DE112011103576B4 - Roller support arrangement of a fiber web machine and partial web winder of a fiber web roll cutting machine - Google Patents

Abstract

Roll support arrangement (10) for a fiber web machine, which has a bearing housing (16) at both ends of the roll, the bearing housing (16) having a securing arrangement (22) via which the roll is supported on the frame or foundation (18) of the fiber web machine can, wherein the securing arrangement (22) of the bearing housing has a vibration damping arrangement (20) between the bearing housing and the frame or the foundation of the fiber web machine, and wherein the vibration damping arrangement (20) has at least two damping zones (20.1, 20.2) which are mutually at least in the Respect are different in that they have different loss coefficients, characterized in that of the at least two different damping zones, the proportion of the first damping zone and the proportion of the second damping zone in the vibration damping arrangement is such that at frequencies of 5 0.1 Hz the influence of the second Damping zone on the total stiffness of the vibration The damping arrangement is greater than that of the first zone, and at frequencies> 5 Hz, the influence of the first zone on the overall rigidity of the vibration damping arrangement is greater than the influence of the second zone.

Description

The present invention relates to a roll support arrangement of a fiber web machine according to the preamble of claim 1, which has a bearing housing at both ends of the roll, the bearing housing having a securing arrangement by means of which the roll can be supported on the frame or the foundation of the fiber web machine, wherein the bearing housing securing arrangement has a vibration damping arrangement which is provided between the bearing housing and the frame or the foundation of the fiber web machine, the damping arrangement having at least two damping zones which have properties that are at least different in that they have different loss factors.

The present invention also relates to a partial web winder of a fiber web roll cutting machine, which has a winding cylinder and / or a so-called support roller (English: “king roll”).

As the widths and speeds of fiber web machines increase, roll vibration becomes an increasingly serious problem. Rollers are used in a fiber web machine, for example, to guide the run of the web and / or a supporting fabric. As far as the properties of the fiber web are concerned, such positions of applied rollers / rollers in which the roller / roller has a function for treating the web, such as roller nips, calender rollers, counter rollers in coating and winding rollers or cylinders, are even more essential. In particular, winding cylinders and support rollers of slitter winder, which are used in the post-treatment of the web, are demanding in terms of vibration, since the winding of consumer rolls of different sizes, possibly containing different defects, is easily affected by excessive vibration. Conventionally, the rollers have been secured to the foundation as stiffly as possible, this being the case in particular with the support rollers of winder.

Vibration is a problem particularly with dual-drum type or carrier belt type slitter winder. The vibration problem in a two-drum winder is caused when the multiple of the rotational frequency of the paper roll, which is formed with support rollers, exceeds the natural frequencies of the support rollers. The same type of vibration problem also arises with the retractor cylinders. Resonant vibrations during the operation of a machine or device often result from insufficient damping or insufficient dynamic stiffness at the resonant frequency. It is often possible to try to improve the situation by directly modifying the resonance structure in such a way that its damping is increased.

The documents WO 98/49394 , WO 00/04227 and WO 00/04228 disclose solutions in which an adjustable mass damper has been provided in the bearing housing of a roll of a paper machine. In the solutions disclosed in these documents, the adjustability of the frequency of the vibration to be damped is established by changing the position of the mass in the vibration beam or, alternatively, by changing the size of the mass. If the damper can be easily accessed, the setting can be changed even while the machine is running. However, such a solution does not always provide an adequate vibration damping effect. In order to provide efficient damping of the vibration, the vibration mass should be very large, which is unfavorable, for example, with regard to the required space and also with regard to the required robust support structures.

Finnish patent FI 94458 discloses a method and a device for controlling the vibration of the rolls of a paper machine. According to the method, the position of the critical speed ranges of the roller is changed during the run. The critical speed is changed by changing the mass of the roller and / or the stiffness and / or the support point of the roller. One suggested alternative is to change the stiffness of the roll's end bearing system. Intermediate elements made of an elastic material can be installed between the spacers of the bearing housings of the end bearings and the body. The rigidity of the securing of the bearing housings can be controlled by adjusting the force with which the bearing housing presses the intermediate elements against the body. The pressing force can be adjusted by means of a cylinder device or a screw.

