SU1109683A1 - Device for automatic checking of electrical circuits - Google Patents

Abstract

DEVICE FOR AUTOMATIC CONTROL OF ELECTRIC CIRCUITS containing a program block connected by a first output to an input of a control unit connected by an output to the first input of a switch connected by a second input to the first output of the measuring block and containing fj contact closure contacts and disconnecting contacts. interconnected and with corresponding terminals for connecting the terminals of the monitored circuit, the first resistor connected by the first pin to the second The eight outputs of the measuring unit, and (N-1 second resistors, different) in that, in order to increase the reliability of the control and enhancement of functionality, an analysis block, an output block, a control inhibit block and a memory block are connected to the first input the output of the measuring unit and the first input of the analysis unit, the second input of which is connected to the second output of the software unit, the first output to the input of the software unit and the second input of the memory unit, the second output to the first input of the output unit connected to the input from The first output of the program block connected by the third output and § the second input respectively to the first input and the first output of the prohibition block i (L control connected by the second output and the second input to the third input and the first output of the memory block, respectively, closing the contacts of each of the fJ pairs contacts are connected to the second output of the measuring unit, and the disconnecting contacts are connected to the second terminals of the first and second resistors, the first one: the output of each T-th second CD resistor t U is connected to the second ac output of the (II) -th second re stories, and the first vybod- t-th second rezis00 torus (i 1 d) - a second vyuodom Purves / th resistor.

Description

i

The invention relates to instrumentation technology and can be used to monitor the correctness of the electrical connections of complex electronic equipment of automation and computing devices.

A device for controlling wiring diagrams is known, which contains an information input unit, the output of which is connected to the inputs of the perforation unit and the decoding unit of input information, the first output of which is connected to the information input of the unit

memory, the output of which is connected to the information input of the printing unit and the first input of the decryption unit, the output of the connecting with the address input of the first switch, the outputs of the first and second switches are connected respectively to the first and second inputs of the resistance measuring unit, the output of which is connected to the control input the print unit j which is connected bilaterally, in connection with the information input unit, the control input of the main memory unit and the second input of the decryption unit. connected to the output of the information distribution unit The input is connected to the second output of the input information decoding unit and the input of the control signal generation counter, the output of which is connected to the control input of the second switch, and the information inputs of the first and second switches of the same name are connected to the corresponding inputs of the device, the address input of the second switch and the control input of the first switch is connected respectively to the outputs of the decryption unit and the counter generation signal Clj,

The disadvantage of this device is the low reliability of the control. To check the operability of the switching elements of the device, it is necessary to alternately connect two different standards of wiring diagrams. In addition, in the operation of the device, the operation of the switching Elements is not monitored, which reduces the reliability of the control.

Closest to the invention is a device for automatic control of electrical circuits.

96832

containing a software unit connected by a first output to an input of a control unit connected by an output to a first input of a switch connected by a second input to a first output of a measuring unit and containing a pair of closing and opening contacts, the first terminals of each contact pair of contacts are interconnected and with the appropriate terminals for connecting the outputs of the monitored circuit, the first resistor connected with the first output to the second output of the measuring unit, and (/ Y-) the second resistors. Г2.

A disadvantage of the known device is its limited functionality, since upon detection of an off-set, the circuit is rejected without specifying the type of violation and the device stops. After the elimination of the first detected fault, the control must be carried out first. If there are several violations, the addresses of all failed closed points and the numbers of the circuits are not indicated. In the event of an open circuit, the device indicates only one number of the closing numbers

0 points. Therefore, the results

the controls are not complete. In addition, the known device is characterized by a low reliability of control, since it does not divide the malfunctioning switching elements before the control starts and during the control from the malfunction of the control object.

The aim of the invention is to increase the reliability of the control and expand the functionality.

The goal is achieved by the fact that the device for automatic control of electrical. circuits containing a software unit: connected by a first output to an input of a control unit connected by an output to a first input of a switch connected by a second input to a first output of a measuring unit and containing N pairs of make and break contacts, with the first terminals of the contacts: where the pair of contacts are interconnected and with the corresponding terminals for connecting the terminals of the monitored circuit, the first resistor connected to the first output to the second output of the measuring unit, and (.) the second resistors, The analysis block, the output block, the control inhibition block and the memory block connected by the first input to the output of the measuring unit and the first input of the analysis unit, the second input of which is connected to the second output of the program block, the first output to the input of the program block and the second input of block memory, the second output - with the first input of the output unit connected by the input to the first output of the software unit connected by the third output and the second input respectively to the first input and the first output of the control inhibit unit connected by the second output the house and the second input, respectively, with the third input and the first output of the memory unit, each contacting each of W pairs of contacts are connected to the second output of the measuring unit, and the opening contacts - with the second terminals of the first and second resistors, the first output of every 1st second resistor i 1J is connected to the second output t, -1 of the j -th second resistor, and the first output of the second second pe3HCTopa (t lj is the second output of the first resistor.

