SE436529B - Tap changers - Google Patents

Abstract

1. Tap changing switch of the load selector type with a plurality of stationary contacts (K1, K2, K3) which are arranged on a path (1), are electrically insulated from one another, and are intended for being connected to the taps of the regulating transformer, with a movable contact carrier (2) carrying one main contact (H) and two auxiliary contacts (M1, M2) located on one side each of the main contact and arranged to be brought into contact with said stationary contacts, and with at least one controllable valve circuit (T1, T2) mounted on the movable contact carrier (2) between the main contact (H) and each of the two auxiliary contacts (M1, M2) and being controllable in both direction, characterized in that the control circuits (3) associated to said valve circuits (T1, T2) are mounted on the movable contact carrier (2) and are arranged to carry current only when a switch-over takes place between the various transformer taps, and that the control circuits (3) for the valve circuits (T1, T2) are connected between the movable auxiliary contacts (M1, M2) for being supplied by a supply voltage.

Description

ssuzem -ß in Z the number of power semiconductors required in such a design. In order to avoid this, it has been proposed to short-circuit or disconnect the thyristors in the operating positions by means of mechanical contacts, so that the thyristors are switched on only during the self-switching (Swedish Explanatory Note 367 273). As a result, relatively small and inexpensive thyristors can be used at the same time as the power losses due to the joint voltage of the thyristors are eliminated. The solutions hitherto proposed for thyristor winding couplers have, however, almost exclusively applied to winding couplers of the type which have a separate selector and load coupler. The object of the present invention is to provide a thyristor winding coupler of the circuit breaker type, which is less space-consuming than hitherto proposed thyristor winding couplers of the above-mentioned type and which is better suited for use with small and medium-sized transformers.

This is achieved according to the invention by a winding coupler which has the features stated in the characterizing part of claim 1. By letting the selector contacts control the ignition sequence of the thyristors, the thyristors with associated electronic control circuits can be placed on the movable contact carrier, without connection to earth potential. This means that a relatively simple mechanical construction is obtained, which enables the invention to be applied relatively easily to switch selectors of conventional design for use in such cases, where arc-free load switching is of essential importance. In order to prevent step shorting of the transformer in the event of a possible fault in a thyristor or in the electronic control system, it is possible in a manner known per se (cf. the above-mentioned Swedish explanation 367 273) to arrange ¿“2ï an eäkfinë in the connection between someone In parallel with the fuse, a resistor is arranged, which is dimensioned to serve as a switching resistor after a possible tripping of the fuse.

The operational reliability of the winding coupler can be further improved by arranging in the connection between at least one of the cooling contacts and the main contact two parallel, in both directions controllable thyristor devices, one of which is connected in series with a fuse and the other with a switching resistor. With such an arrangement, circulating current can be allowed to flow for a certain time of the switching process without a short circuit occurring, and outgoing thyristors thereby have plenty of time to switch off. The invention will be described in more detail in connection with a number of exemplary embodiments shown in the accompanying drawing; Fig. 1 shows a simple principle diagram for a winding coupler according to the invention, Fig. 2 shows a contact movement diagram for this winding coupler, Fig. 3 shows a principle diagram for a further developed winding coupler with 2 thyristor devices per phase, Fig. 4 shows a more detailed principle diagram for a winding coupler. 4 thyristor devices per phase, and Fig. 5 shows a schematic diagram for a winding coupler with 3 thyristor devices per phase.

The winding coupler shown in Fig. 1 is of the breaker selector type, which means that the entire coupling process takes place in the selector, and it is made in a so-called pennant coupling. The winding coupler contains a plurality of fixed contacts arranged along a path 1, of which three contacts K1, K2, K3 are shown. These contacts, which are arranged at equal distances from each other, are electrically insulated from each other and are intended to be connected to the sockets of a control transformer. The movable part of the winding coupler comprises a contact carrier, which can be constituted by a main contact arm 2, which carries a main contact H and two auxiliary contacts M1, M2. With the aid of insulating spacer elements, the auxiliary contacts are fixedly mounted on the main contact arm 2 on each side thereof. Between the main contact H and each of the two auxiliary contacts M1 and M2, a valve device T1 and T2 controllable in both directions is arranged. Each such valve device can consist of two antiparallel-connected thyristors or of another device with a corresponding function, for example a triac. The valve devices T1, T2 with associated control device 3 are also mounted on the movable contact arm 2. The transformer's voltage is used to supply the control electronics, whereby no additional connection is required between the moving part of the winding coupler and the outside world. Through the arrangement shown, it is possible, for example, when switching from K2 to K3, to have access to the step voltage between M1 and M2 from, for example, Ä0 ms before the first thyristor is to be switched on, for example 20 ms after the entire switching process has been completed. In a winding coupler practically designed according to the principle diagram in Fig. 1, the fixed contacts K1, K2, K3, etc. are preferably arranged along a circular path, and the movable part of the winding coupler is attached to a drive shaft which is mounted so that that its longitudinal axis is coaxial with the circular path of the fixed contacts.

