DE1242703B - Control circuit for turning on and off telephone answering and call recording devices - Google Patents

Description

Control circuit for turning on and off telephone answering and call recorders The present invention relates to a control circuit for the automatic switching on and off of an electrical load for actuation of control circuits in telephone answering and call recording devices, e.g. B. a relay coil, depending on the presence or absence of signal pulses, e.g. B. speech impulses, using one of the impulses to be charged capacitor for controlling a switching device provided with a control element.

They are control circuits already operated by electrical signals become known, in which a constant electrical signal as well as intermittent electrical signals cause the load resistor to be switched on. For the For the purposes of telephone answering machines and call recorders do not use such known arrangements, because the device then with a constant telephone callsign would work continuously, even if the calling party would have hung up the phone.

It has also become known an arrangement in which the discharge a capacitor ignites a glow lamp in order to switch on a relay. The capacitor is charged by electrical impulses, which are not otherwise Own functions.

The present invention has now set itself the task of a To create control circuit of the type mentioned, through which a load remains on by intermittent electrical input signals and then turns off when either the time between these intermittent signals or the duration of a signal exceeds a certain maximum. The intermittent Input signals are derived from the received by the device from a calling party Language derived. The device is switched off if either the rest period after a speech period exceeds a certain maximum or after a call duration signal on the telephone line for a certain period of time is present.

The object is achieved according to the invention in that the Control member of the relay coil or other load to control the to switching device that switches on and off the said devices leading circuit is arranged in the charging circuit of a capacitor, so that this when flowing a Charging current is switched on, and that a second parallel to the capacitor Switching device is arranged, the control member of which can be influenced by the signal pulses is to turn on this switching device and thus the first switching device turn off.

An exemplary embodiment of the invention is to be described in more detail with reference to the drawing explained.

In the preferred switching arrangement shown in the drawing, one side of a capacitor 10 is connected via a resistor 12 to a negative terminal 14 of a voltage source. The opposite side of the capacitor is connected in series to the base of a transistor 20 via a rectifier 16 and a potentiometer 18. The emitter of this transistor is connected to a terminal, for example grounded, which is positive with respect to the negative voltage applied to terminal 14. A resistor 22 connects the base and emitter of transistor 20 to obtain a reverse voltage for it.

A second capacitor 24 is connected at one end between the rectifier 16 and the potentiometer 18 and at its opposite end connected to the positive voltage pole so that it is charged in series with the first-mentioned capacitor 10.

The charging path of the capacitor 10 is connected in parallel with a transistor 26, the collector of which is connected between the capacitor 10 and the resistor 12 and the emitter of which is connected to the positive voltage pole. The base and the emitter of the transistor 26 are connected to one another by a blocking resistor 28 to which a filter capacitor 32 is connected in parallel. As will be described in more detail below, this transistor circuit controls a discharge path for the capacitor 10 via a rectifier 30 whose positive pole is connected to the positive voltage pole and whose negative pole is connected between the capacitor 10 and the positive pole of the rectifier 16.

The base of the transistor 26 is connected to the signal input 38, 40 in the forward direction via a resistor 34 and a rectifier 36.

A relay winding 42 was assumed as the electrical load in the present exemplary embodiment, which is connected at one end to the collector of the transistor 20 and at its other end to the negative terminal 14 of the voltage source. Contacts 44, 46 of the relay operate the control circuits connected to terminals 48 and 50 in the telephone answering and recording device.

The operation of the invention is described below with reference to the drawing. When a telephone call arrives, operating voltage is applied to the control circuit. The capacitors 10 and 24 therefore begin to charge, which results in a current flow in the base-emitter circuit and in the emitter-collector circuit of the transistor 20. The emitter-collector circuit therefore acts as a switch in the circuit of the relay winding 42, the switch being actuated by the current flow in the base-emitter circuit. This energizes the relay winding 42 so that the associated contacts in the circuit of the device are closed.

The time required for the capacitor 10 to fully charge becomes determined by the setting of the potentiometer 18. This setting can be done via can be varied over a considerable range to achieve the desired charging time achieve. For example, it has a charging time of around 15 seconds for the shown to be desirable.

When the capacitor 10 has been fully charged, there is no longer any current flow in the charging circuit. The charged capacitor 24 then discharges via the potentiometer and the base-emitter circuit of the transistor 20, whereby the latter remains conductive for a short period of time, for example of about 3 seconds, for purposes explained in more detail below. After the capacitor 24 has completely discharged, the transistor 20 is blocked and the relay winding 42 is de-energized, the contacts 44, 46 open, and the circuit of the device is interrupted.

