Savoniova větrná turbína / Savonius rotor

Záviška, Radek

January 2015

The diploma thesis is focused on designer works of Savounius rotor for Raječko location. Finish of this design work is equipment, which will be used in this location as decentralized source of electrical energy. In thesis are written manufacturing processes as so as the process of design part including the calculation part, which is focused on characteristic quantity of Savonius rotor. Thesis is finished by econominal assessment of project.

Performance assessment of transient behaviour of small wind turbines

Pope, Kevin

01 August 2009

Small wind turbine installations have a variety of potential uses, each with unique performance demands and operating conditions. Many applications require that the turbine is placed in wind conditions that are not ideal for optimum operation. Better predictive techniques can improve wind turbine performance through improved control strategies and enhanced designs. Conventional methods of wind power design and control utilize an average power coefficient. In this thesis, various techniques to predict the transient power coefficient of a wind turbine are developed. The operation of a Savonius wind turbine is accurately represented, with a new model which considers the flow distributions to predict the changes in power output at all rotor positions. Another model is developed that represents the dynamics of a small horizontal wind turbine, including the effect of transient wind conditions on rotor speed and acceleration. These can supplement current methods to determine turbine placement, selection and categorization.

Wind turbine

Transient power coefficient

Savonius wind turbine

Integrering av Savonius-vindturbiner och solpaneler / Integration of Savonius wind turbines and solar panels

Kihlberg, Kristofer

January 2018

This thesis considers the integration between Savonius wind turbines and photovoltaics to form a hybrid power system. Different integration techniques were studied to find the most suited technique and the necessary components. The hybrid system was then to be compared with a solar panel system of equal sizing to investigate whether it could compete in terms of production and profitability. A model of the hybrid systems was built in MATLAB Simulink to simulate the production of the systems. Simulations used SMHI measurement data over wind speeds, solar radiation and temperature, with data resolution of one hour for 2017. The Swedish electricity trading market was also studied to determine which guidelines and prices that apply when selling electricity to the grid. The investment costs for the systems were estimated to allow economic conclusions to be drawn. The result was that a hybrid system had a higher power delivery to the load but the total production was higher for the solar system. The hybrid system couldn’t compete with the profitability of the solar system in the studied case. Possible reasons for the result was that the wind resources at the tested location wasn’t enough and that the price for wind turbines was high. Conclusions was that the price of the turbines needs to decrease in order to make the hybrid system more competitive. For hybrid systems that contain wind turbines, it is important that the chosen site has good wind resources to take advantage of the potential of the turbines.

Hybridsystem

Savonius

Vindkraft

Solpanel

Vertikalaxlad

Energy Systems

Energisystem

Evaluation of Self-Starting Vertical Axis Wind Turbines for Stand-Alone Applications

