Nanoprecipitation in bearing steels
Nanoprecipitation in bearing steels
θ-phase is the main hardening species in bearing steels and appears in both martensitically and bainitically hardened microstructures. This work presents a survey of the microstrucural features accompanying nanoprecipitation in bearing steels. Nanoprecipitate structures formed in 1C-1.5Cr wt.% with additions of Cr, Mn, Mo, Si and Ni are studied. The work is combined with thermodynamic calculations and neural networks to predict the expected matrix composition, and whether this will transform martensitically or bainitically. Martensite tetragonality, composition and the amount of retained austenite are related to hardness and the type of nanoprecipitate structures in martensitic grades. The θ-phase volume fraction, the duration of the bainite to austenite transformation and the amount of retained austenite are related to hardness and a detailed quantitative description of the precipitate nanostructures. Such description includes compositional studies using energy-dispersive spectroscopy, which shows that nanoprecipitate formation takes place under paraequilibrium. Special attention is devoted to a novel two-step bainite tempering process which shows maximum hardness; we prove that this is the most effective process for incorporating solute into the precipitates, which are finer than those resulting from one-step banitic transformation processes.
Carbides, Nanostructure, Precipitation, Steels, Tempering
7155-7167
Barrow, A.T.W.
ffad9c70-d98f-4f91-a74d-7d99c8cde11a
Rivera-Díaz-Del-Castillo, P.E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
November 2011
Barrow, A.T.W.
ffad9c70-d98f-4f91-a74d-7d99c8cde11a
Rivera-Díaz-Del-Castillo, P.E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Abstract
θ-phase is the main hardening species in bearing steels and appears in both martensitically and bainitically hardened microstructures. This work presents a survey of the microstrucural features accompanying nanoprecipitation in bearing steels. Nanoprecipitate structures formed in 1C-1.5Cr wt.% with additions of Cr, Mn, Mo, Si and Ni are studied. The work is combined with thermodynamic calculations and neural networks to predict the expected matrix composition, and whether this will transform martensitically or bainitically. Martensite tetragonality, composition and the amount of retained austenite are related to hardness and the type of nanoprecipitate structures in martensitic grades. The θ-phase volume fraction, the duration of the bainite to austenite transformation and the amount of retained austenite are related to hardness and a detailed quantitative description of the precipitate nanostructures. Such description includes compositional studies using energy-dispersive spectroscopy, which shows that nanoprecipitate formation takes place under paraequilibrium. Special attention is devoted to a novel two-step bainite tempering process which shows maximum hardness; we prove that this is the most effective process for incorporating solute into the precipitates, which are finer than those resulting from one-step banitic transformation processes.
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Accepted/In Press date: 7 August 2011
e-pub ahead of print date: 22 September 2011
Published date: November 2011
Keywords:
Carbides, Nanostructure, Precipitation, Steels, Tempering
Identifiers
Local EPrints ID: 492720
URI: http://eprints.soton.ac.uk/id/eprint/492720
ISSN: 1359-6454
PURE UUID: a4ba13bf-2005-4408-92d5-a3e2a17489ff
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Date deposited: 13 Aug 2024 16:31
Last modified: 14 Aug 2024 02:07
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Author:
A.T.W. Barrow
Author:
P.E.J. Rivera-Díaz-Del-Castillo
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