用于直流微电网的高升压变换器设计及效率优化

doi:10.19595/j.cnki.1000-6753.tces.222228

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摘要针对清洁能源输出电压等级较低难以实现直流微电网并网的问题,提出一种基于开关耦合电感的无源钳位结构的高升压DC-DC变换器。所提变换器采用开关耦合电感结构连接变换器的输入端与输出端。通过调整耦合电感的匝比提高电压增益。此外,采用无源钳位结构回收漏感能量,抑制功率开关管上的电压尖峰,降低功率开关管的电压应力,提高变换器的电能转换效率。该文介绍变换器的工作原理,推导了变换器的稳态特性和各元件的设计参数,详细分析变换器的损耗以及选择有利的参数提高效率,如合理设计耦合电感匝比。搭建一台输入电压为40 V、输出电压为400 V、满载功率为250 W的实验样机,验证了变换器的可行性和理论分析的正确性。实测的最高效率和满载效率分别为97.59 %和97.10 %。

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关键词 ：开关耦合电感, 高升压, DC-DC变换器, 效率优化, 直流微电网

Abstract：Since the excessive use of fossil energy has caused global warming and an energy crisis, clean energy development has gained much more attention. In order to reduce the impact of clean energy based distributed generation grid-connect, improving the conversion efficiency and reliable performance, DC microgrid plays an important role. However, the low output voltage of clean energy should be boosted to a suitable voltage level of the DC microgrid grid-connected. Therefore, a high step-up DC-DC converter using switched coupled inductor and passive clamp circuit is proposed. The switched coupled inductor technique is connected to the input and the output parts, and the voltage gain can be further improved by adjusting the turns ratio of the coupled inductor. In addition, by applying a passive clamp circuit, the energy stored in the leakage inductor is recycled, and the voltage spike on the power switch can be suppressed. Hence, the voltage stress on the switch is reduced, and the efficiency can be improved.
The operating principles and steady-state performance in continuous conduction mode (CCM) and discontinuous conduction mode (DCM) are analyzed in detail. The operating mode is analyzed through the key waveforms and equivalent circuits. Considering the coupling coefficient has no significant effect on the voltage gain, the ideal voltage gain is (2+n)/(1-D) where n=n_s/n_p. Under n=2 and D=0.6, the voltage gain can reach 10. Hence, the proposed converter can achieve high voltage gain. Meanwhile, the voltage stress and current stress of components are studied, including semiconductor devices and passive devices. Moreover, the parameters of the magnetizing inductor and capacitors are designed.
The power loss is divided into four parts: power switch, diode, capacitor, and inductor losses. The theoretical efficiency and non-ideal voltage gain are obtained. Compared with the ideal and non-ideal voltage gains at the appropriate duty cycle, the effect of parasitic parameters of components is negligible. The proposed converter has higher voltage gain and efficiency, lower voltage stress of the power switch, and fewer components than the high step-up converter.
A 40 V-input, 400 V-output, 250 W experimental prototype is built by choosing the proper value and type of components. Considering the inductor loss, the material of core and turns ratio are selected to achieve the highest efficiency. The measured voltage and current of components are consistent with the theoretical analysis. Also, the measured maximum and full-load efficiencies are 97.59 % and 97.10 %, respectively. Total power loss is 5.49 W at 250 W. The proposed converter has the following advantages.
(1) The high voltage gain is obtained by switched coupled inductor, suitable for the DC microgrid grid-connected.
(2) Through the experiment results, the low voltage stress of the power switch validates that the passive clamp circuit inhibits the voltage spike effectively.
(3) The beneficial parameters are chosen to improve the efficiency, verifying the power loss analyses through the experiment.
(4) Fewer components are required, which improves reliability.

Key words： Switched coupled inductor high step-up DC-DC converter efficiency optimization DC microgrid

收稿日期: 2022-11-29

PACS:

TM46

基金资助:国家自然科学基金（62171143, 61871465）和广东省自然科学基金（2021A1515011948）资助项目

通讯作者: 刘洺辛男,1976年生,博士,教授,博士生导师,研究方向为无线传感网络和新能源电力变换技术。E-mail: liumx@gdou.edu.cn

作者简介: 罗朋男,1988年生,讲师,博士研究生,研究方向为电力电子变换技术。E-mail: dqluopeng@163.com

引用本文:

罗朋, 潘锦超, 洪濬哲, 刘洺辛. 用于直流微电网的高升压变换器设计及效率优化[J]. 电工技术学报, 2023, 38(20): 5530-5546. Luo Peng, Pan Jinchao, Hong Junzhe, Liu Mingxin. Design and Efficiency Optimization of a High Step-Up Converter for DC Microgird. Transactions of China Electrotechnical Society, 2023, 38(20): 5530-5546.

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