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Tidal stream energy site assessment via three-dimensional model and measurements

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  • Work, Paul A.
  • Haas, Kevin A.
  • Defne, Zafer
  • Gay, Thomas

Abstract

A methodology for assessment of the potential impacts of extraction of energy associated with astronomical tides is described and applied to a site on the Beaufort River in coastal South Carolina, USA. Despite its name, the site features negligible freshwater inputs; like many in the region, it is a tidal estuary that resembles a river. A three-dimensional, numerical, hydrodynamic model was applied for a period exceeding a lunar month, allowing quantification of harmonic constituents of water level and velocity, and comparison to values derived from measurements, recorded at a location within the model domain. The measurement campaign included surveys of bathymetry and velocity fields during ebb and flood portions of a tidal cycle for model validation. Potential far-field impacts of a generic tidal energy conversion device were simulated by introducing an additional drag force in the model to enhance dissipation, resulting in 10–60% dissipation of the pre-existing kinetic power within a flow cross-section. The model reveals effects of the dissipation on water levels and velocities in adjacent areas, which are relatively small even at the 60% dissipation level. A method is presented to estimate the optimal vertical location for the energy conversion device and the potential power sacrificed by moving to a different altitude.

Suggested Citation

  • Work, Paul A. & Haas, Kevin A. & Defne, Zafer & Gay, Thomas, 2013. "Tidal stream energy site assessment via three-dimensional model and measurements," Applied Energy, Elsevier, vol. 102(C), pages 510-519.
    • Handle: RePEc:eee:appene:v:102:y:2013:i:c:p:510-519
    DOI: 10.1016/j.apenergy.2012.08.040
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    Cited by:

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    2. Kim, Eun Soo & Sun, Hai & Park, Hongrae & Shin, Sung-chul & Chae, Eun Jung & Ouderkirk, Ryan & Bernitsas, Michael M., 2021. "Development of an alternating lift converter utilizing flow-induced oscillations to harness horizontal hydrokinetic energy," Renewable and Sustainable Energy Reviews, Elsevier, vol. 145(C).
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    4. Marta-Almeida, Martinho & Cirano, Mauro & Guedes Soares, Carlos & Lessa, Guilherme C., 2017. "A numerical tidal stream energy assessment study for Baía de Todos os Santos, Brazil," Renewable Energy, Elsevier, vol. 107(C), pages 271-287.
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    6. Lewis, M.J. & Neill, S.P. & Hashemi, M.R. & Reza, M., 2014. "Realistic wave conditions and their influence on quantifying the tidal stream energy resource," Applied Energy, Elsevier, vol. 136(C), pages 495-508.
    7. Kirinus, Eduardo de Paula & Oleinik, Phelype Haron & Costi, Juliana & Marques, Wiliam Correa, 2018. "Long-term simulations for ocean energy off the Brazilian coast," Energy, Elsevier, vol. 163(C), pages 364-382.
    8. Marco Piano & Peter E. Robins & Alan G. Davies & Simon P. Neill, 2018. "The Influence of Intra-Array Wake Dynamics on Depth-Averaged Kinetic Tidal Turbine Energy Extraction Simulations," Energies, MDPI, vol. 11(10), pages 1-21, October.
    9. Tang, H.S. & Kraatz, S. & Qu, K. & Chen, G.Q. & Aboobaker, N. & Jiang, C.B., 2014. "High-resolution survey of tidal energy towards power generation and influence of sea-level-rise: A case study at coast of New Jersey, USA," Renewable and Sustainable Energy Reviews, Elsevier, vol. 32(C), pages 960-982.
    10. González-Gorbeña, Eduardo & Pacheco, André & Plomaritis, Theocharis A. & Ferreira, Óscar & Sequeira, Cláudia, 2018. "Estimating the optimum size of a tidal array at a multi-inlet system considering environmental and performance constraints," Applied Energy, Elsevier, vol. 232(C), pages 292-311.
    11. Calandra, Gemma & Wang, Taiping & Miller, Calum & Yang, Zhaoqing & Polagye, Brian, 2023. "A comparison of the power potential for surface- and seabed-deployed tidal turbines in the San Juan Archipelago, Salish Sea, WA," Renewable Energy, Elsevier, vol. 214(C), pages 168-184.
    12. Sanchez, M. & Carballo, R. & Ramos, V. & Iglesias, G., 2014. "Floating vs. bottom-fixed turbines for tidal stream energy: A comparative impact assessment," Energy, Elsevier, vol. 72(C), pages 691-701.
    13. Waggitt, J.J & Scott, B.E, 2014. "Using a spatial overlap approach to estimate the risk of collisions between deep diving seabirds and tidal stream turbines: A review of potential methods and approaches," Marine Policy, Elsevier, vol. 44(C), pages 90-97.
    14. Lewis, M. & Neill, S.P. & Robins, P. & Hashemi, M.R. & Ward, S., 2017. "Characteristics of the velocity profile at tidal-stream energy sites," Renewable Energy, Elsevier, vol. 114(PA), pages 258-272.
    15. Park, Hongrae & Mentzelopoulos, Andreas P. & Bernitsas, Michael M., 2023. "Hydrokinetic energy harvesting from slow currents using flow-induced oscillations," Renewable Energy, Elsevier, vol. 214(C), pages 242-254.
    16. Radfar, Soheil & Panahi, Roozbeh & Javaherchi, Teymour & Filom, Siyavash & Mazyaki, Ahmad Rezaee, 2017. "A comprehensive insight into tidal stream energy farms in Iran," Renewable and Sustainable Energy Reviews, Elsevier, vol. 79(C), pages 323-338.
    17. Sánchez, M. & Carballo, R. & Ramos, V. & Iglesias, G., 2014. "Tidal stream energy impact on the transient and residual flow in an estuary: A 3D analysis," Applied Energy, Elsevier, vol. 116(C), pages 167-177.

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