Kirke, Brian Kinloch, n/a

January 1998

There is an urgent need for economical, clean, sustainable energy supplies, not only in densely populated areas where electricity grids are appropriate, but also in rural areas where stand-alone power supply systems are often more suitable. Although electrical power supply is very versatile and convenient, it introduces unnecessary complexity for some off-grid applications where direct mechanical shaft power can conveniently be provided by a wind turbine. Wind energy is one of the more promising renewable energy sources. Most wind turbines are of the horizontal axis type, but vertical axis wind turbines or VAWTs have some advantages for direct mechanical drive applications. They need no tail or yaw mechanism to orient them into the wind and power is easily transmitted via a vertical shaft to a load at ground level. Blades may be of uniform section and untwisted, making them relatively easy to fabricate or extrude, unlike the blades of horizontal axis wind turbines (HAWTs) which should be twisted and tapered for optimum performance. Savonius rotor VAWTs are simple and may have a place where the power requirement is only a few Watts, but they are inefficient and uneconomical for applications with larger power requirements. VAWTs based on the Darrieus rotor principle are potentially more efficient and more economical, but those with fixed pitch blades have hitherto been regarded as unsuitable for stand-alone use due to their lack of starting torque and low speed torque. This starting torque problem can be overcome by using variable pitch blades, but most existing variable pitch VAWTs, variously known as giromills or cycloturbines, need wind direction sensors, microprocessors and servomotors to control the blade pitch, making them impracticable for stand-alone, non-electrical applications. A simpler but less well known concept is passive or self-acting variable pitch in which the blades are free to pitch under the combined action of aerodynamic and inertial forces in such a way that a favourable blade angle of attack is maintained without the complexity of conventional variable pitch systems. Several fonns of self-acting variable pitch VAWTs or SAPVAWTs have been described in the literature, several patents exist for variants on the concept, and at least two companies world-wide have attempted to commercialise their designs. However the aerodynamic behaviour of these devices has been little understood and most designs appear to have been based on nothing more than a qualitative appreciation of the potential advantages of the concept. This thesis assesses the potential of both fixed and passive variable pitch vertical axis wind turbines to provide economical stand-alone power for direct mechanical drive applications. It is shown that the starting torque and low speed torque problems of VAWTs can be overcome either by passive variable pitch or by a combination of suitable blade aerofoil sections, either rigid or flexible, and transmissions which unload the rotor at low speeds so that high starting torque is not necessary. The work done for this thesis is made up of a sequence of stages, each following logically from the previous one: 1. Several tasks have been identified which could be performed effectively by a self-starting vertical axis wind turbine using direct mechanical drive. These include, a. pumping water, b. purifying and/or desalinating water by reverse osmosis, c. heating and cooling using vapour compression heat pumps, d. mixing and aerating water bodies and e. heating water by fluid turbulence. Thus it is apparent that such a system has the potential to make a useful contribution to society. 2. A literature survey of existing VAWT designs has been carried out to assess whether any are suitable for these applications. 3. As no suitable existing design was identified, an improved form of SAPVAWT has been developed and patented. 4. To optimise the performance of the improved SAPVAWT, a mathematical model has been developed in collaboration with Mr Leo Lazauskas of the University of Adelaide (see Kirke and Lazauskas, 1991, Lazauskas and Kirke, 1992). As far as the author of the present thesis is aware, this is the only existing mathematical model able to predict the performance of this particular type of SAPVAWT, and one of only two worldwide which model SAPVAWTs. 5. In order to use the mathematical model to predict the performance of a given SAPVAWT, it is necessary to have lift, drag and moment data for the aerofoil profile to be used, over a wide range of incidence and Reynolds numbers. A literature search has revealed large gaps in the existing data. 6. Wind tunnel testing has been carried out to assess the effect of camber on the performance of one set of NACA sections at low Reynolds number, and performance figures for other sections have been estimated by interpolation from existing data. 7. Using the assembled aerofoil data, both experimental and estimated, the mathematical model has been used to predict the performance of both fixed and variable pitch VAWTs. It has been found to predict correctly the performance of known fixed pitch VAWTs and has then been used to predict the performance of fixed pitch VAWTs with cambered blades using newly developed profiles that exhibit superior characteristics at low Reynolds numbers. Results indicate that fixed pitch VAWTs using these blade sections should self-start reliably. 8. To validate the mathematical model predictions for self-acting variable pitch, a two metre diameter physical model has been built and tested in a wind tunnel, and acceptable agreement has been obtained between predicted and measured performance. 9. To demonstrate the performance of a SAP VA WT under field conditions, a six metre diameter turbine has been designed, fabricated, erected and tested. 10. Because a prime mover such as a wind turbine is of no use unless it drives a toad, particular attention has been paid to the behaviour of complete systems, including the wind turbine, the transmission and the load. It is concluded that VAWTs with the improved self-starting and low speed torque characteristics described in this thesis have considerable potential in stand-alone, direct mechanical drive applications.

Sustainable energy supplies

wind energy

savonius rotor

vertical axis wind turbines

An Orthogonal Savonius-type Wind Turbine: Design and Experiments

Du, Yingkang

30 May 2016

No description available.

