Abstract

Mg-based alloys are potential high temperature phase change materials for thermal energy storage due to their high melting enthalpy, high thermal conductivity and excellent compatibility with Fe-based containment materials. This work mainly focuses on studying the microstructure and thermophysical characterization of Mg–Bi–Sn alloys phase change materials with 4 different components and their thermal energy storage performance. The experimental results show that the Mg–33Bi–17Sn, Mg–39Bi–17Sn and Mg–45Bi–17Sn alloys mainly consist of primary α-Mg phase and α-Mg + Mg2Sn + Mg3Bi2 eutectic structure, and the Mg–33Bi–23Sn alloy mainly consist of primary α-Mg phase, primary Mg2Sn + Mg3Bi2 phases and α-Mg + Mg2Sn + Mg3Bi2 eutectic structure. Their melting enthalpies are respectively 18.5 J/g, 168.8 J/g, 106.3 J/g and 140.3 J/g, while their melting temperatures are about 515 °C–525 °C. As from the results, the Mg–39Bi–17Sn alloy obtains the highest melting enthalpy, which attributes to its higher proportion of eutectic α-Mg + Mg2Sn + Mg3Bi2 structure. However, the Mg–45Bi–17Sn alloy shows the highest thermal conductivity. In addition, the melting point of Mg–39Bi–17Sn alloys increase by about 1.8 °C, and the melting enthalpy decreases by about 4.2% after 300 thermal cycling. Based on all results, the Mg–39Bi–17Sn alloy shows with great thermalphsycial performance and is expected to be used as thermal energy storage material.

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