DE4114763C1 - - Google Patents

Description

The invention relates to an electronic switching device, for. B. an induc tive, capacitive or optoelectronic proximity switch or one Flow monitor, with a presence indicator that can be influenced from outside, e.g. B. an oscillator with a subordinate to the presence indicator Switch amplifier, with one of the presence indicator on the switch amplifier controllable electronic switch, e.g. B. a transistor, a thyristor or a triac, with a four rectifier elements pointing rectifier bridge and with two supply connections, which in a first variant - called "make polarity" - with a DC voltage are connected or swapping the two supply connections in a second variant - referred to as "break polarity" - are connected to the DC voltage, the switching amplifier two anti has valid control outputs. This can be a two-wire Switchgear, but also a three-wire switchgear - with two supply connections and with an additional signal output - act.

Electronic switching devices of the type in question here are basically executed contactless and have been increasing for about twenty years now instead of electrical, mechanically operated switching devices, which are designed with contacts, used in particular in electrical or electronic measuring, control and regulating circuits. This is especially true for so-called proximity switches, d. H. for electronic switching devices that touch work effortlessly. Such proximity switches are used to indicate whether an influencing element for which the corresponding proximity switch sen is sitiv, has approached the proximity switch sufficiently far. Has namely an influencing element for which the corresponding proximity scarf ter is sensitive, sufficiently close to the proximity switch, so controls the one forming an essential part of the proximity switch Presence indicator the electronic switch around; with one as a closer executed switching device, the non-conductive electronic switch is now  more conductive, while the lei Tending electronic switch now blocks. (With switchgear in question standing type can also be indicated whether a physical quantity of a Influencing medium, for which the switching device is sensitive, a correspond value exceeds or falls below.)

An essential part of the electronic switchgear described above benen type is u. a. the presence indicator that can be influenced from outside.

As a presence indicator, e.g. B. an inductive or capacitive influence cash oscillator may be provided; then it is inductive or capacitive proximity switches (see e.g. the German published documents 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, 23 36 440, 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). As a presence indicator a photo resistor, a photo diode or a photo transistor are also provided be; they are then optoelectronic proximity switches (cf. e.g. German Offenlegungsschriften 28 24 582, 30 38 102, 33 27 328, 35 14 643, 35 18 025, 36 05 885). Finally, a presence indicator can also be used Temperature measuring circuit may be provided; it is then flow guardian (cf. e.g. the German published documents or patent documents 37 13 981, 38 11 728, 38 25 059, 39 11 008, 39 43 437).

In the case of inductive proximity switches, the oscillator applies as long as a metal has not yet reached a predetermined distance, K × V = 1 with K = Feedback factor and V = gain factor of the oscillator, i. H. the Oscillator swings. The corresponding metal part reaches the prescribed NEN distance, the increasing damping of the oscillator leads to a Reduction of the gain factor V, i. H. the amplitude of the oscillator vibration decreases or the oscillator stops vibrating. At kapa  cited proximity switches apply to the oscillator as long as a response body per the capacitance between a response electrode and a counter electrode has not yet reached K × V <1, i.e. H. the oscillator is not oscillating. He if the response body reaches the specified distance, the increasing one leads Capacitance between the response electrode and the counter electrode to one Increase of the feedback factor so that K × V = 1, i. H. the Os zillator starts to swing. In both embodiments - more inductive Proximity switch and capacitive proximity switch - depends on the different states of the oscillator the electronic switch, e.g. B. a transistor, a thyristor or a triac controlled.

Optoelectronic proximity switches have a light transmitter and a light receiver and are also referred to as light barriers. Doing so under one differentiates between a type of light barrier in which the light transmitter and the light receiver on opposite sides of a surveillance route are arranged, and a light barrier type in which the light transmitter and the Light receivers are arranged at the same end of a monitoring section, while a reflector located at the other end of the monitoring path reflect the light beam from the light transmitter back to the light receiver animals. In both cases, the presence indicator responds when the nor light beam from the light transmitter to the light receiver an influencing element that has entered the monitoring section is interrupted becomes. However, there are also light barriers of the light described last type of cabinet in which the light beam coming from the light transmitter only passes through a corresponding influencing element is reflected back to the light receiver becomes.

