Flexible phase change materials with enhanced tensile strength, thermal conductivity and photo-thermal performance

Phase change materials are most potential candidates for storing solar thermal energy with large enthalpy and high exergy. However, the intrinsic drawback such as poor optical absorptive capacity, low thermal conductivity and poor tensile strength restrict the thermal efficiency of phase change materials. To overcome drawback, expanded graphite is used to encapsulate the paraffin then thermoplastic elastomer is used to mix with the powders with twin-screw extrusion technology. The highly flexible phase change composite shows a melting enthalpy of 124.6 J g-1 and a thermal conductivity of 2.2 W m-1 K-1 with 70% of expanded graphite/paraffin. The tensile strength of 2.1 MPa and a breaking elongation of 220%. This flexible phase change composite demonstrates good photo-thermal energy charging/discharging property and shows much larger exergy than traditional fluids in the solar thermal energy systems.

Automated summary

Phase change materials have great potential for storing solar thermal energy, but their poor optical absorptive capacity, low thermal conductivity, and poor tensile strength are limiting factors. By using expanded graphite to encapsulate paraffin and mixing with thermoplastic elastomer, a highly flexible phase change composite with improved thermal conductivity and strength can be produced.