DE1000447B - Control circuit for symmetrical transistor - Google Patents

Description

is closed by a control pulse introduced via the transformer. If the Control pulse due to failure of a

transistor 1 via a further rectifier 30 with 25 mator working pulse generator here is the

a point B in the connection kit between danger that because of the continuous opening of the

the two rectifiers 4 and 5 are connected. The secondary winding J _{b is} parallel to the rectifier 5

a transformer in series with a direct current circle the

judge 6 _ft , for the said
the same forward direction as the rectifier 5 has. In parallel with the rectifier 4, a second secondary winding 7 ″ of the transformer is also in series with a rectifier 6 ″, which is used for this circuit

Transistor load 2 is constantly current-flowing, so that if it is not designed for continuous operation, damage can be caused.

The subject matter of the invention serves to avoid these disadvantages. The new facility makes a difference differs from the acquaintance in that a circuit is provided in which the switching transistor the AC circuit itself is permanently blocked and the same forward direction as the rectifier 4 35 only enables it when a control pulse is received, owns. The primary winding of this transformer Several embodiments of the new device

has been omitted for the sake of simplicity. Without device are shown in Fig. 3 to 6, the circuit elements 6 _U and 6, -, and 7 ,, and ¹ J ₁ , In Fig. 3 for the sake of simplicity, the load and

the arrangement would ^{work so 1} that with the on - the alternator omitted and the load given polarity on the switching transistor 1 a control 40 circuit only the switching transistor 1 shown, current flows through the rectifier 30 and 5 and the intermediate collector and emitter of the switch -Switching transistor opens. For reasons of symmetry results
that even if the polarity of the

Switching transistor remains open because then the control

transistor ι is placed the primary winding 16 of a feed transformer OTS. The secondary windings 14, 14 and 15 of this feed transformer are in series with current through the rectifier 30, 4 can flow. For 45 secondary windings 17, 18 of a control transformer blocking of the switching transistor 1, the secondary matocs, which have a primary winding 19, as well as in the way of the circuit elements 6 _a and 6 _b series with resistors 8, 9, 10 and 11 are used also and 7 ,, which work in such a way that the voltage induced in the transformer between the emitter and collector of the switching transistor 1 has the potential at the point B connected. A point B of the connecting line drew point changes so that the control current is now 50 between the secondary windings 17 and 18 of the more ü1> er these circuit elements, for example 6 "control transformer with the base of the switching and 7 _a instead of the rectifier 30 and 5 flows, transistor connected. Furthermore, point B is with

The control works in such a way that the switching line between the resistors 8 transistor is permanently open by itself and first and 9 via a rectifier 13 and with the connec-

1 Oüü 44 /

Extension line between the resistors ίο and ii galvanically connected via a rectifier 12, the forward direction of these two rectifiers going in the direction of point B. The windings 14, 15 and 16 of the supply transformer are translated in a ratio of 1: 1: 1, for example.

The blocking works in this circuit as follows: With the specified polarity of the switching transistor ι are according to the interpretation of the
Windings of the supply transformer in seconds 10 17 and 18 the secondary windings of the control transformer

but can be, for example, V20 of the switching power of the switching transistor. The control transformer only needs to be designed for the much lower control power of the switching transistor 1, its power is then, for example, only V2000 of the switching power of the switching transistor. For this reason, a circuit according to FIG. 4 is advantageously provided in the cases mentioned, in which with ι again the controlled switching transistor and with

Därwicklungen 14 and 15 induced voltages, the are equal to or greater than the reverse voltage of the switching transistor 1. This calls the winding 14 caused voltage produces a current, deir

mators (or the arrangement of FIG. 3) are designated. In this circuit there are control transistors 21 and 22 are used, to which feed windings. 23 and 24 are assigned, which are

Via the resistor 9 and the rectifier 13 15 ment 25 one between the collector and emitter of the

can flow. In this case, however, occurs at the rectifier 13 only one voltage corresponding to the threshold value of the rectifier, which is also used as the base voltage on Switching transistor 1 occurs. Thus the switching

Switching transistor 1 lying feed transformer fed will.

With the polarity shown in FIG. 4, the control transistor 22 is blocked and the control transistor

Block transistor 1 when the threshold value of the span 20 21 is open, so that the switching transistor 1 has a base

Voltage from the rectifier 13 is lower than the voltage of the emitter layer E against the base of the switching transistor. On the other hand, a voltage is induced in the winding 15, which at the switching transistor 1 in

potential that corresponds approximately to the emitter potential. When a control voltage is induced with the The switching transistor 1 opens as indicated in the polarity in the secondary winding 18 of the control transformer

the indicated sense of polarity acts and because of 25 and thus allows a current flow in no further darder blocking effect of the rectifier 12 through
that formed by this and the resistor 11
Circuit cannot drive current. So it lies
between the base and the collector K of the switching

set load circuit. For reasons of symmetry it again follows that if the polarity is reversed, am Switching transistor 1 the effect of the circuit is retained, since then the other control transistor

transistor ι the voltage of the secondary winding 15, 30 is open.

prevents the collector voltage from affecting the primary winding 25 of the supply transformer

which then prevents the full-electric voltage from driving a current through the resistor 8, the rectifier 13 and the resistors 11 and 10, which would change the potential of B in such a way that the transistor opens by mistake.

