SU1030909A1 - Power supply system - Google Patents

Description

2. The system of claim 1, wherein the windings of the power source are connected between the primary windings of the transformers.

3. System pop. g / differs with the fact that the secondary windings of transformers are connected in series and connected to the first distribution busbars.

. A system according to claim 3, in connection with the fact that the transformers are made of three-winding and the tertiary windings are connected in series and connected to the second distribution busbars. .

5. The system according to claim 2, characterized in that it is equipped with an additional transformer and two three-phase conductors, the primary winding of the additional transformer is connected in parallel to the windings of the power supply through three-phase conductors, and the secondary winding is connected to distribution buses.

6. The system according to claim 2, wherein the source windings are made split, the primary windings of the transformer are also made split and connected

to the corresponding split winding of the source.

7. The system according to claim 2, characterized in that it is provided with an additional power source, the transformers are made of three windings, and the windings of the additional power source are connected to the tertiary windings of the transformers.

8. The system according to claim 2, with the fact that in order to organize the melting of ice on the wires of overhead power lines, it is equipped with switching devices, one of which is intended to short the source pins, the latter is installed on the connection side of the primary winding of the transformer, a second commutation apparatus is installed between the source and the transformer, and a third commutation apparatus is connected to the output of the second switching device connected to the transformer the one of which is connected to the outgoing line.

9. The system according to claim 1, characterized by the fact that the secondary windings

transformers are connected to different distribution buses.

10. The system of claim 9, wherein the transmission lines are connected to different distribution buses.

.eleven. A system according to claim 10, characterized in that it is provided with an additional transformer for connecting consumers, the terminals of the primary winding of which are connected to different transmission lines.

12. The system for l. 10, that is, it is equipped with two additional transformers and additional buses, the primary windings of which are connected to different power lines, and the secondary windings of which are connected by one pins, and the second pins are connected

to the relevant additional tires.

13. The system according to claim 12, that the transmission lines are made with two wires, each wire is connected to two phases of the windings of the main and additional transformers, and the third phases are two main and two additional transformers are pairwise connected between by themselves, and the secondary windings of additional transformers are connected by one outputs to busbars, and their second conclusions are phasewise connected to each other.

one . The system of claim 10, wherein c. in that it is provided with a longitudinal compensation battery, the latter being connected in series to the power line.

15. The system according to claim 12, distinguished by the fact that the phases of one

of the distribution buses are connected by meiod.

16. The system of claim 1, wherein it is provided with an additional power source, the primary and secondary sources being connected to the terminals of the low voltage windings of the respective main transformers, and the second terminals of the sources are interconnected by a jumper.

17. The system according to claim 16, wherein the main transformers are made with different groups of winding connections,

18. The system according to claim 16, characterized in that it is provided with short-circuiting switching

device connected to the jumper.

19. The system of claim 18, wherein it is consistent with the impedance in series with the shorting switching device.

one

The invention relates to power engineering and can be used to increase the efficiency of power supply systems.

A source known to generate electricity in a power plant 1.

The disadvantage of this source is rather large short-circuit currents both at its terminals and inside the source, causing significant electrodynamic and thermal effects. Electricity sources of electricity are performed taking into account the possible actions of short-circuit currents, which leads to a sharp increase in Vix value. However, the reliability of existing powerful sources is still insufficient. According to ORGRES, each third generator with a capacity of 60 MW and above is damaged annually. At generators with a capacity of 300 MW and above. each year is damaged every second. In this case, a significant proportion of damage is caused or accompanied by short circuits. For hydrogenerators, according to ORGRES, such a share is E.

Closest to the technical nature of the invention is a power supply system comprising a source and two transformers. powered by the said source C2.

In order to increase the reliability of system operation, the connection between the stator winding of the generator and the low voltage winding of the block Transformer is performed by a closed box-shaped busbar. However, this solution does not provide a sufficient increase in the reliability of operation of the unit due to possible internal damage in the generator. Each internal short circuit of the generator leads to prolonged downtime of the entire system.

