AT519199A1 - METHOD AND DEVICE FOR WINDING A FIBROUS WEB - Google Patents

Abstract

The subject of this invention is a process for the continuous winding of a fibrous web, in particular a paper or tissue web. The web is guided over a carrier drum (29) and subsequently wound on a winding shaft (4). The winding shaft (4) is held in the primary winding phase by pivotable primary arms (3) and then transferred to secondary arms. According to the invention, the winding shaft (4) is driven in the primary winding phase and in the secondary winding phase by the same pivotable drive unit (1). The subject of this invention is also an apparatus for carrying out the method according to the invention.

Description

METHOD AND DEVICE FOR WINDING A FIBROUS WEB

The subject of this invention is a process for the continuous winding of a fibrous web, in particular a paper or tissue web. The web is guided over a carrier drum and subsequently wound up on a winding shaft. The winding shaft is held in the primary winding phase of pivotable primary arms and then transferred to secondary arms and finished in a secondary winding phase.

The subject of this invention is also an apparatus for carrying out the method according to the invention.

Such a device is described for example in EP 1 225 142 A. The winding shaft (empty drum) is inserted via a lowering device in the primary arms and clamped vertically above the rotating carrier drum.

A geared motor is then coupled on the driver's side FS to the winding shaft to drive it during the primary winding phase. The primary arms are now rotated with a pivoting device as long as the axis of the carrier drum until the rotating winding shaft touches on this. The winding shaft takes over the paper web and starts to wind up and thereby increases its diameter. The primary arms are now further pivoted about the axis of the carrier drum until the primary arms come in a horizontal position. The paper roll touches during the winding process with its circumference or with a peripheral position always the carrier drum. The thickness of the paper roll increases continuously. Therefore, the outer part of the primary arms moves telescopically outward. Finally, the winding shaft is placed on the horizontally displaceable secondary arms and coupled with another geared motor on the drive side TS, which continues to drive the winding shaft in the secondary winding phase. During the secondary winding phase, the secondary arms move away from the carrier drum. The gearmotor arranged on the driver side is disengaged and the primary arms are swiveled up to accommodate a new winding shaft.

As soon as the paper roll has reached the desired size (full tambour) in the secondary winding phase, it is pulled away from the carrier drum, the new winding shaft is placed on the carrier drum by the primary arms and the fibrous web is wound on the new winding shaft. After the ejection of the finished roll of paper from the secondary arms, these move back to the carrier drum and take over the new winding shaft of the primary arms.

This conventional winding method works well in practice, but requires a rather complex construction of the winding device. In particular, the arrangement of geared motors on the driver's side and on the drive side is disadvantageous.

The invention is therefore based on the object to provide a method in which the winding shaft is driven both in the primary and in the secondary winding phase, which, however, can be carried out more cost-effectively and easier to maintain.

This object is achieved by a method according to claim 1. So a method for continuous

Winding a fibrous web, in which the winding shaft is driven in the primary winding phase and in the secondary winding phase of the same pivotable drive unit.

Thus, only one engine and one transmission are required for driving the winding shaft. On the one hand, this leads to cost savings and, on the other hand, it is no longer necessary to provide a drive for the driver and drive side. This leads to a space saving. Likewise, a retrofitting of existing systems without major intervention in the existing scooter is possible. The existing primary arms or secondary arms / slides can be maintained. It would also be conceivable to use a direct drive (torque motor) as a pivotable drive unit, thus the transmission could be saved.

Preferably, the pivotable drive unit is decoupled towards the end of the secondary winding phase of the winding shaft, swung up and coupled with a new inserted in the primary arms winding shaft. The last minutes of the secondary winding phase can also be finished without separate drive of the winding shaft, since the necessary drive power can also be provided by the driven carrier drum.

It is advantageous if the winding shaft is brought to machine speed with a spool ram before it is coupled to the drive unit. A Tambouranwurf is a small drive unit, the empty winding shaft (empty drum) on

Machine speed can accelerate. This shortens the time span during which the winding shaft is not directly driven in the secondary winding phase.

The subject of the invention is also an apparatus for carrying out the method according to the invention.

This device for continuously winding a fibrous web on a driven winding shaft has a carrier drum, pivotable primary arms and secondary arms for supporting the winding shaft. The winding shaft is driven on the primary arms and on the secondary arms by the same drive unit.

Preferably, the drive unit has a motor and a transmission, which are pivotable in synchronism with the primary arms by means of a pivoting frame. The swing frame can be coupled to the primary arms.

If the swing frame is mounted separately from the primary arms and only selectively coupled, the primary arms and the swing frame with the drive unit can be pivoted independently. As a result, the primary arms can already swing up to accommodate a new winding shaft, while the drive unit still drives the almost finished wound winding shaft in the secondary winding phase. Only shortly before the railroad transfer to the new winding shaft, the drive unit pivots high and coupled in the preferably already accelerated by a tambouranwurf empty bobbin.

