DE1041574B - Audio frequency remote control, in which consumers connected to the network are controlled with the help of audio frequency pulses superimposed on a single frequency by the power supply network - Google Patents

Description

Audio frequency remote control with the help of the power supply network superimposed audio frequency pulses of a single frequency connected to the network Consumers are controlled With audio frequency remote control, for example at the so-called ripple control, with the help of audio frequency pulses in one AC voltage power supply network arranged consumers (street lamps, hot water tanks, Stairwell lighting, etc.). The audio frequency is at a transmitting station generated, fed into the power supply network and assigned by the consumers Receivers included. The receivers have a special input circuit for this purpose, with which they sift out the audio frequency from the network and other selection organs respectively. To be able to differentiate between the commands for the various consumer groups or for the individual consumer to create, be specific, according to a specific Emitted impulses scheme used. To control a specific consumer or a group of consumers, a very specific impulse pattern is required. The sound frequency serving as a carrier for the individual impulse images forms here a channel over which the individual commands are transmitted.

The known remote control methods have the disadvantage that the simultaneous Transmission of several different commands over one and the same channel is not possible is possible. So there must always first be a command as an impulse image that leads to his The transmission takes a few minutes to be completed before a new command is issued can be done. This obvious deficiency is all the more disturbing than with the remote control systems used today also special tasks (air warning, Fire alarm etc.) should be fulfilled.

As from the fast implementation of such a special task sometimes The life of people can depend on the well-known remote control systems with single-channel transmission not well suited for this purpose. There is therefore a second one for special tasks Audio frequency channel has been introduced. However, this solution is also unsatisfactory because a special generator is required for the second frequency, which has a considerable Means increase in the cost of the system.

With the invention, the stated disadvantages and difficulties become eliminated. According to the invention, for the transmission of the audio-frequency control commands two channels created in that the one half-wave of the 50 Hz mains voltage Transmitter and the receiver assigned to the first channel by means of suitable ones from her controlled switch connects, but the receiver assigned to the second channel from the transmitter, while the second half-wave of the 50 Hz mains voltage disconnects the transmitter and connects the receiver associated with the second channel in the same way and also separates transmitter and receiver for the first channel from one another.

Thus, when the audio frequency channel is used twice, the Connection paths through the positive or negative half-wave of the mains voltage switched. Appropriately, a grid-controlled switch is used as a switch on the transmission side Electron tubes used, their anode voltages by one or the other half-wave the 50 Hz voltage is formed. The audio frequency control voltage is called the grid voltage given into the network via the electron tube. There are two cold thyratrons on the receiver side provided, to which the half-waves are added as anode voltage and the ignition being carried out by audio frequency pulses which are applied to the grid.

With reference to the drawing, which in Fig. 1 is a circuit diagram of the invention Remote control system and in Fig. 2 shows an explanatory sketch, let the invention described in more detail.

To the phases R, S (Fig. 1) of a power supply network is a Transformer 6 connected, the anode circuit of the with its secondary winding Transmitter tube 2 feeds. A grid-controlled electron tube is provided as the transmitter tube. In the anode circuit of the transmitter tube 2 is a transformer 3, which with its secondary winding is coupled in series with a choke 4 and a capacitor 5 to the network. The audio frequency generator 1 controls the grid of the transmitter tube 2. The anode circuit the transmitter tube forms over the switch 7 or 8 and the Rectifier 16 and 17, which are connected to the ends of the secondary winding of the transformer 6 are two ways. The cathode of the transmitter tube is with a center tap the secondary winding of the transformer 6 is connected.

On the receiver side is one of the capacitor 9 and the choke 10 existing screen arrangement old the mains phases connected and with the starter electrodes the cold thyratron 11 and 12 respectively. The anodes of the cold thyratron lie at the ends of the secondary winding of a transformer 15, which with its primary winding is connected to the network phases R, S. The center tap of the secondary winding the transformer 15 is connected to the cathodes of the Thy ratrons. In the anode circles The receiving relays 13 and 14 are arranged on the two thyratons.

If, for example, switch 7 is closed in the transmitter, it is The anode circuit of the transmitter tube 2 is connected to voltage via the rectifier 16. Since the However, the tube can only work with a positive anode voltage, it is only ever for a half-wave of the network frequency in action, d. i.e., those from the tone frequency generator 1 pulses given on the grid of the tube can only pass through the transformer 3 and the coupling elements 4 and 5 are forwarded to the network R, S, if the transmitter tube receives a positive anode voltage. Used in place of the switch 7 the switch 8 is closed, so the positive anode voltage of the transmitter tube is now offset by 180 ° with respect to that caused when the switch 7 is closed. Corresponding the audio frequency fed into the network becomes the other half-wave of the network voltage transfer. When switches 7, 8 are closed at the same time, a continuous Feeding of audio frequency into the power supply network takes place, however, the the audio frequency superimposed on a half-wave of the mains frequency on the receiving side can easily be separated from the audio frequency superimposed on the other half-wave can.

On the receiving end, the incoming tone frequency is recorded using the Sieve means fed to the starter electrodes of the thyratron. The Thyratrons themselves are so connected to the mains voltage with their anodes that the only Thy r atron is included the one and the other thvratron only at the other half-wave of the line voltage can work. For a halt-thyratron it is irrelevant whether it works required ignition voltage is positive or negative. So it flows, for example in the thyratron 11 only an anode current to actuate the relay 13 when the switch 7 is closed. Correspondingly, the relay 14 is only actuated when switch 8 is closed.

In Fig. 2, the current and voltage ratios at the transmission or shown on the receiver tubes for two periods. With U2 is in the diagram A denotes the voltage present at the transmitter tube 2 when the switch 7 is closed. Below that, in diagram B, the anode current 13 is entered, which only then flows can if the positive voltage U2 is present. In diagram C the current and voltage conditions on the thyratron 11 are shown. The anode of the thyratron receives at the same time as the transmitter tube a positive voltage U 1l, which the ignition of the thyratron and the occurrence of the anode current i1 enables. in the Diagratntn D comparatively the anode voltage U1., Of the Tlivratron 12 is plotted, which is offset by 180 ° with respect to the anode voltage of the other thyratron, see above that no anode current can flow here.

The measures according to the invention described are therefore a Possibility has been created via an available audio frequency channel by alternately periodic utilization of the positive or negative half-wave the mains voltage, two different switching tasks at the same time via two connection paths to execute.

Claims (3)

PATENT CLAIMS: 1. Audio frequency remote control, in which with the help of the power supply network superimposed audio frequency pulses of a single frequency Consumers connected to the network are controlled, characterized in that that created two channels for the transmission of the audio-frequency control commands be that the one half-wave of the 50 Hz mains voltage the transmitter (1) and the dem receiver (13) assigned to the first channel by means of suitable switches controlled by it (2, 11) connects the receiver (14) assigned to the second channel but from the transmitter separates, while the second half-wave of the 50 Hz mains voltage, the transmitter and the dem second channel associated receiver (14) connects in the same way and likewise Separates transmitter and receiver (13) for the first channel from one another. 2. Arrangement according to claim 1, characterized in that the switch on the transmitter side is a Grid-controlled electron tube (2) is used, whose anode voltage is through formed one or the other half-wave of the 50 Hz voltage and that the audio frequency Control voltage is supplied as a grid voltage. 3. Arrangement according to the claims 1 and 2, characterized in that cold thyratron is used as a switch on the receiving side (11,12) are used, to which the half-waves are supplied as anode voltage and which are ignited by the audio frequency pulses. Considered publications: German patent specification No. 804 422.