DE4035054A1 - WINDING DEVICE, USE OF A ROLLER AND CORRESPONDING ROLLER - Google Patents

Abstract

A roller (10) used as support, backing or driven roller in winding devices, is composed of an outer cylindrical roller element (24), on which an elastic, flexible intermediate layer (26) of elastomeric material is applied. On the intermediate layer (26), an external roller mantle (33) of thin-wall spring steel is provided that can be deformed in a plane perpendicular to the axis due to the contact pressure of the roll (2) and can be pressed against the outer perimeter of the roll (2). A broad contact region is created, which leads to a lower specific nip pressure and to a smaller package hardness. Channels (27, 28) in the intermediate layer (26) serve to increase the flexibility and cooling.

Description

Winding devices for paper webs are in different Embodiments known in which on the forming Rolls parallel to the axis of the roll lie against it. At the Carrier roller winder, the winding rests on two parallel to each other revolving support rollers arranged at the same height and is loaded from above by a load roller. At the Back-up roll winder, the winding can be rotated on one axis stored, which in turn is attached to swivel arms. The winding lies against a so-called backup roller. With increasing winding diameter, the axis of the Winding by pivoting the swivel arms from the fixed standing backup roller. The constructions can in detail be designed differently. But they have one thing in common in connection with the invention that on the forming Winding an axially parallel roller is present, for example in the form of the support rollers, support rollers or bela mentioned starch rolls.

In many cases it is important to wrap the paper web with the lowest possible winding tensions. To it is in addition to applying the smallest possible path Tension is also necessary, as little as possible when wrapping against specific nip pressure. The nip pressure, d. H.  the contact pressure of the roller on the winding forming in Investment area is also for the tension in the web responsible. If the roller against the reel is practically not deformable, as is the case with a thick-walled steel roller is the case, is the investment area relatively narrow and only due to the flexibility of the winding certainly. The investment power is then distributed over a low level Area, and the resulting specific pressure is high. The resulting tension in the web lead to a high winding hardness, which is often undesirable.

There are already so-called elastic rollers, i.e. H. Rollers with a stable cylindrical outer circumference Known roll body, which is a coating of rubber or a have elastomeric plastic. When using such rollers as support, support or load rollers deforms under the system pressure not only the winding, but also the material of the roll cover. Its shape fits the wrap something on. The wrap is somewhat in the soft Surface of the roller pressed in. This increases the investment area in the circumferential direction and decreases the specific system pressure, which is desirable in itself. Soon but occurs early due to the deformation of the roll cover axial tensioning of the paper web at the edge of the roll, which is undesirable because it affects the winding quality. Rolls with an elastic coating that immediately counter the wrap works, so bring with regard to the fro position of coils of low hardness no advantages.

The invention has for its object a winding To design the device so that less on its winding Hardness without impairing the other winding quality are producible.

This task is in a first aspect by the in Claim 1 reproduced invention solved.

The basic idea here is that the thin-walled Slightly deform the metal barrel in the circumferential direction,  d. H. can dent and thus the desired magnification of the contact area in the circumferential direction and thus the rings specific system pressure. At the same time but is the thin-walled barrel jacket made of metal in axial direction in contrast to an elastomer or rubber jacket not or hardly deformable and therefore affects the wraps not quality because there are no axial forces.

Rollers with an elastically flexible intermediate layer and thin-walled metallic barrel jacket are known per se. For example, DE-GM 77 23 702 shows the lowest possible moment of inertia around the longitudinal axis of the rotating body, which is to be used, for example, as a towed guide roller for guiding sheet-like materials such as textile sheets, paper sheets, sheets of metal foils and the like. On a circumferential axis 4 , a cylindrical area is provided with a low-density filler, which is surrounded on the outside by a metal shell forming the working roller circumference with a wall thickness of 0.03 to 0.5 mm, which is produced by electroplating or by winding metal foils can.

DE-OS 22 37 949 is a roller with a roller body known from an intermediate layer of bubbles containing filling compound, for example foamed rubber materials or elastomers. On the intermediate layer is arranged a metallic roller shell. The Rollers are said to be used, for example, for calendering textiles certificates are used.

The invention is also implemented in use a roller of the structure shown in claim 2 as Carrier, support or load roller in winding devices for paper or the like.

In the preferred embodiment of the invention the intermediate layer according to claim 3 from a compact elastomeric material with a hardness of 30 to 80 ° Shore A.  

With this training, the entire system is based on the Winding roller still stable enough to prevent unwanted Vibrations at the usually high working speed ent counteract. The metallic barrel jacket of the roller is there Appropriately made of steel (claim 4), which has a radial thickness can have from 1 to 5 mm (claim 5).

A third aspect of the invention in the form of a single NEN suitable for winding devices is in claim 6 reproduced.

The roller barrel can consist of spring steel (Claim 7) because this steel has a particularly large elasti range and without being near the flow limit, the shape of the wrap can adapt well.

The dimensioning of the radial thickness of the intermediate layer largely depends on the individual case. It must be thick enough in order to adjust the elastic ver malleable barrel jacket to the circumference of the wrap. The thickness required for this depends on the system pressure and on the diameter of the roll to be manufactured. The one in Be the upcoming range is between 10 and 100 mm (an Proverbs 8).

An important embodiment of the invention is that channels of at least 10 mm ² distributed over the circumference are formed in the intermediate layer.

The channels should therefore have a macroscopic cross section have and not formed by pores or the like be. They have a double function. First of all increase the flexibility of the overall arrangement because that resilient material of the intermediate layer, if the webs remaining between the channels by an ent speaking deformation of the barrel jacket in turn deformed can more easily dodge sideways. The other function is the cooling function according to claim 10. When the roller rotates arises in the material of the intermediate layer through the  Every revolution that occurs is a significant walk work without precautions to an unacceptable job heating of the resilient material would lead. This is counteracted by the coolant.

The grooves can according to claim 11 in the surface of the intermediate layer and against the inside Barrel jacket be open. That makes the manufacturing easier. The grooves can be circumferential grooves, in particular as screw ben-shaped circumferential grooves can be provided (claims 12, 13), which makes the coolant particularly easy over the whole Distributes circumferential surface. For multi-course training the coolant can be fed back and forth. At intersecting circumferential grooves results in a waffle or diamond-shaped structure.

Because it is especially in the area of the edges of the wrap on it arrives to avoid axial forces and flexibility of the barrel jacket should be particularly large there, it can recommend in the area of the edge of the work area to make the grooves deeper and / or wider than in the middle the work area (claim 14).

According to claim 15, the intermediate layer can be axial outside of the working area away from the barrel jacket Taper on the outside towards the axis for durability to increase the order.

Because the papers often have mineral lines and are accordingly abrasive and thereby the width of the Nips in the circumferential direction of the roller with local displacements the paper web is to be expected in relation to the circumference a coating of the barrel jacket on the working Outer circumference with a wear-resistant substance to Example of a hard metal coating, useful (claim 16). Such a coating also has the function the coefficient of friction between the barrel jacket and the paper or other web material to increase without increasing the System pressure transfer larger circumferential forces on the winding to be able to.

In the drawing is an embodiment of the Erfin shown.

Fig. 1 and 2 show winding devices schematically in a direction perpendicular to the axis of the rollers section;

Fig. 3 shows a longitudinal section through one end of a roller serving as a supporting, supporting or loading roller;

Fig. 4 strongly exaggerates the effect produced by the invention.

In Fig. 1, a support roller winding device 20 is Darge, which is used for winding a paper web 1 to a roll 2 . The web 1 is brought under a certain longitudinal web tension and deflected downward via a deflection roller 3 according to FIG. 1. It wraps from below a driven support roller 4 with a horizontal axis, in addition to which a further support roller 5 of the same design is also arranged with a horizontal axis at the same height and at a short distance. The winding 2 that forms is located at points 6 and 7 with a nip pressure 8 on the support rollers 4 , 5 , which results from the weight of the winding and the support pressure 9 of a loading roller 11 , which is symmetrical about the support rollers 4 , 5 this is arranged and is under the force of a piston / cylinder unit 12 . The loading roller 11 serves to guide the rapidly circulating roll and to form the same evenly.

