SU960690A1 - Pointer type instrument checking device - Google Patents

Description

The invention relates to a measurement technique and can be used to calibrate measuring instruments with a pointer.

A device for calibrating instruments comprising a transmitting television tube shaper is known. circular scan, reference signal source, software, storage device, information processing unit, etc., providing the calculation of the center of rotation of the pointer, finding the scale marks and the subsequent calculation of the measurement error 1.

The disadvantages of these devices are a large amount of memory for each of the types of scales of scanned instruments, complex information processing algorithms, the complexity of setup and adjustment.

The closest in technical essence to the invention is a device for calibrating measuring instruments containing a source of reference signals, the output of which is connected to a calibrated instrument, a movable television tube with an electric motor, having optical communication with the scale of the instrument being tested and connected to the input of the block.

analysis of the video signal and the device for calculating the error, as well as a software device whose input is connected to the output of the transmitting television tube, and the output. with the electric motor drive transmission television tube.

The programer device counts the number of scale marks that have passed through the middle of the field of view of the television tube, and provides movement of the transmitting television tube along the scale of the instrument being turned before receiving

15 marks in the middle of the field of view of the tube by applying a supply voltage to the electric motor. After this, the reference signal source is turned on, the pointer takes the position

20 to the right or left of the calibrated mark (depending on the sign of the error), and in the next horizontal scanning period video pulses from the pointer and the calibrated mark are formed,

25 the time interval between which is converted into the digital equivalent of an error of 2.

The disadvantages of the known device are the presence of moving parts.

30 and low productivity.

The purpose of the invention is to increase productivity.

This goal is achieved by the fact that a device for checking pointer instruments contains a source of reference signals, the output of which is connected to the input of a rotating instrument, a transmitting television tube, a program block and a serially connected memory block, an error calculator and a registering block, the second input of which connected in parallel with the inputs of the source of reference signals and the memory block and with the first output of the program block, the second output of which is connected to the control input of the error block spine, administered mirror optical element which is accomplished through the optical communication transmission of a television tube with power metal emym device serially connected driving oscillator, shaper lowercase. sync pulses, frame sync shaper, the output of which is connected simultaneously to the input of the program block, raster scan generator, the output of which is connected simultaneously with the input of the transmitting television tube and video control element, as well as the pointer code generator, pointer code match element, string code element, video signal generator , block of selectable labels and block selection pointer, and the generator of lower case sync pulses is connected by its first output the second input of the raster scan generator, the second output with the first input of the generator, the pointer code, the second and third inputs of which are connected to the third output of the program block and the output of the master oscillator, respectively, and the third output of the horizontal sync pulse generator is connected to the first input of the index code matching element, the second input of which is connected to the output of the pointer code generator, while the output of the pointer code match element output is connected to the first input of the pointer selection unit, the second input one of which is connected in parallel with the fourth input of the pointer code generator, the first input of the selectable label selection block with the output of the video signal builder, the second input of the selectable label selection block with the second output of the memory block, and the first and second inputs of the video signal builder are connected in parallel with the corresponding inputs of the video monitor element, with the outputs of the transmitting television tube and the element coincidence of the line code, in addition, the first and second inputs of the match element ko-i da line n dsoedineny to the second output of the human .sinhroimpulsov to the third output of the storage unit ti, respectively, and the output selection unit emoy power metal label and the output selection block pointer connected to third and fourth inputs of unit calculating error respectively.

but.

The drawing shows the functional diagram of the device for checking pointer instruments.

The device contains a brush 1

reference signals, turned on at selection 2, a mirror-optical element 3, transmitting television tube 4, memory block 5, error calculation block 6, recording block 7,

software block 8, the master oscillator 9, the shaper 10 horizontal sync pulses, the shaper 11. frame sync pulses, raster scan generator 12, video monitor element 13, video signal generator 14, block of mark selection, element

16 Matching Line Code Element

17 matching the pointer code, the pointer code generator 18 and the block

19 selection pointer.

The device works as follows.

