Solar salt encapsulated into 3D printed activated carbon/alumina supports for thermal energy storage applications

Abstract

The encapsulation of phase change materials (PCMs) into additive manufactured porous supports is attracting great interest for developing thermal energy storage (TES) materials with improved energy performance. Here, highly porous (86%) self-supported 3D activated carbon/alumina supports are fabricated by direct ink writing (DIW) and, then, infiltrated with solar salt, a highly corrosive PCM with a melting temperature around 220 ºC commonly employed in concentrated solar power plants. This novel, robust, chemically compatible, and lightweight infiltrated 3DTES exhibits good thermal energy storage efficiency (70%) and thermal stability, high energy storage density (381 J·g-1), and avoids the liquid leakage of the molten salt. Besides, the 3D activated carbon/alumina support promotes a better ability to absorb solar energy (79%) and enhances the thermal conductivity of the solar salt (up to 64%). These results validate the use of DIW for manufacturing innovative TES with an enhanced energy storage behaviour.