Main Catalog Metallurgy and Science of Materials Metal Science, Thermal Processing of Metals and Alloys

Experimental and theoretical study of surface phenomena in the process of interaction between the low-pressure hydrocarbonic atmospheres and ferroalloys

Authors: Korolev I.P.
Published in issue: #10(15)/2017
DOI: 10.18698/2541-8009-2017-10-180
Category: Metallurgy and Science of Materials \| Chapter: Metal Science, Thermal Processing of Metals and Alloys
Keywords: thermochemical treatment, carbonization, diffusion, low-pressure atmospheres, decarburization, atomistic modeling
Published: 04.10.2017

We have conducted an experimental study of the interaction between the iron previouslysaturated with carbon and low-pressure atmospheres. The effect of the carbon reverse mass-transfer from the ferro-alloy into the medium conforming to the passive stage of the vacuum carburizing technological process was estimated numerically. The reverse mass-transfer poorly depends on the working chambercapacity, and at a temperature of 940 С it equals 0,42×10–5, which amounts about 0,6 from the directmass-transfer coefficient with the active carbonization. Decarburization mostly depends on the composition of the furnace atmosphere. Determining the precise value of this coefficient gives an opportunity to increase the computational accuracy of the carbon concentration-response curves at two-stage and cyclic duties of vacuum carburizing. The results obtained with account of previously published data open up an opportunity to create aphysical model for saturating iron and its alloys of various compositions in hydrocarbonicmedia and for control quality improvement.

References

[1] Smirnov A.E., Semenov M.Yu. The application of vacuum heat and thermo-chemical treatment to improve strength of different heavily loaded machine parts and engineering instruments. Nauka i obrazovanie: nauchnoe izdanie [Science and Education: Scientific Publication], 2014, no. 2. Available at: http://technomag.bmstu.ru/doc/700036.html.

[2] Reinhold B. Plasma carburizing: exotic with potential. International Heat Treatment & Surface Engineering, 2009, vol. 3, no. 4, pp. 136–140.

[3] Ryzhov N.M., Smirnov A.E., Kirillov K.I., Semenov M.Yu. Complex system of ion carbonitriding control. Metallovedenie i termicheskaya obrabotka metallov, 1996, no. 1, pp. 11–15. (Eng. version: Combined system for controlling ion cyanidation. Metal Science and Heat Treatment, 1996, vol. 38, no. 1, pp. 12–15.)

[4] Semenov M.Yu., Smirnov A.E., Ryzhova M.Yu. Computation of carbon concentration curves in vacuum carburizing of steels. Metallovedenie i termicheskaya obrabotka metallov, 2013, no. 1, pp. 38–42. (Eng. version: Metal Science and Heat Treatment, 2013, vol. 55, no. 1–2, pp. 38–42.)

[5] Tesner P.A. Obrazovanie ugleroda iz uglevodorodov gazovoy fazy [Carbon production from hydrocarbon in gaseous phase]. Moscow, Khimiya publ., 1972, 136 p.

[6] Smirnov A.E. Razrabotka sposobov aktivnogo kontrolya i avtomatizatsiya protsessa ionnoy tsementatsii legirovannykh staley. Diss. kand. tekhn. nauk [Development of in-process control methods and automation of alloyed steel ion carbonization process. Kand. tech. sci. diss.]. Moscow, Bauman Press, 1991, 198 p.

[7] Eliseev Yu.S., Krymov V.V., Nezhurin I.P., Novikov V.S., Ryzhov N.M. Proizvodstvo zubchatykh koles gazoturbinnykh dvigateley [Production of gas-turbine engine gears]. Moscow, Vysshaya shkola publ., 2001, 495 p.

[8] Semenov M.Yu., Demidov P.N., Ryzhova M.Yu., Korolev I.P. Carbon mass transfer regularities at case-hardening in low-pressure atmosphere and boundary conditions of simulator. Vestnik Bryanskogo gosudarstvennogo tekhnicheskogo universiteta [Bulletin of Bryansk State Technical University], 2016, vol. 2, no. 3, pp. 102–107.

[9] Exner K.S., Hess F., Over H., Seitsonen A.P. Combined experiment and theory approach in surface chemistry: Stairway to heaven? Surface Science, 2015, vol. 640, pp. 165–180.

[10] Hess F., Farkas F., Seitsonen F.P., Over H. “First‐Principles” kinetic Monte Carlo simulations revisited: CO oxidation over RuO2 (110). Journal of computational chemistry, 2012, vol. 33, no. 7, pp. 757–766.

[11] Gel’chinskiy B.R., Mirzoev A.A., Vorontsov A.G. Vychislitel’nye metody mikroskopicheskikh teorii metallicheskikh rasplavov i nanoklasterov [Computational methods of microscopic theory of metal melts and nanoclusters]. Moscow, Fizmatlit publ., 2011, 196 p.

[12] Kar’kina L.E., Kar’kin I.N., Yakovleva I.L., Zubkova T.A. Computer simulation of carbon diffusion near b/2 [010](001) dislocation in cementite. The Physics of Metals and Metallography, 2013, vol. 114, no. 2, pp. 155–161.

[13] Ryzhov N.M., Semenov M.Yu. Determination of the coefficient of carbon diffusion for calculating nonisothermal regimes of high-temperature ion nitrocarburizing. Metallovedenie i termicheskaya obrabotka metallov, 2000, no. 6, pp. 26–30. (Eng. version: Metal Science and Heat Treatment, 2000, vol. 42, no. 6, pp. 228–233).