DE3210850A1 - Ignition circuit for thyristors connected in antiparallel - Google Patents

Abstract

The invention relates to an ignition circuit for a thyristor arrangement having two antiparallel-connected thyristor branches (1, 2). In this arrangement, the thyristors (1, 2) of the thyristor branches are normally ignited by means of a photo-ignitable auxiliary thyristor (3) which is connected via a diode bridge (5A to 5D) to the gates of the thyristors (1, 2) to be ignited and, on the other hand, to their anodes. In parallel with the photo-ignitable auxiliary thyristor (3), a threshold element (8), for example a break-over diode, is connected. If the voltage present across the thyristors (1, 2) exceeds a particular voltage predetermined by the threshold value of the threshold element, the threshold element (8) conducts and the thyristors loaded in the forward direction are ignited. The voltage present across the thyristors (1, 2) thus collapses and the thyristors (1, 2) are protected against overvoltage. <IMAGE>

Description

Ignition circuit for anti-parallel connected thyristors

(The priority is taken from Japanese application T 56-42307, dated 03/25/1981 claimed) The invention relates to an ignition circuit for a thyristor arrangement with two antiparallel-connected thyristor branches, with normal ignition of the Thyristors of the thyristor arrangement with at least one via diodes to the thyristors coupled auxiliary thyristor takes place and wherein an emergency ignition device with at least a threshold element is provided, which in the event of overvoltage on one of the thyristors Emits firing pulses for the thyristors.

A known ignition circuit with a light-ignitable auxiliary thyristor is shown in FIG. Two thyristors 1 and 2 are connected in anti-parallel. They are ignited by a common light-ignitable auxiliary thyristor 3. Of the light-ignitable auxiliary thyristor 3 is in series with a current limiting resistor 4 in the diagonal branch of a diode bridge with diodes 5A to 5D. This diode bridge is on the one hand to the gate of the thyristor 1 and via the parallel connection of a Diode 6B and a resistor 7B to the cathode of the thyristor 1 and on the other hand to the gate of the thyristor 2 and via the parallel connection of a diode 6A and a resistor 7A is connected to the cathode of this thyristor 2. Depending on the polarity the applied voltage therefore triggers thyristor 1 or thyristor 2, when the light-ignitable auxiliary thyristor 3 is ignited by a light pulse.

To the thyristors 1 and 2 in this ignition circuit against overvoltage to protect, you can according to the circuit of Figure 2 breakover diodes 12A respectively.

12B provide. These are in series with a current limiting resistor 10A or 10B and a diode 11A or 113 parallel to the gate-anode path of the associated thyristor 1 and 2. The diodes 11A and 11B are polarized so that they Block voltages in the reverse direction of the assigned thyristor 1 or 2. the Breakover diodes 12A and 12B have the property that they are up to a certain Threshold voltage has a high internal resistance and above that a very small internal resistance exhibit. So if the anode-cathode voltage of the assigned thyristor 1 or 2 exceeds a specified value, the assigned breakover diode 12A or 12B conductive and the thyristor 1 or 2 ignited. That breaks with him pending voltage together before it reaches dangerous values for the thyristor can increase. In the circuit according to FIG. 2, there is 1, 2 for each thyristor a protection order provided. In this known arrangement, therefore, the circuit complexity relatively high for the protective ignition and therefore costly.

The object of the invention is therefore to provide an ignition circuit of the initially mentioned designed so that the cost of a protective ignition is reduced will.

According to the invention, this object is achieved in that the threshold value element connected in parallel to the auxiliary thyristor.

This ensures that the protective ignition of the thyristors in the event of overvoltage only one threshold value element is required per auxiliary thyristor.

In order to limit the S-current, a resistor can be added in series with the threshold value element i be arranged.

The threshold value element is advantageously a breakover diode. The characteristic curve of the breakover diode, its resistance above a specified voltage reaches a very small value is particularly suitable for this purpose.

Embodiments of the invention are described below with reference to the figures 3 to 5 explained in more detail.

