DFIG Fault Ride Through Improvement During VSC Faults

A. F. Abdou, A. Abu-Siada, H. R. Pota

Abstract


The sensitivity of the doubly fed induction generator (DFIG) to external faults has motivated researchers to investigate the impact of various grid disturbances such as voltage sag and short circuit faults on the fault ride through (FRT) capability of the DFIG. However, no attention has been given to the impact of internal faults within voltage source converters (VSCs) that interface the DFIG with the grid, on the dynamic performance of the machine. This paper investigates the impact of various VSC faults on the dynamic performance and the FRT capability of the DFIG. Faults such as fire-through and flashover within the VSC switches are considered in this paper. Moreover, faults across the DC-link capacitor are included in this study as a common problem in the VSCs. The impact of these faults when they occur within the grid side converter (GSC) and rotor side converter (RSC) are investigated. A proper STATCOM controller to mitigate the effects of these faults on the FRT is proposed. The DFIG compliance with numerous and recently released FRT grid codes under these faults with and without the STATCOM are examined and compared. Furthermore, the capability of a proposed controller to bring the voltage profile at the point of common coupling (PCC) to the nominal steady-state level under five possible VSC faults cases is examined. The proposed controller is efficient, simple, and easy to implement.

Keywords


DFIG, Fire-through, Flashover, STATCOM, FRT, VSC, RSC, GSC, Grid codes

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References


[1] Abdou, A. F., Abu-Siada, A., & Pota, H. R. (2011a, 25-28 Sept. 2011). Application of a STATCOM for damping subsynchronous oscillations and transient stability improvement. Paper Presented at the Universities Power Engineering Conference (AUPEC), 2011 21st Australasian.

[2] Abdou, A. F., Abu-Siada, A., & Pota, H. R. (2011b, 13-16 Nov. 2011). Damping of subsynchronous oscillations and improve transient stability for wind farms. Paper Presented at the Innovative Smart Grid Technologies Asia (ISGT), 2011 IEEE PES.

[3] Abdou, A. F., Abu-Siada, A., & Pota, H. R. (2012a). Application of STATCOM to improve the LVRT of DFIG during DC-link Capacitor Failure. Paper Presented at the Fifteenth International Middle East Power Systems Conference (MEPCON), 2012

[4] Abdou, A. F., Abu-Siada, A., & Pota, H. R. (2012b, 26-29 Sept. 2012). Application of STATCOM to improve the LVRT of DFIG during RSC fire-through fault. Paper Presented at the Universities Power Engineering Conference (AUPEC), 2012 22nd Australasian.

[5] Abdou, A. F., Abu-Siada, A., & Pota, H. R. (2013). Effect of Intermittent Voltage Source Converter Faults on the Overall Performance of Wind Energy Conversion System. International Journal of Sustainable Energy, 1-13.

[6] Abu-Siada, A., & Islam, S. Application of SMES Unit in Improving the Performance of an AC/DC Power System. Sustainable Energy, IEEE Transactions on, 2(2), 109-121.

[7] Ackermann, T. (2005). Wind Power in Power System. West Sussex: John Wiley and Sons Ltd.

[8] Altin, M., Goksu, O., Teodorescu, R., Rodriguez, P., Jensen, B. B., & Helle, L. (2010, 20-22 May 2010). Overview of recent grid codes for wind power integration. Paper Presented at the Optimization of Electrical and Electronic Equipment (OPTIM), 2010 12th International Conference on.

[9] Arrillaga, J. (1998). High voltage direct current transmission. Institution of Electrical Engineers.

[10] Arrillaga, J., Liu, Y. H., & Watson, N. R. (2007). Flexible power transmission: the HVDC options. John Wiley.

[11] Bin, L., & Sharma, S. (2008). A survey of IGBT fault diagnostic methods for three-phase power inverters. Paper presented at the Condition Monitoring and Diagnosis, 2008. CMD 2008. International Conference on.

[12] Bin, L., & Sharma, S. K. (2009). A Literature Review of IGBT Fault Diagnostic and Protection Methods for Power Inverters. Industry Applications, IEEE Transactions on, 45(5), 1770-1777.

[13] Campos-Gaona, D., Moreno-Goytia, E. L., Anaya-Lara, O., & Burt, G. (2010, 19-21 Oct. 2010). Ride-through-fault capabilities of DFIG wind farm connected to a VSC station during a DC fault. Paper Presented at the AC and DC Power Transmission, 2010. ACDC. 9th IET International Conference on.

[14] Darwish, H. A., Taalab, A. M. I., & Rahman, M. A. (2006). Performance of HVDC Converter Protection During Internal Faults. Paper Presented at the Power Engineering Society General Meeting, 2006. IEEE.

[15] Faried, S. O., & El-Serafi, A. M. (1997). Effect of HVDC converter station faults on turbine-generator shaft torsional torques. Power Systems, IEEE Transactions on, 12(2), 875-881.

[16] Fuchs, F. W. (2003, 2-6 Nov. 2003). Some diagnosis methods for voltage source inverters in variable speed drives with induction machines-a survey. Paper Presented at the Industrial Electronics Society, 2003. IECON ‘03. The 29th Annual Conference of the IEEE.

