Spatial propagation characteristics of acoustic emission signals in parallel steel wire cables

•Spatial propagation of AE signals in PSWC was studied.•Hexagonal AE signals propagation was observed in the transverse section.•AE signals propagate oscillationally in the longitudinal section.•Longitudinal velocity is 4.2 times faster than transverse velocity.•AE signals propagate longitudinally a...

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Bibliographic Details
Published in:Measurement : journal of the International Measurement Confederation 2024-02, Vol.226, p.114138, Article 114138
Main Authors: Li, Shengli, Feng, Jie, Liu, Zhenwen, Xu, Bin, Wu, Guangming
Format: Article
Language:English
Subjects:
Acoustic emission
COMSOL
Excitation frequency
Numerical simulation
Parallel steel wire cables
Spatial propagation characteristics
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Summary:•Spatial propagation of AE signals in PSWC was studied.•Hexagonal AE signals propagation was observed in the transverse section.•AE signals propagate oscillationally in the longitudinal section.•Longitudinal velocity is 4.2 times faster than transverse velocity.•AE signals propagate longitudinally and then transversely. Accurate spatial propagation characteristics facilitate damage spatial localization, which is crucial for assessing the condition of parallel steel wire cables (PSWC). Existing studies have focused on the longitudinal propagation of acoustic emission (AE) signals, limiting accurate spatial damage assessment. This study comprehensively explored the spatial propagation characteristics of AE signals in PSWC using finite elements and attenuation tests. AE signals propagate hexagonally on the transverse section, with different amplitude attenuation rates at different angles—8% at 0° and 60°, 5 % at 30° and 45°. Additionally, AE signals exhibit oscillatory propagation between different wires in the longitudinal direction. The longitudinal speed (5706 m/s) is approximately 4.2 times faster than the transverse speed (1371 m/s), and the propagation path can be simplified as longitudinal and then transverse, offering valuable guidance for damage localization. The optimum frequency is 150 kHz in the transverse direction and 30 kHz in the longitudinal direction.
ISSN:0263-2241
1873-412X
DOI:10.1016/j.measurement.2024.114138