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TC4厚度对Ti-AlTi金属-金属间化合物层状复合材料抗穿透行为的影响

Effects of TC4 Thickness on the Penetration Resistance Behavior of Ti-AlTi Metal-Intermetallic Laminated Composites.

作者信息

Wang Yang, Yuan Meini, Zhou Pengfei, Pei Xin, Yang Wei, Tian Zehui

机构信息

School of Aerospace Engineering, North University of China, Taiyuan 030051, China.

School of Mechanical and Electrical Engineering, North University of China, Taiyuan 030051, China.

出版信息

Materials (Basel). 2025 Apr 17;18(8):1846. doi: 10.3390/ma18081846.

DOI:10.3390/ma18081846
PMID:40333485
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12028454/
Abstract

Ti-AlTi metal-intermetallic laminate (MIL) composites with microscale layer thickness have attracted attention in aerospace applications. However, whether millimeter-thick Ti layers can enhance the anti-penetration of Ti-AlTi MIL composites under 400-1000 m/s impact velocities remains unclear. In this study, a Ti-AlTi MIL composite target was prepared by hot press sintering, and the 2D finite element model validated by anti-penetration testing was used to prove that increasing the thickness of the Ti layer significantly increases the stress level and anti-penetration limit of the target. Simulations show that compared with a 0.1 mm Ti layer, a 2.5 mm Ti layer reduces the projectile residual velocity by 100% (600 m/s), 72% (800 m/s), and 38.5% (1000 m/s). With a total thickness difference of 0.1 mm, the crack propagation angles increase by 4° (0.06 mm Ti) and 14° (2.5 mm Ti) compared to a 0.4 mm Ti layer. By analyzing stress wave propagation and energy absorption during penetration, this work reveals that millimeter-thick Ti layers improve anti-penetration performance by controlling heterogeneous interface failure and the crack propagation direction through increased ductile layer thickness. These findings provide data for MIL composites and offer potential cost reductions for high-performance anti-penetration materials.

摘要

具有微米级层厚的钛-铝钛金属间化合物层状(MIL)复合材料在航空航天应用中受到了关注。然而,在400-1000米/秒的冲击速度下,毫米厚的钛层是否能增强钛-铝钛MIL复合材料的抗穿透能力仍不明确。在本研究中,通过热压烧结制备了钛-铝钛MIL复合靶材,并使用经抗穿透测试验证的二维有限元模型来证明增加钛层厚度可显著提高靶材的应力水平和抗穿透极限。模拟结果表明,与0.1毫米厚的钛层相比,2.5毫米厚的钛层可使弹丸残余速度分别降低100%(600米/秒)、72%(800米/秒)和38.5%(1000米/秒)。与0.4毫米厚的钛层相比,在总厚度相差0.1毫米的情况下,裂纹扩展角度分别增加4°(0.06毫米厚的钛层)和14°(2.5毫米厚的钛层)。通过分析穿透过程中的应力波传播和能量吸收,这项工作揭示了毫米厚的钛层通过控制异质界面失效以及通过增加韧性层厚度来控制裂纹扩展方向,从而提高抗穿透性能。这些发现为MIL复合材料提供了数据,并为高性能抗穿透材料提供了潜在的成本降低方案。

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