EP0037926A2 - Method and apparatus for making textured endless yarns - Google Patents

Abstract

Process and apparatus for producing textured continuous filament yarns from synthetic linear high molecular weight substances by means of heated flowing media wherein the filaments are exposed within a first treatment chamber between a yarn introduction zone and a yarn guide zone to the action of a gaseous heated medium in turbulent flow to heat them to a temperature at which the filaments become plastic, transported by means of the turbulent medium through the first treatment zone and then within a second treatment zone passed first through a cylindrical zone from which some of the medium can radially escape and then guided through a slightly conically widening zone from which the medium can likewise escape sideways, with the proviso that the speed of the flowing medium and of the yarn is set in such a way as to produce a ratio of the residence time of the yarn in the cylindrical zone to the residence time in the conically widened zone of from 1:19 to 4:1, preferably from 1:9 to 1:2. <IMAGE>

Description

The patent literature on devices for the production of textured threads using hot fluids or using the air-blowing method is very extensive. A large group of the known devices comprises two-chamber nozzles: the yarn to be textured is conveyed into a first chamber by means of a venturi-like nozzle, while the texturing is effected in the second chamber, which is generally cylindrical, sometimes also conical . For example, according to DE-AS 14 35 653, the second chamber of such a texturing device from a "crimping chamber" which has a constant, tubular cross-section over its entire length and is designed as a spiral spring.

A similar embodiment of a texturing device with a second cylindrical chamber is described in CH-PS 545 359.

Further embodiments of texturing devices of the prior art are known from DE-OS 14 35 366 and DE-OS 21 11 163. The chamber 5 specified in DE-OS 21 11 163 has openings which are formed by lamellae 6.

From DE-AS 20 06 022 a device for the production of textured threads from synthetic linear high-molecular substances by means of heated flowing media is known, which consists of a closed first treatment chamber with a pipe socket for the supply of a flowing medium, a thread introduction channel, one of which Face in the first treatment chamber, a thread guide channel that protrudes from the other end into the first treatment chamber, this thread guide channel being rigidly connected to the treatment chamber and the ratio of the inside width of thread guide channel to thread introduction channel being 1.1: 1 to 4: 1 and thread guide channel and thread introduction channel in a distance of 0.1 to 3 mm are arranged, and a second channel-shaped treatment chamber with slots, which is attached to the free end of the thread guide channel. In this known device, the openings of the second treatment chamber consist of slots which are made radially and in the longitudinal direction of the cylindrical nozzle. Such a treatment chamber is therefore also called a slot nozzle. Slot nozzles generally have 2 to 20 slots, the number of which can be increased depending on the titer and nozzle circumference. The slot widths are usually 0.2 to 1 mm. The CH-PS 530 489 describes a second treatment chamber, which is weakly conical in the thread running direction over its entire effective length.

The second treatment chambers according to DE-AS 20 06 022 or CH-PS 530 489 are relatively sensitive with regard to their dimensional accuracy. In DE-AS.23 31 045, a modified second treatment chamber was therefore described, corresponding to the device in DT-AS 20 06 022, which in its lower part expands conically or step-wise on the outside and a sudden cross-sectional widening to the 2- to Has 10 times the tubular channel, the longitudinal slots also extending into the optionally conically enlarged area, but at the end are closed by a closed ring.

"By modifying the slot nozzle as a second treatment chamber according to DE-AS 23 31 045, its mechanical stability is improved, so that a more uniform crimp is possible under simplified operating conditions.

The second treatment chamber according to DA-PS 20 06 022 or DE-AS 23 31 045, as well as other known devices, show at very high texturing speeds, i.e. . above 2000 m / min a certain tendency to blockage due to the dynamic compression of yarn in the cylindrical interior. This blockage is triggered by the increased friction of the yarn compression on the inner walls of the second treatment chamber at very high texturing speeds; it can lead to yarn breaks and interrupt the texturing process.

On the other hand, a second treatment chamber which widens slightly conically over its entire effective length, e.g. according to CH-PS 530 489 at high working speeds and low yarn count, less than approx. 2000 dtex, often for "blowing out" the yarn compression and thus also for interrupting the texturing process.

