EP0218974A2 - Method and apparatus for producing effect yarn on open-end spinning devices - Google Patents

Abstract

When producing fancy yarn on open-end spinning devices, sliver-like basic fiber material is opened into individual fibers and is fed in an air stream to an open-end spinning element. A fiber sliver of the fancy-effect fiber material is conveyed at constant speed into an air stream by which fiber tufts are separated. Fancy-effect fiber tufts and individual fibers thus separated are fed to an open-end spinning element together with the opened basic fiber material. To carry out this process, a feeding device is provided for the fancy-effect fiber material, such feeding device being driven at constant speed so that the fancy-effect fiber material is brought into the fiber feeding channel in the form of an uninterrupted fiber sliver.

Description

The present invention relates to a method for producing a fancy yarn on open-end spinning devices, in which ribbon-like basic fiber material is dissolved into individual fibers and fed to an open-end spinning element in an air stream, and an apparatus for carrying out this method.

In a known device of this type (DE-OS 2,953,527), the effect fiber material is dissolved by means of a drafting system and the pieces of effect material thus produced are thrown against a screen by means of an air stream for the purpose of further conveyance to the nip between a pair of rotating friction rollers, where they engage combine the base material and twist it into a thread. The frequency length and thickness of the effect material pieces in the effect yarn is determined by means of a program that influences the drive of the drawing rollers for the production of the effect material pieces. Such a drive, controlled by the program, is complex. In addition, only those effects can be created that are entered into the program have been. Since such a program can only have a limited length of variation, it cannot be avoided that the variations are repeated even with complex programming. For fancy yarns, however, it is desirable that as few repetitions of the variations as possible occur or only after long periods.

The object of the invention is to provide a method and a device for producing knitting yarn with which the greatest possible random distribution of the effects is achieved in a simple manner.

This object is achieved according to the invention in that the effect fiber material is fed to an air stream at a constant speed in the form of a closed, ie uninterrupted, fiber ribbon and in that fiber bundles are detached by this air stream and the fiber bundles thus detached, together with the dissolved base fiber material, are used for the open end. Spinning element are fed. The fiber material causing the effects is therefore not dissolved, as was previously the case, by a mechanical dissolving device, but by the suction effect of the flowing air, to which this material is fed. The air flow unevenly releases the fibers from the front end of the sliver retained by a feeder. The distribution of the effect fiber material in the finished fancy yarn is left to chance as to the size and sequence of the fiber groups or fibers detached from the fiber sliver. A normal delivery device without any control is therefore sufficient for carrying out the method, since it is not necessary to control the effects by variable feeding of the Effket fiber material. This method according to the invention is particularly suitable for the production of yarns Suitable for color effects. The method according to the invention is also very suitable for fine yarns in which effects cannot be produced in the desired gradation due to the inertia of the known device.

In order to achieve a good resolution of the effect fiber material and to avoid thread breaks, which could arise from too large tufts of fibers, the flow rate of the air stream is much higher than the feed speed of the effect fiber material.

To support the pneumatic dissolution of the effect fiber material, in a further embodiment of the method according to the invention, this is retained immediately before it is fed into the air stream.

In order to achieve thorough mixing of the individual fibers of the base fiber material and the effect fiber material with uniform yarn failure, it is provided in an advantageous embodiment of the method according to the invention that the effect fiber material is dissolved into fiber tufts in an effect material air flow and the fiber tufts detached in this way are mixed with it Effect material air flow are fed to the transport air flow for the basic fiber material.

In order that the individual fibers detached from the effect fiber material have sufficient time for stretching, the effect fiber material is advantageously supplied to the air stream during its acceleration.

The flow of the individual fibers detached from the base fiber material is not impaired if it is expediently provided that the effect fiber material is dissolved before the acceleration of the air flow has ended.

In order not to impair their parallel position during fiber transport, it is further provided in an expedient embodiment of the method according to the invention that the transport air stream and the effect material air stream have essentially the same flow direction before they are combined.

The fiber material causing the effects is only dissolved pneumatically, but not mechanically. Thus, the intensity of the air flow acting on the fiber material is of essential importance for the dissolution of the fiber band consisting of the effect fiber material. In order to avoid an increase in the spinning negative pressure prevailing at the open-end spinning element only for the detachment of the fiber tufts, the effect fiber material is expediently fed into the transport air stream for the base fiber material at the location of the greatest air speed.

