Influence of tool deterioration on the density of heat flux distribution in the cutting area in end milling of OT4 titanium alloy


Cite item

Full Text

Abstract

The influence of end mill teeth flank wear on the density of heat fluxes taking place in the cutting area is discussed in the paper. The following densities of heat fluxes are dealt with: the density of heat flux which occurs as a result of plastic deformation, the density of heat flux which occurs due to the friction of chips against the cutting face of the mill teeth and that which occurs as a result of flank surface friction against the workpiece being machined.The dependence of the cutting temperature on the value of the tool wear has been obtained. The thermal field in the tool has been calculated. The presented results of the numerical experiment have been obtained by a customized procedure that represents a revised procedure developed by Professor A.N. Resnikov for the conditions of endmilling.  The article describes the main stages of adaptation. There are four of them, and they are based on the geometrical specificity of the chip. Immediate calculation of temperature fields in the cutting area in the endmilling process was performed using a computer finite - element model. The model takes into account the hydrodynamics of the cooling lubricant which, in most cases, takes place in endmilling and other machining processes.

About the authors

D. V. Evdokimov

Samara State Aerospace University

Author for correspondence.
Email: dmitry.evd.ssau@gmail.com

Postgraduate student

Russian Federation

D. L. Skuratov

Samara State Aerospace University

Email: skuratov@ssau.ru

Doctor of Science (Engineering), Professor

Head of the Department of Engine Production Technology

Russian Federation

References

  1. Evdokimov D.V., Fedorov D.G. Skuratov D.L. Thermal Stress Resarch of Processing and Formation of Residual Stress When End Milling of a Workpiece. World Applied Sciences Journal. 2014. V. 31, Iss. 1. P. 51-55. doi: 10.5829/idosi.wasj.2014.31.01.14283
  2. Skuratov D.L., Evdokimov D.V., Fedorov D.G. Research of thermal cycle parameters and surface condition of the samples from high-tension steel 30ХГСН2А at cylindrical external grinding. Life Science Journal. 2014. V. 11, Iss. 10. P. 678-681.
  3. Klocke F., Gierlings S., Brockmann M., Veselovac D. Force-based temperature modeling for surface integrity prediction in broaching nickel-based alloys. Procedia CIRP. 2014 V. 13. P. 314-319. doi.org/10.1016/j.procir.2014.04.053
  4. Kolařík K., Pala Z., Čapek J., Beránek L., Vyskočil Z. Non-destructive inspection of surface integrity in milled turbine blades of inconel 738LC. Applied Mechanics and Materials. 2013. V. 486. P. 9-15. doi.org/ 10.4028/www.scientific.net/amm.486.9
  5. Zhang Q., Mahfouf M., Yates J.R., Pinna C., Panoutsos G., Boumaiza S., Greene R.J., Luis de Leon Modeling and optimal design of machining-induced residual stresses in aluminum alloys using a fast hierarchical multiobjective optimization algorithm. Materials and Manufacturing Processes. 2011. V. 26, Iss. 3. P. 508-520. doi.org/10.1080/10426914.2010.537421
  6. Liu W.W., Wang D.F., Li F., Chen H., Wang C.Z. Research on milling parameters optimization based on surface residual stress for aviation stainless steel. Applied Mechanics and Materials. 2013. V. 526. P. 3-8. doi.org/10.4028/www.scientific.net/amm.526.3
  7. Kravchenko B.A. Teoriya formirovaniya poverkhnostnogo sloya detaley mashin pri mekhanicheskoy obrabotke [Theory of the formation of the surface layer of machine parts in machining]. Kuybyshev: Kuybyshev Politechnical Institute Publ., 1981. 90 p.
  8. Kravchenko B.A., Kravchenko A.B. Fizicheskie aspekty teorii protsessa rezaniya metallov [Physical aspects of the metal cutting process theory]. Samara: Samara State Technical University Publ., 2002. 167 p.
  9. Benabid F., Benmoussa H., Arrouf M. A thermal modeling to predict and control the cutting temperature. The simulation of facemilling process. Procedia Engineering. 2014. V. 74. P. 37-42. doi.org/10.1016/j.proeng.2014.06.220
  10. Zhang E., Zhao S., Chen X., Guo X., Yao J. Finite element analysis of indexable cutter. Liaoning Gongcheng Jishu Daxue Xuebao (Ziran Kexue Ban)/Journal of Liaoning Technical University (Natural Science Edition). 2013. V. 32, Iss. 12. P. 1695-1698. doi: 10.3969/j.issn.1008-0562.2013.12.025
  11. Reznikov A.N. Teplofizika rezaniya [Thermal physics of cutting]. Мoscow: Mashinostroenie Publ., 1969. 288 p.
  12. Reznikov A.N. Teploobmen pri rezanii i okhlazhdenie instrumentov [Heat exchange in cutting and cooling of tools]. Moscow: Mashgiz Publ., 1963. 200 p.
  13. Sotnikova K.F. Normativy rezhimov rezaniya na mekhanicheskuyu obrabotku titanovykh splavov [Guidelines on cutting modes for titanium alloy machining]. Moscow: NIAT Publ., 1980. 230 p.
  14. Skuratov D.L., Zhidyaev A.N., Sazonov M.B. Solid carbide end mills tool life increase in titanium alloys machining by design development and rational choice of geometrical parameters. Research Journal of Applied Sciences. 2014. V. 9, Iss. 11. P. 767-770. doi: 10.3923/rjasci.2014.767.770
  15. Reznikov N.I. Obrabotka rezaniem zharoprochnykh, vysokoprochnykh i titanovykh splavov [Machining of heat-resistant, high-strength and titanium alloys]. Мoscow: Mashinostroenie Publ., 1971. 200 p.
  16. Kravchenko B.A. Mitryaev K.F. Obrabotka i vynoslivost' vysokoprochnykh materialov [Machining and endurance of high-strength materials]. Kuibyshev: Kuibyshevskoe knizhnoe izdatel'stvo Publ., 1968. 132 p.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2016 VESTNIK of the Samara State Aerospace University

This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies