EP4378866A1 - Spreading device for a machine for winding and wrapping a web - Google Patents

Abstract

The invention relates to a spreader device, a machine and a method for winding and rewinding a material web and/or partial material webs, preferably a paper web, a cardboard web or a tissue web, from a parent roll onto at least one winding core to form a winding roll (2), wherein the winding roll (2) is supported by a first (1) and a second (4) support drum and the material web is guided between the parent roll and the winding roll with at least one deflection roller (5) and at least one spreader device (6, 10). According to the invention, the spreader device (10) comprises a spreader bar (11) and a spreader roller (12), which are fastened to a common cross member (15), and that the spreader bar (11) and the spreader roller (12) are each mounted so as to be movable in the direction of the material web independently of one another and at least one air boundary layer is formed between the material web (M) and the spreader device (10) in such a way that the material web (M) is guided without contact. and/or stretched out

Description

The invention relates to a spreading device, a machine and a method for winding and rewinding a material web onto a winding core to form a winding roll in a roll cutting machine after longitudinally cutting a material web unwound from a parent roll, in particular a paper, cardboard or tissue web, preferably with a basis weight of less than 100 g/m ² , wherein the winding roll is supported by a first and a second support drum and wherein the material web is guided between the parent roll and the winding roll via at least one deflection roller and at least one spreading device.

The invention is explained below in connection with the treatment of a paper web. However, it can also be used for other material webs that are handled in a similar way. These include, for example, but are not limited to, fibrous webs made of paper, cardboard, paperboard or tissue.

Paper webs are produced in relatively large widths of up to over 11 m in a paper machine. Production is virtually endless. The direction of the paper machine's fabric travel defines the longitudinal direction and, in the horizontal plane perpendicular to this, the transverse direction for all machines and equipment in the paper mill.

At the end of the paper machine, the paper web produced is wound onto a winding core in its full width. This winding core is replaced cyclically, usually during ongoing production. The web-wide winding roll created in this way is usually referred to as a master roll or full reel.

In order to be manageable for a later user, such as a printing company, 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 the paper web is usually divided 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 issued together as a so-called roll roll. The cutting pattern can be changed from roll roll to roll roll. The longitudinal cutting and winding are conveniently 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 master rolls as well as those for producing partial web or finished rolls, have in common that the web to be wound up to form a winding roll forms a winding gap with at least one winding roller on which it is supported or on which it rests or rests and which is accordingly referred to as a support or carrier roller. These winding rollers, which are in direct contact with the winding rolls being formed, therefore also represent the directly acting tools by means of which the winding quality can be influenced.

The document EP1605205 A1 discloses a device for guiding a running material web. The disclosed device is a guide element which enables a predominantly contactless guidance and deflection of the material web and enables longitudinal folds in a running material web to be avoided.

The document EP0340578 A1 discloses a device for eliminating the tendency of a material web to roll in the direction of travel. This involves a hard rod which is arranged in the moving material web so that the material web is deflected by this rod at more than 120 degrees and the material web has a tendency to roll in the longitudinal direction, counter to the tendency to roll resulting from the subsequent winding in a winding roll. The contact between the material web and the hard rod is made directly, and the hard rod itself is mounted in a rotating bearing bed with air injection.

The solutions mentioned so far have a number of disadvantages.

Material webs with low basis weights, especially basis weights of less than 100g/m ² , tend to have increased wrinkle formation in the material webs that are still to be wound up or have been wound up when they are wound up and rewound after longitudinal cutting compared to heavier material webs. To avoid this, spreader devices are arranged immediately before the material web is wound up into a winding roll or in front of the first support roller.

The usual spreader rollers used as a spreader device are set in rotation to create a spreader effect in the material web through contact (frictional contact) with the moving material web itself. With and through material webs with a low basis weight, there is usually less contact with the moving material web, which is not enough to set the spreader roller in rotation sufficiently to create a spreader effect. This effect is usually counteracted by a greater wrap of the material web around the spreader rollers, but there is an increased tendency for the material web to tear off and also increased wrinkles, preferably longitudinal wrinkles, to form, particularly with low basis weights.

As an alternative, conventional, rigid or rotating spreader bars with direct contact between the bar and the material web can be used. However, in recent times, high speeds of around 2500 m/min are being aimed for when winding and rewinding, which can lead to an increased tendency to tear and increased abrasion of the material web in the event of direct contact. Direct contact with the material web leads to excessive wear on the material web being wound, which is not desirable in terms of quality, and at the same time the abrasion is deposited as a large amount of dust in the surrounding components of the device and the machine. This not only significantly increases the cleaning effort, but also increases the safety risk of fire and explosions due to the increased dust deposits.

