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Application of Backstepping Control With Nonsingular Terminal Sliding Mode Surface Technique to Improve the Robustness of Stator Power Control of Asynchronous Generator-Based Multi-Rotor Wind Turbine System

Adil Yahdou, Habib Benbouhenni, İlhami Çolak, Nicu Bizon

2024Electric Power Components and Systems22 citationsDOI

Abstract

The conventional backstepping control (CBC) technique for the asynchronous generator (AG) incorporated in a multi-rotor wind turbine (MRWT) system faces several challenges, including torque and stator power ripples, lack of robustness, and low-quality stator currents. Furthermore, the CBC performs poorly under distorted grid voltage conditions. To address these issues, this study proposes applying backstepping nonsingular terminal sliding mode control (BNTSMC). The controller design involves incorporating a NTSMC into the control law of the CBC technique, where Lyapunov theory was used to analyze the stability of the suggested approach. The synthesis of the suggested controller revolves around two sliding mode surfaces, specifically the stator powers of the AG, which are used to determine the final control laws. The advantages of this technique are excellent robustness against internal and external disturbances based on NTSMC, and the controller exhibits asymptotic stability based on the backstepping technique. Simulation tests in MATLAB software on a 1.5 MW AG-based MRWT system clearly demonstrate the advantages of BNTSMC over CBC.

Topics & Concepts

BacksteppingControl theory (sociology)Robustness (evolution)StatorTurbineEngineeringRobust controlMATLABWind powerControl engineeringComputer scienceControl systemAdaptive controlControl (management)Mechanical engineeringArtificial intelligenceGeneChemistryOperating systemElectrical engineeringBiochemistryWind Turbine Control SystemsMicrogrid Control and OptimizationIslanding Detection in Power Systems