CZ2014555A3 - Classification method of bobbins according to rigidity of yarn package and apparatus for determining yarn package air-permeability - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a method for sorting yarn spools according to the rigidity of a yarn winding (41) embedded in a dyeing tube (42). The coils (4) are classified into groups according to the winding permeability (41). The invention also relates to a device for detecting the breathability of a yarn winding (41) which is supported on a tube (42) provided with a plurality of through-radial openings (421), the ends (43, 44) of the tube (42) being closed and the inner space of the tube (42 ) is connected to a source (1) of compressed air, wherein a flow meter (2) is included in the supply line to the inner space of the tube (42) and a pressure gauge (3) is connected to the outlet line of the compressed air source (1).

Description

Method for sorting spools according to yarn winding stiffness and device for determining the breathability of yarn winding

Field of technology

Method for sorting bobbins according to the stiffness of a yarn package deposited on a dyeing tube.

Device for detecting the breathability of a yarn roll, which is mounted on a hollow provided with a number of through-going radial holes.

Prior art

The dyeing of yarns and similar linear textile structures is usually performed on a wound spool by extruding a liquid dye through a layer of yarn.

The dyeing device comprises a container connected to the supply of liquid dye from the storage tank and to the discharge of the dye back to the tank. In the container, wound coils are mounted on mandrels 15 formed by perforated tubes, closed on one face, and the inlets to these perforated tubes are connected to the dye supply. The bobbin cores are also perforated, so that the pressurized dye enters the volume of the yarn winding under the cylindrical surface of the bobbin and, after passing through the winding, returns from the container back to the storage tank. Such a device 20 is known, for example, from US 5351351.

The goal of the yarn winding dyeing process is to achieve an even dyeing of all the wound yarn for all the spools of the whole dyed batch. Since the individual windings of yarn may have different stiffnesses, for example due to uneven tightening of the yarn during winding, the yarn 25 may be dyed unevenly. This, of course, also has an adverse effect on the final appearance of the textile product, i.e. knitwear, fabrics and the like, made from such yarns.

Several methods are known from the prior art for determining the stiffness of a coil. Known solutions are based, for example, on measuring the resistance 30 against deformation of a coil. This is done by measuring the resistance force against the penetration of the needle into the winding layer, or against the rotation of the flat needle inserted into the winding layer. Other solutions use the measurement of the reflection of a test weight incident on the surface of the coil.

PS3976CZ

However, such measurements do not assess the coil as a whole. The coil is evaluated only in points, so the result of the evaluation is, in addition to the objective error of the measuring device given by production deviations and its wear, also influenced by subjective error resulting from the method of measurement, which is limited by the capabilities of the device used. The accuracy of the measurement is given by the number of point measurements performed on a specific coil. The precondition for the applicability of the results is a relatively long time for the measurement itself and for its statistical evaluation, as it is known that the variances in the obtained set of measured values are considerable.

The object of the invention is to reduce the time required to determine the stiffness of the yarn winding and to substantially increase the veracity of the evaluation of the measured results.

The essence of the invention

The object of the invention is achieved by a method of sorting spools according to the stiffness of a yarn spool deposited on a dyeing tube, the essence of which is that the spools are sorted into groups according to the breathability of the spool. This criterion is very close to the actual process of dyeing the coils.

Breathability is determined by measuring the pressure drop across the coil layer at a specified constant air flow, or breathability is determined by measuring the air flow through the coil layer at a specified constant air pressure drop across the coil layer. From the point of view of the test result, both methods are practically equivalent and their choice is governed by the availability of test means and / or possible peculiarities of dyed coils, dyes, or the frequency of tests.

To determine the pressure drop across the coil layer, the overpressure of the air supplied to the interior of the closed-face tube is measured against the atmospheric pressure in the surroundings. This also achieves the direction of the pressure drop, which corresponds to the passage of the paint through the coil during practical dyeing.

The object of the invention is also achieved by a device for detecting the breathability of a yarn spool which is mounted on a sleeve provided with a number of through radial holes, the essence of which is that the faces of the sleeve are closed and the inner space of the sleeve is connected to a source of compressed air.

PS3976CZ A flow meter is connected to the inner space of the sleeve and a pressure gauge is connected to the outlet pipe of the compressed air source.