2 power supply for the time of repair work. Sometimes the duration of an emergency generator is simply hundreds of hours. The aim of the invention is to increase the efficiency of the system by significantly limiting the calculated short-circuit current values.

The specified goal is reached

30 by the fact that in the power supply system containing the power source, to the windings of which two main transformers are connected, the outgoing power lines

35 and distribution busbars, the primary windings of transformers are connected in series with the windings of the power source.

Winding power source MO40

can be connected between the primary windings of transformers.

The secondary windings of the transformer can be connected sequentially and connected to the first distribution buses.

Transformers can be made of three-winding and tertiary windings are connected in series and

50 are connected to the second distribution busbars.

In addition, an additional transformer can be installed, the primary winding of which is connected in parallel to the source windings via three-phase current conductors, and the secondary winding is connected to distribution buses.

The source can be made with split windings, the primary windings of transformers are split and connected to the corresponding split source winding.

The power supply system can be equipped with an additional source, power, transformers are made of three windings and the windings of the additional power source are connected to the tertiary windings of transformers.

In order to organize ice melting, a switching device is installed on the wires of overhead power lines on one side of the source winding, shorting the source leads between them, and in the circuit between the connection point of the mentioned KO mutation apparatus and the primary winding of one of the transformers connected on the same side source windings, a second switching device is installed in series, and the primary winding of one of the transformers is connected via the third switching device gadfly overhead transmission line. Improving the efficiency of the system is achieved by the fact that the secondary windings of the transformer are connected to different distribution busbars. Power lines can be connected to different distribution buses. For this purpose, consumers of electric energy are connected via an additional transformer, the terminals of the primary winding of which are connected to various power lines. For the same purpose, power is taken off via two additional transformers, the primary windings of which are connected to different transmission lines, and the secondary windings of which are connected by one pins in series with each other, and by other pins are connected to different sections of additional buses. The power lines are wired two-wire, each wire / which is connected to the corresponding phase of the high-voltage windings of transformers on one and the other side of the power line, and the third phases of the high-voltage windings of the above

transformers are interconnected and the secondary windings of additional transformers are connected to the busbars by one of the terminals, and their second terminals are phase-wise interconnected.

A longitudinal compensation battery can be switched on in series with the power line wires.

One of the bus sections may be shorted.

In addition, in order to significantly limit the calculated magnitudes of short-circuit currents, the system contains another block transformer and a source of electricity, the first I turn of which winding is connected to the low voltage winding of another block transformer, the high voltage winding of which voltages, jumpers are installed between the other terminals of the same phases of the stator windings of both sources. In this case, the connection groups of both block transformers may be different. A short-circuit switching device can be connected to the jumper connecting the other leads of the stator windings of both sources. Additionally, impedance can be switched on in series with the shorting switching device. FIG. 1 shows a power supply system comprising a source and two transformers; in Fig. 2, the source-two three-winding transformer system, the tertiary windings of which are used to power the system's own needs; in fig. 3 - source system - two double-winding transformers with an additional transformer for auxiliary power supply; in fig. - source system of two transformers with split windings; in fig. 5 - system two sources - two transformers; in fig. 6 - source system - two transformers, allowing to organize the melting of ice on the wires of overhead power lines; in fig. 7 system source - two transformers; in fig. 8 and 13 - source system - two transformers - two lines; in fig. 9 and 1 - the option of taking power from a double-circuit overhead line using a single transformer; in fig. 10 and 15 variant of power take-off from two-phase overhead lines with the help of two transformers; in fig. 11 shows an embodiment of a double-circuit transmission line in the form of a four-wire line; in fig. 12 and 16 - double-chain line with longitudinal compensation; in fig. 17 a power supply system comprising two sources and two transformers; in fig. 18 - two sources system - two transformers with a shorting switching device connected to the other terminals of the stator windings of the generators; in fig. 19- system two sources - two transformers with complex resistance in the circuit of the shorting switching device.

