Arrival Time Distributions of Spin-1/2 Particles

Spout fluidized beds are frequently used for the production of granules or particles through granulation. The products find application in a large variety of applications, for example detergents, fertilizers, pharmaceuticals and food. Spout fluidized beds have a number of advantageous properties, such as a high mobility of the particles, which prevents undesired agglomeration and yields excellent heat transfer properties. The particle growth mechanism in a spout fluidized bed as function of particle-droplet interaction has a profound influence on the particle morphology and thus on the product quality. Nevertheless, little is known about the details of the granulation process. This is mainly due to the fact that the granulation process is not visually accessible. In this work we use fundamental, deterministic models to enable the detailed investigation of granulation behaviour in a spout fluidized bed. A discrete element model is used describing the dynamics of the continuous gas-phase and the discrete droplets and particles. For each element momentum balances are solved. The momentum transfer among each of the three phases is described in detail at the level of individual elements. The results from the discrete element model simulations are compared with local measurements of particle volume fractions as well as particle velocities by using a novel fibre optical probe in a fluidized bed of 400 mm I.D. Simulations and experiments were carried out for two different cases using Geldart B type aluminium oxide particles: a freely bubbling fluidized bed and a spout fluidized bed with the presence of droplets. It is demonstrated how the discrete element model can be used to obtain information about the interaction of the discrete phases, i.e. the growth zone in a spout fluidized bed. Eventually this kind of information can be used to obtain closure information required in more coarse grained models.

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CFD-DEM modeling of a three-dimensional prismatic spouted bed

Pietsch

Heinrich

Karpinski

et al. 2017

Powder Technology

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Experimental and Numerical Investigation of Pressure Swirl Atomizers

2011

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The prediction of droplet size distributions for atomization nozzles is important for process design and improvement of industrial spraying processes. However, especially for non-Newtonian liquids, the published research applicable for engineering purposes is rare. To derive fundamental correlations for droplet size distributions in the future, the multiphase flow inside the spray nozzle is investigated by computational fluid dynamics, and measurements of droplet size distributions are done under the same flow conditions. In the present paper, two different hollow-cone nozzles were investigated using the volume-of-fluid method with largeeddy turbulence modeling inside the open source software OpenFOAM®. An experimental test rig suitable for spraying organic solvents was built.

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CFD-DEM modelling of circulation frequencies and residence times in a prismatic spouted bed

Pietsch

Kieckhefen

Heinrich

et al. 2018

Chemical Engineering Research and Design

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Dynamic model development based on experimental investigations of acoustically levitated suspension droplets

Buchholz

Haus

Polt

et al. 2021

International Journal of Heat and Mass Transfer

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Michael Schönherr

Comparison of fibre optical measurements and discrete element simulations for the study of granulation in a spout fluidized bed

CFD-DEM modeling of a three-dimensional prismatic spouted bed

Experimental and Numerical Investigation of Pressure Swirl Atomizers

CFD-DEM modelling of circulation frequencies and residence times in a prismatic spouted bed

Dynamic model development based on experimental investigations of acoustically levitated suspension droplets

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