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Multiscale modelling of wall-to-bed heat transfer in fixed beds with non-spherical pellets: From particle-resolved CFD to pseudo-homogenous models

Elyas M. Moghaddam, E.A. Foumeny, Andrzej Stankiewicz, Johan T. Padding

2021Chemical Engineering Science40 citationsDOIOpen Access PDF

Abstract

We investigate forced convective heat transfer in packings of spheres, cylinders and Raschig rings, made of glass, steel and alumina, in relatively narrow tubes. A detailed comparison is made between resolved pellet-scale, azimuthally-averaged temperature profiles, and 2D-axially-dispersed pseudo-homogenous plug flow (2D-ADPF) predictions. The local temperature deviates significantly from azimuthally-averaged profiles, which in turn deviate from 2D-ADPF predictions. We show that the length dependency of effective heat transfer parameters is caused by thermal (non-)equilibrium between fluid and solid phases along the bed and not related to inadequate insulation of the calming section or the thermocouple’s cross or an under-developed velocity and thermal field at the bed inlet. The influence of pellet shape and thermal conductivity and tube-to-pellet diameter ratio on ker and hw are assessed. We conclude that the models of Specchia/Baldi/Gianetto/Sicardi for all flow regimes and of Martin/Nilles for the turbulent regime are recommended for practical use for spherical particles.

Topics & Concepts

PelletsComputational fluid dynamicsHeat transferParticle (ecology)MechanicsMaterials scienceMass transferThermodynamicsGeologyPhysicsComposite materialOceanographyHeat and Mass Transfer in Porous MediaGranular flow and fluidized bedsLattice Boltzmann Simulation Studies