A comparative study between three-level NSVPWM and two-level NSVPWM strategy for a DFIG-based WTS controlled by neuro-second order sliding mode

  • Habib BENBOUHENNI Ecole Nationale Polytechnique d'Oran Maurice Audin, Oran, Algeria
Keywords: 3L-NSVPWM, 2L-NSVPWM, NSOSMC, DFIG, WTS.

Abstract

In this article, we present a comparative study between three-level neural space vector pulse width modulation (3L-NSVPWM) and two-level neural space vector pulse width modulation (2L-NSVPWM) strategy in neuro-second order sliding mode control (NSOSMC) of  stator active and stator reactive power command of a doubly fed induction generator (DFIG) for wind turbine systems (WTSs). Two commands schemes using NSOSMC-3L-NSVPWM and NSOSMC-2L-NSVPWM are proposed and compared. The validity of the proposed commands schemes is verified by simulation tests of a DFIG. The rotor current, active power and reactive power is determined and compared in the above techniques. The obtained results showed that the proposed NSOSMC with 3L-NSVPWM strategy have stator active and reactive power with low powers ripples and low rotor current harmonic distortion than 2L-NSVPWM strategy.

 

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Published
2020-01-09
Section
Articles