EP0162367A1 - Method and device for performing the piecing operation in an open-end spinning machine - Google Patents

Abstract

In order to improve the re-spinning, in particular with regard to its success rate at high spinning speeds, the free thread end which has been cut to a spinnable end and which has been fixed after being cut to length is exposed to a turbulent air flow which causes it to whip like vibrations. This will roughen the surface of the thread end. The thread end thus prepared is then transferred to the fiber collecting surface of the open-end spinning device. The roughening of the surface of the free thread end is accelerated if the end of the thread is whipped against an edge-like projection or a smoky surface.

Description

The invention relates to a method for preparing a thread end for re-spinning an open-end spinning device, in which the thread end is cut to a pieceable thread end, and a device for carrying out the method.

It is known to pull the thread end required for re-spinning an open-end spinning device from a bobbin, shorten it to a predetermined length (and cut it to length) and then return the thread end thus prepared to the fiber collecting surface of the open-end spinning device, where it relates to the collecting surface fed fibers connects (DE-AS 1.710.021). The spinner usually cuts to length so that she tears the thread over her fingernail or, in the case of thicker threads, over an edge, so that a frayed but defined thread end is created. The thread end produced only by cutting generally does not offer sufficient piecing conditions, so that the success rate when applying the thread is not sufficient, especially at high rotor speeds.

It is also known to shorten the thread purely pneumatically to the length desired for the attachment (DE-OS 2.203.198). The free end of the thread is turned up by a circulating air flow and detached from the rest of the thread by a pneumatic pull, so that a thread end with a fiber beard is formed.

Apart from the fact that an exact cutting point and thus a defined length of the thread end is not achieved in this way, it has been shown when threading at high rotor speeds that the success rate of the piecing process is still unsatisfactory.

The object of the present invention is to improve the automatic thread application in open-end spinning devices, in particular with regard to its success rate at high rotor speeds or spinning speeds.

The object is achieved in that, after being cut to length, the held free thread end is exposed to a turbulent air flow which sets the thread end in whip-like vibrations, and the thread end thus prepared is then transferred to the fiber collecting surface of the open-end spinning device.

Surprisingly, it has been shown that this method achieves a considerable improvement in the success rate for threading even at high rotor speeds or spinning speeds, so that a lowering of the rotor speed for the piecing process compared to the normal spinning process is largely unnecessary. The method has the further advantage that the processed thread length can be selected independently of the stack length and can be adapted to different piecing conditions.

The astonishing success of the process is obviously due to the fact that the thread end is opened up to a certain length, which can be optimized according to the spinning parameters, without losing its strength in this part by removing the twist and parallelization of the fibers. A more roughened surface is created in this part of the thread end, the protruding but still one-sided fibers have a very good affinity for the fibers in the spinning rotor or another fiber collecting surface, so that a quick and very firm connection is created.

The preparation of the thread end is simplified in that the thread to be prepared for piecing is laid out from the thread take-up position to the preparation device and then cut to length, whereupon the free thread end thus created is sucked into the preparation device. In this way, the free thread end is detected immediately after being cut to length by the air flow and automatically introduced into the processing device.

Exact cutting to length is achieved by using a cutting device. The roughening of the surface of the free thread end is accelerated in that the free thread end is whipped against an edge-like projection or against a rough surface. The piecing success and the binding of the fibers to the free thread end is further improved if the free end of the thread is processed to a length which is greater than the stack length. When processing, the thread is expediently held at a distance from its free end which is 1.5 times the length of the stack.

Optimal piecing conditions in open-end rotor spinning result from the fact that the free thread end is prepared in a length that corresponds approximately to the diameter of the spinning rotor. In order to facilitate the handling of the thread for processing, the free thread end is cut to the required distance from the holding point after cutting to length. The insertion of the piecing thread into the spinning device is facilitated in that the free thread end after preparation is brought to the length suitable for insertion into the spinning device and is returned after insertion into the attachment position, from which the release for the attachment process takes place.

The device for performing the method is essentially characterized by the features of claim 11.

