Austenite formation and grain refinement in C-Mn steels

The present work deals with grain refinement and austenite formation in a plain C-Mn steel with 0.17C-0.74Mn (wt pct). To improve the limited work hardening capability of ultrafine grained ferritic steels, new approaches were adopted to develop bimodal ferrite grain size distributions and ultrafine...

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Main Author: Azizi-Alizamini, Hamid
Language:English
Published: University of British Columbia 2011
Online Access:http://hdl.handle.net/2429/30513
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-BVAU.-305132013-06-05T04:19:24ZAustenite formation and grain refinement in C-Mn steelsAzizi-Alizamini, HamidThe present work deals with grain refinement and austenite formation in a plain C-Mn steel with 0.17C-0.74Mn (wt pct). To improve the limited work hardening capability of ultrafine grained ferritic steels, new approaches were adopted to develop bimodal ferrite grain size distributions and ultrafine grained dual phase microstructures. The first approach is based on deformation and annealing of a ferrite-martensite microstructure. Ultrafine grained dual phase steels were obtained through rapid heating of very fine ferrite-carbide aggregates into the intercritical annealing region where partial austenite formation takes place. Hence, austenite formation was systematically investigated using a combination of microstructure characterization and detailed dilatometry analysis. The effect of initial structure and heating rate on austenite formation was examined. The resulting microstructure characteristics and mechanical properties of dual phase steels were also investigated. A multi-phase field modelling approach was adopted to simulate austenite formation from a variety of initial structures including ferrite-spheroidized carbide aggregates, fully pearlitic and ferrite-pearlite structures. The results show that a bimodal distribution of ferrite grains negates the Lüdering effect, yet the improvement of work hardening rate remains marginal compared to fine grained ferrite structures. Very fine grained initial structure and rapid heat treatment cycle are essential parameters to achieve ultrafine grained dual phase steels with improved mechanical properties in the steel employed in this study. For austenite formation, dilatation data can be used to distinguish different stages of microstructure evolution upon heating into the single austenite phase region including ferrite recrystallization, pearlite to austenite and ferrite to austenite transformation. Heating rate has a pronounced effect on the size and morphology of austenite grains in the intercritical annealing region. It is shown that phase field modelling is capable of predicting microstructural changes during austenite formation. It is well suited to capture complex interaction between microstructure processes such as spheroidization, carbide dissolution and coarsening during austenite formation especially in fine grained structures where the length scale is comparable with carbon diffusion distance.University of British Columbia2011-01-04T17:11:52Z2011-01-04T17:11:52Z20102011-01-04T17:11:52Z2011-05Electronic Thesis or Dissertationhttp://hdl.handle.net/2429/30513eng
collection NDLTD
language English
sources NDLTD
description The present work deals with grain refinement and austenite formation in a plain C-Mn steel with 0.17C-0.74Mn (wt pct). To improve the limited work hardening capability of ultrafine grained ferritic steels, new approaches were adopted to develop bimodal ferrite grain size distributions and ultrafine grained dual phase microstructures. The first approach is based on deformation and annealing of a ferrite-martensite microstructure. Ultrafine grained dual phase steels were obtained through rapid heating of very fine ferrite-carbide aggregates into the intercritical annealing region where partial austenite formation takes place. Hence, austenite formation was systematically investigated using a combination of microstructure characterization and detailed dilatometry analysis. The effect of initial structure and heating rate on austenite formation was examined. The resulting microstructure characteristics and mechanical properties of dual phase steels were also investigated. A multi-phase field modelling approach was adopted to simulate austenite formation from a variety of initial structures including ferrite-spheroidized carbide aggregates, fully pearlitic and ferrite-pearlite structures. The results show that a bimodal distribution of ferrite grains negates the Lüdering effect, yet the improvement of work hardening rate remains marginal compared to fine grained ferrite structures. Very fine grained initial structure and rapid heat treatment cycle are essential parameters to achieve ultrafine grained dual phase steels with improved mechanical properties in the steel employed in this study. For austenite formation, dilatation data can be used to distinguish different stages of microstructure evolution upon heating into the single austenite phase region including ferrite recrystallization, pearlite to austenite and ferrite to austenite transformation. Heating rate has a pronounced effect on the size and morphology of austenite grains in the intercritical annealing region. It is shown that phase field modelling is capable of predicting microstructural changes during austenite formation. It is well suited to capture complex interaction between microstructure processes such as spheroidization, carbide dissolution and coarsening during austenite formation especially in fine grained structures where the length scale is comparable with carbon diffusion distance.
author Azizi-Alizamini, Hamid
spellingShingle Azizi-Alizamini, Hamid
Austenite formation and grain refinement in C-Mn steels
author_facet Azizi-Alizamini, Hamid
author_sort Azizi-Alizamini, Hamid
title Austenite formation and grain refinement in C-Mn steels
title_short Austenite formation and grain refinement in C-Mn steels
title_full Austenite formation and grain refinement in C-Mn steels
title_fullStr Austenite formation and grain refinement in C-Mn steels
title_full_unstemmed Austenite formation and grain refinement in C-Mn steels
title_sort austenite formation and grain refinement in c-mn steels
publisher University of British Columbia
publishDate 2011
url http://hdl.handle.net/2429/30513
work_keys_str_mv AT azizializaminihamid austeniteformationandgrainrefinementincmnsteels
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