A novel frequency response analysis model applicable to high-penetration wind power grid

Abstract

The decoupling relationship and low inertia characteristics of wind turbine generator system (WTGS) make the system frequency response more complex. In order to evaluate the frequency stability of high-penetration wind power grid, it is significant to establish an exactly frequency response analysis model. Due to the features of wide spatial distribution and large number of WTGS in the power grid, the wind speed and actual operating state faced by WTGS in different regions have obvious discrepancy, which makes the traditional frequency response models that merely considers the single operating state of WTGS have evident limitations. Therefore, in order to consider the discrepancy of frequency regulation characteristics caused by the spatial dispersion of WTGS, an improved frequency response modeling method which can take into account the frequency regulation characteristics of multiple wind speeds is proposed. This method uses small signal analysis theory and fuzzy control method to construct an improved equivalent aggregation model of WTGS. Combining this model with the typical system frequency response (SFR) model, a novel frequency response model considering different wind conditions and different frequency regulation characteristics of WTGSs is established. Finally, an improved IEEE-118 bus system is used for case analysis to verify the correctness and superiority of the proposed method for high-penetration wind power grid.