SU1440978A1 - Apparatus for measuring relative deformation of textile materials - Google Patents

Abstract

This invention relates to a measurement technique. The purpose of the invention is to expand the functionality by measuring the area of the material. The measurement of the shrinkage of the material is carried out by controlling the width at the entrance and exit to the deformation zone. using sensors 1, 2 width, produced at certain intervals of the length of the passing material.

Description

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controlled by sensors 11, 12 length. The current width at the entrance and exit of the zone is entered into blocks 3, 4 of the memory according to the signal from the output of differentiators 14, 16 of the falling edge of pulses from sensors 11, 12 of length and is added to the previously obtained values, stored by shh-tmis in blocks 7, 8 memories, adders 5, 6. Overwriting information in blocks 7, 8 occurs on a signal from the output of diff

The invention relates to a measurement technique and can be used to measure the shrinkage of roll materials.

The aim of the invention is to enhance the functionality by also measuring the area of the material.

The drawing shows the block diagram of the device.

A device for measuring the relative deformation of textile materials, rials contains two measurement channels each of the channels has a sequence. 1 n 2 wide width sensors, the first blocks 3 and 4 of the memory, the first adders 5 and 6, the second 7 and 8 and the third 9 and 10 memory blocks, the output of the second blocks 7 and 8 of the memory are connected to the second inputs of the first adders 5 and 6, pulse sensors 11 and 12 are lengths, differentiators 13-16, the outputs of the first and second pulse sensors 1) and 12 are connected to the inputs of differentiators 13-16, respectively, and the outputs of differentiators 13 and 15 are connected to the second inputs of the second blocks 7 and 8 of memory, respectively, the output of the differentiator 13 is also connected to the input of the first sensor 1 bus The outputs of the differentiator 15 are also connected to the input of the second width sensor 2, in addition, the device contains a series-connected computing unit 17 (for example, micro computers) and a shrink indicator 18 connected in series to the second sc matrix 19 and the fourth memory block 20, the output of which is connected to the second input of the second adder 19, subsequently

of the factorization 13, 15. Information from the area of the material 23 according to the signal of the generator of 24 clock pulses is copied into blocks 9, 10 of the memory, processed by the computing unit 17, and the resulting shrinkage value is displayed on the indicator 18. The adder 19 and the block 20 of the memory serve to measure the total area of the material being monitored, and the counter 21 and indicator 22 to measure its length. 1 il.

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24 connected lengthwise counter and length indicator 22, rolled material 23, 24 clock pulse generator, the first output of which is connected to the third inputs of the first 3 and 4 and second 7 and 8 memory blocks, the second output to the second inputs of the third blocks 9 and 10 of memory and the second input of the fourth memory block 20, the output of which is connected to the first input of the second adder 19, and the output of the second memory block 8 of the second measurement channel is connected to the second input of the second adder 19.

A device for measuring the relative deformation of textile materials works as follows.

During movement of the rolled material 23, the pulse sensors 11 and 12 produce pulses corresponding to the passage in the measurement zone of a certain piece of material 23. Measurement of the deformation of the rolled material 23 over the area is carried out by controlling its width and length at the entrance and exit for certain, predetermined, time interval. The measurement interval is set by the generator 24 clock pulses. Differentiators 13 and 15 separate the leading edge of the pulses of the pulse sensors 11 and 12 of length, which are fed further to the inputs of the width sensors 1 and 2, where the current value of the width of the rolled material 23 is measured. At the same time, the signal goes to the second blocks 7 and B where the previous value of the total width of the material being processed is entered 23. If we assume that the measurement starts from the initial moment of time, then at this moment the 24 clock pulse generator at its first output generates a signal which blocks 3, 4, 7, and 8 of memory. Therefore, in blocks 7 and 8 of the memory, the first pulse from the outputs of the pulse sensors 11 and 12 is written to a value equal to zero. The measurement interval of sensors 1 and 2 of width is zoned so that by the end of the pulses at the outputs of sensors 11 and 12 of length, the width measurement is over. In this connection, the pulses from the differentiators 14 and 16, which separate the leading edge of the pulses from the sensors 11 and 12, cause

the area of the processed material 23.

overwriting the measured value of the widths of 8 and 20 memory into memory block 20, into cones in memory blocks 3 and 4. The next torus accumulates the value of the total pulses from the outputs of the sensors 11 and 12 lengths of the leading edge, measures the new current widths from sensors 1 and 2 widths and records 25 the sum of the contents of the memory blocks into blocks 7 and 8, respectively, and the falling edge of the sensors pulses 11

12 lengths allocated to differentiator-. „„

7 / 4х-г-г,. f length sensor and the first block of folders

mi 14 and 16. Record new

-. - ti, serially connected widths of blocks 3 and 4 pa. In this case, the totals 5 and 6 form the indicated sums at the inputs of blocks 7 and 8 of the memory. Thus, during the measurement time t, given by the generator of 24 clock pulses, 35 potential due to the measurement in blocks 7 and 8 of memory occurs on the area of the material, the accumulation of the total values of the width of the material 23 for the considered time interval t. After this time, the generator of 24 clock pulses with 40 memory blocks, the outputs of which connects the signals to the second kena to the inputs of the computing unit, the output which, upon arrival in the width controller and two differentials 7 and 8 of the memory, contains With tori in them, the outputs of the sensors for the width of the connection are rewritten into blocks 9 with the first inputs of the first blocks and 10 memories. Blocks 9 and 10 of memory are 45 memory, the inputs of the differentiators of the first measurement channel are connected to the output of the invention.

