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301	Επίδραση κατανεμημένων παραγωγών στη λειτουργία συστήματος ηλεκτρικής ενέργειας Παπανικολάου, Κωνσταντίνα 03 April 2015 (has links) Στην παρούσα διπλωματική εργασία πραγματοποιείται μελέτη της επίδρασης ενός συστήματος διασύνδεσης ανεμογεννήτριας με το δίκτυο μέσης τάσης, όσον αφορά την έγχυση αρμονικών από την ανεμογεννήτρια προς το δίκτυο. Η μελέτη περιλαμβάνει τη μοντελοποίηση κάθε τμήματος ενός δικτύου μέσης τάσης με πραγματικά στοιχεία που πάρθηκαν από τη ΔΕΗ. Επιπλέον, μοντελοποιείται μια ανεμογεννήτρια τύπου σύγχρονης μόνιμων μαγνητών, καθώς και όλοι οι ηλεκτρονικοί μετατροπείς ισχύος που απαιτούνται για τη διασύνδεση αυτής με το δίκτυο μέσης τάσης. Όλα τα επιμέρους μοντέλα διασυνδέονται μεταξύ τους ώστε να αποτελέσουν το συνολικό μοντέλο που περιλαμβάνει το δίκτυο μέσης τάσης με τις γραμμές μεταφοράς, τους μετασχηματιστές, τα φορτία και τους πυκνωτές αντιστάθμισης που διαθέτει και την ανεμογεννήτρια μαζί με τους μετατροπείς συνδεδεμένη σε ένα ζυγό του δικτύου. Από το μοντέλο αυτό εξάγεται το αρμονικό περιεχόμενο τόσο στο ζυγό της ανεμογεννήτριας όσο και σε διπλανούς ζυγούς και συγκρίνεται κάθε φορά με το πρότυπο IEC 61000-3-6 που θέτει τα όρια για την έγχυση αρμονικών στο δίκτυο μέσης τάσης. Αρχικά, γίνεται μια αναφορά στα πλεονεκτήματα της αιολικής ενέργειας έναντι των άλλων συμβατικών μορφών ενέργειας. Επιπλέον, αναφέρονται τα προβλήματα που δημιουργούνται από την παρουσία ανώτερων αρμονικών στο δίκτυο. Έπειτα, πραγματοποιείται θεωρητική ανάλυση κάθε τμήματος του δικτύου μέσης τάσης. Για κάθε τμήμα δημιουργείται, επίσης, ένα μοντέλο στο Matlab/Simulink που βασίζεται σε στοιχεία από τη ΔΕΗ και εξισώσεις που αφορούν το εκάστοτε τμήμα. Στη συνέχεια, αναλύεται και μοντελοποιείται στο Matlab/Simulink και κάθε τμήμα του συστήματος διασύνδεσης της ανεμογεννήτριας με το δίκτυο μέσης τάσης που περιλαμβάνει την ανεμογεννήτρια τύπου σύγχρονης μόνιμων μαγνητών, ανορθωτική διάταξη, μετατροπέα συνεχούς τάσης σε συνεχή, τριφασικό αντιστροφέα, φίλτρο και μετασχηματιστή. Για κάθε μετατροπέα αναλύεται και μοντελοποιείται και έλεγχος κλειστού βρόχου. Τέλος, τα επιμέρους μοντέλα συγκροτούνται σε ένα συνολικό μοντέλο. Μεταβάλλοντας το συντελεστή φόρτισης των μετασχηματιστών του δικτύου, το συντελεστή ισχύος και το πλήθος των ανεμογεννητριών που συνδέονται στον ίδιο ζυγό, εξάγεται το αρμονικό περιεχόμενο για διάφορους ζυγούς και ελέγχεται αν αυτό συμφωνεί με το πρότυπο IEC 61000-3-6. Επιπλέον, εξετάζεται το αρμονικό περιεχόμενο της τάσης, όταν ο ζυγός διασύνδεσης αλλάζει θέση μέσα στο υπό μελέτη δίκτυο, καθώς και όταν αλλάζει η ταχύτητα του ανέμου. / In the present diploma thesis a study of the effect of a wind turbine system interconnection with medium voltage grid is conducted, in terms of harmonic injection of the turbine to the grid. The study includes the modeling of each part of a medium voltage grid with actual data taken from the Public Power Corporation of Greece. Furthermore, a synchronous wind turbine with permanent magnets is modeled along with all the electronic power converters that are required for the interconnection with the medium voltage grid. All the individual models are connected together to form the overall model, including the medium voltage transmission lines, transformers, loads and their compensation capacitors, along with the wind turbine and the power converters. The wind turbine is connected in a bus of the medium voltage grid. Then, the harmonic content in both the bus of the wind turbine and in other buses of the grid is extracted and compared with the standard IEC 61000-3-6 that sets the limits for harmonic injection in medium voltage grid. Initially, the advantages of use of wind energy are mentioned compared to other conventional forms of energy. Furthermore, the problems caused by the presence of harmonics in the grid are discussed. A theoretical analysis of each section of the medium voltage grid is conducted. For each section, a model in Matlab / Simulink is also created, based on data from the Public Power Corporation of Greece and on equations related to each section. Then, every part of the system connecting the wind turbine to the medium voltage grid is analyzed and modeled in Matlab/Simulink. This system consists of a synchronous wind turbine with permanent magnets, DC-to-DC converter, three-phase inverter, filter and transformer. A closed loop control for each converter is also analyzed and modeled. Finally, the aforementioned models are built up into one single model. By varying the load factor of the grid transformers, the power factor and the number of wind turbines connected to the same bus, the harmonic content of various buses is extracted and checked if it complies with the standard IEC 61000-3-6. Moreover, the harmonic content of the voltage is calculated, when the system of wind turbine changes position in the present medium voltage grid, as well as when the wind speed is changed. Ανεμογεννήτρια Δίκτυο μέσης τάσης Αρμονικό περιεχόμενο 621.313 Wind turbine Medium voltage grid Power converters Total harmonic distortion Matlab/Simulink