Japanese Patent Laid-Open Publication JP 3082843 discloses an arrangement for reducing vibration in a roll. The drive motor of the roller is secured to the body in a flexible manner. The fuse has an intermediate element made of vibration-resistant rubber, which is arranged between the base plate of the fuse element of the drive motor and the body. The bottom plate locking screws extend through the body plate to a cylinder that is fixed to the bottom surface of the body plate where they attach to the piston in the Cylinders are attached. There are rubber sleeves under the heads of the locking screws, which means that the bottom plate is secured in a floating manner. There is a bracket on the inside surface of the cylinder that limits the upward movement of the piston. There is a spring between the cover of the cylinder and the top surface of the piston and a pressure space with compressed air as the pressure medium between the bottom surface of the piston and the bottom of the cylinder. First, the piston is pressed against the holder of the cylinder inner surface with compressed air, whereby a minimal pressing force is directed towards the intermediate element and the rubber sleeves. When the pressure of the compressed air under the piston is reduced, the piston is moved downwards by the force of the spring above the piston, whereby a greater pressing force is directed towards the intermediate elements and the rubber sleeves. Thus, the pressure of the pressure medium can be used to adjust the stiffness of the roller lock.

Finnish patent FI 118482 discloses supporting a roll of a paper machine or board machine, the roll being supported at its ends in a rotatable manner on bearings in a bearing housing, the bearing housings being supported on the body or on the foundation of the machine with elastic intermediate elements . This document shows a certain advantageous range for the spring constant of the intermediate elements. In this arrangement, the damping capacity of the elastic, weakly damped structure is increased by changing the operating conditions of the structure so that damping is brought to the structure to be damped through the fuses. Then the static stiffness of the structure and its support decreases, but the dynamic stiffness of the structure itself increases.

Separate intermediate elements are typically used in order to achieve a high loss coefficient in the frequency range of the vibration to be damped and the operating conditions. Such spacers, in other words intermediate elements with a high loss coefficient, usually also have a strong tendency to creep, as a result of which the deformation of the element under tension gradually increases. This causes misalignment in the rolls of the fiber web machine and consequently malfunctions. In particular in winders of the winder of the support roller type, the alignment errors of the support rollers lead to winding errors.

The DE 10 2004 000 033 A1 discloses a roll support assembly for a fiber web machine having a bearing housing at both ends of a roll. The bearing housing has a securing arrangement by means of which the roller is supported on a frame or a foundation of the fiber web machine. The securing arrangement has a vibration damping arrangement between the bearing housing and the frame and the foundation of the fiber web machine. The vibration damping arrangement has two damping zones which are different from one another in that they have different loss coefficients. The spring stiffness and the damping can be changed.

The object of the present invention is, in particular, to improve the state of the art in this field by providing a roll support arrangement of a fiber web machine which can efficiently influence the vibration of the roll in an even more reliable manner than before.

The object of the present invention is achieved by a roll support arrangement which has a bearing housing at both ends of the roll. The bearing housing has a securing arrangement via which the bearing housing and also the roller can be supported on the frame or the foundation of the fiber web machine. The securing arrangement of the bearing housing has a vibration damping arrangement which is arranged between the bearing housing and the frame and the foundation of the fiber web machine. The vibration damping arrangement has at least two vibration damping zones which are different from one another at least in that they have different loss coefficients. The invention is mainly characterized in that of the at least two different damping zones, the portion of the first damping zone and the portion of the second damping zone in the vibration damping arrangement is such that at frequencies of ≤ 0.1 Hz, the influence of the second damping zone on the overall rigidity of the Vibration damping arrangement is greater than that of the first zone, and at frequencies of ≥ 5 Hz, the influence of the first zone on the overall rigidity of the vibration damping arrangement is greater than the influence of the second zone.

This has the effect that the movement of the bearing housings due to the creep of the damping arrangement, ie the gradual deformation, is minimized over time, while at the same time a time-efficient vibration damping is maintained when the roller is applied. In the roll support system, the vibration damping arrangement, which is provided between the bearing housing and the frame or the foundation of the fiber web machine, is subjected to a substantially constant compressive force. If that Vibration damping system is arranged below the bearing housing, in particular the downward movement, ie the sinking of the bearing housing, is avoided or minimized.

According to an exemplary embodiment of the present invention, the at least two different damping zones are made from different materials.

