Fast-Frequency Response Provided by DFIG-Wind Turbines and its Impact on the Grid

Danny Ochoa; Sergio Martinez

doi:10.1109/TPWRS.2016.2636374

Fast-Frequency Response Provided by DFIG-Wind Turbines and its Impact on the Grid

Danny Ochoa, Sergio Martinez

Technical University of Madrid

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

237 Citas (Scopus)

Resumen

This paper presents a methodology for the analysis of frequency dynamics in large-scale power systems with high level of wind energy penetration by means of a simplified model for DFIG-based wind turbines. In addition, a virtual inertia controller version of the optimized power point tracking (OPPT) method is implemented for this kind of wind turbines, where the maximum power point tracking curve is shifted to drive variations in the active power injection as a function of both the grid frequency deviation and its time derivative. The proposed methodology integrates the model in a primary frequency control scheme to analyze the interaction with the rest of the plants in the power system. It is also proven that, under real wind conditions, the proposed version of the OPPT method allows us to smooth the wind power injected into the grid, thereby reducing frequency fluctuations.

Idioma original	Inglés
Número de artículo	7776939
Páginas (desde-hasta)	4002-4011
Número de páginas	10
Publicación	IEEE Transactions on Power Systems
Volumen	32
N.º	5
DOI	https://doi.org/10.1109/TPWRS.2016.2636374
Estado	Publicada - sep. 2017
Publicado de forma externa	Sí

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title = "Fast-Frequency Response Provided by DFIG-Wind Turbines and its Impact on the Grid",

abstract = "This paper presents a methodology for the analysis of frequency dynamics in large-scale power systems with high level of wind energy penetration by means of a simplified model for DFIG-based wind turbines. In addition, a virtual inertia controller version of the optimized power point tracking (OPPT) method is implemented for this kind of wind turbines, where the maximum power point tracking curve is shifted to drive variations in the active power injection as a function of both the grid frequency deviation and its time derivative. The proposed methodology integrates the model in a primary frequency control scheme to analyze the interaction with the rest of the plants in the power system. It is also proven that, under real wind conditions, the proposed version of the OPPT method allows us to smooth the wind power injected into the grid, thereby reducing frequency fluctuations.",

keywords = "Ancillary services, doubly-fed induction generator, fast-frequency response, primary frequency control, wind power integration",

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AB - This paper presents a methodology for the analysis of frequency dynamics in large-scale power systems with high level of wind energy penetration by means of a simplified model for DFIG-based wind turbines. In addition, a virtual inertia controller version of the optimized power point tracking (OPPT) method is implemented for this kind of wind turbines, where the maximum power point tracking curve is shifted to drive variations in the active power injection as a function of both the grid frequency deviation and its time derivative. The proposed methodology integrates the model in a primary frequency control scheme to analyze the interaction with the rest of the plants in the power system. It is also proven that, under real wind conditions, the proposed version of the OPPT method allows us to smooth the wind power injected into the grid, thereby reducing frequency fluctuations.

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KW - fast-frequency response

KW - primary frequency control

KW - wind power integration

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Fast-Frequency Response Provided by DFIG-Wind Turbines and its Impact on the Grid

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