The effects of ply clustering positions and orientations on multi‐directional composite laminates' low velocity impact resistance.

In this paper, nine different carbon fiber laminates containing clusters are designed using the ant colony ACO algorithm, which have similar equivalent bending stiffnesses and B‐matrices, with the differences being the fiber orientation of the clusters and the position of the clusters in the laminates. The dynamic mechanical characterization of laminates for low velocity impact (LVI) at three different energies was carried out by means of a falling weight impact experiment. The experimental results show that the main form of failure of the laminate is delamination failure at low energy impacts, and shear fracture becomes more and more obvious with the elevation of the impact energy, which was observed in detail by the stereo microscope and electron microscope. The damage area of the laminate and the force and displacement curves after 30 J energy impact were compared by x‐ray scanning to derive the effects of the angle of the ply cluster fibers and the different positions of the ply clusters in the laminate on the impact resistance of the laminate. In conclusion, when designing the laminate, consideration should be given to designing 45° clusters on the impacted side and 90° clusters in the middle layer of the laminate to obtain the best impact resistance. Highlights: Designed 9 types of laminates with different laminate structures based on ACO algorithm.Different laminates have similar equivalent bending stiffnesses and the B matrix as close to 0 as possible.LVI tests at three energies were performed on 9 types of laminates.The effects of different orientations of the clusters and the position of the clusters in the laminate on the impact resistance of the laminate were investigated. [ABSTRACT FROM AUTHOR]