Interrupting Condition Imposed on a Circuit Breaker Connection with Fault Current Limiter under Short-Line Fault Regime

E. Calixte, Y. Yokomizu, H. Shimizu, T. Matsumura, and H. Fujita

References

  1. [1] Y.S. Cha, Z. Yang, L.R. Turner, & Roger B. Poeppel, Analysisof a passive superconducting fault current limiter, IEEE Trans.on Applied Superconductivity, 8(1), 1998, 20–25. doi:10.1109/77.662690
  2. [2] T. Matsumura, T. Uchii, & Y. Yokomizu, Development of flux-lock-type fault current limiter with high-TC superconductingelement, IEEE Trans. on Applied Superconductivity, 7(2),1997, 1001–1004. doi:10.1109/77.614676
  3. [3] T. Hara, T. Okuma, T. Yamamoto, D. Ito, K. Takaki, &K. Tsurunaga, Development of a new 6.6 kV/1000 A classsuperconducting fault current limiter for electric power systems,IEEE Trans. on Power Delivery, 8(1), 1993, 182–191. doi:10.1109/61.180335
  4. [4] Y. Yokomizu, T. Matsumura, H. Okubo, & Y. Kito, Current-limiting performance of a YBa2Cu3O7−−x superconductor bythe transition from superconducting to normal conductingstate, European Trans. on Electrical Power Engineering, 5(2),1995, 99–105.
  5. [5] T. Ueda, M. Morita, H. Arita, J. Kida, Y. Kurosawa, &T. Yamagiwa, Solid-state current limiter for power distributionsystem, IEEE Trans. on Power Delivery, 8(4), 1993, 1796–1801. doi:10.1109/61.248287
  6. [6] S. Sugimoto, J. Kida, H. Arita, C. Fukui, & T. Yamagiwa,Principle and characteristics of a fault current limiter withseries compensation, IEEE Trans. on Power Delivery, 11(2),1996, 842–847. doi:10.1109/61.489342
  7. [7] J. Skindhøj, J. Glatz-Reichenbach, & R. Strümpler, Repetitivecurrent limiter based on polymer PTC resistor, IEEE Trans.on Power Delivery, 13(2), 1998, 489–494. doi:10.1109/61.660919
  8. [8] N. Engelman, E. Schreurs, & B. Drugge, Field test results fora multi-shot 12.47 kV fault current limiter, IEEE Trans. onPower Delivery, 6(3), 1991, 1081–1086. doi:10.1109/61.85851
  9. [9] F.M. Gatta, F. Iliceto, S. Lauria, & B. Dilli, TRVs acrosscircuit breakers of series compensated lines: Analysis, designand operation experience in the 240 kV Turkish grid, CIGRESC 13, Session 2002, Report 13–109.
  10. [10] D. Dufournet & J.M. Willieme, Generator circuit breakers:SF6 breaking chamber—Interruption of current with non-zeropassage—Influence of cable connection on TRV of system fedfaults, CIGRE SC 13, Session 2002, Report 13–101.
  11. [11] T. Shimato, K. Chiyajo, K. Nakanishi, K. Hirasawa,A. Kobayashi, & T. Sugiyama, Evaluation of interruptioncapability of gas circuit breakers on large time constants ofDC component of fault current, CIGRE SC 13, Session 2002,Report 13–104.
  12. [12] A.L.J. Janssen, L.H. te Paske, R.P.P. Smeets, & Y.J. Shin,Limitations of high-power testing methods for EHV and UHVcircuit-breakers, CIGRE SC 13, Session 2002, Report 13–105.
  13. [13] R.P.P. Smeets, D.F. Peelo, J.H. Sawada, & L. Van Der Sluis,Evolution of stresses in distribution networks and their impacton testing and certification of medium voltage switchgear,CIGRE SC 13, Session 2002, Report 13–106.
  14. [14] Y. Kito, T. Matsumura, & H. Kato, Reduction effect of cryoresistive fault current limiter on transient recovery voltage,Trans. of IEE of Japan, 104-B(8), 1984, 527–533 (in Japanese).
  15. [15] E. Calixte, Y. Yokomizu, T. Matsumura, & H. Fujita, Effectof fault current limiter on transient recovery voltage across acircuit breaker under breaker terminal fault condition, Proc.Technical Committee on Static Apparatus, SA-00-38, Sendai,Japan, November 2000, 13–18.
  16. [16] Standard of Japanese Electrotechnical Committee, JEC-2300,Denkishoin, 1998 (in Japanese).
  17. [17] H.M. Ryan & G.R. Jones, SF6 switchgear (London: Peter Prerinus, 1989), IEE Power Engineering series 10 page 47.

Important Links:

Go Back