A rapid preparation of the thread end is achieved in that at least one edge-like projection is provided in the region of the oscillating thread end or a rough surface is arranged. In a preferred embodiment, the free thread end is surrounded in its longitudinal direction by a tubular shield through which the turbulent air flow is directed. For this purpose, the compressed air nozzle is directed against the inner wall of the shield. A particularly effective air turbulence is created in that the compressed air nozzle is directed into the shield at an acute angle with respect to the central axis thereof. In order to further accelerate the roughening of the surface of the free thread end, it is provided that a plurality of compressed air nozzles open into the shield, the openings of which lie opposite one another and which are acted upon in an alternating sequence. In the event that individual fibers come loose from the separation point or the thread surface when the free thread end is roughened, the shielding can be connected to a suction line.

When a suction air nozzle is used, it points behind the inlet opening for the free thread end, as seen in the flow direction one or more secondary air openings. It is thereby achieved that the thread end is hit particularly intensively against the rough inner surface of the shield. The arrangement of the secondary air openings takes place in such a way that the secondary air openings open into the suction air nozzle eccentrically to the bore axis. The secondary air openings preferably open tangentially to the inner diameter into the suction air nozzle, as a result of which an effective turbulent torsional flow is generated which prevents the thread from being untwisted. A simple manufacture of the suction air nozzle is possible in that the secondary air openings are formed by a groove-like recess in the nozzle wall.

In order to ensure a sufficiently high turbulent suction air flow, the flow cross section of the inlet opening is smaller than that of the secondary air opening or secondary air openings. When using a conventional spinning vacuum of 700 mm water column for thread preparation, the diameter of the inlet opening for the free thread end is 2 to 5 mm depending on the thread size.

The inlet opening is expediently arranged in a cover which overlaps the wall of the suction air nozzle. This makes the device easily accessible and therefore easy to maintain. The introduction of the free end of the thread into the preparation device is facilitated in that the inlet opening has a funnel-shaped widening over which the thread holding device can be positioned at a close distance. In a preferred embodiment, in which a strong turbulent suction air flow is generated which optimally coincides with the spinning rotation of the thread, four staggered side air openings are distributed over the circumference of the suction air nozzle, and each of the side air openings is connected to the atmosphere via a bypass. The suction air nozzle is connected to a suction line via the shield. It is particularly advantageous if the suction line is connected to the suction device producing the negative vacuum, since the negative pressure on the fibers and the thread is already matched by the spinning process. Excessive stresses on the thread end are therefore avoided. In an embodiment that simplifies the manufacture of the device, the suction air nozzle is made in one piece with the shield.

A threading aid for the thread is created in that the shield is slotted in the longitudinal direction. If necessary, the shield can be slotted in the direction of movement of the thread towards the fiber collecting surface. In a preferred embodiment, the shield is a square tube and is arranged essentially in the direction of exit of the thread from the thread holding device. This promotes the whip-like movement of the thread end due to the turbulence flow. However, the shield can also be arranged transversely to the direction of exit of the thread from the thread holding device. In a structurally simple manner, the shield is arranged stationary in the swivel area of the thread holding device. Alternatively, there is the possibility that the shield can be fed to the free thread end. The shield can simultaneously serve to guide the free thread end into the thread take-off tube of the spinning device. According to current knowledge, a clear width of the shield, which is in a range of 8 to 15 mm at a given negative pressure of 700 mm water column, has proven to be optimal for the preparation of the free thread end by a suction air stream. The shield is expediently designed as a sleeve which is arranged axially displaceably in a holder of the nozzle.

• Figur 1 eine Fadenansetzvorrichtung beim Ansetzvorgang an der Spinnstelle;
• Figur 2 eine im Schwenkbereich einer Fadenhaltevorrichtung angeordnete Abschirmung mit Druckluftdüse(n), im Längsschnitt;
• Figur 3 eine Darstellung der einzelnen Phasen der Vorbereitung und Überführung des Fadenendes zur Spinnvorrichtung, in Seitenansicht;
• Figur 4 die Darstellung nach Figur 3 in der Draufsicht;
• Figur 5 eine im Schwenkbereich der Fadenhaltevorrichtung angeordnete Abschirmung mit einer Saugluftdüse, teilweise im Längsschnitt;
• Figur 6 eine Saugluftdüse mit einer als Hülse ausgebildeten Abschirmung in vergrößerter Darstellung, teilweise im Längsschnitt; und
• Figur 7 einen Querschnitt durch die Saugluftdüse gemäß Figur 6.

