CS246219B1 - A method for measuring surface density of fabrics and apparatus for carrying out the method - Google Patents

Abstract

The essence of the solution is that the total luminous flux passing through the illuminated textile and a width-adjustable rectangular measuring slit, located under the textile, is measured and evaluated, the width of which is set to an integral multiple of the mean yarn pitch of the measured textile system, or to the minimum fluctuation of the output signal of the areal density, which is found in the vicinity of a rough estimate of the mean yarn pitch. The device consists of an illuminating, sensing, evaluating and possibly recording part. Its essence is that the illuminating part is supplemented by an adjustable or replaceable measuring slit (C), located near the textile. The sensing part consists of a sensitive photoelement, the output of which is followed by an evaluating and recording part, containing a linear recording voltmeter (2) or an analog-to-digital converter connected to a microcomputer. The width of the measuring slot (C) is preferably equal to the thread pitch of the measured flat textile system. The solution can be used primarily to determine the extent of stripe pattern in textiles, to evaluate local defects in textiles and also to determine the average thread pitch in textiles.

Description

The invention relates to a method for measuring the surface density of textiles and to an apparatus for carrying out the method. A change in the areal density of textiles is manifested, for example, by stiffness. The surface density measurement method utilizes a combination of the optical method with subsequent photoelectric sensing and evaluation of the data obtained by passing the fabric at a uniformly adjustable speed across the direction of the light beams.

The variability in the fabric surface density, such as the stiffness, is caused by the varying fineness or the varying distribution of the two sets of yarns forming the fabric and by the variability of the angles of their interconnection. The variability of these parameters appears visually as a streak. The variation in surface density of the fabric can be periodic, random or local.

In textile production, the stiffness is determined on a viewing table under oblique illumination by a classifier. The subjective perception of the classifier is decisive for the classification of the fabric into the quality class.

Since there is no objective way of detecting the variability in fabric density, national and industry standards for test quality define this defect only superficially.

Since the stiffness is caused by the manufacturing machine or the entire manufacturing technology, an objective method of detecting surface density variability is needed to eliminate defects in the manufacturing machine and automate inspection work, such as inspection.

Optical methods have been used to measure surface density in the past. Two methods were used, which are described below.

The yarn-free interface is detected by the light passing through the fabric and the photon pulse thus obtained is used as the gating pulse of the pulse counter derived by the transmission from the movement of the fabric. The number of pulses between the gates is proportional to the width of the thread and the width of the gap. The apparatus utilizing this method has not proved to be due to the following shortcomings of the method: the hairiness of the staple yarns causes false gate pulses, so the measurement result is incorrect, the plain yarn fabrics on the contrary cause slippage in the feed mechanism.

According to a second method, the optical image of the surface of the fabric captured on the film taken in reflected monochromatic coherent light, essentially a hologram, is a Fourier image of the surface according to the coordinate. The transparency of the obtained film with the same light allows objective determination of fabric defects by a special procedure. The method requires laser technology and optical laboratory level.

The proposed method of the invention is based on an optical method. It is based on experimentally proven knowledge that the optical density and areal density of a fabric are proportional to the operating accuracy. The method of measuring the surface density consists in measuring and evaluating the total amount of light passing through the fabric moving at a uniform adjustable speed.

At the output of the measurement photoelement, an electrical signal is obtained which is proportional to the instantaneous areal density of the fabric. This signal is then recorded in the form of an analogue quantity or converted into digital form with further evaluation by statistical methods of spectral and correlation analysis.

The principle of measuring the areal density of textiles and the variation of the areal density, as well as determining the fabric density, is to illuminate the fabric with a total luminous flux passing through a width adjustable rectangular measuring slot and a modulated fabric moving above the rectangular measuring slot perpendicular to its longer dimension. is measured photoelectrically. In this case, the width of the rectangular measuring slot is set to an integral multiple of the mean yarn pitch of the measured fabric system, or to a minimum the variation in the area density output signal found around the rough estimate of the mean yarn pitch.

As the measuring slot includes a plurality of yarns of the second set along the length, the influence of their fineness varies and their pitch varies more and more and the proportion of variations in the density of the measured yarn set in the output signal increases relatively. In order to achieve the filtering effect of the measuring slot with respect to the nature of the measured defect, i.e. the streak, the slot width is adjustable.

