CS220232B1 - Programmable memory logic product circuit wiring, especially for control and signaling systems of process equipment - Google Patents

Abstract

The invention solves the connection of a logical product circuit with a programmable memory, especially for security systems of technological equipment. The connection according to the invention includes two product elements, two sum elements and an output relay element. It can be supplemented with a diode-resistor network, thereby achieving an expansion of the input conditions. The connection according to the invention allows the implementation of a logical product of up to one hundred input information in a single circuit with the possibility of storing this product in the same circuit. The connection has a significantly lower consumption at the inputs than previously known connections. It allows for simple design and implementation of any sequential control and security systems with their higher reliability.

Description

The invention solves connection of logic product circuit with programmable memory, especially for security systems of technological devices. The circuitry of the invention comprises two product elements, two total elements, and an output relay element. It can be supplemented by a diode resistance network, thus achieving an extension of the input conditions. The circuitry according to the invention allows the realization of a logical product of up to one hundred input information in a single circuit, with the possibility of simulating this product in the same circuit. Wiring has considerably lower power consumption at inputs than previously known wiring. It allows simple design and implementation of any sequential control and signaling systems at higher reliability.

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Fig. 1

The invention solves the connection of a logic product circuit with a programmable memory, especially for control and security systems of technological equipment.

The known connections of six-phase or reed relays are characterized by higher input consumption and a limited number of inputs for these connections. This leads to greater design and implementation effort and at the same time to lower reliability of these wiring.

These drawbacks are largely eliminated by the connection of a logic product circuit with a programmable memory, especially for the control and safety systems of the technological devices according to the invention, whose essence is that its sum input is connected to the first input of the first sum member whose second input is connected with dynamic summation input wiring. The first input of the first product member is coupled to the first product input of the wiring. The second product wiring input is coupled to the second input of the first summation member. Third input, first sum, term. it is connected to the third product input of the wiring. The programming product input wiring is connected to the fourth input of the first product member whose output is coupled to the third input of the first sum member. The output of the first summation member is connected to the second input of the second summation member. The first input of the second summation member is connected to the feedback input of the wiring. The output of the second summation member is connected to the first input of the second product. The second input of the second product is connected to the power input of the wiring. The output of the second product is connected both to the feedback output of the wiring and to the output of the output relay member. The output of the relay output member is connected to the wiring output. The wiring blocking input is coupled to the inhibiting input of the second product member. Said wiring can be further supplemented so that the diode resistance network output is connected to the programming product input of the wiring. The output of the resistor network is coupled to the anode of the first output diode, the anode of the second output diode to the anode of the nth output diode. The cathode of the first output diode is coupled to the cathode of the first input diode and the first resistor. Similarly, the cathode of the second output diode is coupled to the cathode of the second input diode and the second resistor. Likewise, the cathode of the nth output diode is coupled to the cathode of the nth input diode and to the nd resistor. The first input of the diode resistor wiring is coupled to the anode of the first input diode. Similarly, the second input of the diode resistor network connection is only with the anode of the second and input diodes. Also, the nth input of the diode resistance network of the circuit is coupled to the anode of the nth input diode. The first resistor, as well as the second resistor, as well as the nth resistor, are connected to a zero logic wiring signal source.

The circuit according to the invention allows the realization in a single circuit of a logical product of up to one hundred input information with the possibility of storing this product in the same circuit. a circuit for generating larger logic products, and no additional logic circuit is required to memorize these products. At the same time, the wiring has significantly lower power consumption. inputs known so far, · known connections. Wiring · enables simple design and realization of arbitrary, sequential control and signaling systems as well as their reliability.

The drawings show an exemplary wiring diagram., Na? FIG. 1 is a schematic diagram of a logic product circuit with programmable memory. Fig. 2 shows the diodoodp, the weave network.

The summing input 1 is connected to the first input 221 of the first summation member 22, to whose second input 222 the dynamic summing input 2 is connected. First product input. 3. The wiring is connected to the first input 211. of the first product 21 and its second input 212 is connected to the second product input 4 and its third input 213 the third product input 5. The programming product input wiring 6 is coupled to the fourth input 214 'of the first product 21, whose output 215 is coupled to the third input 223 of the first sum member 22, the output 224 of which is connected to the second input 232 of the second sum member 23, to the first input 231 is connected to the feedback input 11 of the wiring and whose output 233 is coupled to the first input241 of the second summation member 24a. 7. wiring: only connection: second input: i2,42v · second connection; To the third input 2: 48: a blocking input 8c is connected. Exit·. 2444the second, the main element 24 \ jecspojeraiise: reconnect the output 12 wiring: and - with the input 251. output? a relay member 25, whose output 2B2 is connected to. output, & · wiring. '

