TY - JOUR
T1 - ORIENTED THERMAL CONDUCTIVE COMPOSITE PHASE-CHANGE MATERIAL ENABLED BY ORIENTED EXPANDABLE GRAPHITE SKELETON FOR HEAT STORAGE
AU - Xu, Zhiqi
AU - Zhang, Shaoliang
AU - Shen, Yongliang
AU - Liu, Shuli
N1 - Publisher Copyright:
© 2024 International Committee of the SCMT conferences. All rights reserved.
PY - 2024
Y1 - 2024
N2 - Commonly used PCMs have low thermal conductivity and high thermal resistance, which is not conducive to heat transfer, making it difficult for materials to quickly absorb and conduct heat. This study presents the fabrication and characterization of an oriented thermal conductive composite phase-change material (OTC-CPCM) using the vacuum adsorption method and compression-induced self-assembly method. Paraffin wax (PW), oriented worm expandable graphite (WEG), and high-purity graphite sheets (GS) were incorporated to form distinct layered structures perpendicular to the pressure direction, establishing stable thermal flow channels. The influence of WEG content on microstructure, thermal conductivity, and phase change characteristics was investigated. Results show that higher WEG content enhances the layered structure and thermal conductivity of the OTC-CPCM while reducing the supercooling degree during solid-state phase transition. Moreover, the OTC-CPCM exhibits excellent leak-proof performance, with cyclic stability increasing with higher WEG content. These findings demonstrate the potential of OTC-CPCM in thermal management, building energy conservation, and heat storage applications.
AB - Commonly used PCMs have low thermal conductivity and high thermal resistance, which is not conducive to heat transfer, making it difficult for materials to quickly absorb and conduct heat. This study presents the fabrication and characterization of an oriented thermal conductive composite phase-change material (OTC-CPCM) using the vacuum adsorption method and compression-induced self-assembly method. Paraffin wax (PW), oriented worm expandable graphite (WEG), and high-purity graphite sheets (GS) were incorporated to form distinct layered structures perpendicular to the pressure direction, establishing stable thermal flow channels. The influence of WEG content on microstructure, thermal conductivity, and phase change characteristics was investigated. Results show that higher WEG content enhances the layered structure and thermal conductivity of the OTC-CPCM while reducing the supercooling degree during solid-state phase transition. Moreover, the OTC-CPCM exhibits excellent leak-proof performance, with cyclic stability increasing with higher WEG content. These findings demonstrate the potential of OTC-CPCM in thermal management, building energy conservation, and heat storage applications.
KW - Composite Phase Chage Material
KW - Compression-induced Self-assembly
KW - Cyclic Stability
KW - Micro Morphology
KW - Thermal Storage Capacity
UR - https://www.scopus.com/pages/publications/105019643139
U2 - 10.18552/2024/SCMT/607
DO - 10.18552/2024/SCMT/607
M3 - Conference article
AN - SCOPUS:105019643139
SN - 2515-3048
JO - Sustainable Construction Materials and Technologies
JF - Sustainable Construction Materials and Technologies
T2 - 6th International Conference on Sustainable Construction Materials and Technologies, SCMT 2024
Y2 - 9 June 2024 through 14 June 2024
ER -