@article{10902/35538,
year = {2025},
month = {1},
url = {https://hdl.handle.net/10902/35538},
abstract = {This paper introduces a robust framework within the OpenFOAM® environment to model the complex case of floating Oscillating Water Column (OWC) systems. It integrates existing modules for wave generation and absorption, overset mesh for dynamic mesh motion, and the Moody mooring model. A significant novel contribution of this work is the incorporation of a movable porous medium zone, designed to emulate the damping effect of the Power Take-Off (PTO) turbine. The paper first presents a validation of the coupled framework, comprising the tailored version of the two-phase fluid dynamics solver with the porous medium zones, the Overset algorithm for mesh motion and the Moody model for mooring systems. The validated model is then used to demonstrate the capabilities of the porous media zone in replicating the PTO damping for a floating OWC under constant loadings and regular waves. It is observed that the presence of the PTO alters the natural frequency and maximum displacements of the floating body, but has very little influence in the main displacements. The different characterisations of the PTO influence the frictional forces. The air flow is modified in the vicinity of the PTO due to the frictional forces exerted by the porous zone.},
organization = {Josh Davidson is funded by MCIN and by the European Union NextGenerationEU/PRTR-C17.I1, as well as by IKUR Strategy under the collaboration agreement between Ikerbasque Foundation and BCAM on behalf of the Department of Education of the Basque Government.},
publisher = {Elsevier Ltd},
publisher = {Applied Ocean Research, 2025, 154, 104309},
title = {Porous medium-based PTO damping and overset mesh motion: a combined approach for effective OpenFOAM® simulations of floating OWCs},
author = {Barajas Ojeda, Gabriel and López Lara, Javier and Davidson, Josh and Romano, Alessandro},
}