The drawing shows the block diagram of the device.

The device for monitoring the object 1, including the controlled points, contains the measuring unit 3, the software unit 4, the switch 5, the closing contacts 6 L1, the opening contacts - 7 N, the first resistor, the second resistors -, the analysis unit 9., the block 10 output, block 1 ban control, memory block 12, block 13 control.

The first output of the software block 4 is connected to the input of the control unit 13 connected by the output to the first input of the switch 5 connected by the second input to the first output of the measuring unit 3 and containing pairs of closing and opening contacts. The first terminals of the contacts of each pair of contacts are connected to each other and to the corresponding terminals for connecting the outputs of the monitored circuit, the first resistor is connected to the first output of the second output of the measuring unit 3. The first output of the memory block 12 is connected to the output

the measuring unit 3 and the first input of the analysis unit 9, the second input of which is connected to the second output of the program unit 4, the first output to the input of the program unit 4, c

the second input of the memory unit 12, the second output - with the first input of the output unit 10 connected by the input to the first output of the software unit 4 connected by the third output and the second one, the input respectively to the first input and the first output of the I 1 block of the control connected to the second output and the second input, respectively, with the third input and the first output of the 12-spam block. Closing contacts - each of W. A pair of contacts are connected to the second measuring output

block 3, and the closing contacts 7 W - with the second pins of the first and second resistors, with the first output of each L -th second resistor - 8 (1 1)

connected to the second view of the L-lj-th second resistor - and the first output of the L-th second resistor lj- with the second output of the first resistor.

The device works as follows.

The initial state of the switch 5 is monitored as follows.

Checks the unlocked state

contacts - when the block is turned off 4. The self-control program starts. The resistance of the circuit between the first and second inputs of the measuring unit 3 is determined. The resistance value from the output of the measuring unit 3 is fed to the input of the analysis unit 9. To the other input of this block, from the output of program block 4, a reference resistance value is fed.

If the contacts of all contacts, JS are open, the measured resistance value coincides with the reference one, from the second output of the analysis unit 9

the second input of program block 4 receives a sign of continuing control and the device proceeds to the next check.

If the contacts of several contacts - 6 M are closed and the smallest contact number with closed contacts is equal, then a circuit is formed, containing the measuring input

unit 3, closed contact contacts, serial connection m of additional resistors - 8-I1, another input of measuring unit 3. From the output of measuring unit 3 to the inputs of memory block 12 and analysis unit 9, the value t comes, From the first output of analysis unit 9 there comes a sign the first input of the I / O output unit and the message Closing of the contact 6 is output. Simultaneously from the output of the analysis block 9, the record permission sign comes to the input of the memory block 12. The number L7 is entered into the memory block 12 and from the output of the block is transmitted through the block 11 of the control ban to the program block 4, from where it goes to the input of the control block 13 and the input of the output block 10. Output block 10 complements the message Closing of contact 6 with the number of this contact m.

Control unit 13 opens. contact The previously described resistance circuit / P-R turns out to be open (/ -resistance of each of the resistors -.

If there are still contact closures 6, then the following faulty contact 6 t is detected, having the smallest number (for example,) of the remaining ones. Similarly, the number is printed by the output unit 10, and the control unit 13 times 1 pin 7 and the resistance circuit T-R is broken

If the contact closure 6 t is the last one, then when contact 7 opens, the resistance becomes infinitely large equal to the resistance of the open contacts). The analysis unit 9 compares this value with the reference one, issues a sign of continuing control to the program unit 4 along with the start of the circuit and the device proceeds to the next check. Information about the numbers of faulty contacts — in-W, 6 (in the present example), recorded in memory block 12, is not used for these checks.

Checking the closed state of the contacts is implemented as follows

From software block 4 to the input of control block. 13 the number of the last contact enters together with the sign of the beginning of the circuit, and to the other input of block 9 of the analysis - the reference resistance value. Closes contact. If the contact is closed, the resistance of the circuit becomes equal to NK. This value of A / coincides with the reference value, therefore from the analysis block 9 to the input of the program block 4 a sign of continuation of the control is output. From software block 4, control number 13 receives the number of contact 6 (// - iJ along with the sign of the beginning of the circuit, and analysis block 9 receives the reference value paBHoe (/ V-l) R. Similarly to the last contact, the health of the remaining contacts 6 is checked, and the resistance of the circuit decreases each time by the value of /.

