Directional chitosan/carbon fiber powder aerogel supported phase change composites for effective solar thermal energy conversion and hot compression

Solar energy is an important green energy. Its efficient utilization has attracted wide attention. Phase change materials can absorb and release significant amounts of latent heat, which are expected to compensate for the intermittence and instability of solar energy. In this study, directional chitosan/carbon fiber powder aerogels were successfully prepared as a support matrix by directional freezing technique for encapsulation of phase change materials. Carbon fiber powder with low cost, high thermal conductivity and good light absorption was selected as a light trap and heat conduction reinforcing filler. Paraffin was effectively encapsulated in directional chitosan/carbon fiber powder aerogels via vacuum impregnation. The prepared paraffin/chitosan@carbon fiber powder composites (PA/CS@CFP) can achieve a high load rate (>94 %) and maintain good encapsulation capability, high enthalpy (211.9-257.5 J/g), thermal stability, solar-thermal energy conversion and storage capability. The lightweight, directional, high porosity CS@CFP aerogels are good matrices of phase change materials, which can realize the solar-thermal conversion and enhance the thermal response of the composite. Additionally, a human heat pack was developed to provide heating for human comfort after solar charging. PA/ CS@CFP composites have great potential for solar energy utilization, waste heat recovery, building energy saving, and hot compression.

Automated summary

Solar energy is an important green energy source and efficient utilization of solar energy has been a popular issue. In this study, chitosan/carbon fiber powder aerogels were used as a support matrix for phase change materials, and paraffin was successfully encapsulated in the aerogels. The resulting composites showed high load rate, good encapsulation capability, high enthalpy, thermal stability, solar-thermal energy conversion, and storage capability. The composites have great potential for solar energy utilization, waste heat recovery, building energy saving, and hot compression.