EP0051223A1 - Method and device for introducing yarns and the like in a winding machine - Google Patents

Abstract

For the safe insertion of threads (49a-d) into a winding device (2) and simultaneous application of the threads to the bobbin tubes (5), the threads (49a-d) are removed from the eyes provided at the apex of the traversing triangle by means of a suction gun (74) (70) (thread guide) attached to a displaceable rail, thread guide pins (51) placed for insertion into the winding device (2) at the free end of the bobbin mandrel. These guide pins (51) then bring the threads (49a-d) into position before the catch means (6) by moving the rail (48) back in such a way that the threads (49a-d) are pivoted by a thread guide arranged in a stationary but pivotable manner (41 or 79), are taken over by the guide pins 51 and brought together in a further pivoting movement into the catching means (6). In this way, the winding process begins for all coils at the same time.

Description

The invention relates to a method and a device for introducing threads and the like into a winding device with at least two traversing devices arranged axially next to one another and associated spool sleeves located on a spool.

The method also includes the features that each thread coming from a thread guide above the winding device is taken over by a manual or automatic thread suction device and then placed on a thread guide above and on individual thread guides below the traversing device and guided outside the traversing area, and that the thread is guided Threads are brought by means of the lower thread guides from a starting position at the outer end of the bobbin mandrel into an area in front of a thread catching means of the corresponding bobbin tube and then, for simultaneous detection of all threads, these are simultaneously guided into the catching means and then wound up.

The device further includes the features that a thread catcher is assigned to each of the bobbin tubes, and that the winding device is equipped with a thread guide bar above the traversing device, and for each thread a thread guide pivotable against the bobbin tubes and a device pivoting the thread guides together against the tubes.

The side-by-side and two-tier stacking of winding machines on the one hand and the multi-thread winding on the other hand as well as the need to hand over all threads safely and at the same time to all bobbin tubes in order to obtain uniform bobbin weights required a replacement of the manual single-thread transfer.

A device according to the preamble of claims 1 and 2 is known from German Offenlegungsschrift 26 27 643.

In this device, the threads delivered by a thread guide or a delivery unit are taken over by means of a thread suction device, but are then guided together on a thread guide rod on the front side in front of the winding device by means of guide notches as a bundle, but separately from one another. Subsequently, when the threads are simultaneously moved through the insertion gap of the winding device, these threads are moved in front of one another by means of thread eyelets movable along the supporting axis of the bobbin tubes and taking over the threads at a distance corresponding to the bobbin tubes arranged in a row.

Subsequently, a swivel beam carrying the thread eyelets is pivoted against or under the spool sleeves for the simultaneous insertion of the threads into the catch slots of the sleeves.

Simultaneously with the movement of the thread eyelets, the threads are lifted out of the guide notches of the thread guide rod so that they can move freely along the thread guide rod into the position corresponding to the thread tension.

The thread eyelets are moved by displaceable disks which carry the thread eyelets and are mounted on a rotatable threaded spindle. One of the washers is provided with an internal thread and is moved as a nut (hereinafter referred to as the nut washer) by the rotating threaded spindle. The remaining disks are slidably arranged on the spindle and connected to one another by driver rods.

The disadvantages of the device are that the possible inaccuracy of the disks or the thread positions in front of the catch slot has to be compensated for by an additional movement parallel to the axis of the bobbin mandrel, in order to be sure that each thread is actually caught by the catch slot. The possible inaccuracy arises on the one hand from the imprecise positioning of the nut washer due to the speed of the motor-driven spindle and on the other hand from the possibility that the friction between the drive rod and the washer can be greater than that between the spindle and the washer.

This circumstance also creates the disadvantageous process step that the threads have to be moved beyond the positions of the catch slots in the axial direction and must be returned together to be sure that the threads are caught by the catch slots.

The object of the invention is to remedy these disadvantages. The invention as characterized in the claims procedurally solves the problem in such a way that the threads are taken over individually by means of pivotable thread guides when moving from the outer end of the spool mandrel in front of the corresponding bobbin tubes and are held in an intermediate position by the pivoting thread guides before being caught by the catching means, and that the threads are in this intermediate position be kept exactly in front of and essentially parallel to the fishing gear.

