Journal Press India^®

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This study primarily focuses on analyzing the stability of the SMIB system when subjected to small signals. The small signal stability of a Single Machine Infinite Bus (SMIB) system is demonstrated by plotting the eigenvalue, which represents rotor oscillations, against the voltage regulator gain and machine loading. Furthermore, the integration of the pole placement technique and the utilization of TCSC in the production of PSS will enhance the reliability of the SMIB system's low-level signals. An analysis is conducted to compare the effects of PSS and TCSC on the oscillations of the rotor's speed and angle. In the final phase of the design process, careful thought was given to choosing a feedback control signal for the PSS. The duration required to respond to messages is a crucial determinant of their effectiveness.

Keywords

SSS, SMIB, FACTs Devices, Power System Stabilizer (PSS),

1. E. Larsen and D. Swann, “Applying Power System Stabilizers”, Part I: General Concepts, Part II: Performance Objectives and Tuning Concept, Part III: Practical Considerations, IEEE Trans. PAS, Vol.-100, no.-6, pp. 3017–3046, 1981.
2. M.A.Pai, D.P. Sen and K.R.Padiyar, ‘Topics in small signal analysis of power systems’, New Delhi, India, Narosa Publishing House, 2003.
3. P.Kundur, M. Klein, G.J.Rogers, and M.S. Zywno, ‘Applications of power system stabilizers for enhancement of overall system stability’, IEEE Transactions on power systems, vol. 4, no. 2, pp. 614-626, 1989.
4. P.Kundur, ‘Power System Stability and Control’, New York, NY, McGraw-Hill, 1994.
5. P.Kundur, M. Klein, G. J. Rogers, and M.S. Zywno,’Applications of power system stabilizers for enhancement of overall system stability’, IEEE Trans. on Power Systems, vol. 4, no. 2, pp. 614-626, 1989.
6. Kamwa, R. Grondin, and G. Trudel, ‘IEEE PSS2B versus PSS4B:The limits of performance of modern power system stabilizers’, IEEETrans. Power Syst., vol. 20, no. 2, pp. 903–915, May 2005.
7. G. E. Boukarim, S. Wang, J. H. Chow, G. N. Taranto, and N. Martins, ‘A comparison of classical, robust and decentralized designs for multiple power system stabilizers’, IEEE Trans. Power Syst., vol. 15, no. 4, pp. 1287–1292, Nov. 2000.
8. G. J. W. Dudgeon, W. E. Leithead, A. Dysko, J. O’Reilly, and J. R.McDonald, ‘The effective role of AVR and PSS in power systems: Frequency response analysis’, IEEE Trans. Power Syst., vol. 22,no. 4, pp.1986–1994, Nov. 2007.
9. K.R.Padiyar, M.A.Pai and C. Radhakrishna, ‘A Versatile system model for the dynamic stability analysis of power system including HVDC links’,IEEE Trans. Power Apparatus Systems,Vol.PAS-100,pp.1871-1880,April 1981.
10. Pal, B., & Chaudhuri, B. (2006). Robust control in power systems. Springer Science & Business Media.
11. J. H. Chow, J.J. Sachez Gasca, ‘Pole placement design of power system stabilizers’, IEEE Trans. on Power App. Syst., vol-4, pp.271-277, Feb.1989.
12. A. Ahmed, B. Muquabel, and M.A.Abido, ‘Review of conventional PSS design methods’, GCC Conference IEEE, 2006.
13. K.E. Bollinger, A. Laha, R. Hamilton and T. Harras, ‘Power system stabilizer design using root-locus methods’, IEEE Trans. PAS., Vol. PAS-94, pp.1484-1488, Sep./Oct. 1975.
14. F.P de Mello and C. Concordia, ‘Concepts of synchronous machine stability as affected by excitation control’, IEEE Tran. On Power apparatus and systems, Vol. PAS-88 pp.316-329, April 1969.
15. Eslami, M., Shareef, H., & Mohamed, A. (2010). Application of PSS and FACTS devices for intensification of power system stability. International Review of Electrical Engineering (IREE), 5(2), 552-570.
16. N.G. Hingorani, ‘FACTS-Flexible AC Transmission System’, Proceedings of Fifth International Conference on AC and DC Power Transmission- IEE Conference Publication 345, pp.1-7, 1991.
17. A. Edris, ‘Proposed Terms and Definitions for Flexible AC Transmission System (FACTS)’, IEEE Trans. Power Delivery, Vol-12, no-4, pp. 1848-1852, 1997.
18. Singirikonda, S., Sathishgoud, G., & Harikareddy, M. (2014). Transient stability of AC generator controlled by using fuzzy logic controller. Int J Eng Res Appl, 4(3).
19. S. Panda and N. P. Padhy, ‘MATLAB/SIMULINK Based Model of Single-Machine Infinite-Bus with TCSC for Stability Studies and Tuning Employing GA,’ International Journal of Energy and Power Engineering, Vol-1(3), 2007.
20. S. Akhtar, A. Saha and P. Das, ‘Modeling, Simulation and Comparison of Various FACTS Devices in Power Systems, ‘International Journal of Engineering Research & Technology (IJERT), Vol.-1(8), October 2012.
21. D. Mohanty, A. Ahamad and M. A. Khan, ‘Modeling, Simulation and Performance Analysis of FACTS Controller in Transmission line,’ International Journal of Emerging Technology and Advanced Engineering, Volume 3, Issue 5, May 2013.
22. B.S. Nitve, ‘Modeling, Simulation and Analysis of the Thyristor-Controlled Series Capacitor (TCSC)’ Journal of Smart Grid Technology, Vol-2, Issue 2, 2017.
23. S. Sharma, ‘Modeling & Simulation Study of TCSC based Damping Controller for Power System’, International Journal of Engineering Research & Technology (IJERT),Vol. 6 Issue 04, April 2017.