M. Huber scite author profile

We present simulations and experiments of drainage processes in a micro-model. A direct numerical simulation is introduced which is capable of describing wetting phenomena on the pore scale. A numerical smoothed particle hydrodynamics model was developed and used to simulate the two-phase flow of immiscible fluids. The experiments were performed in a micro-model which allows the visualization of interface propagation in detail. We compare the experiments and simulations of a quasistatic drainage process and pure dynamic drainage processes. For both, simulation and experiment, the interfacial area and the pressure at the inflow and outflow are tracked. The capillary pressure during the dynamic drainage process was determined by image analysis.

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On the physically based modeling of surface tension and moving contact lines with dynamic contact angles on the continuum scale

Huber

Keller

Säckel

et al. 2016

Journal of Computational Physics

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Boundary Handling at Cloth–Fluid Contact

Huber

Eberhardt

Weiskopf

2014

Computer Graphics Forum

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We present a robust and efficient method for the two‐way coupling between particle‐based fluid simulations and infinitesimally thin solids represented by triangular meshes. Our approach is based on a hybrid method that combines a repulsion force approach with a continuous intersection handling to guarantee that no penetration occurs. Moreover, boundary conditions for the tangential component of the fluid's velocity are implemented to model the different slip conditions. The proposed method is particularly useful for dynamic surfaces, like cloth and thin shells. In addition, we demonstrate how standard fluid surface reconstruction algorithms can be modified to prevent the calculated surface from intersecting close objects. For both the two‐way coupling and the surface reconstruction, we take into account that the fluid can wet the cloth. We have implemented our approach for the bidirectional interaction between liquid simulations based on Smoothed Particle Hydrodynamics (SPH) and standard mesh‐based cloth simulation systems.

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Inflow/outflow with Dirichlet boundary conditions for pressure in ISPH

Kunz

Hirschler

Huber

et al. 2016

Journal of Computational Physics

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M. Huber

Study of Multi-phase Flow in Porous Media: Comparison of SPH Simulations with Micro-model Experiments

On the physically based modeling of surface tension and moving contact lines with dynamic contact angles on the continuum scale

Boundary Handling at Cloth–Fluid Contact

Inflow/outflow with Dirichlet boundary conditions for pressure in ISPH

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