Total Residual Stress Measurement by Using Ultrasonic Technique

Fatih Uzun; Ali Bilge

Year 2011, Volume: 24 Issue: 1, 135 - 141, 14.01.2011

Fatih Uzun Ali Bilge

Abstract

References

Uzun, F., “Through Thickness Residual Stress Evaluation in Heat Affected Zone”, M.Sc. Thesis, Yeditepe University, Istanbul (2009).
Li, L., J. Ding, F. Liu, and J. Zhang, “Study on Travel Time Measurement with LCR Wave in Shear Stress Evaluation”, IEEE International Conference on Mechatronics and Automation, (2006).
Bray, D. E., and W. Tang, “Subsurface Stress Evaluation in Steel Plates and Bars Using the LCR Ultrasonic Wave”, Nuclear Engineering and Design (2007).
Uzun, F., and A. N. Bilge, “Through Thickness Ultrasonic Residual Stress Evaluation Using Pulse- Echo Method”, EU JRC 12th NET Meeting Petten, Holland (2007).
Vangi, D., “Stress Evaluation by Pulse-Echo Ultrasonic Longitudinal Wave”, Experimental Mechanics, 41:277-281 (2001).
Hughes, D. S., and J. L. Kelly, “Second-Order Elastic Deformation of Solids”, Physical Review, 92:1145-1149 (1953).
Iwashimizua, Y., and K. Kubomuraa, “Stress- Induced Rotation of Polarization of Elastic Waves in Slightly Anisotropic Materials”, International Journal of Solids and Structures, 9:99-114 (1973).
US Department of Transportation Federal Railroad Administration, “Residual Stresses in Railroad Commuter Car Wheels”, Research Results, RR99- 01 (1999).
Walaszek, H., J. Hoblos, P. Bouteille, Cetim, G. Bourse, and C. Robin, “Ultrasonic Stress Measurement: Application to Welded Joints”, ECNDT (2006).
Frankel, J., Scholz, W., Capsimalis, G., and Korman, W., “Residual Stress Measurement in Circular Steel Cylinders”, Ultrasonic Symposium, 1009-1012 (1983).
Clark, A. V., and J. C. Moulder, “Residual Stress Determination in Aluminium Using Electromagnetic Acoustic Transducers”, Ultrasonics, 253-259 (1985).
Marshall, M. B., Lewis, R., and Dwyer-Joyce, R. S., “The Application of Ultrasound As a Tool for Studying Contact Stresses in Railway Engineering Component Contacts”, Joint Rail Conference, 83- 88 (2005).
Qozam, H., J. Hoblos, G. Bourse, C. Robin, H. Walaszek, P. Bouteille, and M. Cherfaoui, “Ultrasonic Stress Measurement in Welded Component by Using Lcr Waves: Analysis of The Microstructure Effect”, Materials Science Forum, 524-525: 453-458 (2006).
Schneider, E., K. Goebbels, G. Hübschen, and H. J. Selzburger, “Determination of Residual Stress by Time of Flight Measurements with Linear- Polarized Shear Waves”, Ultrasonics Symposium, 956-959 (1981).
Noronha, P. J., Wert, J. J., and Kinser, D. L., “Characterization of Material Parameters and The Measurement of Residual Stress Using Ultrasonic Techniques”, Ultrasonics Symposium, 230-233 (1973).
Namkug, M., and J. S. Heyman, “Residual Stress Characterization with a Magnetic/Ultrasonic Technique”, Ultrasonics Symposium, 950-954 (1984).
British Energy, “Manufacture and Welding of Plate Specimens”, (2008).

Total Residual Stress Measurement by Using Ultrasonic Technique

Year 2011, Volume: 24 Issue: 1, 135 - 141, 14.01.2011

Fatih Uzun Ali Bilge

Abstract

Ultrasonic technique is of paramount importance in residual stress measurement. The technique has many advantages than other residual stress measurement techniques. However, precision and determining acoustoelastic constants are main difficulties that are encountered. Based on the principle that source of the welding residual stress is welding heat, relation between thermal stress and ultrasonic wave velocity variations are investigated. By using their relation, a new attempt on determining welding residual stress is developed.

