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CFD simulations of the wave energy converter Crestwing
Ocean wave energy has the potential of contributing significantly to the industrial energy production and export, both as a standalone solution by using wave energy converters (WECs) in wave energy parks, and in combination with offshore wind energy. For comparison the power intensity of wind is 0.4-0.6 kW/m2, solar is 0.1-0.2 kW/m2 and wave power intensity is about 2-3 kW/m2 [1, 2]. The wave energy converter Crestwing is an attenuator type of WEC with proven technology originating from the shipbuilding industry [3]. Although both model and full scale tests have demonstrated a high efficiency, many avenues are open for optimizing efficiency and minimizing costs to drive down the levelized cost of electricity. Effective energy harvesting is only conceivable by interpretation of underlying physics and optimization of key parameters of a WEC such as the hull shape. For these goals we use state-of-the-art CFD simulation tools based on fifth-order Stokes wave theory, overset mesh technique and dynamic fluid body interaction. At the conference we will present verification and validation of the CFD model relying on existing model tests and use the CFD results to highlight the key components of the Crestwing WEC [4, 5].
CFD simulations of the wave energy converter Crestwing
Ocean wave energy has the potential of contributing significantly to the industrial energy production and export, both as a standalone solution by using wave energy converters (WECs) in wave energy parks, and in combination with offshore wind energy. For comparison the power intensity of wind is 0.4-0.6 kW/m2, solar is 0.1-0.2 kW/m2 and wave power intensity is about 2-3 kW/m2 [1, 2]. The wave energy converter Crestwing is an attenuator type of WEC with proven technology originating from the shipbuilding industry [3]. Although both model and full scale tests have demonstrated a high efficiency, many avenues are open for optimizing efficiency and minimizing costs to drive down the levelized cost of electricity. Effective energy harvesting is only conceivable by interpretation of underlying physics and optimization of key parameters of a WEC such as the hull shape. For these goals we use state-of-the-art CFD simulation tools based on fifth-order Stokes wave theory, overset mesh technique and dynamic fluid body interaction. At the conference we will present verification and validation of the CFD model relying on existing model tests and use the CFD results to highlight the key components of the Crestwing WEC [4, 5].
CFD simulations of the wave energy converter Crestwing
Kovács, Gergely (author) / Leibetseder, Daniela (author) / Pilgaard Bloom, Rune (author) / Shao, Yanlin (author) / Walther, Jens Honore (author)
2023-01-01
Kovács , G , Leibetseder , D , Pilgaard Bloom , R , Shao , Y & Walther , J H 2023 , ' CFD simulations of the wave energy converter Crestwing ' , 10th International Conference on Computational Methods in Marine Engineering , Madrid , Spain , 27/06/2023 - 29/06/2023 .
Conference paper
Electronic Resource
English
DDC:
690