Clean Power

Ukrainian (UA)English (United Kingdom)

The National Academy of Sciences of Ukraine


The Institute of Electrodynamics

About Institute

DOI: https://doi.org/10.15407/publishing2018.50.016

OPTIMAL ARCHITECTURE AND EQUIPMENT OF THE DISTRIBUTION LINE MONITORING SYSTEM

I. Blinov, Ye. Parus, O. Rybina, S. Tankevych
Institute of Electrodynamics of the National Academy of Sciences of Ukraine,
Peremohy, 56, Kyiv-57, 03680, Ukraine,
е-mail:  This e-mail address is being protected from spambots. You need JavaScript enabled to view it

The article focuses on the formalization of the tasks of development and use of the system of monitoring of fault states in distribution electric networks. The basic functions of the monitoring system and means of realization of such functions are determined. The mathematical model of the problem of choosing the optimal architecture of the monitoring system formalized in the article. The basis of the model presented as the task of maximizing profit (or minimizing damage) from the installation and use of the monitoring system. The main components of the process of selecting the optimal architecture of the monitoring system are presented. The tasks of the subsystem of information support in decision making for analysis of operational information from monitoring means are determined. References 11.
Key words: fault indicators, distribution line, monitoring of emergency conditions.

1. Blinov I.V., Parus Ye.V., Tankevych S.Ye. Optimization of fault indicators setting for overhead power lines monitoring. Elektronika ta zviazok. 2017. Vol 22. № 1 (96). P. 50–57. (Ukr)
2. Blinov I.V., Parus Ye.V., Polyshchuk O.Iu, Zhurvalov I.V. Monitoring of overhead power lines using fault indicators. Elektrycheskye sety y systemy. 2013. № 4. P. 42–46. (Rus)
3. Lutsiak V.V. Remote method for determining the location of interphase short circuit in a 6-35 kV distribution network with overhead transmission lines. Visnyk Kryvorizkoho tekhnichnoho universytetu, 2006. P. 112–115. (Ukr)
4. Zubko V.M., et al. Effectiveness of monitoring the closures in networks with isolated neutral. Visnyk Kharkivskoho natsionalnoho tekhnichnoho universytetu silskoho hospodarstva im. Petra Vasylenka. 2010. Vol. 102. P. 21–23. (Ukr)
5. Walling R.A., et al. Summary of distributed resources impact on power delivery systems. IEEE Transactions on power delivery, 2008. № 23. P. 1636–1644.
6. Lezhniuk P.D., Kutina M.V. Methods and means of protection against breakage of wires and finding fault location in distribution network with complex topology voltage 6-35 kV. Vinnitsia: VNTU, 2014. 152 p. (Ukr)
7. Hai O.V., Kozyrskyi V.V. Choosing the optimal number of partitioning devices for 10 kV power distribution networks. Elektryfikatsiia ta avtomatyzatsiia silskoho hospodarstva. 2004. Vol. 2. P. 12–20. (Ukr)
8. Pazii V. H. Improving the efficiency of short-circuit targeting devices in 6-10 kV electrical distribution networks based on PLC technologies. Enerhetyka ta kompiuterno-intehrovani tekhnolohii v APK. 2014. № 2. P. 14–16. (Ukr)
9. Dercree National Commission for the State Regulation Energy and utilities of Ukraine № 685 from 25.05.2017. On approving the reliability of power supply targets for 2017 (http://www.nerc.gov.ua/?id=25441)
10. Jahedi A., Javidan J., Nasiraghdam H. Multi-objective modeling for fault indicators placement using of NSGA II to reduce off time and costs in distribution network. Technical and Physical Problems of Engineering. 2014. Vol. 6. Issue 21. No 4. P. 106–111.
11. Bjerkan Е., Venseth Т. Locating Earth-Faults in Compensated Distribution Networks by means of Fault Indicators. International Conference on Power Systems Transients (IPST’05). 2005. Paper № IPST05. 107 р.