Deviating effects can be achieved according to the invention when the same slivers are fed in that the constant feed speed of the effect fiber material is adjusted according to the desired effects.

In order to produce effects from more than just two colors, the effect fiber material can also be supplied in the form of a plurality of fiber bands, wherein these two or more effect material fiber bands can also be supplied at different constant speeds.

To carry out the described method, the fiber feed channel has, according to the invention, a feed opening through which the effect fiber material passes through the fiber feed channel is supplied, which is supplied by the feed device at a constant speed. The effect fiber material in the form of tufts of fibers is detached pneumatically in this way.

Since it has been shown that the pneumatic dissolving of this material can be significantly supported by guiding the effect fiber material over a tear-off edge, such a tear-off or retention edge is advantageously provided between the feed device and the first fiber feed channel.

In order to optimize the detachment of fibers and tufts of fibers in the air flow, it can be provided that the fiber feed channel has cross-sectional areas with different speeds of the air flow guided by it and that the feed opening is arranged in the area of the higher flow speed in the fiber feed channel. For this purpose, a band guide is advantageously provided which keeps the fiber band in the region of the higher flow speed.

In order to ensure that both the individual fibers detached from the base fiber material and from the effect fiber material can calm down before reaching the open-end spinning element, it is expediently provided according to the invention that in the case of a fiber feed channel with a tapering and an adjoining one cylindrical part of the feed opening is arranged in the tapered part of the fiber feed channel.

According to the invention, the fiber band consisting of the effect fiber material is to be dissolved in time in the air stream in such a way that the fiber band changes the fiber orientation of the Individual fibers released from the basic fiber material are not impaired. This is achieved according to the invention in that the feed opening is formed by the end of a fiber feed channel for the effect fiber material, the length of which exceeds the maximum stack length of the individual fibers contained in the effect fiber material.

So that the spinning vacuum can have an optimal effect in the second fiber feed channel, so that even at a relatively low spinning vacuum a reliable dissolution of the effect fiber material exposed to the air stream is achieved, it is advantageously provided that the fiber feed channel for the effect fiber material is essentially in Longitudinal direction of the fiber feed channel for the basic fiber material opens into it. If the fiber feed channel for the base fiber material starts tangentially from an opening roller, then according to a preferred embodiment of the subject matter of the invention, the fiber feed channel for the effect fiber material forms the rearward extension of the fiber feed channel for the base fiber material.

So that the effect fiber material is not dissolved too finely, but also remains in tufts after the pneumatic detachment from the fiber sliver, it is provided that the effect fiber material is fed to the base fiber material on its transport path between the opening roller and the open-end spinning element. In order to achieve early feeding and thus thorough mixing, it can be provided in a further embodiment of the subject matter of the invention that the interior of the opening roller housing in the area of the start of the fiber feed channel for the basic fiber material has an extension into which the fiber feed channel for the effect Fiber material opens tangentially to the opening roller.

It has been shown that, with the device unchanged, a normal yarn can also be spun without effects by not feeding any fiber material into the feed opening. The air sucked in through the feed opening does not impair the normal spinning process. If, however, it is considered useful for better control of the air conditions, it can also be provided in a further embodiment of the device according to the invention that a closure member is assigned to the feed opening. This is advantageously arranged in the area of the undissolved sliver, so that when a fancy yarn is being produced, no fibers that have already been detached from the sliver can get stuck here.

An adjustable drive is advantageously assigned to the feed device, so that the constant feed speed of the effect fiber material can be determined in different ways compared to the base fiber material.

According to the invention, a pair of rollers or a drafting device can be used as the feeding device for the effect fiber material, the distortion in the drafting device being determined in such a way that the fiber ribbon warped in the drafting device is not dissolved into individual fibers, but also forms a fiber structure when leaving the drafting device, so that The tufts of fibers are removed pneumatically by an air flow.

In order to be able to increase the variety of effects, it is also possible to provide a plurality of feed devices and feed openings for feeding effect fiber material into the fiber feed channel.

