3D printing as an automated manufacturing method for a carbon fiber-reinforced cementitious composite with outstanding flexural strength (105 N/mm2)

As research interest in the additive manufacturing of cementitious materials for structural uses has been continuously increasing, the question of how to incorporate tensile reinforcement in an automated process has gained further importance. Our research describes a carbon fiber-reinforced cementitious composite produced by common extrusion techniques applied in 3D printing as a means to effectively control fiber alignment. Optimization of the mixture design and consistency allows for admixing up to 3 vol.-% chopped carbon fibers, leading to specimens that can reach a flexural strength exceeding 100 N/mm(2) without the addition of further continuous reinforcement. Fiber integrity during the process was checked using optical microscopy. Analysis of the microstructure shows that approximately 70% of the fibers are aligned within +/- 5 degrees of a preferential direction. Micromechanical single-fiber push-out tests confirm an interfacial fracture toughness typical for strain-hardening systems. The first insights into a 'lost formwork' approach commonly employed in 3D printing show that the reinforcement remains effective even when combined with nonreinforced mortar.

Automated summary

The research discusses a carbon fiber-reinforced cementitious composite fabricated through 3D printing, achieving high flexural strength without the need for additional continuous reinforcement. Optimization of mixture design and consistency effectively controls fiber alignment, with approximately 70% of fibers aligned within a specified range. Analysis shows that the reinforcement remains effective even when combined with nonreinforced mortar in a 'lost formwork' approach commonly used in 3D printing.