TY - JOUR
T1 - Three dimensional multi fluid modeling of Geldart B bubbling fluidized bed with complex inlet geometries
AU - Ostermeier, Peter
AU - Vandersickel, Annelies
AU - Gleis, Stephan
AU - Spliethoff, Hartmut
N1 - Publisher Copyright:
© 2017 Elsevier B.V.
PY - 2017/5/1
Y1 - 2017/5/1
N2 - The hydrodynamics of dense solid-gas fluidized beds are strongly affected by the geometry of the bed and the properties of the bed material. The objective of this study is to numerically investigate the influence of the following aspects on these fluidization hydrodynamics: three dimensional versus two dimensional modeling, wall boundary conditions, particle size distribution, particle sphericity and inlet geometry of the nozzle floor. Simulations are carried out in a fully Eulerian framework to describe the gas (air) and solid phases (corundum, Geldart B, mean particle diameter 197 μm, sphericity 0.82). Analysis of particle-wall-interactions is performed by variation of the specularity coefficient φ, which characterizes the tangential momentum transfer from the particles to the wall. Different particle sizes can be accounted for by defining several granular solid phases, each representing one particle diameter respectively. The sphericity factor ψ is incorporated into the drag model to include the effect of the non-spherical shape of the particles on the fluid-solid-interactions. Comparison of simulation predictions and experimental data from a cylindrical lab-scale test rig (inner diameter 140 mm, nozzle floor) show good agreement with respect to externally accessible values (expansion, pressure drop, bubbling dynamics and solid circulation at the wall). Internal phenomena are validated by comparison with empirical correlations and data measured inside the fluidized bed. Additionally, the arrangement of the nozzles of the inlet geometry is modified to prove the predictive capability of the model. Results show that all of the aforementioned aspects strongly affect the hydrodynamics of the numerical simulation and therefore should be considered when modeling fluidized beds with non-spherical widely-distributed particles and complex inlet geometries.
AB - The hydrodynamics of dense solid-gas fluidized beds are strongly affected by the geometry of the bed and the properties of the bed material. The objective of this study is to numerically investigate the influence of the following aspects on these fluidization hydrodynamics: three dimensional versus two dimensional modeling, wall boundary conditions, particle size distribution, particle sphericity and inlet geometry of the nozzle floor. Simulations are carried out in a fully Eulerian framework to describe the gas (air) and solid phases (corundum, Geldart B, mean particle diameter 197 μm, sphericity 0.82). Analysis of particle-wall-interactions is performed by variation of the specularity coefficient φ, which characterizes the tangential momentum transfer from the particles to the wall. Different particle sizes can be accounted for by defining several granular solid phases, each representing one particle diameter respectively. The sphericity factor ψ is incorporated into the drag model to include the effect of the non-spherical shape of the particles on the fluid-solid-interactions. Comparison of simulation predictions and experimental data from a cylindrical lab-scale test rig (inner diameter 140 mm, nozzle floor) show good agreement with respect to externally accessible values (expansion, pressure drop, bubbling dynamics and solid circulation at the wall). Internal phenomena are validated by comparison with empirical correlations and data measured inside the fluidized bed. Additionally, the arrangement of the nozzles of the inlet geometry is modified to prove the predictive capability of the model. Results show that all of the aforementioned aspects strongly affect the hydrodynamics of the numerical simulation and therefore should be considered when modeling fluidized beds with non-spherical widely-distributed particles and complex inlet geometries.
KW - Computational fluid dynamics
KW - Eulerian approach
KW - Fluidized bed
KW - Hydrodynamics
KW - Kinetic theory of granular flow
UR - http://www.scopus.com/inward/record.url?scp=85013450462&partnerID=8YFLogxK
U2 - 10.1016/j.powtec.2017.02.015
DO - 10.1016/j.powtec.2017.02.015
M3 - Article
AN - SCOPUS:85013450462
SN - 0032-5910
VL - 312
SP - 89
EP - 102
JO - Powder Technology
JF - Powder Technology
ER -