DE2409887C3 - Control circuit - Google Patents

Description

The invention relates to a control circuit for interrupting a connection between a power amplifier and a loudspeaker when switched off an AC source by opening a power switch with an between the amplifier and the loudspeaker lying switching device and at least one of a blocking state in a conducting state controllable element.

A control circuit of the type mentioned is already known from DT-OS 22 17 523. The interruption the connection between the power amplifier and the loudspeaker when switching off the AC power source as a result of opening a power switch is in the known control circuit in Executed as a function of the output signal of the amplifier, the output signal of the amplifier is monitored and exceeds a certain value

In the DT-AS 12 99 328 there is an overload protection circuit for loudspeakers described in which when a specified for the consumer is exceeded Power limit the connection between the amplifier and the loudspeaker is interrupted. the Exceeding a predetermined power consumption value of the loudspeaker leads to activation a relay and a break in the connection between loudspeaker and amplifier.

In contrast, the invention is based on the object of providing a control circuit of the type mentioned at the beginning Kind of creating an undesirable noise when turning off an AC power source prevented by the loudspeaker as well as overloading the loudspeaker.

According to the invention, this object is achieved in that the controllable element is a relay control transistor is operative with a smoothing filter to provide a first smoothed voltage to the Amplifier is connected and fed by the smoothing filter with a first preset potential is, wherein the smoothing filter is connected to a rectifier circuit that the control transistor is conductive when the power switch is closed that a relay connected to the control transistor to establish the connection between the amplifier and the loudspeaker by actuating the Switching device is controlled when the transistor is conductive, the transition time of the smoothing filter in reducing the first smoothed voltage to one below the first preset

Potential value when the AC power source feeding the rectifier circuit is switched off is large, so that a circuit connected to the control transistor is provided which has a circuit with a time constant that is considerably smaller than the transition time of the smoothing filter when the AC source is switched off and controls the first preset potential to reduce the latter closed power switch to keep constant and to reduce the preset potentia ¹ when switching off the AC power source by cfis short time constant, so that the control transistor is non-conductive and the connection between the amplifier and the loudspeaker is quickly interrupted

Further refinements of the invention emerge from the subclaims.

The control circuit according to the invention advantageously contains a circuit with a small time constant that is independent of the output of the power amplifier, which responds when the power switch is opened and the connection between the amplifier and the Loudspeaker interrupts in a comparatively short time compared to the known circuits. The actual The signal path is not influenced in any way by the switching function when the power switch is opened, since the circuitry that opens the connection between loudspeaker and amplifier in a separate current path to the signal path is located.

In the following, preferred embodiments of the invention will be described in more detail with reference to drawings explained it shows

F i g. 1 a protection circuit with the inventive Control circuit,

F i g. 2 and 3 voltage diagrams to explain the mode of operation of the control circuit according to the invention and

F i g. 4 shows a protection circuit with a modified control circuit according to the invention.

In Fig. Figure 1 is a control circuit according to the invention in conjunction with a conventional one used therewith Circuit arrangement illustrated. A primary winding 5a of a transformer 5 is connected to an alternating current network 1 via a mains switch 3. The transformer 5 is conventional Manner trained; a full-wave rectifier circuit 10 is connected to its secondary winding 56, in which four diodes 11, 13, 15 and 17 are connected in series. The one supplied by the secondary winding 56 AC voltage is applied to a pair of opposite connection points 10a and 106 so that a DC voltage is obtained from the other pair of connection points 10c and 10d.

The rectifier circuit 10 is not based on the one shown in FIG. 1 limited bridge double-throw circuit shown; on the contrary, any other suitable rectifier circuit can be used.

The pulsating voltage supplied by the output of the rectifier circuit is applied to two in series connected capacitors 19 and 21 are applied, which are parallel to the rectifier circuit 10. From Fig. 1 it can be seen that a connection point between capacitors 19 and 21 is connected to ground. The delivered pulsating voltage is thus smoothed into a uniform DC voltage that can be applied to a Power amplifier 61 is suitable. Each capacitor 19 and 21 has a relatively large capacitance, e.g. B. 47Ο0μΡ, so that the smoothed voltage needs a long transition time to turn off the Power switch 3 to get into a steady state.

