Figure 13 Relation between an oxide inclusion located at a triple point and three wings along the prior austenitic grain boundaries. Fish eye in a bearing steel failed in the gigacycle regime. [1] Mughrabi H. Specific features and mechanisms of fatigue in the ultrahigh [2] Bathias C. and Paris P. C (2004). Gigacycle fatigue in mechanical practice, editor: Marcel Dekker, Section [3] Quian G., Zhou C. , Hong Y. Experimental and theoretical investigation of environment and theoretical investigation media on VHCF behavior for a structural steel. Acta Met. 59 (2011) 1321 [4] Murakami Y. The Mechanisms of Fatigue Failure in the Ultra long Life Regime. [5] Sakai T. Review and prospects for current studies on very high cycle fatigue of metallic materials for machine structural use, Fourth International Conference on Very High Cycle Fatigue (VHCF [6]Shiozawa, K.Morii, Y. Nishino. Lu L. Subsurface crack initiation and propagation mechanisms in high strength steel in VHCF regime 2006, 28, 1521-1532 [7] Bathias C., Paris P.C. Initiation in the gigacycle fatigue regime, Fourth International Conference on Very High Cycle Fat TMS (The Minerals, Metals& materials Society),2007[ [8] P. Lukás, L. Kunz, L. Navrátilová, O. Bokuvka: Fatigue Damage of Ultrafine Materials Science and Engineering A, vol. 528, 2011, pp.7036 [9] Muller-Bollengen C., Zimmermann M. , Christ H.J; VHCF behavior of austenitic steel and the effect of induced martensite [10 C. Bathias. ASTM A01Symposium, Tampa, Nov 2011,Gigacycle fatigue: A new Tool For Exploring Bearing Steel; J.ASTM,2012 [11] Wang Chong, Wagner D., Bathias C.Gigacycle Fatigue Mechanisms in Armco Iron, IJF,June 2012 [12 ] Evans M. H. White Structure Flaking in Wind Turbine Gearbox bearings. Mat Sc. And tech. Aug 2011, 1 References [1] Mughrabi H. Specific features and mechanisms of fatigue in the ultrahigh-cycle regime, Int. Jl of fatigue 28 (2006) 1501 7, and ISBN 0 media on VHCF behavior for a structural steel. Acta Met. 59 (2011) 1321-132. Metal Fatigue. Elsevier. Oxford. 2002. UK current studies on very high cycle fatigue of metallic materials for machine structural use, Fourth International Conference on Very High Cycle Fatigue (VHCF-4), TMS (The Minerals, Metals& materials Society),2007 bsurface crack initiation and propagation mechanisms in high strength steel in VHCF regime [8] P. Lukás, L. Kunz, L. Navrátilová, O. Bokuvka: Fatigue Damage of Ultrafine-Grain Copper in Very-High Cycle Fatigue Region, Materials Science and Engineering A, vol. 528, 2011, pp.7036– 7040] Bollengen C., Zimmermann M. , Christ H.J; VHCF behavior of austenitic steel and the effect of induced martensite g, Wagner D., Bathias C.Gigacycle Fatigue Mechanisms in Armco Iron, IJF,June 2012 [12 ] Evans M. H. White Structure Flaking in Wind Turbine Gearbox bearings. Mat Sc. And tech. Aug 2011, 1- 28 (2006) 1501-1508 , and ISBN 0-8247-2313-9 [3] Quian G., Zhou C. , Hong Y. Experimental and theoretical investigation of environment and theoretical investigation of environmental IFJ [7] Bathias C., Paris P.C. Initiation in the gigacycle fatigue regime, Fourth International Conference on Very High Cycle Fatigue (VHCF-4), High Cycle Fatigue Region, 19.
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