EP0286893A1 - Method to secure a yarn, delivered at a constant speed, to a bobbin - Google Patents

Abstract

A thread (6), which is delivered at a constant speed, is first brought into circumferential contact with the winding tube (7). The winding tube has the same direction of movement as the thread in the area of the peripheral contact. Then the thread tension of the thread between the winding tube (7) and the take-off device, e.g. Suction gun (26) greatly reduced. As a result, parts of the thread lie over the circumference of the winding tube, so that they are overwound by the thread running on.

Description

The invention relates to a method according to the preamble of claim 1. This method is known from DE-PS 32 11 603.

If the thread is to be caught on the empty tube of a winding spindle when the thread and the surface speed of the empty tube are in sync, special devices, in particular on the empty tube, are required in order to improve the catching effect and to achieve a catch safety that is acceptable for practical operation, which is more than 99 % must be to arrive. For this reason, it is proposed in US Pat. No. 4,099,679 that the usual circumferential groove of the empty sleeve be equipped with a transverse groove. In general, however, there is the idea - cf. in particular DE-OS 25 24 415 -that a greater catch safety can be achieved in that the thread and surface of the empty tube are in opposite directions.

When spinning man-made fibers it has been found, however, that at thread speeds of more than 4,000 m / min, the safety of catching this method drops dramatically, even with very experienced operators, in a way that suggests that this method cannot be improved, but for these high ones Thread speeds are technically unusable.

The object of the invention is to provide a method for applying chemical fibers to the empty tube of the winding devices at high thread speeds.

The invention is only apparently based on the known method described above, in which the thread and surface of the empty tube are brought into contact with one another in the same direction or in the opposite direction and the thread in a catch groove of the empty tube, that is to say by applying non-positive and positive forces the empty sleeve is clamped. The invention turns away from the idea that these clamping forces must and can be made sufficiently large to increase safety in catching.

The solution to the problem arises from claim 1. Claims 2 to 5 specify advantageous methods for reducing the thread tension or thread speed of the thread between the winding tube and the take-off device.

Claim 5 creates for lossless winding machines, in which two winding spindles are alternately brought into winding operation, a lay-up method that requires only extremely little equipment, but guarantees absolute catching safety and thus lossless operation even at the highest thread speeds.

• Fig. 1 bis 3 die Folgen der Verfahrensschritte anhand eines schematisch im Querschnitt und in der Ansicht gezeigten Ausführungsbeispiels einer Aufspul­vorrichtung;
• Fig. 4, 5 zwei Verfahrensstufen zum Anlegen eines Fadens an eine Leerhülse;
• Fig. 6A, 6B Ausführungen einer Fadenbremse;
• Fig. 7 eine Modifizierung der Verfahrensstufe nach Fig. 5.

The invention is described below using exemplary embodiments. Show it:

• 1 to 3 show the consequences of the method steps on the basis of an exemplary embodiment of a winding device shown schematically in cross section and in view;
• 4, 5 two process stages for applying a thread to an empty tube;
• 6A, 6B embodiments of a thread brake;
• 7 shows a modification of the method step according to FIG. 5.

The winding device consists of the traversing device 1 with reversing thread shaft 2 and traversing thread guide 3. The traversing thread guide 3 is guided back and forth in the grooves 4 of the reversing thread shaft and in the straight guide 5. Through the traversing thread guide 3, the thread 6 is laid on the sleeve 7 to form a package 8. The sleeve 7 is firmly clamped on the winding spindle 9.1. The winding spindle 9.1 is driven with the direction of rotation 10 in a manner not shown. During the winding process, the second winding spindle 9.2 with the sleeve 7 clamped thereon is in the waiting position. Likewise, the auxiliary thread guide 11, which will be described later, is still in the waiting position.

