Digitally Controlled Bridgeless Totem-Pole Power Factor Corrector

Q3 Environmental Science Tikrit Journal of Engineering Sciences Pub Date : 2022-11-22 DOI:10.25130/tjes.29.3.10

Khalaf S. Gaeid, Waleed M. Zapar, Rami A. Maher, A. L. Salih, Mohib A. Qasim

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引用次数: 2

Abstract

This paper presents the steps of designing, controlling, and implementing a 3kW Gallium-Nitride (GaN)-based bridgeless totem-pole power factor corrector (PFC) for single-phase 230V rectifier applications. The bridgeless design of such a converter combined with zero-recovery switching loss of GaN transistors enables more efficient design operation compared to traditional Si-based solutions. Thermally efficient design with forced-air cooling for the switching devices increased the power density beyond 100W/inch3 while keeping the power switches temperatures less than the thermal limits. Continuous Conduction Mode (CCM) was adopted in this work for better converter stability and was analyzed thoroughly along with the losses breakdown for each part of the converter. The digital control model of the converter was discussed in detail accompanied by the hardware design steps for the converter. Experimental results proved a maximum efficiency of 98.9% during 2.4kW operation and 98.6% during 3kW (full load) operation with minimum Total Harmonics Distortion (THD) of AC input current of 2.78% at rated current (13A) when converting the AC input voltage (230V) to 400 VDC.

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数字控制无桥图腾柱功率因数校正器

本文介绍了用于单相230V整流器应用的3kW氮化镓(GaN)基无桥符号极功率因数校正器(PFC)的设计、控制和实现步骤。这种转换器的无桥设计与GaN晶体管的零恢复开关损耗相结合，与传统的基于si的解决方案相比，可以实现更高效的设计操作。采用强制空气冷却的热效率设计将开关器件的功率密度提高到100W/inch3以上，同时保持功率开关的温度低于热极限。为了提高变换器的稳定性，本文采用连续导通模式(CCM)，并对变换器各部分的损耗进行了分析。详细讨论了变换器的数字控制模型，并给出了变换器的硬件设计步骤。实验结果表明，当将交流输入电压(230V)转换为400 VDC时，在额定电流(13A)下，交流输入电流的总谐波失真(THD)最小为2.78%，在2.4kW时效率最高，在3kW(满载)时效率最高为98.9%。

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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