АНАЛІЗ ВПЛИВУ ТЕХНОЛОГІЧНИХ ФАКТОРІВ НА ФУНКЦІЮ ПЕРЕТВОРЕННЯ КОМПЛАНАРНОГО ЄМНІСНОГО СЕНСОРА БИТТЯ ВАЛІВ

V.O. Bereznychenko; O.Ye. Pidchibii

doi:10.15407/publishing2021.59.093

No. 59 (2021), PROCEEDINGS OF THE SCIENTIFIC AND TECHNICAL CONFERENCE OF YOUNG SCIENTISTS

No. 59 (2021)

ANALYSIS OF THE TECHNOLOGICAL FACTORS INFLUENCE ON RESPONSE FUNCTION OF THE COPLANAR CAPACITIVE SHAFT BEATING SENSOR

PROCEEDINGS OF THE SCIENTIFIC AND TECHNICAL CONFERENCE OF YOUNG SCIENTISTS

https://doi.org/10.15407/publishing2021.59.093

Published 2021-09-20

V.O. Bereznychenko⁺⁻
O.Ye. Pidchibii⁺⁻

V.O. Bereznychenko

Institute of Electrodynamics of the National Academy of Sciences of Ukraine, pr. Peremohy, 56, Kyiv, 03057, Ukraine

https://orcid.org/0000-0002-9961-1703

O.Ye. Pidchibii

Institute of Electrodynamics of the National Academy of Sciences of Ukraine, pr. Peremohy, 56, Kyiv, 03057, Ukraine

https://orcid.org/0000-0003-1310-9358

Article_13 PDF (Українська)

Keywords

hydrogenerator
shaft beating
capacitive sensor
technological factors
computer simulation

How to Cite

Bereznychenko, V.O., and O.Ye. Pidchibii. “ANALYSIS OF THE TECHNOLOGICAL FACTORS INFLUENCE ON RESPONSE FUNCTION OF THE COPLANAR CAPACITIVE SHAFT BEATING SENSOR”. Proceedings of the Institute of Electrodynamics of the National Academy of Sciences of Ukraine, no. 59, Sept. 2021, p. 093, doi:10.15407/publishing2021.59.093.

Abstract

In the paper presents results of analysis of the influence of the thickness of the dielectric substrate of a capacitive beating sensor, the electrodes of which are made of foil dielectric type FR4, on the transformation function of the sensor by methods of computer modeling are presented. The results of research by methods of computer modeling of the influence of the thickness of the dielectric substrate of a capacitive beating sensor, the electrodes of which are made of foil dielectric type FR4, on the transformation function of the sensor are presented. The studies were performed in the measurement range of the sensor with a change in the thickness of the dielectric selected from a standard line of material sizes. A comparative analysis method for manufacturing capacitive sensors using PCB technology was done. As a result of the analysis, the dependences of the influence of the thickness of the dielectric substrate on the conversion function of the capacitive sensor are obtained. Bibl. 20, fig. 2, table.

https://doi.org/10.15407/publishing2021.59.093

Article_13 PDF (Українська)

References

Bryzgalov V.I., Gordon L.A. Gidroelektrostancii: Krasnoyarsk: Publishing and Printing Center Krasnoyarsk State Technical University. 2002. 541 p. (Rus)

ISO 20816-5:2018. Mechanical vibration. Measurement and evaluation of machine vibration. Part 5: Machine sets in hydraulic power generating and pump-storage plants. [Released: 2018-12-01]. ISO/TC 108/SC 2 Measurement and evaluation of mechanical vibration and shock as applied to machines, vehicles and structures, 2018. 60 p.

Zaitsev I.O., Sidorchuk V.E. Optoelectronic sensor for measuring the shaft runout of turbo- and hydrogenerators. Instrumentation -2017: Collection of materials of reports of the 10th international scientific and technical conference. Minsk, 01-03 Nov. 2017. Minsk: BNTU, 2017. Pp. 366368. (Rus)

Levitsky A.S., Zaitsev I.O., Bereznychenko V.O. Features measuring radial run-out hydraulic unit shaft cy-lindrical surfaces. Hidroenerhetyka Ukrainy. 2019. No 12. Pp. 3944. (Ukr)

Levytskyi A.S., Zaitsev I.O., Bereznychenko V.O. Relative and absolute radial vibration of the shaft of the vertical unit. Hidroenerhetyka Ukrainy. 2019. No 34. Pp. 3639. (Ukr)

