AUTHOR=Graupner Nina , Hohe Jörg , Schober Michael , Rohrmüller Benedikt , Weber David , Bruns Lisa , Bruns Albert , Müssig Jörg TITLE=A Competitive Study of the Static and Fatigue Performance of Flax, Glass, and Flax/Glass Hybrid Composites on the Structural Example of a Light Railway Axle Tie JOURNAL=Frontiers in Materials VOLUME=Volume 9 - 2022 YEAR=2022 URL=https://www.frontiersin.org/journals/materials/articles/10.3389/fmats.2022.837289 DOI=10.3389/fmats.2022.837289 ISSN=2296-8016 ABSTRACT=The most common studies in the literature are those analysing fatigue life under cyclic loading for flax fibre reinforced composites. A novel type of staple fibre yarn made from flax tow with almost unidirectional fibre orientation and a quasi-unidirectional fabric was developed for composite applications. Additionally, a hybrid material made of flax and glass was produced for a demonstrator component (axle tie of a narrow-gauge railway). For such an application, the investigation of fatigue strength is of particular importance. Therefore, the fatigue behaviour of flax, glass and hybrid flax/glass composites was investigated in the high cycle fatigue (HCF) range. A total of 10^6 load cycles were carried out. From about 7³ to 8³ loading cycles, the flax laminate was found to have higher fatigue strength than the glass fibre-reinforced composite. The hybrid materials tend to show a higher fatigue strength than the glass type from approximately 2*10^5 load cycles. Results based on a finite element method have also demonstrated better fatigue properties at an increased number of load cycles for flax-based composites than the glass fibre-reinforced component. The flax/glass component's fatigue strength ranged between the flax values and the glass fibre-reinforced composites. Overall, the hybrid material shows significantly better static bending and impact characteristics than flax and considerably better fatigue properties than the glass fibre-reinforced composite making the hybrid material attractive for an application in an axle tie.