CS212488B1 - Connection of the synchronization circuit for the switch rooms with three systems of bus bars - Google Patents

Description

It is an object of the present invention to provide a synchronization circuit for a switchgear with three busbar systems comprising at least four switches and three switches which solve the selection of the necessary synchronization voltages of the three branch bus systems in a simple and completely stereotyped manner. in the control room without direct connection to the state of the respective busbar disconnectors in the switch room.

Up to now, synchronization circuits have been used for substations with three busbar systems requiring the application of both cumbersome synchronization voltages from the metering cabinet in the substation and where the selection of synchronization voltages is made by transferring these voltages through signal switches of the respective bus disconnectors. via signaling switches of disconnectors and switches of all longitudinal and transverse couplings of the switchgear busbars.

The disadvantage of these wiring is that the cable lengths of the required cables with large cross-sections reach several tens of kilometers in large substations, because they cannot be connected to common cables with control and signal circuits. Another disadvantage is the fact that the synchronization voltage has to be transferred through many tens of terminals and contacts, so that it has large clearances and it is often necessary to use voltage boost transformers. Another significant disadvantage is the large number of signal cylinder contacts required for disconnectors, which must be frequently multiplied by a large number of relays. A disadvantage is also the danger of revisions of cabinets and devices in the switchgear due to the ever-present synchronization voltage in all branches, which cannot be switched off, which leads to short circuits and damage to the distribution system in case of improper maintenance procedure.

The above-mentioned disadvantages are eliminated by the connection of the synchronization circuit for the three busbar substations according to the invention, consisting of at least four switches and three switches for each branch of the substation, according to the invention, characterized in that the first wiring input is connected to the first switch input; firstly, the first input of the first switch, secondly, the first input of the second switch, and secondly, the first input of the third switch, the output of which is connected to the third output of the wiring. The fourth input of the wiring is connected to the second input of the second switch and to the input of the fourth switch, the output of which is connected to the second ring synchronization busbar.

The second orbital synchronization busbar is connected both to the output of the second switch and to the output of the third switch, the input of which is connected both to the third input of the wiring and to the second input of the second switch. The output of the second switch is coupled to the second wiring output, the first output of which is coupled to the output of the first switch.

The second input of the first switch is connected both to the input of the second switch and to the second input of the wiring. The output of the first switch is coupled to the first orbital synchronization busbar.

The advantage of connecting a synchronization circuit for substations with three busbar systems according to the invention is that it enables to connect the necessary synchronization voltages directly in the control room area from the protection and measurement fields where they are always introduced. As switching is done directly in the control room, the need for synchronization cables decreases to less than a tenth of the current needs and the distribution is not exposed to adverse weather conditions, the chassis is revised and maintained and also not threatened by external intervention during cabinet and instrument maintenance. Due to the considerably fewer terminals, contacts, and short cable lengths, no larger cable cross sections or voltage transformers are required. The wiring is simple and easy to modify and expand as the substation changes and expands.

An example of a synchronization circuit for substations with three busbar systems for one voltage circuit is shown in the attached diagram. It consists of at least four switches and three switches. The first wiring input 17 is connected to the first switch input 24, the first input 32 of the first switch 6, the first input 35 of the second switch 6, and the first input 38 of the third switch 6, whose output 40 is connected to the third output 23 connection. The fourth wiring input 20 is connected both to the second input 39 of the third switch 6 and to the input 30 of the fourth switch 8, whose output 31 is connected to the second ring synchronization busbar 8.

The second orbital synchronization busbar 8 is connected to the output 27 of the second switch 2 and to the output 24 of the third switch 6, the input 28 of which is connected to the third input 19 of the wiring and to the second input 36 of the second switch 6. connected to the second wiring output 22, the first output 21 of which is connected to the output 34 of the first switch 6. The second input 33 of the first switch 8 is connected both to the input 16 of the second switch 2 and to the second input 18 and the output 25 of the first switch 8 is connected to the first circular synchronization busbar 8.

The individual wiring elements can be characterized as follows:

The first, second, third and fourth switches 6, 7, 8 and 8 are either conventional electromagnetic relays or small contactors with make contacts and are used in each synchronized tap, wherein the first switch 8 may preferably be identical to the tap selector relay. However, contactless AC switches such as triacs can also be used. The first, second and third switches 6, 6 and 6 are also either electromagnetic relays or small contactors with changeover contacts, or contactless AC switches can also be used. The function of the synchronization circuit connection for substations with three busbar systems is as follows:

The first switch 6 is controlled so that it is closed only when a synchronized tap is selected and therefore can advantageously be identical to the tap selector relay. The second switch 2 is controlled so that it is closed only when the synchronized tap is selected and at the same time the disconnector of the first tap-bus system is switched on. Similarly, the third switch X is controlled so that it is closed only when the synchronized tap is selected and the second tap-bus system disconnector is closed at the same time. The fourth switch X is controlled so that it is closed only when the synchronized tap is selected and at the same time the disconnector of the third tap-bus system is closed.

