COMPUTER-AIDED PROTOTYPING OF INTERDIGITAL TRANSDUCERS FOR THE STRUCTURAL HEALTH MONITORING OF PLANAR STRUCTURES

Authors

  • Michał Mańka AGH University of Science and Technology
  • Łukasz Ambroziński AGH University of Science and Technology
  • Tadeusz Uhl AGH University of Science and Technology

DOI:

https://doi.org/10.7494/mech.2013.32.2.69

Keywords:

Lamb wave, ultrasonic, numerical simulation, damage detection, Structural Health Monitoring, SHM

Abstract

In recent years an intensive research activity into the application of guided waves (GWs) for structural health monitoring (SHM) can be observed. For instance, Lamb waves (LWs) have shown a great potential in monitoring of thin, planar structures. However, due to the dispersive and multimodal nature of the LWs, their snapshots can consist of many pulses even for an intact structure, which makes damage detection very complex. Moreover, small PZT transducers, most commonly used in SHM systems, act normally as omni-directional wave sources; therefore, dense or sparse transducers networks are required for damage localization. Some of the above-mentioned drawbacks of single PZT emitters and sensors can be overcome using interdigital transducers (IDT) designed to excite and sense a single, selected mode. The mode-tuning is performed by changing the span of finger electrodes to match the wavelength of the excited mode for the selected frequency. An IDT is a directional source, therefore, it generates a wave steered to the direction perpendicular to the electrodes. The width of the excited main lobe can be determined by the length of the electrodes. Since many parameters of the IDTs influence the LWs propagation, techniques for the simulation of the wave excitation and propagation are needed. In the paper, numerical tools for the computer aided design and virtual prototyping of the IDTs are presented. The simulation technique is based on the frequency-dependent transfer function of the structure, and due to its computational efficiency it can be used for fast testing of IDTs’ performance and for preliminary transducer design for further finite element simulations, and prototyping.

Downloads

Download data is not yet available.

References

Capineri L., Gallai A., Masotti L., Materassi M. 2002, Design Criteria And Manufacturing Technology Of Piezo-Polymer Transducer Arrays For Acoustic Guided Waves Detection. IEEE Ultrasonic Symposium.

Giurgiutiu V. 2008, Structural health monitoring with piezoelectric wafer active sensors. Academic Press.

Hayward G., Hailu B., Farlow R., Gachagan A., McNab A. 2001, The design of embedded transducers for structural health monitoring applications. Proceedings of the SPIE, 2001, pp. 312–323.

Jin J., Quek S.T., Wang Q. 2005, Design of interdigital transducers for crack detection in plates. Ultrasonics, no. 43, pp. 481–493.

Luginbuhl P., Collins S.D., Racine G., Gretillat M.A., de Rooij N.F., Brooks K.G., Setter N. 1997, Microfabricated Lamb Wave Device Based on PZT Sol-Gel Thin Film for Mechanical Transport of Solid Particles and Liquids. Journal of Microelectromechanical Systems, vol 6, no. 4, pp. 337–346.

Mańka M., Rosiek M., Martowicz A., Stępiński T., Uhl T. 2012, Lamb wave transducers made of piezoelectric macro-fi ber composite, Structural Control and Health Monitoring, 2012.

Manka M.M., Rosiek M., Martowicz A., Uhl T., Stepinski T. 2011, Properties of Interdigital Transducers for Lamb-wave Based SHM Systems. The 8th International Workshop on Structural Health Monitoring - Stanford University – 2011, Stanford.

Monkhouse R.S.C., Wilcox P.D., Cawley P. 1997, Flexible interdigital PVDF transducers for the generation of Lamb waves in structures. Ultrasonics, no. 35, pp. 489–498.

Monkhouse R.S.C., Wilcox P.W., Lowe M.J.S., Dalton R.P., Cawley P. 2000, The rapid monitoring of structures using interdigital Lamb, Smart Materials and Structures, no. 9, pp. 304–309.

Na J.K., Blackshire J.L. 2010, Interaction of Rayleigh surface waves with a tightly closed fatigue crack, NDT&E International, 2010, pp. 432–439.

Na J.K., Blackshire J.L., Kuhra S. 2008, Design, fabrication and characterization of single-element interdigital transducers for NDT applications. Sensors and Actuators A, no. 148, pp. 359–365.

Paćko P., Bielak T., Spwncer B., Staszewski J., Uhl T. 2012, Lamb wave propagation modelling and simulation using parallel processing architecture and graphical cards. Smart Materials and Structures, 2012,pp. 1–13.

Raghavan A., Cesnik C.E.S. 2007, Review of Guided-wave Structural Health Monitoring. The shock and vibration digest, vol 2, no. 39, pp. 91–114.

Rose J. 2004, Ultrasonic waves in solid media. Cambridge University Press.

Wilcox P.D. 1998, Lamb Wave Inspection of Large Structures Using Permanently Attached Transducers. Imperial College of Science, Technology and Medicine, London.

Wilcox P.D., Cawley P., Lowe M.J.S. 1998, Acoustic fields from PVDF interdigital transducers. IEE Proceedings Science, Measurement and Technology, 1998, pp. 250–259.

Williams B.R., Park G., Inman D.J., Wilkie K.W. 2002, An Overview of Composite Actuators with Piezoceramic Fibers. 20th International Modal Analysis Conference, Los Angeles.

Downloads

Issue

Vol. 32 No. 2 (2013)

Section

Articles

License

Remember to download, sign, scan and attach the copyright notice

This file should be uploaded as a Supplementary file (Step 4) of the submission procedure.