Mixed-mode fatigue crack growth in stainless steels under biaxial loading

Journal of Engineering Materials and Technology, Transactions of the ASME

Volumn 118, Issue 3, 1996, Pages 349-355

  Wang, Ming ^a   Qian, Cai Fu ^a   Wu, Bao Juan ^a   Dai, Shu Ho ^a   Li, J C M ^b  

^a NANJING TECH UNIVERSITY   (China)

^b UNIVERSITY OF ROCHESTER   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CALCULATIONS; CRACK INITIATION; CRACK PROPAGATION; DEFLECTION (STRUCTURES); FATIGUE TESTING; FRACTURE MECHANICS; LOADS (FORCES); STEEL TESTING; STRAIN; STRESS ANALYSIS; STRESS INTENSITY FACTORS;

BIAXIAL LOADING; BRANCHED CRACKS; CRACK GROWTH ANGLES; DEFLECTED CRACKS; MIXED MODE FATIGUE CRACK GROWTH; STRAIN ENERGY DENSITY FACTOR;

STAINLESS STEEL;

EID: 0030195819     PISSN: 00944289     EISSN: 15288889     Source Type: Journal    
DOI: 10.1115/1.2806817     Document Type: Article

References (30)

1. Bold, P. E., Brown, M. W., and Allen, R. J., 1992, “A Review of Fatigue Crack Growth in Steels Under Mixed-Mode I and II Loading” Fatigue Fract Engng Mater. Struct., vol. 15, No, 10, pp. 965-977.
2. Chambers, A. C., Hyde, T. H., and Webster, J. J., 1991, “Mixed Mode Fatigue Crack Growth at 550°C Under Plane Stress Conditions in Jethete M152,” Engng, Fract. Mech, vol. 39, No. 3, pp. 603-609.
3. Davis, Joseph R., et al., 1990, “Metal Handbook,” ASM International, vol. 1, Tenth edition, pp. 870-954.
4. Erdogan, F., Sih, G. C., 1963, “On the Crack Extension in Plates Under Plane Loading and Transverse Shear” ASME, JOURNAL BASIC ENGINEERING, vol. 85, pp. 519-527.
5. Gao, H., Alagok, N., Brown, M. W., and Miller, K. J., 1985, “Growth of Fatigue Cracks Under Combined Mode I and Mode II Loads” Multiaxial Fatigue, ASTM STP 853, K. J. Miller and M. W. Brown, eds., American Society for Testing and Materials, pp, 184-202.
6. Gdoutos, E. E., 1987, “Mixed-Mode Crack Growth Predictions,” Engng, Fract. Mech., vol. 28, pp. 211-221.
7. Guo, Y. H., and Srivatsan, T. S., 1994, “Influence of Mixed-Mode Loading on Fatigue-Crack Propagation,” Engng Fract. Mech., vol. 47, No. 6, pp. 843-866.
8. Hussain, M. A., Pu, S. L., and Underwood, J., 1974, “Strain Energy Release Rate for a Crack Under Combined Mode I and Mode II Loading,” Fracture Analysis, ASTM STP 560, pp, 2-28.
9. Kitagawa, H., Yuuki, R., Tohgo, K., and Tanabe, M., 1985, “A Dependency of Fatigue Growth of Single and Mixed-Mode Cracks Under Biaxial Stresses,” Multiaxial Fatigue, ASTM STP 853, K. J. Miller and M. W. Brown, eds American Society for Testing and Materials, pp. 111-134.
10. Liu, H. W., 1985, “Shear Fatigue Crack Growth: a Literature Survey,” Fatigue Fract. Engng. Mater. Struct, vol. 8, No. 4, pp. 295-313.
11. Mageed, A. M. Abdel, and Pandey, R. K., 1991, “Mixed Mode Crack Growth Under Static and Cyclic Loading in Ai-Alloy Sheets,” Engng. Fract. Mech., vol, 40, No. 2, pp. 371-385.
12. Melin, S., 1986, “When Does a Crack Grow Under Mode II Conditions,” Iit. J. Fract 30, pp, 103-114.
13. Otsuka, A., and Aoyama, M., 1991, “Mode II Fatigue Under Compression Stress Field, a Simplified Model of Rolling Contact FatiguePresented at MMFF 91”, Vienna, Austria, pp, 15-19.
