WO2017054097A1 - Method and device for testing elongated textile test material - Google Patents

Abstract

The invention relates to a device (1) for testing elongated textile test material (9), containing a capacitive measuring unit (21) for carrying out a capacitive measurement on the textile testing material (9), a gravimetric measuring unit (3) for carrying out a gravimetric measurement on the textile test material (9), and an analysis unit (4) connected to the capacitive measuring unit (21) and the gravimetric measuring unit (3) in order to analyze measurement results. The analysis unit (4) is designed to computationally link a result of the capacitive measurement to a result of the gravimetric measurement. The computational link allows information to be given about the material composition of the textile test material (9).

Description

 METHOD AND DEVICE FOR TESTING LONG TERM

 TEXTILE TESTING

AREA OF EXPERTISE

The present invention is in the field of textile quality testing. It relates to a method and a device for testing elongated textile test material such as yarn, roving or sliver, according to the preamble of the corresponding independent claims. Moreover, the invention also relates to a compilation of textile data for a plurality of textile materials or material mixtures, according to the preamble of a further independent patent claim.

STATE OF THE ART

Devices for the capacitive examination of an elongate textile test material, such. As a yarn, a roving or sliver, are known. They contain a measuring gap through which the test material is moved in its longitudinal direction. The measuring gap is formed by two surfaces parallel to the test material and arranged on both sides of the test material, to which electrodes of a measuring capacitor are assigned. Due to measurements of the capacitance of the measuring capacitor statements about the in the

Condenser located Prüfgut be made. US-6,072,319 A discloses a capacitive device for measuring properties of a textile product in a measuring nip in which the textile product is introduced. The device comprises a measuring circuit and a compensation circuit. The latter can be used to compensate for disturbing influences such as moisture changes in the air in the measuring gap or unwanted mechanical changes in the measuring gap width. The measuring circuit includes a measuring capacitor whose planar electrodes form the measuring gap for receiving the test material, and leads to the electrodes. The compensation circuit includes an identically constructed one

Compensation capacitor and corresponding lines. A method and apparatus for determining levels of solids in a sample are disclosed in US 6,346,819 Bl. The test material is exposed to an electric field and dielectric properties of the field with the test material are determined. From the dielectric properties of two electrical variables are determined and combined, creating a characteristic value that is independent of the mass of the test material. The characteristic value is compared with a previously determined characteristic value for the substances concerned and from this the proportion of solid substances is determined.

To determine the yarn count or yarn count (gammasse per length or

Yarn length per mass) is measured a certain length of the yarn to be tested, separated from the rest of the yarn and weighed on a precision balance. The yarn mass is divided by the yarn length or vice versa. In the same way, the band number of a sliver or a roving can be determined. Garnprüfgeräte each with a capacitive measuring module and a module for

 Determination of the yarn count are described in the specifications DE-34'02'181 A I, US Pat. No. 5,025,660 A and WO 2004/063696 A2. According to each of these documents, results of measurements of the capacitive measuring module and the module for determining the yarn number are output individually and independently of each other.

PRESENTATION OF THE INVENTION

It is an object of the present invention to provide a further method and a further device with which a material composition of the elongated textile test material can be determined or at least a change in the material composition can be ascertained. Furthermore, a compilation of textile data for the

Use be provided in Erftndungsgemässen method. These and other objects are achieved by the method, composition and apparatus defined in the independent claims. Advantageous embodiments are given in the dependent claims. The invention proposes, in addition to the capacitive measurement to make a gravi metric measurement on the textile material to be tested and to link results of the two measurements computationally. In this document, the term "capacitive measurement" is understood as meaning a measurement of a capacitance of a measuring capacitor influenced by the test material. "Gravimetric measurement" in this document means a measurement of a mass of the test material by determining its weight. The method according to the invention is used to test elongate textile samples such as yarn, roving or sliver. A capacitive measurement and a gravimetric measurement are carried out on the textile test material. A result of the capacitive measurement and a

The result of the gravimetric measurement is computationally linked. The result of the capacitive measurement preferably relates to a first one

 Reference length and the result of the gravimetric measurement to a second reference length. The two reference lengths do not need to be the same.

In one embodiment, the computational link includes a

Quoticntenbildung. The quotient formation preferably consists of the formation of a quotient of the result of the capacitive measurement and the result of

gravimetric measurement.

In one embodiment, a result of the computational link is compared with a reference value. Because of the comparison of the result of the computational

Linking with the reference value is concluded on a material composition of the textile test material. The reference value can be formed from at least one previous measurement on at least one textile test object. The reference value is z. B. a

Mean value from earlier measurements on textile test items. From a significant deviation of the result of the computational linkage from the reference value it can be concluded that the textile test material has a different material composition than a reference test material to which the reference value relates. The invention also relates to a compilation of textile data for a plurality of textile materials or material mixtures. Any textile material or

Material mixture is associated with a reference value, which is a computational linkage of at least one result of a capacitive measurement and at least one result of a gravimetric measurement of the relevant textile material or material mixture.

