Comparative performance analysis of variable speed controllers in a wind energy system using NARMA L2 neuro-controller and Super- twisting sliding mode controller

Senouci, Meriem; Benzergua, Fadela; Khalfallah, Naima

doi:10.15199/48.2023.09.28

Artykuł - szczegóły

Tytuł artykułu

Comparative performance analysis of variable speed controllers in a wind energy system using NARMA L2 neuro-controller and Super- twisting sliding mode controller

Autorzy

Senouci Meriem , Benzergua Fadela , Khalfallah Naima

Wybrane pełne teksty z tego czasopisma

http://pe.org.pl/

Identyfikatory

DOI

10.15199/48.2023.09.28

Warianty tytułu

Analiza porównawcza wydajności regulatorów zmiennej prędkości w systemie energetyki wiatrowej z wykorzystaniem neurokontrolera NARMA L2 i kontrolera trybu ślizgowego Super-skręcanie

Języki publikacji

Abstrakty

Wind turbine performance is affected by wind speed, which can cause fluctuations in the frequency and voltage levels of the grid, leading to blackouts. To preserve grid stability, it is important to regulate wind turbine speed. In this paper, a comparative study of a super-twisting sliding mode controller and a NARMA L2 neuro-controller is implemented to control variable speed in a wind generator system, regarding their overshoot value, settling time, and rise time. The proposed controller’s performance has been verified in MATLAB®/Simulink. The simulation results indicate the greater performance of the NARMA-L2 neuro-controller in terms of robustness and the fastest dynamic response.

Na wydajność turbiny wiatrowej wpływa prędkość wiatru, która może powodować wahania częstotliwości i napięcia w sieci, co prowadzi do przerw w dostawie prądu. Aby zachować stabilność sieci, ważne jest, aby regulować prędkość turbiny wiatrowej. W niniejszej pracy przeprowadzono analizę porównawczą super-skrętnego regulatora trybu ślizgowego i neuro-kontrolera NARMA L2 do sterowania zmienną prędkością w systemie generatora wiatrowego, w odniesieniu do ich wartości przekroczenia, czasu ustalania i czasu narastania. Działanie proponowanego regulatora zostało zweryfikowane w programie MATLAB®/Simulink. Wyniki symulacji wskazują na większą wydajność neurosterownika NARMA-L2 w zakresie odporności i najszybszej odpowiedzi dynamicznej.

Słowa kluczowe

turbine model speed control NARMA L2 super-twisting sliding mode

model turbiny regulacja prędkości obrotowej NARMA L2 tryb ślizgowy z super skrętem

Wydawca

Wydawnictwo SIGMA-NOT

Czasopismo

Przegląd Elektrotechniczny

Rocznik

2023

Tom

R. 99, nr 9

Strony

150--154

Opis fizyczny

Bibliogr. 20 poz., rys., tab.

Twórcy

autor

Senouci Meriem

meriem.senouci@univ-usto.dz

Applied Power Electronics Laboratory (LEPA), Faculty of Electrical Engineering, Department of Electrotechnical Engirneering University of Science and Technology of Oran Mohamed BOUDIAF, Algeria

autor

Benzergua Fadela

benz_fad@yahoo.fr

Applied Power Electronics Laboratory (LEPA), Faculty of Electrical Engineering, Department of Electrotechnical Engirneering University of Science and Technology of Oran Mohamed BOUDIAF, Algeria

autor

Khalfallah Naima

khalfalla_naima@yahoo.fr

Department of Electrical Engineering, National Polytechnic School of Oran-Maurice Audin (ENPO-MA), Algeria

