Channel constrictions in which strong currents are mainly driven by tidal processes represent
sites with high potential for harvesting renewable and predictable tidal stream energy. Tidal Current
Turbines (TCTs) deployed in arrays appear to be the most promising solution to efficiently capturing
this carbon neutral energy resource. However to ensure the sustainable character of such projects,
the balance between power extraction maximization and environmental impact minimization must
be found so that device layout optimization takes into account environmental considerations. This is
particularly appropriate since both resource and impact assessments go intrinsically hand in hand.
The present method proposes the use and adaptation of ocean circulation models as an assessment
tool framework for tidal current turbine (TCT) array-layout optimization. By adapting both
momentum and turbulence transport equations of an existing model, the present TCT
representation method is proposed to extend the actuator disc concept to 3-D large scale ocean
circulation models. Through the reproduction of physical experiments to reasonable accuracy, grid
and time dependency tests and an up-scaling exercise, this method has shown its numerical validity
as well as its ability to simulate accurately both momentum and turbulent turbine-induced
perturbations in the wake. These capabilities are demonstrated for standalone devices and device
arrays, and are achieved with a relatively short period of computation time. Consequently the
present TCT representation method is a very promising basis for the development of a TCT array
layout optimization tool. By applying this TCT representation method to realistic cases, its capability
is demonstrated for power capture assessment and prediction of hydrodynamic interactions as
would be required during the layout deployment optimization process. Tidal energy has seen
considerable development over the last decade and the first commercial deployments are likely to
take place within the next 5 years. It is hoped that this new tool and the numerical approaches
described herein will contribute to the development of TCT array power plants around the world.
Date of Award | 2013 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Daniel Conley (Other Supervisor) |
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- Wake interactions
- Numerical modeling
- Regional Ocean Circulation Modelling System (ROMS)
- Tidal current turbine arrays
Numerical Modelling for Hydrodynamic Impact and Power Assessments of Tidal Current Turbine Arrays
Roc, T. (Author). 2013
Student thesis: PhD