10.3901/JME.2025.22.189

机械工程学报 ›› 2025, Vol. 61 ›› Issue (22): 189-197.doi: 10.3901/JME.2025.22.189

• 运载工程 • 上一篇

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主动径向与迫导向转向架曲线通过性能差异化研究

田师峤^1,2, 罗湘萍¹, 肖春昱¹, 周劲松¹, 宫岛¹, 赵增闯^1,3

1. 同济大学铁道与城市轨道交通研究院上海 201804;
2. 西南交通大学轨道交通运载系统全国重点实验室成都 610031;
3. 中车浦镇阿尔斯通运输系统有限公司芜湖 241000

收稿日期:2024-11-05 修回日期:2025-05-12 发布日期:2026-01-10
作者简介:田师峤(通信作者),男,1992年出生,副研究员。主要研究方向为轨道车辆动力学及主动径向控制。E-mail:tianshiqiao291@163.com
基金资助:
国家自然科学基金(52202479); 四川省自然科学基金青年基金(2025ZNSFSC1323); 中国博士后科学基金(2021M702477); 轨道交通运载系统全国重点实验室自主课题(202JRVL-T17)资助项目。

Comparative Assessment of Curving Performance in Active Steering and Forced Steering Bogies

TIAN Shiqiao^1,2, LUO Xiangping¹, XIAO Chunyu¹, ZHOU Jinsong¹, GONG Dao¹, ZHAO Zengchuang^1,3

1. Institute of Rail Transit, Tongji University, Shanghai 201804;
2. State Key Laboratory of Rail Transit Vehicle System, Southwest Jiaotong University, Chengdu 610031;
3. CRRC Puzhen Alstom Transportation Systems Limited, Wuhu 241000

Received:2024-11-05 Revised:2025-05-12 Published:2026-01-10

摘要/Abstract

摘要： 采用主动径向或迫导向转向架均可以大幅提高轨道车辆的曲线通过性能。但两种径向转向架由于导向方式的不同，在进出圆曲线的过渡段有着不同的瞬态动力学性能。并且，主动径向与迫导向转向架均改变了传统转向架一系悬挂处的结构与物理拓扑，因此同一动力学参数对不同转向架曲线通过性能的影响规律也会存在差异。为回答上述问题，首先建立主动径向、迫导向车辆动力学模型，分别分析其在两种典型曲线工况上的曲线通过性能。研究结果表明，迫导向转向架的导向方式存在几何惯性滞后，因此其曲线通过性能在进出圆曲线的过渡段会降低。而只要主动径向系统径向动作超前或滞后的距离不超过三分之一车辆定距，且最大动作速度不低于6.5 mm/s，那么主动径向转向架的曲线通过性能便优于迫导向转向架。然后采用灵敏度分析方法，以磨耗数为指标，综合比较关键动力学参数对传统、主动径向、迫导向转向架曲线通过性能的影响规律。结果表明，主动径向与迫导向转向架将轮对导向的行为与一系悬挂刚度解耦，因此在参数设计时可以不用考虑一系悬挂刚度对曲线通过性能的制约，为转向架参数设计带来便利。

关键词: 径向转向架, 动力学, 曲线通过性能, 灵敏度分析

Abstract: The curving performance of a rail vehicle may be significantly enhanced by employing either active or forced steering bogies. Nevertheless, the transient dynamics at the transition curve differ between these two types of steering bogies due to their distinct steering mechanisms. Moreover, as both active and forced steering bogies alter the structure and physical topology of a conventional bogie suspension, the manner in which the same dynamic parameters influence curving performance might also exhibit discrepancies. To address these questions, active and forced steering vehicle dynamics models have been established in this study, followed by an analysis of the curving performance of both vehicles on two typical curves. Findings have revealed that a geometric inertia lag is experienced by the forced-steering bogie, thereby diminishing its curving performance during transitions curve. If the response lag of the active steering system remains below one third of the vehicle pitch and the maximum speed of movement does not fall short of 6.5 mm/s, the curving performance of the active steering bogie has been shown to surpass that of the forced steering bogie. Then a sensitivity analysis method has been employed, with the wear number utilized as an indicator, to comprehensively contrast the influence patterns of key dynamic parameters on the curving performance of conventional, active steering, and forced steering bogies. Results have demonstrated that the wheelset steering behavior is decoupled from the primary suspension stiffness by active and forced steering bogies, thereby enabling the elimination of primary suspension stiffness constraints on curving performance during parametric design, which brings convenient to bogie design.

Key words: steering bogie, dynamics, curving performance, sensitivity analysis

中图分类号:

TG156

田师峤, 罗湘萍, 肖春昱, 周劲松, 宫岛, 赵增闯. 主动径向与迫导向转向架曲线通过性能差异化研究[J]. 机械工程学报, 2025, 61(22): 189-197.

TIAN Shiqiao, LUO Xiangping, XIAO Chunyu, ZHOU Jinsong, GONG Dao, ZHAO Zengchuang. Comparative Assessment of Curving Performance in Active Steering and Forced Steering Bogies[J]. Journal of Mechanical Engineering, 2025, 61(22): 189-197.

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主动径向与迫导向转向架曲线通过性能差异化研究

Comparative Assessment of Curving Performance in Active Steering and Forced Steering Bogies

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