Smart Search 



Title of the article

METHOD OF SELECTING THE OPERATION PARAMETERS OF ELECTRIC SPINDLE WITH AEROSTATIC SUPPORTS FOR SEPARATION OF SEMICONDUCTOR PLATES TO CRYSTALS. PART 1. DEVELOPMENT OF A MATHEMATICAL MODEL OF AXIAL OSCILLATIONS OF THE ELECTRIC SPINDLE

Authors

KOVENSKY Alexander E., Head of STC-271, Planar OJSC, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

BASINIUK Vladimir L., D. Sc. in Eng., Prof., Chief of the R&D Center “Mechanical Engineering Technologies and Processing Equipment” – Head of the Laboratory of Gearing Systems and Processing Equipment, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

VOLKOTRUB Ryta E., Researcher of the Laboratory of Gearing Systems and Processing Equipment, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

In the section DYNAMICS, DURABILITY OF VEHICLES AND STRUCTURES
Year 2020 Issue 3 Pages 48–54
Type of article RAR Index UDK 621.81 Index BBK  
DOI https://doi.org/10.46864/1995-0470-2020-3-52-48-54
Abstract The article presents the results of studies of the mechanism of the occurrence of axial vibrations in the mechanical system “electrospindle shaft with aerostatic bearings – cutting diamond disk – cuttable semiconductor wafer”. A mathematical model of the resulting axial vibrations of the electrospindle shaft is proposed, taking into account the natural frequencies of mechanical vibrations of the electrospindle shaft, the working feed rate, the ratio of the axial stiffness of the diamond disk and the axial aerostatic bearings of the electrospindle shaft, the position of the peripheral surface of the semiconductor wafer relative to the direction of the working feed, and the damping properties of the mechanical system under consideration. The use of the proposed model made it possible to obtain engineering dependences, one of which have the possibility to estimate the influence of the above parameters on the deformation of the cutting diamond disk, the value of which is related to the quality of the initial section of the cut groove, the other, which arises in addition to the quasi-static, related to the axial component of the cutting force, dynamic component of the axial load, which is one of the main sources occurrence of cracks and chips of the cutting edges of diamond disks and semiconductor wafers.All of this, in aggregate, will make it possible to develop an adaptive methodology for controlling the functioning parameters of the drives, which ensures the required quality of the slot to be cut in the absence of chips and cracks in the diamond disk and semiconductor wafer.
Keywords