Then the first material has a different loss coefficient than the second material.

According to another embodiment, the damping zones are separate pieces that are connected to one another. Then a vibration damping assembly can be easily formed by placing various pieces with the desired properties side by side.

It is advantageous for the operation of the damping system that the damping zones of the vibration damping arrangement are symmetrically divided with respect to the normal of the roller mounting surface on both sides of the central axis.

It is furthermore advantageous that the damping zones of the vibration damping arrangement between the bearing housings are divided symmetrically with respect to the roller center in the direction of the central axis.

According to another embodiment of the present invention, the damping zones are formed from one piece which has zones with different properties.

According to an exemplary embodiment of the present invention, the first damping zone has a loss coefficient of> 0.1.

According to an exemplary embodiment of the present invention, the second damping zone has a loss coefficient of <0.3.

According to another exemplary embodiment of the present invention, the first damping zone has a loss coefficient of> 0.3.

According to another exemplary embodiment of the present invention, the second damping zone has a loss coefficient of <0.1.

Of the at least two different damping zones, the proportion of the first damping zone and the proportion of the second damping zone in the vibration damping arrangement is such that at frequencies of ≤ 0.1 Hz the influence of the second damping zone on the overall stiffness of the vibration damping arrangement is greater than that of the first zone, and at frequencies of ≥ 5 Hz, the influence of the first zone on the overall rigidity of the vibration damping arrangement is greater than the influence of the second zone.

According to another embodiment, of the at least two different damping zones, the portion of the first damping zone and the portion of the second damping zone in the vibration damping arrangement is such that at frequencies of ≤ 0.1 Hz the influence of the second damping zone on the overall rigidity of the vibration damping arrangement is greater than that of the is the first zone, and at frequencies of ≥ 10 Hz, the influence of the first zone on the overall rigidity of the vibration damping arrangement is greater than the influence of the second zone.

The damping system is preferably formed from a plate-like structure.

According to an embodiment of the present invention, the material having a low loss coefficient is arranged at the position where the damping system is subjected to the greatest stress.

The arrangement according to the invention produces, in particular, an advantageous influence on a partial web winder of a winder. In particular, vibration problems of a partial web winder of a winder can be solved in the partial web winder of a winder that has a winding cylinder and / or a support roller, the winding cylinder and / or the support roller of the partial web winder having a roller support arrangement that has a bearing housing at both ends of the roller. The bearing housing has a securing arrangement by means of which the bearing housing and also the roller can be supported on the frame or the foundation of the fiber web machine. The securing arrangement of the bearing housing has a vibration damping arrangement which is arranged between the bearing housing and the frame or the foundation of the fiber web machine. The invention is mainly characterized in that the vibration damping arrangement has at least two damping zones which have properties which differ from one another at least in such a way that their loss coefficients are different.

Other characteristic features of the present invention are disclosed in the appended claims and the description of the embodiments shown in the drawings.

• 1 zeigt schematisch eine Walzenstützanordnung eines Ausführungsbeispiels gemäß einem Ausführungsbeispiel der vorliegenden Erfindung.
• 2 zeigt das Prinzip einer Lösung gemäß einem Ausführungsbeispiel der vorliegenden Erfindung.
• 3 zeigt ein Walzenstützsystem gemäß einem Ausführungsbeispiel der vorliegenden Erfindung.
• Die 4 und 5 zeigen den Betrieb einer Anordnung gemäß einem Ausführungsbeispiel der vorliegenden Erfindung.
• 6 zeigt ein Walzenstützsystem gemäß einem anderen Ausführungsbeispiel der vorliegenden Erfindung.
• 7 zeigt verschiedene Alternativen zum Ausführen der Schwingungsdämpfungsanordnung gemäß der vorliegenden Erfindung.

The present invention and its operation are described below with reference to the accompanying schematic drawings.

• 1 shows schematically a roll support arrangement of an embodiment according to an embodiment of the present invention.
• 2 shows the principle of a solution according to an embodiment of the present invention.
• 3 Figure 3 shows a roll support system according to an embodiment of the present invention.
• The 4th and 5 show the operation of an arrangement according to an embodiment of the present invention.
• 6th Fig. 10 shows a roll support system according to another embodiment of the present invention.
• 7th Figure 11 shows various alternatives for implementing the vibration damping arrangement according to the present invention.

