Steel Quenching in Liquid Media under Pressure Considering Process from the Point of View of Physics

International Journal of Applied Physics

© 2020 by SSRG - IJAP Journal

Volume 7 Issue 3

Year of Publication : 2020

Authors : Nikolai I. Kobasko

10.14445/23500301/IJAP-V7I3P116

How to Cite?

Nikolai I. Kobasko, "Steel Quenching in Liquid Media under Pressure Considering Process from the Point of View of Physics," SSRG International Journal of Applied Physics, vol. 7,  no. 3, pp. 102-107, 2020. Crossref, https://doi.org/10.14445/23500301/IJAP-V7I3P116

Abstract:

Quenching in liquid media under pressure requires accurate cooling time interruption calculation to perform the correctly technological process. The paper shows that real and effective heat transfer coefficients can be used for this purpose. The last provides approximate core cooling time calculation of steel part during quenching. The possibility of performing the low-temperature thermomechanical treatment in forging shops is discussed in the paper. The physics of the nucleate boiling process and critical heat flux densities are considered. Examples of cooling time calculations in the paper are provided. The proposed approach can be used in forging and heat-treating industries and useful for scientists and engineers.

Keywords:

Liquid Media, Steel Quenching

References:

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