In the following, an inductive proximity switch is always used as an example delt. Nevertheless, all statements always apply to other types of electronic switching devices of the type described above and previously explained ter type, especially for capacitive and optoelectronic proximity scarf ter and for flow monitors.  

Electronic switching devices of the type in question are - like electri mechanical, mechanically operated switchgear - both as a make contact (in the affected The state of the presence indicator is the electronic switch conductive) and as an opener (in the affected state of the presence ind kators, the electronic switch is non-conductive).

Since it is now undesirable for storage reasons, on the one hand as a closer, on the other hand to use electronic switching devices designed as break contacts, there are a variety of electronic switching devices in question Type that can be used both as a make contact and as a break contact. In particular, there are electronic switching devices that are "programmable by connection" are (see. DE-PSen 31 23 828 and 32 14 836). "Connection programmable" means that by a certain connection of the switching device to the Supply voltage is determined whether the switching device as a make contact or works as an opener.

In particular, there are different types of "connection programmable" elec tronic switching devices known. In a first embodiment - Instead of the actually only two - three or four supply devices conclusions provided. Depending on whether the supply voltage to the first and the second supply connection or to the first and the third Ver supply connection (Fig. 1 and 3 of DE-PS 31 23 828, Fig. 2 of DE-PS 32 14 836) or to the first and the second supply connection or to the third and the fourth supply connection (Fig. 4 of DE-PS 31 23 828) connected the switching device works as a make contact or a break contact (or vice versa) returns). In a second embodiment, which is called "Qua dronorm "has attracted considerable attention on the market, only the necessary ones two supply connections available (see. Fig. 1 of DE-PS 31 23 828 in Connection with column 4, lines 48 to 59). Depending on whether the positive Supply voltage to the first and the negative supply voltage the second supply connection or the negative supply voltage to the first and the positive supply voltage to the second supply is created, the "Quadronorm" switching device works as a break contact or as a closer (or vice versa).  

On the one hand, in the "connection programming described above in detail baren "switching devices - as part of the switching amplifier or between the Switch amplifier and the electronic switch - an exclusive OR gate required and have commercial integrated circuits (IC's) that extensive for electronic switching devices of the type in question here used, usually no exclusive OR gate. On the other hand there are a variety of specific ones for electronic switchgear here type in question developed integrated circuits in which the Switching amplifier has two antivalent control outputs (see the inte free circuit TCA 205 from Siemens AG, Siemens data book 1982/1983 "Integrated Circuits for Industrial Applications", pages 191-200, and the integrated circuit TDE 0160 from THOMSON-CSF, THOMSON- Datasheet "THOMSON-EFCIS Integrated Circuits TDE 0160").

The invention is based on the object, a further embodiment to specify a "connection programmable" electronic switching device, So to design the electronic switching device described above and to further develop that it is "connection programmable".

The switching device according to the invention is now characterized in that the electronic switches then and only then from the first control output - normally open - Control output - the switching amplifier can be controlled when the ver supply voltage in "make polarity" to the supply connections is closed, and then and only then from the second control output - normally closed control output - the switching amplifier is controllable when the supply voltage in "break contact polarity" connected to the supply connections is. According to the invention it has been recognized that the integrated switching circles for electronic switching devices often existing antivalent tax outputs - NO control output and NC control output - of the switching conn starters can be used in a surprisingly simple manner to implement "connection programmable" switching device without it Exclusive OR gate required.  

In the electronic switching device according to the invention there is a control signal at the normally open control output of the switching amplifier only "effective" if the switching device according to the invention as a make contact to the supply voltage is connected or if the supply voltage in "NO contact polar "is connected to the supply connections the electronic switching device according to the invention a control signal at the NC Control output of the switching amplifier only "effective" if this is invented Switching device according to the invention is connected to the supply voltage as a break contact sen or if the supply voltage in "NC polarity" to the Ver supply connections is connected.

Refinements and developments of the teaching of the invention result from the claims subordinate to claim 1. Furthermore the invention is based on an exemplary embodiment only illustrative drawing again - and supplementary - explained; it shows

Fig. 1 is a circuit diagram of a first embodiment of an inventive electronic switching device and

Fig. 2 is a circuit diagram of a second embodiment of an electronic switching device according to the Invention.