Bibliografia

[1] Sanchez Gomez, M., & Lundquist, J. K. (n.d.). The effect of wind direction shear on turbine performance in a wind farm in central Iowa. https://doi.org/10.5194/wes-2019-22
[2] Slootweg, J. G., & Kling, W. L. (2003). The impact of large scale wind power generation on power system oscillations. Electric Power Systems Research, 67(1), 9–20. https://doi.org/10.1016/S0378-7796(03)00089-0
[3] Liu, Y., & Zhang, J. (2018). Research on the effects of wind power grid to the distribution network of Henan province. AIP Conference Proceedings, 1955.
[4] Ahmed, S. D., Al-Ismail, F. S. M., Shafiullah, M., Al-Sulaiman, F. A., & El-Amin, I. M. (2020). Grid Integration Challenges of Wind Energy: A Review. In IEEE Access (Vol. 8, pp. 10857–10878). Institute of Electrical and Electronics Engineers Inc.
[5] Boukhezzar, B., & Siguerdidjane, H. (n.d.). Nonlinear Control of Variable Speed Wind Turbines without wind speed easurement. Proceedings of the 44th IEEE Conference on Decision and Control.
[6] Furat Abdal Rassul Abbas and Mohammed Abdulla Abdulsada. Simulation of Wind-Turbine Speed Control by MATLAB; nternational Journal of Computer and Electrical Engineering, Vol. 2, No. 5, October, 2010 1793-8163
[7] Asghar, A. B., & Liu, X. (2018). Adaptive neuro-fuzzy algorithm to estimate effective wind speed and optimal rotor speed for variable-speed wind turbine. Neurocomputing, 272, 495– 504.
[8] Song, Y. D., Dhinakaran, B., & Bao, X. Y. (n.d.). Variable speed Control of wind turbines using nonlinear and adaptive algorithms.
[9] Muyeen, S. M., & Al-Durra, A. (2013). Modeling and control strategies of fuzzy logic controlled inverter system for grid interconnected variable speed wind generator. IEEE Systems Journal, 7(4), 817–824.
[10] Nasiri, M., Mobayen, S., & Zhu, Q. M. (2019). Super-Twisting Sliding Mode Control for Gearless PMSG-Based Wind Turbine. Complexity, 2019. https://doi.org/10.1155/2019/6141607
[11] Ahmed, S., Adil, H. M. M., Ahmad, I., Azeem, M. K., Huma, Z. E., & Khan, S. A. (2020). Super twisting sliding mode Algorithm based nonlinear MPPT control for a solar PV system with artificial neural networks based reference generation. Energies, 13(14).
[12] Doumi, M. H., Aissaoui, A., Tahour, A., Abid, M., & Tahir, K. (2016). Nonlinear integral backstepping control of wind energy Conversion system based on a Double – Fed Induction Generator. Przegląd Elektrotechniczny, 92(3), 130-135.
[13] A. J. Mahdi, W. H. Tang, Q. H. Wu, “Derivation of a complete transfer function for a wind turbine generator system by experiments,” in Proc. 2011 IEEE Power Engineering and Automation Conference, Vol. 1, pp. 35-38, 2011.
[14] R. Karthik , A. Sri Hari , Y. V. Pavan Kumar , D. John Pradeep “Modelling and Control Design for Variable Speed Wind Turbine Energy System”. 2020 International Conference on Artificial Intelligence and Signal Processing (AISP)  January 10-12, 2020, VIT-AP University, Amaravati, Andhra Pradesh, India- 52223.
[15] Yang, C., Ren, E., & Dang, J. (2012). Analysis research of control method model on automobile brake test rig. Przegląd Elektrotechniczny, 88(7b), 375-378.
[16] Al-Dujaili, A. Q., Falah, A., Humaidi, A. J., Pereira, D. A., & Ibraheem, I. K. (2020). Optimal super-twisting sliding mode Control design of robot manipulator: Design and comparison study. International Journal of Advanced Robotic Systems, 17(6).
[17] Dekali, Z., Baghli, L., & Boumediene, A. (2021). Improved Super twisting based high order direct power sliding mode Control of a connected dfig variable speed wind turbine. Periodica Polytechnica Electrical Engineering and Computer Science, 65(4), 352–372.
[18] Dash, S. (n.d.). Load Frequency Control of Solar PV and Solar Thermal Integrated Micro grid using Narma-L2 Controller
[19] Alhanjouri, M. (2015). Speed Control of DC Motor Using Artificial Neural Network. International Journal of Science and Research, 6, 2319–7064.
[20] Koleva, R., Lazarevska ,A. M., & Babunski, D. (2022). Artificial Neural Network based Neuro controller for Hydropower Plant Control. TEM Journal, 11(2) , 506 – 512

Typ dokumentu

Bibliografia

Identyfikator YADDA

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