High‐velocity impact resistance and energy absorption behavior of Carbon‐Kevlar hybrid composite laminates

Sun, Jianbo; Wang, Chao; Zhao, Sai; Cao, Junchao; Yin, Liang; Liu, Yongjiao; Yang, Zhiyong; Yi, Kai; Huang, Jia; Zhang, Chao

doi:10.1002/pc.27820

Polymer Composites

2023

DOI: 10.1002/pc.27820

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High‐velocity impact resistance and energy absorption behavior of Carbon‐Kevlar hybrid composite laminates

Jianbo Sun,

Chao Wang,

Sai Zhao

et al.

Abstract: This study investigated the high‐velocity impact behavior of composite plates with different hybrid ratios and structural configurations through experimental and numerical simulation studies. The results showed that the critical penetration velocity of the composite plate generally increases with an increase in the volume fraction of aramid fibers. The high‐velocity impact finite element model developed in this study accurately simulated the high‐velocity impact behavior of laminated fiber composite plates wit… Show more

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2024

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Cited by 4 publications

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High‐velocity impact behavior of nonwoven mats and unidirectional prepreg hemp and flax fibers reinforced hybrid biocomposites

Baysal,

Turkmen,

Yayla

2024

Polymer Composites

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High specific impact strength and stiffness are demanded in various applications, leading to the widespread utilization of fiber‐reinforced polymers. Synthetic fiber‐reinforced polymers have been used to meet these engineering requirements. However, the current popularity of biocomposites arises from their environmental friendliness, ease of availability, and affordability, making them a favored alternative to synthetic‐based fiber‐reinforced polymers. An assessment must be conducted to determine whether biocomposites can replace their synthetic fiber counterparts, necessitating a thorough investigation into their impact behavior. This study aims to unveil the impact performance of hybrid biocomposites made from unidirectional prepregs comprising flax/polypropylene fibers and nonwoven mats composed of hemp/polypropylene fibers. The impact performance of hybrid biocomposites has also been studied concerning the number of layers and stacking sequence. Eight different designs of biocomposite plates are manufactured through compression molding and subsequently subjected to high‐velocity impact tests. Additionally, numerical simulation using the FEM is utilized to model and analyze the impact behavior of one specimen. The test results indicate that each design possesses unique characteristics and impact behaviors differ.Highlights Adding prepreg significantly improved mechanical performance in the biocomposites. Performance enhancement varies depending on the stacking sequence. Adding multiple layers of UD prepregs enhances mat impact performance. Numerical simulations validate the Tsai‐Wu criterion for impact testing.

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High‐velocity impact behavior of nonwoven mats and unidirectional prepreg hemp and flax fibers reinforced hybrid biocomposites

Baysal,

Turkmen,

Yayla

2024

Polymer Composites

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show abstract

Investigation of energy absorption in epoxy-based Aramid fabrics -Basalt hybrid composites under oblique high velocity impact

Rahmani,

Kazemian,

Imanparast

2024

Polym. Bull.

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Machine learning approach to evaluating impact behavior in fabric-laminated composite materials

Hiremath,

Zhang,

Zhang

et al. 2024

Results in Engineering

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High‐velocity impact resistance and energy absorption behavior of Carbon‐Kevlar hybrid composite laminates

Cited by 4 publications

References 46 publications

High‐velocity impact behavior of nonwoven mats and unidirectional prepreg hemp and flax fibers reinforced hybrid biocomposites

High‐velocity impact behavior of nonwoven mats and unidirectional prepreg hemp and flax fibers reinforced hybrid biocomposites

Investigation of energy absorption in epoxy-based Aramid fabrics -Basalt hybrid composites under oblique high velocity impact

Machine learning approach to evaluating impact behavior in fabric-laminated composite materials

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