Low-velocity impact resistance behaviors of bionic double-helicoidal composite laminates

Abstract

To improve the low-velocity impact resistance of composite laminates, a bionic double-helicoidal composite laminate (BDHCL) emulated from the micro-structure of coelacanth scales is proposed. The micro-structure is a double helicoidal Bouligand structure in which two adjacent collagen layers are arranged into an orthogonal bilayer and then rotating at a small helix angle. Three types of helicoidal configurations with different derivatives are designed, including sine rotation angle (SRA), linear rotation angle (LRA), and exponential rotation angle (ERA). The progressive intra-laminar and inter-laminar damage model is adopted to capture the failure behaviors of material. The impact behaviors of BDHCLs with several helix angles and included angles of the bilayer are studied. The results show that the double-helicoidal Bouligand structure has a higher resistance load and shallower penetration depth. The impact resistance of ERA laminate has the maximum improvement among the above three types of helix angle. A certain included angle of bilayer for the BDHCL will exhibit excellent impact resistance.