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A two-stage sorption strategy to improve heat storage performance of salt/porous matrix composites

Wenjing Wei, Luxi Yang, Giulio Santori, Yongliang Li, Cher Hon Lau, Xianfeng Fan

2024Solar Energy10 citationsDOIOpen Access PDF

Abstract

• A two-stage adsorption strategy was proposed to prepare CSPM for heat storage. • Dynamics vapour sorption tests were conducted to prove the two-stage strategy. • The salts SrCl 2 /SrBr 2 acts as moisture pump and MOF acts as the water reservoir. • The composites present heat storage capacities up to 1526 J/g with good stability. Composites combining salt hydrates and porous matrix like metal–organic frameworks (MOFs) are used to enhance the performance of thermochemical storage materials. However, the mechanism for the enhancement and the strategy for the selection of salt hydrates and porous matrix are not clear. The heat storage performance is determined by water adsorption dynamics, capacity and their sorption energy of the single components. The single components (salts or matrix) normally have either fast water adsorption dynamics or high-water uptake capacity, but not both of them. In this study, we investigate the enhancement of adsorption in composite materials, and a novel strategy is then proposed to combine the advantages from adsorbents with higher adsorption dynamics at low water partial pressure with those with a high capacity at high water partial pressure to promote the water adsorption capacity and kinetics, hence efficient energy storage. Two types of composites have been used to demonstrate the two-stage strategy developed in this study, in which SrCl 2 and SrBr 2 are incorporated into MOF MIL-101(Cr) to enhance adsorption and heat storage. In these composites, SrCl 2 and SrBr 2 can be regarded as the moisture pumps, capturing water vapour from air to improve the adsorption dynamics, while MIL-101(Cr) with high adsorption capacity functions as a water reservoir to take the water accumulated by the salts. Through this two-stage design, the water sorption capacity of the composites is 2–3 times higher than the water uptake of either salts or MOF within 120 min. As SrCl 2 has a faster water adsorption kinetics than SrBr 2 , SrCl 2 /MIL-101(Cr) reaches an uptake of 0.73 g/g, however, the water sorption capacity of SrBr 2 /MIL-101(Cr) is 0.54 g/g. The composite samples also present good heat storage capacities of 1462 J/g for SrCl 2 /MIL-101(Cr) and 1526 J/g for SrBr 2 /MIL-101(Cr), and good cycling stability after 15 repeating adsorption/desorption cycles.

Topics & Concepts

SorptionMaterials scienceComposite materialPorosityMatrix (chemical analysis)Stage (stratigraphy)Salt (chemistry)Thermal energy storagePorous mediumChemical engineeringAdsorptionChemistryThermodynamicsOrganic chemistryBiologyPaleontologyEngineeringPhysicsAdsorption and Cooling SystemsPhase Change Materials ResearchHygrothermal properties of building materials
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