Carbide size refinement by controlling the heating rate during induction tempering in a low alloy steel

Carbide size refinement by controlling the heating rate during induction tempering in a low alloy steel

•Heating rate in induction tempering affects microstructure and hardness.•Carbides can be refined with high heating rates and short holding times.•Matrix weaker recovery is one of the factors intervening in carbide refinement.•The refinement is higher in carbides located at high angle misorientation...

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Bibliographic Details
Published in:Materials in engineering Vol. 62; pp. 296 - 304
Main Authors: Revilla, C., López, B., Rodriguez-Ibabe, J.M.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-10-2014
Subjects:
Boundaries
Carbides
Grain boundary carbides
Hardness
Heating rate
Induction tempering
Low alloy steel
Low alloy steels
Martensite
Tempering
Grain boundary carbides
Induction tempering
Heating rate
Low alloy steel
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Summary:•Heating rate in induction tempering affects microstructure and hardness.•Carbides can be refined with high heating rates and short holding times.•Matrix weaker recovery is one of the factors intervening in carbide refinement.•The refinement is higher in carbides located at high angle misorientation boundaries. The application of high heating rates in tempering treatments can provide a valuable tool for refining carbide sizes, mainly those located at high angle grain boundaries. This work analyses the influence of heating rates ranging from 1 to 300°C/s during the tempering treatment of a 0.42%C low alloy steel. The results indicate that when high heating rates are combined with short holding times, predicting hardness will require the inclusion of the heating up and cooling down cycles in addition to the holding time and temperature used in the definition of the conventional Hollomon–Jaffe tempering parameter (TP). The effect of heating rate on carbide size distribution has been quantified, distinguishing between particles located at high (HAB) and low (LAB) misorientation angle boundaries. The former correspond to those carbides nucleated at prior γ grain, martensite block or packet boundaries whereas the latter refer to those nucleated within martensite laths and at lath boundaries. The refinement obtained has been evaluated from the point of view of hardness behaviour.
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ISSN:0261-3069
DOI:10.1016/j.matdes.2014.05.053