Multifunctional auxetic and honeycomb composites made of 3D woven carbon fibre preforms

Three dimensional (3D) woven composites started to find applications in various industrial sectors, mainly in aerospace and with a potential in automotive. 3D-woven fabrics can be architected to form complex and near-net-shape preforms ready for automated composites manufacturing. The 3D-woven honeycomb fabric is designed to include additional functionality into finished composites, such as positive and negative Poisson's ratios. In this study, complex honeycomb architectures were created using various weave designs to demonstrate the effects of auxetic behaviours when manufactured into a composite structure. A Staubli 3D-weaving system equipped with Jacquard UNIVAL 100 and creel of 3072 6 k carbon fibre tows were used to weave the designed honeycomb architecture. With the aid of hard polyester foam inserts, the 3D-woven fabrics were converted to honeycomb and auxetic preforms. These preforms were infused using epoxy resin to manufacture a set of honeycomb and auxetic composite structures. In comparison with the baseline honeycomb structure, it is proven that the developed auxetic composites exhibited negative Poisson's ratio of-2.86 and-0.12 in the case of tensile and compression tests respectively.

Automated summary

Three dimensional (3D) woven composites have found applications in various industries, including aerospace and potentially automotive. By utilizing different weave designs, complex honeycomb architectures can be created to demonstrate auxetic behaviors in composite structures. By weaving with specific equipment and materials, auxetic composite structures with negative Poisson's ratios can be manufactured.