It has now been found that textured threads made of synthetic linear high-molecular substances can be produced at high speed and with high reliability by means of a gaseous, heated flowing medium according to a method in which the threads are placed between a thread insertion zone and a thread guide zone in a first treatment zone of the Exposure to the gaseous, turbulent flowing heated medium exposes, heated to a temperature at which the threads can be plasticized, by means of the turbulent flowing medium is transported through the first treatment zone and then in a second treatment zone from which a part of the medium can escape radially to the action of the medium remaining in the second treatment chamber and the inflowing ambient air, whereby thread and flowing medium in the second Treatment zone first passes through a cylindrical zone from which the medium can partially escape radially, and then leads through a weakly conically widening zone from which the medium can also escape laterally, with the proviso that the speeds of the flowing medium and thread are set so that a ratio of the dwell time of the thread in the cylindrical zone to the dwell time in the conically widening zone is between 1:19 and 4: 1, preferably between 1: 9 and 1: 2.

The method can be carried out, for example, with a device as shown schematically in FIGS. 1 and 3. This device for producing textured threads from synthetic linear high-molecular substances by means of heated flowing media consists of a thread introduction channel 1, a treatment chamber 2, a pipe socket 3 for supplying the flowing medium, a thread guide channel 4 which connects the treatment chamber 2 to a tubular treatment chamber 5, which is provided with openings 6 through which the flowing medium can escape laterally, the treatment chamber 5 in the range from 1/20 to 4/5, preferably from 1/10 to 1/3 of its length, calculated from the end of the thread guide channel 4, is cylindrical in shape and then widens conically in the thread running direction, the pitch ratio of the conical enlargement being 1: 5 to 1: 150, preferably 1:20 to 1:70. .

"Adherence to the process parameter of the relation between the residence time in the cylindrical zone and in the conically widening zone is essential for trouble-free texturing at high speeds, e.g. the yarn breaks caused by excessive friction are less common.

The dwell time is primarily dependent on the length, the aspect ratio of the cylindrical part and the conically widening part, but also on the slope in the conically widening part. Both device parameters have an influence on the process parameters residence time or residence time ratio, since they determine the friction of the thread in the device. Other influencing variables are total and individual titer of the threads, differences in the type of polymer, differences in the cross-sectional shape of the threads and finally the texturing speed itself.

In the present context, the term threads is understood to mean continuous monofilaments or bundles of endless monofilaments, tapes, flat threads or splice threads made of foils and foil strips. The titer of the individual threads can be, for example, between 1 and 35 dtex; preference is given to using single threads whose titer is between 10 and 30 dtex. The number of individual threads in the bundle can be between 2 and a few thousand. Thread bundles which have 50 to 250 individual continuous threads are preferably used. Thread bundles with a total texture titer of 500 to 5000 dtex are preferably used. The threads in the bundles of threads or yarns can be fed to the crimping treatment both drawn and partially drawn. It is also possible to use threads with a round or profiled, for example trilobal, cross section. ⁱ

The synthetic linear or practically linear thread-forming organic high-molecular substances for the production of the threads are, in particular, customary linear synthetic high-molecular polyamides with carbonamide groups recurring in the main chain, linear synthetic high-molecular polyesters with recurring ester groups in the main chain, thread-forming olefin polymers, thread-forming polyacrylonitrile units or predominantly containing polyacrylonitrile units thread-forming acrylonitrile copolymers and cellulose derivatives, and also cellulose esters. Suitable high-molecular compounds are, for example, nylon 6, nylon 66, polyethylene terephthalate, linear polyethylene or isotactic polypropylene.

Suitable gaseous, flowing media are those which are customarily used in blast texturing processes, for example nitrogen, carbon dioxide, water vapor and, in particular for economic reasons, air.

