EFFECTIVENESS OF SGSC IN A GRID CONNECTED DFIG-WT SYSTEM DURING GRID VOLTAGE DISTURBANCES, 42-55.

Subir Datta, Jyoti P. Mishra, and Anjan K. Roy

References

1. [1] B.H. Chowdhury and S. Chellapilla, Double fed induction generator control for variable speed wind power generation, Elsevier Power System Research, 76, 2006, 786–800.
2. [2] M. Cheng and Y. Zhu, The state of the art of wind energy conversion systems and technologies: A review, Energy Conversion and Management, 88, 2014, 332–347.
3. [3] J. Lopez, P. Sanchis, X. Roboam, and L. Marroyo, Dynamic behaviour of the doubly fed induction generator during three-phase voltage dips, IEEE Transactions on Energy Conversion, 22(3), 2007, 709–717.
4. [4] Z. Chen, Compensation schemes for a SCR converter in variable speed wind power systems, IEEE Transactions on Power Delivery, 19(2), 2004, 813–821.
5. [5] IEEE, IEEE recommended practices and requirements for harmonic control in electrical power systems, IEEE Std. 519-2014 (June 11, 2014).
6. [6] R. Piwko, N. Miller, G. Sanchez, X. Yuan, R. Dai, and J. Lyons, Integrating large wind farms into weak power grids with long transmission lines, Proc. IEEE/PES Transmission and Distribution Conf. and Exhibition, Dalian, 2005, 1–7.
7. [7] J. Morren and S.W.H. Haan, Ride through of wind turbines with doubly-fed induction generator during a voltage dip, IEEE Transactions Energy Conversions, 20(2), 2005, 435–441.
8. [8] W. Qiao, R.G. Harley, and G.K. Vanayagamoorthy, Coordinated reactive power control of a large wind farm and a STATCOM using heuristic dynamic programming, IEEE Transactions Energy Conversions, 24(2), 2009, 493–503.
9. [9] H. Amaris and M. Alfonso, Coordinated reactive power management in power networks with wind turbines and FACTS devices, Energy Conversion and Management, 52(7), 2011, 2575–2586.
10. [10] A. Rahim and E. P. Nowicki, Super capacitor energy storage system for fault ride-through of a DFIG wind generation system, Energy Conversion and Management, 59, 2010, 96–102.
11. [11] O.A. Baqi and A. Nasiri, Series voltage compensation for DFIG wind turbine low voltage ride through solution, IEEE Transactions Energy Conversions, 26(1), 2011, 272–802.
12. [12] S. Zhang, K.J. Tseng, S. Choi, T.D. Nguyen, and D.L. Yao, Advanced control of series voltage compensation to enhance wind turbine ride through, IEEE Transactions Power Electronics, 27(2), 2011, 763–772.
13. [13] A. Leon, M.F. Farias, P.E. Battaiotto, J.A. Solsona, and M.I. Valla, Control strategy of a DVR to improve stability in wind farms using squirrel-cage induction generators, IEEE Transactions on Power Systems, 26(3), 2011, 1609–1617.
14. [14] C. Wessels, F. Gebhardt, and F.W. Fuchs, Fault ride-through of a DFIG wind turbine using dynamic voltage restorer during symmetrical and asymmetrical grid faults, IEEE Transactions on Power Electronics, 26(3), 2011, 807–815.
15. [15] R.A. Jerin, N. Prabaharan, K. Palanisamy, and S. Umashankar, FRT capability in DFIG based wind turbines using DVR with combined feed-forward and feed-back control, International Conf. on Alternative Energy in Developing Countries and Emerging Economies, Bangkok, Thailand, May 2017.
16. [16] R.A. Jerin, N. Prabaharan, K. Palanisamy, and S. Umashankar, Improved fault ride through capability of DFIG based wind turbines using synchronous reference frame control based dynamic voltage restorer, ISA Transactions, 70, 2017, 465–474.
17. [17] D. Zhu, L. Deng, and Q. Huang, Inductance-simulating control for DFIG-based wind turbine to ride-through grid faults, IEEE Applied Power Electronics Conf. and Exposition (APEC), Long Beach, CA, USA, March 2016, 3521–3525.
