A DC SSCB With Range-Limited Parallel Operation Switches and a Snubber Circuit Utilizing Inverse Current Injection

A DC SSCB With Range-Limited Parallel Operation Switches and a Snubber Circuit Utilizing Inverse Current Injection

Although many snubber circuits have been studied, research on circuits that effectively suppress surge voltage while supporting bidirectional operation remains relatively limited. This paper proposes a bidirectional snubber circuit with an inverse current injection to effectively suppress the surge...

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Bibliographic Details
Main Authors: Jae-Seong Jo, Sun-Pil Kim, Sang-Hyeok Lee, Sung-Geun Song, Feel-Soon Kang
Format: Article
Language:English
Published: IEEE 2025-01-01
Series:IEEE Access
Subjects:
DC circuit breaker (DCCB)
inverse current injection
metal oxide varistor (MOV)
silicon carbide (SiC)
snubber circuit
solid-state circuit breaker (SSCB)
Online Access:https://ieeexplore.ieee.org/document/11045385/
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Summary:Although many snubber circuits have been studied, research on circuits that effectively suppress surge voltage while supporting bidirectional operation remains relatively limited. This paper proposes a bidirectional snubber circuit with an inverse current injection to effectively suppress the surge voltage generated when a solid-state circuit breaker (SSCB) switch is turned off. It generates inverse current using an LC resonant circuit employing thyristors and suppresses the surge voltage by forcing the fault current to be zero when the SSCB switch is turned off. The capacitor absorbs the energy stored in the line inductance on the power source and load sides, thereby preventing voltage increases. In addition, the SSCB switches are structured in parallel so that only the SiC MOSFET with low conduction loss is turned on during normal operation. When the fault current increases and reaches a specific current threshold, the Si MOSFET is driven in parallel until reaching the breaking current value. This solves the price increase problem due to the SiC switch’s current rating. The operational mode is described in detail with theoretical analysis, and the validity is verified through simulation and scaled-down experiments. The surge voltage suppression performance of the proposed snubber is evaluated by comparing it with the conventional RCD snubber and Metal Oxide Varistor (MOV)-based snubber, and the surge voltage occurrence due to the inverse current injection timing mismatch is analyzed to present the range of allowable delay time. Finally, the cost model analysis evaluates the economic feasibility of the proposed snubber applying the parallel switch structure.
ISSN:2169-3536

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