The device according to the invention for testing elongated textile test material such as yarn, roving or sliver contains a capacitive measuring unit for carrying out a capacitive measurement on the textile test material, a gravimetric measuring unit for carrying out a gravimetric measurement on the textile test object and a device connected to the capacitive measuring unit and the gravimetric measuring unit Evaluation unit for the evaluation of measurement results. The evaluation unit is to be calculated

Linking a result of the capacitive measurement and a result of the gravimetric measurement set up.

In one embodiment, the evaluation unit is set up to form a quotient of the result of the capacitive measurement and the result of the gravimetric measurement.

TITLE OF DRAWINGS

Hereinafter, embodiments of the invention will be explained in detail with reference to the drawings.

 Figure 1 shows a Ausfühiungsform an inventive device.

 FIG. 2 shows in a bar chart results of gravimetric measurements on in each case five samples of three different types of belt.

FIG. 3 shows results of capacitive measurements in a bar chart

 the same 15 bands as Figure 2.

FIG. 4 shows, in a bar chart, quotients from the respective results of the capacitive and gravimetric measurements. FIG. 5 shows in a histogram a frequency distribution of quotients fictitious

Measurement results.

EMBODIMENT OF THE INVENTION

1 shows an embodiment of a device 1 according to the invention. It includes a yarn testing device 2, which is known from US Pat. No. 5,025,660 A, for measuring a yarn 9. The yarn testing device 2 can have various modules for measuring various properties of the yarn 9 include. At least one module 21 is a capacitive module which is adapted to be capacitive

Measurement on the yarn 9 make. In the capacitive measurement, an average dielectric constant of the materials in a measurement capacitor is determined, which is a measure of a mass and a material composition of the gambling section located in the measurement capacitor.

Furthermore, the device 1 includes a gravimetric measuring device 3, for example a

Precision balance, for a gravimetric measurement on the yarn 9. Preferably, after the capacitive measurement, a portion of the yarn 9 having a predetermined length in the yarn tester 2 is separated from the remainder of the yarn 9 and pneumatically required by a line 23 to the precision balance 3. The yarn section is placed on a weighing plate 31 of the precision balance 3 and weighed. From the weight and the length of the yarn section, the mass per unit length of the yarn 9, d. H. the yarn count, be calculated.

A result mc of the capacitive measurement and a result of never the gravimetric measurement are sent to a computer 4, e.g. B. a workstation, transmitted for evaluation. The evaluation includes a mathematical combination of the result mc of the capacitive measurement with the result mc of the gravimetric measurement. For comparability of the results, it is advantageous if each of the results mc, ITIG refers to a specific reference length of the yarn 9; the reference length for the result mc of the capacitive measurement but the reference length for the result mc of the gravimetric measurement can be different. The results mc, mc can be expressed in arbitrary units measured and indicated. Preferably, the computational link is a formation of the quotient mc / fflo. A result of the computational linkage may be on a connected to the computer 4 output unit, for. B. a screen 41, are issued to an operator.

Upon detection of a deviation of the quotient mc / mo from a reference value, an alarm may be issued, e.g. B. also on the screen 4L The reference value can be specified as a fixed value and / or calculated as an average value from previous measurements. The said fixed value can be determined as an average of several measurements and recorded in a table as described below.

The above description of an embodiment in which the textile test material is a yarn 9 is not intended to limit the generality of the present invention in any way. The invention also relates to other elongated textile test items such as tape or roving. Corresponding devices for the capacitive measurement of tapes or rovings are known. The evaluation need not be done in a stand-alone computer, but can be performed in a processor of the tester 2 or the gravimetric measuring device 3.

FIG. 2 shows, in a bar chart 200, results mo of gravimetric measurements on different bands. In each case, five equally long samples of three different types of belt were weighed and from the respective weight of the mass mc; the sample is determined. The mass ratio of polyester to cotton is 25:75 for the first belt type, 52:48 for the second belt type and 65:35 for the third belt type; the

Ratios are given below the figure 4 for the figures 2-4 together.

Variations in the measurement results within a band type were determined by

Caused band hum variations.

The column diagram 300 of Figure 3 shows results mc of capacitive measurements for the same bands as in Figure 2, in the same order. Again, variations in the measurement results within a band type are noted, which in turn are caused by band number variations. Finally, FIG. 4 shows a bar chart 400 with the quotients mc / mc; from the respective results of the capacitive measurements and the gravimetric measurements. A comparison with FIG. 3 illustrates two advantages of the mathematical combination of the results mc, mc. First, the variations within a band type are smaller, ie the signal-to-noise ratio is greater. Second, the three different types of bands are more clearly distinguishable.