If contact 7 I1 is open, when closing the contact, the resilience does not change cfm + l j.R to m-R and does not coincide with the reference value C of the analysis unit 9 on the output unit 10, a break sign is displayed. The output unit 10 will print the message Opening contact 7 together with the contact number that comes from the program unit 4. At the same time, the sign of continuing control comes from the output of the analysis unit 9 to the input of the program unit 4 and the device switches to monitoring KoiwaKta 7 (). After checking all the contacts, the contacts are opened, the contents of the memory block 12 are zeroed and the device stops.

The control of the circuits of the object 1 for integrity is as follows.

Object 1 scans the program and runs its check program. From the output of software block 4 to the input of control unit 13. the number of the first point of the first circuit being tested and the indication of the beginning of the circuit is fed, and from the other output of software block 4 the reference resistance value is fed to the input of analysis block 9. The control unit 13 connects the first point of the object 4 by means of a contact to the input of the measuring unit 3. The resistance between the first and second inputs of the measuring unit 3 is determined.

If the contact does not close, then this resistance is close to infinite, i.e. equal to the resistance of all open contacts 6. From the output of the measuring unit 3, this value is fed to the input of the analysis unit 9, where it is compared with the etalon1.1m value. From the output of the analysis unit 9, the first input of the output unit 10 receives a break sign. The number of the failed contact coincides with the number of the controlled point of object 1, and is fed to the input of block 10 of the output from another output of program block 4. The output block 10 prints the message Opening contact 6 and indicates that its sequence number is 1, the control stops and is carried out further after elimination malfunction. If the contact is closed, the resistance becomes equal to R. This value comes from block 3 to analysis block 9, from whose output to the input of program block 4 a sign of continuing control is received. From another output of software block 4 to the input of control block 13, the number of the first point of object 1, but without the sign of the beginning of the circuit, appears. The control unit 13 opens the contact, after which the resistance of the circuit containing the closed contact is measured, the connecting cable harness, the point of the object point 1), the closed contact cable, the resistors and. The resistance value is determined by the smallest point number of the object 1, which is associated with the point in question. The resistance of the circuit containing the remaining points of the object 1, having a connection with the point, is shunted by a circuit, a connecting cable harness, and a closed contact. The measured resistance should be 2 R.. If the contact does not break, this resistance does not change, i.e. remains equal to E, and the analysis unit 9 outputs to the output unit 10 a closure indication. The output unit 10 prints the message Closing the contact 7 together with the number I of this contact, received from the output of the program unit 4. Thus, in the control process, all opening contacts are checked for opening. Next, the contact is opened and a circuit is formed that contains a closed contact, a connecting cable harness, points, and a connecting cable harness, close 1 8 contact, resistors, and. The analysis unit 9, after comparing the resistance received at the input from the measuring unit 3 with the reference value received at the other input from the program unit 4, gives to the second input of the program unit 4 a sign of continuing monitoring. The program unit 4 gives the number of the next fourth point to the input of the control unit 13, and to the input of the analysis unit 9 a new reference value of the resistance, the circuit. The control unit 13 softens the contact and the new measured resistance enters the analysis unit 9. If the contact does not open, then the resistance does not change, the output of the IO output unit is reported. Contact 7 is closed and number 4 is indicated. , close to infinite. In block 9 analysis occurs. its comparison with the reference one and the input of the program block 4 receives a sign of continuing control. From software block 4 to the input of control unit 13 is given the number of the first point of the next circuit () together with a sign of the beginning of the circuit, and to the input of analysis block 9 a new reference value. The control unit 13 closes the contact and the control continues according to the described procedure. Circuit break control is considered by the example of a chain between points, and. Let the connection of points and be broken. When the contact is opened, the resistance of the circuit becomes infinitely large and, in particular, greater than the reference one. The analysis block 9 shows on the output block 10 a sign of a communication break. The message Communication Obligation will be printed together with the number received from the output of program block 4. Simultaneously from the output of analysis block 9, the sign of the continuation of control and the sign of the beginning of a new circuit are input to the input of program block 4. Next point number. together with the sign of the beginning of a new circuit, it enters from software block 4 to the input of control unit 13 and to the second input of output unit 10. The output block completes the number of the message Disconnection. The control unit 13 connects the point via a contact to the first input of the measuring unit 3, since there is a sign of the beginning of a new circuit. In this case, the crawl 1, that the point is connected to the input of the measuring unit 3 through points, 2 and a closed contact, so that the further monitoring completely coincides with that described. Monitoring of other circuits on an open circuit is carried out in a similar sequence of actions. The control of this circuit on the closures with other circuits is considered on the example of the closure of a circuit of points,. and with other chains. Let, for example, close the points and between them. When the contact is opened, a circuit is formed containing points 2, and a closed contact7 35 resistors, and. The resistance 3R is less than the standard 4 I (corresponding to the point). Therefore, the analysis unit 9 outputs to the output unit 10 a sign of a false communication. The output unit prints the message False Communication. From the output of the measuring unit 3, the value arrives simultaneously at the input of the unit 2 of the memory. The sign of recording resolution arrives at the other input of memory block 12 from the output of analysis block 9. The point number is recorded in memory block .12 and from the output of this block, through control block 11 and program block 4, enters control block 13 and output block 10. The output block completes the number of the False Communications message. The control unit 13 opens the contact. A circuit is formed containing the points,, and, closed contacts and resistors.,, And. The resistance coincides with the reference one; therefore, the analysis unit 9 gives the program unit 4 a sign of continuing monitoring. The next common point number goes to control unit 13, and at the same time software unit 1 changes the reference in the infinity analysis block, since the point must be the last point of the circuit. Since there is a connection between the circuit under consideration and a point, the measured resistance is equal to a QW. This resistance is less than the reference infinite one, therefore, from the analysis block 9, the false link sign arrives at the output block 10. However, such messages are not printed by the output block 10 until those from the output of program block 4 receive i sign of the beginning of a new circuit (i.e. until all closures belong to the same circuit. At the same time, from measuring block 3 to block I2 a point number is sent from the second output of the analysis unit 9 to the second input of the 12pam tee block - a permission sign to power this number to the input stack.From the code of the memory 12, the monitoring prohibition block I1 and the program block 4 feed the point number 13 controls and an output block 10. The output block 10 supplements with a number The message False connection and, and the control unit I3 opens the contact. Since the circuit under consideration has no more connections, the measured resistance is infinite. The analysis unit 9 indicates that the control unit 4 continues to monitor the new unit together with the indication of the beginning of the new chain and - sign of rewriting from the input stack to the output stack. The number of the first point of the next circuit comes from program block 4 to the input of block P of the control ban, to the second input of which, the output of block 12 of memory receives the first number stored there (number then chki. If the numbers match, then it is not necessary to monitor this point, as it is; closes one of the previously tested. From the output of block 11 of the control ban, a sign of the ban on the first input of the program block 4 is issued, and from another output - the sign of the exclusion of the number to the input of the memory block 2. In program block 4, the number of the next point is selected, which enters block 1 of the control prohibition. In memory block 12, the contents of the input stack are overwritten by the output stack (in the current example, the first output stack number matches the number from program block 4, so there is no information in the input stack, i.e., its capabilities are not used as a buffer memory ). The first number of the output stack goes to block 11 of the control ban. The 11 occurs again. 1 coincidence, signs of prohibition and exclusion of the number are formed. In software block 4, the next numbered number of the first point of the next circuit is selected, and the value zero from the output stack of memory 12 is set to block 11 of the control prohibition. the sign of the beginning of the circuit is fed to the code of the control unit 13, and the corresponding, reference value is fed to the second input of the analysis unit 9 and the monitoring continues as described. The device provides high accuracy of control, because before starting work and in the process of control, the operability of all switching elements is checked. The device separates the malfunctions of the switch and the object 1, for one cycle it detects all communication disturbances in the object 1 and displays the results of the control in an obvious way. In the program of the device, there are no procedures for finding closures or interruptions by any sorting of points, so the time, control, varies slightly: in the presence of drugs, tested electrical circuits. Each violation of the type of break increases the control time by approximately the time of one violation of the type of closing of the switching, and the crown reduces it by the same time. Upon detection of breaks and closures, the numbers of points in the break and closed circuits are precisely indicated, which expands the functionality of the device.

