A procedure of studying stationary motions of a rotor with attached bodies (auto-balancer) using a flat model as an example

Authors

DOI:

https://doi.org/10.15587/1729-4061.2019.169181

Keywords:

rotor, isotropic support, auto-balancer, stationary motion, stability of motion, equation of steady motion.

Abstract

The energy method of studying rotor dynamics has been modernized. The method is applicable to the rotors mounted on isotropic elastic-viscous supports when bodies are attached to the rotors and relative motion of these bodies is prevented by elastic and viscous forces. The method is designed to search for steady motions and determine conditions of their existence as well as assess stability of the rotor system. Relative motions of the attached bodies cease at steady motions and the system rotates as a single whole around the axis of rotation formed by supports.

Effectiveness of the method was illustrated by an example of a flat model of a rotor and an auto-balancer with many loads in the form of balls, rollers or pendulums.

It has been established that the system has family of main motions (the rotor is balanced at them) both with and without damping in supports at a sufficient balancing capacity of the auto-balancer.

In the absence of damping in supports, the system has:

‒ isolated secondary motions at which the rotor is unbalanced and centers of mass of the loads are deflected to the side of imbalance or in the opposite direction if there is unbalance of the rotor;

‒ one-parameter families of secondary motions at which the centers of mass of the loads lie on one straight line in the absence of unbalance of the rotor.

In the presence of damping in supports:

‒ the system has isolated secondary motions at which the centers of mass of the loads lie on one straight line and this straight line forms an angle with the imbalance vector depending on the rotor speed in the presence of the rotor imbalance;

‒ there are no secondary motions in the absence of the rotor imbalance.

The secondary motions and domains of their existence do not depend on the angular velocity of the rotor in the absence of damping in supports but they depend on the angular velocity of the rotor in the presence of the rotor imbalance.

Both in the presence and in the absence of damping in supports:

‒ only the secondary motion at which total imbalance of the rotor and loads is greatest can be stable at sub-resonant rotor speeds;

‒ only a family of main motions can be stable at super-resonant rotor speeds.

Author Biographies

Gennadiy Filimonikhin, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropyvnytskyi, Ukraine, 25006

Doctor of Technical Sciences, Professor, Head of Department

Department of Machine Parts and Applied Mechanics

Irina Filimonikhina, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropyvnytskyi, Ukraine, 25006

PhD, Associate Professor

Department of Mathematics and Physics

Iryna Ienina, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropyvnytskyi, Ukraine, 25006

PhD, Associate Professor

Department of Automation Production Processes

Serhii Rahulin, Flight Academy of the National Aviation University Dobrovolskoho str., 1, Kropyvnytskyi, Ukraine, 25005

