Evaluation of potential marine current turbine sites in North American waters

Andersson, Tim, Akram, Muhammad Arsal, Carlnäs, Carl-Henrik, Salisbury, Tiffany

January 2020

Suitable locations for marine current power generation were scouted. The specific turbines considered in this project are vertical axis turbines and require an water velocity of 0.8 m/s to start and has a system efficiency of 20%. In the beginning of the project focus was directed towards areas along Florida's coastal line with high water velocities tapping into the Gulf Stream. Data found the velocities did not meet the water speed requirements. Following this observation, it was decided to discontinue further research in the Florida region and divert the attention towards waters in Alaska. There current velocities were found to be significantly higher. Because velocities vary over time marine current power is not relevant in Alaska, but rather the closely related technology tidal power. Two areas in Alaska distinguished themselves, Cook Inlet and Aleutian Islands.Potential power and annual energy extraction were estimated for turbine stations at each site. A battery energy storage system was implemented to counteract varying water velocities. The most promising site could steadily deliver 269 kW and an annual energy production of 2.44 GWh per turbine.

vertical axis

marine current turbines

alaska

florida

Annan elektroteknik och elektronik

Caractérisation temporelle et spectrale de champs instationnaires non gaussiens : application aux hydroliennes en milieu marin / Temporal and spectral characterization of non-stationary non-gaussian fields : application to tidal turbines in marine environment

Suptille, Mickaël

09 January 2015

L’environnement opérationnel des pales et des structures porteuses des hydroliennes est de nature incertaine, compte tenu de la variabilité de l’écoulement (turbulence, sillage, houle, courants. . .). Ces éléments structuraux subissent donc des états de contraintes multiaxiaux complexes avec des fortes variations temporelles à caractère aléatoire. Ainsi, le dimensionnement basé sur des critères statiques déterministes apparaît insuffisant pour tenir compte de la complexité de l’histoire du chargement mécanique et de sa variabilité.Ce travail vise à établir des méthodes de dimensionnement adaptées à cette situation, pour la conception de structures hydroliennes aux risques et aux coûts maîtrisés. La démarche adoptée repose sur la description de l’écoulement et de ses grandeurs statistiques, afin de caractériser les efforts exercés sur l’hydrolienne et les contraintes mécaniques extrêmes en pied de pale. / The operating environment of tidal turbines blades and body is uncertain, due to the flow variability (turbulence,wake, tide, streams...). These structural elements then undergo strongly time-varying complex multi-axial random stress states. A design based on static and deterministic criteria thus appears insufficient to take the complexity and the variability of the mechanical loading into account. This work aims at setting sizing methods that are adapted to this situation, in order to design tidal turbines with mastered risks and costs. The proposed method lies on a statistical description of the flow, in order to characterize the load of the turbine and the extreme mechanical stresses at the blade foot.

Caractérisation statistique

Représentation temporelle

Représentation spectrale

Marine current turbines

Spectral analysis

Stochastic processes

Random fields

Non gaussian

Non stationary

Statistical characterization

Temporal quantification

Numerical simulation of a marine current turbine in turbulent flow

Xin, Bai

January 2014

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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Hydrodynamic modelling for structural analysis of tidal stream turbine blades

Allsop, Steven Christopher

January 2018

The predictable nature of the tides offers a regular, reliable source of renewable energy that can be harnessed using tidal stream turbines (TSTs). The UK's practically extractable tidal stream energy resource has the potential to supply around 7 % of the country's annual electricity demand. As of 2016, the world's first commercial scale arrays have been deployed around the UK and France. The harsh nature of the marine operating environment poses a number of engineering challenges, where the optimal turbine design solution remains under investigation. In this thesis, a numerical model is developed to assess the power production and hydrodynamic behaviour of horizontal axis tidal turbines. The developed model builds upon well established and computationally efficient Blade Element Momentum Theory (BEMT) method for modern three-bladed wind turbines. The main novel contribution of this thesis is extending the application to an alternative design of a ducted, high solidity and open centre TST. A validation study using measurements from multiple different scale model experimental tank tests has proven the applicability of the model and suitability of the imposed correction factors. The analytical modifications to account for ducted flow were subsequently indirectly verified, where predictions of turbine power and axial thrust forces under optimal operating speeds were within 2 % of those using more advanced computational fluid dynamics (CFD) methods. This thesis presents a commercial application case of two turbines designed by OpenHydro, examining the BEMT performance with a sophisticated blade resolved CFD study. A comparison of results finds that the model is capable of predicting the average peak power to within 12 %, however it under predicts thrust levels by an average of 35 %. This study concludes that the model is applicable to ducted turbine configurations, but is limited in capturing the complex flow interactions towards the open centre, which requires further investigation. The computational efficiency of the newly developed model allowed a structural analysis of the composite blades, thus demonstrating it is suitable to effectively evaluate engineering applications. Stresses are seen to be dominated by flap-wise bending moments, which peak at the mid-length of the blade. This tool will further enable EDF to perform third party assessments of the different turbine designs, to aid decision making for future projects.

