Mathematical Modeling and Stability Analysis of a Hybrid Five-Level Static VAR Compensation for Efficient Power Transmission

  IJETT-book-cover  International Journal of Engineering Trends and Technology (IJETT)          
  
© 2018 by IJETT Journal
Volume-63 Number-1
Year of Publication : 2018
Authors : C.O. Omeje
DOI :  10.14445/22315381/IJETT-V63P204

Citation 

MLA Style: C.O. Omeje"Mathematical Modeling and Stability Analysis of a Hybrid Five-Level Static VAR Compensation for Efficient Power Transmission" International Journal of Engineering Trends and Technology 63.1 (2018): 17-27.

APA Style:C.O. Omeje (2018). Mathematical Modeling and Stability Analysis of a Hybrid Five-Level Static VAR Compensation for Efficient Power Transmission. International Journal of Engineering Trends and Technology, 63(1), 17-27.

Abstract
This paper presents a comprehensive analysis of a hybrid fault tolerant five-level voltage source inverter which is applied in the control of reactive power flow for a given transmission line. The mathematical modeling of this five-level Static Var Compensator formed by a cascade between a three-level flying capacitor and H-bridge in their d-q axis is presented in this work. A stability test analysis on the five-level based Static Var Compensator is illustrated herein

Reference
[1] Xiao-Ping, Z. Rehtanz, C. Bikash, P. Flexible AC Transmission Systems: Modeling and Control. Springer publishers Berlin Heidelberg New York, 2006.
[2] Hingorani, N.G. Gyugyi L. Understanding FACTS: Concepts and Technology of flexible AC Transmission System, Institute of Electrical and Electronic Engineers, New York, 2000.
[3] Enrique Acha, Claudio Fuerte-Esquivel, Hugo Ambriz-Perez and Cesar Angeles-Camacho, ?FACTS Modeling and Simulation in Power Networks?.John Wiley and sons, New York, 2004.
[4] Kejun L., Jianguo Z., Chenghui Z. and Wei-Jen L. Dynamic simulator for thyristor-controlled series capacitor. IEEE Trans. Ind. Appli., Vol. 46 pp.1096-1102, 2010.
[5] Ambriz – Perez H. Acha, E. and Fuerte-Esquivel C.R. ?Advanced SVC models For Newton-Raphson Load Flow and Newton Optimal Power flow studies?. IEEE Trans Power Systems 15(1), pp.129-136, Nov. 2000.
[6] Fuerte-Esquivel, C.R. Acha, E. Ambriz-Perez, H. ?Integrated SVC and step-down transformer model for Newton-Raphson load flow studies?, IEEE Power Engineering Review 20(2), pp. 45-46, 2000.
[7] Kale M, Ödzemir E. Harmonic and reactive power compensation with shunt active power filter under non-ideal mains voltage. Electric Power Systems Research.Vol.74, N0.3, pp. 363-370, 2005.
[8] Bouzidi M, Bouafia S, Bouzidi A, Benaissa A, Barkat S. ?Application of Backstepping to the Virtual Flux Direct Power Control of Five-Level Three-Phase Shunt Active Power Filter?. International Journal of Power Electronics and DriveSystem (IJPEDS).Vol. 4, N0.2, pp.173–191, 2014.
[9] Saad S, Zellouma L. ?Fuzzy Logic Controller for Three Level Shunt Active Filter Compensating Harmonics and Reactive Power?. Electric Power Systems Research.Vol.79, N0.10, pp.1337-1341, 2009.
[10] Xiong, L. Poh Chiang,L. Peng, W. Blaabjerg,F. Tang,Yi. and Essam A. Al-Ammar, ?Distributed Generation Using Matrix converter In Reverse Power Mode?. IEEE Transactions on Power Electronics Vol. 28, No.3, March, 2013.
[11] BENGHANEM, M.—DRAOU, A. ?A New Modeling and Control Analysis of an Advanced Static Var Compensator using a Three Level (Npc) Inverter Topology, J. Electrical Engineering
[12] Vol. 57 No. 5 (2006), pp. 285-290, 2006.
[13] Banga, A. and Kaushik, S.S. Modeling and simulation of SVC controller for enhancement of power system stability, International Journal of Advances in Engineering & Technology, Vol. 3, issue 9, pp. 79-84, 2011.
[14] Azeddine, Draou ?An Advanced Static Var Compensator Based on A Three Level IGBT Inverter Modeling Analysis and Active Power Filtering?. Journal of Electrical Engineering, Vol.63, No.6, pp. 392-396, 2012.
[15] Benghanem, M. and Draou, A. ?A New Modeling and Control Analysis of An advanced Static Var Compensator Using A Three-Level (NPC) Inverter Topology, Journal of Electrical Engineering, Vol. 57, N0.5 2006, pp.285-290.
[16] Dass, H.K. Advanced Engineering Mathematics, S.Chand and Company ltd, NewDelhi.2010.
[17] Sindhu MR, Nair G, Manjula, Nambiar TNP. ?Dynamic Power Quality Compensator with an Adaptive ShuntHybrid Filter?.International Journal of Power Electronics and Drive System (IJPEDS).Vol.4, No. 4, pp.508–516, 2014.
[18] EdrisPouresmaeil, Daniel Montesinos-Miracle, Oriol Gomis-Bellmunt, Antoni Sudrià-Andreu. ?Instantaneous Active and Reactive Current Control Technique of Shunt Active Power Filter Based On The Three-Level NPC Inverter?. European Transactions on Electrical Power System.Vol. 21 No.7, pp. 2007–2022, 2011.
[19] ChaghiAbdelaziz, Guetta Amor, BenoudjitAzzedine. Four–legged active power filter compensation for a utility distribution system. Journal of Electrical Engineering.Vol. 55 N0.2, pp.31-35, 2004.
[20] Oltean, S.E. ?Modern Control Of Static Var Compensator For Power System Stability enhancement, Scientific Bulletin of the PetruMaior? University of TîrguMure?, Vol. 9 No.1, pp. 33-37, 2012.
[21] Banga, A. and Kaushik, S.S. ?Modeling and simulation of SVC controller for enhancement of power system stability?. International Journal of Advances in Engineering & Technology, Vol. 3, issue 9, pp.79-84, 2011.

Keywords
Thyristor controlled Reactor, Hybrid Five-Level VSI, Static Var Compensator, State- Space Stability Test, Eigen Values, HVDC and Reactive power.