The output line 4 for the load current is connected to the movable main contact arm 2 via trailer contacts (not shown).

Fig. 2 shows a contact movement diagram for the winding coupler according to Fig. 1 when switching from contact K2 (operating mode L2) to contact K3 (operating mode L3) and vice versa. The designations 23a - 23e and 32a - 32e on the left in the figure denote different intermediate positions of the movable contact system of the winding coupler during an increase maneuver (coupling to higher winding speed) or during a decrease maneuver (coupling to lower winding speed). The numbers 1 and 0 at the three contact branches M1, H and M2 indicate whether each branch is live or non-live.

In the operating modes of the main contactless load current, while the auxiliary contacts M1 and M2 are broken and are located in the openings between the fixed contacts.

In the case of an increase operation from operating mode L2 to operating mode L3, the switching process is as follows: At position 23a: The auxiliary contacts M1 and M2 close approximately at the same time to the fixed contacts K2 and K3, respectively. The electronics receive supply voltage. The valve device T1 receives an ignition signal. - "- 23b: The main contact H breaks arc-free from contact K2.

The valve device T1 takes over the load current. _ "- 23c: The valve device T1 goes out. The valve device T2 switches on and takes over the load current. -" - 23d: The main contact H closes with the fixed contact K3. The valve device T2 goes out. The load current is taken over by the main contact H. 4 "- 23e: The auxiliary contacts M1 and M2 break from the contacts K2 and K3, respectively. These breaks are also arc-free, since both azo2ss1 ~ a valve devices T1 and T2 are previously switched off.

The movable contact system now continues its movement until the auxiliary contacts are in their places in the openings between the fixed contacts, whereby operating mode LS is reached.

The coupling process during a reduction operation from the operating position L3 to the operating position L2 is, as shown in Fig. 2, analogous to that described above, but the valve devices are switched on in reverse order.

Fig. 3 shows an embodiment with two thyristor devices T1, T2 per phase, where a fuse S is arranged in series with each thyristor device as protection in the event of a possible short circuit, due to faults in a thyristor or in the control circuits. Parallel to each fuse is a resistor R. This shunt resistor serves partly to facilitate the fuse's break of the short-circuit current, and partly to maintain the operation after the fuse has tripped by then serving as a conventional switching resistor.

Fig. H shows the principle diagram of a winding coupler with four thyristor devices T1'-TN per phase. Each thyristor device comprises two anti-parallel connected thyristors.

Between the main contact H and each of the auxiliary contacts M1 and M2 are two parallel-connected thyristor devices T1, T3 and T2, TH, respectively. Of the two thyristor devices in each such parallel connection, one thyristor device T1, T2 is connected in series with a fuse S and the other thyristor device T3, TN is connected in series with a resistor R.

Through this arrangement, circulating current can be allowed to flow without a step short circuit occurring. Furthermore, as in the embodiment according to Fig. 3, it is achieved that the winding coupler is not deactivated in the event of a thyristor failure. If any of the fuses trip due to short-circuited thyristors, the winding switch automatically switches to working as a conventional winding switch.

The winding switch according to fig Ä works in the following way when switching from contact K2 to K3 (increase operation): 10 15 .äs âšüâ fi äi ”t 3 o The movable auxiliary contacts M1 and M2 make contact with the fixed contacts K2 and K3 respectively. Step voltage is then obtained between M1 and M2, whereby the electronic control device 3 receives supply voltage. At the same time, voltage is obtained between H ooh M2, whereby the control logic receives information about the direction of movement.

The thyristor device T1 receives an ignition signal but does not conduct current.

The main contact H leaves K2 and the thyristor device T1 takes over the load current. Contact H breaks arc-free. The ignition signal is immediately transferred to the thyristor device T3 which takes over the current when T1 is switched off at the next current zero crossing. T3 has an ignition signal for 11-1H ms, after which TÅ is ignited. Depending on the phase position in which the ignition sequence started, circulating current can now flow via T3, TU and the switching resistors R. The circulation current ceases when T3 is switched off at the next current zero. At low load current, the T3 can possibly be switched off before current zero of the opposite circulation current, which then ceases immediately.

