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Numerical modelling of phase change material melting process embedded in porous media: Effect of heat storage size

Talebizadeh Sardari, Pouyan; Walker, Gavin S; Gillott, Mark; Grant, David; Giddings, Donald

Authors

Gavin S Walker

MARK GILLOTT MARK.GILLOTT@NOTTINGHAM.AC.UK
Professor of Sustainable Building Design

DAVID GRANT DAVID.GRANT@NOTTINGHAM.AC.UK
Professor of Materials Science



Abstract

The aim of this paper is to study the influence of enclosure size in latent heat thermal energy storage systems embedded in a porous medium for domestic usage of latent heat thermal energy storage heat exchangers. A 2-D rectangular enclosure is considered as the computational domain to study the heat transfer improvement for a phase change material embedded in a copper foam considering a constant heat flux from the bottom surface. Different dimensions of the composite system are examined compared with a system without a porous medium. The thermal non-equilibrium model with enthalpy-porosity method is employed for the effects of porous medium and phase change in the governing equations, respectively. The phase change material liquid fraction, temperature, velocity, stream lines and the rate of heat transfer are studied. The presence of a porous medium increases the heat transfer significantly, but the improvement in melting performance is strongly related to the system's dimensions. For the dimensions of 200 × 100 mm (W × H), the melting time of porous-phase change material with the porosity of 95% is reduced by 17% compared with phase change material-only system. For the same storage volume and total amount of thermal energy added, the melting time is lower for the system with a lower height, especially for the phase change material-only system due to a higher area of the input heat. The non-dimensional analysis results in curve-fitting correlations between the liquid fraction and Fo.Ste.Ra−0.02 for rectangular latent heat thermal energy storage systems for both phase change material-only and composite-phase change material systems within the parameter range of 1.16 less than less than Lf less than 1 and 0 less than Fo.Ste.Ra−0.02 less than 0.57. Over a range of system's volume, heat flux and surface area of the input heat flux, the benefit of composite phase change material is variable and, in some cases, is negligible compared with the phase change material-only system.

Citation

Talebizadeh Sardari, P., Walker, G. S., Gillott, M., Grant, D., & Giddings, D. (2019). Numerical modelling of phase change material melting process embedded in porous media: Effect of heat storage size. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 1-19. https://doi.org/10.1177/0957650919862974

Journal Article Type Article
Acceptance Date Jun 20, 2019
Online Publication Date Jul 18, 2019
Publication Date Jul 18, 2019
Deposit Date Aug 3, 2019
Publicly Available Date Mar 28, 2024
Journal Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy
Print ISSN 0957-6509
Electronic ISSN 2041-2967
Publisher SAGE Publications
Peer Reviewed Peer Reviewed
Pages 1-19
DOI https://doi.org/10.1177/0957650919862974
Keywords Phase change material, porous media, natural convection, latent heat thermal energy storage system, melting process
Public URL https://nottingham-repository.worktribe.com/output/2383773
Publisher URL https://journals.sagepub.com/doi/10.1177/0957650919862974

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