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New simulation tool helps predict wave energy device performance in real ocean conditions

Researchers have created a high-precision digital tank that models how waves and ocean currents interact with wave energy converters, a critical gap for commercializing renewable ocean power. The breakthrough could accelerate deployment timelines and reduce costly prototyping by allowing manufacturers to test devices virtually under varied sea conditions before building them.

Originaltitel: Development of an SPH-based numerical wave-current tank and application to wave energy converters

Abstrakt

<p>This research proposes a high-fidelity based numerical tank designed to analyze the modified hydrodynamics that develops in waves-current fields, aimed at generating power matrices for wave energy converters (WEC). This tank is developed within the open source DualSPHysics Lagrangian framework using the Smoothed Particle Hydrodynamics (SPH) method, validated with physical data, and applied to simulate a point-absorber WEC. Our proposed numerical facility implements open boundary conditions, employing third-order consistent wave theory for direct generation, with flow field constrained by a Doppler correlation function. Reference data is collected from dedicated physical tests for monochromatic waves; the wave-current numerical basin demonstrates very high accuracy in terms of wave transformation and velocity field. In the second segment of this paper, a current-aware power transfer function is computed for the taut-moored point-absorber Uppsala University WEC (UUWEC). Parametrically defined regular waves with uniform currents are utilized to map an operational sea state featuring currents of different directions and intensities. In terms of power capture capabilities, the modified dynamics observed in presence of currents translates in a dependence of the WEC's power matrix not only on wave parameters, but also on current layouts. The UUWEC's power output has revealed that regardless of current directionality, annual output consistently decreases, with a registered power drop as high as 10% when an expected current field is introduced.</p>

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