To open the switching transistor 1 by a control pulse, it is necessary for this reason, a to induce additional voltage which counteracts the voltage on the winding 15. This can e.g. B.

can be connected directly to the alternator (not shown) in the event of an ohmic load and does not need to be tapped at the collector and emitter of the switching transistor 1, as shown. With the circuit discussed so far, inductive load and when switching the AC circuit difficulties arise, for example from the phase shift between current

by a series winding 17 of a control 40 and voltage. To avoid this you can

transformer happen. Another way to open the transistor is that on Place the control transformer with the windings 17 to 19 in the connection line between the

advantageous except for the control winding 18 in series with of the feed winding 24 another winding i8 “des Control transformer can be provided, which supplies such an additional voltage that the

Point B and the base of the switching transistor 1 a 45 fende control transistor and thus also the switching

Arrangement 20 is provided, which consists of a transformer 2o _a and a rectifier arrangement 20 ,, in a Graetz circuit.

From the circuit it can be seen that in both

transistor is opened even if the voltage on the primary coil 25 alone would not be sufficient for opening. The same applies to the other circuit, in which a control _{circuit 17 a of} the control cases because of the symmetry of the circuit also with 50 transformer in series with the supply winding 23 reversal of the potential at the switching transistor 1 is located.

desired effect is achieved. The difference Another simplification of a circuit arrangement

in the use of the control transformer or the voltage for operating symmetrical transistors is in arrangement 20 only that when using Fig. 5 is shown in which the supply transformer with a control transformer always only a half-wool 55 of its windings 23, 24 and 25 in omission is allowed to come through, while when using the approach, only the two correspondingly designed order 20 can pass through both half-waves. These windings iy _a and i8 _{a of} the control transformer can be made clear in a simple manner, in which it is seen that the task of the supply transformer is taken over by the circuit elements mentioned for the with. A further exemplary embodiment of the instant under consideration by equation 60 is shown in FIG. 6, in which the corresponding polarity is used to control the voltage sources. Switching transistor only a single control transformer The circuit shown in FIG. 3 can be very expensive in the case of mator with its secondary windings 17 and 18 large transistors, in particular. The necessary current distribution, especially when it comes to alternating current circuits, the transistors 21, 22, 1 are controlled by a lower frequency, since the required 65 resistors 26 and 27, 28, as is known, connect the resistors 26, 27 to transformers correspondingly larger the base of the control transistors 21 and 22 must be measured. The dimensioning of the supply with the potential point B in the connecting line transformer according to Fig. 3 is namely for the voltage between the two control windings 17 and 18. The switching transistor 1 and the control dimensioning of these resistors can advantageously be designed so that the current of the switching transistor, its power 70 be designed that the resistance ratio of 26

Claims (11)

1 ÜUÜ 44 / or 27 to 28 corresponds approximately to the current gain factor. P A T] ■; X j A X S P H Γ CHE: ι. Control circuit for symmetrical transistor, which is provided in an AC circuit as a switching transistor and as a function of Occurrence of control variables is controllable, characterized in that between the base and each outer electrode (collector or emitter) of the switching transistor (1) control means arranged in this way are that the switching transistor is permanently blocked in the idle state of the control means. 2. Control circuit according to claim 1, characterized in that that the control means via control transistors controlled by them as a function of the base potential of the switching transistor in the opening Affect the senses. 3. Control circuit according to claim 1, characterized in that that the control means serve together with to feed the circuits formed by the base and the external electrodes Means using resistors and / or control transistors affect the base potential. 4. Control circuit according to claims 1 and 2, characterized in that the base with each of the outer electrodes of the switching transistor via a common one connected to the base Resistance due to the series connection of a control transistor with a secondary winding a control transformer is in connection and the bases of both control transistors via each another resistor to the connection line between the two secondary windings of the control transformer are connected. 5. Control circuit according to claim 4, characterized by such a dimensioning of the individual resistors that the resistance ratio of each of the respective control transistor associated resistor (26, 27) and the resistor (28) associated with the switching transistor corresponds approximately to the current amplification factor. 6. Control circuit according to claims 1, 2 and 4, characterized in that if omitted of the resistance assigned to the switching transistor instead of the resistance assigned to the control transistors a further second secondary winding of the control transformer is provided for each of the two resistors is. 7. Control circuit according to claims 1, 3 and 6, characterized in that in series with every second secondary winding of the control transformer one secondary winding each Supply transformer is arranged with such a connection of the three each assigned to a control transistor. Secondary windings of the control and supply transformer that the effects of these windings with respect to those of them and support the respective control transistor formed circuit. 8. Control circuit according to claim 7, characterized in that the primary winding of the supply transformer is connected to the two outer electrodes of the switching transistor. 9. Control circuit according to claim 7, characterized in that in the event of a purely ohmic Load on the AC circuit directly affects the primary winding of the supply transformer is connected to the alternator feeding the alternating current circuit. 10. Control circuit according to claims 1 and 3. characterized in that the base of the switching transistor with the two outer electrodes of the switching transistor via series-connected secondary windings of a feed and a Control transformer and two resistors in series is connected and in parallel to the series connection of the two co-operating windings and a resistor in each case a rectifier is located, the forward direction of the rectifier on the connection point the base line is directed to the secondary windings. 11. Control circuit according to claims 7 and 10, characterized in that in place of the Secondary windings of the supply transformer in the two base electrode circuits of the Control transistors or the switching transistor one of the secondary winding of the supply transformer dependent direct current source - its negative pole to the base of the switching transistor is connected - in which the base of the switching transistor with the secondary windings of the Control transformer connecting line is provided. 1 sheet of drawings © 609 740/148 12. 56