EP3934997A1

EP3934997A1 - Driving of a roll slitting machine

Info

Publication number: EP3934997A1
Application number: EP19817691.9A
Authority: EP
Inventors: Ewald Wetschenbacher; Alexander Stengler
Original assignee: Voith Patent GmbH
Current assignee: Voith Patent GmbH
Priority date: 2019-03-05
Filing date: 2019-12-10
Publication date: 2022-01-12
Anticipated expiration: 2039-12-10
Also published as: EP3934997C0; CN113518752A; EP3934997B1; DE102019105485A1; CN113518752B; WO2020177910A1

Abstract

The invention relates to a method and a device for winding a material web (1) onto a winding tube (2) to form a wound roll (3) in roll slitting machines after the longitudinal cutting of a material web (1), which is unwound from a parent roll (4), the parent roll (4) and the wound roll (3) being driven and the web tension between the parent roll (4) and the wound roll (3) being measured. The invention aims to improve the winding result in roll slitting machines by virtue of the fact that, in accordance with the operating state, the driving (8) of the parent roll (4) or the driving (9, 10) of the wound roll (3) is carried out in such a way that the web tensile stress lies in a specified interval.

Description

Slitter winder drive

The invention relates to a method for winding a material web onto a winding tube to form a winding roll in roll cutting machines after longitudinal cutting of a material web unwound from a parent roll, the parent roll and the winding roll being driven.

The invention also relates to a device for winding a material web onto a winding tube to form a winding roll in roll cutting machines after longitudinal cutting of a material web unwound from a parent roll, comprising two axially parallel support rollers for supporting the winding roll with the formation of two winding gaps, the material web in the first winding gap is guided to the winding roll with at least partial looping of the first support roller and the second support roller downstream of the first support roller in the material web running direction is free from being looped by the material web and a drive with a control unit is assigned to each of the mother roll and the first support roller, in particular for carrying out the method.

The invention is explained below in connection with the treatment of a paper web. However, it can also be used accordingly for other railways that are to be handled similarly. These are, for example, but not exhaustively, sheets of cardboard, cardboard, plastic or metal foils.

Paper webs are produced in a paper machine in relatively large widths of up to over 11 m. The production is almost endless. The direction of movement of the goods in the paper machine defines the longitudinal direction for all machines and equipment in the paper mill and the transverse direction in the horizontal plane perpendicular to it.

At the end of the paper machine, the paper web produced is wound onto a winding core in full width. This winding core is replaced cyclically, usually while production is running. The web-wide winding roll produced in this way is usually referred to as the parent roll or full reel. In order to be manageable for a later user, for example a print shop, the paper web wound on a master roll must be cut into several parallel partial webs, the widths of which are suitable for the respective later user. These widths can vary greatly from case to case, so that the division of the paper web is usually carried out according to an individually definable cutting pattern.

The partial webs are then wound up into winding rolls, which are called partial web or finished rolls and which are output together as so-called roll litter. The pattern can be changed from roll to roll. The longitudinal cutting and winding are expediently carried out in a single machine, which is then often referred to as a roll cutting device.

All of the winding devices described above, i.e. those for producing parent rolls as well as those for producing partial or finished rolls, have in common that the web to be wound to form a winding roll forms a winding gap with at least one winding roller on which it is supported or on which it is rests or rests on and which is accordingly referred to as a support or support roller. These winding rollers, which are in direct contact with the winding rollers that are being formed, thus also represent the tools that act directly and by means of which the winding quality can be influenced.

While the main drive of the winding roll is speed-controlled and determines the speed of the winder, the drive of the parent roll is torque-controlled with superimposed web tension control.

In particular, when the unwinding is accelerated and decelerated, there are fluctuations in the web tension, which affects the winding result. The centrifugal mass of the parent roll is of great importance.

The parent roll is relatively inhomogeneous in terms of specific weight, since it is usually wound harder in the core than on the outside. Therefore, the calculation of the flywheel mass and consequently the control of the drive torque when accelerating and braking is very imprecise.

Such machines are described, for example, in DE 30 30 798 A1 and DE 10 2010 039 007 A1. The object of the invention is to improve the winding result in slitting machines.

According to the invention, the object was achieved in that the web tension between the parent roll and the winding roll is measured and, depending on the operating state, the drive of the mother roll or the drive of the winding rolls takes place in such a way that the web tension is within a predetermined interval.

