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X-Ray Fractography on Stress Corrosion Cracking of High Strength Steel

Published online by Cambridge University Press:  06 March 2019

Yukio Hirose ,
Zenjiro Yajima  and
Keisuke Tanaka
Yukio Hirose
Affiliation:
Faculty of Education, Kanazawa University, 1-1 Marunouchi, Kanazawa 920, Japan
Zenjiro Yajima
Affiliation:
Faculty of Engineering, Kanazawa Institute of Technology, 7-1 Oogigaoka, Nonoichi, Kanazawa 921, Japan
Keisuke Tanaka
Affiliation:
Faculty of Engineering, Kyoto University, Yoshida Honmachi, Sakyo-ku, Kyoto 606, Japan
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Extract

X-ray fractography is a new method utilizing the X-ray diffraction technique to observe the fracture surface for the analysis of the micromechanisms and mechanics of fracture. The line broadening of X-ray diffraction profiles and the residual stress are two of the important X-ray parameters. Among them, the X-ray residual stress has been confirmed to be particularly useful for the fracture surfaces of high strength steels, and applied to the fracture surface of fracture toughness specimens and the fatigue fracture surface.

Type
II. X-Ray Strain and Stress Determination
Information
Advances in X-Ray Analysis , Volume 27: Thirty-Second Annual Conference on Applications of X-ray Analysis, August 1-5, 1983 , 1983 , pp. 213 - 220
Copyright
Copyright © International Centre for Diffraction Data 1983

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References

1. Yajima, Z., Hirose, Y. and Tanaka, K., X-Ray Diffraction Observation of Fracture Surfaces of Ductile Cast Iron, Advances in X-Ray Analysis, 26:291 (1983).Google Scholar
2. Tanaka, K., and Hatanaka, N., Residual Stress Near Fatigue Fracture Surfaces of High Strength and Mild Steels Measured by X-Ray Method, J. Soci. Mat. Sci. Jap., 31:215 (1982).Google Scholar
3. Hirose, Y., Tanaka, K. and Okabayashi, K., Nucleation and Growth of Stress Corrosion Cracking in Notched Plates of High-Strength Low-Alloy Steel, J. Soci. Mat. Sci. Jap., 27:545 (1978).Google Scholar
4. Hirose, Y., and Tanaka, K., Nucleation and Growth of Stress Corrosion Cracks in Notched Plates of High Strength Steels, ICM 3, 11:409 (1979).Google Scholar
5. Yajima, Z., Hirose, Y. and Tanaka, K., X-Ray Diffraction Study on Fracture Surface Made by Fracture Toughness Tests of Blunt Notched CT Specimen of High Strength Steel, J. Soci. Mat. Sci. Jap., 32:783 (1983).Google Scholar
6. Levy, N., Marcal, P.V., Ostergren, W.J., and Rice, J.R., Small Seal Yielding Near a Crack in Plane Strain:A Finite Element Analysis, Int. J. Frac. Mech., 7:143 (1971).Google Scholar
7. Hirth, J.P., Effects of Hydrogen on the Properties of Iron and Steel, Metall. Trans. 11:816 (1980).Google Scholar
8. Beachem, C.D., A New Model for Hydrogen-Assisted Cracking (Hydrogen “Embrittlement“), Metall. Trans. 3:437 (1972),Google Scholar
9. Gerberich, W.W., and Chen, Y.T., Hydrogen-Controlled Cracking-An Approach to Threshold Stress Intensity, Metall. Trans. 6A:271 (1975).Google Scholar
10. Gerberich, W.W., Garry, J., and Lesser, J.F., Grain Size and Concentration Effects in Internal and External Hydrogen Embrittlement, Effect of Hydrogen on Bhavior of Materials, 70, TMS-AIME, New York (1976).Google Scholar
11. Van Leeuwen, H.P., The Kinetics of Hydrogen Embrittlement a Quantitative Diffusion Model, Eng. Frac. Mech. 6:141 (1974).Google Scholar
12. Hirose, Y., and Tanaka, K., Micromechanisms of Stress Corrosion Cracking In High Strength Steel, ICMC 81:553 (1981).Google Scholar
13. Hirose, Y., and Mura, T., Nucleation Mechanisms of Stress Corrosion Cracking, Eng. Frac. Mech. 16:339 (1983).Google Scholar
14. Hirose, Y., and Mura, T., Growth Mechanism of Stress Corrosion Cracking in High Strength Steel, To be published in Eng. Frac. Mech.Google Scholar