In Situ Encapsulation of Phase‐Change Thermal‐Storage Material using 3D Polymer‐Aided Cross‐Linked Porous Carbon

Phase‐change materials are of great interest in solving mismatch between energy supply and demand. However, the vulnerability of solid–liquid phase‐change materials to leakage during the phase‐change process limits their development and application in practice. Herein, the enhancement of the shape s...

Full description

Saved in:
Bibliographic Details
Published in:Advanced energy and sustainability research 2023-03, Vol.4 (3), p.n/a
Main Authors: Xiao, Tong, Liu, Qingyi, Lin, Yixuan, Lin, Tingyu, Zhao, Jiateng, Sun, Wenjie, Chen, Xiao, Liu, Changhui
Format: Article
Language:English
Subjects:
Alternative energy sources
Chemical reactions
Curing
Curing agents
Encapsulation
Energy consumption
Energy storage
Energy usage
Graphite
Heat conductivity
Latent heat
Leakage
Liquid phases
phase-change materials
Phenolic compounds
Phenolic resins
Phenols
Photothermal conversion
Polyethylene glycol
Polymers
Pores
Porous materials
Reagents
Renewable resources
Resins
shape stable
Temperature
Thermal conductivity
Thermal energy
thermal-energy storages
Three dimensional composites
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Phase‐change materials are of great interest in solving mismatch between energy supply and demand. However, the vulnerability of solid–liquid phase‐change materials to leakage during the phase‐change process limits their development and application in practice. Herein, the enhancement of the shape stability of phase‐change materials is achieved through an organic–inorganic composite. The mixture of phenolic resin and polyethylene glycol forms a homogeneous solution based on their excellent mutual solubility and is able to be adsorbed into the pores of the expanded graphite by means of a vacuum‐impregnation strategy. The 3D cross‐linked network structure of phenolic resin is formed within the pores of expanded graphite, enabling in situ encapsulation of polyethylene glycol. It is worth noting that the curing reaction of phenolic resin is able to be initiated by heating up without the addition of any curing agent and other auxiliary materials. A thermal conductivity enhancement of 20 times than that of polyethylene glycol is achieved along with a photothermal conversion efficiency of 63.72% and with a latent heat of 134.94 J g−1 without leakage. The mixture of phenolic resin and polyethylene glycol is adsorbed into the pores of the expanded graphite by means of a vacuum impregnation, after which the cross‐linking curing reaction of the phenolic resin is initiated by heating. The strategy eliminates inherently uneven and insufficient encapsulation of polyethylene glycol in the 3D cross‐linked network structure.
ISSN:2699-9412
2699-9412
DOI:10.1002/aesr.202200164