302	Supervisory Hybrid Control of a Wind Energy Conversion and Battery Storage System Khan, Muhammad Shahid 31 July 2008 (has links) This thesis presents a supervisory hybrid controller for the automatic operation and control of a wind energy conversion and battery storage system. The supervisory hybrid control scheme is based on a radically different approach of modeling and control design, proposed for the subject wind energy conversion and battery storage system. The wind energy conversion unit is composed of a 360kW horizontal axis wind turbine mechanically coupled to an induction generator through a gearbox. The assembly is electrically interfaced to the dc bus through a thyristor-controlled rectifier to enable variable speed operation of the unit. Static capacitor banks have been used to meet reactive power requirements of the unit. A battery storage device is connected to the dc bus through a dc-dc converter to support operation of the wind energy conversion unit during islanded conditions. Islanding is assumed to occur when the tiebreaker to the utility feeder is in open position. The wind energy conversion unit and battery storage system is interfaced to the utility grid at the point of common coupling through a 25km long, 13.8kV feeder using a voltage-sourced converter unit. A bank of static (constant impedance) and dynamic (induction motor) loads is connected to the point of common coupling through a step down transformer. A finite hybrid-automata based model of the wind energy conversion and storage system has been proposed that captures the different operating regimes of the system during grid-connected and in islanded operating modes. The hybrid model of the subject system defines allowable operating states and predefines the transition paths between these operating states. A modular control design approach has been adapted in which the wind energy conversion and storage system has been partitioned along the dc bus into three independent system modules. Traditional control schemes using linear proportional-plus-integral compensators have been used for each system module with suitable modifications where necessary in order to achieve the required steady state and transient performance objectives. A supervisory control layer has been used to combine and configure control schemes of the three system modules to suite the requirements of system operation during any one operating state depicted by the hybrid model of the system. Transition management strategies have been devised and implemented through the supervisory control layer to ensure smooth inter-state transitions and bumpless switching among controllers. It has been concluded based on frequency domain linear analysis and time domain electromagnetic transient simulations that the proposed supervisory hybrid controller is capable of operating the wind energy conversion and storage system in both grid-connected and in islanded modes under changing operating conditions including temporary faults on the utility grid. hybrid control wind energy supervisory control linear control micro grid battery storage induction generator wind turbine finite hybrid automata microgrid 0544
