To the problem of mathematical modelling of the three-phase asymmetrical distribution network

The asymmetrical distribution electric network is considered in the conditions of functioning of the automated meter reading and control system (AMRCS). The problem of identification of its mathematical model in a complex form which comes down to definition of phase shifts of the variables (currents, tension) defining an electric status of three-phase network is formulated. The method of its solution based on the mathematical ratios describing functional communications between state variables and use of algorithms of parameter optimization is offered. The realization of identification procedure of model of a distribution network is enabled with direct use of the basic data obtained on communication channels from subscriber's meters of the electric power. The method can be used for a solution of a number of functional tasks as a part of the AMRCS oriented for diagnostics of statuses of a trunk line and energy losses in a distribution network.

1. Eremina MA. Development of automatic systems for commercial accounting of energy resources (AMRMS). Molodoj uchenyj. 2015;3:135-138.

2. Sapronov AA, Kuzhekov SL, Tynjanskij VG. Expeditious identification of uncontrollable electricity consumption in electric networks up to 1 kV. News of higher education institutions. Electromecanics. 200;1:55-58.

3. Ershov AM, Filatov OV, Molotok AV. System of protection of an electrical network of 380B against breaks of an air-line. Elektricheskie stancii. 2016;5:28-33.

4. Klochkov AN. The device for detection of three-phase networks with break of a phase wire. Vestnik Krasnoyarskogo gosudarstvennogo agrarnogo universiteta. 2011;1:221-223.

5. Omorov TT, Takyrbashev BK, Zakiriayev KE. On the Problem of Diagnosing Open-Circuit Faults of Electric Lines in Three-Phase Distribution Networks. Electricity. 2018;8:24-28.

6. Ponomarenko OI, Holiddinov II. Influence of the asymmetrical modes on losses of power in electrical networks of the distributed systems of power supply. Energetik. 2015;1:6-8.

7. Kosouhov FD, Vasilev NV, Filippov AO. Decrease in losses from asymmetry of currents and improvement of quality of electric energy in networks of 0,38 kV with household loadings. Electrical Equipment. 2014;6:8-12.

8. Averbuh MA, ZHilin EV. About losses of the electric power in systems of power supply of individual housing construction. Energetik. 2016;6:54-57.

9. Kiselev MG, Lepanov MG. Balancing currents in power supply networks with a power electric regulator of inactive power. Elektrotekhnika. 2018;11:63-70.

10. Naumov IV, Ivanov DA, et al. The symmetrizing device for three-phase networks with a zero wire. Pat.№ 2490768 (RF). Byull. № 23. 20.08.2013.

11. Omorov TT. Balancing of the Distributed Electrical Network by Method of Digital Regulation. Mechatronics, automation, management. 2018;19(3):194-200.

12. Omorov TT, Takyrbashev BK. To a problem of optimization of asymmetrical working hours of distributive networks. Devices and systems: Management, Control, Diagnostics.2016;6:11-15.

13. Kochergin SV, Kobelev AV, Hrebtov NA, et al. Modeling of rural distributive electric networks 10/0,4 of kV. Fractal simulation Publ. 2013;15-13.

14. Demirchjan KS, Nejman LR, Korovkin AV. Theoretical foundations of electrical engineering. 2009;1:512.

15. Zelenskii EG, Kononov SA, Kostyukova SS. Identification of parameters of distribution networks by synchronized current and voltage measurements. Russian Electrical Engineering. 2016;87(7):363-368.

16. Stepanov AS, Stepanov SA, Kostyukova SS. Identification of parameters of models of electric network elements on the basis of tellegen , s theorem. Russian Electrical Engineering.2016;87(7):369-372.

17. Bahvalov NS. Numerical methods. M.: The science, 1975. 632p

18. .Pshenichnyi BN, Danilin UM. Numerical methods in extreme. М.: The science, 1975. 319 p.

19. Omorov TT, Kojekova GA. Synthesis of the laws of control of the interconnected electric drivers. Devices and systems: Management, Control, Diagnostics. 2009;10:10-13.

20. Omorov TT, Kojekova GA.Synthesis of control system by the synchronous generator. Devices and systems: Management, Control, Diagnostics. 2011;5(91):5-9.