为优雅失效设计复合材料

A. Micheal, Y. Bahei-El-din, Mahmoud E. Abd El-Latief
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引用次数: 0

摘要

在不可避免的情况下,复合材料层压板的故障最好是优雅地发生,以避免财产损失和可能的生命损失。虽然固有的不均匀性导致损伤相关能量耗散缓慢,但整体破坏是以纤维为主的,并且以相当脆的方式发生。多向层通常具有更强的延展性。此外,刚度和强度以及成本是设计复合材料层压板时需要考虑的重要因素。因此,在保持合理失效的同时,实现高力学性能和低成本的优化是非常必要的。采用混合系统和分层设计复合材料层压板,允许逐渐的损伤能量耗散,是本工作中提出的两种优化机械性能同时避免灾难性失效的方法。在混合系统设计中,将较便宜的玻璃增强层与碳增强层结合在一起,可以提供一种具有成本效益的产品,边际力学性能发生变化,并且在失效时具有延展性。在不影响极限载荷的情况下,混合玻璃/碳复合材料层压板在三点弯曲下的破坏应变是碳复合材料试样的两倍。建筑层压板也创造了能量耗散机制,通过在内部层的纤维中引入切割,故意使其不连续。这在切割下一层之前造成了更长的损坏路径,导致双重破坏应变,载荷边际减少。光纤不连续性在间距和分布方面的影响是考虑的因素之一。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Designing Composites for Graceful Failure
When inevitable, failure in composite laminates is preferred to occur gracefully to avoid loss of property and possibly life. While the inherent inhomogeneity leads to slow dissipation of damage-related energy, overall failure is fiber-dominated and occurs in a rather brittle manner. Multidirectional plies usually give a more ductile response. Additionally, stiffness and strength as well as cost are important factors to consider in designing composite laminates. It is hence desirable to optimize for high mechanical properties and low cost while keeping graceful failure. Designing composite laminates with hybrid systems and layups, which permit gradual damage energy dissipation, are two ways proposed in this work to optimize for mechanical properties while avoiding catastrophic failure. In the hybrid system design, combining the less expensive glass reinforced plies with carbon reinforced plies offers a cost-effective product, marginal mechanical properties change and ductile profile upon failure. Hybrid glass/carbon composite laminates subjected to three-point bending showed strain to failure which is double that measured for carbon composite specimens, without affecting the ultimate load. Energy dissipation mechanisms were also created by building laminates which were intentionally made discontinuous by introducing cuts in the fibers of the interior plies. This created a longer path for damage before cutting through the next ply resulting in double failure strain with marginal reduction in load. The effect of fiber discontinuity in terms of spacing and distribution are among the factors considered.
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