Page 414 - Biaxial Multiaxial Fatigue and Fracture

P. 414

398 M. FILIPPINI ET AL.

2. Brown, M.W. and Miller, K.J. (1973). A Theory for Fatigue Under Multiaxial Stress-
Strain Conditions. Proc. of the IMechE, 187,745-756.
3. Lohr, R.D. and Ellison, E.G. (1980). A Simple Theory for Low Cycle Multiaxial Fatigue.
Fatigue of Eng. Mater. Struct., 3, 1-17.
4. Wang, C.H. and Brown, M.W. (1993). Fatigue Fract. Engng Mater. Struct., 16, 1285-
1298.
5. Socie, D.F. and Marquis, G.B. (2000). Multiaxial Fatigue. SAE, Warrendale, PA.
6. Socie, D.F. (1993). Critical Planes Approaches for Multiaxial Fatigue Damage
Assessment. In: Advances in Multiaxial Fatigue, ASTM STP 11 91, pp. 7-36, McDowell,
D.L. and Ellis, R. (Eds). ASTM, Philadelphia, PA.
7. Garud, Y.S. (1981). A New Approach to the Evaluation of Fatigue Under Multiaxial
Loadings. J. of Engineering Materials and Technology, Trans. of the ASME, 103, 118-
125.
8. Ellyin, F. and Xia, Z. (1993). A General Fatigue Theory and Its Application to Out-of-
Phase Cyclic Loading. J. of Engineering Materials and Technologv, Trans. of the ASME,
115,411-416.
9. Park, J. and Nelson, D. (2000). Evaluation of an energy-based approach and a critical
plane approach for predicting constant amplitude multiaxial fatigue life. Int. J. Fatigue, 22,
23-39.
10. Garud, Y.S. (1981). Multiaxial Fatigue: A Survey of the State of the Art. Journal of
Testing and Evaluation, JTEVA, 9, 165-1 78.
11. McDowell, D.L. (1996). In: Fatigue and Fracture, ASM Handbook Vol. 19, pp. 263-273,
ASM Int.. Materials Park, OH.
12. Eliyin, F.-(1997). Fatigue Damage, Crack Growth and Life Prediction. Chapman & Hall,
London.
13. Sonsino, C.M. and Grubisic, V. (1989). Fatigue Behavior of Cyclically Softening and
Hardening Steels Under Multiaxial Elastic-Plastic Deformation. In: Multiaxial Fatigue,
ASTM STP 853, pp. 586-605, Miller, K.J. and Brown, M.W. (Eds). ASTM, Philadelphia,
PA.
14. Tipton, S.M. and Nelson, D.V. (1985). Fatigue Life Predictions for a Notched Shaft in
Combined Bending and Torsion. In: Multiaxial Fatigue, ASTM STP 853, pp. 514-550,
Miller, K.J. and Brown, M.W. (Eds). ASTM, Philadelphia, PA.
15. Foletti, S. and Passerini, M. (2000). Modelli elasto-plastid e fatica a basso numero di
cicli in stato di sollecitazione multiassiale. Eng. Degree Thesis, (in Italian), Politecnico di
Milano, Milano.
16. Fatemi, A., Kurath, P. (1988). Multiaxial Fatigue Life Prediction Under the Influence of
Mean-Stresses. J. of Engineering Materials and Technology, Trans. of the ASME, 110,
380-388.
17. Socie, D., Kurath, P. and Koch, J. (1989). A Multiaxial Fatigue Damage Parameter. In:
Biaxial and Multiaxial Fatigue, EGF 3, pp. 535-550, Brown, M.W. and Miller, K.J. (Eds).
MEP, London.
18. Kurath, P., Downing, S.D. and GalIiart, D.R. (1989). Summary ofNon-Hardened Notched
Shaft Round Robin Program. In: Multiaxial fatigue: analysis and experiments, pp. 13-31,
Leese, G.E. and Socie, D.F. (Eds). SAE, Warrendale, PA.
19. Doquet, V. and Pineau, A. (1991). Multiaxial Low-Cycle Fatigue Behavior of a Mild
Steel. In: Fatigue under Biaxial and Multiaxial Loading, ESIS 10, 81-101, Kussmaul, K.,
McDiarmid, D. and Socie, D.F. (Eds). MEP, London.
20. Sonsino, C.M. (200 1). Influence of load and deformation-controlled multiaxial tests on
fatigue life to crack initiation. Int. J. Fatigue, 23, 159-1 67.

409 410 411 412 413 414 415 416 417 418 419