The present invention enables, without tape preparation and random control, that a shift-resistant fancy yarn, in particular a yarn with color effects, can be produced in a simple manner, the effects in terms of sequence and size being left to chance. The effect fiber material is not dissolved mechanically, so that no conventional dissolving device for the effect fiber material is required. If the fiber material provided is still too strong for direct pneumatic dissolution, the pair of rollers of the feed device can be formed by the pair of output rollers of a conventional drafting device, which, however, only warps the fiber material so far that a still closed, i.e. uninterrupted sliver emerges from this drafting system. This sliver is then released pneumatically. In this way, an irregular dissolution of the band-shaped effect fiber material into tufts of fibers is achieved without the need for special, irregularly controllable and drivable dissolving devices. The device according to the invention is thus very simple in construction. It is also not necessary with a favorable embodiment of the device according to the invention to increase the spinning vacuum, which generates the air flow causing the sliver to dissolve, compared to the normal spinning process, so that the device according to the invention is not only simple in construction, but also economical Operation is.

• Figur 1 in schematischer Seitenansicht eine erste Ausbil­dung der erfindungsgemäßen Vorrichtung;
• Figur 2 in schematischem Querschnitt die Anordnung der Ein­mündung eines zweiten Faserspeisekanals in den ersten Faserspeisekanal im Zusammenhang mit einer eine Garniturwicklung tragenden Auflösewalze;
• Figur 3 in schematischer Seitenansicht eine Abwandlung der in Figur 1 gezeigten Vorrichtung;
• Figur 4 in schematischer Seitenansicht eine Ausbildung der erfindungsgemäßen Vorrichtung mit zwei Liefervor­richtungen für das Effekt-Fasermaterial; und
• Figur 5 in der Draufsicht die Zuführöffnung des zweiten Faserspeisekanals.

The invention is described in more detail below with reference to exemplary embodiments and drawings, with all the details not necessary for understanding the invention being omitted from the drawings for simplicity and clarity. Show it:

• Figure 1 is a schematic side view of a first embodiment of the device according to the invention;
• FIG. 2 shows a schematic cross section of the arrangement of the opening of a second fiber feed channel into the first fiber feed channel in connection with an opening roller carrying a clothing winding;
• Figure 3 is a schematic side view of a modification of the device shown in Figure 1;
• Figure 4 is a schematic side view of an embodiment of the device according to the invention with two delivery devices for the effect fiber material; and
• Figure 5 is a top view of the feed opening of the second fiber feed channel.

The open-end spinning device shown in FIG. 1 has, as the most important elements, a spinning element designed as a spinning rotor 1, a opening device 2 designed as opening roller 22 and a fiber feed channel 3 for the base fiber material 26, which extends from opening roller 22 to spinning rotor 1.

The spinning rotor 1 is arranged in a housing 10 which is connected via a connection 11 to a vacuum source, not shown. The housing 10 is closed with a cover 12, through which the fiber feed channel 3 and a thread take-off channel 4 extend into the interior of the spinning rotor 1.

In the fiber feed channel 3 for the basic fiber material, the feed opening 52 of a fiber feed channel 5 opens for the Effect fiber material 7. A feed device 6 is arranged in front of the inlet mouth 50 of this fiber feed channel 5. In this case, a distance serving as an air inlet opening 51 is provided between the feed device 6 and the fiber feed channel 5.

The feed device 6 essentially has a pair of rollers which consists of a drivable feed roller 60 and a pressure roller 61 which rests elastically thereon. The feed roller 60 is driven by a motor 63 at a constant speed via an overdrive 62.

The base fiber material 26 is supplied to the opening roller 22 arranged in a housing 25 in the usual way by means of a feed device 24 and is broken up into individual fibers 20 by the opening roller 22. A transport air flow 9 is generated in the fiber feed channel 3 by the negative pressure present at the connection 11 of the housing 10. This transport air flow 9 serves as a transport medium for the individual fibers 20 leaving the opening roller 22. In addition, this transport air flow in the fiber feed channel 3 causes an effect material air flow 90 to be created in the fiber feed channel 5.

Through the continuously and uniformly driven feed device 6, the effect fiber material in the form of a sliver 7 is fed to the fiber feed channel 5 at a constant speed. A slightly twisted sliver band or an untwisted stretch band can be used as the sliver 7. In both cases, this sliver 7 also forms a closed, ie uninterrupted, company even after it leaves the feed device 6 association. A strong suction effect is exerted on the leading end 70 of the sliver 7 by the aforementioned effect material air flow 90, which penetrates into the fiber feed channel 5 through the air inlet opening 51. The leading end 70 flutters back and forth in the fiber feed channel 5 and is turned open when the fiber sliver 7 is a twisted fiber sliver. Individual fibers and tufts of fibers 71, the rear end of which have left the clamping area of the feed device 6, are irregularly released from the fiber sliver 7 by the air and, with the aid of the effect material air flow 90, are conveyed through the feed opening 52 into the fiber feed channel 3, where they emerge from the Mix sliver 7 of individual fibers and tufts of fibers 71 with individual fibers 20 released from the basic fiber material and together with the individual fibers 20 of the dissolved basic fiber material 26 are fed to the open-end spinning element, for example a spinning rotor 1. The sliver 7 is thus purely pneumatic, the effect being controlled solely by the fiber friction.

