SU342189A1 - DEVICE FOR AUTOMATIC INSTALLATION CHECKS - Google Patents

Description

The device for automatic verification of electrical installation is intended to guarantee verification (the presence of the necessary installation circuits and the check of the absence of spurious connections between the circuits or points of the test object) of the correctness of the installation of electronic computers or other radio engineering and radio-electronic devices with a large installation volume.

In the case of serial production of electronic computers, automation of installation testing is decisive because it eliminates the search for installation errors during complex commissioning, which significantly shortens the time for complex computer setup and allows for an efficient computer setup method.

Devices for mounting testing are known in which it is energized, its voltage is supplied in turn to each point of the object under test through a connection switch; with the help of the polling switch, all other points of the object are polled at each step of the switch of the connection for the presence of a "sign (energizing voltage); The addresses of the points with a "sign are compared with the addresses listed in the installation check program of this object, and according to the comparison results, the analysis circuit generates signals of correct and incorrect connections.

However, such devices, even when using electronic circuits in a polling or connection switch, have insufficient test speed.

In the known assembly verification devices, the inspection time increases in a quadratic dependence on the increase in the inspection volume.

In the case of serial production of a computer and checking the installation of computer cabinets having a volume of more than 20,000 points, the time for testing by a known device at a clock frequency of 2000 Hz is

-. 20000 200000 seconds 55 hours. 2000

The purpose of the invention is to provide an inspection of an object of 20,000 points in 1-1.5 hours; the ability to scan objects up to 46,000 points; automatic display of information about errors detected by the installation.

This goal is achieved by the fact that the device contains steps of serially connected pulse distributor, register, decoder and polling switch t-th stage, the input of which is connected to the output of the polling switch (t-1) -th stage (where t 1, ..., p ). The second input of the polling switch

the first stage is connected to the switch output of the connection of control points, the output of the polling switch of the nd stage is connected to the corresponding inputs of the pulse distributors of each stage. The second output of the register of the th stage is connected to one of the inputs of the pulse distributor (1- | -1) -th stage, and the second output of the register of the n-th stage is connected to the corresponding input of the analysis circuit. The third outputs of the registers of each stage are connected to one of the inputs of the comparison circuit, the input of the output unit and the output of the decoder of the control point connection channel, the second output of the i-th stage pulse distributor is connected to the second input of the decoder (i-1) -th stage and to one of the inputs pulse distributor (f-1) -th stage, the input and output of the clock pulse generator are connected to the corresponding inputs of the pulse distributors of each stage.

In the proposed device, the survey of points for the presence of an excitation voltage goes not along each point sequentially, but first in a large array of points (the highest stage), then upon detection of points along smaller and smaller arrays, and so on until a specific individual point with an excitation voltage is detected. (junior level). If no excitation voltage is detected in an array of points at any polling stage, then this array is not polled at lower stages.

In the proposed device, the entire test object of 46080 points is divided into 4 "cabinets of 11520 points (4 arrays of points of the fifth survey level), each cabinet is divided into 8" blocks of 1,440 points (of an array of points of the fourth stage); each block - to 8 "sections with 180 points (4X8X8 256 arrays of the third stage), each section - to 12" connectors with 16 contacts (4X6X812 4072 arrays of points of the second stage).

The entire device is 46080 points.

V-level survey 1 .... 4 cabinet4 tact

IV 1 .... 8 block 8 cycles

III 1 .... 8 sections8

II I .... 12 sockets12

I 1 .... 16 contacts16

Total

48 cycles

In connection with such a division of the survey, the search for any point with a "symptom (excitation voltage) is carried out in 48 cycles. Therefore, a polling time of 46080 points at a clock frequency of 2000 Hz is