18. [18] I. Khan, K. Zeb, W.U. Din, S.U. Islam, M. Ishfaq, S. Hussain, and H.J. Kim, Dynamic modeling and robust controllers design for doubly fed induction generator-based wind turbines under unbalanced grid fault conditions, Energies, 12, 2019, 1–23.
19. [19] W. Uddin, K. Zeb, A. Tanoli, and A. Haider, Hardware-based hybrid scheme to improve the fault ride through capability of doubly fed induction generator under symmetrical and asymmetrical faults, IET Generation, Transmission and Distribution, 12, 2017, 200–206.
20. [20] P.S. Flannery and G. Venkataramanan, Unbalanced voltage sag ride-through of a doubly fed induction generator wind turbine with series grid-side converter, IEEE Transactions on Industry Applications, 45(5), 2009, 1879–1887.
21. [21] P.S. Flannery and G. Venkataramanan, A fault tolerant doubly fed induction generator wind turbine using a parallel grid side rectifier and series grid side converter, IEEE Transactions on Power Electronics, 23(3), 2008, 1126–1135.
22. [22] L. Xu and Y. Wang, Dynamic modeling and control of DFIG based wind turbines under unbalanced network conditions, IEEE Transactions on Power Systems, 22(1), 2007, 314–323.
23. [23] A.O. Ibrahim, T.H. Nguyen, D.C. Lee, and S.C. Kim, A fault ride through technique of DFIG wind turbine systems using dynamic voltage restorers, IEEE Transactions on Energy Conversion, 26(3), 2011, 871–882.
24. [24] Y. Liao, H. Li, J. Yao, and K. Zhuang, Operation control of a grid connected DFIG based wind turbine with series grid-side converter during network unbalance, Elsevier Electrical Power systems Research, 81(1), 2011, 228–236.
25. [25] J. Yao, H. Li, Z. Chen, X. Xia, X. Chen, Q. Li, and Y. Liao, Enhanced control of a DFIG-based wind-power generation system with series grid-side converter under unbalanced grid voltage conditions, IEEE Transactions on Power Electronics, 28(7), 2013, 3167–3181.
26. [26] J.G. Neilson and F. Blaabjerg, Comparison of system topologies for dynamic voltage restorer, Conf. Rec. IEEE/IAS Annual Meeting, Vancouver, Canada, 2001.
27. [27] N.H. Woodley, L. Morgan, and A. Sundaram, Experience with an inverter-based dynamic voltage restorer, IEEE Transactions on Power Delivery, 14(3), 1999, 1181–1186.
28. [28] M. Vilathgamuwa, A.A.D.R. Perera, S.S. Choi, and K.J. Tseng, Control of energy optimized Dynamic Voltage Restorer, Conf. Rec. IEEE/IECON, San Jose, CA, 1999.
29. [29] G.N. John, N. Michael, N. Hans, and B. Frede, Control and testing of a dynamic voltage restorer (DVR) at medium voltage level, IEEE Transactions on Power Electronics, 19(3), 2004, 806–813.
30. [30] S. Datta, J.P. Mishra, and A.K. Roy, Unbalance and non-linear stator voltage control of a grid connected DFIG based WECS using NSC, 12th IEEE India International Conf. Electronics, Energy, Environment, Communication, Computer, Control, (E3-C3), Delhi, India, December 2015.
31. [31] Z. Lei, P.C. Loh, and F. Gao, An integrated nine-switch power conditioner for power quality enhancement and voltage sag mitigation, IEEE Transaction on Power Electronics, 27(3), 2012, 1177–1190.
32. [32] S. Datta, J.P. Mishra and A.K. Roy, Operation and control of a DFIG based grid connected WECS using NSC during grid fault and with unbalance non-linear load, International Journal of Ambient Energy, 39(7), 2018, 732–742.
33. [33] R. Pena, J.C. Clear, and G.M. Asher, Doubly fed induction generator using back-to-back PWM converters and its application to variable speed wind energy generation, IEE Proceedings – Electric Power Applications, 143(3), 1996, 231–241.

Important Links:

• Abstract
• DOI: 10.2316/J.2019.203-0101
• From Journal (203) International Journal of Power and Energy Systems - 2019

Go Back