Active Displacement Control of Pantograph-catenary System for a Half-body Railway Model

Q2 Engineering

Periodica Polytechnica Transportation Engineering Pub Date : 2024-02-20 DOI:10.3311/pptr.23285

Munaliza Ibrahim, Mohd Azman Abdullah, Mohd Hanif Harun, Fathiah Mohamed Jamil, Fauzi Ahmad

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引用次数: 0

Abstract

The pantograph is an essential component that provides electrical contact between the overhead wires and the electric train. The quality of the current collection in high-speed trains is directly influenced by the mechanical interaction between the pantograph collector head and the overhead contact line. To overcome these challenges and improve pantograph performance, researchers and engineers have explored innovative solutions, including the introduction of active control mechanisms. Excitation by the vehicle is one of the normal disturbances in the dynamic interaction of the pantograph and the overhead line. The vertical effects of vehicle-track vibrations on the interaction between the pantograph and the overhead contact line have not yet been adequately researched. To fill this research gap, this study establishes models for both the pantograph-catenary interaction and the vehicle-track system. In this study, the performance of the modified Skyhook-Proportional-Integral-Derivative (PID) controller was investigated for a half-body of a railway pantograph-catenary system. Track irregularities such as step, sine, and random were applied to perturb the suspension system. The performance of both passive and active systems was investigated by considering the track irregularities as a basis. The root mean square analysis (RMS) found that active displacement control of pantograph-catenary systems for a half-body railway model equipped with modified Skyhook-PID controllers performed better than the passive systems. In summary, the future experimental approach for active half-body railway model could incorporate this simple modification of the Skyhook-PID controller.

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半体铁路模型受电弓-全轮系统的主动位移控制

受电弓是在架空导线和电力列车之间提供电接触的重要部件。受电弓集电头与架空接触线之间的机械相互作用直接影响高速列车的集电质量。为了克服这些挑战并提高受电弓的性能，研究人员和工程师们探索了创新的解决方案，包括引入主动控制机制。车辆的振动是受电弓和架空线路动态交互过程中的正常干扰之一。车辆轨道振动对受电弓和架空接触线之间相互作用的垂直影响尚未得到充分研究。为了填补这一研究空白，本研究建立了受电弓与轨道的相互作用以及车辆与轨道系统的模型。在这项研究中，针对铁路受电弓-轨道系统的半体，研究了改进型 Skyhook 比例积分微分 (PID) 控制器的性能。对悬挂系统施加了阶梯、正弦和随机等轨道不规则扰动。以轨道不规则性为基础，研究了被动和主动系统的性能。均方根分析（RMS）发现，在半体铁路模型中，配备改进型 Skyhook-PID 控制器的受电弓-悬挂系统的主动位移控制性能优于被动系统。总之，未来的主动式半体铁路模型实验方法可以采用这种对 Skyhook-PID 控制器的简单修改。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Periodica Polytechnica Transportation Engineering Engineering-Automotive Engineering

CiteScore

2.60

自引率

0.00%

发文量

期刊介绍： Periodica Polytechnica is a publisher of the Budapest University of Technology and Economics. It publishes seven international journals (Architecture, Chemical Engineering, Civil Engineering, Electrical Engineering, Mechanical Engineering, Social and Management Sciences, Transportation Engineering). The journals have free electronic versions.