PhD

Department of Aviation Engineering

References

  1. Thearle, E. L. (1950). Automatic dynamic balancers (Part 2 – Ring, pendulum, ball balancers). Machine Design, 22 (10), 103–106.
  2. Gusarov, A. A. (2002). Avtobalansiruyuschie ustroystva pryamogo deystviya. Moscow: Nauka, 119.
  3. Filimonikhin, G. B. (2004). Zrivnovazhennia i vibrozakhyst rotoriv avtobalansyramy z tverdymy koryhuvalnymy vantazhamy. Kirovohrad: KNTU, 352.
  4. Detinko, F. M. (1956). Ob ustoychivosti raboty avtobalansira dlya dinamicheskoy balansirovki. Izv. AN SSSR. OTN. Mekh. i Mashinostr, 4, 38–45.
  5. Muyzhniek, A. I. (1956). Nekotorye voprosy teorii avtomaticheskoy dinamicheskoy balansirovki. Voprosy dinamiki i prochnosti, 6, 123–145.
  6. Blekhman, I. I. (1981). Sinhronizatsiya v prirode i tekhnike. Moscow: Nauka, 352.
  7. Nesterenko, V. P. (1985). Avtomaticheskaya balansirovka rotorov priborov i mashin so mnogimi stepenyami svobody. Tomsk: Izd-vo Tomsk. un-ta, 84.
  8. Filimonikhin, G. B. (1996). K ustoychivosti osnovnogo dvizheniya dvuhmayatnikovogo avtobalansira. Dopovidi Natsionalnoi akademiyi nauk Ukrainy, 8, 74–78. Available at: http://dspace.kntu.kr.ua/jspui/handle/123456789/6796
  9. Gorbenko, A. N. (2003). On the Stability of Self-Balancing of a Rotor with the Help of Balls. Strength of Materials, 35 (3), 305–312. doi: http://doi.org/10.1023/a:1024621023821
  10. Filimonikhina, I. I. (2006). Zastosuvannia funktsiyi Hamiltona do vyznachennia umov nastannia avtobalansuvannia rotora z nerukhomoiu tochkoiu. Konstruiuvannia, vyrobnytstvo ta ekspluatatsiya silskohospodarskykh mashyn, 36, 241–246.
  11. Green, K., Champneys, A. R., Lieven, N. J. (2006). Bifurcation analysis of an automatic dynamic balancing mechanism for eccentric rotors. Journal of Sound and Vibration, 291 (3-5), 861–881. doi: https://doi.org/10.1016/j.jsv.2005.06.042
  12. Ruelle, D. (1989). Elements of Differentiable Dynamics and Bifurcation Theory. Academic Press, 196. doi: https://doi.org/10.1016/c2013-0-11426-2
  13. Filimonikhin, G. B., Filimonikhina, I. I., Pirogov, V. V. (2014). Stability of Steady-State Motion of an Isolated System Consisting of a Rotating Body and Two Pendulums. International Applied Mechanics, 50 (4), 459–469. doi: https://doi.org/10.1007/s10778-014-0651-9
  14. Artyunin, A. I., Eliseyev, S. V. (2013). Effect of "Crawling" and Peculiarities of Motion of a Rotor with Pendular Self-Balancers. Applied Mechanics and Materials, 373-375, 38–42. doi: https://doi.org/10.4028/www.scientific.net/amm.373-375.38
  15. Antipov, V. I., Dentsov, N. N., Koshelev, A. V. (2014). Dynamics of the parametrically excited vibrating machine with isotropic elastic system. Fundamental'nye issledovaniya, 8, 1037–1042. Available at: http://www.fundamental-research.ru/ru/article/view?id=34713
  16. Lu, C.-J., Wang, M.-C. (2011). Stability analysis of a ball–rod–spring automatic balancer. International Journal of Mechanical Sciences, 53 (10), 846–854. doi: https://doi.org/10.1016/j.ijmecsci.2011.07.005
  17. Rezaee, M., Mohammad Ettefagh, M., Fathi, R. (2019). Dynamics and Stability of Non-Planar Rigid Rotor Equipped with Two Ball-Spring Autobalancers. International Journal of Structural Stability and Dynamics, 19 (02), 1950001. doi: https://doi.org/10.1142/s0219455419500019
  18. Strauch, D. (2009). Classical Mechanics: An Introduction. Springer-Verlag Berlin Heidelberg. doi: https://doi.org/10.1007/978-3-540-73616-5

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Published

2019-05-30

How to Cite

Filimonikhin, G., Filimonikhina, I., Ienina, I., & Rahulin, S. (2019). A procedure of studying stationary motions of a rotor with attached bodies (auto-balancer) using a flat model as an example. Eastern-European Journal of Enterprise Technologies, 3(7 (99), 43–52. https://doi.org/10.15587/1729-4061.2019.169181

Issue

Vol. 3 No. 7 (99) (2019): Applied mechanics

Section

Applied mechanics

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Copyright (c) 2019 Gennadiy Filimonikhin, Irina Filimonikhina, Iryna Ienina, Serhii Rahulin

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