HU187264B - Protection circuit for overload protection of transistor switching circuit - Google Patents

Abstract

The overload protection circuit, for a transistor switch, employs a thyristor to protect the switch. The transistor is unaffected by unwanted voltage spikes originating from the thyristor. An auxiliary transistor (T2) is connected in series with the protection thyristor (Th) and conducts only when the thyristor is conducting. The thyristor is shunted by a capacitor (C2) which may be in series with a protective resistor (R4). The auxiliary transistor's base may be connected to its own potential source (U') at the same time as the switching transistor's base is connected to its own source, i.e. ground. The circuit may be used in telephone exchanges where signals currents from low impedance current sources are connected to lines via transistor switches.

Description

BACKGROUND OF THE INVENTION The present invention relates to a protective circuit for overload protection of a transistor switching circuit, wherein a short-circuit circuit is connected to the control input of the transistor circuit circuit, and a short-circuit circuit includes a thyristor.

The problem of overload protection of a transistor switching circuit is often raised when an overload hazard can occur due to a malfunction, for example due to too low a load resistor in the load circuit or too high a load capacitance resulting in too high switching current surges. This problem is particularly common in telecommunication technology when signaling currents from low-resistance power supplies need to be connected to a cable using a transistor switching circuit.

There are two options for protecting transistor switch circuits against overload, namely using electronic load current limiting or controlling circuits, or using a switching element, such as a thyristor, that short-circuits the control transistor input of the switching transistor.

The disadvantage of using an electronic load current limiting or regulating circuit is that these electronic circuits draw relatively high power during the time when the permissible load is exceeded and immediately after the overload, so that normally the power that can be switched without the risk of overload is limited to a value , which is less than the power that can be switched with the electronic switching device. In addition to this disadvantage, when using a transistor switching circuit, it is not clear whether an appreciable signal or signal portion has been transmitted during or immediately after overloading.

In these cases, it is more advantageous to use a thyristor which, when overloaded, short-circuits the input of the switching transistor because after a short period of time depending on the time constant of the thyristor's collection circuit, the load current disappears rapidly and completely. it can switch as it is built into a limiting or regulating circuit or, in the case of signal currents, this power can be obtained from a power source with significantly lower internal resistance. In addition, it is advantageous for the je current to be transmitted more clearly because there is no signal current to be transmitted in the event of an overload, especially not after the overload is removed during the signal stream since the ignited thyristor stays on until the current signal is completed.

In practice, however, such an overload protection method has the disadvantage of interfering voltage peaks from the load circuit, i.e. the line between the anode and the cathode of the thyristor, for example due to a sudden charging or discharging of a capacitance or possibly due to a power surge. which causes the thyristor to ignite even though no overload has occurred.

It is an object of the present invention to provide a circuit breaker as defined in the introduction, which cannot be influenced by undesired disturbance voltage peaks, but provides effective protection against overloads by means of a thyristor.

The object of the present invention has been achieved in that the collector emitter section of the auxiliary transistor is connected in series with the thyristor in the short circuit, the base of the auxiliary transistor is connected to a voltage divider which is connected is led.

In another preferred embodiment, the voltage divider is coupled between a pole of an additional voltage source via a thyristor and auxiliary switch, and the actuator of the control switch and the auxiliary switch are mechanically connected.

In this latter preferred embodiment, the voltage divider is practically completely independent of the line, so that the interference voltage peaks appearing therein cannot reach the voltage divider and thus cannot ignite the short circuit.

In the event that an independent voltage source cannot be provided to the voltage divider, a capacitor is preferably connected in parallel with the thyristor. It may also be advantageous to have a capacitor connected in series with the capacitor.

In a further preferred embodiment of the protective circuit according to the invention, the auxiliary transistor is connected in series to the emitter collector circuit of the auxiliary transistor.

The protective circuit according to the invention will now be described in more detail with reference to the embodiments shown in the accompanying drawings, in which

Fig. 1 shows a known transistor switching circuit which protects against overload by means of a thyristor and which forms the basis of the invention,

Figure 2 shows an improved transistor switch circuit according to the invention.

The transistor switch circuit of FIG. 1 may serve to apply the -U voltage to an emitter collector section 2137264 of an exemplary npn switching transistor T1, for example for signaling to a load resistor R1, e.g. a capacitance C1, such as the capacitance of the conductors, can be coupled in parallel with the load resistor R1. For this purpose, a control switch S is connected to the control input of the switching transistor T1, by means of which resistor R1 can be connected to the base of the switching transistor T1, in this example, to a ground potential and thus to the conductive state.

To prevent the Rl load being too low - for example. in the event of a disturbance - the load transistor T1 is too high, its emitter circuit contains resistor R2, which in the short-term overcurrent switches the ignition voltage Th through the integrating RC member consisting of resistor R3 and capacitor C1 shortly after the permissible load current is exceeded the thyristor Th is coupled to the control input of the T1 switching transistor and, after the resistor R1, to the emitter and base of the T1 switching transistor. Under normal operating conditions, the Th thyristor remains inactive, but when overloaded, as mentioned above, ignites and short-circuits the control input by closing the transistor T1 and rapidly releasing the load current. The thyristor Th then stays on until the control switch S re-opens and re-ignites when the overload has been removed.

The presently described circuitry has the disadvantage that, at higher interference voltage peaks at the load resistor R1, a rapid voltage surge occurs at Th thyristyrone, which causes the Thyristor anode cathode transition to ignite and interrupt the load current or signaling.

