Study of a damper based on a multilayer magnetorheological elastomer

Cover Page

Cite item

Full Text

Abstract

The research presented in the work focuses on a damper that utilizes an "intelligent" material called multilayer magnetorheological elastomer. These devices are of interest due to their ability to adjust the elastic properties, size, and shape of the working body by manipulating the external magnetic field. They also have a high load capacity. The effectiveness of the damper's vibration isolation is determined by its design, manufacturing technology, and the composition of the multilayer magnetorheological elastomer. The mechanical and magnetic hysteresis of the device allows for evaluating the controllability of the damper and its ability to absorb vibrations. Research results indicate the presence of a symmetric and narrow hysteresis loop, not exceeding 7 μm, within the operating range of control currents.

About the authors

Vladimir S. Tabakaev

Bauman Moscow State Technical University (BMSTU)

Author for correspondence.
Email: vladimirt530@gmail.com

Undergraduate student of the Department of Mechanical Engineering Technology (MT-11)

Russian Federation, Moscow

Aleksei M. Bazinenkov

Bauman Moscow State Technical University (BMSTU)

Email: a.bazinenkov@yandex.ru

Candidate of Science (Engineering), Associate Professor
of the Department of Mechanical Engineering Technology (MT-11)

Russian Federation, Moscow

Grigorii B. Tuzhba

Bauman Moscow State Technical University (BMSTU)

Email: Tuzhbag@me.com

Undergraduate student of the Department of Mechanical Engineering Technology (MT-11)

Russian Federation, Moscow

Alina K. Shagimuratova

Bauman Moscow State Technical University (BMSTU)

Email: alina_shagimuratova@icloud.com

Master of Engineering

Russian Federation, Moscow

References

  1. Kutsubina, N. V. and Sannikov, A. A. (2014), Teoriya vibrozashchity i akusticheskoy dinamiki mashin [Theory of Vibration Protection and Acoustic Dynamics of Machines], Ural State Forest Engineering University, 2014, 167 p. (in Russian).
  2. Chelomey, V. N., (1981), Vibratsii v tekhnike: zashchita ot vibratsii i udarov [Vibrations in Engineering: Vibration and Impact Protection], in Frolov, K. V. (ed.), Mashinostroenie, Moscow, 456 p. (in Russian).
  3. Preumont, A. (1997), Vibration Control of Active Structures. Volume 179. Solid Mechanics and Its Applications, 266 p.
  4. Song, G., Sethi, V. and Li, H.-N. (2006), "Vibration control of civil structures using piezoceramic smart materials", Engineering Structures, Volume 28, Issue 11, pp. 1513-1524.
  5. Kuo, W. H., Wang, Y. P., Shiao, Y., Guo, J., Chiang, M. H. and Din, Y. K. (2006), "Semi-active Control of Vehicle Suspension System Using Electrorheological Dampers", 2006 6th World Congress on Intelligent Control and Automation.
  6. Deng, Hua-xia and Gong, Xing-long (2008), "Application of magnetorheological elastomer to vibration absorber", Communications in Nonlinear Science and Numerical Simulation, Volume 13, Issue 9, pp. 1938-1947.
  7. Song, Henan; Shan, Xiaobiao; Hou, Weijie; Wang, Chang; Sun, Kaiwei and Xie, Tao. (2023), "A novel piezoelectric-based active-passive vibration isolator for low-frequency vibration system and experimental analysis of vibration isolation performance", Energy, Volume 278, Part A, 1 September 2023, 127870.
  8. Vasiliev, S. G. (2016), "P'ezoelektricheskie, piroelektricheskie i uprugie svoystva mikrotrubok difenilalanina" [Piezoelectric, pyroelectric, and elastic properties of microtubules of diphenylalanine], Ph.D. Thesis, Ural Federal University named after the first President of Russia, B. N. Yeltsin, Ekaterinburg, Russian Federation. (in Russian).
  9. Gorshkov, V. N., Kolupaiev, V. O., Boiger, G. K., Mehreganian, N., Sareh, P. and Fallah, A. S (2024), "Smart controllable wave dispersion in acoustic metamaterials using magnetorheological elastomers", Journal of Sound and Vibration, March 2024, Volume 572.
  10. Fu, J. , Yu, M. , Dong, X. and Zhu, L. X. (2013), "Magnetorheological elastomer and its application on impact buffer", Journal of Physics : Conference Series,Volume 412 (2013), 012032.
  11. Zhu, Zhisen; Wang, Ze; Dai, Keren; Wang, Xiaofeng; Zhang, He and Zhang, Wenling (2023). "An adaptive and space-energy efficiency vibration absorber system using a self-sensing and tunable magnetorheological elastomer", Nano Energy, Volume 117, 108927.
  12. Bazinenkov, A. M., Shagimuratova, A. K., Makeev, I. V., Bakharev, V. A. and Mukhanov, V. V. (2023), "Thin-film electrodea of dielectric elastomers actuators based for active vibration control system", Proceedings of 6th International Conference "Dynamics and Vibroacoustics of Machines" (DVM2022), in Shakhmatov, E. V. (ed.), Izdatel'stvo Samarskogo universiteta [Samara University Publ.], pp. 90-92. (in Russian).

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2024 Tabakaev V.S., Bazinenkov A.M., Tuzhba G.B., Shagimuratova A.K.

Creative Commons License
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

Journal of Dynamics and Vibroacoustics

ISSN 2409-4579 (Online)

Publisher and Founder: Samara National Research University, 34, Moskovskoye shosse, Samara, 443086, Russian Federation.

Extract from the register of registered media

Editor-in-chief:  Academician of the RAS
E. V. Shakhmatov 

4 issues per year.

Free price

Editorial address: room 324, 43, Gaya street, Samara, 443086

Address for correspondence: 34, Moskovskoye shosse, Samara, 443086, Russian Federation, Samara National Research University (room 324, building 14)

Phone: 8 (846) 267 47 66

e-mail: dynvibro@ssau.ru

www: https://dynvibro.ru

© Samara University

 

This website uses cookies

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

About Cookies