The power supply system (Fig. 1) contains a power source 1, the leads of the stator winding of which are connected to the low voltage winding of the block main transformer 2, whose high voltage winding is connected to the high voltage distribution buses 3 through the high voltage winding of the second main transformer, winding the high voltage of which is connected on the other side of the stator winding of the power source 1. The high voltage winding of the second main transformer is connected to the high voltage buses 3.

In the normal operation of the system, the linear currents of the low voltage windings of transformer 2 and transformer C are equal to the current of the stator winding of power supply 1 and are magnetizing currents for both transformers. The currents of the high voltage windings of transformers 2 and t are also equal and are the demagnetizing currents dp of both transformers. The difference between the reduced currents of both transformer windings is a no-load current.

The voltage of the stator winding of source 1 is balanced by the sum of the voltage on the low voltage windings of transformers 2 and. The distribution of voltages between the block transformer 2 and the additional transformer C is forcibly set by the parameters of their idling characteristics. The vectorial sum of the voltage of the high voltage windings of transformers 2 and is applied to high voltage buses.

 In the proposed power supply system, there are no overcurrents, both when there is an interphase closure inside the stator winding of source 1, and when the insulation of the jumpers connecting the source leads to the windings of transformers 2 and + is damaged.

0 There are no overcurrents also for any kind of damage to the insulation of the block transformer 2, the low voltage winding of the additional transformer 4 and the jumper connecting the high voltage winding of the transformers 2 and. In the above mentioned emergency conditions, there is only a redistribution of voltages on the windings of transformers 2 and 4, and the voltage of source 1, busbars 3 and high voltage supplied by source 1 to the power system will be unchanged.

Assume that a three-phase short circuit has occurred at the terminals of the stator winding of source 1 connected to transformer 2. In this case, the entire voltage of source 1 will be applied to the low voltage winding of the transformer. With the same transformation ratios of transformers 2 and +, the value of operating currents in all elements of the block will not change, and transformer 2

5 will be connected in series to the load current circuit with its dissipation resistance. Since the high voltage winding current of the transformer 2 tie has changed, the low voltage winding current of this transformer has not changed either. Consequently, only the no-load current of the transformer k will flow through the short circuit point,

five

When a three-phase circuit at the terminals of the stator winding of the source 1 connected to the low voltage winding of the transformer k, the processes are similar to those described with the

0 the difference that the power of source 1 is supplied to the network through transformer 2.

