DE1172349B - Remote control circuit for wireless triggering of switching processes - Google Patents

Description

Remote control circuit for wireless triggering of switching processes The invention relates to a remote control circuit for wireless triggering of Switching operations with a number of switching units that have a relatively large area are scattered. Such a remote control circuit is particularly suitable for central switching on and off of street lights.

There are already known remote control circuits in which the wireless transmitted switching signals on a carrier wave with different audio frequencies modulated and as pulse trains (arranged on the individual switching units) Recipient. There are parallel to each receiver and one on each The audio frequencies matched channels are connected downstream that carry the control voltages for the switching relays to be influenced, so that every desired switching process by selecting the audio frequency assigned to the relevant switching relay can be triggered. Such remote control circuits are already in everyone tuned channel a bistable circle has been arranged through the over the affected channel is flipped into its conductive state and thereby feeds the switching relay of this channel, with the resetting of the bistable Circuits and thus the switching relay in all coordinated channels at the same time takes place by means of a cancellation signal that is transmitted via an additional tuned channel is transmitted.

The remote control circuits of the type outlined above are relative susceptible to glitches. In addition, they do not allow selective tripping of similar switching operations with switching units combined in groups, unless the expense of a corresponding number of additional audio frequencies is accepted.

These disadvantages of the known remote control circuits are intended by the Invention are eliminated, namely - based on a remote control circuit with two different audio frequencies and with two appropriately matched receiver sides Channels - by the fact that each of the two channels ("to channel" resp. "Off channel") is connected to one of the two halves of a bistable circle and a summing circuit which includes the incoming in the respective channel Pulses summed up and after receiving a predetermined number of pulses one Total voltage as control voltage on one or the other input of the bistable Circle outputs, the state of which in turn influences the switching relays. In the proposal of the invention, it takes place in each of the two downstream of the receiver Channels a count of the switching pulses, whereby an actuation of the bistable circuit and thus a triggering of the switching process can only take place if a predetermined one minimum number of switching pulses has passed through the relevant channel. This makes it possible in a simple manner to add individual groups of switching units set a different number of pulses so that either by sending out first a smaller and then a larger number of pulses (at the same audio frequency) a successive switching the groups of switching units can be brought about or by sending it out alone a large number of pulses a simultaneous switching of all switching units can be made. Furthermore, the bistable can be used with each switching unit Circle and thus the switching relay assigned two parallel channels, their supply the overturning of the bistable circuit into the conductive or non-conductive state determined, set to a different number of necessary switching pulses, so that for switching off groups of switching units one of the switching on independent order is possible, including the in groups Combination of switching units for the switch-off process is not the same as in groups Summary for the power-up process needs to be.

Since the usual summing circuits are usually designed that the total voltage drops again after a more or less short time, if none new pulses are supplied, is the remote control circuit constructed according to the invention very insensitive to any glitches. That is why it is straightforward possible, an already existing radio wave modulated with speech and music to be used as a carrier wave for the switching pulses.

Further details of the invention are given in an exemplary embodiment explained in more detail with reference to the drawings. F i g. 1 is a block diagram a switching unit used in the remote control circuit according to the invention, F i g. 2 is a graphical representation of the individual points in the switching unit according to FIG. 1 occurring wave trains.

The embodiment of the invention described below Remote control circuit is used to wirelessly switch on and off the street lights within a certain larger area from one central station, the many Kilometers outside the boundaries of the area concerned. At each switching point for the street lighting has a switching unit, their structure in FIG. 1 is shown in more detail.

At the central station, a radio transmitter is arranged with a selected carrier frequency works and each point of the area to be covered supplied with sufficient signal strength. If the area to be covered is relative is small, a low-power transmitter is sufficient. Preferably, however a high power transmitter, e.g. B. a conventional radio transmitter, used, the one can cover a correspondingly large area. The one broadcast by the radio station As soon as a switching process is to be effected, a carrier wave is generated by means of a conventional Facilities are briefly modulated with switching signals that are converted from audio frequencies into consist of a sequence of discrete pulses. The audio frequencies are in order to also use the carrier wave for transmission when using a radio transmitter of speech or music usable, expediently close to the upper limit of the listening area. In the example considered here, audio frequencies of 8 kHz and 9 kHz, in the form of a train of six pulses with one Repetition frequency of 1 Hz and a ratio of 1: 1 between pulse duration and Length of the pulse gaps can be modulated onto the carrier wave. The frequency of 8 kHz will be referred to as the "on frequency" in the following, while the frequency of 9 kHz should be referred to as the »off frequency«.