The required temperatures of the flowing medium can be within wide limits. The temperature range from 100 to 400 ° C has proven to be particularly useful. In particular, the most favorable temperature conditions depend on the melting or plasticizing temperatures of the thread-forming materials, on the time during which the gas quantities can act on the threads, on any preheating and finally on the thickness of the threads. Naturally one cannot use a temperature which leads to a melting of the threads under the conditions used, although the temperature itself can be above the melting or the decomposition points of the thread-forming materials used, provided that the threads run at a correspondingly high speed, ie smaller Dwell time through the treatment zone i be performed. The higher the texturing speed, the higher the temperature of the texturing medium can be above the melting or decomposition point of the thread-forming material used. The plasticizing ranges are, for example, for linear polyethylene at 80 to 90 ° C, for polypropylene at 80 to 120 ° C, for nylon 6 at 162 to 190 ° C, for nylon 66 at 210 to 240 ° C, for polyethylene terephthalate at 190 to 230 ° C and for polyacrylonitrile at 215 to 245 ° C.

The type of polymer has an influence insofar as the favorable plasticizing temperatures are different and the ratio of the temperature of the flowing medium to the filament temperature is involved: the higher the temperature of the flowing medium, the higher the speed. The cross-sectional shape of the individual threads is important insofar as it contributes to how far the thread heats up on its way through the nozzle and is thus accessible to plasticization.

The setting of the desired ratio of the residence times results from the length ratio between the cylindrical and the conically widening zone, but also from the slope in the conically widening part, because the friction is then determined depending on the total or individual titer of the threads. For example, for a texturing speed of 2000 m / min and higher and a stretch titer of the yarn of 1200 f 67 dtex, a residence time ratio between cylindrical and conically widening zone of 2: 5 with a pitch ratio in the conically widening zone of 1/30 for one undisturbed texturing is an advantage. If the ratio between the cylindrical and the conically widening zone is chosen to be smaller, it can be used to blow out the yarn compression from J come to the second treatment chamber and the texturing process is interrupted. Conversely, in the case of a ratio greater than 2: 5 in the example above, blockage can occur due to excessive yarn friction on the chamber walls, the process also being interrupted.

Due to the conical widening in the end part of the nozzle as seen in the thread running direction, flow conditions other than in the cylindrical part arise due to the wall friction of the thread bundle. This leads to the fact that depending on the yarn titer, yarn cross section, texturing speed as well as temperature conditions and pitch ratio of the conical extension, the yarn compression is more or less compact. In this process, yarn compression occurs within the second treatment zone, which results in part of the outlet openings for the gaseous medium being covered, so that the pressure rises and the yarn compression is lifted out of the second treatment zone until the openings for the lateral one Exit are exposed so far that the pressure is no longer sufficient to promote the yarn compression through the second treatment zone. Part of the medium always escapes laterally and another (smaller) part remains in the second treatment zone during yarn compression. No special measures are required to determine these proportions, they set themselves up under the given conditions. All parameters that lead to a stronger yarn compression, such as high yarn denier, round yarn cross section, high texturing speed, high temperature and low pitch ratio, cause the texturing medium to emerge to an increased extent laterally between the lamellae of the second texturing chamber. At the same time, the component of the texturing-J which effects the yarn feed takes off mediums in the axial direction. Under extreme conditions, it can happen that the axial component of the texturing medium is no longer sufficient for the continuous conveying of the yarn compression, the axial conveying comes to a standstill and thus a blockage of the second chamber, associated with an interruption of the texturing process, occurs. On the other hand, for lower temperatures, low yarn titer, trilobal cross-section and high pitch ratio of the conical extension, the component of the texturing medium in the axial direction of the second chamber can become so large that the wall friction of the yarn compression is no longer sufficient to maintain the dynamic balance. At this other extreme, the yarn compression is virtually blown out of the second chamber and the texturing is also interrupted. It is therefore crucial for the texturing process according to the invention, with suitable friction and flow conditions having to be maintained in the second treatment chamber under the given boundary conditions, that the specified ratio of the residence time of the yarn in the cylindrical or conically widening zone of the second treatment chamber is selected .

Suitable devices are shown schematically in FIGS. 1 to 4. Figure 1 shows a longitudinal section through a texturing device with a second treatment chamber with a cylindrical and conically widening interior.

