Vibrations control of railway vehicles using decentralized proportional integral derivative controller with flow direction optimization algorithm

IF 1.1 Q4 ENGINEERING, MECHANICAL

Journal of Mechanical Engineering and Sciences Pub Date : 2023-09-27 DOI:10.15282/jmes.17.3.2023.9.0763

Nitish Kumar, Amit Kumar

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引用次数: 0

Abstract

The reduction of vibration-induced discomfort in vehicles is an important goal in the field of transportation engineering. Several mathematical models with various controlling techniques, from classical to modern, have been employed to achieve better ride comfort. Still, no comprehensive solution has yet been found. Therefore, this paper proposes a 17-degree-of-freedom (minimum number of coordinates) dynamic model of a full-scale railway vehicle integrated with wheel-rail contact forces and an active suspension system. Two controllers, termed system and force tracking controllers, suppress the vehicle body's vibrations. Based on a multi-loop control structure, three optimally tuned Proportional Integral Derivative controllers evaluate the desired control forces and performs the system controller’s action. While the force-tracking controller generates the command voltage to track that forces. The parameters of controllers are tuned with a novel metaheuristic optimization algorithm known as the flow direction algorithm (FDA), and the results are compared with two other optimization techniques, i.e., particle swarm optimization and ant colony optimization. The simulated results show that the ride comfort of the vehicle is improved with FDA, as the root mean square values of the lateral, roll, and yaw accelerations are reduced by 42.01%, 33.12%, and 48.24%, respectively. Moreover, the simulated results of the proposed model are validated with the experimental results of accelerations. The simulated results show that the proposed system tuned with the metaheuristic algorithm outperforms with a significant reduction in vehicle vibrations.

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流动方向优化的分散比例积分导数控制器在轨道车辆振动控制中的应用

减少车辆振动引起的不适是交通运输工程领域的一个重要目标。几个数学模型与各种控制技术，从古典到现代，已被用于实现更好的乘坐舒适性。然而，目前还没有找到全面的解决办法。因此，本文提出了考虑轮轨接触力和主动悬架系统的全尺寸轨道车辆17自由度(最小坐标数)动力学模型。两个控制器，称为系统和力跟踪控制器，抑制车身的振动。基于多环控制结构，三个最优调谐比例积分导数控制器评估所需的控制力并执行系统控制器的动作。而力跟踪控制器产生命令电压来跟踪力。采用一种新的元启发式优化算法——流向优化算法(FDA)对控制器参数进行了优化，并将优化结果与粒子群优化和蚁群优化进行了比较。仿真结果表明，采用FDA后，车辆的横向加速度、侧滚加速度和偏航加速度的均方根值分别降低了42.01%、33.12%和48.24%，改善了车辆的乘坐舒适性。并将模型的仿真结果与加速度实验结果进行了验证。仿真结果表明，采用元启发式算法调整后的系统具有较好的性能，显著降低了车辆振动。

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

Journal of Mechanical Engineering and Sciences ENGINEERING, MECHANICAL-

自引率

0.00%

发文量

审稿时长

20 weeks

期刊介绍： The Journal of Mechanical Engineering & Sciences "JMES" (ISSN (Print): 2289-4659; e-ISSN: 2231-8380) is an open access peer-review journal (Indexed by Emerging Source Citation Index (ESCI), WOS; SCOPUS Index (Elsevier); EBSCOhost; Index Copernicus; Ulrichsweb, DOAJ, Google Scholar) which publishes original and review articles that advance the understanding of both the fundamentals of engineering science and its application to the solution of challenges and problems in mechanical engineering systems, machines and components. It is particularly concerned with the demonstration of engineering science solutions to specific industrial problems. Original contributions providing insight into the use of analytical, computational modeling, structural mechanics, metal forming, behavior and application of advanced materials, impact mechanics, strain localization and other effects of nonlinearity, fluid mechanics, robotics, tribology, thermodynamics, and materials processing generally from the core of the journal contents are encouraged. Only original, innovative and novel papers will be considered for publication in the JMES. The authors are required to confirm that their paper has not been submitted to any other journal in English or any other language. The JMES welcome contributions from all who wishes to report on new developments and latest findings in mechanical engineering.