Immersed-boundary/soft-sphere method for particle-particle-fluid interaction in a viscous flow: An OpenFOAM solver

We developed a stable OpenFOAM solver for Immersed Boundary Method based on direct forcing and regularized delta function. The soft-sphere model and a lubrication model were implemented to consider particle-particle collision in a viscous flow. We proposed a fluid-structure interaction (FSI) coupling method to accurately calculate the fluid forcing term and particle velocity. Our solver was validated for fixed and moving bodies, including rotation. The accuracy of various FSI schemes was evaluated in predicting the solid and fluid flow behavior in a viscous flow. It was demonstrated that neglecting or simplifying the fluid momentum change affects the accuracy of the solid velocity and fluid flow dynamic; for higher solid-to-fluid density ratios, a larger deviation was predicted. Furthermore, the FSI schemes highly influenced the behavior of the formed vortices. The solver was validated to predict the effective restitution coefficient of particles in a viscous flow as a function of the Stokes number. We also thoroughly analyzed the dynamic flow behavior of colliding particles through the pressure and velocity field and fluid force. This analysis helped us accurately determine the rebound velocity of particles in case of high Stokes numbers when the effect of viscous force is significant. & COPY; 2023 The Society of Powder Technology Japan. Published by Elsevier BV and The Society of Powder Technology Japan. This is an open access article under the CC BY license (http://creativecommons.org/ licenses/by/4.0/).

Automated summary

The researchers developed a stable OpenFOAM solver for Immersed Boundary Method and implemented a fluid-structure interaction (FSI) coupling method to accurately calculate the fluid forcing term and particle velocity. The solver was validated for fixed and moving bodies, and the accuracy of various FSI schemes and their impact on solid and fluid flow behavior in a viscous flow were evaluated. The study also analyzed the dynamic flow behavior of colliding particles and predicted the effective restitution coefficient of particles in a viscous flow.