Figure 2 shows an enlarged section A-A 'of the second treatment chamber shown in Figure 1.

FIG. 3 shows the sectional view of a texturing device with a modified shape of the second treatment chamber. L

FIG. 4 shows an enlarged section B-B 'of the modified form of the second treatment chamber shown schematically in FIG. 3.

FIG. 1 schematically shows a complete texturing device with the second treatment chamber 5, which is essential for the device. The treatment chamber 2 with thread introduction channel 1 for the thread 7 and thread guide channel 4 corresponds to the construction known from DE-AS 20 06 022. It consists of a cylindrical tube. The thread introduction channel 1 for feeding the threads 7 into the treatment chamber 2 and the thread guide channel 4 are screwed into this tube or fastened in another way. The thread guide channel has a centering body 8 on the side facing the thread introduction channel 1, which is provided with rectifying air channels 9 and has a bushing 10 with an external thread on the other side. The nozzle 3 serves to supply the flowing medium, for example air. The treatment chamber 5 is arranged at the free end of the thread guide channel 4 protruding from the treatment chamber 2. This consists of an externally cylindrical slot nozzle which is pushed coaxially onto the thread guide channel 4 and can be fixed thereon by means of a locking screw 11. The slot nozzle is provided at the end protruding beyond the thread guide channel 4 with slots 6 penetrating the tube wall in the radial direction. The distance between the end of the thread guide channel 4 and the beginning of the slots 6 in the interior is 0.1 to 3 times, preferably 0.8 to 1.4 times the outer diameter of the thread guide channel 4. The texturing effect increases with the number of slots 4 18 to 18 have been found to be convenient, generally 10 to 16 are used. The slot width is expediently 0.3 to 1, preferably 0.4 to 0.6 mm.

To be able to vary the length of the slots 6. a cylindrical metal element 12 can be pushed over the second treatment chamber and fixed by means of a screw 13. This displaceable metal element 12 can also be designed as a mouth protector. The feature of the second treatment chamber, which is essential to the invention, is that its interior has a cylindrical shape in the area D to D _o and widens conically in the area D _o to D ₁ . The length ratio between the cylindrical and the conically widening part is 1:19 to 4: 1, preferably 1: 9 to 1: 2 (in other words, the cylindrical part comprises 1/20 to 4/5, preferably 1/10 to 1 / 3 the length (calculated from the end of the thread guide channel).

FIG. 2 shows the internal shape of the second treatment chamber, which is essential to the invention, on an enlarged scale. The designations correspond to those in FIG. 1.

In FIG. 3, the same designations apply as in FIG. 1 in the upper part of the modified texturing device. That means: thread 7, thread introduction channel 1, treatment chamber 2, thread guide channel 4, centering body 8, air channels 9, feed connector 3, bushing 10, screw 11 and slots 6 correspond. The second treatment chamber widens conically on the outside or in sections. The length of the inner cylindrical part before the conical extension extends to about 1/20 to 4/5 of the entire length, in particular 1/10 to 1/3. The overall length is generally about

at 80 to 150 mm, so that the maximum length of the cylindrical part is 120 mm (for a total length of 150 mm), preferably about 50 mm (for an overall length of 150 mm).

The slots are also guided radially outwards in the part of the second treatment chamber which is conically or partially expanded. Inside, the cross section of the channel running through the second treatment chamber can suddenly expand 2 to 10 times, preferably 2 to 5 times, at a point where the full outer diameter is reached. The slots are then led radially through the enlarged part of the cylinder, parallel to the longitudinal axis of the cylinder, over a length which corresponds approximately to the current inner diameter. The cylindrical part with the larger diameter can be closed off by a solid ring 14. In order to be able to vary the length of the slots, it is advantageous to push a cylindrical metal element 12 over the second treatment chamber, which can be fixed with suitable means, for example the screw 13.

FIG. 4 shows the internal shape of the modified second treatment chamber from FIG. 3, which is essential to the invention, on an enlarged scale.