After or shortly before the winding process has ended, i.e. when the bobbin 8 is almost full, the bobbin spindle 9.1 is moved away from the traversing device with the direction of movement 12. Synchronously with this, the winding spindle 9.2 is driven with a drive, not shown, and moved with the empty sleeve 7 stretched in the direction of arrow 14 into the plane of the thread path in the final state shown in FIGS. 2 and 3. For this purpose, the two winding spindles 9.1 and 9.2 are mounted in a carrier 18 which is rotatable about the axis of rotation 19. The thread continues to be guided back and forth by traversing thread guide 3 and is therefore laid on the package of the bobbin 2.

The auxiliary thread guide 11 is now folded into the thread running plane of the thread run 6. The thread runs onto the slope 54 of the auxiliary thread guide 11 and is thereby lifted out of the traversing thread guide 3 and caught in the thread guide slot 56. By moving the auxiliary thread guide in the direction of arrow 16 - as shown in FIG. 3 - the thread is brought out of the area of the bobbin length H, namely into the normal plane of the catch slot 17 provided in each sleeve 7. This axial movement falls the thread, which was still wound up on the full cheese 8 on the chuck 9.1, down from the cheese, so that it is now only wound on the sleeve 7 of the chuck 9.1.

In contrast to the known method cited, the thread is deliberately thrown off the full bobbin 8 when it is put on. As a result, the winding speed of the thread is reduced in accordance with the diameter ratio between the sleeve 7 and the full bobbin 8. At the same time, the wrap around the empty sleeve and therefore also the entrainment by the empty sleeve is increased. To increase the entrainment, it may also be expedient to provide a thread catch notch 17 on the empty tube. The thread catch notch also exerts lateral clamping forces on the thread. All of these events and measures help to ensure that the thread between the winding spindle 9.2 with the empty tube and the winding spindle 9.1 swings. However, since the thread - as can be seen from the cross section of FIG. 3 - already wraps the empty tube 7 on the chuck 9.2 with a considerable wrap angle and the winding spindle 9.2 runs faster than the winding spindle 9.1, the thread now forms a winder on the empty tube 7 It is thereby carried along by the empty tube 7, the surface speed of which, in terms of amount and direction, is equal to the thread speed. As a result, the thread tears between the winding spindle 9.1 and 9.2 since the surface speed of the cheese 8 is equal to the thread speed, but not the surface speed of the sleeve 7 on the winding spindle 9.1, on which the thread is now wound.

It should be noted that in the method described, the thread has indeed also been placed in a catch slot 17 on the empty tube of the winding spindle 9.2. This promotes winder formation. This can happen in particular at lower speeds between 3,000 and 5,000 m / min Thread speed may be appropriate. With an increase in the thread speed, on the other hand, the tendency for winder formation increases so much that the thread catching groove can be dispensed with from a limit to be determined. As I said, this limit depends on the thread speed. However, it is also determined by the size of the empty tube and the nature of the thread. In particular, chemical threads, which consist of a very large number of individual filaments with very low filament titers, are more prone to winding than chemical threads with only a few thick individual filaments.

A very special advantage of this method should also be pointed out: with all lossless winding machines, in which the thread is alternately wound on two winding spindles, there is the problem that the thread torn from the full bobbin is still thrown around by the outgoing full bobbin and at the same time strikes the new coil. This leads to damage to the new bobbin to be formed or even to the interruption of the winding process due to the thread end being flung around. This disadvantage is avoided here, since the torn end of the thread is located on the very small diameter of the empty tube and therefore does not protrude beyond the surface of the full package 8.

FIGS. 4 to 6 show a further exemplary embodiment with a winding machine which has only one winding spindle 9.

The thread is guided from the head thread guide 21, which forms the tip of the traversing triangle, to the traversing device 1. The traversing device 1 consists of two oppositely rotating vanes 37 and 38 and a guide ruler 39 DE-35 16 475 shown. Beneath the traversing device 1 is the auxiliary thread guide 11, which essentially corresponds to the embodiment according to the exemplary embodiment of FIGS. 1 to 3. The coil formed on the winding spindle 9 and the empty sleeve 7 stretched thereon is driven in operation by the contact roller or drive roller 20 on its circumference. There is also provided an axle drive motor, not shown, through which the winding spindle 9 is driven directly. Furthermore, the winding machine has a swivel arm 32 which can be swiveled about swivel axis 33 and carries a thread guide 34 (brake thread guide) on its other free side. The swivel axis is parallel to the winding spindle. In addition to its pivoting movement, the pivoting arm 32 can carry out an axial movement parallel to the winding spindle 9.

