Effect of Heating Rate and Silicon Content on Kinetics of Austenite Formation during Continuous Heating

Bernardo Hernández-Morales; O. Vázquez-Gómez; E. López-Martínez; H.J. Vergara-Hernández; L. Olmos

doi:10.4028/www.scientific.net/MSF.783-786.771

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HomeMaterials Science ForumMaterials Science Forum Vols. 783-786Effect of Heating Rate and Silicon Content on...

Effect of Heating Rate and Silicon Content on Kinetics of Austenite Formation during Continuous Heating

Abstract:

The first step in a heat treating cycle is the austenitizing of the as-received material. Despite its importance, this step has received relatively little attention. In this work, the kinetics of austenite formation during continuous heating tests of steel samples with low and high silicon content was determined as a function of heating rate. The microstructural evolution was characterized through dilatometric analysis of cylindrical samples (7 mm × 20 mm), continuously heated in a protective atmosphere at constant heating rates ranging from 2 to 40 °C/min. The critical temperatures and the transformation kinetics were determined from the derivative of the relative length change as a function of temperature. As the heating rate increases the critical temperatures and the transformation temperature range increase; the addition of silicon produces a more marked effect. The transformation kinetics data were correlated using an Avrami-type equation. The kinetic parameter n is nearly independent of heating rate while the parameter k is a strong function of the heating rate; in both cases, slightly larger values were obtained for the high-silicon steel.

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Periodical:

Materials Science Forum (Volumes 783-786)

Pages:

771-776

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.783-786.771

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Online since:

May 2014

Authors:

Bernardo Hernández-Morales*, O. Vázquez-Gómez, E. López-Martínez, H.J. Vergara-Hernández, L. Olmos

Keywords:

CHT Diagram, Dilatometry, Non-Isothermal Kinetics

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References

[1] Charlie R. Brooks, Austenitization of Steels, in: Principles of the Heat Treatment of Plain Carbon and Low Alloy Steels, Chapter 6, ASM International, Materials Park, Ohio, 1996, pp.205-234.

DOI: 10.31399/asm.tb.phtpclas.t64560205

Google Scholar

[2] K. Laason, P. Peetsalu, M. Saarna, P. Kulu, V. Mikli, L. Lind and J. Beilma, Influence of steel austenitization to part quality in continuous austempering, Estonian Journal of Engineering 8 (2012) 221-231.

DOI: 10.3176/eng.2012.3.07

Google Scholar

[3] K.W. Andrews, Empirical formulae for the calculation of some transformation temperatures, J. of the Iron and Steel Institute 20 (1965) 721-727.

Google Scholar

[4] L.A. Dobrzanski and J. Trzaska, Application of neural networks for prediction of critical bvalues of temperatures and time of the supercooled austenite transformations, J. of Materials Processing Technology 155-156 (2004) 1950-(1955).

DOI: 10.1016/j.jmatprotec.2004.04.056

Google Scholar

[5] B. Pawlowski, Dilatometric examination of continuously heated austenite formation in hypoeutectoid steels, J. of Achievements in Materials and Manufacturing Engineering 54/2 (2012) 185-193.

Google Scholar

[6] F.L.G. Oliveira, M.S. Andrade and A.B. Cota, Kinetics of austenite formation during continuous heating in a low carbon steel, Materials Characterization 58 (2007) 256-261.

DOI: 10.1016/j.matchar.2006.04.027

Google Scholar