Two embodiments of the invention are described below with reference to the accompanying drawings. It shows

• Figure 1 shows a thread attachment device during the attachment process at the spinning station;
• FIG. 2 shows a shield with a compressed air nozzle (s) arranged in the swivel range of a thread holding device, in longitudinal section;
• Figure 3 is a side view of the individual phases of preparation and transfer of the thread end to the spinning device;
• Figure 4 shows the representation of Figure 3 in plan view;
• FIG. 5 shows a shield arranged in the swivel range of the thread holding device with a suction air nozzle, partly in longitudinal section;
• Figure 6 shows a suction air nozzle with a shield designed as a sleeve in an enlarged view, partially in longitudinal section; and
• 7 shows a cross section through the suction air nozzle according to FIG. 6.

The invention is described below in connection with an open-end rotor spinning device, to which a maintenance carriage is assigned, from which the thread attachment takes place. However, it can also be used with advantage in other open-end spinning devices, for example a friction spinning device.

The spinning machine 1 (FIG. 1) generally has a large number of spinning positions. The open-end spinning device producing the thread is located in a housing 10. The housing 10 has a thread draw-off tube 11 through which the spun thread (dashed line) leaves the open-end spinning device and is drawn off by means of a pair of draw-off rollers 12. The thread is wound into a bobbin S by the winding device 13.

To operate the spinning station, a maintenance device W is provided, which can be moved along the spinning stations and performs a wide variety of maintenance processes, e.g. also re-spinning the thread at the spinning position after thread break. To do this, it is necessary to search for the broken thread running onto the spool on the spool, to pull the end of the thread found from the spool and to reinsert it into the spinning device so that it contacts the fibers in the spinning device and thus the spinning process starts again Gear is set. If the thread end cannot be attached to the fibers in the spinning device during the first attachment process, the warning device repeats the attachment attempt, but time is lost as a result and the maintenance capacity of the maintenance device is considerably impaired. In addition, the efficiency of the entire machine is reduced by extending the downtime of the spinning device. So it is essential that the success rate when starting is as high as possible.

If an interruption of the spinning process has occurred, the maintenance device is usually called to the relevant spinning station in order to carry out the steps necessary to restart the spinning process. It is common for the spinning device to be cleaned first of fiber residues and dirt before the actual re-spinning takes place.

In the device described here, for example, a suction pipe 14 on the carriage is used for maintenance again Direction W arranged, which is movable from a rest position into a dashed-line thread take-up position, in which the mouth of the suction tube 14 is located in front of the spool S which is lifted from its drive roller and driven in the unwinding direction and picks up the thread end. The thread is sucked through the suction tube 14 and this is moved back to its rest position, the thread exiting through a longitudinal slot in the suction tube 14 and extending exposed from the spool S to the lower part of the suction tube 14.

For the return of the thread end taken up and unwound by the suction tube 14 from the spool S, a pair of clamping rollers 2, 20 is provided, which serves as a thread holding device and can be set in rotation by a drive means, not shown. The pair of rollers 2, 20 is overhung on the carriage of the maintenance device W on a swivel arm 30 and can be pivoted about an axis 3 between a thread take-up position I and a thread dispensing position IV for returning the thread end into the thread outlet tube of the open-end spinning device. The pair of rollers 2, 20, by pivoting, grips the thread extending from the bobbin S to the lower part of the suction tube 14, whereupon the thread F is severed below the pair of rollers 2, 20 holding it clamped at a predetermined point. The cutting takes place by means of a knife 15 which, in cooperation with an anvil roller 16, produces a defined thread end (FIG. 3, position I). The separated piece of thread is sucked off through the suction pipe 14.

The distance of the separation point from the holding point of the thread F given by the clamping line of the pair of rollers 2, 20 and thus the length of the free thread end F 'to be prepared for piecing can be chosen and determined independently of the stack length depending on the piecing conditions. It has been shown that a free thread end F 'of a length which is greater than the stack length and is preferably 1.5 times the stack length, enables problem-free piecing under a wide variety of piecing conditions with a very high success rate and results in a particularly firm piecing.

