employee from 01.01.2007 until now
Orenburg, Russian Federation
employee from 01.01.1997 until now
Orenburg, Orenburg, Russian Federation
employee from 01.01.2014 until now
Orenburg, Russian Federation
UDK 62 Инженерное дело. Техника в целом. Транспорт
Increasing the rigidity of universal self-centering devices is one of the topical trends in the design of machine tooling. Calculation of the load distribution between the turns and teeth of a spiral rack and pinion mechanism is a complex engineering problem. When working on the article, it was revealed that an adjacent pair of turns and teeth that are in engagement does not always coincide with a geometrical adjacent pair due to the error in the execution of turns and teeth along the pitch and profile. This is based on experimental data and the proposition that errors in the pitch and profile of the spiral determine the nature of the working pressures in the engagement of the turns and teeth. The article discusses technical solutions in which the rigidity of self-centering devices increases without significant structural changes due to the establishment of the correspondence of the algorithm for changing the elastic properties of parts of the spiral-rack mechanism to the algorithm for changing the load between the bearing elements. Constructive solutions based on the implementation of elastic displacement of the first most loaded turn are proposed, which allows to reduce the interference between the tooth of the cam rack and the turn of the disk spiral. This circumstance contributes to the redistribution of the load in the engagement of the bearing elements of the spiral-rack mechanism. The tests of the developed structures were carried out, which gave positive results.
rigidity, load distribution, spiral rack and pinion mechanism, lathes
1. Feng P.F., Yu D.W., Wu Z.J., Uhlmann E. Jaw-chuck stiffness and its influence on dynamic clamping force during high-speed turning. International Journal of Machine Tools and Manufacture. 2008. Vol. 48. Is. 11. Pp. 1268-1275.
2. Lu K., Wang Y., Gu F., Pang X., Ball A. Dynamic modeling and chatter analysis of a spindle-workpiece-tailstock system for the turning of flexible parts. Int J Adv Manuf Technol. 2019. Vol. 104. Pp. 3007-3015.
3. Singh A., Asjad M., Gupta, P. Reconfigurable machine tools: a perspective. Life Cycle Reliab Saf Eng. 2019. Vol. 8. Pp. 365-376.
4. Rahman M., Ito Y. Machining Accuracy of a Cylindrical Workpiece Held by Three-Jaw Chuck. Bul. of the Japan Society of Precision Eng. 1979. Vol. 13. No. 1. Pp. 7-12.
5. Thorenz B., Westermann H.-H., Steinhilper R. Evaluation of the influence of different clamping chuck types on energy consumption, tool wear and surface qualities in milling operations. Procedia Manufacturing. 2018. Vol. 21. Pp. 575-582.
6. Lu K., Gu F., Longstaff A., Li G. An investigation into tool dynamics adaptation for chatter stability enhancement in the turning of flexible workpieces. Int J Adv Manuf Technol. 2020. Vol. 111. Pp. 3259-3271.
7. Feng P.F., Yu D.W., Wu Z.J., Uhlmann E. An improved computation model for critical bending force of three-jaw chucks. Journal of Materials Processing Technology. 2008. Vol. 208. Is. 1-3. Pp. 124-129.
8. Rahman M., Tsutsumi M. Effect of spindle speed on clamping force in turning. Journal of Materials Processing Technology. 1993. Vol. 38. Is. 1-2. Pp. 407-415.
9. Nyamekye K., Mudiam S. S. A model for predicting the initial static gripping force in lathe chucks. The International Journal of Advanced Manufacturing Technology. 1992. Vol. 7. Pp. 286-291.
10. Tsutsumi M. Chucking force distribution of collet chuck holders for machining centers Journal of Mechanical Working Technology. 1989. Vol. 20. Pp. 491-501.
11. Chernyanskiy P.M. The Residual effect of mechanical systems of machines [Posledeystvie mechnicheskoy sistemy stankov]. Bulletin of machine-building. 2013. No. 1. Pp. 57-59. (rus)
12. Ivasishin G.S. Influence of elastic aftereffect and additivity of elastic aftereffect of an elastic system of a precision metal-cutting machine on the static characteristic of friction wear resistance and fretting resistance of flat guides [Vliyanie uprugogo posledeystviya i additivnosti uprugogo posledeystviya uprugoj sistemy pretsizionnogo metallorezhustchego stanka na staticheskuyu harakteristiku treniya iznosostoykost i frettingostoykost ploskih napravlyaustchih]. Friction and lubrication in machines and mechanisms. 2006. No. 9. Pp. 32-39. (rus)
13. Ivasishin G.S. Effect of elastic aftereffect on the contact stiffness of machine tools and automatic rotary lines [Vliyanie uprugogo posledeystviya na kontaktnuyu zhestkost metallorezhustchih stankov i avtomaticheskih rotornyh liniy]. Bulletin of higher educational. Series «Engineering». 1988. No. 3. Pp. 126-130. (rus)
14. Seregin A.A., Kravtsov A.G. Monitoring of technological systems when processing precise surfaces of a complex contour [Monitoring technologicheskih system pri obrabotke tochnih poverhnostej slozhnogo kontura]. Bulletin of the South Ural State University. Series «Mechanical Engineering». 2018. Vol. 18. No. 4. Pp. 48-56. (rus)
15. Blinov D.S., Morozov M.I. Uneven distribution of the load between the mating turns of the roller and the screw with the nut of the planetary roller screw [Neravnomernost raspredeleniya nagruzki mezhdu sopryagaemimi vitkamirolika i vinta s gaykoj planetarnoj rolikovintovoj peredachi]. Science and Education: scientific publication of the Moscow State Technical University named after N.E. Bauman. 2014. No. 9. Pp. 1-14. (rus)
16. Seregin A.A. Self-centering lathe chuck. Certificate of authorship USSR, no. 1514502, 1989. (rus)
17. Ivasishin G.S. Three-jaw self-centering lathe chuck. Certificate of authorship USSR, no. 984704, 1982. (rus)
18. Ivasishin G. S., Paryshkura M.I., Seregin A.A. Spiral Grinding Machine. Certificate of authorship USSR, no. 1288028, 1987. (rus)
19. Walter M.F., Ståhl J.E. The connection between cutting and clamping forces in turning. International Journal of Machine Tools and Manufacture. 1994. Vol. 34, Is. 7. Pp. 991-1003.
20. Estrems M., Arizmendi M., Cumbicus W.E., López A. Measurement of clamping forces in a 3 jaw chuck through an instrumented aluminium ring. Procedia Engineering. 2015. Vol. 132. Pp. 456-463.