Abstract
Recycling carbon-fibre-reinforced plastic (CFRP) and recovering high-cost carbon fibre (CF) is a preoccupation of scientific and industrial committees due to the environmental and economic concerns. A commercialised nonwoven mat, made of recycled carbon fibre and manufactured using carding and needle-punching technology, can promote second-life opportunities for carbon fibre. This paper aims to evaluate the mechanical and preforming behaviour of this nonwoven material. We focus on the influence that the fibre orientation distribution in the nonwoven material has on its mechanical and preforming behaviour at the preform scale, as well as the tensile properties at composite scale. The anisotropy index induced by fibre orientation is evaluated by analysing SEM micrographs using the fast Fourier transform (FFT) method. Then, the anisotropy in the tensile, bending, and preforming behaviour of the preform is inspected, as well as in the tensile behaviour of the composite. Additionally, we evaluate the impact of the stacking order of multi-layers of the nonwoven material, associated with its preferred fibre orientation (nonwoven anisotropy), on its compaction behaviour. The nonwoven anisotropy, in terms of fibre orientation, induces a strong effect on the preform mechanical and preforming behaviour, as well as the tensile behaviour of the composite. The tensile behaviour of the nonwoven material is governed by the inter-fibre cohesion, which depends on the fibre orientation. The low inter-fibre cohesion, which characterises this nonwoven material, leads to poor resistance to tearing. This type of defect rapidly occurs during preforming, even at too-low membrane tension. Otherwise, the increase in nonwoven layer numbers leads to a decrease in the impact of the nonwoven anisotropy behaviour under compaction load.
Highlights
In 2017, the global demand for carbon fibres, to be used in 114.7 ktons of carbon-fibrereinforced plastics (CFRP), was approximately 70.5 ktons [1], and it could reach 122.8 ktons in 2022 [2]
The recycled fibres are currently used in relatively low-performance applications such as injection moulding and 3D printing; other processes, such as carding or wet deposition, which are used to ensure that nonwoven fabrics retain their fibre length, offer improved mechanical properties that could allow recycled fibre composites to be used in higher-performance applications [7]
The present paper aimed to evaluate the physical properties and mechanical performance of a nonwoven manufactured by the ELG Company from recycled carbon fibre
Summary
In 2017, the global demand for carbon fibres, to be used in 114.7 ktons of carbon-fibrereinforced plastics (CFRP), was approximately 70.5 ktons [1], and it could reach 122.8 ktons in 2022 [2]. Wei et al [12] described a wet-laid process, used to mix rCF and PA6 fibres together in a mat of randomly oriented fibres, which were formed in composite samples by compression moulding. Barnett et al [7] compared the mechanical properties of composite samples obtained by compression moulding with PPS film and repurposed virgin carbon fibre nonwovens manufactured by the wet-laid process and recycled carbon fibre nonwovens provided by ELG carbon fibre. In these studies, the distribution of the length and orientation of fibres in a nonwoven mat were studied for their critical influence on the mechanical properties at composites scales. The nonwoven fabrics have no directionality and are randomly distributed in the longitudinal and transverse direction [12]
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