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引用次数: 0
摘要
无线电力传输(WPT)系统已有几十年的历史,最近随着电动汽车(EV)的广泛使用而变得非常流行。在这项研究中,我们设计并实现了一种具有串联补偿拓扑结构的电感耦合 WPT 系统,可用于电动汽车。首先,生成了系统的三维麦克斯韦(ANSYS Electromagnetics Suite 18)模型。通过系统地改变每个参数的值,分析了各个参数对耦合系数的影响。结果,得到了一个耦合系数较高的系统。利用该系统,在 Simplorer(ANSYS Electromagnetics Suite 18)电路中对三种不同的负载情况进行了效率研究。随后,构建了系统原型,并将实验结果与模型结果进行了比较。研究结果表明,随着负载电阻的增加,系统的输出功率和效率都会提高。本研究获得的结果有望为改进 WPT 系统设计提供有价值的启示。
Design and Implementation of a Wireless Power Transfer System for Electric Vehicles
Wireless power transfer (WPT) systems, which have been around for decades, have recently become very popular with the widespread use of electric vehicles (EVs). In this study, an inductive coupling WPT system with a series–series compensation topology was designed and implemented for use in EVs. Initially, a 3D Maxwell (ANSYS Electromagnetics Suite 18) model of the system was generated. The impact of individual parameters on the coupling coefficient was analyzed through systematic variations in each parameter’s values. As a result, a system with a higher coupling coefficient was obtained. Using this system, three distinct load cases were investigated for their efficiency in the Simplorer (ANSYS Electromagnetics Suite 18) circuit. Subsequently, a prototype of the system was constructed, and the experimental results were compared with the model’s results. This study shows that both the output power and the efficiency of the system increase as the load resistance increases. The results obtained in this study are anticipated to offer valuable insights for the enhancement of WPT system design.
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