The advantages of the solution according to the invention are the relative simplicity of its implementation, the achievement of repeatable results, the availability of means 5 forming test equipment and the possibility to archive measured values in order to trace back the cause of the changed stiffness of the coil resp. coloring.

Explanation of drawings

The device for measuring the yarn winding stiffness according to the invention is schematically shown in the drawing, where Fig. 1 is a block diagram of a pneumatic circuit, Fig. 2 shows the interdependence of air flow (Q) through the winding (y-axis) and air pressure drop (P). in the measured coil (x-axis) and in Fig. 3 the course of the jets in a longitudinal section through the volume of the coil.

¹⁵ Examples of embodiments of the invention

The device for determining the breathability of a yarn package according to the invention uses a principle which physically corresponds to the method of dyeing the yarn carried out during its production.

The breathability of the winding is due to its stiffness, which is the result of tightening 20 individual wraps when winding the spool. During dyeing, the dyeing liquid is forced through the winding layer in order to achieve an even dyeing of the yarn. The stiffness of the coil and thus its breathability is therefore performed by extruding the fluid analogously to the dyeing process itself. For practical reasons, which are mainly the cost of the equipment, the laboriousness of measuring and maintaining the winding of the yarn in a dry state, the test fluid is a gas, preferably air.

The breathable yarn winding 41 resists the air passage by a pressure drop P, i.e. the difference between the pressure before the air enters the winding layer 41 and the air pressure behind the winding layer 41. The pressure drop P increases with the stiffness of the winding 41 and the flow rate Q of extruded air. For the same dimensions of the yarn winding 41, which are its length, its outer diameter and the outer diameter of the sleeve 42, the breathability of the winding 41 is a fundamental parameter that characterizes the stiffness of the winding 41. 'PS3976EN average breathability of the individual tested coils 41, not the absolute value of breathability and the material will not be damaged in any way.

An exemplary embodiment of the device according to the invention is shown in FIG. 1. A source 1 of compressed air 5 with a flow meter 2 arranged preferably in the outlet branch of the source 1 of compressed air is used to determine the air permeability. To this branch, behind the flow meter 2, a pressure gauge 3 is connected. The spool 41 is mounted on a sleeve 42, which is provided with a plurality of evenly distributed radial through-holes 421 for dyeing the yarn along its length. At one end 43, the sleeve 42 is closed for measuring purposes. In the second face 44 there is a compressed air supply inlet 45 for measurement purposes.

Since the outer surface of the coil is in contact with the surrounding atmosphere, the value of the pressure drop P on the coil layer 41 is practically identical to the inlet pressure Po of the supplied air.

In a first alternative of the device according to the invention, the compressed air source 1 is provided with means for adjusting the flow rate Q of the supplied air. The source 1 of compressed air can also be a low-pressure blower, or an outlet from a central compressed air distribution system (not shown) with a flow control means can be used. If a separate compressed air source 1 is used, the flow meter can be included in its suction, but this usually has a negative effect on the suction conditions of the compressed air source 1.

In the second alternative, the compressed air source 1 supplies a constant amount of air, or the compressed air source 1 is coupled to a known pressure regulator (not shown) that is not sufficiently accurate.

Fig. 2 shows a graph of the interdependence of the air flow Q in m ³ / h through the coil layer 41 and the pressure drop P in kPa.

In the first alternative, the determination of the stiffness of the yarn windings 41 is performed by measuring the air flow Q through the flow meter 2 at the selected constant pressure drop.

P1 on the coil layer measured by the pressure gauge 3. For one coil 4 the selected pressure drop P1 is reached after setting the source 1 to the flow Q 1, for another coil 4 the same pressure drop P 1 is reached after setting the source 1 to the flow O 1. The higher flow Q1 characterizes the soft coil 41, the lower flow Q2 characterizes the hard coil 41.

PS3976CZ

In the second alternative, the determination of the stiffness of the yarn windings 41 is performed by measuring the pressure drop P with the pressure gauge 3 at a set constant air flow Qi verified by the flow meter 2.

From the values of the pressure drop P measured for different flow rates Q, whole curves of the interdependence of the pressure drop P and the flow cross section Q can be constructed for laboratory use. The curve K2 below characterizes a stiffer coil 41 than the curve K2 above.

