SU1030642A1 - Method and apparatus for measuring parameters of elongated articles motion - Google Patents

Abstract

1. The method of measuring the parameters of the movement of long products consists in the fact that the basic and additional position sensors are installed in the direction of movement from the workpiece and the transit time is measured by two successively located points of the product between them, that, in order to expand the functionality, by providing a measurement of linear deformation, the second base and second additional sensors, position, by the passage of two consecutive points of the article the distance between the sensors and the passage section, bounded by two consecutive points of the article, the distance between the first and second base position sensors. 2, A device for the purpose of parametering the movement of long products, QO-containing three product position sensors and three generators connected to them, a correlation velocity measurement unit, the inputs of which are connected to the first and second formers, five key elements and five triggers , the output of each of which is connected to the first input of the corresponding key element, a clock generator, an output block with an indicator, and two counters connected to the inputs of a computing unit, and Especially because it is equipped with a separation unit for two colors in series with S located product points, a quarter of a position sensor and a fourth formifier connected to it, a recognition unit for two sequentially located production points, a sequential connecting sixth trigger and a sixth key element, and four counters, the input of the healing unit of two from consecutive points of the product is connected to the output of the first imager, the first output with the enable input of the first counter and the first input of the unit identifying the two-sided ™ ISDs of the product points, the second exit is with the third meter enabling input and the second block input. As recognition of the two sequentially located points of the product, the output of the first key element C1 is identified with the enable input of the second counter, the forbidden input of the third counter and. the second input of the first trigger, the output of the second driver, is connected to the second inputs of the first and second key elements, the output of the second key element

Description

The terminal is connected with the prohibiting input of the First and Secondary meters and the second input of the second trigger; the output of the third driver is connected to the second of the third and fourth keys: elements, the output of the third key of the ground terminal is connected to the second input of the fifth counter and the second input of the third trigger, the fourth output the former is connected to the second inputs of the fifth and sixth key elements, the output of the fourth key element is connected to the enable input of the fourth counter and the second input of the fourth key element ementa, vyhots fifth key element connected to -this

the input of the fifth counter, the decisive input of the sixth counter and the second input of the fifth trigger; The code of the sixth key element is connected to the prohibiting inputs of the fourth and neck counters, the second input of the sixth trigger and the third output of the block of two sub-sequentially located points from the peep, the first inputs of the trigger are connected to the corresponding outputs. There are two units of identification of two product points that are consistently assigned, a clock pulse generator, and a clock with counting inputs of counters, each output of which is connected with a corresponding computer code.

The invention relates to a visual engineering technique and is intended to measure linear deformations of long products, for example, ribbons, rovings, yarns of natural and chemical fibers in the process of forming products of spin on textile machines. A known method for measuring the parameter of the movement of long products, Zakyuchi, is that in the course of movement of the product, the basic and additional, 1shi- are established. position sensors and measure the time of passage of two successively located points of the article of distance between them ClI.

The disadvantage of the method is its limited functionality, since it is not possible to measure linear deformations of the product.

A device is known for measuring the dimensions of long products, containing three product position sensors and three forms connected to them, a correlation measurement unit soon, the inputs of which are connected to the outputs of the first and second formers, five key elements and five three the generators, the output of each of which is connected to the first input of the corresponding 1 pc of a cell, is a pulse generator, a computing unit with an INDEI boat and two counters are connected (5 with computing units 2 ”

The disadvantage of the device is limited functionality.

The purpose of the invention is the expansion of functional capabilities through the provision of linear strain measurement.

The goal is achieved by those. which is according to the measurement method of Laramet. The movement of lengthy parts, in the course of which the base and additional sections are established during the movement of the product, the effective position sensors and the transit time are measured by two consecutive points from the distance between them, and are set as the product moves by the fixed distance of the second base and second additional position sensors, measure the transit time of two successively located points of the product, the distance between these sensors, and the passage time of the section is limited two consecutive points of the product, the distance between the first and second basic positions of the position,

