A comparison study of water diffusion in unidirectional and 2D woven carbon/epoxy composites

A comparison study of water diffusion in unidirectional and 2D woven carbon/epoxy composites

The use of CFRP composites is significantly increasing in the aerospace, automotive, and marine industries, particularly in safety critical primary structures. This work presents a newly developed experimental approach to investigate the directional diffusion of water in CFRP composites with the use...

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Bibliographic Details
Published in:Polymer composites Vol. 43; no. 1; pp. 118 - 129
Main Authors: Almudaihesh, Faisel, Holford, Karen, Pullin, Rhys, Eaton, Mark
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 01-01-2022
Blackwell Publishing Ltd
Subjects:
Aerospace industry
Aerospace safety
Carbon-epoxy composites
Diffusion coefficient
Diffusion rate
fiber architecture
Fiber-matrix adhesion
Fibre waviness
interfacial condition
Materials selection
Moisture
moisture diffusion
Safety critical
Saturation
water absorption
water ingress mechanism
Water purification
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Summary:The use of CFRP composites is significantly increasing in the aerospace, automotive, and marine industries, particularly in safety critical primary structures. This work presents a newly developed experimental approach to investigate the directional diffusion of water in CFRP composites with the use of Fick's law. The approach is used to study the effect of fiber architecture on directional diffusion rates, with a particular focus on the role of fiber waviness in the diffusion process. A comparison of water diffusion is made in three different fiber architectures: Unidirectional (UD), plain weave, and twill weave. The specimens were fully immersed in 90°C purified water until their maximum moisture saturation was achieved, with some specimens being selectively exposed from the edges only to obtain the directional diffusion coefficients. The water penetration process into the CFRP structure initiate from the micro‐cracks and defects. The experimental work of this study shows sharp mass increases within the first stage followed by an equilibrium stage where saturation is present. The interfacial region is found to be a critical parameter where detachment of the interfacial fiber/matrix bonding is observed further demonstrating the potential effect of different fiber architecture in this region. UD fiber architecture showed ~20% higher diffusion coefficient in the Dx,y direction compared with plain and twill woven architectures. The weave patterns in 2D woven fiber architectures are therefore believed to play a key role on the moisture ingress mechanism and subsequently contributed in slowing down the capillary process in the interfacial region. This has implications for materials development and selection for CFRP composites used in moist environments.
ISSN:0272-8397
1548-0569
DOI:10.1002/pc.26361