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Development of a CFD-based numerical wave tank of a novel multipurpose wave energy converter

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  • Oliveira, D.
  • Lopes de Almeida, J.P.P.G.
  • Santiago, A.
  • Rigueiro, C.

Abstract

The development of new wave energy converters usually involves small-scale experiments in physical wave tanks. The jump to physical models at larger scales is an expensive and time-consuming process that can be supported by computational fluid dynamics (CFD) models. Using the CFD approach, it is possible to numerically simulate complex flows with high accuracy, once validation with experimental data has been carried out. This article describes an approach based on guidelines taken from the literature and adopted to develop and explore the capabilities of a CFD-based numerical wave tank for a novel multipurpose wave energy converter, REEFS. An incremental validation procedure, using experimental data collected with a piston-type wave tank, was adopted; the procedure began with wave-only tests which were followed by wave-structure interaction tests. Snapshots of numerical and experimental approaches were used to analyse fluid flow in the envelope of the REEFS converter. The results demonstrate that the CFD-based numerical wave tank model can adequately simulate the global wave surface profile, as well as local complex phenomena, such as the Venturi aspiration effect, that typically occur near the exterior stay vanes of the device. The results encourage the adoption of this model for future REEFS analysis.

Suggested Citation

  • Oliveira, D. & Lopes de Almeida, J.P.P.G. & Santiago, A. & Rigueiro, C., 2022. "Development of a CFD-based numerical wave tank of a novel multipurpose wave energy converter," Renewable Energy, Elsevier, vol. 199(C), pages 226-245.
  • Handle: RePEc:eee:renene:v:199:y:2022:i:c:p:226-245
    DOI: 10.1016/j.renene.2022.08.103
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    References listed on IDEAS

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    1. Windt, Christian & Davidson, Josh & Ringwood, John V., 2018. "High-fidelity numerical modelling of ocean wave energy systems: A review of computational fluid dynamics-based numerical wave tanks," Renewable and Sustainable Energy Reviews, Elsevier, vol. 93(C), pages 610-630.
    2. Ransley, E.J. & Greaves, D. & Raby, A. & Simmonds, D. & Hann, M., 2017. "Survivability of wave energy converters using CFD," Renewable Energy, Elsevier, vol. 109(C), pages 235-247.
    3. Lopes de Almeida, J.P.P.G. & Mujtaba, B. & Oliveira Fernandes, A.M., 2018. "Preliminary laboratorial determination of the REEFS novel wave energy converter power output," Renewable Energy, Elsevier, vol. 122(C), pages 654-664.
    4. Elhanafi, Ahmed & Fleming, Alan & Macfarlane, Gregor & Leong, Zhi, 2016. "Numerical energy balance analysis for an onshore oscillating water column–wave energy converter," Energy, Elsevier, vol. 116(P1), pages 539-557.
    5. Windt, Christian & Davidson, Josh & Ransley, Edward J. & Greaves, Deborah & Jakobsen, Morten & Kramer, Morten & Ringwood, John V., 2020. "Validation of a CFD-based numerical wave tank model for the power production assessment of the wavestar ocean wave energy converter," Renewable Energy, Elsevier, vol. 146(C), pages 2499-2516.
    6. Gunn, Kester & Stock-Williams, Clym, 2012. "Quantifying the global wave power resource," Renewable Energy, Elsevier, vol. 44(C), pages 296-304.
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    1. Luan, Zhengxiao & Chen, Bangqi & Jin, Ruijia & He, Guanghua & Ghassemi, Hassan & Jing, Penglin, 2024. "Validation of a numerical wave tank based on overset mesh for the wavestar-like wave energy converter in the South China Sea," Energy, Elsevier, vol. 290(C).

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