4 shows the bobbin change, namely the application of a new thread to the empty tube 7. The winding spindle 9 is in a changing position in which it is not in contact with the contact roller 20. The winding spindle is driven by its final drive motor. The thread is lifted out of the traversing device 1 behind the head thread guide 21 by the auxiliary thread guide 11, so that it is not moved back and forth. The thread is separated from the full bobbin (not shown) and is drawn off by the suction gun 31. It is guided so that its direction of movement coincides with the direction of movement of the empty tube in the area in which the thread has contact with the empty tube. The head thread guide 21 and the auxiliary thread guide 11, the brake thread guide with groove 35 (FIG. 6) and also the thread suction gun 26 are positioned axially so that the thread runs in the end region of the empty tube 7. A thread feed slot can also be located in the empty tube in this end region.

Now - as shown in Fig. 5 - the swivel arm is pivoted with the indicated direction of movement. The brake thread guide 34 bypasses the empty tube 7 between the winding spindle 9 and the suction gun 26. As a result, the wrap angle increases both on the empty tube and on the brake thread guide 34. This larger wrap already makes the thread on the one hand by the winding spindle 9 or empty tube 7 taken with reduced slip and on the other hand braked on the brake thread guide 34. The result is that the thread swings between the empty sleeve 7 and the brake thread guide 34 and thereby forms a winder.

A different design and arrangement of the pivot point 33 with the pivot arm 32 and the pivot thread guide 34 can - as shown in FIG. 7 - achieve a wrap angle of the thread on the empty tube 7 of approximately 270 ° or more. The thread suction gun 26 is held such that the thread is guided between the brake thread guide 34 and the suction gun 26 without touching the empty sleeve 7. This strong wrapping of the empty sleeve also results in a large wrapping and braking effect of the thread on the brake thread guide 34. In addition, the thread is already very close to the piece of thread that runs towards the empty tube 7. If the thread now swings between the empty tube 7 and the brake thread guide 34, there is a high probability that the folding piece of thread 13, which tends to lie against the empty tube, will be wound under the incoming thread. This is the typical process of winder formation, which is used here to safely catch the thread on the empty tube 7.

In order to increase the braking effect of the brake thread guide 34, the brake thread guide has a thread running groove 35 with different friction properties. In a peripheral area with a relatively small central angle, the Thread running groove a little friction. The thread lies in this circumferential region 31 as long as it loops around the brake thread guide only at a slight angle. The peripheral region 31 is arranged so that it first comes into contact with the thread during the pivoting movement of the pivot arm 32. A cutting notch 36 adjoins the peripheral region 31. This cutting notch is crescent-shaped and extends with increasing and then further decreasing depth from one end of the peripheral region 31 to the other. The cutting notch 36 thus extends over a central angle into which the thread gets when the swivel arm 32 and the brake thread guide 34 reach the outermost swivel position shown in FIG. 5. Because the thread runs into the cutting notch, a very strong, lateral braking force is exerted on it which, depending on the design of the cutting notch, can go so far that the thread breaks off or is cut.

As a result, the clapping of the thread between the swivel thread guide 34 and the empty tube 7 is still promoted, so that the intended winder formation on the empty tube occurs safely. The entanglement can also be promoted in that the empty tube has a thread catch slot on its circumference. If the head thread guide 21, the auxiliary thread guide 11, the running groove 35 on the brake thread guide 34 and the suction gun 26 are positioned axially such that the thread runs into the thread catch notch of the empty tube, the thread catch notch exerts a lateral clamping force on the thread. As a result, the thread is conveyed very strongly and almost positively with increasing wrapping of the empty tube 7, so that there is no more slip on the empty tube 7. The tensile force exerted by the empty tube 7 on the thread is thereby increased and the tensile force between the swivel thread guide 34 and the empty tube 7 is correspondingly reduced.

