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Grid Connection of Permanent Magnet Generator Based Renewable Energy SystemsApelfröjd, Senad January 2016 (has links)
Renewable energy is harnessed from continuously replenishing natural processes. Some commonly known are sunlight, water, wind, tides, geothermal heat and various forms of biomass. The focus on renewable energy has over the past few decades intensified greatly. This thesis contributes to the research on developing renewable energy technologies, within the wind power, wave power and marine current power projects at the division of Electricity, Uppsala University. In this thesis grid connection of permanent magnet generator based renewable energy sources is evaluated. A tap transformer based grid connection system has been constructed and experimentally evaluated for a vertical axis wind turbine. Full range variable speed operation of the turbine is enabled by using the different step-up ratios of a tap transformer. This removes the need for a DC/DC step or an active rectifier on the generator side of the full frequency converter and thereby reduces system complexity. Experiments and simulations of the system for variable speed operation are done and efficiency and harmonic content are evaluated. The work presented in the thesis has also contributed to the design, construction and evaluation of a full-scale offshore marine substation for wave power intended to grid connect a farm of wave energy converters. The function of the marine substation has been experimentally tested and the substation is ready for deployment. Results from the system verification are presented. Special focus is on the transformer losses and transformer in-rush currents. A control and grid connection system for a vertical axis marine current energy converter has been designed and constructed. The grid connection is done with a back-to-back 2L-3L system with a three level cascaded H-bridge converter grid side. The system has been tested in the laboratory and is ready to be installed at the experimental site. Results from the laboratory testing of the system are presented. / Wind Power / Wave Power / Marine Currnet Power
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Avaliação do potencial de energias marinhas na região de São Sebastião / Assessment of the marine energies potential in the Sao Sebastiao regionFortes, Joao Flesch 02 March 2018 (has links)
Este trabalho quantifica o potencial de extração de energias marinhas associadas a ondas e correntes na região de São Sebastião, identificando locais mais adequados para tal extração. Para isso, se utiliza o modelo University of Miami Wave Model (UMWM) para simulação de ondas e o Stevens Estuarine and Coastal Ocean Model (sECOM) para simulação de correntes, analisando o período de julho de 2016 a junho de 2017. A região imediatamente ao largo da Ilha de São Sebastião apresenta um dos maiores potenciais do Estado de São Paulo para extração de energia marinha, com intensidade média anual do fluxo de energia de ondas de 22,3 kW/m e de densidade de potência de correntes de até 473,2 W/m2. Outro ponto com potencial de extração de energia das correntes está situado no interior do Canal de São Sebastião, com valor médio de 370,0 W/m2. / This research quantifies the potential of marine energy due to wave and currents in the Sao Sebastiao region, identifying the most suitable sites for such extraction. For this purpose, it is used the University of Miami Wave Model (UMWM) for wave simulation and the Stevens Estuarine and Coastal Ocean Model (sECOM) for current simulation, analyzing the period from July 2016 to June 2017. The region near the offshore side of the Sao Sebastiao Island shows one of the greatest potential in the State of Sao Paulo for marine energy extraction, with the average annual wave energy flux of 22.3 kW/m and mean current power density of up to 473.2 W/m2. Another point with potential of energy extraction from currents is located within the Sao Sebastiao Channel with the average value of 370.0 W/m2.
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Numerical simulation of a marine current turbine in turbulent flowXin, Bai January 2014 (has links)
The marine current turbine (MCT) is an exciting proposition for the extraction of renewable tidal and marine current power. However, the numerical prediction of the performance of the MCT is difficult due to its complex geometry, the surrounding turbulent flow and the free surface. The main purpose of this research is to develop a computational tool for the simulation of a MCT in turbulent flow and in this thesis, the author has modified a 3D Large Eddy Simulation (LES) numerical code to simulate a three blade MCT under a variety of operating conditions based on the Immersed Boundary Method (IBM) and the Conservative Level Set Method (CLS). The interaction between the solid structure and surrounding fluid is modelled by the immersed boundary method, which the author modified to handle the complex geometrical conditions. The conservative free surface (CLS) scheme was implemented in the original Cgles code to capture the free surface effect. A series of simulations of turbulent flow in an open channel with different slope conditions were conducted using the modified free surface code. Supercritical flow with Froude number up to 1.94 was simulated and a decrease of the integral constant in the law of the wall has been noticed which matches well with the experimental data. Further simulations of the marine current turbine in turbulent flow have been carried out for different operating conditions and good match with experimental data was observed for all flow conditions. The effect of waves on the performance of the turbine was also investigated and it has been noticed that this existence will increase the power performance of the turbine due to the increase of free stream velocity.
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Fluid Mechanics of Vertical Axis Turbines : Simulations and Model DevelopmentGoude, Anders January 2012 (has links)
Two computationally fast fluid mechanical models for vertical axis turbines are the streamtube and the vortex model. The streamtube model is the fastest, allowing three-dimensional modeling of the turbine, but lacks a proper time-dependent description of the flow through the turbine. The vortex model used is two-dimensional, but gives a more complete time-dependent description of the flow. Effects of a velocity profile and the inclusion of struts have been investigated with the streamtube model. Simulations with an inhomogeneous velocity profile predict that the power coefficient of a vertical axis turbine is relatively insensitive to the velocity profile. For the struts, structural mechanic loads have been computed and the calculations show that if turbines are designed for high flow velocities, additional struts are required, reducing the efficiency for lower flow velocities.Turbines in channels and turbine arrays have been studied with the vortex model. The channel study shows that smaller channels give higher power coefficients and convergence is obtained in fewer time steps. Simulations on a turbine array were performed on five turbines in a row and in a zigzag configuration, where better performance is predicted for the row configuration. The row configuration was extended to ten turbines and it has been shown that the turbine spacing needs to be increased if the misalignment in flow direction is large.A control system for the turbine with only the rotational velocity as input has been studied using the vortex model coupled with an electrical model. According to simulations, this system can obtain power coefficients close to the theoretical peak values. This control system study has been extended to a turbine farm. Individual control of each turbine has been compared to a less costly control system where all turbines are connected to a mutual DC bus through passive rectifiers. The individual control performs best for aerodynamically independent turbines, but for aerodynamically coupled turbines, the results show that a mutual DC bus can be a viable option.Finally, an implementation of the fast multipole method has been made on a graphics processing unit (GPU) and the performance gain from this platform is demonstrated.
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