Litcius/Paper detail

Insights into the high-velocity impact behaviour of bio-inspired composite laminates with helicoidal lay-ups

Hongxu Wang, Caizheng Wang, Paul J. Hazell, Ashleigh Wright, Zhifang Zhang, Xudong Lan, Ke Zhang, Ming Zhou

2021Polymer Testing69 citationsDOIOpen Access PDF

Abstract

This study explored the impact response of two bio-inspired composite laminates with linear and non-linear helicoidal fibre architectures. The helicoidal laminates, together with quasi-isotropic and cross-ply control samples, were fabricated using heterocyclic aramid fibres and tested against a spherical projectile under high impact velocities. The results revealed that helicoidal lay-ups with small rotation angles led to inferior perforation resistance and energy absorption capacity when compared to the quasi-isotropic and cross-ply counterparts. The cross-ply configuration was confirmed as the optimal fibre architecture for impact perforation. Post-impact inspections highlighted that the failure mechanisms of laminates were significantly affected by their lay-ups. The number of fractured fibres was found to reduce with the decrease of inter-ply angle. This was due to the small rotation angles promoted a wedge-in mechanism. Moreover, a smaller angle mismatch resulted in diminished overall delamination area in a laminate. Due to these two effects, therefore, helicoidal lay-up configurations with small inter-ply angles are not recommended for impact-resistant laminates reinforced by tough fibres.

Topics & Concepts

Materials scienceProjectileComposite materialComposite laminatesPerforationAramidComposite numberIsotropyAnisotropyWedge (geometry)Delamination (geology)FiberGeometryPunchingPhysicsTectonicsSubductionQuantum mechanicsPaleontologyMetallurgyBiologyMathematicsMechanical Behavior of CompositesHigh-Velocity Impact and Material BehaviorCellular and Composite Structures