Graphene nanoplatelets composite membranes for thermal comfort enhancement in performance textiles

The advent of 2D nanostructured materials as advanced fillers for polymer matrix composites has opened the doors to a plethora of new industrial applications requiring both electric and thermal management. Unique properties, in fact, can arise from accurate selection and processing of 2D fillers and their matrix. Here, we report an innovative family of nanocomposite membranes based on polyurethane (PU) and graphene nanoplatelets (GNPs), designed to improve thermal comfort in functional textiles. GNP particles were thoroughly characterized (through Raman, atomic force microscopy, high-resolution TEM, scanning electron microscope), and showed high crystallinity (I-D/I-G= 0.127), low thickness (D50 < 6-8 layers), and high lateral dimensions (D50 approximate to 3 mu m). When GNPs were loaded (up to 10% wt/wt) into the PU matrix, their homogeneous dispersion resulted in an increase of the in-plane thermal conductivity of composite membranes up to 471%. The thermal dissipation of membranes, alone or coupled with cotton fabric, was further evaluated by means of an ad hoc system designed to simulate a human forearm. The results obtained provide a new strategy for the preparation of membranes suitable for technical textiles, with improved thermal comfort.

Automated summary

The use of 2D nanostructured materials as advanced fillers in polymer matrix composites has opened up new industrial applications requiring both electrical and thermal management. The accurate selection and processing of 2D fillers and their matrix can result in unique properties. The development of a family of nanocomposite membranes based on polyurethane and graphene nanoplatelets has shown significant improvements in in-plane thermal conductivity and thermal comfort.