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Integral Sliding Mode Control for Maximum Power Point Tracking in DFIG Based Floating Offshore Wind Turbine and Power to Gas

Lin Pan, Ze Zhu, Yong Xiong, Jingkai Shao

2021Processes30 citationsDOIOpen Access PDF

Abstract

This paper proposes a current decoupling controller for a Doubly-fed Induction Generator (DFIG) based on floating offshore wind turbine and power to gas. The proposed controller realizes Maximum Power Point Tracking (MPPT) through integral sliding mode compensation. By using the internal model control strategy, an open-loop controller is designed to ensure that the system has good dynamic performance. Furthermore, using the integral Sliding Mode Control (SMC) strategy, a compensator is designed to eliminate the parameter perturbation and external disturbance of the open-loop control. The parameters of the designed controller are designed through Grey Wolf Optimization (GWO). Simulation results show that the proposed control strategy has better response speed and smaller steady-state error than the traditional control strategy. This research is expected to be applied to the field of hydrogen production by floating offshore wind power.

Topics & Concepts

Control theory (sociology)TurbineDecoupling (probability)Integral sliding modeController (irrigation)Offshore wind powerSliding mode controlOperating pointWind powerInduction generatorMaximum power point trackingEngineeringMaximum power principleComputer scienceControl engineeringControl (management)PhysicsVoltageInverterElectronic engineeringNonlinear systemElectrical engineeringMechanical engineeringBiologyAgronomyArtificial intelligenceQuantum mechanicsWind Turbine Control SystemsFrequency Control in Power SystemsMultilevel Inverters and Converters
Integral Sliding Mode Control for Maximum Power Point Tracking in DFIG Based Floating Offshore Wind Turbine and Power to Gas | Litcius