The width of the measuring slot is therefore chosen, for example, as closely as possible to the median spacing of the threads of the fabric to be measured, so that the measuring slot acts as a narrowband filter. For example, if the fabric consists of yarns of the same fineness distributed at the same pitches, the component with the frequency of passage of the individual yarns above the measuring gap disappears completely. Variations in fabric density due to variability in thread fineness and pitch variation will result in significant variations in the output signal, increasing the sensitivity of the method. Moreover, removal of the component having the frequency of passage of the individual threads through the optical beam will make it possible to substantially reduce the sampling rate of the digital measurement, and thus, with the same memory capacity of the processor, to include a longer sample length.

On the other hand, if the width of the slot changes continuously, the drop in output signal variation to a minimum means that the width of the measuring slot is equal to an integer multiple of the mean pitch of the thread. Then, by finding a minimum variation in the output signal by continuously varying the slot width around the rough estimate of the thread pitch of the measured system, a setting was found where the width of the measuring slot is identical to the mean thread pitch, which allows direct determination of the set. Similarly, it is possible to suppress the component of surface density fluctuation caused by alternation of binding, pair-like goods etc. in the photoelement signal.

The apparatus for performing this method of measuring the fabric density, the variation of the fabric density, and the detection of the fabric fabric consist of a lighting, sensor, evaluation and possibly registration part. The illumination portion comprises a stabilized light source, behind which is located an optic consisting of a collimator and an optical filter. The essence of the solution is that the lighting part is supplemented with an adjustable or replaceable measuring slot located between the optical filter and the fabric to be measured, near the fabric. The sensor part then consists of a sensitive photodetector, to which the output is connected by the signal conditioning circuits and the evaluation and registration part comprising a line registration voltmeter or an analog-to-digital converter connected to a microcomputer. The length of the rectangular measuring slot is at least 20 times its width.

The fabric to be measured moves uniformly at a defined speed relative to the optical system. Movement of the fabric is ensured by a drive mechanism with adjustable speed. Then the luminous flux, and thus the electrical signal at the output of the photoelement, changes in proportion to the variation in the density of the thread system being measured. The frequency of the output signal fluctuation is proportional to the frequency of occurrence of the defect in the fabric and the speed of the feed of the fabric.

An exemplary embodiment of the device according to the invention is shown in the drawing, which represents a group diagram.

The device consists of lighting, sensor and registration. The illumination part consists of a halogen bulb Z powered by a stabilized DC power supply ST, an optic 0 and a replaceable optical filter F and an adjustable measuring slot C. The sensor part comprises a photomultiplier FN powered by a high voltage MV source via a switch S and a current to voltage converter. The registration part consists of a line registration voltmeter 2 with adjustable paper speed. The power supply Z is used to supply the electronic circuits of the device.

The steady luminous flux generated by the halogen lamp Z is concentrated by the optic O into a parallel beam and after passing through the optical filter F and the measuring slit C it falls perpendicular to the fabric. The part of the beams allocated by the measuring slot C impinges on the photocathode FK of the photomultiplier FN and generates a direct proportional anode current 2®. The current converter 2 is converted to a voltage of approximately 10 A to a voltage of 0 to 10 V. voltmeter 2 at the output or after digitization by analog-to-digital converter processed by microprocessor. If, for example, the fabric is perpendicular to the longitudinal axis of the slit in the space between the measurement slit C and the photocathode FK, the fabric density will modulate the light beam impinging on the FK photocathode and the registration voltmeter 2 records instantaneous values proportional it is possible to decide on the uniformity of the measured fabric.

The measuring slot has a width adjustable and measurable by means of a micrometer screw and is rectangular in shape. The luminous flux incident on the photoelement is given by the luminous intensity of the source, the area of the slit and the optical density of the fabric. The luminous intensity of the source and the area of the measuring slot remain constant during the measurement. The optical density of the fabric is given by the ratio of covered and free area. This ratio depends on the density of the fabric in the direction of both sets of yarns and the fineness of the yarns from which the fabric is made. During the measurement, the fabric is positioned so that the direction of the yarn assembly in which, for example, the stiffness is measured, is approximately equal to the longer side of the measuring slot. The length of the slot is such that it comprises a plurality of threads of the remaining second set of threads.

