A New Approach for Steady-State Calculations and Control of Doubly-Fed Induction Generator Performance Based on the Wind Turbine
Keywords:
Wind energy, DFIG, Rotor side converter, Fuzzy logic control, Steady-state control, Performance control.Abstract
The ecological advantages of renewable energy, especially wind farms, motivate grid integration. The doubly-fed induction generator (DFIG) is the topology most frequently utilized in the industrial sector, which offers improved performance control. Despite all these advantages, several drawbacks have disrupted control and reduced system performance. This system threatens the safety and stability of the wind energy system because of the direct interaction between the grid and DFIG. Therefore, DFIG-based wind systems must conduct a steady-state (SS) evaluation and create control techniques. In this paper, a new modified control strategy for the rotor side of a DFIG is proposed utilizing a mathematical model with a stator magnetization strategy . The stator magnetization strategy aims at an analyzer steady-state of the DFIG to solve the disturbance problem and control all DFIG variables to meet system requirements better. The programming results were validated in the MATLAB environment. System performance shows the effectiveness of the proposed strategy in obtaining a viable model with an error rate of 1.99%. The results validate the programming and enhance the current DFIG's failure analysis, machine performance, steady-state validation, and search efficiency.
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