DE4200207C1 - Electronic switch, e.g. inductive, capacitive or opto-electronic proximity switch - has switching distance set through external terminals and voltage supplied from external source - Google Patents

Abstract

The proximity switch has at least one element (7) which can be set to fix the switching distance. The switch determines the magnitude of the distance according to its state, and at least two external terminals which can be used. The state of the element and so the switching distance can be set through the external terminals (8, 9, 10) and the voltage supplied to the equipment from the network voltage or the voltage source (12). Different voltages are possible and at least one control signal can be obtained for setting the state of the element which then is able to adjust the working of the two oscillators (1, 2). ADVANTAGE - Switching distance can easily be set.

Description

The invention relates to an electronic switching device, for. B. an inductive, capacitive or optoelectronic proximity switch, with at least one determining the switching distance, with regard to its determining the switching distance adjustable state adjustable switching distance determination element and with min at least two externally assignable connections.

On the one hand, an electronic switching device is generally introduced spoke, on the other hand, are examples of such a switching device indukti ve mentioned capacitive or optoelectronic proximity switches. The general my wording - electronic switching device - is chosen because the invention not only with inductive, capacitive or optoelectronic proximity switches. The reference to inductive, capacitive or Optoelectronic proximity switches are given because the inventor underlying problem especially with inductive, capacitive and op toelectronic proximity switches occurs. The electronic switching Devices generally applicable teaching of the invention should therefore follow in the which explains primarily in connection with an inductive proximity switch be tert.

Electronic switching devices of the type in question here are basically Contactless and have been increasing for more than twenty years Dimensions instead of electrical, mechanically operated switching devices, the con are executed with a clock, used in particular in electrical or electronic measuring, control and regulating circuits. This applies in particular to Proximity switch, d. H. for electronic switchgear that ar contactless work. With such switching devices, it is indicated whether there is an influence element for which the corresponding proximity switch is sensitive, the proximity has approached the switch sufficiently far. It has an influence solution element for which the corresponding proximity switch is sensitive, the Proximity switches are sufficiently close, so one controls an essential one presence component that forms part of the proximity switch  electronic switches provided in the proximity switch; at a The switching device designed as a make contact is the one that was initially non-conductive electronic switches conductive, while one designed as a break contact Switchgear that initially blocks conductive electronic switches.

An essential component of proximity switches of the type mentioned above is u. a. a presence indicator that can be influenced from outside. At induk tive or with capacitive proximity switches is a presence indicator usually an inductively influenced oscillator or a capacitively influenced flowable oscillator provided (see, for example, the German Offenlegungsschrift ten or interpretations or patents 19 51 137, 19 66 178, 19 66 213, 20 36 840, 21 27 956, 22 03 038, 22 03 039, 22 03 040, 22 03 906, 23 30 233, 23 31 732, 23 56 490, 26 13 423, 26 16 265, 26 16 773, 26 28 427, 27 11 877, 27 44 785, 29 43 911, 30 04 829, 30 38 692, 31 20 884, 32 09 673, 32 38 396, 33 20 975, 33 26 440, 33 27 329, 34 20 236, 34 27 498, 35 19 714, 36 05 499, 37 22 334, 37 22 335, 37 22 336, 37 23 008 and 40 32 001). Optoelectronic Proximity switches have a photoresistor as a presence indicator Photodiode or a phototransistor (see e.g. the German Offenle 28 24 582, 30 38 102, 33 27 328, 35 14 643, 35 18 025 and 36 05 885).

Incidentally, belong to the electronic switching devices with which the Doctrine of the invention is concerned, for. B. also so-called flow monitors, the one Show temperature measurement circuit (see e.g. the German disclosure document or patents 37 13 891, 38 11 728, 38 25 059, 39 11 008 and 39 43 437).

In the case of inductive proximity switches, the oscillator applies as long as one meter tallteil has not yet reached a predetermined distance, K · V = 1 with K = feedback factor and V = gain factor of the oscillator, i.e. H. the oscillator oscillates. The corresponding metal part reaches the specified one NEN distance, the increasing damping of the oscillator leads to a Ver  decrease in gain V, d. H. the amplitude of the oscillator oscillation supply decreases or the oscillator stops vibrating. With capacitive Proximity switches apply to the oscillator as long as a response body Capacity between a response electrode and a counter electrode is not yet has reached K · V <1, i.e. H. the oscillator is not oscillating. Reaches the Response body the specified distance, so leads the increasing capacity between the response electrode and the counter electrode for an enlargement of the feedback factor K, so that K · V = 1, i.e. H. the oscillator be starts to swing. In both embodiments - inductive proximity scarf ter and capacitive proximity switch - depends on the different Chen states of the oscillator an electronic switch, for. B. a transi stor, a thyristor or a triac.

