RESEARCH OF ELECTROMAGNETIC INTERFERENCE EFFECTS ON THE OPERATIONAL STABILITY OF A MEASURING DEVICE

Authors

Erkin Uljaev, Tashkent State Technical University. Address: 2 Universitetskaya st., 100095, Tashkent city, Republic of Uzbekistan.Follow
Elyor Faxriddinovich Khudoyberdiev, Tashkent State Technical University. Address: 2 Universitetskaya st., 100095, Tashkent city, Republic of Uzbekistan.Follow
Utkirjon Murodillayevich Ubaydullayev, Tashkent State Technical University. Address: 2 Universitetskaya st., 100095, Tashkent city, Republic of Uzbekistan.Follow
Shohrux Nurali o‘g‘li Narzullayev, Tashkent State Technical University. Address: 2 Universitetskaya st., 100095, Tashkent city, Republic of Uzbekistan.Follow

Abstract

The article explores the impact of electromagnetic interference on the performance of measuring devices used in industrial environments. An experimental analysis of sensor parameters and the influence of electromagnetic fields on their accuracy was conducted. Testing methodologies utilizing shielding technologies were developed to enhance interference resistance. The results confirm the efficiency of protective shielding in ensuring stable device operation under various interference sources.

First Page

176

Last Page

183

References

1. Grigor'ev, V.I. (1985). Elektromagnitnaya sovmestimost' radioelektronnykh sredstv [Electromagnetic Compatibility of Radio-Electronic Means]. M.: Radio i svyaz'. 272 p. (in Russian).

2. Romanov, V.A. (1990). Elektromagnitnye pomekhi [Electromagnetic Interference]. M.: Energoatomizdat. 115 p. (in Russian).

3. Mathur, P., Raman, S. (2020). Electromagnetic Interference (EMI): Measurement and Reduction Techniques. Journal of Electronic Materials. 49(5), 2975-2998. https://doi.org/10.1007/s11664-020-07979-1

4. Kuznetsov, A.I. (1987). Elektromagnitnye pomekhi v sistemakh upravleniya [Electromagnetic Interference in Control Systems]. M.: Mashinostroenie. 312 p. (in Russian).

5. Korobeynikov, A.A., Titov, V.V. (2006). Elektromagnitnaya sovmestimost' [Electromagnetic Compatibility]. M.: Goryachaya liniya – Telekom. 118 p. (in Russian).

6. GOST 13109-97. Elektricheskaya energiya. Elektromagnitnaya sovmestimost' tekhnicheskikh sredstv. Normy kachestva elektricheskoy energii v sistemakh elektrosnabzheniya obshchego naznacheniya [Electrical energy. Electromagnetic compatibility of technical equipment. Quality standards for electrical energy in general-purpose power supply systems]. M.: Standartinform, 1998. (in Russian).

7. RD 153-34.0-15.502-2002. Metodicheskie ukazaniya po kontrolyu i analizu kachestva elektricheskoy energii v sistemakh elektrosnabzheniya [Guidelines for Monitoring and Analyzing the Quality of Electrical Energy in Power Supply Systems]. M.: Standartinform, 2002. (in Russian).

8. Adamczyk, B. (2017). Foundations of Electromagnetic Compatibility: with Practical Applications. New York: John Wiley & Sons Ltd., 632 p.

9. Uljaev, E., Ubaydullaev, U.M., Narzullaev, S.N., Khudoyberdiev, E.F., Haydarov, F.G. (2020). Classification of detectors of capacitive humidity transducers of bulk materials. International Journal of Advanced Science and Technology, 29, 1949-1953.

10. Shabalina, N.A. (2012). Elektromagnitnye pomekhi v promyshlennosti: printsipy vozniknoveniya i vliyanie na elektronnoe oborudovanie [Electromagnetic Interference in Industry: Principles of Occurrence and Impact on Electronic Equipment]. Innovatsii v nauke: sb. st. po mater. XIII mejdunar. nauch.-prakt. konf. Novosibirsk: SibAK, 112-119 (in Russian).

11. Uljaev, E., Ubaydullaev, U.M., Khudoyberdiev, E.F., Narzullaev, S.N.(2023). Capacitive moisture meter for bulk materials. Uzb.pat. IAP [07318], Feb. 28, 2023.

12. Uljayev, E., Ubaydullayev, U.M., Narzullayev, S.N., Khudoyberdiyev, E.F. (2024). Intellectual Device for Measuring the Humidity of Bulk Materials. In: Aliev, R.A., et al. 12th World Conference “Intelligent System for Industrial Automation” (WCIS-2022). WCIS 2022. Lecture Notes in Networks and Systems, 718. Springer, Cham. https://doi.org/10.1007/978-3-031-51521-7_3.

13. Uljayev, E., Khudoyberdiyev, E.F., Narzullayev, S.N. (2023). Razrabotka konstruktsii i funktsional'noy skhemy polutsilindricheskogo yomkostnogo potochnogo vlagomera [Development of the design and functional diagram of a semi-cylindrical capacitive flow moisture meter]. Descendants of Al-Farghani electronic scientific journal of Fergana branch of TATU named after Muhammad al-Khorazmi, 1(4), 114-122. (in Russian).

14. Uljayev, E., Khudoyberdiyev, E.F., Narzullayev, S.N. (2024). Artificial Neural Network Based Grain Moisture Measuring Device. Chemical Technology, Control and Management. 2(116), 59-65.

15. Uljayev, E., Ubaydullayev, U.M., Narzullayev, S.N. (2020). Capacity transformer of coaxial and cylindrical form of humidity meter. Chemical Technology, Control and Management. 4(4), 23-30. https://doi.org/10.34920/2020.4.23-30.

16. Uljayev, E., Khudoyberdiyev, E.F., Narzullayev, S.N. (2024). Investigation of the parameters of semicylindrical capacitive sensor. Chemical Technology, Control and Management. 4 (118), 22-29.

17. Uljaev, E., Narzullayev, S.N., Ubaydullayev, U.M., Shoira, S. (2022). Increasing the Accuracy of Calibration Device for Measuring the Moisture of Bulk Materials. Proc. ICoRSE 2021, Lecture Notes in Networks and Systems, 305, 285-292. https://doi.org/10.1007/978-3-030-83368-8_20.

Recommended Citation

Uljaev, Erkin; Khudoyberdiev, Elyor Faxriddinovich; Ubaydullayev, Utkirjon Murodillayevich; and Narzullayev, Shohrux Nurali o‘g‘li (2024) "RESEARCH OF ELECTROMAGNETIC INTERFERENCE EFFECTS ON THE OPERATIONAL STABILITY OF A MEASURING DEVICE," Chemical Technology, Control and Management: Vol. 2024: Iss. 5, Article 30.
DOI: https://doi.org/10.59048/2181-1105.1650