Crushing behavior and energy absorption of node self-locked Kagome honeycomb

This work proposes a self-locked Kagome honeycomb (SLKH) structure to realize better balance between energy absorption and cost efficiency. The structure uses a simple and creative bending preparation method to form a triangle nested self-locking pattern with distinct layers, rich shapes, easy assembly, flexibility and efficiency. The quasi-static experiments and numerical simulations are employed to investigate the energy absorption behavior and dynamic response. Numerical analysis is conducted to reveal the influence of cell size, angle at the connecting plate, and number of bent plates on the energy absorption performance of SLKH. Additionally, a theoretical estimation model for mean crushing force of SLKH structure is established, providing guidance for efficient parameter design and selection. The results demonstrate that the SLKH exhibits superior energy absorption performance with low cost.