It is advantageous if the drive unit is mounted on a carriage which can be moved on guide rails on the pivoting frame. Thus, the drive unit of the constantly moving away from the carrier drum winding shaft can easily follow.

The exact position of the drive unit on the swing frame can be detected by Linearwegaufnehmer.

In the following two embodiments of the invention will be described with reference to drawings. Show it:

Fig. 1 is a schematic sectional view of a first embodiment of the rewinder according to the invention;

Fig. 2 is a schematic (side view) of Figure 1;

3 shows a section through the coupling device between the gearbox and the winding shaft.

4 shows a section (viewed in the machine direction) through the coupling device between the gearbox and the winding shaft;

Fig. 5 is a schematic sectional view of a second embodiment of the rewinder according to the invention;

Fig. 6 is a schematic (side view) of Figure 5;

Like reference numerals in the respective figures indicate like components, respectively.

Figure 1 and Figure 2 show a first embodiment of the invention. The drive unit 1 consists essentially of a motor 6, a gear 5 connected thereto and the toothed coupling unit 7, which are arranged on a carriage 8. The carriage 8 is slidably mounted on guide rails 9 and is accurately positioned by means of screw jack 10 and a servo motor 11. Instead of the Spindelhubgetriebes also a hydraulic cylinder could be used.

The positioning of the drive unit 1 is such that the center of the transmission output shaft 12 is always centered to the winding shaft 4.

A Linearwegaufnehmer 13 determined at any time the exact position of the drive unit. 1

The drive unit 1, the guide rails 9, the Spindelhubgetriebe 10 and the servo motor 11 are located on a swing frame. 2

In the primary winding phase of the swing frame 2 pivots synchronously with the primary arms 3 on which the winding shaft 4 is mounted. The increase in distance (caused by the diameter increase of the wound winding shaft 4 through the medium to be wound up) is covered by moving the drive unit 1 on the guide rails 9.

The pivoting movement of the pivoting frame 2 can be effected by means of a (for example pressure-controlled) cylinder 18 in order not to additionally load the hydraulic cylinders of the primary arms 3 with the pivoting moment of the pivoting frame 2.

In the secondary winding phase, the swing frame 2 remains in the horizontal position. The diameter increase of the paper roll is covered by the large driving range of the drive unit 1 on the rails 9 during the entire Sekundärwickelphase.

The toothed coupling unit 7 is seated on a separate carriage 20, which is displaceable on guide rails 21 transversely to the machine direction.

By moving the carriage 20 transversely (perpendicular) to the machine direction so the drive pinion 22 engages in the winding shaft bell 23 on or off.

The method of this carriage 20 can be done for example by a pneumatic or hydraulic cylinder 24.

In Figures 1 and 2, the swing frame 2 is rotatably mounted on one side on a pedestal 14 and flanged on the other side directly to the primary arm 3.

The flanging of the driver 15 takes place on any surface of the primary arm. 3

Thus, the flange of the driver 15 can also be done in the pivoting center of the primary arm 3 (as shown in Figure 1), if this is possible with existing or new scooters.

A possible variant, in the retrofitting of a drive unit 1 according to the invention on an existing scooter is the welding of a disk 16 in the middle of the drive-side primary arm 3, there to flange the carrier 15.

Figures 3 and 4 show the gear coupling unit 7 in detail. The drive pinion 22 is mounted on a separate vertical slide 25. To small

Position deviations (center gearbox output shaft 12 to center winding shaft 4) to compensate, the drive pinion 22 is mounted on a separate vertical slide 25.

The vertical slide 25 is slidable on guide rails 26 and is for example via (pneumatic or

Hydraulic) cylinder 27, or centered over air bellows and additionally stabilized.

The position deviation (center drive pinion 22 to center gearbox output shaft 12) is detected by a separate position sensor 28.

The deviation is corrected immediately by position correction of the drive unit 1. The carriage 8 of the drive unit 1 is thus continuously tracked by position correction on the rails 9, so that the vertical slide 25 remains as possible in the middle and thus the shaft offset (center drive pinion 22 to the center of the transmission output shaft 12) remains as low as possible.

The shaft offset is compensated for example by means of a speed-sensitive double crank clutch 19 (Schmidt clutch) or a propeller shaft.

If the deviation (center drive pinion 22 to the middle of the transmission output shaft 12) is too fast or exceeds a preset permissible level, the toothed clutch unit 7 disengages immediately from the winding shaft 4 in order to avoid possible machine damage.

