On the Possibility of Modernizing Moving Coils of the Electrodynamic Vibration Stand

Authors: Zuev Al.A., Proskurin A.V. Published: 25.09.2023
Published in issue: #3(146)/2023  

DOI: 10.18698/0236-3941-2023-3-89-97

Category: Mechanical Engineering and Machine Science | Chapter: Machines, Units and Technological Processes  
Keywords: vibration testing, electrodynamic vibration stand, moving coil, conductor, modernization


Currently, testing products for vibration strength and vibration resistance became much more complicated, since the mass of test objects increased, vibration modes (including vibration shocks) are of more complex nature, and, as a result, the equipment operates at the maximum modes and fails. The most complex malfunction that occurs during prolonged hard work of the vibration stand is the breakdown of a moving coil, which repair, as a rule, is possible only in the specialized centers. The paper considers design of a regular moving coil of the high-power vibration stand and indicates its disadvantages. A modernized design of the moving coil is proposed increasing its strength, as well as a device for winding it, which provides necessary tension of the conductor during winding and turning the fiberglass frame. Results of operation of the vibration units with modernized coils are presented, capabilities of the Russian Federal Nuclear Center --- Zababakhin All-Russia Research Institute of Technical Physics in terms of modernizing the vibration stands of various traction forces and structures during repair of the moving coils are indicated. Conclusion is made on the advantages of the modernized moving coils

Please cite this article in English as:

Zuev A.A., Proskurin A.V. On the possibility of modernizing moving coils of the electrodynamic vibration stand. Herald of the Bauman Moscow State Technical University, Series Mechanical Engineering, 2023, no. 3 (146), pp. 89--97 (in Russ.). DOI: https://doi.org/10.18698/0236-3941-2023-3-89-97


[1] Flinn K. Control of multiple shakers using MIMO methods for testing large objects. Proizvodstvo elektroniki, 2018, no. 5, pp. 114--120 (in Russ.).

[2] Kleymenov G.B. Dinamicheskie modeli raketno-kosmicheskikh konstruktsiy [Dynamic models of rocket and space structures.]. Moscow, MATI Publ., 2011.

[3] Levchenko A.S. Levels of vibration impact during testing of spacecraft avionics equipment. Raketno-kosmicheskoe priborostroenie i informatsionnye sistemy [Rocket-Space Device Engineering and Information Systems], 2020, no. 4, pp. 74--82 (in Russ.).

[4] Turkalov O. Fundamentals of vibration testing and structural analysis. Tekhnologii v elektronnoy promyshlennosti, 2018, no. 1, pp. 54--65 (in Russ.).

[5] Nesterov A.P. Vibration testing and data analysis. Modern approach. Pribory i sistemy. Upravlenie, kontrol, diagnostika [Instruments and Systems: Monitoring, Control, and Diagnostics], 2017, no. 11, pp. 52--54 (in Russ.).

[6] Zverev A.Ya., Chernykh V.V. Experimental determination of acoustic and vibroacoustic characteristics of multilayer composite panels. Acoust. Phys., 2018, vol. 64, no. 6, pp. 750--759. DOI: https://doi.org/10.1134/S1063771018060143

[7] Svatkov D.S. Use of finite element methods of research in the techniques vibration tests. Uspekhi sovremennoy radioelektroniki [Achievements of Modern Radioelectronics], 2016, no. 11, pp. 273--277 (in Russ.).

[8] Gordeev B.A., Okhulkov S.N., Lyubimov A.K., et al. Research of the amplitude-frequency characteristics of magnetorheological hydromounts under the influence of broadband random vibration. Vestnik mashinostroeniya, 2020, no. 5, pp. 3--7 (in Russ.).DOI: https://doi.org/10.36652/0042-4633-2020-5-3-7

[9] Tukalov O.A. Sentek Dynamics vibration test systems. Tekhnologii v elektronnoy promyshlennosti, 2016, no. 3, pp. 74--80 (in Russ.).

[10] Chelpanov I.B., Kochetkov A.V. Electrodynamic vibration stands, their selection and application. Vestnik mashinostroeniya, 2014, no. 5, pp. 85--88 (in Russ.).

[11] Aung Tkhura, Simonov B.M., Timoshenkov A.S. Study on resistance of samples of capacitive type micromecanical accelerometers to mechanical stress. Izvestiya vuzov. Elektronika [Proceedings of Universities. Electronics], 2019, vol. 24, no. 6, pp. 619--626 (in Russ.). DOI: https://doi.org/10.24151/1561-5405-2019-24-6-619-626

[12] Abanin D.A., Zuev A.A., Khalitov R.T. Sposob izgotovleniya katushki vysokovoltnogo elektrotekhnicheskogo ustroystva [Method of coil manufacturing of high voltage electrotechnical device]. Patent RU 2566810. Appl. 07.03.2014, publ. 27.10.2015 (in Russ.).

[13] Abanin D.A., Deryabin D.Yu., Zasukhin V.V., et al. Sposob izgotovleniya katushki dlya elektrodinamicheskoy ustanovki [Coil manufacturing method for electrodynamic installation]. Patent RU 2729199. Appl. 26.12.2019, publ. 05.08.2020 (in Russ.).

[14] Zhdanok A.A., Kuznetsov V.A., Tolochko B.P., et al. The use of the mechanochemical method for obtaining modifiers of in-mold copper modification. Chemistry for Sustainable Development, 2022, vol. 30, no. 3, pp. 226--235. DOI: https://doi.org/10.15372/CSD2022377

[15] Nedobitkov A.I. Peculiarities of current overload in the car electric network. Pozharovzryvobezopasnost [Fire and Explosion Safety], 2019, vol. 28, no. 4, pp. 42--50 (in Russ.). DOI: https://doi.org/10.18322/PVB.2019.28.04.42-50