Power system stability : Mode identification in the power system oscillations using wide area measurement systems

##plugins.themes.academic_pro.article.sidebar##

Published Jun 2, 2015
Download
PDF
Statistic

Downloads

Download data is not yet available.

Metrics

Metrics Loading ...
Volume 11, Issue 2, June 2015

##plugins.themes.academic_pro.article.main##

Matta Srinu Babu
Research Scholar, Electrical Engineering, BBD University, Lucknow, UP - 226028
Ajay Shankar
Assistant Professor, Electrical Engineering, BBD University, Lucknow, UP - 226028
K. Seethalekshmi
Professor and the Director of the School of Engineering, BBD University, Lucknow, UP - 226028

Abstract

In the past few decades power system oscillation damping remains as one of the major concerns for secure and reliable operation of power systems. In response to a continual increase in demand, power systems are driven closer to their limits, especially those of transmission capacity. As such, enhancing the transfer capability, while keeping the system stable, is one of the main goals for system operators. When we transfer a bulk amount of power over a long distance through relatively weak tie lines and high gain exciters then problem of small signal oscillation occurs. These oscillations have also resulted into instability and blackouts in the power system. In this instability problem there are different frequency components which are known as modes. This paper work consist of identification of low frequency components i.e. local area and inter area modes of oscillations in two area power system and also in IEEE 39 bus system.

##plugins.themes.academic_pro.article.details##

How to Cite
Srinu Babu, M., Shankar, A., & Seethalekshmi, K. (2015). Power system stability : Mode identification in the power system oscillations using wide area measurement systems. Power Research - A Journal of CPRI, 247–258. Retrieved from https://cprijournal.in/index.php/pr/article/view/720

References

  1. P Kundur, Power System Stability, McGraw Hill. 1994.
  2. M Anderson and A A Fouad, Power System control and Stability, The Iowa University Press, 1977.
  3. G Rogers, Power System Oscillations, Kluwer Academic Publishers, Boston/ London/Dordrecht-2000.
  4. P Kundur, M Klein, G J Rogers and M S Zywno, Application of power system stabilizers for enhancement of overall system stability. IEEE Trans. on Power App. Syst, Vol. PWRS-4, pp. 614-626, May 1989.
  5. K R Padiyar, Power System Dynamics, BS Publication, Hyderabad, 2008.
  6. G J Rogers, Methods for Small Signal Analysis of Very Large Power Systems, IEEE Proceedings on the 25th Conference on Decision and Control, pp. 393-398, 1987.
  7. J Barquin, L Rouco and H R Vargas, Generalized Selective Modal Analysis, IEEE Power Engineering Society Winter Meeting, Vol. 2, pp. 1194-1199, 2002.
  8. Y Huang, Z Xu and W Pan, A Practical Analysis Method of Low Frequency Oscillation forLarge Power Systems, IEEE Power Engineering Society General Meeting, Vol. 2, pp. 1623-1629, June, 2005.
  9. E H Abed, M A Hassouneh, W A Hashlamoun,Modal Participation Factors Revisited: One Definition Replaced by Two, American Control Conference, pp. 1140-1145, 2009.
  10. S H Horowitz, Arun G. Phadke, Power System Relaying, John Wiley and Sons Ltd, Third edition, 2008.
  11. S Chakrabarti, E Kyriakides, T Bi, D Cai and V Terzija,Measurements Get Together, IEEE Power and Energy Magazine, Vol. 07, No. 01, pp. 41-49, 2009.
  12. Y Li, X Zhou and J Zhou, A new algorithm for distributed power system state estimation based on PMUs, IEEE, International Conference on Power System Technology, 2006.
  13. J Mooney, P E and N Fisher, Application guidelines for power swing detection on transmission systems, Schweitzer Eng. Lab. Inc, 59thAnnual Conference for Protective Relay Engineers, 2006.
  14. P Kundu, J Ganeswara Rao, P K Nayak and A K Pradhan, Wide Area Measurement based Out-of-Step Detection Technique, IEEE Conference, pp. 1-5, 2011.
  15. E V Larsen, DASwann, Applying Power System Stabilizers, Part-1, Part-2, Part-3, IEEE Trans. on power App. Syst, Vol. PAS -100, pp. 3017-3046, June, 1981.
  16. E Z Zhou, O P Malik and G S Hope, Theory and method of power system stabilizer location, IEEE Transactions on Energy Conversion, Vol. 1, No. 01, pp. 170-176, 1991.
  17. S S Sharif, Nonlinear PSS design technique, IEEE,IEEE Trans. on power App. Syst, Vol. 10, pp. 44-47,1995.
  18. Y Zhang and A Bose, Design of widearea damping controllers for inter-area oscillations, IEEE Trans.Power Syst., Vol. 23, pp. 1136-1143, 2008.
  19. G Balas, R Chiang, A Packard and M Safonov, Robust Control Toolbox 3: User’s guide, Natick, MA: The Mathworks, 2006.
  20. A Heniche and I Kamawa, Assessment of two methods to select wide-area signals for power system damping control, IEEE Trans. Power Syst., Vol. 23, pp. 572—581, 2008.
  21. M Srinu Babu and K Seethalekshmi,Out of step detection using Wide area measurements, International colloquium on SMART GRID – CIGRE, Mysore, India, November, 2013.
  22. M Pai, Energy function analysis for power system stability, Springer Science andBusiness Media, 1989.
  23. R Jabr, B Pal, N Martins and J Ferraz, Robust and coordinated tuning of powersystem stabiliser gains using sequential linear programming, Generation, Transmission Distribution, IET, Vol. 4, pp. 893–904, August, 2010.