A device for measuring the relative deformation of textile materials, containing two measurement channels, each of which has pulses — a calculating unit and a first indicator, a clock pulse generator, and a counter, characterized in that, in order to expand, the function is supplied in series with each channel. connected by the first adder, the second and the third

The result of an n-1 measurement of the area of the material 23 entering the zone and leaving the deformation zone while the same result is erased in blocks 7 and 8 of the memory. This achieves the possibility of continuous measurement of the deformation of the material 23, and the duration of the deformation calculation by the memory blocks 9 and 10 can be compared to the first pulse length sensor, the inputs of the differentiators of the second measurement channel are connected to the output 5Q of the second pulse length sensor, the outputs of the first channel differentiators are connected to the second inputs of the second memory blocks, as well as with the inputs of the width sensors, respectively, are output with the measurement time, i.e. time-gg moves second channel differentiators

him t. Information from the outputs of the blocks 9 are connected to the second inputs of the first

and 10 memory goes to the memory calculator, respectively, output

block 17, which calculates the relation of the first differentiator of the second permissible deformation of the material 23 .. la connected to the input of the counter, the output

The results are displayed on indicator 8,

After time t, which ensures the capture of information from the outputs of memory blocks 7 and 8 and rewriting it into memory blocks 9 and 10, a signal is formed at the first output of the clock generator 24, embedding the contents of 6j-tocs 3, 7, 4 and 8. The measurement cycle is repeated.

Simultaneously with these operations, the counter 21 constantly counts the metrases of the processed material 23, the result is reflected on the indicator 22. To calculate the total area of the processed material 23 upon receipt of a pulse from the second generator output 24 clock pulses, the sum of the blocks is recorded

the area of the processed material 23.

8 and 20 of the memory into the memory block 20, in which the value of the total

8 and 20 of the memory into the memory block 20, in which the value of the total

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 length sensor and first block of dads

ti, consistently connected zy-

capabilities due to the measurement of the area of the material, memory devices, outputs of which are connected to the inputs of the computing unit, a width sensor and two differentiators, outputs of the width sensors connect the first inputs of the first memory blocks, the inputs of the differentiators of the first channel measurements are connected with the formula of the invention

A device for measuring the relative deformation of textile materials, containing two measurement channels, each of which has pulses — a calculating unit and a first indicator, a clock pulse generator, and a counter, characterized in that, in order to expand functionality by measuring the area material, memory devices, the outputs of which are connected to the inputs of the computing unit by the width sensor and two differentiators, the outputs of the width sensors are connected to the first inputs of the first memory blocks, First of differentiators s th measuring channel connected to vyho

The structure is equipped with the first and the second and third

The house of the first pulse length sensor; the inputs of the differentiators of the second measurement channel are connected to the output 5Q of the second pulse length sensor; the outputs of the first channel differentiators are connected to the second inputs of the second memory blocks, as well as to the inputs of the width sensors, respectively;

The first memory block of each channel, the output of the clock generator iiSMSpeHHft is connected to the input of the first one connected to the third inputs of the first sums, the output of the second memory block and the second memory blocks, the second from each measurement channel is connected to the second inputs of the third block. with the second input of the first adder, a memory box and the second input of the fourth; in addition, the device is equipped with a memory block, the output of which is connected by a second one with the first input of the second summator, the fourth memory block and a, and the output of the second memory unit the second indicator, which channel measurements Yu second input coupled to an output of the counter is connected to the first input of the second adder vtorvd.

Claims (1)

Claim A device for measuring the relative deformation of textile materials, containing two measurement channels, each of which has a pulse length sensor and a first memory unit, series-connected computing unit and a first indicator, a clock generator, and also a counter, characterized in that, in order to expand the functional opportunities due to measuring also the area of the material, the device is equipped with series-connected first adder, second and third memory blocks connected to each channel, output which are connected to the inputs of the computing unit, a width sensor and two differentiators, the outputs of the width sensors are connected to the first inputs of the first memory blocks, the inputs of the differentiators of the first measurement channel are connected to the output of the first pulse length sensor, the inputs of the differentiators of the second measurement channel are connected to the output of the second pulse length sensor , the outputs of the first channel differentiators are connected to the second inputs of the second memory blocks, as well as to the inputs of the width sensors, respectively, the outputs of the second differentiators The channel ioators are connected to the second inputs of the first memory blocks, respectively, the output of the first differentiator of the second channel is connected to the counter input, the output of the first memory block of each measurement channel is connected to the input of the first adder, the output of the second memory block of each measurement channel is connected to the second input of the first adder, in addition , the device is equipped with a second adder, a fourth memory unit and a second indicator connected in series to the output of the counter, the first 1440978 6 the output of the clock generator is connected to the third inputs of the first and second memory blocks, the second output & output is with the second inputs of the third memory blocks and the second input of the fourth memory block, the output of which is connected to the first input of the second adder, and the output of the second memory block 10 of the second the measurement channel is connected to the second input of the second adder. Compiled by V. Pisarevsky