Abstract

Recycled polypropylene filaments for fused filament fabrication were investigated with and without 14 wt% short fibre carbon reinforcements. The microstructure and mechanical properties of the filaments and 3D printed specimens were characterized using scanning electron microscopy and standard tensile testing. It was observed that recycled polypropylene filaments with 14 wt% short carbon fibre reinforcement contained pores that were dispersed throughout the microstructure of the filament. A two-stage filament extrusion process was observed to improve the spatial distribution of carbon fibre reinforcement but did not reduce the pores. Recycled polypropylene filaments without reinforcement extruded at high screw speeds above 20 rpm contained a centreline cavity but no spatially distributed pores. However, this cavity is eliminated when extrusion is carried out at screw speeds below 20 rpm. For 3D printed specimens, interlayer cavities were observed larger for specimens printed from 14 wt% carbon fibre reinforced recycled polypropylene than those printed from unreinforced filaments. The values of tensile strength for the filaments were 21.82 MPa and 24.22 MPa, which reduced to 19.72 MPa and 22.70 MPa, respectively, for 3D printed samples using the filaments. Likewise, the young’s modulus of the filaments was 1208.6 MPa and 1412.7 MPa, which reduced to 961.5 MPa and 1352.3 MPa, respectively, for the 3D printed samples. The percentage elongation at failure for the recycled polypropylene filament was 9.83% but reduced to 3.84% for the samples printed with 14 wt% carbon fiber reinforced polypropylene filaments whose elongation to failure was 6.58%. The SEM observations on the fractured tensile test samples showed interlayer gaps between the printed and the adjacent raster layers. These gaps accounted for the reduction in the mechanical properties of the printed parts.

Highlights

  • fused deposition modeling (FDM) or fused filament fabrication (FFF) is a 3D CAD-controlled process that melts the feedstock in the extrusion head [6]

  • It was observed that recycled polypropylene filaments with 14 wt% short carbon fibre reinforcement contained pores that were dispersed throughout the microstructure of the filament

  • The microstructure and mechanical properties of extruded recycled polypropylene filaments without and with 14 wt% carbon fibre reinforcement were investigated. These filaments were subsequently used to 3D print specimens using fused filament fabrication to assess their suitability for additive manufacturing of commercial quality components

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Summary

Introduction

FDM or FFF is a 3D CAD-controlled process that melts the feedstock in the extrusion head [6]. Post-processing of the printed part may be necessary to clean and remove any support. In the FDM method, the first stage is to create a 3D model with CAD software. The part file is transformed into a Stereolithography file (STL) which contains the instruction codes for the machine tool to pursue a defined tool path [7]. FDM technology offers lower cost, robustness, multi-material flexibility, and simplicity [4]

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