Thermal conductivity evolution of a compressed expanded natural graphite – Phase change material composite after thermal cycling

•Thermal conductivities of CENG-PCM identical on liquid and solid phase in spite of the expansion of the plate.•Thermal conductivities and latent heat of CENG-PCM constant after 1500 melting-cooling cycles.•Delamination and deformation of CENG-PCM slab after thermal cycling.•Migration of PCM at the...

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Veröffentlicht in:	Thermal science and engineering progress 2022-02, Vol.28, p.101047, Article 101047
Hauptverfasser:	Jadal, Mariam, Soto, Jérôme, Delaunay, Didier
Format:	Artikel
Sprache:	eng
Schlagworte:	Expanded natural graphite Latent heat storage Mechanics Phase change material Physics Thermal characterisation Thermal conductivity Thermal cycling Thermics
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container_title	Thermal science and engineering progress
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creator	Jadal, Mariam Soto, Jérôme Delaunay, Didier
description	•Thermal conductivities of CENG-PCM identical on liquid and solid phase in spite of the expansion of the plate.•Thermal conductivities and latent heat of CENG-PCM constant after 1500 melting-cooling cycles.•Delamination and deformation of CENG-PCM slab after thermal cycling.•Migration of PCM at the external surface of the CENG composite after a few thermal cycles. Compressed Expanded Natural Graphite (CENG) impregnated with Phase Change Material (PCM) is an interesting material for latent heat storage application requiring a high heat transfer rate. This composite material, that has orthotropic properties, undergoes expansion while the PCM changes phase that might affect its thermal properties and its mechanical integrity. In order to assess this possible evolution, the CENG-PCM thermal conductivities in the two principal directions have been measured before and after a 1500 thermal cycling test. The thermal characterisation was performed using two methods: a classic hot guarded plate method and a more originally inverse method. The results show no significant change of the thermal conductivity values after ageing cycles in spite of the appearance of cracks in the planar direction of the composite. We can conclude that the delamination of the CENG was not sufficient to affect the thermal conductivities. In addition, a DSC analysis shows that the latent heat is also almost unchanged after the thermal cycling.
doi_str_mv	10.1016/j.tsep.2021.101047
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Compressed Expanded Natural Graphite (CENG) impregnated with Phase Change Material (PCM) is an interesting material for latent heat storage application requiring a high heat transfer rate. This composite material, that has orthotropic properties, undergoes expansion while the PCM changes phase that might affect its thermal properties and its mechanical integrity. In order to assess this possible evolution, the CENG-PCM thermal conductivities in the two principal directions have been measured before and after a 1500 thermal cycling test. The thermal characterisation was performed using two methods: a classic hot guarded plate method and a more originally inverse method. The results show no significant change of the thermal conductivity values after ageing cycles in spite of the appearance of cracks in the planar direction of the composite. We can conclude that the delamination of the CENG was not sufficient to affect the thermal conductivities. 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Compressed Expanded Natural Graphite (CENG) impregnated with Phase Change Material (PCM) is an interesting material for latent heat storage application requiring a high heat transfer rate. This composite material, that has orthotropic properties, undergoes expansion while the PCM changes phase that might affect its thermal properties and its mechanical integrity. In order to assess this possible evolution, the CENG-PCM thermal conductivities in the two principal directions have been measured before and after a 1500 thermal cycling test. The thermal characterisation was performed using two methods: a classic hot guarded plate method and a more originally inverse method. The results show no significant change of the thermal conductivity values after ageing cycles in spite of the appearance of cracks in the planar direction of the composite. We can conclude that the delamination of the CENG was not sufficient to affect the thermal conductivities. 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subjects	Expanded natural graphite Latent heat storage Mechanics Phase change material Physics Thermal characterisation Thermal conductivity Thermal cycling Thermics
title	Thermal conductivity evolution of a compressed expanded natural graphite – Phase change material composite after thermal cycling
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