CS240742B1 - Wiring to ensure a stable phase sequence - Google Patents

Abstract

The aim of the solution is to ensure a constant phase sequence of the three-phase system at the terminals of the appliances and at the same time to exclude connection failure due to a failure of any connection element, especially detectors. The goal was achieved by connecting with a combination of two phase sequence detectors with pairs of START and STOP buttons, protective relays and contactors.

Description

The aim of the solution is to ensure a constant sequence of phases of the three-phase system on the terminals of the appliances and at the same time to eliminate the failure of the connection due to the failure of some connection member, especially detectors. The target was achieved by combining two phase sequence detectors with pairs of START and STOP buttons, protective relays and contactors.

switch 30 of the first relay 4, both through the second closed contact 7 of the first relay 4 and through the open contact 26 of the second relay 24 to the second switch 31 of the second relay 24 and the neutral 14. The power switching is then performed by three pairs of contacts 9 of the first contactor 5 and three pairs of contacts 29 of the second contactor 25. The first input conductor 11 of phase A is connected both to the first input contact 9 of the first contactor 5 and to the third input contact 29 of the second contactor 25.

The second input conductor 12 of phase B is connected both to the second input contact 9 of the first contactor 5 and to the second input contact 29 of the second contactor 25. The third input conductor 13 of phase C is connected both to the third input contact 9 of the first contactor 5 and contact 29 of the second contactor 25. The first output conductor 15 is connected both to the first output contact 9 of the first contactor 5 and to the first output contact 29 of the second contactor 25. The second output conductor 16 is connected to the second output contact 9 of the first contactor 5 and the second output contact 29 of the second contactor 25. The third output conductor 17 is connected both to the third output contact 9 of the first contactor 5 and to the third output contact 29 of the second contactor 23. Both the first 1 and second 2 detectors are connected to the neutral conductor 14.

The first and second pushbuttons START 2, 22 are mechanically coupled by coupling 18. The first and second STOP buttons 3, 23 are also coupled by mechanical coupling 19.

Both buttons START 2, 22 always switch on at the same time, just as both buttons STOP 3, 23 switch off at the same time.

Two detectors 1, 21 are provided in the circuit according to the invention. Each of these detectors 1, 21 has two inputs, a first power phase input and a second monitored phase input, which is monitored for delaying or overtaking the power phase. If the sedimented phase is delayed after the power phase, the detector 1, 21 opens and the power phase voltage appears at its output. If the monitored phase is ahead of the detector, the detector 1, 21 remains closed and the output of the power phase voltage does not appear at its output. The phase sequence detectors 1, 21 are connected such that the first detector 1 monitors the clockwise rotation and the second detector 21 monitors the leftward rotation. The set of three input conductors 11, 12, 13 is clockwise rotating if the second phase B on the input second conductor 12 is delayed after phase A on the first input conductor 11. In this case, the output of the first detector 1 shows the power phase A, voltage at the first node 10 and current can be passed through the first STOP button 3 to the coil of the first contactor 5, which closes its power taps 9, thereby connecting the unchanged three-phase system from the input wires 11, 12 and 13 to the output wires. 15, 16 and 17. Phase A from the first input conductor 11 does not appear through the second detector 21 at the second node 20 because its second input is connected to the third phase C of the third conductor 13 that is ahead of the first phase A, will have no influence.

If the input wires 11, 12 and 13 have a left-handed system of phases in which the second phase B is ahead of the first phase A and the third phase C is delayed after the first phase A and the output wires 15, 16 and 17 require a right-handed system, output wires 15, 16 and 17 change the phase sequence. The first detector 1 does not output current from the first input conductor 11, since phase B from the second input conductor 12 is ahead of phase A on the first input conductor 11, the voltage does not appear at the first node 19 and therefore does not appear on the coil of the first contactor 5. does not switch its power contacts 9. Conversely, the voltage occurs at the second node 29 because the second detector 21 transmits the current of the first phase A from the first input conductor 11, since the second input of the monitoring phase of the detector 21 is phase C from the third input conductor 13. phase A delayed. The current from the second node 20 through the second START 22 and the second STOP 23 switches to the coil of the second contactor 25 which is closed, its locking contact 28 remains closed and its power contacts 29 interconnects the first input wire 11 to the third output wire 17, the second input conductor 12 to second output conductor 16 and third input conductor 13 to first output conductor 15. As a result, phases A and C are switched between each other, so that the right-handed system is again secured on the output conductors 15, 16 and 17.

