Mathematical modelling of induction hardening on view of thermal stresses

• Autorzy: Kuvaldin A. , Lepeshkin A.

Warianty tytułu

PL

Modelowanie matematyczne hartowania indukcyjnego punktu widzenia naprężeń cieplnych

• Języki publikacji: EN

Abstrakty

EN

Mathematical modelling of regimes of induction hardening of details in view of phase transformations, non-stationary thermal and thermostress state, residual stresses and fatigue has been carried out.

PL

W pracy omówiono modelowanie matematyczne układów hartowania indukcyjnego elementów z punktu widzenia przemian fazowych, staniu niestacjonarnych naprężeń cieplnych, naprężeń szczątkowych i zmęczenia materiału.

Słowa kluczowe

EN

induction hardening; thermal stresses

PL

hartowanie indukcyjne; naprężenia cieplne

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2008
• Tom: R. 84, nr 11
• Strony: 215--218
• Opis fizyczny: Bibliogr. 10 poz., wykr.

Twórcy

autor

Kuvaldin A.

autor

Lepeshkin A.

• Moscow Power Engineering Institute, str. Krasnokazarmennaja 14, 105835 Moscow,

Bibliografia

• [1] Кuvaldin А.B., Lepeshkin A.R. High-speed modes of induction heating and thermostresses articles: monograpf. – Novosibirsk: NSTU Publishing House, - “Modern electrotechnics“. (2006). Vol. 7, 284.
• [2] Кuvaldin А.B., Lepeshkin A.R. Numerical modeling of rate regimes of induction heating and thermal stress state of heated products. Research in Electrotechnology and Applied Informatics, Conference Proceedings, Katowice, (2005), 71-78.
• [3] Кuvaldin А.B., Lepeshkin A.R. The rate induction superficial hardening in view of thermal and residual stresses, “Induction, Dielectric, Conduction and Electromagnetic Processing”. Proceedings of International Symposium on Heating by Electromagnetic Sources, HES-04, Padua, (2004), 661-666.
• [4] Barglic J., Ducki K. Mathematical modeling of continual induction surface hardening of axi-symmetricbodies. Research in Electrotechnology and Applied Informatics, Conference Proceedings, Katowice, (2005), 173-178.
• [5] Kurek K., Dołęga D. The 2D and 3D Analysis of the induction hardening process considering changes in the material microstructure. “Induction, Dielectric, Conduction and Electromagnetic Processing”. Proceedings of International Symposium on Heating by Electromagnetic Sources, HES-04, Padua, (2004), 577-584.
• [6] Di Pieri C., Lupi S., Cappello A, Crepaz G. Capacitors - discharge induction heating installations for high –frequency pulse hardening, 10-th UIE Congress, Stockholm, Sweden, 1984, p. 312.
• [7] Nacke B., Wrona E. Design of complex induction hardening problems by the use of numerical simulation, Research in Electrotechnology and Applied Informatics, Conference Proceedings, Katowice, (2005), 159-164.
• [8] Demidovich V.B., Rassudova N.V., Sherbakova I.A., Shorshina V.K. Identification of processes of induction hardening on one-dimensional model. Proceedings of X conference "Application of high frequency currents in electrotechnic", Leningrad, (1986), 112.
• [9] Goldstein R., Nemkov V., Madeira R. Optimizing axle-scan hardening inductors. Industrial Heating. (2007), December, 47-50.
• [10] Rudnev V. Tips for successful induction hardening of steels. Industrial Heating. (2005), January, 29-30.