Effects of Crosswind on Pantograph–Catenary Wear Using Nonlinear Multibody System Dynamic Algorithms

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC World Electric Vehicle Journal Pub Date : 2023-09-06 DOI:10.3390/wevj14090250
Siripong Daocharoenporn, M. Mongkolwongrojn
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Abstract

In this study, a multibody system (MBS) computational framework is developed to determine the exact location of the contact point and wear prediction resulting from the pantograph–catenary interaction. The railroad vehicle models in the MBS computational framework comprise rigid-body railroad vehicles, rigid-body pantograph systems, and flexible catenary systems. To avoid incremental rotation, the nonlinear finite element absolute nodal coordinate formulation is used to model a flexible catenary system in the MBS computational framework. To avoid co-simulation processes, the rigid-body railroad vehicle and the pantograph and flexible catenary systems were integrated into the MBS algorithms. The pantograph–catenary interaction is modeled using an elastic contact formulation developed to include the effect of pantograph–catenary separation and sliding contact. The proposed MBS approach evaluates the location of the contact point, contact force, and normal wear rate (NWR) from the mechanical and electrical contributions. This investigation considers the vibration caused by a crosswind scenario and determines the numerical result in the case of a steady crosswind scenario. The steady crosswind scenario contains the advantage of pantograph–catenary aerodynamic design, and the vibration of the catenary system remains significant after the excitation of a steady crosswind. In the case of a steady crosswind, the higher value of the steady crosswind effect significantly increases the mean contact force and the NWR from the mechanical contribution. After crosswind load disturbances, the mean contact force decreases, but the standard deviation of the contact force increases. Therefore, the NWR from the electrical contribution increases significantly. However, the total NWR increases with the crosswind velocity.
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用非线性多体系统动力学算法研究横风对受电弓-接触网磨损的影响
在本研究中,开发了一个多体系统(MBS)计算框架,以确定接触点的准确位置,并预测弓网相互作用产生的磨损。MBS计算框架中的铁路车辆模型包括刚体铁路车辆、刚体受电弓系统和柔性接触网系统。为了避免增量旋转,在MBS计算框架中,使用非线性有限元绝对节点坐标公式对柔性悬链线系统进行建模。为了避免协同仿真过程,将刚体轨道车辆、受电弓和柔性接触网系统集成到MBS算法中。使用弹性接触公式对弓网相互作用进行建模,该公式包括弓网分离和滑动接触的影响。所提出的MBS方法根据机械和电气贡献来评估接触点的位置、接触力和正常磨损率(NWR)。本研究考虑了侧风情景引起的振动,并确定了稳定侧风情景下的数值结果。稳定侧风场景包含受电弓-接触网空气动力学设计的优势,并且在稳定侧风激励后,接触网系统的振动仍然显著。在稳定侧风的情况下,稳定侧风效应的较高值显著增加了机械贡献的平均接触力和NWR。侧风荷载扰动后,平均接触力减小,但接触力的标准偏差增大。因此,来自电贡献的NWR显著增加。然而,总NWR随着侧风速度的增加而增加。
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来源期刊
World Electric Vehicle Journal
World Electric Vehicle Journal Engineering-Automotive Engineering
CiteScore
4.50
自引率
8.70%
发文量
196
审稿时长
8 weeks
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