Laserowe badania ultradźwiękowe

• Autorzy: Szelążek J.
• Języki publikacji: PL

Słowa kluczowe

PL

badania ultradźwiękowe; fala ultradźwiękowa; laser półprzewodnikowy

EN

ultrasonic testing; ultrasound wave; semiconductor laser

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Dozór Techniczny
• Rocznik: 2006
• Tom: z. 6
• Strony: 131--136
• Opis fizyczny: Bibliogr. 17 poz., rys., wykr.

Twórcy

autor

Szelążek J.

• IPPT PAN, Warszawa

Bibliografia

• [1] White, R. M. (1963). “Generation of Elastic Waves by Transient Surface Heating”, Journal of Applied Physics 34, pp. 3559-3567.
• [2] Primbsch, E. and Bickel, W. (1983). “Apparatus for Producing Ultrasonic Waves in a Workpiece”, U. S. Patent 4, 379, 409.
• [3] Pulse Compression Techniques for Laser Generated Ultrasound, R. F. Anastasi, E. I. Madaras, http://citeseer.ist.psu.edu/cache/papers/cs/12473/ftp:zSzzSztechreports.larc.nasa.govzSzpubzSztechreportszSzlarczSz1999zSzmtgzSzNASA-99-ieeeirus-rfa.pdf/anastasi99pulse.pdf
• [4] A. Graff, Wave motion in elastic solids, Dover Publications, New York, 1991.
• [5] Generation of ultrasound for material testing using low power diode laser, Syed Hasan Atique, Brian Culshaw, Graham Thursby, Fengzhong Dong, cmp. Eee. Strath. Ac. Uk/generation%20of%20ultrasound%20for%20material%20testing.pdf
• [6] A. Sliwiński, Ultradźwięki I ich zastosowania, WNT Warszawa, 2001.
• [7] Shusharin A. V., Evaluationg Calculation of Mechanical Stresses due to Metal in Absorption of Laser Pulse, Russian Journal of Nondestructive Testing, Vol. 37, No. 8, 2001, pp. 546-553 (transl. from Defektoskopija)
• [8] S. -C. Wooh, J. -Y. Wang, Nondestructive Characterization of Planar Defects Using Laser-Generated Ultrasonic Shear Waves. Res. Nondestr Eval (2001) 13: 215-230
• [9] S. Yu. Gureyich, Yu. V. Petriv, E. V. Golubev, Experimental Investigation into Laser Generation of Surface Acoustic Waves in Ferromagnetics, Russian Journal of Nondestructive Testing, Vol. 40, No. 2, 2004, pp. 109-112.
• [10] B. Mitra, A. Shelamoff and D J Booth An optical fibre interferometer for remote detection of laser generated ultrasonics Meas. Sci. Technol. 9 (1998) 1432-1436.
• [11] http://www.inl.gov/physics/nlo/laserultrasonic.shtml
• [12] Ridgway, P. L., Hunt, A. J., Quinby-Hunt, and Russo, R. E., “Laser Ultrasonics on Moving Paper”, Ultrasonics 37: 395-403 (1999) http://sensors.lblgov/pdfs/LUS_ridgway.pdf
• [13] http://statusreports-atp.nist.gov/reports/95-02-0005PDF.pdf
• [14] J. B. Walter, K. L. Telschov and R. E. Haun, “Laser acoustic molten metal depth sensing in titanium”, Advanced Sensors for Metals Processing, eds. B. W. Brusey, J. F. Bussicre, M. Dubois, and A. Moreau (Canadian Institute of Mining, Metallurgy and Petroleum, Montreal, Quebec, 1999, 265-274
• [15] E. Fraizier, M.-H. Nadal, and R. OLTRA, “Viscoelastic constants evaluation up to the melting temperature of metallic materials by laser-ultrasonics”, Ultrasonics, Vol 40, n 1-8, 2002, pp. 543-769
• [16] Laser-ultrasonics: a non-contact method to characterize elastic properties of metal up to the melting point, M.-H. Nadal, E. Fraizier, R. Oltra, WCU 2003, Paris, September 7-10, 2003, http://www.sfa.asso.fr/wcu2003/proces/website/articles/000349.pdf
• [17] Proceedings of US-Japan Symposium on Advancing Applications of NDE, Mauri, Hawaii, June 20-24, 2005, Laser Ultrasonic Inspection of Welds Used In Shipbuilding, Marvin Klein, Todd Sienicki and Jerome Eichenberg.