Reconfiguration du dispositif de commande d’une éolienne en cas de creux de tension / Control reconfiguration of a doubly fed induction machine based wind generator to increase the low voltage ride through capability

Peng, Ling

17 June 2010

Avec le développement de l’éolien, les prescriptions techniques de raccordement de cette technologie obligeront le maintient de sa connexion lors d’incidents sur la tension du réseau électrique. L’enjeu pour le gestionnaire du réseau est de pouvoir utiliser tous les générateurs pour garantir la stabilité du système électrique.A partir d’un modèle dynamique d’une éolienne à base de Machine Asynchrone à Double Alimentation (MADA), une commande vectorielle améliorée a été proposée en prenant en compte la dynamique du flux statorique engendrée par la chute de tension. Les performances supérieures en terme de maintient de la production ont été établies par comparaison avec la méthode de commande classique. Son domaine d’utilisation a été également déterminé.Pendant les creux de tension importants, une protection matérielle (crowbar) est implémentée avec un contrôle de la démagnétisation de la MADA. En outre, de la puissance réactive peut être produite à la fois par la MADA et par le convertisseur connecté au réseau électrique au cours de la défaillance du réseau.Un contrôle vectoriel à hystérésis des courants pour les deux convertisseurs électroniques multiniveaux est proposé et évalué pour améliorer la réponse dynamique de ces convertisseurs et pour réduire les effets des variations des paramètres sur les performances de la commande. Selon la durée du défaut, des objectifs différents de contrôle doivent être réalisés en priorité pour empêcher des surintensités rotoriques et pour fournir de la puissance réactive. Une reconfiguration complète du dispositif de commande de cette éolienne est détaillée pour renforcer le maintient de la production éolienne lors de défaillances / With the massive development of wind energy, the technical requirements for connecting this technology will require the improvement of the fault ride-through capability of grid-connected wind turbines. The task for the grid system operator is to use all generators to ensure the stability of the electrical system.From a dynamic model of a Doubly Fed Induction Generator (DFIG) based wind generator, an improved vector control has been proposed by taking into account the dynamics of the magnetic flux, which are generated by the voltage dip. The higher performances have been established by comparison with the conventional control method. The operation domain was also determined.During serious voltage dips, a hysteresis control scheme of the active Crowbar is proposed to protect the system within a demagnetization method of the DFIG. Moreover, additional reactive power can be produced both by the MADA and the grid-side converter in order to support the electric network during the grid fault.A space vector hysteresis current control strategy of both three-level converters is proposed to improve the dynamic response of the system and to reduce the parameter variation effects on the control performanceDepending on the grid fault duration, different control objectives have to be achieved with priority to restrain the rotor over-current or to supply reactive power. Then the reconfiguration scheme of the control strategies of high power DFIG wind turbine system is proposed to enhance the fault ride-through capability of the DFIG system. With this specific methodology, the DFIG can stay connected and can supply maximal reactive current during voltage dips to help voltage recovery

Creux de tension

Insensibilité aux creux de tension

Modélisation graphique

Reconfiguration de la commande

Eolienne

Commande vectorielle

Doubly fed induction generator

Voltage dip

Low voltage ride-through

Graphical modeling

Control reconfiguration

Wind generator

Vector control

Análise de de sistemas de distribuição com modelagem de geradores eólio-elétricos dos tipos I, II e IV / Analysis of distribution systems modeling wind generators of types I, II and IV

