Interference Analysis of Medium Voltage Air Line 20 KV Feeder Using Failure Mode and Effects Analysis Method

  • Yan Min Tun Department of Electrical Power Engineering, Mandalay Technological University, Myanmar
  • Aung Than Win Department of Electrical Power Engineering, Mandalay Technological University, Myanmar
Keywords: Interference, Voltage, Feeder

Abstract

This article discusses the interference analysis of medium voltage air line 20 kv feeder using failure mode and effects analysis method. The distribution network consists of two parts, the first the distribution network consists of two parts, the first is the medium / primary voltage (JTM) network, which supplies electrical power from the sub-transmission substation to the distribution substation, the primary distribution network uses three wires or four wires for three phases. the impact of the reliability index from the calculation of the impact of the reliability index based on the number of disturbances (SAIFI), it shows that in January 2019 it has the highest index value, namely SAIFI, 1,695 disturbances/ subscribers. From the results of the calculation of the impact of the reliability index based on the number of blackouts (SAIDI), it shows that in January 2019 the SAIDI index value was 3,883 hours/customer.

References

Bayliss, C. R., Bayliss, C., & Hardy, B. (2012). Transmission and distribution electrical engineering. Elsevier.

Chowdhury, A., & Koval, D. (2011). Power distribution system reliability: practical methods and applications (Vol. 48). John Wiley & Sons.

Filip, F. C. (2011). Theoretical Research on the Failure Mode and Effects Analysis (FMEA) Method and Structure. In fourth International Conference on Manufacturing Engineering, Quality and Production Systems (pp. 176-181).

Liu, H. C., Liu, L., Bian, Q. H., Lin, Q. L., Dong, N., & Xu, P. C. (2011). Failure mode and effects analysis using fuzzy evidential reasoning approach and grey theory. Expert Systems with Applications, 38(4), 4403-4415.

Mateo, C., Postigo, F., de Cuadra, F., San Roman, T. G., Elgindy, T., DueƱas, P., ... & Palmintier, B. (2020). Building large-scale US synthetic electric distribution system models. IEEE Transactions on Smart Grid, 11(6), 5301-5313.

Paiva, P. C., Khodr, H. M., Dominguez-Navarro, J. A., Yusta, J. M., & Urdaneta, A. J. (2005). Integral planning of primary-secondary distribution systems using mixed integer linear programming. IEEE Transactions on Power systems, 20(2), 1134-1143.

Pentti, H., & Atte, H. (2002). Failure mode and effects analysis of software-based automation systems. VTT Industrial Systems, STUK-YTO-TR, 190, 190.

Reddy, A. S., Reddy, M. D., & Reddy, M. S. K. (2017). Network Reconfiguration of Primary Distribution System Using GWO Algorithm. International Journal of Electrical and Computer Engineering, 7(6), 3226.

Senger, E. C., Manassero, G., Goldemberg, C., & Pellini, E. L. (2005). Automated fault location system for primary distribution networks. IEEE Transactions on power delivery, 20(2), 1332-1340.

Short, T. A. (2014). Electric power distribution handbook. CRC press.

Sun, D. I., Farris, D. R., Cote, P. J., Shoults, R. R., & Chen, M. S. (1982). Optimal distribution substation and primary feeder planning via the fixed charge network formulation. IEEE Transactions on Power Apparatus and Systems, (3), 602-609.

Published
2020-12-31
How to Cite
Tun, Y. M., & Win, A. T. (2020). Interference Analysis of Medium Voltage Air Line 20 KV Feeder Using Failure Mode and Effects Analysis Method. Journal La Multiapp, 1(6), 28-34. https://doi.org/10.37899/journallamultiapp.v1i6.301