DE2442061B2 - Contactless logic circuit - Google Patents

Description

The invention relates to a contactless logic circuit with electronic unit circuits as Replacement for make and break contacts of a relay, in which the input and output connections of the standard circuits to the input and output connections of a Circuit carrier plate are performed, the unit circuits from a NAND gate and a Inverter exist, which is connected to one input of the NAND gate, the other input with a Voltage source is connected, and the logic circuit is designed so that a direct transfer in relay circuit diagrams is possible.

It has long been known that devices with relays when performing certain control processes whose mode of operation is based on the mechanical closing or opening of the relay contacts. Such facilities have several Disadvantages, such as B. the frequent occurrence of relay malfunctions, short life and a constant Maintenance and inspection. Efforts have therefore been made for a long time to gradually replace systems with relay contacts with contactless electronic logic circuits with semiconductor components that have the perform equivalent functions to conventional devices with relay contacts.

If a control process that has an operating mode equivalent to a relay contact circuit is included in the Concepts of the conventional logic circuits shown, then special logic circuit symbols must be used, which compared to the in The symbols used in relay circuits are completely different. Engineers and technicians working with the Symbols of relay technology are familiar, therefore necessarily have to be familiar with new and unusual logical symbols and their interpreta-

acquisition.

When implementing a command sequence for a conventional Relay contact circuit in the command sequence for a logic circuit must be a conventional one Circuit diagram can be rewritten into a completely new circuit diagram. In this implementation, the There is a relatively high risk that mistakes will be made in the command plan.

Even when a certain command sequence is implemented by conventional logic circuits ι ο have such logic circuits due to the external noise influences affecting the circuit a low, disadvantageous operational reliability.

As mentioned above, there have been several major barriers to implementing conventional logistics shear circuits with mechanical contacts in contact lens logic circuits.

In those cases in which a contactless command sequence is implemented by conventional logic circuits there has long been a need for at least three different circuits, viz Use AND gates, OR gates and inverter circuits. These circuits must be interconnected be. The required use of various kinds of circuits has a complex circuit structure and a larger space requirement. '

You have therefore already contactless logic circuits of the type mentioned (DE-OS 21 13 610) developed the standard circuits from one NAND gate and an inverter with two inputs included. However, there is only a very special circuit structure with these known unit circuits Can be implemented with four-fold NAND gates and six-fold inverters. Correspondingly, this can be known logic circuit only realize a very special relay contact sequence, so that this known Circuit is limited in its usability.

It is the other hand, according to DE-AS 12 29134 a special ^E: nheitsschaltkreis known, which consists of a total of four AND circuits, the two parallel -to-connected current branches represent, each leg includes two AND circuits to a negated input Each AND The circuit has three inputs. This circuit, too, cannot be used to implement any relay contact sequences using contactless logic circuits; it is rather limited to a special purpose, to a special relay contact arrangement

In contrast, the invention is based on the object of providing a contactless logic circuit of the create initially mentioned type ru, whose unit circuits of a type in a simple manner to any Contact arrangements that correspond to conventional relay control circuits can be interconnected.

This object is achieved by the characterizing features of the ^r '~> part of claim 1.

With the contactless logic circuit according to the invention, it is possible to design any control circuits in the relay circuit diagram structure known to all circuit designers and to implement them as a t> o logic circuit without mechanical contacts. According to the invention, circuit boards of only one type are used. Relay circuits that contain several mechanical relay contacts can be easily simulated with the "logic circuit according to the invention, without the need for a" translation "of the relay circuit diagram The circuit carrier plates according to the invention are economical to manufacture because of their similar structure.Only one circuit carrier plate has to be kept in stock, which significantly simplifies storage.

The circuit according to the invention works faultlessly in spite of external noise influences. It enables simple interlocking of circuit operations in the individual circuit areas that control the relay correspond.

Advantageous further developments are characterized by the subclaims Circuit according to the invention a device containing capacitance for the time delay of signals provided and connected to the devices for generating and applying the driver signal. In order to the circuit can be used as a timing circuit to achieve the delay in the switching operation.

