Hydrokinetic Tidal Energy Resource Assessments Using Numerical Models

Numerical models have been widely used for the resource characterization and assessment of tidal instream energy. The accurate assessment of tidal stream energy resources at a feasibility or project-design scale requires detailed hydrodynamic model simulations or high-quality field measurements. This study applied a three-dimensional finite-volume community ocean model (FVCOM) to simulate the tidal hydrodynamics in the Passamaquoddy–Cobscook Bay archipelago, with a focus on the Western Passage, to assist tidal energy resource assessment. IEC Technical specifications were considered in the model configurations and simulations. The model was calibrated and validated with field measurements. Energy fluxes and power densities along selected cross sections were calculated to evaluate the feasibility of the tidal energy development at several hotspots that feature strong currents. When taking both the high current speed and water depth into account, the model results showed that the Western Passage has great potential for the deployment of tidal energy farms. The maximum extractable power in the Western Passage was estimated using the Garrett and Cummins method. Different criteria and methods recommended by the IEC for resource characterization were evaluated and discussed using a sensitivity analysis of energy extraction for a hypothetical tidal turbine farm in the Western Passage.

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HF Radars for Wave Energy Resource Assessment Offshore NW Spain

Remote Sensing ◽

10.3390/rs13112070 ◽

2021 ◽

Vol 13 (11) ◽

pp. 2070

Author(s):

Ana Basañez ◽

Vicente Pérez-Muñuzuri

Keyword(s):

Wave Energy ◽

Numerical Models ◽

Wave Spectrum ◽

Energy Resource ◽

Electrical Energy ◽

Resource Assessment ◽

Electricity Production ◽

Statistical Validation ◽

Wave Energy Converters ◽

Energy Converters

Wave energy resource assessment is crucial for the development of the marine renewable industry. High-frequency radars (HF radars) have been demonstrated to be a useful wave measuring tool. Therefore, in this work, we evaluated the accuracy of two CODAR Seasonde HF radars for describing the wave energy resource of two offshore areas in the west Galician coast, Spain (Vilán and Silleiro capes). The resulting wave characterization was used to estimate the electricity production of two wave energy converters. Results were validated against wave data from two buoys and two numerical models (SIMAR, (Marine Simulation) and WaveWatch III). The statistical validation revealed that the radar of Silleiro cape significantly overestimates the wave power, mainly due to a large overestimation of the wave energy period. The effect of the radars’ data loss during low wave energy periods on the mean wave energy is partially compensated with the overestimation of wave height and energy period. The theoretical electrical energy production of the wave energy converters was also affected by these differences. Energy period estimation was found to be highly conditioned to the unimodal interpretation of the wave spectrum, and it is expected that new releases of the radar software will be able to characterize different sea states independently.

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A Methodology to Characterize Internal Solitons in the Ocean

Volume 7B: Ocean Engineering ◽

10.1115/omae2018-77869 ◽

2018 ◽

Author(s):

Henrique Coelho ◽

Zhong Peng ◽

Dave Sproson ◽

Jill Bradon

Keyword(s):

Internal Waves ◽

Large Scale ◽

Numerical Models ◽

Phase Speed ◽

Selection Procedure ◽

Wave Theory ◽

Tidal Energy ◽

Internal Tides ◽

Linear Wave ◽

Soliton Generation

Internal waves in the ocean occur in stably stratified fluids when a water parcel is vertically displaced by some external forcing and is restored by buoyancy forces. A specific case of such internal waves is internal tides and their associated currents. These currents can be significant in areas where internal waves degenerate into nonlinear solitary waves, known as solitons. Solitons are potentially hazardous for offshore engineering constructions, such as oil/gas pipelines and floating platforms. The most efficient mechanism of soliton generation is the tidal energy conversion from barotropic to baroclinic component over large-scale oceanic bottom obstructions (shelf breaks, seamounts, canyons and ridges). In this paper, a methodology is provided to compute diagnostics and prognostics for soliton generation and propagation, including the associated currents. The methodology comprises a diagnostic tool which, through the use of a set of theoretical and empirical formulations, selects areas where solitons are likely to occur. These theoretical and empirical formulations include the computation of the integral body force (1), the linear wave theory to compute the phase speed and the empirical model proposed by (2). After the selection procedure, the tool provides initial and boundary conditions for non-hydrostatic numerical models. The numerical models run in 2D-V configuration (vertical slices) with horizontal and vertical resolutions ranging from 50 to 200 m and 5 to 10 m, respectively. Examples are provided for an open ocean location over the Mascarene Plateau in the Indian Ocean. Validation of diagnostics and prognostics are provided against ADCP and satellite data.