Due to the uncontrolled fluttering of the leading end 70 of the sliver 7, the individual fibers and tufts 71 are pneumatically released from the sliver 7 in an irregular manner, so that they differ in sequence and size. Therefore, even after the union and mixing of the individual fibers 20 and fiber tufts 71, no homogeneous fiber mixture is produced. The resulting fancy yarn 40 is thus also irregularly patterned, although no effect control devices are provided. The random distribution of the effects results automatically from the removal of fibers and tufts of fibers 71.

Any fiber materials can be spun together in the manner described and with the aid of the device described. However, the effects appear most clearly when the spinning rotor 1 is supplied with fiber material of different colors or hues via the two fiber feed channels 3 and 5. This creates a yarn with uneven color effects.

As FIG. 1 shows, the fiber feed channel 5 is of such a length that the dissolution of the fiber band 7 into individual fibers and fiber tufts 71 with the aid of the effect material air flow 90, i.e. still in the fiber feed channel 5, before this opens into the fiber feed channel 3 with the transport air flow 9. The leading end 70 of the sliver 7 thus does not protrude into the transport air flow, which conveys the individual fibers 20 detached from the base fiber material 26, and thus cannot adversely affect the fiber transport from the opening roller 22 to the spinning rotor 1. To ensure this, the length of the fiber feed channel 5 is selected so that it exceeds the maximum stack length of the individual fibers 71 contained in the effect fiber material. In this way, the effect fiber material, which has already been broken down into individual fibers 71, is introduced into the transport air stream 9 for the base fiber material with the aid of this effect material air flow 90.

In a modification of the device described and the method described, it can also be provided that the fiber feed channel 5 is shorter than in the above-mentioned example when the space is limited. The leading end 70 of the sliver 7 should, however, protrude only so far into the fiber feed channel 3 that the fiber transport between the opening roller 2 and the spinning rotor 1 is not significantly disturbed. It has been shown that this - provided the inside diameter of the fiber feed channel 3 is sufficient - is generally the case when the fiber feed channel 5 has a minimum length which is greater than the minimum staple length of the individual fibers 71 contained in the effect fiber material.

Various additional measures can be taken to ensure that the fiber orientation of the individual fibers 20 and fiber tufts 71 detached from the two fiber material templates is not disturbed. Thus, according to FIG. 3, which shows a modification of the device shown in FIG. 1, it is provided that the transport air flow 9 and the effect material air flow 90 in the fiber feed channels 3 and 5 have essentially the same flow direction even before they are combined. Since in the exemplary embodiment shown in FIG. 3 the fiber feed channel 5 forms the rearward extension of the fiber feed channel 3, the fiber feed channel 5 opens into the fiber feed channel 3 essentially in the direction of flow of the transport air flow 9. However, the same is also achieved if, in a modification of the device shown in FIG. 1, the angle α between the two fiber feed channels 3 and 5 is chosen to be correspondingly large.

On the one hand, thorough mixing of the basic fiber material 26 and the effect fiber material is desired so that thread breaks do not occur due to excessively large tufts of fibers 71 which are fed to the spinning element (spinning rotor 1). On the other hand, however, this mixing should not be too great, since otherwise the mixture will be too uniform and there will be no more effects. For this reason, the effect fiber material is fed into the transport air stream for the base fiber material 26 after it has been detached from the dissolving device 2.

The already mentioned FIG. 3 shows a very early feeding of the effect fiber material into the above-mentioned transport air flow for the basic fiber material 26, namely tangentially into the housing 25 of the opening roller 22. The interior space receiving the opening roller 22 has in the area of the beginning of the fiber feed channel 3 for the base fiber material 26 is an extension 27, so that the individual fibers 20 of the base fiber material 26 can already detach from the clothing of the opening roller 22 before they leave the interior of the opening roller housing 25. According to FIG. 3, the fiber feed channel 5 for the effect fiber material 7 opens into this extension 27 of the interior in such a way that the fibers and fiber tufts 71 of the effect fiber material still get into the opening roller housing 25, but without coming into contact with the clothing of the opening roller 22 to get.