Optoelectronic proximity switches have a light transmitter and a light receiver and are also referred to as light barriers. Make a difference one distinguishes between a type of light barrier in which the light transmitter and the Light receivers arranged on opposite sides of a surveillance route net and a type of light barrier in which the light transmitter and the light receivers are arranged at the same end of a monitoring path, while a reflector arranged at the other end of the monitoring section is from the Light transmitter outgoing light beam reflected back to the light receiver. In In both cases, the presence indicator responds when it is normally from the light transmitter to the light receiver through a light beam into the Monitoring path passed influencing element is interrupted. It However, there are also light barriers of the light barrier type described last, where the light beam coming from the light transmitter can only be Influencing element is reflected back to the light receiver.

In connection with inductive and capacitive proximity switches is further above that if an influencing element for which the Proximity switch is sensitive, with an inductive proximity switch  Metal part and with a capacitive proximity switch a so-called An speaking body, reached a predetermined distance (coming from a distance) or exceeds (coming from up close) one belonging to the proximity switch electronic switch is reversed. The previously regarding its importance device explained so-called predetermined distance is usually with switching distance designated.

About the electronic switching devices with which the teaching of the invention concerned, now belongs u. a. at least one determining the switching distance visually adjustable its determining the switching distance Sensing range determination element. It can determine the switching distance de state of the switching distance determining element can be continuously changed; it can z. B. is a resistor whose resistance value - as the Sensing distance determining state - can be changed continuously. It can but also a switching distance determination element can be used, the Sensing distance determining state can only take discrete values; it can act z. B. a resistor, the resistance value only in steps can be changed, or simply a component with the logical additions were O or L, z. B. a switch.

In the introduction it is said that to the electronic switching device with which the The teaching of the invention is concerned with at least two externally assignable connections ren. These externally assignable connections serve on the one hand to feed the Supply voltage that the switching device needs and from which the - in the Re gel deviating from the supply voltage - internal operating voltage - for the presence indicator, etc. - is obtained; to that extent they are external assignable connections also called supply connections. On the other hand, serve the externally assignable connections of the lead of the switching signal, i.e. the Realization of the switch function; to this extent the externally verifiable An conclusions also called signal connections.  

There are now electronic switching devices of the type in question, in which the supply connections and the signal connections coincide, i.e. ins In total only two externally assignable connections are provided, which function the supply connections and the signal connections have; then it is so-called two-wire switching devices. There are also electronic switching devices te, where an externally assignable connection as both a supply connection as well as used as a signal connection, while a second external document bar connection as a further supply connection and a third external document cash connection can be used as a further signal connection; It is about then so-called three-wire switchgear. After all, there is also electro African switchgear, in which two externally assignable connections as a supplier connections and two further externally assignable connections as signal connections conclusions are used; it is then a four-wire switchgear. Four-wire switching devices are used, for. B. needed if between the Versor supply voltage and the switching signal should be galvanically isolated.

In the prior art, from which the invention is based, the switching distance determining elements that can be set with regard to their state that determines the switching distance and that are adjustable from the outside, as a rule potentiometers, are used (see, for example, DE-OSen 31 36 994 and 34 25 752 and DE-GM 88 06 233). It is also known to use a two-piece coil core as the switching distance-determining adjustable switching distance determination element, in which a core piece is adjustable relative to the other core piece from the outside (see. DE-PS 31 37 928). The mechanical adjustability implemented in both cases is not without problems. First of all, the above-mentioned switching distance determination elements as mechanical components are susceptible to faults, particularly sensitive to vibrations, provided with relatively large tolerances and are not always available in a so-called SMD version (potentiometer) or not available at all (two-piece coil core). In addition, the setting is sometimes difficult, casting problems occur and a complex mechanism is required if a certain degree of protection, for. B. IP 67, is to be guaranteed. Finally, "sensitive signals", for example the voltage drop across the emitter resistor of the oscillator transistor of the oscillator gate of an inductive proximity switch (cf. the emitter resistor 14 in the drawing of DE-PS 19 66 178), must be transported to "unfavorable places", ie at places are transported, which do not rule out an influence on the "sensitive signals" with sufficient certainty.

