Investigation of the effect of transverse crack on the modal properties of cantilever beams with different geometries using finite element analysis

2017 Recent Developments in Control, Automation & Power Engineering (RDCAPE) Pub Date : 2017-10-01 DOI:10.1109/RDCAPE.2017.8358235

Sameera Mufazzal, S. Muzakkir

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引用次数: 1

Abstract

Vibration analysis of structure for early detection of crack and its subsequent quantification for preventing sudden and unpredicted failure of the system and ensuring uninterrupted functionality, is one of the extensively used techniques that offer several advantages over others. The geometry of the structure plays an important role in governing its vibrational behavior in the presence of crack. The present work uses FEA to investigate the effect of single transverse crack on natural frequencies of vibration in cantilever beams of three different cross-sectional areas through Modal Analysis. The analysis has been carried out for two different crack depths with three different crack locations. The results reveal that the onset of crack reduces the natural frequency of vibration, although, the quite low sensitivity of frequency shift to damage, demands either a highly precise measurement or a considerably large damage to be confidently detected. Moreover, the effect of crack location on modal frequencies is not uniform for the beams, with varying cross-sections, however, for a particular mode, the shifts in frequency have a similar trend in all the beams.

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采用有限元方法研究横向裂纹对不同几何形状悬臂梁模态特性的影响

结构振动分析是一种广泛使用的技术，可以早期发现裂缝，并对其进行量化，以防止系统突然和不可预测的故障，并确保不间断的功能。在存在裂纹时，结构的几何形状对控制其振动行为起着重要作用。本文采用有限元法，通过模态分析研究了单横裂纹对三种不同横截面悬臂梁固有振动频率的影响。对两种不同裂纹深度、三种不同裂纹位置进行了分析。结果表明，裂纹的发生降低了振动的固有频率，尽管频率位移对损伤的敏感性很低，需要高度精确的测量或相当大的损伤才能自信地检测到。此外，对于不同截面的梁，裂纹位置对模态频率的影响是不均匀的，但对于某一特定模态，所有梁的频率变化趋势相似。

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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2017 Recent Developments in Control, Automation & Power Engineering (RDCAPE)

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