The device is characterized in that the thread guide strip is movable (in a manner known per se) such that the thread is guided in a working position of the guide strip outside the action area C of the traversing device, and that below the mentioned guide strip, hereinafter referred to as the first guide strip, A second guide bar, provided with guide notches and movable from a rest position into a working position, is provided, the number of notches of which corresponds to the number of threads to be wound, that the threads on the one hand by the pivotable thread guides and on the other hand by the guide notches of the second guide bar in the working position in one Intermediate position are feasible, that they are seen substantially perpendicular, perpendicular to the bobbin axis in the direction of view, and exactly in front of the corresponding catching means, that a guiding means is also provided on which the threads, in a starting position de s guide means, can be guided individually at the outer end of the bobbin mandrel and on which the pivotable thread guides can be guided from their starting position within their pivoting range in such a way that the threads that can be guided with this guide means into the winding machine and in front of the catching means can be taken over by the pivotable thread guides and into the mentioned intermediate position are feasible, and that the pivotable thread guide can also be pivoted into the starting position by means of the device for joint pivoting against the sleeves.

One embodiment of the device is that the means for guiding the thread guides and the threads is a guide rail which can be displaced essentially parallel to the spool mandrel axis and which is provided with steps on the end opposite the free end of the spool mandrel and a thread guide pin is provided for each step.

Further advantageous embodiments are contained in claims 4-10.

The advantages achieved by the invention are essentially to be seen in the fact that the threads for takeover by the catching means are brought in a simple manner precisely and in a stationary manner in front of the catching means relative to the axial direction of the bobbin tubes.

• Fig. 1 eine Ansicht der erfindungsgemässen Spulvorrichtung mit ausgefahrener Führungsschiene, halbschematisch dargestellt.
• Fig. 2 eine Draufsicht der Spulvorrichtung von Fig. 1 mit der ersten und zweiten Fadenführungsleiste, halbschematisch dargestellt.
• Fig. 3 die Spulvorrichtung von Fig. 1 mit eingefahrener Führungsschiene,
• Fig. 4 eine Draufsicht der ersten und zweiten Fadenführungsleiste, halbschematisch dargestellt,
• Fig. 5 eine halbschematische Darstellung der Schwenkvorrichtung für die Fadenführer,
• Fig. 6 ein Detail der Vorrichtung von Fig. 5 in Pfeilrichtung II (Fig. 5), geschnitten dargestellt,
• Fig. 7 Detail-Querschnitt in Richtung III-III der Vorrichtung von Fig. 5,
• Fig. 8 Fadenführer der Vorrichtung von Fig. 5 in Pfeilrichtung IV (Fig. 5) gesehen,
• Fig. 9 Fadenführer von Fig. 8 in Pfeilrichtung V gesehen,
• Fig. 10 die Führungsschiene von Fig. 1 und 2 einzeln in der Draufsicht gemäss Pfeilrichtung I-I (Fig. 1) dargestellt,
• Fig. 10a einen Teil der Führungsschiene von Fig. 10, vergrössert dargestellt,
• Fig. 11 eine schematische Darstellung des Fadenlaufes beim Einbringen des Fadens in die Spulvorrichtung,
• Fig. 12 eine Variante der Schwenkvorrichtung von Fig. 5,
• Fig. 13 ein Detail der Vorrichtung von Fig. 12 vergrössert dargestellt,
• _Fig. 14 Querschnitt in Richtung VI-VI des Details von Fig. 13,
• Fig. 15 die schematische Darstellung des Fadenlaufs von Fig. 11 mit der Variante von Fig. 12,
• Fig. 16 die Spulvorrichtung von Fig. 1, d.h. mit ausgefahrener Führungsschiene und mit einer Variante der Fadenführer,
• Fig. 17 die Spulvorrichtung von Fig. 16 mit eingefahrener Führungsschiene,
• Fig. 18 die schematische Darstellung des Fadenlaufs von Fig. 11 mit dem Fadenführer von Fig. 16 und 17,
• Fig. 19 die Führungsschiene der Fig. 16 und 17 einzeln in der Draufsicht gemäss Pfeilrichtung VII-VII von Fig. 16 dargestellt,
• Fig. 20 einen Fadenführer und die Führungsschiene samt Führungsstift der Führungsschiene von Fig. 19 vergrössert dargestellt.

