Litcius/Paper detail

Randomly stacked open cylindrical shells as functional mechanical energy absorber

Tomohiko G. Sano, Emile Hohnadel, Toshiyuki Kawata, Thibaut Métivet, Florence Bertails-Descoubes

2023Communications Materials12 citationsDOIOpen Access PDF

Abstract

Abstract Structures with artificially engineered mechanical properties, often called mechanical metamaterials, are interesting for their tunable functionality. Various types of mechanical metamaterials have been proposed in the literature, designed to harness light or magnetic interactions, structural instabilities in slender or hollow structures, and contact friction. However, most of the designs are ideally engineered without any imperfections, in order to perform deterministically as programmed. Here, we study the mechanical performance of randomly stacked cylindrical shells, which act as a disordered mechanical metamaterial. Combining experiments and simulations, we demonstrate that the stacked shells can absorb and store mechanical energy upon compression by exploiting large deformation and relocation of shells, snap-fits, and friction. Although shells are oriented randomly, the system exhibits statistically robust mechanical performance controlled by friction and geometry. Our results demonstrate that the rearrangement of flexible components could yield versatile and predictive mechanical responses.

Topics & Concepts

MetamaterialMaterials scienceMechanical energyMechanical designMechanical systemDeformation (meteorology)Mechanical strengthCompression (physics)Mechanical engineeringComposite materialStructural engineeringEngineeringOptoelectronicsPhysicsPower (physics)Quantum mechanicsAdvanced Materials and MechanicsCellular and Composite StructuresStructural Analysis and Optimization