Experimental Comparison of Innovative Composite Sorbents for Space Heating and Domestic Hot Water Storage

In this study, the development and comparative characterization of different composite sorbents for thermal energy storage applications is reported. Two different applications were targeted, namely, low-temperature space heating (SH) and domestic hot water (DHW) provision. From a literature analysis, the most promising hygroscopic salts were selected for these conditions, being LiCl for SH and LiBr for DHW. Furthermore, two mesoporous silica gel matrixes and a macroporous vermiculite were acquired to prepare the composites. A complete characterization was performed by investigating the porous structure of the composites before and after impregnation, through N-2 physisorption, as well as checking the phase composition of the composites at different temperatures through X-ray powder diffraction (XRD) analysis. Furthermore, sorption equilibrium curves were measured in water vapor atmosphere to evaluate the adsorption capacity of the samples and a detailed calorimetric analysis was carried out to evaluate the reaction evolution under real operating conditions as well as the sorption heat of each sample. The results demonstrated a slower reaction kinetic in the vermiculite-based composites, due to the larger size of salt grains embedded in the pores, while promising volumetric storage densities of 0.7 GJ/m(3) and 0.4 GJ/m(3) in silica gel-based composites were achieved for SH and DHW applications, respectively.

Automated summary

This study reports the development and comparative characterization of different composite sorbents for thermal energy storage applications, targeting low-temperature space heating and domestic hot water provision. Promising results were achieved with silica gel-based composites for both applications, demonstrating higher volumetric storage densities.