Air lime renders with microencapsulated phase change materials: Assessment of microstructural and thermal properties
Andrea Rubio‐Aguinaga, J.M. Fernandez-Alvarez, Í. Navarro-Blasco, J.I. Álvarez
Abstract
Microencapsulated phase change materials (PCMs) have been successfully integrated into air lime-based rendering mortars to enhance thermal properties, aiming to boost the thermal efficiency of the buildings in which are applied. Two microencapsulated PCMs, with melting points at 18℃ and 24℃, were seamlessly introduced into fresh rendering mortars in varying proportions (5 %, 10 %, and 20 % by weight of lime), in formulations that include different chemical additives, such as a superplasticizer (polycarboxylate ether) and an adhesion enhancer (starch-based additive). In some mixes, metakaolin (MK) was also added as a mineral admixture. Starch addition was seen to promote the formation of aragonite and vaterite (calcium carbonate polymorphs), facilitating the smooth integration of microcapsules within the lime matrix. Hotbox simulations with tested materials containing as low as 0.01–0.04 g of PCM per gram of dry mortar, yielded outstanding energy efficiency values (822.4 and 732.8 kJ/m 2 , respectively, for PCMs with melting points at 18℃ and 24℃). Temperature attenuations of up to 6.1°C during the heating stage and up to 3.9°C during the cooling stages were observed. This outcome not only emphasizes the potential for enhancing thermal efficiency through PCM incorporation into air lime renders but also hints at a remarkable future for energy-efficient construction materials. • Complete integration of PCM microcapsules was observed within lime matrix. • Promotion of aragonite and vaterite crystallization was found to be starch-mediated. • PCM-bearing lime mortars demonstrated effective thermal regulation. • Hotbox simulations showed high efficiency with low PCM content (0.01–0.04 g). • Temperature drops of up to 6.1°C were observed in heating; 3.9°C in cooling.