Otherwise, an electronic switching device of the type in question, namely an inductive proximity switch known (see. DE-PS 36 08 639), in which a combination of resistances is used as the switching distance determining element the, switching transistors and fuses is provided and the Sensing distance determining state of this sensing distance determining element with the help of the external influencing element and one via an external Connection applicable control voltage is fixable. The outer Influencing element in the distance from one belonging to the oscillator Vibrating circuit coil arranged, the ent of the switching distance to be set speaks. After applying the control voltage from which clock pulses are generated will be the effective resistance of a combination of contradictions stands, switching transistors and fuses position determination element larger until it becomes effective Resistance causes the oscillator to stop vibrating. So ver tied is that no clock pulses are generated from the control voltage and the effective resistance of the switching distance determination element is no longer changed. The Zu determines the desired switching distance state of the switching distance determination element is thus set.

The invention is based on the object or the problem for an elek tronic switching device of the type in question a particularly simple Specify adjustability of the switching distance.

The electronic switching device according to the invention, in which the task or Problem, as previously derived and explained, is now solved first and essentially characterized in that the state of the switching distance  mood element - and thus the switching distance - via the externally verifiable Connections is adjustable, namely depending on the connection of the switch device to the supply voltage at least one control signal for setting tion of the state of the switching distance determination element is obtained. According to the invention, a measure is used that leads to a completely different one Ren purpose has long been known, namely for the external specification of the function "Make contact" or "break contact" of a switching device that functions as either "make contact" or can be used as an "opener" (cf. DE-OSen 26 28 427, 31 23 828, 32 14 836, 40 23 502 and 41 14 763, their disclosure content the person skilled in the art can implement the invention in detail).

According to the teaching of the invention, a switching device is created in which min at least two internally specified switching distances via the externally assignable Connections of an "can be activated", namely by the way of the connection conclusion of the switching device according to the invention to the external supply chip nung. Consequently, one and the same switching device with the user-side Possibility to be offered, e.g. B. a small switching distance as required (usually with a large operating reserve and a wide temperature range) or a large switching distance (usually with a small operating reserve and small temperature range) to realize - without mechanical, from components to be mechanically adjusted on the outside are used.

In particular, there are various options for the inventive method To design and further develop electronic switching devices.

In a preferred embodiment of the switching device according to the invention is a rectifier bridge with at least four rectifiers on the input side Ter provided and the control signal from the rectifier bridge nal ge for setting the state of the switching distance determining element won.

Regarding the setting of the state of the sensing distance determination element with the help of depending on the connection of the switching device to the  Control signal obtained from the supply voltage, there are various possibilities keiten. Such a possibility is characterized in that the tax signal - directly or indirectly - controls at least one control transistor and with the help of the control transistor, the switching distance determining element is adjustable. Another possibility is characterized in that the control signal is fed to the control input of a control logic and the Control output of the control logic to the switching distance determination element closed is.

Incidentally, in terms of further possibilities of design and Refinements of the electronic switching device according to the invention referenced on the one hand to the claims subordinate to claim 1, on the other hand to exemplary embodiments which are described below in connection with Drawings are explained. Show in the drawing

Fig. 1 is a block diagram of an electronic circuit according to the invention, the device in its basic structure

Fig. 2 shows a first embodiment of the oscillator of the switching device according to Fig. 1,

Fig. 3 shows a second embodiment of the oscillator of the switching device according to Fig. 1,

Fig. 4 shows a first embodiment of a switching device according to the invention,

Fig. 5 shows a second embodiment of a switching device according to the invention,

Fig. 6 shows a third embodiment of a switching device according to the invention,

Fig. 7 shows a fourth embodiment of a switching device according to the invention,

Fig. 8 is a detailed view with respect to a first embodiment of the control electronics of the switching device according to Fig. 1 and

FIG. 9 shows a detailed illustration in relation to a second exemplary embodiment of the control electronics of the switching device according to FIG. 1.

Shown in the figures are electronic switching devices according to the invention on the one hand, specifically in FIGS . 1 and 4 to 7, on the other hand only circuit details of electronic switching devices according to the invention which are sufficient for understanding the teaching of the invention.

