OPTIMAL DESIGN AND CONTROL OF AC-DC-DC WIND ENERGY SYSTEM FOR ELECTRIC VEHICLE BATTERIES RECHARGING STATIONS, 1-9.

Saber Hadj Abdallah, and Souhir Tounsi

References

1. [1] P.D. Singh and S. Gao, Fuzzy based AC-DC-AC convertercontrolled micro hydro renewable power generation using par-allel asynchronous generators for remote areas, InternationalJournal of Renewable Energy Research-IJRER, 10(1), 2020,260–273.
2. [2] M. Quraan, Q. Farhat, and M. Bornat, A new control schemeof back-to-back converter for wind energy technology, Proc.6th Int. Conf. Renew. Energy Res. Appl. ICRERA, San Diego,CA, USA, 5–8 Nov. 2017, 354–358.
3. [3] M.G. Sim˜oes, B.K. Bose, and R.J. Spiegel, Fuzzy logic basedintelligent control of a variable speed cage machine windgeneration system, IEEE Transactions on Power Electronics,12(1), 1997, 87–95.
4. [4] N. Harrabi, M. Souissi, A. Aitouche, and M. Chaabane,Intelligent control of grid-connected AC-DC-AC converters fora WECS based on T-S fuzzy interconnected systems modelling,IET Power Electronics, 11(9), 2018, 1507–1518.
5. [5] P.D. Singh and S. Gao, Efficient AC-DC-AC converter foroperation of variable speed small scale hydro power generationschemes, Journal of Electrical Systems, 17(1), 2021, 1–20.
6. [6] H.J. Shin, J.Y. Choi, H.W. Cho, and S.M. Jang, Analyticaltorque calculations and experimental testing of permanentmagnet axial eddy current brake, IEEE Transactions onMagnetics, 49(7), 2013, 4152–4155.
7. [7] R. Yazdanpanah and M. Mirsalim, Axial-flux wound-excitationeddy-current brakes: Analytical study and parametric model-ing, IEEE Transactions on Magnetics, 50(6), 2014, 1–10.
8. [8] A. Deshpane, Development of hydraulic brake design systemapplication, International Journal of Research in Science andTechnology, 5(3), 2015, 61–70.
9. [9] G. Chen and X. Cai, Reconfigurable control for fault-tolerantof parallel converters in PMSG wind energy conversion system,IEEE Transactions on Sustainable Energy, 10(2), 2019,604–614.
10. [10] J.H. Kang and H.W. Lee, The development of wind turbinebrake by finite element method, International Journal ofApplied Engineering Research, 11(20), 2016, 10294–10298.
11. [11] S. Tounsi and S.H. Abdallah, Robust control strategiesdedicated to electric vehicle motorization, InternationalJournal of Power and Energy Systems, 40(2), 2020,57–63.
12. [12] S. Tounsi, Optimal design and control of linear motor atlow displacement, Journal Mechatronic Systems and Control,46(3), 2021, 171–178.
13. [13] S. Tounsi, Finite element validation of the analytical modelof variable reluctance motor, International Journal of Powerand Energy Conversionn, Inderscience Publisher, 11(3), 2020,248–259.
14. [14] N. Nasri and S. Tounsi, Design and optimization of renewableenergy structure, Journal of Electrical Engineering, 7(48),2017, 1–13.
15. [15] J. Kang and H. Lee, The development of rotor brakes forwind turbines, International Journal of Applied EngineeringResearch, 12(15), 2017, 5094–5100.

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• Abstract
• DOI: 10.2316/J.2024.203-0396
• From Journal (203) International Journal of Power and Energy Systems - 2024

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