Self-assembly fabrication of GO/TiO2@paraffin microcapsules for enhancement of thermal energy storage

To increase the thermal energy utilization rate of phase change materials (PCMs), an efficient composite structure was devised by integrating graphene oxide (GO) nanosheets and the microencapsulated paraffin with TiO2 shell. A collection of GO/TiO2@paraffin microcapsules was prepared by interfacial...

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Bibliographic Details
Published in:Powder technology 2021-06, Vol.385, p.546-556
Main Authors: Ji, Wei, Cheng, Xiaomin, Chen, Sihong, Wang, Xiuli, Li, Yuanyuan
Format: Article
Language:English
Subjects:
Chemical composition
Composite materials
Composite structures
Condensates
Condensation polymerization
Energy storage
Energy utilization
Enthalpy
Fabrication
Graphene
Graphene oxide nanosheets
Heat conductivity
Heat storage
Heat transfer
Hydrogen bonding
Hydrogen bonds
Latent heat
Low temperature
Microcapsule composites
Microcapsules
Morphology
Nanostructure
Paraffin
Paraffins
Phase change materials
Self-assembly
Sol-gel processes
Spherical shells
Thermal conductivity
Thermal energy
Thermal properties
Thermal utilization
Thermodynamic properties
Titanium dioxide
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Summary:To increase the thermal energy utilization rate of phase change materials (PCMs), an efficient composite structure was devised by integrating graphene oxide (GO) nanosheets and the microencapsulated paraffin with TiO2 shell. A collection of GO/TiO2@paraffin microcapsules was prepared by interfacial condensation polymerization in a sol-gel system, and the microstructure, chemical composition, and thermal properties were studied. Herein, the composite appeared a spherical core-shell structural morphology, and the GO nanosheets self-assemble on the surface of the microcapsules by sharing electrons and hydrogen bonds. The latent heat of microcapsules is more than 160.75 J/g, and the thermal conductivity enhanced from 0.195 to 0.297 W·m−1·K−1 thanks to the highly thermally conductive of GO nanosheets. In addition, the thermal conductivity is almost doubled compared to paraffin and preserving a high phase change enthalpy. It can be observed that most GO nanosheets were dispersed evenly on the surface of TiO2@paraffin microcapsules without obvious agglomeration, while a series of results indicated that paraffin, TiO2, and GO were physically combined. The prepared GO/TiO2@paraffin microcapsules composite PCMs with high thermal conductivity and great energy storage density is widely promising for low temperature heat storage. At the same time, this work provides a novel idea for the application of carbon material in the field of thermal energy storage microcapsule composite PCMs modification. [Display omitted] •The sol-gel method is used to prepare high-efficiency heat storage microcapsules.•The thermal conductivity of the microcapsules has been doubled to 0.291 W·m−1·K−1.•Encapsulation efficiency exceeds 80%, which can effectively prevent leakage.•After hundreds of cycles, the microcapsules are still stable and efficient.
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2021.03.020