Thermal conductivity and mechanical properties enhancement of CF/PPBESK thermoplastic composites by introducing graphene

Design and preparation structure/function integrated polymer composites with high thermal conductivities and ideal mechanical properties have attracted widespread attention. Nanoscale graphene were employed to fabricate the thermal-structural integration graphene/carbon fiber/copoly (phthalazinone ether sulfone ketone) composites via solution prepreg followed by hot-compression method. The thermal conductivity (lambda) and mechanical properties were all improved with the formation of graphene thermally conductive self-reinforced network. The thermal conductivity was increased to 1.057 W/(m K) by 89.8% higher than the pure carbon fiber composites. Moreover, the flexural strength (1878 MPa), compressive strength (907 MPa) and interlaminar shear strength (66 MPa) of graphene-modified composites improved with 22.1%, 51.9%, and 24.5% than the conventional composites, respectively. Dynamic mechanical analysis has proved that graphene/carbon fiber/copoly (phthalazinone ether sulfone ketone) composites had excellent high temperature mechanical properties, which presented a great potential for structure/function integrated composites.

Automated summary

By employing nanoscale graphene, thermal-structural integration graphene/carbon fiber/copoly (phthalazinone ether sulfone ketone) composites with improved thermal conductivity and mechanical properties were successfully prepared. These composites showed great potential for structure/function integrated materials.