The invention is explained in more detail below on the basis of illustrated exemplary embodiments. It shows:

• Fig. 1 is a view of the winding device according to the invention with the guide rail extended, shown semi-schematically.
• Fig. 2 is a top view of the winding device of Fig. 1 with the first and second thread guide bar, shown semi-schematically.
• 3 shows the winding device of FIG. 1 with the guide rail retracted,
• 4 is a top view of the first and second thread guide bar, shown semi-schematically,
• 5 is a semi-schematic representation of the pivoting device for the thread guide,
• 6 shows a detail of the device of FIG. 5 in the direction of arrow II (FIG. 5), shown in section,
• 7 detailed cross-section in the direction III-III of the device of FIG. 5,
• 8 thread guide of the device of FIG. 5 seen in the direction of arrow IV (FIG. 5),
• 9 thread guide of FIG. 8 seen in the direction of arrow V,
• 10 shows the guide rail of FIGS. 1 and 2 individually in plan view according to arrow direction II (FIG. 1),
• 10a shows part of the guide rail of FIG. 10, enlarged,
• 11 shows a schematic illustration of the thread path when the thread is introduced into the winding device,
• 12 shows a variant of the pivoting device from FIG. 5,
• 13 shows an enlarged detail of the device from FIG. 12,
• _F ig. 14 cross section in the direction VI-VI of the detail from FIG. 13,
• 15 shows the schematic representation of the thread path of FIG. 11 with the variant of FIG. 12,
• 16 shows the winding device of FIG. 1, ie with the guide rail extended and with a variant of the thread guide,
• 17 the winding device of FIG. 16 with the guide rail retracted,
• 18 shows the schematic representation of the thread run of FIG. 11 with the thread guide of FIGS. 16 and 17,
• 19 shows the guide rail of FIGS. 16 and 17 individually in plan view according to arrow direction VII-VII of FIG. 16,
• 20 shows a thread guide and the guide rail together with the guide pin of the guide rail from FIG. 19 enlarged.

In a machine housing 1 of a winding device 2, a friction roller and a winding mandrel 4 are rotatably mounted (not shown). The spool mandrel 4 can be moved from a moved away position (rest position) (not shown) into a raised position (working position, FIGS. 1 and 2) and back.

In the raised position of the spool 4 rest on this clampable spool sleeves 5 on the friction roller 3 and thereby get the desired speed and rotation direction. A catch slot 6 is provided on the bobbin tubes 5 for clamping a thread caught therein.

A first thread guide bar 8 is slidably mounted in a support 7 fastened to the machine housing 1. The displacement directions 9a and 9b (FIG. 4) are given by the interaction of guide bolts 10 fastened in the support 7 and guide slots 71 provided in the thread guide bar 8. The displacement takes place in one direction by means of a pneumatic piston 11, the cylinder 12 of which is attached to the support 7 (not shown), and in the other direction by means of a tension spring 13. The tension spring 13 is clamped between a support part 7a and the guide bar 8. The cylinder head 14 of the piston 11 bears against the end face 15 of the guide bar 8.

Below the guide bar 8, a second guide bar 16 is rotatably and displaceably mounted by means of a bearing block 17 fastened to a support part 7b.

The displacement in the forward direction takes place by means of a pneumatic piston 18, the cylinder 19 of which is fastened to the support 7 (not shown), and in the rearward direction by means of a compression spring 21 arranged between the bearing block 17 and a grooved roller 20. The grooved roller 20 in turn is at one End connected to a shaft 22 to which the thread guide bar 16 is attached at the other end.

The grooved roller 20 has a groove 23 which is in engagement with a sliding block 24 fastened to a support part 7c. The piston head 26 of the piston 18 bears against the end face 25 (FIG. 4) of the grooved roller 20.