Keywords

Ultrasonic technique, Residual stress, Welding, Thermal stress

References

Uzun, F., “Through Thickness Residual Stress Evaluation in Heat Affected Zone”, M.Sc. Thesis, Yeditepe University, Istanbul (2009).
Li, L., J. Ding, F. Liu, and J. Zhang, “Study on Travel Time Measurement with LCR Wave in Shear Stress Evaluation”, IEEE International Conference on Mechatronics and Automation, (2006).
Bray, D. E., and W. Tang, “Subsurface Stress Evaluation in Steel Plates and Bars Using the LCR Ultrasonic Wave”, Nuclear Engineering and Design (2007).
Uzun, F., and A. N. Bilge, “Through Thickness Ultrasonic Residual Stress Evaluation Using Pulse- Echo Method”, EU JRC 12th NET Meeting Petten, Holland (2007).
Vangi, D., “Stress Evaluation by Pulse-Echo Ultrasonic Longitudinal Wave”, Experimental Mechanics, 41:277-281 (2001).
Hughes, D. S., and J. L. Kelly, “Second-Order Elastic Deformation of Solids”, Physical Review, 92:1145-1149 (1953).
Iwashimizua, Y., and K. Kubomuraa, “Stress- Induced Rotation of Polarization of Elastic Waves in Slightly Anisotropic Materials”, International Journal of Solids and Structures, 9:99-114 (1973).
US Department of Transportation Federal Railroad Administration, “Residual Stresses in Railroad Commuter Car Wheels”, Research Results, RR99- 01 (1999).
Walaszek, H., J. Hoblos, P. Bouteille, Cetim, G. Bourse, and C. Robin, “Ultrasonic Stress Measurement: Application to Welded Joints”, ECNDT (2006).
Frankel, J., Scholz, W., Capsimalis, G., and Korman, W., “Residual Stress Measurement in Circular Steel Cylinders”, Ultrasonic Symposium, 1009-1012 (1983).
Clark, A. V., and J. C. Moulder, “Residual Stress Determination in Aluminium Using Electromagnetic Acoustic Transducers”, Ultrasonics, 253-259 (1985).
Marshall, M. B., Lewis, R., and Dwyer-Joyce, R. S., “The Application of Ultrasound As a Tool for Studying Contact Stresses in Railway Engineering Component Contacts”, Joint Rail Conference, 83- 88 (2005).
Qozam, H., J. Hoblos, G. Bourse, C. Robin, H. Walaszek, P. Bouteille, and M. Cherfaoui, “Ultrasonic Stress Measurement in Welded Component by Using Lcr Waves: Analysis of The Microstructure Effect”, Materials Science Forum, 524-525: 453-458 (2006).
Schneider, E., K. Goebbels, G. Hübschen, and H. J. Selzburger, “Determination of Residual Stress by Time of Flight Measurements with Linear- Polarized Shear Waves”, Ultrasonics Symposium, 956-959 (1981).
Noronha, P. J., Wert, J. J., and Kinser, D. L., “Characterization of Material Parameters and The Measurement of Residual Stress Using Ultrasonic Techniques”, Ultrasonics Symposium, 230-233 (1973).
Namkug, M., and J. S. Heyman, “Residual Stress Characterization with a Magnetic/Ultrasonic Technique”, Ultrasonics Symposium, 950-954 (1984).
British Energy, “Manufacture and Welding of Plate Specimens”, (2008).

There are 17 citations in total.

Details

Primary Language	English
Journal Section	Chemical Engineering
Authors	Fatih Uzun Ali Bilge This is me
Publication Date	January 14, 2011
Published in Issue	Year 2011 Volume: 24 Issue: 1

Cite

APA	Uzun, F., & Bilge, A. (2011). Total Residual Stress Measurement by Using Ultrasonic Technique. Gazi University Journal of Science, 24(1), 135-141.
AMA	Uzun F, Bilge A. Total Residual Stress Measurement by Using Ultrasonic Technique. Gazi University Journal of Science. January 2011;24(1):135-141.
Chicago	Uzun, Fatih, and Ali Bilge. “Total Residual Stress Measurement by Using Ultrasonic Technique”. Gazi University Journal of Science 24, no. 1 (January 2011): 135-41.
EndNote	Uzun F, Bilge A (January 1, 2011) Total Residual Stress Measurement by Using Ultrasonic Technique. Gazi University Journal of Science 24 1 135–141.
IEEE	F. Uzun and A. Bilge, “Total Residual Stress Measurement by Using Ultrasonic Technique”, Gazi University Journal of Science, vol. 24, no. 1, pp. 135–141, 2011.
ISNAD	Uzun, Fatih - Bilge, Ali. “Total Residual Stress Measurement by Using Ultrasonic Technique”. Gazi University Journal of Science 24/1 (January 2011), 135-141.
JAMA	Uzun F, Bilge A. Total Residual Stress Measurement by Using Ultrasonic Technique. Gazi University Journal of Science. 2011;24:135–141.
MLA	Uzun, Fatih and Ali Bilge. “Total Residual Stress Measurement by Using Ultrasonic Technique”. Gazi University Journal of Science, vol. 24, no. 1, 2011, pp. 135-41.
Vancouver	Uzun F, Bilge A. Total Residual Stress Measurement by Using Ultrasonic Technique. Gazi University Journal of Science. 2011;24(1):135-41.