Published September 22, 2025 | Version v1
Journal article Open

THE POSSIBILITIES OF USING A NEW TYPE PHASE REGULATOR

Authors/Creators

  • 1. Kyrgyz State Technical University named after I. Razzakov
  • 2. yrgyz State Technical University named after I. Razzakov
  • 3. OJSC Electric Power Plants

Description

This research addresses the development of a new type of phase regulating device capable of performing both phase regulation and phase conversion functions. The aim of the study is to determine the output parameters of this newly created device when applied to harmonic electrical oscillations. The proposed phase regulator allows continuous adjustment of harmonic phases within the range of 0° to 360° in a four-wire industrial frequency network. To analyze its operation, a mathematical model was constructed using nodal potential equations and the equivalent generator method. The scientific significance lies in the creation of a simple yet effective design that employs only a single circuit element, such as a variable resistor (rheostat, potentiometer) or, alternatively, a laboratory adjustable autotransformer (LATR). Depending on its configuration, the output can be single-phase, twophase, or three-phase, providing flexibility for different applications. The device was studied through mathematical modeling to evaluate its characteristics. The practical significance of the research is considerable: phase regulation is a highly relevant task in electrical engineering, power engineering, radio engineering, and automation. The proposed phase regulator can be effectively used in rectifier technology employing thyristors, in controlled shunt reactors, and in electric drives, where it offers advantages of simplicity, cost-effectiveness, and dual functionality. 

Files

Deutsche internationale Zeitschrift für zeitgenössische Wissenschaft №112 2025-35-47.pdf

Files (1.1 MB)

Additional details

References

  • 1. Sabirov T.N., Smirnov M.A. Digital phase regulator based on a programmable timer. Engi-neering Herald of Don. 2018;(2):121–129. 2. Goryachev V.Ya., Brostilova T.Yu., Kis-lyakov S.V. Mechanical quantity sensors based on phase regulators with a moving magnetic field. Reliability and Quality of Complex Systems. 2017:59–69. 3. Butorin V.M. Millimeter-wave phase regu-lator based on two semiconductor varactors. Elec-tronic Equipment. Series 1. Microwave Technolo-gy. 2011;3(510):55–65. 4. Kokhanov A.B. Technology of synchro-nous detection of signals. Radioelectronics and Communications Systems. 2007;50:593–602. 5. Butikov E.I., Bykov A.A., Kondratyev A.S. Physics in Examples and Problems: Textbook for Universities. Moscow: Nauka; 1989. 464 p. 6. Malygin A.N., Prasko A.D., Trotsenko I.V. Device for estimating the difference in amplitudes, frequencies, and phases of sinusoidal electrical oscillations. Izvestiya TulaGU Technical Sciences. 2020;(2):94–98. 7. Electrical Machines [Internet]. Available from: https://servomotors.ru/documentation/electromotor/book47/book47p32.html. 8. Moskalev Yu.V. Determination of the min-imum number of turns of the coils of the secondary winding of a transformer multi-phase converter. Omsk Scientific Herald. 2022;1(181):61–66. 9. Roginskaya L.E., Gorbunov A.S., Yalalova Z.I. Improvement of electromagnetic compatibility of converter devices with the network and load using multi-phase transformers. Electrical and In-formation Systems. 2014;10(3):21–29. 10. Karekar S. Modeling and simulation of three phases to seven phases transformer connec-tion. International Journal for Research in Applied Science and Engineering Technology. 2016;4(3):273–280. 11. Yusoff N., Karim K., Ghani S., et al. Analy-sis of multiphase transformer supplying a static and dynamic load. Journal of Engineering and Applied Sciences. 2016;11(14):8987–8991. 12. Kharlamov V.V., Moskalev Yu.V., Lysenko V.S. Modeling the operation of a converter for con-necting a three-phase asynchronous motor to a single-phase network. Practical Power Electronics. 2020;4(80):14–19.