Multi-objective optimization for improving printing efficiency and mechanical properties of 3D-printed continuous plant fibre composites

The mechanical properties and printing efficiency (i.e. the printing time) are often contradictory goals in 3D printing of continuous fibre composites. In this work, we presented a multi-objective optimization method for improving both the mechanical properties and printing efficiency of 3D-printed continuous flax-fibre-reinforced composites (CFFRCs). It was found that the printing efficiency of the CFFRCs with the optimal processing parameters was remarkably improved by 40% without sacrificing the tensile strength of the composites. This study provides an effective method for the improvement of the production efficiency of high-quality 3D-printed continuous fibre reinforced composites.

Automated summary

This study presents a multi-objective optimization method to improve both the mechanical properties and printing efficiency of 3D-printed continuous flax-fibre-reinforced composites (CFFRCs). It was found that the printing efficiency of CFFRCs was remarkably improved by 40% without sacrificing the tensile strength of the composites when using the optimal processing parameters. This study provides an effective method to enhance the production efficiency of high-quality 3D-printed continuous fibre reinforced composites.