 In addition, a device for measuring the motion parameters of lengthy goods, containing three product position sensors and three formers connected to them, a velocity correlation unit, whose inputs are connected with the outputs of the first and second formers, five key elements of the TDB and five trigger points , the output of each of which is connected to the first input of the corresponding key element, the generator of clock pulses, calculate 310 a warm bpok with an indicator and the counter of the counter, connected to the gate of the computing unit, is equipped with With an eye to tracing two product points, a fourth position sensor and a quarter generator with it, a recognition unit for two consecutive product points, sequentially connected by a sixth trigger and a sixth key element, and four counters, the input of the extraction unit two consecutive points of the product are connected to the output of the first shaper, the first output is connected with the enabling input of the first counter and the first input of the identification unit of two successively Possible points of the product, the second output with the enable input of the third counter and the second input of the identification unit of two consecutive product points, the output of the first key element is connected with the permit input of the second counter, prohibiting actuation of the third counter and the second input of the first trigger, the output of the second driver is connected to the second inputs of the first and second key elements, the output of the second key element is connected to the prohibiting input of the first and second counters and the second input of the second trigger, the output retego shaper connected to the second inputs of the third and fourth key elements output of the third key element connected to the enabling input of the fifth counter and a second input of the third flip-flop, a fourth output is connected to formers. the second inputs of the fifth and sixth key elements, the output of the fourth key element is connected to the enabling input of the fourth counter and the second input of the fourth key element, the output of the fifth key element is connected to the inhibiting input of the fifth counter, allowing the second input of the fifth counter and the second input of the fifth of the trigger, the output of the sixth key element is connected to the prohibitory inputs of the fourth and sixth counters, the second input of the sixth trigger and the third output of the allocation of two consecutive points The device's output, the first inputs of the flip-flops are connected to the corresponding outputs of the identification unit of two consecutive points of the product, the output of the clock generator is connected to the counting inputs of the counters, the output of each of which is connected to 24 corresponding inputs of the computing unit. The drawing shows a block diagram of the described device. The device contains four sensors 1 4 4 positions of product 5, threads installed along its line of movement and connected with its outputs to four formers of 6–9 pulses, “correlation measurement unit 10, rate 11, the recognition of two consecutive points of the product , block 12 of the allocation of two consecutive points of the product, key elements 13. - 18, trigger 19-24, counters 25-30, clock generator 31, computing unit 32 with indicator 33. The outputs of drivers 6 and 7 are connected to the inputs of the correction unit 10 insulating 1gamereni speed vskhod which one of the inputs of the discrimination unit 11 of two successive article points out shaper 6 soed1shen to the input unit 12 sequentially extracting raspolozhennk article points -a generator 7 is connected with the main key inputs. 13 and 14. The output of the imaging unit 8 is connected to the main inputs of the key, elements 15 and 16, and the output of the imaging device 9 is connected to the main inputs of the key elements 17 and 18. The outputs of the block 11 are connected, respectively, from the inputs of the flip-flops 19-24, the outputs of which are connected respectively to the control inputs of the elements 1318, the outputs of which are connected to the other inputs of the flip-flops 19-24. The outputs of block 12 are connected to the enabling inputs of counters 25 and 26. The output of element 13 is connected with the enabling inputs of counter 27 and the inhibiting input of counter 26, the output of key element 14 is connected to the inhibiting inputs of counters 25 and 27. The counting inputs of counters 25-30 are connected to a generator 31 TaKTOBbLx pulses, and the outputs of these counters with the inputs of the initial data of the block 32, the output of the measurement result of which is connected with 1 Torch 33, The essence of the method is as follows. On a lengthy product, such as threads, there are defective thickenings (knots, twigs, and others), which, when passing by the position sensors, cause the appearance of pulsed signals. If the two defectively located points of the product are to select the so-called defective thickeners f and K of the thread, and measure the transit time of these thickenings between the first basic (A) and additional (A) position sensors, and then measure the transit time of these thickenings nor between the second baseline (c) and the additional (B) position sensors and the transit time of the section, bounded by these thickenings, the distance between the first and second non-spacing position sensors, then, The value of relative linear deformation can be derived from the formula J,. (AA) iMt, J, {t,) ;, (6B) i4SBW (H) iK A) I - while the distance t is thickened by sensors A Aj, (K .- the transit time k of the distance k between the sensors AA and the transit time of the defect. (With the 5h section Itc of the basic sensor Bj, time is passed through the defective area fk of the basic sensor A; the transit time of the thickening i of the distance, sensors, and VB | vv the transit time of the distance between the sensors BB by thickening 1c. The method with the aid of a drying device is as follows. An error on the presence of defective cheeks is removed by sensors 1 4 and fed to the formers 6 to 9 impulses COJB, where the root of the pulses from defective thickening of the filament 5 is formed. given from the output of the imager 6, the pulses from the defective bulges enter the block 12, the signals from the successive bulges are extracted, after which the operation of the block 12 is blocked until the implanted defective 2 thicknesses {i and all four date 1 - 4; In block 11, the most probable transit time of adjacent defective thickenings of sensors 2 - 4 is determined with regard to the speed of movement of the thread, the moments of passage of adjacent defective thickenings past sensor 1 and the deviation of the growth rate of thread 5, C of block 11 pulses The most probable passing of the next defective thickenings i and k by sensors 2 4 goes to one of the inputs of the corresponding triggers 19 i24, which keep the key elements 13 and 18 in the open state, about the moment of probable waiting until the moment of arrival of the impulses ows of neighboring defective quences i and Kc formers 7–9. Thus, at the output of the key element 13, the pulse i l characterizing the passage will be determined. defective thickening and past the sensor 2. At the outputs of the key elements 14-18. gp pulses K., ig, gi, are determined. “Pulses from block 12 and key editors 13–8 are fed to the inputs of counters, where the left counter input allows for counting pulses from the generator 31 clock pulses, and the right input prohibits clock pulse counting. The frequency of the oscillator 31 is selected from the required accuracy and the mas1N ' measurement tab. Counter 25 determines the time interval (Ml) 1c), respectively, the counters determine the intervals (t) -., (D1d -, (tg, g), 1 - fcgr Q), -, (tg). With exit counters. The values of the indicated time intervals are fed to the inputs of the initial data of block 32, where the dependence P- () i (./ J (B) i ° (BB) .i / (4Bk (t) iK) is calculated. The invention allows to increase the The production of spin products due to the establishment of permissible limits for the variation of linear deformation in short time margins and to increase the productivity of the equipment, as it ensures timely adjustment of the technological equipment according to the received diagnostic signals.

