Role of the Process Zone in Fatigue Crack Initiation and Propagation

• Autorzy: Panasyuk V. , Ostash O.
• Konferencja: The First European Summer School of Fatigue and Fracture (ESSFF1) and The Ninth Polish-Ukrainian-German Summer of Fracture Mechanics (SSFM9) on NEW RESULTS IN FATIGUE AND FRACTURE. Vol.1 (1,9;19-26.06.2005;Zakopane;Polska)
• Języki publikacji: EN

Słowa kluczowe

EN

fatigue crack; fracture mechanics

• Wydawca: Oficyna Wydawnicza Politechniki Opolskiej
• Czasopismo: Zeszyty Naukowe. Mechanika / Politechnika Opolska
• Rocznik: 2005
• Tom: z. 79
• Strony: 243--256
• Opis fizyczny: Bibliogr. 26 poz., rys., tab.

Twórcy

autor

Panasyuk V.

• Karpenko Physico-Mechanical Institute of NAS of Ukraine

autor

Ostash O.

• Karpenko Physico-Mechanical Institute of NAS of Ukraine

Bibliografia

• [1] Schijve J.: Predictions on fatigue life and crack growth as an engineering problem. A state of the. art survey, Fatigue '96, Vol. II, Proceedings ofthe Sixth InternatiOnal Fatigue Congress, 6-10 May 1996, Berlin, Germany Pergamon Press, p.p. 1149-1164.
• [2] Ostash O.P., Panasyuk V.V., Kostyk C.M.: A phenomenological model of fatigue macrocrack initiation near stress concentrators, Fatigue Fract. Engng Mater. Struct., 1999, Nr 2, p. p. 161-172.
• [3] Pangborn R.N., Weismaim S., Kramer J.R.: Work hardening in the surface layer and in hulk during fatigue, Scripta Metallurgica, 1978, N2 2, p.p. 129-131.
• [4] Alyohin V.P.: Physics of Strength and Plasticity of Material Surface Layers, Moscow, Nauka, 1983, 280 p.p. (in Russian).
• [5] Prokorenko A.V., Torgov V.N.: Surface properties and fatigue limit of metal. Communication 1. Yield strength dependence on the depth of layer, Problems of Strength, 1986, Nr 4, p.p. 28-34 (in Russian).
• [6] Keller R., Gerberich W.W.: Surface versus hulk deformation in fatigue, Scripta Metallurgica, 1989, Nr 7, p.p. 1115-1120.
• [7] Ostash O.P., Panasyuk V.V.: Fatigue process zone at notches, Int. J. Fatigue, 2001, Nr 7, p. p. 627-636.
• [8] Pluvinage G.: Fatigue and fracture emanating from notch; the use o f the notch stress intensity factor, Nuclear Engng Design, 1998, Nr 185, p.p. 173-184.
• [9] Qylafsku G., Azari Z., Kadi N., Gjonaj N., Pluvinage G.: Application of a new model proposal for the fatigue life prediction on notches and key-seats, Int. J. Fatigue, 1999, Nr 8, p.p. 753-760.
• [10] Ostash O.P., Panasyuk V.V.: A unified approach to fatigue macrocrack initiation and propagation, Int. J. Fatigue, 2003, Nr 8, p. p. 703-708.
• [11] Ahmed H.Y. De los Rios E.R., Yates J.R.: The influence of notch plastisity on short fatigue crack behaviour, Fatigue Fract. Engng Mater. Struct., 1994, Nr 2, p.p. 235-242.
• [12] Chemini C., Angot G., Chacrone A., Pluvinage G.: Stress, strains and plastisity at notch tip, Proceedings of the 1st Workshop on Influence of Local Stress and Strain Concentrators on the Reliability and Safety of Structures, 10-12 April 1995, Miskole- Apolca, Hungary.
• [13] Chien C.-H., Coffin L.F.: A new metbod for predicting fatigue life in notched geometries, Fatigue Fract. Engng Mater. Struct., 1998, Nr l, p.p. 1-15.
• [14] Lukas P., Kiesnil M.: Fatigue limit and notched bodies, Mater. Sci. Engng, 1978, Nr l, p.p. 61-66.
• [15] Peterson R.E.: Notch sensitivity, Metal fatigue (Sines G., Weisman I.L., editors), New York, Me Craw-Hill, 1959, p.p. 293-306.
• [16] Neuber H.: Kerbspannungslehre, Berlin, Springer, 1945. (Trans. Theory of Notch Stress, U.S. Office of Technical Services, 1961).
• [17] Peterson R.E.: Stress concentration factor, New York, John Wiley and Sons, 1974.
• [18] Taylor D., Wang G.: The validation of some methods of notch fatigue analysis, Fatigue Fract. Engng Mater. Struct., 2000, v. 23, p. p. 387-394.
• [19] 0stash O.P., Panasyule V.V.: Theory of initiation and propagation of fatigue cracle, Soviet Materials Science, 1988, Nr 1, p.p. 10-17 .
• [20] Majumdar S., Morrow J.D.: Correlation between fatigue crack propagation and law cycle fatigue properties, Fracture Toughness and Slow-Stable Cracking, ASTM STP 559, American Society for Testing and Materials, 1974, p.p. 159-182.
• [21] Lal D.N., W eis V.: A notch analysis of fracture approach to fatigue crack propagation, Metallurgical Transactions, 1978, Nr 3, p.p. 413-426.
• [22] Glinka G.: A notch stress-strain analysis approach to fatigue crack growth, Engng Fract. Mech., 1985, Nr 2. p.p. 245-261.
• [23] Furuya Y., Shimada H.: Local crack-tip strain approach to fatigue crack propagation, Engng Fract. Mech., 1987, Nr 3, p.p. 349-356.
• [24] Klesnil M., Lukas P.: Fatigue of metalic materials, Prague, Academia, 1980, 239 p.p.
• [25] Troshchenko V.T. Investigation of the threshold stress intensity factors at cyclic loading. Communication 2. Prediction of the fatigue limit and the fatigue crack propagation, Problems of Strength, 1998, Nr 5, p.p. 5-11 (in Russian).
• [26] Yarema S.Ya., Ostash O.P.: About the fracture toughness of materials at cyclic loading, Soviet Material Science, 1978, Nr 5, p.p. 112-114.