The object of the invention is to improve a spreader device in such a way that a quick change with a spreader device between material webs with low, preferably low basis weights less than or equal to 100 g/m ² , and high basis weights is possible.

A further aspect of the invention is to improve the spreading device for material webs with low basis weights, preferably low basis weights of less than or equal to 100 g/m ² , so that the material web can be wound up or wrapped without creases and with reduced or no abrasion of the material web. This means that creases in the material web are eliminated or the formation of creases in the material web is avoided and no or only a small amount of dust occurs.

The object is achieved according to the invention by a spreader device according to independent claim 1, a machine comprising the spreader device according to the invention according to claim 8 and a method for operating the spreader device according to claim 9. Further advantageous embodiments of the present invention can be found in the subclaims
The spreader device is characterized in that it comprises a spreader bar and a spreader roller, and that these are fastened to a common cross member, and that the spreader bar and the spreader roller are each mounted so as to be movable essentially in the direction of the material web, independently of one another.

In an alternative embodiment, the spreading device is characterized in that the spreading rod comprises a base body, at least one air supply line and at least one nozzle module, and that the at least one nozzle module can be connected to the base body and the air supply line.

In an alternative embodiment, the spreading device is characterized in that the at least one nozzle module comprises a nozzle base body, at least one nozzle outlet opening and at least one nozzle channel, and that the at least one nozzle outlet opening and the at least one nozzle channel are arranged and shaped such that a substantially constant outlet pressure is set in an air outlet stream.

In an alternative embodiment, the spreading device is characterized in that the at least one nozzle module comprises at least ten nozzle outlet openings, and that the extension of the at least one nozzle in the length direction is less than or equal to 150 mm, in the width direction is less than or equal to 20 mm and in the height direction is less than or equal to 20 mm.

In an alternative embodiment, the spreader device is characterized in that the spreader rod is arranged such that an air outlet flow of the at least one nozzle module is directed directly onto the material web, so that an air boundary layer is formed between the spreader rod and the material web.

In an alternative embodiment, the spreader device is characterized in that the spreader rod is arranged such that an air outlet flow of the at least one nozzle module is directed onto a surface of the rotating spreader roller in contact with the material web, so that an air boundary layer is formed between the material web and the surface.

In an alternative embodiment, the spreader device is characterized in that the spreader bar or the spreader roller is wrapped around the material web at an angle of less than or equal to 45°, preferably less than or equal to 30°, in particular less than or equal to 20°.

The machine is characterized in that it comprises at least one spreading device according to the invention.

The method is characterized in that at least one air boundary layer is formed between the material web and the spreader device by the spreader device, such that the material web is guided and/or spread without contact.

In an alternative embodiment, the method is characterized in that the air boundary layer is formed between the material web and a spreader bar included in the spreader device.

In an alternative embodiment, the method is characterized in that the air boundary layer is formed between the material web and a spreader roller included in the spreader device.

1. a) eine in der Breitstreckvorrichtung umfasste Breitstreckstange für Flächengewichte kleiner gleich 100 g/m² der Materialbahn eine Luftgrenzschicht ausbildet und in Eingriff mit der Materialbahn gebracht wird, derart, dass die Breitstreckstange die Materialbahn führt und/oder breitstreckt, und dass
2. b) eine in der Breitstreckvorrichtung umfasste Breitstreckwalze in Eingriff mit einer Materialbahn gebracht wird, derart, dass die Breitstreckwalze für Flächengewichte größer 100 g/m2 die Materialbahn führt und/oder breitstreckt.

In an alternative embodiment, the method is characterized in that

1. a) a spreader bar included in the spreader device for basis weights of less than or equal to 100 g/m ² of the material web forms an air boundary layer and is brought into engagement with the material web in such a way that the spreader bar guides and/or spreads the material web, and that
2. b) a spreader roller included in the spreader device is brought into engagement with a material web such that the spreader roller guides and/or spreads the material web for basis weights greater than 100 g/m2.

