Details Details PDF BIBTEX RIS Title The Effect of the Production Process and Heat Processing Parameters on the Fatigue Strength of High-Grade Medium-Carbon Steel Journal title Archives of Foundry Engineering Yearbook 2012 Issue No 2 Authors Lipiński, T. ; Wach, A. Keywords heat treatment ; metallography ; Steel ; fatigue strength ; Fatigue Durability ; production process Divisions of PAS Nauki Techniczne Publisher The Katowice Branch of the Polish Academy of Sciences Date 2012 Type Artykuły / Articles Identifier DOI: 10.2478/v10266-012-0036-7 ; eISSN 2299-2944 Source Archives of Foundry Engineering; 2012; No 2 References Borowiecki B. (2011), Casting defects analysis by the Pareto method, Archives of Foundry Engineering, 11, 3, 33. ; Gajewski M. (2009), Rare earth metals influence on morphology of non-metallic inclusions and mechanism of GP240GH and G17CrMo5-5cast steel cracking, Archives of Foundry Engineering, 9, 4, 45. ; Lipiński T. (2010), The effect of the production process of medium-carbon steel on fatigue strength, Archives of Foundry Engineering, 10, 2, 79. ; Senberger J. (2011), Checking the metallurgy with the aid of inclusion analysis, Archives of Foundry Engineering, 11, 1, 118. ; Lipiński T. (2009), The effect of out-of-furnace treatment on the properties of high-grade medium-caborn structural steel, Archives of Foundry Engineering, 10, 93. ; Wypartowicz J. (2005), The influence of non - metallic inclusions in steel with progressive solidification, Hutnik - Wiadomości Hutnicze, 1. ; Lipiński T. (2010), The Share of Non-Metallic Inclusions in High-Grade Steel for Machine Parts, Archives of Foundry Engineering, 10, 4, 45. ; Kalandyk B. (2006), The Influence Of The Deoxidation And Modification On The Morphology Of Non-Metallic Inclusion In The Carbon Cast Steels, Archives Of Foundry, 6, 18, 419. ; Roiko A. (2012), Anisotropic distribution of non-metallic inclusions in a forged steel roll and its influence on fatigue limit, International Journal of Fatigue, 41, 158, doi.org/10.1016/j.ijfatigue.2011.12.023 ; Miner M. (1945), Cumulative damage in fatigue, Trans. ASM, 65, 159. ; Kocańda S. (1985), Zmęczeniowe pękanie metali. ; Pyttel B. (2011), Very high cycle fatigue - Is there a fatigue limit?, International Journal of Fatigue, 33, 49, doi.org/10.1016/j.ijfatigue.2010.05.009 ; Lis T. (2002), Modification of non-metallic dispersion phase in steel, Metallurgy and Foundry Engineering, 1/28, 29. ; Murakami Y. (2002), Metal fatigue, Effects of small defects and nonmetallic inclusions, 57. ; Yang Z. (2010), Relationship among fatigue life, inclusion size and hydrogen concentration for high-strength steel in the VHCF regime, Materials Science and Engineering A, 527, 559, doi.org/10.1016/j.msea.2009.10.056 ; Ekengren J. (2012), Extreme value distributions of inclusions in six steels, Extremes, 15, 257, doi.org/10.1007/s10687-011-0139-5 ; Saberifar S. (2012), The interaction between non-metallic inclusions and surface roughness in fatigue failure and their influence on fatigue strength, Materials and Design, 35, 720, doi.org/10.1016/j.matdes.2011.10.028 ; Costa N. (2011), On a new temperature factor to predict the fatigue limit at different temperatures, International Journal of Fatigue, 33, 624, doi.org/10.1016/j.ijfatigue.2010.11.004 ; Kailash Jajam (2012), Role of inclusion stiffness and interfacial strength on dynamic matrix crack growth: An experimental study, International Journal of Solids and Structures, 49, 1127, doi.org/10.1016/j.ijsolstr.2012.01.009 ; Lipiński T. (2009), Non-metalic inclusions structure dimension in high quality steel with medium caborn contents, Archives of Foundry Engineering, 9, 75.