A Smoothed Particle Hydrodynamics approach for thermo-capillary flows

•Smoothed Particle Hydrodynamics (SPH) model for thermo-capillary flow driven by gradients of the surface tension.•Continuum surface force (CSF) approach including Marangoni forces.•Convergence study for thermos-capillary flow. Interfacial-driven flows are important phenomena in many processes. In t...

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Bibliographic Details
Published in:Computers & fluids 2018-11, Vol.176, p.1-19
Main Authors: Hopp-Hirschler, Manuel, Shadloo, Mostafa Safdari, Nieken, Ulrich
Format: Article
Language:English
Subjects:
Boundary conditions
Capillary flow
Computational fluid dynamics
Computer simulation
Divergence
Finite volume method
Fluid flow
Fluid mechanics
Marangoni effect
Mechanics
Meshless method
Model testing
Multiphase flow
Physics
Single-phase flow
Smooth particle hydrodynamics
Smoothed particle hydrodynamics (SPH)
Software
Surface tension
Temperature
Temperature gradients
Thermal convection
Vortices
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Summary:•Smoothed Particle Hydrodynamics (SPH) model for thermo-capillary flow driven by gradients of the surface tension.•Continuum surface force (CSF) approach including Marangoni forces.•Convergence study for thermos-capillary flow. Interfacial-driven flows are important phenomena in many processes. In this article, we present a Smoothed Particle Hydrodynamics (SPH) model for thermo-capillary flow driven by gradients of the surface tension. The model is based on the continuum surface force (CSF) approach including Marangoni forces. An incompressible SPH approach using (i) density-invariant divergence-free (DIDF), (ii) corrected SPH and (iii) particle shifting approaches for multi-phase systems is used for accurate results. We carefully validate the proposed model using several test cases. First, we demonstrate the effects of corrected SPH and particle shifting approaches using Taylor-Green vortex. Then, we study single-phase flow problems to validate correct implementation of boundary conditions, momentum and energy balance using lid-driven cavity, diffusive transport problem, and buoyancy-driven cavity test cases. Afterward, we investigate different multi-phase flow problems to validate normal and tangential component of the surface tension. Finally, we apply the model to thermo-capillary rise of a droplet due to a temperature gradient. We present a convergence study and compare the results with their counterparts obtained from OpenFoam software as well as Finite Volume method (FVM) reference from literature. We demonstrate that the proposed model is very accurate for thermo-capillary flow. The simulation results of the current SPH approach will be available online for the community.
ISSN:0045-7930
1879-0747
DOI:10.1016/j.compfluid.2018.09.010