DE2436624A1 - Coded electronic contactless proximity switch - has signal generator whose voltage charges capacitor under timer control - Google Patents

Abstract

The proximity switch has a touch plate connected to an oscillator that generates a signal voltage independent of the duration of the operator fingers in the region of the touch plate. This signal voltage is stored in a capacitor circuit. The capacitor charge state and the duration of the signal voltage are compared by a timing element such that a switching signal is released only, when a given trigger level is exceeded and when the capacitor charge time is not longer than the duration of the signal voltage. The coded switch is insensitive to noise signals.

Description

Electronic, non-contact switching device Addition to patent ............... (patent application P 354676.1) The main patent (patent application P 2354676.1) concerns an electronic, contactless switching device, the Via a total of two external lines on the one hand to a voltage source and on the other can be connected to a consumer, containing a non-contact Sensor that is fed by the load current or the mains voltage and its rectified and an output voltage that changes in relation to the state of approach to a signal transmitter and the output signal of which is fed to an electronic switching element.

The main patent (patent application P 2354676.1) is based on the following from: Switching devices of the type described above with an externally influenceable Sensors that contain an oscillator, for example, are increasingly being called capacitive Switchgear used in house installation, with two and more such switching devices are connected in parallel to from different places switching a consumer, e.g. a light bulb, on and off.

Since these switching devices are in an existing installation have to be inserted, in contrast to known non-contact Switching devices with three external lines, one of which is used to supply power to the Sensor is used, only switching devices with a total of two external lines for the auxiliary voltage and used by the consumer.

A problem with the practical design of these switching devices consists in creating a circuit arrangement for the sensor and the signal transmitter as well as the evaluation circuit of the signal voltage, which enables several switching devices to be connected in parallel and to keep the current consumption of the sensors and signal transmitters low. Another problem is that the switching device is insensitive to interference from the network close. The solution causes difficulties because on the one hand, as I said, only a total of two lines are available and, on the other hand, the existing one Line installation must be used, so none against interference shielded cables are available.

In a known embodiment of a so-called two-wire transmitter (e.g. according to DIN 19234) the encoder is connected to a switching amplifier via a total of two lines connectable. The encoder consists of e.g. a transistor oscillator, its supply voltage is fed to the oscillator via a two-wire line. The pending on the spool high-frequency stray field forms the response zone. If metal is immersed in the Stray field energy is withdrawn from the oscillator and the associated change the internal resistance of the oscillator is used to control the switching amplifier. In the undamped state, the oscillator has a low resistance Direct current Internal resistance correspondingly small. The idle current has a certain value. When the oscillator is approached, its internal resistance becomes high. Corresponding the current consumption drops to a lower value. The current change takes place analogous to the degree of damping of the oscillator, i.e. analogous to the approaching state of the metal object. The change in current is statically effective as long as the object is in the effective range of the encoder. In this case it is a dynamic one Working point, in contrast to the static working point, which is caused by the quiescent current consumption is formed in the undamped state of the oscillator. The static ones are advantageous and the dynamic working point far apart when an object approaches to achieve the largest possible drop in current at the oscillator. The power drop can be used in the switching amplifier in an evaluation threshold, e.g. a trigger, evaluate. This known embodiment is disadvantageous because the wider the dynamic and static operating points are apart, the greater the Quiescent current consumption of the encoder is. Another disadvantage of this encoder is that that not easily several such encoders via a parallel connection to one common circuit are to be connected, e.g. to connect a Trigger switching process. Instead, it is required for a specific one Number of encoders to be switched in parallel, e.g. 20, the evaluation threshold in the common Circuit to be set externally. From the above it can be seen that the quiescent current consumption increases with the number of donors. The individual partial flows of the encoder add up, so that in a two-wire circuit in which the auxiliary voltage is from the load current or the mains voltage is derived, ultimately the consumer is no longer completely turns off.

The teaching of the main patent (patent application P 2354676.1) is therefore the task of creating a contactless switching device on which without changing the common circuit several sensors in parallel via two lines each can be switched and the quiescent current consumption is just large enough for the sensor to feed and furthermore disturbances from the network do not affect the switching status.

