Mixture model for two-phase flows with high density ratios: A conservative and realizable SPH formulation

Abstract: The numerical modelling of two-phase mixture flows with high density ratios (e.g. water/air) is challenging. Multiphase averaged models with volume fraction representation encompass a simple way of simulating such flows: mixture models with relative velocity between phases. Such approaches were implemented in SPH (Smoothed Particle Hydrodynamics) using a mass-weighted definition of the mixture velocity, but with limited validation. Instead, to handle high density ratios, a mixture model with a volumetric mixtu… Show more

“…To preserve the symmetry of Fig. 1: Control volume in a two-component flow (gas phase in red, liquid phase in blue), the corresponding volume fractions and velocity fields [21,22].…”

“…SPH particles are no longer assigned to a specific phase: each individual particle carries the different phases with their respective volume fractions and are moved with a unique mixture velocity field. In this work, we aim at testing the performances of the SPH mixture model developed in [21,22] for air-water flows. Nevertheless, this modeling requires to tackle several questions, addressed in this work:…”

“…However, few works considered multifluid open boundaries. We choose here the approach developed in [19] and extend it to the mixture model detailed in [21,22] to allow distinct phases or mixtures to enter and leave the domain.…”

“…The Smoothed Particle Hydrodynamics (SPH) method appears as a natural way to model such highly distorted flows. To avoid computationally prohibitive costs related to the full discretization of bubbles or drops, a mixture model for high density ratio flows relying on a volume-based formulation with relative velocity between phases has first been developed and validated in [21,22]. Instead of having a once and for all assigned phase as in multifluid SPH, each particle now carries both phases through their respective volume fractions.…”

Air Entrainment Modeling in the SPH Method: A Two-Phase Mixture Formulation with Open Boundaries

“…To preserve the symmetry of Fig. 1: Control volume in a two-component flow (gas phase in red, liquid phase in blue), the corresponding volume fractions and velocity fields [21,22].…”

“…SPH particles are no longer assigned to a specific phase: each individual particle carries the different phases with their respective volume fractions and are moved with a unique mixture velocity field. In this work, we aim at testing the performances of the SPH mixture model developed in [21,22] for air-water flows. Nevertheless, this modeling requires to tackle several questions, addressed in this work:…”

“…However, few works considered multifluid open boundaries. We choose here the approach developed in [19] and extend it to the mixture model detailed in [21,22] to allow distinct phases or mixtures to enter and leave the domain.…”

“…The Smoothed Particle Hydrodynamics (SPH) method appears as a natural way to model such highly distorted flows. To avoid computationally prohibitive costs related to the full discretization of bubbles or drops, a mixture model for high density ratio flows relying on a volume-based formulation with relative velocity between phases has first been developed and validated in [21,22]. Instead of having a once and for all assigned phase as in multifluid SPH, each particle now carries both phases through their respective volume fractions.…”

Air Entrainment Modeling in the SPH Method: A Two-Phase Mixture Formulation with Open Boundaries

“…In the case of multiphase systems the USAW method can be used, e.g. a recent work on the SPH mixture model [55]. Since it was developed with a different purpose in mind, it does not have any specific feature which would make it tempting for interfacial flows modelling.…”

A Robust Method for Wetting Phenomena Within Smoothed Particle Hydrodynamics

Multiphase Flow Modelling Using Smoothed Particle Hydrodynamics: Considerations on Sediment Transport