In the following, exemplary embodiments of the invention are described in more detail with reference to the drawing. It shows

Figs. IA and IB are circuit diagrams showing a relay contact circuit or the basic structure of the unit circuit of a corresponding logic circuit represent,

F i g. 2A, 2B and 2C Circuit diagrams with two relay circuits in which two relay contacts are in series with one another are connected, a logic symbol equivalent to the relay contact circuit, and a logic circuit which is composed of two unit circuits

F i g. 3A, 3B and 3C circuit diagrams of a relay circuit with two relay contacts connected in parallel, the conventional logical symbol corresponding to this circuit, and a logical structure of two Unit circuits,

F i g. 4A and 4B are circuit diagrams of a relay circuit in which two relay contacts are parallel to each other and a Relay contact is in series with this parallel connection, and an equivalent logical connection that consists of Standardized circuits are constructed,

5A and 5B are circuit diagrams of a relay circuit with four relay contacts that are parallel to each other and a basic structure of one of these relay circuits equivalent logic circuit,

F i g. 6 is a schematic block diagram of an installation with a logic circuit,

F i g. 7A and 7B a plan view and a front view of a carrier plate for a logic circuit,

F i g. Fig. 8 is a circuit diagram of an embodiment of a logic circuit on a carrier plate can be installed and corresponds to a conventional relay,

F i g. 9 a circuit diagram of a stabilized power supply unit, which is installed on the carrier plate and

Fig. 10 is a circuit diagram of an embodiment of a Connection unit which can be switched between a logic circuit and external connection devices.

First, a basic structure of the unit circuit will now be described below.

Fig. 1A shows a conventional relay circuit with a relay contact. A relay contact 12 is located between the input terminal 10 and the Output connection 11. This contact goes off when

generation of the relay coil 13 responding to a signal applied to the control input 14 into the closed Condition over. If a signal is present at the input connection 10 when the relay contact 12 is closed, it can this signal can be picked up at the output terminal 11.

In Pig. IB is shown a logic circuit that the relay contact circuit of FIG. 1A corresponds to, and which is hereinafter referred to as the "unit circuit". The unit circuit has a basic structure in which a signal applied to an input connection 15 arrives at the input of a NAND element 17.

The signal from the terminal 15 is applied via an inverter 16, while a signal is applied to the input 18 Control signal is applied via the inverter 19 to the other input of the NAND gate 17. It will that is, a logical product (AND-NOT) is formed and the output signal at the output terminal 20 is removed.

Is the control voltage applied to the control terminal 18 large (hereinafter referred to as W level), the control voltage before it is applied to an input of the NAND gate 17, converted by the inverter 19 into a small voltage (hereinafter referred to as L level). The result is that the Output signal of the NAND gate 17 regardless of whether the signal level is on, input signal 15 low or high, is always at the W level. This state corresponds to that shown in FIG. 1A Circuit when relay contact 12 is open.

If, on the other hand, the control signal at the control input 18 has a level L, the control signal is fed to an input of the NAND element 17 via the inverter 19 as a // level. A signal is then passed from the input connection 15 via the inverter 16 to the NAND gate 17. This signal goes like this. as it is, through element 17 and appears as an output signal at output terminal 20. This state is equivalent to the operating state of the relay circuit shown in FIG. 1A when contact 12 is closed.

In Fig. 2B there is shown a logic circuit which the unit circuit with two input and output terminals 21 and 22 in series Relay contacts 23a and 236 corresponds to that shown in FIG. 2A is shown. The circuit of Fig. 2B includes the Input terminals 24a and 24b and a NAND gate 25 in the illustration of the conventional logic Circuit symbols. Only when both relay contacts 23a and 236 are closed, i. h if signals to both Input terminals 24a and 246 are applied, an output signal can be picked up at the output terminal 26 will.

If the relay contact circuit according to Fig. 2A is constructed by means of the standard circuits, results the in F i g. The circuit shown in Fig. 2C. I. E. from the inverter 28a and the NAND gate 29a and from unit circuits consisting of the inverter 286 and the NAND gate 296 correspond to each Relay contact 23a and relay contact 236. These two unit circuits are in series with one another. An input signal applied to the input terminal 27 can then only be used at the output terminal 31 as Ausgarigssigna! decrease when ar. both input ports 30a and 306 signals are applied.

The circuit shown in FIG. 3A with two inputs 32a and 326, one output connection 34 and two relay contacts 33a and 336, which are parallel to each other, can be made using the conventional logical symbols represented by an OR element 36 and two input terminals 35a and 356 be, see F i g. 3B. If at least one of the contacts 33a and 336 is closed, i. h "if a Signal applied to the input terminal 35a or the input terminal 356 can be at the output terminal 37 an output signal can be picked up.