The thyristor device TÅ has an ignition signal for 11-TH ms, after which T2 is switched on and, due to the lower impedance in that branch, starts conducting current immediately. T2, leads until the main contact H makes contact with K3 and the switching is thereby completed. T2 retains its ignition signal until M2 leaves K3.

In a maneuver in the opposite direction, the process becomes analogous to the above, but the thyristor devices are switched on in reverse order.

The thyristor and resistor arm arrangement shown in Fig. H provides protection against short circuits in the event of a re-igniting thyristor. The only thing that happens in such a case is that the circulation current continues to flow for another half period.

A possible thyristor failure, regardless of whether the cause is overcurrent or overvoltage, results in one or more short-circuited thyristors. Such a breakdown in any of the thyristor devices T1 or T2 causes the tripping of the respective fuse. The parallel thyristor group is then also switched off, if it does not have an ignition signal. The end result is that the winding coupler ~ no longer breaks arc-free, but continues to operate.

Fig. 5 shows the principle diagram of a winding coupler with three thyristor devices T1-T3 per phase, of which T1 and T3 are arranged parallel between the auxiliary contact M1 and the main contact H, while T2 is arranged between the auxiliary contact M2 and the main contact H. The thyristor device T1

Claims (4)

A thyristor device T3 is connected in series with a switching resistor R, and the thyristor device T2 is connected in series with a parallel connection of a fuse S and a resistor R. The winding coupler according to Fig. 5 operates in principle on in the same way as shown in Fig. H. In the event of a switch from contact K2 to K3 (increase operation), the sequence of events is as follows: a) The auxiliary contacts M1 and M2 enter the fixed contacts K2 and K3, respectively. Supply voltage to the control electronics is then obtained between M1 and M2. The thyristor device T1 receives an ignition signal. b) The main contact H breaks arc-free from K2, and the thyristor device T1, which already has an ignition signal, begins to conduct. Ignition signal is then given to the thyristor device T3, while the ignition signal to T1 is removed. At the next current zero throughput, the load current commutates from T1 to T3. c) Ignition signal is given to T2, whereby circulating current occurs. The ignition signal to T3 * is removed and T3 goes out at the next current zero crossing. d) The main contact H enters the fixed contact K3, whereby the thyristor device T2, which still has ignition current, goes out. The winding coupler according to Fig. 5 offers the same advantages as that shown in Fig. 4, and it also becomes cheaper, since the number of thyristors is smaller. However, due to the asymmetrical construction of the winding coupler according to Fig. 5, the control circuits become somewhat more complicated. PATENT REQUIREMENTS Winding switch type breaker switch containing a plurality of fixed contacts (K1, K2, K3) arranged electrically isolated from each other along a path (1) and intended for connection to a socket of a control transformer, and a movable contact carrier (2), on which a main contact ( H) and two auxiliary contacts (M1, M2) arranged on each side of the main contact are mounted for co-operation with the fixed contacts, characterized in that between the main contact (H) and each of the two auxiliary contacts (M1, M2) is arranged at least one valve device (T1, T2) controllable in both directions, the valve devices (T1, T2) with associated Strength grease saw (3) being mounted on the movable contact carrier (2) and carrying current only when switching between different transformer socket. & ä02sa1-A -v-n 8 Winding coupler according to Claim 1, characterized in that the valve device connections (T1, T2) control circuits (3) are connected between the movable auxiliary contacts (M1, M2) for utilizing the transformer step voltage for supplying the control circuits, wherein the fixed and movable contacts of the winding coupler are arranged in relation to each other so that the supply voltage is available at least 5 ms before the first thyristor is to be switched on. f Winding coupler according to Claim 1 or 2, characterized in that a fuse (S) in series with one of said valve devices is arranged in the connection between each auxiliary contact (M1, M2) and the main contact (H). (T1, T2), wherein a resistor (R) is arranged parallel to the fuse which is dimensioned to serve as a switching resistor after a possible tripping of the fuse (É). ' Winding coupler according to claim 3, characterized in that in the connection between at least one of the auxiliary contacts (M1, M2) and the main contact (H) two parallel-connected valve devices (T1, T3) are arranged, said fuse (S) is connected in series with one valve device (T1) con said resistor (R) with the other (T3).