Scientific Reports (Nov 2024)

SSO optimized FOFPID regulator design for performance enhancement of doubly fed induction generator based wind turbine system

  • Rafik Dembri,
  • Lazhar Rahmani,
  • Badreddine Babes,
  • Hatim G. Zaini,
  • Sherif S. M. Ghoneim,
  • Amanuel Kumsa Bojer,
  • Aymen Flah,
  • Ahmed B. Abou Sharaf

DOI
https://doi.org/10.1038/s41598-024-76457-z
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 25

Abstract

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Abstract A wind turbine system (WTS) is a highly coupled and nonlinear system where the output power depends upon highly uncertain wind speed. Therefore, the quality of produced power becomes a challenging problem for researchers. Direct Vector Control (DVC) is a powerful and widely utilized power control strategy to deal with winds that vary rapidly and randomly. As a result, this article employed the newly developed Social Spider Optimization (SSO) technique to optimize the design parameters of Fractional-Order Fuzzy Proportional-Integral with Derivative (FOFPID) regulator to maintain the output power of the studied DFIG-based WTS at the rated value under dynamic wind conditions. The suggested FOFPID controller integrates the capabilities of the Fuzzy intelligent regulator and the Fractional-Order controller, enhancing DFIG current control while allowing independent control of active and reactive power. The approach is incorporated within the DVC strategy of the DFIG’s rotor-side converter (RSC), replacing the conventional Proportional-Integral (PI) regulator in the internal current loops. Extensive performance evaluations are conducted under various operating conditions, including active power reference changes, parameter uncertainties, and rapid wind speed variations. Comparative analyses with SSO-optimized PID and Fuzzy regulators show that the FOFPID regulator performs better in terms of maximum overshoot, extreme undershoot, settling time, Total Harmonic Distortion (THD), and Weighted Total Harmonic Distortion (WTHD). The suggested FOFPID regulator also displays stronger robustness against parameters mismatch and weather change than other regulator architectures.

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