 high short-circuit currents to be checked

5, the mechanical strength of the windings of both source 1 and transformers 2 and 4 occur during short circuits on high voltage buses 3. However, it must be borne in mind that this current is limited by both the resistance of source 1 and the resistance of the windings of transformers 2 and. In a standard power supply system, for internal damages at the source, the sum of the currents from the source itself as well as from the power system (through the block transformer) flows through the damage site. Calculations show that the short-circuit currents in the proposed power supply system are about 3-5 times less than in standard systems. After an emergency shutdown of the standard system, overcurrents from the source flow through the damage site until the AGP system is able to completely extinguish the magnetic field of the generator using the AGP system. Thus, the proposed power supply system allows not only to limit the calculated emergency currents, but also significantly reduce the duration of their flow, which is important from the point of view of the thermal stability of the system equipment. The advantages of the proposed variant of the block should include a substantial constructive simplification of the jumpers connecting the elements of the system. FIG. 2 presents a variant of the topic in which the issue of Gittani's own needs of the power plant is resolved. Unlike the considered system (Fig. 1), in this embodiment, the main transformers 2 and 4 have tertiary windings, one of which is connected in a star. The secondary and tertiary windings are connected in series with each other, and the tertiary windings are connected to the second distribution busbar 5. From the examples considered above, it is clear that the sum of the voltage of the tertiary windings of transformers 2 and 4, both in normal conditions and for all damages inside The block is unchanged, which determines the effective functioning of the mechanisms of their own needs. A power supply option for the own needs of the power plant, which allows to simplify the design of the 2 k transformers, is shown in FIG. 3. In contrast, V8 of the variant shown in FIG. 1, this version of the system has an additional transformer 6, the primary winding of which is connected parallel to the stator winding of source 1, and the secondary winding is connected to the second distribution busbars 5. The primary winding of transformer 6 is connected to source 1 using two three-phase conductors 7 and 8. It is important that the conductors 7 and 8 were made so that short circuits between them are eliminated. The only dangerous case in the circuit (Fig. 3) may be the simultaneous breakdown or overlapping of two terminals of the primary winding of the second additional transformer 6, which is unlikely to occur. Power generators are often made with split stator windings. An embodiment of a system comprising a generator with split windings is shown in FIG. Transformers 2 and t have split low voltage windings, each of the split windings of transformers 2 and t being connected to a corresponding split generator stator winding 1. In standard systems, short circuits between Split stator windings are accompanied by significant overcurrents. In the proposed embodiment, each of the split windings of the generator 1 is not connected to the corresponding split wires (Transformers 2 and 4 may not be electrically connected to each other. As a result, even insulation damage between the split windings of a single stator generator phase. Torus 1 does not result to the appearance of overcurrents. If such an electrical connection through the split windings of transformers 2 and 4 is provided, then the dissipation of the split windings of transformers 2 is possible and can limit many times This is caused by a very small amount of voltage under which the emergency currents flow.In Fig. 5, a system is presented in which transformers 2 have tertiary windings, between the terminals of which the stator winding of an additional source 9 9103 of power is turned on. All the advantages of the new variants of the power supply system relate to the cases of operation of powerful synchronous machines in the synchronous mode. th compensator. The developed schematic diagram of the power supply system makes it possible to efficiently use the equipment of the system also with the aim of organizing the melting of ice on the wires of overhead lines leaving the switchgear of the power plant. One of the variants of the circuit is shown in FIG. 6, A switching device 10 is installed on the side of the stator winding of the source I connected to the main transformer 2, shorting the output of the stator winding of the source} .8 circuit between the connection point of the switching device 10 and the winding the voltage of the block transformer 2 is installed the second switching device 11. To the low voltage winding of the transformer 2 through the three switching device 12 are connected the wires of the aerial outgoing transmission line ( A) 13. Except for the switching device 10, to disable the unit 11 and turn the unit 12, then the overhead wire current 13 will flow providing effective control of gololednoizmorozevymi the formations. Even with short circuits x on OHL 13, the magnitude of the emergency current will not exceed the rated current of the heat. Similarly to this circuit (FIG. 6), a circuit can be assembled in which the wires of an overhead line 13 are connected to the low voltage winding of an additional transformer. With an appropriate choice of the nominal voltage of the low voltage windings of transformers 2 and, it is possible to repair one of the transformers and ensure the normal operation of the generator in the unit with the remaining transformer 4 or 2.. The power supply system (Fig. 7) contains a source 1, the stator winding of which on one side is connected to the low voltage winding of the main transformer 2, the high voltage winding of which is connected to the high voltage distribution buses 3. In addition, the system has a second main transformer, the low voltage winding of which is connected to the other side of the stator winding of source 1, and the high voltage winding is connected to the second high voltage distribution busbars 5. In normal operation, the voltage of the stator winding of the source 1 is distributed between windings of low voltage transformers 2i. The magnitude of the voltages applied to transformers 2 and depends on the idling characteristics of these transformers. The voltage on the distribution buses j and 5 of high voltage is determined by the transformation ratio of transformers 2 and 4. In order to maintain the voltage on tires 3 and i within acceptable limits, it is advisable to maintain the required power ratio of the loads connected to the tires 3 and b. In the event of a short circuit at any point in the system (Fig. 7), the short circuit currents differ little from the load currents. In this case, there is a forcing (increase) of voltage on the non-recurring elements of the system. So, for example, at damage-. A transformer 2 or short circuit on the tires 3 increases. The voltage across the transformer k and the tires i). In order to more clearly maintain the normal voltage on tires 3 and 5, additional power sources can be connected to them, which can take the difference in the power of the loads connected to the Bus and the power allocated to the power source (Fig, U). On these buses, In this case, the system connection scheme may be useful also from the point of view of increasing the stability of the electrical network. The device (FIG. 8) additionally has two lines T and 15 which are connected respectively to buses 3 and b and to distribution buses 16 and 17 of receiving substations. Presented in FIG. 8 and 13 system source 1 - two transformers 2 and 4 - two lines 1 and 1i have the same properties as the device shown in Fig.7. In this case, the currents of the short-circuit are limited. also in case of damage on lines Tt and 15, which makes it possible to significantly simplify the switching equipment.

