A fast dynamic model of a two-sided permanent magnet electrodynamic suspension system in a maglev train

IF 1.7 4区 工程技术 Q3 ENGINEERING, CIVIL
Bo Wang, S. Luo, Weihua Ma, Guanchun Li, Zhiyun Wang, Jie Xu, Xiaoxu Zhang
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引用次数: 0

Abstract

In vehicle dynamics research, a dynamics model is essential, as it provides the basis for the demonstration of early system design of vehicle as well as the verification and optimization of the dynamics performance of the final product. To promote the development of a permanent magnet (PM) Electrodynamic Suspension (EDS) in a maglev train, research was carried out in order to explore a fast dynamics modeling, with suspension system based on two-sided PM. First of all, a halbach array was taken as the object of study, with the analytical solution of its magnetic force obtained by theoretical derivation according to magnet filed and 2D analytical method; then, the magnetic force was discretized into a data matrix of displacement, force, and speed; thirdly, the data matrix was introduced in SIMPACK to establish a magnet-track relationship in scalar form, and a dynamics model of the two-sided PM EDS maglev system was finished by the theory of multi-body dynamics modeling; finally, the proposed modeling was validated by the agreement between theoretical derivation and dynamics model calculation of the heaving frequency and pitching frequency of the frame; at the same time, it was also validated by the agreement of dynamic responses between the modeling by vehicle-track coupled dynamics theory and the dynamic model calculation of the levitation gap and force. According to the established dynamics model, dynamic response of the system at the speed of 600 km/h was calculated, and the feasibility of the two-sided PM EDS maglev train was verified. The simulation speed of model which was established before is 50 times that of the mathematical model by the vehicle-track coupled dynamics, thus providing reference for the future research in this regard.
磁悬浮列车双面永磁电动力悬挂系统的快速动力学模型
在车辆动力学研究中,动力学模型是必不可少的,它为车辆早期系统设计的论证以及最终产品动力学性能的验证和优化提供了依据。为促进磁悬浮列车永磁电动悬架系统的发展,开展了基于双面永磁的磁悬浮悬架系统快速动力学建模研究。首先以哈尔巴赫阵列为研究对象,根据磁场和二维解析法,通过理论推导得到其磁力的解析解;然后,将磁力离散成位移、力和速度的数据矩阵;第三,在SIMPACK中引入数据矩阵,以标量形式建立磁轨关系,利用多体动力学建模理论建立双向永磁EDS磁悬浮系统的动力学模型;最后,通过对车架起伏频率和俯仰频率的理论推导和动力学模型计算,验证了所提模型的正确性;同时,车辆-轨道耦合动力学理论模型与悬浮间隙和力的动力学模型计算结果吻合,验证了该方法的有效性。根据建立的动力学模型,计算了系统在600 km/h速度下的动态响应,验证了双向PM EDS磁悬浮列车的可行性。之前建立的模型的仿真速度是车轨耦合动力学数学模型的50倍,为今后的研究提供了参考。
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来源期刊
CiteScore
4.80
自引率
10.00%
发文量
91
审稿时长
7 months
期刊介绍: The Journal of Rail and Rapid Transit is devoted to engineering in its widest interpretation applicable to rail and rapid transit. The Journal aims to promote sharing of technical knowledge, ideas and experience between engineers and researchers working in the railway field.
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