Developing bearing steels combining hydrogen resistance and improved hardness

Materials and Design

Volumn 43, Issue , 2013, Pages 499-506

  Szost, B A ^a   Vegter, R H ^a   Rivera Diaz del Castillo P E J ^a  

^a Department of Materials Science and Metallurgy   (United Kingdom)

Author keywords

Hydrogen embrittlement; Nanostructured materials; Precipitation; Steel

Indexed keywords

CARBIDES; HARDNESS; HYDROGEN EMBRITTLEMENT; MICROSTRUCTURE; NANOSTRUCTURED MATERIALS; PRECIPITATION (CHEMICAL); STEEL; STEELMAKING; TEMPERING; THERMAL DESORPTION; TRANSMISSION ELECTRON MICROSCOPY;

AFTER-HEAT TREATMENT; BEARING STEELS; CEMENTITE PRECIPITATES; COMPUTATIONAL MODELLING; HYDROGEN RESISTANCE; HYDROGEN TRAP; LOW HARDNESS; STEEL PRODUCTION TECHNOLOGY; STRENGTHENING PARTICLES; TRAPPING ABILITY;

HYDROGEN;

EID: 84866391696     PISSN: 02613069     EISSN: 18734197     Source Type: Journal    
DOI: 10.1016/j.matdes.2012.07.030     Document Type: Article

References (34)

1. Barrow A.T.W., Rivera-Díaz-del-Castillo P.E.J. Nanoprecipitation in bearing steels. Acta Mater 2011, 59:7155-7167.
2. Furumura K.M., Abe T.Y. Development of long life bearing steel for full film lubrication and for poor and contaminated lubrication. Motion Control 1996, 30-36.
3. Forest B, Saleil J, Damie G. Precipitation of non-metallic inclusions during the solidification of continuously cast bearing steel. In: 2nd European continuous casting conference, vol. 1; 1994. p. 321-8.
4. Ciruna J.A., Szieleit H.J. The effect of hydrogen on the rolling contact fatigue life of AISI 52100 and 440C steel balls. Wear 1973, 107-118.
5. Kino N., Otani K. The influence of hydrogen on rolling contact fatigue life and its improvement. Soc Automot Eng Jpn 2003, 24:289-294.
6. Evans M.H. White structure flaking (WSF) in wind turbine gearbox bearings: effects of 'butterflies' and white etching cracks (WECs). Mater Sci Technol 2012, 28:3-22.
7. Toribio J. Hydrogen embrittlement of prestressing steels: the concept of effective stress in design. Mater Design 1997, 18:81-85.
8. Siddiquia S., Abdul-Wahaba R.A., Bakheit C. Investigating the variation in the properties of hydrogenated 0.31% carbon steel. Mater Design 2008, 29:922-927.
9. Oldena C., Thaulowa V., Johnsen R. Modelling of hydrogen diffusion and hydrogen induced cracking in supermartensitic and duplex stainless steels. Mater Design 2008, 29:1934-1948.
10. Thomas R.L.S., Scully J.R., Gangloff R.P. Internal hydrogen embrittlement of ultrahigh-strength AERMET 100 steel. Metall Mater Trans 2003, 34A:327-342.
11. Nagumo M., Nakamura M. Hydrogen thermal desorption relevant to delayed-fracture susceptibility of high-strength steels. Metall Mater Trans A 2001, 339-347.
12. Pressouyre G.M. The classification of hydrogen traps in steel. Metall Trans A 1979, 10A:1571-1573.
13. Michler T., Balogh M. Hydrogen environment embrittlement of an ODS RAF steel - role of irreversible hydrogen trap sites. Int J Hydrog Energy 2010, 35:9746-9754.
14. Murakami Y. Effects of small defects and nonmetallic inclusions on the fatigue strength of metals. Mech Corros Prop 1991, 51-52:37-42.
15. Luzginova N. Microstructure and transformation kinetics in bainitic steels. PhD thesis, Delft University of Technology; 2008. p. 16-8.
16. 3 precipitation in Fe-C-Mo-V steels and relationship to hydrogen trapping. Proc Roy Soc A 2006, 2315-2330.
17. Barrow A.T.W., Kang J.-H., Rivera-Díaz-del-Castillo P. ε{lunate}→η→θ transition in 100Cr6 and the effect on mechanical properties. Acta Mater 2012, 60:2805-2815.
18. Miller P., Beaven M.K., Smith G. An atom probe study of the ageing of iron-nickel-carbon martensite. Metall Trans A 1983, 1021-1024.
19. Choo W.Y., Young Lee J. Thermal analysis of trapped hydrogen in pure iron. Metall Trans A 1982, 135-140.
20. Choo W., Young Lee J. Hydrogen trapping phenomena in carbon steel. J Mater Sci 1982, 17:1930-1938.
21. Tarui T., Yamasaki S. Evaluation method of delayed fracture property and overcoming techniques of delayed fracture of high strength steels. Tetsu-To-Hagane/J Iron Steel Inst Jpn 2002, 88:612-619.
22. Pressouyre G.M. A classification of hydrogen traps in steel. Metall Trans A 1979, 10:1571-1573.
23. Effenberg G. Ternary alloy systems. Phase diagrams. Crystallographic and thermodynamic data. Iron systems. Selected systems from C-Cr-Fe to Co-Fe-S, vol. IV/11D2S. Berlin Heidelberg New York: Springer; 2008.
24. Hagihara Y., Takai K., Hirai K. Delayed fracture using CSRT and hydrogen trapping characteristic of V-bearing high-strength steel. ISIJ Int 2012, 52:298-306.
25. Wei FG, Hara T. Nano-precipitates design with hydrogen trapping character in high strength steels. In: Proceedings of the 2008 international hydrogen conference; 2008. p. 448-55.
26. Eliezer T, Boellinghaus D. Hydrogen trapping mechanisms in structural materials. In: Proceedings of the 2008 international hydrogen conference; 2008.
27. Enomoto M., Hirakami D. Thermal desorption analysis of hydrogen in high strength martensitic steels. Metall Mater Trans A 2011, 1-10.
28. 3Ti intermetallic nanoprecipitates. Acta Mater 2010, 58:3582-3593.
29. Xu W., Rivera-Díaz-Del-Castillo P.E.J., Yan W., Yang K., San Martn D., Kestens L.A.I., et al. A new ultrahigh-strength stainless steel strengthened by various coexisting nanoprecipitates. Acta Mater 2010, 58:4067-4075.
30. Takahashi J., Kawakami K. The first direct observation of hydrogen trapping sites in tic precipitation-hardening steel through atom probe tomography. Scripta Mater 2010, 261-264.
31. Hong G., Lee J.Y. The interaction of hydrogen and the cementite-ferrite interface in carbon steel. J Mater Sci 1983, 18:271-277.
32. Lee J., Lee S.M. Hydrogen trapping phenomena in metals with B.C.C. and F.C.C. structure by the thermal desorption analysis technique. Surf Coat Technol 1986, 28:301-314.
33. Maroef I. Hydrogen trapping in ferritic steel weld metal. Int Mater Rev 2002, 4:191-223.
34. Park Y.D., Maroef A., Landau A. Retained austenite as a hydrogen trap in steel welds. Weld J 2002, 27-35.