Resumen
Methodologies to be used in numerical models based on Reynolds-averaged Navier?Stokes (RANS) equations and the volume of fluid (VoF) to deal with waves over coastal structures, which involve wave breaking and overtopping and porous structures, are shown in this manuscript. Two turbulence models, k-e NLS (non-linear Reynolds stress tensor) and k-e SCM (stabilized closure model), that are used to avoid the growth of the eddy viscosity, are implemented in the FLUENT® numerical model. Additionally, equations of momentum and turbulence models are adapted to simulate porous media of coastal structures. Comparisons of performance of k-e NLS, k-e SCM and standards k-e and k-? SST models in several classical cases of regular and random waves on coastal structures are carried out. It was noticed that the standard k-e turbulence model, and k-? SST with less intensity, over-predicted eddy viscosity, caused the decay of the free surface elevation and under-estimated wave overtopping discharge. k-e NLS and k-e SCM turbulence models have similar performance, with slightly better results of k-e NLS, showing good agreement with experimental ones.