WO1998048432A1

WO1998048432A1 - Circuit arrangement for a load transfer switch

Info

Publication number: WO1998048432A1
Application number: PCT/AT1998/000103
Authority: WO
Inventors: Alexandre Kalinitchenko
Original assignee: Elin Oltc Stufenschalter Für Transformatoren Gmbh
Priority date: 1997-04-22
Filing date: 1998-04-21
Publication date: 1998-10-29
Also published as: EP0978131A1; DE59801004D1; AT406988B; ATE203124T1; EP0978131B1; AU7012098A; ATA67997A

Abstract

The invention concerns a circuit for a load transfer switch comprising a regulating winding with a regulating stage (1) whose load current can be conducted via a lower or a higher winding tap (2, 3) and via at least two selector contacts (4, 5) and two permanent contacts (6, 7) with a common terminal lead (8). Switching from the lower to the higher winding tap or vice versa occurs via a first load transfer switch (9), wherein contact (10) is located in the connection of the selector contact (4) to the permanent contact (6) and the contact (11) is placed in the connection of the selector contact (5) to the permanent contact (7). The root contact of the first load transfer switch is connected via a transition resistor (13) and a bridging switch (14) in series to the common terminal lead (8). A second load transfer switch (15) is provided, wherein contact (16) is once again connected to the connection of the selector contact (4) to the permanent contact (6) and contact (17) is connected to the connection of selector contact (5) to permanent contact (7). The root contact (18) of said second load transfer switch (15) is connected to the connection of the transition resistor (13) and the bridging switch (14) by means of a thyristor circuit (19). The thyristor circuit (19) has antiparallel-connected thyristors.

Description

CIRCUIT ARRANGEMENT FOR A LOAD SWITCH

DESCRIPTION

The invention relates to a circuit arrangement in a load changeover switch of a tap changer for uninterrupted switching of the control winding of a transformer, the load current being feasible via a low or higher winding tap of a control stage of a control winding and via a connection of at least two selector contacts and two permanent contacts the changeover from the lower to the higher winding tapping or vice versa, a first changeover switch is provided, one of the two contacts of the first changeover switch being connected to the connection of a selector contact with a permanent contact, and the root contact of this first changeover switch being connected in series via a switching resistor and one Bridging switch is connected to the common derivative and a second changeover switch is provided, at the root contact of which is a thyristor circuit consisting of antiparallel connected thyristors is closed.

Such an arrangement is known from EP 0 375 687 B2. In this arrangement, the load current is briefly transferred to a relief circuit that is between the

Root connection of this first switch and the common derivative is arranged. This relief circuit also has a thyristor circuit with anti-parallel connected thyristors. In addition, the relief circuit has a second switch, which is in series with the thyristor circuit. Of this second changeover switch, one changeover contact is direct and the other changeover contact is via

Overvoltage resistance connected to the root contact of the first switch.

A disadvantage of this circuit arrangement is that the contact erosion is only avoided when switching off. When the permanent contacts are switched on, contact bruises occur, which leads to brief arcing. These arcing causes the contacts to burn up and soot oil also occurs. It must therefore be used to ensure proper Operating contacts and oil are changed after a certain number of operations, so that the resulting shutdown of the transformer leads to interruptions in operation.

With the diverter switch according to the cited EP-PS, the movement sequence controlled by the diverter switch shaft is carried out only in one direction. Most tap changer types, however, use diverter switches whose movement sequence from the diverter switch shaft has a reciprocating movement. This means that another mechanical motion converter is necessary.

The object of the invention is to provide a circuit arrangement in a diverter switch of a tap changer for uninterrupted switching of the control winding of a transformer of the type mentioned, which avoids the disadvantages of the known arrangements and which increases the service life of the diverter switch.

The object is achieved by the invention. The circuit arrangement according to the invention in a diverter switch is characterized in that the two contacts of this second changeover switch are also each connected to the connection of a selector contact with a permanent contact and the root contact of this second changeover switch is connected via the thyristor circuit to the connection of the overrunning resistor and the bypass switch.

With the invention it is possible for the first time to implement both movements without additional components.

This circuit arrangement according to the invention does not increase the component expenditure in order to achieve an arc-free switching from one control stage to another. Contact erosion is also prevented, both when switching on and when switching off the permanent contacts. The invention provides a largely maintenance-free diverter switch for tap changers.

On the basis of the usual switching time, the mechanical switching elements used in the known diverter switch and the

Overvoltage resistors are used. Only one ignition device for the thyristors is required.

The invention is explained in more detail using exemplary embodiments which are illustrated in the drawing. 1 shows the circuit arrangement with a diverter switch and FIGS. 2, 3 and 4 the associated flow diagrams.

