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TECHNICAL PAPERS

High-Cycle Thermal Fatigue Crack Initiation and Growth Behavior in a Semi-Infinite Plate Model

[+] Author and Article Information
Makoto Hayashi

Mechanical Engineering Research Laboratory, Hitachi, Ltd., Tsuchiura, Ibaraki, 300-0013 Japane-mail: hayashi@merl.hitachi.co.jp

J. Pressure Vessel Technol 123(3), 305-309 (Feb 05, 2001) (5 pages) doi:10.1115/1.1372327 History: Received March 20, 1998; Revised February 05, 2001
Copyright © 2001 by ASME
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References

Hayashi,  M., Enomoto,  K., Saito,  T., and Miyagawa,  T., 1998, “Development of Thermal Fatigue Testing Apparatus With BWR Water Environment and Thermal Fatigue Strength of Stainless Steel,” Nucl. Eng. Des., 184, pp. 113–122.
Hayashi,  M., 1998, “Thermal Fatigue Behavior of Thin-Walled Cylindrical Carbon Steel Specimens in Simulated BWR Environment,” Nucl. Eng. Des., 184, pp. 123–133.
Hayashi,  M., 1998, “Thermal Fatigue of Type 304 Stainless Steel in Simulated BWR Environment,” Nucl. Eng. Des., 184, pp. 135–144.
Hirano,  A., Hayashi,  M., Takehara,  H., Tanaka,  M., and Iikura,  T., 1998, “Development of a Facility for High Cycle Thermal Fatigue Testing in Pure Water and Measurement of Heat Transfer Coefficient in an Annular Gap between Rotating Inner and Stationary Outer Cylinders,” Trans. Jpn. Soc. Mech. Eng., Ser. A, 64, pp. 1468–1474.
Hirano, A., Hayashi, M., Sagawa, W., Takehara, H., Tanaka, M., and Iikura, T., 1994, “High Cycle Thermal Fatigue Crack Initiation Behavior of Austenitic Type 304 Stainless Steel in Pure Water,” ASME PVP-Vol. 287, pp. 19–25.
Marsh,  D. J., 1981, “A Thermal Shock Fatigue Study of Type 304 and 316 Stainless Steel,” Fatigue Eng. Mat. Sruc., 4, pp. 179–195.
Bethge,  K., Munz,  D., and Stamm,  H., 1988, “Growth of Semi-Elliptical Surface Cracks in Ferritic Steel Plates under Cyclic Thermal Shock Loading,” Fatigue Fract. Eng. Mater. Struct., 11, pp. 467–482.
Fukuda,  Y., Satoh,  Y., Abe,  H., and Modokoro,  M., 1994, “Crack Propagation and Arrest Behavior under Thermal Striping in Liquid Sodium,” J. Soc. Mater. Sci. Jpn., 43, pp. 1591–1596.
Buchalet,  C. B., and Bamford,  W. H., 1976, “Stress Intensity Factor Solutions for Continuous Surface Flaws in Reactor Pressure Vessel,” Mechanics of Crack Growth, ASTM Spec. Tech. Publ., ASTM STP590, ASTM, pp. 385–402.
Shiratori, M., Yu, Q., Nishijima, A., and Watanabe, K., 1995, “Analysis of Stress Intensity Factors for Surface Cracks in Thermal Stress Field” ASME PVP-Vol. 305, pp. 379–385.
Fett, T., and Munz, D., 1997, Stress Intensity Factors and Weight Functions, Computational Mechanics Publications, pp. 285–288.
Andersson, P., et al., 1996, “A Procedure for a Safety Assessment of Components with Cracks—Handbook,” 3rd Revised Edition, SAQ KONTROLL AB, pp. 38–41.
Usami,  S., Fukuda,  Y., and Shida,  S., 1986, “Micro-Crack Initiation, Propagation and Threshold in Elevated Temperature Inelastic Fatigue,” ASME J. Pressure Vessel Technol., 108, pp. 214–225.
Delvin, S. A., and Ricardella, P. C., 1978, “Fracture Mechanics Analysis of JAERI Model Pressure Vessel Test,” ASME PVP-Vol. 91, pp. 1–8.

Figures

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Mechanism of thermal fatigue crack initiation at a T-connection joint
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Magnification factors for calculation of stress intensity factor 9
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Relationship between frequency and stress amplitude on n metal surface
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S-N curve of type 304 stainless steel
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Allowable temperature range for crack initiation
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Temperature distribution near a metal surface
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Stress distribution near a metal surface (f=1–20 Hz)
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Stress distribution near a metal surface (f=0.1–1 Hz)
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Stress distribution near a metal surface (f=0.01–0.1 Hz)
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Stress intensity distribution near a metal surface (f=1–20 Hz)
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Stress intensity distribution near a metal surface (f=0.1–1 Hz)
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Stress intensity distribution near a metal surface (f=0.01–0.1 Hz)
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Effect of heat convection coefficient on stress distribution (f=1 Hz)
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Effect of heat convection coefficient on stress intensity distribution (f=1 Hz)
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Relationship between crack arrest depth and frequency

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