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Heat transfer to a gas from densely packed beds of monodisperse spherical particles

Abstract

Particle resolved direct numerical simulation (PR-DNS) has emerged as a promising method to improve gas-particle heat transfer closure models. To date, this method has been applied in random and regular particle assemblies at comparably high void fractions. This paper presents a new methodology for deriving heat transfer correlations from PR-DNS of very dense particle packings relevant for packed bed applications. First particle packings were generated using the discrete element method (DEM). After geometric modifications in regions of close particle-particle proximity, a fine mesh with low cell skewness was created for PR-DNS. Grid independence and the effect of the geometry modification were thoroughly investigated. It was also established that steady state simulations are accurate for PR-DNS in this case. Simulations carried out in different assemblies of ∼100 particles showed significant variation of local transfer rates, implying that it is important to specify a confidence interval when reporting correlations derived from PR-DNS. A newly developed Nusselt number correlation predicts values in the lower range of predictions from literature correlations. This implies that the use of the currently available correlations may over-predict heat transfer in densely packed beds.

Category

Academic article

Client

  • EU / 604656
  • Sigma2 / NN1008K

Language

English

Author(s)

  • Arpit Singhal
  • Schalk Cloete
  • Stefan Radl
  • Rosa Quinta-Ferreira
  • Shahriar Amini

Affiliation

  • Norwegian University of Science and Technology
  • University of Coimbra
  • SINTEF Industry / Process Technology
  • Graz University of Technology

Year

2017

Published in

Chemical Engineering Journal

ISSN

1385-8947

Publisher

Elsevier

Volume

314

Page(s)

27 - 37

View this publication at Cristin