Effect of lamination sequence and warhead shape on impact resistance of fiber‐metal laminates

A detailed experimental investigation was carried out for the high‐velocity ballistic response of AA 1100‐H14 based carbon‐fiber metal laminates (FMLs). FMLs with different metal volume fractions and the same thickness of carbon‐epoxy fiber laminates were tested to examine the surface and internal damage. The ballistic performance parameters, namely % escalation in absorbed energy, specific energy absorbed, ballistic limit, specific perforation energy, first cracking energy, and global deformation profile, were studied and a comparison was drawn with pure carbons fiber reinforced epoxy composite laminates. Despite having greater thickness, pure carbon fiber‐reinforced epoxy composite laminates absorbed less impact energy than FMLs and failed catastrophically. For FMLs, the % escalation in the absorbed energy and the specific energy absorption kept increasing with the increasing impact velocity until the onset of perforation. Once the perforation started, both these parameters showed a decreasing trend. Thick FMLs absorbed a good amount of energy, leading to projectile recoil suffering minimal damage. The ballistic velocity, specific perforation energy, and first cracking energy on the front and rear face of FMLs layers showed an increasing trend. The minimum for the thinner and maximum for the thicker FMLs attributed to the large thickness and more metal volume fraction. Contrary to the large deformation of the impacting points, pure carbon fiber‐reinforced epoxy composite laminates showed very minimal deformation as compared to FMLs. The brittle nature of the epoxy resin resisted the deformation to a large extent leading to less energy absorption.Highlights High‐velocity ballistic response of AA 1100‐H14 based carbon‐FMLs was investigated. Ballistic performance parameters of FMLs were studied and was compared with carbons fiber reinforced composite laminates. The ballistic limit of FMLs showed a direct dependence its thickness and metal volume fraction. In the absence of any metallic layer, pure carbons fiber reinforced composite laminates absorbed less impact energy.

Section: Research Gap Addressed In the Papermentioning

confidence: 99%

High‐velocity ballistic response of AA 1100‐H14 based carbon‐fiber metal laminates: An experimental investigation

Jamsheed,

Rashid,

Velmurugan

2023

Effect of symmetric and asymmetric aluminum arrangements on the low‐velocity impact performance of glass fiber‐reinforced aluminum laminate (GLARE)

Zhang,

Wang,

Wang

et al. 2023

Glass fiber‐reinforced aluminum laminate (GLARE) possesses superior impact performance than both metal and fiber‐reinforced composite. It was found previously that the low‐velocity impact (LVI) performance of GLARE is governed by aluminum at different locations. This implies that reasonably rearranging aluminum in GLARE may bring in some improvements if the functions of different aluminum are all fully played. In this view, the effect of aluminum arrangement on the LVI performance of GLARE was investigated by separately comparing eight symmetric and eight asymmetric GLARE. Finite element analysis was adopted due to its advantage in quantitatively capturing the detailed damage parameters, and it was verified by LVI tests under different impact energy. The LVI performance was elucidated from both impact resistance and energy absorption aspects, where the former included the force and damage responses, and the latter involved the energy absorbed ratio and absorption efficiency. Based on the mechanical and damage parameters, impact resistance and energy absorption factors were proposed for comprehensive characterization. It revealed that arranging aluminum symmetrically in GLARE by placing thinner aluminum in the middle is an effective way to improve its LVI performance.Highlights Aluminum arrangement influenced evidently on the low‐velocity impact (LVI) damage degrees of glass fiber‐reinforced aluminum laminate (GLARE). Impact resistance and energy absorption factors were quantitively defined. Symmetric GLARE with thinner middle aluminum had superior LVI performance. Optimal aluminum arrangement could be simply estimated by energy dissipation.

Impact resistance performance and structural optimization of lightweight composite target plate

Zhou,

Zheng

2024

The finite element model of a 7.62 mm armor‐piercing incendiary bomb penetrating lightweight composite target is established. The structure of the target plate is composed of boron carbide ceramic/carbon fiber laminate/aramid fiber laminate/damping material. The reasonable distribution position of damping material is explored by designing the material structure and geometric parameters. Genetic algorithm is used to optimize the structure of the lightweight composite target plate, and the feasibility of the optimization results is verified through experiments. The results show that under the same surface density, the energy absorption value of the target plate with a certain thickness of back layer damping is 1.36% higher than that of the target plate without damping. And the damping material on the back layer can act as a buffer layer to reduce blunt trauma caused by bullets to the human body. The surface density of the optimized lightweight composite target plate is reduced by 21.6% under the same protection capability. This work provides a theoretical foundation for the impact resistance design and optimization of lightweight composite target plates.Highlights Impact resistance performance of lightweight composite target plate is investigated. The impacting analytical model of the structure is established. The validity of the optimized impacting analytical model is verified by numerical simulation.