14. Otsuka, A., Mori, K., Okshoma, T., and Tsuyama, S., 1981, “Mode II Fatigue Crack Growth in Aluminum Alloys and Mild Steel,” Advances in Fracture Research-Pro. 5th Int. Conf. Fract, Cannes, pp. 1851-1858.
15. Otsuka, A., Mori, K., and Miyata, T., 1975, “The Condition of Fatigue Crack Growth in Mixed Mode Condition,” Engng Fract. Mech., vol. 7, pp. 429-439.
16. Palaniswamy, K., and Knauss, K. G., 1972, “Propagation of A Crack Under General Inplane Tension,” Int. J. Fract Mech. 8, pp. 114-117.
17. Pandey, R. K., and Patel, A. B., April 1984, “Mixed-Mode Fatigue Crack Growth Under Biaxial Loading,” Int. J. Fatigue, pp. 119-123.
18. Qian, 1996, “On Mixed-Mode Fatigue Crack Growth and Dislocation Emission from a Mode I Crack,” Ph.D. Thesis, Nanjing Institute of Chemical Technology, P. R. China.
19. Qian, C. F., Wang, M. O., Wu, B. J., Dai, S. H., and Li, J. C. M., 1996, “Symmetric Branching of Mode II and Mixed-Mode Fatigue Crack Growth in a Stainless Steel,” next paper.
20. Roberts, R., and Kibler, J. J., 1971, “Mode II Fatigue Crack Propagation,” ASME J, Basic Engng., pp. 671-680.
21. Sakane, M., Ohnami, M., and Sawada, M., 1987, “Fracture Modes and Low Cycle Biaxial Fatigue Life at Elevated Temperature,” ASME J. ENGINEERING MATER. TECHNOL., vol. 109, No. 3, pp. 236-243.
22. Shlyannikov, V. N., and Braude, N. Z., 1992, “A Model for Predicting Crack Growth Rate for Mixed-Mode Fracture Under Biaxial Loads,” Fatigue Fract. Engng. Mater. Struct., vol. 15, No. 9, pp. 825-844.
23. Sih, G. C., 1974, “Strain-Energy-Density Factor Applied to Mixed Mode Crack Problems,” Int. J. Fract., vol. 10, No. 3, pp. 305-321.
24. Sih, G. C., and Barthélémy, N., 1980, “Mixed-Mode Fatigue Crack Growth Predictions,” Engng. Fract Mech., vol. 13, pp. 439-451.
25. Smith, E. W., and Pascoe, K. J., 1983, “The Behavior of Fatigue Cracks Subject to Applied Biaxial Stress: a Review of Experimental Evidence,” Fatigue Engng. Mater, Struct, vol. 6, No, 3, pp. 201-204.
26. Smith, E. W., and Pascoe, K. J., 1985, “Fatigue Crack Initiation and Growth in a High-Strength Ductile Steel Subject to in-Plane Biaxial Loading,” Multiaxial Fatigue, ASTM STP 853, K. J. Miller and M. W. Brown, eds., American Society for Testing and Materials, pp. 111-134.
27. Smith, M. C., 1984, “Some Aspects of Mode II Fatigue Crack Growth,” Ph.D thesis, Churchill College, Department of Engineering, University of Cambridge.
28. Wang, M. O., Hu, R. H., Zhang, C. J., and Dai, S. H., 1992, “An Experimental Investigation on the Fatigue Crack Growth in Mode II Condition,” Proceedings; 7th Int. Conf. Pressure Vessel Technol, Germany, vol. 2, pp. 1413-1427.
29. Woo, C. W., and Ling, L. H., 1984, “On Angle Crack Initiation under Biaxial Loading,” J. Strain Analysis, vol. 19, pp. 51-59.
30. Zamrick, S. Y., Seibi, A., and Davies, D. C., 1991, “Fatigue Crack Initiation from an Induced Angled Surface Crack Under Biaxial Anticlastic Bending,” Fatigue Under Biaxial and Multiaxial Loading, ESIS 10, pp. 223-238.