Abstract
Numerical modeling of currents and waves is used throughout the marine energy industry for resource assessment. This study compared the output of numerical flow simulations run both as a standalone model and as a two-way coupled wave–current simulation. A regional coupled flow-wave model was established covering the English Channel using the Delft D-Flow 2D model coupled with a SWAN spectral wave model. Outputs were analyzed at three tidal energy sites: Alderney Race, Big Roussel (Guernsey), and PTEC (Isle of Wight). The difference in the power in the tidal flow between coupled and standalone model runs was strongly correlated to the relative direction of the waves and currents. The net difference between the coupled and standalone runs was less than 2.5%. However, when wave and current directions were aligned, the mean flow power was increased by up to 7%, whereas, when the directions were opposed, the mean flow power was reduced by as much as 9.6%. The D-Flow Flexible Mesh model incorporates the effects of waves into the flow calculations in three areas: Stokes drift, forcing by radiation stress gradients, and enhancement of the bed shear stress. Each of these mechanisms is discussed. Forcing from radiation stress gradients is shown to be the dominant mechanism affecting the flow conditions at the sites considered, primarily caused by dissipation of wave energy due to white-capping. Wave action is an important consideration at tidal energy sites. Although the net impact on the flow power was found to be small for the present sites, the effect is site specific and may be significant at sites with large wave exposure or strong asymmetry in the flow conditions and should thus be considered for detailed resource and engineering assessments.
Highlights
Tidal energy holds the potential to be part of the effort to de-carbonize and transform the global electricity generation sector
The viability of large-scale deployments will be defined by the ability of the industry to produce electricity at competitive costs, a challenge that is largely governed by the tidal energy resource, the technical plant availability, and the capital investment and operational cost
This study investigated the modeled wave and current conditions at three tidal energy sites in the English Channel using a Delft3D Flexible Mesh simulation coupled with a SWAN wave model
Summary
Tidal energy holds the potential to be part of the effort to de-carbonize and transform the global electricity generation sector. Numerous locations are being investigated as potential sites for tidal stream energy. It has the potential for significant contribution to world-wide electricity generation. Several pilot projects and small-scale generators have been demonstrated successfully, with 36.6 MW of of tidal stream energy installed cumulatively up to the end of 2020, producing over 60 GWh [2]. The viability of large-scale deployments will be defined by the ability of the industry to produce electricity at competitive costs, a challenge that is largely governed by the tidal energy resource, the technical plant availability, and the capital investment and operational cost. Tidal energy projects often utilize numerical simulations to provide information about site conditions. Flow and wave models are used to understand the resource, calculate power outputs, and assess the operational conditions
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