Zinc-rich eutectic alloys for high energy density latent heat storage applications

The interest on latent heat storage (LHS) materials has experienced a remarkable increase during last years. The main advantage of PCM materials is their higher energy density compared to sensible materials one. In this article the synthesis process and structural and thermophysical characterization...

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Bibliographic Details
Published in:Journal of alloys and compounds 2017-05, Vol.705, p.714-721
Main Authors: Risueño, E., Faik, A., Gil, A., Rodríguez-Aseguinolaza, J., Tello, M., D'Aguanno, B.
Format: Article
Language:English
Subjects:
Alloys
Energy storage
Eutectic alloys
Eutectic metallic alloys
Eutectic temperature
Eutectics
Flux density
Heat conductivity
Heat of fusion
Heat storage
Heat transfer
Inorganic salts
Latent heat
Latent heat storage
Melting
Phase change material (PCM)
Physical properties
Solid state
Structural analysis
Structural characterization
Synthesis
Thermal conductivity
Thermal energy storage
Thermophysical properties
Zinc base alloys
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Summary:The interest on latent heat storage (LHS) materials has experienced a remarkable increase during last years. The main advantage of PCM materials is their higher energy density compared to sensible materials one. In this article the synthesis process and structural and thermophysical characterization of Zn84Al8.7Mg7.3, Zn88.7Al11.3 and Zn92.2Mg7.8 (at.%) eutectic metallic alloys have been performed in order to evaluate their potentiality as PCMs for LHS applications. Their correct synthesis process has been proved by the structural study and their melting/solidification temperatures, heat of fusion, specific heat and thermal conductivity have been investigated. The results show melting temperatures of 344 °C, 382 °C and 371 °C and heat of fusion of around 132 J g−1, 118 J g−1 and 106 J g−1 for Zn84Al8.7Mg7.3, Zn88.7Al11.3 and Zn92.2Mg7.8, respectively. The obtained energy densities for the investigated alloys are almost two times higher than the ones for similar metallic PCM reported in literature. On the other hand, the measured thermal conductivities are ranging in the solid state from 66 to 139 W m−1 K−1 and in the liquid state, from 33 to 58 W m−1 K−1, which represent the main advantage of these PCM candidates when are compared to the most studied ones such as the inorganic salts. The proposed storage materials can be a highly suitable solution in TES applications when compact system, high power levels and very fast thermal responses are required. •High conductivity metallic PCMs were synthetized and investigated for TES application.•The structural properties of three eutectic metal alloys were investigated.•Their relevant thermophysical properties in thermal energy storage field were carried out.•The high energy densities of Zn- rich metal alloys have been highlighted.•Very promising PCMs in TES applications, where a compact system and fast thermal response are required, have been identified.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2017.02.173