3D printing of dual phase-strengthened microlattices for lightweight micro aerial vehicles

The rapid advancement in CAD and 3D printing technology have brought the rise of mechanical metamaterials which inspired from nature and have optimized microstructural features to exhibit superior mechanical properties over conventional materials for various structural applications. Here, by adopting dual-phase strengthening mechanism in crystallography, we proposed a microlattice strengthening strategy which incorporates stretching-dominated octet-truss (OCT) units as the second phase particles into the diagonal planes of the bending-dominated body-centered cubic (BCC) lattice matrix, to form an anisotropic OCT-BCC lattice. The OCT-BCC dual-phase microlattice possess superior specific compressive strengths that are similar to 300% and 600% higher than BCC microlattices along its horizontal direction and longitudinal direction, respectively, accompanied with a significant increase in stiffness and energy absorption as well. Moreover, a large-scale OCT-BCC lattice metamaterial with dimensions up to 5.0 cm x 2.0 cm x 1.0 cm was successfully manufactured and integrated into a micro aerial vehicle (MAV). The metamaterial-integrated MAV has an airframe that is similar to 65% lighter than its bulk counterpart, resulting in a significant increase (similar to 40%) in flight duration. This work not only provides an effective metamaterial enhancement design strategy, but also promotes the practical application of large-scale 3D printed metamaterial in the field of micro unmanned aerial vehicle. (C) 2021 The Author(s). Published by Elsevier Ltd.

Automated summary

This study introduces a microlattice strengthening strategy based on a dual-phase mechanism and successfully manufactures a large-scale OCT-BCC lattice metamaterial, which is integrated into a micro aerial vehicle, resulting in a significant increase in flight duration.