Simulations of melting in fluid-filled packed media due to forced convection with higher temperature

Simulations of melting in fluid-filled packed media due to forced convection with higher temperature

An original CFD-DEM method, named as CD-MELT, is developed to model the isothermal melting of a packed bed subjected to a forced convection with higher temperature. The formulation of CD-MELT allows a high degree of representation of the melting process. With specific melting parameters, the particl...

Full description

Saved in:
Bibliographic Details
Main Authors: Soon, Genevieve, Zhang, Hui, Yang, Chun, Law, Adrian Wing-Keung
Other Authors: School of Civil and Environmental Engineering
Format: Article
Language:English
Published: 2022
Subjects:
Engineering::Civil engineering
Discrete Element Method
Computational Fluid Dynamics
Online Access:https://hdl.handle.net/10356/155834
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
Description
Summary:An original CFD-DEM method, named as CD-MELT, is developed to model the isothermal melting of a packed bed subjected to a forced convection with higher temperature. The formulation of CD-MELT allows a high degree of representation of the melting process. With specific melting parameters, the particles in the packed bed undergo mass, diameter and temperature change individually, and the packed bed is reconfigured afterward through particles collision and contact. The phase changes are accounted for via source terms using a mass loss fraction, ranging from 0 (initial mass) to 1 (complete melting), which is introduced for the first time and differs from other existing models. The CD-MELT's predictions are compared with the results from an earlier experimental study on the melting of a single ice sphere as well as a packed bed of ice spheres due to a forced convection of warm water. The comparison is found to be satisfactory despite the use of a coarse mesh, and the computation run is stable despite the varying mesh-particle size ratio. Finally, the effects of spring constant and restitution coefficient in the particle collision model are further investigated for the case of a non-floating packed bed under forced convection. Recommendations are made on how their suitable values can be determined in future melting studies.

Similar Items