According to the teaching of the main patent (patent application P 2354676.1) solved that the output voltage of the signal generator of the supply voltage Is superimposed and tapped with low resistance in a subsequent signal evaluation stage becomes, whereby the directly objective teaching of the main patent goes as follows, that the output of an oscillator with the input (gate) of a unijunction transistor, in particular a programmable Uni junction transistor connected, whose Anode-cathode path in series with a capacitor at the operating voltage (auxiliary voltage ) and also with the anode at the tap of an ohmic voltage divider. Around In the undamped state, the unijunction transistor is blocked. As soon as an approach takes place at the sensor, the voltage threshold at the gate drops below the value of the Anode threshold, so that the anode-cathode path is ignited. This comes about a strong surge of charge occurs across the capacitor, which is only produced by an ohmic one Resistance is limited in the course of signal evaluation. According to the teaching of the main patent (Patent application P 2354676.1) is the low resistance in the + or -line the sensors connected in parallel, parallel to a series connection of a Zener diode and the base-emitter path of a switching transistor connected. The voltage drop at the cons ~ stand is much smaller than the operating voltage. If the unijunction transistor switches through, full operating voltage is available for a short time at the resistance. This high voltage level appears as a needle impulse on the resistor on and is tapped via the Zener diode as a threshold and the switching transistor supplied, at its collector a short switching signal with full operating voltage (Auxiliary voltage) is present. This switching signal serves as a setting signal for a bistable Tilting stage. Depending on the switching state of the flip-flop, the consumer is on or switched off.

The low-resistance signal evaluation is relatively insensitive to high-resistance interference, since most of the interference voltage is at the internal resistance of the Source of interference drops and thus does not reach the signal threshold of the switching device will.

The switching device according to the main patent (patent application P 2354676.1) has already proven itself extremely well in domestic electrical installations, as it it is possible for the first time to switch on a consumer without touching a switching element. and switch off, the switching device in any existing installation subsequently can be inserted because, like a mechanical switch, only two in total External lines are available and several sensors also only have two external lines each can be interconnected in parallel with a load circuit. In this way can be combined with a main unit, e.g. consisting of a sensor circuit and a load circuit and one or more extensions that only consist of one sensor circuit, switch one or more consumers on and off or toggle from different locations.

It has meanwhile been found that with very long control lines the Interference sensitivity of the switching device according to the main patent (patent application P 2354676.1 ) increases. This is the case when main and sub-branches are far apart and the control lines are laid parallel to other supply lines. That can usually not be avoided, especially in house installation. Main cause are unwanted coupling of the control lines with the power line. these can caused by inductive, capacitive or galvanic means, e.g. by Overvoltages on the power line or voltage drops due to high-energy high-frequency interference fields, arcs, etc. The energy content of such interference voltages can be sufficient to bypass even a very low-resistance circuit of the control lines and to simulate a switching signal.

The object of the invention is to provide a programmed or coded control signal generation and evaluation, so that interference pulses of the above do not influence the switching status of the switching device.

The invention relates to an electronic switching device, which over a total of two external lines on the one hand to a voltage source and on the other hand to one Consumers can be connected, containing at least one non-contact Sensor that is fed by the load current or the mains voltage and its rectified and an output voltage that changes in relation to the approximate state to a signal generator and the output signal of which is fed to an electronic switching element, wherein the output signal of the signal generator is superimposed on the supply voltage of the sensor and is tapped in a subsequent signal evaluation circuit, after Patent .............. (patent application P2354676.1) and consists in the fact that the signal transmitter a time-limited signal voltage independent of the duration of the approach to the sensor generated that are charged in a memory for the duration of the signal voltage and one Threshold is supplied that the charging time of the memory and the duration of the signal voltage can be compared with one another with at least one timing element and a switching signal only takes place when the threshold is exceeded and the charging time of the memory is not longer than the duration of the signal voltage.

The signal voltage can take the form of a pulse of a defined width (e.g.

> 50 <200 ms) or a pulse or wave packet. The pulse length or number of pulses per time of the signal voltage is essential, or frequency and amplitude of the wave packet. You must with every approach the sensor can be repeated in exact sequence, since the signal is picked up in the evaluation only responds to constant set values.

