Features of the creation of electric power quality control systems in power supply systems of space rocket complexes

Authors

DOI:

https://doi.org/10.15588/1607-6761-2025-1-4

Keywords:

quality, electric power, power supply system, control, structure, consumer, principle of operation

Abstract

Purpose. Solution of electric power quality issues at space rocet complexes during the execution of launch preparation and launch cycles for the space rocket through the creation and solution of the electric power quality control system (EPQCS) as a separate structure within the power supply system of space rocet complexes PSS SRC with the provision of specified power parameters.

Methodology. Review of literary sources on the subject, method of expert evaluations, method of system analysis, method of experimental research.

Findings. Indicators of electricity quality, which are the most important for SRC electricity consumers, and which must be monitored, are given. The main requirements to EPQCS have been determined. In case of exceeding the permissible limits of electricity power quality indicators, EPQCS will allow to take operational measures necessary to counter off-nominal situations, by using to the management of the elements of the power supply system. Information security was carried out using a routinely adopted structural block diagram of such systems, on the basis of which the three-tier structure of the EPQCS was implemented. The algorithm and basic principles of the operation of the EPQCS in the nominal mode and the mode beyond the limits of the power quality indicators (PQI) are reviewed. A short description of the structure, as well as an example of the algorithm for managing the EPQCS subordinates, has been included.

Originality. The task of a comprehensive approach to electricity power quality indicators was solved and created electric power quality control system in the SRC power supply systems. Microprocessor control means primarily provide speed in comparison with similar systems based on analog-to-digital converters. The proposed EPQCS carries out electricity quality control with the display of data on the operator's screen in real time, continuous monitoring with fixation and registration of the main parameters, as well as notification of the operator in case off-nominal situations.

Practical value. Developed, manufactured and successfully passed all types of tests of the electric power quality control system for the SRC «Сyclone -4» (Brazil), and partly for the SRC «Сyclone -4М» (Canada).

Author Biographies

V.S. Reva, “Yuzhnoye” SDO

Postgraduate Student of the electric drive department engineering of the Dnipro University of Technology, Head of the group, «Yuzhnoye» SDO, Krivorizska street, 3, Dnipro

О.G. Lysenko, Dnipro University of Technology

Ph.D. technical Sciences, associate professor, associate professor of the electric drive department engineering of the Dnipro University of Technology, Dmytro Yavornytskyi Avenue, 19,Dnipro

О.V. Udovyk, Dnipro University of Technology

Postgraduate student of the Department of electric power engineering of the of the Dnipro University of Technology, Dmytro Yavornytskyi Avenue, 19, Dnipro

References

Linnyk A. K. (2021). Philosofski aspektu rozrobku raketno-kosmichnoi techniku (Philosophical as-pects of the development of rocket and space technology) [Electronic resource]. System design and analysis of aerospace technique characteris-tics. Vol. 28, No. 1. 14–19. Access mode: https://doi.org/10.15421/472102

Pravyla URKT-01.01 Rozrobka, vygotovlennya ta ekspluataciya raketno-kosmichnoi tekhniku (Rules URKT-01.01 Development, manufacture and operation of rocket and space technology). [Put into effect by the order of the NKAU dated 12.12.2001 №210]. – 12 p.

Fedorov O.P. (2014) Kosmichna tekhnika ta tekhnologii. Enciklopediya Suchasnii Ukrainy. Ky-iv: Institut Encyklopedicheskih doslidgen NAN Ukrainy (Space engineering and technologies. En-cyclopedia of Modern Ukraine. Kyiv: Institute of Encyclopedic Research of the National Academy of Sciences of Ukraine). URL: https://esu.com.ua/article-3846.

Shevtsov V. Yu. (2022). Tehnologsya proektuvann-ya I konstruyuvannya tehniky I tehnichnyh sys-tem. Systemne proektuvannya ta analiz harakter-ystyk aerokosmichnoi tehniky. (Technologies of design and construction of equipment and tech-nical systems) [Electronic resource]. System design and analysis of aerospace technique characteris-tics. Vol. 26, No. 1, 63–70. Access mode: https://doi.org/10.15421/471909

Volodarsky E.T. (2014). Systema monitoringu yakosti elektrychnoi energii u decentralizovanych systemach electropostachannya (Electric energy quality monitoring system in decentralized power supply systems) [Electronic resource]. Eastern Eu-ropean Journal of Advanced Technologies. No. 318 (69), 10–18.

Abdel-Galil, T., Kamel M., Youssed A. M. (2004). Power quality disturbance classification using the inductive inference approach [Text]. IEEE Trans. on Power Delivery. Vol. 19, No. 4. 1812–1818.

He, H., Starzyk, J. A. (2006). A self-organizing learning array system for power Quality classifica-tion based on wavelet transform [Text]. IEEE Trans. on Power Delivery. Vol. 21, No 1, 286–295.

Yang, H. T., Chung, L., Liao, C. C. (2001). A de-noising sheme for enhancing wavelet-based power quality monitoring system [Text]. IEEE on Power Delivery. Vol. 16, Issue 3, 353–360.

