Development of a Corresponding Model for Double-Fed Wind Power Generation System

A comprehensive model has been developed for the double-fed wind power generation system. This model integrates critical components including the rotor, stator, power electronics converter, and control system. The rotor component, typically modeled using rotational dynamics equations, captures mechanical energy generation from wind turbine rotation. The stator module implements electromagnetic conversion algorithms to transform mechanical energy into electrical energy. The power electronics converter serves as the grid interface, employing PWM (Pulse Width Modulation) control strategies and IGBT switching algorithms for efficient power conversion. The control system incorporates sophisticated regulation algorithms, including vector control and maximum power point tracking (MPPT), to optimize turbine performance and ensure operational safety. Through this model implementation, researchers can simulate system behavior under various conditions, analyze dynamic responses using MATLAB/Simulink environments, and enhance design parameters through iterative testing and algorithm refinement. This approach facilitates deeper understanding of system complexities and enables improvements in both design architecture and operational efficiency.