303	Supervisory Hybrid Control of a Wind Energy Conversion and Battery Storage System Khan, Muhammad Shahid 31 July 2008 (has links) This thesis presents a supervisory hybrid controller for the automatic operation and control of a wind energy conversion and battery storage system. The supervisory hybrid control scheme is based on a radically different approach of modeling and control design, proposed for the subject wind energy conversion and battery storage system. The wind energy conversion unit is composed of a 360kW horizontal axis wind turbine mechanically coupled to an induction generator through a gearbox. The assembly is electrically interfaced to the dc bus through a thyristor-controlled rectifier to enable variable speed operation of the unit. Static capacitor banks have been used to meet reactive power requirements of the unit. A battery storage device is connected to the dc bus through a dc-dc converter to support operation of the wind energy conversion unit during islanded conditions. Islanding is assumed to occur when the tiebreaker to the utility feeder is in open position. The wind energy conversion unit and battery storage system is interfaced to the utility grid at the point of common coupling through a 25km long, 13.8kV feeder using a voltage-sourced converter unit. A bank of static (constant impedance) and dynamic (induction motor) loads is connected to the point of common coupling through a step down transformer. A finite hybrid-automata based model of the wind energy conversion and storage system has been proposed that captures the different operating regimes of the system during grid-connected and in islanded operating modes. The hybrid model of the subject system defines allowable operating states and predefines the transition paths between these operating states. A modular control design approach has been adapted in which the wind energy conversion and storage system has been partitioned along the dc bus into three independent system modules. Traditional control schemes using linear proportional-plus-integral compensators have been used for each system module with suitable modifications where necessary in order to achieve the required steady state and transient performance objectives. A supervisory control layer has been used to combine and configure control schemes of the three system modules to suite the requirements of system operation during any one operating state depicted by the hybrid model of the system. Transition management strategies have been devised and implemented through the supervisory control layer to ensure smooth inter-state transitions and bumpless switching among controllers. It has been concluded based on frequency domain linear analysis and time domain electromagnetic transient simulations that the proposed supervisory hybrid controller is capable of operating the wind energy conversion and storage system in both grid-connected and in islanded modes under changing operating conditions including temporary faults on the utility grid. hybrid control wind energy supervisory control linear control micro grid battery storage induction generator wind turbine finite hybrid automata microgrid 0544
304	Wind-turbine wake flows - Effects of boundary layers and periodic disturbances Odemark, Ylva January 2014 (has links) The increased fatigue loads and decreased power output of a wind turbine placed in the wake of another turbine is a well-known problem when building new wind-power farms and a subject of intensive research. These problems are caused by the velocity gradients and high turbulence levels present in the wake of a turbine. In order to better estimate the total power output and life time of a wind-power farm, knowledge about the development and stability of wind-turbine wakes is crucial. In the present thesis, the flow field around small-scale model wind turbines has been investigated experimentally in two wind tunnels. The flow velocity was measured with both hot-wire anemometry and particle image velocimetry. To monitor the turbine performance, the rotational frequency, the power output and the total drag force on the turbine were also measured. The power and thrust coefficients for different tip-speed ratios were calculated and compared to the blade element momentum method, with a reasonable agreement. The same method was also used to design and manufacture new turbine blades, which gave an estimate of the distribution of the lift and drag forces along the blades. The influence of the inlet conditions on the turbine and the wake properties was studied by subjecting the turbine to both uniform in flow and different types of boundary layer in flows. In order to study the stability and development of the tip vortices shed from the turbine blades, a new experimental setup for phase-locked measurements was constructed. The setup made it possible to introduce perturbations of different frequencies and amplitudes, located in the rear part of the nacelle. With a newly developed method, it was possible to characterize the