SU1663431A1 - Device for measurements of opaque plane figure area - Google Patents

Abstract

This invention relates to instrumentation technology. The aim of the invention is to improve the reliability of the device by providing diagnostic capabilities for monitoring the device in the process of measuring the area of the object being monitored. A device for measuring the area of opaque flat figures comprises an optically coupled emitter 1 and a radiation receiver 2, the pulses from whose output, having passed through the amplifier 32, the threshold element 35, the tenth matching circuit 17, the first OR circuit 30 and the fourth matching circuit 11, are summed up The first counter 5. When the object changes color, the sensor 36 controls and the background changer 37 triggers, the signal from the output of which closes the tenth matching circuit 17 and, through the second inverter 34, opens the fifth matching circuit 12, pulses from the output of receiver 2 Neither the first inverter 33 converts to the standard for this device type and enters the first counter 5. The signal from the sensor output of 3 lines during operation of the device, i.e. while the start button 43 is pressed, prepares the second and third counters 26, 27, the third RS flip-flop 20, through the first RS flip-flop 18 and the second coincidence circuit 9 allow the first generator 23 to control the write mode of the radiation receiver 2 and prepare the second generator 24 that controls the read mode of the receiver 2 radiation. The third and fifth RS-triggers 20 and 22 and the eighth and ninth circuits 15, 16 coincide with the determination of the mode of operation of the device, the modes are identified on the indicators 40 and 41, "Test" and "Operation". The second counter 26, the second circuit OR 31, the seventh coincidence circuit 14, the fifth counter 29 and the fourth RS flip-flop 21 take control of the correct operation of the radiation receiver 2, the sixth coincidence circuit 13, the fourth counter 28 and the fourth RS flip-flop occupy the control of the admissible object size. 21. Control errors are identified by the "Avariya" indicator 39. The measurement result is recorded in the area recorder 42. 1 il.

Description

The invention relates to a measuring and control technique and can be used to measure the area of opaque flat shapes.

The aim of the invention is to improve the reliability of the device by providing diagnostic capabilities for monitoring the device in the process of measuring the area of the object being monitored.

The drawing shows a block diagram of the device.

A device for measuring the area of opaque flat figures comprises an optically coupled emitter 1 and a radiation receiver 2, a 3 line sensor, a conveyor 4 mechanically connected to a 3 line sensor, the first counter 5 connected in series, the decoder 6 and the first indicator, ten matching schemes 8 through 17, and p of RS-flip-flops from 18 through 22, the first, second and third generators 23, 24, 25, second, third, fourth and fifth counters 26, 27. 28, 29, first and second circuits OR 30 , 31, amplifier 32, first and second inverters 33, 34, threshold element 35, contrast sensor 36, block 37 the background exchange, the conveyor control unit 38, the second indicator 39 Avariya, the third indicator 40 Test, the fourth indicator 41 Work, the recording device 42 and the Start button 43 connected to the installation inputs of the fifth counter 29 and the fourth RS flip-flop 21 whose output is connected to the inputs of the conveyor control unit 38, the second indicator 39 of Avariya, the third generator 25uIpulses and the first input of the first matching circuit 0, the second input of which is connected to the sensor output of 3 lines, the output connected to the R input of the first RS flip-flop 18, the second inverter inputs second and third counters 26, 27, adjusting input of the third RS-trigger 20 and a first input of the second oscillator 24, the output of the first RS- flip-flop 18 is connected to a first input of a second coincidence circuit 9, a second input

which is connected to the first output of the third pulse generator 25 and the first input of the third coincidence circuit 10, the output is connected to the first input of the first pulse generator 23, the first output of which

connected to the control input of the radiation receiver 2, the second output is connected to the R-input of the second RS-flip-flop i9 and the installation input of the first RS-flip-flop 18, the second input is connected to the output of the third counter 27, the setting input of the second RS-flip-flop 19 and the first inputs of the sixth , seventh, eighth and ninth circuits 13, 14, 15, 16 coincidence, the output of the second RS-flip-flop

