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Evolution of fibre deflection leading to kink-band formation in unidirectional glass fibre/epoxy composite under axial compression

Ying Wang, Monica Jane Emerson, Knut Conradsen, Anders Bjorholm Dahl, Vedrana Andersen Dahl, Éric Maire, Philip J. Withers

2021Composites Science and Technology51 citationsDOIOpen Access PDF

Abstract

We present the first experimental observation and quantification of the evolution of the three-dimensional (3D) deflection of fibres leading up to kink-band formation in notched unidirectional glass fibre-epoxy composites. This has been achieved by in situ synchrotron X-ray computed tomography (CT) quantified by advanced image analysis. The 3D trajectories of individual fibres were extracted to monitor the change in fibre profiles with increasing compressive load. Initially the fibre trajectory varies significantly from fibre to fibre, the waviness of which cannot be represented by a simple idealised profile. However, the change in the fibre shapes during axial compression is similar for all fibres, as the fibres deflect towards the final kinking direction. The precursor to kink-band nucleation has been identified as a local tilting of fibres in the region where the kink bands ultimately form, defining a micro-buckle band. Even at 99.9% of the failure load this micro-buckle band is much narrower (~150 μm (~12 fibre diameters) wide), and the angle of inclination of the band much shallower (~8°), compared to the final 300–400 μm (25–33 fibre diameters) wide, and 25–30° inclined, kink band. It is notable that kink-band boundaries are delineated by fibre fractures, many of which exhibit wedge-shaped multiple fractures.

Topics & Concepts

Materials scienceEpoxyComposite materialComposite numberDeflection (physics)Glass fiberCompression (physics)OpticsPhysicsMechanical Behavior of CompositesOptical measurement and interference techniquesStructural Response to Dynamic Loads
Evolution of fibre deflection leading to kink-band formation in unidirectional glass fibre/epoxy composite under axial compression | Litcius