For the preparation of the cut-off thread end F ', the pair of rollers 2, 20 is assigned a compressed air nozzle 5 which is connected to a compressed air line 4 and which opens into a tubular shield 51 arranged in the pivoting range of the pair of rollers 2, 20 (FIG. 2). The shield 51 is arranged with a holder 50 essentially in the direction of exit of the thread F from the pair of rollers 2, 20. The compressed air nozzle 5 is directed against the inner wall 52 of the shield 51, preferably in an acute angle α of the shield with respect to the central axis 51. According to present knowledge, an angle has been found to about 45 ^o to be particularly favorable. The shield 51 is preferably designed as a square tube, but it can also have a different cross section. In order to accelerate the preparation of the free thread end, the inner wall 52 is provided with at least one projection with a sharp edge extending in the longitudinal direction of the shield 51, or it has a rough surface. The latter can be created inexpensively by lining the inner wall 52 with sandpaper, with standard grain sizes being sufficient. The turbulent air flow required for the preparation of the thread end can be increased by a second compressed air nozzle 5 ', shown in broken lines in FIG. For this purpose, it is expedient to let the second compressed air nozzle 5 'open at the same angle α into the shield 51 as the compressed air nozzle 5, the openings of the two compressed air nozzles 5 and 5' lying opposite one another. Appropriately controlled valves alternately apply compressed air to the nozzles.

After cutting to length, the pair of rollers 2, 20 is pivoted with the free thread end F 'held by them over the shield 51 (FIGS. 3 and 4, position II). Simultaneously or immediately thereafter, compressed air is blown through the nozzle 5 into the shield 51 by opening a valve and a turbulent air flow is generated, in the embodiment shown in FIG. 3 (position II) with two nozzles in alternating sequence through the nozzles 5 and 5 '. In this case, the free thread end F 'is conveyed into the shield 51 by the injector effect occurring at the inlet of the shield 51. Deviating from this procedure, it can be provided that the free thread end F 'is returned in the direction S to the bobbin after cutting from the pair of rollers 2, 20 and the returned thread length is taken up, for example, by a pneumatic thread store. By reversing the direction of rotation of the pair of rollers 2, 20, the free thread end F 'is then brought back to the original predetermined length to the holding point after pivoting over the shield 51 and sucked into the shield 51 by the air flow. During the pivoting of the roller pair 2, 20, only a short piece of thread protrudes from the roller pair in this procedure. For better handling, this procedure can also be used with advantage after preparation for the introduction of the thread end into the thread take-off tube.

The turbulent air flow directed through the shield 51 sets the free thread end F 'in whip-like vibrations and thus causes individual fiber ends to be exposed and spread apart from the thread surface, as indicated in FIGS. 3 and 4 (position III). Due to the rough inner wall 52 or at least one angular projection in the shield 51, which lies in the area of the oscillating thread end F 'and against which the thread end F' is whipped by the turbulent air flow, the exposing of fiber ends is accelerated nends and takes a minimum of time to prepare the free thread end F '. Individual fibers or fiber pieces that may come loose from the separation point or from the thread piece during this processing are removed by a suction line 53 connected to the shield (FIG. 2).

After a predetermined time as a function of the height of the rotation and also the strength of the thread, the compressed air supply is set in the shield 51 and the pair of rollers 2, 20 with the processed thread end F 'which it holds fixed in front of the opening of the thread outlet tube 11 of the open end Spinning device pivoted (Fig. 3 and 4, position IV). As a result of the negative pressure prevailing in the spinning device, the thread end F 'is drawn into the thread outlet tube 11 and, after being released by the pair of rollers 2, 20, it finally reaches the fiber collecting surface 6 of the spinning device, where it is spun onto the fed fiber ring.

In a second exemplary embodiment, for the preparation of a free thread end, the pair of rollers 2, 20 is assigned a suction air nozzle 7 with a tubular shield 51 arranged after it, which are located in the swivel range of the pair of rollers 2, 20 (FIG. 5).

