Determination of the speed of a microprocessor relay protection device of open architecture with a reed switch and the industrial internet of things

Authors

DOI:

https://doi.org/10.15587/1729-4061.2023.276588

Keywords:

protective relay, actuation speed, reed switch, magnetic field, open source, industrial internet of things, electric experimental installation

Abstract

The paper presents the development of a microprocessor-based relay protection device on open architecture. Currently, there is a problem with modern microprocessor relay protection: the impossibility to replace the damaged element with alternatives from other manufacturers. The solution to this problem is the use of devices with open architecture. The study developed a structural model of a microprocessor-based relay protection device based on an open architecture with the industrial Internet of things application. Open architecture is achieved through open protocols and the principle of modularity. The industrial Internet of things technology transfers the control action of triggering blocking. A microprocessor-based relay protection device prototype based on an open architecture was developed. The simulation of the developed device was conducted. The appearance of higher harmonics and aperiodic components in the short-circuit current was not considered during modeling. Due to the study's limitations in the form of lack of load, current and voltage sensors, such as Hall sensors, and inductance coils, the subject of this study is only the speed of operation. A high multiplicity current generation setup was assembled for experimental testing. The developed relay protection device on an open architecture trips faster than the traditional solution. The application of the Internet of Things allowed it to ensure the blocking of non-selective tripping. The obtained results are provided by structural simplification compared to traditional solutions and speed of information transfer with the application of the Internet of things. The developed open architecture device with the industrial Internet of things technology application gives new possibilities for relay protection systems, including flexibility to meet the requirements in connection with the introduction of distributed power

Author Biographies

Alexandr Neftissov, Astana IT University

PhD, Associate Professor

Research and Innovation Center "Industry 4.0"

Assiya Sarinova, Astana IT University

PhD, Associate Professor

Research and Innovation Center "Industry 4.0"

Ilyas Kazambayev, Astana IT University

Doctoral Student

Research and innovation center "Industry 4.0"

Lalita Kirichenko, Astana IT University

Doctoral Student

Research and innovation center "Industry 4.0"

Oleksandr Kuchanskyi, Taras Shevchenko National University of Kyiv

Doctor of Technical Sciences, Head of Department

Department of Information Systems and Technology

Adil Faizullin, Astana IT University

Master of Technical Sciences, Director of Department

Department of Strategy and Corporate Governance 

References

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Determination of the speed of a microprocessor relay protection device of open architecture with a reed switch and the industrial internet of things

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Published

2023-04-29

How to Cite

Neftissov, A., Sarinova, A., Kazambayev, I., Kirichenko, L., Kuchanskyi, O., & Faizullin, A. (2023). Determination of the speed of a microprocessor relay protection device of open architecture with a reed switch and the industrial internet of things. Eastern-European Journal of Enterprise Technologies, 2(5 (122), 20–30. https://doi.org/10.15587/1729-4061.2023.276588

Issue

Vol. 2 No. 5 (122) (2023): Applied physics

Section

Applied physics

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Copyright (c) 2023 Alexandr Neftissov, Assiya Sarinova, Ilyas Kazambayev, Lalita Kirichenko, Oleksandr Kuchanskyi, Adil Faizullin

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