Electron beam weld modelling of ferritic steel: effect of prior-austenite grain size on transformation kineticsCitation formats

  • External authors:
  • C.J. Hamelin
  • M.C. Smith
  • Y.L. Sun
  • Q. Xiong

Standard

Electron beam weld modelling of ferritic steel: effect of prior-austenite grain size on transformation kinetics. / Vasileiou, A.N.; Hamelin, C.J.; Smith, M.C.; Francis, J.A.; Sun, Y.L.; Flint, T.F.; Xiong, Q.; Akrivos, V.

In: Procedia Manufacturing, Vol. 51, 19.11.2020, p. 842-847.

Research output: Contribution to journalArticlepeer-review

Harvard

APA

Vancouver

Author

Vasileiou, A.N. ; Hamelin, C.J. ; Smith, M.C. ; Francis, J.A. ; Sun, Y.L. ; Flint, T.F. ; Xiong, Q. ; Akrivos, V. / Electron beam weld modelling of ferritic steel: effect of prior-austenite grain size on transformation kinetics. In: Procedia Manufacturing. 2020 ; Vol. 51. pp. 842-847.

Bibtex

@article{de007c80ef8b4266ae96b200e8249142,
title = "Electron beam weld modelling of ferritic steel: effect of prior-austenite grain size on transformation kinetics",
abstract = "Ferritic steels experience solid-state phase transformation (SSPT), which causes volumetric changes due to differences in the atomic packing density of different phases in the steel. The importance of the prior austenite grain size (PAGS) as an input physical variable is assessed, for adequately modelling the anisothermal SSPT during welding of ferritic steels. The knowledge of the PAGS value pre-requires a thorough microstructural study of each particular weld, information that might be difficult to acquire. A relationship between hardness, PAGS and phase fractions is proposed to be used to feed in weld models. The case of a single-pass, autogenous, reduced-pressure electron beam weld is used for this study. The adequacy of the finite-element weld model in predicting the micro-constituents, the hardness and the residual stress is demonstrated via comparing the predicted results of the thermo-metallurgical and stress analyses with the set of corresponding experimental data. This work aims at providing a better understanding of the impact of PAGS on transformation kinetics and best practice guidelines for modelling, using an extensively validated electron beam weld model as baseline.",
author = "A.N. Vasileiou and C.J. Hamelin and M.C. Smith and J.A. Francis and Y.L. Sun and T.F. Flint and Q. Xiong and V. Akrivos",
year = "2020",
month = nov,
day = "19",
doi = "10.1016/j.promfg.2020.10.118",
language = "English",
volume = "51",
pages = "842--847",
journal = "Procedia Manufacturing",
issn = "2351-9789",
publisher = "Elsevier BV",

}

RIS

TY - JOUR

T1 - Electron beam weld modelling of ferritic steel: effect of prior-austenite grain size on transformation kinetics

AU - Vasileiou, A.N.

AU - Hamelin, C.J.

AU - Smith, M.C.

AU - Francis, J.A.

AU - Sun, Y.L.

AU - Flint, T.F.

AU - Xiong, Q.

AU - Akrivos, V.

PY - 2020/11/19

Y1 - 2020/11/19

N2 - Ferritic steels experience solid-state phase transformation (SSPT), which causes volumetric changes due to differences in the atomic packing density of different phases in the steel. The importance of the prior austenite grain size (PAGS) as an input physical variable is assessed, for adequately modelling the anisothermal SSPT during welding of ferritic steels. The knowledge of the PAGS value pre-requires a thorough microstructural study of each particular weld, information that might be difficult to acquire. A relationship between hardness, PAGS and phase fractions is proposed to be used to feed in weld models. The case of a single-pass, autogenous, reduced-pressure electron beam weld is used for this study. The adequacy of the finite-element weld model in predicting the micro-constituents, the hardness and the residual stress is demonstrated via comparing the predicted results of the thermo-metallurgical and stress analyses with the set of corresponding experimental data. This work aims at providing a better understanding of the impact of PAGS on transformation kinetics and best practice guidelines for modelling, using an extensively validated electron beam weld model as baseline.

AB - Ferritic steels experience solid-state phase transformation (SSPT), which causes volumetric changes due to differences in the atomic packing density of different phases in the steel. The importance of the prior austenite grain size (PAGS) as an input physical variable is assessed, for adequately modelling the anisothermal SSPT during welding of ferritic steels. The knowledge of the PAGS value pre-requires a thorough microstructural study of each particular weld, information that might be difficult to acquire. A relationship between hardness, PAGS and phase fractions is proposed to be used to feed in weld models. The case of a single-pass, autogenous, reduced-pressure electron beam weld is used for this study. The adequacy of the finite-element weld model in predicting the micro-constituents, the hardness and the residual stress is demonstrated via comparing the predicted results of the thermo-metallurgical and stress analyses with the set of corresponding experimental data. This work aims at providing a better understanding of the impact of PAGS on transformation kinetics and best practice guidelines for modelling, using an extensively validated electron beam weld model as baseline.

U2 - 10.1016/j.promfg.2020.10.118

DO - 10.1016/j.promfg.2020.10.118

M3 - Article

VL - 51

SP - 842

EP - 847

JO - Procedia Manufacturing

JF - Procedia Manufacturing

SN - 2351-9789

ER -