Modes in electrical systems with mobile AC traction substations

Innovative scenarios of reliable energy supply of transportation process aimed at reducing the specific energy consumption and increase energy efficiency of the systems of electric traction. The article suggests innovative energy saving directions in traction networks of railways and new circuit solutions accessing traction substations in energy systems networks, ensure energy security of the transportation process. To ensure the energy security of rail transport special schemes were developed to propose the concept of external power traction substations, which would increase the number of connections to the networks of 220 - 330 kV, as well as the creation of transport and energy corridors, development of its own supply of electric networks of 110 kV substations and mobile RP-110 kV of next generation. Therefore, the investment program of the structures owned by the Ukrainian Railways (Ukrzaliznytsia) need to be synchronized in their technological characteristics, as well as the criteria of reliability and quality of power supply with the same external energy investment programs. It is found that without any load on left or right supplying arm one of two less loaded phases of traction transformer begins generating specific modes in the supplying three-phase line. Thus, modes of mobile substation cause leakage in one of the phases of the supply line of traction transformers of active-capacitive current, and as a result generating energy in the main power line of 154 kV, which is fixed and calculated by electricity meters. For these three phase mode supply network is necessary to use 1st algorithm, i.e. taking into account the amount of electricity as the energy in all phases. For effective application of reactive power compensation devices in the AC traction power supply systems it is proposed to develop regulatory documentation on necessity of application and the order of choice of parameters and placement of compensation systems taking into account operation mode of power systems and the use of software systems with imitation of instantaneous interrelated schemes of transport loads.

energy security, railway transport, the process of transportation, networks of power systems, efficiency of modes, mobile traction substations

1. Energy Strategy of Railways for the period up to 2015 and for the future by 2020. Approved by state administration of Railway Transport of Ukraine on November 26, 2013, 104 p. (in Ukr.)

2. Kornienko V. V., Kotel’nikov A. V., Domanskij V. T. Elektrifikatsiya zheleznyh dorog. Mirovye tendencii i perspektivy (Аnaliticheskiy obzor) [Electrification of railways. Global trends and perspectives (Analytical Review)]. Kiyev, Transport of Ukraine Publ., 2004, 196 p.

3. Markvardt K. G. Elektrosnabzheniye elektrifitsirovannykh zheleznykh dorog [Power supply of electrified railways]. Moscow, Transport Publ., 1982. 528 p.

4. Rene Pelis’e. Jenergeticheskie sistemy [Energy Systems]. Moscow, Higher School Publ., 1982, 568 p.

5. Domanskiy I. V. Electrification of railways — source of energy efficiency of the transport. Zalіznichniy transport Ukraїni [Railway Transport of Ukraine]. 2014, no. 1, pp. 19 – 24, 31 – 33.

6. Domanskiy I. V. Sistemniy analіz zovnіshn’ogo elektropostachannya tyagovikh pіdstantsіy zalіznits’ [System analysis of external power supply traction substations of railways]. Elektrotekhnіka і elektromekhanіka [Electrical engineering and electromechanics]. 2013, no. 3, pp. 54 – 63.

7. Domanskiy I. V. Prospects of development schemes and technical solutions to external power railway traction substations. Bulletin of NTU “KhPІ”, Series: Mathematical modeling in engineering and technology, 2013, 5 (979), pp. 54 – 65.

8. Rules ordering system Traction Power railways of Ukraine. Number IS-0009: approved. Order Railways year 24.12.2004., no. 1010CH. Ministry of Transport and Communications of Ukraine. Kiyev, 2005, 80 p., (in Ukr.)

9. Shidlovskij A. K., Kuznecov V. G., Nikolaenko V. G. Optimizatsiya nesimmetrichnykh rezhimov sistem elektrosnabzheniya [Optimization of asymmetrical modes of power supply systems]. Kiyev, Naukova Dumka Publ., 1987, 174 p.

10. Zakarjukin V. P., Krjukov A. V. Slozhnonesimmetrichnye rezhimy elektricheskikh sistem [Complex-asymmetrical modes of electrical systems]. Irkutsk, Irkutsk University Publ., 2005, 273 p.

11. Zhelezko Yu. S. Poteri elektroenergii. Reaktivnaya moshchnost’. Kachestvo elektroenergii [Loss of electricity. Reactive power. Power quality]. Moscow, ENAS Publ., 2009, 456 p.

12. Borodulin B. M., German L. A., Nikolaev G. A. Kondensatornye ustanovki elektrifitsirovannykh zheleznykh dorog [Capacitor units of electrified railways]. Moscow, Transport Publ., 1983, 183 p.

13. German L. A., Goncharenko V. P. Sovremennaya skhema prodol’noy emkostnoy kompensatsii v sisteme tyagovogo elektrosnabzheniya [Modern longitudinal capacitive compensation scheme in the traction power supply]. Vestnik RGUPS, 2013, no. 2, pp. 12 – 17.

14. Domanskiy I. V. Rezhimy raboty sistemy tyagovogo elektrosnabzheniya peremennogo toka s ustroystvami kompensatsii reaktivnoy moshchnosti [Modes of operation of the system of traction power AC using compensation devices reactive power]. Elektrotekhnіka і elektromekhanіka [Electrical engineering and electromechanics], 2015, no. 3, pp. 59 – 66.

15. Domanskiy I. V. Razvitiye metodov rascheta sistem tyagovogo elektrosnabzheniya i pitayushchikh ikh energosistem [Development of methods of calculation of systems traction power supply and them of power supply systems]. Elektrotekhnіka і elektromekhanіka elektromekhanіka [Electrical engineering and electromechanics], 2015, no. 4, pp. 62 – 68.