DE1257952B - Circuit arrangement for controlling the flow of current in a direct current circuit by means of a thyristor, which is subjected to countercurrent for the purpose of extinguishing by discharging a capacitor - Google Patents

Description

Circuit arrangement for controlling the flow of current in a direct current circuit by means of a thyristor, which for the purpose of extinction by discharging a capacitor is charged with countercurrent The currently commercially available. for a converter operation or thyristors intended for switching larger currents have the properties conventional mercury vapor and gas discharge valves. The ignition of a thyristor takes place with the help of a control pulse applied to the associated control electrode. The deletion, d. H. the blocking of the thyristor takes place only after the on the thyristor lying voltage has become zero or negative. Sufficient security against unintentional re-ignition is given if in the de-energized state there has been a counter voltage across the thyristor for a certain period of time. The latter Condition is met with an AC voltage connection.

If the thyristor is supplied from a DC voltage source, then special measures must be taken to interrupt the flow of current in the thyristor to be hit. In this case it is known to use the current-carrying thyristor in this way to switch to a charged capacitor that the discharge current of the capacitor is opposite to the current flowing through the thyristor. The discharge current must be so large that the current is certain to run for a predeterminable time of the thyristor becomes zero and in this de-energized state on the thyristor one Counter voltage is present. The connection takes place in the known circuit arrangement the quenching capacitor by a second thyristor, which has a special timing element is triggered depending on the ignition of the first thyristor. The deletion of the first thyristor takes place by discharging the quenching capacitor. The second thyristor remains energized after the extinguishing process until the first thyristor is restored ignites and the quenching capacitor, which has been reloaded in the meantime, is placed on the second thyristor switches. The second thyristor is extinguished if the extinction capacitor is sufficient Voltage of a polarity opposite to that of the erasing process described above owns.

A major disadvantage of the known circuit arrangement is that unsafe quenching of the thyristor. Between the end of the quenching process of a thyristor and the re-ignition of this thyristor must be a certain minimum time, which is required for sufficient charge reversal of the quenching capacitor. Will this minimum time fallen below, then the capacitor voltage is still too low to cancel of a thyristor. In these circumstances, both remain the one the other thyristor is also live. But this also leaves the capacitor voltage constantly at a value of practically zero. A new deletion process is no longer possible start up.

It is therefore the object of the invention to provide an operationally reliable one with little effort To create working circuit arrangement, which has the disadvantage described above avoids.

Accordingly, the invention relates to a control circuit arrangement the flow of current in a direct current circuit by means of a thyristor, the purpose of Deletion after a predeterminable time automatically by using electronic Switching elements caused a discharge from the DC voltage source via a Ohmic charging resistor charged capacitor is acted upon with countercurrent.

The invention is that the circuit arrangement as a an astable flip-flop circuit that oscillates only while the thyristor is conducting current is.

With the subject matter of the invention one will again and again by itself ongoing deletion process guaranteed. The timer and capacitor extinguishing circuit are united in itself. The discharge of the capacitor repeats itself with a predeterminable Period of the astable multivibrator while the thyristor is live.

There is a preferred embodiment of the subject matter of the invention in the fact that as a stable trigger circuit a known per se, a double Base diode containing flip-flop is provided, being at the connection point of capacitor and charging resistor of the emitter of the double base diode is connected, the first of which Base is connected to the pole of the thyristor facing away from the load and its second base via an ohmic series resistor to the pole of the DC voltage source to which the load is connected. Details of the multiple Also known as the "unijunction transistor", the double-base diode and the Astable flip-flops already known for the ignition of thyristors are, for example pages 44 to 47 of the second edition (1961) of the SCR manual from General Electric can be found.

The invention is based on the embodiments shown in the drawing explained in more detail. F i g. 1 shows the basic circuit arrangement of the invention.

F i g. 2 and 3 show further developments of the invention.

