DE2340377C3 - Circuit arrangement for use in electromechanical switch devices with n (n greater than or equal to 3) separately operable working contacts - Google Patents

Description

The invention relates to a circuit arrangement for the bounce-free transmission of the logical -i Schalizustandcs or the inverted sound state

ao of working contacts of an electromechanical switching device with π (η ^ 3) separately operable working cones. of which at most only one is closed, switching outputs assigned to the work contacts, from which the inputs

* 5 digital circuits can be applied.

The through working contacts. z. B. by key switch, Information generated are often supplied to digitally operating facilities that are based on use this information to perform certain logical operations. To achieve perfect work Clear switching states are required for these digital devices. One possible cause of the error is in the electromechanical working contacts. which when actuated by bouncing a change in through this Koniakt can cause the signal to be generated. For immediate switching of those at risk of interference pulses Inputs of logic circuits are therefore not suitable for normal mechanical working contacts, because every sound process is accompanied by an impact more or less long series of pulses can be connected. This allows z. B. when switching on and off of the counting inputs or the counting direction inputs of up-down counters, incorrect switching occurs. These disadvantages of purely mechanical sounders are alleviated, for example, by non-contact sounders Electronic switching elements on a magnetic basis avoided, but they are relatively expensive.

In this context there is also a circuit arrangement known, which is able to occur when switching an electromechanical working contact To suppress bounce pulses. This scarf-ming essentially contains a monostable multivibrator which, when the electromechanical Switch is controlled in their working position. The one with it

SS achieved implementation of the switching country points, however the disadvantage that the duration during which the The monostable toggle switch remains in its working position for the duration of the actuation of the reversed contact is independent, i.e. the switching states are

* ° be forged.

From the German interpretation 12 90 587 is one Sound arrangement for the implementation of the weeping electromechanical Umschaltkoniakt - d. H. not through an Arbcilskonlakt - generated switching

* 5 gears in an electronically evaluable, from Kon lactation processes. Koniakiflugzeil and Siörimpulscn ineffective State known. This converter circuit contains / white gaiters, the first inputs of which

if subjected to a constant logical excitement are. The first entrance of the first gate is on the other hand with the Ruhesejte and the first entrance of the second gate with the working side of the switching contact tied together. The second inputs of both s gates are each connected to the output of the converter circuit forming outputs of the other gate connected. Either NOR gates can be used as gates or NAND gates can be used, depending on whether the constant logical excitation "one" or is "zero". Occurs when the Ümschallekontakt is actuated with this circuit a multiple opening and closing of the contact, the remains The switching state of the arrangement is retained anyway. The disadvantage of this debouncing circuit is ij in that it is responsible for the supply of digital information A changeover contact is required in order to have correct digital information at the output of the arrangement to obtain. In many cases, however, the use of a toggle switch is not possible. In this context reference is made to those Schaller in which, for example, odfi * in one plane of rotation Button set of three or more normally open contacts always only one contact is closed and this should, for example, switch through the earth potential while the other contacts are open.

In the case of simple key switches, it is already known Turn on the switch to remove the contacts /? C timing element to which an applied voltage quickly builds up when the contacts close, which only slowly decreases when the contacts are opened. Such timers are in use when generating digital signals by means of contacts unsuitable in and of themselves, as this is due to Contact pressure generated signal depending on pressure, condition of contacts, charging of the one used in the timer Capacitor may have different amplitude and duration and thus an ambiguous signal can be.

It is the object of the invention. to create a bounce-free electronic switch for switching through logical functions, in which only one of three or more electromechanical working switches is always closed and in which the disadvantages of the known switching devices are avoided. According to the invention, which relates to a circuit arrangement of the type mentioned at the outset, this object is achieved in that η first gates each assigned to a normally open contact with n-i inputs and π second gates each assigned eiiu-m work conact with η Inputs are provided that the first gates are connected in such a way that in the rest position of all arbcil contacts with all their inputs of one of the two logic switching states and in a working position of any work contact each at one of their inputs with the exception of the one in each case In the working position, the working contact associated with the first gate is acted upon by the other of the two logical Schallzusiändc that the outputs of the first gates are each connected to an input of the same working contact associated / wide gate, that the output of each of the / lingering gates with an input of all the rest of the second age group and that the outputs of the temporary gates form the circuit outputs assigned to the respective working cones. In (vycnsatz / u known iniegrierenden circuits where additional delays must be taken against the contact processes of electromechanical working contacts in buying, resulting in the arrangement of the invention, no additional delays. It can be ordinary switch means with electromechanical working contacts use, where by the gate connection makes the bouncing ineffective.

Are the inputs of all first gates in the rest position of all working contacts of the logical switching state If "one" is applied, AND gates can be used for the first gates and NAND gates for the second gates be used.

In contrast, the inputs of all first gates are in the rest position of all working contacts of the logical When switching state »Zero« is applied, the first gates are OR gates and the second gates NOR gate can be used.

Further details of the invention are illustrated by means of three in three figures, exemplary embodiments explained in more detail.