Hryb O. G., Gapon D. A., Ierusalimova T. S., Belov M. S., Leleka O. V. (2016). Monitoryng spogiv-annya elektroenergii z kontrolem yakosti (Moni-toring of electricity consumption with quality con-trol). Bulletin of Vinnytsia Polytechnic Institute. No. 2, P. 39-44. Access mode: http://nbuv.gov.ua/UJRN/vvpi_2016_2_8

Coleman P. (2007). Power Quality Monitoring [Electronic resource]. Electrical Engineering Handbook. Mode of access: https://doi.org/10.1201/9781420009255.ch33

Sinchuk І. О., Kotyakova M. G. (2023). Electricity quality control in the aspect of implementation of micro grid technology [Electronic resource]. Scientific notes of Taurida National V.I. Vernadsky University. Series: Technical Sciences. Vol. 1, No. 2, 288–292. Mode of access: https://doi.org/10.32782/2663-5941/2023.2.1/45

Bunko V., Кondrat О., Bunko N. (2024). Analysis of the use and implementation of the smart system for monitoring the electrical energy of the educational building [Electronic resource]. Transactions of Kremenchuk Mykhailo Ostrohradskyi National University. No. 4, 169–176. Mode of access: https://doi.org/10.32782/1995-0519.2024.4.22

An example of implementing an automated sys-tem for monitoring and commercial accounting of electricity (ASKOE) [Electronic resource] – Access mode: https://www.svaltera.ua/presscenter/articles/4379.php – Screen title

Energy consumption accounting and maintenance control systems [Electronic resource] – Access mode: https://innovinnprom.com/galuzevi-rishennya/systemy-obliku-energospozhyvannya-i-kontrolyu-tehnichnogo-obslugovuvannya – Screen title

DSTU EN 50160:2023 Haracterystyky naprugy elektropostaczannya v mererzach zagalnogo pryznaczennya. – [Replaces DSTU EN 50160:2014; valid from 1998-01-01] – Kyiv, Minekonomrozvytku Ukrainy. (Characteristics of power supply voltage in general purpose electrical networks, Kyiv, Ministry of Economic Develop-ment of Ukraine), 27p.

DSTU 3466-96 Yakist elektrychnoi energii terminy ta vyznachennya. – [Valid from 1998-01-01] – Kyiv NUVO "Energokompleks" (Quality of electrical energy, terms and definitions, Kyiv, NUVO "Energokompleks"), 15p.

IEEE 1547:2003. Standard for Interconecting Distributed Resources with Electric Power System. – [Valid from 2023-07-28] , 2003. – 16 p.

Frolov V.P. Metod formuvannya struktur system bezperebiinogo elektropostachannya startovyh kompleksiv raket-nosiiv na osnovi matematych-nogo moduluvannya: dys… kand. techn. nauk: 05.07.06 (The method of forming the structures of uninterrupted power supply systems of launch complexes based on modeling: diss. Ph.D. tech-nical of science: 05.07.06)/ Kharkiv: Nac. Aero-kosm. Un-t. im. N.E. Gukovskogo Khark. aviac. In-t. 171p.

H. Wayne Beaty. (2002). Electrical Power Systems Quality. [S. l.]: McGraw-Hill Professional, 528.

Romero G. (2011). Power Quality Harmonics Analysis and Real Measurements Data [Electronic resource]. InTech, Mode of access: https://doi.org/10.5772/699

Janik P. Kosobudzki G, Schwarz H. (2017). Influ-ence of increasing numbers of RE-inverters on the power quality in the distribution grids: A PQ case study of a representative wind turbine and photo-voltaic system [Electronic resource]. Frontiers in Energy. Vol. 11, No. 2, 155–167. Mode of access: https://doi.org/10.1007/s11708-017-0469-3

Pivnyak G. Assessment of power supply energy efficiency by voltage quality criterion [Electronic resource] / G. Pivnyak et al. // Rynek Energii. – 2021. – No. 4(155). P. 75-84. ISSN 14255960.

El Hajji M., Mahmoudi H., Labbadi M. (2020). The electromagnetic interferance caused by high voltage power lines along the electrical railway equipment [Electronic resource]. International Journal of Electrical and Computer Engineering (IJECE). Vol. 10, No. 5, 45-81. Mode of ac-cess: https://doi.org/10.11591/ijece.v10i5.pp4581-4591

Stones J., Collinson A., (2001). Power quality [Electronic resource]. Power Engineering Journal. Vol. 15, No. 2, 58–64. Mode of ac-cess: https://doi.org/10.1049/pe:20010201

J. Lamoree. (1994). Voltage sag analysis case studies [Electronic resource]. IEEE Transactions on Industry Applications. Vol. 30, No. 4, 1083–1089. Mode of access: https://doi.org/10.1109/28.297926

Bollen M. H. J. (1996). Voltage sags: effects, miti-gation and prediction [Electronic resource]. Power Engineering Journal. Vol. 10, No. 3, 129–135. Mode of access: https://doi.org/10.1049/pe:19960304

Published

2025-04-30

How to Cite

Reva, V., Lysenko О., & Udovyk О. (2025). Features of the creation of electric power quality control systems in power supply systems of space rocket complexes. Electrical Engineering and Power Engineering, (1), 32–41. https://doi.org/10.15588/1607-6761-2025-1-4