Analysis of Switched Inductor‐Based High Gain SEPIC for Microgrid Systems

DC microgrids are getting more attention because majority of the renewable energy sources generate DC output voltage and also modern gadgets require DC voltage for its operation. In this work, high gain SEPIC (HGSC) topology is derived from switched inductor voltage boosting cell (SIVBC). The HGSC c...

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Veröffentlicht in:International transactions on electrical energy systems 2024-01, Vol.2024 (1)
Hauptverfasser: K., Jayanthi, Senthil Kumar, N., J., Gnanavadivel, Stonier, Albert Alexander, Peter, Geno, Arun, Vijayakumar, Ganji, Vivekananda
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Sprache:eng
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Zusammenfassung:DC microgrids are getting more attention because majority of the renewable energy sources generate DC output voltage and also modern gadgets require DC voltage for its operation. In this work, high gain SEPIC (HGSC) topology is derived from switched inductor voltage boosting cell (SIVBC). The HGSC converter provides continuous source current due to SIVBC and high conversion ratio and achieves maximum efficiency of 97.88% when compared with the existing SEPIC topology. The operating modes, conversion ratio expression, power loss distribution, voltage drop, current stress of the semiconductor devices, and efficiency are also analysed. In DC microgrids, the HGSC intends to track the peak power from solar PV array. An incremental conductance algorithm is employed to track the peak power of the solar PV modules. The power flow in the microgrid system is analysed by employing synchronous reference frame theory‐based current controller. In order to validate the theoretical concepts of the HGSC converter, the hardware model is developed for the load rating of 1,000 W/380 V output voltage.
ISSN:2050-7038
2050-7038
DOI:10.1155/2024/8591539