The second thread guide bar 16 has the same spacing the A four guide notches 27a, 27b, 27c and 27d. These distances correspond to the mutual distances between the catch slots 6 and the sleeves 5 clamped on the spool mandrel.

Below the two guide strips, the generally known traversing devices 28 (Fig. 11, - shown in Fig. 2 hinted) with the traversing thread guides 29 (Fig. 11) are arranged in their traversing area C (Fig.3) known way, the thread for winding formation on the bobbin back and forth.

Below this traversing device 28, a thread guide swiveling device 30 (FIGS. 5 and 11) is also provided. This device 30 comprises a shaft 31 which is rotatably mounted within a hollow shaft 32.

The hollow shaft 32 in turn is rotatably supported in a bearing 33 embedded in the housing part la (FIG. 5) and in a bearing 34 recessed in the support part 7d. The axial fixation of the hollow shaft 32 takes place on the one hand by means of a shaft collar 37 which abuts the bearing 33 on the end face and on the other hand by means of a bearing cover 38 fastened in the support part 7d which abuts the hollow shaft 32 on the end face.

Thread guide elements 39a-d are pivotally arranged on the hollow shaft 32, each consisting of a bush 35 rotatably mounted on the hollow shaft 32 and a rod 40 fastened to it and thread guides 41 fastened to the rod 40. On a rod 40 belonging to the rod 40 and slightly angled to it (apparent from FIG. 8) rod extension 42, the free end is designed as a sliding shoe 43.

A helical spring 36 fastened on the one hand to the bush 35 and on the other hand to the hollow shaft 32 has the function of pushing the bush 35 in the direction B (FIGS. 7 and 11), i.e. counterclockwise, as seen from the free end of the spool, so as to pivot the thread guide elements 39a-d in this direction.

An anchored in the shaft 31 and in guide slots 71 and 72 (Fig. 7) of the hollow shaft 32 and. Bush 35 guided driving mandrel 47 prevents axial movements of the shaft 31 and the bush 35 on the one hand and on the other hand limits the pivoting movement of the rods 40 by the length of the guide slot 72 of the hollow shaft 32 (exact function will be described later). The width of the guide slots 71 and 72 is selected so that the mandrel 47 is guided in it by friction.

The thread guide 41 has a thread guide notch 44 (FIG. 9) formed from the thread guide edges 45 and 46. The thread guide edges 45 and 46 form an opening angle α of less than 90 °, e.g. an angle of 60 °.

Also below the traversing device 28 is a guide rail 48 (FIGS. 1, 3 and 10) which can be displaced essentially parallel to the spool mandrel axis. This rail 48 serves to guide the thread guide elements 39a-d (FIG. 5) by means of the sliding shoes 43 and the threads 49a, 49b, 49c and 49d during the insertion of the threads into the winding machine.

For this purpose, the rail 48 is provided on the inside 50 facing the spool with thread guide pins 51, while the opposite outside 52 serves to guide the sliding shoes 43.

Furthermore, the rail on the upper narrow side 53 (Fig. 3) so provided with steps 54 so that the distance a between the stepped end face 54a and the guide pin 51 _(FIG. 10a) is equal to or less than the Gleitschuhbreite b (Fig. 9) is.

The division c (Fig. 10a), i.e. the distance from pin to pin 51, which corresponds to the distance between the end faces 54a, is selected such that when the threads 49a-d are introduced into the winding machine by means of the rail 48, at the moment the threads 49a-d are transferred from the first guide bar 8 to the second guide bar 16, the threads are guided on the guide bar 16 in such a way that each thread passes into its corresponding guide notch 27a-d when it continues to slide on the guide bar 16. The corresponding position of the rail 48 is indicated in Fig. 1 with the dash-dotted representation of the threads 49a-d.

On the lower narrow side, the rail 48 is connected by a driver 55 to the piston 56 of a pneumatic cylinder 57, which in turn is attached to the machine housing 1.