Galdino, Francisco Clebson Sousa

05 June 2015

Made available in DSpace on 2016-08-31T13:33:43Z (GMT). No. of bitstreams: 1 FranciscoCSG_DISSERT.pdf: 1707836 bytes, checksum: f3a5558058650f68e08a82541000dc7b (MD5) Previous issue date: 2015-06-05 / In power distribution systems are the major causes of voltage imbalances, variations in single-phase loads cause the currents in the conductors of the three phases is different, resulting in different voltage drops, causing imbalance. The study of voltage imbalances in the distribution of energy is very important, since the proper functioning of equipment connected to the system is directly related to the mains imbalance factor. When it comes to stress profiles, has become one of the biggest challenges of electric utilities, which is to serve consumers and customers with adequate voltage levels to those required in current legislation in Brazil has the 2001 resolution no. 505 ANEEL (National Electric Energy Agency) stating that the voltage to be contracted with the utility or the ONS should be between 95% (0.95 pu) and 105% (1.05 pu) of the nominal operating voltage system at the delivery point. In relation to electrical losses, although not established limits by law, these are an important economic factor for electric utilities, seeking to reduce them to maximize their profits. When it comes to connecting wind turbines to the distribution systems is not aware of scholarly conducting parallel operating conditions of the various components that operate in this plan when they are working together with the different configurations of wind generators. The objective of this study is to analyze the imbalances problem, tensions profiles and electrical losses in distribution systems by various operating situations, especially with the inclusion of wind turbines type I, II and IV, based on the system 13 bars IEEE. Also, are proposed and simulated some ways to reduce imbalances and losses through the use of engineering techniques: as promoting the balancing system loads, connecting wind farms to the distribution feeder, installing banks of single-phase voltage regulators at substations and correcting the power factor of the generator turbines. Technical proposals to reduce the levels of network imbalance are effective and also influenced the reduction of overall system losses and improve the levels of stress profiles and are therefore measures that may contribute to the proper functioning of a power system / Nos sistemas de distribuição de energia elétrica se encontram as maiores causas dos desequilíbrios de tensão, variações nas cargas monofásicas fazem com que as correntes nos condutores das três fases sejam diferentes, o que resulta em quedas de tensões diferentes, provocando desequilíbrio. O estudo de desequilíbrios de tensão na distribuição de energia é muito importante, uma vez que o bom funcionamento de equipamentos ligados ao sistema está diretamente relacionado ao fator de desequilíbrio da rede elétrica. Quando se trata de perfis de tensões, tem-se um dos maiores desafios das concessionárias de energia elétrica, que é atender os consumidores e clientes com níveis de tensão adequados aos exigidos na legislação vigente, no Brasil tem-se a resolução de 2001 nº 505 da ANEEL (Agência Nacional de Energia Elétrica) estabelecendo que a tensão a ser contratada com a concessionária ou com o ONS deve situar-se entre 95% (0,95 p.u) e 105% (1,05 p.u) da tensão nominal de operação do sistema no ponto de entrega. Já com relação às perdas elétricas, apesar de não serem estabelecidos limites pela legislação vigente, estas são um importante fator econômico para as concessionárias de energia elétrica, que buscam diminuí-las para maximizar seus lucros. Quando se trata de conexão de turbinas eólicas nos sistemas de distribuição não se tem conhecimento de trabalhos acadêmicos que realizam um paralelo das condições de operação dos diversos componentes que atuam nesse plano quando os mesmos estão atuando juntamente com as diferentes configurações de geradores eólicos. O objetivo deste trabalho é analisar o problema de desequilíbrios, perfis de tensões e das perdas elétricas em sistemas de distribuição mediante diversas situações de operação, principalmente com a inserção de turbinas eólicas tipo I, II e IV, tomando como base o sistema 13 barras do orgão IEEE. Além disso, são propostas e simuladas algumas maneiras de reduzir os desequilíbrios e perdas através do uso de técnicas de engenharia: como promovendo o balanceamento de cargas do sistema, conectando parques eólicos ao alimentador de distribuição, instalando bancos de reguladores de tensão monofásicos em subestações e corrigindo o fator de potência dos geradores das turbinas. As técnicas propostas para reduzir os graus de desequilíbrio da rede se mostraram eficazes e influenciaram também na redução das perdas globais do sistema e melhora dos níveis de perfis de tensões, sendo portanto medidas que podem contribuir para o bom funcionamento de um sistema de energia elétrica

Fluxo de carga trifásico

Modelagem trifásica

Parques eólicos

Sistema de distribuição

Gerador eólico trifásico

Three-phase load flow

Three-phase modeling: Wind farms

The distribution system

Three-phase wind generator

Supervision d’une ferme éolienne pour son intégration dans la gestion d’un réseau électrique, Apports des convertisseurs multi niveaux au réglage des éoliennes à base de machine asynchrone à double alimentation / Management of a wind farm and integration in the operational power system, Contribution of multilevel power electronic converters for the control of doubly fed induction machine based wind generators

