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http://dx.doi.org/10.3807/JOSK.2013.17.4.323

Preliminary Study of the Measurement of Foreign Material in Galvanic Corrosion Using Laser Ultrasonic  

Hong, Kyung Min (Department of Mechanical Engineering, Chonbuk National University)
Kang, Young June (Department of Mechanical Engineering, Chonbuk National University)
Park, Nak Kyu (Korea Atomic Energy Research Institute)
Choi, In Young (Department of Mechanical Engineering, Chonbuk National University)
Publication Information
Journal of the Optical Society of Korea / v.17, no.4, 2013 , pp. 323-327 More about this Journal
Abstract
A laser ultrasonic inspection system has the advantage of nondestructive testing. It is a non-contact mode using a laser interferometer to measure the vertical displacement of the surface of a material caused by the propagation of ultrasonic signals with the remote ultrasonic generated by laser. After raising the ultrasonic signal with a broadband frequency range using a pulsed laser beam, the laser beam is focused to a small point to measure the ultrasonic signal because it provides an excellent measurement resolution. In this paper, foreign materials are measured by a non-destructive and non-contact method using the laser ultrasonic inspection system. Mixed foreign material on the corroded part is assumed and the laser ultrasonic experiment is conducted. An ultrasonic wave is generated by pulse laser from the back of the specimen and an ultrasonic signal is acquired from the same location of the front side using continuous wave laser and Confocal Fabry-Perot Interferometer (CFPI). The characteristic of the ultrasonic signal of existing foreign material is analyzed and the location and size of foreign material is measured.
Keywords
Laser ultrasonic; Pulse laser; Confocal Fabry-perot interferometer; Galvainc corrosion; Foreign material;
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  • Reference
1 J. P. Monchalin, "Optical detection of ultrasound," UFFC 33, 485-499 (1986).   DOI   ScienceOn
2 C. B. Scruby and L. E. Drain, "Laser ultrasonic: techniques and applications," Adam Hilger New York, 223-324 (1990).
3 S. S. Lee and T. S. Jang, "Understanding of laser-based ultrasonic," Journal of the Korean Society for Nondestructive Testing 22, 74-87 (2002).
4 Q. Shan, C. M. Chen, and R. J. Dewhurst, "A conjugate optical confocal Fabry-Perot interferometer for enhanced ultrasound detection," Measurement Science and Technology 6, 921-928 (1995).   DOI   ScienceOn
5 J. D. Aussel, A. L. Burn, and J. C. Badboux, "Generating acoustic wave by laser: theoretical and experimental study of emission source," Ultrasonic 26, 245-255 (1998).
6 C. B. Scruby, R. J. Dewhurst, D. A. Hutchins, and S. B. Plamer, "Quantitative studies of thermally generated elastic waves in laser-illuminated metals," Journal of Applied Physics 51, 6210-6216 (1980).   DOI   ScienceOn
7 S. K. Park, S. H. Baik, H. K. Jung, Y. M. Cheong, B. H Cha, N. K. Park, and Y. J. Kang, "Depth detection of a thin aluminum plate in laser ultrasonic testing using a confocal Fabty-Perot laser interferometer," Journal of the Korean Physical Society 59, 3262-3266 (2011).   DOI   ScienceOn
8 S. K. Park, S. H. Baik, M. C. Park, C. H. Lim, and S. W. Ra, "Development of a laser-generated ultrasonic inspection system by using adaptive error correction and dynamic stabilizer," Journal of the Korean Society for Nondestructive Testing 25, 391-399 (2005).