The power amplifier 61 is a directly coupled amplifier without an output capacitor and provides a speech current to a loudspeaker 65 connected to it. A relay control transistor closes as the next stage 29, whose collector 29c is connected to a collecting line 27 via a relay 25 is, which proceeds from the smoothing filter consisting of the capacitors 19 and 21. The relay 25 is provided to connect between the power amplifier 61 and the speaker 65 only to be fully established during his state of excitement. The base 296 of the control transistor 29 is over a resistor 23 is connected to the line 27 and receives from this a preset potential, so that the transistor 29 remains conductive as long as the power switch 3 is closed

A transistor 53, the collector 53c of which is connected to the base 296 of the transistor 29, is non-conductive, as long as the power switch 3 is closed, so that the Preset elite potential occurring at the base 296 is maintained during the closing time of the power switch 3 will. In the described circuit arrangement according to FIG. 1 would be without the dashed line Part to fear that the speaker 65 when opening the power switch 3 as a result of the loss the DC balance in the amplifier 6t generates a noise or that it is damaged, what from the already mentioned large transition time of the smoothed voltage due to the capacitors 19 and 21 with such large capacities would result.

This undesirable process is, however, indicated by the circuit 2 shown in dashed lines in FIG. 1, the mode of operation of which is described below. Another secondary winding 5c with a center tap 9 is connected to a full-wave rectifier 34 consisting of diodes 35 and 37. These two diodes 35, 37 alternately supply rectified current to the next stage, which is a smoothing filter consisting of a capacitor 39 and a resistor 41. The capacitance of the capacitor 39 is relatively small, e.g. B. 1 μΡ, and the value of the resistor 41, z. B. 5.6 ΚΩ, selected so that their time constant is 5.6 msec. It follows that when you open the power switch 3, the value of the rectified and filtered voltage decreases quickly. Thus, the screened voltage contains a number of undulations due to the short time constant, as indicated by the letter A in FIG. 2 is indicated, so that it must be flattened by suitable means before it is fed to the next stage. For this purpose, a tip clipper or tip limiter, which consists of a series connection of a resistor 43 and a Zener diode 45, is used in the present embodiment. The peak limiter prevents the positive amplitude of the wave from exceeding a set value. The opposite F i g. 2 limited or trimmed voltage is shown in FIG. 3 and is opposite to curve A in FIG. 2 limited to voltage B. The Zener diode used can be replaced by another suitable voltage limiting element.

The limited voltage B is applied to the base 496 of a transistor 49 via a base resistor 47, so that this transistor remains conductive. The collector 49c of the transistor 49 is connected to the line 27 via a collector resistor 51 and

which is connected directly to the base 536 of the transistor 53. As long as the power switch 3 is closed, the flattened voltage B is continuously supplied to the base 496 due to the fact that the potential of the base 536 is almost zero because the transistor 49 is conductive. The transistor 53 is consequently non-conductive as long as the power switch 3 is closed. Therefore, the potential at the base 296 is kept at the preset value, as explained in detail above.

If the power switch 3 is opened, then the The value of the voltage to be screened by the capacitor 39 and the resistor 41 decreases rapidly; for the limited voltage applied to base 496 of transistor 49 is the same. The transistor 49 therefore becomes non-conductive due to insufficient potential at its base, whereby the following transistor 53 is influenced in such a way that it becomes conductive by supplying a suitable base potential. The base 296 is then inevitably connected to earth, from which it follows that the transistor 29 quickly becomes non-conductive. It should be noted that the voltage appearing on the line 27 is due to the large transition time mentioned above slowly decreasing As a result, the relay 25 is deactivated and quickly breaks the connection between the power amplifier 61 and the speaker 65.

The control circuit according to the invention was explained in connection with a circuit that has a Transformer 5 This transformer 5 is not absolutely necessary for the AC voltage down to a desired value. When not using the transformer 5 however, the full-wave rectifiers 10 and 34 must be replaced by half-wave rectifiers.