Claims (1)

DEVICE FOR AUTOMATIC CONTROL OF ELECTRICAL CIRCUITS, containing a program unit connected by a first output to an input of a control unit connected by an output to the first input of a switch connected by a second input to the first output of the measuring unit and containing pj pairs of make and break contacts, the first contact outputs of each pairs of contacts are interconnected and with the corresponding terminals for connecting the terminals of the controlled electric circuit, the first resistor connected by the first output to the second output house of the measuring unit, and (Nl) second resistors, characterized in that, in order to increase the reliability of control and expand the functionality, an analysis unit, an output unit, a control inhibitory unit and a memory unit connected to the output of the measuring unit by the first input and the first input of the analysis unit, the second input of which is connected to the second output of the program unit, the first output - with the input of the program unit and the second input of the memory unit, the second output - with the first input of the output unit, connected by the input to the first output program block connected to the third input and second input, respectively, with the first input and the first output of the control inhibit unit, connected to the second output and second input, respectively, with the third input and the first output of the memory unit, the closing contacts of each of the 6 / pairs of contacts are connected to the second output of the measuring unit , and the disconnecting contacts with the second terminals of the first and second resistors, and the first: the first terminal of each I-second resistor] ί / 1) is connected to the second terminal (Ll) -ro of the second resistor, and the first terminal is of the f-th second th resistor (ί = 1) - with the second output of the first resistor. SU „, .1109683