使用间接机电阻抗测量的部件认证

M. Albakri, P. Tarazaga
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引用次数: 0

摘要

由于机电阻抗测量作为结构健康监测解决方案的成功,它已被用作传统和增材制造零件的无损评估手段。在这个过程中,压电换能器要么直接嵌入被测部件中,要么与被测部件表面结合。虽然这种方法已被证明能够检测制造异常,但被测部件的仪器要求阻碍了其广泛采用。为了解决这一限制,最近研究了通过仪表固定装置或试验台进行间接机电阻抗测量,用于零件认证和无损评估应用。在这项工作中,通过仪器夹具间接连接到被测部件的压电换能器获得的机电阻抗特征进行了数值研究。这是为了更好地理解仪器夹具和被测部件之间的耦合及其对制造缺陷灵敏度的影响。为此,为仪表夹具、被测零件和夹具/零件装配开发了数值模型。采用频域谱元法,对10 ~ 50khz范围内的机电阻抗特征进行了数值模拟。选择对被测部件缺陷最敏感的频率范围的标准被提出,并使用标准损伤度量定义进行评估。结果表明,可根据夹具设计及其动态响应预先选择最佳频率范围。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Part Authentication Using Indirect Electromechanical Impedance Measurements
Motivated by its success as a structural health monitoring solution, electromechanical impedance measurements have been utilized as a means for non-destructive evaluation of conventionally and additively manufactured parts. In this process, piezoelectric transducers are either directly embedded in the part under test or bonded to its surface. While this approach has proven to be capable of detecting manufacturing anomalies, instrumentation requirements of the parts under test have hindered its wide adoption. To address this limitation, indirect electromechanical impedance measurement, through instrumented fixtures or testbeds, has recently been investigated for part authentication and non-destructive evaluation applications. In this work, electromechanical impedance signatures obtained with piezoelectric transducers indirectly attached to the part under test, via an instrumented fixture, are numerically investigated. This aims to better understand the coupling between the instrumented fixture and the part under test and its effects ON sensitivity to manufacturing defects. For this purpose, numerical models are developed for the instrumented fixture, the part under test, and the fixture/part assembly. The frequency-domain spectral element method is used to obtain numerical solutions and simulate the electromechanical impedance signatures over the frequency range of 10–50 kHz. Criteria for selecting the frequency range that is most sensitive to defects in the part under test are proposed and evaluated using standard damage metric definitions. It was found that optimal frequency ranges can be preselected based on the fixture design and its dynamic response.
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