In Fig. 2, a backup roll winding device is given again, in which the web 1 is wound into a roll 2 , which does not rest on support rollers, but is mounted on an axis on swivel arms 13 , which are essentially upright and on the ground at 14 are pivotally mounted. By acting on the swivel arms 13 piston / cylinder units 15 , the winding 2 is pulled against an approximately at the same height fixed support roller 16 . A nip pressure 17 results. The paper web 1 reaches the support roller 16 from above via deflecting rollers 18 , 19 and is wound onto the roll 2 after passing through the nip.

Thus, the rollers 4 , 5 , 11 , 16 each lie in nips with the nip presses 8 , 9 , 17 on the winding 2 and determine the winding hardness of the winding 2 by their surface behavior. The rollers 4 , 5 , 11 , 16 are therefore basically the same. and given by rollers 10 , the internal structure of which can be seen from FIG. 3. The roller 10 comprises a cylindrical hollow roller 21 , in each of which a rotationally symmetrical end piece 22 is inserted, for example welded, at the ends, which protrudes outward beyond the end of the hollow roller 21 and forms the roll neck 23 there . These parts together form the roller body 24 . The construction shown is sufficient if the length of the roller 10 is not too great and the load is not too high. In other cases, the hollow roller 21 can be part of a hydraulically internally supported roller, for example a roller which can be deflected, for example according to DE-OS 22 30 139.

The outer circumference 25 of the roller body 24 is cylindrical. On the outer circumference 25 , an intermediate layer 26 made of a compact, elastically flexible polyurethane with a hardness of 50 ° Shore A is attached. The wall thickness corresponds to that of the cylindrical roller tube 21 and is approximately 30 mm. In the outer circumference of the intermediate layer 26 , helical circumferential grooves 27 , 28 are provided, the width of which is approximately 4 mm and the depth of which is approximately 12 mm. In the embodiment example, the circumferential grooves 27 , 28 form a two-start screw. The two screw threads formed by the circumferential grooves 27 and 28 are connected via connecting bores 29 , 31 to a central bore 32 in the roll neck 23 in connection through which a cooling medium, for example air or water, can be supplied, which through the circumferential grooves 27 , 28 according to FIG. 3 is conveyed from left to right. The roller 10 is designed accordingly at the right end and contains a discharge line for the cooling medium there. Other fluid guides are also known. The only important thing is that the circumferential grooves 27 , 28 are evenly distributed over the circumference and relatively close together.

The cylindrical outer periphery of the intermediate layer 26 is covered by a thin-walled barrel jacket 33 made of spring steel of approximately 2 mm radial thickness, which is supported on the intermediate layer 26 and covers this over its entire extent. In addition, the outwardly open grooves 27 , 28 , which have a substantially rectangular cross section with a rounded bottom, are closed to the outside by the barrel jacket 33 .

In Fig. 3, the lower part of the winding 2 is indicated above, which bears against the barrel jacket 33 . His left limit according to FIG. 3 can fluctuate between the limits 34 and 34 '. The grooves 27 , 28 can in this area, as indicated by dashed lines, be deeper and possibly also wider, in order to ensure a particular elastic compliance of the entire arrangement in the edge area of the winding.

The running jacket 33 lies firmly against the intermediate layer 26 essentially over the entire extent of the roller. However, removed at the ends at 26 'of the outer periphery of the intermediate layer 26 inwardly from the inner periphery of the running casing 33rd This serves to increase the flexibility and avoid damage caused by edge effects.

The outside of the running jacket 33 has a coating 36 made of hard metal in order to counteract the long-term abrasive effect of the paper web 1 and to increase the coefficient of friction between the running jacket 33 and the paper web 1 .

The effect of the invention is exaggerated in Fig. 4 indicates. The roller 10 is relatively easily deformable in a plane perpendicular to the axis, because the running jacket 33 consists of thin spring steel and is only elastically backed by the intermediate layer 26 . The running jacket 33 therefore dented somewhat in the manner shown in FIG. 4 and nestled against the circumference of the roll in the nip in an abutment area 35 which is relatively wide due to the nesting, in any case much wider than that of a completely rigid counter roll would. The contact force that arises per unit length is thus distributed over this relatively large contact area 35 , so that a rather low specific nip pressure arises, which complies with the formation of a low winding hardness, which is desirable in some cases.

With the deformation in the plane perpendicular to the axis, as can be seen in Fig. 4, there are only very insignificant changes in length in the axial direction, so that the winding 2 in the region of its edge 2 'is not stressed and the winding quality at the edge is not is impaired.

