氧化铝芯纤维金属层压板材料结构对抗弯强度的影响

Q4 Engineering

Fatigue of Aircraft Structures Pub Date : 2023-02-13 DOI:10.2478/fas-2022-0003

Mariusz Frankiewicz, M. Karoluk, R. Dziedzic, Tristan Timmel, P. Scholz

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引用次数: 0

摘要

金属纤维层压板(FMLs)由PA6聚酰胺预涂料和玻璃和碳纤维增强以及铝合金芯制成的层组成，是其他类型航空航天FML材料(如眩光或CARALL)的新变种。通过使用热塑性基质，它们可以通过冲压工艺成形，这使得生产过程比传统的层压方法(如真空袋装)更有效。除了提高冲击能量吸收效率外，金属芯还可以有效地将复合材料部件粘合到相邻的金属结构上。本文介绍了由连续的纤维增强热塑性外层和金属铝合金内嵌层(层数、增强纤维的类型和方向)组成的纤维-金属层合板的材料结构对其静态和疲劳弯曲性能的影响。在本研究中，采用一步变温固结工艺制备了8种层压结构。结果表明:在三点弯曲疲劳试验中，试样在应力<30%的静态弯曲强度下，循环次数超过106次;纵向增强层为主的层压板在FML样品中显示出最高的疲劳强度。增强纤维的种类和层数对分析的力学性能影响较小。

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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The Influence of Material Configuration of Fibre-Metal Laminates with Alumina Core on Flexural Strength

Abstract Fibre metal laminates (FMLs) consisting of layers made of PA6 polyamide prepregs reinforced with glass and carbon fibres and an aluminium alloy core are the new variant of the other types used by aerospace FML materials such as GLARE or CARALL. By using a thermoplastic matrix, they can be shaped by stamping processes, which allows for a more efficient production process than classical laminating methods such as vacuum bagging. In addition to the improved impact energy absorption efficiency, the metallic core can be utilised to effectively bond the composite part to adjacent metallic structures. This article presents the influence of the material configuration of fibre-metal laminates consisting of continuous fibre-reinforced thermoplastic outer layers integrated with a layer of metallic aluminium alloy inserts—a number of layers, type and direction of reinforcing fibres—on the static and fatigue flexural properties. In this study, eight laminate configurations were prepared using a one-step variothermal consolidation process. The results showed that in the three-point flexural fatigue test, the samples exceeded 106 cycles at stresses <30% of the static bending strength. Laminates with predominantly longitudinally reinforced layers showed the highest fatigue strength among the FML samples analysed. The type of reinforcing fibres and the number of layers were less affected on the analysed mechanical properties.

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来源期刊

Fatigue of Aircraft Structures Engineering-Safety, Risk, Reliability and Quality

CiteScore

0.40

自引率

0.00%

发文量

期刊介绍： The publication focuses on problems of aeronautical fatigue and structural integrity. The preferred topics include: full-scale fatigue testing of aircraft and aircraft structural components, fatigue of materials and structures, advanced materials and innovative structural concepts, damage tolerant design of aircraft structure, life extension and management of ageing fleets, structural health monitoring and loads, fatigue crack growth and life prediction methods, NDT inspections, airworthiness considerations.