What material properties and mechanical characteristics do the printed components have, and how do they compare with components from other manufacturing processes such as the fused layer process or injection molding?
Katrakova-Krüger: An electrophotographically printed tension rod made of ABS has a tensile strength of around 1900 MPa, a modulus of elasticity of around 40 MPa and an elongation at break of just over 2 percent. This means that our tensile strength is 25 percent higher than that of FDM (1627 MPa) and 20 percent lower than that of injection molding (2300 MPa). The modulus of elasticity of our sample is 43% higher than that of FDM (22 MPa) and only 12% lower than that of injection molding (44 MPa) for the same material. The elongation at break is similar to FDM at around 3%, but significantly lower than the values achieved in injection molding (12%). However, we are continuously working on further improving the mechanical properties.
What advantages does this process offer, for example for industrial applications, compared to other 3D printing processes?
Katrakova-Krüger: Thanks to the high printing speed of electrophotography and the two-step process, high production rates can be achieved. The use of small polymer particles enables a high print resolution. It is also possible to process different materials in one component and produce several parts at the same time. As the process is not dependent on gravity, an application in space would also be possible.
What is the current throughput of the developed 3D printing prototype and what factors influence the number of workpieces that can be produced?
Katrakova-Krüger: The maximum build-up rate depends on the 2D printer size and the number of stamping machines. In the 2D area, printing speeds of up to 5 m² per minute are currently possible. It is possible to print several layers of a component or to print different components at the same time. Up to 8 different toner materials per layer can be printed simultaneously. The overall production speed increases the more transfer units work in parallel. In principle, the process is able to compete with injection molding in terms of quantities.