THE RESEARCH OF A TEMPERATURE FIELD WHEN TURNING WITH VIBRATIONS SUPERPOSITION


Cite item

Full Text

Abstract

The temperature of a cutting process influences significantly the quality of the treated surface and the performance of a tool. The rational use of vibrations, including the ultrasonic frequency vibrations is one of the means to improve the efficiency of a cutting process. However, there are no analytical studies of the temperature of turning with vibration superposition. It was accepted that the total heat output power when turning was equal to the sum of heat output powers of sources aroused as the result of the transition to the heat of work of deformation and work of friction forces on the leading and flank surfaces of a tool. The paper presents the mathematical dependences for calculation of the components of the total power of heat release. The authors took into account that the yield stress, which determines the cutting and frictional forces on the contact surfaces of a cutter, workpiece, and chip, depends on the temperature in the plastic deformation area. The law of distribution of thermal power density on the shear plane was taken as uniform; the combined law was adopted on the surface of the contact of a chip with the front surface of a cutter; the asymmetric normal law was adopted on the surface of the contact of a cutter with a workpiece. The authors gave the dependence for the calculation of the cutting depth when applying vibrations in the direction perpendicular to the treated surface. Heat exchange at the boundaries of the objects contacting with the process liquid or air is given in the form of the Newton-Richman law. The thermal conductivity equations of the contacting objects were solved in combination with the general boundary conditions in the contact zone using the finite element method. The method of calculation based on the discrete analogs of the heat conduction equations is implemented in the original programs. The authors compared the results of calculation of temperatures when turning without the vibrations superposition with the experimentally obtained results, in this case, the discrepancy between the calculated and experimental values does not exceed 10 %. The simulation of the turning process with the superposition of ultrasonic vibrations showed that the main component of the cutting force Pz reduced by a mean of 11 %, the maximum temperature in the zone of contact of the back surface of a cutter with a workpiece reduced by 20 %, and the maximum temperature in the zone of contact of the front surface of a cutter with a chip reduced by 26 %.

About the authors

A. N. Unyanin

Ulyanovsk State Technical University

Author for correspondence.
Email: a_un@mail.ru

Unyanin Aleksandr Nikolaevich - Doctor of Sciences (Engineering), Associate Professor.
432027, Ulyanovsk, Severny Venetz Street, 32. Tel.: +7 903 320-53-51

Russian Federation

P. R. Finageev

Ulyanovsk State Technical University

Email: pavel_finageev@mail.ru

Finageev Pavel Ramdisovich - postgraduate student.
432027, Ulyanovsk, Severny Venetz Street, 32. Tel.: +7 904 184-74-63

Russian Federation

References

  1. Petrakov Yu.V., Drachev O.I. Modelirovanie protsessov rezaniya [Modeling of Cutting Processes]. Staryy Oskol, TNT Publ., 2011. 240 p.
  2. Zheleznov G.S., Skhirtladze A.G. Protsessy mekha-nicheskoy i fiziko-khimicheskoy obrabotki materialov [The processes of mechanical and physicochemical treatment of materials]. Staryy Oskol, TNT Publ., 2011. 456 p.
  3. Reznikov A.N. Teplofizika protsessov mekhanicheskoy obrabotki materialov [Thermal physics of mechanical processing of materials]. Moscow, Mashinostroenie Publ., 1981. 287 p.
  4. Abhang L.B., Hameedullah M. Chip-Tool Interface Temperature Prediction Model for Turning Process. International Journal of Engineering Science and Technology, 2010, vol. 2, pp. 382-393.
  5. Vorontsov A.L. Starting positions and critical remarks about modern methods of theoretical research of thermophysics processes. Spravochnik. Inzhenernyy zhurnal у prilozheniem, 2016, no. S3, pp. 2-8.
  6. Zubchenko A.S., ed. Marochnik staley i splavov [Grading of steels and alloys]. 2nd izd., dop. i ispr. Moscow, Mashinostroenie Publ., 2003. 784 p.
  7. Vorontsov A.L. Definition of temperature fields and contact temperatures at cutting Part 1. Spravochnik. Inzhenernyy zhurnal s prilozheniem, 2016, no. S8, pp. 9-15.
  8. Kiselev E.S., Kovalnogov V.N. Mekhanicheskaya obra-botka zagotovok v usloviyakh kriticheskogo teplomas-soperenosa [Mechanical processing of blank parts in the circumastances of critical heat and mass transfer]. Moscow, RAN Publ., 2008. 250 p.
  9. Unyanin A.N., Khusainov A.S. The ultrasonic grinding process temperature field study. MATEC Web of Conferences, 2017, vol. 129, pp. 10-11.
  10. Nath C., Rahman M. Effect of machining parameters in ultrasonic vibration cutting. International Journal of Machine Tools and Manufacture, 2008, vol. 48, no. 9, pp. 965-974.
  11. Unyanin A.N. Analytical research on the temperature field at milling with ultrasonic oscillations superposition. Vestnik Rybinskoy gosudarstvennoy aviatsionnoy tekhnologicheskoy akademii im. P.A. Soloveva, 2017, no. 2, pp. 229-235.
  12. Reznikov A.N., Reznikov L.A. Teplovye protsessy v tekhnologicheskikh sistemakh [Thermal processes in technological systems]. Moscow, Mashinostroenie Publ., 1990. 288 p.
  13. Vorontsov A.L. The basic physical and mathematical positions of new theory Part 1. Spravochnik. Inzhenernyy zhurnal s prilozheniem, 2016, no. S7, pp. 14-23.
  14. Talantov N.V. Fizicheskie osnovy protsessa rezaniya, iznashivaniya i razrusheniya instrumenta [The physical basis of the cutting process of wear and destruction of the tool]. Moscow, Mashinostroenie Publ., 1992. 240 p.
  15. Vorontsov A.L., Sultan-Zade N.M., Albagachiev A.Yu. Development of a new theory of cutting 9. Practical calculations of cutting parameters in turning. Russian Engineering Research, 2008, vol. 28, no. 9, pp. 878-888.
  16. Vorontsov A.L., Sultan-Zade N.M., Albagachiev A.Yu. Development of a new theory of cutting 7. Mathematical description of the formation of different chips, pulsation of the cutting force, and contact parameters of the machined billet surface and the rear cutter surface. Russian Engineering Research, 2008, vol. 28, no. 7, pp. 674-680.
  17. Yashcheritsyn P.I., Feldshteyn E.E., Kornievich M.A. Teoriya rezaniya [Cutting theory]. Minsk, Novoe znanie Publ., 2006. 512 p.
  18. Vologin M.F., Kalashnikov V.V., Nerubay M.S., Shtrikov B.L. Primenenie ultrazvuka i vzryva pri obrabotke i sborke [Application of ultrasonic vibrations and explosion when processing and assembling]. Moscow, Mashinostroenie Publ., 2002. 264 p.
  19. Koldaev V.D. Chislennye metody i programmirovanie [Numerical methods and programming]. Moscow, INFRA-M Publ., 2009. 544 p.
  20. Vasin S.A., Vereshchaka A.S., Kushner V.S. Rezanie materialov: Termomekhanicheskiy podkhod k sisteme vzaimosvyazey pri rezanii [Metal cutting. Thermomechanical approach to the system of interconnections during cutting]. Moscow, MGTU im. N.E. Baumana Publ., 2001. 448 p.
  21. Vorontsov A.L. Practical calculations of temperature of cutting Part 1. Spravochnik. Inzhenernyy zhurnal s prilozheniem, 2017, no. S2, pp. 14-23.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c)



This website uses cookies

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

About Cookies