Properties of Hyper-Elastic-Graded Triply Periodic Minimal Surfaces

The mechanical behaviors of three distinct lattice structures-Diamond, Gyroid, and Schwarz-synthesized through vat polymerization, were meticulously analyzed. This study aimed to elucidate the intricacies of these structures in terms of their stress-strain responses, energy absorption, and recovery characteristics. Utilizing the described experiments and analytical approaches, it was discerned, via the described experimental and analytical procedure, that the AM lattices showcased mechanical properties and stress-strain behaviors that notably surpassed theoretical predictions, pointing to substantial disparities between conventional models and experimental outcomes. The Diamond lattice displayed superior stiffness with higher average loading and unloading moduli and heightened energy absorption and dissipation rates, followed by the Gyroid and Schwarz lattices. The Schwarz lattice showed the most consistent mechanical response, while the Diamond and Gyroid showed capabilities of reaching larger strains and stresses. All uniaxial cyclic compressive tests were performed at room temperature with no dwell times. The efficacy of hyper-elastic-graded models significantly outperformed projections offered by traditional Ashby-Gibson models, emphasizing the need for more refined models to accurately delineate the behaviors of additively manufactured lattices in advanced engineering applications.

Automated summary

The mechanical behaviors of three lattice structures-Diamond, Gyroid, and Schwarz synthesized through vat polymerization were analyzed to understand their stress-strain responses, energy absorption, and recovery characteristics. The experimental results showed that the AM lattices exhibited mechanical properties that surpassed theoretical predictions, indicating differences between conventional models and experimental outcomes. The Diamond lattice displayed superior stiffness and energy absorption rates, while the Schwarz lattice showed consistent mechanical response. The study emphasized the need for refined models to accurately predict the behaviors of additively manufactured lattices in advanced engineering applications.