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Process-structure–property study of 3D-printed continuous fiber reinforced composites

Jin Young Jung, Siwon Yu, Heejin Kim, Eunho Cha, Geun Sik Shin, Su Bin Eo, Sook Young Moon, Min Wook Lee, Michael Kucher, Robert Böhm, Jun Yeon Hwang

2024Composites Part A Applied Science and Manufacturing30 citationsDOIOpen Access PDF

Abstract

3D-printed fiber-reinforced composites hold many advantages compared to conventional composites in terms of individualization, mass customization, design freedom, and tailoring the composite geometry to load-bearing specifications. Among candidate continuous fibers for reinforcement, basalt fibers (BFs) serve as an eco-friendly alternative with excellent physical and thermal properties. However, the applicability of continuous BFs to be used for 3D-printed polymer composites was rarely addressed in existing literature. Especially, the effects of impregnation density during manufacturing and the influence of local fiber distribution on the fracture behavior of BF-reinforced composites remain unclear. In this study, a solution coating process was employed as a fiber pre-treatment to improve the packing density of BF in a polylactide (PLA) matrix. The effects of the resulting fiber volume fraction (8–31 %) and the local fiber distribution on the tensile fracture mechanisms of 3D printed BF/PLA samples are thoroughly analyzed using three-dimensional X-ray tomography. It was found that at a concentration of 3 wt%, the coating solution uniformly dispersed optimally between the fibers, resulting in improved impregnation densities of the BF in the PLA matrix. Thus, the resulting composite exhibited a tensile strength of 175 MPa and a Young’s modulus of 6.2 GPa, respectively. A standard linear solid (SLS) model is used for property prediction within a composite design framework to be applied to 3D-printed BF/PLA structures. The model is validated with experimental data from tensile tests. The obtained results demonstrate the applicability of eco-friendly BF/PLA composites for 3D printing of industrial high-performance applications with an individualized property profile.

Topics & Concepts

Materials scienceComposite materialFiberFiber-reinforced compositeAdditive Manufacturing and 3D Printing TechnologiesInnovations in Concrete and Construction MaterialsNatural Fiber Reinforced Composites
Process-structure–property study of 3D-printed continuous fiber reinforced composites | Litcius