Claims (2)

1. The method of measuring the motion parameters of long products, is that in the direction of movement of the product establish a basic and additional position sensors and measure the travel time of two successive points of the product the distance between them, distinguishing with the fact that, in order to expand the functionality , due to the provision of measuring linear strain, set in the direction of the product at a fixed distance, the second base and second additional sensors, positions, measure the time the passage of two successive points of the product, the distance between these sensors and the passage time of the distance bounded by two successive points of the product, the distance between the first and second basic position sensors. 2. A device for measuring the motion parameters of long products, containing three product position sensors and three shapers connected to them, a correlation speed measurement unit, the inputs of which are connected to the outputs of the first and second shapers, five key elements and five triggers, the output of each of which is connected to the first input of the corresponding key element, a clock generator, a computational unit with an indicator and two counters connected to the inputs of the computational unit, t then, it is equipped with a unit for extracting two successive points of the product, a fourth position sensor and a fourth former connected to it, a unit for identifying two successive points of the product, connected in series with the sixth trigger and. by the sixth key element, and four counters, the input of the unit for extracting two consecutively located product points is connected to the output of the first driver, the first output to the enabling input of the first counter and the first input of the recognition unit for two consecutive product points, the second output to the allowing input of the third counter and the second input of the recognition unit of two consecutive points of the product, the output of the first key element is connected to the enable input of the second counter, which prohibits the input m of the third counter and. the second input of the first trigger, the output of the second driver is connected to the second inputs of the first and second key elements, the output of the second key ele SU, 1030642 is connected to the inhibitory input of the first and second counters and the second input of the second trigger, the output of the third driver is connected to the second inputs of the third and fourth key elements, the output of the third key element is connected to the enable input of the fifth counter and the second input of the third trigger, the output of the fourth driver is connected to the second inputs of the fifth and sixth key elements, the output of the fourth key element is connected to the enable input of the fourth counter and the second input of the fourth key of the first element, the output of the cast key element is connected to the pre-input of the fifth counter, once the decisive input of the sixth counter and the second input of the fifth trigger, the output of the sixth key element is connected to the inhibit inputs of the fourth and sixth counters, the second input of the sixth trigger and the third block output allocation of two sequentially located points of the product, the first inputs of the triggers are connected to the corresponding outputs of the recognition unit of two consecutively located points of the product, the output of the clock generator and pulse is co-cenen with counting inputs of counters, the output of each of which is connected to the corresponding input of the computing unit.