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Reduced graphene oxide and zirconium carbide co-modified melamine sponge/paraffin wax composites as new form-stable phase change materials for photothermal energy conversion and storage
writer:Jie Yang, Yanlin Jia, Naici Bing*, Lingling Wang, Huaqing Xie, Wei Yu*
keywords:Photothermal conversion, Form-stable PCMs, Thermal energy storage, Reduced graphene oxide, Melamine sponge
source:期刊
specific source:Applied Thermal Engineering, Volume 163, 25 December 2019, 114412
Issue time:2019年
Photothermal energy conversion and storage are crucial in solar collection systems. However, it is difficult for traditional media to balance high photothermal conversion, thermal conductivity and thermal energy storage. Considering the advantages of nanofluids (volumetric absorption systems) and PCMs (high latent storage density), we develop novel form-stable PCMs for solar collection systems and overcome the disadvantages of current systems, which take melamine sponge as supporting materials, paraffin wax as solid-liquid PCMs, reduced graphene oxide and zirconium carbide as solar absorption and thermal conduction additives. The results demonstrate that the rich network skeleton structure of reduced graphene oxide modified melamine sponge provides huge surface tension and capillary force to support paraffin wax for achieving the shape-stability before and after phase transition, and the latent enthalpy reaches 137?J/g. The composites PCMs with different content zirconium carbide show good photoabsorption, high thermal storage capacity and excellent heat transfer property. The photothermal conversion efficiency is up to 81% when doped with 0.01?wt% zirconium carbide. The maximum thermal conductivity of composites PCMs is 121% higher than that of paraffin wax. The reduced graphene oxide and zirconium carbide co-modified melamine sponge/paraffin wax composites show its great potential in solar energy utilization and storage.