Insight into the Induction Hardening Behavior of a New 0.40% C Microalloyed Steel: Effects of Initial Microstructure and Thermal Cycles
Vahid Javaheri, Satish Kolli, Bj{\o}rnar Grande, David Porter

TL;DR
This study investigates how initial microstructure and heating rates influence the induction hardening behavior of a new 0.40% C microalloyed steel, revealing mechanisms of austenite formation and optimal processing conditions for improved hardness.
Contribution
It provides new insights into the effects of initial microstructure and heating rates on austenite formation mechanisms and grain size in a novel microalloyed steel during induction hardening.
Findings
Diffusional and diffusionless mechanisms control austenite formation.
Ultrafast heating rates lead to a massive transformation overtaking diffusion.
Optimal hardness achieved with lower bainite microstructure at 50°C/s heating rate.
Abstract
The induction hardening behavior of a new, hot-rolled 0.4 wt.% carbon steel with the two different starting microstructures of upper and lower bainite has been simulated using a Gleeble 3800. The effect of heating rate in the range 1 - 500 {\deg}C/s on austenite grain size distribution has been rationalized. Dilatometry together with Scanning Electron Microscopy combined with Electron Backscatter Diffraction analyses and thermodynamic simulations provide insight into the austenite formation mechanisms that operate at different heating rates. Two main mechanisms of austenite formation during re-austenitization were identified: diffusional and diffusionless (massive). At conventional (1-5 {\deg}C/s) and fast (10-50 {\deg}C/s) heating rates the austenite formation mechanism and kinetics are controlled by diffusion, whereas at ultrafast heating rates (100-500 {\deg}C/s) the formation of…
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