In the case of a nonwoven fabric that is formed by a random arrangement of textile fibers, the position of the measurement slit relative to the fabric defines the direction in which the surface density will be evaluated.

The following is an example of using the proposed fabric density measurement device to determine the range of fabric stiffness.

Example 1

It is required to determine the source of the periodic streakiness of the production machine, ie the condition. The procedure will be divided into several characteristic points.

A fabric sample having a width corresponding to the displacement device and a length large enough to contain a plurality of visible or predicted strips is clamped into the apparatus of the invention.

The dimension of the measuring slit in the direction of travel shall be selected or set equal to the nominal pitch A of the thread-forming yarn set or determined as a small integral multiple of n. The multiple shall not exceed the number of threads in the K-thread. only the approximate value and the slot width are changed by turning the micrometer screw until the output signal fluctuations with the passage frequency of the individual threads disappear. Then the micrometer reading exactly corresponds to the nominal A spacing.

The sensitivity of the photoelement, eg the photomultiplier, is adjusted according to the optical density of the fabric to be measured so that the signal variation as the fabric moves at a speed v optimally utilizes the measuring range of the instrument.

The electrical signal x (t) from the photoelement is recorded by a recording voltmeter, optionally using an analog-to-digital converter, and a time pulse generator of a period t, generating a set of time-equivalent optical density fx (t) 1 samples and stored in computer memory or other recording medium.

The data set is subjected to computer processing and the mean value, X, optical density scattering D and spectral power density Gxx (f) are evaluated.

If the fabric sample was measured at velocities v, then the distinct spectral power density lines Gxx (f) at the frequencies, ^ 2 ' ^and t ^< ^ · of the amplitudes G ^, (^, etc.) indicate the existence of streaks in the fabric with period

Ί A. f, ^N2A . F.

etc. with threads with a proportional proportion Vg ^, yt ₂ , etc.

If the measurement slot dimension A is set improperly, a line appears at a frequency equal to v in the spectrum

which corresponds to the basic pitch of the thread and is therefore not a fabric defect. Also, the spectral line at the frequency v is not a defect

corresponding to the duty cycle.

Similarly, it is possible to evaluate the streaks from the direct graphical record made at the recording speed v. Then the distance L between the peaks of the record corresponds to a period stream

N

of threads. However, in the case of two or more banding sources, the evaluation is difficult.

Example 2

The example describes the evaluation of the local lane pattern, eg lanes after stopping and restarting.

The fabric sample should be inserted into the feed mechanism as carefully as possible with wefts parallel to the longer dimension of the measuring slot. The width of the measuring slot must be precisely adjusted to the weft pitch value at steady weaving, when the output signal fluctuation drops to a minimum. The sensitivity of the photoelements, eg photomultipliers, is adjusted according to the optical density of the fabric to be measured so that the signal variation as the fabric moves at a given speed optimally utilizes the measuring range of the apparatus. The pattern density of the fabric will record in detail the dilution in the stream and the subsequent weft pitch equalization to a steady weaving value. Recording lengths are transformed into number of tags by ratio

Claims (2)

1. A method of measuring the basis density of fabrics and changes in the basis density of streaks, and a method of detecting an arrangement based on an electrical measurement of the luminous flux passing through a moving fabric, characterized in that the fabric is illuminated by light whose total luminous flux defined by a width adjustable rectangular the measuring slit and the modulated fabric moving above the rectangular measuring slit perpendicular to its longer dimension is photoelectrically measured and the width of the rectangular measuring slit is set to an integral multiple of the median thread pitch of the measured fabric system, possibly minimizing fluctuations in surface area output signal found rough estimate of the mean pitch of the threads. 2. Apparatus for carrying out the method according to claim 1, comprising a lighting, sensor, evaluation and, optionally, a registration part, the lighting part comprising a stabilized light source, followed by an optic consisting of a collimator and an optical filter, characterized in that the lighting part is provided with a width-adjustable or replaceable rectangular measuring slot (C) located near the fabric, and the sensor portion being a sensitive photodetector, the output of which is connected to an evaluation and registration portion, comprising a line registration voltmeter (2) or an analog-to-digital converter connected to a microcomputer.