The interior of the second treatment chamber has a cylindrical shape in the range from D to D in all the embodiments according to FIG. 1 to FIG. 4. D _o indicates the point in the second treatment chamber at which the thread guide channel 4 ends. The length of the cylindrical part of the second treatment chamber D to D _o can be 1/20 to o 4/5, preferably 1/10 to 1/3, the length of the second treatment chamber, calculated from the end of the thread guide channel.

For a second treatment chamber with a total length of, for example, 100 mm, into which the thread guide channel projects 30 mm (ie with an effective length of 70 mm), the length of the cylindrical part can be from 3.5 to 56 mm. For texturing speeds of 2000 m / min and higher and with high total stretch titers, for example in the range of 1200 - 3500 dtex, blockages and thus breaks can occur due to the increased friction of the yarn compression with a fully cylindrical inner bore in the slot nozzle. This disturbance is eliminated by reducing the length of the cylindrical inner part of the second treatment chamber to 1/20 to 4/5, preferably 1/10 to 1/3, of the effective length of the second treatment chamber in combination with a subsequent conical expansion. The higher the yarn titer, the shorter the cylindrical inner part of the second treatment chamber should be selected, e.g. B. We recommend a cylindrical part of 3.5 mm with a total length of the second treatment chamber of 100 mm for a yarn stretching titer of approx. 3000 dtex and higher at a texturing speed of 2000 m / min. For a yarn stretch titer of 800 dtex, on the other hand, a length of the cylindrical part of the second treatment chamber of approximately 23 mm is advantageous, which corresponds to a length of 1/3 of the cylindrical part of the second treatment chamber, based on its effective length of 70 mm. The length of the cylindrical part of the second treatment chamber depends within certain limits on the slope ratio of the subsequent conical widening under otherwise identical process conditions. In this context, the pitch ratio of the conical extension means the ratio d ₂ - d ₁ / h, where d ₂ = large diameter of the truncated cone, d ₁ = small diameter of the truncated cone and h = height of the truncated cone. With a slope ratio of 1/50, for example, with a J Height of the truncated cone of 50 mm d ₂ - d ₁ = 1 mm. If this example is transferred to FIGS. 1 to 4, it follows that in the case of an inner diameter of the second treatment chamber in the cylindrical part (area D - D _{o '} ) o of, for example, 3 mm with a pitch ratio of 1/50 the final diameter of the conical extension Is 3.8 mm if the conical extension (D, - D ₁ ) is 40 mm long.

If the pitch ratio increases, for example from 1/50 to 1/40, the cylindrical part in _. Limits are extended or vice versa. In general, a slope ratio of the conical extension in the range from 1/5 to 1/150, preferably 1/20 to 1/70, has proven successful. For smaller yarn counts, below 1000 dtex, it is advisable to use a pitch ratio of 1/70 to 1/100 and smaller. Conversely, higher yarn titer of over 2000 dtex can be processed more advantageously with a larger pitch ratio of 1/40 to 1/30 and higher. It is advantageous if the length of the cylindrical part of the slot nozzle is adapted to the yarn titer by simple tests, the speed and the other texturing conditions.

By matching the length of the cylindrical part of the second treatment chamber with the length of a downstream conical extension, variable in length (and the pitch ratio), it is possible to create an unusually wide range of applications for a texturing device. Yarn stretch titers can thus be processed without problems in wide ranges, preferably in the range from 450 to 4500 dtex and more, at high speeds of 2000 m / min and higher. The texturing device can also be determined by simple preliminary tests on the cross-sectional shape of the individual capillaries of the yarn. slightly adjust the capillary number and other yarn parameters. Finally, by adapting the cylindrical and the conically widening part, the texturing device is also suitable for partially or fully integrated texturing processes, for example stretch texturing or spin-stretch texturing, which differ greatly due to the different process management in the structure of the surface properties and the plasticity of the yarn before entering the texturing device differentiate.

The so-called "crimping" is determined to characterize the effect of the texturing of yarns etc.