vortices and follow their development downstream, using only the streamwise velocity component. Measurements were also performed on porous discs placed in different configurations. The results highlighted the importance of turbine spacings. Both the measurements on the turbine and the discs were also used to compare with large eddy simulations using the actuator disc method. The simulations managed to predict the mean velocity fairly well in both cases, while larger discrepancies were seen in the turbulence intensity. / <p>QC 20140424</p> wind power wind-turbine model wind tunnel porous disc hot-wire anemometry particle image velocimetry blade element momentum method large eddy simulations actuator disc method
305	Simulation and control of windfarms Spruce, Christopher John January 1993 (has links) This thesis examines the design of supervisory controllers for windfarms of pitch-controlled wind turbines. The control objectives are the maximisation of the financial income from the generated electricity and the minimisation of the turbines' fatigue damage. The design exploits the wide variations in the ratio of financial income to fatigue damage which are found both spatially across windfarms and as a function of time. The supervisory control strategy makes use of the ability of pitch-controlled turbines to operate with variable power set points; a capability which is rarely exploited in practice. A windfarm simulation which has been developed for the purposes of testing supervisory controllers is described. It is shown that the simulation is a suitable test-bed for this application. Results are presented which demonstrate how the fatigue damage of a turbine's gearbox and structural components vary as functions of the mean wind-speed, turbulence intensity and power set point, both for isolated turbines and for turbines experiencing wake effects. A lifetime performance function is proposed and 'ideal' power set point curves are evaluated using a genetic search algorithm. It is shown that significant improvements in performance can be achieved if the operation of the turbines is altered to take account of variable electricity tariffs. A windfarm control strategy that splits the turbines into interacting and non-interacting categories is found to give good results. Using data generated by the simulation, it is shown that simple cost functions can be developed for non-interacting turbines which, when used in a controller, give performance that is close to the 'ideal'. A similar cost function is applied to a group of three interacting turbines, and it is found that substantial reductions in all measures of total annual fatigue damage are achieved for a small reduction in total annual financial income. The on-line implementation of windfarm supervisory controllers is discussed and the behaviour of a simple hill-climbing algorithm is examined using a simulated group of three interacting turbines. 621.45
306	Constant Voltage, Constant Frequency Operation Of A Self-excited Induction Generator Caliskan, Ahmet 01 October 2005 (has links) (PDF) In this thesis, control schemes for the self-excited induction generator are developed with Matlab/Simulink. Self-excited induction generator is considered as a constant voltage-constant frequency supply for an isolated load. A wind turbine is assumed to be the variable-speed drive of the induction generator. Control schemes aim to ensure a constant voltage-constant frequency operation of the induction generator in case of the variations in the wind speed and/or the load. From the general model of the self-excited induction generator, the characteristics of the system and the dynamic responses of the system in case of any disturbance are examined. Next, the control strategies are developed both for the squirrel-cage rotor induction generator and for the wound-rotor induction generator. Two control loops are necessary for constant voltage-constant frequency operation of a variable speed induction generator, one for the voltage regulation and the other for the frequency regulation. After developing the control loops, constant voltage-constant frequency operation of the self-excited induction generator is simulated with a cage type saturation adaptive induction generator, a fixed capacitor with thyristor controlled reactor (TCR) used for frequency regulation and switched external resistors connected to the stator terminals used for voltage regulation.
