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Abstract

A new design of an induction transducer has been developed for measuring linear and torsional vibrations in different directions with high sensitivity by constructing an inertial element consisting of four mutually perpendicular sectors and making the masses of two adjacent sectors different from the masses of the other two adjacent sectors. By constructing an inertial element in the form of a sector with two mutually diametric magnetic cores and different masses, and placing it between the horizontal and vertical axes, a design of an induction transducer has been developed that highly sensitively measures linear and torsional vibrations in different directions, and the mass of the inertial element is small. Mathematical models have been developed that allow determining the change in the position of the four mutually perpendicular pole terminals of the inertial element of the created induction vibration transducers under the influence of the acceleration applied to the transducer, based on the balance of forces acting on the inertial element.

First Page

24

Last Page

31

References

  1. Amirov, S.F., Shoimkulov, A.A., Fayzullayev, J.S., Botirov, X.E. (2024). Induction vibration transducer. Patent of the Republic of Uzbekistan No. IAP 7661.
  2. Amirov, S.F., Karimov, I.A., Yuldashev, N.R., Mamadaliyev, U.Sh., Shoimkulov, A.A. (2024). Angular displacement transducer. Patent of the Republic of Uzbekistan No. IAP 7683.
  3. Amirov, S.F., Shoimkulov, A.A. (2023). Study of dynamic characteristics of the mechanical link of the developed inertial-type induction vibration transducer. Chemical Technology, Control and Management, 6, 23–32.
  4. Amirov, S.F., Shoimkulov, A.A. (2023). Inertial-type induction vibration transducers. Railway Transport: Current Problems and Innovations, 4, 133–145.
  5. Amirov, S.F., Shoimkulov, A.A. (2023). Dynamic characteristics of the developed inertial-type induction vibration transducer. The Scientific Journal Vehicles and Roads, 4, 153–162.
  6. Amirov, S.F., Shoimkulov, A.A. (2024). New inertial-type induction vibration transducers. The Scientific Journal Vehicles and Roads, 1, 13–22.
  7. Amirov, S.F., Shoimkulov, A.A. (2024). Correction of dynamic characteristics of induction vibration transducers. The Scientific Journal Vehicles and Roads, 1, 37–44.
  8. Amirov, S.F., Shoimkulov, A.A. (2024). Study of dynamic characteristics of developed inertial-type induction vibration transducers. Railway Transport: Current Problems and Innovations, 1, 106–114.
  9. Fayzullayev, J.S., Shoimkulov, A.A. (2024). Errors of a new induction vibration transducer. The Scientific Journal Vehicles and Roads, 77–83.
  10. Fayzullayev, J.S., Shoimkulov, A.A. (2024). Additional errors of induction vibration transducers. Railway Transport: Current Problems and Innovations, 96–107.
  11. Shoimkulov, A.A., Turdibekov, K.Kh., Fayzullayev, J.S. (2023). Selection of diagnostic parameters and an algorithm for functional diagnostics of traction asynchronous motors. Progress of Science and Technology, 1, 146–154.
  12. Shoimkulov, A.A., Amirov, S.F. (2022). Operating conditions and malfunctions of traction asynchronous motors of electric locomotives and the current state of their diagnostics. Acta of Turin Polytechnic University in Tashkent, 3, 57–62.
  13. Amirov, S.F., Shoimkulov, A.A. (2024). Static and dynamic characteristics of the developed inertial-type induction vibration transducer. The Scientific Journal Vehicles and Roads, 1, 125–135.
  14. Amirov, S.F., Shoimkulov, A.A. (2022). Advantages of electromagnetic diagnostics of traction asynchronous motors of electric locomotives. European Multidisciplinary Journal of Modern Science, 7, 439–442.
  15. Shoimkulov, A.A. (2022). Advantages of test and functional diagnostics in troubleshooting traction asynchronous motors of electric locomotives. International Journal of Theoretical and Practical Research, 2(11), 26–31.
  16. Amirov, S.F., Sharapov, S.A., Sulliev, A.K., Boltaev, O.T. (2023). Biparametric resonant transformer sensor of large linear movements. AIP Conference Proceedings.
  17. Turdibekov, K., Sulliev, A., Iskandarova, O., Bobosulov, J. (2023). Experimental and statistical methods for studying modes of electric power systems under uncertainty. E3S Web of Conferences.
  18. Kasimov, S.A., Sulliev, A., Eshkabilov, A.A. (2023). Optimizing pulse combustion systems for improved efficiency and sustainability in thermal power engineering. E3S Web of Conferences.
  19. Amirov, S., Sulliev, A., Sharapov, S. (2023). Study of differential transformer displacement sensors. E3S Web of Conferences.
  20. Amirov, S., Sulliev, A., Sharapov, S. (2023). Investigation of biparametric resonance sensors with distributed parameters. E3S Web of Conferences.
  21. Yakubov, M., Sulliev, A., Sanbetova, A. (2023). Modern methods for evaluating metrological indicators of measurement and processing channels for diagnostic values of traction power supply. IOP Conference Series: Earth and Environmental Science.

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