A crank mechanism 58 (FIGS. 5 and 6) consisting of a pneumatic cylinder 59, the cylinder rear side of which is pivotally connected to a housing part 1b and a hinge pin 60 for the power transmission between a hinge part 61 fastened to the piston end and an am Shaft end 62 of shaft 31 fastened joint part 63.

To rotate the hollow shaft 32, a crank mechanism 64 is used in an analogous manner, consisting of a pneumatic cylinder 65, a pivotally connected to the housing part 1b hinge part 66 fastened to the piston end, a hinge part pair 67 fastened to shaft end 68 and a hinge pin 69 for power transmission between hinge parts 66 and 67.

Threads 49a, 49b, 49c and 49d are introduced into the winding device 2 as follows:

1st phase:

Threads coming from thread guides 70a, 70b, 70c and 70d (FIG. 1) or from a delivery plant (not shown) are sucked in by means of a so-called suction gun 74 or an equivalent suction device (not shown), onto the first thread guide bar 8 (FIG. 11) and guided to the thread guide pins 51. This position of the threads is shown in Fig. 11 with a solid line.

In this position, the threads are no longer detectable by the traversing thread guides 29 and are freely tensioned in the space between the thread guide bar 8 and the thread guide pins 51.

The thread guides 70a to 70d form the apex of the traversing triangle and, in a manner known per se, are located essentially perpendicularly above the center of the traversing region of each bobbin tube 5, shown in FIG. 3 with region C.

Before the threads 49a to 49d were guided to the corresponding thread guide pins 51, the guide rail was brought from the starting position shown in FIG. 3 into the working position shown in FIG. 1 by actuating the cylinder 57 (not described). Then Betä actuation of the cylinder 59, the shaft 31 (FIG. 5) is rotated such that the thread guide elements 39a-d are pivoted from the starting position D shown in FIG. 11 with a dotted line into the position D1 shown with a broken line. This takes place in that the driving mandrel 47, as a result of this rotation, arrives in the guide slot 72 in the position shown in FIG. 7 in the position shown in FIG. 11, ie in contact with the other end of the guide slot 72, so that the helical spring 36 (FIG. 5) the sleeve 35 rotates in the direction of rotation B (FIG. 11) until the sliding shoes 43 rest against the outside of the rail 52.

In this first insertion phase, as shown in FIGS. 2 and 4, the threads rest on the guide bar 8, but not yet on the second thread guide bar 16, which has also already been brought into the working position.

It can be seen from FIG. 1 that the threads 49a and 49b, when distributed in front of the corresponding catch slots 6 of the sleeves 5, can only be transferred to the second thread guide strip 16 when they are in the positions between the guide notches 27b and 27a (FIG. 4 ) respectively 27b and 27c. For this reason, the second phase, namely the distribution of the threads 49a to 49d in front of the catch slots 6, is controlled as follows:

2nd phase:

Upon a further manual push of a button (not shown), the pneumatic cylinder 57 begins to move the piston 56 and thus the guide rail 48 from the position shown in FIG. 1 to the position shown in FIG. 3. A little delayed, namely when the rail 48 reaches the position of the threads shown in dash-dotted lines in FIG. 1 , by relieving the pressure on the cylinder 12 (FIG. 4), the first thread guide bar 8 is displaced obliquely back in the direction 9b into the starting position shown in FIG. 11 by the tension spring 13 in such a way that the threads 49a to 49d on the second guide bar 16, however, do not yet come to rest in the guide notches 27a-d and continue to slide until each thread is stopped in the corresponding guide notch 27a to 27d on the path still to be covered on the guide bar 16, ie the thread 49a in the notch 27a, the thread 49b in the notch 27b, etc.

