TY - JOUR
T1 - Fluidization of spherocylindrical particles
AU - Mahajan, Vinay V.
AU - Nijssen, Tim M.J.
AU - Fitzgerald, Barry W.
AU - Hofman, Jeroen
AU - Kuipers, Hans
AU - Padding, Johan T.
PY - 2017
Y1 - 2017
N2 - Multiphase (gas-solid) flows are encountered in numerous industrial applications such as pharmaceutical, food, agricultural processing and energy generation. A coupled computational fluid dynamics (CFD) and discrete element method (DEM) approach is a popular way to study such flows at a particle scale. However, most of these studies deal with spherical particles while in reality, the particles are rarely spherical. The particle shape can have significant effect on hydrodynamics in a fluidized bed. Moreover, most studies in literature use inaccurate drag laws because accurate laws are not readily available. The drag force acting on a non-spherical particle can vary considerably with particle shape, orientation with the flow, Reynolds number and packing fraction. In this work, the CFD-DEM approach is extended to model a laboratory scale fluidized bed of spherocylinder (rod-like) particles. These rod-like particles can be classified as Geldart D particles and have an aspect ratio of 4. Experiments are performed to study the particle flow behavior in a quasi-2D fluidized bed. Numerically obtained results for pressure drop and bed height are compared with experiments. The capability of CFD-DEM approach to efficiently describe the global bed dynamics for fluidized bed of rod-like particles is demonstrated.
AB - Multiphase (gas-solid) flows are encountered in numerous industrial applications such as pharmaceutical, food, agricultural processing and energy generation. A coupled computational fluid dynamics (CFD) and discrete element method (DEM) approach is a popular way to study such flows at a particle scale. However, most of these studies deal with spherical particles while in reality, the particles are rarely spherical. The particle shape can have significant effect on hydrodynamics in a fluidized bed. Moreover, most studies in literature use inaccurate drag laws because accurate laws are not readily available. The drag force acting on a non-spherical particle can vary considerably with particle shape, orientation with the flow, Reynolds number and packing fraction. In this work, the CFD-DEM approach is extended to model a laboratory scale fluidized bed of spherocylinder (rod-like) particles. These rod-like particles can be classified as Geldart D particles and have an aspect ratio of 4. Experiments are performed to study the particle flow behavior in a quasi-2D fluidized bed. Numerically obtained results for pressure drop and bed height are compared with experiments. The capability of CFD-DEM approach to efficiently describe the global bed dynamics for fluidized bed of rod-like particles is demonstrated.
UR - http://resolver.tudelft.nl/uuid:fa3d1ee7-6779-4aac-a95c-cb9484884ede
UR - http://www.scopus.com/inward/record.url?scp=85024101304&partnerID=8YFLogxK
U2 - 10.1051/epjconf/201714006019
DO - 10.1051/epjconf/201714006019
M3 - Conference article
AN - SCOPUS:85024101304
SN - 2100-014X
VL - 140
JO - EPJ Web of Conferences
JF - EPJ Web of Conferences
M1 - 06019
T2 - 8th International Conference on Micromechanics on Granular Media
Y2 - 3 July 2017 through 7 July 2017
ER -