F i g. 1 shows a bounce-free electronic switch with three contacts using AND gates (first gate) and NAN D gates (second gate);

F i g. 2 shows a bounce-free switch with four contacts using AND gates (first Gate) and NAND gates (second gate) and

F i g. Figure 3 shows a bounce-free electronic switch according to the invention with three contacts in use of OR gates (first gate) and NOR gates (second gate).

F i g. 1 shows a bounce-free switch arrangement according to the invention with three electromechanical working contacts 1, 2 and 3. One connection of the working contacts 1, 2 and 3 is connected to earth, while the other connection is connected to the positive pole via a resistor 6, 4 and 5 + U is connected to a grounded operating voltage source. Each normally open contact 1, 2 and 3 is assigned two gates, namely normally open contact 1 an AND gate 7 and a NAND gate 16, working clock 2 an AND gate 8 and a NAND gate 17 and working contact 3 an AND gate 9 and a NAND gate 18. AND gate 7 has two inputs 10 and 11, AND gate 8 has two inputs 12 and 13, and AND gate 9 has two inputs 14 and 15. The inputs 10 and 13 are on the connection of the normally open contact 3 facing away from the ground side, the inputs II and 15 on the terminal of the normally open contact 2 facing away from the ground side and the inputs 12 and 14 on the terminal of the normally open contact 1 facing away from the ground side. The NAND gates 16, 17 and 18 each have three inputs, namely 19, 20, 21 and 22, 23, 24 and 25, 26, 27 respectively. The output of the AND gate 7 is connected to the input 19 of the NAND gate I «J. the output of the AND gate 8 is connected to the input 23 of the NAND gate 17 and the output of the AND gate 9 is connected to the input 27 of the NAND gate 18. The outputs of the NAND gates 16, 17 and II at the same time form the outputs 28, 29 and 30 of the overall circuit, at which the Schaltzurtand of the associated Arbeilsoniakle 1, 2 and 3 is present. The inputs 20 and 21 of the NAND gate 16 are at the output 29 and 3J of the NAND gates 17 and 18, the inputs 22 and 24 of the NAND gate 17 at the output 28 and 30 of the NAND gates 16 and 18 and the Inputs 25 and 2f> of the NAND gate <■ at the output

aisle 28 or 29 of the NAND (lukewarm 16 and 17.

The schallung according to I i g. I thus transmits the Switching states of the working contacts I. 2 and 3 on the outputs 28, 29 and 30. It is assumed that Frdpotential represents the logic state »zero« When, for example, the normally open contact I is pressed, the two AND gates 8 and 9 are on the output side switched to the logic state "zero", since there is a transmission potential at inputs 12 and 14 (= logic state Zero). The logic circuits at the inputs 10 and II of the gate 7 are through Actuation of the working cone I not changed, so that at these inputs 10 and II as well as on Input 13 of AND gate 8 and the operating voltage + // is applied to input 15 of AND gate 9, wel before the logical sound addition "Fms" represents. in the The example of operation given exists at the outputs the AND gates 8 and 9 the logical switching state "zero", while the AND (latter 7 the logical Switching status »one« is present. Since the two NAND gates 17 and 18 have at least one input the logic state "zero" exists, namely at inputs 23 and 27, and at outputs 29 and 30 these two gates / wanglaufig the logic switching state "one" before. Through the logical click coupling from the outputs 29 and 30 to the two fingers 20 and 21 of the NAND gate 16 is due to the existence of the logical state "Fms" at all three inputs 19, 20 and 21 of the NAND gate 16 at its output 28 the logic switching state "zero" jo This state corresponds to the button position of the normally open contact I. Even if the operating contact I is opened again, the sound conditions remain on the outputs 28, 29 and 30, there is one against locking on the side. Only after pressing another normally open contact, i. H. either of the Ar bcitskoniaktes 2 or J. arise at two of the exits 28. 29 and 30 new relationships. The bounce The mutual connection of the Inputs of each NAND gate with the outputs of the other NAND clatters forced because already

uic first Scnaiiiiaiikc »Γιπν» »Nuü« an nüim <icr

Arbeil contacts 1. 2 or 3 the potential states very much sets quickly. Further pulse trains on the same work contact can no longer cause any changes For a switching edge triggered by pressing another normally open contact leaves a new switching state develop.

This principle can also be extended to switches with more than three normally open contacts. In Fig. 2 is the Circuit arrangement of a bounce-free electronic switch with four working contacts shown in detail. Due to the additional working contact 31 compared to the arrangement in FIG. 1 is also an additional one AND gate 33 and an additional NAND gate 40 are provided. All AND gates 7. 8. 9 and 33 have three inputs in this example, with the additional input of gate 7 at 34.

the additional gate 8 entrance with 35th the additional Input of gate 9 with 36 and the three inputs of the additional AND gate 3 3 with 37. 38 and 39 are designated. The NAND gates 16, 17, 18 and 40 also show opposite your example after I 1 g I one more input. The additional Input of the NAND gate 16 is with 41, the addi before the entrance of the NAND galler 17 at 42, the addi before the entrance of the gate 18 with 43 and the four entrances of the additional NAND gallery 40 are designated 44, 45, 46 and 47. The one connection of the additional Arbcilkontaktcs 31 is connected to earth while the other connection via a resistor 32 to the positive pole + i / of the grounded Hetricbsspanmings <| ucl! c connected. The mode of operation agrees with that of the circuit according to Γ 1 g. I match.

