期刊文献+

Effect of Nb on Austenite Formation and Decomposition in an X80 Linepipe Steel 被引量:1

Effect of Nb on Austenite Formation and Decomposition in an X80 Linepipe Steel
原文传递
导出
摘要 Advanced high strength steels for pipeline applications,e.g.X80 grades,have complex microstructures and are frequently microalloyed with Nb.In the hot rolled product it is sought to have Nb precipitated as Nb(CN).However,when processing these steels Nb may be in solution and critically affects the microstructure evolution,e.g.austenite decomposition on the run-out table of a hot mill.Further,microstructure changes in the heat affected zone (HAZ) during girth welding of these linepipe steels may occur with Nb precipitated or in solution.In the HAZ,depending on welding procedures,the material undergoes a number of austenite formation and decomposition cycles and the amount of Nb in solution varies along these stages.In selected positions of the HAZ,thermal cycles peak at the intercritical region and the partial formation of austenite and subsequent decomposition constitutes additional complexity.Developing reliable process models for run-out table cooling and the HAZ hinges on an accurate tracking of microstructure evolution,which is strongly influenced by the amount of Nb in solution.The present study provides more insight into the effect of Nb on austenite formation and decomposition.Firstly,a novel experimental methodology is presented to measure quantitatively the effect of Nb on transformation temperatures pertinent to austenite decomposition,notably ferrite.A model for ferrite formation that accounts for solute drag of Nb is proposed to describe the experimental observations.Secondly,an experimental study will be presented to quantify the effect of Nb in and out of solution on austenite formation in the intercritical region.It is found that the morphology of intercritical austenite,as well as the kinetics of its formation is strongly affected by the starting microstructure and the state of Nb. Advanced high strength steels for pipeline applications,e.g.X80 grades,have complex microstructures and are frequently microalloyed with Nb.In the hot rolled product it is sought to have Nb precipitated as Nb(CN).However,when processing these steels Nb may be in solution and critically affects the microstructure evolution,e.g.austenite decomposition on the run-out table of a hot mill.Further,microstructure changes in the heat affected zone (HAZ) during girth welding of these linepipe steels may occur with Nb precipitated or in solution.In the HAZ,depending on welding procedures,the material undergoes a number of austenite formation and decomposition cycles and the amount of Nb in solution varies along these stages.In selected positions of the HAZ,thermal cycles peak at the intercritical region and the partial formation of austenite and subsequent decomposition constitutes additional complexity.Developing reliable process models for run-out table cooling and the HAZ hinges on an accurate tracking of microstructure evolution,which is strongly influenced by the amount of Nb in solution.The present study provides more insight into the effect of Nb on austenite formation and decomposition.Firstly,a novel experimental methodology is presented to measure quantitatively the effect of Nb on transformation temperatures pertinent to austenite decomposition,notably ferrite.A model for ferrite formation that accounts for solute drag of Nb is proposed to describe the experimental observations.Secondly,an experimental study will be presented to quantify the effect of Nb in and out of solution on austenite formation in the intercritical region.It is found that the morphology of intercritical austenite,as well as the kinetics of its formation is strongly affected by the starting microstructure and the state of Nb.
出处 《Journal of Iron and Steel Research International》 SCIE EI CAS CSCD 2011年第S1期658-663,共6页
基金 financial support by the Natural Sciences and Engineering Research Council of Canada(NSERC) Evraz Inc.NA Trans Canada Pipelines,Ltd.
  • 相关文献

参考文献9

  • 1Kumkum Banerjee,Matthias Militzer,Michel Perez,Xiang Wang.Nonisothermal Austenite Grain Growth Kinetics in a Microalloyed X80 Linepipe Steel[J]. Metallurgical and Materials Transactions A . 2010 (12)
  • 2Dongsheng Liu,F. Fazeli,M. Militzer,W.J. Poole.A Microstructure Evolution Model for Hot Rolling of a Mo-TRIP Steel[J]. Metallurgical and Materials Transactions A . 2007 (4)
  • 3M. Militzer,E. B. Hawbolt,T. R. Meadowcroft.Microstructural model for hot strip rolling of high-strength low-alloy steels[J]. Metallurgical and Materials Transactions A . 2000 (4)
  • 4Morrison W.B.Microalloy Steels-the Beginning. Journal of Materials Science and Technology . 2009
  • 5Okaguchi S,Hashimoto T,Ohtani H.Effect of Nb,V and Ti on Transformation Behavior of HSLA Steel in Accelerated Cooling. Proc.Conf.Thermec’’88 . 1988
  • 6DeArdo A.J.,Hua M.I.,Cho K.J.et al.On Strength of Microalloyed Steels:an Interpretive Review. Journal of Materials Science and Technology . 2009
  • 7Militzer M.,Fazeli F,Azizi-Alizamini H.Modelling of Microstructure Evolution in Advanced High Strength Steels. Proc 2-(nd) International Conf.on Super-high Strength Steels . 2010
  • 8Poole W,Militzer M,Fazeli F.et al.Microstructure Evolution in the HAZ of Girth Welds in Linepipe Steels for the ??Arctic. IPC2010-31155 . 2010
  • 9Takahama Y,Sietsma J.Mobility Analysis of the Austenite to Ferrite Transformation in Nb Microalloyed Steel by Phase Field Modelling. ISIJ International . 2008

同被引文献9

引证文献1

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部