CROWBAR RESISTANCE SETTING AND ITS INFLUENCE ON DFIG LOW VOLTAGE RIDE THROUGH

Shengqing Li, Yao Ming, Yuwen Zhang, and Wenfeng Wu

References

  1. [1] F. Wang and J. Jiang, Wind power with a dual PWM converter control strategy of the power balance of joint research, Proceedings of the CSEE, 26(22), 2006, 134–139.
  2. [2] Y. She, W. Jiang, C. Kan, et al., An optimization control system of back-to-back front-end rectifier under unbalanced grid, Proceedings of the CSEE, 35(09), 2015, 2261–2271.
  3. [3] Y. Chi, W. Wang, and H. Dai, Improve grid wind farms based on doubly-fed induction generator transient voltage stability study, Proceedings of the CSEE, 25(27), 2007, 25–31.
  4. [4] F. Nagata, K. Kuribayashi, K. Kiguchi, and K. Watanabe, Simulation of fine gain tuning using genetic algorithms for model-based robotic servo controllers, Proc. IEEE Int. Symp. Computational Intelligence in Robotics and Automation, IEEE, Jacksonville, USA, 2007, 196–201.
  5. [5] Y.Y. Wu and Y.Q. Wu, Stability analysis for recurrent neural networks with time-varying delay, International Journal of Automation and Computing, 6(3), 2009, 223–227.
  6. [6] J.C. Zagal and J. Ruiz-del-Solar, Combining simulation and reality in evolutionary robotics, Journal of Intelligent and Robotic Systems, 50(1), 2007, 19–39.
  7. [7] E. Papadopoulos, I. Papadimitriou, and I. Poulakakis, Polynomial-based obstacle avoidance techniques for nonholonomic mobile manipulator systems, International Journal of Robotics and Automation, 41(4), 2005, 229–247.
  8. [8] J.A. Yang and Y.B. Zhuang, An improved a technology optimization algorithm for solving a complex combinatorial optimization problem, Applied Soft Computing, 10(2), 2010, 653–660.
  9. [9] X.J. Jing, Behavior dynamics based motion planning of mobile robots in uncertain dynamic environments, International Journal of Robotics and Automation, 53, 2005, 99–123.
  10. [10] J.A. Fernández Le´on, F.M. Tosini, G. Acosta, and H.N. Acosta, An experimental study on evolutionary reactive behaviours for mobile robots navigations, Journal of Computer Science and Technology, 5(4), 2005, 183–188.
  11. [11] S. Kamio and H. Iba, Adaptation technique for integrating genetic programming and reinforcement learning for real robot, IEEE Transactions on Evolutionary Computation, 9(3), 2005, 318–333.
  12. [12] X. Chen, K. Watanabe, K. Kiguchi, and K. Izumi, Path tracking based on closed-loop control for a quadruped robot in a cluttered environment, ASME Transactions on Dynamic systems, Measurement and Control, 124, 2002, 272–280.
  13. [13] P. Graham, J. David, B.Z. Atkinson, A analytical study of grid-fault response of wind turbine, doubly-fed induction generator, IEEE Transactions on Energy Conversion, 25(4), 2010, 1081–1091.
  14. [14] J. Morren and S.W.H.S. Haan, Three-phase short-circuit current of wind turbines with doubly fed induction generator, IEEE Transactions on Energy Conversion, 22(1), 2007, 174–180.
  15. [15] LI da analysis D of short circuit currenournal of Intelligent and Robotic Systems of wind turbine, doubly-fed induction generator, Proc. IEEE Conf. 1st industrial Electronics and Applications, May 24-26200-6, Singapore, 1–5.
  16. [16] X. Zhang, D. Xu, and W. Li, Analysis of three-phase short circuit current of doubly fed induction generator, Journal of Motor and Control, 12(5), 2008, 493–497.
  17. [17] Y. He and G. Hu, Doubly-fed asynchronous wind turbine several hot problems in parallel operation, Proceedings of the CSEE, 32(27), 2012, 1–15.
  18. [18] Y. Zhong, S. Li, et al., Induction wind turbine LVRT measure on line overcurrent protection effect, Proceedings of the CSUEPSA, 28(06), 2016, 19–25
