Thermal cycling testing of Zn–Mg–Al eutectic metal alloys as potential high-temperature phase change materials for latent heat storage

This article presents the thermal stability testing results of five high-temperature phase change materials for their potential use in latent thermal energy storage systems. The tested materials are eutectic metal alloys [Zn 84 Al 8.7 Mg 7.3 , Zn 88.7 Al 11.3 , Zn 92.2 Mg 7.8 , Zn 72 Mg 28 and Mg 70...

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Bibliographic Details
Published in:Journal of thermal analysis and calorimetry 2017-08, Vol.129 (2), p.885-894
Main Authors: Risueño, E., Gil, A., Rodríguez-Aseguinolaza, J., Tello, M., Faik, A., D’Aguanno, B.
Format: Article
Language:English
Subjects:
Alloy systems
Alloys
Aluminum base alloys
Analysis
Analytical Chemistry
Chemistry
Chemistry and Materials Science
Cycles
Energy (Physics)
Energy consumption
Energy storage
Enthalpy
Eutectic temperature
Heat
Heat storage
Inorganic Chemistry
Latent heat
Magnesium base alloys
Materials selection
Measurement Science and Instrumentation
Melting
Metals (Materials)
Phase change materials
Physical Chemistry
Polymer Sciences
Product development
Solidification
Specialty metals industry
Storage capacity
Thermal cycling
Thermal cycling tests
Thermal energy
Thermal stability
Zinc
Zinc compounds
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Summary:This article presents the thermal stability testing results of five high-temperature phase change materials for their potential use in latent thermal energy storage systems. The tested materials are eutectic metal alloys [Zn 84 Al 8.7 Mg 7.3 , Zn 88.7 Al 11.3 , Zn 92.2 Mg 7.8 , Zn 72 Mg 28 and Mg 70 Zn 24.9 Al 5.1 (at.%)] with phase change temperatures in the range of 340–380 °C. The five candidates have been selected not only for their adequate melting temperature and high fusion enthalpy, but also for the availability and appropriate costs [2–3 $/kg (Rodríguez-Aseguinolaza in J Therm Anal Calorim 117:93–99, 2014 )] of Zn, Al, and Mg primary metals. As it is well known and demonstrated in previous works, the use of metal alloys presents noticeable benefits on the TES solutions based on their implementation. The particular advantages introduced by the Zn–Mg–Al system in terms of maximization of the storage capacity and appropriate operation temperature justify a deeper analysis of these alloys, previously studied, for a complete thermal performance. In this work, with the aim of reproducing a realistic thermal cycling behaviour in real heat storage applications, the selected candidates have been subjected to short- and long-term thermal cycling tests by 100 and 500 melting/solidification cycles, respectively. These experiments permitted to detect any potential evolution of the thermodynamic and structural properties of the investigated materials that could be sign of an undesirable chemical decomposition or phase segregation. As a conclusion, the Zn 84 Al 8.7 Mg 7.3 , Zn 88.7 Al 11.3 , Mg 72 Zn 28 and Mg 70 Zn 24.9 Al 5.1 alloys have been identified as very promising latent heat storage materials due to their long-term thermal stability.
ISSN:1388-6150
1588-2926
DOI:10.1007/s10973-017-6261-0