19 is connected to the second input of the third coincidence circuit 10, the output of which is connected to the counting input of the third counter 27 and the second input of the second pulse generator 24, the first output of which is connected to

the first input of the fourth coincidence circuit 11, the second output is connected to the read input of the radiation receiver 2, the output of which through the amplifier 32 and the threshold element 35 is connected to the input of the first inverter 33 and the first input of the tenth coincidence circuit 17, the second input of which is connected to the input of the second the inverter 34 and the output of the background changer 37, the input of which is connected to the output of the contrast sensor 36, the output of the first inverter 33 is connected to the first input of the fifth coincidence circuit 12, the second input of which is connected to the output of the second inverter 34, the output is connected with the first input of the first circuit OR 30,

the second input of which is connected to the output of the tenth matching circuit 17, the output being connected to the second input of the fourth matching circuit 11, the counting input of the second counter 26 and the R-input of the third RS flip-flop 20,

the third input of the fourth coincidence circuit 11 is connected to the second output of the third pulse generator 25, the output is connected to the counting input of the first counter 5, the second output of which is connected to the information input of the recording device 42,

the control input is connected to the first output, and the zero input is connected to the second output of the registering device 42, the first input of which is connected to the input of the fourth operation indicator 41, the second input of the sixth 13 coincidence, and the direct output of the CL73. o r-trigger. 5 2 second input- connected to. of the third indicator 40 Test, cleared by the course of the choo-rout of the RATING ACCOUNT ° 8, SbN-TYauschPM ChHOЈ.M

On that counting, p 29 and reverse1 1. The he / O of that RS-flip-flop 22 outputs of the ERO of the scheduling 26 is connected to the main switch OR 31, which is connected to the second input of the seventh xeMh, h created t .. -th course of which syedichech with SPIRTIM of that counter 29, its code r - .., rL yen with the second R-Bxocof. etterto.o RS-nir hera 21, the output of circuit 13 is connected to the counting input of the fourth counter 23, the output of which is connected to the first R-input of the fourth RS-flipgeo 21, the forward and reverse outputs of the third RS-flip-flop 20 are connected respectively to the second inputs of the eighth and ninth coincidence circuits 15, 16, the outputs of which are connected respectively to the R input and the installation input of the fifth RS flip-flop 22.

The device works as follows

By pressing the start button 43, the counter 29 of the fourth RS flip-flop 21 is reset. At the output of the fourth RS flip-flop 21, a command is issued that allows the third generator 25 to start, to turn on the conveyor control unit 38 and pass through the first circuit 8 match to the R input of the first RS flip-flop 18 signals from the 3-line sensor.

A 3-row sensor, mechanically connected to the conveyor 4, generates a command to enable the start of reading information in the row, coming through the first matching circuit 8 to the R input of the first RS-trigger 18, and resets the counters 26, 27. At the same time, the output of the trigger 18 a signal is generated that permits the passage of signals from the third generator 25 pulses to the input of the first generator 23 pulses, which generates a sequence of commands necessary to read information from the photosensor of the radiation receiver 2 to its electrical circuit. After the end of the read cycle, the first generator 23 of the pulse-in generates a command to prohibit the passage of pulses from the generator 25 through the second circuit 9 by matching the signal to the first RS flip-flop 18 and at the same time switching the second RS trigger 18 to allow the passage of pulses from the third generator 25 through the third circuit 10, matching the second pulse generator 24.

The second generator of 24 pulses forms at the second output a sequence of commands, according to which electrical information from receiver 2 is radiated, “but output to the CMP transmitter PC.). With

5 1 in the color of the measurement object, the information pulse sequence through the amplifier 32, the threshold element 35, the tenth matching circuit 17, the first OR circuit 30, the fourth matching circuit 11 is fed to the first counter 5, which sums the resulting pulse train.

With the white color of the item

a contrast sensor 36 forms a signal to

- change the background, and block 37 change: background issues

5 through the second inverter 34 to the fifth matching circuit 12 and the tenth matching circuit 17. In this case, the information sequence of pulses through the amplifier 32, the threshold element 35, the first

0, the inverter 33, the analogue coincidence circuit 12, the first OR circuit 30. The fourth coincidence circuit 11 arrives at the first counter 5, which summarizes the resulting pulse train. The obtained number is transmitted through the decryption unit 6 to the first indication 7. To synchronize and increase the noise immunity of the second; a 24-pulse network generates a count resolution signal at the first input of the fourth matching circuit 11.