By using a suction air nozzle, the preparation of the thread can be made more economical, since suction air is required for the various types of maintenance work and is therefore also available for the preparation of the thread end. The suction air nozzle 7 can be made in one piece with the shield 51 or can also be releasably connected to it. The shield 51 is arranged with a holder 50 essentially in the direction of exit of the thread F from the pair of rollers 2, 20 and is connected to the suction line 53.

The suction line 53 is preferably connected to the suction device which produces the spinning vacuum, so that the suction air flow passed through the shield 51 corresponds to the spinning vacuum during rotor spinning, which is usually 700 mm water column.

The suction air nozzle 7 has as close as possible to its inlet opening for the free thread end F 'at least one secondary air opening 71 which opens eccentrically to the bore axis of the suction air nozzle 7 and preferably tangentially to the inside diameter (FIG. 7). In the shown and preferred embodiment, four secondary air openings 71 arranged offset from one another are distributed over the circumference of the suction air nozzle 7, each of which opens into the suction air nozzle 7 eccentrically to the bore axis and tangentially to the inside diameter thereof. It is important that the secondary air openings 71 are arranged so that the turbulent air flow generated by the suction air nozzle 7 and guided by the shield 51 is superimposed on a torsional flow component which follows the spinning rotation of the thread end to be processed and prevents the thread from unraveling. The secondary air openings 71 are produced in a simple manner in that the free end of the nozzle wall surrounding the inlet opening is recessed or slit-like.

The free end of the thread is introduced into the suction air nozzle 7 and the shield 51 arranged downstream of it through the inlet opening 81, which is arranged centrally in a cover 8 which overlaps the wall of the suction air nozzle 7. The lid 8 is releasably attached to the suction air nozzle 7 and can therefore be removed so that the suction air nozzle 7 and the shield 51 are accessible for maintenance work. In addition, the arrangement of the inlet opening 81 in a cover simplifies the manufacture of the device. When using a cover that covers the wall of the suction air nozzle each of the secondary air openings 71 via a bypass 72, connected to the atmosphere. The sucking in of the thread end to be processed into the suction air nozzle 7 and the shield 51 is made easier by a funnel-shaped widening of the inlet opening which can be seen in FIG. In order to generate a correspondingly high turbulent air flow, the flow cross section of the inlet opening 81 for the free thread end is dimensioned smaller than that of the secondary air openings. When using the spinning pressure of 700 mm water column for thread preparation, depending on the thread thickness, an inlet opening 81 with a diameter of 2 to 5 mm is provided. Given the given conditions, these dimensions have proven to be particularly favorable.

For the spinning of a rotor spinning device, a free thread end is preferably prepared in a length that corresponds approximately to the diameter of the spinning rotor. The preparation is also accelerated here in that the inner wall 52 of the shield 51 is provided with at least one projection extending in the longitudinal direction of the shield with a sharp edge or a rough surface (FIG. 5). In the embodiment according to FIG. 6, the shield 51 is designed as a sleeve, the inner wall of which is provided with the sharp-edged projection or the rough surface. In this embodiment, the shield 51 is clamped in a holder 9 of the suction air nozzle 7 designed as a clamping sleeve by means of a union nut 91. After loosening the union nut 91, the shield 51 can be axially displaced, as indicated by the double arrow, so that the sharp-edged projection or the rough surface can be brought into the region of the thread end caused by the turbulent suction air flow in whip-like vibrations according to the thread length to be processed. According to previous knowledge, optimal processing of the free thread end is then achieved with a suction air flow corresponding to a spinning vacuum of 700 mm water column is sufficient if the clear width of the shield 51 is in the range of 8 to 15 mm.

Deviating from the procedure in the first embodiment, it can be provided that the thread F, which extends from the spool S to the lower part of the suction tube 14 according to FIG. 1 and is gripped by the pair of rollers 2, 20 in the thread take-up position I, is only cut after the Roller pair 2, 20 has been pivoted via the inlet opening 81 of the suction air nozzle 7 and has thus laid the thread from the thread take-up position I to the preparation device. The cutting takes place by the knife 15 in cooperation with the anvil roller 16, which are arranged at a predetermined distance from the suction air nozzle 7 (FIG. 5). The separated thread end is sucked through the suction tube 14, while at the same time the free thread end F ', which is held by the roller pair 2, 20 positioned in close proximity in front of the funnel-shaped extension, is sucked through the inlet opening 81 into the suction air nozzle 7 and the shield 51 into which suction air is introduced shortly before the thread is cut to length by opening a valve. The turbulent suction air flow generated in this way sets the free thread end F 'in whip-like vibrations, as a result of which fiber ends are spread apart from the thread surface and the thread receives a rougher surface.

