Metallic Composites as Form-Stable Phase Change Alloys

Elisabetta Gariboldi; Maxime Perrin

doi:10.4028/www.scientific.net/MSF.941.1966

Paper Titles

Effect of Slit Shape on Joinability of Zircaloy - SiC/SiC Composite Tube Joint with Titanium Powder
p.1944

Effect of Processing Route on Microstructure and Mechanical Properties of a Ti-3Al-2.5V/TiB Composite
p.1950

Development of Tool Steel Matrix Composites with High Thermal Conductivity
p.1956

Tensile Fracture of TiB Whisker Reinforced Ti Alloy Matrix Composites
p.1961

Metallic Composites as Form-Stable Phase Change Alloys
p.1966

Structural Stability of Hafnia-Based Materials at Ultra-High Temperature
p.1972

Joining of AlN and Al with Compositional Graded Layer by Centrifugal Mixed-Powder Method
p.1978

Tribological Properties of Aluminum and Silicon Borides at High Temperatures
p.1984

Spark Plasma Sintering of High-Energy Ball-Milled ZrB₂ and HfB₂ Powders with 20vol% SiC
p.1990

HomeMaterials Science ForumMaterials Science Forum Vol. 941Metallic Composites as Form-Stable Phase Change...

Metallic Composites as Form-Stable Phase Change Alloys

Abstract:

Metallic materials can be used as Phase Change Materials for thermal storage, since they absorb/release relatively high latent heat for solid/liquid transformation during the heating/cooling parts of thermal cycles including their melting/solidifying range. The active PCM phase can also be mixed to another phase, melting at higher temperature, forming metallic composites, also referred in literature as Phase Change Alloys. To be considered as ‘form stable’ material, leakage of the molten active phase must be prevented. The present contribution focuses on the processing/microstructure/ properties correlations of PCAs based on the simple Al-Sn system, with activation temperature of about 230°C. They were produced by mixing Al powders to two different Sn powders adopting different compaction techniques and heat treatments, and cycled to simulate service. Their microstructure, thermal and mechanical response in as-manufactured and after service revealed that, amongst those experimentally available, PCA produced by compaction at room temperature inhomogeneous a blend of the powders is the optimal procedure, with good absorbed/released enthalpy and thermal stability after service.