Characteristics of breaking vorticity in spilling and plunging waves investigated numerically by SPH
Articolo
Data di Pubblicazione:
2020
Abstract:
The present paper, places emphasis on the vorticity induced by wave breaking, which
greatly contributes to sediments pick up and suspension as well as to air–water exchange at
the wave interface, thus deserving a thorough study. A weakly-compressible smoothed particle
(WCSPH) model, coupled with a two-equation model for turbulent stresses, has been
employed for this scope. A careful calibration of the SPH’s numerical parameters has been
first performed, based on experiments carried out in a sloped wave channel, specifically
using wave elevation and velocity data. Once proved the reliable performance of the model,
the characteristics of vorticity induced just prior and post breaking for both the cases of a
spilling and a plunging wave have been numerically studied. The main and detailed results
indicate that for both the types of breakers there is a cause-effect relation observed between
the stream wise flow deceleration and the vorticity generation.
greatly contributes to sediments pick up and suspension as well as to air–water exchange at
the wave interface, thus deserving a thorough study. A weakly-compressible smoothed particle
(WCSPH) model, coupled with a two-equation model for turbulent stresses, has been
employed for this scope. A careful calibration of the SPH’s numerical parameters has been
first performed, based on experiments carried out in a sloped wave channel, specifically
using wave elevation and velocity data. Once proved the reliable performance of the model,
the characteristics of vorticity induced just prior and post breaking for both the cases of a
spilling and a plunging wave have been numerically studied. The main and detailed results
indicate that for both the types of breakers there is a cause-effect relation observed between
the stream wise flow deceleration and the vorticity generation.
Tipologia CRIS:
1.1 Articolo in rivista
Keywords:
Smoothed particle hydrodynamics models · Spilling breaking · Plunging
breaking · Velocity field · Vorticity
Elenco autori:
De Padova, Diana; Ben Meftah, Mouldi; De Serio, Francesca; Mossa, Michele; Sibilla, Stefano
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