Numerical analysis of vhcf cruciform test specimens with non-unitary biaxiality ratios

Q4 Engineering
D. Montalvão, Attila Blaskovics, P. Costa, L. Reis, M. Freitas
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引用次数: 8

Abstract

With the development of new materials, it is now known that there is no such thing as a fatigue endurance limit, i.e., materials do not have infinite life when the stress level is such that there is no fracture up to 10 million (1E7) cycles. The problem of testing materials above this number of cycles is that most testing equipment operates well below 150 Hz, making testing up to 1 billion (1E9) cycles or above an impracticality. The recent developments of ultrasonic testing machines where frequencies can go as high as 20 kHz or above enabled tests to be extended to these ranges in just a few days. This is now known as Very High Cycle Fatigue (VHCF). On the other hand, critical components used in Engineering applications are usually subjected to multi-axial loads, as is the case of the fuselage and wings of aircrafts which are subjected to biaxial states of stress. In this paper, VHCF cruciform test specimens purposely designed to develop orthogonal biaxial stresses with different biaxiality ratios will be analysed. The specimens are composed from Aluminium 6082-T651, a medium strength alloy used in many highly stressed engineering applications, including trusses, cranes, bridges and transportation. The specimens work as tuning forks with determined mode shapes at 20±0.5 kHz, where maximum principal stresses are developed at the centre of the specimen. Finite Element Analysis (FEA) is used to assess the dynamic behaviour of the specimens. The framework on how to design and manufacture cruciform specimens with different biaxiality ratios will be explained in a clear way so it can be used by other engineers in the field.
具有非一元双轴比的vhcf十字试件的数值分析
随着新材料的发展,人们现在已经知道,疲劳耐久性极限是不存在的,也就是说,当应力水平达到1000万(1E7)次循环时,材料不会有无限的寿命。测试超过这个周期数的材料的问题是,大多数测试设备运行远低于150 Hz,使得测试高达10亿(1E9)周期或更高是不切实际的。超声波测试仪的最新发展,频率可以高达20千赫或以上,使测试可以在短短几天内扩展到这些范围。这就是现在所说的甚高循环疲劳(VHCF)。另一方面,工程应用中使用的关键部件通常承受多轴载荷,如飞机的机身和机翼承受双轴应力状态的情况。本文将对设计成具有不同双轴比的正交双轴应力的VHCF十字形试件进行分析。样品由铝6082-T651组成,这是一种中等强度的合金,用于许多高应力工程应用,包括桁架,起重机,桥梁和运输。在20±0.5 kHz的频率下,样品作为音叉工作,其中最大主应力在样品的中心发展。有限元分析(FEA)用于评估试件的动力性能。关于如何设计和制造不同双轴比的十字形试样的框架将以清晰的方式解释,以便其他工程师在现场使用。
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
CiteScore
1.10
自引率
0.00%
发文量
24
审稿时长
33 weeks
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