DE1162451B - Arrangement for setting the response threshold of a ripple control receiver - Google Patents

Description

Arrangement for setting the response threshold of a ripple control receiver There are methods and devices for receiving from the power network superimposed Control signals become known in which these control signals are initially in filters be separated from the heavy current and then control an auxiliary voltage source in such a way that that on the one hand a predetermined minimum response voltage is required and that on the other hand, the effect of the screened control pulses is limited in terms of amplitude will. It would be advantageous if, in addition to limiting the control pulses, by which a certain minimum necessary control pulse duration even with large control signals is enforced, the responsiveness of the receiving devices the size of the interference level present in each case could be influenced, as is the case with HF receivers is already known.

The invention now relates to an arrangement for setting the response threshold of a ripple control receiver depending on the interference level at the interference voltages Via a resonance transformer, a capacitor forming the response threshold charge, and is characterized in that the charging voltage of the capacitor the signal voltage at the base of a transistor is opposite.

On the basis of the description and the figures, the inventive Process and exemplary embodiments for this purpose are explained. F i g. 1 shows a circuit diagram a device, FIG. 2 shows a variant of the circuit diagram according to FIG. 1, F. i g. 3 shows a further circuit variant according to FIG. 6th

In a receiving device according to FIG. 1 the terminals 11, 12 connected to the power network and protected with a fuse 13. A first series resonant circuit with the primary winding 17 of a band filter 10 and one Capacitor 19 is set to the frequency of the control pulses to be processed by the receiver, for example, tuned to 1050 Hz. So there are preferably signals of this Frequency in the band filter 1.0 induced on its secondary winding 18. This secondary winding 18, together with another capacitor 40, also forms one of the aforementioned Frequency-tuned parallel resonant circuit, so that the pulses with the control frequency are even more preferred.

A second series resonant circuit with a capacitor 14 and the primary winding 15 of a transmitter 20, on the other hand, is very much on the frequency of one in the associated network pronounced interference voltage U "matched, for example to a strongly protruding 19. Mains harmonics, corresponding to 950 Hz, at a mains frequency of 50 Hz. The Response voltage of the receiving device is now according to the size of this Interference voltage Ud controlled.

For this purpose, the secondary winding 16 of the transformer 20 operates on a rectifier and storage arrangement with a rectifier 24, a first storage capacitor 23 and a resistor 22, as a result of which a control DC voltage Ur occurs on the storage capacitor 23. Storage capacitor 23 and resistor 22 operate with a time constant TS. A first voltage-dependent resistor 21 parallel to the secondary winding 16 limits excessively large interference pulse peaks, which could result in excessive charging of the storage capacitor 23. In addition to the control pulses Ust induced in the secondary winding 18, the control DC voltage U i occurring at the charging capacitor 23 is now present. Connected in series in such a way that the AC voltage variable effective at the base-emitter path of a transistor 28 represents the difference between the control pulse voltage Ust and the control DC voltage U i. The emitter of the npn transistor 28 operates via a rectifier 31 to a further memory circuit with a charging capacitor 32 and a resistor 33, the time constant TL of which is substantially greater than the time constant TS.

The alternating voltages occurring at transistor 28 call -as soon they exceed a threshold given by a diode 27 - by a resistance 30 amplitude-limited charging current pulses I, 1, which the charging capacitor 32 to the charging voltage U, .1. Since the mentioned charging current pulses I, 1 are not further depend on the size of the alternating voltage at the emitter - if this is the mentioned Has exceeded the threshold value, the charging speed remains with which the charging capacitor 32 is charged, always the same.

A relay 34 is connected in series parallel to the charging capacitor 32 Valve 36 and the closed switch section of a switch 35. The valve 36 represents a semiconductor element with falling current-voltage characteristics, which is non-conductive at a voltage below a defined breakover voltage is, however, suddenly in the conductive state when this breakover voltage is reached passes and thus the storage capacitor 32 suddenly discharges. There too the relay 34 is traversed by this current surge, it attracts and sets the changeover switch 35 in the other position, whereby the motor 38 is connected to the mains voltage and consequently starts up. A switch 37 actuated by the motor 38 then performs the function of the actual recipient.

Without the valve 36, which the maximum possible charging voltage U, .1 limited to the value Uk, the charging voltage U, I would be one of the control voltage U, t independent final value E determined by the voltage divider 25, 26 strive.

A variant of the receiver circuit is shown in FIG. 2. In the same are first of all the input resonant circuits and the rectifier and storage arrangement for generating the control DC voltage U, the same as in FIG. 1.

Instead of the transistor 28, however, a controlled ion tube 50 is used to supply the charging current. The properties of the tube 50 result in the following advantages over the transistor 28: The tube exhibits a pronounced tilting effect, ie when the voltage at the control electrode rises, the tube suddenly changes from the blocked state to the conductive state. In addition, the tube current is maintained for the duration of each positive half-cycle of the alternating voltage U ". This enables a much faster charge of the charging capacitor 32. In addition, a discharge tube 51 is included in FIG nothing changes.

F i g. 3 shows, as a further embodiment, a push-pull circuit of the secondary-side resonant circuit 18, 40 of the band filter 10 and the use of two transistors 28 'and 28 " The charging time for the call charging of the storage capacitor 32 can therefore be shortened further.

Claims (3)

Claims: 1. Arrangement for setting the response threshold of a ripple control receiver depending on the interference level at the interference voltages charge a capacitor forming the response threshold via a resonance transformer, characterized in that the charging voltage (U,) of the capacitor (23) of the Base of a transistor (28) lying signal voltage (U ,,) is opposite. 2. Arrangement according to claim 1, characterized in that the charging voltage (U,) of the capacitor (23) is opposite to the signal voltage (U ") lying on the control electrode of a controlled ion tube (50). 3. Arrangement according to claim 1, characterized in that the charging voltage (U,) of the capacitor (23) is opposite to the signal voltage (US,) lying at the bases of two push-pull transistors (28 ', 28 ") Publications: German Auslegeschriften No. 1071 775. 1067084.