In the switching device designed according to the invention, a signal voltage generated and transmitted in a very specific form, which is queried in the signal evaluation will. This training can, for example, prevent interference that is induced in the control line will, with a probability bordering on certainty, not the switching state influence, since interference voltages, which have the form and duration of the signal voltage, practically do not occur.

There are several options for generating the signal voltage. One The first possibility is to connect to the output of the sensor, e.g. an oscillator, to switch a monostable multivibrator whose quasi-stable state is longer or lasts shorter than the damping of the oscillator when switching. In this case becomes the output voltage of the oscillator when damped directly used for control. At a given threshold, the one-shot becomes Flip-flop triggered and for the duration of the quasi-stable state e.g. by a A drop in the operating voltage of the oscillator is superimposed. To trigger the monostable Tilt level completely independent of the duration of the approach to the sensor (C> zillator) it is advisable to trigger the monostable multivibrator via a trigger signal. This can be done with a signal generator, as taught in the teaching of the main patent, done by feeding the output voltage of the oscillator to a pulse generator which generates a needle pulse when approaching the oscillator, regardless of the duration of the approach and the time of removal from the feeler. It may prove beneficial rather than proportionate wide pulse to generate a pulse packet as signal voltage.

In this way, for example, the power consumption can be reduced considerably. The easiest this measure can be implemented by using the pulse generator as a pulse generator is switched, which for the duration of the approach or more advantageously via the monostable Tilting stage, i.e. independent of the duration of the approach during the quasi-stable State, a pulse chain superimposed on the operating voltage. The monostable multivibrator forms a gate for the pulse generator. Instead of pulse chains, you can also use Wave packets are worked. In this case a directly from the oscillator, preferably sine oscillator, branched frequency sequence switched to a gate.

A monostable multivibrator can again serve as the gate. In detail this solution looks like this. In series with the oscillator is a pulse generator and switched a gate. The frequency branched off by the oscillator is transmitted via a line the bistable tilting stage or the gate. Since the frequency of this oscillator is e.g. between 10 and 500 kHz, it is advisable to use the derived Reduce the frequency with a frequency divider, e.g. to approx. 3 kHz, in order to reduce the attenuation to decrease.

When the oscillator is approached, the gate circuit is activated via the pulse generator opened, the oscillator frequency is set for the duration of the opening time of the gate circuit or - transmit the divided frequency.

In the signal evaluation, the timing element is the series connection of the The memory and the threshold are connected in parallel, the running time of the timer corresponds to the duration of the signal voltage. If there is a signal voltage in the signal evaluation on, the memory is charged by the signal voltage until a threshold is exceeded. Simultaneously with the leading edge of the signal voltage, the Timing element controlled, which is set so that it is at the end of the signal voltage drops automatically. The threshold is advantageously chosen so that the charging up to the threshold takes place a little faster than the runtime of the timer. At the The threshold of the memory and at the output of the timer are two pieces of information on, namely threshold exceeded and timer not yet expired. The two Statements become in a logical connection, e.g. an AND connection a switching signal processed in a known manner on a bistable Flip-flop is switched.

The charging of the signal voltage can easily be done with a RC element take place, with the threshold voltage of one or more series-connected diodes or transistors can be used.

Interference voltages or interference pulses transmitted to the control line will, are largely suppressed. Is the signal voltage based on a pulse of a certain width, the memory becomes in the case of narrower interference pulses or the RC element is not charged up to the threshold. An input variable for the There is no logical connection. For interference voltages of a certain frequency this is also the case. The timer has already expired before the Threshold is reached.

The statements described above for the signal voltage in the form of a pulse of a certain width also apply to signal voltages in Form of impulse or wave cap, so that on a further explanation of this Correlations can be dispensed with.

A further improvement in immunity to interference is achieved by that the first timing element is connected in parallel with a further timing element whose Running time is shorter than the running time of the first timing element and a switching signal only takes place when the second timer has expired. In this case it can the second timing element with a N ICHT link and the first timing element with the memory or the RC element with an AND logic element to a NOT AND logic link are interconnected. This also means that there are disruptions very large energy content, which could quickly charge the memory.