The handling of the coils, the closing of the cavities 42 with a sealing plug on the face 43 and a plug with a compressed air supply on the face 44, can be easily automated. With the help of suitable transducers, it is also possible to archive the measured values of the pressure drop P and the air flow rate Q in order to trace back the cause of the changed stiffness of the coil resp. coloring.

It is obvious that with the usual arrangement of the winding on the spool, a uniform field of jets of flowing fluid cannot be assumed. Especially in the areas on the small radius of both faces of the coil 411, there is a short-circuit flow from the sleeve towards the front intermediate rings of the coil.

For research and development purposes, it is possible to determine the uniformity of the flow through the coil layer 41 by means of numerical simulation, to determine the locations of the short-circuit air flow 20 and, if necessary, to propose modifications to reduce the non-uniformity of the coil flow.

Based on the confrontation of the results obtained by the method of numerical simulation with the known operating process, it is possible to propose the use of cover plates of overlapping the faces of the individual coils. This restricts the flow of dye from the radial 25 holes 421 directly into the face of the coil 411, especially through its portion immediately adjacent to the surface of the sleeve 42, increasing the flow of dye towards the "corners ¹ " . A similar positive effect on the uniformity of this coloring of these parts of the winding is also the small distance between the faces of the adjacent spools, which are folded practically on top of each other in the dyeing device 30 in the axial direction.

The result of the numerical simulation is also the finding that even coils with the same average breathability determined by the described method have different flow intensities in different places of the winding volume, ie face, circumference or transition from face to circumference, ie theoretically different local coloration. This shortcoming is

PS3976CZ can be effectively reduced during the dyeing process by alternating the flow directions of the dye into the mass of the coil from the tube to the circumference and vice versa. It is obvious that a certain minimum dyeing time must also be observed for dyeing the whole volume, so that all places in the coil have the possibility to saturate with the dye. If 5 spools of one color batch are sorted into groups given by a certain range of breathability, the dyeing time of a group of stiffer spools will be longer than the dyeing time of a group of softer spools.

PS3976CZ

List of reference marks compressed air source flow meter pressure gauge spool (with yarn winding) yarn winding

411 coil face

421 through holes in the cavity

422 transition (from the front of the coil to the cylindrical surface of the coil - "corner") front of the sleeve (blind)

431 jet (in the area of the blind face of the tube) face of the tube (with air supply)

441 jet (in the area of the face of the air supply tube) air inlet opening

K1 curve of pressure dependence on the flow of a less rigid coil

K2 curve of pressure dependence on the flow of a stiffer coil

P pressure drop on the coil layer

After air overpressure before entering the cavity (against the atmospheric pressure of the surroundings)

Pi air pressure drop (= air pressure in the inlet to the sleeve - specific - for a softer coil)

P ₂ air pressure drop (= air pressure in the inlet to the sleeve - specific - for stiffer winding)

Q air flow

Qi air flow (specific - for a softer coil)

Q ₂ air flow (specific - for stiffer winding)

Claims (5)

PATENT CLAIMS A method of sorting bobbins (4) according to the stiffness of a yarn package (4T) deposited on a dyeing tube (42), characterized in that the bobbins (4) are sorted into groups according to the breathability of the package (41). Method according to claim 1, characterized in that the breathability is determined by measuring the pressure drop (P) on the winding layer (41) at a determined constant air flow (Q). Method according to claim 1, characterized in that the breathability is determined by measuring the air flow (Q) through the winding layer (41) at a determined constant air pressure drop (P) on the winding layer. Method according to claim 2 or 3, characterized in that, in order to detect the pressure drop (P) on the winding layer (41), the overpressure (P _o ) of the air supplied to the interior of the closed-end sleeve (42, 44) is measured. ) against ambient atmospheric pressure. A device for detecting the breathability of a yarn winding (41), which is mounted on a sleeve (42) provided with a plurality of through-holes (421), characterized in that the faces (43, 44) of the sleeve (42) are closed and (42) is connected to a source (1) of compressed air, wherein a flowmeter (2) is connected in the inlet line to the inner space of the sleeve (42) and a pressure gauge (3) is connected to the outlet line of the source (1).