Electrical Engineering

Wind energy

Savonius-type wind turbine

Wind tunnel

MPPT

VAWT

Modélisation des systèmes éoliens verticaux intégrés aux bâtiments : modélisation du couple production / Bâtiment / Modeling of vertical axis wind systems integrated into buildings : modeling of coupling between Production / Buildings

Jaohindy, Placide

20 August 2012

La technique d'intégration des systèmes éoliens verticaux (VAWT) au service des logements individuels, collectifs et tertiaires est une approche intéressante pour les acteurs de la maitrise d'énergie pour promouvoir une utilisation rationnelle de l'énergie. Le choix de l'implantation d'une éolienne en milieu urbain est déterminé par la hauteur des bâtiments, la vitesse du vent et l'intensité de turbulence du site. Les conditions de vents sévères à faible altitude sont favorables à une implantation de VAWT. Dans certaines villes, la hauteur moyenne des bâtiments est relativement faible et ceci fait qu'en ces lieux, les VAWTs sont appréciables par rapport aux HAWTs. La mécanique des fluides numériques (CFD) est mise en œuvre pour modéliser les écoulements d'air au travers d'éoliennes et des bâtiments. Un problème CFD modélisé avec un modèle de turbulence approprié donneront des résultats de simulations qui s'approcheront des réalités physiques et des résultats de l'expérimentation. Dans cette étude, les modèles standard k-" et SST k-! ont été utilisés. Après analyse des possibilités d'intégration d'une VAWT, la toiture reste la zone d'intégration la plus intéressante. En plus de l'étude aérodynamique, nous avons entamé une modélisation électrique de la chaîne de conversion de l'éolienne en utilisant le logiciel Matlab/Simulink. Le travail a été effectué dans le but de déterminer la puissance électrique susceptible d'être produite par l'éolienne. Pour finaliser cette étude, un modèle de couplage électrique de VAWTs avec un bâtiment considéré comme un modèle de charge est présenté. / The building integration of the vertical axis wind turbine (VAWT) to supply the individual, collective and tertiary residences consumption is an interesting approach that can help architects and the actors of the energy control to promote a rational use of renewable energy in the in homes. The choice of the location of the urban wind turbine type is determined by building height, wind speed and turbulence intensity of the site. The severe conditions of wind at low altitude are favorable for a VAWT installation. In some cities, the average buildings height is low, in these places, the VAWTs must be appreciable compared to the HAWTs. The modelling of the air flow through the wind turbine and the couple building-wind turbine involves the computation fluid dynamics (CFD). A problem modeled with a suitable turbulence model will give results that approach the physical reality and the experiment results. In this study, the standard k-" and SST k-! models were used. After analyzing the possibilities of VAWT integration, the roof is the most interesting integration area. In addition to CFD method, we have started to study the electrical model of the VAWT. The work was conducted to determine the electrical power generated by the wind turbine using Matlab/Simulink software. To complete the study, a VAWT model coupled with a building where the building is considered as a consumption model is presented.

Éolienne à axe vertical (VAWT)

Éolienne à axe horizontal (HAWT)

Rotor Savonius

Intégration architecturale

Modélisation numérique

CFD

Modélisation éléctrique

Vertical axis wind turbine (VAWT)

Horizontal axis wind turbine (HAWT)

Rotor Savonius

Architecural integration of wind turbine

Numerical modeling.

CFD

Electrical modeling.

Análise aerodinâmica de turbinas eólicas Savonius empregando dinâmica dos fluidos computacional