If the relay contact circuit shown in FIG. 3A is simulated in the form of standard circuits, the result is the circuit shown in FIG. 3C. This circuit consists of two unit circuits lying parallel to one another. A unit circuit contains the input terminals 38a and 41a, the inverter 39,) and an AND gate 406, the other unit circuit comprises the input terminals 386 and 416, an inverter 396 and a NAND gate 406. The two output terminals of these NAND gates 40a and 406 406

2 "are connected to each other for the common output connection 43 and form a permanently connected OR circuit 42.

According to the logic circuit concept of the invention, the circuit shown in FIG. 1B specified as the basic structure

2ϊ unit circuit essentially as a relay contact to be viewed as. The connections to other standard circuits can be made according to the circuit diagram make which is similar to the circuit diagram of a conventional relay contact circuit. A command

if> follow a relay cor. clock circuit Can then easily with a logic circuit can be realized.

The circuit shown in Figure 4A contains two relay contacts 44 and 45 connected in parallel and a relay contact connected in series with this parallel connection 46. This circuit can be represented by the logic circuit of Figure 4B. These logic circuit includes two unit circuits 47 and 48 connected in parallel, both of which have the basic structure indicated in FIG. 1B, it also contains a further unit circuit 49 in series with the OR circuit made up of the unit circuits 47 and 48 connected in parallel. Since the two NAND gates of this circuit are connected via negative logic, the circuit is hardly influenced by external noise influences during signal transmission. The fall of one through Faulty operation caused by the infiuence of noise can be neglected. Another benefit of this Circuit consists in the fact that if damaged, an «in

the output signal assumes the level value L in such a semiconductor component present in a unit circuit. This behavior corresponds to the opening of the relay contact in a relay contact circuit. The device operated by an output signal from the logic circuit therefore remains open, which ensures operational reliability

5A shows a relay arrangement of a known type with a relay coil 50 and four relay contacts 51a, 516, 51c and 5id, which change over to the open or closed state as a function of the excitation or de-excitation of the coil 50. In order to produce an equivalent for this arrangement, a block of relay logic circuits is constructed with four inverters 52a, 526, 52c and 52i / and four NAND gates 53a, 536, 53c and S3d , see FIG. 5B. One or two circuit blocks of this circuit structure are arranged on a single carrier plate each
To one of the inputs of all NAND gates 53a

through 53d , a gate signal D is applied from terminal 54. This gate signal is on via an inverter 52e, but it can also lie the ^T interference signal D from the terminal 55 via the inverter 52 and / 52g. To create a circuit equivalent for a relay operated in / 4 mode (normally open contact), see FIG. 5A, signal D must be applied from terminal 54. In order to achieve a circuit equivalent for a relay operating in β mode (normally closed contact), signal Z5 must be applied to connection 55.

6 shows a schematic block diagram of a Arrangement in which a sequence of logic circuits is reduced to a practical application example. As in Fig. 6 is an external switch 60 grounded at one end via a noise eliminator Connection unit 61 connected to a logic circuit 62 for forwarding a signal to the next level. The logic circuit 62 consists of a plurality of circuit boards one and the same Type with interconnected connections. Each of the carrier plates takes one of the shown in FIG. 5B Circuits on. The output signal of the Igosichen circuit 62 is passed through a driver circuit 63 reinforced. A relay 64 is energized by the amplified drive current and operates a predetermined one Facility (not shown). The relay 64 can, depending on the applications of the device by a Replace the lamp, a TRIAC (triode AC switch), or an alternating current circuit.

In the following, a carrier plate for the logic circuit will now be described, which has the structure of the logic circuit simplified.

The F i g. 7A and 7B show, in a top view and in a front view, respectively, a preferred embodiment of a carrier plate for a logic circuit. On a base plate 80 there are several IC housings 81, resistors 82 and capacitors 83, which represent a logic circuit which is equivalent to two 4-contact relays. Two recesses 84a and 84Z) of different dimensions are provided on the upper edge of the base plate 80 in order to enable error-free orientation and introduction into a frame for receiving the plates. On the upper edge of the base plate 80 there are also several connections 85 for connection to corresponding plugs (not shown).

The subcircuit 86 (shown in dashed lines) represents a stabilized DC voltage source which is based on Each carrier plate is located In the event that only one stabilized power supply for several carrier plates is provided, there is namely an incorrect operation of the logic circuits due to external noise caused by a line between the stabilized power supply and the individual carrier plates are captured. In the case of the carrier plate structure shown is therefore for each individual carrier plate has a stabilized power supply in the vicinity of a logic circuit provided, whereby errors due to external noise influences be avoided.