In order to remedy any disturbances in the fiber orientation caused by the combination of the transport air flow 9 and the effect material air flow 90, it is provided according to FIG. 3 that the fiber feed channel 3 for the base fiber material 26 has a first conical channel section 30 and has a second, substantially cylindrical channel section 31. The feed opening 52 of the fiber feed channel 5 for the effect fiber material 7 opens into the fiber feed channel 3 in the region of the first, ie the tapering, channel section 30. In this way, the transport air flow 9 is initially accelerated, with the exception of the individual fibers 20 of the base fiber material 26, the individual fibers 71 of the effect fiber material delivered into the accelerating transport air flow by means of the effect material air flow 90 are also stretched. So that this can be done, it is ensured by the described length setting for the fiber feed channel 5 that the leading end 70 of the The sliver 7 extends at most into the conical channel section 30 of the fiber feed channel 3, so that the detachment of the fibers 71 takes place before the acceleration of the transport air flow 9 has ended. The combined air flow then passes into the cylindrical channel section 31, through which the air flow flows essentially at a constant speed. The individual fibers 20 and fiber tufts 71, which due to their inertia can only delay the acceleration of the air, are subsequently accelerated in the calming phase in the cylindrical channel section 31, their stretching and parallel orientation being improved.

The described device can be modified in various ways by exchanging features with equivalents or other combinations. As FIG. 3 shows, the special design of the feed device 6, for example, is irrelevant. Thus, instead of the pair of rollers formed by the feed roller 60 and the pressure roller 61, a drafting device can also be provided (see input roller pair 64 and output roller pair 65), which reduces the fiber sliver 7 fed to such a thickness that this in the air flow in the second fiber feed channel 5 - and possibly in the first fiber feed channel 3, if the leading end 70 of the fiber band 7 extends into this first fiber feed channel 3 - can be broken down into individual fibers and fiber bundles 71. The speed ratios between the input roller pair 64 and the output roller pair 65 - and possibly other roller pairs - are chosen so that the sliver 7 fed is reduced to the desired thickness, but is in no way resolved into individual fibers and fiber tufts 71.

Just as the special design of the feed device is in principle irrelevant, the open-end spinning element can also be designed as desired. A pair of friction rollers 13 is therefore shown in FIG. 3 as an exemplary embodiment of such a spinning element. The air flow sucked in by the spinning element is weaker than in rotor spinning. For this reason, the air flow can also be increased if necessary by compressed air supplied by means of an injector nozzle (see compressed air nozzles 58 and 59).

If fiber feed channels 3 and 5 are always provided in the exemplary embodiments described above, the fiber feed channel 5 for the effect fiber material 7 can still be omitted under certain circumstances. The band-shaped effect fiber material is then introduced into the fiber feed channel 3 through a feed opening 52, with a correspondingly selected distance of the feed device 6 from the feed opening 52 and thus from the fiber feed channel 3 ensuring that the fiber ribbon 7 only extends so far into the fiber feed channel 3, that proper dissolution of the effect fiber material is guaranteed there.

As FIG. 2 shows, the opening roller 22 has a sawtooth-like clothing winding 8. The screw-like passages of the clothing winding 8 move the air from one end face 28 of the opening roller 22, at which the end 80 leading the rotation (arrow 21) of the opening roller 22 the clothing winding 8 is in the direction of the end face 23, on which the trailing end 81 of the clothing winding 8 is located, or vice versa. The direction in which air migrates laterally depends on whether the peripheral speed of the opening roller 22 is greater than that Air speed is or vice versa. The air speed thus increases over the cross section in the direction of the end face 23 or 28 of the opening roller 22. In order to be able to fully utilize this higher air speed and the injector effect caused by it to dissolve the effect fiber material, the effect fiber material is fed into the transport air stream 9 for the basic fiber material 26, based on the cross section, at the location of the greatest air speed . According to FIG. 2, this should be at the front side 23 of the opening roller 22, which is why the fiber feed channel 5 in this embodiment opens into the fiber feeding channel 3 offset toward the front side 23 of the opening roller 2. In this way, the feed opening 52 opens into the fiber feed channel 3 in the region of the higher flow velocity, namely on the side of the fiber feed channel 3 to which the air is conveyed through the clothing winding 8.

