DFIG-Based Wind Turbine System using Four-Level FSVM Strategy

  • Habib Benbouhenni Ecole Nationale Polytechnique d'Oran Maurice Audin, Oran, Algeria
  • Zinelaabidine Boudjema university of Chlef
  • Abdelkader Belaidi Ecole Nationale Polytechnique d'Oran Maurice Audin, Oran, Algeria
Keywords: Keywords—Direct vector command; doubly fed induction generator; space vector modulation; fuzzy space vector modulation; fuzzy logic.

Abstract

Abstract—Traditional direct vector command (DVC) structures which include proportional-integral (PI) regulators of a doubly fed induction generator (DFIG) driven have some disadvantages such as parameter tuning complications, mediocre dynamic performances and reduced robustness. Thus, based on analysis of the DFIG model supplied by new modulation technique, this article addresses a four-level space vector modulation (SVM) based on fuzzy logic algorithm (FSVM). The classical DVC command with SVM technique has large ripples on the stator active and stator reactive developed by the DFIG. In order to solve this disadvantage, the DVC command with FSVM technique is proposed. Simulation results show the effectiveness of the proposed command scheme especially in power ripples behavior, reference tracking test and robustness against generator parameters variations.

References

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Published
2018-11-02
How to Cite
Benbouhenni, H., Boudjema, Z., & Belaidi, A. (2018). DFIG-Based Wind Turbine System using Four-Level FSVM Strategy. Majlesi Journal of Energy Management, 6(3), 7-19. Retrieved from https://em.majlesi.info/index.php/em/article/view/334
Issue
Vol 6 No 3 (2017): September
Section
Articles

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