Abstract
This study investigates the influence of load ratio and impact damage on the fatigue behaviour of high-performance carbon fibre reinforced polymers (CFRP) with areal fibre weights between 30 gsm and 360 gsm. For undamaged samples, the ultimate tensile and compressive strength, as well as the fatigue properties, are evaluated with regard to their layer thicknesses. The fatigue tests were performed under tension-tension (R=0.1), tension-compression (R=-0.5) and compression-compression (R=10) regime. The results are illustrated as a constant-life diagram, and a piecewise linear interpolation examines a first prediction. The results show that static and fatigue performance improves with decreasing layer thickness. Particularly under tension-compression loading, significant improvements are observed, due to the suppression of matrix cracks and delaminations with thinner layers. In addition, the effect of low-energy impact on the fatigue behaviour of Thin- and Thick-Ply laminates is investigated. The tests demonstrate that although the delamination area is larger, Thin-Ply laminates can sustain higher stresses and still reach the same number of load cycles in contrast to Thick-Ply laminates. Computed tomography measurements visualize 3-dimensional the damage progression after various cycles and prove that the Thin-Ply composites show no increase in the damaged area during fatigue. The interlaminar stress at the delamination is not sufficient for expansion. In contrast, in the case of thicker layers, the damage growths progressively throughout the whole sample with increasing number of cycles.
Highlights
Fatigue and impact tests are of particular interest in the design process of structural components
The failure behaviour is fibre-dominated in both cases, and no differences between the layer thicknesses can be observed
The layer thickness at which delamination is completely suppressed depends on the materials used and their properties, such as the toughness of the matrix
Summary
Fatigue and impact tests are of particular interest in the design process of structural components. Defects in laminated composite structures like voids and impact damages have a major influence on the fatigue behaviour [2,3] Due to their lightweight performance, carbon fibre reinforced polymers are increasingly used. The defects are distributed within the material, whereby the damage pattern’s size and shape depend on several factors These include, for example, the properties of the samples to be tested, such as stiffness and layer structure, the clamping system used and the applied impact energy. The detection of such damage is difficult. Defects in laminated composite structures like voids and impact damages have a major influence on the fatigue behaviour [15]
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