An advanced Backstepping Control Scheme via Active and Reactive Powers for DFIM-Based on Variable-Speed Turbine Energy

Kadi, Sara; Benbouhenn, Habib; Hamdan, I.; Abdelkarim, Emad

doi:10.21608/sej.2024.338390.1071

An advanced Backstepping Control Scheme via Active and Reactive Powers for DFIM-Based on Variable-Speed Turbine Energy

Document Type : Original Article

Authors

¹ Power equipments Characterization and Diagnosis Laboratory (USTHB) Algiers, Algeria

² Electrical & Electronics Engineering, Nisantasi University, Istanbul, Turkey

³ Department of Electrical Engineering, College of Engineering and Information Technology, Buraydah Private Colleges, Buraydah 51418, kingdom of Saudi Arabia. & Department of Electrical Engineering , Faculty of Engineering, South Vally University

⁴ Electric Engineering Department, Aswan university, Aswan, Egypt & Department of Electrical Engineering, College of Engineering and Information Technology, Buraydah Private Colleges, Buraydah 51418, kingdom of Saudi Arabia.

10.21608/sej.2024.338390.1071

Abstract

This paper presents a control scheme using active and reactive power control with advanced backstepping control of doubly-fed induction machine (DFIM) based on variable-speed wind-energy-conversion system (WECS). The modelling and control of WECS are introduced using DFIM with back-to-back converters for a variable-speed application. Also, the aim is to design and compare two-distinct decoupling control strategy to control the rotor-side converter with integral proportional (PI) control (indirect control) strategy and nonlinear integral backstepping control strategy, this system employs a maximum power-point tracking (MPPT) strategy to maximize the extraction of power during the conversion process. The proposed studied system is tested using MATLAB/Simulink in terms of decoupling, the robustness against-parameters variations and the reference-tracking stability. This results is completed by a comparative study which reflect the better performance of studied control method. According to simulation data, the control scheme improves DFIM-turbine system performance.

Keywords

Main Subjects

Electrical Engineering

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