Christoph Kloss scite author profile

We present a multi-purpose CFD-DEM framework to simulate coupled fluid-granular systems. The motion of the particles is resolved by means of the Discrete Element Method (DEM), and the Computational Fluid Dynamics (CFD) method is used to calculate the interstitial fluid flow. We first give a short overview over the DEM and CFD-DEM codes and implementations, followed by elaborating on the numerical schemes and implementation of the CFD-DEM coupling approach, which comprises two fundamentally different approaches, the unresolved CFD-DEM and the resolved CFD-DEM using an Immersed Boundary (IB) method. Both the DEM and the CFD-DEM approachare successfully tested against analytics as well as experimental data.

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Influence of rolling friction on single spout fluidized bed simulation

Goniva

Kloss

Deen³

et al. 2012

Particuology

450

189

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Efficient implementation of superquadric particles in Discrete Element Method within an open-source framework

2016

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Particle shape representation is a fundamental problem in the Discrete Element Method (DEM). Spherical particles with well known contact force models remain popular in DEM due to their relative simplicity in terms of ease of implementation and low computational cost. However, in real applications particles are mostly non-spherical, and more sophisticated particle shape models, like superquadric shape, must be introduced in DEM. The superquadric shape can be considered as an extension of spherical or ellipsoidal particles and can be used for modeling of spheres, ellipsoids, cylinder-like and box(dice)-like particles just varying five shape parameters. In this study we present an efficient C++ implementation of superquadric particles within the open-source and parallel DEM package LIGGGHTS. To reduce computational time several ideas are employed. In the particle-particle contact detection routine we use the minimum bounding spheres and the oriented bounding boxes to reduce the number of potential contact pairs. For the particlewall contact an accurate analytical solution was found. We present all necessary mathematics for the contact detection and contact force calculation. The superquadric DEM code implementation was verified on test cases such as angle of repose and hopper/silo discharge. The simulation results are in good agreement with experimental data and are presented in this paper. We show adequacy of the superquadric shape

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LIGGGHTS – Open Source Discrete Element Simulations of Granular Materials Based on Lammps

Kloss¹,

Goniva²

2011

117

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Hybrid parallelization of the LIGGGHTS open-source DEM code

et al. 2015

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Christoph Kloss

Models, algorithms and validation for opensource DEM and CFD-DEM

Influence of rolling friction on single spout fluidized bed simulation

Efficient implementation of superquadric particles in Discrete Element Method within an open-source framework

LIGGGHTS – Open Source Discrete Element Simulations of Granular Materials Based on Lammps

Hybrid parallelization of the LIGGGHTS open-source DEM code

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