In the figures there are essentially only circuit details from him electronic switching devices according to the invention, in the exemplary embodiments len of inductive proximity switches, shown for understanding nis the teaching of the invention are required.

To those shown in the figures, electronic switching devices include a influenceable from the outside proximity indicator, wherein the inductive proximity therefore an oscillator 1, a the presence indicator or the oscillator 1 switches subordinate switching amplifier 2, an indicator of the presence or the oscillator 1 via the amplifier 2 Controllable electronic switch 3 , a rectifier bridge 4 having four rectifier elements and two supply connections 5 , 6 . The switching amplifier 2 has two antivalent control outputs, namely a normally open control output 7 and a normally closed control output 8 .

For the electronic switching devices shown in the figures, de NEN are DC switching devices, it applies first that the electronic switch 3 then and only then from the NO control output 7 of the switching amplifier 2 can be controlled when the supply voltage in "Normally open polarity" is connected to the supply connections 5 , 6 , and can then and only then be conductively controlled by the normally closed control output 8 of the switching amplifier 2 when the supply voltage is connected to the supply connections 5 , 6 in "normally closed polarity". According to the invention, it has been recognized that the integrated switching circuits for electronic switching devices of the type in question frequently present antivalent control outputs - normally open control output 7 and opening control output 8 - of the switching amplifier 2 can be used in a particularly simple manner for this purpose, " to implement connection-programmable "switching devices without the need for an exclusive OR gate.

In the two exemplary embodiments of electronic switching devices according to the invention shown in the figures, a control signal at the normally open control output 7 of the switching amplifier 2 is only "effective" when the switching device is connected as a normally open contact to the supply voltage or when the supply voltage is in "normally open" polarity "is connected to the supply connections 5 , 6 . Correspondingly, a control signal at the NC control output 8 of the switching amplifier 2 is only "effective" when the switching device according to the invention is connected as an NC contact to the supply voltage or when the supply voltage is connected in "NC contact polarity" to the supply connections 5 , 6 is.

For the embodiment of an electronic switching device according to the invention shown in Fig. 1 now applies that between the normally open control output 7 of the switching amplifier 2 on the one hand and the control input 9 of the electronic switch 3 on the other hand, a control transistor 10 is provided that the base 11 of the control transistor 10th then and only then can be controlled by the normally open control output 7 of the switching amplifier 2 if the supply voltage in "normally open polarity" is connected to the supply connections 5 , 6 , and then and only then can be controlled by the normally closed control output 8 of the switching amplifier 2 , when the supply voltage is connected to the supply connections 5 , 6 in "open polarity", and that the electronic switch 3 can be turned on by the controlled control transistor 10 . In particular, a control resistor 12 , 13 is provided between the NO control output 7 of the switching amplifier 2 and the base 11 of the control transistor 10 and between the NC control output 8 of the switching amplifier 2 and the base 11 of the control transistor 10 and is between those of the base 11 of the control transistor 10 fer NEN ends of the drive resistors 12 , 13 and each supply connection 5 , 6 each have a connection programming diode 14 , 15 switched in the forward direction. In addition, for the embodiment shown in Fig. 1 of an electronic switching device according to the invention that between the normally open control output 7 of the switching amplifier 2 and the associated control resistor 12 and between the normally closed control output 8 of the switching amplifier 2 and the associated control resistor 13 , a Ent Coupling resistor 16 or 17 is provided and that an auxiliary control transistor 18 is connected upstream of the control transistor 10 .