In case of emergency or planned decommissioning of equipment components of one half of the system, the second can function normally.

Depending on the specific implementation features of the device, the normal operation of half of the system can be ensured both at elevated and at nominal voltages (for example, by reducing the excitation current of source 1).

A possible option for taking power from the system (Fig. 8) is shown in Fig. 9.

The device (Fig. 9 and 1 ") for taking power from a system identical to that of Figs. 8 and 18 has an additional transformer 6, some of the primary windings of which are connected via buses 16 to the power line k, and the other terminals of the primary winding of the transformer 10 on the opposite side, the windings are connected via bus 17 to another power transmission line If.

The secondary winding of the transformer 6 is connected to the tires 18, from which the consumer is powered.

The described power take-off scheme ensures a constant voltage on load tires 18 when any element of the power supply system is damaged, source 1– two transformers 2 and 4 - two lines 1 and 15, and also limits the amount of current at the site of damage to the value of the no-load current of one of the transformers 2 or 4, with Increased (up to two times) nominal voltage.

If we select transformers 2, D and 6 with induction reserve, ensuring their long-term operation under double operating voltage, and also correspondingly increase the isolation of power lines, shutting down one of the semi-chains will not lead to a decrease in transmitted power. The cost of 1U and 15 lines of transmission can be significantly reduced by reducing the size between the wires, as well as the rejection of the installation of the ground wire. This is due to the self-extinguishing of the arc when any of the air gaps overlap due to the small short-circuit current. All the equipment of the system (Fig. U) can practically be calculated without taking into account accidental impacts only under normal operating conditions.

It is also possible to carry out a power take-off with the help of two transformers (Fig. 10 and 15).

In this variant for power take-off, two additional transformers 6 and 19 are installed, the primary windings of which are connected respectively via buses 16 and 17 to pink ones

line 1t and 15 transmissions. Here, the secondary windings of the transformers 6 and 19 are connected in series and connected on the other side of the windings to different sections of buses 18 and 20.

The features of the operation of the proposed device are identical to the device shown in FIG. 8 and 13.

In particular, a power takeoff from tires 18 and 20 can be arranged.

in the same way as the power takeoff from the tires 3 and 5 of the system (FIG. 9).

FIG. 11 shows an embodiment of a double-circuit transmission line in the form of a four-wire

lines. In principle, the connection scheme is identical to that of the system shown in FIG. 9. At the same time, power lines 14 and 15 are two-wire, each wire of which is connected via buses 3, 16 and 5.17 to the corresponding phase of the high-voltage windings of transformers 2 and 4, b and 19 on one side and the other of said lines 1 and 15

power transmission, and the third phases of the high-voltage windings of the above-mentioned transformers 2 and 4, 6 and 19 are interconnected.