Said wiring can be further supplemented so that the programming input B: the wiring can be connected to the output of a 3ftide resistor network. for bonding,. which? it can be "remotely connected". such that resistive networks are connected to the output · 3B jsou: · connected, anodes · first and output diodes · 324. second? output diodes 32.2; to? nth output diode ··· 3SLn. Cathode first output: diodes -.- 324.5 is coupled to the cathode of the first input diode,

31.1 and with the first resistance 33.1. The cathode of the second output diode 32.2 is coupled to the cathode of the second input diode 31.2 and to the second resistor 33.2. The cathode of the n-th output diode 33.n is coupled to the cathode of the n-th input diode 31.n and the n-th resistor 33.n. The second terminals of the first resistor 33.1, the second resistor 33.2 to the nth resistor 33n, are connected to a source of the neutral logic signal 40 of the wiring.

The first input product 21 together with the second product 24 are formed, for example, by a transistor circuit. The first summation member 22 and the second summation member 23 are common diode totals, the second input 222 of the first summation member 22 being a conventional derivative RC member. The output relay member 25 is, for example, a reed relay.

In the practical application of the circuit according to the invention, the input circuit conditions are connected to the first circuit product input 3, the second circuit product input 4 and the third circuit product input 5. The number of input conditions can be extended by connecting a diode resistance network, the output of which 30 is connected to the programming product input of the wiring 6 and to the inputs

30.1 to 30.n additional circuit input conditions are connected up to, for example, a total of one hundred input conditions. If the conditions on all the product inputs 3, 4, 5 and all connected inputs 30.1 to 30.n of the diode resistance network are met, the signal at the output of the first product 21 is applied via the first adder 22 and the second adder 23. to the first input 241 of the second product 24. At the output 244 of the second product 24 and via the output relay 25, the output 32 pu 9 of the wiring is signaled only when the signal is on the power input 7 of wiring and blocking input 8 wiring. By applying a signal to the summation input 1 of the wiring, the signal at the wiring output 9 is regardless of the state of the signals at inputs 3, 4, 5 and the connected inputs

30.1 to 30.n, but at the same time there must be a signal at input 7 and not a signal at input 8 wiring. By interconnecting the feedback input 11 of the wiring with the feedback output 12 of the wiring, the circuit output is remembered, i.e. the signal at the wiring output 9 persists even after the loss of the signals at inputs 3, 4, 5 at the connected inputs 30.1 to 30.n The condition of the duration of the memory condition is the presence of the signal at input 7 and the absence of the signal at input 8. The memory of output 9 is cleared by applying a signal to input 8 or losing the signal at input 7. by applying a signal to the dynamic summation input 2 of the wiring under the same conditions as in the previous case.

The circuit according to the invention finds application in the realization of control and safety devices of technological units.

Claims (2)

Wiring of a programmable memory logic product circuit, in particular for control and signaling systems of technological equipment, characterized in that its sum input (1) is connected to the first input (221) of the first sum member (22), whose second input (122: 2) is connected to a dynamic summation input (, 2) of the circuit, the first input (2,1,1) of the first product (21) being connected to the first product of the circuit (3), the second product of the circuit (4) of the circuit is connected to the second input (212) of the first summation member (21), the third input (213) of which is connected to the third product input (5) of the wiring, the programming product of the wiring input (6) being connected to the fourth input (214) of the first a product (21) whose output (2,15) is connected to a third input (223) of the first sum member (22), whose output (2124) is connected to a second input (202) of the second sum member (2), 3), whose first input (231) is coupled to the feedback input (1,1) of the wiring and whose output (233) is coupled to the first input (2411) of the second product (24), whose second input (242) is coupled to the power supply input (7) and whose output (244) is coupled to the feedback feedback output (12) and the input (251) of the output relay member (25), the output (252) of which is coupled to the output stage (9); the engagement blocking input (8) is coupled to the inhibiting input (243) of the second product member (24). '2. 1. The circuitry of the programmable memory logic circuit as recited in claim 1, characterized in that a diode-resistance network output (30) connected to the anode of the first output diode (32.1) and the anode of the second output diode is connected to the programming product input of the circuit. (3,2.2) to the anode η- of the output diode (32.n), the cathode of the first output diode (32.1) being connected to the cathode of the first input diode (31.1) and the first resistor (33.1), the cathode of the second output diode ( 32.2) is coupled to the cathode of the second input diode (31.2) and the second resistor (33.2) until the cathode of the nth output diode (, 32.n) is coupled to the cathode of the nth input diode, (31.n) and to the n- the first input (310.1) of the diode resistor network is connected to the anode of the first input diode (31.1), as well as the second input (30.2) of the diode resistor network is connected to the anode of the second input diode (31.2) to n -the input (30.n) of the diode resistance network zapo The first resistor (33.1), the second resistor (33.2) to the nth resistor (33.n) are connected to the zero-wiring logic power supply (40).