A presence indicator belongs to the exemplary embodiments of electronic switching devices according to the invention shown in the figures. In Figs. 1 and 4 to 7 inductive proximity switches are shown. The presence indicator is out as an inductively controllable oscillator 1 leads. Implementation options for the inductively influenced oscillator 1 are shown in FIGS. 2 and 4 to 7. The electronic switching device according to the invention can also be a capacitive proximity switch. Then the presence indicator is designed as a capacitive oscillator 2 . A possible implementation of a capacitively influenceable Os zillators 2 shows Fig. 3. Not shown that the electronic switching device according to the invention can also be out as an optoelectronic proximity switch. In such an embodiment, the property indicator includes a light transmitter and a light receiver.

Because the teaching of the invention does not deal with presence indicators for proximity circuit switch, it is not necessary to make further statements here. Instead, reference is made to the introductory remarks.

In the embodiments shown in FIGS . 1 and 4 to 7 inventive electronic switch, a switching amplifier 3 is arranged downstream of the oscillator 1 . Furthermore, the electronic switching devices shown include an electronic switch 4 controlled by the oscillator 1 via the switching amplifier 3 , for example a thyristor, a transistor or a triac, a current and voltage supply circuit 5 for the provision of the internal operating voltage and a rectifier bridge 6 provided on the input side. Since the teaching of the invention is also not concerned with the switching amplifier 3 , the electronic switch 4 and the current and voltage supply circuit 5 , details can be waived and the references given in the introductory statements to the previously published publications.

What is important for the teaching of the invention is that the electronic switching devices shown have at least one switching distance determining element, clearly visible of its switching distance determining state, adjustable switching distance determining element 7 and at least two externally assignable connections 8 , 9 . In the illustrated embodiments, three externally assignable connections 8 , 9 , 10 ( FIGS. 1, 4 and 5 and 7 to 9) or four externally assignable connections 8 , 9 , 10 , 11 ( FIG. 6) are realized.

To avoid repetition, the terms "Schaltab stand "," Sensing range determination element "and" externally assignable connections " Again, reference is made to the introductory remarks.

According to the invention, the state of the switching distance determination element 7 - and thus the switching distance - can be set via the externally assignable connections 8 , 9 , 10 , 11 . This creates a switching device in which at least two internally predetermined switching distances can be "activated" via the externally assignable connections 8 , 9 , 10 , 11 , namely by the manner in which the switching device according to the invention is connected to the - only in FIG . 1 Darge set - external supply voltage 12. Consequently, one and the same switching device can be offered with the user-side possibility, e.g. B. depending on the need to realize a small switching distance or a large switching distance - without using mechanical, mechanically adjustable components from the outside.

After the above explanation of the general teaching of the invention and the advantages achieved in relation to those indicated in the figures or the implementation options shown, the following:

Applies to electronic switching devices according to the invention in the embodiment as in ductive or capacitive proximity switches that they have an oscillator 1 or 2 and the switching distance determining element 7 belongs to the oscillator gate 1 or 2 . In this case, the positive feedback, the negative feedback, the amplitude or the frequency, by the switching element 7 of the distance determining Oszil lators 1 and 2, be adjustable. For an embodiment of the electronic switching device according to the invention as an optoelectronic proximity switch, it applies that a light transmitter and a light receiver is provided and the switching distance determining element belongs to the light transmitter and / or to the light receiver. The transmission power of the light transmitter and / or the response sensitivity of the light receiver can then be set by the switching distance determination element.

In all the exemplary embodiments of switching devices according to the invention shown in the figures, at least one control signal is obtained as a function of the connection of the switching device to the supply voltage 12 . This is a measure that has long been known for a completely different purpose, namely for the external specification of the function "make contact" or "break contact" of a switching device that can be used either as a "make contact" or as a "break contact" (cf. DE-OS 31 23 828, JP-OS-57 32 131 and DE-OSen 32 14 836, 40 23 502 and 41 14 763).

In the purpose of the external specification of the function "NO contact" or "NC contact" Switchgear used either as a "make contact" or as a "break contact" The state of the art becomes the external specification of the function "NO" or "NC" implemented differently.  

In the switching devices according to DE-OS 31 23 828, JP-AS-57 32 131 and DE-OS 32 14 836, an exclusive OR gate is provided in each case (reference characters Chen 12 in DE-OS 31 23 828, reference numerals Ro in JP-AS-57 32 131 and reference number 5 in DE-OS 32 14 836). The first input of the exclusive OR gate is connected to the output of a presence indicator, the second input can be supplied with a reverse control signal and the output is connected to the control input of an electronic switch. The reverse control signal is obtained depending on the connection of the switching device to the supply voltage. For example, applies to the switching device according to DE-OS 32 14 836 with three externally assignable connections 11 , 12 and 19 that then and only then the reverse control signal is obtained when the switching device with its connections 11 and 12 is connected to the supply voltage.