This is another measure to improve the immunity to interference achieved that in the course of the signal evaluation in series with the parallel connection Memory or RC element and the timer or elements a trigger is connected.

It should also be mentioned that the discharge of the RC element or the memory can take place after the trigger has dropped. It can be with the timers Likewise act to monostable multivibrators.

The invention is shown in several exemplary embodiments in the drawing shown I It.

1 shows the block diagram of the switch according to the invention, FIG. 2 shows a block diagram of the signal generation, FIG. 3 shows a further block diagram for pulse packet generation, FIG. 4 shows a further block diagram for wave packet generation, 5 shows the pulse diagram of the switch according to FIG. 1 or 2 of the drawing.

The electronic contactless switching device according to FIG. 1 the drawing consists of a sensor circuit I and a circuit II.

Both circuits are connected to one another via a two-core cable.

The sensor circuit consists of an externally approximate, e.g. the human hand, controllable oscillator 6, a pulse generator 7 and one monostable multivibrator 8.

The oscillator 6 works e.g. according to the Hardley principle with a Transistor. The frequency-determining part of the oscillator 6 is formed by a resonant circuit inductance and an oscillating circuit capacitance. The feedback loop of the oscillator is over a flat capacitor 9 closed. He is e.g. with one electrode to the base of the oscillator transistor and with the second Electrode connected to the output of the resonant circuit. The two electrodes grip roughly like combs into one another, so that the field lines are evenly between the electrodes Distribute over the entire capacitor surface. By approaching an object to the electric field of the capacitor, its capacitance is reduced and the Feedback is reduced, which results in a reduction in the oscillator oscillation Has.

A transistor with a high-impedance input and serves as the pulse generator 7 negative characteristic, e.g. a programmable unijuncfion transistor whose input (Gate) is at the output threshold (e.g. a resistor) of the oscillator. The anode-cathode path of the transistor is e.g. in series with a capacitor to operating voltage and also to a voltage divider with the anode. The cathode is at negative potential.

If you approach the capacitor 9 with your hand, for example the feedback of the oscillator is reduced. Proportional to the state of approach the oscillation amplitude also moves. By a subsequent rectification and filtering with diode and capacitor, the rectified output voltage behaves of the oscillator analogous to the approach state. The output of the oscillator will be applied to the input of the unijunction transistor. In the undamped state the threshold at the anode of the unijunction transistor is slightly lower than the DC voltage at the input of the unijunction transistor. The transistor is blocked. As soon as a Approaching the capacitor 9 takes place, the voltage threshold drops at the input of the unijunction transistor below the value of the anode voltage threshold, so that the anode-cathode path ignites. This creates a strong surge of charge About the capacitor, which acts as a trigger signal for the subsequent monostable Tilt stage 8 is used. The structure and mode of operation of a monostable multivibrator is sufficient known, so that a description of the details can be dispensed with. the The pulse width of the output signal of the monostable multivibrator is freely selectable and lies e.g.

between 50 - 200 ms. This comparatively broad impulse is that Operating voltage of sensor circuit I superimposed. It is unlikely to have one Interference pulse has the same width as the signal pulse. The sensor circuit I is e.g. summarized on a circuit board and connected to the circuit via a two-wire line II connected.

Trigger 10 is at the input of circuit II the signal pulse is tapped as a threshold and transferred to the memory or the RC element 11 fed. Interfering signals that are below the trigger threshold remain in the train further signal evaluation has no effect.

In series with the trigger 10 is the parallel connection, consisting from the memory 11 and the timing element 12 and possibly 13. The memory 11 is designed in such a way that that the charging approximately with the end of the signal voltage of the sensor circuit I also is finished. The signal voltage exceeds the upper limit of the storage capacity The threshold Us (Fig. 5) is the charging of the memory until it is reached the threshold Us is the measure with which the duration of the signal voltage is compared. In addition the timing element 12 and possibly 13 is used. The running time of the timing element 12 corresponds to Duration of the signal voltage of the sensor circuit 1, in the described embodiment the width of the signal pulse of the monostable multivibrator 8.

The monostable multivibrator can also be used as the timing element 12 will.

