Abstract
Aerated concrete (AC) was incorporated with micro-encapsulated phase change materials (PCMs) to form a novel PCM-composite AC with improved thermal storage capacity. RT25 paraffin was selected as the PCM and the composite materials were prepared by adding micro-encapsulated paraffin as an ingredient at various loadings. The effective thermal conductivity of the composite samples was measured at both 17 ºC and 35 ºC, while the paraffin was in solid and liquid phases, respectively. The volumetric heat capacity of the composites were also measured. Results showed that both the thermal conductivity and volumetric heat capacity increase upon adding the micro-encapsulated paraffin. However, they were found to decrease when further increase the paraffin loading. The maximum thermal conductivity and volumetric heat capacity were enhanced by approximately 35% and 30% when the paraffin loadings were 1% wt. and 3% wt., respectively. Since the increase of thermal conductivity leads to the deterioration of the thermal insulation performance, the composite samples with 3% wt. micro-encapsulated paraffin with lower thermal conductivity but the highest volumetric heat capacity was exhibited to be more appropriate.
Highlights
Embedding phase change materials (PCMs) in porous building materials has been proposed as a passive means to improve the thermal mass of building envelopes and reduce building energy consumption [1,2,3]
The photographic and microscopic images one of the composite samples with 3% wt. mass fraction of micro-encapsulated paraffin are shown in Fig. 1, indicating that the micro paraffin capsules with various sizes, which are marked with red circles, are nearly distributed
The composite samples with 3% wt. micro-encapsulated paraffin with lower thermal conductivity but the highest volumetric heat capacity was exhibited to be more appropriate to be utilized in building envelopes
Summary
Embedding phase change materials (PCMs) in porous building materials has been proposed as a passive means to improve the thermal mass of building envelopes and reduce building energy consumption [1,2,3]. The third is incorporating micro-encapsulated PCM at the time of mixing [9]. With high porosity and mechanical strength, AC is proved to be a potential candidate to integrate with PCM, and the incorporation of PCM into AC can significantly improve the thermal energy storage capacity of the composite material [13]. In previous researches, there is a lack of investigation on AC samples integrated with PCM. Their thermal conductivity will likely increase because the thermal conductivity of paraffin is higher than that of air, leading to deterioration of the thermal insulation performance. The effects of embedding microencapsulated paraffin inclusions on the thermal conductivity and heat capacity of PCM-composites were quantified. The results in this work can be used to guide the design of PCM-composite AC for energy efficient buildings
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