In the switching devices according to DE-OSen 40 23 502 and 41 14 763 it is assumed gone that the presence indicator belonging to these switchgear Tor downstream switching amplifier has two antivalent control outputs.

For the switching device according to DE-OS 40 23 502 applies that a second electronic switch is provided, the two electronic switches can be controlled by the two antivalent control outputs of the switching amplifier and is ensured that the current in each of the two electronic switches can only flow in one direction, in different directions in the two switches. For the switching device shown in Fig. 1 of DE-OS 40 23 502 now applies that when the terminal 4 to the positive pole of the supply voltage and the terminal 5 to the negative pole of the supply voltage is connected, only that between the terminals 4th and 5 lying, via the Zener diode 23 , the transistor 9 and the protective diode 13 leading de current path is conductive (with the transistor 9 driven ), while when the terminal 5 is connected to the positive pole of the supply voltage, the terminal 4 is connected to the negative pole of the supply voltage is, only that between the connections 5 and 4 , via the Zener diode 22 , the transistor 8 and the protective diode 12 leading current path is conductive (when the transistor 8 is driven ).

For the switching device according to DE-OS 41 14 763 it applies that the electronic switch can then be conductively controlled from the first control output - normally open control output - of the switching amplifier if the supply voltage is connected to the connections in "normally open polarity". and then and only then from the second control output - normally closed control output - of the switching amplifier can be controlled when the supply voltage is connected to the connections in "normally closed polarity". Different embodiments of the previously described switching device known from DE-OS 41 14 763 are described on the one hand in claims 2 to 5 and shown in Fig. 1, on the other hand described in claims 6 and 7 and in Fig. 2 Darge represents.

The exemplary embodiments of electronic switching devices according to the invention shown in FIGS. 4 to 6 largely correspond in their basic structure to the electronic switching device shown in FIG. 2 of DE-OS 32 14 836, so that in order to avoid repetitions, first of all refer to the description of this electronic switching device may be referred to in DE-OS 32 14 836. It is essential that the reversal control signal is generated in the manner or in a comparable manner as in the electronic switching device according to FIG. 2 of DE-OS 32 14 836, in the electronic switching devices according to the invention shown in FIGS . 4 to 6 the control signal is obtained with which the state of the switching distance determining element 7 - and thus the switching distance - is adjustable. In particular, the control signal controls a control transistor 13 ( FIG. 4) or two control transistors 13 , 14 ( FIGS. 5 and 6) and is by means of the control transistor 13 ( FIG. 4) or the control transistors 13 , 14 ( FIG. 5 and 6) the switching distance determination element 7 adjustable. The control transistors 13 are inversely operated bipolar transistors, which in the case of saturation operation has the advantage of a particularly low voltage drop on the collector-emitter path.

In the exemplary embodiments shown in FIGS . 4 to 7, electronic switching devices according to the invention, the switching distance at the effective emitter resistance of the oscillator 1 is determined. The effective emitter resistance of the oscillator 1 is therefore the switching distance determination element 7 . To the switching distance determination element 7 now include a first, always effective switching resistance 15 , in addition, a further switchable switching resistance 16 ( FIG. 4) or two further switchable switching resistance 16 , 17 . Depending on whether - through a certain connection of the switching device to the supply voltage 12 - the control transistor 13 , the control transistor 14 or the control transistors 13 and 14 are conductive, the switching distance determining state of the switching distance determining element 7 , i.e. the effective emitter resistance, is also determined by Sensing distance resistor 16 , from sensing distance resistor 17 or from sensing distance resistors 16 and 17 .

FIGS. 4 to 7, the skilled artisan readily seen, under which condition which of the control transistors 13 and 14 is conductive, wel cher the externally assignable ports 8, 9, 10, 11 to voltage to the supply must be connected 12 so that this need not be presented here in detail.

In the embodiment of an electronic switching device according to the invention shown in FIG. 1, it is generally indicated that the control signal, obtained in connection with the rectifier bridge 6 , is fed to the control input 18 of a control logic 19 and the control output 20 of the control logic 19 is connected to the switching distance determining element 7 is.

