Evaluation of Early-Stage Fatigue Damage in Metal Plates Using Quasi-Static Components of Low-Frequency Lamb Waves

IF 2 Q2 ENGINEERING, MULTIDISCIPLINARY
Kun Wu, Caibin Xu, Mingxi Deng
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Abstract

Abstract Nonlinear Lamb waves including second harmonic and acoustic-radiation-induced quasi-static components (QSC) have a potential for accurately evaluating early-stage fatigue damage. Most previous studies focus on second-harmonic-based techniques that require phase velocity matching and are hard to isolate interferences from ultrasonic testing systems. The aforementioned requirement and deficiency limit applications of the second-harmonic-based techniques. In this study, a QSC-based technique of low-frequency Lamb waves is proposed for early-stage fatigue damage evaluation of metal plates, which does not need to require phase velocity matching and can remove interferences from ultrasonic testing systems. Both in simulations and in experiments, the primary Lamb wave mode at a low frequency that meets approximate group velocity matching with the generated QSC is selected. In finite element simulations, different levels of material nonlinearities by changing the third-order elastic constants are used to characterize levels of fatigue damage. Numerical results show that the magnitude of the generated QSC pulse increases with the levels of fatigue damage. Early-stage fatigue damage in aluminum plates with different fatigue cycles is further experimentally evaluated. The generated QSC pulse is extracted from received time-domain signals using the phase-inversion technique and low-pass digital filtering processing. The curve of the normalized relative acoustic nonlinearity parameter versus the cyclic loading number is obtained. Numerical simulations and experimental results show that the early-stage fatigue damage in aluminum plates can effectively be evaluated using the QSC generated by low-frequency Lamb waves.
用低频Lamb波准静态分量评价金属板的早期疲劳损伤
非线性Lamb波包括二次谐波和声辐射诱导的准静态分量(QSC),具有准确评估早期疲劳损伤的潜力。大多数先前的研究都集中在基于二次谐波的技术上,这些技术需要相速度匹配,并且很难从超声波检测系统中隔离干扰。上述要求和不足限制了二次谐波技术的应用。本研究提出了一种基于qsc的低频Lamb波早期疲劳损伤评估技术,该技术不需要相速度匹配,并且可以消除超声检测系统的干扰。在仿真和实验中,选择了与生成的QSC近似群速度匹配的低频Lamb波主模式。在有限元模拟中,通过改变三阶弹性常数的不同程度的材料非线性来表征疲劳损伤的程度。数值结果表明,随着疲劳损伤程度的增加,所产生的QSC脉冲的幅度增大。进一步对不同疲劳循环次数下铝板的早期疲劳损伤进行了实验研究。通过相位反转技术和低通数字滤波处理,从接收到的时域信号中提取产生的QSC脉冲。得到了归一化声学相对非线性参数随循环加载次数的变化曲线。数值模拟和实验结果表明,利用低频兰姆波产生的QSC可以有效地评价铝板的早期疲劳损伤。
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
3.80
自引率
9.10%
发文量
25
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