Litcius/Paper detail

Modelling and experimental study of hydrogen permeation in polymer composites: Effects of fibre agglomeration and orientation

Mustafa Okumuş, F.J.J.G. Janssen, Łukasz Figiel

2025Composites Part A Applied Science and Manufacturing8 citationsDOIOpen Access PDF

Abstract

This work combines modelling and experiments to provide a new insight into the effects of microstructural features on the overall hydrogen permeability of polymer composites. A three-dimensional (3D) modelling approach exploiting the representative volume element (RVE) concept was developed to investigate the influence of fibre agglomerations and fibre orientation within each ply on the overall hydrogen permeability. The model was validated using full-scale permeation experiments on a thermoplastic composite pipe (TCP) composed of E-glass fibre-reinforced high-density polyethylene (EGF/HDPE) at different temperatures. Model predictions showed that local fibre clustering can significantly reduce permeability by increasing the tortuosity of diffusion pathways, thus creating additional resistance to hydrogen permeation. The effect of fibre orientation on hydrogen permeability was found to depend on the level of fibre agglomeration - while for plies with fibre-rich domains the orientation had an insignificant effect on permeability, the latter was noticeably reduced with increasing ply misalignment when plies contained uniform fibre distribution. This research presents the first hydrogen permeability assessment of EGF/HDPE composites, highlighting the potential of this material system for hydrogen distribution applications.

Topics & Concepts

Materials scienceComposite materialEconomies of agglomerationPolymerPermeationOrientation (vector space)HydrogenChemical engineeringMembraneMathematicsOrganic chemistryBiologyGeneticsChemistryGeometryEngineeringComposite Material MechanicsGraphite, nuclear technology, radiation studiesHigh voltage insulation and dielectric phenomena