Effect of Different Production Processes on Metallic Composite Phase Change Materials for Thermal Energy Storage

Chiara Confalonieri; Elisabetta Gariboldi

doi:10.4028/www.scientific.net/MSF.1016.359

Paper Titles

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Change of Microstructure and Analysis of Fracture of the Ti-50.8 at.% Ni Alloy in the Ultrafine-Grained State after Multiple Martensitic Transformations with a Large Number of Cycles
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Effect of Different Production Processes on Metallic Composite Phase Change Materials for Thermal Energy Storage
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HomeMaterials Science ForumMaterials Science Forum Vol. 1016Effect of Different Production Processes on...

Effect of Different Production Processes on Metallic Composite Phase Change Materials for Thermal Energy Storage

Abstract:

Phase Change Materials (PCMs) can be applied in Thermal Energy Storage and Thermal Management systems, exploiting the storage and release of latent heat associated to a phase transition. Among them, metallic PCMs can be used at medium and high temperatures (i.e. above 150°C), storing higher heat per unit volume at higher temperatures with respect to the most widely investigated polymeric and salt-based PCMs. Miscibility Gap Alloys (MGAs) can be used to obtain multiple-phase mixtures in which the active phase (the actual PCM) is mixed to a second, high-melting temperature phase, with negligible interaction between them. These can actually be considered as fully metallic composite materials specifically developed for thermal management. Suitable microstructures can prevent leakage of active phase when the solid-liquid transition occurs, resulting in a form-stable PCM (FS-PCM). However, obtaining these microstructures it is not trivial. The present study focuses on a solid-liquid FS-PCM consisting of a ‘classical’ fully metallic FS-PCM, an Al-Sn based MGAs produced by powder metallurgy. The goal was to evaluate the effect of different production processes on thermal and mechanical behaviour of the PCM. Particularly, powder metallurgy routes including both simple mixing and ball milling were compared and further combined. Moreover, several compression and sintering conditions were considered, also substituting Al powders with Al-alloy powders, in order to optimize the material microstructures in view of suitable thermal and mechanical properties. Finally, the casting route with a rapid solidification approach was investigated for the same alloy.

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Periodical:

Materials Science Forum (Volume 1016)

Pages:

359-365

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.1016.359

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Online since:

January 2021

Authors:

Chiara Confalonieri*, Elisabetta Gariboldi

Keywords:

Al2618-Sn, Al-Sn, Metallic Composite Phase Change Materials, Powder Metallurgy, Rapid Solidification, Thermal Energy Storage

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