# Impact Response Features and Penetration Mechanism of UHMWPE Subjected to Handgun Bullet

**Authors:** Yihui Zhu, Yang Song, Wei Wu, Jie Ma, Zhuangqing Fan, Yaoke Wen, Cheng Xu, Min Xia, Weifeng Da

PMC · DOI: 10.3390/polym16101427 · 2024-05-17

## TL;DR

This study examines how UHMWPE laminates respond to handgun bullets, revealing damage patterns and energy conversion to improve protective gear for military and police personnel.

## Contribution

The study introduces a numerical method to analyze UHMWPE's impact response and energy conversion during bullet penetration.

## Key findings

- Bullet penetration caused cross-shaped failure due to fiber compression and aggregation.
- Maximum in-plane shear strain occurred at ±45° with values of 0.0904 and −0.0928.
- Most erosion energy occurred in the first four sublaminates, with major energy change at 75 μs in the fourth sublayer.

## Abstract

Ensuring military and police personnel protection is vital for urban security. However, the impact response mechanism of the UHMWPE laminate used in ballistic helmets and vests remains unclear, making it hard to effectively protect the head, chest, and abdomen. This study utilized 3D-DIC technology to analyze UHMWPE laminate’s response to 9 mm lead-core pistol bullets traveling at 334.93 m/s. Damage mode and response characteristics were revealed, and an effective numerical calculation method was established that could reveal the energy conversion process. The bullet penetrated by 1.03 mm, causing noticeable fiber traction, resulting in cross-shaped failure due to fiber compression and aggregation. Bulge transitioned from circular to square, initially increasing rapidly, then slowing. Maximum in-plane shear strain occurred at ±45°, with values of 0.0904 and −0.0928. Model accuracy was confirmed by comparing strain distributions. The investigation focused on bullet-laminate interaction and energy conversion. Bullet’s kinetic energy is converted into laminate’s kinetic and internal energy, with the majority of erosion energy occurring in the first four equivalent sublaminates and the primary energy change in the system occurring at 75 μs in the fourth equivalent sublayer. The results show the damage mode and energy conversion of the laminate, providing theoretical support for understanding the impact response mechanism and improving the efficiency of protective energy absorption.

## Full-text entities

- **Chemicals:** lead (MESH:D007854), UHMWPE (MESH:C111601)

## Figures

33 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11124957/full.md

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Source: https://tomesphere.com/paper/PMC11124957