Enhanced thermal properties of novel shape-stabilized PEG composite phase change materials with radial mesoporous silica sphere for thermal energy storage.

Xin Min,Zhaohui Huang,Ruilong Wen,Yan’Gai Liu,Xiaowen Wu,Tingting Qian,Yaoting Huang,Minghao Fang

doi:10.1038/srep12964

Abstract

Radial mesoporous silica (RMS) sphere was tailor-made for further applications in producing shape-stabilized composite phase change materials (ss-CPCMs) through a facile self-assembly process using CTAB as the main template and TEOS as SiO2 precursor. Novel ss-CPCMs composed of polyethylene glycol (PEG) and RMS were prepared through vacuum impregnating method. Various techniques were employed to characterize the structural and thermal properties of the ss-CPCMs. The DSC results indicated that the PEG/RMS ss-CPCM was a promising candidate for building thermal energy storage applications due to its large latent heat, suitable phase change temperature, good thermal reliability, as well as the excellent chemical compatibility and thermal stability. Importantly, the possible formation mechanisms of both RMS sphere and PEG/RMS composite have also been proposed. The results also indicated that the properties of the PEG/RMS ss-CPCMs are influenced by the adsorption limitation of the PEG molecule from RMS sphere with mesoporous structure and the effect of RMS, as the impurities, on the perfect crystallization of PEG.

Highlights

Industry is the driving engine of economic development, and energy must be seen as the fuel for this engine
A new polyethylene glycol (PEG)/SiO2 shape-stabilized composite phase change material (ss-CPCM) based on radial mesoporous silica (RMS) with enhanced thermal properties for thermal energy storage was prepared via vacuum impregnation operation
The microstructure of templates stemming from CTAB is one key for the texture properties of the resultant mesoporous materials[36]

Summary

Introduction

Industry is the driving engine of economic development, and energy must be seen as the fuel for this engine. PEG based composite PCMs stabilized by mesoporous matrices are promising candidates for high performance heat storage systems.

Results

Conclusion