307	Estudo do fluxo de potência de um gerador de indução de dupla alimentação atuando em um sistema de geração eólio-elétrica / Study of variation of power flow of a doubly-fed induction generator acting on a wind power generation system Natália Moreira Jacob 03 April 2013 (has links) A captação de energia eólica tem sido alvo de estudos em todo o mundo nas últimas décadas devido aos incentivos pela busca por geração de energia por meio de fontes alternativas. A configuração mais utilizada atualmente são as turbinas de três pás com eixo horizontal, upwind, operando com velocidade variável com limitação de potência por variação de passo, e utilizando o gerador de indução de dupla alimentação. A operação em velocidade variável com atuação no ângulo de passo permite a máxima captação de energia para as diferentes velocidades de vento, enquanto evita que a turbina ultrapasse o seu valor nominal de potência. O uso de conversores permite o controle das correntes do rotor, variando sua velocidade, e o controle da potência reativa de estator, e a montagem do tipo back-to-back permite que o fluxo de energia do rotor flua para a rede ou da rede. A modelagem matemática do sistema foi toda referenciada no referencial síncrono com notação vetorial e orientação de fluxo de rede, simplificando os modelos matemáticos. Para a montagem dos controladores foi utilizado o método de Controle de Modelo Interno e de Resistência Ativa. A montagem de todo o sistema para simulação foi realizada no Matlab/Simulink, e seu desenvolvimento é mostrado no decorrer do trabalho. Este trabalho analisa o fluxo de energia do sistema, desde a energia captada pelo vento até a energia entregue à rede. Para isso, são feitas análise dos fluxos das potências ativa e reativa do sistema, para fator de potência unitário, indutivo e capacitivo e para os mais recorrentes comportamentos do vento. Também são feitas análises a respeito dos regimes de operação do sistema, definidos a partir da relação entre os fluxos de potência, concluindo que a máquina poderá operar como gerador ou motor, devido principalmente à intensidade da variação do vento. / The use of wind energy has been the subject of studies around the world in recent decades due to the incentives to search for power generation through alternative sources. The most widely used configuration has been the three blades with horizontal axis and upwind turbine, operating in variable speed with power limitation by varying the pitch angle, and using the doubly fed induction generator configuration. The variable speed operation with power limitation enable for maximum energy harvesting for different wind speeds and prevents the turbine exceeds its nominal power. The use of converters allows for control of the rotor currents, varying the speed, and stator reactive power, and assembling type back-to-back allows for the rotor energy flux to flow into and out of the grid. Mathematical modeling of the whole system was referenced in the synchronous reference frame with vector notation and oriented by the grid flux, simplifying the mathematical models. For installation of the drivers, were used the Internal Model Control and Active Damping methods. The assembly of the entire system for simulation was conducted on Matlab / Simulink, and its step to step is shown in this work. This study analyzes the energy flow of the system, from the energy harvest from de wind to the energy delivered to the grid. To reach this, flow analysis of active and reactive power of the system is done, using unity, inductive and capacitive power factor, for the most recurrent wind behaviors. Analysis are made about the operation regimes of the system, defined as the relationship between the power flows, concluding that the machine can operate as a generator or motor, mainly due to the variation of the wind intensity. Escorregamento Fluxo de potência Gerador de indução dupla alimentação Sistema de potência Turbina eólica Doubly-fed induction generator Power flow Power system Slipping Wind turbine
308	Emulação dos regimes permante e transitório das turbinas de eixo horizontal incluindo o modelo estático da turbina magnus / Emulation of the static and dynamic characteristics of horizontal axis wind turbines including the steady-state representation of a magnus turbine Corrêa, Leonardo Candido 24 January 2014 (has links) Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / The lodgment of wind sites is in a visible growing demand not only in Brazil, but all over the world. The wind energy, even though consolidated, still hosts many scientific researches and industrial development in several areas such as control, power converter topologies and stability of grid connected wind turbines (WT). Due to the remarkable development of this technology in the market and the wind seasonality characteristics, it is difficult to study this power source in its operation field. Thus, a controlled environment