3D printed hierarchical re-entrant honeycombs: Enhanced mechanical properties and the underlying deformation mechanisms

Re-entrant honeycombs are one type of lightweight cellular materials with superior energy absorption and impact resistance. Yet, the mechanical properties of re-entrant honeycombs need to be further improved due to its bending-dominated deformation mechanism. In this study, we designed a novel stretching-dominated re-entrant honeycomb by combining the structural hierarchy and auxetic cellular configurations. Such hierarchical re-entrant honeycomb (H-ReH) is manufactured through fine-resolution 3D printing technique. The mechanical behavior and deformation mechanism of the designed H-ReH has been investigated through combined digital image correlation and finite element simulation. The 3D-printed H-ReHs exhibit enhanced specific stiffness, specific initial-buckling strength, structural stability and specific energy absorption capacity due to the uniquely combined deformation mechanisms. A competition between the 1st order and the 2nd order hierarchy has been revealed, which governs the mechanical properties of the H-ReHs. These findings provide thorough un-derstandings and facilitate future design of lightweight but robust cellular materials.

Automated summary

In this study, a novel stretching-dominated re-entrant honeycomb (H-ReH) was designed by combining structural hierarchy and auxetic cellular configurations. The mechanical behavior and deformation mechanism of H-ReH were investigated using digital image correlation and finite element simulation. The results showed that the 3D-printed H-ReH exhibited enhanced specific stiffness, initial-buckling strength, structural stability, and energy absorption capacity due to the uniquely combined deformation mechanisms.