The transition from the stable state to the quasi-stable state becomes through the leading edge of the signal voltage and the transition from the quasi-stable state back to the stable state takes place automatically with the end of the signal voltage of the sensor circuit 1. The memory 11 can be used as a capacity memory, magnetic memory or the like. Be constructed. The easiest way to do this is with an RC element by charging the capacitor through a resistor as long as how the signal voltage of sensor circuit I is present. The discharge can be steeper Flank also take place via a resistor after the trigger 10 has dropped.

The trigger threshold of the trigger 10 is set by a signal voltage exceeded, the memory or the RC element 11 is charged. At the same time will the timer 12 is driven by the leading edge of the signal voltage.

If it is a signal voltage from sensor circuit I, the Threshold Us exceeded if the timer 12 has not yet expired. Acts it is a glitch whose pulse width is narrower than that of the monostable Flip-flop 8, or an interference voltage with strong dips, is used in the first case the memory is not fully charged.

No voltage is tapped at the Us threshold. In the second case charging is only ended when the timer has expired. For the use case are these statements sufficient to largely compensate for all types of faults that occur. In order to protect the circuit against interference pulses with high energy content, we recommend it is necessary to connect a further timer 13 in parallel to the timer 12, wherein the running time of the timer 13 is shorter than that of the timer 12. For the embodiment with A timing element 12 has two statements for evaluating the signal voltage of the sensor circuit I available, namely threshold Us exceeded and timer 12 has not yet expired.

For the embodiment with the second timing element 13 there is another Statement added; namely timer 13 has expired.

The information can be for the first embodiment with a AND operation 14 process into a switching signal that is given when at the inputs 16 and 17 of the AND link 14, the threshold voltage Us and the The signal voltage is present via the timing element 12.

For the second embodiment, for example, there is a NAND operation 15 in question. At the third input 18 there is an O signal via the timing element 13.

Fig. 5 of the drawings shows the timing diagram of the embodiments according to Fig. 1 of the drawing. The number n of switching sequences is in the time sequence t shown. After the trigger threshold UT is exceeded, level "C" the charging of the memory 11. At the same time after stage "D" and E E "the Timers 12, 13 controlled. The dash-dotted line shows the signal states of the timers when the threshold Us is reached. Switching stage "F" provides the switching signal for the electronic switching element. Before discussing these relationships in more detail further solutions for signal generation are described.

Fig. 2 of the drawing shows a simplification of the signal generation.

The monostable multivibrator 8 is controlled directly by the oscillator 6.

Fig. 3 of the drawing shows a circuit for pulse packet generation.

The ImpulsgeJer 7 according to Fig. 1 of the drawing is a pulse generator 19 switched, which triggers a pulse train when approaching the capacitor 9.

This can be done with essentially the same circuit structure as with the pulse generator 7. To limit the time, the pulse chain is set to a Gate 20 switched. A monostable multivibrator can serve as the gate. During the quasi-stable In the state of the flip-flop, a certain number of pulses are transmitted can in principle be evaluated with the same levels 10, 11, 12, 13, 14, 15. on a repetition of the details can therefore be dispensed with instead of pulse packets wave packets can also be generated. The advantage is that for this Purpose of the oscillator frequency an auxiliary frequency is branched off, which is also is switched to a gate 21. Fig. 4 shows the block diagram of this embodiment. A pulse generator is again connected between the gate 21 and the oscillator 6, at a certain approach to the capacitor 9 generates a pulse that the gate 21 opens for a certain time (approx. 50 - 200 ms). During this time the auxiliary frequency of the operating voltage derived from the oscillator is used as the carrier Superimposed. It can be advantageous to divide the auxiliary frequency with a frequency divider to move from the HF range to the LF range. Even with this one In the form of the signal voltage, the signal evaluation remains the same and can be used with the the blocks described.

The output signal of the logic connection 14, 15 is applied to the input a bistable flip-flop 24 switched. It is switched on so that when approaching the output signals of the logic connection to the capacitor 9 of the sensor circuit 14, 15 cause the bistable multivibrator (flip-flop) to tip over with the output the bistable multivibrator 24 is the ignition circuit 25 of the output stage 26th controlled. The output stage 26 forms an electronic switching element, e.g. a triac or thyristor.

