Warianty tytułu
Języki publikacji
Abstrakty
Purpose: This article is devoted to methods for predicting the results of surface modification of titanium alloys in glow discharge nitriding. With this advantage, it is given to the analytical criteria as the most appropriate for design automation of processes processing. Design/methodology/approach: The methodology is the position that the nitriding process is a combination of several competing processes leading to the formation of both nitrides, nitrogen diffusion into the depth of the surface and to spray it. The main principle of assessing the intensity of each of them is that each elementary process is the most successful in the case when it created for optimal energy conditions. Findings: Developed a system of analytical criteria - relative energy factors, which qualitatively and adequately reflect the real processes of nitriding of titanium alloys in a glow discharge. Compliance with these indicators were tested in experimental treatment of samples resulting in an energy generating process model. Practical implications: The results were primarily used for computer-aided design modification processes, the optimal choice of the technological nitriding mode, the basis for the software control systems equipment for the processing of titanium alloys. Originality/value: The proposed energy model for the nitriding process in a glow discharge has no current analogues in the world.
Rocznik
Tom
Strony
53--62
Opis fizyczny
Bibliogr. 12 poz., rys., tab.
Twórcy
autor
- Khmelnickiy State University, Ukraine, pastim@mail.ru
autor
- Khmelnickiy State University, Ukraine
autor
- University of Technology and Life Sciences, Bydgoszcz, Poland, shalapko@yahoo.com
autor
- Khmelnickiy State University, Ukraine
Bibliografia
- [1] I.M. Pastukh, Theory and practice of without hydrogen glow discharge nitriding, Kharkov, KIPT, 2006.
- [2] I. Pastukh, Physico-technical metal surface treatment without hydrogen nitriding in a glow discharge, dis. Doctor of. sciences: 05.03.07 (2008) (in Ukrainian).
- [3] I. Pastukh, Energy analysis models nitriding in a glow discharge, Journal of Khmelnitsky National University 5 (2006) 7-14 (in Ukrainian).
- [4] I.M. Pastukh, N.S. Mashovets, Prediction formation of nitrides of titanium alloys by nitriding in a glow discharge, Journal of Khmelnitsky National University 3/2 (2007) 28-37 (in Ukrainian).
- [5] I. Pastukh, Kinetics of near-cathode processes as a factor of the energy spectrum of the flow, Herald of the Technological University of Skirts 1/1 (2004) 3-64 (in Ukrainian).
- [6] D.A. Prokoshkin, Chemical and thermal treatment methods have become, Proceedings of the Moscow Institute of Steel and Alloys – DSTI (1938) 3-133 (in Russian).
- [7] A.V. Belotskii, O.G. Pahorenko, High radiography processes of heat treatment of metals, K.: Polytechnic Institute (1979) 103 (in Russian).
- [8] B.N. Arzamasov, Chemical heat treatment of alloys in the activated gas atmospheres, Bulletin of Mechanical Engineering 9 (1986) 49-53 (in Russian).
- [9] N.S. Mashovets, Contact analytical criteria with real structure of titanium alloys nitrided in a glow discharge, Journal of Khmelnitsky National University 6 (2008) 16-21 (in Ukrainian).
- [10] B.N. Arzamasov, A.G. Bratuhin, S. Eliseev, T. Panagiotou, Ionic chemical heat treatment of alloys Moscow, Publishing House of the MSTU Bauman, 1999, 400 (in Russian).
- [11] J. Lahtin, Physical processes during ion nitriding, In. Protective coatings on metals, Kyiv 2 (1968) 225-229 (in Russian).
- [12] V.G. Kaplun, Scientific bases of technology hardening machine parts and tools ion nitriding in hydrogen-free environments: dis. Doctor. tehn. Sciences: 05.02.01, Khmelnitsky, 1992, 450 (in Russian).
Typ dokumentu
Bibliografia
Identyfikatory
Identyfikator YADDA
bwmeta1.element.baztech-81133646-9b34-41f7-a031-610ce4a655ec