Journal article
Soft Turn-Off DC Solid-State Circuit Breakers with Flexible Dual Tripping Schemes
IEEE journal of emerging and selected topics in power electronics, pp 1-1
2023
Abstract
A novel solid-state circuit breaker (SSCB) topology with two combined tripping schemes is proposed in this paper: 1) fault current bypass (FCB) tripping and 2) soft turn-off tripping by transient commutation current injection (TCCI). There are four main contributions in this work. 1) Flexible combined dual tripping schemes are realized by one single topology. 2) The traditional monotonous hard switching FCB tripping with fast isolation speed cannot handle heavy load faults due to gate oscillations caused by higher d i /d t and d v /d t . Compared to pure FCB tripping, the combined soft turn-off tripping by TCCI in this work realizes zero current switching (ZCS) for the semiconductor switch to suppress its gate oscillations at heavy load fault interruption. 3) The capacitors in the TCCI circuits are automatically self-charged by the dc bus during the off state of SSCB, which greatly simplifies the design by getting rid of external capacitor charging circuits. 4) Reclosing and immediate reopening operations are realized, which enhances the practicality of this work A 375 V/20 A SSCB is designed and developed to experimentally validate the proposed dual tripping schemes at light load fault (57 A) and heavy load fault (325 A). The SSCB demonstrates an ultrafast response speed of 5.2 μs with FCB tripping and 19.6 μs with TCCI soft turn-off tripping. The reclosing and reopening operation is also validated based on IEEE Standard C37.14. This paper is accompanied by a slide as multimedia material demonstrating the contributions of the presented work.
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7 citations in Scopus
Details
- Title
- Soft Turn-Off DC Solid-State Circuit Breakers with Flexible Dual Tripping Schemes
- Creators
- Shuyan Zhao - Drexel UniversityReza Kheirollahi - Drexel UniversityYao Wang - Drexel UniversityHua Zhang - Rowan UniversityXiaoqing Song - University of Arkansas at FayettevilleBoran Fan - Virginia TechJun Wang - University of Nebraska–LincolnYue Cao - Oregon State UniversityFei Lu - Drexel University
- Publication Details
- IEEE journal of emerging and selected topics in power electronics, pp 1-1
- Publisher
- IEEE
- Grant note
- DE-AR0001114 / Advanced Research Projects Agency - Energy (10.13039/100006133)
- Resource Type
- Journal article
- Language
- English
- Academic Unit
- Electrical and Computer Engineering
- Scopus ID
- 2-s2.0-85177068456
- Other Identifier
- 991021811739904721