1 shows a control stage 1 of a control winding, the load current of which can be fed to a common derivative 8 via a lower or higher winding tap 2, 3 and at least two selector contacts 4, 5 and two permanent contacts 6, 7. The changeover from the lower to the higher winding tapping or vice versa takes place via a first changeover switch 9. This changeover switch 9 has two contacts 10, 11 for the changeover and a root contact 12. The contact 10 of the switch 9 is on the connection of the selector contact 4 with the permanent contact 6 and the contact 11 is on the connection of the selector contact 5 with the

Permanent contact 7 placed. The root contact 12 of the first changeover switch 9 is connected to the common derivative 8 via a switching resistor 13 and a bridging switch 14 which is in series. Furthermore, a second changeover switch 15 is provided, which has two contacts 16, 17 for the changeover and a root contact 18. The contact 16 of this changeover switch 15 is again connected to the connection of the selector contact 4 to the permanent contact 6 and the contact 17 is connected to the connection of the selector contact 5 to the permanent contact 7. The root contact 18 of this second switch 15 is connected via a thyristor circuit 19 to the connection of the switching resistor 13 and the bypass switch 14. The thyristor circuit 19 has antiparallel thyristors. According to FIG. 2, the switching from one tap to another tap of control stage 1 of a control winding is described in steps using a flowchart. The left-hand designations in FIG. 2 correspond to the switches or thyristors and contacts in FIG. 1.

The following switchover is described: Initial state: permanent contact 6 closed, permanent contact 7 open, final state: permanent contact 6 open, permanent contact 7 closed.

Intervals:

A: Selector contacts 4, 5 and permanent contact 6 closed; Permanent contact 7 and bypass switch 14 open; Thyristors 19 not fired; Switch 15 connects contact 16 with root contact 18;

Switch 9 connects contact 10 with root contact 12; Load current flows via winding tapping 2 as well as via selector contact 4 and permanent contact 6 for common derivation 8;

B: the thyristors of the thyrister circuit 19 are ignited;

C: the bridging contact 14 is closed without erosion (the protection circuit is parallel to this bridging contact 14: fired thyristor circuit 19, contact 16 closed with root contact 18, closed permanent contact 6 given)

D: the permanent contact 6 opens without erosion (the protective circuit is parallel to this permanent contact 6: fired thyristor circuit 19, contact 16 with root contact 18 closed, closed bypass contact 14 given); Load current flows through changeover switch 15, thyristor circuit 19 and

Bypass switch 14; E: Thyristor circuit 19 is no longer ignited and only leads the load current to the next zero crossing; then the load current flows through changeover switch 9, contact resistance 13 and bypass switch 14;

F: Changeover switch 15 switches from contact 16 to contact 17 without current;

G: Thyristor circuit 19 is ignited; this creates a compensating current which flows via selector contact 4, changeover switch 9, contact resistance 13, thyristor circuit 19, changeover switch 15 to selector contact 5;

H: permanent contact 7 is closed without erosion (parallel to this permanent contact 7 is the protective circuit: fired thyristor circuit 19, contact 17 with root contact 18 closed, closed bypass contact 14 given); the circuit: thyristor circuit 19, changeover switch 15, permanent contact 7 and bypass switch 14 has practically equivalent potential (the

Voltage drop between any points in this circle is very small);

I: bypass switch 14 opens without burning (parallel to this

Bridging contact 14 is the protective circuit: ignited thyristor circuit 19, contact 17 with root contact 18 closed, closed permanent contact 7 given); the load current flows through the permanent contact 7;

J: Thyristor is no longer fired; and only leads the equalizing current until the next zero crossing;

K: the changeover switch 9 changes the contact position from the contact 10 to the currentless state

Contact 11.

In the case of a movement sequence in one direction, the above sequence is correspondingly repeated with the next switchover from A to K (initial state: permanent contact 7 closed, permanent contact 6 open, final state: permanent contact 7 open, permanent contact 6 closed). In the case of a to-and-fro motion sequence, the sequence from K to A is run through the next switchover. The following switching is described below:

Initial state: permanent contact 7 closed, permanent contact 6 open, final state: permanent contact 7 open, permanent contact 6 closed.