48

46080 1100 villages:; 0.31 hours

2000

According to the step-by-step polling scheme, the time increases almost linearly depending on the number of checked points, therefore, the proposed device can be effectively used when checking objects with large

the number of connection points (5000 --- 50000). Under these conditions, the polling time is crushed 100-900 times compared with the successive polling of each point. 5 The block diagram of the device is given in the drawing, where it is indicated: / - the object to be checked; 2 - switch of connection of control points, 3 - switch of polling of the first stage; 4 - the decoder of this stage; 5 - the switch 10 of the second stage survey and 6 - the decoder of this stage; 7 - the switch of the interrogation of the nth stage and 8 - the decoder of this stage; 9 - analysis scheme; 10 is the switch register; // - the switch decoder of the subkey 15; 12, and 14 are the registers of the first, second and lth steps, respectively, 15, 16 and 17 are the pulse distributors of the first, second and nth steps, respectively, 18 is the clock generator; 19 is a 0 comparison circuit; 20 is a scheme for changing the addresses of points; 21 - output unit; 22 - input block.

The test object 1 is connected to the outputs of the connection switch 2 and the corresponding inputs of the first stage of the switch 5 of the interrogation torus 3, to the inputs of which the digital outputs of the first stage decoder 4 are fed.

The outputs of the switch 3, corresponding to each array of points of the second stage, are given to the corresponding inputs of the switch of the second poll 5, which is also controlled by the digital outputs of the decoder 6 of the second stage, etc. up to the poll switch 7 / g-th stage 5 and its control decoder 8. The output of the interrogation switch controls the distributors of interrogation pulses 15-17, the output of each of which is connected to the input of the corresponding register 12-14. In addition, by the second output, the pulse distributor of the upper stage 17 is connected to the input of the pulse distributor 16 and the decoder 6 of the lower stage, etc. up to the decoder 4 and the pulse distributor 15 of the first step. The second output of the latter is connected to the analysis circuit 9, where the signal "contact is found. The input of each pulse distributor is connected to the output of the pulse generator 18. 0

The registers of steps 12-14 are connected to a comparison circuit 19 and a device for outputting 27 information about the addresses of detected points. The output of the overflow of the register 12 of the lower 5th stage is connected to the input of the pulse distributor 16 of the upper stage, and the output of the overflow of the register 14 of the last stage is connected to the analysis circuit 9. The last one output is connected to the distributors of all pulses of all the stages and the pulse generator 18, and the other to the register connection switch 11, which is connected to connection switch 2 via decoder 10. Register output // is connected to information output device 21. 5 The information input unit 22 is connected to the address change circuit 20 and the analysis circuit 9, and the address change circuit 20 is connected to the address comparison circuit 19 and, through it, to the analysis circuit 9.5 The device works as follows. Analysis Circuit 9 writes a +1 to the connection switch register. In the register, the address of the connection point appears, which through the decoder 10 establishes the switch-10 torus of connection 2 at the selected point, i.e., it applies an excitation voltage to it, which through the mounting circuit of the object of test 1 goes to all other points of this circuit. Then the analysis circuit generates a resolution for 15 operation of the pulse generator 18, the pulses from which are fed to the pulse distributors of all stages. In the initial position, the distributor of pulses of the senior stage prohibits the operation of the distributors named after 20 pulses 16, 15 and decoders of the lower stage 6, 4. As a result, all outputs of the decoders of the polling stages 6, 4 send the enable signals to the inputs of the polling switches of the stages 5, 3, so The sig-25 signal from the excitation voltage from the test object passes through the interrogation switches 3, 5 to the input of the interrogation switch 7 of the highest level. In the initial state, at the output of the interrogation switch 7 of the highest step-30, there is no signal corresponding to the presence of the excitation voltage due to the "zero state of register 14". After the pulse generator 18 has started to give out pulses, through the disabling pulse distributor 17 that does not have 35, the register 14 starts filling up, which through the decoder 8 and the beam switch 7 of the upper stage begins polling the arrays of the upper stage points. As soon as the array 40 having at least one point with exciting voltage falls under survey 40, a signal corresponding to the presence of a "sign appears at the output of the switch 7, this signal translates into the forbidden state and fixes the pulse distributor 17 in it which gives permission for the operation of the decoder 6 and the pulse distributor 16 junior. At the same time, the decoder 6 prohibits the output from the outputs 50 of the switch of the interrogation 5 of this stage of signals corresponding to the “attribute. The pulse generator begins to fill in the register 13, which, through the decoder 6 and the interrogation switch 5, gives instructions to interrogate the arrays of points 55 of this stage, which are part of the upper stage array, found during the polling at the considered stage. As soon as an array containing at least one point with exciting voltage gets to the poll at this stage, the signal from the switch output to the interrogator at the polling of the last (lowest) stage, which runs similarly. At this stage, there is not an array of points, but a separate specific point, which has a driving voltage and is included in more and more enlarging arrays of points, found at the previous stages of the survey. In this case, the pulse distributor 15 is transferred to the forbidden position by the output signal of the interrogation switch 7 and is fixed in it, and from its output sends the contact signal to the analysis circuit. Thus, as a result of the step interrogation, the address is written in the step registers (12-14) the detected point, and the signal “contact found” was received in the analysis circuit, i.e., the same result was obtained as in the case of sequential polling of each point, but already with a significantly smaller expenditure of time (polling cycles). The analysis circuit, having received the contact signal found from the pulse distributor 15 and the signal of the result of the address comparison from the comparison circuit 19, generates a signal of correctness or incorrectness of the assembly. A signal to output the information about the error is sent from the analysis circuit 9 according to the assembly error signal. After this, the analysis circuit 9 with its signal puts the pulse distributor 15 into the working state. When the pulse distributor 15 transitions into the working state, the "contact is found" signal is found and the polling of the corresponding points of the younger polled array continues. If there is an excitation voltage point among them, then it is analyzed again and the operation continues as after the first point detected. If there is no point with excitation in the lowest polled array, then the register 12 goes from the overflow pulse to the initial position and the second-stage pulse distributor 16 is transferred to the working state with the same overflow pulse and allows the continuation of polling of the second-step point arrays, etc., to until an array of the presence of a sign is detected (the survey passes until a specific point is found with the exciting voltage and then, as already described above), the register of the highest step of the query and its overflow are full will not go to the analysis circuit as a signal to end the test of this circuit; by this signal, the connecting switch switches the voltage to a new point, since the analysis circuit issues +1 to the register 11, and the address of the first point of the new circuit and the process her check goes as described above. Missing connections detect