0 With the second Ba.ho Ds of the torpedo generator 25 imputas. The third input of the fourth circuit 11 of coincidence is fed to a frequency that is a multiple of the true measured area to bring the first

5 for a surveyor 5. For example, with a 2 mm pitch measurement line and 2 mm pitch lines at the second output of the third control unit 25, during the passage of one information pulse on the first and second input, the fourth matching circuit 11 must generate four pulses. Then the readings of counter 5 will reflect the received information about the area in mm2, i.e. the true area value will be obtained

5 measured object

Simultaneously with the information reading cycle and its first counter 5 counting, the third counter 27 counts the number of polled cells of the radiation receiver 2,

0 receiving the signal from the third matching circuit 10. After polling the last cell from the output of the third counter 27, the signal translates the second RS flip-flop 19 to a position that prohibits the passage of pulses from

5 of the third generator 25 through the third circuit

10 matches to the second generator 24, and also sets the first generator 23 of pulses to the initial state. This completes the row polling cycle. The second cycle of operation begins on the second sensor signal of 3 lines. And so on.

The use of radiation receivers using the principle of operation of devices with charge coupling allows, during the operation of the device, to monitor its operability, to determine the phase of its operation — Test, Work, Avari.

Information characterizing the health of the device — all the cells of the radiation receiver are illuminated, indicates the health of the device as a whole, and, therefore, can be used as a test cell.

This device function is implemented by the third RS flip-flop 20, the eighth and ninth coincidence circuits 15 and 16, and the fifth RS flip-flop 22.

The third RS flip-flop 20 is prepared by a start-of-line signal from a 3-line sensor, which is fed to it via the first matching circuit 8. Information pulses from the threshold element 35 arrive at the R-input of the third RS-flip-flop 20. If there is no information for the entire line, i.e. all elements of the radiation receiver 2 are illuminated, then the third RS flip-flop 20 will remain in the initial state and upon arrival from the output of the third counter 27 of the signal to the first inputs of the eighth 15th and ninth 16 coincidence circuits information from the output of the third RS-flip-flop 20 will be overwritten in the fifth RS-flip-flop 22. At the same time, at its inverse output, a signal turns on, which will turn on the third indicator light 40 Test.

In the event that one or more cells of the radiation receiver 2 are darkened, the third RS flip-flop 20 will change the initial state and after arriving at the first inputs of the eighth 15th and ninth 16 information coincidence circuits, it will also be overwritten into the fifth RS-tmggger 22. However, it will record a signal to the direct output, which will turn on the fourth light indicator. 41 Operation. At the same time the indicator light 40 Test goes out.

Information that characterizes the loss of device performance can be presented in two versions.

First option. All cells of the radiation receiver 2 are darkened when polling several lines. If one line is darkened, the device should treat this information as a malfunction.

This function is implemented on the second counter 26, the second circuit OR 31, the seventh circuit 14, the match, and the fifth counter 29. By the start of line signal from sensor 3

the rows coming through the first matching circuit 8 to the input of the zero setting of the second counter 26, it is set to zero. The capacity of the counter 26 must be equal to the number of cells in the radiation receiver 2.

Further, the information received from the radiation receiver 2 through the amplifier 32 and the threshold element 35 is fed to the input of the second counter 26 and is summarized. If all cells are darkened, which corresponds to a completely missing signal from the radiation receiver 2, which is estimated by the OR 31 circuit from the outputs of the second counter 26, then by the signal the line end from the third counter output 27 through the seventh circuit

14 matches, information about this is entered in the fifth section 29. If a device malfunctions, then the signal from the inverse output of the first RS flip-flop 22, i.e. on the Test signal, counter 29 is zeroed. If all the cells of the radiation receiver 2 are darkened for the number of lines specified by the fifth counter 29, a signal is output to its second input (counter 29) to the second input (second R input)

the fourth RS flip-flop 21, the output of which then forms a command, including the second light indicator 39 of Avari, as well as prohibiting the operation of the third generator 25, passing the signal from the 3-line sensor and ordering to stop the conveyor 4 of the conveyor control unit 38.

The second option. The length of the measurement object clearly exceeds the number of rows specified for its measurement, i.e. if it is known that the maximum length of the skin, for example, 2 m, then the number of lines required for its full measurement at a line spacing of 2 mm is 103.

If, under these conditions, the device measures 10J + X lines (where X is the number of lines incident on the movement of the skin on the conveyor belt due to slippage), then it can be said with confidence that the device is faulty.

This information is processed by the sixth coincidence circuit 13 and the fourth counter 28.