For the embodiment of an electronic switching device according to the invention shown in Fig. 2 applies first that a normally open control transistor 19 and between the normally closed control output 8 of the switching amplifier 2 and between the normally open control output 7 of the switching amplifier 2 and the control input 9 of the electronic switch 3 the control input 9 of the electronic switch 3, an NC control transistor 20 is provided that the base 21 of the NO control transistor 19 can then and only be controlled by the NO control output 7 of the switching amplifier 2 when the supply voltage in "NO polarity" to the Supply connections 5 , 6 is connected so that the base 22 of the break control transistor 20 can be controlled only from the break control output 8 of the switching amplifier 2 when the supply voltage is connected to the supply connections 5 , 6 in "break polarity", and that the electronic switch 3 can be conductively controlled by the controlled normally open control transistor 19 or by the controlled normally closed control transistor 20 . This is realized in the exemplary embodiment in that between the base 21 and the emitter 23 of the normally open control transistor 19 and between the base 22 and emitter 24 of the normally closed control transistor 20 on the one hand and each supply connection 5 , 6 on the other, one in Forward direction switched connection programming diode 25 , 26 is provided.

Finally, for the exemplary embodiments of electronic switching devices according to the invention, which are shown in FIGS . 1 and 2, that the control input 9 of the electronic switch 3 with the collector 27 of the control transistor 10 ( FIG. 1) or with the collectors 28 , 29th the normally open control transistor 19 and the normally closed control transistor 20 ( FIG. 2) is connected.

For the function of the electronic switching devices according to the invention shown in FIGS . 1 and 2, the following:

Is connected in the electronic switching device shown in Figure 1 to the United supply terminal 5 of the negative pole of the supply voltage and to the supply terminal 6 of the positive terminal of the supply voltage, then this switch works as a make contact; this connection of the supply voltage is thus a connection in "make polarity". A control signal at the normally open control output 7 of the switching amplifier 2 leads to the auxiliary control transistor 18 and the control transistor 10 becoming conductive and consequently also the electronic switch 3, which in the exemplary embodiment consists of four transistors, is controlled to be conductive. A control signal at the opening control output 8 of the switching amplifier 2 remains ineffective because of the programming diode 15 .

. Is connected in the shown in Fig electronic switching device to the supply connection 5 Ver 1 of the positive pole of the supply voltage and supply terminal to the negative terminal 6 of the versor of the supply voltage, then this switching device operates as an opener; this connection of the supply voltage is thus a connection in "break polarity". A control signal at the normally closed control output 8 of the switching amplifier 2 leads to the fact that the auxiliary control transistor 18 and the control transistor 10 become conductive and that the electronic switch 3 is also controlled to be conductive. A control signal at the NO control output 7 of the switching amplifier 2 remains ineffective because of the connection programming diode 14 .

If the electronic switching device shown in FIG. 2 is connected to the supply terminal 5 of the positive pole of the supply voltage and to the supply terminal 6 of the supply pole of the supply voltage, then this switching device works as a make contact; this connection of the supply voltage is here a connection in "make polarity". A control signal at the normally open control output 7 of the switching amplifier 2 leads to the normally open control transistor 19 becoming conductive and consequently also the electronic switch 3 , again consisting of four transistors, being controlled. A control signal at the NC control output 8 of the switching amplifier 2 remains ineffective because of the connection programming diode 26 .

Is connected in the electronic switching device shown in Fig. 2 to the supply terminal 5 of the negative pole of the supply voltage and to the supply terminal 6 of the positive terminal of the supply voltage, then this switching device works as a break contact; this connection of the supply voltage is here a connection in "break polarity". A control signal at the NC control output 8 of the switching amplifier 2 leads to the NC control transistor 20 becoming conductive and consequently the electronic switch 3 also being controlled to be conductive. A control signal at the NO control output 7 of the switching amplifier 2 remains ineffective because of the connection programming diode 25 .

Claims (8)