In this way, the fluctuations in the balance of forces in the area between the unwinding and the unwinding can be reduced. The conditions in the winding area are therefore stable and reproducible.

Since changes in the web tension occur particularly strongly during acceleration and braking processes, the drive of the winding rollers should take over the control of the web tension when accelerating and braking the unwinding. The drive of the parent roll determines the line speed. The same is advantageous for crawler gear.

Because of the significantly lower weight of the winding rolls, the influence of the effective flywheel is significantly lower than with the parent roll.

At the production speed of the unwinding, the drive of the parent roll should take over the control of the web tension, as has been usual and proven up to now. The drive of the winding rolls determines the line speed in this operating state.

Depending on the operating status, the parent roll should be driven at times speed-controlled / -regulated and at times torque-controlled / -regulated.

Advantageously, the parent roll should be speed-controlled / -regulated during the crawl speed, when accelerating or when braking the unwinding, and torque-controlled / -regulated at the production speed of the unwinding.

In contrast to this, the winding roll should be driven at least predominantly in a speed-controlled manner. With regard to the device, it is essential that between the master roll and the first support roller there is at least one web tension detecting sensor which, depending on the operating state, can be connected by the machine control to the control unit of the drive of the mother roll or the control unit of the drive of the first support roller.

The invention is to be explained in more detail below using an exemplary embodiment.

In the accompanying drawing, the figure shows a schematic structure of a roll cutting machine.

The preferred embodiment of a roll winding device according to the invention shown in the figure is implemented in connection with a roll cutting device designed as a support roll winding device.

Essential components of this roll cutting device are an unwinding device 15, in which the paper web 1, in its width essentially the working width of a paper machine upstream of the roll cutting device and corresponding to the paper machine (not shown here), is drawn off from a master roll 4, a cutting section 17 in which the paper web 1 is used Production of partial webs in selectable width formats is divided longitudinally according to their running direction and a winding arrangement 16 located in the area of their winding.

The master roll 4 is assigned its own drive 8 with a control unit.

For this purpose, the cutting section 17 usually comprises disk-shaped cutting devices as essential components, which are shown here in the form of upper knives 18 and lower knives 19 that act on one another.

In order to prevent vibrations of the moving material web 1 in the area of the cutting section 17, this area is delimited by deflection rollers 20 in the example shown.

In addition to the two support rollers 5, 6 the at least one winding roll 3 to be wound and the support roller 21 form essential elements of the winding arrangement 16. Although only the end face of a single winding roll 3 is visible in the figure, it is assumed here that in the Image plane extending Y-direction further Winding rolls 3 behind the winding roll 3 shown are located in the winding bed formed from the two support rollers 5, 6.

The core of the winding rolls 3 that form in the course of the winding process consists of a winding tube 2 with which the beginning of a finite section of a partial web of material web 1 is connected and then spanned by continuous winding to form so-called winding layers.

The two axially parallel support rollers 5, 6 serve to support the winding roll 3 with the formation of two winding gaps 11, 12, whereby in the first winding gap 11 the material web 1 is guided to the winding roll 3 with partial wrapping around the first supporting roller 5 and that of the first supporting roller 5 in the web running direction 7 downstream second support roller 6 is free from being wrapped around by the material web 1.

The second carrier roller 6, which forms the second winding gap 12 on the outer circumference of the winding roller 3 in the direction of rotation, is always mechanically coupled to the first carrier roller 5 via the winding roller 3.

A drive 9, 10 with a control unit is assigned to each of the two support rollers 5, 6.

It has proven useful if the first support roller 5 is speed-controlled in the web running direction 7 of the paper web 1 and the second support roller 6 is torque-controlled, the torque control of the second support roller 6 being independent of the influence of the actual value of the speed of the first support roller 5 and the load sharing takes place in such a way that the winding roll 3 is driven at least predominantly with speed control.

To dampen vibrations, the support rollers 5, 6 can have an elastic mounting. Likewise, at least one of the two support rollers 5, 6 can have a coating or sheathing that becomes effective on the material web 1.

In order to ensure a continuous unwinding and winding process with an optimal winding result, it is necessary that the web tension of the material web 1 between the unwinding and the winding up is essentially constant so that no damage occurs to the material web 1. On a non-uniform one Winding errors that can be traced back to web tension can be reflected, for example, in cracks or wrinkles and can also cause corresponding consequential damage.