• Man belastet das in kochendem Wasser entwickelte und noch feuchte Garn mit einem Gewicht von 0,05 cN/dtex und bestimmt die Länge L₁. Daran anschließend wird das gleiche Garnstück mit dem Gewicht von 0,001 cN/dtex belastet und die Länge L₂ gemessen. Die Einkräuselung ergibt sich dann folgendermaßen:
  

This means the following value, which is expressed in%:

• The yarn developed in boiling water and still moist is loaded with a weight of 0.05 cN / dtex and the length L _{1 is determined} . Then the same piece of yarn is loaded with the weight of 0.001 cN / dtex and the length L _{2 is} measured. The crimp then results as follows:
  

example 1

An undrawn polyamide 6 roving with the titer 4100 f 67 dtex is drawn off from a bobbin and fed to the drawing device of a drawing texturing machine, the drawing ratio being set to 1: 3.45. The temperature of the Einlaufgalette in the draw box is 100 ⁰ C and the temperature of the stretching field Auslaufgalette 150 ° C. The preheated and stretched thread with a stretch titer of 1200 dtex is washed with a Gej Speed of 2000 m / min fed a crimping device shown in Fig. 1. Air at a temperature of 300 ° C. is supplied through the pipe socket 3 at a pressure of 5.3 bar, the air quantity being adjusted to 6.5 Nm ³ / h by adjusting the thread introduction channel 1 in relation to the thread guide channel 4.

The thread insertion channel has a clear width of 1.1 mm; the thread guide channel 4 has a clear width of 2.4 mm, an outer diameter of 3.0 mm and a total length of 127 mm. The thread guide channel 4 projects into the treatment chamber 5, an externally cylindrical slot nozzle, up to the point 30 mm marked with D ₀ . The total length of the treatment chamber 5 is 100 mm, which results in an effective length of 70 mm. The treatment chamber 5 is interspersed over this effective length with 12 radially extending slots with a width of 0.5 mm. The cylindrical inner part of the treatment chamber 5, so the distance D _O -. D _0, in Figure 1-4 is 20 mm, a length of 2/7 of the effective length of 70 mm of the treatment chamber 5 corresponds. The conical extension D ₀ , - D ₁ adjoining the cylindrical inner part has a length of 50 mm and a pitch ratio of 1/50.

The crimp of the yarn thus produced is 11.2%.

Example 2-7

In the accompanying table, the conditions essential to the invention for various yarn stretching titers are given. All other texturing parameters with the exception of the clear width of the thread insertion channel in Example 7, where a diameter of 1.3 mm (instead of 1.1 mm) was used correspond to the information from Example 1.

Claims (2)

1. A process for the production of textured continuous filaments from synthetic linear high-molecular substances by means of heated flowing media, in which the filaments between a thread insertion zone and a thread guide zone in a first treatment chamber are exposed to the action of a gaseous turbulent flowing heated medium, heated to a temperature at which the threads become plastifiable, are transported through the first treatment zone by means of the turbulent flowing medium and are then exposed in a second treatment zone, from which part of the medium can escape radially, to the action of the medium remaining in the second treatment zone and the inflowing ambient air, characterized in that that thread and flowing medium in the second treatment zone are first passed through a cylindrical zone from which the medium can partially escape radially, and then through a weakly conically widening zone from which the Medium can also escape laterally, with the proviso that the speed of the flowing medium and thread is adjusted so that the ratio of the dwell time of the thread in the cylindrical zone to the dwell time in the conically widened zone is 1:19 to 4: 1 , preferably 1: 9 to 1: 2. 2. Device for the production of textured threads from synthetic linear high molecular substances by means of heated flowing media, consisting of a thread introduction channel 1, a treatment chamber 2, a pipe socket 3 for the supply of the flowing J Medium, a thread guide channel 4, which connects the treatment chamber 2 with a tubular treatment chamber 5, which is provided with openings 6 through which the flowing medium can escape laterally, characterized in that the treatment chamber 5 in the range from 1/20 to 4/5, preferably from 1/10 to 1/3 of their length, calculated from the end of the thread guide channel 4, is cylindrical on the inside and then widens conically in the thread running direction, the pitch ratio of the conical extension 1/5 to 1/150 , preferably 1/20 to 1/70.

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