Browse > Article
http://dx.doi.org/10.5516/NET.2007.39.5.637

DEFECT DETECTION WITHIN A PIPE USING ULTRASOUND EXCITED THERMOGRAPHY  

Cho, Jai-Wan (Nuclear Robotics Lab., Korea Atomic Energy Research Institute)
Seo, Yong-Chil (Nuclear Robotics Lab., Korea Atomic Energy Research Institute)
Jung, Seung-Ho (Nuclear Robotics Lab., Korea Atomic Energy Research Institute)
Kim, Seung-Ho (Nuclear Robotics Lab., Korea Atomic Energy Research Institute)
Jung, Hyun-Kyu (Nuclear Robotics Lab., Korea Atomic Energy Research Institute)
Publication Information
Nuclear Engineering and Technology / v.39, no.5, 2007 , pp. 637-646 More about this Journal
Abstract
An UET (ultrasound excited thermography) has been used for several years for a remote non-destructive testing in the automotive and aircraft industry. It provides a thermo sonic image for a defect detection. A thermograhy is based On a propagation and a reflection of a thermal wave, which is launched from the surface into the inspected sample by an absorption of a modulated radiation. For an energy deposition to a sample, the UET uses an ultrasound excited vibration energy as an internal heat source. In this paper the applicability of the UET for a realtime defect detection is described. Measurements were performed on two kinds of pipes made from a copper and a CFRP material. In the interior of the CFRP pipe (70mm diameter), a groove (width - 6mm, depth - 2.7mm, and length - 70mm) was engraved by a milling. In the case of the copper pipe, a defect was made with a groove (width - 2mm, depth - 1mm, and length - 110 mm) by the same method. An ultrasonic vibration energy of a pulsed type is injected into the exterior side of the pipe. A hot spot, which is a small area around the defect was considerably heated up when compared to the other intact areas, was observed. A test On a damaged copper pipe produced a thermo sonic image, which was an excellent image contrast when compared to a CFRP pipe. Test on a CFRP pipe with a subsurface defect revealed a thermo sonic image at the groove position which was a relatively weak contrast.
Keywords
Non Destructive Test; Ultrasound Excited Thermography; Pipe; Defect Detection;
Citations & Related Records

Times Cited By Web Of Science : 0  (Related Records In Web of Science)
연도 인용수 순위
  • Reference
1 L.D. Favro, X. Han, Z. Ouyang, and R.L. Thomas, 'Progress in thermosonic crack detection', Proc. of SPIE, 4360, 546 (2001)
2 L. D. Landau and E. M. Lifshitz, Theory of Elasticity, 3rd ed, p. 137, Butterworth Heinermann (1997)
3 X. Han, Z. Zeng, W.Li, S. Islam. J. Lu, V. Loggins, E. Yitamben, L.D. Favro, G. Newaz and R.L. Thomas, 'Acoustic chaos for enhanced detectability of cracks by sonic infrared imaging', J. Appl. Phys., 95, 3792 (2004)   DOI   ScienceOn
4 G. Busse, A. Dillenz and T. Zweschper, 'Defect selective imaging of aerospace structures with elastic-wave-activated thermography', Proc. of SPIE, 4360, 580 (2001)
5 X. Han, L.D. Favro, Z. Ouyang and R.L. Thomas. 'Thermosonics: detecting cracks and adhesion defects using ultrasonic excitation and infrared imaging', Int. J of Adhesion, 76, 151 (2001)   DOI   ScienceOn
6 T. Zweschpher, G. Riegert, A. Dillenz and G. Busse, 'Ultrasound burst phase thermography (UBP) for applications in the automotive industry,' AIP Conf. Proc., 657, 531 (2003)
7 X. Han, V. Loggins, Zhi Zeng, L.D. Favro and R.L. Thomas, 'Mechanical model for the generation of acoustic chaos in sonic infrared imaging', Appl. Phys. Lett., 85, 1332 (2004)   DOI   ScienceOn
8 R. B. Mignogna, R.E. Green Jr, J.C. Duke Jr, E.G. Henneke II and K.L. Reifsnider, 'Thermographic investigation of high-power ultrasonic heating in materials', Ultrasonics, 19, 159 (1981)   DOI   ScienceOn
9 L.D. Favro, X. Han, Z. Ouyang, G. Sun, H. Sui and R.L. Thomas, 'Infrared imaging of defects heated by a sonic pulse', Rev. Sci. Instr., 71, 2418 (2000)   DOI   ScienceOn
10 W.O. Miller, 'An evaluation of sonic IR for NDE at Lawrence Livermore National Laboratory', Proc. of SPIE, 4360, 534 (2001)
11 T. Zweschpher, A. Dillenz, D. Scherling and G. Busse, 'Ultrasound excited thermography using frequency modulated elastic waves,' Insight, 45, 1 (2003)
12 L.D. Favro, R.L. Thomas, X. Han, Z. Ouyang, G. Newaz and D. Gentile, 'Sonic infrared imaging of fatigue cracks', Int. J of Fatigue, 23, S471(2001)   DOI   ScienceOn
13 J. Rantala, D. Wu, A. Salerno and G. Busse, 'Lock-in thermography with mechanical loss angle heating at ultrasonic frequencies,' Proc. Int Conf. Quantitative InfraRed Thermography (QIRT96), Stuttgart, Germany, Sep.2-5, (1996)