Abstract
This paper presents a numerical investigation of thermal response of mortar panels, incorporating macro-encapsulated paraffin in different forms. Two types of macro capsules were fabricated and tested in this study using an instrumented hot plate device. The experimental results show that macro encapsulated paraffin reduced the temperature and increased time lag in the mortar panels due to the latent heat capacity of paraffin. Finite element models adopting the effective heat capacity method to model phase change effects were able to capture the overall thermal response of panels incorporated with paraffin well. Then, a parametric study was conducted using the validated finite element (FE) modelling technique to investigate the effects of different forms of macro capsules, the quantity of paraffin and the position of macro capsules. It was found that the tube and sphere macro capsules showed similar thermal responses, while the plate shaped capsules may cause a non-uniform temperature distribution in mortar panels. The quantity and position of paraffin have significant effects on the thermal response of the mortal panels. A higher paraffin content results in a significantly longer temperature lag and a lower temperature during the phase transition of paraffin. Furthermore, placing the paraffin away from the heating face can cause a longer temperature lag on the other face, which is desirable for building façade applications.
Highlights
Phase change materials (PCMs) are combined thermal storage materials that can store and release energy in the form of heat [1]
This paper presented numerical investigations of the thermal response of mortar panels incorporating paraffin encapsulated in different forms of macro capsules
The finite element (FE) models were first validated against the experimental results of mortar panels incorporated with the two forms of macro capsules fabricated in this study
Summary
Phase change materials (PCMs) are combined (sensible and latent) thermal storage materials that can store and release energy in the form of heat [1]. Macro capsules should be made of materials with good thermal conductivity for an effective heat transfer to a PCM. Silva [14] investigated effects of a macro encapsulated PCM on the thermal behavior of hollow brick masonry walls. Numerical simulations have been applied to investigate the heat transfer within cement concrete or mortar containing a PCM. Based on the literature review, it can be concluded that relatively few studies have been conducted to determine effects of different forms of macro capsules on thermal response of mortar panels. A parametric study was performed to provide a better understanding of the effects of macro encapsulated PCMs on the thermal response of mortar panels
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