The part 87 framed by dashed lines represents a module area for changing the connection. By connecting the individual modules, the logic circuit can be changed so that a circuit & 5 can be formed which corresponds to a relay contact circuit in A, B or A-Ä mode such as will be explained in more detail later.

On the end face of the carrier plate 80 is the labeling plate 88, in which the light-emitting diodes 89 are attached that indicate whether the power supply, the first relay logic circuit, the second relay logic circuit, etc. work in normal operation. To carry out the maintenance inspection therefore only has to be checked whether these diodes light up, so no special equipment is required for inspection. the This makes maintenance extremely easy.

For operational use, the carrier plate is inserted vertically into a plate holder so that the right and left sides of the plate shown in Figure 7A, the top and bottom edges represent.

F i g. 8 shows a circuit diagram of a relay logic circuit equivalent to a 4-contact relay and on top of one described carrier plate is arranged. This circuit represents a more practical embodiment than which is shown schematically in P i g. 5B shows the circuit shown.

The relay logic circuit equivalent to a 4-contact relay contains the inverters 100a to 100c / and the NAND gates 101a to 101c /. To operate this circuit, a signal is applied via a terminal 110 to an input terminal of each NAND gate 104, 105 and 106 via an inverter 102 . A signal present at the terminal 111 is applied to the other input terminal of each NAND gate 104, 105, 106 via the inverter 103. The output of a NAND gate 104 is supplied to the terminal 113a through an inverter 107. A connection 113Z) is connected to one input connection each of the NAND gates 101a and 101c and to a connection 114a. The output connection of the NAND gate 105 is connected to the connection 115a, while the connection 115Z) is connected to an input connection of the NAND elements 101 /) and 101c / and also to the connection I14Z>.

The connections 113a, 113Z), 114a, 114Z), 115a and 115Z) each correspond to a module in the module area 87 of FIG. 7A.

If signals are present at both connections 110 and 111, the NAND gates 104, 105, 106 emit output signals, and a driver signal is applied to one input each of the NAND gates 101a to 10c /. If it is necessary to quickly interrupt the operation of the circuit, only the signal at terminal 111 need be removed. No output signal is then generated by the NAND gates 104 to 106. There is then no drive signal to the NAND gates 10a to 101c /. As a result, no output signal then appears at the output connections 112a to 112d of the NAND gates 101a to 10Id, regardless of whether a signal is present at the input connections 109a to 109c /. The operation of the circuit is thus interrupted. Terminal 111 can therefore be used for interrupt operations.

During normal operation of the circuit, the NAND gate 106 also provides an output signal, the light emitting diode 108 (which corresponds to the diodes 89 in FIGS. 7A and 7B) illuminating and indicating normal operation

The manner in which the specified relay logic circuit depending on the operating mode of the relay contact of the 4-Koniakiereiäis works In order for the circuit to work in the / 4 operation of a relay (normally open contact), the Ports 113a and 1136 and ports 114a and

114ύ are connected to each other. Then that will The output signal of the inverter 107 is applied to one input each of the individual NAND gates 101 a to 101 </.

So that the circuit works like a relay in ß mode (normally closed contact), terminals 115a and 1156 and terminals 114a and 114 /) are connected to each other. Then it will be the output signal of the NAND gate 105 is applied to one input each of the four gates 101a to 101 (/.

So that the circuit is like a relay in / 1-fl operation works with two normally open contacts and two normally closed contacts, the must Connection 113a with 1136 and connection 115a with I15i> get connected. Then the output signal of the inverter 107 is sent to one input of the two NAND gates 101a and 101c placed, while the output signal of the NAND gate 105 to one each Input of the two NAND elements lOlfc and 101c / is placed.

The stabilized DC voltage source 86, see FIG. 7A, contains a known circuit comprising a transistor Q 1, a resistor R 14, a Zener diode ZD, the capacitances C 7 and C8, see FIG. 9.

To create a logic circuit with a predetermined sequence of circuit operations by using to produce several circuit boards in connections between the circuit units, of each corresponding to a pair of relay contacts, it is sufficient that some of the desired Connection pins (which correspond to the connections to be connected) of the plug into which the end piece 85 is inserted, optionally by suitable methods, e.g. B. by clamping or soldering ° tc, with each other get connected.

