Abstract
Wind-generated energy is a fast-growing source of renewable energy use across the world. A dual-feed induction machine (DFIM) employed in wind generators provides active and reactive, dynamic and static energy support. In this document, the droop control system will be applied to adjust the amplitude and frequency of the grid following the guidelines established for the utility’s smart network supervisor. The wind generator will work with a maximum deloaded power curve, and depending on the reserved active power to compensate the frequency drift, the limit of the reactive power or the variation of the voltage amplitude will be explained. The aim of this paper is to show that the system presented theoretically works correctly on a real platform. The real-time experiments are presented on a test bench based on a 7.5 kW DFIG from Leroy Somer’s commercial machine that is typically used in industrial applications. A synchronous machine that emulates the wind profiles moves the shaft of the DFIG. The amplitude of the microgrid voltage at load variations is improved by regulating the reactive power of the DFIG and this is experimentally proven. The contribution of the active power with the characteristic of the droop control to the load variation is made by means of simulations. Previously, the simulations have been tested with the real system to ensure that the simulations performed faithfully reflect the real system. This is done using a platform based on a real-time interface with the DS1103 from dSPACE.
Highlights
Wind energy is progressively gaining importance in the world’s electricity production, with important engineering aspects to be addressed for its integration into conventional electricity grids
Some studies have been developed in order to analyze the installation of small wind turbines in urban areas
The amplitude of the4.stator voltage is regulated by adjusting the reactive power as deThe reactive energy scribed in the Section 4. is controlled by the grid side converter (GSC) and by the rotor side converter (RSC) [17]
Summary
Wind energy is progressively gaining importance in the world’s electricity production, with important engineering aspects to be addressed for its integration into conventional electricity grids. In wind turbines, when control is carried out by means of the power drivers, as is the case of the DFIM, the speed is adjusted according to the wind speed in order to optimize energy production This allows the regulation of the generator at the point of maximum. System based on wind generators to contribute to the compensation of the frequency and This control scheme was initially proposed and simulated in the IEEE Internaamplitude variations of the voltage of the microgrids. This work goes further, in this previous work,detailed the proposed approach represents was only validated by means of providing more simulations using a more model, control which accurately the some simulation results using a simple wind turbine model This new work goes further, dynamics of the real system.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