When the rail 48 is further pushed back into the starting position, the steps 54 (FIG. 3) release the further pivoting path of the thread guides 41 (FIG. 11) by the sliding shoes 43 pivoting past the end faces 54a over the steps 54. This pivoting movement lasts until the sleeve 35 (FIG. 7) lies against the driving mandrel 47 by means of a guide slot 71 (shown in solid lines in FIG. 11). In this process, the threads 49a-d are taken over by the thread guides 41. This position of the threads between thread guide 41 and notch 27a-d is shown in FIG. 11 with a broken line. In order to ensure this thread takeover, the spatial relationships between the sliding shoe 43 and the thread guide 41 are such that when the sliding shoe 43 swivels over the corresponding step, the leading edge 46 (FIG. 9) is already in front of the thread, in the direction of view of the spool axis and from the free End of the bobbin seen here before the shoe 43 (Fig. 11) pushes the thread away from the guide pin 51. The distance between the end face 43a (FIG. 8) of the slide shoe and the thread is therefore greater than the distance between the thread and the fingertip 46a. To guarantee this, all glides must be of the same length shoes 43 the rod extension 42 be substantially parallel to the outside 52 of the rail 48. In addition, the distance m shown in FIG. 9 must be greater than the distance a shown in FIG. 10a.

At the end of this second phase, the threads 49a-d, as shown in FIG. 3 and shown in broken lines in FIG. 11, lie freely tensioned within the winding device between the notches 27a-d and the thread guides 41 next to the traversing area C and just in front of it appropriate fishing gear and essentially parallel to it. In addition, the cylinder 59 continues to be pressurized in the same sense, but is prevented from moving further by said abutment of the driving mandrel 47 in the guide slot 72.

3rd phase:

In this phase, the pneumatic cylinder 65 (FIG. 5) is actuated and the hollow shaft 32 is thereby rotated in the direction B (FIG. 7). This enables the shaft 31 to be rotated further, so that the thread guide elements 39a-d jointly pivot into the position F shown in broken lines in FIG. 11. As a result, the threads 49a-d get into the corresponding catch slots 6 and are torn off by the suction gun 74, so that the turns on the sleeve begin to form.

The stroke of the cylinder 65 is adapted to the pivoting movement of the thread guides 41 between positions E and F. The stroke of the cylinder 59 is such that the thread guides can be pivoted between positions D and F. The force of the cylinder 59 is dimensioned such that the positions D, E and F of the stroke and force of the cylinder 65 are given.

After the position F has been reached by the thread guide elements 39a-d, the pneumatic cylinder 19 (FIG. 5) is relieved. As a result, the spring 21 displaces the grooved roller 20 and thus the second thread guide strip 16 back into the starting position. As a result of the swirl movement that occurs, the guide bar 16 is rotated at the same time and pivots the notches 27a-d out of the thread path. The threads 49a-d are now freely stretched between the thread guides 70a-d and the sleeves 5 and, as a result of this thread tension, strive in the traversing area C, in which they are gripped by the traversing thread guides 29. During this twisting movement, the threads are guided through the notches 27a-d in such a way that some reserve turns are placed between the catch slot 6 and the traversing area C. The normal winding process begins when the threads 49a-d are gripped by the traversing thread guides 29.

4th phase:

Finally, the cylinders 59 and 65 are reversed (not shown), so that the thread guide elements 39a-d pivot back into the position D shown in FIG. 11 with a dotted line. This starting position is shown in Fig. 7.

A variant A of the invention is shown in FIGS. 12 to 15.

This variant consists in that instead of the bush 35 (FIG. 5) and the coil spring 36, a coil spring 75 is connected on the one hand to the rod 40 and on the other hand to a bolt 76 anchored in the shaft 31. The remaining elements in connection with the rod 40 are the ones already described and accordingly have the same Designations. In addition, a trough-shaped stop 77 serving to receive the elements 75, 76 and 40 prevents the coil spring 75 from bending in this direction. The stop 77, with its end bordering the shaft 31, is guided in the guide slot 73 in such a friction-locked manner that axial displacements of the shaft 31 are thereby prevented.

The insertion of the threads 49a-d into the winding device 2 essentially takes place, as described earlier, with the exception that the thread guides 41 are pivoted through the steps 54 by means of the tensioning force of the coil spring 75. The following description section is therefore limited to the function of the new elements:

In the 1st phase, after the rail 48 has been brought into the working position (FIG. 1), the shaft 31 is rotated in the direction B (FIG. 15) until the stop 77 (FIG. 14) at the slot end 78 of the slot 73 is present. In this position, the sliding shoes 43 (see FIG. 11) rest on the rail outside 52, i.e. the thread guide elements 39a-d are in the position shown in FIG. 15 with a broken line. In this position Dl of the thread guide elements 39a-d, the coil spring 75 is bent in accordance with the position of the bolt 76 and the rod 40 (not shown), i.e. it is not against the stop 77.