Each switching unit is for receiving the broadcast from the radio station Wave train A with a tuned to the carrier frequency of the radio transmitter, appropriate transistorized receivers with automatic gain control 2, which can be of any suitable standard type, and a low-frequency output stage owns. The receiver is fed via an antenna 1 in the form of an a ferrite rod arranged coil, which together with an additional capacitor forms the tuning circuit for the selected carrier frequency. Alternatively, however a coil arranged on a ferrite pot core can also be used, which through a tuning capacitor tuned to the selected carrier frequency and over a blocking capacitor is powered. In the latter case, the whole can Device can be placed in a sealed container. Has been very suitable it turned out to equip the receiver 2 with five transistors. One of Transistors serve as a mixer oscillator, two more transistors are used for Amplification of the intermediate frequency signal, the fourth transistor is a diode for Rectify the intermediate frequency signal and the last transistor is used as an audio frequency amplifier switched. The output of the diode is connected to the latter transistor via a the amplitude control serving potentiometer is supplied.

The output voltage B supplied by the receiver 2, the modulation of the carrier wave emitted by the radio station is sent to two parallel Channels created. The two channels are armed by tuning circles 3 and 3 ' the on-frequency or the off-frequency matched so that each channel only those Part of the audio frequency output of the receiver 2, which is located on the Natural frequency of the tuning circuit in question is located. Both are useful Tuning circuits 3 and 3 'as tuned audio frequency amplifiers equipped with transistors formed, each of which is followed by a further amplifier 4 or 4 ' is. The matched amplifiers can be operated with maximum efficiency will.

The output voltage C from the two amplifiers 4 and 4 ' is fed to a conventional rectifier 5 or 5', which can be coupled to an amplitude limiter circuit and which supplies a square wave train with a frequency of 1 Hz as output voltage D. The output voltage D of the two rectifiers 5 and 5 'is applied to a summing circuit 6 or 6', the output voltage E of which represents a wave train rising in the form of a staircase and reaches a predetermined height when six switching pulses of the audio frequency assigned to the channel in question with wave train A arrive are.

The summing circuit 6 or 6 'can expediently consist of a so-called diode pump exist, which is known in numerous embodiments. Such a diode pump basically contains two capacitors of different sizes between which there is a large diode leading to the smaller capacitor at the front. The square wave train is fed to the large capacitor, and the output voltage will be across the smaller one Capacitor removed. Each square pulse that is fed in causes the two capacitors in proportion to their capacities, so that the smaller capacitor only charges up to a correspondingly small partial voltage. If before the feed of the next pulse the large capacitor is appropriately discharged the smaller capacitor takes its charge, so that when dividing the next pulse on the two capacitors the smaller capacitor (at least in a first approximation) is charged to twice the partial voltage. So the increases The voltage across the smaller capacitor increases in steps.

The output voltage E supplied by the summing circuits 6 and 6 ' is connected to one of the two halves of a (suitably transistorized) bistable binary circuit 7 applied, which is such that it is only from one State changes over to its other state when the output voltage E exceeds the above-mentioned has reached a predetermined value.

That half of the bistable circuit 7, which is connected to the channel tuned to-on-frequency, generates the switching voltage F and is connected to the winding of an electromagnetic relay connected as a load, while the other half of the bistable circuit 7 z. B. is loaded with a resistor 8. The switching contacts RLA1 of the relay are components of the electrical supply circuit for street lighting. The arrangement is made in such a way that the relay contacts close when the relay winding is fed and thus enable the power supply to the street lighting to be switched. Since the relay, once energized, remains energized until a signal is transmitted at the off frequency, it can be of simple construction.

That half is in the normal state of the switching unit of the bistable circuit 7, which contains the relay winding as a load, in the non-conductive State so that the relay winding is not fed and thus the street lights are switched off is.