for testing is desirable. This dissertation presents a topology of horizontal axis wind turbines (HAWT) emulator using a DC motor to provide an electrical generator the same torque that it would if it was driven by a typical WT. In addition to the static model, represented by the pitch angle and power coefficient, a dynamic model of HAWT is proposed in order to improve the representation of real turbines in the field, which allows characterizing the effect of wind shear, towering shadowing and turbine yaw. Furthermore, it permits emulating large inertia machines through smaller engines, by changing the torque imposed on the generator. The appealing motivation in this thesis is that the Magnus turbine emulation includes a relative new type of wind machine that possesses rotating cylinders instead of the traditional propeller blades in traditional HAWT. It is shown how these cylinders increase the available torque, then producing useful power even at lower wind speeds. Simulated and experimental results to evaluate the performance of the wind turbine emulator are presented. Both turbines are analyzed with and without MPPT. Finally the conclusions of this work are presented as well as new proposals for future works. / A instalação de parques eólicos tem se expandido não só no mundo, mas também no Brasil. A energia eólica, apesar de ser já bastante consolidada, ainda é palco para muitos trabalhos científicos e pesquisas na indústria nas áreas de controle, topologias de conversores de potência e estabilidade na conexão de aerogeradores com a rede. Devido a este fato junto com a sazonalidade do vento, torna-se difícil estudar esse tipo de fonte em seu âmbito de operação, sendo assim desejável um ambiente controlado para testes. Esta dissertação apresenta uma topologia para emulação de turbinas de eixo horizontal (HAWT) utilizando um motor de corrente contínua para acionar geradores com o mesmo torque que haveria caso estivessem acoplados a uma turbina real. Para melhor verossimilhança com as turbinas em campo, além do modelo estático composto pelo ângulo de passo das pás e o coeficiente de potência, propõe-se um modelo dinâmico para representar o efeito cortante do vento, o sombreamento da torre e o direcionamento da turbina em relação ao vento. Além do mais, o modelo proposto permite também a emulação de máquinas de grande inércia usando motores de menor porte, pela simples alteração do torque imposto ao gerador. O diferencial nesta dissertação consiste na possibilidade de emulação da turbina Magnus, que é um aerogerador que possui cilindros girantes no lugar das tradicionais pás presentes nas HAWT, que aumentam o torque disponível. Com isto, pode-se mostrar como a turbina Magnus pode gerar maior potência em baixas velocidades vento. São apresentados então os resultados simulados e experimentais avaliando o comportamento completo do emulador de turbinas eólicas. Ambas as turbinas são analisadas com e sem MPPT. Finalmente, são mostradas as conclusões do trabalho e as propostas para futuros trabalhos. Emulador de turbinas eólicas Modelo estático Modelo dinâmico Turbina Magnus Wind turbine emulator Static model Dynamic model Magnus turbine CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA
309	Estudo comparativo de p?s para aerogeradores de grande porte fabricadas em materiais comp?sitos refor?adas com fibra de carbono ou fibra de vidro Campos, Maxdavid Oliveira 30 December 2013 (has links) Made available in DSpace on 2014-12-17T14:07:12Z (GMT). No. of bitstreams: 1 MaxdavidOC_DISSERT.pdf: 4786704 bytes, checksum: 3c7952fbe7ed29e1b8d03e70a62dab6c (MD5) Previous issue date: 2013-12-30 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / The research and development of wind turbine blades are essential to keep pace with worldwide growth in the renewable energy sector. Although currently blades are typically produced using glass fiber reinforced composite materials, the tendency for larger size blades, particularly for offshore applications, has increased the interest on carbon fiber reinforced composites because of the potential for increased stiffness and weight reduction. In this study a model of blade designed for large generators (5 MW) was studied on a small scale. A numerical simulation was performed to determine the aerodynamic loading using a Computational Fluid Dynamics (CFD) software. Two blades were then designed and manufactured using epoxy matrix composites: one reinforced with glass fibers and the other with carbon fibers. For the structural calculations, maximum stress failure criterion was adopted. The blades were manufactured by Vacuum Assisted Resin Transfer Molding (VARTM), typical for this type of component. A weight comparison of the two blades was performed and the weight of the carbon fiber blade was approximately 45% of the weight of the fiberglass reinforced blade. Static bending tests were carried out on the blades for various