By signal Test with inverse output

The second RS flip-flop 22 fourth counter 28 is set to zero. Upon completion of the line reading, the signal from the output of the third counter 27 through the sixth circuit 13 coincides with the presence of a signal at its second output from the direct output of the fifth RS flip-flop 22 to the counter 28 lines.

If the operation mode ends before the fourth counter 28 overflows, then by the Test signal from the inverse output of the second RS flip-flop 22 it will be set to zero, and the device will continue to work,

If the overrun of the four-hour counter 28 occurs, then, by its signal, a command is generated to the first R-input of the four RS-flip-flop 21 at the exit of the fourth RS-flip-flop 21, which turns on the second network indicator 39 Alvari 1, prohibits the third generator 25, passing the signal from the 3 line sensor and warns to stop the conveyor 4 to the conveyor control unit 3B. ,

The signals from the outputs of the fifth P3-three Gera 22 are fed to the area recorder 42 of the measured object, which generates a signal for reading information from the first counter 5 according to the signal from the inverse output of the fifth RS-flip-flop 22 and then the signal to reset it.

Claims (1)

Invention Formula A device for measuring the area of opaque flat figures, comprising an optically coupled emitter and radiation receiver, a row sensor, a conveyor mechanically coupled to the row sensor and connected in series with a first counter, a decoder and a first indicator, characterized in that Equipped with ten coincidence circuits, five RS triggers, three pulse generators, two OR circuits, an amplifier, two inverters, a threshold element, a contrast sensor, a background changer, a second, third, even the twisted and fifth counters, the control unit, the conveyor, the second, third and fourth indicators, the registering device and the Start button connected to the installation inputs of the fifth counter and the fourth RS flip-flop, the output of which is connected to the inputs of the conveyor control unit, the second indicator Avari, the third pulse generator and the first input of the first coincidence circuit, the second input of which is connected to the output of the row sensor, the output is connected to the R input of the first RS flip-flop, by tapping the inputs of the second and third counters; input of the third RS-flip-flop and the first input of the second oscillator, the output of the first RS-trigger is connected to a first input of a second coincidence circuit, the second input of which connected to the first output of the third pulse generator and the first input of the third coincidence circuit, the output is connected to the first input of the first pulse generator, 5 the first output of which is connected to the control input of the radiation receiver, the second output is connected to the R input of the second RS-trigger and the installation the input of the first RS trigger, the second input is connected to the output 0 of the third counter, the setup input of the second RS flip-flop and the first inputs of the sixth, seventh, eighth and ninth coincidence circuits, the output of the second RS flip-flop is connected to the second input of the third circuit  match, the output of which is connected to the counting input of the third counter and the second input of the second pulse generator, the first output of which is connected to the first input of the fourth match circuit, the second 0, the output is connected to the reading input of the radiation receiver, the output of which through the amplifier and the threshold elements is connected to the input of the first inverter and the first input of the tenth matching circuit, the second input 5 of which is connected to the input of the second inverter and the output of the background changer, the input of which is connected to the output of the contrast sensor, the output of the first inverter is connected to the first input of the fifth coincident circuit, the second input of which is connected to the output of the second inverter, the output is connected to the first input of the first circuit OR, the second input of which is connected to the output of the tenth matching circuit, the output is connected 5 with the second input of the fourth coincidence circuit, the counting input of the second counter and the R input of the third RS flip-flop, the third input of the fourth coincidence circuit is connected to the second output of the third pulse generator; the output is connected to the counting input of the first counter, the second output of which is connected to the information input the recording device, the control input is connected to the first output, and the zeroing 5 input - with the second output of the registering device, the first input of which is connected to the input of the fourth Work indicator, the second input of the sixth coincidence circuit and the direct output of the fifth RS flip-flop, the second input is connected to the input of the third Test indicator, zeroing the fourth counter stroke , by zeroing the input of the fifth counter and the reverse output of the fifth RS trigger, the outputs of the second counter are connected to the inputs of the second OR circuit, the output of which is connected to the second input of the seventh coincidence circuit, the output of which is connected to the estimated input of the fifth account tichka, the output of which is connected to the second R-input of the fourth RS-flip-flop, the output of the sixth circuit 11166343112 match is connected to the counting input of the second inputs of the eighth and ninth circuits the fourth counter, the output of which is connected-coincident, the outputs of which are connected by the sonne with the first R-input of the fourth RS-trigger, responsibly with the R-input and the installation Hera, forward and reverse outputs by a third-way fifth RS-flip-flop. RS-flip-flops are connected respectively c5