A 3D Mechanism-driven Hexagonal Metamaterial: Evaluation of Auxetic Behavior

This paper investigates an unconventional 3D printable auxetic metamaterial realized by a unique sliding mechanism. The concept of 3D sliding induced hexagonal auxetic (SIHA) metamaterial is proposed with stable auxetic behavior and improved compression load response, as compared with the conventional re-entrant structure. For a single SIHA lattice cell, the theoretical model concerning the sliding mechanism is developed and verified by both finite element analysis (FEA) and experiment. Furthermore, the compression properties of the periodic SIHA structure are evaluated by FEA with experimental verification. A 3D conventional re-entrant honeycomb (REH) structure is adopted for comparison. It is shown that the FEA results agree with the experimental results, and overall superior performance of SIHA structure is obtained, which is reflected by higher compression resistance and more stable auxetic behavior. Moreover, the sensitivity of performance with respect to the friction coefficient in the sliding mechanism is investigated. It is found that the performance and auxetic behavior of the SIHA metamaterial is sensitive to the friction condition. Force-strain curve increases with the input friction coefficient, while an excessive friction coefficient may cause undesirable effects on the slip mechanism. Overall, the friction sliding and collapsing structural mechanism-driven structures could provide a new way to entrap elastic energy under compression deformations.

Automated summary

This paper introduces a stable 3D sliding-induced hexagonal auxetic metamaterial concept, demonstrating higher compression resistance and stable auxetic behavior through theoretical modeling, finite element analysis, and experimentation. Additionally, the sensitivity of performance and auxetic behavior to the friction coefficient in the sliding mechanism is investigated.