Ghennam, Tarak

29 September 2011

La première thématique développée dans ce mémoire vise à développer de nouveaux algorithmes pour la commande des éoliennes reposant sur une machine asynchrone à double alimentation et des convertisseurs multi niveaux. Deux stratégies de contrôle direct du courant, basées sur l’Hystérésis à Zones Carrées et l’Hystérésis à Zones Circulaires (HZCi) ont été proposées. Celles-ci consistent à appliquer des vecteurs de tension appropriés pour contrôler les puissances actives et réactive générées et permettent également d’équilibrer les tensions du bus continu interne des convertisseurs. Des résultats de simulation et d’expérimentation montrent que la stratégie basée sur l’HZCi est meilleure en termes de forme d’onde et de contenu harmonique des tensions de sortie.La seconde concerne la supervision et la gestion des puissances active et réactive dans une ferme éolienne au vu de son intégration dans un réseau électrique. Cette supervision centralisée est assurée par un algorithme qui distribue les consignes de puissance aux éoliennes de la ferme de manière proportionnelle. Ces références sont fonction de la capacité maximale de production de l’éolienne. Pour cela, une analyse des transits de puissance dans le système éolien à base de la machine asynchrone à double alimentation a été effectuée. Elle a permis de déterminer la caractéristique (P, Q) du générateur et de calculer ses limites de compensation en termes de puissance réactive. Une gestion locale des puissances de chaque éolienne a été développée permettant ainsi une répartition des puissances entre le stator de la machine et le convertisseur coté réseau en considérant plusieurs modes de fonctionnement du système éolien / This research work deals with two topics conditioning the large scale development of wind turbines into electrical grids. The first is devoted to the development of new algorithms for the control of Doubly Fed Induction Machine (DFIM) based wind energy conversion systems. Two direct current control strategies have been proposed and are based on the hysteresis square areas (HZCA) and hysteresis circular areas (HZCI). Both strategies apply an appropriate voltage vector to control the active and reactive powers delivered to the grid, and also, to balance the voltages of the inner DC bus converter. Simulation and experimental results show that the HZCI strategy is better than HZCA in terms of output voltage waveforms and harmonic contain.The second topic is dedicated to the active and reactive powers supervision in a wind farm in order to supply prescribed power references from the grid operator. This supervision is ensured by a centralized algorithm that distributes power references between wind turbines in a proportional way. These references are calculated according to the maximum production capacity of wind turbines. An analysis of the power flow in the DFIM based wind energy system has been made to identify the (P, Q) characteristic and to calculate limits in terms of reactive power compensation. The local power management of each wind system has been developed allowing the powers distribution between the stator of the DFIM and the grid side converter by considering several operating modes of the wind generator

Commande vectorielle

Eolienne

Convertisseur multiniveaux

Gestion de réseaux électriques

Répartition de puissance

Commande par hysteresis

Doubly fed induction machine

Vector control

Wind generator

Multilevel converters

Power system management

Power dispatching

Hysteresis control

620

Reactive Power Planning And Operation of Power Systems with Wind Farms for Voltage Stability Improvement

Moger, Tukaram

January 2015

In recent years, the electric power industry around the world is changing continuously due to transformation from regulated market structure to deregulated market structure. The main aim of the transformation of electric supply industry under open access environment is to overcome the some of the limitations faced by the vertically integrated system. It is believed that this transformation will bring in new technologies, integration of other sources of energy such as wind, solar, fuel cells, bio-gas, etc., which are self sustainable and competitive, and better choice for the consumers and so on. As a result, several new issues and challenges have emerged. One of the main issues in power systems is to support reactive power for maintaining the system voltage profile with an acceptable margin of security and reliability required for system operation. In this context, the thesis addresses some of the problems related to planning and operation of reactive power in power systems. Studies are mainly focused on steady state operation of grid systems, grid connected wind farms and distribution systems as well. The reactive power support and loss allocation using Y-bus approach is proposed. It computes the reactive power contribution from various reactive sources to meet the reactive load demand and losses. Further, the allocation of reactive power loss to load or sink buses is also computed. Detailed case studies are carried out on 11-bus equivalent system of Indian southern region power grid under different loading conditions and also tested on 259-bus equivalent system of Indian western region power grid. A comparative analysis is also carried out with the proportional sharing principle and one of the circuit based approach in the literature to highlight the features of the proposed approach. A new reactive power loss index is proposed for identification of weak buses in the system. The new index is computed from the proposed Y-bus approach for the system under intact condition as well as some severe contingencies cases. Fuzzy logic approach is used to select the important and severe line contingencies from the contingency list. The validation of weak load buses identification from the proposed reactive power loss index with that from other well known existing methods in the literature such as Q-V sensitivity based modal analysis and continuation power flow method is carried out to demonstrate the effectiveness of the proposed index. Then, a short-term reactive power procurement/optimal reactive power dispatch analysis is also carried out to determine the optimum size of the reactive compensation devices to be placed at the weak buses for reactive compensation performance analysis in the system. The proposed approach is illustrated on a sample 5-bus system, and tested on sample 10-bus equivalent system and 72-bus equivalent system of Indian southern region power grid. A comprehensive power flow analysis of PQ type models for wind turbine generating units is presented. The different PQ type models of fixed/semi-variable speed wind turbine generating units are considered for the studies. In addition, the variable speed wind turbine generating units are considered in fixed power factor mode of operation. Based on these models, a comparative analysis is carried out to assess the impact of wind generation on distribution and transmission systems. 27-bus equivalent distribution test system, 93-bus equivalent test system and SR 297-bus equivalent grid connected wind system are considered for the studies. Lastly, reactive power coordination for voltage stability improvement in grid connected wind farms with different types of wind turbine generating units based on fuzzy logic approach is presented. In the proposed approach, the load bus voltage deviation is minimized by changing the reactive power controllers according to their sensitivity using fuzzy set theory. The fixed/semi-variable speed wind turbine generating units are also considered in the studies because of its impact on overall system voltage performance even though they do not support the system for voltage unlike variable speed wind generators. 297-bus equivalent and 417-bus equivalent grid connected wind systems are considered to present the simulation results. A comparative analysis is also carried out with the conventional linear programming based reactive power optimization technique to highlight the features of the proposed approach.