K: Selector contacts 4, 5 and permanent contact 7 closed; Permanent contact 6 and bypass switch 14 open;

Thyristors 19 not fired;

Switch 15 connects contact 17 with root contact 18;

Switch 9 connects contact 11 with root contact 12;

Load current flows via winding tapping 3 as well as via selector 5 and permanent contact 7 for common derivation 8;

J: Changeover switch 9 changes its current position from contact 11 to contact 10 without current;

I: the thyristors of thyrister circuit 19 are ignited; this creates a

Compensation current which flows via selector contact 4, changeover switch 9, contact resistance 13, thyristor circuit 19, changeover switch 15 to selector contact 5; the voltage drop at the open bypass contact 14 is very small;

H: the bridging contact 14 is closed without erosion (the protection circuit is parallel to this bridging contact 14: fired thyristor circuit 19, contact 17 closed with root contact 18, closed permanent contact 7 given); the circuit: thyristor circuit 19, changeover switch 15, permanent contact 7 and bypass switch 14 has practically equivalent potential (the voltage drop between any points in this circuit is very small); G: the permanent contact 7 opens without burning (the protective circuit is parallel to this permanent contact 7: fired thyristor circuit 19, contact 17 closed with root contact 18, closed bypass contact 14 given); Load current flows through changeover switch 15, thyristor circuit 19 and bypass switch 14;

Q: Thyristor circuit 19 is no longer ignited; and only leads the current to the next zero crossing; Load current flows through selector contact 4, changeover switch 9, contact resistance 13 and bypass switch 14;

E: Changeover switch 15 changes its current position from contact 17 to contact 16 without current;

D: Thyristor circuit 19 is ignited and takes over the load current; the voltage drop at the open permanent contact 6 is very small;

C: permanent contact 6 is closed without erosion (parallel to this permanent contact 6 is the protective circuit: fired thyristor circuit 19, contact 16 with root contact 18 closed, closed bypass contact 14 given);

B: the bypass switch 14 opens without burning (parallel to this

Bridging contact 14 is the protective circuit: ignited thyristor circuit 19, contact 17 with root contact 18 closed, closed permanent contact 7 given);

A: the thyristor circuit is no longer ignited;

If a to-and-fro movement is specified by the load switch shaft and steps A to K are carried out, the changeover switch 9 changes its state at the end of the changeover process. When steps K to A are carried out, the changeover switch 9 changes its state at the beginning of the changeover process. The current flows in the load switch are not changed either by the change in state of the changeover switch 9 at the beginning or at the end of the changeover process. According to FIG. 3, the switching from one tap to another tap of control stage 1 of a control winding is described in steps using a flowchart. The left-hand designations in FIG. 3 correspond to the switches or thyristors and contacts in FIG. 1.

The difference to the processes shown above is that the switch 9 changes its switch position only at the end of the switching process, for both movement sequences, that is, both for specifying the movement in one direction and for a reciprocating movement by the

Diverter switch shaft is derived. Each changeover process in the diverter switch is analogous to the sequence A to K according to FIG. 2.

According to FIG. 4, the switching from one tap to another tap of control stage 1 of a control winding is described in steps using a flowchart. The left-hand designations in FIG. 4 correspond to the switches or thyristors and contacts in FIG. 1.

The difference to the processes shown above is that the switch 9 changes its switch position only at the beginning of the switching process for both movement sequences, that is to say both for specifying the movement in one direction and for a reciprocating movement by the diverter switch shaft is derived. Each changeover process in the diverter switch is analogously to the sequence K to A according to FIG. 2.

As shown above, both turn on and turn off the

Permanent contacts 6 and 7 are free of erosion, since at the time of switching the protective circuit is always closed: bypass switch 14 closed, thyristor circuit 19 ignited, changeover switch 15 closed accordingly. Likewise, the bridging switch 14 is opened and closed without burning, since at the time of switching the protective circuit: fired thyristor circuit 19, correspondingly closed changeover switch 15, and correspondingly closed permanent contact 6 or 7 is provided. The changeover switches 9 and 15 are switched without current, since the thyristor circuit 19 is at this time is not ignited and is conductive. Contact erosion is prevented both when switching on and when switching off all contacts.

Reference list

Control stage winding tapping winding tapping selector contact selector contact

Permanent contact Permanent contact Derivation Switch contact

Contact root contact overrunning resistance bypass switch contact

Contact Contact root contact thyristor circuit

Claims

Claim

Circuit arrangement in a load switch of a tap changer for uninterrupted switching of the control winding of a transformer, the load current being feasible via a lower or higher winding tap of a control stage of a control winding and via a connection of at least two selector contacts and two permanent contacts with a common derivation and for switching from Lower to the higher winding tapping or vice versa, a first changeover switch is provided, whereby one of the two contacts of the first changeover switch is connected to the connection of a selector contact with a permanent contact and the root contact of this first changeover switch is connected to the common one via a contact resistance and a bypass switch in series Derivation is connected and a second changeover switch is provided, to the root contact of which a thyristor circuit consisting of antiparallel connected thyristors is connected indicates that the two contacts (16, 17) of this second switch (15) are also each connected to the connection of a selector contact (4, 5) with a permanent contact (6, 7) and the root contact (18) of this second switch (15 ) is connected via the thyristor circuit (19) to the connection of the switching resistor (13) and the bypass switch (14).