Abstract
Different bio-inspired Bouligand thin-ply Carbon-Fibre-Reinforced Plastic (CFRP) laminates with a pitch angle as low as 2.07∘ are realised, which is the smallest pitch angle realised in literature. The angle is therefore close angles found in biological microstructures. Low-Velocity Impact (LVI) and residual compressive strength tests determined the damage tolerance of the structures. Investigated were two different interlaminar fracture toughnesses and two different metal-Bouligand-CFRP-layups. The low pitch angle results in significantly higher residual strengths than 45∘ quasi-isotropic (QI) layups, despite the significantly lower proportion of 0∘ fibres. Higher fracture toughness and hybridisation with steel layers lead to reduced matrix damage without increasing residual compressive strength. In-plane plane tension properties are determined with a pitch angle of 2.59∘. The results reveal, that the unnotched tensile strength is significantly lower. However, only helicoidal, sub-critical matrix cracking and no delaminations occur before final failure. The sub-critical matrix cracking leads to almost no notch sensitivity and a similar open-hole-tensile strength to 45∘-QI layups despite the low number of 0∘-fibres.
Highlights
Fibre-reinforced plastics (FRP) exhibit complex failure mechanisms, due to their multi-scale nature and different constituents
Hybridisation with metal-layer leads to reduced matrix damage, but the residual strength is lower than non-hybrid Carbon-Fibre-Reinforced Plastic (CFRP) layups, due to formation of local delaminations
The residual strength still exceeds the strength of 45◦ QI layups
Summary
Fibre-reinforced plastics (FRP) exhibit complex failure mechanisms, due to their multi-scale nature and different constituents. The constituents are defining the laminate strength and failure process, and laminate design. The interaction between the layup and layer thickness has a decisive influence on the failure behaviour. A fairly new approach to control the damage behaviour of FRP is the use of advanced layup designs inspired by nature. Impact loading is of particular interest because the layered structure of composites results in low out-of-plane strength. In CFRP Structures damages induced by LVI are hard to detect visually. These damages are so-called, barely visible damage (BVID)
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