The number of AND gates and that of the NAND Gate agrees with the number of normally open contacts provided in the switch device ubcrcm The NAND gates have as many inputs as Normally open contacts while the AND gates each have one input less. So can Use normal rotary and key switches, whose profile properties require little additional effort. namely, by involving animals, preferably integrated (l: \ tterelcmcnte. be eliminated

I i g 3 shows a bounce-free electronic switch arrangement according to the invention with three electromechanical working contacts 51. 52 and 53. In this case play lies one connection of the Aibeilskonlakle 51. 52 and 53 at positive potential, while the other at Conclusion about a contradiction in each case 57, 58 and 59, 111 Ground potential is also connected in this version The er.ipoiential example is logical sound state »zero« and the positive operating voltage is assigned the logical switching state »one«. | every Ar bcitskontakt 51, 52 and; two gates are assigned, namely an ODEiR gate 54 and a NOR gate 60 to the working contact 52 OR gate 55 and a NOR gate 61 and the Arbcitskontakt 53 an OR gate 56 and a NOR

Ciutlcr 52. HtT'ichlÜch der Arw-ihl git * r f'.attprpintfünpr

and their connections are in accordance with the exemplary embodiment according to FIG. 1. Also the off gates 63. 64 and 65 of gates 60. 61 and 62 are in fed back in a consistent manner. On the basis of the opposite logical Switching status at the corresponding switching points. d. H. an interchange, also has agreement with regard to the logical mode of operation of the Circuit with that according to F- "i g. 1. Similar circuits can also be used as a combination of NAND- and represent NOR or NOR and NAND gates in the first and second gate groups, respectively, one Inversion of the switching function at the input and output

successful ("one" "" zero "and vice versa).

To enter the switching function, instead of the working normally closed contacts can also be used.

For this purpose 2 sheets of drawings

Claims (7)

P; male claims: 1.Circuit arrangement for prellfrcien Wejtergabc the logical switching state or the inverted sound state of working contacts of an electromechanical switching device with η (π ^ 3) separately operable working contacts, of which at most only one is closed, switching outputs assigned to the working contacts, from which the inputs digital circuits are applied, characterized in that π first gates (7, 8, 9) each assigned to a working contact (1, 2, 3) and each with n inputs (t0, 11; 12, 13; 14, 15) and π second gates (16, 17, 18) each assigned to a working contact (1, 2, 3) and each with η inputs (19, 20.21; 22.23.24; 25.26. 27) are provided that the first Gates (7, 8, 9) are connected on the input cable so that in the rest position of all working contacts (i, 2, 3) with all of their inputs (10 to 15) they are from one of the two logical switching states and in the working position of any working contact (1, 2, 3) at one of their inputs (10 to 15) with the exception of the normally open contact (1. 2,3) assigned first gate (7,8,9) are acted upon by the other of the two logic switching states that the outputs of the first gates (7,8.9) each with an input (19,23.27) of the same working contact! (i. 2. 3) associated second gate (16, 17. 18) are connected so that the output of each of the second gates (t6. 17. ta) with an input (22, 25; 20.26; 21.24) of all <ibris » : n of the second gate is connected and that the outputs of the second gates (16. 17. 18) form the circuit outputs (28.29.30) assigned to the respective Arbeiiskontakievi (1. 2. 3). 2. Circuit arrangement according to claim 1, characterized characterized in that the first gates AND gates (7,8.9) and the second gates NAND gates (16. 17.18) and that the inputs (10 to 15) of all first gates (7, 8, 9) are in the rest position of all Working contacts (1. 2. 3) from the logical sound state "One" are applied. 3. Circuit arrangement according to claim I. characterized characterized in that the first gates OR gates (54, 55, 56) and the second gates NOR gates (60.61.62) are and that the inputs of all first Galter (54.55.56) in the rest position of all Working cones (51,52,53) from the logical switching state "Zero" are applied (Fig. 3). 4. Circuit arrangement according to claim I, characterized in that the first gates are NOR gates and the second gates are NAND gates and that the logical signal is inverted at the respective associated circuit output (“one” - “>> zero” and vice versa }. 5. Sound arrangement according to claim I. characterized in that the first gates are NAND gates and the second gates are NOR gates and that the logical sound function is inverted at the respective associated sound output (“one” - “zero” and vice versa ). 6. Circuit arrangement according to one of the preceding claims, characterized in that each working contact (1, 2, 3) at its one terminal each having an input (12, 14) of the first gate (8, 9) not assigned to it and each having one (6) is connected by η resistors (4,5,6) and that between the interconnected other ends of the η resistors (4, 5, 6) and the second connection of the working contacts (1, 2, 3) an operating voltage source (LJ) lies. 7. Circuit arrangement according to one of the preceding claims, characterized in that instead of the working contacts, rest contacts are provided.