No Cover Image

Conference Paper/Proceeding/Abstract 1395 views

Directional diffusion of moisture in carbon fibre-epoxy composites: experiments and modelling

Feras Korkees Orcid Logo, Sue Alston, Cris Arnold

20th International Conference on Composite Materials, Copenhagen, 19-24th July 2015

Swansea University Author: Feras Korkees Orcid Logo

Abstract

Water diffusion into composites in different directions was examined in this study, with the aim of determining the best way of measuring diffusion coefficients and also to provide values to compare with model predictions. The water absorption behaviour of unreinforced epoxy resins and carbon fibre...

Full description

Published in: 20th International Conference on Composite Materials, Copenhagen, 19-24th July 2015
Published: 2015
URI: https://cronfa.swan.ac.uk/Record/cronfa31086
Tags: Add Tag
No Tags, Be the first to tag this record!
Abstract: Water diffusion into composites in different directions was examined in this study, with the aim of determining the best way of measuring diffusion coefficients and also to provide values to compare with model predictions. The water absorption behaviour of unreinforced epoxy resins and carbon fibre reinforced epoxy composite materials was examined with long term exposure to different environmental conditions. Initial Fickian absorption was observed followed by a slower second stage that continues for at least 3.7 years. Fibre architecture was found to be an important aspect controlling absorption, where water diffusion along fibres was observed to be about three times faster than across the fibres and about seven times faster than through the thickness. A three-dimensional finite element computer model based on Fickian diffusion behaviour was developed to predict the levels of moisture absorption under hot/humid environments. A multi-scale modelling approach was used which allows the results of simulations at the microstructural level to be used to predict the diffusivities in different directions. Experimental results provided a baseline for the validation of the model, and comparison of these data with model predictions showed close matching and good agreement. The diffusion showed high dependency on the detailed microstructure.
Keywords: Directional diffusion, Moisture absorption, Multi-scale modelling
College: Faculty of Science and Engineering