In Fig. 1, a DC voltage source U is connected to terminals 1 and 2. A thyristor 6 should switch on a current via a load resistor 7 after a control pulse has been applied to terminal 3. A part of the circuit arrangement which contains the components 8 to 12 and which is connected to terminal 1 of the DC voltage source U via terminals 4 and 5 is used to subsequently erase the thyristor 6. The meaning of terminals 4 and 5 will be explained with reference to FIGS. 2 and 3 are explained. 8 denotes a quenching capacitor, 9 denotes a charging resistor, 11 denotes a double base diode protected against overvoltages in the reverse direction with the aid of a rectifier diode 10, and denotes a series resistor with 12. It should also be noted that the rectifier diode 10, in addition to fulfilling the aforementioned task, contributes to achieving a shorter time sequence in the operation of the circuit arrangement. If you omitted the load resistor 7 and the rectifier diode 10 while opening the relevant circuits, connected the negative pole 2 directly to the right connection of the capacitor 8 and replaced the thyristor 6 with a linear ohmic resistance, then you would have a known embodiment of an astable multivibrator to be present.

As long as in FIG. 1, the thyristor 6 is not ignited, the capacitor 8 is charged via the load resistor 7 to the polarity shown above the capacitor 8. The charging current flows from the positive terminal 1 via the load resistor 7, the quenching capacitor 8, the emitter E of the double base diode 11 and the first base B 1 of the double base diode 11 to the negative terminal 2 of the DC voltage source. In addition, the resistors 9 and 12 are current-carrying via the double base diode 11. As soon as the capacitor 8 is fully charged, the double base diode 11 blocks. If a control signal of the polarity shown is now applied to terminals 3 and 2, the thyristor 6 ignites. If the above-described charging process of the capacitor 8 has not yet ended, then the double base diode 11 is now blocked. The discharge of the capacitor 8 is supported by the DC voltage source U via the charging resistor 9, via which the subsequent charge reversal of the capacitor 8 takes place. The polarities shown in brackets result from the latter. The time constant of the charge reversal circuit is essentially determined by the product of the ohmic value of the charging resistor 9 and the capacitance of the capacitor 8. According to this time constant, the capacitor voltage reaches the so-called breakdown voltage of the double base diode 11 after a certain time. The resistance between the emitter E and the first base B 1 of the double base diode 11 collapses. The capacitor 8 discharges through the double base diode 11 and the thyristor 6, so that the latter is de-energized and thus extinguished. The capacitor 8 is then recharged from the DC voltage source U via the load resistor 7 and the double base diode 11. As long as the voltage on the capacitor 8 has not yet reached the value zero, a voltage in the reverse direction is applied to the de-energized thyristor 6. This ensures reliable blocking of the thyristor 6 and prevents unwanted re-ignition.

With the completed charge transfer of the capacitor 8 to the above Capacitor 8, the polarity shown is restored to the initial state. The double base diode 11 blocks when its emitter current has a minimum value, the so-called Holding current, falls below, d. i.e. when the capacitor 8 is fully charged. Of the The current then flowing through the emitter E is only available through the charging resistor 9 certainly. This current must be in the in the F i g. 1 and 2 illustrated embodiments be smaller than the holding current.

The circuit arrangement of FIG. 2 is true with regard to the essentials Components and the designations with the circuit arrangement of FIG. 1 match.

In Fig. 2 is an electronic switch between terminals 4 and 5 placed, which is only closed when the thyristor 6 is triggered. This can be a reduction in power consumption and thus a reduction in the continuous output of the Achieve circuit arrangement. A flat transistor is used as an electronic switch 25 is provided, the emitter-base circuit of which is connected to the load resistor 7 is. An ohmic resistor 13 is used to limit the control current, a rectifier diode 14 is used for voltage relief when the thyristor 6 is blocked.

In Fig. 2 is also indicated with dashed lines, how the extinguishing performance can be increased. The higher extinguishing performance results from if the double base diode 11 has further double base diodes 11 ', each of which has its own Quenching capacitors 8 ', charging resistors 9' and rectifier diodes 10 'assigned are to be connected in parallel. Joint ignition of the double base diodes 11, 11 ' is enforced by a common series resistor 12. If namely a double base diode ignites, then because of the common series resistor 12, the voltage between the two bases of the other double base diodes lowered. With this diminished Voltage but also the breakdown voltage of the other double base diodes is reduced, so that these will now also ignite with certainty. The circuit arrangement the F i g. 3 is linked to the circuit arrangements of FIG. 1 and 2. For each other corresponding components are again given the same reference numerals. With the The circuit arrangement of FIG. 3 should have a shorter period of time between ignition and reliable erasure of the thyristor 6, especially when the load resistance 7 is small will. To get an overview of the dimensioning of an executed circuit arrangement are given in Fig. 3 entered some numerical values.

