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Effects of High Mean Stress on Fatigue of Nodular Cast Iron
Technical Paper
2003-01-0911
ISSN: 0148-7191, e-ISSN: 2688-3627
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English
Abstract
The effects of high mean stresses on the fatigue behavior of nodular iron are studied in this paper. The high mean stresses are applied by two constant- minimum stress test sets and one constant- maximum stress test set. These constant maximum/minimum stress tests, together with standard fully reversed fatigue tests and overload tests, are specially designed not only to show mean stress effects on the fatigue behavior of materials but also to help determine material constants that can be used with a closure-based fatigue method to perform fatigue analysis. The ability of various fatigue methods in predicting mean stress effects on fatigue is also assessed.
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Citation
Chu, C. and Chernenkoff, R., "Effects of High Mean Stress on Fatigue of Nodular Cast Iron," SAE Technical Paper 2003-01-0911, 2003, https://doi.org/10.4271/2003-01-0911.Also In
References
- DuQuesnay D.L. MacDougall C. Dabayeh A. Topper T.H. Notch Fatigue Behavior as Influenced by Periodic Overloads Int. J. Fatigue 17 2 91 99 1995
- Gungor S. Edwards L. Effect of Surface Texture on the Initiation and Propagation of Small Fatigue Cracks in a Forged 6082 Aluminum Alloy Materials Science and Engineering A160 1 17 24 15 Jan 1993
- MacDougall C. Topper T.H. The Influence of Variable Amplitude Loading on Crack Closure and Notch Fatigue Behavior Int. J. Fatigue 19 389 400 1997
- Dabayeh, A. A. MacDougall C. Topper, T. H. Crack Opening Stress Reductions due to Overloads and Underloads in 2024-T351 Aluminum SAE 1045 Steel. In Proceedings 6th International Fatigue congress (Fatigue ’96) 589 594 1996
- DuQuesnay D.L. Pompetzki M.A. Topper T.H. Fatigue Life Predictions for Variable Amplitude Strain Histories SAE Trans 102 455 465 1993
- DuQuesnay D.L. Topper T.H. Yu M.T. Pompetzki M.A. The Effective Stress Range as a Mean Stress Parameter Int. J. Fatigue 14 1 45 50 1992
- Constant Amplitude Low-Cycle Fatigue Testing 1990 Annual Book of ASTM Standards 03.01 E606 ASTM Philadelphia, Pa
- Pompetzki M.A. Saper R.A. Topper T.H. Software for high frequency control of variable amplitude fatigue tests Can. Metall. Q. 25 181 194 1986
- Chernenkoff R.A. Fully Reversed and Mean Stress Fatigue Tests of Nodular Cast Irons http://www.fatigue.org/data.html
- Smith K.N. Watson P. Topper T.H. A Stress Strain Function for the Fatigue of Metals J. Materials 5 4 767 778 1970
- Brown M.W. Miller K.J. A Theory for Fatigue under Multiaxial Stress-Strain Conditions Procs. Inst. Mech. Engrs 187 65 745 755 1973
- Fatemi A. Kurath P. Multiaxial Fatigue Life Predictions under the Influence of Mean Stresses ASME J. Engrg. Matls. Tech. 110 380 388 1988
- Goodman J. Mechanics Applied to Engineering Longmans, Green & Company London 1899
- Morrow J. Fatigue Properties of Metals Fatigue Design Handbook, SAE 21 30 1968
- Vormwald M. Seeger T. The Consequences of Short Crack Closure on Fatigue Crack Growth under Variable Amplitude Loading Fat. and Frac. Engrg. Matls. Structs 14 2/3 205 225 1991
- Dabayeh A.A. Topper T.H. Changes in Crack Opening Stress after Underloads and Overloads in 2024-T351 Aluminum Alloy Int. J. Fatigue 17 261 269 1995
- Chu C.-C. Chernenkoff R.A. Bonnen J.J.F. Experiments and Analysis of Mean Stress Effects on Fatigue for SAE 1045 Steels Fatigue & Fracture Mechanics 33rd ASTM STP 1417 Reuter W.G. Piascik R.S. 493 509 2002
- DuQuesnay D.L. Fatigue Damage Accumulation in Metals subjected to High Mean Stress and OverloadCycles Ph.D Thesis Univ. Waterloo, Ontario Canad 1991
- Chu C.-C. Chernenkoff R.A. Crack closure- based analysis of fatigue tests with mean stresses Int. J. Fatigue 23 S187 S194 2001