1. a) eine in der Breitstreckvorrichtung umfasste Breitstreckwalze in Eingriff mit einer Materialbahn gebracht wird, und dass
2. b) eine in der Breitstreckvorrichtung umfasste Breitstreckstange, für Flächengewichte kleiner gleich 100 g/m² der Materialbahn, eine Luftgrenzschicht zwischen der Breitstreckwalze und der Materialbahn ausbildet, derart, dass die Breitstreckwalze mit einem indirekten Kontakt über die Luftgrenzschicht die Materialbahn führt und/oder breitstreckt, und dass
3. c) die Breitstreckwalze für Flächengewichte größer 100 g/m²der Materialbahn, die Materialbahn mit einem direkten Kontakt führt und/oder breitstreckt und die Luftgrenzschicht abgeschaltet ist.

In an alternative embodiment, the method is characterized in that

1. a) a spreader roller included in the spreader device is brought into engagement with a material web, and that
2. b) a spreader bar included in the spreader device, for basis weights of less than or equal to 100 g/m ² of the material web, forms an air boundary layer between the spreader roller and the material web, such that the spreader roller guides and/or spreads the material web with indirect contact via the air boundary layer, and that
3. c) the spreader roller for basis weights greater than 100 g/m ² of the material web, guides and/or spreads the material web with direct contact and the air boundary layer is switched off.

The invention expressly also extends to such embodiments which are not given by combinations of features from explicit references to the claims, whereby the disclosed features of the invention - as far as this is technically reasonable - can be combined with one another.

Corresponding elements of the embodiments in the figures are provided with the same reference numerals. The functions of such elements in the individual figures correspond to one another unless otherwise described and unless contradictions arise. A repeated description is therefore omitted.

It is also pointed out that the differing features of the embodiments shown can be exchanged for one another and combined with one another. The invention is therefore not limited to the combinations of features shown in the embodiments shown.

Further features and advantages of the invention will become apparent from the following description of preferred embodiments with reference to the drawings.

• Figur 1 zeigt eine Draufsicht einer Anordnung einer Breitstreckvorrichtung in einer Maschine zum Auf- und Umwickeln einer Materialbahn.
• Figur 2a -b zeigen eine Seitenansicht der Figur 1, mit unterschiedlichen Betriebspositionen einer Breitstreckvorrichtung.
• Figur 3a -c zeigen eine Ausführung einer in einer Breitstreckvorrichtung umfassten Breitstreckstange.
• Figur 4 zeigt eine Seitenansicht einer Anordnung einer Breitstreckstange und einer Breitstreckwalze in einer Breitstreckvorrichtung.
• Figur 5a -c zeigen verschiedene Ansichten einer in einer Breitstreckstange umfassten Düse.

In the following, the invention is explained with reference to the following figures.

• Figure 1 shows a plan view of an arrangement of a spreader device in a machine for winding and rewinding a material web.
• Figure 2a -b show a side view of the Figure 1 , with different operating positions of a spreading device.
• Figure 3a -c show an embodiment of a spreader bar included in a spreader device.
• Figure 4 shows a side view of an arrangement of a spreader bar and a spreader roller in a spreader device.
• Figure 5a -c show different views of a nozzle enclosed in a spreader bar.

The figures are given in a common coordinate system, where MD is the machine direction or the main direction of movement of the web, CD is the transverse direction of the web or the machine, and z is the third axis in a right-handed coordinate system.

The Figure 1 shows a schematic and simplified representation of a machine 1 for winding and rewinding a material web M or several partial material webs M. The material web M is unrolled from a master roll or a spool by an unwinding device (not shown).

In an alternative embodiment, the material web M coming from the master roll is cut into several material sub-webs in a longitudinal cutting device (not shown) and fed further.

The material web M or the partial material webs M move in a running direction L which is indicated by directional arrows. The material web M is guided from the parent roll over at least one deflection roller 5 and deflected. The material web M is then guided over at least one spreading device 10 to a first carrier drum 3 and over this and wound onto at least one winding core to at least one winding roll 2. The winding roll 2 is supported and driven by the first carrier drum 3 and a second carrier drum 4, forming at least one winding gap. In the case shown, the material web M is cut into five partial material webs and wound onto five winding cores to form five winding rolls 2. It can be wound from at least one winding roll up to any number of winding rolls.

In an alternative embodiment, the machine 1 shown can comprise a second spreading device 6 arranged in front of the first spreading device 10. This is advantageous if the desired spreading cannot be achieved by a spreading device alone. A spreading device can be designed, for example, as a spreading bar or a spreading roller.

The at least one spreader device 10 further comprises at least one spreader bar 11 and one spreader roller 12, which are adjustably attached to a common cross member 15. Depending on the type of material web to be processed, this arrangement allows the advantages of a spreader bar for material webs with low basis weights and the advantages of a spreader roller for higher basis weights to be used together.