Presented version of the system

requires significantly lower capital costs for the construction of the line due to the reduction in the number of wires. Since the load currents of the respective phases of lines 1 and 15 are out of phase due to the particular design of the circuit, the connection of the third phases of the high voltage windings of transformers 2 and A, as well as 6 and 19, ensures normal circulation of the currents and almost symmetrical voltage on the buses 18 and 20 loads.

FIG. 12 and 16 present the proposed system with a longitudinal compensation of inductive resistance. The R-Diagram of the system connection is identical to the diagram in Fig. 8 and 13. Additionally, the capacitor banks 21 and 22 are included in the dissection of lines 1 and 15. The use of longitudinal compensation of the inductive resistance of the system due to the specificity of the system modes significantly reduces the calculated effects on the capacitor batteries 21 and 22. This is explained by the absence of an overcurrent during a short circuit of any kind on lines I and 15, to which the batteries are so sensitive in standard network diagrams. Consequently, instead of special capacitors, batteries 21 and 22 can be equipped with conventional capacitors designed for shunt capacitor batteries, which significantly reduces the cost of building capacitor batteries 21 and 22 and increases the efficiency of the entire system. Shown in FIG. 17, the system contains the source I, the stator winding of which on one side is connected to the low voltage winding of the transformer 2, and its high voltage winding is connected to the high voltage buses. The stator winding of the other source 23 on the one hand is connected to the low voltage winding of the other main transformer t, and its high voltage winding is connected to other high voltage buses 5. Jumpers 2k are installed between the other terminals of the phases of the stator windings of the same name and the points 1 and 23. This scheme of connecting the elements of the power supply system (Fig. 17) allows one to substantially limit the calculated short-circuit currents and to form a voltage at the time of a short-circuit on the intact elements of the electrical system, which increases its dynamic stability. For example, with a three-phase short circuit. On high voltage tires 3, the total emf of sources 1 and 23 is applied to transformer k and acts oppositely to the emf of a power system connected to high voltage buses 5. Thus, the resulting emf does not exceed the nominal value, but the current component is k.3., Which flows to the place of damage from the block under consideration. y is limited by the total reactance of two transformers 2 and A, two generators 1 and 23, and the equivalent reactance of a system connected to bus 5-. Even when the system is operating on tires of infinite power, the calculated value of the current k.z is halved. If the system reacts; connected to the tires 5, is different from zero, there is an additional current limit short-circuit. In this case, the voltage on the tires 5 becomes higher than the nominal by the amount of current produced by the cs. on the resistance of the system. If the coupling groups of transformers 2 and k are the same, then in normal mode the voltage vectors on buses 3 and 5 must be out of phase. In order to have voltage vectors on buses 3 and b in phase, it is advisable to change the connection group of one of the block transformers to six-word units, which, as a rule, does not cause difficulties, since all six voltage windings are usually displayed on the cover of the block transformer. It is also advisable to change to six standard units the group of the auxiliary transformer connection of the system connected to that block transformer, the group of connection + 1 of which is changed. This is useful for the condition of transferring the unit's own needs to the standby transformer of the station's own needs without redeeming the consumers' needs. FIG. 18 shows a variant of the power supply system with a shorting switching device 25 connected to the jumper 2k. The connection circuit of the elements is completely identical to the circuit in FIG. 17 The presence of a switching device 25 provides greater flexibility of the circuit due to the possibility of independent operation of the blocks consisting of source 1 and transformer 2, as well as source 23 and transformer 5. Such work may be required, for example, when putting out to repair some circuit element. In addition, when the position of the switching device 25 is on, it is possible to synchronize each of the electric power sources of the circuit with the system independently.

15

The circuit in FIG. The LE is identical to the circuit in FIG. 18. Additionally, an impedance 26 is sequentially included in the circuit of the shorting device 25, for example, a reactor or an active resistor can be installed. Its purpose is to reduce the constant time of the emergency circuit, as well as a slight decrease in the voltage forcing on the intact elements of the electrical network during a short circuit.

