Superconducting fault current limiter application in a power-dense marine electrical system

S.M. Blair; C.D. Booth; I.M. Elders; N.K. Singh; G.M. Burt; J. McCarthy

Superconducting fault current limiter application in a power-dense marine electrical system

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Superconducting fault current limiter application in a power-dense marine electrical system

Author(s): S.M. Blair ; C.D. Booth ; I.M. Elders ; N.K. Singh ; G.M. Burt ; J. McCarthy
DOI: 10.1049/iet-est.2010.0053

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Author(s): S.M. Blair ¹ ; C.D. Booth ¹ ; I.M. Elders ¹ ; N.K. Singh ^{1, 2} ; G.M. Burt ¹ ; J. McCarthy ³
- Affiliations: 1: Institute for Energy and Environment, University of Strathclyde, Glasgow, UK
  2: Institute for Energy and Environment, Vestas Wind Systems A/S, Randers, Denmark
  3: Institute for Energy and Environment, Rolls-Royce Marine Electrical Systems, Portsmouth, UK
Source: Volume 1, Issue 3, September 2011, p. 93 – 102
DOI: 10.1049/iet-est.2010.0053 , Print ISSN 2042-9738, Online ISSN 2042-9746

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Power-dense, low-voltage marine electrical systems have the potential for extremely high fault currents. Superconducting fault current limiters (SFCLs) have been of interest for many years and offer an effective method for reducing fault currents. This is very attractive in a marine vessel in terms of the benefits arising from reductions in switchgear rating (and consequently size, weight and cost) and damage at the point of fault. However, there are a number of issues that must be considered prior to installation of any SFCL device(s), particularly in the context of marine applications. Accordingly, this study analyses several such issues, including: location and resistance sizing of SFCLs; the potential effects of an SFCL on system voltage, power and frequency; and practical application issues such as the potential impact of transients such as transformer inrush. Simulations based upon an actual vessel are used to illustrate discussions and support assertions. It is shown that SFCLs, even with relatively small impedances, are highly effective at reducing prospective fault currents; the impact that higher resistance values has on fault current reduction and maintaining the system voltage for other non-faulted elements of the system is also presented and it is shown that higher resistance values are desirable in many cases. It is demonstrated that the exact nature of the SFCL application will depend significantly on the vessel's electrical topology, the fault current contribution of each of the generators, and the properties of the SFCL device, such as size, weight, critical current value and recovery time.

References

1. 1)
  - A. Oliver , A. Smith , M. Husband , M. Bailey , Y. Feng . Assessment of small bend diameter magnesium diboride wire for a superconducting fault current limiter application. IEEE Trans. Appl. Supercond. , 1942 - 1945
2. 2)
  - B. Gromoll , G. Ries , W. Schmidt . Resistive fault current limiters with YBCO films 100 kVA functional model. IEEE Trans. Appl. Supercond. , 656 - 659
3. 3)
  - W. Paul , M. Chen , M. Lakner . Superconducting fault current limiter: applications, technical and economical benefits, simulations and test results.
4. 4)
  - J. Langston , M. Steurer , S. Woodruff , T. Baldwin , J. Tang . A generic real-time computer simulation model for superconducting fault current limiters and its application in system protection studies. IEEE Trans. Appl. Supercond. , 2090 - 2093
5. 5)
  - Y. Gong , Y. Huang , N. Schulz . Integrated protection system design for shipboard power system. IEEE Trans. Ind. Appl. , 1930 - 1936
6. 6)
  - Manitoba HVDC Research Centre, available at https://pscad.com/products/pscad/, accessed June 2010.
7. 7)
  - B.C. Sung , D.K. Park , T.K. Ko . Study on optimal location of a resistive SFCL applied to an electric power grid. IEEE Trans. Appl. Supercond. , 2048 - 2052
8. 8)
  - Areva T&D: ‘Network protection & automation guide’, 2005, p. 89.
9. 9)
  - IEC 60909-0: ‘Short-circuit currents in three-phase a.c. systems – part 0: calculation of currents’, 2001.
10. 10)
  - Su, C.L., Su, C.Y., Lee, C.C., Chen, C.J.: `Fault current limiter allocation in electric ship power systems', IEEE Electric Ship Technologies Symp., April 2009, Baltimore, USA, p. 53–58.
11. 11)
  - M. Stemmle , M. Steurer , P.G. McLaren , D. Muthumuni , F. Foucher . Transient studies of fault current limiters in ship power systems with PSCAD. Flux Mag. , 9 , 12 - 14
12. 12)
  - R. Dommerque , S. Krämer , A. Hobl . First commercial medium voltage superconducting fault-current limiters: production, test and installation. Supercond. Sci. Technol. , 1 - 10
13. 13)
  - H. Kraemer , W. Schmidt , B. Utz . Test of a 1 kA superconducting fault current limiter for DC applications. IEEE Trans. Appl. Supercond. , 1986 - 1989
14. 14)
  - B.W. Lee , J. Sim , K.B. Park , I.S. Oh . Practical application issues of superconducting fault current limiters for electric power systems. IEEE Trans. Appl. Supercond. , 620 - 623
15. 15)
  - I.N. Dul'kin , D.V. Yevsin , L.M. Fisher , V.P. Ivanov , A.V. Kalinov , V.A. Sidorov . Modeling thermal process in a resistive element of a fault current limiter. IEEE Trans. Appl. Supercond. , 7 - 13
16. 16)
  - N.K. Singh , R.M. Tumilty , G.M. Burt . System-level studies of a mgb2 superconducting fault-current limiter in an active distribution network. IEEE Trans. Appl. Supercond. , 54 - 60
17. 17)
  - Blair, S.M., Singh, N.K., Booth, C.D., Burt, G.M.: `Operational control and protection implications of fault current limitation in distribution networks', Proc. 44th Int. Universities Power Engineering Conf., September 2009, Glasgow, UK.
18. 18)
  - IEEE Std. 421.5–2005 (Revision of IEEE Std 421.5–1992): ‘IEEE recommended practice for excitation system models for power system stability studies’, 2006.
19. 19)
  - Blair, S.M., Singh, N.K., Elders, I.M., Booth, C.D., Burt, G.M., McCarthy, J.: `Investigation of superconducting fault current limiter application in a power-dense marine electrical network', Fifth IET Int. Conf. Power Electronics, Machines and Drives, April 2010, Brighton, UK.
20. 20)
  - A.S. Emhemed , R.M. Tumilty , N.K. Singh , G.M. Burt , J.R. McDonald . Analysis of transient stability enhancement of LV-connected induction microgenerators by using resistive-type fault current limiters. IEEE Trans. Power Syst. , 885 - 893
21. 21)
  - C. Booth , I. Elders , J. Schuddebeurs , J. McDonald , S. Loddick . Power system protection for more and full electric marine systems. Proc. IMarEST B, J. Mar. Des. Oper. , 37 - 45
22. 22)
  - M. Noe , M. Steurer . High-temperature superconductor fault current limiters: concepts, applications, and development status. Supercond. Sci. Technol. , R15 - R29
23. 23)
  - Husband, M., Booth, C.D.: `Superconducting fault current limiters for marine applications', Int. Conf. World Maritime Technology Conf., March 2006, London, UK.
24. 24)
  - K. Butler , N. Sarma , C. Whitcomb , H. Do Carmo , H. Zhang . Shipboard systems deploy automated protection. IEEE Comput. Appl. Power , 31 - 36

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