Upon termination of the operation of the connected device, the STOP buttons 3, 23 interrupt the current on the coils of the first and second contactors 5, 25, their power contacts 9, respectively. 29, together with the locking contacts 8, respectively. 28, disconnects, breaks the connection of the input wires 11, 12 and 13 with the output wires 15, 16 and 17. Thus, the power supply on all output wires is interrupted. The phase current can be reconnected with the START 2, 22 buttons as described above.

If a fault occurs on either of the detectors of the first 1 or the second 21, then the nodes of the first 10 and the second 20 will have the same voltage, either phase or zero. Since both the first 4 and second 24 relays monitor the non-equivalence of the voltage states at the first 10 and second 20 nodes, they do not allow the contactors of the first 5 with the power contacts 9 or the second 25 with the power contacts 29.

If phase voltage occurs at both nodes first 10 and second 20, both relays 4, 24 and first switch 3Π of the first re switch; Also, the second switch 31 of the second relay 24 interrupts the current circuit of the contactors 5, 25 so that in this case they cannot be actuated by the START 2, 22 buttons.

If no voltage is present at both the first node 10 and the second node 20, then there will be no voltage at the outputs of both the START 2, 22, and therefore also at the coils of both contactors 5, 25, so that their power contacts S, 29 do not switch. no connection between the input wires 11, 12, and 13 and the output wires 15, 1B, 17, so that there will be no voltage at the output 8 of the wires 15, 18 and 17.

In this case, it is necessary to check both detectors first 1, 21 to eliminate the fault and then again to ensure further operation as described above.

Claims (1)

Connections for ensuring a continuous phase sequence of a three-phase system with start-stop buttons, contactors and relays, characterized in that the first input wire (11) is connected to the first input of the first detector (1), the second input is connected to the second input wire ( 12) and whose output is connected via the first node (10) to the neutral wire (14) via the coil of the first relay (4) and to the first contact of the first START button (2). ) of the first contactor (5) back to the first node (10), first to the first contact of the first STOP button (3), the second contact of which is connected via the coil of the first contactor (5) to the first switch (30) of the first relay (4) on the one hand through the break contact (6) of the first relay (4) and the make contact (27) of the second relay (24) to the second switch (31) of the second relay (24) and to the neutral (14); is connected to p the first input of the second detector (21), the second input of which is connected to the third input conductor (13) and whose output is connected via the second node (20) to the second relay coil (241 to the neutral conductor) START button (22), if the second contact is connected both via the lock contact (28) of the second contactor (25) back to the second node (20) and second contact of the second button of the STOP switch (23), whose second contact is connected via the coil second contactor (25) on the first switch (30) of the first relay (4), on the other hand through the make contact (7) of the first relay (4) and through the opening contact (26) of the second relay (24) to the second switch (31) of the second relay (24) and neutral (14), wherein the first input conductor (11) is connected both to the first input contact (9) of the first contactor 15, and to the third input contact (29) of the second contactor (25), the second input conductor (12) is connected to n and a second input contact (9) of the first contactor (5). both the second input contact (29) of the second contactor (25) and the third input conductor (13) are connected both to the third input contact (9) of the first contactor (5) and to the first input contact (29) of the second contactor (25); further, the first output conductor (15) is connected both to the first output contact (9) of the first contactor (5) and to the first output contact (29) of the second contactor (25), the second output conductor (16) is connected to the second output contact (9) of the first contactor (5), on the one hand to the second output contact (29) of the second contactor (25), and the third output conductor (17) is connected to the third output contact (9) of the first contactor (5), (29) a second contactor (25).