Time-frequency domain analysis of Lamb wave propagation in metallic plates

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Published: Jul 27, 2023
Keywords:
Lamb waves, nondestructive evaluation, signal processing

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Erick Rojas Mancera
aInstituto Tecnológico Superior de Purísima del Rincón
Armando Mares Castro
Instituto Tecnológico Superior de Purísima del Rincón
Antonio Balvantín García
Universidad de Guanajuato, Salamanca
Pablo Alberto Limon Leyva
Instituto Tecnológico de Sonora
Elso Rodríguez García
Instituto Tecnológico Nacional de México en Celaya

Abstract

The necessity to inspect and evaluate large engineering structures, without point-to-point time-consuming inspections, has been a motivation to implement different confident and faster techniques. A growing technique is the use of guided waves. The implementation of guided waves such as Lamb waves, recently has been increasing for nondestructive evaluation in plate-like structures and components. However, Lamb wave multimode and inherent noise can interfere to identify properly Lamb wave mode propagation. In this work, the identification of Lamb wave modes propagated in thin metallic plates using Short Time Fourier Transform (STFT) has been implemented. The identification of Lamb waves was using dispersive curves computed for an aluminum plate with 1.9 mm in thickness. Experimental Lamb waves were generated using piezoelectric sensors and then digitalized to compute STFT in measured signals. Subsequently, theoretical dispersive curves were plotted over spectrograms obtained from analyzed measured signals, to identify the experimentally generated lamb wave modes. Results show that the proposed methodology is feasible for the identification of Lamb wave modes, at three different excitation frequencies to excite Lamb wave modes. 
 

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How to Cite
Rojas Mancera, E., Mares Castro, A., Balvantín García, A., Limon Leyva, P. A., & Rodríguez García, E. (2023). Time-frequency domain analysis of Lamb wave propagation in metallic plates. Ingenio Magno, 14(1), 64 - 69. Retrieved from http://revistas.ustatunja.edu.co/index.php/ingeniomagno/article/view/2790
Issue
Vol. 14 No. 1 (2023): Ingenio Magno vol. 14 - 1
Section
Articulos

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Author Biography

Erick Rojas Mancera, aInstituto Tecnológico Superior de Purísima del Rincón

Gestor de la revista Ingenio Magno de la Universidad Santo Tomás seccional Tunja

References

[1] Balvantín, A., Disodado-De-la-Peña, J., Limon-Lyva, P., & Hernández-Rodríguez, E. (2018). Study of guided wave propagation on a plate between two solid bodies with imperfect contact conditions. Ultrasonics, 83, 137-145.

[2] Dwivedi, S., Vishwakarma, M., & Soni, A. (2018). Advances and researches on non destructive testing: A review. Materials Today: Proceedings, 5(2), 3690-3698.

[3] Gorgin, R., Luoa, Y., & Wub, Z. (2020). Environmental and operational conditions effects on Lamb wave based structural health monitoring systems: A review. Ultrasonics, 105, 106114.

[4] Ismail, N., Hafizi, Z., Lim, K., & Ahmad, H. (2022). Lamb Wave Actuation Techniques for SHM System-A Review. International Conference on Mechanical Engineering Research (pp. 677-685). Singapore: Springer.

[5] Lamb, H. (1917). On waves in an elastic plate. Proceedings of the Royal Society of London, 93(648), 114-128.

[6] Liao, S., Lu, O., & Xu, L. (2020). Super-resolution ultrasound lamb wave NDE imaging of anisotropic airplane laminates via deconvolutional neural network. IEEE Transactions on Instrumentation and Measurement, 70, 1-8.

[7] Rojas, E., Baltazar, A., & Loh, K. (2015). Damage detection using the signal entropy of an ultrasonic sensor network. Smart Materials and Structures, 24(7), 075008.

[8] Rose, J. (2014). Ultrasonic Guided Waves in Solid Media. Cambridge: Cambridge University Press.

[9] Viktorov, I. (1970). Rayleigh and Lamb waves: physical theory and applications. Plenum press.