N.V. De Carvalho

On longitudinal compressive failure of carbon-fibre-reinforced polymer: from unidirectional to woven, and from virgin to recycled

Modelling the longitudinal compressive failure of carbon-fibre-reinforced composites has been attempted for decades. Despite many developments, no single model has surfaced to provide simultaneously a definitive explanation for the micromechanics of failure as well as validated predictions for a generic stress state. This paper explores the reasons for this, by presenting experimental data (including scanning electron microscopic observations of loaded kink bands during propagation, and brittle shear fracture at 45° to the fibres) and reviewing previously proposed micromechanical analytical and numerical models. The paper focuses mainly on virgin unidirectional (UD) composites, but studies for woven and recycled composites are also presented, highlighting similarities and differences between these cases. It is found that, while kink-band formation (also referred to in the literature as microbuckling) is predominant in UD composites under longitudinal compression, another failure mode related to the failure of the fibres can be observed experimentally. It is also shown that the micromechanics of the failure process observed in UD composites is similar to that in other fibre architectures, hence encouraging the adaptation and application of models developed for the former to the latter.

Fibre-dominated compressive failure in polymer matrix composites

Abstract: Models describing longitudinal compressive failure of carbon fibre reinforced polymers (CFRP) have been attempted for decades. Despite many developments, no single model has surfaced to provide simultaneously a definitive explanation for the micromechanics of failure and validated predictions for a generic stress state. This chapter explores why, by presenting new experimental data (including scanning electron microscope (SEM) observations of loaded kink bands during propagation, and brittle shear fracture at 45xa0° to the fibres) and proposing new micromechanics analytical and numerical models. The paper focuses on unidirectional (UD) composites, but studies of woven and recycled composites are also presented, highlighting similarities and differences with UD.