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Tidal energy resource characterisation in the Dover Strait by using VHF radar and ADCP measurements

Progress in Renewable Energies Offshore ◽

10.1201/9781315229256-13 ◽

2016 ◽

Author(s):

M Thiébaut ◽

A Sentchev

Keyword(s):

Energy Resource ◽

Tidal Energy ◽

Vhf Radar ◽

Adcp Measurements

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Tidal energy resource characterization in Chacao Channel, Chile

International Journal of Marine Energy ◽

10.1016/j.ijome.2017.11.002 ◽

2017 ◽

Vol 20 ◽

pp. 1-16 ◽

Cited By ~ 11

Author(s):

Maricarmen Guerra ◽

Rodrigo Cienfuegos ◽

Jim Thomson ◽

Leandro Suarez

Keyword(s):

Energy Resource ◽

Tidal Energy

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Tidal energy resource characterization: methodology and field study in Admiralty Inlet, Puget Sound, WA (USA)

Proceedings of the Institution of Mechanical Engineers Part A Journal of Power and Energy ◽

10.1177/0957650912470081 ◽

2013 ◽

Vol 227 (3) ◽

pp. 352-367 ◽

Cited By ~ 38

Author(s):

B Polagye ◽

J Thomson

Keyword(s):

Field Study ◽

Puget Sound ◽

Energy Resource ◽

Tidal Energy ◽

Admiralty Inlet

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Effect of waves on the tidal energy resource at a planned tidal stream array

Renewable Energy ◽

10.1016/j.renene.2014.10.029 ◽

2015 ◽

Vol 75 ◽

pp. 626-639 ◽

Cited By ~ 47

Author(s):

M. Reza Hashemi ◽

Simon P. Neill ◽

Peter E. Robins ◽

Alan G. Davies ◽

Matt J. Lewis

Keyword(s):

Energy Resource ◽

Tidal Energy ◽

Tidal Stream

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In-Stream Tidal Energy Resources in Macrotidal Non-Cohesive Sediment Environments: Effect of Morphodynamic Changes at Two Bays in the Upper Gulf of California

10.20944/preprints202011.0514.v1 ◽

2020 ◽

Author(s):

Anahí Bermúdez-Romero ◽

Vanesa Magar ◽

Markus S. Gross ◽

Victor M. Godínez ◽

Manuel López-Mariscal ◽

...

Keyword(s):

High Resolution ◽

Gulf Of California ◽

Energy Production ◽

Energy Resource ◽

Tidal Energy ◽

Potential Effect ◽

Energy Resources ◽

Renewable Energy Resources ◽

Error Statistics ◽

High Resolution Models

While many in-steam tidal energy resource studies have been carried out globally, very few studies have assessed the effect of seabed changes on tidal energy resources. For coastal regions in particular, where the seabed is generally more mobile than in deep waters, bathymetric evolution could have a significant effect on tidal energy production. Here two high-resolution models, one purely hydrodynamic and one morphodynamic, are used to analyse the potential effect of natural morphodynamic evolution on tidal energy resources at two macro-tidal sandy bays, Adaír Bay and San Jorge Bay, in the Upper Gulf of California, Mexico. The high-resolution models are validated using a low-resolution model and ADCP observations to assess the agreement between model predictions and observations of tides at three ADCP moorings within the domain of interest. The models’ skill is evaluated using several error statistics such as the mean relative error, the root mean square error (RMSE), and the correlation coefficient. It was found that the regions with the largest bed changes, and also the largest renewable energy resources, were near the shore. Moreover, the results indicated a good correlation between a) regions with the most significant depth changes, and b) the regions where the difference in annual energy production with and without depth change was largest. Finally, the morphodynamic model was run for two years, and the evolution of a zonal profile (in the west-east direction) off the coast at the southeastern corner of Adaír Bay was inspected. This profile evolved towards a featureless equilibrium profile, in good agreement with the morphological classification for macro-tidal sandy environments and with the model assumptions. But most importantly, this natural evolution would not be detrimental to tidal energy exploitation at the site.

