Characterization of solids mixing patterns in bubbling fluidized beds

▶ Mixing of solids modeled with DEM-CFD and validated by radioactive particle tracking. ▶ A 2D model can predict solids mixing in axial direction but cannot be used for radial direction. ▶ Gross and internal circulations were detected and showed that affect solids axial diffusivity. ▶ Coalescence an...

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Veröffentlicht in:Chemical engineering research & design 2011-06, Vol.89 (6), p.817-826
Hauptverfasser: Norouzi, H.R., Mostoufi, N., Mansourpour, Z., Sotudeh-Gharebagh, R., Chaouki, J.
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Sprache:eng
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Zusammenfassung:▶ Mixing of solids modeled with DEM-CFD and validated by radioactive particle tracking. ▶ A 2D model can predict solids mixing in axial direction but cannot be used for radial direction. ▶ Gross and internal circulations were detected and showed that affect solids axial diffusivity. ▶ Coalescence and breakage of bubbles were investigated and showed graphically in the bed. Behavior of the solid phase in fluidized beds was studied by a 2D CFD-DEM approach to obtain more information on the solid mixing and circulation. Hydrodynamic parameters, including solid diffusivity, and internal and gross circulations were considered in this study. To validate the simulation, time-position data obtained by the Radioactive Particle Tracking (RPT) technique were used. It was shown that the 2D model can satisfactorily predict the axial diffusivity, while the radial diffusivity calculated based on the model is an order of magnitude smaller than the experimental one in 3D. The influence of aspect ratio of the bed, type of distributor, and inlet gas velocity on solids mixing pattern were also studied. The solids flow pattern in the bed changed considerably by increasing the aspect ratio. Different solid circulations were captured by numerical model for the two types of distributors, namely porous and injection types. The results suggested that increasing the superficial gas velocity caused rigorous internal and gross circulations, which in return, improved solids mixing and decreased deviations from well mixed state.
ISSN:0263-8762
DOI:10.1016/j.cherd.2010.10.014