With this resistance 26, the system can operate in normal mode with the switching device 25 turned on, since with equal loading of both sources 1 and 23, the voltage at the connection point

3090916

resistance 2b is zero. In the event of a short circuit in the network, the presence of resistance 26 significantly reduces the levels of short-circuit currents.

The proposed schemes (Figs. 17-19) of the connection of the elements of the system are easily realized not only at new stations, but also at existing ones, while 10 non-standard equipment is not required to carry out the scheme.

The proposed schemes for the implementation of the power supply system significantly reduce the cost of their manufacture, increase the reliability of operation due to a significant limitation of short circuit currents.

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Claims (19)

1. ELECTRICAL SUPPLY SYSTEM, containing a power source, to the windings of which are connected two main transformers, outgoing power lines and distribution buses, characterized in that, in order to limit short-circuit currents, the primary windings of the transformers are connected in series with the windings of the power source. / Figure 1 S and „..1030909 2. The system by π. 1, characterized in that the windings of the power source are connected between the primary windings of the transformers. 3. Pop system. 2, characterized in that the secondary windings of the transformers are connected in series and connected to the first distribution buses. 4. The system according to claim 3, distinguished by the fact that the transformers are tri-winding and the tertiary windings are connected in series and connected to the second distribution buses. . 5. Pop system. 2, characterized in that it is equipped with an additional transformer and two three-phase current conductors, with the primary winding of the additional transformer connected in parallel to the power source windings through three-phase current conductors, and the secondary winding is connected to the distribution buses. 6. System pop. 2, characterized in that the windings of the source are split, the primary windings of the transformer are also split and connected to the corresponding split winding of the source. 7. The system according to claim 2, characterized in that it is equipped with an additional power source, the transformers are tri-winding and the windings of the additional power source are connected to the tertiary windings of the transformers. 8. The system of claim 2, with the fact that for the purpose of organizing. reduction of ice melting on the wires of overhead power lines, it is equipped with switching devices, one of which is intended for shorting the source leads,. the latter being installed on the side of the connection of the primary winding of the transformer, a second switching device is installed between the source and the transformer, and the output of the third switching device is connected to the output of the second switching device connected to the transformer, the second output of which is connected to the outgoing line. 9. Pop system, ^ characterized in that the secondary windings of the transformers are connected to different distribution buses. 10. The system according to claim 9, with η and the fact that the power lines are connected to various distribution buses. , 11. The system of pop. 10, characterized in that it is equipped with an additional transformer for connecting consumers, the terminals of the primary winding of which are connected to various power lines. 12. The system according to claim 10, characterized in that it is equipped with two additional transformers and additional buses, the primary windings of which are connected to various power lines, and the secondary windings of which are connected by one terminal and connected to the corresponding terminals additional tires. 13. The system according to claim 12, with the proviso that the power lines are made of two wires, each wire is connected to two phases of the windings of the main and additional transformers, and the third phase. 'Two main and two additional transformers are interconnected in pairs, and the secondary windings of additional transformers are connected to busbars with one terminal, and their second terminals are phase-wise interconnected. 14. Pop system. 10, distinguished by the fact that it is equipped with a longitudinal compensation battery, the latter being connected in series to the power line. 15. Pop system. 12, distinguished by the fact that the phases of one of the distribution buses are interconnected. 16. The system of claim. ^ Characterized in that it is equipped with an additional power source, the main and additional sources being connected with one terminal to the terminals of the low voltage windings of the respective main transformers, and the second terminal of the sources are connected by a jumper. 17. The system according to π. ^. characterized in that the main transformers are made with different groups of windings. 18. The system of pop. 16, characterized in that it is equipped with a short-circuit switching device connected to a jumper. 19. The system according to p. 18. Characterized in that the complex resistance is connected in series with the short-circuit switching device.