Fig. 8 now shows a detailed illustration relating to a first execution of the control logic, for example 19 of the switching device of FIG. 1. In this case 19 total, the control logic three different in their resistance values connected to the external assignable terminals 8, 9, 10 control resistors 21, 22 , 23 on, in series with each control resistor 21 , 22 , 23 is a control diode 24 , 25 , 26 . In addition, two control transistors 27 , 28 are easily seen, which are with their collector-emitter paths 29 , 30 in series to the control resistors 21 , 22 and 23 respectively. The two control resistors 21 , 22 are thus connected to one another at their ends remote from the externally assignable connections 8 , 9 .

The control logic 19 shown in FIG . B. be used in an electronic switching device according to the invention designed as an optoelectronic proximity switch. Here, for. B. via the connection 8, the transmission power of the light transmitter and the connections 9 and 10, the response sensitivity of the light receiver can be set.

Modifications to the control logic 19 shown in FIG. 8 are readily possible. For example, one can do without the second control transistor 28 and connect all three star resistors 21 , 22 , 23 to one another at their ends which are externally assignable connections 8 , 9 , 10 . Via the assignment of connections 8 , 9 and / or 10 , the transmit power of the light transmitter - and thus the switching distance - can be set in a total of six stages.

Finally, FIG. 9 also shows a detailed illustration in relation to a second exemplary embodiment of the control electronics 19 of the switching device according to FIG. 1. This is because the control logic 19 has a decoder 31 . Depending on whether port 8 and / or port 9 and / or port 10 is "programmed", various outputs of decoder 31 are activated.

Claims (11)

1. Electronic switching device, for. B. inductive, capacitive or optoelectronic proximity switches, with at least one of the switching distance determine the, with regard to its state determining the switching distance, adjustable switching distance determining element and with at least two externally assignable connections, characterized in that the state of the switching distance determination element ( 7 ) - and thus the switching distance - adjustable via the externally assignable connections ( 8 , 9 , 10 , 11 ), namely depending on the connection of the switching device to the supply voltage ( 12 ) at least one control signal for setting the state of the switching distance determination element ( 7 ) is obtained. 2. Electronic switching device according to claim 1, namely inductive or capacitive proximity switch, with an oscillator, wherein the switching distance mood element belongs to the oscillator, characterized in that by the switching distance determining element ( 7 ) the positive feedback, the negative feedback, the amplitude or the frequency of the Oscillator ( 1 , 2 ) is adjustable. 3. Electronic switching device according to claim 1, namely optoelectronic Proximity switch, with a light transmitter and a light receiver, the Sensing range determination element to the light transmitter and / or to the light temperature catcher, characterized in that by the switching distance determination element the transmission power of the light transmitter and / or the response sensitive speed of the light receiver is adjustable. 4. Electronic switching device according to one of claims 1 to 3, characterized in that a rectifier bridge ( 6 ) with at least four rectifier elements is provided on the input side and the control signal is obtained from the rectifier bridge ( 6 ). 5. Electronic switching device according to one of claims 1 to 4, characterized in that the control signal - directly or indirectly - operated at least one control transistor ( 13 , 14 ), preferably in the embodiment as a bipolar transistor and inversely, controls and with the help of the control transistor ( 13 , 14 ) the switching distance determination element ( 7 ) is adjustable. 6. Electronic switching device according to one of claims 1 to 4, characterized in that the control signal is fed to the control input ( 18 ) of a control logic ( 19 ) and the control output ( 20 ) of the control logic ( 19 ) is connected to the switching distance determining element ( 7 ) . 7. Electronic switching device according to claim 6, characterized in that the control logic ( 19 ) has at least two different in their resistance values, to the externally assignable connections ( 8 , 9 , 10 ) connected control resistors de ( 21 , 22 , 23 ). 8. Electronic switching device according to claim 7, characterized in that in series with each control resistor ( 21 , 22 , 23 ) is a control diode ( 24 , 25 , 26 ). 9. Electronic switching device according to claim 7 or 8, characterized in that in series with the control resistors ( 21 , 22 , 23 ), the collector-emitter path ( 29 , 30 ) is at least one control transistor ( 27 , 28 ). 10. Electronic switching device according to claim 9, characterized in that at least two control resistors ( 21 , 22 ) at their the externally assignable connections ( 8 , 9 ) far ends are connected to each other. 11. Electronic switching device according to claim 6, characterized in that the control logic ( 19 ) has a decoder ( 31 ).