用于旋翼飞机部件的玻璃体复合材料

Mithil Kamble, N. Koratkar, C. Picu
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引用次数: 0

摘要

碳纤维增强复合材料(CFRP)由于其高强度重量比而经常用于旋翼飞机部件。碳纤维是主要的载荷载体,而聚合物基体为CFRP组件提供了结构完整性。源自基体的疲劳破坏是碳纤维增强材料构件设计的制约因素。疲劳破坏以小尺度亚临界裂纹的形式开始,最终发展为宏观裂纹/剪切局部化导致最终破坏。通过抑制初期裂纹来改善聚合物基体的断裂和疲劳性能是目前研究的方向。热固性聚合物由于交联密度高而具有优异的强度,被广泛用作基体材料。然而,由于热固性材料中没有自愈机制,因此在部件的整个生命周期中,损伤是不可逆转的积累。一类被称为玻璃体的新材料为开发抗疲劳碳纤维增强材料提供了一种新方法。Vitrimers是一种结合共价自适应网络(CAN),具有可逆的交联反应,可被热等外部能量刺激激活。由于交联网络是可逆的,初期的损伤可以通过加热“愈合”。本文研究了己二酸与环氧树脂反应制备的玻璃体的自愈性能。首先对玻璃体进行静态试验,以探测其力学性能,然后进行疲劳试验。然后用玻璃体制成玻璃体CFRP (vCFRP)复合材料,并对其静态和疲劳性能进行测试。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Vitrimer Composites for Rotorcraft Components
Carbon fiber reinforced composites (CFRP) are frequently used in rotorcraft components due to their high strength to weight ratio. Carbon fibers are the principal load carriers whereas polymer matrix provides structural integrity to the CFRP components. Fatigue failure originating in the matrix pose a design constraint on CFRP components. The fatigue failure originates in form of small scale sub-critical cracks which eventually grow into macroscopic cracks/shear localization resulting in eventual failure. Research efforts have been directed at improving fracture and fatigue performance of polymeric matrix by arresting incipient cracks. Thermoset polymers are widely used as matrix material as they posses superior strength due to high crosslinking density. However, since no self-healing mechanism operates in thermosets, damage is irreversibly accumulated over the life cycle of components. A new class of materials called vitrimers provide a novel approach to develop fatigue resistant CFRP. Vitrimers are associative covalent adaptive networks (CAN) which have reversible crosslinking reactions which can be activated by external energy stimulus like heat. As the crosslinked network is reversible, the incipient damage can be 'healed' by application of heat. In this work we explore the self-healing properties of vitrimer fabricated by the reaction of adipic acid and epoxy resin. The vitrimer is initially tested in static tests to probe mechanical properties, followed by fatigue experiments. The vitrimer is then used to make a vitrimeric CFRP (vCFRP) composite and is tested for its static and fatigue performance.
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