Double switch two leg high gain boost converter for renewable energy applications in a DC microgrid

2020 IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES) Pub Date : 2020-12-16 DOI:10.1109/PEDES49360.2020.9379449

M. Samiullah, I. Ashraf, A. Iqbal, J. Lam, P. K. Maroti

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引用次数: 4

Abstract

The voltage output at the terminals of a DC generating source such as Photovoltaic and Fuel cells is not enough to be integrated with the DC bus of a microgrid. Therefore, an efficient DC-DC converter is demanded for boosting the voltage. The available conventional converter needs to be operated at an extremely large duty ratio resulting in various detrimental effects on the converter circuit. Impaired transient response, increased EMI and voltage spikes are observed as a consequence of large duty ratio. High gain DC/DC converters are thus sought which must be attaining sufficiently high voltage on moderate duty ratio. This paper presents a novel converter utilizing two switches and switch inductors to come across the voltage suitable for integration of a renewable energy source into a DC microgrid. This particular converter does not uses transformers, coupled inductors, or some cascaded configurations. Moreover, the switches being controlled simultaneously do not need a complex control circuitry. The analysis of the introduced converter is done in CCM and DCM along with the boundary conditions. The performance is verified through simulation and experimental results.

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用于直流微电网中可再生能源应用的双开关双支路高增益升压变换器

光伏电池和燃料电池等直流电源的终端输出电压不足以与微电网的直流母线集成。因此，需要一种高效的DC-DC变换器来提高电压。现有的传统变换器需要在非常大的占空比下工作，从而对变换器电路产生各种不利影响。由于占空比较大，可以观察到瞬态响应受损、电磁干扰增加和电压尖峰。因此，高增益DC/DC转换器必须在中等占空比下获得足够高的电压。本文提出了一种新型的转换器，利用两个开关和开关电感来获得适合将可再生能源集成到直流微电网中的电压。这种特殊的转换器不使用变压器、耦合电感或一些级联配置。此外，同时控制的开关不需要复杂的控制电路。对所引入的变换器在CCM和DCM中进行了分析，并给出了边界条件。通过仿真和实验结果验证了其性能。

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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2020 IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES)

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