Reactive Power

Wind Power

Wind Farms

Grid Connected Wind Farms

Distributed Power Generation

Power System Stability

Reactive Power Planning

Voltage Stability Analysis

Reactive Power Support

Power Flow Analysis

Power Loss Allocation

Wind Generator Unit

Wind Turbine Generating Unit

Electrical Engineering

DESIGN, ANALYSIS AND IMPLEMENTATION OF A NOVEL DOUBLE SIDED E-CORETRANSVERSE FLUX MACHINE WITH AXIAL AIRGAP

Husain, Tausif

January 2017

No description available.

Electrical Engineering

Electromagnetics

Gestion de l'énergie dans un système multi-sources photovoltaïque et éolien avec stockage hybride batteries/supercondensateurs / Energy management in a photovoltaic/wind hybrid power system with batteries/supercapacitors storage

Croci, Lila

18 December 2013

Ce mémoire présente le travail de recherche effectué pour la conception d'une stratégie de commande originale, destinée aux systèmes de puissance hybrides en sites isolés. Le système considéré, voué à l'alimentation électrique d'une habitation, comprend deux sources, un groupe de panneaux photovoltaïques et une petite éolienne, et deux types de stockage, un banc de batteries lithium-ion et un de supercondensateurs. Face au problème de gestion de l'énergie dans un système hybride, et aux enjeux de maximisation de sa puissance produite, nous proposons de développer une stratégie de commande basée sur les flux d'énergie. pour cela, nous présentons dans un premier temps les modélisations d'Euler-Lagrange et hamiltonienne du système. Ces modèles permettent d'utiliser la propriété de passivité de celui-ci, et ainsi de synthétiser des commandes par injection d'amortissement pour chaque source, afin de maximiser sa production, et pour les supercondensateurs, dans le but d'assurer une répartition cohérente des flux d'énergie entre eux et les batteries. Les commandes sont finalement mises en œuvre dans un simulateur, puis dans un banc d'essai expérimental, afin d'une part de comparer leurs performances à celles de solutions préexistantes, et d'autre part de valider le bon fonctionnement du système hybride complet les utilisant. / This thesis presents the research about design of a new control strategy for stand-alone hybrid power systems. The considered system is composed of two sources, a group of photovoltaic panels and a low-power wind generator, and of two kinds of storage, a bank of lithium-ion batteries and one of supercapacitors. Faced with the problem of energy management in a hybrid power system, and with necessity of maximizing the produced power, we intend to develop an energy-based control strategy.For this purpose, we present the system's Euler-Lagrange modeling and Hamiltonian modeling. These models allow the use of the passivity property, and then the design of Passivity-Based Controllers for each source, in order to maximize its production, and for the supercapacitors, to ensure a fitted power sharing between batteries and them. The controllers are finally implemented in a simulator, and then in a experimental test bench, in order to compare their performances to pre-existent solutions, and tovalidate the control law for the global hybrid system.

Système de puissance hybride

Site isolé

Générateur photovoltaïque

Éolienne

Batterie litium-Ion

Supercondensateur

Modélisation d'Euler-Lagrange

Modélisation hamiltonienne

Commande passive

Commande par injection d'amortissement

Commande par mode de glissement

Suivi du point de puissance maximale

Gestion d'énergie

Hybrid power system

Stand alone system

Photovoltaic generator

Wind generator

Litiumion battery

Supercapacitor

Euler-Lagrange modeling

Hamiltonian modeling

Passivity-Based control

Sliding mode control

Maximum power point tracking

Energy management

629.8