MAXIMUM POWER QUALITY TRACKING OF ARTIFICIAL NEURAL NETWORK CONTROLLER-BASED DOUBLE FED INDUCTION GENERATOR FOR WIND ENERGY CONVERSION SYSTEM
DOI:
https://doi.org/10.59277/RRST-EE.2024.2.12Keywords:
Artificial neural network (ANN), Doubly fed induction generator (DFIG), Wind energy conversion systems (WECSs), Distribution static compensator (DSTATCOM), Total harmonics distortion (THD), Power quality (PQ)Abstract
Renewable energy sources are playing a crucial role in satisfying the upcoming energy source needs for the world. The current power system is power electronics converter based, with several non-linear loads and spotted generations of renewable energy sources, resulting in many power quality issues. Most existing research analyzed MATLAB simulations and presented a high Total Harmonics Distortion (THD) level. This research work proposed an artificial neural network (ANN) control technique for a doubly fed induction generator (DFIG) based wind energy conversion systems (WECSs). To decrease chattering phenomena during the excitation arrangement, an advanced controller works for adaptive modification of the irregular power gain, even preserving the strength of the closed-loop scheme. The proposed PI controller one step forward improves reliability and tracks maximum voltage from the pulse width modulation rectifier. At primary, the modeling of the DFIG was presented. Then, using the proposed ANN controller, the rotor magnitude was tuned to recognize vector control of active and reactive power. The converter intends to activate at unity power factor and provide input currents with adequate harmonic content. The interface between the power’s electronic converter and the DFIG pulls out the most real power potential. The proposed prototype hardware model and simulation results are verified.
References
(1) T. Jiang, Y. Zhang, Robust predictive rotor current control of doubly fed induction generator under unbalanced and distorted grid, IEEE Trans. Energy Convers (2021)
(2) D. Xu, F. Blaabjerg, W. Chen, N. Zhu, Advanced control of doubly fed induction generator for wind power systems, Hoboken, NJ, USA, Wiley (2018).
(3) M.R. Agha Kashkooli, S.M. Madani, T.A. Lipo, Improved direct torque control for a DFIG under symmetrical voltage dip with transient flux damping, IEEE Trans. Ind. Electron., 67, 1, pp. 28–37 (2020).
(4) C. Cheng, H. Nian, Low-complexity model predictive stator current control of DFIG under harmonic grid voltages, IEEE Trans. Energy Conv., 32, 3, pp. 1072–1080 (2017).
(5) P. Cheng, C. Wu, J. Ma, F. Blaabjerg, Coordinated derived current control of DFIG’s RSC and GSC without PLL under unbalanced grid voltage conditions, IEEE Access, 8, pp. 64760–64769, (2020).
(6) L. Fan, S. Yuvarajan, R. Kavasseri, Harmonic analysis of a DFIG for a wind energy conversion system, IEEE Trans. Energy Conv., 25, 1, pp. 181–190 (2010).
(7) ***Centre for Wind Energy Technology, Ministry of New and Renewable Energy, Central Government of India, Indian Wind Grid Code, New Delhi, India (2009).
(8) S. Tamalouzt, K. Idjdarene, T. Rekioua, R. Abdessemed, Direct torque control of wind turbine driven doubly fed induction generator, Rev. Roum. Sci. Techn. – Électrotechn et Énerg., 61, 3, pp. 244–249 (2016).
(9) F. Amrane, A. Chaiba, B.E. Babes, S. Mekhilef, Design implementation of high-performance field-oriented control for grid-connected doubly fed induction generator via hysteresis motor current controller, Rev. Roum. Sci. Techn. Électrotechn. et Énerg., 61, 4, pp. 319–324, Bucharest (2016).
(10) F. Amrane, A. Chaiba, B. Francois, B.E. Babes, Real time implementation of grid - connection control using robust PLL for WECS in variable speed DFIG-based on HCC, IEEE Xplore (2017).
(11) F. Amrane, A. Chaiba, A novel direct power control for grid connected doubly fed induction generator based on hybrid artificial intelligent control with space vector modulation, Rev. Roum. Sci. Techn. -Électrotechn. et Energ., 61, 3 pp. 263–268 (2016).
(12) F. Amrane, A. Chaiba, B. Francois, B.E. Babes, Experimental design of stand-alone field-oriented control for WECS in variable speed DFIG-based on hysteresis current controller, IEEE Xplore (2017).
(13) B. Babes, A. Boutaghane, N. Hamouda, Design and real-time implementation of an adaptive fast terminal synergetic controller based on dual BF neural networks of voltage control Dc to Dc step down converter, Electrical engineering, Springer (2022).
(14) M.M. Kiani, W. Wang, W. Lee, Elimination of system-induced torque pulsations in doubly-fed induction generators via field reconstruction method, IEEE Trans. Energy Conv., 30, 3, pp. 1228–1236 (2015).
(15) J. Samanes, E. Gubia, J. Lopez, R. Taberna, Sub-synchronous resonance damping control strategy for DFIG wind turbines, IEEE, 8 (2020).
(16) M.A. Soliman, H.M. Hasanien, A. Al-Durra, M. Debouza, High performance frequency converter-controlled variable-speed wind generator using linear-quadratic regulator controller, IEEE Transactions on Industry Applications, 56, 5, pp. 5489–5498 (2020).
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