1. Electronic switching device, in particular inductive, capacitive or opto-electronic proximity switches or flow monitors, with a presence indicator that can be influenced from the outside, for. B. an oscillator, with a downstream of the presence indicator switching amplifier, with an electronic switch controllable by the presence indicator via the switching amplifier, e.g. B. a transistor, a thyristor or a triac, with a rectifier bridge having four rectifier elements and with two supply connections, which in a first variant - referred to as "make polarity" - are connected to a direct voltage or by swapping the two supply connections in a second variant - referred to as "NC polarity" - are connected to the DC voltage, the switching amplifier having two non-equivalent control outputs, characterized in that the electronic switch ( 3 ) then and only then from the most control output - NO control output ( 7 ) - the switching amplifier ( 2 ) is controllably conductive when the supply voltage is connected in "make polarity" to the supply connections ( 5 , 6 ) and then and only then from the second control output - break control output ( 8 ) - of the switching amplifier ( 2 ) can be controlled when the supply voltage is in "NC contact ät "is connected to the supply connections ( 5 , 6 ). 2. Electronic switching device according to claim 1, characterized in that between the normally open control output ( 7 ) of the switching amplifier ( 2 ) and the normally closed control output ( 8 ) of the switching amplifier ( 2 ) on the one hand and the control input ( 9 ) of the electronic switch ( 3 ) on the other hand a Steuertransi stor ( 10 ) is provided that the base ( 11 ) of the control transistor ( 10 ) and then only from the NO control output ( 7 ) of the switching amplifier ( 2 ) can be controlled when the supply voltage in "NO -Polarity "is connected to the supply connections ( 5 , 6 ), and can then and only then be controlled by the break control output ( 8 ) of the switching amplifier ( 2 ) when the supply voltage in" break polarity "to the supply connections ( 5 , 6 ) is connected, and that the electronic switch ( 3 ) can be controlled by the controlled control transistor ( 10 ). 3. Electronic switching device according to claim 2, characterized in that between the normally open control output ( 7 ) of the switching amplifier ( 2 ) and the base ( 11 ) of the control transistor ( 10 ) and between the normally closed control output ( 8 ) of the switching amplifier ( 2nd ) and the base ( 11 ) of the control transistor ( 10 ) each have a drive resistor ( 12 , 13 ) is provided and between the base ( 11 ) of the control transistor ( 10 ) distal ends of the drive resistors ( 12 , 13 ) and each supply connection ( 5th , 6 ) a connection programming diode ( 14 , 15 ) switched in the forward direction is provided. 4. Electronic switching device according to claim 3, characterized in that between the normally open control output ( 7 ) of the switching amplifier ( 2 ) and the associated control resistor ( 12 ) and between the normally closed control output ( 8 ) of the switching amplifier ( 2 ) and the associated Control resistor ( 13 ) each has a decoupling resistor ( 16 or 17 ) is provided. 5. Electronic switching device according to one of claims 2 to 4, characterized in that an auxiliary control transistor ( 18 ) is connected upstream of the control transistor ( 10 ) on the input side. 6. Electronic switching device according to claim 1, characterized in that between the normally open control output ( 7 ) of the switching amplifier ( 2 ) and the control input ( 9 ) of the electronic switch ( 3 ) a normally open control transistor ( 19 ) and between the normally closed Control output ( 8 ) of the switching amplifier ( 2 ) and the control input ( 9 ) of the electronic switch ( 3 ) an NC control transistor ( 20 ) is provided that the base ( 21 ) of the NO control transistor ( 19 ) then and only then Normally open control output ( 7 ) of the switching amplifier ( 2 ) can be controlled when the supply voltage is connected in "normally open polarity" to the supply connections ( 5 , 6 ) that the base ( 22 ) of the normally closed control transistor ( 20 ) then and only then from the NC control output ( 8 ) of the switching amplifier ( 2 ) can be controlled when the supply voltage is connected in "NC polarity" to the supply connections ( 5 , 6 ) and that the electronic switch ( 3 ) can be conductively controlled by the controlled normally open control transistor ( 19 ) or by the controlled normally closed control transistor ( 20 ). 7. Electronic switching device according to claim 6, characterized in that between the base ( 21 ) or the emitter ( 23 ) of the normally open control transistor ( 19 ) and between the base ( 22 ) or the emitter ( 24 ) of the opening ner - Control transistor ( 20 ) on the one hand and each supply connection ( 5 , 6 ) on the other hand, each has a switching pro gramming diode ( 25 , 26 ) connected in the forward direction. 8. Electronic switching device according to one of claims 2 to 7, characterized in that the control input ( 9 ) of the electronic switch ( 3 ) with the collector ( 27 ) of the control transistor ( 10 ) or with the collector ren ( 28 , 29 ) of Normally open control transistor ( 19 ) and the normally closed control transistor ( 20 ) is connected.