Akwa, João Vicente

January 2010

Neste trabalho, são apresentados a discussão de conceitos fundamentais, a metodologia e os resultados de simulações numéricas baseadas no Método de Volumes Finitos do escoamento de ar sobre algumas opções de configurações de turbinas eólicas do tipo Savonius, com e sem estatores, em operação e, também, em condições estáticas, como as encontradas nas partidas das mesmas. Comparam-se os resultados para diferentes domínios computacionais, bem como alternativas de discretização espacial e temporal, visando apresentar a influência desses sobre os valores obtidos e estabelecer os parâmetros computacionais adequados para a análise das turbinas em estudo. Nas simulações numéricas, desenvolvidas empregando o programa comercial Star-CCM+, a equação da continuidade e as equações de Navier-Stokes com médias de Reynolds são resolvidas, juntamente com as equações de um modelo de turbulência adequado, que é escolhido, para a obtenção dos campos de pressão e de velocidade do escoamento. Emprega-se um domínio contendo uma região com malha móvel, na qual o rotor é inserido. A cada simulação, a velocidade angular da região de malha móvel é especificada de maneira a variar a razão de velocidade de ponta do rotor. Através da integração das forças ocasionadas devido aos gradientes de pressão e das forças originadas pelo atrito viscoso sobre as pás do rotor eólico, obtém-se o coeficiente de torque em cada simulação. O torque e as forças atuantes no rotor também são obtidos de forma semelhante. Com esses dados, outros parâmetros como a potência e o coeficiente de potência são obtidos. Análises dos principais parâmetros de desempenho do rotor Savonius são realizadas e indicam uma boa concordância com resultados experimentais e de simulações numéricas realizadas por outros autores. Os resultados obtidos nas simulações apresentaram-se bastante representativos do fenômeno analisado. / This research work presents a discussion of basic concepts, the methodology and the results of numerical simulations based on Finite Volume Method for the air flow through some configuration options of the Savonius wind turbines, with and without stators, in operation, and also under static conditions, such as those found in the self starting. Results for different computational domains, as well as alternative spatial and temporal discretization are compared, in order to present the influence of these on the obtained values from the computational analysis of the turbines in study. In the numerical simulations, performed using the commercial software Star-CCM+, the equation of continuity and the Reynolds Averaged Navier-Stokes Equations were solved, together with the equations of a turbulence model appropriate, which is chosen, so that the fields of pressure and velocity could be found. It was used, in the calculations, a domain containing a region with a moving mesh, in which the rotor was inserted. In each simulation, the rotational rate of the moving mesh region was specified so as to vary the tip speed ratio of rotor. Through the integration of the forces arising due to the pressure gradients and the forces originated from the viscous friction on the wind rotor blades, the moment coefficient could be obtained in each simulation. The moment and forces acting on the rotor were also obtained similarly. With these data, other parameters such as the power and the power coefficient of the wind rotor could be obtained. Analysis of the principals performance parameters of the Savonius wind rotor were performed and indicated a good agreement with experimental results and numerical simulations performed by other authors. The simulations results are quite representative of the phenomenon analyzed.

Energia eólica

Turbinas eólicas

Simulação numérica

Dinâmica dos fluidos computacional

Savonius wind turbine

Computational fluids dynamics

Operation

Aerodynamic features

Análise aerodinâmica de turbinas eólicas Savonius empregando dinâmica dos fluidos computacional

Akwa, João Vicente

January 2010

Neste trabalho, são apresentados a discussão de conceitos fundamentais, a metodologia e os resultados de simulações numéricas baseadas no Método de Volumes Finitos do escoamento de ar sobre algumas opções de configurações de turbinas eólicas do tipo Savonius, com e sem estatores, em operação e, também, em condições estáticas, como as encontradas nas partidas das mesmas. Comparam-se os resultados para diferentes domínios computacionais, bem como alternativas de discretização espacial e temporal, visando apresentar a influência desses sobre os valores obtidos e estabelecer os parâmetros computacionais adequados para a análise das turbinas em estudo. Nas simulações numéricas, desenvolvidas empregando o programa comercial Star-CCM+, a equação da continuidade e as equações de Navier-Stokes com médias de Reynolds são resolvidas, juntamente com as equações de um modelo de turbulência adequado, que é escolhido, para a obtenção dos campos de pressão e de velocidade do escoamento. Emprega-se um domínio contendo uma região com malha móvel, na qual o rotor é inserido. A cada simulação, a velocidade angular da região de malha móvel é especificada de maneira a variar a razão de velocidade de ponta do rotor. Através da integração das forças ocasionadas devido aos gradientes de pressão e das forças originadas pelo atrito viscoso sobre as pás do rotor eólico, obtém-se o coeficiente de torque em cada simulação. O torque e as forças atuantes no rotor também são obtidos de forma semelhante. Com esses dados, outros parâmetros como a potência e o coeficiente de potência são obtidos. Análises dos principais parâmetros de desempenho do rotor Savonius são realizadas e indicam uma boa concordância com resultados experimentais e de simulações numéricas realizadas por outros autores. Os resultados obtidos nas simulações apresentaram-se bastante representativos do fenômeno analisado. / This research work presents a discussion of basic concepts, the methodology and the results of numerical simulations based on Finite Volume Method for the air flow through some configuration options of the Savonius wind turbines, with and without stators, in operation, and also under static conditions, such as those found in the self starting. Results for different computational domains, as well as alternative spatial and temporal discretization are compared, in order to present the influence of these on the obtained values from the computational analysis of the turbines in study. In the numerical simulations, performed using the commercial software Star-CCM+, the equation of continuity and the Reynolds Averaged Navier-Stokes Equations were solved, together with the equations of a turbulence model appropriate, which is chosen, so that the fields of pressure and velocity could be found. It was used, in the calculations, a domain containing a region with a moving mesh, in which the rotor was inserted. In each simulation, the rotational rate of the moving mesh region was specified so as to vary the tip speed ratio of rotor. Through the integration of the forces arising due to the pressure gradients and the forces originated from the viscous friction on the wind rotor blades, the moment coefficient could be obtained in each simulation. The moment and forces acting on the rotor were also obtained similarly. With these data, other parameters such as the power and the power coefficient of the wind rotor could be obtained. Analysis of the principals performance parameters of the Savonius wind rotor were performed and indicated a good agreement with experimental results and numerical simulations performed by other authors. The simulations results are quite representative of the phenomenon analyzed.

