A Review of Solid-State Circuit Breakers

Although conventional electromechanical circuit breakers have a proven record as effective and reliable devices for circuit protection, emerging power distribution technologies and architectures, such as dc microgrids, require improved interruption performance characteristics (e.g., faster switching...

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Veröffentlicht in:	IEEE transactions on power electronics 2021-01, Vol.36 (1), p.364-377
Hauptverfasser:	Rodrigues, Rostan, Du, Yu, Antoniazzi, Antonello, Cairoli, Pietro
Format:	Artikel
Sprache:	eng
Schlagworte:	Breaker topology Circuit breakers Circuit design Circuit protection Clamps Commutation current sensing Distributed generation Electric power distribution Fault detection fault protection gate driver Power semiconductor devices R&D Research & development Silicon Silicon carbide Solid state Solid state circuits solid-state circuit breaker Subsystems Switching Thyristors Topology trip electronics voltage clamping
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container_title	IEEE transactions on power electronics
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creator	Rodrigues, Rostan Du, Yu Antoniazzi, Antonello Cairoli, Pietro
description	Although conventional electromechanical circuit breakers have a proven record as effective and reliable devices for circuit protection, emerging power distribution technologies and architectures, such as dc microgrids, require improved interruption performance characteristics (e.g., faster switching speed). The need for faster switching operation, in combination with the latest developments of advanced power semiconductor technologies, has spurred an increase in the research and development in the area of solid-state circuit breakers. This article provides a comprehensive review of various solid-state circuit breaker technologies that have been reported in the literature during recent years. First, we categorize solid-state circuit breakers based on key features and subsystems, including power semiconductor devices, main circuit topologies, voltage clamping methods, gate drivers, fault detection methods, and commutation methods for power semiconductor devices. Second, we discuss the various challenges associated with the design of solid-state circuit breakers from the perspective of generic applications and provide a comparison of several solid-state breaker technologies based on key metrics. Finally, we provide a useful framework and point of reference for future development of solid-state circuit breakers for many emerging power distribution applications.
doi_str_mv	10.1109/TPEL.2020.3003358
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subjects	Breaker topology Circuit breakers Circuit design Circuit protection Clamps Commutation current sensing Distributed generation Electric power distribution Fault detection fault protection gate driver Power semiconductor devices R&D Research & development Silicon Silicon carbide Solid state Solid state circuits solid-state circuit breaker Subsystems Switching Thyristors Topology trip electronics voltage clamping
title	A Review of Solid-State Circuit Breakers
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