Your search keyword '"He, Fangfang"' showing total 2 results

1. Supercooling degree decrease of barium hydroxide octahydrate employing 3D porous silver foam as supporting material.

Author

Song, Keliang, Jiang, Zhuoni, He, Fangfang, Li, Yongsheng, He, Zhiyu, Li, Yintao, Wang, Peng, He, Guansong, and Yang, Wenbin

Subjects

*SUPERCOOLING, *FOAM, *PHASE transitions, *PHASE change materials, *BARIUM, *ELECTROLESS plating

Abstract

Inorganic hydrated salts possess high latent heat of phase transition and are promising phase change materials (PCMs). However, the issues of supercooling, low thermal conductivity, susceptibility to leakage, and phase separation significantly impediment the practical applications of inorganic hydrated salts. In this study, it is proposed to decrease the inorganic hydrated salt supercooling degree by increasing the surface roughness of the porous material and to load the nucleating agent silver (Ag) onto polydopamine (PDA) modified melamine foam (MF) by electroless plating to obtain 3D porous Ag foams, which are then utilized as support materials. The results demonstrated that the 3D porous Ag foam compounded with barium hydroxide octahydrate (BHO) can ameliorate the shortcomings of leakage and reduce the supercooling degree in the cooling process. The composite not only exhibits high enthalpy of over 248.5 J/g and high thermal conductivity of 1.82 W·m−1·K−1 but also has a low supercooling degree of 0.21 ℃. Furthermore, the composites exhibited superior shape stability and thermal cycling stability. This study provides an effective method for reducing the supercooling degree of inorganic hydration salts. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

2. Shape-stabilized phase change materials of barium hydroxide octahydrate based on Cu‐coated melamine foam.

Author

Song, Keliang, Liu, Zhipeng, Yang, Aoshuang, Li, Yongsheng, He, Fangfang, Jiang, Zhuoni, Li, Xiaoan, Chen, Zhengguo, and Yang, Wenbin

Subjects

*PHASE transitions, *MELAMINE, *PHASE change materials, *ELECTROLESS plating, *BARIUM, *THERMOCYCLING

Abstract

Hydrated salt phase change materials (PCMs) have the advantages of high energy storage density and low cost, and have great application prospects in the field of phase change energy storage. However, the problems of supercooling, phase separation and leakage of hydrated salt PCMs limit their further applications. In this work, we designed and fabricated Cu-coated melamine foam (MF)/barium hydroxide octahydrate (BHO) shape-stabilized phase change materials (SSPCMs) with low supercooling. MF was used as supporting material and Cu as a nucleating agent and thermal conductivity enhancer by loading it onto MF via electroless plating. BHO was then encapsulated into the MF@Cu skeleton through vacuum impregnation to obtain BHO@MF@Cu SSPCMs. The results demonstrated that BHO@MF@Cu SSPCMs not only present very low supercooling degree of 0.12 °C and high thermal energy capacity of 247 J/g, but maintained a latent heat of phase transition of 229.3 J/g with little change in enthalpy after 100 thermal cycles. Moreover, compared to BHO, SSPCMs exhibited high thermal conductivity of 1.687 W m−1 K−1, excellent shape stability, and thermal cycling stability. In summary, BHO@MF@Cu SSPCMs with low supercooling degree were prepared by electroless plating and vacuum impregnation in this study, which provides a new strategy to reduce the supercooling degree of hydrated salt PCMs. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023