Zaitsev I.O., Levytskyi A.S. Determination of response characteristic of capacitive coplanar air gap sensor. Proceedings of the 2017 IEEE Microwaves, Radar and Remote Sensing Symposium (MRRS-2017) August 29 – June 30, 2017 Kyiv, Ukraine. 2017. Pp. 85–88. DOI: https://doi.org/10.1109/MRRS.2017.8075034

Levytskyi A.S., Zaitsev Ie.O., Kromplyas B.A. Determination of the response characteristic of the capacitive sensor of the air gap in the hydrogenerator SGK 538/160-70M. Pratsi Institutu Elektrodynamiki NAN Ukrainy. 2016. No 43. Pp. 134137. (Ukr)

Zaitsev I.O., Levytskyi A.S., Sydorchuk V.E. Air gap control system for hydrogenerators. Pribory i metody izmerenij. 2017. Vol. 8. No 2. Pp. 122–130. DOI: https://doi.org/10.21122/2220-9506-2017-8-2-122-130 (Rus)

Zaitsev Ie.O., Levytskyi A.S., Kromplyas B.A. Capacitive distance sensor with coplanar electrodes for large turbogenerator core clamping system. Proceedings of the 2019 IEEE 39th International Conference on Electronics and Nanotechnology (ELNANO), April 16–18, 2019, Kiev, Ukraine. Pp. 644647. DOI: https://doi.org/10.1109/ELNANO.2019.8783916

Levytskyi A.S., Zaitsev I.O., Kobzar K.O. Measuring the stroke of cone disk springs in power accumulators of the turbogenerator stator core using acapacitive sensor. Pribory i metody izmerenij. 2018, Vol. 9. No 2. Pp. 121–129. DOI: https://doi.org/10.21122/2220-9506-2018-9-2-121-129 (Rus)

Levytskyi A.S., Zaitsev I.O., Smyrnova A.M. Elastic sensitive element for force transducers of the effort in the powerful turbogenerators stator tightening prisms core. Pratsi Institutu Elektrodynamiki NAN Ukrainy 2018. No 49. Pp. 32–39. DOI: https://doi.org/10.15407/publishing2018.49.032 (Ukr)

Levytskyi A.S, Fedorenko G.M. Gruboj O.P. Monitoring of the status of powerful hydro and turbo generators using capacitive meter for the parameters of mechanical defects. K.: ІED NANU Publ., 2011. 242 p. (Ukr)

Zaitsev Ie. Development of theory and practical implementation of optoelectronic systems for diagnosing mechanical parameters of powerful turbo- and hydrogenerators: author's ref. dis. ... cand. tech. Sciences: 05.13.05 / Inst. of Electrodynamics of NAS of Ukraine. Kyiv, 2020. 40 p. (Ukr)

Zaitsev Ie., Levytskyi A., Bereznychenko V. Hybrid diagnostics systems for power generators faults: systems design principle and shaft run-out sensors. Power systems research and operation: Selected Problems. Springer, 2022. URL: https://www.springer.com/gp/book/9783030829254#aboutBook (accessed: 21.06.2021)

Bereznychenko V., Zaitsev Ie. Non-contact capacitive sensor for powerful electrical machine shafts ron-out control systems. Pratsi Institutu Elektrodynamiki NAN Ukrainy 2020. Vol. 57. Pp. 81–88. DOI: https://doi.org/10.15407/publishing2020.57.081 (Ukr)

Zaitsev Ie., Levytskyi A. Hybrid electro-optic capacitive sensors for the fault diagnostic system of power hydrogenerator. Clean Generators - Advances in Modeling of Hydro and Wind Generators. Intechopen, 2020. 185 p. Pp. 2542. DOI: https://doi.org/10.5772/intechopen.77988

Sysoeva S. Automotive position sensors. Modern technologies and new perspectives. Part 11. Capacitive sensors - new players in the automotive market. Komponenty i tekhnologii. 2006. No 4. (Rus)

Lin Jackson, Bissonnette Marc R. A new capacitive proximity probe immune to electrical runout. URL: https://www.marubun.co.jp/legacy/product/measurement/electric/qgc18e0000000pef-att/PCS_CMVA.pdf (accessed: 01.07.2021)

ANSI/ IPC-A-600G. Acceptability of Printed Boards. [Released: 2004-07-01]. IPC association connecting electronics industries, Bannockburn, Illinois USA, 2004. 140 p.

Yatsyuk L.A., Kosogin O.V., Ushchapovskiy D.Yu., Linyucheva O.V., Fatov Yu.F. The technology of applying non-metallic pokrittіv and wiring boards for hand-held mounting: handpicker. Kiev. KPI im. I. Sikorskogo, Politechnika, 2018. 330 p.