1 Figure 3 shows schematically a roll support arrangement 10 a fiber web machine according to an embodiment of the present invention, used in connection with a partial web winder 11 . Here the other supporting structure is a set of belt rollers 14th , which can also be a roller alone. The roller support arrangement is in connection with a roller 12th that are rotatable at their ends on bearings in bearing housings 16 is supported. For the sake of clarity of illustration, the bearing housing is 16 only shown here from one end, but it is obvious that a bearing housing is present at both ends of the roller. The bearing housing of the support roller 12th are also on the frame or the foundation 18th supported by the machine. The support roller 12th also works here as a winding cylinder, via which the partial web is brought over the partial web winder. The bearing housing is of course also on the frame or the foundation 18th via a backup arrangement 22nd fixed. The structure of the fuse arrangement 22nd is such that it allows movements substantially perpendicular to the securing plane, but the movement of the bearing housing 16 prevents or significantly restricts in the machine direction and the cross direction. The bearing housing is on the frame or the foundation via intermediate elements of the vibration damping arrangement 20th supported. In 1 is the fuse arrangement 22nd designed in such a way that the frame of the fiber web machine has locking elements 20.3 which are secured to the foundation and which control the movement of the bearing housing 16 Restrict or prevent in the machine direction and the transverse direction and thus lock them. Partial web rolls 16 are made with two partial web winders 11 the roll type wound in a manner known per se.

The vibration damping arrangement 20th is preferably a plate-like structure between the bearing housing and the frame or foundation 18th of the fiber web machine is arranged so that the mass of the roll and the forces directed towards it during operation are transmitted through the vibration damping arrangement to the frame or the foundation. The vibration damping arrangement is preferably arranged so that it extends to the entire support surface of the bearing. According to a first exemplary embodiment of the present invention, the vibration damping arrangement has at least two damping zones which have properties that are different from one another. The vibration damping zones 20.1 and 20.2 differ from each other at least in that they have different loss coefficients. The damping zones are preferably arranged in a parallel connection. In this way, the vibration damping arrangement becomes even more reliable in operation. The vibration damping zone 20.1 that have a larger loss coefficient than the second damping zone 20.2 especially in the main frequency range of the vibration to be damped, contributes to efficient damping of the vibration. Because the loss coefficient of the second damping zone 20.2 is smaller than that of the first damping zone, the second damping zone also has a weaker tendency to creep. Then, the sinking of the bearing housings over time due to creep, that is, gradual deformation, is also minimized. Because of this, the damping arrangement according to the present invention provides both efficient damping of the vibration and it also enables avoiding or at least minimizing the change in the position and / or the orientation of the roller 12th due to deformation of the damping element over time. In this way, the occurrence of errors in the roll alignment and thus subsequent winding errors in a two-drum web winder, which result from the creep, can at least be minimized. It also reduces the need to control the alignment and realign the roller.

2 shows the principle of an embodiment according to the present invention. 12th shows a roller 12th ; only one end of it is shown here. The roller has a roller shell with shaft bearing journals 12a attached to their ends. The roller 10 is about the shaft journal 12a on bearing housings 16 supported. The roller can thus around its longitudinal axis, which is through the bearing housings 12a is supported, be rotated. On the connection between the shaft journal 12a and the bearing housings 16 is given the reference symbol 16 ' in 2 Referenced. The bearing housing 16 are on the frame or the foundation 18th the fiber web machine via an elastic support, ie a vibration damping arrangement 20th supported. In practice, the vibration properties of the frame and the foundation must also be taken into account, but this has not been illustrated here for the sake of clarity.

The vibration damping arrangement 20th thus has at least two oscillation zones 20.1 and 20.2 in a parallel connection that have properties that differ from each other at least in that they have different loss coefficients. Thus, each zone separately takes up a share of the total load and participates in the damping of the oscillation according to its properties.

