Effects of Coating Post-processing on Mechanical Properties of Strut-and-Node-Based SLA Lattice Structures

Lattice structures play an increasingly crucial role in Additive Manufacturing (AM) to enhance the performance of parts for industrial and biomedical applications. Among AM technologies, VAT photopolymerization is one of the most suitable in producing shapes characterized by a good resolution and fine details as required for lattice structures. High stiffness and strength photoresins are commonly adopted when strut-and-node lattice structures, based on stretch-dominated unit cells, are printed. However, this choice can lead to brittle and sudden structural failures, undermining the use of these structures due to safety reasons. This work evaluates the effect of chemical post-processing on the deformation behavior and the tensile properties of SLA strut-and-node-based lattice structures. FCC (Face-Centered Cubic) lattice structures with two different layer heights were tested, and a highly deformable UV resin was used as a coating product. Results evidenced an increase in specimen elongation up to 64% for coated FCC lattice structures with respect to as printed samples. Chemical post-processing based on resin coating demonstrated to be an effective solution to get additively manufactured strut-and-node-based lattice structures characterized both by high strength and high strain.