Design of an Orthotropic Piezoelectric Composite Material Phased Array Transducer for Damage Detection in a Concrete Structure
Publication: Publication Date: 1 November 2016Testing Method:
In order to verify the feasibility and effectiveness of the sensor used in complex concrete materials, an innovative application of ultrasonic phased array detection for a concrete structure was investigated. Comparing with the traditional piezoelectric composites, orthotropic piezoelectric composite material (OPCM) can be used as transducers in damage detection show clear advantages because of their high sensitivity and directivity along the polarization direction. A low frequency ultrasonic phased array transducer consisting of 16 OPCM elements is studied. The optimal array parameters, such as the phased array element interval, the array element width, and number of elements, are obtained by studying the total displacement changes as various parameters change at the focus point in the concrete structure. This configuration allowed the variation and control of the wave field directivity in the concrete structure during the measurements. The measurements were taken on concrete specimens using a precise time-delay device. The experimental measurements were compared to theoretical calculations to investigate the influence of different array element parameters. The results show that an OPCM phased array transducer can be used to detect damage in a concrete block.
- J. Dodson, and D. Inman. Ultrasonics 53:677–685 (2013).
- B. Dutton, A. R. Clough, and M. Rosli NDT & E International 44(4):353–360 (2011).
- G. Peng, and L. Xingfa. Journal of Experimental Mechanics 29(1):1–10 (2014).
- M. Tehranchi, H. Eftekhari, and M. Ranjbaran. Sensor Letters 11(1):125–127 (2013).
- C. Dang, L. W. Schmerr Jr., and A. Sedov. Research in Nondestructive Evaluation 14 (4):203–228 (2003).
- R. Ahmad, and T. Kundu. Journal of the Acoustical Society of America 17(4):1762–1776 (2005).
- J. V. Hatfield, N. R. Scales, A. D. Armitage, P. J. Hicks, Q. X. Chen, and P. A. Payne. Sensors and Actuators A: Physical 41(1–3):167–173 (1994).
- L. Satyanarayan, J. Chandrasekaran, B. Mayfield, and Balasubramaniam. NDT&E International 41(1):32–43 (2008).
- A. Erhard, G. Schenk, T. Hauser, and V. Volz. Nuclear Engineering and Design 206 (2):325–336 (2001).
- J. Poguet, P. Ciorau, and G. Fleury. Journal of Nondestructive Testing 7(10):12 (2002).
- Y. Nonaka, K. Kodaira, M. Odakura, T. Matsui, and M. Touma. Karyoku Genshiryoku Hatsuden 60(1):54–58 (2009).
- Z. Xinyu, G. Tie, and Z. Bixing. Chinese Journal of Acoustics 28(2):146–153 (2009).
- G. C. McLaskey, S. D. Glaser, and C. U. Grosse. Journal of Sound and Vibration 329 (12):2384–2394 (2010).
- S. Moriya, Y. Miki, and T. Yokobayashi. Japanese Journal of Radiology 29(3):166–170 (2011).
23 Page Views
0 PDF Downloads
0 Facebook Shares