Nanocrystalline Core Losses in High Power IPT Systems for EV Charging Applications

IF 5 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of power electronics Pub Date : 2025-03-24 DOI:10.1109/OJPEL.2025.3553159

Wenting Zhang;Seho Kim;Grant A. Covic

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Abstract

This article discusses the effectiveness of the nanocrystalline cores in high-power inductive power transfer (IPT) systems. The core losses and equivalent series resistances (ESRs) of the ferrite and nanocrystalline cores in IPT pads are simulated in ANSYS Maxwell based on measurements of their magnetic properties using the partial cancellation method. Simulated results are verified using experiments of core loss measurements in IPT pads. Both simulated and experimental findings show that the ESR of IPT pads using fractured nanocrystalline cores decreases with higher excitation current, contrary to the typical behaviour of an IPT pad built using ferrite. This behaviour is in accordance with characterisation results of ferrite and nanocrystalline toroids and is analysed using Steinmetz coefficients. A 10 kW IPT system is set up to validate the effectiveness of the fractured nanocrystalline cores. Compared to TDK N95 ferrite cores, an IPT system using non-fractured nanocrystalline cores has a 0.6% reduction in dc-dc efficiency, while that of fractured nanocrystalline cores improves by 0.1% and operates with a lower magnetic flux density within the magnetic core.

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用于电动汽车充电的大功率IPT系统中的纳米晶磁芯损耗

本文讨论了纳米晶铁芯在大功率感应功率传输（IPT）系统中的有效性。利用ANSYS Maxwell软件对IPT焊盘中铁氧体和纳米晶铁芯的磁芯损耗和等效串联电阻（esr）进行了部分消去法模拟。模拟结果通过IPT焊盘铁芯损耗测量实验得到验证。模拟和实验结果均表明，采用断裂纳米晶铁芯的IPT衬垫的ESR随着激励电流的增加而降低，这与使用铁氧体构建的IPT衬垫的典型行为相反。这种行为与铁氧体和纳米晶环形体的表征结果一致，并使用Steinmetz系数进行了分析。建立了一个10 kW的IPT系统来验证裂缝纳米晶岩心的有效性。与TDK N95铁氧体铁芯相比，采用非断裂纳米晶铁芯的IPT系统的dc-dc效率降低了0.6%，而采用断裂纳米晶铁芯的IPT系统的dc-dc效率提高了0.1%，并且磁芯内的磁通密度更低。

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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