Evaluating Contact-Less Sensing and Fault Diagnosis Characteristics in Vibrating Thin Cantilever Beams with a MetGlas® 2826MB Ribbon

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2024-01-06 DOI:10.3390/vibration7010002
Robert-Gabriel Sultana, Achilleas Davrados, Dimitrios Dimogianopoulos
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引用次数: 0

Abstract

The contact-less sensing and fault diagnosis characteristics induced by fixing short Metglas® 2826MB ribbons onto the surface of thin cantilever polymer beams are examined and statistically evaluated in this study. Excitation of the beam’s free end generates magnetic flux from the vibrating ribbon (fixed near the clamp side), which, via a coil suspended above the ribbon surface, is recorded as voltage with an oscilloscope. Cost-efficient design and operation are key objectives of this setup since only conventional equipment (coil, oscilloscope) is used, whereas filtering, amplification and similar circuits are absent. A statistical framework for extending past findings on the relationship between spectral changes in voltage and fault occurrence is introduced. Currently, different levels of beam excitation (within a frequency range) are shown to result in statistically different voltage spectral changes (frequency shifts). The principle is also valid for loads (faults) of different magnitudes and/or locations on the beam for a given excitation. Testing with either various beam excitation frequencies or different loads (magnitude/locations) at a given excitation demonstrates that voltage spectral changes are statistically mapped onto excitation levels or occurrences of distinct faults (loads). Thus, conventional beams may cost-efficiently acquire contact-less sensing and fault diagnosis capabilities using limited hardware/equipment.
用 MetGlas® 2826MB 带评估振动薄悬臂梁的无接触传感和故障诊断特性
本研究对将短 Metglas® 2826MB 磁带固定在薄悬臂聚合物梁表面所产生的无接触传感和故障诊断特性进行了检查和统计评估。横梁自由端受到激励时,振动带(固定在靠近夹具一侧)会产生磁通量,磁通量通过悬挂在振动带表面上方的线圈,用示波器记录为电压。由于只使用常规设备(线圈、示波器),而不使用滤波、放大和类似电路,因此设计和操作的成本效益是该装置的关键目标。此外,还介绍了一个统计框架,用于扩展以往关于电压频谱变化与故障发生之间关系的研究成果。目前,不同水平的波束激励(在一定频率范围内)会导致统计上不同的电压频谱变化(频率偏移)。该原理也适用于给定激励下梁上不同大小和/或位置的负载(故障)。在给定励磁条件下,使用各种横梁励磁频率或不同负载(大小/位置)进行的测试表明,电压频谱变化在统计学上与励磁水平或不同故障(负载)的发生相关联。因此,传统横梁可以利用有限的硬件/设备,经济高效地获得非接触式传感和故障诊断能力。
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
3.20
自引率
0.00%
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0
审稿时长
10 weeks
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