DE2530145C3 - Circuit arrangement for the protection of several amplifiers connected in parallel - Google Patents

Description

The invention relates to a circuit arrangement according to the preamble of claim 1. A Such a circuit arrangement is known from AEG-Mitteilungen 41 (1951), pp. 240, 241, the Amplifiers are formed by mercury vapor rectifiers in a power converter system.

A power converter system with thyristors is also known from BBC-Nachrichten 46 (1964), pp. 414 to 416 as parallel-connected amplifiers, which have a total of fuse switching means in the form of Fuses are connected to an operating voltage source. There are also controllable Switching means are provided in the supply lines for the operating voltage, which at the same time block the thyristors, when an overload occurs because the output current exceeds a set point. With this If only one amplifier or a few amplifiers are overloaded, it is not possible to turn them off by themselves, but keep the other amplifiers working.

This object is namely to be achieved with the invention and automatically without great effort jo should be avoided that if an amplifier fails, the output of this amplifier the Outputs of the remaining amplifiers additionally loaded or short-circuited.

This object is achieved by a circuit arrangement having the features of claim 1. Further developments and advantageous embodiments of the invention are specified in the subclaims.

The invention is explained in more detail using an exemplary embodiment that is shown in the drawing «N explained. It shows

F i g. 1 shows a block diagram for the circuit according to the invention and

FIG. 2 shows an exemplary embodiment for one in the circuit according to FIG. 1 control circuit used.

In Fig. 1 is a block diagram for the inventive Circuit shown, on the basis of which the principle of the invention is explained. To feed a Loudspeaker 11 in an acoustic Bosch sound system a line 22 is provided to which the outputs 6 and 16 of two amplifiers 4 and 14 can be switched on. The circuit shows only two amplifiers. In itself the number of parallel switched amplifier any, d. H. selected according to the power to be delivered to the loudspeaker U will.

The amplifier 4 is connected to the operating voltage Ub applied to the terminal 1 via a fuse switching means 2, which in the simplest case consists of an automatic current fuse. The safety switching means can also consist of a controllable electronic circuit to which a corresponding control voltage is applied in the event of a fault.

The connection point 3 between the fuse 2 and the power supply connection of the amplifier 4 is connected to the first input 7 of a control circuit 9. This control circuit 9 has a second input 8, which is connected to a signal output 5 of the

Amplifier 4 is connected The amplifier 4 is provided with a standard automatic protective device, in the event of overload, the amplifier 4 z. B. protects by the fact that its input is short-circuited. A voltage derived from this protective device is fed to the output 5 of the amplifier 4, see above that at this output 5 a signal only appears when the protective device in case of overload or also addressed shortly before

The control circuit 9 is constructed in such a way that a signal or a control voltage only appears at its output 23 if a signal appears at the connection point 3 and if no signal appears at the output 5 of the amplifier 4 AND circuit on, where η is then inverted within the control circuit 9, the output signal of the output 5 of the amplifier 4 or at the output 5 of the amplifier 4 only a signal appears when the automatic protective device of the amplifier 4 is not active In each of these cases appears only then a control signal at the output 23 of the control circuit 9 when both the amplifier 4 is connected to the line 21 with the operating voltage source Ub (terminal 1) and the automatic protective device of the amplifier 4 has not yet responded.

With the aforementioned control voltage, a controllable switch 10 is switched to conduct current, the between the NF useful signal output 6 of the amplifier 4 and the loudspeaker 11 to be fed is arranged.

It can be seen that the amplifier 4 is only connected to the loudspeaker 11 when it is ensured that it is supplied with the operating voltage and that it is not already overloaded.

According to the amplifier 4 is a second amplifier 14 with its output 16 via a controllable switch 20 is connected to the feed line 22 for the loudspeaker 11. To control the Switch 20, a control circuit 19 connected to switch 20 via its output 24 is provided, which is constructed in the same way and acts in exactly the same way as the control circuit 9, the input 17 of the control circuit 19 to the connection point 13 of the power supply connection of the amplifier 14 with a fuse 12 is connected. The second input 18 of the control circuit 19 is via the output 15 of the amplifier 14 is connected to its automatic protective device.

In Fig. 2 is an advantageous embodiment of the Control circuit 9 shown in FIG. At the input terminal 7 of the circuit according to FIG. 2 just lies then a signal voltage when the corresponding amplifier is supplied with the operating voltage. At input terminal 8, on the other hand, only has a signal voltage when the automatic protective device of the amplifier in question has responded, i.e. when there is a risk of overload.

The signal voltage at input terminal 7 is equal to the operating voltage, since this terminal - as in F i g. 1 - is connected directly to the power supply line of the assigned amplifier By means of a voltage divider made up of a Zener diode 28 and a resistor 29, the aforementioned signal voltage is generated divided down to a value with which a transistor 35 can be driven at its base. A resistor 30 is placed in the line leading to the base of this transistor as a protective resistor inserted.

