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Development of EMTDC model component for HTS power cable considering critical current, critical temperature and recovery time

임계전류, 임계온도 및 회복시간을 고려한 초전도 전력케이블의 EMTDC 모델 컴포넌트 개발

  • Published : 2006.03.01

Abstract

Before applying HTS power cable to the real utility. system analysis should be carried out by some simulation tools . Hereby the electrical power system analysis is very important for practical use of HTS devices. Nowadays PSCAD/EMTDC simulation tool is one of the most popular and useful analysis tool for the electrical power system analysis. Unfortunately the model component for HTS power cable is not provided in the PSCAD/EMTDC simulation tool In this paper. the EMTDC model component for HTS power cable has been developed considering critical current, critical temperature and recovery time constant that depend on the sorts of HTS wire. The numerical model of HTS Power cable in PSCAD/EMTDC was designed by using the real experimented data obtained from the real HTS 1G wire test. The utility application analysis of HTS power cable was also performed using the developed model component and the parameters of the real utility network in this study. The author's got good results. The developed model component for HTS power cable could be variously used when the power system includes HTS power cable, especially it will be readily analyzed by PSCAD/EMTDC in order to obtain the data for the level of fault current power flow, and power losses, and so on.

Keywords

References

  1. Jeffrey O.Willis, "Superconducting Transmission Cables" IEEE Power Engineering Review, pp. 10-14, 2000 https://doi.org/10.1109/39.857447
  2. Aldo Bolza. Piero Metra, Marco Nassi. Mujibar Mrahman, "RECENT Development in HTS Power Cable Application" IEEE Transactions on applied superconductivity vol. 7, NO.2, pp. 339-344. June 1997 https://doi.org/10.1109/77.614499
  3. N.Kelly, M.Massi, L.Masur, "Application of HTS wire and cables to Power Transmission: State of the Art and Opportunities", IEEE Transactions on applied superconductivity, pp. 448-454, 2001
  4. T.Kiss, M.Inoue, "Quench Characteristics in HTSC Devices", IEEE Transactions on applied superconductivity, vol. 6. NO.2, pp. 1073-1076. 1999
  5. 이재득, 박민원, 유인근, "A STUDY ON THE MODELING OF SUPERCONDUCTING FAULT LIMITERS USING EMTDC", IFAC Symposium on Power Plants & Power Systems Control. Vol. 1. pp. 399-404, 2003
  6. 한상근, 박민원, 유인근. "REAL TIME SIMULATION SCHEME FOR STAND-ALONE WIND POWER GENERATION SYSTEMS", IFAC Symposium on Power Plants & Power Systems Control, Vol. 1, pp. 278-282, 2003
  7. 오상수, 하흥수, 하동우, 김상철, 권영길, 류강식. "Development of Bi-2223/Ag superconducting wire for power application", ICEE. Vol.3, pp. 1578-1581. 2002
  8. Chen Min, Yoitsu Sekiguchi. Shoji Mashio. Munehisa Mitani. Atsuhide. Jinno, "Study of Ground-Fault Surge in Buried EHV Cable Line Based on EMTP Simulation", IEEE/PES Transmission and Distribution Conference and Exhibition, Vol 2, pp. 1290-1293. 2002
  9. Takato Masuda, Masayuki Hiroes. Shigeki Isojima. "Verification tests of a 100m High-Tc SUPERCONDUCTING Cable" IEEE/PES Transmission and Distribution Conference and Exhibition. Vol. 2. pp. 1298-1303, 2002
  10. D.F. Lee, P.M.Martin, D.M. Kroeger, M.W. Rupich, Q.Li. G.N.Riley, "Effects of initial cold work conditions on the deformation and current capacity of monofilament and multi filamentary Bi-2223 conductors" Super.Sci.Tech. . Vol. 10. pp. 702-711. 1997 https://doi.org/10.1088/0953-2048/10/9/011