It should also be mentioned that the supply voltage for sensor circuit I and signal evaluation when the switch is in the "Off" position via a series connection of Resistance, capacitor and diode are tapped from the mains voltage via consumer 27 will. When the switch is set to "On", the phase control tip determined by the ignition circuit is available the mains voltage as supply voltage.

Claims (14)

Patent claims: 1) Electronic switching device, which can be connected to a voltage source on the one hand and to a consumer on the other hand via a total of two external lines, containing a non-contact sensor, which is fed by the load current or the mains voltage and whose rectified output voltage, which changes in relation to the approaching state, is a signal transmitter and the output signal of which is fed to an electronic switching element, the output signal of the signal generator being superimposed on the supply voltage of the sensor and being tapped in a subsequent signal evaluation circuit, according to the patent. (Patent application P 2354676.1) characterized in that the signal generator 8, 19 and 20, 21 and 22 and 23 generates a time-limited signal voltage independent of the duration of the approach to the sensor 6, 9, which is stored in a memory 11 for the Duration of the signal voltage charged and fed to a threshold Us, so that the charging time of the memory and the duration of the signal voltage are compared with at least one timing element 12 and a switching signal only occurs when the threshold Us is exceeded and the charging time of the memory 11 is not longer than the duration of the signal voltage. 2) Electronic switching device according to claim 1, characterized in that that the timing element 12 of the series connection of the memory 11 and the threshold Us in parallel is switched and the running time of the timer 12 is the duration of the signal voltage is equivalent to. 3) Electronic switchgear .... according to claim 1 and 2, characterized in that the first timing element 12 a further timing element 13 is connected in parallel, the running time of which is shorter than the running time of the first timing element 12 and a switching signal only occurs if the second timer has already expired. 4) Electronic switchgear .... according to claim 1 - 3 characterized in that the charging of the Signal voltage takes place with an RC element and that the timing elements 12, 13 simultaneously triggered by the leading edge of the signal voltage when charging begins. 5) Electronic switchgear .... according to claim 1 - 4, characterized in that the output signals of the memory or RC element and the timing element 12 and possibly 13 in a logical Logic circuit to be processed into a switching signal that is known per se Way is switched to a bistable multivibrator 24. 6) Electronic switchgear .... according to claim 1 - 5, characterized in that the memory or the RC element 11 and the timing element 12 are interconnected with an AND logic element 14 are. 7) Electronic switchgear .... according to claim 1 - 6, characterized in that the second timing element 13 with a N ICHT link element and the first timing element 12 and the memory or the RC element 11 with an AND logic element to a N ICHT-UN D-Verkn Upfungsgl ied 15 are connected. 8) Electronic Schaltgerot according to claims 1-7, characterized in that that in series with the parallel connection of memory or RC element 11 and the timing element 12 and / or 13 a trigger 10 is connected. 9) Electronic switchgear. .... according to claim 1 - 8 characterized in that at the output of the Oscillator 6 is connected to a monostobile multivibrator 8, which at a certain Output voltage of the oscillator is controlled and its quasi-stable state takes longer or shorter than the damping of the oscillator when switching. 10) E lektron ical switching device according to claim 1 - 9, characterized in that that between the oscillator 6 and the monostable multivibrator 8, a pulse generator 7 is connected to a certain approximation to the capacitor 9 generates a needle pulse that acts as a trigger signal for the monostable multivibrator 8 serves. 11) Electronic switching device according to claim 1 - 10, characterized in that that in series with the oscillator 6, a pulse generator 19 and a gate 20 are connected are and at a certain approach to the capacitor 9 of the pulse generator 19 is controlled and the gate 20 is opened for a certain number of pulses. 12) Electronic switchgear .... according to claim 1-11, characterized in that one of the oscillator frequency branched auxiliary frequency is switched to a gate 21. 13) Electronic switchgear .... according to claim 1 - 12 characterized in that the gate has a Pulse generator 22 connected in series with the oscillator is opened. 14) Electronic switching device according to claim 1 - 13, characterized in that that the high-frequency auxiliary frequency branched off from the oscillator 6 with a frequency divider 23 is reduced to a low-frequency mudolation frequency. Blank page