Experimental Study on the Current Limiting Characteristics of a Saturated Iron-Core Superconducting Fault Current Limiter in DC Power Systems

Several recent studies have proposed a conceptual design of a saturated iron-core superconducting fault current limiter (SI-SFCL) for DC power systems, but experimental studies to verify its operating characteristics and performance have not yet been conducted. In this paper, a laboratory-scale SI-S...

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Veröffentlicht in:	IEEE transactions on applied superconductivity 2021-08, Vol.31 (5), p.1-5
Hauptverfasser:	Dao, Van Quan, Lee, JaeIn, Kim, Chang-Soon, Park, Minwon
Format:	Artikel
Sprache:	eng
Schlagworte:	Capacitors Circuit faults Circuits Current limiters DC power system Direct current electromagnetic analysis fault current Fault currents Finite element analysis Finite element method high-temperature superconducting coil Iron Magnetic cores Performance tests Power systems Superconducting coils superconducting fault current limiter Superconductivity System effectiveness
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creator	Dao, Van Quan Lee, JaeIn Kim, Chang-Soon Park, Minwon
description	Several recent studies have proposed a conceptual design of a saturated iron-core superconducting fault current limiter (SI-SFCL) for DC power systems, but experimental studies to verify its operating characteristics and performance have not yet been conducted. In this paper, a laboratory-scale SI-SFCL was designed and tested to operate in a 500 V, 50 A DC power system. First, the detailed configuration, specifications, and hardware manufacturing contents of the SI-SFCL were presented, and then an experimental circuit was developed and installed for the performance test of the SI-SFCL in normal operation and failure conditions. A 3D finite element method model was constructed to compare the simulation results and experimental results for the operating function of the SI-SFCL. Without the SI-SFCL, the maximum fault current level was 500 A, as a result, the SI-SFCL has a large current limit function, which can reduce the magnitude of the fault current up to the design target value of 73.6%. The results obtained in this study can be effectively applied to large-scale SI-SFCL development studies for HVDC power systems.
doi_str_mv	10.1109/TASC.2021.3069797
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In this paper, a laboratory-scale SI-SFCL was designed and tested to operate in a 500 V, 50 A DC power system. First, the detailed configuration, specifications, and hardware manufacturing contents of the SI-SFCL were presented, and then an experimental circuit was developed and installed for the performance test of the SI-SFCL in normal operation and failure conditions. A 3D finite element method model was constructed to compare the simulation results and experimental results for the operating function of the SI-SFCL. Without the SI-SFCL, the maximum fault current level was 500 A, as a result, the SI-SFCL has a large current limit function, which can reduce the magnitude of the fault current up to the design target value of 73.6%. 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subjects	Capacitors Circuit faults Circuits Current limiters DC power system Direct current electromagnetic analysis fault current Fault currents Finite element analysis Finite element method high-temperature superconducting coil Iron Magnetic cores Performance tests Power systems Superconducting coils superconducting fault current limiter Superconductivity System effectiveness
title	Experimental Study on the Current Limiting Characteristics of a Saturated Iron-Core Superconducting Fault Current Limiter in DC Power Systems
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