A rotary instrument 2 with an arcuate scale is installed in front of the mirror-optical element 3 in the field of view of a transmitting television tube 4. On the video control element 13 a horizontal linear image of the scale of the instrument being scanned is observed. vertically arranged scale marks and pointer. Convert arc-shaped scale to linear

the image is made by a mirror-optical element 3, consisting of a lens and a mirror with a working surface in the form of a circular cone, the center line of which is located

vertically, and forming a slope, at an angle of 45, and the radius of curvature of the mirror surface in the working area is equal to twice the radius of the scale being turned. The calibrated instrument is installed so that the axis of rotation of the pointer is in the middle of the working surface of the mirror and its axial line.

Claims (2)

On the screen of the video monitor element 13, two raster lines with an increased brightness are formed, their position is determined by the codes of the working raster lines recorded in the memory block. The scanner device 2 is installed in front of the mirror-optical element 3 so that one of the raster lines intersects all the marks on the image of the scale of the scanned instrument, and the other is above or below the scale marks and crosses only the pointer image. Software block 8 switches to verification mode. At his command, the source 1 of the reference signals generates a measuring signal corresponding to the first mark to be checked and delivers it to the input of the instrument being scanned. 2. At the same time, the code of the first turning point is recorded in the registering unit 7, and in memory block 5, in addition to the memory cells with sequence numbers of working lines of the cell and the total number of marks of the scale being scanned and the accuracy class instrument, whose ki is with the sequence number of the first. The raster scan generator 12 generates sawtooth stresses of the frame and line sweeps. It is synchronized from the giving generator 9 through the counter shapers of 10 and 11 horizontal and frame clock pulses. Each line of the raster corresponds to a certain code of the driver 11 frame sync pulses. Each vertical line corresponds to a certain code of the generator of 10 line sync pulses. Frame sync pulses are also used to synchronize software block 8. The current code of the driver of the 11 frame sync pulses is compared in element 16 of the line code match with the codes of the working lines of memory block 5. When the codes coincide, strobe pulses are generated, which are fed to the video control element 13 to highlight the brightness of the working lines of the raster and the video signal generator 14 to receive on. its output is a pointer pulse on one working line and a pulse of scale number numbers and a pointer on another working line. The shaper 18 of the pointer code contains a counter divider that operates synchronously with the counter divider of the shaper of 10 horizontal sync pulses. The counter divider of the driver 18 by the command of the program block (after completion of the pointer setting process, i.e. 1-2 seconds after the reference signal of the mark being turned on) is stopped by a pointer pulse from the output of the video driver 14, and thus, remembers the pointer code which is applied to the pointer code element 17. This element also supplies the current counter code of the divider of the 10 for horizontal sync pulses. At the time of the coincidence of the codes, the element 17 generates a pulse, which coincides in time with the moment npoctiioTpa of the pointer. This pulse allows you to select in the block 19 of the selection of the pointer a pointer pulse from the video signal of the working line containing the pulses of all the scale marks and the pointer. . Block 15 of the selectable label has a counter for the number of pulses on a 1-working line and an element of coincidence that, by a known sequence number nj | the first scale mark to be checked highlights the pulse of this mark. The pulses of the label being checked and the pointer are fed to the error calculation unit 6, where the time interval between these pulses is converted into the digital equivalent of the error and compared with the permissible error of the device being tested. The magnitude and sign of the error, as well as its compliance with the accuracy class, are recorded in the recording unit 7. Verification of the first point is completed. A software device generates a verification code for the second point to be verified. Shaper 18 code pointer and. The error calculation unit 6 is reset. The source 2 of the reference signals generates a measurement signal corresponding to the second point to be checked, in memory block 5, instead of cells with the sequence number n of the first point being scanned, with the sequence number P2. The second verified point, the recording unit 7 records the code of the second verified point. Otherwise, the process is repeated. In order to calibrate multidirectional instruments, the device is supplemented with a manipulator, which, after completing the verification of all calibrated points on the scale of program block 8, switches the instrument to be tested to the next measurement limit, and the verification process is repeated at the non-limit. To test multi-devices, it is proportional to the number of scales that increase the capacity of memory block 5. At the end of the instrument calibration on the first scale, the program block 8 includes in the memory block 5 new cells with the raster working row codes recorded in them, the total number of marks on the scale, the instrument accuracy class on the scale and the sequence numbers of the marks to be checked. Claim device for calibration of dial gauges containing source