Advantageously, depending on the requirements of the material web to be processed, the spreader bar and/or the spreader roller can be brought into engagement with the material web. This can preferably be done fully or semi-automatically by an adjustment device which is connected to the machine's control system.

This arrangement advantageously allows an expanded range of material web properties, for example very light and very heavy basis weights, to be wound and rewound using a spreader device without complicated changeover work. This arrangement advantageously allows creases that have formed, in particular longitudinal creases, to be removed from the material web M or longitudinal creases to be avoided by the spreader device 10.

Another advantage is the joint arrangement on a common crossbeam 15, which can reduce manufacturing costs and complexity.

The adjustment device (not shown) is suitable for bringing either the spreader bar 11 or the spreader roller 12 into engagement with the material web M, depending on the requirement, and it is also advantageously conceivable to bring both the spreader bar 11 and the spreader roller 12 into engagement with the material web at the same time.

The Figure 2a and 2b show a side view of the arrangement Figure 1 with different operating positions of the spreader device 10 with the enclosed spreader bar 11 and the spreader roller 12, which are adjustably attached to a common cross member 15. An arrangement of the spreader bar 11 in front of the spreader roller 12 is shown, but it is also conceivable that the spreader bar 11 is arranged after the spreader roller 12. The spreader roller 12 extends at least over the entire transverse direction CD of the material web M.

Figure 2a shows the spreader device 10 with the spreader roller 12 in working position 121. The spreader roller 12 is mounted on the crossbeam 15 so that it can move or adjust in the direction of the material web M. The double arrow, also designated 121, indicates the possible direction of movement of the spreader roller 12 or of an included adjustment device. The working position 121 is characterized by the fact that the spreader roller 12 is in direct or indirect contact with the moving material web M, see also the following description of Figure 4 .

Furthermore, the Figure 2a the spreader bar 11 in a waiting position 112, the spreader bar 11 is mounted on the cross member 15 so that it can move or adjust in the direction of the material web M. The double arrow marked 112 indicates the possible direction of movement of the spreader bar 11 or the included adjustment device.

The material web M wraps around the spreader roller 12 at an angle W12 shown, whereby the selected wrap angle W has an effect on the spread and the formation of folds. It is advantageous if the wrap angle W11, W12 is set to less than or equal to 90°, preferably less than 45°, and thus folds, preferably longitudinal folds, in the material web M can be avoided and/or folds that have already formed before the spreader device 10 can be eliminated.

Figure 2b shows the Figure 2a alternative operating position of the spreader device 10, whereby the spreader bar 11 is now in working position 111 and the Spreader roller 12 is in waiting position 122. The spreader bar 11 extends at least over the entire transverse direction CD of the material web M.

The material web M wraps around the spreader bar 11 at an angle W11 shown, whereby the selected wrap angle W has an effect on the spreading and the formation of folds.

The material web M is in direct or indirect contact with the spreader bar 11.

In the Figures 3a-c and Figure 4 Detailed illustrations of possible embodiments of the spreader bar 11 and the spreader roller 12 are shown.

In a "direct contact", a surface of a base body 113 of the spreader bar 11 or a surface or surface coating 129 of the spreader roller 12 touches the material web M. For an "indirect contact", an adjustable air boundary layer LG or an air cushion LG is arranged between the surface of the base body 113 of the spreader bar 11 or the surface or surface coating 129 of the spreader roller 12 and the material web M and the material web M floats or hovers at an adjustable distance D above the two surfaces 113 or 129. The material web M has no direct contact with the surface 113 or 129. It is advantageous if the adjustable air boundary layer LG or the adjustable distance D is set to less than or equal to 5 mm, preferably less than or equal to 1 mm, but at least greater than or equal to 0.1 mm.

The Figure 3a shows a side view of the spreader bar 11. This comprises a rigid base body 113, which is firmly connected to at least one bearing 115, whereby - not shown - the spreader bar cross member 115 can be adjustably connected to the fastening cross member 15 of the spreader device 10. Alternatively, the base body 113 can also be adjustably connected directly to the fastening cross member 15.

Furthermore, the spreader bar 11 comprises at least one further adjustment device 119, which enables adjustment in the machine direction MD and z-direction and thus makes the spreading of the spreader bar 11 controllable or adjustable.

