№82-17

Information support for operation of energy system with distributed generation

B. Moroz¹,          https://orcid.org/0000-0002-5625-0864

Yu. Papaika¹,      https://orcid.org/0000-0001-6953-1705

Ye. Koshelenko¹,https://orcid.org/0000-0003-3600-1550

M. Lutsenko¹,     https://orcid.org/0000-0001-6406-2364

B. Makarchuk¹   https://orcid.org/0009-0000-0511-7900

¹Dnipro University of Technology, Dnipro, Ukraine

Coll.res.pap.nat.min.univ. 2025, 82:196-206

Full text (PDF)

https://doi.org/10.33271/crpnmu/82.196

ABSTRACT

Purpose. The purpose of the study is to analyze the challenges and to develop principles and conditions for organizing information support of intelligent power systems with distributed generation at the stages of design, reengineering, and operation of their structural components through optimal message processing, considering their value and aging characteristics.

The methods.The method of rational message processing in single- and multiprocessor computing systems has been applied as a tool for selecting and studying the main characteristics of the system without (or with) resource allocation management and system reconfiguration.

Findings.Dynamic assessment of qualitative and quantitative information characteristics in real-time operational control is a fundamental prerequisite for the creation of “intelligent” control tools for power facilities and networks.

To determine information aging and value characteristics, a methodology and algorithm have been substantiated to address key tasks such as classifying the necessary information for effective management of distributed generation power systems, developing relevant models for studying and forecasting qualitative-quantitative characteristics and significance of input data, and applying expert evaluation methods.

Originality.The effectiveness of using the method of rational organization of message processing in single- and multiprocessor computing systems as a tool of the system itself for selecting and studying changes in the patterns of interaction of the main characteristics of modes in systems with distributed generation has been proven, which allows solving the problems of control strategy, failure of elements, changes in the characteristics of value and aging of messages, and the introduction of new elements into the system with its transfer to the class of adaptive, self-regulating ones.

Practical implementation.The application of the proposed methodological approaches to rational message processing in single- and multiprocessor computing systems is a primary condition for the creation of “intelligent” distributed generation power systems and their prospective development in Ukraine.

Keywords: information support, power system, distributed generation, information aging, message processing, Smart Grid.

References

1. Pivniak, H., Aziukovskyi, O., Papaika, Y., Lutsenko, I., & Neuberger, N. (2022). Problems of development of innovative power supply systems of Ukraine in the context of European integration. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 5, 89–103. https://doi.org/10.33271/nvngu/2022-5/089

2. Kyrylenko, O. V. (Ed.). (2016). Intelligent electric networks: elements and modes : monograph. Institute ofElectrodynamics of the National Academy of Sciences of Ukraine.

3. Shvachych, G., Moroz, B., Pobocii, I., Kozenkov, D., & Busygin, V. (2019). Automated Control Parameters Systems of Technological Process Based on Multiprocessor Computing Systems. Advances in Computer Vision, 666–688. https://doi.org/10.1007/978-3-030-17798-0_53.

4. Kyrylenko, O.V., Blinov, I.V., & Tankevych, S.Ye. (2012). Smart Grid ta orhanizatsiia informatsiinoho obminu v elektroenerhetychnykh systemakh. Tekhnichna elektrodynamika, 3, 47–48.

5. IEC 62351 Cyber Security Series for the Smart Grid. (n.d.). https://syc-se.iec.ch/deliveries/cybersecurity-guidelines/security-standards-and-best-practices/iec-62351/

6. Kyrylenko,O.V., Pavlovskyi,V.V., Steliuk, A.O., & Lenha, O.V. (2023).Analiz zminy chastoty v OES Ukrainy za riznykh rezhymiv yii roboty. Tekhnichna elektrodynamika,1, 51–55.