  19. [19] J. Vidal, G. Abad, J. Arza, et al., The single-phase DC crowbar topologies for low voltage ride through fulfillment of high-power doubly fed induction generator based wind turbines, IEEE Transactions on Energy Conversion, 32(1), 2013, 37–49.
  20. [20] D. Xu, W. Wang, and N. Chen, Based on the lever to protect doubly-fed wind power low voltage motor through dynamic characteristic analysis, Proceedings of the CSEE, 45(22), 2010, 29–36.
  21. [21] D. Xiang, S. Yang, and R. Li, Grid symmetrical failure doublyfed induction generator is not to take off the network running system simulation, Proceedings of the CSEE, 18(10), 2006, 130–135.
  22. [22] Y. Zhang, R. Tong, J. Zhao, et al., Doubly-fed wind power generator transient characteristic and low voltage across solutions, Automation of Electric Power Systems, 37(6), 2013, 7–11.
  23. [23] Y. He and P. Zhou, Variable speed constant frequency doublyfed asynchronous wind power system low voltage through technical review, Journal of Electrotechnics, 24(9), 2009, 140–146.
  24. [24] X. Zhu, L. Shi, N. Chen, et al., Considering crowbar resistance and exit time of doubly-fed wind power generator is low voltage across, Automation of Electric Power Systems, 38(18) 2010, 84–89.
  25. [25] L. Wei, Y. Chen, and G. Chen, Doubly-fed induction wind turbines low voltage through the theoretical analysis and experimental research of control strategy, Electric Technology, 25(7), 2011, 30–36.
  26. [26] S. Hu, D. Zhao, B. Zhao, et al., Doubly-fed wind power generator test research the characteristic of low voltage across, High Voltage Technology, 18(03), 2010, 789–795.
  27. [27] J. Yao, Y. Liao, and H. Li, String of networking side converter of DFIG wind power system low voltage through control, Automation of Electric Power Systems, 8(6), 2010, 98–103.
  28. [28] S. Qi, F. Li, S. He, et al., With low voltage through the ability to cluster access wind fault characteristic simulation, Power System Protection and Control, 43(14), 2015, 55–62.
  29. [29] Z. Liu, C. Liu, and G. Li, For improving the capability of direct-drive permanent magnet low voltage through the fan power coordinated control method, Automation of Electric Power Systems, 12(3), 2015, 23–29.
  30. [30] C. Wei, X. Song, et al., A doubly-fed induction wind generator control strategy of low voltage across, Journal of electrotechnics, 32(9), 2010, 170–175.
  31. [31] M. Zhang and H. Jiang, Adaptive low voltage ride-through of doubly-fed induction generators based on crowbar with a parallel dynamic resistor, Transactions of China Electrotechnical Society, 29(02), 2014, 271–278.
  32. [32] P. Su, Y. Zhang, Based on the active type IGBT crowbar LVRT doubly-fed wind power system simulation, Power System Protection and Control, 38(23), 2010, 164–171.
  33. [33] H. Ma, G. Yong, Y. Yang, et al., Fuzzy optimization of crowbar resistance for low-voltage ride through of doubly-fed induction generators, Proceedings of the CSEE, 32(34), 2012, 17–23.
  34. [34] J. Yang, J.E. Fletcher, and J. O’Reilly, A series dynamic resistor based crowbar protection scheme for doubly-fed induction generator during various fault conditions, IEEE Transactions on Energy Conversion, 25(2), 2010, 422–432.
  35. [35] I. Erlich, W. Winter, and A. Dittrich, Advanced grid requirements for the integration of wind turbines into the germane transmission system, Power Engineering Society General Meeting, Montreal, Que. Duisburg University, 2006, 1–7.
  36. [36] J. Li and H. Xu, Low voltage ride through technology of wind power generation system (Beijing: Machery Industry Press, 2008).

Important Links:

Go Back