However, particularly when accelerating and braking, changes in the web tension can occur that are relatively large.

The unwinding and winding process must therefore be adapted to one another.

For this purpose, the drive 8 of the parent roll 4 and the drives 9, 10 of the support rollers 5, 6 are connected to the machine control 14 via their respective control units.

In addition, the web tension of the material web 1 between the master roll 4 and the first support roller 5 is detected by a sensor 13 and transmitted to the machine unit 14.

A controller is understood here to mean the entirety of the functional components required to carry out control and regulation tasks and their links. This includes control devices, regulators, devices for recording actual values, disturbance variables and actuating devices as well as their interconnections.

The purpose of the machine control system 14 is to ensure that, depending on the operating state, the drive 8 of the parent roll 4 or the drive 9, 10 of the winding rolls 3 takes place in such a way that the web tension is within a predetermined interval.

For this purpose, the sensor 13 is connected by the machine control 14 to the control unit of the drive 8 of the master roll 4 or the control unit of the drive 9 of the first carrier roll 5, depending on the operating state for a higher-level web tension control.

In normal operation, i.e. At the unwinding production speed, the drive 8 of the parent roll 4 is torque-controlled with a superordinate web tension control so that the web tension is within a predetermined interval. The drive 9 of the first support roller 5 is only speed-controlled.

In contrast to this, during crawling and when accelerating or braking the unwinding, the drive 9 of the first support roller 5 is speed-controlled with superordinate web tension control, so that the web tension is within a predetermined interval. The drive 8 of the parent roll 4 is only speed-controlled. This means that the master roll 4 is driven at times with speed control and at times with torque control.

During the critical creeping, acceleration and braking, the relevant centrifugal mass is essentially determined by the winding roll 3, which is considerably lighter than the parent roll 4, which minimizes the fluctuations in the web tension.

Claims

1. A method for winding a material web (1) onto a winding tube (2) to form a winding roll (3) in winder after the longitudinal cutting of a material web (1) unwound from a parent roll (4), the parent roll (4) and the winding roll (3) are driven, characterized in that

the web tension between the parent roll (4) and winding roll (3) is measured and, depending on the operating state, the drive (8) of the mother roll (4) or the drive (9,10) of the winding roll (3) takes place in such a way that the web tension is within a specified Interval.

2. The method according to claim 1,

characterized,

that when the unwinding is accelerated or decelerated, the drive (9, 10) of the winding roll (3) takes place in such a way that the web tension is within a predetermined interval.

3. The method according to claim 1 or 2,

characterized,

that the drive (9, 10) of the winding roll (3) takes place in the crawling mode in such a way that the web tension is within a predetermined interval.

4. The method according to any one of the preceding claims,

characterized,

that at the production speed of unwinding the drive (8) of the parent roll (4) takes place in such a way that the web tension is within a predetermined interval.

5. The method according to any one of the preceding claims,

characterized,

that the parent roll (4) is driven at times speed-controlled / -regulated and at times torque-controlled / -regulated.

6. The method according to any one of the preceding claims,

characterized, that the winding roll (3) is driven at least predominantly speed-controlled / -regulated.

7. The method according to any one of the preceding claims,

characterized,

that the parent roll (4) is driven in a speed-controlled / -regulated manner during the crawling speed, when accelerating or braking the unwinding.

8. The method according to any one of the preceding claims,

characterized,

that the parent roll (4) is driven torque-controlled / -regulated at the production speed of the unwinding.

9. Device for winding a material web (1) onto a winding tube (2) to form a winding roll (3) in winder after the longitudinal cutting of a material web (1) unwound from a parent roll (4), comprising two support rollers (5, axially parallel to one another) 6) to support the winding roll (3) with the formation of two winding gaps (11, 12), wherein in the first winding gap (11) the material web (1) is guided to the winding roll (3) with at least partial wrapping around the first support roller (5) and the the first support roller (5) in the web running direction (7) downstream of the second support roller (6) is free from being wrapped by the material web (1) and the parent roll (4) and the first support roller (5) each have a drive (8, 9) Control unit is assigned, in particular for performing the method according to one of the preceding claims,

characterized,

that between the master roll (4) and the first carrier roll (5) at least one sensor (13) which detects the web tension is arranged which, depending on the operating state, is transmitted by the machine control (14) to the control unit of the drive (8) of the master roll (4) or the control unit of the drive (9) of the first support roller can be connected.