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65, the transistor 35 is located with its collector connected through a load resistor 34 to the operating voltage Ub Its output voltage is conducted via a decoupling diode 36 to the base of a further transistor 38 which additionally via a protective resistor 31 and a further decoupling diode 32 from the input terminal 8 forth is controlled. Since the signal voltage applied to input terminal 8, which is derived from the automatic protective device of the assigned amplifier, is significantly lower than the signal voltage applied to terminal 7, there is no further voltage divider between terminal 8 and the base of transistor 38. A voltage which controls the transistor 38 is generated at the bleeder resistor 33 at the base of the transistor 38. The collector of the transistor 38 is connected to the operating voltage Ub via a load resistor 37. The output voltage of transistor 38 falling across this load resistor 37 directly controls a third transistor 39 at its base. Between the collector of this transistor 39 and the operating voltage, ie between the terminals 23, there is a relay 42 which controls the switch 10 in FIG. 1 represents. The diode 43 connected in parallel with the relay 42 is used to suppress induced voltage peaks when the relay drops.

The circuit described so far works as follows. If a signal voltage is applied to the input terminal 7, it controls the transistor 35 to conduct current via the voltage divider 28, 29 and the resistor 30, so that the collector of this transistor is almost ground potential.This ground potential only then reaches the base via the decoupling diode 36 of transistor 38, v. If a positive signal voltage is not applied to the base of the transistor 38 via the input terminal 8, the resistor 31 and the decoupling diode 32. The transistor 38 is therefore only activated with ground potential at its base and thus blocked when the operating voltage is applied to terminal 7 and no signal voltage is applied to terminal 8.

In this case, the transistor 39 is controlled to be conductive via the resistor 37, so that the relay 42 responds and its normally open contact, namely the switch 10 in FIG. 1, closes.

If either the operating voltage at terminal 7 drops out (overload of the amplifier power supply) or a signal voltage appears at terminal 8 (protective device of the amplifier responds) the transistor 38 is controlled to be conductive, which in turn has the consequence that the transistor 39 and thus the Relay 42 de-energized. The assigned amplifier is thus taken from the feed line 22 in FIG. 1 switched off.

The automatic protective device of the amplifier can be constructed in such a way that the outputs 5 and 15 of amplifiers 4 and 14 in FIG. 1 tapped signal voltage is generated before the overload occurs entry. This has the advantage that the protective circuit described does not only appear in the event of a fault responds, but shortly before. This means that the remaining seconds will not be available for a fraction of a second Amplifier endangered.

Finally, it is also possible to build the automatic protection circuit of the amplifier so that the Signal voltage at the outputs 5 and 15 of the amplifiers 4 and 14 in FIG. 1 even after it has been eliminated the disturbance (overload) for a certain time

can be tapped. This can be achieved in a simple manner by means of a delay circuit for the drop in the signal voltage. This measure has the advantage that the previously "disturbed" amplifier is only connected to the load again when it is fully functional again and therefore does not endanger the other amplifiers for a fraction of a second.
The circuit according to FIG. 2 has two lamps 26 and 27 to display the operating status of the two signal paths which control the control circuit 9. the operating voltage is present. The second lamp 27 is connected to the terminal 8. It lights up when the protective device of amplifier 4 has responded.

1 sheet of drawings

Claims (8)

Patent claims: 1. Circuit arrangement for the protection of a plurality of controllable switching means (10, 20) with their Outputs of amplifiers connected in parallel (4, 14), each with an automatic protective device (5,15) are provided against overload, each amplifier (4, 14) via fuse switching means (2, 12) is connected to an operating voltage source (1) and to generate a control variable for the controllable switching means (10, 20) each have a control circuit (9, 19) which is connected to their Output (23, 24) is only one that switches the switching means (10, 20) to the conductive state Emits control variable when the fuse switching means (2, 12) are conductive, characterized in that that the control circuit (9,? 9) with two inputs (7, 8 and 17, 18) to the automatic Protective device (5.15) and the security means (2,12) is connected and structured in such a way that it only specifies the control variable if the automatic protective device (5, 15) not due to overloading of the amplifier concerned (4, 14) is active. 2. Circuit arrangement according to claim 1, characterized in that an input (7, 17) of the Control circuit (9,19) to the connection point (3, 13) between the power supply connection of the amplifier (4, 14) and the associated safety switching means (2,12) is connected. 3. Circuit arrangement according to claim 1, characterized in that the control circuit (9, 19) as logical "AND" link is set up, at the first input of which a signal is only present, when the amplifier in question is connected to the operating voltage source, and to its A signal is only applied to the second input if the automatic protective device does not respond to a Overload of the amplifier responds. 4. Circuit arrangement according to claim 1, characterized in that the control circuit (9) has a first, the controllable switching means (42) driving switching transistor (38) contains, the base of which on the one hand to one generated by the relevant protective device in the undisturbed operating state Voltage (8) and on the other hand via an inverting second switch transistor (35) to one of the voltage derived from the operating voltage of the amplifier (7) is connected. 5. Circuit arrangement according to claim 4, characterized in that the collector of the first Switching transistor (38) is connected to the base of a third switching transistor (39) which the controllable switching means (42) controls. 6. Circuit arrangement according to claim 5, characterized in that the base of the second switching transistor (35) via a Zener diode (28) and an ohmic resistor (29) Voltage divider is connected to the operating voltage terminal of the amplifier concerned (4). 7. Circuit arrangement according to claim 4, characterized in that between the second switching transistor (35) and the first switching transistor (38) a first decoupling diode (36) is arranged, and that between the automatic protection device and the first transistor (38) another Decoupling diode (32) is arranged. 8. Circuit arrangement according to claim 1, characterized characterized in that means for delaying the fall of the automatic protective device generated signal voltage are provided.