Title :
Electromechanical Dynamics of Controlled Variable-Speed Wind Turbines
Author :
Ghosh, Sudipta ; Senroy, Nilanjan
Author_Institution :
Dept. of Electr. Eng., Indian Sch. of Mines, Dhanbad, India
Abstract :
Variable-speed wind turbines are increasingly penetrating into the electrical grid, replacing the conventional synchronous-generator-based power plants and thus decreasing the available inertial response for primary frequency stability. This paper offers a deeper understanding of variable-speed wind turbine generators (WTGs) in the context of maximum power point tracking and obtaining primary frequency response. Linearized models have been obtained between the wind velocity and the system frequency versus the power output. System complexity has been studied from the point of view of modal analysis of a two-mass drive train model of a WTG, as well as Hankel singular values. Finally, individual WTG models have been combined to form wind farms, whose complexity has again been found to depend on the nature of modeling of the WTG drive trains.
Keywords :
frequency response; frequency stability; maximum power point trackers; modal analysis; power generation control; power grids; turbogenerators; variable speed drives; wind power plants; wind turbines; Hankel singular values; WTG drive trains; controlled variable-speed wind turbine generator; electrical grid; electromechanical dynamics; inertial response; linearized models; maximum power point tracking; modal analysis; primary frequency response; primary frequency stability; system complexity; system frequency; two-mass drive train model; wind farms; wind velocity; Frequency control; Generators; Load modeling; Shafts; Torque; Wind speed; Wind turbines; Deloading; linearization; maximum power point tracking (MPPT); model order reduction (MOR); pitch control; primary frequency control; transfer function; wind power generation; wind turbine generator (WTG);
Journal_Title :
Systems Journal, IEEE
DOI :
10.1109/JSYST.2013.2280037