The quotients mc / rnc and / or other mathematical combinations of at least one result mc of a capacitive measurement and at least one result ITIG of a gravimetric measurement can be used for various textile materials and textile

 Materi al likes i can be held as reference values in a table. A simple, emerged from the measurements according to Figures 2-4 table could, for. B. look like this:

By comparing a measured quotient mc / niG with reference values from such a table, in principle, the material composition and the

 Mass ratio of the measured textile 9 to be determined. Although such an absolute determination may not always be clear, reference values of certain materials or mixtures of materials are so close to each other that they are statistically indistinguishable. But even in such cases, the inventive method is of great benefit, because it at least on relative changes of

 Material composition indicates. Namely, if two samples have significantly different quotients mc / mc, they have different

Material compositions on. Thus, with the method according to the invention, errors in the spinning process, such as the above-mentioned permutation of input tapes, can be detected and corrected. A collection of reference values may also be present in a form other than a table, e.g. B. as plain text or as a graphic. The compilation can be electronic, z. B. as a database. FIG. 5 shows in the form of a histogram 500 a frequency distribution of quotients mc / mG of fictitious results of measurements on a multiplicity of textile test items. Also plotted are calculated from it

Probability density functions 501, 502. Obviously, the measured textile samples belong to two different types of samples or samples, which can be confirmed by statistical methods known per se. The expected values of the two probability density functions 501, 502 are designated in FIG. 5 by μι and μ ₂ , respectively. It could be z. B. μι = 1.49 and μ ₂ = 1.69. By comparison with reference values from a table described above, it can in principle be concluded from the material composition of the two samples: Probably the first type of sample is a polyester / cotton mixture with a mass ratio of 52:48 and the second type of sample a polyester / cotton Mixture with one

Mass ratio of 25:75. With certainty can be said that the two

Samples have different material compositions. Of course, the present invention is not limited to those discussed above

Embodiments limited. The formation of the quotient mc / mo is only one preferred example for the mathematical combination of the results of the capacitive measurement and the gravimetric measurement; other computational links are possible. With knowledge of the invention, the skilled person will be able to derive further variants, which also belong to the subject of the present invention.

Claims

1. A method for testing elongate textile test material (9) such as yarn, roving or sliver, wherein  a capacitive measurement and a gravimetric measurement are carried out on the textile test material (9),  characterized in that  a result (mc) of the capacitive measurement and a result (mo) of  gravimetric measurement are computationally linked together. The method of claim 1, wherein the result (mc) of the capacitive measurement relates to a first reference length and the result (mc) of the gravimetric measurement relates to a second reference length. 3. The method of claim 1 or 2, wherein the computational link a  Quotient formation includes. 4. The method according to claim 3, wherein the quotient formation consists of the formation of a quotient (mc / mG) from the result (mc) of the capacitive measurement and the result (mc) of the gravimetric measurement. 5. The method according to any one of the preceding claims, wherein a result of  computational link is compared with a reference value. 6. The method of claim 5. wherein due to the comparison of the result of the computational link with the reference value to a  Material composition of the textile test material (9) is closed. 7. The method of claim 5 or 6, wherein the reference value is formed from at least one previous measurement on at least one textile Prüfgut. 8. The method of claim 7, wherein the reference value is an average of previous measurements on textile samples. 9. The method according to any one of claims 5-8, wherein it is concluded from a significant deviation of the result of the computational link from the reference value that the textile test material (9) has a different material composition than a Referenzprüfgut, to which the reference value refers. 10. compilation of textile data for a plurality of textile materials or material mixtures,  characterized in that  a reference value is associated with each textile material or material mixture, which is a computational linkage of at least one result (mc) of a capacitive measurement and at least one result (niG) of a gravimetric measurement on the relevant textile material or material mixture. 1 1. Device (1) for testing elongated textile test material (9) such as yarn, roving or sliver, including  a capacitive measuring unit (21) for carrying out a capacitive measurement on the textile test material (9),  a gravimetric measuring unit (3) for carrying out a gravimetric measurement on the textile test material (9) and  an evaluation unit (4) connected to the capacitive measuring unit (21) and the gravimetric measuring unit (3) for the evaluation of measurement results,  characterized in that  the evaluation unit (4) is set up for computational linking of a result (mc) of the capacitive measurement and of a result (mc) of the gravimetric measurement. 12. Device (1) according to claim 1 1, wherein the evaluation unit (4) for forming a Quotient (mc / mc) from the result (mc) of the capacitive measurement and the result (ιησ) of the gravimetric measurement is set up.