If the fiber feed channel 5 has the same width as the fiber feed channel 3, a tape guide 66 (FIG. 5) is arranged before the introduction of the fiber ribbon 7 into the second fiber feed channel 5 so that it holds the fiber ribbon 7 on the side of the fiber feed channel 5 on which the greater air speed forms in the fiber feed channel 3.

Due to the described asymmetrical supply of the effect fiber material 7 in a cross-sectional area of the fiber feed channel 3 with increased flow speed, an intensive suction effect on the fiber sliver 7 is achieved, since the flow speed is substantially higher than the feed speed of the fiber sliver 7, so that the normal, adjacent to the spinning element Spinning vacuum is also sufficient for the dissolution of the sliver 7.

To achieve different fancy yarns, it is also possible to connect the feed device 6 to the motor 63 (FIG. 1) in such a way that the transmission ratio can be set to different values. This can be done, for example, by replacing gear wheels on the drive shafts of motor 63 and feed roller 60. Depending on the desired intensity of the effects, a higher or a lower feed speed can thus be selected for the feed device, but this then remains constant during the production process.

It can also be provided that in addition to the fiber feed channel 5 with its feed device 6, a further fiber feed channel 57 with an air inlet opening 53 and a feed opening 56 and a feed device 67 opens into the fiber feed channel 3 in order to feed effect fiber material in the form of a further sliver 72. The feed device 67 also consists of a feed roller 670 and a pressure roller 671. The feed roller 670 is driven by the motor 63 by means of an overdrive 620. In order that the effects which are produced by the sliver 7 fed by means of the feed device 6 and those which are produced by the sliver 72 which is fed by means of the feed device 67 are different, the feed devices 6 and 67 become from the motor by suitably determining the transmission ratio 63 driven out at different constant speeds.

The effect fiber material of different fiber tapes 7 and 72 can be fed to the fiber feed channel 3 through several or a single feed opening, depending on the space available. In the latter case, the dissolved or still to be dissolved effect fiber material is brought together at the latest at the common feed opening.

In order to achieve defined dissolution ratios, the sliver 7 and / or 72 can be retained by the feed device 6 or 67 while it is exposed to the air flow. For this purpose, however, a retaining or tear-off edge 54 can be provided between the feed device 6 or 67 and the first fiber feed channel 3. According to FIG. 1, this is located between fiber feed channel 5 and fiber feed channel 3. Also according to FIG. 4, a tear-off edge 54 is provided at this point, while a tear-off edge 55 designed as a pin is provided at a kink in the fiber feed channel 57. Such a tear-off edge 54 or 55 is very important, since it limits the effect of the air on the free end of the sliver 7 or 72. In this way it is avoided that too large pieces of fiber can get into the spinning element, which could lead to thread breaks.

If normal yarn without effects is to be produced with the described open-end spinning device, it is sufficient to interrupt the supply of effect fiber material through the supply opening 52 and / or 57. This is done by stopping the drive of the feed device 6 and / or 67. The air inlet opening 51 or 53, which is required during the production of fancy yarns to produce a transport and dissolving air flow, has no effect on the transport of the basic fiber material Detached individual fibers 20. However, if an air supply is not desired here for reasons of air balance in the open-end spinning device, then, as is shown schematically in FIG. 3 using the example of the fiber feed channel 5, the fiber feed channel 5 can also be assigned a controllable closure member 91, which in its closed position prevents such an air supply. Training of the closure member and its control can be designed differently as required. In order not to impair the transport of the individual fibers 71 detached from the sliver 7 to the fiber feed channel 3 and to rule out the risk of fiber compression, the closure member 91 in the embodiment shown in FIG. 3 is in that area of the fiber feed channel 3 in which the sliver 7 is still has not been broken down into individual fibers and fiber bundles 71.