Energia eólica

Turbinas eólicas

Simulação numérica

Dinâmica dos fluidos computacional

Savonius wind turbine

Computational fluids dynamics

Operation

Aerodynamic features

Estudo numérico e experimental do escoamento sobre um rotor eólico Savonius em canal aerodinâmico com alta razão de bloqueio

Akwa, João Vicente

January 2014

Neste trabalho, são inicialmente discutidas as dificuldades referentes à obtenção de resultados numéricos para a operação de uma turbina Savonius independentes do grau de discretização, tamanho de domínio de cálculo e de máximo tempo físico simulado. Também são relatadas as divergências entre as metodologias numéricas e experimentais adotadas por diversos autores, que dificultam análises e comparações dos resultados obtidos por meio dessas metodologias com os resultados próprios obtidos. Devido a esses fatos, no presente trabalho, uma série de procedimentos experimentais e numéricos são realizados para efetuar análises do escoamento sobre uma turbina eólica Savonius. Nos experimentos em canal aerodinâmico, perfis de velocidade e parâmetros da turbulência são obtidos pela técnica de anemometria de fio quente. Medições com o uso de tubos de Pitot e manômetros eletrônicos são efetuadas para avaliar a variação da pressão e os perfis de velocidade média em posições selecionadas. Além de dados para análise, informações úteis para uso como condições de contorno nas simulações numéricas também são obtidas. Os fenômenos são reproduzidos através de simulações numéricas pelo Método de Volumes Finitos, que solucionam as equações da continuidade, de Navier-Stokes com médias de Reynolds e do modelo de turbulência k-ω SST. Análises experimentais e numéricas considerando o escoamento sobre um cilindro, que mantém semelhanças com o escoamento sobre o rotor, também são realizadas. Simulações numéricas do escoamento sobre o cilindro são efetuadas, fornecendo resultados representativos do escoamento real, quando geometrias tridimensionais são aplicadas na modelagem numérica. Nas simulações do escoamento sobre o rotor Savonius em condição estática, resultados representativos do escoamento real são obtidos com o uso de uma modelagem que leva em consideração a rugosidade das pás do rotor, estacionado na posição angular de 90°. Para posições angulares menores, não se obteve uma boa concordância entre os resultados experimentais e numéricos. A realização deste trabalho fornece informações úteis para a análise do fenômeno e tem potencial para contribuir com futuros trabalhos desse tema. / This research work initially presents a discussion about the difficulties related to obtaining numerical results for the operation of a turbine Savonius independent of the degree of discretization, calculation domain size and maximum physical time of the simulation. The differences between the numerical and experimental methodologies adopted by various authors difficult the analysis and comparisons of the results obtained through these methods with the results obtained by the methodology. Due to these facts, in this research work, a series of experimental and numerical procedures are performed to conduct analyzes of flow over a Savonius wind turbine. In the experiments on aerodynamic channel, velocity and turbulence profiles parameters are obtained by the technique of hot wire anemometry. Measurements using Pitot tubes and electronic manometers are made to evaluate the variation of pressure and mean velocity profiles at selected positions. In addition to data analysis, useful information for use as boundary conditions in the numerical simulations are also obtained. The phenomena are reproduced through numerical simulations by Finite Volume Method, that solve the equations of continuity, Reynolds-averaged Navier–Stokes equations and the equation of the turbulence model k-ω SST. Experimental and numerical analyzes considering the flow over a cylinder, which holds similarities with the flow over the rotor, are also performed. Numerical simulations of the flow over the cylinder are made, providing results representative of the actual flow when three-dimensional geometries are applied in numerical modeling. In flow simulations over the Savonius rotor in static condition, at 90°, representative results of the actual flow are obtained using a model that takes into account the roughness of the rotor blades. For smaller angular positions a good agreement between experimental and numerical results was not obtained. This work provides useful information for the analysis of the phenomenon and has the potential to contribute to future work on this theme.

