Investigation of Carbon Fibres Reclamation by Pyrolysis Process for Their Reuse Potential

During Carbon Fibre Reinforced Polymers (CFRPs) manufacturing, large quantities of scrap are being produced and usually disposed to landfill or incinerated, resulting in a high environmental impact. Furthermore, CFRP parts that have been damaged or reached their end-of-life, follow the same disposal route and because of this, not only the environment is affected, but also high added-value materials, such as carbon fibres (CFs) are lost without further valorisation. Several recycling technologies have been suggested, such as pyrolysis, to retrieve the CF reinforcement from the CFRPs. However, pyrolysis produces CFs that have residual resin and pyrolytic carbon at their surface. In order to retrieve clean long fibres, oxidation treatment in high temperatures is required. The oxidation treatment, however, has a high impact on the mechanical properties of the reclaimed CFs; therefore, an optimised pyrolysis procedure of CFRPs and post-pyrolysis treatment of reclaimed fibres (rCFs) is required. In this study, CFRPs have been subjected to pyrolysis to investigate the reclamation of CF fabrics in their primal form. The temperature of 550 degrees C was selected as the optimum processing temperature for the investigated composites. A parametric study on the post-pyrolysis treatment was performed in order to remove the residues from the fabrics and at the same time to investigate the CFs reusability, in terms of their mechanical and surface properties.

Automated summary

Large amount of scrap produced during Carbon Fibre Reinforced Polymers (CFRPs) manufacturing is usually disposed to landfill or incinerated, resulting in a high environmental impact. Recycling technologies such as pyrolysis have been suggested to retrieve the carbon fibres (CFs) from CFRPs, but pyrolysis produces CFs with residual resin and pyrolytic carbon at their surface. This study investigates the reclamation of CF fabrics in their primal form through pyrolysis and post-pyrolysis treatment, aiming to remove residues and assess CFs reusability in terms of mechanical and surface properties.