Analysis of Lightning Performance on 345 kV Transmission Lines Using Python Programming

Analysis of Lightning Performance on 345 kV Transmission Lines Using Python Programming

  • Fri Murdiya Universitas Riau
  • Rofi Dept. Electrical Engineering Universitas Riau
DOI: https://doi.org/10.31258/ijeepse.3.3.65-76
Abstract viewed: 357 times
pdf downloaded: 450 times
Keywords: BFOR, lightning performance, OOP, overhead transmission lin

Abstract

One of main causes of interruption of electrical power supply is the lightning strike on overhead power transmission lines. The lightning performance of transmission line can be determined by value of shielding failure flashover rate (SFFOR) and back flashover rate (BFOR). The object of this study is to create a computer application to compute lightning performance on the transmission lines using Python programming. Pythons package tkinter used for program interface window. Application programming is done by using the concept of object-oriented programming (OOP) using Pythons keyword class. Validation shows that the application has applied the method correctly with a percentage error 0 % for SFFOR and 3.14 % for BFOR. The application can do analysis on the factors that affecting SFFOR and BFOR such as the effect of thunder day, tower foot resistance, and number of isolator disk. The results obtained in this study is computer application that can perform lightning performance analysis and analysis of factors that can affect it, such as thunder day, tower foot resistance and the number of isolator disk.

References

[1] M. T. Barros, "Apontamentos da Cadeira de Alta Tensão," 2011.

[2] J. A. M. Valesco, J. C. Araujo and S. Bedoui, "Lightning Performance Analysis of Transmission Lines Using the Monte Carlo Method and Parallel Computing," Ingeniare, Revista Chilena de Ingenieria, vol. 26, no. 3, pp. 398-409, 2018.

[3] P. N. Mikropaulus, T. E. Tsovilis and D. E. Zlitidis, "Software Development for the Evaluation of the Lightning Performance of Overhead Transmission Lines," UPEC, 2010.

[4] R. Zoro and F. Murdiya, "The Performance of Lightning Protection System on 275 kV Transmission Lines Siguragura-Kualatanjung, North Sumatra, Indonesia," IEEE International Conference on Condition Monitoring and Diagnosis, pp. 1236-1241, 2012.

[5] R. Zoro and E. Y. Pranomo, "Lightning Performance of Extra High Voltage 500 kV Lines at East Java-Indonesia," IPTEK, The Journal for Technology and Science, vol. 19, no. 4, pp. 100-108, 2008.

[6] E. S. D. A. Abrantes, “Lightning Performance of Transmission Lines,” Instituto Superior Tecnico of The Universidade de Lisbon, 2016.

[7] J. G. Anderson, “Lightning Performance of Transmission Line,” dalam Transmission Line Reference Book 345 kV and Above/Second Edition, 2nd penyunt., California, Electric Power Research Institute, 1982, pp. 545-593.

[8] R. B. Anderson and A. J. Erikson, "Lightning Parameters for Engineering Application," CSIR, Pretoria, South Africa, 1979.

[9] IEEE Working Group, “IEEE Estimating the Lightning Performance of Overhead Transmission Lines,” Institute Electrical and Electronics Engineers Inc., New York, 1997.

Published
2020-10-12
How to Cite
[1]
F. Murdiya and R. Hariadi, “Analysis of Lightning Performance on 345 kV Transmission Lines Using Python Programming: Analysis of Lightning Performance on 345 kV Transmission Lines Using Python Programming”, IJEEPSE, vol. 3, no. 3, pp. 65-76, Oct. 2020.