Thermomechanical Processing of V-N Structural Plate Steels in Low Temperature Austenite

Kevin Mark Banks; Dannis Rorisang Nkarapa Maubane

doi:10.4028/p-Hrn2ut

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HomeMaterials Science ForumMaterials Science Forum Vol. 1105Thermomechanical Processing of V-N Structural...

Thermomechanical Processing of V-N Structural Plate Steels in Low Temperature Austenite

Abstract:

Austenite restoration during thermomechanical (TM) rolling of typical vanadium-microalloyed structural steels was studied to optimize strength in the as-rolled and air-cooled condition. Multi-pass plate rolling simulations were performed on V-N microalloyed and CMn steels to compare recrystallisation behaviour in various temperature regions. Included were a conventional schedule ending at high temperature and two TM schedules with mill exit temperatures in the intermediate and low austenite regions. Increasing delay periods after roughing enhance the suppression of recrystallisation after the start of finishing thereby increasing both nucleation site density and nucleation rate for ferrite formation and refinement in grain size. Good agreement was found between microstructures after industrial TM rolling and those obtained from laboratory simulations. Although precipitation of vanadium carbonitrides is an effective strengthening mechanism, appreciable gains in yield strength due to grain refinement can be achieved by rolling in the lower austenite region. Low nitrogen contents in V steels produce coarser final ferrite grain sizes and lower strengths probably due to a larger precipitate size. V-N steels display similar flow behaviour to CMn grades down to approximately 825°C at low to intermediate strain rates but may experience alternate regions of work hardening and dynamic softening at lower temperatures in austenite.

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Periodical:

Materials Science Forum (Volume 1105)

Pages:

105-110

DOI:

https://doi.org/10.4028/p-Hrn2ut

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Online since:

November 2023

Authors:

Kevin Mark Banks*, Dannis Rorisang Nkarapa Maubane

Keywords:

Grain Refinement, Strength, Thermomechanical Rolling, Vanadium Nitrogen Steel

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