A Novel Buck-boost Converter and Its Control Strategy for New Energy Power Generation

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A Novel Buck-boost Converter and Its Control Strategy for New Energy Power Generation

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[1]LUO Peng,CHEN Guanghao,YANG Donghong,et al.A Novel Buck-boost Converter and Its Control Strategy for New Energy Power Generation[J].Journal of Zhengzhou University (Engineering Science),2024,45(02):97-105.[doi:10.13705/j.issn.1671-6833.2023.05.016]

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Journal of Zhengzhou University (Engineering Science)[ISSN 1671-6833/CN 41-1339/T] Volume: 45 Number of periods: 2024 02 Page number: 97-105 Column: Public date: 2024-03-06

Title:: A Novel Buck-boost Converter and Its Control Strategy for New Energy Power Generation

Author(s):: LUO Peng; CHEN Guanghao; YANG Donghong; GUO Lei; School of Electronic and Information Engineering, Guangdong Ocean University, Zhanjiang 524088, China

Keywords:: coupled inductor; buck-boost converter; small signal model; PI controller; feedforward control

CLC:: -

DOI:: 10.13705/j.issn.1671-6833.2023.05.016

Abstract:: To solve the problem that the output voltage of the new energy power generation device varied greatly and it was difficult to realize energy storage, a novel single-switch coupled buck-boost converter based on PI controller and feed-forward control was presented. The voltage gain could be adjusted by the turns ratio of the coupled inductor, and the voltage stress on the power switch was suppressed by the passive clamped circuit with recycled leakage inductor energy. Compared with traditional buck-boost converter, the proposed converter had the advantages of wider voltage conversion ratio, continuous input current, and low voltage stress on power switch. Combing PI controller with feedforward control strategy, superior input transient response of the converter during the whole input voltage range is obtained. The operating principles and steady-state characteristics of proposed converter were analyzed and derived in detail, respectively, and the performances were compared with other single-tube buck-boost converters. The small-signal model was derived, and the correctness of PI parameter design was verified by bode diagram. The design process of PI controller combined with feedforward control strategy was analyzed. Finally, an experimental prototype with a rated power of 100 W, 20 V to 60 V input, and 48 V output was built to verify the performance of the proposed converter in boost mode and buck mode, and the feasibility of PI controller combined with feed-forward control strategy. The measured maximum efficiencies with the boost and buck modes were 97. 08% and 97. 10%, respectively.

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Last Update: 2024-03-08