Contribution à la modélisation et à la conception optimale de génératrices à aimants permanents pour hydroliennes / Modeling and optimal design of permanent-magnet generators for marine tidal current turbines

Djebarri, Sofiane

06 March 2015

L'amélioration des performances des chaînes de conversion dédiées à la récupération d'énergie par les hydroliennes est un point particulièrement important pour rendre cette ressource économiquement attractive. La minimisation du coût de l'énergie produite passe nécessairement par une amélioration des performances de la chaîne de conversion électromécanique et une réduction des coûts de maintenance et de production des éléments la constituant. Dans ce contexte particulier, les génératrices à aimants permanents apparaissent particulièrement intéressantes dans la mesure où elles sont bien adaptées à un fonctionnement à basse vitesse et à fort couple. Ceci permet d'éliminer des systèmes mécaniques très complexes, encombrants et exigeants en maintenance, tels que le multiplicateur de vitesse et/ou le système d'orientation des pales. L'objectif de cette thèse est d’explorer un certain nombre de pistes concernant les outils, les concepts et les règles de conception à mettre en oeuvre pour dimensionner une génératrice associée en entraînement direct à une turbine hydrolienne à pas fixe. Les outils mis au point dans ces travaux englobent des modèles multi-physiques intégrés dans une démarche de conception qui se veut la plus globale possible. Cette méthodologie tient compte de la caractéristique de la ressource (courants de marées), de celle de la turbine (hélice), des spécifications de la génératrice à aimants permanents, de la mise en oeuvre d’une stratégie de pilotage associant MPPT et limitation de puissance par défluxage à fort courants de marées, en plus des contraintes liées au convertisseur. L'environnement de conception développé est basé sur un couplage des modèles dans une procédure d'optimisation. Les résultats obtenus mettent en lumière les points clés associés au développement d’une telle génératrice pour un contexte hydrolien. / The improvements of marine current turbines drive train are key features to ensure safe operation and to make tidal energy resource cost-attractive. In this context, eliminating mechanical systems that demand high-level of maintenance can be an interesting way to improve the global behavior of tidal turbines. For that purposes, the presented studies focus on design methodologies and concepts of direct-driven generators associated with fixed-pitch turbines. The proposed designs are based on multiphysics models of the generator that are integrated in an optimization process taking into account the drive train environment. For these reasons, several models have been integrated into a global design strategy in order to find solutions that improve marine current turbines performances. This strategy is based on the use of an optimization process that combines electromagnetic model, thermal model, turbine performances model, and tidal resource velocity profile. This methodology integrates also an efficient control strategy based on a maximum power point tracking (MPPT) approach at low tidal speed and a flux-weakening power limitation control at high tidal speed. This control at high tidal velocities is in this work achieved by considering only the generator electrical control without using blade pitching systems. The obtained results highlight trends that could lead to an improvement of the design and they help designers to set relevant technological choices in order to ensure significant cost reduction and highly improve the reliability of marine current turbines.

Conception optimale

Machines à aimants permanents

Machines à flux axial

Modélisation électromagnétique

Modélisation thermique

Modèles analytiques inverses

Énergie des courants de marées

Hydroliennes

Association machine/hélice

POD

Rim-Driven

Entraînement direct

Turbines à pas fixe

Entraînements à vitesse variable

Limitation de puissance par défluxage

Optimal design

Permanent magnet generators

Axial flux machines

Electromagnetic models

Analytical models

Thermal modeling

Tidal energy

Marine current turbines

Generator/turbine association

POD

Rim-Driven

Direct-drive

Fixed-pitch turbines

Variable speed drive

Flux-weakening

Power leveling

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