Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The prediction of temperature distributions in the tool-chip-workpiece interface is not obvious with the complexity of the induced phenomena. For this purpose, we developed a thermal model in orthogonal metal cutting based on the thermal model of Komanduri and Hou that determines temperature distributions in the tool-chip-workpiece separately, each in its own axes system. The overall distribution is obtained by assembling three temperature distributions at the tool-chip-workpiece interface. Our developed model returns global temperature distributions in the real time throughout the tool-chip-workpiece in the same coordinate system. Our simulation results compared to the original maps showed a perfect correspondence, unlike the computation time and computation steps.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
553--567
Opis fizyczny
Bibliogr. 20 poz., rys.
Twórcy
autor
- Laboratory of Mechanics Applied, Faculty of Mechanical Engineering USTO-MB, Oran, Algeria
autor
- Laboratory of Mechanics Applied, Faculty of Mechanical Engineering USTO-MB, Oran, Algeria
autor
- Ibn-Khaldun University of Tiaret, Electrical Engineering Department, Algeria
Bibliografia
- 1. Blok H., 1938, Theoretical study of temperature rise at surface of actual contact under oiliness lubricating conditions, Proceedings of General Discussion on Lubrication and Lubricants, Institution of Mechanical Engineers, 222-235
- 2. Boothroyd G., 1963, Temperatures in orthogonal metal cutting , Pro Institution of the Mechanical Engineers, G.I. London, 177, 29, 789-810
- 3. Chao B.T., Trigger K.J., 1953, The significance of the thermal number in metal cutting, ASME Transactions of American Society of Mechanical Engineers, 75, 109-120
- 4. Chao B.T., Trigger K.J., 1955, Temperature distribution at the tool-chip interface in metal cutting, ASME Transactions of American Society of Mechanical Engineers, 77, 2, 1107-1121
- 5. Chao B.T., Trigger K.J., 1958, Temperature distribution at tool-chip and tool-work interface in metal cutting, ASME Transactions of American Society of Mechanical Engineers, 20, 1, 311-320
- 6. Carslaw H.S., Jaeger J.C., 1959, Conduction of Heat in Solids, Oxford, UK, Oxford University Press
- 7. Jaeger J.C., 1942, Moving sources of heat and the temperatures at sliding contacts, Proceedings Royal Society of NSW, 76, 203-224
- 8. Hahn R.S., 1951, On the temperature developed at the shear plane in the metal cutting process, Proceedings of First US National Congress of Applied Mechanics, 661-666
- 9. Huang Y., Liang S. Y., 2005, Cutting temperature modeling based on non-uniform heat intensity and partition ratio, Machining Science and Technology, 9, 301-323
- 10. Karpat Y., ¨ Ozel T., 2006, Predictive analytical and thermal modeling of orthogonal cutting process – Part I: Predictions of tool forces, stresses, and temperature distributions, ASME Transactions of American Society of Mechanical Engineers, 128, 435-444
- 11. Karpat Y., ¨ Ozel T., 2008, Analytical and thermal modeling of high-speed machining with chamfered tools, ASME Transactions of American Society of Mechanical Engineers, 130, 0110014-01-011001-15
- 12. Hou Z.B., Komanduri R., 1997, Modeling of thermomechanical shear instability in machining, International Journal of Mechanical Sciences, 39, 11, 1273-1314
- 13. Komanduri R., Hou Z.B., 2000, Thermal modeling of the metal cutting process, Part I: Temperature rise distribution due to shear plane heat source, International Journal of Mechanical Sciences, 42, 1715-1752
- 14. Komanduri R., Hou Z.B., 2001a, Thermal modeling of the metal cutting process, Part II: Temperature rise distribution due to frictional heat source at the tool-chip interface, International Journal of Mechanical Sciences, 43, 57-88
- 15. Komanduri R., Hou Z.B., 2001b, Thermal modeling of the metal cutting process, Part III: Temperature rise distribution due to the combined effects of shear plane heat source and the toolchip interface frictional heat source, International Journal of Mechanical Sciences, 43, 89-107
- 16. Loene W.C., 1954, Distribution of shear-zone heat in metal cutting, ASME Transactions of American Society of Mechanical Engineers, 76, 121-125
- 17. Loewen E.G., Shaw M.C., 1954, On the analysis of cutting tool temperatures, ASME Transactions of American Society of Mechanical Engineers, 76, 217-231
- 18. Rosenthal D., 1946, The theory of moving sources of heat and its application to metal treatments, ASME Transactions of American Society of Mechanical Engineers, 68, 849-866
- 19. Trigger K.J., Chao B.T., 1951, An analytical evaluation of metal cutting temperature, ASME Transactions of American Society of Mechanical Engineers, 73, 57-68
- 20. Wright P.K., McCormic, S.P., Miller T. R., 1980, Effect of rake face design on cutting tool temperature distributions, ASME Journal of Engineering for Industry, 102, 2, 123-128
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-975cc40f-5440-4a6f-bd47-e768e08987a5