Claims (26)

1. A method for producing a fancy yarn on open-end spinning devices, in which ribbon-like basic fiber material is dissolved into individual fibers and fed to an open-end spinning element in an air stream, characterized in that the effect fiber material is fed to an air stream at a constant speed in the form of a sliver is and by this air flow fiber tufts detached and the detached fiber tufts together with the dissolved base fiber material are fed to the open-end spinning element. 2. The method according to claim 1, characterized in that the flow rate of the air stream is substantially higher than the feed rate of the effect fiber material. 3. The method according to claim 1 or 2, characterized in that the effect fiber material undergoes retention immediately before it is fed to the air stream. 4. The method according to one or more of claims 1 to 3, characterized in that the effect fiber material is dissolved in an effect material air stream to form tufts of fibers and the detached fiber tufts are supplied with this effect material air flow to the transport air stream for the base fiber material. 5. The method according to one or more of claims 1 to 4, characterized in that the effect fiber material is fed to the latter during the acceleration of the transport air flow. 6. The method according to claim 5, characterized in that the detachment of the effect fiber material takes place before the acceleration of the transport air flow has ended. 7. The method according to one or more of claims 1 to 6, characterized in that the transport air flow and the effect material air flow have substantially the same flow direction before they are combined. 8. The method according to one or more of claims 1 to 7, characterized in that the supply of the effect fiber material in the transport air stream for the base fiber material, based on the cross section, takes place at the location of the greatest air speed. 9. The method according to one or more of claims 1 to 8, characterized in that the constant feed rate of the effect fiber material is determined depending on the desired effects. 10. The method according to one or more of claims 1 to 9, characterized in that the effect fiber material is supplied in the form of several fiber tapes. 11. The method according to claim 10, characterized in that the fiber slivers consisting of effect fiber material are supplied to the transport air stream at different constant speeds. 12. An apparatus for carrying out the method according to one or more of claims 1 to 11, with a dissolving device for dissolving the base fiber material and a fiber feed channel for feeding the base material from the dissolving device to the open-end spinning element and a feed device for feeding effect fiber material, characterized in that the fiber feed channel (3) has a feed opening (52, 56) through which the effect fiber material is fed to the fiber feed channel (3, 5), which is supplied by the feed device (6, 67) at a constant speed. 13. The apparatus according to claim 12, characterized in that a retaining edge (54, 55) is provided between the feed device (6, 67) and the fiber feed channel (3). 14. The apparatus of claim 12 or 13, characterized in that the fiber feed channel (3) has cross-sectional areas with different speeds of the air flow guided by it and the feed opening (52, 56) is arranged in the region of the higher flow speed in the fiber feed channel (3). 15. The apparatus according to claim 14, characterized by a belt guide (66) which holds the sliver (7) in the region of the higher flow rate. 16. The device according to one or more of claims 12 to 15, with a fiber feed channel, which has a tapered and then a cylindrical part, characterized in that the feed opening (52, 56) is arranged in the tapered part of the fiber feed channel (3) is. 17. The apparatus according to claim 16, characterized in that the feed opening (52, 56) through the end of a fiber feed channel (5, 57) is formed for the effect fiber material, the length of the maximum staple length of the individual fibers contained in the effect fiber material (71 ) exceeds. 18. The apparatus according to claim 17, characterized in that the fiber feed channel (5, 57) for the effect fiber material opens substantially in the longitudinal direction of the fiber feed channel (3) for the base fiber material in this. 19. The apparatus of claim 18, wherein the opening device has an opening roller and the fiber feed channel for the base fiber material is arranged tangentially to the opening roller, characterized in that the fiber feed channel (5, 57) for the effect fiber material the rearward extension of the fiber feed channel ( 3) forms for the base fiber material. 20. The apparatus according to claim 19, characterized in that the interior of the opening roller housing (25) in the region of the beginning of the fiber feed channel (3) for the basic fiber material has an extension (27) in which the fiber feed channel (5, 57) for Effect fiber material opens tangentially. 21. The device according to one or more of claims 12 to 20, characterized in that the feed opening (52, 57) is associated with a closure member (9). 22. The apparatus according to claim 21, characterized in that the closure member (9) is arranged in the region of the undissolved sliver (7, 72). 23. The device according to one or more of claims 12 to 22, characterized in that the feed device (6, 67) is assigned an adjustable drive (62, 63). 24. The device according to one or more of claims 12 to 23, characterized in that the feed device (6) is designed as a pair of rollers (60, 61). 25. The device according to one or more of claims 12 to 24, characterized in that the feed device (6) is designed as a drafting system (64, 65). 26. The device according to one or more of claims 12 to 25, characterized by a plurality of feed devices (6, 67) and feed opening (52, 56) for feeding effect fiber material into the fiber feed channel (3) for the base fiber material.

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