The base body 113 comprises at least one opening in which a nozzle module 14 is arranged. The nozzle module 14 is connected to at least one air supply line 116, which supplies the nozzle module 14 with a pressurized medium, preferably air. The air exits into the environment and in the direction of the material web M from at least one nozzle outlet opening 142 contained in the nozzle module 14. The nozzle outlet opening 142 is specially designed in terms of shape and form in order to achieve a uniform pressure distribution over the extension of the spreader rod 11 in the transverse direction CD. Each nozzle outlet opening 142 is connected to the air supply line 116 via a specially designed nozzle channel 141.

Figure 3b shows an enlarged view of the base body 113 and the nozzle module 14 of the spreader bar 11 from Figure 3a . The moving material web M and the air boundary layer LG generated by the exit of the air between the base body 113 or the nozzle module 14 and the material web M are also shown. The material web M moves at a distance D or an air boundary layer thickness D indirectly over the spreader bar 11.

Figure 3c shows a plan view of the spreader bar 11 in an alternative embodiment with three adjustment devices 119 for the spreader effect and five arranged nozzle modules 14 in the base body 113. The spreader bar 11 and the enclosed nozzle modules 14 extend over the entire transverse direction CD of the material web M.

Figure 4 shows a side view of an alternative embodiment of the spreading device 10 with a spreading roller 12 in working position 121. The material web M also moves indirectly over the surface or surface coating 129 of the spreader roller 12 with an air boundary layer LG arranged therebetween, which in this embodiment is formed by a spreader rod 11 arranged in the direction of the surface of the spreader roller 12 and by the enclosed nozzle module 14 and by the generated air outlet flow 146.

Advantageously, in this embodiment, the spreader roller 12 can remain permanently in working position 121 for different material web basis weights and for low basis weights, preferably less than or equal to 100 g/m ² , the air boundary layer LG is generated as required by the spreader rod 11.

This enables advantageous operation of the spreader roller 12 for material webs M with higher basis weights, preferably greater than 100 g/m ² , without an air boundary layer LG and activation of the air boundary layer LG by the nozzle modules 14 included in the spreader rod 11 for material webs with low basis weights, preferably less than or equal to 100 g/m ² .

The Figures 5a-c show different views of the nozzle module 14 enclosed in a spreader rod 11.

Figure 5a shows a front view of the nozzle module 14 with an enclosed nozzle base body 143 with several nozzle outlet openings 142 and several nozzle channels 141 contained in the nozzle body 143.

The number and shape of the nozzle outlet openings 142 and the nozzle channels 141 significantly influence the profile of the air outlet flow 146 that is generated. These are preferably designed for a substantially constant or equal pressure profile in the air outlet flow 146. Each nozzle module 14 is supplied with air via an air inlet flow 145.

For particularly efficient integration into existing spreader bar base bodies 113, the nozzle modules 14 should be kept as small as possible. As in Figure 5b in a plan view of the nozzle module 14 and in Figure 5c shown in a side view of the nozzle module 14.

The dimensions or extensions of the nozzle module 14 are a length A of up to 200 mm, preferably less than or equal to 150 mm. A width B is less than or equal to 20 mm and a height B is less than or equal to 20 mm.

The requirements for dimensions and flow profile have shown that additive manufacturing processes, for example different 3D printing processes, are particularly advantageous for the nozzle modules 14.

List of reference symbols

1

Machine for winding and rewinding

2

winding roll

3

first carrier drum

4

second carrier drum

5

Deflection roller

6

Second spreading device

10

Spreading device

11

Spreader bar

111

Working position spreader bar

112

Waiting position spreader bar

113

Base body with nozzle module holder 14

115

Bearing base body

116

Air supply

119

Adjustment device position, spread

12

Spreader roller

121

Working position spreader roller

122

Waiting position spreader roller

129

Surface coating of the spreader roller

14

Nozzle module

141

Nozzle channel

142

Nozzle outlet opening

143

Nozzle body

145

Air inlet flow

146

Air outlet flow

15

Mounting crossbar

W11

Deflection angle material web over spreader bar

W12

Deflection angle of material web over spreader roller

A

length

B

Width

D

thickness

H

Height

lg

Air boundary layer

M

Material web

L

Direction of material web

MD

Machine direction

CD

Transverse direction

Z

Coordinates

Claims (13)

