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基于氮化镓的6.6千瓦、450伏双向车载充电器的开发,集成了1千瓦、12伏辅助DC-DC转换器,具有高功率密度。

Development of GaN-Based, 6.6 kW, 450 V, Bi-Directional On-Board Charger with Integrated 1 kW, 12 V Auxiliary DC-DC Converter with High Power Density.

作者信息

Reali Alessandro, Alemanno Alessio, Ronchi Fabio, Rossi Carlo, Florian Corrado

机构信息

Department of Electrical, Electronic, and Information Engineering "Guglielmo Marconi", University of Bologna, 40136 Bologna, Italy.

Arca Tecnologie s.r.l., 40026 Imola, Italy.

出版信息

Micromachines (Basel). 2024 Dec 2;15(12):1470. doi: 10.3390/mi15121470.

DOI:10.3390/mi15121470
PMID:39770223
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11679712/
Abstract

Automotive-grade GaN power switches have recently been made available in the market from a growing number of semiconductor suppliers. The exploitation of this technology enables the development of very efficient power converters operating at much higher switching frequencies with respect to components implemented with silicon power devices. Thus, a new generation of automotive power components with an increased power density is expected to replace silicon-based products in the development of higher-performance electric and hybrid vehicles. 650 V GaN-on-silicon power switches are particularly suitable for the development of 3-7 kW on-board battery chargers (OBCs) for electric cars and motorcycles with a 400 V nominal voltage battery pack. This paper describes the design and implementation of a 6.6 kW OBC for electric vehicles using automotive-grade, 650 V, 25 mΩ, discrete GaN switches. The OBC allows bi-directional power flow, since it is composed of a bridgeless, interleaved, totem-pole PFC AC/DC active front end, followed by a dual active bridge (DAB) DC-DC converter. The OBC can operate from a single-phase 90-264 Vrms AC grid to a 200-450 V high-voltage (HV) battery and also integrates an auxiliary 1 kW DC-DC converter to connect the HV battery to the 12 V battery of the vehicle. The auxiliary DC-DC converter is a center-tapped phase-shifted full-bridge (PSFB) converter with synchronous rectification. At the low-voltage side of the auxiliary converter, 100 V GaN power switches are used. The entire OBC is liquid-cooled. The first prototype of the OBC exhibited a 96% efficiency and 2.2 kW/L power density (including the cooling system) at a 60 °C ambient temperature.

摘要

最近,越来越多的半导体供应商已将汽车级氮化镓功率开关推向市场。利用这项技术能够开发出效率极高的功率转换器,与采用硅功率器件的组件相比,其工作开关频率要高得多。因此,新一代功率密度更高的汽车功率组件有望在高性能电动汽车和混合动力汽车的开发中取代硅基产品。650V硅基氮化镓功率开关特别适用于为标称电压为400V电池组的电动汽车和摩托车开发3-7kW车载电池充电器(OBC)。本文介绍了一款使用汽车级650V、25mΩ分立氮化镓开关的电动汽车6.6kW OBC的设计与实现。该OBC允许双向功率流,因为它由一个无桥、交错、图腾柱PFC AC/DC有源前端组成,后面跟着一个双有源桥(DAB)DC-DC转换器。该OBC可以从单相90-264Vrms交流电网运行到200-450V高压(HV)电池,并且还集成了一个辅助1kW DC-DC转换器,用于将HV电池连接到车辆的12V电池。辅助DC-DC转换器是一个带有同步整流的中心抽头移相全桥(PSFB)转换器。在辅助转换器的低压侧,使用100V氮化镓功率开关。整个OBC采用液冷方式。该OBC的第一个原型在60°C环境温度下表现出96%的效率和2.2kW/L的功率密度(包括冷却系统)。

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引用本文的文献

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