Interaction of a scanning laser-generated ultrasonic line source with a surface-breaking flaw.

The scanning laser source (SLS) technique has been proposed recently as an effective way to investigate small surface-breaking cracks. By monitoring the amplitude and frequency changes of the ultrasound generated as the SLS scans over a defect, the SLS technique has provided enhanced signal-to-noise performance compared to the traditional pitch-catch or pulse-echo ultrasonic methods. In previous work, either a point source or a short line source was used for generation of ultrasound. The resulting Rayleigh wave was typically bipolar in nature. In this paper, a scanning laser line source (SLLS) technique using a true thermoelastic line source (which leads to generation of monopolar surface waves) is demonstrated experimentally and through numerical simulation. Experiments are performed using a line-focused Nd:YAG laser and interferometric detection. For the numerical simulation, a hybrid model combining a mass-spring lattice method (MSLM) and a finite difference method (FDM) is used. As the SLLS is scanned over a surface-breaking flaw, it is shown both experimentally and numerically that the monopolar Rayleigh wave becomes bipolar, dramatically indicating the presence of the flaw.

[1]  Jean-Pierre Monchalin,et al.  Broadband optical detection of ultrasound by two‐wave mixing in a photorefractive crystal , 1991 .

[2]  Quantitative accuracy of the mass-spring lattice model in simulating ultrasonic waves , 2002 .

[3]  D. Royer,et al.  Experimental and theoretical waveforms of Rayleigh waves generated by a thermoelastic laser line source. , 2000, Ultrasonics.

[4]  Yongseok Choi,et al.  Simulation of ultrasonic waves in various types of elastic media using the mass spring lattice model , 2000 .

[5]  Laser Generated Rayleigh and Lamb waves , 2002 .

[6]  L. R. F. Rose,et al.  Point‐source representation for laser‐generated ultrasound , 1984 .

[7]  Sridhar Krishnaswamy,et al.  Mass spring lattice modeling of the scanning laser source technique. , 2002, Ultrasonics.

[8]  R. Dewhurst,et al.  Surface Acoustic Wave Interactions with Cracks and Slots: A Noncontacting Study Using Lasers , 1986, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[9]  Jan Drewes Achenbach,et al.  Laser ultrasonic detection of surface breaking discontinuities: Scanning laser source technique , 2000 .

[10]  J. Monchalin Optical Detection of Ultrasound , 1986, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[11]  Bernstein,et al.  Line source representation for laser-generated ultrasound in aluminum , 2000, The Journal of the Acoustical Society of America.

[12]  H. Yamawaki,et al.  NUMERICAL CALCULATION OF SURFACE WAVES USING NEW NODAL EQUATIONS , 1992 .

[13]  J. Spicer,et al.  Hybrid laser/broadband EMAT ultrasonic system for characterizing cracks in metals. , 2002, The Journal of the Acoustical Society of America.

[14]  F. A. Silber,et al.  ULTRASONIC TESTING OF MATERIALS , 1978 .

[15]  Hyunjune Yim,et al.  Numerical simulation and visualization of elastic waves using mass-spring lattice model , 2000, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[16]  J. Ready Effects of high-power laser radiation , 1971 .

[17]  C. M. Scala,et al.  Near-field ultrasonic Rayleigh waves from a laser line source , 1996 .

[18]  Leonard J. Bond,et al.  A computer model of the interaction of acoustic surface waves with discontinuities , 1979 .

[19]  C. M. Scala,et al.  Laser ultrasonics for surface-crack depth measurement using transmitted near-field Rayleigh waves , 2000 .

[20]  Richard J. Dewhurst,et al.  Surface‐breaking fatigue crack detection using laser ultrasound , 1993 .

[21]  Jan Drewes Achenbach,et al.  Ultrasonic imaging of small surface-breaking defects using scanning laser source technique , 2002 .