Abstract
A lot of development is carried out on renewable energy technologies for the upcoming trend among which wind energy system and solar energy system is mostly admired and preferred due to the availability of their sources. This paper deals with the wind energy system and control method implementations on the wind turbine system for continuity in the supply of power. Basically, two types of generators, asynchronous and synchronous generator can be used in the function of wind power system. Among asynchronous machines, we are implementing doubly fed induction machine (DFIM), which operates as generator in one of the operation modes for the conversion of mechanical energy (obtained from the wind conversion system) to electrical energy. The wind turbine implemented with DFIM is linked to a grid modeled system via following converters termed as converter of rotor side and converter of stator side converter whose firing angles are dependent on the vector control designed for the system to ensure a better-quality output power. The DFIG based wind turbine model is designed by using MATLAB Simulink software and vector control on the rotor side depends on d-axis current and the required transformation matrices are modeled by using function blocks. The results obtained are studied and analyzed properly considering some of the practical considerations and are able to explain the working of the system.
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Kumar, R., Sekhar, C., Manna, S., Akella, A.K. (2022). Implementation of Complete Vector Control for DFIG Based Wind Turbine. In: Kumar, S., Singh, B., Singh, A.K. (eds) Recent Advances in Power Electronics and Drives. Lecture Notes in Electrical Engineering, vol 852. Springer, Singapore. https://doi.org/10.1007/978-981-16-9239-0_16
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DOI: https://doi.org/10.1007/978-981-16-9239-0_16
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