Experimental studies of a small scale horizontal axis tidal turbine

Franchini, Italo

17 November 2016

The research in this thesis focuses on the investigation of tidal turbines using a small scale horizontal axis tidal turbine and a 2D hydrofoil testing rig, combining experiments with simulations to provide comprehensive results and to better understand some of the variables that affect their performance. The experimental campaigns were carried out at the University of Victoria fluids research lab and the Sustainable Systems Design Lab (SSDL). The experimental testing rigs were re-designed by the author and are now fully automated, including a friendly graphical user interface for easy implementation. Particle image velocimetry (PIV) technique was used as the quantitative flow visualization method to obtain the time-averaged flow fields. This thesis presents three investigations. The first study aims to quantify the impacts of channel blockage, free surface effects and foundations on hydrokinetic turbine performance, using porous discs and an axial flow rotor. The results were used to cross-validate computational fluid dynamics (CFD) simulations. It was found that as wall blockage increases, thrust and power are incremented with and without the inclusion of free surface deformation. Discrepancies between simulations and experimental results on free surface effects compared to a slip wall were obtained and hence further research is recommended and the author gives some advice on how to proceed in this investigation. The second study determines the performance of four hydrofoil candidates over a range of low Reynolds number (Re), delivering useful information that can be applied to low Re energy conversion systems and, specifically in this case, to improve the performance of the small scale tidal turbine at the SSDL lab. The study combines the 2D hydrofoil test rig along with PIV measurements in order to experimentally obtain lift and drag coefficients. The experiments were carried out in the recirculating flume tank over the range of low Re expected for the small scale rotor rig, in order to provide more accurate results to improve rotor blade design. In addition, numerical simulations using XFOIL, a viscid-inviscid coupled method, were introduced to the study. These results were analysed against experiments to find the most suitable parameters for reliable performance prediction. The final results suggested that adding a numerical trip at a certain chordwise distance produced more reliable results. Finally, an experimental study on turbine rotor performance and tip vortex behavior was performed using again the rotor rig and PIV. Blade design and rotor performance were assessed, showing good agreement with Blade Element Momentum (BEM) simulations, particularly at predicting the tip speed ratio corresponding to the maximum power coefficient point. Regarding the wake structure, tip vortex locations (shed from the blade tips) were captured using PIV in the near wake region, showing evidence of wake expansion. The velocity and vorticity fields are also provided to contribute to the development and validation of CFD and potential flow codes. / Graduate / 0548 / 0547 / 0538 / iafranch@uvic.ca

tidal turbine

porous disc

tidal power

horizontal axis tidal turbine

2D hydrodynamic coefficients

blockage effect

free surface effect

foundations

tip vortex

blade design

Etude des tuyères composites pour une conception optimale d'une hydrolienne à axe horizontal / Study of composites ducts for optimal design of an horizontal axis tidal turbine

Ait Mohammed, Mahrez

13 January 2017

La raréfaction des ressources fossiles non renouvelables et le dérèglement climatique font de la question énergétique un enjeu d’envergure mondiale. L’exploitation de nouvelles sources d’énergie renouvelable devient alors un objectif de première importance. L’énergie produite à partir des courants marins suscite depuis quelques années un intérêt particulier. Le concept de turbine sous-marine, appelée hydrolienne, désigne le dispositif permettant de convertir l’énergie cinétique des courants marins en énergie électrique. Ce travail de recherche traite les problématiques que pose la conception des hydroliennes à axe horizontal. Il sera mis en évidence que le monde des hélices marines présente une piste intéressante pour l’étude du comportement hydrodynamique des hydroliennes. Certains concepteurs d’hydroliennes avancent que l’ajout d’un système de carénage est favorable pour améliorer le rendement hydrodynamique. L’étude du gain hydrodynamique à encombrement constant que pourrait procurer l’ajout d’un carénage a donc été choisie comme point de départ de ce travail de recherche. Pour répondre au besoin des industriels lié à une problématique de gain de masse, les matériaux composites présentent un atout considérable en raison de leurs excellents rapports «masse/résistance» et «masse/rigidité». Une réalisation d’un carénage en matériaux composites présentant le meilleur ratio «puissance/masse» a été obtenue. Un carénage d’hydrolienne est de par sa position particulièrement confronté à des chocs. Ceci peut s’avérer très délicat car la structure composite en question est soumise à des sollicitations sévères liées à l’environnement marin. L’impact sur un carénage d’hydrolienne a été traité en détail dans ce travail de recherche. / Against the backdrop of the increasing scarcity of non-renewable fossil resources and climate change, the energy problem has become a worldwide issue. Hence, the exploitation of new renewable energy sources becomes a worldwide goal of primary importance. The concept of the underwater turbine, called tidal current turbine, designates the device which allows the conversion of the kinetic energy produced by marine currents in electric energy. This research study examines the problems related to the design of horizontal axis tidal current turbines. The present study shows that the world of marine propellers, sometimes entirely left out by the designers of tidal current turbines, presents an interesting avenue of research with regard to the hydrodynamic behaviour of tidal current turbines. Certain designers of tidal current turbines use a duct and hold that the addition of the duct contributes to the improvement of the hydrodynamic performance. Therefore, the study of the hydrodynamic benefits of ducted turbine using a constant overall cross-section than the bare turbine was the starting point of the present research work. In order to meet the needs of the manufacturers of tidal current turbines, which is generally linked to a problem of mass gain, composite materials present a considerable asset on account of their excellent «mass/resistance» and «mass/rigidity» relations. A structural design of ducted tidal current turbines using composite materials has therefore been examined. Hence, the design of a composite duct which yields the best «power/mass» ratio has been proposed. The duct of the tidal current turbine is especially confronted by the impacts due to its particular position. The impact damage aspect has also been examined in detail in the present research study.

Hydrolienne à axe horizontal

Hydrolienne carénée

Performance hydrodynamique

Optimisation

Matériaux composites

Conception structurelle

Impact

Endommagement

Horizontal axis tidal turbine

Ducted tidal turbine

Hydrodynamic performance

Composite materials

Structural design

Impact

Damage

531

621.24