When the rail 48 is pushed back into the starting position, the pivoting operation into the position E of the thread guide elements 39a-d shown in solid lines takes place by means of the tensioning force of the spring 75, namely until the spring 75 and the spring-side end of the rod 40 bear against the stop 77. The further process, ie the turning of the hollow shaft 32 and the shaft 31 for pivoting the thread guide elements 39a-d in position F, etc., happens as described earlier.

Another possible application of the invention is shown by variant B with FIGS. 16-20. In this variant, the thread guide element 79 (FIG. 20) consists of a thread guide 80 fastened to a rod 40a with a thread guide notch 81, formed from a long finger 82 and a short finger 83.

The rod 40a can be fastened analogously to the rod 40 at the same location on the bush 35.

The functions during the insertion of the threads 49a-d into the winding device 2 correspond to the functions described for phases 1-4, with the exception that the thread guides 80 slide directly on the outside 52 of the guide rail 48 by means of the end faces 84 and 85. This happens e.g. for thread 49d as follows:

When the rail 48 moves back into the starting position, the end face 84 first slides on the outside 52 and then transfers the guidance to the short finger 83 when pivoting via the corresponding step 54.

The lengths of the two fingers 82 and 83 are selected such that, after the long finger 82 lies above the step 54, the end face 84 has not yet reached the inside 50, i.e. the thread 49d passes the finger 82.

Only after the finger 83 is also no longer guided on the outer side 52, that is to say thereby releases the complete pivoting of the thread guide 80 via the step 54, is the thread 49d gripped by the thread guide notch 81 and continues to pivot until the rod 40a comes to a standstill in position E. This takes place on the condition that the distance k (FIG. 20) between the end faces 84 and 85 is greater than the distance n between the end face 54a of the step 54 and the guide pin 51. For the distances between the end faces 54a of the other steps and the same applies to the other pins 51.

After all threads 49a-d have been detected in this way, the further procedure is as described in phases 3 and 4.

Variant B can also be combined with variant A.

The method described and the device can also be used for other thread catching devices which, in addition to the sleeves, e.g. are provided on the mandrel itself. Such devices replace the aforementioned catch slots 6.

Such a coil mandrel is e.g. known from US-PS 4106 711 and GB-PS 1562 548.

The third phase proceeds as follows with the bobbin mandrel with the conical thread guide surface 11 and the teeth 12 shown in the patent specifications mentioned:

The thread guide elements 39a-d and 79, respectively, bring the corresponding thread 49a-d to the corresponding surface 11 when pivoting into the position F. Due to the existing thread tension generated by the suction gun, the thread slides on the surface 11 into the area of the teeth 12 and becomes as recorded and cut off as described in the patent specifications.

The position of a surface 11 along the coil mandrel essentially corresponds to the position of a catch slot 6.

Claims (10)