diamond disk, aerostatic bearings, crystals, vibrations, cutting, electrospindle

  You can access full text version of the article.
Bibliography
  1. Kovensky A.E., Basiniuk V.L., Glazunova A.A. Monitoring i upravlenie parametrami kolebaniy vysokoskorostnogo elektroshpindelya na aerostaticheskikh podshipnikovykh oporakh [Monitoring and control of oscillation parameters of a highspeed electrospindle on aerostatic bearings]. Aktualnye voprosy mashinovedeniya, 2019, iss. 8, pp. 154–158 (in Russ.).
  2. Shkolyk S.B., Zaitsev V.A., Tsyrkun D.P., Volkotrub R.E. Nekotorye osobennosti pretsizionnoy planarizatsii plastin [Some features of precision planarization of plates]. Aktualnye voprosy mashinovedeniya, 2018, iss. 7, pp. 86–89 (in Russ.).
  3. Basiniuk V.L., Volkotrub R.E., Lobkova M.P., Shkolyk S.B., Tsyrkun D.P. Nekotorye osobennosti podshipnikovykh uzlov pretsizionnykh vysokoskorostnykh elektroshpindeley [Some features of the bearing assemblies of precision high-speed electrospindles]. Aktualnye voprosy mashinovedeniya, 2017, iss. 6, pp. 173–176 (in Russ.).
  4. Shchetinin V.S. Nauchnoe obosnovanie sozdaniya i razrabotka vysokoskorostnykh shpindelnykh uzlov na gazomagnitnykh oporakh metallorezhushchikh stankov. Diss. dokt. tekhn. nauk [Scientific rationale for the creation and development of high-speed spindle assemblies on the gas-magnetic supports of metal-cutting machines. Extended Abstract of D. Sc. Thesis]. Komsomolsk-on-Amur, 2011. 35 p. (in Russ.).
  5. Kuznetsov N.K., Perepelygina A.Yu., Kononenko R.V. Identifikatsiya parametrov i modelirovanie dinamiki trekhmassovoy mekhatronnoy sistemy [Parameters identification and simulation of three-mass mechatronic system dynamics]. Proceedings of Irkutsk State Technical University, 2010, no. 3, pp. 6–11 (in Russ.).
  6. Makhov A.A., Poznyak G.N. Dinamicheskaya model shpindelya na aerostaticheskikh oporakh [Dynamic model of a spindle on aerostatic bearings]. RUDN journal of engineering researches, 2004, no. 1(8), pp. 76–82.
  7. Poshekhonov R.A., Lapshin V.V., Zakharevich E.M., Kiryanov V.P. Udarnaya diagnostika aerostaticheskogo shpindelnogo uzla so sfericheskimi oporami [Impact diagnostics of an aerostatic spindle unit with spherical bearings]. Science and education, 2014, no. 7. Available at: http://technomag.bmstu.ru/doc/717582.html (accessed 06 February 2020) (in Russ.).
  8. Poshekhonov R.A. Primery rascheta sfericheskoy aerostaticheskoy opory s uchetom smeshcheniy i skorosti shpindelya [Spherical aerostatic bearing calculation examples, taking into account the spindle velocity and displacement]. Engineering journal: science and innovation, 2012, no. 6. Available at: http://engjournal.ru/catalog/eng/teormech/272.html (accessed 06 January 2020) (in Russ.).
  9. Kosmynin A.V., Vinogradov S.V., Vinogradov V.S., Schetinin V.S., Smirnov A.V. Chastichno poristye gazostaticheskie opory shpindelnykh uzlov. Teoriya i eksperiment [Partially porous gas-static supports of spindle assemblies. Theory and experiment]. Moscow, Akademiya estestvoznaniya Publ., 2011. Available at: http://www.rae.ru/monographs/119 (accessed 06 January 2020) (in Russ.).
  10. Guskov A.M., Poshekhonov R.A. Segmentnaya model dlya rascheta sfericheskikh aerostaticheskikh opor [Segment model for calculating spherical aerostatic supports]. Science and education, 2011, no. 12. Available
    at: http://technomag.bmstu.ru/ doc/286475.html (accessed 06 January 2020) (in Russ.).
  11. Poshekhonov R.A. Raschet sfericheskikh aerostaticheskikh opor pri zadannom smeshchenii i skorosti shpindelya [Calculation of spherical aerostatic bearings at a given offset and spindle speed]. Science and education, 2012, no. 10. Available at: https:// cyberleninka.ru/article/n/raschet-sfericheskih-aerostaticheskih-opor-pri-zadannom-smeschenii-i-skorosti-shpindelya (accessed 06 January 2020) (in Russ.).
  12. Kosmynin A.V., Kabaldin Yu.G., Vinogradov V.S., Chernobay S.P. Ekspluatatsionnye kharakteristiki gazovykh opor vysokoskorostnykh shpindelnykh uzlov [Operational characteristics of gas supports of high-speed spindle units]. Moscow, Akademiya estestvoznaniya Publ., 2005. 218 p. (in Russ.).
  13. Li X., Du H., Bo L., Gih K.L. Numerical simulation of slider air bearings based on a mesh-free method for HDD applications. Microsystem Technologies, 2005, vol. 11, no. 8–10, pp. 797–804.
  14. Stepanynts L.G., Zablotsky N.D., Sipenkov I.E. Method of Theoretical Investigation of Externally Pressurized Gas-Lubricated Bearings. Transactions of ASME. Journal of Lubrication Technology, 1969, vol. 91, no. 1, pp. 166–170.
  15. Shatokhin S.N. Teoriya i metody proektirovaniya adaptivnykh gidrostaticheskikh i aerostaticheskikh shpindelnykh opor i napravlyayushchikh metallorezhushchikh stankov. Diss. dokt. tekh. nauk [Theory and design methods of adaptive hydrostatic and aerostatic spindle bearings and guides for metal cutting machines. Extended Abstract of D. Sc. Thesis]. Krasnoyarsk, 2010. 50 p. (in Russ.).
  16. Usakin K.S., Ignatyev A.A. Modelirovanie dinamicheskogo sostoyaniya shpindelnogo uzla pretsizionnogo tokarnogo modulya dlya vyyavleniya situatsiy, pri kotorykh neobkhodima dopolnitelnaya balansirovka dlya minimizatsii urovnya vibratsii [Simulation of dynamic machining unit precision turning module for identification of situations in which additional balance is necessary for vibration minimization]. Vestnik Saratovskogo gosudarstvennogo tekhnicheskogo universiteta, 2010, vol. 2, no. 1(45), pp. 89–97 (in Russ.).
  17. Khomyakov V.S., Kochinev N.A., Sabirov F.S. Modelirovanie i eksperimentalnoe issledovanie dinamicheskikh kharakteristik shpindelnykh uzlov. Obrabotka konstruktsionnykh materialov v mashinostroenii [Modeling and experimental investigation of spindle dynamic performance. Processing of structural materials in mechanical engineering]. News of the Bulletin of Tula State University. Technical Sciences, 2011, iss. 3, pp. 251–259 (in Russ.).