Claims (16)

1. Winding device for webs ( 1 ) made of paper or the like, in which at least one roller ( 10 ) as supporting, supporting or loading roller ( 4 , 5 ; 16 ; 11 ), which has a load-bearing roller body, bears on the winding ( 2 ) ( 24 ) with cylindri cal outer circumference ( 25 ), one on the outer circumference ( 25 ) of the roller body ( 24 ) attached, radially elastically flexible intermediate layer ( 26 ) and one on the outer circumference of the intermediate layer ( 26 ) attached, cylindrical, to the axis of Has roller body ( 24 ) concentric thin-walled barrel jacket ( 33 ) made of elastically deformable metal under the contact pressure. 2. Use of a roller ( 10 ) with a rotationally symmetrical load-bearing roller body ( 24 ), with an intermediate layer ( 26 ) made of a low-density material applied to the roller body ( 24 ) and a thin-walled, cylindrical, attached to the outer circumference of the intermediate layer ( 26 ) rule, to the axis of the roller body ( 24 ) concentric running jacket ( 33 ) made of metal as a support, support or loading roller ( 4 , 5 ; 16 ; 11 ) in winding devices for webs ( 1 ) made of paper or the like. 3. winding device or use of a roller according to claim 1 or 2, characterized in that the intermediate layer ( 26 ) consists of a compact elastomeric material with a hardness of 30 to 80 ° Shore A. 4. winding device or use of a roller according to one of claims 1 to 3, characterized in that the barrel jacket ( 33 ) consists of steel. 5. winding device or use of a roller according to claim 4, characterized in that the barrel jacket ( 33 ) has a radial thickness of 1 to 5 mm. 6. roller as a supporting, supporting or loading roller ( 4 , 5 ; 16 ; 11 ) for a winding device for webs ( 1 ) made of paper or the like,
with a load-bearing roller body ( 24 ) with a cylindrical outer circumference ( 25 ),
with a radially elastically resilient intermediate layer attached to the outer circumference ( 25 ) of the roller body ( 24 ) and made of a compact elastomeric material with a hardness of 30 to 80 ° Shore A with channels ( 27 , 28 ) distributed along the circumference, closely arranged next to one another,
and with a cylindrical wall jacket ( 33 ) made of steel and having a radial thickness of 1 to 5 mm, which is mounted on the outer circumference of the intermediate layer ( 26 ), is cylindrical, concentric to the axis of the roller body ( 24 ) and thin-walled and elastically deformable under the contact pressure. 7. winding device, use of a roller or roller according to one of claims 1 to 6, characterized in that the barrel jacket ( 33 ) consists of spring steel. 8. winding device, use of a roller or roller according to one of claims 1 to 7, characterized in that the intermediate layer ( 26 ) has a radial thickness of 10 to 100 mm. 9. winding device, use of a roller or roller according to one of claims 1 to 8, characterized in that in the intermediate layer ( 26 ) over the circumference, closely arranged channels ( 27 , 28 ) of at least 10 mm clear cross-section are formed. 10. Winding device, use of a roller or roller according to claim 9, characterized in that the channels ( 27 , 28 ) can be connected to a coolant source and a coolant can flow through them. 11. Winding device, use of a roller or roller according to claim 9 or 10, characterized in that the channels as seen on the outer circumference of the intermediate layer ( 26 ), against the barrel jacket ( 33 ) out open grooves are formed. 12. winding device, use of a roller or roller according to claim 11, characterized in that the grooves as Circumferential grooves are formed. 13. winding device, use of a roller or roller according to claim 12, characterized in that the circumferential grooves ( 27 , 28 ) extend helically. 14. Winding device, use of a roller or roller according to one of claims 11 to 13, characterized in that that the grooves are deeper in the area of the edge of the work area and / or wider than in the middle of the work area. 15. winding device, use of a roller or roller according to one of claims 1 to 14, characterized in that the intermediate layer ( 26 ) axially outside the Ar beitsbereich at the edge of the barrel jacket ( 33 ) outwards against the axis of the roller body ( 24th ) tapered. 16. Winding device, use of a roller or roller according to one of claims 1 to 15, characterized in that the barrel jacket ( 33 ) carries a wear-resistant coating ( 36 ) on the working outer circumference.