the torus generates a prohibition signal each time when the comparison circuit 19 generates a match signal when the address of the stage register is equal to the corresponding bits of the address change circuit 20, which goes before the output of the signal "the contact is found from the pulse distributor 15, and the analysis circuit gives the command to output information about the missing circuit, a new address is entered into the address relocation scheme. Further, the device works in a similar way.

Thus, in one cycle of the interrogation polling, both unnecessary and missing connections in the circuit being tested are revealed, but with a minimum amount of time (clock pulses), since during the incremental polling, only those arrays of points that have an excitation voltage , or in its absence, only the point whose address is written to the point address change register is polled.

Subject invention

A device for automatically checking the installation, comprising a series-connected switch of connecting test points, a register, a decoder, an analysis circuit, a comparison circuit, an address change circuit and an input unit whose output is connected to one of the inputs of the analysis circuit, the second output is connected to the generator input

pulses, and an output unit, characterized in that, in order to increase the speed of the mounting check, the device contains n steps of serially connected pulse distributor, register, decoder and polling switch, one of the inputs of the polling switch / - and stage connected to the output of the polling switch (i-1) -th stage (where i, ..., n), one of the inputs of the first-stage polling switch is connected to the switch output of the control point connection, the output of the n-th poll switch is connected to the corresponding distributor inputs pulses of each stage, the output of the register of the i-th stage is connected to one of the inputs of the pulse distributor (/ + 1) -th stage, and the output of the register of the l-th stage is connected to the corresponding input of the analysis circuit, the other outputs of the registers

each stage is connected to one of the inputs of the comparison circuit, the input of the output unit and the output of the decoder of the control point connection channel, the output of the pulse distributor of the tth stage is connected to one of

the inputs of the decoder (i-1) -th stage and to one of the inputs of the pulse distributor (i-1) -th stage, the input and output of the clock generator are connected to the corresponding inputs of the pulse distributors of each stage ..,,