Estudio del efecto de los huecos de tensión en el generador de inducción doblemente alimentado

The aim of this doctoral thesis is to analyse the dynamic behaviour of the doubly-fed induction generator exposed to voltage sags. This electrical machine is mainly used in variable-speed wind turbines. Due to the noticeable increase in recent years in grid integration of wind turbine energy systems...

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Detalhes bibliográficos
Autor: Rolán Blanco, Alejandro|||0000-0002-9855-6933
Tipo de documento: tese
Data de publicação:2012
País:España
Recursos:Universitat Politècnica de Catalunya (UPC)
Repositório:UPCommons. Portal del coneixement obert de la UPC
Idioma:espanhol
OAI Identifier:oai:upcommons.upc.edu:2117/94529
Acesso em linha:https://hdl.handle.net/2117/94529
https://dx.doi.org/10.5821/dissertation-2117-94529
Access Level:Acceso aberto
Palavra-chave:Huecos de tensión simétricos
Energía eólica
Ingeniería eléctrica
Calidad de la energía eléctrica
Despeje de la falta
Capacidad de respuesta frente a huecos de tensión
Generador de inducción doblemente alimentado
Huecos de tensión asimétricos
Energia eòlica
Generadors elèctrics
Àrees temàtiques de la UPC::Energies
Descrição
Resumo:The aim of this doctoral thesis is to analyse the dynamic behaviour of the doubly-fed induction generator exposed to voltage sags. This electrical machine is mainly used in variable-speed wind turbines. Due to the noticeable increase in recent years in grid integration of wind turbine energy systems, the transmission system operators have developed the grid codes, which are the technical specifications that wind turbines have to achieve when a fault occurs. Faults are the most common causes that originate voltage sags. Therefore, the first step to ensure electricity supply continuity as well as to improve power quality when this kind of faults occur is to analyse the dynamic behaviour of the generator exposed to voltage sags. The stator of the doubly-fed induction generator is directly connected to the grid, whereas its rotor is connected by means of a power converter. The converter consists of a rectifier or rotor-side converter and an inverter or grid-side converter, which are linked by a DC bus. It is assumed that the rotor-side converter keeps constant the rotor current in the synchronous reference frame during the entire event. This hypothesis allows the electrical transient to be solved analytically. The voltage limit of the rotor-side converter is also taken into account in order to determine the situations where the rotor current can be controlled. This doctoral thesis is structured as follows. Firstly, the mathematical model of voltage sags is given. Secondly, both dynamic and steady-state models of the doubly-fed induction machine are obtained. Thirdly, the steady-state behaviour of the doubly-fed induction generator is analysed for different generated powers and it is studied, by means of an analytical approach, its electrical transient when exposed to voltage sags. The analytical results are validated by numerical integration of the system of equations with a MATLAB ode solver and by means of the PSpice circuit simulator. It is also carried out an exhaustive study of the effect that voltage sags cause on the doubly-fed induction generator, considering all the typologies (symmetrical and unsymmetrical voltage sags) and varying their parameters (duration and depth). Moreover, the fault-clearing process is taken into account, which has a strong influence on the voltage that the rotor-side converter requires to control the rotor current. The terms abrupt sag and discrete sag stand for voltage sags whose voltage recovery is produced instantaneously or in different steps, respectively. Finally, by means of an analytical study, which is validated by the simulation of different loads exposed to voltage sags, a grouping of voltage sags whose voltage recovery is produced in different steps is proposed. It is observed that from the fourteen discrete voltage sag types in the literature, it is enough to consider only five types. This is a significant advantage, as the number of simulations or laboratory tests carried out on an electrical device exposed to voltage sags is reduced.