REFERENCE SIGN LISTING

1 traversing device
2 reverse thread shaft
3 traversing thread guides
4 grooves
5 straight guidance
6 threads
7 sleeve
7.2 Empty sleeve
8 cheese
8.1 full spool
9.1 winding spindle
9.2 winding spindle
10 direction of rotation
11 auxiliary thread guides
12 translational direction of movement (arrow) of the winding spindle 9.1
13 thread piece
14 translational direction of movement (arrow) of the winding spindle 9.2
15 translatory direction of movement (arrow) of the winding spindle
16 Direction of movement of the auxiliary thread guide
17 catch slot
18 carriers
19 axis of rotation
20 contact roller
21 fixed thread guides
22 direction, arrow
23 lifting plate
24 direction of movement
25 catch notch
26 suction device, suction gun
27 scissors
28 Direction of movement of thread guide 21
29 axial movement
30 swiveling movement
31 peripheral area
32 swivel arm
33 pivot point
34 Swivel thread guide
35 thread running groove
36 notch
37 wings, driving arm
38 wings, driving arm
39 Ruler
40 gearbox
41
42 rotor
43 rotor
44
45 center point
46 center point
47 Direction of rotation
48 Direction of rotation
49
50
51
52
53
54 Start-up level, start-up slope, slope
55 binding bead
56 thread guide slot
57 thread plane
58 Bottom of the thread guide slot

Claims (6)

1. Procedure
to apply a thread delivered at a constant speed to a winding tube which is clamped on a rotating winding spindle, in which the delivered thread is drawn off by a take-off device and brought into peripheral contact with a partial circumference of the winding tube in such a way that the peripheral speed of the winding tube is on the part circumference touched and the thread speed is rectified, and the thread is caught by the winding tube and severed between the winding tube and the take-off device,
characterized in that
after the thread (6) has been brought into circumferential contact with the winding tube (7), the thread tension or speed of the thread between the winding tube or thread speed of the thread between the winding tube and take-off device (suction gun 26, winding spindle 9.2 with full bobbin 8) is reduced in such a way,
that the thread forms a winder on the bobbin tube (7) and is thereby caught. 2. The method according to claim 1,
characterized in that
the thread tension or thread speed is reduced in that the pulling force of the pulling device is reduced in such a way that the thread slips. 3. The method according to claim 1,
characterized in that
the thread between the winding tube and take-off device is subjected to the action of a thread brake (35, 36). 4. The method according to claim 3,
characterized in that
the thread between the bobbin and take-off device is deflected in such a way (brake thread guide 34) that it is braked by the deflection friction. 5. The method according to claim 4,
characterized in that
the thread between the bobbin and take-off device is deflected such that the thread first wraps around the bobbin with a wrap angle of more than 180 °, preferably more than 270 °, and then deflected and guided to the take-off device without touching the bobbin case. 6. The method according to claim 1,
characterized in that
the thread is alternately wound on one of two winding spindles (9.1, 9.2), which winding spindles are moved alternately into a predetermined operating position,
that to change the thread from the bobbin with the full bobbin (8) to the bobbin (9.2) with the empty bobbin (7), the latter bobbin is brought into a feed position, the feed position - in the thread running direction - essentially in front of the bobbin the full bobbin and on the same side of the thread in such a way that the common axial plane of the two bobbin spindles is not penetrated by the thread run,
that the thread is lifted out of the traversing device (1),
that the thread between the winding spindle (9.2) with the empty tube (7) and the winding spindle with the full bobbin (8) is drawn out in a loop such that it wraps around the partial diameter of the empty tube (7),
that the thread between the empty tube (7) and the full bobbin (8) is guided axially such that the thread falls off the full bobbin and is wound on the bobbin tube (7.1) of the full bobbin (8).

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