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NTIS 바로가기Proceedings of the Institution of Mechanical Engineers. Part J, Journal of engineering tribology, v.228 no.10, 2014년, pp.1047 - 1062
Evans, M-H , Wang, L , Wood, RJK
The formation of white etching cracks in the 1 mm zone beneath the contact surface in steel rolling element bearings causes a premature wear failure mode called white structure flaking. The formation drivers of white etching cracks are contested, as are the initiation and propagation mechanis...
Tamada, K., Tanaka, H.. Occurrence of brittle flaking on bearings used for automotive electrical instruments and auxiliary devices. Wear: An international journal on the science and technology of friction, lubrication and wear, vol.199, no.2, 245-252.
Evans, M-H. White structure flaking (WSF) in wind turbine gearbox bearings: Effects of ‘butterflies’ and white etching cracks (WECs). Materials science and technology : MST : a publication of the Institute of Metals, vol.28, no.1, 3-22.
Kohara, Mika, Kawamura, Takayuki, Egami, Masaki. Study on Mechanism of Hydrogen Generation from Lubricants. Tribology transactions : a publication of the Society of Tribologists and Lubrication Engineers, vol.49, no.1, 53-60.
Motion & Control NSK 1 2004
Kino, Nobuo, Otani, Keizo. The influence of hydrogen on rolling contact fatigue life and its improvement. JSAE review, vol.24, no.3, 289-294.
Uyama, Hideyuki, Yamada, Hiroki, Hidaka, Hideyuki, Mitamura, Nobuaki. The Effects of Hydrogen on Microstructural Change and Surface Originated Flaking in Rolling Contact Fatigue. Tribology online, vol.6, no.2, 123-132.
Evolution Stadler K
Lund, Thore B.. Sub-Surface Initiated Rolling Contact Fatigue-Influence of Non-Metallic Inclusions, Processing History, and Operating Conditions. Journal of ASTM International, vol.7, no.5, 1-12.
J ASTM Int Vegter RH 1 7 2009 10.1520/JAI102543
Greco, A., Sheng, S., Keller, J., Erdemir, A.. Material wear and fatigue in wind turbine Systems. Wear: An international journal on the science and technology of friction, lubrication and wear, vol.302, no.1, 1583-1591.
Evans, M.H., Richardson, A.D., Wang, L., Wood, R.J.K.. Serial sectioning investigation of butterfly and white etching crack (WEC) formation in wind turbine gearbox bearings. Wear: An international journal on the science and technology of friction, lubrication and wear, vol.302, no.1, 1573-1582.
Evans, M.H., Richardson, A.D., Wang, L., Wood, R.J.K.. Effect of hydrogen on butterfly and white etching crack (WEC) formation under rolling contact fatigue (RCF). Wear: An international journal on the science and technology of friction, lubrication and wear, vol.306, no.1, 226-241.
Evans, M.H., Wang, L., Jones, H., Wood, R.J.K.. White etching crack (WEC) investigation by serial sectioning, focused ion beam and 3-D crack modelling. Tribology international, vol.65, 146-160.
Tribol Int Evans M-H
Evans, M.H., Walker, J.C., Ma, C., Wang, L., Wood, R.J.K.. A FIB/TEM study of butterfly crack formation and white etching area (WEA) microstructural changes under rolling contact fatigue in 100Cr6 bearing steel. Materials science & engineering. properties, microstructure and processing. A, Structural materials, vol.570, 127-134.
Transient Process Tribol Kuhn M 459 43 2003
Grabulov, A., Petrov, R., Zandbergen, H.W.. EBSD investigation of the crack initiation and TEM/FIB analyses of the microstructural changes around the cracks formed under Rolling Contact Fatigue (RCF). International journal of fatigue, vol.32, no.3, 576-583.
Rolling bearing, rolling bearing for fuel cell, compressor for fuel cell system and fuel cell system Iso K 2007
Nagumo, M., Nakamura, M., Takai, K.. Hydrogen thermal desorption relevant to delayed-fracture susceptibility of high-strength steels. Metallurgical and materials transactions. A, Physical metallurgy and materials science, vol.32, no.2, 339-347.
Nagumo, M.. Hydrogen related failure of steels - a new aspect. Materials science and technology : MST : a publication of the Institute of Metals, vol.20, no.8, 940-950.
Takai, K., Shoda, H., Suzuki, H., Nagumo, M.. Lattice defects dominating hydrogen-related failure of metals. Acta materialia, vol.56, no.18, 5158-5167.
Murakami, Yukitaka, Matsunaga, Hisao. The effect of hydrogen on fatigue properties of steels used for fuel cell system. International journal of fatigue, vol.28, no.11, 1509-1520.
Matsubara, Y, Hamada, H. A Novel Method to Evaluate the Influence of Hydrogen on Fatigue Properties of High Strength Steels. Journal of ASTM International, vol.3, no.2, 14048-.
Hirth, John P.. Effects of hydrogen on the properties of iron and steel. Metallurgical transactions A, Physical metallurgy and materials science, vol.11, no.6, 861-890.
19th ASM heat treating society proceedings including steel heat treating in the new millennium Walton HW 558 1999
Enomoto, M., Hirakami, D., Tarui, T.. Thermal Desorption Analysis of Hydrogen in High Strength Martensitic Steels. Metallurgical and materials transactions. A, Physical metallurgy and materials science, vol.43, no.2, 572-581.
Weld J Park D 27 2002
Pressouyre, G. M.. A classification of hydrogen traps in steel. Metallurgical transactions A, Physical metallurgy and materials science, vol.10, no.10, 1571-1573.
Birnbaum, H.K., Sofronis, P.. Hydrogen-enhanced localized plasticity-a mechanism for hydrogen-related fracture. Materials science & engineering. properties, microstructure and processing. A, Structural materials, vol.176, no.1, 191-202.
Oriani, R. A.. Whitney Award Lecture-1987:Hydrogen-The Versatile Embrittler. Corrosion, vol.43, no.7, 390-397.
Szost, B.A., Rivera-Diaz-del-Castillo, P.E.J.. Unveiling the nature of hydrogen embrittlement in bearing steels employing a new technique. Scripta materialia, vol.68, no.7, 467-470.
Fujita, Shinji, Matsuoka, Saburo, Murakami, Yukitaka, Marquis, Gary. Effect of hydrogen on Mode II fatigue crack behavior of tempered bearing steel and microstructural changes. International journal of fatigue, vol.32, no.6, 943-951.
Murakami, Yukitaka, Kanezaki, Toshihiko, Mine, Yoji, Matsuoka, Saburo. Hydrogen Embrittlement Mechanism in Fatigue of Austenitic Stainless Steels. Metallurgical and materials transactions. A, Physical metallurgy and materials science, vol.39, no.6, 1327-1339.
Lewis, MWJ, Tomkins, B. A fracture mechanics interpretation of rolling bearing fatigue. Proceedings of the Institution of Mechanical Engineers. Part J, Journal of engineering tribology, vol.226, no.5, 389-405.
Fatigue of materials Suresh S 1991
Grabulov, A., Ziese, U., Zandbergen, H.W.. TEM/SEM investigation of microstructural changes within the white etching area under rolling contact fatigue and 3-D crack reconstruction by focused ion beam. Scripta materialia, vol.57, no.7, 635-638.
Mechanical metallurgy Dieter GE 1986 3
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