TY - JOUR

T1 - Damage Tolerance and Notch Sensitivity of Bio-Inspired Thin-Ply Bouligand Structures

AU - Körbelin, Johann

AU - Goralski, Philip

AU - Kötter, Benedikt

AU - Bittner, Florian

AU - Endres, Hans-Josef

AU - Fiedler, Bodo

N1 - Funding Information: This work was carried out with funding from the German Research Foundation (DFG) within the project number 283641236. This financial support is gratefully acknowledged

PY - 2021/7

Y1 - 2021/7

N2 - 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.

AB - 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.

KW - CT analysis

KW - Failure

KW - Hybrid

KW - Layered structures

KW - Microstructures

KW - Stress concentrations

UR - http://www.scopus.com/inward/record.url?scp=85119197095&partnerID=8YFLogxK

U2 - 10.1016/j.jcomc.2021.100146

DO - 10.1016/j.jcomc.2021.100146

M3 - Article

VL - 5

JO - Composites Part C: Open Access

JF - Composites Part C: Open Access

SN - 2666-6820

M1 - 100146

ER -