1. A method for introducing threads and the like into a winding device with at least two traversing devices arranged axially next to one another and associated spool sleeves located on a spool, each thread coming from a thread guide above the winding device being taken over by a thread suction device and then by means of this to a thread guide above and placed on individual thread guides below the traversing device and guided outside the traversing area, and that the threads are brought by means of the lower thread guides below the traversing device from a starting position at the outer end of the bobbin mandrel into an area in front of a thread catching means of the corresponding bobbin tube and then at the same time Detection of all threads, these are guided into the catching means at the same time and then wound up, characterized in that the threads (49a-d) advance when moving from the outer end of the bobbin mandrel (4) the corresponding catching means (6) are taken over individually by means of pivotable thread guides (41) and are held in an intermediate position by the pivoting thread guides (41) before being caught by the catching means (6) at the same time, and the threads (49a-d) are in this intermediate position are held exactly in front of the fishing gear (6). 2. Device for introducing threads and the like into a winding device with at least two traversing devices arranged axially next to one another and associated bobbin sleeves located on a bobbin mandrel, each of which is assigned a thread catching means. e.g. a catch slot, as well as with a thread guide bar above the traversing device and per thread a thread guide pivotable against the bobbin sleeves, and with a device pivoting the thread guide together against the sleeves, characterized in that the thread guide bar (8) (in a known manner) in such a way It is movable that the thread (49) is guided in a working position of the guide bar (8) outside the action area C of the traversing device, and that below the guide bar (8), hereinafter referred to as the first guide bar, a second one provided with guide notches a rest position in a working position movable guide bar (16) is provided, the number of notches (27a-d) corresponds to the number of threads (49a-d) to be wound, that the threads (49a-d) on the one hand by the pivotable thread guides (41) and on the other through the guide notches (27a-d) of the second guide bar (16) which is in the working position i n can be guided in an intermediate position such that they are seen essentially perpendicularly, in the viewing direction perpendicularly to the bobbin axis, and are guided exactly in front of the corresponding catching means (6), that in addition a guide means (48) is provided on which the threads, in a starting position of the Guide means, which can be guided individually at the outer end of the bobbin mandrel (4), and on which the pivotable thread guides (41) can be guided from their starting position within their pivoting range in such a way that they can be guided with this guide means into the winding machine and in front of the catching means (6) Threads (49a-d) can be taken over by the pivotable thread guide (41) and can be guided into the intermediate position mentioned, as well as the pivotable thread guide (41) by means of the device device for joint pivoting against the sleeves (5) are also pivotable into the starting position. 3. Device according to claim 2, characterized in that the means for guiding the thread guide and the threads is a guide rail (48) which can be displaced essentially parallel to the spool mandrel axis and which has steps (54) on the one hand at the end substantially opposite the free end of the spool mandrel. provided and a thread guide pin (51) is provided per step. 4. Device according to claims 2 and 3, characterized in that the thread guide (41) when pivoting from the starting position on a longitudinal side of the rail (48) when moving the rail (48) in the machine and thus when inserting the threads (49a -d) can be guided into the winding device in such a way that the threads (49a-d) located in front of the corresponding catching means (6) can be detected by the thread guides (41) by pivoting the thread guides (41) via the corresponding step (54). 5. Device according to claims 1 and 4, characterized in that the pivoting device contains a rotatable and drivable mounted hollow shaft (32) for receiving a shaft (31) rotatably and drivably mounted therein, and means for pivotably receiving the thread guides (41 ) and means for pivoting the thread guides (41) into the starting position D, into the intermediate position E and into a position in which the threads (49a-d) guided by the guide notches (27a-d) and the pivotable thread guides (41) the catching means (6) can be caught, hereinafter referred to as thread catching position F. 6. The device according to claim 5, characterized in that the means for pivotally receiving the thread guide (41) comprise a rotatable and drivable sleeve (35) on the hollow shaft, which is connected to the thread guide (41) by means of a rod (40) . 7. Device according to claims 5 and 6, characterized in that the means for pivoting the thread guide (41), the shaft (31) and the hollow shaft (32) and a with the hollow shaft and the sleeve (35) connected spring (36) and are an entraining mandrel (47) anchored in the shaft (31), which is non-positively connected to the bush (35) by means of a guide slot (71). 8. The device according to claim 5, characterized in that the means for pivotally receiving the thread guide (41) comprise a spring (36), on the one hand with a bolt (76) anchored in the shaft (31) and on the other hand with a thread guide Rod (40) is connected, and that the means for pivoting the thread guide (41) on the one hand this spring (36) and on the other hand the shaft (31) and the hollow shaft (32). 9. The device according to claim 8, characterized in that the pivoting movement of the thread guide (41) by means of spring (76) in the direction facing the sleeves (5) can be limited by a stop (77) anchored in the shaft (31). 10. The device according to claim 5, characterized in that the hollow shaft (32) can be driven such that the thread guide (41) from the intermediate position E into the thread catching position F can be pivoted.

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