percentages of the design load and deflections measurements were compared with the values obtained from finite element simulations. A good agreement was observed between the measured and calculated deflections. In summary, the results of this study confirm that the low density combined with high mechanical properties of carbon fibers are particularly attractive for the production of large size wind turbine blades / A pesquisa e desenvolvimento de p?s de aerogeradores s?o fundamentais para acompanhar o crescimento no setor de energias renov?veis em todo mundo. Apesar das p?s atualmente serem produzidas tipicamente com materiais comp?sitos refor?ados com fibras de vidro, a tend?ncia de aumento no tamanho das p?s, especialmente no setor offshore, cresce tamb?m o interesse por materiais comp?sitos refor?ados com fibras de carbono, devido ?s suas propriedades, como elevado m?dulo de elasticidade combinado com baixa densidade. Nesse trabalho um modelo de p? desenvolvido para geradores de grande porte (5 MW) foi estudado em escala reduzida. Foram realizados estudos num?ricos empregando t?cnicas de Computational Fluid Dynamics (CFD) para determinar o carregamento aerodin?mico na p?. Foram projetadas e fabricadas duas p?s com materiais comp?sitos de matriz ep?xi, sendo uma p? com refor?o de fibras de vidro e outra com fibras de carbono. Para os c?lculos estruturais, foi adotado o crit?rio de falha por tens?o m?xima. As p?s foram fabricadas pelo processo de Vacuum Assisted Resin Transfer Molding (VARTM), t?pico para este tipo de componente. Uma compara??o do peso das duas p?s foi realizada, e a p? de fibra de carbono apresentou 45% do peso da p? de fibra de vidro. Ensaios est?ticos de flex?o foram realizados nas p?s para v?rios percentuais do carregamento de projeto e as deflex?es medidas foram comparadas com os valores obtidos nas simula??es num?ricas por elementos finitos. Uma boa concord?ncia foi observada entre os valores de deflex?o medidos e calculados. Em resumo, os resultados obtidos neste trabalho confirmam que a baixa densidade combinada com elevadas propriedades mec?nicas das fibras de carbono s?o atrativas para a produ??o de p?s de aerogeradores de grande porte CNPQ::ENGENHARIAS
310	Effect of atmospheric ice accretion on the dynamic performance of wind turbine blades Alsabagh, Abdel Salam January 2017 (has links) Atmospheric icing presents serious challenges to the development of wind power of the wind energy industry in cold regions. The potential detrimental impact on the safe operation of wind turbines and the energy harvest hasn't been fully understood and requires further investigation. This thesis presents the research on icing profiles under different weather conditions and their impact on natural frequency, fatigue life, and lift and drag of the wind turbine blade. The research aims to develop a further understanding of the effect of atmospheric ice accretion on the structural integrity and aerodynamic performance of wind turbine blades through numerical and aerodynamic investigations to address the challenges facing the industry. A 5-MW NREL (National Renewable Energy Laboratory) wind turbine blade was selected for this study, due to availability of required geometric design parameters and experimental data for verification. The turbine rotor and its three blades were modelled and numerically simulated with commercial finite element software ANSYS. Three icing scenarios were chosen according to the ISO Standard and the corresponding icing profiles were developed to investigate their influence on vibrational behaviours of the wind turbine blade and rotor under different weather conditions. Icing loads were applied on the leading edge of the blade and natural frequency results were compared between clean and iced blades. It was found that harsh icing weather drove the natural frequency down to the near resonance limit, which could lead to significant issue on structural integrity of the wind turbine. The effect of atmospheric ice accretion with additional load due to varying wind speeds on the fatigue life of the wind turbine blade has been investigated. Significant reduction of fatigue life was found due to the increase of the von Mises stresses. Finally, computational fluid dynamics (CFD) analysis was carried out to investigate the effect of atmospheric ice accretion on the aerodynamic performance of typical 1-MW and 5-MW wind turbine blades. Results of the drag and lift coefficients and power production under different icing scenarios were obtained for five angles of attack. Compared with the results of the clean aerofoil profile, remarkable reduction in the power generation was observed due to the accreted ice at various aerofoil sections in the spanwise direction of the blade, demonstrating the detrimental impact of atmospheric icing on energy harvest for the wind energy industry. 621.406

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