[17] Global Wind Statistics 2011. Global Wind Energy Council. Retrieved from http://www.gwec.net/

[18] Gole, A. M., Filizadeh, S., & Wilson, P. L. (2005). Inclusion of Robustness into Design Using Optimization-Enabled Transient Simulation. Power Delivery, IEEE Transactions on, 20(3), 1991-1997.

[19] He, R.-M., Wang, J.-L., Ma, J., Xu, Y.-H., & Han, D. (2009). Impacts of DFIG-based wind farm on load modeling. Paper Presented at the Power & Energy Society General Meeting, 2009. PES ‘09. IEEE.

[20] Hingorani, N. G., & Gyugyi, L. (2000). Understanding FACTS: concepts and technology of flexible AC transmission systems. IEEE Press.

[21] Ibrahim, A. O., Thanh Hai, N., Dong-Choon, L., & Su-Chang, K. (2011). A Fault Ride-Through Technique of DFIG Wind Turbine Systems Using Dynamic Voltage Restorers. Energy Conversion, IEEE Transactions on, 26(3), 871-882.

[22] Khederzadeh, M. (2007). Coordination Control of Statcom and Ultc of Power Transformers. Paper Presented at the Universities Power Engineering Conference, 2007. UPEC 2007. 42nd International.

[23] Lopez, J., Sanchis, P., Roboam, X., & Marroyo, L. (2007). Dynamic Behavior of the Doubly Fed Induction Generator During Three-Phase Voltage Dips. Energy Conversion, IEEE Transactions on, 22(3), 709-717.

[24] Musgrove, P. (2010). Wind Power. New York: Cambridge University Press.

[25] Nelder, J. A., & Mead, R. (1965). A Simplex Method for Function Minimization. The Computer Journal, 7(4), 308-313.

[26] Padiyar, K. R. (1990). HVDC Power Transmission Systems: Technology and System Interactions. Wiley.

[27] Padiyar, K. R., & Kulkarni, A. M. (1997). Design of Reactive Current and Voltage Controller of Static Condenser. International Journal of Electrical Power & Energy Systems, 19(6), 397-410.

[28] Pena, R., Clare, J. C., & Asher, G. M. (1996). Doubly Fed Induction Generator Using Back-To-Back PWM Converters and Its Application to Variable-Speed Wind-Energy Generation. Electric Power Applications, IEE Proceedings, 143(3), 231-241.

[29] Petersson, A., & Lundberg, S. (2002). Energy Efficiency Comparison of Electrical Systems for Wind Turbines. Paper Presented at the Nordic Workshop on Power and Industrial Electronics, Stockholm, Sweden.

[30] Rahimi, M., & Parniani, M. (2010). Transient Performance Improvement of Wind Turbines With Doubly Fed Induction Generators Using Nonlinear Control Strategy. Energy Conversion, IEEE Transactions on, 25(2), 514-525.

[31] Rolan, A., Corcoles, F., & Pedra, J. (2011). Doubly Fed Induction Generator Subject to Symmetrical Voltage Sags. Energy Conversion, IEEE Transactions on, 26(4), 1219-1229.

[32] Sethom, H. B. A., & Ghedamsi, M. A. (2008). Intermittent Misfiring Default Detection and Localisation on a PWM Inverter Using Wavelet Decomposition. Journal of Electrical Systems, 4(2). 222-234.

[33] Shaoyong, Y., Bryant, A., Mawby, P., Dawei, X., Li, R., & Tavner, P. (2011). An Industry-Based Survey of Reliability in Power Electronic Converters. Industry Applications, IEEE Transactions on, 47(3), 1441-1451.

[34] Sheng, H., Xinchun, L., Yong, K., & Xudong, Z. (2011). An Improved Low-Voltage Ride-Through Control Strategy of Doubly Fed Induction Generator During Grid Faults. Power Electronics, IEEE Transactions on, 26(12), 3653-3665.

[35] Shuhui, L., & Haskew, T. A. (2007). Analysis of Decoupled d-q Vector Control in DFIG Back-to-Back PWM Converter. Paper Presented at the Power Engineering Society General Meeting, 2007.

[36] Tsili, M., & Papathanassiou, S. (2009). A Review of Grid Code Technical Requirements for Wind Farms. Renewable Power Generation, IET, 3(3), 308-332.

[37] Van-Tung, P., & Hong-Hee, L. (2012). Performance Enhancement of Stand-Alone DFIG Systems With Control of Rotor and Load Side Converters Using Resonant Controllers. Industry Applications, IEEE Transactions on, 48(1), 199-210.

[38] Xin, L., Tao, Z., Yongning, C., & Weisheng, W. (2009, 27-31 March 2009). Short Circuit Current Characteristic of Wind Generators. Paper Presented at the Power and Energy Engineering Conference, 2009. APPEEC 2009. Asia-Pacific.

[39] Xing, Z., Tingyu, Q., Zhen, X., & Renxian, C. (2011, 15-17 July 2011). Dynamic analysis of doubly fed induction generator during symmetrical voltage swells. Paper Presented at the Mechanic Automation and Control Engineering (MACE), 2011 Second International Conference on.

[40] Zhe, C., Guerrero, J. M., & Blaabjerg, F. (2009). A Review of the State of the Art of Power Electronics for Wind Turbines. Power Electronics, IEEE Transactions on, 24(8), 1859-1875.




DOI: http://dx.doi.org/10.3968/j.est.1923847920130501.772

DOI (PDF): http://dx.doi.org/10.3968/g3629

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