Spreading device (10) for guiding and spreading a material web (M) or partial material webs (M), preferably a paper web, a cardboard web or a tissue web, for use in a machine for winding and rewinding the material web (M), wherein the material web (M) is guided between a parent roll and at least one winding roll over at least one deflection roller (5) and over the at least one spreading device (10),
characterized in that the spreading device (10) comprises a spreading rod (11) and a spreading roller (12), and that these are attached to a common cross member (15), and that the spreader bar (11) and the spreader roller (12) are each mounted so as to be movable independently of one another essentially in the direction of the material web (M). Spreading device (10) according to claim 1,
characterized in that the spreader bar (11) comprises a base body (113), at least one air supply line (116) and at least one nozzle module (14), and that the at least one nozzle module (14) can be connected to the base body (113) and the air supply line (116). Spreading device (10) according to claim 2,
characterized in that the at least one nozzle module (14) comprises a nozzle base body (143), at least one nozzle outlet opening (142) and at least one nozzle channel (141), and that the at least one nozzle outlet opening (142) and the at least one nozzle channel (141) are arranged and shaped such that a substantially constant outlet pressure is set in an air outlet stream (146). Spreading device (10) according to claim 2 or 3,
characterized in that the at least one nozzle module (14) comprises at least ten nozzle outlet openings (142), and that the extension of the at least one nozzle (14) in the length direction (A) is less than or equal to 150 mm, in the width direction (B) is less than or equal to 20 mm and in the height direction (H) is less than or equal to 20 mm. Spreading device (10) according to one of claims 2 to 4,
characterized in that
the spreader bar (11) is arranged such that an air outlet stream (146) of the at least one nozzle module (14) is directed directly onto the material web (M), so that an air boundary layer (LG) is formed between the spreader bar (11) and the material web (M). Spreading device (10) according to one of claims 2 to 4,
characterized in that
the spreader rod (11) is arranged such that an air outlet stream (146) of the at least one nozzle module (14) is directed onto a surface (129) of the rotating spreader roller (12) in contact with the material web (M), so that an air boundary layer (LG) is formed between the material web (M) and the surface (129). Spreading device (10) according to one of the preceding claims,
characterized in that
the spreader bar (11) or the spreader roller (12) is wrapped around the material web (M) at an angle (W11, W12) of less than or equal to 45°, preferably less than or equal to 30°, in particular less than or equal to 20°. Machine (1) for winding and rewinding a material web (M) and/or partial material webs (M), preferably a paper web, a cardboard web or a tissue web, from a master roll onto at least one winding core to form a winding roll (2), wherein the winding roll (2) is supported by a first (1) and a second (4) support drum and the material web (M) between the parent roll and the winding roll (2) comprises at least one deflection roller (5) and at least one spreader device (6, 10), preferably two spreader devices (6, 10),
characterized in that
the machine comprises a spreading device (10) according to claim 1. Method for winding and rewinding a material web (M) and/or partial material webs (M), preferably a paper web, a cardboard web or a tissue web, from a parent roll onto at least one winding core to form a winding roll (2), wherein the winding roll (2) is supported by a first (1) and a second (4) support drum, and the material web is guided between the parent roll and the winding roll (2) with at least one deflection roller (5) and at least one spreader device (6, 10),
characterized in that
at least one air boundary layer (LG) is formed between the material web (M) and the spreading device (10) by the spreading device (10), such that the material web (M) is guided and/or stretched without contact. Method according to claim 9
characterized in that
the air boundary layer (LG) is formed between the material web (M) and a spreader rod (11) included in the spreader device (10). Method according to claim 9
characterized in that
the air boundary layer (LG) is formed between the material web (M) and a spreader roller (12) included in the spreader device (10). Method according to claim 9 or 10
characterized in that a) a spreader bar (11) included in the spreader device (10) forms an air boundary layer (LG) for basis weights of less than or equal to 100 g/m ² of the material web (M) and is brought into engagement with the material web (M) in such a way that the spreader bar (11) guides and/or spreads the material web (M), and that b) a spreader roller (12) included in the spreader device (10) is brought into engagement with a material web (M) such that the spreader roller (12) guides and/or spreads the material web (M) for basis weights greater than 100 g/m2. Method according to claim 9 or 11
characterized in that a) a spreader roller (12) included in the spreader device (10) is brought into engagement with a material web (M), and that b) a spreader bar (11) included in the spreader device (10), for basis weights of less than or equal to 100 g/m ² of the material web (M), forms an air boundary layer (LG) between the spreader roller (12) and the material web (M), such that the spreader roller (12) guides and/or spreads the material web (M) with indirect contact via the air boundary layer (LG), and that c) the spreader roller (12) for basis weights greater than 100 g/m ² of the material web (M), guides and/or spreads the material web (M) with direct contact and the air boundary layer (LG) is switched off.

Images