In Fig. Figure 4 illustrates a modified embodiment of the invention; equal parts are in F i g. 4 with the same reference numerals as in FIG. 1 referred to

According to FIG. 4, a differentiating circuit 87 is connected to the amplifier 61, the amplifier 61 the receives unbalanced voltage and provides an output signal which is proportional to the voltage is at the base of a transistor 85, which in turn becomes conductive under the condition that the applied thereto Voltage exceeds a predetermined value. The base 536 of transistor 53 is through a resistor 83 and the transistor 85 connected to the line 27, while the cathode of a diode 81 to the Base 536 and its anode is connected to the collector 49c, so that the potential of the base 536 to the mentioned preset value can be increased, which is sufficient to make the transistor 53 conductive. the Diode 81 prevents the collector current of transistor 85 from flowing into collector 49c of transistor 49 As in connection with F i g. 1 has been described, the transistor 53 remains blocked as long as the power switch 3 is closed. As a result, the relay 29 is energized, so that the connection between the power amplifier 61 and the speaker 65 is completely manufactured. The appearance of the unbalanced Voltage in the directly coupled power amplifier 61 causes the connection is instantly interrupted even if the power switch 3 is closed, so that the speaker 65 is protected against too high a direct current. The circuit according to FIG. 4 indicates when opening the Power switch 3 works in the same way as the embodiment according to FIG. 1 on when the current blocking Diode 81 is arranged in the manner described.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Control circuit for interrupting a connection between a power amplifier and a loudspeaker when switching off an alternating current source by opening a power switch with a switching device located between the amplifier and the loudspeaker and at least one controllable element from a blocking state to a conducting state, characterized in that the controllable element is a relay control transistor (29) which is operatively connected to a smoothing filter (19, 21) for supplying a first smoothed voltage to the amplifier (61) and is fed by the smoothing filter with a first preset potential, the smoothing filter is connected to a rectifier circuit (10), that the control transistor (29) is conductive when the mains switch (3) is closed, that a relay (25) connected to the control transistor (29) to establish the connection between the amplifier (61) and the speaker (65) by actuation g of the switching device (63) is activated when the transistor is conductive, the transition time of the smoothing filter (19, 21) when the first smoothed voltage is reduced to a value below the first preset potential when the rectifier circuit (10) is switched off AC power source is large that a circuit (2) connected to the control transistor (29) is provided which has a circuit with a time constant that is considerably smaller than the transition time of the smoothing filter (19, 21) when the AC power source (1) is switched off and the first preset potential controls to keep the latter constant when the mains switch (3) is closed and to reduce the preset potential quickly when the AC source (1) is switched off by the short time constant, so that the control transistor (29) becomes non-conductive and the connection between the amplifier (61 ) and the loudspeaker (65) quickly interrupts. 2. Control circuit according to claim 1, characterized in that the circuit is smaller Time constant containing circuit (2) a rectifier circuit (34) for converting the AC voltage into a second rectified DC voltage and a rectifier circuit to this (34) connected smoothing filter (39, 41) for generating a second, smoothed voltage has that the second smoothing filter (39, 4i) contains the circuit with a small time constant, that in the circuit (2) a peak limiter SS (43, 45) is provided which is connected to the second smoothing filter (39, 41) is connected, derives the smoothed second voltage and thereby flattens it, that a voltage part exceeding a preset value is cut off, and that with the peak limiter (43, 45) a control device (49, 53) for the delivery of the limited Voltage is connected, which is connected to the control transistor (29) and the first preset Potential! Controls so that the control transistor (29) is conductive when the control device (49, 53) is fed with the limited voltage. 3. control circuit according to claim 1 or 2, characterized in that the control device consists of two transistors (49,53) 4. Control circuit according to at least one of the preceding claims, characterized in that that to the amplifier (61) a differentiating circuit (87) is connected, which via a Transistor (85) with the control device (49,53) in Connection 5. Control circuit according to claim 4, characterized in that between the two transistors (49, 53) of the control device a diode (81) is provided, the cathode of which via a resistor (83) is connected to the collector of the transistor (85) connected to the differentiating circuit (87) is