The first switch X is controlled so that its first input 32 is connected to its output χχ only when the first on-load tap-changer is switched on and the on-load tap-switch is switched on independently of the on-load tap. In all other cases, the second input 33 of the first switch X is connected to its output χχ. Similarly, the second switch 6 is controlled so that its first input 35 is connected to its output 37 only when the disconnector of the second on-load busbar system is closed and the on-load switch is switched on at the same time. In all other cases, the second input 36 of the second switch X is connected to its output 37. The third switch 2 is controlled so that its first input 38 is connected to its output 40 only when the disconnector of the third on-load busbar is closed and the on-load switch is on. In all other cases, the second input 39 of the third switch 2 is closed with its output X0.

Thus, when the synchronization circuit for three busbar systems according to the invention is connected, the synchronization voltage is fed to the first round synchronization busbar 8 from its own branch voltage converters, connected to the control room and supplied to the first wiring input 17; the synchronization voltage is always supplied from the nearest tap connected to the same busbar system to which the synchronized tap is connected, in the case of the first busbar system from the second input 18 wiring via the second switch 2; switch X, in the case of a third busbar system from the fourth input 20, connected via the fourth switch χ.

For use in busbar coupling field synchronization, the wiring can be easily expanded by an additional seven switches, similar to those in the basic wiring. The fifth, sixth, seventh, eighth, ninth, tenth, and eleventh switches 110. 11. 12. χχ, 14. 15 and 16 are similar switches to the first, second, third, and fourth switches X, 2, χ and χ. They are only used in busbar coupler fields. The fifth switch 10 is closed only when the busbar coupling is selected and its first busbar disconnector is closed at the same time. Similarly, the sixth switch 11 is closed only when the busbar coupler is selected and its second busbar disconnector is closed at the same time.

The seventh switch 12 is closed only when the busbar coupling is selected and its third busbar disconnector is closed at the same time.

The eighth switch 13 is closed only when the busbar coupling is selected and at the same time its disconnector of the second busbar system is closed. The ninth switch 14 is closed only when the busbar coupling disconnectors of both the first and second busbar systems are closed and the busbar coupling switch is closed at the same time. Similarly, the tenth switch 15 is closed only when the busbar clutch disconnectors of the first and third busbar systems and the busbar clutch switch are closed at the same time. The eleventh switch 16 is closed only when the busbar clutch switch and both the second and third busbar disconnectors are closed.

When synchronizing in the busbar coupling, the first busbar synchronization voltage 8 is fed to the first busbar system connected to the first busbar system via the second input 18 via the first switch X and the fifth switch X0, the second busbar synchronization voltage being applied. again from the nearest branch, connecting to the second busbar system from the third input 19 wiring through the second switch 6 and the sixth switch χχ. On the second round busbar X, the synchronization voltage is applied to the third busbar system again from the nearest tap connected to the third busbar system from the fourth input 20 connected via the third switch 2 and the seventh switch 12; to the second busbar system from the third input 19 wiring through the second switch X and the eight switch XX ·

If the busbar coupler is connected, ie both busbar disconnectors and the on-load switch are closed, the ninth switch 14 is closed when the first and second busbar systems are closed, the tenth switch 15 is closed when the first and third busbar systems are closed and in the third busbar system, the eleventh switch 16 is closed. In these cases, the voltages on their closed busbar systems are always the same and are applied to one or the other of the roundabout synchronizing busbar 8 or 6 each from the nearest branch connected to one of the two busbar systems. On the other of the two orbital synchronization busbars, as before, the voltage of the remaining busbar system is reconnected, again from the nearest branch connected to this remaining system. This ensures synchronization in the busbar couplings in all operating states.

The connection will be used both for the reconstruction of existing power stations and for the construction of new power stations.

Claims (2)

Synchronous circuit connection for switchgear with three busbar systems, comprising at least four switches and three switches, characterized in that the first wiring input (17) is connected both to the input (24) of the first switch (1) and to the first input (17). 32) a first switch (5), both with a first input (35) of a second switch (6) and with a first input (38) of a third switch (7), whose output (40) is connected to a third wiring output (23), the fourth input (20) is connected to the second input (39) of the third switch (7) and to the input (30) of the fourth switch (4), the output (31) of which is connected to the second circular synchronization busbar (9) connected to the output (27) of the second switch (2) and to the output (24) of the third switch (3), whose input (28) is connected to the third input (19) of the wiring and second input (36) of the second switch (6), the output of which (37) is associated with the species wiring output (22) of which the first output (21) is connected to the output (34) of the first switch (5), the second input (33) of which is connected to the input (16) of the second switch (2) and to the second input (18), the output (25) of the first switch (1) being connected to the first orbital synchronization busbar (8). Connection according to Claim 1, characterized in that the first ring synchronization busbar (8) is connected both to the output (43) of the sixth switch (11) and to the output (41) of the fifth switch (10) whose input (42) is connected to the input (51) of the tenth switch (15), firstly to the first wiring output (21) and secondly to the input (49) of the ninth switch (14), the output (50) of which is connected to the second wiring output (22) the input (44) of the sixth switch (11), the input (47) of the eighth switch (13) and the input (53) of the eleventh switch (16), the output (54) of which is connected to the third output (24) , on the one hand with the output (52) of the tenth switch (15) and on the other hand with the input (45) of the seventh switch (12), whose output (46) is connected to the output (48) of the eighth switch (13) and (9).