A High-Efficiency IPT System With Series-Capacitor Full-Bridge Configuration and Inverse Coupled Current Doubler Rectifier for High-Input, Low-Voltage, and High Output Current Applications

A High-Efficiency IPT System With Series-Capacitor Full-Bridge Configuration and Inverse Coupled Current Doubler Rectifier for High-Input, Low-Voltage, and High Output Current Applications

Different from the widely used high-voltage (HV) inductive power transfer (IPT) systems, the low-voltage IPT systems with HV input suffer from the following challenges: the high output current brings high conduction losses in the secondary side, especially at the receiver coil; and the HV conversion...

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Veröffentlicht in:IEEE transactions on power electronics 2024-09, Vol.39 (9), p.11849-11861
Hauptverfasser: Li, Xiaobin, Ma, Hongbo, Tong, Guo, Lu, Song, Qiu, Zhongcai, Xu, Jianping, Feng, Quanyuan
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Sprache:eng
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Efficiency optimization
high output-current applications
high-voltage (HV) conversion ratio
High-voltage techniques
inductive power transfer (IPT) system
Inverters
Rectifiers
series-capacitor full-bridge (SCFB)
Stress
Switching loss
Topology
Voltage
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container_end_page 11861
container_issue 9
container_start_page 11849
container_title IEEE transactions on power electronics
container_volume 39
creator Li, Xiaobin
Ma, Hongbo
Tong, Guo
Lu, Song
Qiu, Zhongcai
Xu, Jianping
Feng, Quanyuan
description Different from the widely used high-voltage (HV) inductive power transfer (IPT) systems, the low-voltage IPT systems with HV input suffer from the following challenges: the high output current brings high conduction losses in the secondary side, especially at the receiver coil; and the HV conversion ratio, such as 400 V input and 24 V output, results in the difficulties in designing the compensation parameters and loosely coupled transformer. To overcome these issues, a novel IPT topology is proposed in this article by incorporating the series-capacitor full-bridge (SCFB) inverter and inverse coupled current doubler rectifier. Thus, the following three improvements are achieved: first, the voltage stress of three primary switches is reduced to half of the input voltage because of the special series capacitor structure. Second, the inherent one-fourth voltage conversion ratio is achieved and reduced greatly the difficulties in designing the compensation parameters. Third, the current flowing through rectifier circuit is reduced to half of conventional full-bridge rectifier. Furthermore, the LC-LCC compensation is employed for matching the proposed SCFB topology while a novel parameter optimization method is proposed to improve the conversion efficiency. To demonstrate the claimed features of the proposed solution, a 1.2 kW IPT prototype with 400 V input, constant voltage 24 V output is built and tested. The measured efficiency curve indicates that the efficiency from 8 to 50 A load keeps above 94.5% and peaks at 96.63%.
doi_str_mv 10.1109/TPEL.2024.3414416
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and the HV conversion ratio, such as 400 V input and 24 V output, results in the difficulties in designing the compensation parameters and loosely coupled transformer. To overcome these issues, a novel IPT topology is proposed in this article by incorporating the series-capacitor full-bridge (SCFB) inverter and inverse coupled current doubler rectifier. Thus, the following three improvements are achieved: first, the voltage stress of three primary switches is reduced to half of the input voltage because of the special series capacitor structure. Second, the inherent one-fourth voltage conversion ratio is achieved and reduced greatly the difficulties in designing the compensation parameters. Third, the current flowing through rectifier circuit is reduced to half of conventional full-bridge rectifier. Furthermore, the LC-LCC compensation is employed for matching the proposed SCFB topology while a novel parameter optimization method is proposed to improve the conversion efficiency. To demonstrate the claimed features of the proposed solution, a 1.2 kW IPT prototype with 400 V input, constant voltage 24 V output is built and tested. 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subjects Efficiency optimization
high output-current applications
high-voltage (HV) conversion ratio
High-voltage techniques
inductive power transfer (IPT) system
Inverters
Rectifiers
series-capacitor full-bridge (SCFB)
Stress
Switching loss
Topology
Voltage
title A High-Efficiency IPT System With Series-Capacitor Full-Bridge Configuration and Inverse Coupled Current Doubler Rectifier for High-Input, Low-Voltage, and High Output Current Applications
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