FIG. 3 shows a basic circuit of the invention as in the circuit According to Figure 1, two thyristors 1 and 2 are connected in antiparallel and are ignited during operation with the aid of a light-ignitable auxiliary thyristor 3. The auxiliary thyristor 3 is in series with a resistor 4 in the diagonal of a diode bridge the diodes 5A to 5D. The diode bridge is between the gates of the two thyristors 1 and 2 arranged and also on the one hand via the parallel connection of a diode 6B and a resistor 7B and on the other hand via the parallel connection of a diode 6A and a resistor 7A with the anode and cathode connections of the thyristors 1 and 2 connected. Parallel to the series connection of resistor 4 and light ignitable Auxiliary thyristor 3 is the series connection of a breakover diode 8 with opposite one Polarity and a current limiting resistor 9. The breakover diode 8 that too is referred to as a thyristor diode, but can also be replaced by a thyristor whose gate is connected in parallel by one of the anode-cathode path Z-diode is controlled. A voltage-current characteristic is thus also corresponding the breakover diode achieved.

It is also possible to use a diac instead of the breakover diode. With the diodes 5A to 5D that thyristor 1 or 2 for ignition selected for the polarity of the current voltage in the conduction direction and this thyristor 1 or 2, a gate current is supplied. The diode 6A or 6B prevents the at the anode-cathode path of the thyristors 1 and 2 voltage present at the gate of the thyristor 1 that is currently in the reverse direction or 2 is supplied. The resistors 7A and 7B are used to limit the current.

As described, so is with the bridge circuit with the diodes 5A to 5D one of the thyristors 1 or 2 selected for ignition, the AC connections of the bridge circuit are connected to the gates of the thyristors 1 and 2, respectively. To the DC connections of the bridge circuit is the anti-parallel circuit of the light-ignitable auxiliary thyristor 3 and the breakover diode 8, each of which has a Current limiting resistor 4 or 9 is connected upstream. The anti-parallel connection of the light-ignitable auxiliary thyristor 3 and breakover diode 8 can also be done directly via a common current limiting resistor or without any current limiting resistor connected to the DC outputs of the bridge circuit.

If in this circuit arrangement the light-ignitable auxiliary thyristor 3 receives a light pulse, the gate of the in Conduction direction located thyristor 1 or 2 from the anode-cathode path Ignition pulse supplied. The thyristors 1 and 2 are therefore dependent on the applied voltage and the gate current derived from it are ignited alternately. For example, when the anode potential of the thyristor 1 is positive with respect to its cathode potential is, a gate current flows through the diode 6A, the diode 5A, the current limiting resistor 4, the light-ignitable auxiliary thyristor 3 and the diode 5D for Gate of the Ihyristor 1. This triggers the thyristor 1. If, on the other hand, the anode of the Thyristor 2 is positive with respect to its cathode, a gate current overflows the diode 6B, the diode 5C, the resistor 4, the light-ignitable auxiliary thyristor 3 and the diode 5B to the gate of the thyristor 2 and thus ignites this ;.

If one weighs either for the thyristor 1 or 2 in the conduction direction Voltage during such an ignition process exceeds a specified value, the breakover diode 8 becomes conductive when its threshold value is exceeded. So that will a gate current is supplied to thyristor 1 or 2, which is stressed by overvoltage, corresponding to the polarity of the voltage applied to thyristors 1 and 2 one of the thyristors 1 or 2 ignites. The ignition current for this protective ignition flows via the same current path as with normal ignition, but not via the Resistor 4 and the light-ignitable auxiliary thyristor 3, but instead via the resistor 9 and the breakover diode 8. This protective ignition causes the Thyristors 1 and 2 protected from breakdown due to overvoltage. The occurrence of a gate current during protective ignition can be monitored by a light-emitting diode is inserted in series with the breakover diode 8, which has a light guide is electrically isolated and connected to a fault signaling device.