If the calling subscriber begins to speak his message during the charging time of the capacitor 10, the voice alternating current signal received at the input terminal 38 is rectified in the rectifier 36 and passed on to the base of the transistor 26 via the filter circuit. The transistor 26 is turned on so that the capacitor 10 can discharge through the emitter-collector circuit. In this way, the emitter-collector circuit of the transistor 26 acts as a switch in the discharge circuit of the capacitor 10, the switch being actuated by the current flow in the base-emitter circuit. When the discharge of the capacitor 10 begins, the capacitor 24 also discharges and continues to keep the transistor 20 conducting. The intermittent signal arriving at the input 38 must now be of such a nature and the time constant of the charging and discharging circuit of the capacitor 24 must be selected so that the relay 42 does not drop out due to an uninterrupted signal period that is too long because the capacitor 24 is completely discharged. A short discharge time of about 3 seconds for this capacitor has been found to be very suitable for normal speech.

If the speech signals are interrupted during a period which exceeds a certain period of time, for example approximately 15 seconds, the blocking of the transistor 26 for this period of time has the consequence that the capacitor 10 is fully charged. If the capacitor 24 is then also completely discharged, the transistor 20 is blocked and the relay 42 drops out. This state can occur, for example, when the calling subscriber has finished his message, but has not hung up the receiver within the interval of 15 seconds.

When the calling subscriber has finished his message and hangs up the receiver, a continuous signal on the telephone line causes the transistor 26 to be continuously conductive, so that the capacitor 10 is completely discharged. Since the capacitor cannot be charged as long as the transistor 26 is conductive, no more current flows in the base-emitter circuit of the transistor 20 after the second capacitor 24 has completely discharged, so that the relay 42 is de-energized.

The intermittent signal arriving at input 38 can be supplied in the form of a telephone message as described above or in the form of high-frequency pulses. The electrical load is turned off when the intermittent signal is replaced by a steady signal or no signal for a period of time determined by the setting of potentiometer 18 which determines the time constant for both capacitor 10 and capacitor 24.

Claims (7)

Claims: 1. Control circuit for the automatic switching on and off of an electrical load for the actuation of control circuits in telephone answering and call recording devices, e.g. B. a relay coil, depending on the presence or absence of signal pulses, e.g. B. voice pulses, using a capacitor to be charged by the pulses to control a switching device provided with a control member, characterized in that the control member (20 be) of the relay coil (42) or another load for controlling the leading to said devices Circuit (48, 50) on and off switching device (20 ce) is arranged in the charging circuit of a capacitor (10) so that it is switched on when a charging current flows, and that a second switching device (20 ce) is arranged parallel to the capacitor whose control element (26 be) can be influenced by the signal pulses in order to switch on this switching device (26c-e) and thus to interrupt the flow of the charging current to the capacitor (10) with the result that the first switching device ( 20ce) is switched off. 2. Control circuit according to claim 1, characterized characterized in that as controllable switching devices including their control members Transistors are used, their control element in each case through the base-emitter circuit and their switching device is formed in each case by the emitter-collector circuit will. 3. Control circuit according to claim 1, characterized in that a device (18) for changing the charging time, in particular an adjustable resistor, is provided in the charging circuit of the capacitor (10). 4. Control switch according to claim 1, characterized in that parallel to the control member (20 be) of the one switching device (20 ce) at the same time with the capacitor (10) to be charged second capacitor (24) is arranged so that its subsequent to the full charging and the beginning of the discharge of the first capacitor (10) via the control element (20 be) flowing discharge current causes the maintenance of the switched-on state of the switching device (20 ce). S. Control circuit according to Claims 3 and 4, characterized in that the for Adjustment device provided for changing the charging time of the first capacitor (10) (18) is arranged in such a way that it also leads to a change in the discharge time of the second capacitor (24) can serve. 6. Control circuit according to claim 1, characterized in that the control member (26 be) of the second switching device (26e-e) can be connected to a source (38) of intermittent audio-frequency signals. 7. Control circuit according to claim 1, characterized in that the control member (26 be) of the second switching device (26c-e) is used for connection to the circuit of a telephone connection. B. Control circuit according to claims 1 and 4, characterized in that a rectifier (16) is arranged in the charging circuit such that the discharge current of the second capacitor (24 ) is directed or displaced onto the base-emitter circuit of the first transistor (20) will.