Efficiency of adjustable few-stage filter compensating installations in AC traction network

The paper gives comparative characteristic of a continuously adjustable and stepwise adjustable (switchable) filter-compensating installations (FCI) in the traction network of AC railways. Technical and economic calculations were carried out to increase throughput and reduce electric power losses. Effectiveness of switchable FCI is substantiated, taking into account features of traction.

Feasibility of using regulated FCIs at the traction network at the partitioning station is mainly determined by the need to increase the railway capacity by increasing the voltage on electric locomotive current collector, as well as due to the reduction of electric power losses in the traction network and in the external power supply system.

Efficiency of increasing the carrying capacity of the voltage in the traction network is determined by the maximum power of the FCI, and if these powers in the continuously adjustable, stepwise adjustable and unregulated units are equal, then the effect in increasing the carrying capacity will be the same. The effectiveness of reducing power losses in the traction network when using FCI installation at a partition station is generally limited, firstly, by the fact that electric locomotive is distributed throughout the entire inter-substation zone and, secondly, electric locomotive current is distributed between the partitioning post and the traction substations, and therefore FCI can compensate for only part of the electric locomotive current. This explains the limited possibilities in reducing power losses in the traction network of continuously adjustable FCI.

As a rule, in most cases, according to the operating experience of domestic traction power supply, the nominal power of FCI at the partitioning station is 3–5 Mvar. In the future, as the traction load increases, its capacity will increase to 7–10 Mvar. With an increase in the power of FCI over 10 Mvar, one should consider a distributed system of FCI in the inter-substation zone.

It is shown that the experience of regulated FCIs in the traction network of domestic railways indicates the need to develop a standard version of an economically adjustable unit, and the development can be based on the option of switchable FCI presented in the article.

filter compensating installation, switchable installation, technical and economic calculations, capacity, power losses

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

2. GOST 32895–2014. Electrification and electricity supply of railways. Terms and Definitions. Moscow, Standartinform Publ., 2014, 30 p. (in Russ.).

3. German L. A., Serebryakov A. S. Reguliruemye ustanovki emkostnoy kompensatsii v sistemakh tyagovogo elektrosnabzheniya zheleznykh dorog. Ucheb. posobie [Adjustable capacitive compensation settings in railway power supply systems. Reference book]. Moscow, FGBOU “Uchebno-metodicheskiy tsentr po obrazovaniyu na zheleznodorozhnom transporte” [Federal State Budgetary Educational Institution “Educational and Methodical Center for Education on Railway Transport”] Publ., 2015, 316 p.

4. Instructions on the selection of parameters and locations for installation of longitudinal and transverse capacitive compensation in AC traction power supply systems: Technical Designation no. P-04/11 dated November 28, 2011. Approved by the Electrification and Power Supply Directorate of the Central Infrastructure Directorate, an branch of the JSC “Russian Railways”. Moscow, JSC “RZD” Publ., 2012, 15 p. (in Russ.).

5. STO RZhD 07.022.2–2015. Railway AC traction power supply system. Methods for choosing the locations and power of devices for longitudinal and transverse compensation of reactive power. Moscow, JSC “RZD” Publ., 2015, 23 p. (in Russ.).

6. On approval of expenditure rates and estimated levels of costs for economic tasks. Order no. 675r of the Senior Vice President of the Russian Railways V. V. Mikhaylov, dated April 7, 2017 (in Russ.).

7. German L. A. Umen'shenie poter' energii batareyami poperechnoemkostnoy kompensatsii, raspolozhennymi v tyagovoy seti [Reduction of energy losses by the batteries of cross-capacitive compensation located in the traction network]. Trudy MIIT. Vyp. 302. Voprosy energosnabzheniya elektricheskikh zheleznykh dorog [Proceedings of MIIT. Iss. 302. Power supply issues for electric railways]. Moscow, Transport Publ., 1969, pp. 69–82.

8. German L. A., Serebryakov A. S., Dulepov D. E. Fil'trokompensiruyushchie ustanovki v sistemakh tyagovogo elektrosnabzheniya zheleznykh dorog [Filter compensating installations in systems of traction power supply of railways]. Knyaginino, NGIEU Publ., 2017, 402 p.

9. Gapanovich V. A. Rezul'taty vnedreniya nauchnotekhnicheskikh rabot i zadachi na 2017 god [Results of the implementation of scientific and technical work and tasks for 2017]. Zheleznodorozhnyy transport, 2017, no. 2, pp. 24–28.

10. Serebryakov A. S., German L. A., Dulepov D. E. et al. Switchable singlephase transverse capacitive compensation device in an AC traction network. Utility patent no. 2475912 FIPS (Rospatent), dated March 9, 2011, pabl. February 20, 2013. Bul. no. 5.

11. Vasil'ev S. N., Goncharenko V. P., Latmanizov M. V. et al. Device for automatic regulation of reactive power compensation. Utility patent no. 2459335 FIPS (Rospatent), dated April 22, 2011, pabl. August 20, 2012, Bul. no. 23.

12. German L. A., Serebryakov A. S., Goncharenko V. P. et al. Installation step transverse capacitive compensation. Utility patent no. 2656368 FIPS (Rospatent), dated July 1, 2016, pabl. June 5, 2018, Bul. no. 16.