Vibration Analysis for NDE of Ceramic Components

2021 48th Annual Review of Progress in Quantitative Nondestructive Evaluation Pub Date : 2021-07-28 DOI:10.1115/qnde2021-75218

B. Köhler, K. Tschöke, M. Stephan, Sergey Gartsev, M. Barth

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Abstract

In this contribution we study vibration testing for ceramic parts on the example of an electrolyte cup, used in a prospective power cells design. An adapted experimental arrangement for the vibration excitation and the acoustic measurements was built and tested. In parallel, extensive numerical modal analysis simulations were performed using ANSYS. The resonance spectra obtained by modelling agree with the experimentally determined spectra in such a way that the experimentally determined eigenfrequencies can be assigned to the cup modes. The correctness of this identification was verified by direct mode visualization with scanning laser doppler vibrometry. A much faster and potentially in-line capable method for experimental mode identification is the simultaneous measurement at several points using a microphone array and subsequent signal evaluation with operational modal analysis. This procedure was successfully tested. Features in the spectra connected with the presence of flaws are discussed. These features include the drop of some eigenfrequencies and the splitting of degenerated modes.

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陶瓷元件无损检测的振动分析

在这篇文章中，我们以电解质杯为例，研究了陶瓷部件的振动测试，用于未来的动力电池设计。建立了一种适合于振动激发和声学测量的实验布置，并进行了测试。同时，利用ANSYS进行了广泛的数值模态分析仿真。通过建模得到的共振谱与实验确定的谱一致，从而可以将实验确定的特征频率分配给杯模。通过扫描激光多普勒振动仪的直接模式显示验证了该识别的正确性。实验模态识别的一种更快且可能在线的方法是使用麦克风阵列在多个点同时测量，然后使用操作模态分析进行信号评估。此程序已成功测试。讨论了与缺陷存在有关的光谱特征。这些特征包括一些特征频率的下降和退化模态的分裂。

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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2021 48th Annual Review of Progress in Quantitative Nondestructive Evaluation

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