INFLUENCE OF HEAT TRANSFER COEFFICIENT ON QUENCHING PROCESSES SIMULATION

1 DANEV Iliyan
Co-authors:
2 GOSPODINOV Danail 3 RADEV Rossen 4 ILIEVA Mariana
Institutions:
1 University of Ruse, Ruse, Bulgaria, EU, idanev@uni-ruse.bg
2 University of Ruse, Ruse, Bulgaria, EU, dgospodinov@uni-ruse.bg
3 University of Ruse, Ruse, Bulgaria, EU, rradev@uni-ruse.bg
4 University of Ruse, Ruse, Bulgaria, EU, mdilieva@uni-ruse.bg
Conference:
29th International Conference on Metallurgy and Materials, Brno, Czech Republic, EU, May 20 - 22, 2020
Proceedings:
Proceedings 29th International Conference on Metallurgy and Materials
Pages:
500-505
ISBN:
978-80-87294-97-0
ISSN:
2694-9296
Published:
27th July 2020
Proceedings of the conference were published in Web of Science and Scopus.
Metrics:
762 views / 460 downloads
Abstract

Currently, heat treatment is the most common and effective method for changing the properties of metals and their alloys. Ferrous alloys most often are heat treated and the most commonly used process of heat treatment is the quenching. At quenching the final structure and material’s properties are formed during the fast cooling process. Therefore, the correct choice of cooling conditions is critical for quality of quenched parts. The simulation of quenching is one of the modern approaches for researching the cooling processes. In order to obtain reliable results, the correct input data for simulation are crucial. It is commonly accepted that the heat transfer coefficient (HTC) plays most significant influence on the simulation results. Meanwhile in the specialized literature there are quite different values of HTC even at equal cooling conditions and a few data regarding its influence on the simulation results. The aim of this paper is to determine to what extent the results obtained after simulation of quenching processes are influenced by HTC. Samples of different dimensions and ratios between length and diameter (L/D), made of medium carbon steel (C45 EN 10083), were studied. Results for the influence of HTC together with geometry of the quenched parts, especially samples with different ratio length/diameter (L/D), are presented in the article.

Keywords: Quenching simulation, heat transfer coefficient, cooling ability

© This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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