Modelling the hot deformation of a microalloyed steel

Saham Sadat Sharifi; Ricardo Henrique Buzolin; Marina Melo Gontijo; Felix Meixner; Christian Hoflehner; M. C. Poletti; Christof Sommitsch

Modelling the hot deformation of a microalloyed steel

Saham Sadat Sharifi^*, Ricardo Henrique Buzolin, Marina Melo Gontijo, Felix Meixner, Christian Hoflehner, M. C. Poletti, Christof Sommitsch

^*Korrespondierende/r Autor/-in für diese Arbeit

Institut für Werkstoffkunde, Fügetechnik und Umformtechnik (3030)

Publikation: Konferenzbeitrag › Poster

Abstract

During the continuous casting process, alloys are exposed to mechanical and thermal stresses which might lead to damage. The strain hardening effect and dynamic softening behavior of a microalloyed steel are correlated to the damage behavior occurring during hot deformation.
The use of physically based models in modelling thermomechanical processes allows for a better understanding of the mechanisms responsible for the material properties. They are a powerful tool to improve industrial processes. In this work, a model featuring dislocation density as an internal variable was developed to capture the work-hardening and dynamic softening of a microalloyed steel at processing conditions. At higher temperature i.e. the Austenitic range as a low SFE material, dynamic recrystallization is the dominant softening mechanism during thermomechanical processing. DRX model is implemented, and the damage behavior is modelled by considering the effects of the microstructure evolution and the DRX fraction.

Originalsprache	englisch
Publikationsstatus	Veröffentlicht - 22 Apr. 2022
Veranstaltung	Advanced Materials Poster Day 2022: AMD 2022 - TU Graz, Graz, Österreich Dauer: 22 Apr. 2022 → …

Konferenz

Konferenz	Advanced Materials Poster Day 2022
Kurztitel	AMD 2022
Land/Gebiet	Österreich
Ort	Graz
Zeitraum	22/04/22 → …

Fields of Expertise

Advanced Materials Science

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AMD-Saham Sharifi

K1-Met P2.3 - Thermomechanische Modellierung von Strangguss und Warmwalzen
Sommitsch, C.
1/07/19 → 30/06/23
Projekt: Forschungsprojekt

Dieses zitieren

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title = "Modelling the hot deformation of a microalloyed steel",

abstract = "During the continuous casting process, alloys are exposed to mechanical and thermal stresses which might lead to damage. The strain hardening effect and dynamic softening behavior of a microalloyed steel are correlated to the damage behavior occurring during hot deformation.The use of physically based models in modelling thermomechanical processes allows for a better understanding of the mechanisms responsible for the material properties. They are a powerful tool to improve industrial processes. In this work, a model featuring dislocation density as an internal variable was developed to capture the work-hardening and dynamic softening of a microalloyed steel at processing conditions. At higher temperature i.e. the Austenitic range as a low SFE material, dynamic recrystallization is the dominant softening mechanism during thermomechanical processing. DRX model is implemented, and the damage behavior is modelled by considering the effects of the microstructure evolution and the DRX fraction. ",

author = "Sharifi, {Saham Sadat} and Buzolin, {Ricardo Henrique} and {Melo Gontijo}, Marina and Felix Meixner and Christian Hoflehner and Poletti, {M. C.} and Christof Sommitsch",

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day = "22",

language = "English",

note = "Advanced Materials Poster Day 2022 : AMD 2022, AMD 2022 ; Conference date: 22-04-2022",

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T1 - Modelling the hot deformation of a microalloyed steel

AU - Sharifi, Saham Sadat

AU - Buzolin, Ricardo Henrique

AU - Melo Gontijo, Marina

AU - Meixner, Felix

AU - Hoflehner, Christian

AU - Poletti, M. C.

AU - Sommitsch, Christof

PY - 2022/4/22

Y1 - 2022/4/22

N2 - During the continuous casting process, alloys are exposed to mechanical and thermal stresses which might lead to damage. The strain hardening effect and dynamic softening behavior of a microalloyed steel are correlated to the damage behavior occurring during hot deformation.The use of physically based models in modelling thermomechanical processes allows for a better understanding of the mechanisms responsible for the material properties. They are a powerful tool to improve industrial processes. In this work, a model featuring dislocation density as an internal variable was developed to capture the work-hardening and dynamic softening of a microalloyed steel at processing conditions. At higher temperature i.e. the Austenitic range as a low SFE material, dynamic recrystallization is the dominant softening mechanism during thermomechanical processing. DRX model is implemented, and the damage behavior is modelled by considering the effects of the microstructure evolution and the DRX fraction.

AB - During the continuous casting process, alloys are exposed to mechanical and thermal stresses which might lead to damage. The strain hardening effect and dynamic softening behavior of a microalloyed steel are correlated to the damage behavior occurring during hot deformation.The use of physically based models in modelling thermomechanical processes allows for a better understanding of the mechanisms responsible for the material properties. They are a powerful tool to improve industrial processes. In this work, a model featuring dislocation density as an internal variable was developed to capture the work-hardening and dynamic softening of a microalloyed steel at processing conditions. At higher temperature i.e. the Austenitic range as a low SFE material, dynamic recrystallization is the dominant softening mechanism during thermomechanical processing. DRX model is implemented, and the damage behavior is modelled by considering the effects of the microstructure evolution and the DRX fraction.

M3 - Poster

T2 - Advanced Materials Poster Day 2022

Y2 - 22 April 2022

ER -

Modelling the hot deformation of a microalloyed steel

Abstract

Konferenz

Fields of Expertise

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Projekte

K1-Met P2.3 - Thermomechanische Modellierung von Strangguss und Warmwalzen

Dieses zitieren