Figure 4 shows a further embodiment of the invention. Included are a thyristor arrangement with the thyristors 1 and 2, which are essentially the The arrangement of Figure 1 corresponds to and a thyristor arrangement with the thyristors 1 'and 2', in which, compared to the arrangement in FIG. 3, the lithium-ignitable auxiliary thyristor is omitted, connected in series. The thyristors 1, 1 'and 2, 2' are Each connected in series and are alternated by a common light-ignitable auxiliary thyristor 3 ignited via pulse transformers 13A and 13B. A breakover diode 8 is antiparallel to the common light-ignitable auxiliary thyristor 3 switched so that each of the thyristors 1, 1 ', 2, 2' in the same manner as above explained, is protected from a breakdown due to overvoltage.

The number of thyristor assemblies connected in series with each an anti-parallel connection of two thyristors can be chosen arbitrarily, whereby the number of secondary windings of the pulse transformers 13A and 13B of the number must correspond to the thyristor arrangements connected in series. Are there the primary windings of the pulse transformers 13A, 13B always to the AC voltage inputs connected to the diode bridge 5A to 5D, to whose DC voltage outputs the light-ignitable auxiliary thyristor 3 is located. With the number of thyristor arrangements connected in series in practice are of course the performance of the pulse transformer and the light-ignitable auxiliary thyristor and the cost of such an extension to consider.

Another embodiment of the invention is shown in FIG. Two thyristor arrangements with anti-parallel connected thyristors 1, 2 or

1 ', 2' connected in series. The ignition devices for the Protective ignition in the event of overvoltage is almost identical to the arrangement according to FIG. 4. However, there are two separate pulse transformers for each thyristor arrangement 13A, 13A 'and 13B, 13Bi are present. The corresponding secondary windings of the Pulse transformers 13A, 13A 'and 13B, 13B' are Uber diodes 14A to 14D, respectively. 14A 'to 14D' connected in parallel. If in one of the two thyristor arrangements a fault occurs can therefore reduce the gate current for the thyristor faulty Stage supplied by the other thyristor arrangement. The pulse transformers l3A, 1 3A! and 13B, 13B 'with the secondary windings connected in parallel therefore be interconnected so that a secondary winding of each pulse transformer with a gate connection of a thyristor of the associated thyristor arrangement and the second secondary winding to the gate terminal of a thyristor of the other Thyristor arrangement is connected. Each thyristor arrangement has one for ignition own light-ignitable auxiliary thyristor and a breakover diode for protective ignition on. This involves relatively high costs, but four can or more thyristors are still triggered by a thyristor arrangement, if an error occurs in one of the thyristor arrangements. So this circuit can can also be used with high reliability requirements. Besides that, she can Number of thyristor arrangements connected in series with the number of secondary windings -the pulse transformers are increased within wide limits.

In summary, it can be stated that in a circuit arrangement for the ignition of anti-parallel switched thyristors with a combination of a light-ignitable auxiliary thyristor and a breakover diode provide protection against overvoltages is obtained.

Normally, the ignition takes place via a light-ignitable auxiliary thyristor, which supplies a gate current to a thyristor in the event of a light pulse. In the event of a fault, when the forward voltage across a thyristor has a predetermined value Exceeds the value, a breakover diode supplies a gate current for a thyristor Protective ignition. Therefore, compared to known arrangements to achieve the Protective function required number of switching elements can be significantly reduced. The production costs are reduced by simplifying the circuit arrangement.

L e it e i t e

Claims (4)

Patent application for ignition circuit for a thyristor arrangement with two anti-parallel connected thyristor branches, with the normal ignition of the thyristors the thyristor arrangement with at least one coupled to the thyristors via diodes Auxiliary thyristor takes place and provides an emergency ignition device with at least one threshold value element is provided, the trigger pulses for the thyristors in the event of overvoltage at the thyristors indicates that the threshold value element (8) the auxiliary thyristor (3) is connected in parallel. 2. Ignition circuit according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the auxiliary thyristor (3) can be triggered by light. 3. Ignition circuit according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that a resistor (9) is arranged in series with the threshold value element (8) is. 4. Ignition circuit according to one of claims 1 to 3, d a d u r c h g It is evident that the threshold value element (8) is a breakover diode is.