The in F i g. The logic circuit shown in FIG. 8 can be operated as a timing circuit. A delay may arise all logical operations can be achieved by inserting a separate capacitor C9, which controls the has the desired capacitance value and is placed between the outputs of the inverter 102 and ground, such as illustrated by the dashed line.

The connection unit inserted between the external switching contacts and the logic circuit contains a known connection circuit 120 and a circuit unit 121, see FIG it is possible to transfer a signal to the contact-free logic circuit and thereby external sound contact noise to eliminate. On the support plate for the connection unit, the one shown in FIG. 9 The stabilized voltage source shown is used.

In the in F i g. 7A two logic circuits, each equivalent to a relay with four contacts, on a single carrier plate installed with a plurality of IC units 81 set; it is possible, if required, both of them Realize relay logic circuits within a single IC unit.

In addition, several connection units, ζ. Β. 4 to 8, train. It is also advantageous to control the DC voltage driver circuits within a single IC unit realize.

While the aforementioned embodiments are all constructed with semiconductor components, it is for the It is obvious to those skilled in the art to replace the semiconductor components with corresponding logical fluid elements and to build the logic circuits with these elements.

For this purpose 4 sheets of drawings

Claims (10)

1 claims: 1. Contactless logic circuit with standard electronic circuits as a replacement for make and break contacts of a relay, in which the on and Output connections of the unit circuits are routed to the input and output connections of a circuit board, the unit circuits comprising a NAND element and an inverter exist, which is at one input of the NAND gate, the other input is connected to a voltage source, and the logic circuit so is constructed so that a direct transfer in relay current schedules is possible, characterized in that for the construction of the logical Circuit several identically designed circuit carrier plates (80) can be used, of which each contains a plurality of the unit circuits and that the input and output terminals of each Circuit carrier plate (80) are connected to one another in such a way that the Einhcitsscnaiikrcisc zürn Execution of an AND or an OR link in a known manner in series or in parallel are connected to each other. 2. Logic circuit according to claim 1, characterized in that the NAND elements (29a, 29b; 40a, 40b) are connected to one another in the form of negative logic. 3. Logic circuit according to claim 1, characterized in that several circuit carrier plates (80) have a stabilized DC voltage source (86) for the voltage supply of the circuit components arranged on the carrier plate. 4. Logic circuit r-ach claim 1, characterized in that each Einhcitsschaltkreis one Inverter (16) and a NAND gate (17) and means for transferring a signal via the Inverter (16) to an input of the NAND gate (17), and that the circuit board (80) Means for generating a drive signal and for applying the drive signal to a Each of the NAND gates (17) contains input. 5. Logic circuit according to claim 4, characterized in that the means for applying of the driver signal means for applying a "!" signal and also means for applying an "O" signal, and that means (87) on each circuit board (80) for optionally applying the »!« signal or the »O« signal to the corresponding input of the NAND members (17) are provided. so 6. Logic circuit according to claim 4, characterized in that the means for applying of the driver signal contain NAND gates (104, 105), which occur when two incoming signals coincide respond through two input terminals, and that the means for applying the drive signal turn off all standard circuits by removing a signal from the two input terminals during a desired interruption time. 7. Logic circuit according to claim 4, characterized in that a capacitance (C9) containing devices for time delaying signals are provided and connected to the devices for applying the driver signal and produce a time delay of the logical operations of the logic circuit. 8. Logic circuit according to claim 1, characterized characterized in that a unit circuit or several within a single (C-unit (81) is or are formed. 9. Logic circuit according to claim 1, characterized in that connection units (61) between external mechanical switching contacts (60) and an input of the NAND gate of the logic circuit (62) are provided, and that the Connection unit (61) receives a signal via the switching contact (60) after the noise has been eliminated and which provides signal swings to the NAND gate of the logic circuit (62) 10. Logic circuit according to one or more of claims 1 to 9 with a plurality of circuit units, characterized in that each of the Unit circuits a NAND gate (17) with an inverter (16) in front of an input of the NAND gate (17) contains that a unit circuit is connected to the output of the NAND gate of another unit circuit and a logical one OR connection represents the logical OR operations that another circuit unit from the output of the NAND gate to the The input of the inverter of a further unit circuit is connected to carry out a logical AND operation, and that devices are provided, with the help of which the unit circuits to simulate a Koniakt and a Winding containing relay circuit are interconnected.