ZVS Soft Switching Operation Region Analysis of Modular Multi Active Bridge Converter Under Single Phase Shift Control

Modular multi active bridge (MMAB) converter can provide multiple dc ports using modular H-bridge. When voltage conversion ratios of each port are not equally balanced, zero-voltage-switching (ZVS) turn- on of power semiconductors in the MMAB converter cannot be secured under single phase shift (SPS...

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Veröffentlicht in:	IEEE transactions on industrial electronics (1982) 2023-07, Vol.70 (7), p.6865-6875
Hauptverfasser:	Wang, Haoyu, Zeng, Yangbin, Ji, Shiqi, Zhao, Zhengming, Yuan, Liqiang, Mo, Xin
Format:	Artikel
Sprache:	eng
Schlagworte:	Active control Bridge circuits Conversion ratio Electric converters Electric potential Equivalent circuits Frequency-domain analysis Inductance Modular multi active bridge (MMAB) operation region Phase shift single phase shift (SPS) Superposition (mathematics) Switches Switching Topology Voltage Zero voltage switching zero voltage switching (ZVS)
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container_issue	7
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container_title	IEEE transactions on industrial electronics (1982)
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creator	Wang, Haoyu Zeng, Yangbin Ji, Shiqi Zhao, Zhengming Yuan, Liqiang Mo, Xin
description	Modular multi active bridge (MMAB) converter can provide multiple dc ports using modular H-bridge. When voltage conversion ratios of each port are not equally balanced, zero-voltage-switching (ZVS) turn- on of power semiconductors in the MMAB converter cannot be secured under single phase shift (SPS) control, increasing power loss and leading to lower efficiency. To estimate the efficiency of the converter in various conditions, ZVS operation region of MMAB converters under SPS is comprehensively derived based on steady-state time domain with superposition theorem. Voltage conversion ratios are taken as main variables for ZVS region analysis and influences of them are comprehensively analyzed. Full ZVS regions and constrained ZVS regions are obtained by ZVS discriminants. Simulation and experimental results for a three-port MMAB prototype are given to verify the theoretical analysis of ZVS operation region.
doi_str_mv	10.1109/TIE.2022.3204954
format	Article
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When voltage conversion ratios of each port are not equally balanced, zero-voltage-switching (ZVS) turn- on of power semiconductors in the MMAB converter cannot be secured under single phase shift (SPS) control, increasing power loss and leading to lower efficiency. To estimate the efficiency of the converter in various conditions, ZVS operation region of MMAB converters under SPS is comprehensively derived based on steady-state time domain with superposition theorem. Voltage conversion ratios are taken as main variables for ZVS region analysis and influences of them are comprehensively analyzed. Full ZVS regions and constrained ZVS regions are obtained by ZVS discriminants. 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subjects	Active control Bridge circuits Conversion ratio Electric converters Electric potential Equivalent circuits Frequency-domain analysis Inductance Modular multi active bridge (MMAB) operation region Phase shift single phase shift (SPS) Superposition (mathematics) Switches Switching Topology Voltage Zero voltage switching zero voltage switching (ZVS)
title	ZVS Soft Switching Operation Region Analysis of Modular Multi Active Bridge Converter Under Single Phase Shift Control
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