同质板状固体中的低频振动和缺陷检测建模

IF 2.6 3区 材料科学 Q2 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Journal of Nondestructive Evaluation Pub Date : 2024-08-14 DOI:10.1007/s10921-024-01115-3
Joshua O. Aigbotsua, Robert A. Smith, Tom Marshall, Bruce W. Drinkwater
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引用次数: 0

摘要

对蜂窝、轻木和泡沫等芯材外皮的厚截面夹层结构进行检测时,需要依靠低频振动技术,通过振幅或相位响应的变化来识别缺陷。然而,目前的工业方法通常仅限于检测特定类型的缺陷,可能会忽略其他缺陷。此外,这些方法无法收集有关缺陷类型或深度的详细信息,因为它们只能分析可用数据的一小部分,而不是全部相关响应谱。本文通过分析全部相关频谱(5-50 kHz),探讨了使用俯仰捕捉变体低频振动检测均质固体缺陷的科学依据。结构中的缺陷会导致受影响区域的局部刚度和质量降低,引起上面一层的共振,从而产生被称为局部缺陷共振(LDR)的放大振动。在这项研究中,用 5-50 kHz 的啁啾信号激励一块深度为 1 mm、直径为 40 mm 的圆形平底孔 (FBH)(代表表皮缺陷)的铝板,并在距离激励点 17 mm 处监测其响应。数值模型采用有限元分析 (FEA),解决了创建精确模型的难题。概述了优化数值模型和减少模型-实验误差的过程,包括缺乏材料阻尼知识等挑战。研究强调了探头刚度和阻尼效应建模对于实现模型与实验之间一致性的重要性。加入这些效应后,最大 LDR 频率误差从约 3 kHz 降至 1 kHz 以下。此外,这项研究还提出了一种方法,通过与模型响应的比较,可以对缺陷进行分类。最小差值误差用于量化模型与实验之间的共振频率误差。由于共振频率是缺陷形状、尺寸和深度的函数,因此共振频率误差谱中相对较低的均方根误差表明了缺陷的特征。最后,通过宽带激励信号和缺陷中平面的线扫描,探讨了使用间距捕捉探头进行缺陷检测和尺寸测量的方法。本文介绍了一种使用间距捕捉探针进行缺陷大小测量的方法,并通过实验进行了验证。当缺陷宽度至少是 17 毫米探针间距的两倍时,就可以使用间距捕捉探针实现精确的缺陷尺寸测量。
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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Modelling Low-Frequency Vibration and Defect Detection in Homogeneous Plate-Like Solids

The inspection of thick-section sandwich structures with skins around core materials such as honeycomb, balsa, and foam relies on low-frequency vibration techniques to identify defects through changes in amplitude or phase response. However, current industrial methods are often limited to detecting specific types of defects, potentially overlooking others. Moreover, these methods do not gather detailed information about the defect type or depth, as they only analyse a small portion of the available data instead of the full relevant response spectrum. This paper explores the scientific basis of using low-frequency vibration in the pitch-catch variant for defect detection in homogeneous solids, through analysis of the full relevant frequency spectrum (5–50 kHz). Defects in structures lead to reduced local stiffness and mass in the affected area, causing resonance in the layer above, resulting in amplified vibrations known as local defect resonance (LDR). In this work, an aluminium plate with a 40 mm diameter circular flat-bottomed hole (FBH) at a depth of 1 mm (representing a skin defect) is excited with a chirp signal of 5–50 kHz, and the response is monitored 17 mm away from the excitation point. Finite-element analysis (FEA) is used for the numerical model, addressing challenges in creating an accurate model. The process to optimise the numerical model and the reduce model-experiment error is outlined, including challenges such as the lack of knowledge of material damping. The study emphasizes the importance of modelling the probe’s stiffness and damping effects for achieving agreement between the model and experiment. After incorporating these effects, the maximum LDR frequency error decreased from approximately 3 kHz to less than 1 kHz. In addition, this study presents a method with the potential for defect classification through comparison to modelled responses. The minimum difference error was used to quantify the resonance frequencies’ error between the model and the experiment. Since the resonant frequencies are a function of the defect’s shape, size, and depth, a relatively low root mean squared (RMS) error across the resonance frequency error spectrum indicates the defect’s characteristics. Finally, defect detection and sizing using the pitch-catch probe are explored with a wide-band excitation signal and a line scan through the mid-plane of the defect. A method for defect sizing using a pitch-catch probe is presented and experimentally validated. Accurate defect sizing is achieved with the pitch-catch probe when the defect width is at least \(\ge \) twice the 17 mm pin-spacing of the probe.

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来源期刊
Journal of Nondestructive Evaluation
Journal of Nondestructive Evaluation 工程技术-材料科学:表征与测试
CiteScore
4.90
自引率
7.10%
发文量
67
审稿时长
9 months
期刊介绍: Journal of Nondestructive Evaluation provides a forum for the broad range of scientific and engineering activities involved in developing a quantitative nondestructive evaluation (NDE) capability. This interdisciplinary journal publishes papers on the development of new equipment, analyses, and approaches to nondestructive measurements.
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