研究复合材料在汽车应用中的显著阻尼响应

1, 2024 Pub Date : 2024-03-06 DOI:10.46632/jacp/3/1/2
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引用次数: 0

摘要

通过对复合材料部件的检查,工程师和制造商可以加深对失效标准、初始失效的起因以及层压板内部损伤扩展的理解。本研究深入探讨了冲击引起的退化演变,并为三种不同的复合材料类别确定了力或赫兹失效阈值的上限。冲击研究表明,与静态冲击条件相比,复合材料在动态冲击条件下的强度显著增加,这突出表明了材料对加载速率的敏感性。复合材料在装甲平台实现有效弹道防护方面发挥着至关重要的作用,因为根据其预期应用,它们必须承受不同能量水平的物理载荷。精确的设计和制造是针对不同能量冲击提供充分保护的必要条件:维护和操作过程中工具产生的低能量冲击、外部元素撞击表面产生的中等能量冲击以及武器产生的高能量冲击。纤维增强复合材料因其出色的比强度、减重优势和易制造性,在航空、航海和陆地工业中得到广泛应用。它们在航空航天和军事应用中尤为重要。在许多玻璃纤维应用中,聚酯树脂是环氧树脂的一种成本效益高且易于成型的替代品。本研究旨在探索 E 玻璃复合材料的低速冲击特性,与其他增强复合材料相比,E 玻璃复合材料更容易获得,成本效益更高。研究重点是通过测试三种不同的样品来评估这些材料的冲击特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigation of Composite Materials for Significant Damping Response in Automotive Applications
Through the examination of composite components, engineers and manufacturers can enhance their understanding of failure criteria, the initiation of initial failures, and the propagation of damage within laminates. This study delves into the evolution of impact-induced degradation and establishes upper limits on force or Hertz failure thresholds for three distinct composite categories. Impact investigations reveal that the strength of composite materials significantly increases under dynamic impact conditions compared to static ones, underscoring the material's sensitivity to loading rates. Composite materials play a crucial role in achieving effective ballistic protection for armor platforms, given the varying energy levels of the physical loads they must withstand based on their intended applications. Precise design and manufacturing are necessary to provide adequate protection against impacts of different energies: low-energy impacts from tools during maintenance and operations, intermediate-energy impacts from external elements striking the surface, and high-energy impacts from weapons. Fiber-reinforced composite materials find widespread use across the aviation, marine, and terrestrial industries due to their outstanding specific strength, weight reduction benefits, and ease of manufacturing. They are particularly crucial in aerospace and military applications. Polyester resins offer a cost-effective and easily moldable alternative to epoxy resins in many fiberglass applications. This study aims to explore the low-velocity impact characteristics of E-Glass composites, which are more readily available and cost-effective compared to other reinforced composites. The research focuses on evaluating the impact properties of these materials through testing three different samples.
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