Moeini Sedeh, M. and Khodadadi, J.M. (2013) Thermal Conductivity Improvement of Phase Change Materials/Graphite Foam Composites. Carbon, 60, 117-128. - References

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Moeini Sedeh, M. and Khodadadi, J.M. (2013) Thermal Conductivity Improvement of Phase Change Materials/Graphite Foam Composites. Carbon, 60, 117-128. http://dx.doi.org/10.1016/j.carbon.2013.04.004

has been cited by the following article:

TITLE: A Modified Kelvin Model for Thermal Performance Simulation of High Mechanical Property Open-Cell Metal Foams

AUTHORS: Chuan Zhang, Feng Zhu, Houssem Badreddine, Xiaolu Gong

KEYWORDS: Simulation, Metal Foam, Phase Change Materials (PCMs), Melting, Heat Transfer

JOURNAL NAME: Journal of Materials Science and Chemical Engineering, Vol.3 No.7, July 1, 2015

ABSTRACT: This paper proposes a modified Kelvin model for high mechanical property open-cell metal foams and investigates its application in thermal simulations. The thermal conductivity is simulated based on the steady state method and the results are consistent with experimental values. The melting process of phase change materials (PCMs) in Kelvin model and its modified model is numerically investigated under a temperature constant heat resource. By detecting the temperature variations, it shows that the metal foam greatly improves the heat transfer in energy storage systems. Besides, the comparison of the melting process in two foam models indicates that the systems based on high mechanical property metal foams have a shorter melting time. The melting process of paraffin in modified Kelvin metal foam models with three different porosities (65%, 70% and 75%) are numerically analyzed and compared.