In Fig. 1, a dashed line capacitor C2 and a resistor R4 connected in series are coupled in parallel with the control input for the purpose of filtering any voltage surge occurring on the Th thyristor. However, this has the disadvantage that the capacitor C2 is coupled parallel to the base-emitter transition of the switching transistor T1, and since the capacitor C2 must be relatively large at low load resistances R1 to filter out the desired voltage jump, The base of the T1 switching transistor produces a flat impulse rise, so that the T1 switching transistor is already overloaded at normal load due to the slow passage of the hyperbolan at higher load currents.

FIG. 2 illustrates an embodiment of the transistor switch circuit of FIG. 1 in accordance with the present invention, which avoids the difficulties described above. The components of the transistor switching circuit already shown in FIG. 1 have the same designations in FIG. According to the present invention, a short circuit comprising a thyristor connected to the drive input of the switching transistor T1, in which the collector-emitter transition of an auxiliary transistor T2 is connected in series with the thyristor and is connected to the base divider V of resistors R5 and R6. The voltage divider is connected between the thyristor Th and the control switch S connected to the control input. The resistors R5 and R6 are selected to have a conductive potential at the base of the auxiliary transistor T2 when the thyristor is lit. In this way, the control input of the transistor T1 is short-circuited by the ignited thyristor Th and the auxiliary transistor T2; in contrast, the Thyristor Th is normally unlinked from the switching transistor T1 and hence the interference voltage peaks from the load side cannot influence its condition. In particular, in order to avoid interruption of the thyristor voltage in the T1 switching transistor power supply, and in the T1 switching power supply, and in the T1 switching circuit, a particularly strong interference voltage peak is obtained a capacitor C2 with which, optionally, a resistor R4 is connected in series. The C2 capacitor filters the rapid voltage changes on the Th thyristor. Contrary to the known switching of Fig. 1, capacitor C2 does not reduce the signal slope because thyristor Th and capacitor C2 are thus uncoupled from switch T1 via auxiliary transistor T2. Of course, the R5 and R6 resistors must be selected for high value.

The resistor R6 connected in series with the base emitter transition of the auxiliary transistor T2 and the resistor R5 connected in parallel with capacitor C2, optionally together with resistor R4, determine the slope of the voltage surge on the thyristor if the voltage is disturbed. If the interference voltage peak comes from the load circuit of the transistor T1, which may be a conductor, for example, resistor R1 is effective in addition to resistor R6.

The mentioned non-coupling of the Th thyristor and the RC member discussed above work together to suppress the interference voltage peaks and, on the other hand, to close the transistor emitter collector of the T1 switching transistor with a higher ramp and thus a lower loss in case of significant overload. will. In addition, it also ensures that the transistor switching circuit operates at a higher ramp slope and therefore less power loss.

The short-circuited state of the control input of the transistor T1 after an overload hazard is maintained as long as the control switch S is closed. If the overload hazard occurs only during a short-term fault, it is again possible to switch the -U voltage (or + U in the case of a pnp transistor) to the load resistor Rl via the next overload control test. wire of.

In a preferred embodiment of the protective circuit according to the invention, a Zener diode ZD1 is placed in the common branch of the control circuit of the transistor T1 and the short-circuit to increase the closing safety. From the load side, the polarity of the coupled is to better filter out high interference voltage peaks in which the collector base transition of the auxiliary transistor T2 can become a conductor and hence the said interference voltage peaks reach the auxiliary transistor T2 and resistor T collector transition, a diode D2 is connected in series. In addition, a diode D1 which suppresses extremely high interference peaks can also be inserted in the load circuit.

Finally, a Zener diode ZD2 and a resistor R7 can be placed in the ignition circuit of the Thyristor after the RC member consisting of the aforementioned R3 resistor and C1 capacitor.

Finally, the dashed line in Fig. 2 indicates that the voltage divider consisting of resistors R5 and R6 is not connected to the control input, but is connected to a voltage source U 'independent of other voltage sources via an auxiliary switch S'. The auxiliary switch S 'operates synchronously with the control switch S, which can be achieved, for example, by being mechanically connected to one another via their actuator. As a result, the voltage divider consisting of resistors R5, R6 is completely uninsulated from the line as a potential source of interference.

Claims (5)

1. Circuit Breaker for Overload Protection of Transistor Switch Circuit with Short Circuit Connected to Control Input of Transistor Switch Circuit 10 and a thyristor in the short-circuit, characterized in that the collector-emitter section of the auxiliary transistor (T2) is connected in series with the thyristor (Th) in the short-circuit, the base of the auxiliary transistor (T2) being It is connected to the dividing point (V) of 15 voltage dividers (R5, R6), which voltage switch (R5, R6) is connected between the thyristor (Th) and the control input and via the control input control switch (S) One of its 20 poles is led. 2. Protective Circuit to Protect Transistor Switch Circuit against Overload with Short Circuit Connected to Transistor Switch Circuit Control Input 25 and a thyristor in the short-circuit, characterized in that the collector-emitter section of the auxiliary transistor (T2) is connected in series with the thyristor (Th) in the short-circuit, the base of the auxiliary transistor (T2) being Connected to the dividing point (V) of a voltage divider (R5, R6), one pole of a voltage source is connected to the control input control switch (S), and a voltage source (R5, R6) is connected to the thyristor (Th) and auxiliary switches (S ') It is connected between one pole (U ') and the actuator of the control switch (S) and the auxiliary switch (S') are mechanically connected to each other. 40 An embodiment of a protective circuit according to claim 1, characterized in that a capacitor (C2) is connected in parallel to the thyristor (Th). The protective circuit according to claim 3 45, characterized in that a resistor (R4) is connected in series with the capacitor (C2). 5. An embodiment of a protective circuit according to any one of claims 1 to ^5, characterized in that a diode (D2) is connected in series to the emitter collector circuit of the auxiliary transistor (T2).