Modified incompressible smooth particle hydrodynamics in porous media method for modeling the damping of a waves train on an inclined porous structure - Université de Poitiers Access content directly
Journal Articles International Journal for Numerical Methods in Fluids Year : 2022

Modified incompressible smooth particle hydrodynamics in porous media method for modeling the damping of a waves train on an inclined porous structure

Melissa Ramos Ortega
  • Function : Author
Université de Poitiers
Institut Pprime
Anthony Beaudoin
Université de Poitiers
Institut Pprime

Abstract

In this work, the ISPHP method proposed by Akbari and Namin in 2013 has been modified by implementing the Taylor expansion of a classical smoothing function. The modified ISPHP method with the Taylor expansion of the smoothing function, the optimization of the solving of Poisson's equation and the wave maker, has been used to simulate the damping of a waves train on an inclined porous structure. The comparison between the numerical results obtained with the modified ISPHP method and the experimental data obtained by Carrasco et al. in 2020 has shown on the one hand that the modified ISPHP method could be used to study the damping of a waves train on an inclined porous structure and on the other hand that the dimensionless number could be used to characterize the energy transformations of the interaction of a waves train and an inclined porous structure.

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Engineering Sciences [physics]

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https://hal-univ-poitiers.archives-ouvertes.fr/hal-04077911

Submitted on : Friday, April 21, 2023-6:40:18 PM

Last modification on : Saturday, April 22, 2023-4:04:54 AM

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Dates and versions

hal-04077911 , version 1 (21-04-2023)

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Cite

Melissa Ramos Ortega, Anthony Beaudoin. Modified incompressible smooth particle hydrodynamics in porous media method for modeling the damping of a waves train on an inclined porous structure. International Journal for Numerical Methods in Fluids, 2022, 94 (3), pp.223-250. ⟨10.1002/fld.5052⟩. ⟨hal-04077911⟩

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