As already mentioned above, the spinning twist is retained in the thread end, so that the thread end retains its strength. The preparation of the thread end F 'is also carried out very quickly here by whipping the thread end against the rough inner wall 52 of the shield 51.

When the processing of the thread end has ended after a predetermined time, the suction air supply is stopped. The processed free thread end can then, in order to facilitate insertion into the spinning device, on the for Introduce suitable length, for example, by driving the bobbin S in the winding direction and rewinding a certain length of thread on the bobbin S. The pair of rollers 2, 20 with the prepared thread end is now pivoted into the thread delivery position IV before the opening of the thread take-off tube 11 (FIG. 1). There the thread end is drawn into the thread take-off tube 11 due to the negative pressure prevailing in the spinning device. After a certain length of thread wound back onto the bobbin S has been returned to the thread take-off tube 11, the free thread end is released by the pair of rollers 2, 20 and reaches the fiber collecting surface of the spinning device, where it is spun onto the fed fiber ring.

The device described can be modified and developed in various ways. The shield 51 can thus be provided with a longitudinal slot for the insertion of the thread end F '. Depending on the space available, there is also the possibility of arranging the shield 51 transversely to the direction of exit of the thread from the pair of rollers 2, 20 or another thread holding device, for example a thread clamp. Furthermore, instead of a stationary shield 51, a movable shield can be provided, which is fed to the free thread end F 'and at the same time also serves to guide the free thread end F' into the thread outlet tube 11. In this case, the shield is provided with a longitudinal slot in the direction of movement of the thread towards the spinning device, through which the thread running into the spinning device is released upon the return movement of the shield into the starting position. It is of course also possible to arrange such a device according to the invention for preparing the thread end in a stationary manner at each spinning station.

Claims (41)