With a smaller load resistance 7 and the same level of DC supply voltage A larger quenching capacitor 8 is required. To keep the To enable thyristor 6 to continue, the one limited by the charging resistor 9 must Charging current can be increased. As already explained, however, was allowed with the circuit arrangements the F i g. 1 and 2 the charging current does not exceed a certain critical value or the ohmic value of the charging resistor 9 does not fall below a certain value. Otherwise the double base diode 11 would not be erased. In the circuit arrangement the F i g. 3, the aforementioned condition is circumvented in that the charging current of the capacitor 8 when switching through the double base diode 11 with the help of additional Medium is blocked. As additional means are a junction transistor 20 and a Control device with the components 21 to 24 is provided. The junction transistor 20 is connected in series with the ohmic resistor 9 and determines the charging current of the capacitor B. The transistor 20 is when the double base diode is switched on 11 blocked. The criterion for switching through is that of the second base B 2 of the double base diode 11 flowing and thus detectable at the series resistor 12 current. Only when the double base diode 11 conducts its quiescent current, that is about 3 to 5 mA, the charging current of the capacitor 8 is released via the transistor 20.

The F i g. 3 is explained again in context.

The DC supply voltage U is applied to terminals 1 and 2. To the The load resistor 7 is connected upstream of the thyristor 6. The one now on the thyristor 6 Reverse voltage blocks the rectifier diode 14, whereby the transistor 25 also Is blocked. A base terminating resistor 17 ensures defined voltage conditions in the part of the circuit arrangement serving to delete the thyristor 6. This is currently still turned off because of the blocked surface transistor 25 part Via an ohmic series resistor 16 and a Zener diode 15 with constant voltage provided. Only the quenching capacitor 8 can act on the reverse voltage of the thyristor 6 via a rectifier diode 19 and because of the lack of base-2 voltage such as charge a normal diode-acting emitter-base-1 path of the double-base diode 11. The rectifier diode 19 is connected to the quenching capacitor 8 in series Ohmic current limiting resistor 18 bridged. The current limiting resistor 18 is therefore only effective when the thyristor 6 is triggered.

When the thyristor is ignited by a positive pulse applied to terminal 3, the following are conductive: rectifier diode 14, the flat transistor 25, the zener diode 23 connected in series with a resistor 25 and the flat transistor 20. The double base diode 11 and the flat transistor 21 are still blocked . When the thyristor 6 is triggered, the capacitor 8 discharges via the limiting resistor 18, the thyristor 6 and the rectifier diode 10. The transistor 20 forces a constant current established by the zener diode 23, with which the capacitor 8 is recharged. This continues until the capacitor voltage reaches the breakdown voltage of the double base diode 11 (the breakdown voltage is approximately 0.56 to 0.78 times the value of the double base voltage). The capacitor 8 now discharges via the double base diode 11 and the thyristor 6. The circuit closes via the rectifier diode 19 the surface transistor 21 is opened. This in turn removes the control voltage from the flat transistor 20 , so that this transistor blocks and interrupts the charging current. As a result of the countercurrent flowing through the thyristor 6, the latter is extinguished, and the capacitor 8 is recharged to the reverse voltage now applied to the thyristor 6. The rectifier diode 14 blocks again and, via the flat transistor 25, de-energizes the circuit arrangement which serves to quench the thyristor 6.

If the thyristor 6, for example because of another positive Signal at terminal 3, is immediately re-ignited, then the capacitor discharges 8 except for a voltage of magnitude zero. Because of the lack of reverse voltage on the semiconductor valve 6, however, the capacitor B is not recharged. The double base diode 11 blocks, so that the base-2 current is reduced to its quiescent current value. So that locks the transistor 21 and enables the transistor 20. The one now about the transistor 20 flowing charging current charges the capacitor 8 again up to the breakdown voltage the double base diode 11 on. A new deletion process then begins. The deletions and their frequency are essentially only the size of the capacitor 8 and dependent on the charging current determined by the transistor 20.

