Integrating phase change materials (PCMs), which store thermal energy as latent heat, into renewable energy production is an efficient way to harness solar energy. Thereby, the aim of this work is to develop convenient and efficient method to prepare a bio‐composite phase change materials (BCPCMs) that are eco‐friendly and cheap. The polyethylene glycol (PEG) with large latent heat was used as PCM, eggshell powder (ES) as an energy storage material (bio‐energy resources/bio‐waste is converted into useful energy storage material), the low‐density polyethylene (PE) performed as the supporting material and powder graphite (G) was the additives for improving the thermal conductivity. According to thermal gravimetric analysis (TGA), the use of ES and G improved the thermal stability of BCPCM. On the other hand, the results of the differential calorimetric analysis (DSC) showed that BCPCM6 with the addition of 5 wt% of graphite filler in the mixture PEG/PE/ES (70/20/5 wt%) provides excellent thermal stability and high energy storage density per unit mass. In light of its high latent heat storage capacity of 120.1 J/g as well as its ability to prevent PEG exudation, BCPCM ensures higher thermal conductivity and shape stability during phase transition than ordinary PCM. Significant enhancement in melting‐solidification time shows an improvement in Thermal Energy Storage (TES) response time to the demand by adding ES and G respectively to the PCM. Based on the obtained results, the BCPCM as a potential candidate for an application in buildings of hot and dry climates.Highlights
Shape‐stabilized BCPCMs were prepared by blending and impregnating method.
The BCPCM combines a high storage capacity and high heat propagation rate.
BCPCM6 provides excellent thermal stability and high energy storage density.
Enhancement in melting‐solidification time by adding ES and G to the PCM.
BCPCM as a candidate for an application in buildings of hot and dry climates.