1. A method for preparing a thread end for re-spinning an open-end spinning device, in which the thread end is cut to a spinnable end, characterized in that, after being cut to length, the held free thread end is exposed to a turbulent air flow which sets the thread end in whip-like vibrations, and the thread end thus prepared is then transferred to the fiber collecting surface of the open-end spinning device. 2. The method according to claim 1, characterized in that the thread to be prepared for the thread is laid out from the thread take-up position to the preparation device and then cut to length, whereupon the resulting free thread end is sucked into the preparation device. 3. The method according to claim 1 or 2, characterized in that the cutting to length is carried out by a cutting device. 4. The method according to claim 1, characterized in that the free thread end is whipped against an edge-like projection. 5. The method according to claim 1, characterized in that the free thread end is whipped against a rough surface. 6. The method according to any one of claims 1 to 5, characterized in that the free end of the thread is processed in a length that is greater than the stack length. 7. The method according to claim 6, characterized in that the thread is held during processing at a distance from its free end which is 1.5 times the length of the stack. 8. The method according to claim 6, characterized in that the free end of the thread is processed in a length which corresponds approximately to the diameter of the spinning rotor. 9. The method according to any one of claims 1 to 8, characterized in that the free thread end after cutting to the required distance for the preparation is brought to the holding point. 10. The method according to any one of claims 1 to 9, characterized in that the free thread end after processing brought to the length suitable for insertion into the spinning device and is returned after insertion into the attachment position, from which the release for the attachment process he follows. 11. Device for performing the method according to one of claims 1 to 10, with a thread holding device holding the thread at a distance from its end, characterized in that the thread holding device (2, 20), at least one compressed air nozzle (5) or a suction air nozzle ( 7) is assigned, which generates a turbulent air flow which sets the held thread end (F ') in whip-like vibrations. 12. The apparatus according to claim 11, characterized in that in the region of the oscillating thread end (F ') at least one edge-like projection is provided. 13. The apparatus according to claim 11, characterized in that a rough surface is arranged in the region of the oscillating thread end (F '). 14. Device according to one of claims 11 to 13, characterized in that the free thread end (F ') is surrounded in its longitudinal direction by a tubular shield (51) through which the turbulent air flow is passed. 15. The apparatus according to claim 14, characterized in that the compressed air nozzle (5) against the inner wall (52) of the shield (51) is directed. 16. The apparatus according to claim 15, characterized in that the compressed air nozzle (5) is directed at an acute angle (α) with respect to the central axis of the shield (51). 17. The apparatus of claim 15 or 16, characterized in that a plurality of compressed air nozzles (5, 5 ') open into the shield (51), the mouths of which are opposite one another and which are acted upon in alternating order. 18. Device according to one of claims 14 to 17, characterized in that the shield (51) can be connected to a suction line (53). 19. The apparatus according to claim 11, characterized in that the suction air nozzle (7) seen in the flow direction behind the inlet opening (81) for the free thread end (F ') has one or more secondary air openings (71). 20. The apparatus according to claim 19, characterized in that the secondary air openings (71) eccentrically to the bore axis of the suction air nozzle (7) open into this. 21. The apparatus according to claim 20, characterized in that the secondary air openings (71) tangent to the inner diameter of the suction air nozzle (7) open into this. 22. Device according to one of claims 19 to 21, characterized in that the secondary air opening (71) is formed by a groove-like recess in the nozzle wall. 23. Device according to one of claims 19 to 22, characterized in that the flow cross section of the inlet opening (81) is smaller than that of the secondary air openings (71). 24. The device according to claim 23, characterized in that the diameter of the inlet opening (81) for the free thread end (F ') is 2 to 5 mm depending on the thread thickness. 25. Device according to one of claims 19 to 24, characterized in that the inlet opening (81) is arranged in a cover (8) overlapping the wall of the suction air nozzle (7). 26. Device according to one of claims 19 to 25, characterized in that the inlet opening (81) has a funnel-shaped extension, over which the thread holding device (2, 20) can be positioned at a close distance. 27. The device according to one of claims 19 to 26, characterized in that four staggered secondary air openings (71) are distributed over the circumference of the suction air nozzle (7) and each of the secondary air openings (71) via a bypass (72) connected to the atmosphere is. 28. Device according to one of claims 11 to 14 and 19 to 27, characterized in that the suction air nozzle (7) via the shield (51) is connected to a suction line (53). 29. The device according to claim 28, characterized in that the suction line (53) is connected to the suction device generating the spinning vacuum. 30. The device according to claim 28, characterized in that the suction air nozzle (7) with the shield (51) is made in one piece. 31. The device according to claim 14, characterized in that the shield (51) is slotted in the longitudinal direction. 32. Apparatus according to claim 31, characterized in that the shield (51) is slotted in the direction of movement of the thread towards the spinning device. 33. Apparatus according to claim 14, characterized in that the shield (51) is a square tube. 34. Apparatus according to claim 14, characterized in that the shield (51) is arranged substantially in the direction of exit of the thread from the thread holding device (2, 20). 35. Apparatus according to claim 14, characterized in that the shield (51) is arranged transversely to the direction of exit of the thread from the thread holding device (2, 20). 36. Apparatus according to claim 11, characterized in that the thread holding device (2, 20) is movable between a thread take-up position and a position emitting the thread end to the fiber collecting surface of the open-end spinning device. 37. Apparatus according to claim 36, characterized in that the shield (51) is arranged stationary in the swivel range of the thread holding device (2, 20). 38. Apparatus according to claim 14, characterized in that the shield (51) the free thread end (F ') is adjustable. 39. Apparatus according to claim 38, characterized in that the shield (51) serves at the same time for guiding the free thread end (F ') into the thread take-off tube (11) of the spinning device. 40. Apparatus according to claim 14, characterized in that the clear width of the shield (51) is in a range of 8 to 15 mm. 41. Apparatus according to claim 14, characterized in that the shield (51) is designed as a sleeve which is arranged axially displaceably in a holder (9) of the nozzle (7).

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