Design and Energy Absorption Study of an Asymmetric Windmill‐Style Negative Poisson's Ratio Honeycomb Structures

The negative Poisson's ratio (NPR) structure, as one of the representatives of advanced lightweight honeycomb materials, has good application prospects in aerospace, vehicles, biomedical, and other fields due to its unique deformation mechanism and huge energy absorption potential. In this article, a 2D asymmetric windmill‐style composite honeycomb (AWH) with NPR effects is presented and its compression properties are systematically assessed using both axial compression experiments and simulations. Through the experimental results, the accuracy and applicability of the finite‐element model are verified, indicating that the shape of the rotating arrangement and the stable internal design of the triangle make it have significantly higher energy absorption capacity than traditional symmetric reentrant honeycomb structures. In addition, the influence of the height, width, and cell spacing of asymmetric unit cell indentation points on the compression characteristics of AWH under axial quasi‐static compression conditions is further analyzed through orthogonal simulation experiments. In this study, a certain theoretical basis for the design and energy absorption application of NPR materials is provided, indicating that AWH has excellent mechanical properties and broad application prospects.