Energia eólica

Turbinas eólicas

Métodos numéricos

Dinâmica dos fluidos computacional

Savonius rotor

Cylinder

Flow

Computational fluid dynamics

Experiments on aerodynamic channel

Análise aerodinâmica de turbinas eólicas Savonius empregando dinâmica dos fluidos computacional

Akwa, João Vicente

January 2010

Neste trabalho, são apresentados a discussão de conceitos fundamentais, a metodologia e os resultados de simulações numéricas baseadas no Método de Volumes Finitos do escoamento de ar sobre algumas opções de configurações de turbinas eólicas do tipo Savonius, com e sem estatores, em operação e, também, em condições estáticas, como as encontradas nas partidas das mesmas. Comparam-se os resultados para diferentes domínios computacionais, bem como alternativas de discretização espacial e temporal, visando apresentar a influência desses sobre os valores obtidos e estabelecer os parâmetros computacionais adequados para a análise das turbinas em estudo. Nas simulações numéricas, desenvolvidas empregando o programa comercial Star-CCM+, a equação da continuidade e as equações de Navier-Stokes com médias de Reynolds são resolvidas, juntamente com as equações de um modelo de turbulência adequado, que é escolhido, para a obtenção dos campos de pressão e de velocidade do escoamento. Emprega-se um domínio contendo uma região com malha móvel, na qual o rotor é inserido. A cada simulação, a velocidade angular da região de malha móvel é especificada de maneira a variar a razão de velocidade de ponta do rotor. Através da integração das forças ocasionadas devido aos gradientes de pressão e das forças originadas pelo atrito viscoso sobre as pás do rotor eólico, obtém-se o coeficiente de torque em cada simulação. O torque e as forças atuantes no rotor também são obtidos de forma semelhante. Com esses dados, outros parâmetros como a potência e o coeficiente de potência são obtidos. Análises dos principais parâmetros de desempenho do rotor Savonius são realizadas e indicam uma boa concordância com resultados experimentais e de simulações numéricas realizadas por outros autores. Os resultados obtidos nas simulações apresentaram-se bastante representativos do fenômeno analisado. / This research work presents a discussion of basic concepts, the methodology and the results of numerical simulations based on Finite Volume Method for the air flow through some configuration options of the Savonius wind turbines, with and without stators, in operation, and also under static conditions, such as those found in the self starting. Results for different computational domains, as well as alternative spatial and temporal discretization are compared, in order to present the influence of these on the obtained values from the computational analysis of the turbines in study. In the numerical simulations, performed using the commercial software Star-CCM+, the equation of continuity and the Reynolds Averaged Navier-Stokes Equations were solved, together with the equations of a turbulence model appropriate, which is chosen, so that the fields of pressure and velocity could be found. It was used, in the calculations, a domain containing a region with a moving mesh, in which the rotor was inserted. In each simulation, the rotational rate of the moving mesh region was specified so as to vary the tip speed ratio of rotor. Through the integration of the forces arising due to the pressure gradients and the forces originated from the viscous friction on the wind rotor blades, the moment coefficient could be obtained in each simulation. The moment and forces acting on the rotor were also obtained similarly. With these data, other parameters such as the power and the power coefficient of the wind rotor could be obtained. Analysis of the principals performance parameters of the Savonius wind rotor were performed and indicated a good agreement with experimental results and numerical simulations performed by other authors. The simulations results are quite representative of the phenomenon analyzed.

Energia eólica

Turbinas eólicas

Simulação numérica

Dinâmica dos fluidos computacional

Savonius wind turbine

Computational fluids dynamics

Operation

Aerodynamic features