A Fault Tolerant Doubly Fed Induction Generator Wind Turbine Using a Parallel Grid Side Rectifier and Series Grid Side Converter

With steadily increasing wind turbine penetration, regulatory standards for grid interconnection have evolved to require that wind generation systems ride-through disturbances such as faults and support the grid during such events. Conventional modifications to the doubly fed induction generation (D...

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Veröffentlicht in:	IEEE transactions on power electronics 2008-05, Vol.23 (3), p.1126-1135
Hauptverfasser:	Flannery, P.S., Venkataramanan, G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Architecture Computer architecture Converters Diodes Disturbances Doubly fed induction generator (DFIG) dynamic voltage restorer Electricity Electricity generation Fault tolerance Faults Generators Induction generators Low voltage Mesh generation Power system stability Rectifiers Shafts Turbines voltage sag ride-through Wind energy generation Wind power wind turbine Wind turbines
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container_title	IEEE transactions on power electronics
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creator	Flannery, P.S. Venkataramanan, G.
description	With steadily increasing wind turbine penetration, regulatory standards for grid interconnection have evolved to require that wind generation systems ride-through disturbances such as faults and support the grid during such events. Conventional modifications to the doubly fed induction generation (DFIG) architecture for providing ride-through result in compromised control of the turbine shaft and grid current during fault events. A DFIG architecture in which the grid side converter is connected in series as opposed to parallel with the grid connection has shown improved low voltage ride through but poor power processing capabilities. In this paper, a unified DFIG wind turbine architecture which employs a parallel grid side rectifier and series grid side converter is presented. The combination of these two converters enables unencumbered power processing and robust voltage disturbance ride through. A dynamic model and control structure for this architecture is developed. The operation of the system is illustrated using computer simulations.
doi_str_mv	10.1109/TPEL.2008.921179
format	Article
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Conventional modifications to the doubly fed induction generation (DFIG) architecture for providing ride-through result in compromised control of the turbine shaft and grid current during fault events. A DFIG architecture in which the grid side converter is connected in series as opposed to parallel with the grid connection has shown improved low voltage ride through but poor power processing capabilities. In this paper, a unified DFIG wind turbine architecture which employs a parallel grid side rectifier and series grid side converter is presented. The combination of these two converters enables unencumbered power processing and robust voltage disturbance ride through. A dynamic model and control structure for this architecture is developed. 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Conventional modifications to the doubly fed induction generation (DFIG) architecture for providing ride-through result in compromised control of the turbine shaft and grid current during fault events. A DFIG architecture in which the grid side converter is connected in series as opposed to parallel with the grid connection has shown improved low voltage ride through but poor power processing capabilities. In this paper, a unified DFIG wind turbine architecture which employs a parallel grid side rectifier and series grid side converter is presented. The combination of these two converters enables unencumbered power processing and robust voltage disturbance ride through. A dynamic model and control structure for this architecture is developed. 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subjects	Architecture Computer architecture Converters Diodes Disturbances Doubly fed induction generator (DFIG) dynamic voltage restorer Electricity Electricity generation Fault tolerance Faults Generators Induction generators Low voltage Mesh generation Power system stability Rectifiers Shafts Turbines voltage sag ride-through Wind energy generation Wind power wind turbine Wind turbines
title	A Fault Tolerant Doubly Fed Induction Generator Wind Turbine Using a Parallel Grid Side Rectifier and Series Grid Side Converter
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