Título
Unravelling dynamic recrystallisation in a microalloyed steel during rapid high temperature deformation using synchrotron X-raysAutor-a (de otra institución)
Versión
Version publicada
Derechos
© 2024 The AuthorsAcceso
Acceso abiertoVersión del editor
https://doi.org/10.1016/j.actamat.2024.120265Publicado en
Acta Materialia Vol. 278. N. art. 120265. October, 2024Editor
ElsevierPalabras clave
alloyed steel
diffraction
deformations
Dynamic recrystallization ... [+]
diffraction
deformations
Dynamic recrystallization ... [+]
alloyed steel
diffraction
deformations
Dynamic recrystallization
ODS 12 Producción y consumo responsables [-]
diffraction
deformations
Dynamic recrystallization
ODS 12 Producción y consumo responsables [-]
Materia (Tesauro UNESCO)
TermodinámicaAcero
Tecnología de materiales
Clasificación UNESCO
Tecnología de materialesResumen
Microstructure evolution during high-strain rate and high-temperature thermo-mechanical processing of a 44MnSiV6 microalloyed steel is investigated using in situ synchrotron high-energy powder X-ray d ... [+]
Microstructure evolution during high-strain rate and high-temperature thermo-mechanical processing of a 44MnSiV6 microalloyed steel is investigated using in situ synchrotron high-energy powder X-ray diffraction. The conditions selected replicate a newly developed near solidus high-strain rate process designed for reducing raw material use during the hot processing of steels. High temperatures (exceeding 1300 °C) and high strain rate
= 9 s-1 processing regimes are explored. The lattice strains and dislocation activity estimated from diffraction observations reveal that the microstructure evolution is primarily driven by dynamic recrystallisation. A steady-state stress regime is observed during deformation, which develops due to intermittent and competing work hardening and recovery processes. The texture evolution during the heating, tension, shear deformation and cooling stages is systematically investigated. The direct observation of phase evolution at high-temperature and high-strain rate deformation enables a comprehensive understanding of new manufacturing processes and provides deep insights for the development of constitutive models for face-centred cubic alloys. [-]
Financiador
Comisión EuropeaPrograma
RFCSNúmero
RFCS-2018-800763URI de la ayuda
Sin informaciónProyecto
Hybrid Semi-Solid Forming (HSSF)Colecciones
- Artículos - Ingeniería [683]
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