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Applications of Serial-Parallel Compensated Resonant Topology in Wireless Charger System Used in Electric Vehicles

Applications of Serial-Parallel Compensated Resonant Topology in Wireless Charger System Used in Electric Vehicles
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摘要 There are lots of factors that can influence the wireless charging efficiency in practice, such as misalignment and air-gap difference, which can also change all the charging parameters. To figure out the relationship between those facts and system, this paper presents a serial-parallel compensated(SPC) topology for electric vehicle/plug-in hybrid electric vehicle(EV/PHEV) wireless charger and provides all the parameters changing with corresponding curves. An ANSYS model is built to extract the coupling coefficient of coils. When the system is works at constant output power, the scan frequency process can be applied to wireless power transfer(WPT) and get the resonant frequency. In this way, it could determine the best frequency for system to achieve zero voltage switching status and force the system to hit the maximum transmission efficiency. Then frequency tracking control(FTC) is used to obtain the highest system efficiency. In the paper, the designed system is rated at 500 W with 15 cm air-gap, the overall efficiency is 92%. At the end, the paper also gives the consideration on how to improve the system efficiency. There are lots of factors that can influence the wireless charging efficiency in practice, such as misalignment and air-gap difference, which can also change all the charging parameters. To figure out the relationship between those facts and system, this paper presents a serial-parallel compensated(SPC) topology for electric vehicle/plug-in hybrid electric vehicle(EV/PHEV) wireless charger and provides all the parameters changing with corresponding curves. An ANSYS model is built to extract the coupling coefficient of coils. When the system is works at constant output power, the scan frequency process can be applied to wireless power transfer(WPT) and get the resonant frequency. In this way, it could determine the best frequency for system to achieve zero voltage switching status and force the system to hit the maximum transmission efficiency. Then frequency tracking control(FTC) is used to obtain the highest system efficiency. In the paper, the designed system is rated at 500 W with 15 cm air-gap, the overall efficiency is 92%. At the end, the paper also gives the consideration on how to improve the system efficiency.
作者 FU Yongsheng LEI Ming GAO Leilei ZHOU Gang 付永升;雷鸣;高磊磊;周刚(College of Electroric Information Engineering,Xi’an Technological University;Shaanxi Yanchang Petroleum Anyuan Chemical Co. ,Ltd.)
出处 《Journal of Donghua University(English Edition)》 EI CAS 2019年第1期15-22,共8页 东华大学学报(英文版)
基金 Department of Technology in Shaanxi Province,China(No.2016GY-126)
关键词 wireless power transfer(WPT) zero voltage switching frequency tracking control(FTC) ELECTRIC vehicle/plug-in hybrid ELECTRIC vehicle(EV/PHEV) wireless power transfer(WPT) zero voltage switching frequency tracking control(FTC) electric vehicle/plug-in hybrid electric vehicle(EV/PHEV)
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