As soon as the street lighting is to be switched on, the carrier wave emitted by the central station is modulated with a pulse train of six pulses with on-frequency, which have a repetition frequency of 1 Hz and whose ratio of pulse length to the length of the pulse gaps is 1: 1. The receivers 2 located in each switching unit then emit the output voltage B representing the modulation of the carrier wave to the two tuned audio frequency amplifiers 3 and 3 '. However, only the amplifier 3, which is tuned to the on-frequency, responds to this output, so that the voltage B can only be processed further in the channel connected downstream of this amplifier. The rectifier 5 thus supplies a square wave which consists of six pulses with a repetition frequency of 1 Hz and which has a ratio of pulse duration to pulse gap of 1: 1. This square wave arrives at the summing circuit 6. As soon as six pulses have passed through, the output voltage E of the summing circuit 6 has reached the value necessary to overturn the bistable circuit 7. Accordingly, half of the bistable circuit 7, which was previously in the non-conductive state, is now conductive, so that the winding of the relay is fed, the relay contacts RLA 1 close and cause the power supply to the street lighting.

When the street lighting is to be switched off again, the carrier wave emitted by the central station is modulated with a pulse train of six pulses with an off frequency, analogous to the manner described for switching on. This pulse train is processed further by the channel connected downstream of the amplifier 3 ', which is tuned to the off frequency, and causes a renewed change in the state of the bistable circuit 7. ends, and as a result, the power to the street lighting is cut off.

When the relay has already been actuated in a certain direction by a signal from one of the two switching frequencies, the transmission of further signals of this frequency can no longer influence the setting of the relay. Accordingly, it is possible to design some of the switching units at the individual switching points so that they only respond to a certain first number of pulses in the switching signal, while other switching units are designed so that they only respond to a second, larger number of pulses in the React switching signal. A signal that is composed of too small a number of pulses supplies an output voltage to the summing circuit 6 or 6 'which cannot cause the bistable circuit 7 to overturn and which drops continuously in the absence of further pulses until it finally returns to zero Level has reached. By suitable selection of the number of necessary switching pulses, it is possible, for example, to switch on the lighting of traffic signs before the general street lighting and to switch it off again after the general street lighting.

Similar results can be achieved by using more as two different audio frequencies for modulating the carrier wave. Included are the matched amplifiers in the receiving systems at the stations to be switched tuned to different frequencies, so that the respective relays can be operated selectively. The first-mentioned type of selective activity However, individual stations is more advantageous as they are associated with less effort and since it is also permitted, by immediately sending out the maximum number of switching pulses all switching points in a simple manner if necessary switch at the same time.

The relays cannot be actuated by any error pulses, regardless of whether these error pulses are superimposed on the radio transmission or whether they appear in the high-voltage line of the transistor circuits.

Of course, signals of different characters can also be changed by changing them other features are formed, for example by changing the repetition frequency and the relationship between pulse duration and pulse gap. In this case, of course, must modified the switching arrangement at the individual switching points in a corresponding manner will.

Claims (3)

Claims: 1. Remote control circuit for wireless triggering of switching processes, for example to switch street lights on and off, using wirelessly transmitted signals that are modulated on a carrier wave with two different audio frequencies and transmitted as pulse trains to receivers, with each receiver having two parallel and channels tuned to one of the audio frequencies are connected downstream, which supply the control voltages for the switching relays to be influenced, characterized in that at each receiver each of the two channels ("on channel" or "off channel") with one of the two halves a bistable circuit (7) and a summing circuit (6 or 6 ') which sums the incoming pulses in the relevant channel and after receiving a predetermined number of pulses a sum voltage (E) as a control voltage on one or the other input of the bistable circuit, of its state in turn the switching relays to be influenced. 2. Circuit according to claim 1, characterized in that the Summing circuit (6 or 6 ') is a diode pump, which in a manner known per se on an incoming pulse train (D) an outgoing step-shaped wave train (E) returns. 3. Circuit according to claim 1 or 2, characterized in that the winding of the switching relay as a load in one half of the bistable circle (7). Documents considered: German Patent Specifications No. 653 857, 1 012 356; British Patent Nos. 511311, 684,949; U.S. Patent Nos. 2,321,651, 2,344,618, 2,643,369, 2,645,771 .