Figures 5 and 6 show a further embodiment of the invention. The primary arms 3 and the swing frame 2 can be moved independently.

The swing frame 2 is rotatably supported on both sides independently on the pedestals 14 and coupled via a driver 15 with the primary arm 3.

The driver 15 can be mechanically coupled to the swing frame 2 and decoupled.

The coupling can take place, for example, via a cylinder 17 actuated by a cylinder.

When winding during the primary winding phase of the swing frame 2 is fixedly coupled via the pin 17 with the primary arm 3 to have exactly the same pivot position.

When winding during the secondary winding phase, it is possible to decouple the swing frame 2 in the horizon position. Thus, the primary arms 3 can swing independently of the swing frame 2. This makes it possible to place a new winding shaft 4 (empty drum) in the primary arms 3 again, while the drive unit 1 still drives the winding shaft 4 on the secondary arms.

By coupling the swing frame 2 with the primary arms 3 ensures that the swing frame 2 pivots completely synchronously with the primary arms 3.

With the rewinder according to the invention different winding sequences can be realized.

Sequence 1:

The drive unit 1 drives the winding shaft 4 during the primary and secondary winding phase.

Only the last 2-3 minutes of the secondary winding phase winds the scooter without directly driven winding shaft. 4

This time is required in order to simultaneously swing up the drive unit 1 with the primary arms 3, to retract the carriage 8 and to couple the drive pinion 22 into a new winding shaft 4 in order to accelerate it to machine speed.

Sequence 2:

The drive unit 1 and the primary arms 3 can be pivoted independently of each other.

The drive unit 1 drives the winding shaft 4 almost during the entire primary and secondary winding phase.

The primary arms 3 are swung up earlier than the swing frame 2.

The last minute of the secondary winding phase winds the scooter without the drive unit 1. This time is needed to also turn up the drive unit 1 and to couple the drive pinion 22 in a new winding shaft 4. This new winding shaft 4 has previously been brought in the primary arms 3 by means of Tambouranwurf on machine speed and the drive unit 1 engages shortly before the Tambourwechsel (changing shaft) in the new winding shaft 4 a.

Sequence 3:

Again, the drive unit 1 and the primary arms 3 can be pivoted independently.

This sequence is possible for scooters, which can also be operated without drive unit 1, because the winding shaft 4 is also driven via the carrier drum 29.

The winding shaft 4 (empty drum 4) is brought in the primary lever 3 by means of Tambouranwurf to machine speed. The drive unit 1 engages at any time during the primary or secondary winding phase. Thus, with the drive unit 1, a drum in the secondary winding phase can be "finished".

The following new winding shaft 4 is then accordingly only from the time by the

Drive unit 1 driven until the drive unit 1 has engaged again. The drive pinion 22 thus already engages in a wound winding shaft 4.

Claims (9)

claims 1. A method for continuously winding a fibrous web, in particular a paper or tissue web, wherein the web is guided over a rotating carrier drum (29) and subsequently wound on a rotating winding shaft (4) and wherein the winding shaft (4) in a primary winding phase is held by pivotable primary arms (3) and then transferred to secondary arms and in a secondary winding phase is further wound, characterized in that the winding shaft (4) in the primary winding phase and in the secondary winding phase of the same pivotable drive unit (1) is driven. 2. The method according to claim 1, characterized in that the drive unit (1) towards the end of the secondary winding phase of the winding shaft (4) uncoupled, swung up and with a new in the primary arms (3) inserted winding shaft (4) is coupled. 3. The method according to claim 2, characterized in that the winding shaft (4) is brought to a Tambouranwurf to machine speed, before being coupled to the drive unit (1). 4. An apparatus for continuously winding a fibrous web, in particular a paper or tissue web, on a driven winding shaft (4) with a carrier drum (29), with pivotable primary arms (3) and secondary arms for supporting the winding shaft (4), characterized in that the winding shaft (4) on the primary arms (3) and on the secondary arms by the same drive unit (1) can be driven. 5. Apparatus according to claim 4, characterized in that the drive unit (1) has a motor (6) and a transmission (5) which are pivotable by means of a pivot frame (2) synchronously with the primary arms (3). 6. Apparatus according to claim 5, characterized in that the pivoting frame (2) with the primary arms (3) can be coupled. 7. The device according to claim 6, characterized in that the pivot frame (2) is mounted separately from the primary arms (3), so that the primary arms (3) and the pivot frame (2) are independently pivotable. 8. Device according to one of claims 5 to 7, characterized in that the drive unit (1) is mounted on a carriage (8) which is movable on guide rails (9) on the pivot frame (2). 9. Apparatus according to claim 8, characterized in that the exact position of the drive unit (1) on the pivot frame (2) via Linearwegaufnehmer (13) is detectable.