The circuit arrangements described are also advantageous for Ignition of converter valves connected in parallel and / or in series can be used for which depend on powerful ignition pulses with a steep rising edge. With the Load resistor 7 are then the control paths via decoupling intermediate elements connected to the relevant converter valves. The load resistor 7 can here be formed only by the primary winding of a pulse transformer.

Claims (10)

Claims: 1. Circuit arrangement for controlling the current flow in a DC circuit by means of a thyristor, which for the purpose of extinction after a predeterminable time automatically effected by means of electronic switching elements Discharge from the DC voltage source via an ohmic charging resistor charged capacitor is charged with countercurrent, characterized in that that the circuit arrangement as an astable and only during current conduction of the thyristor (6) oscillating trigger circuit is formed. 2. Circuit arrangement according to claim 1, characterized in that the astable trigger circuit is an known flip-flop circuit containing a double base diode (11) is provided, the emitter at the connection point of the capacitor (8) and charging resistor (9) (E) the double base diode (11) is connected, the first base (B 1) to the the load (7) facing away from the pole of the thyristor (6) is connected and the second Base (B2) via an ohmic series resistor (12) to pole (1) of the DC voltage source (1, 2) is in connection to which the load (7) is connected. 3. Circuit arrangement according to claim 2, characterized in that the first base (B1) and the emitter (E) the double base diode (11) one from the first base (B 1) towards the Emitter (E) current-conducting rectifier diode (10) is connected. 4. Circuit arrangement according to claim 2 or 3, characterized in that charging resistor in a manner known per se (9), series resistor (12) and double base diode (11) are dimensioned such that a current flowing through the charging resistor (9) is lower than that for maintaining it a low-resistance state of the double base diode (11) required of their Emitter (E) to the first base (B 1) flowing current (F i g. 1, 2). 5. Circuit arrangement according to claim 2 or 3, characterized in that the charging resistor (9, 20) with With the help of a flat transistor (20), the control device (21 to 23) is designed such that the charging current is only released when the over the second base (B 2) of the double base diode (11) flowing current its quiescent current value has not exceeded (Fig. 3). 6. Circuit arrangement according to claim 5, characterized in that by the control device (21 to 23) the base current of the junction transistor (20) is initially determined by a Zener diode (23), which, however, when the quiescent current value is exceeded via the second base (B 2 ) the double base diode (11) flowing and detected at the associated series resistor (12) current is short-circuited by means of an additional transistor (21) (FIG. 3). 7. Circuit arrangement according to one of claims 2 to 6, characterized in that the double base diode (11) at least one additional double base diode (11 ') connected to the series resistor (12) is connected directly in parallel, the respective additional double base diode (11 ') a separate one with its own charging resistor (9') and its own rectifier diode (10 ') connected quenching capacitor (8') is assigned (F i g. 2). B. Circuit arrangement according to claims 2 to 7, characterized in that between the capacitor (8) and a controllable semiconductor valve (6) a current limiting resistor (18) is provided is, one pole of which with the capacitor (8) and the other pole with the thyristor (6) is connected, the current limiting resistor (18) for the direction of a the thyristor (6) applied in the countercurrent direction by means of an additional current Rectifier diode (19) is short-circuited (Fig. 3). 9. Circuit arrangement according to claims 2 to 8, characterized in that a switching device (25) is provided, depending on the switching state of the thyristor (6) to the Deletion of the thyristor (6) serving part (8 to 12) of the circuit arrangement the DC voltage source (1, 2) connects (F i g. 2, 3). 10. A circuit arrangement according to claim 9, characterized in that a switching device controlled by the voltage across the load (7) is provided, which is in the DC voltage supply line between the one terminal of the load (7) on the one hand and the one terminals of the charging resistor (9) and series resistor (12) is arranged on the other hand (Fig. 2, 3). Considered publications: "SCR-Manual" of General Electric, 1961, pages 44 to 47, 49, 143.