Low velocity impact resistance of hybrid CFRP‐elastomer‐metal laminates: Influence of stacking sequence and impact conditions on damage mechanisms

IF 4.8 2区 材料科学 Q2 MATERIALS SCIENCE, COMPOSITES
Zhongyu Li, Alexander Jackstadt, Junyuan Zhang, Wilfried V. Liebig, Luise Kärger
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Abstract

Fiber‐metal laminates (FMLs) are generally regarded as excellent lightweight materials for advanced structure design. To enhance the mechanical properties, the common FMLs can be optimized using carbon fibers. However, the combination of carbon fibers with aluminum induces interfacial challenges. Preventing galvanic corrosion with elastomeric interlayers is an effective solution. The lay‐up configuration greatly effects the impact damage resistance of hybrid CFRP‐elastomer‐metal laminates (HyCEMLs). In this work, micro‐CT scans and optical micrographic inspections on HyCEMLs are conducted after impact tests to ascertain the microstructural origins behind the mechanical performance changes. In addition, finite element models of different HyCEML configurations are built to complement the limited experimental data. The damage mechanisms of HyCEML with different configurations under various impact conditions are further compared. The numerical results suggest that impact energy is a more informative measure in terms of damage mode and size than impact velocity and momentum. Results also indicate that when the thickness for each sub‐laminate of HyCEML is maintained the same, hybrid laminates with aluminum stacked outside is beneficial for delaying the occurrence of matrix cracking and delaminations, and enhances HyCEML's resistance to global deformation. These findings will contribute to engineering hybrid laminates with desired impact performance for lightweight load‐bearing structures.Highlights The hybrid laminate with elastomeric interlayers is a forward‐looking solution in impact applications. Impact energy is a more informative measure in terms of assessing the damage mode and extent in HyCEMLs. The influence of stacking sequence on damage mechanisms of HyCEMLs is evaluated. Microstructural origins behind variations of hybrid laminates in the impact resistance are revealed.

Abstract Image

混合 CFRP-弹性体-金属层压板的低速抗冲击性能:堆叠顺序和冲击条件对损坏机制的影响
纤维-金属层压板(FML)通常被认为是用于先进结构设计的优秀轻质材料。为了提高机械性能,可以使用碳纤维对普通 FML 进行优化。然而,碳纤维与铝的结合会带来界面难题。使用弹性夹层防止电化学腐蚀是一种有效的解决方案。层叠结构对 CFRP-弹性体-金属混合层压板(HyCEML)的抗冲击破坏性有很大影响。本研究在冲击试验后对 HyCEML 进行了显微 CT 扫描和光学显微照片检查,以确定机械性能变化背后的微观结构根源。此外,还建立了不同 HyCEML 配置的有限元模型,以补充有限的实验数据。进一步比较了不同配置的 HyCEML 在各种冲击条件下的损坏机制。数值结果表明,与冲击速度和动量相比,冲击能量是衡量损坏模式和损坏大小的更有参考价值的指标。结果还表明,当 HyCEML 每个子层压板的厚度保持不变时,外层叠加铝的混合层压板有利于延迟基体开裂和分层的发生,并增强 HyCEML 的抗整体变形能力。这些研究结果将有助于为轻质承重结构设计具有理想冲击性能的混合层压板。在评估 HyCEML 的损坏模式和程度方面,冲击能量是一种更有参考价值的测量方法。评估了堆叠顺序对 HyCEML 损伤机制的影响。揭示了混合层压板抗冲击性能变化背后的微观结构根源。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Polymer Composites
Polymer Composites 工程技术-材料科学:复合
CiteScore
7.50
自引率
32.70%
发文量
673
审稿时长
3.1 months
期刊介绍: Polymer Composites is the engineering and scientific journal serving the fields of reinforced plastics and polymer composites including research, production, processing, and applications. PC brings you the details of developments in this rapidly expanding area of technology long before they are commercial realities.
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