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Bardsey – an island in a strong tidal stream: underestimating coastal tides due to unresolved topography

Ocean Science ◽

10.5194/os-16-1337-2020 ◽

2020 ◽

Vol 16 (6) ◽

pp. 1337-1345

Author(s):

J. A. Mattias Green ◽

David T. Pugh

Keyword(s):

Satellite Altimetry ◽

Energy Resource ◽

Tidal Energy ◽

Small Scale ◽

Phase Lag ◽

Wake Effect ◽

Tidal Dissipation ◽

Tidal Energetics ◽

Tidal Stream ◽

Tidal Streams

Abstract. Bardsey Island is located at the western end of the Llŷn Peninsula in northwestern Wales. Separated from the mainland by a channel that is some 3 km wide, it is surrounded by reversing tidal streams of up to 4 m s−1 during spring tides. These local hydrodynamic details and their consequences are unresolved by satellite altimetry and are not represented in regional tidal models. Here we look at the effects of the island on the strong tidal stream in terms of the budgets for tidal energy dissipation and the formation and shedding of eddies. We show, using local observations and a satellite-altimetry-constrained product (TPXO9), that the island has a large impact on the tidal stream and that even in this latest altimetry-constrained product the derived tidal stream is under-represented due to the island not being resolved. The effect of the island leads to an underestimate of the current speed in the TPXO9 data in the channel of up to a factor of 2.5, depending on the timing in the spring–neap cycle, and the average tidal energy resource is underestimated by a factor up to 14. The observed tidal amplitudes are higher at the mainland than at the island, and there is a detectable phase lag in the tide across the island; this effect is not seen in the TPXO9 data. The underestimate of the tide in the TPXO9 data has consequences for tidal dissipation and wake effect computation and shows that local observations are key to correctly estimating tidal energetics around small-scale coastal topography.

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Effect of Wave-Current Interaction on Strong Tidal Current

Volume 10: Ocean Renewable Energy ◽

10.1115/omae2018-78121 ◽

2018 ◽

Author(s):

Aleksandar Jakovljević ◽

Martin Dumont ◽

Frédéric Dias

Keyword(s):

Velocity Field ◽

Energy Resource ◽

Tidal Energy ◽

Research Area ◽

Stokes Drift ◽

Area Of Interest ◽

Time Period ◽

Tidal Turbine ◽

Wave Heights ◽

Wave Energy Spectrum

We consider the influence of wave-current interactions (WCI) on the tidal energy resource through changes in the velocity field of tidal currents. In order to investigate this, we have run three models: SWAN (stand-alone), ROMS (stand-alone) and COAWST (two-way coupled ROMS and SWAN model). The research area of our studies is Alderney Race, France, an area with strong currents, which has a strong potential for tidal turbine deployment. The time period used for the simulations was March 2008, when a strong storm hit the Alderney Race area and produced significant wave heights (Hs) of up to 7 m and a Stokes drift near the surface close to 0.3 m/s. Furthermore, in order to see the extent of the influence of large waves on current parameters, two virtual storms with larger waves have been generated by magnifying the wave energy spectrum and changing the frequency of the spectrum of the real storm in March 2008. The 3D and the barotropic velocity field were analysed in order to see if the WCI in the waters of Alderney Race during storm conditions can cause a significant increase or decrease of the current speed and through which mechanisms. This study also investigates the Turbulent Kinetic Energy (TKE) in order to portray the turbulent conditions in the area of interest which are important for resource characterisation and device design.

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