3 shows a roll support system 10 according to a preferred embodiment of the present invention in connection with a roller 12th . The roller has a central axis 30th , the jacket of the roller being rotationally symmetrical relative to this. The roller is on the frame or the foundation 18th The fiber web machine is mounted on the operator side and drive side, which makes the mounting surface the direction 32 of their normals. The mounting surface can deviate from a plane, so that the direction of the normals corresponds on average to the direction of their normals. In the embodiment of 3 are the vibration damping zones 20.1 and 20.2 the roller 12th the vibration damping system 20th that have different properties, preferably on both sides of the roll center axis 30th symmetrical relative to the normal 32 divided. The normals of both mounting surfaces of the bearing housing are preferably parallel, thereby creating the damping zones 20.1 and 20.2 on both sides of the roll center axis 30th symmetrically relative to the plane divided by the normals 32 the mounting surfaces of the bearing housing is formed.

The roller has a center point 34 in the direction of the central axis 30th which, when the roller has been mounted in the fiber web machine, usually coincides with the center line of the fiber web machine. Now are the damping zones 20.1 and 20.2 the vibration damping arrangement 20th between the bearing housings 16 symmetrical relative to the roll center 34 - parallel to the central axis of the roller - divided.

The operation of an arrangement in accordance with a preferred embodiment of the present invention is illustrated in FIGS 4th and 5 shown. 4th shows the stiffnesses Y1 a zone of a material A and a zone of a material B and the total stiffness of the zones A and B as a function of the frequency X. The material A here represents the first damping zone and the material B represents the second damping zone.

In the drawing, the linear horizontal axis X is frequency and the linear vertical axis is rigidity Y1 . As can be seen here, the stiffness of the zone of material A increases sharply as a function of frequency, the stiffness of the part formed from material B remaining approximately constant.

5 shows the loss coefficient Y2 from the combined effect of the zones made of material A and material B and the loss coefficient of the parts of A and B as a function X of frequency. If the vibration damping system were made from material A only, the loss coefficient would be close to a frequency of 0 Hz, for example 0.1 Hz at a frequency of X1 on the order of 0.285. In the method of the present invention this can be reduced to about 1/3 of that, which is about 0.13, for example. In a corresponding manner, as far as the tendency to creep is concerned, the zone made from material B is stiffer than a zone made from material A at 0 Hz. Thus, the lower tendency of material B to creep dominates at 0 Hz and there are fewer alignment problems with the roller than before. However, at frequencies above 10 Hz that need to be attenuated, the frequency is X2 , the total loss coefficient is still close to the loss coefficient of material A and provides good vibration damping properties in practice. The stiffness of a material that has a larger loss coefficient increases greatly as a function of frequency, at which point the stiffness of a material with a lower loss coefficient does not change significantly as the frequency increases. The thicknesses and areas of materials A and B are chosen so that the influence of material B on the overall stiffness of the damping arrangement is stronger than that of material A, close to 0 Hz and / or at very low frequencies, but still so that At the frequencies to be damped, the influence of material A on the stiffness is greater than that of material B.

6th shows a further embodiment of the present invention, which is in connection with a roller 12th is shown. The roller 12th is rotatable at its ends on bearings in bearing housings 16 supported. The roller bearing housing 12th are in an elastic manner on the frame or the foundation 18th the fiber web machine, for example, via a spring element or spring elements 20.6 supported, which is / are arranged under the bearing housings. The bearing housing is on the frame or the foundation 18th by means of locking elements 20.3 secured, which allow a movement essentially perpendicular to the securing plane of the bearing housing (here: upwards - downwards), but the movement of the bearing housing 16 prevent or substantially limit them in the machine direction or the cross direction. The bearing housing is on the frame or the foundation 18th in a flexible manner, for example via a spring element or spring elements 20.6 supported, which is / are arranged under the bearing housings. The spring elements can be metal springs, for example. The damping of the elasticity is done with intermediate elements 20th accomplished the vibration damping arrangement, which is provided between the locking elements and the bearing housing, the intermediate elements also in this embodiment, at least two damping zones 20.1 and 20.2 which have mutually different properties. The damping zones are created with separate intermediate elements. The damping zones 20.1 and 20.2 differ from each other at least in that they have different loss coefficients. The damping zones are preferably arranged as different damping elements.

7th Figure 11 shows various alternatives for implementing the vibration damping arrangement according to the present invention. 7a shows an embodiment in which the vibration damping arrangement has separate damping elements or pieces 7.1 , 7.2 and 7.3 has, of which the pieces 7.1 and 7.3 at the edges are identical and the piece 7.2 between them a different loss coefficient than the pieces 7.1 and 7.3 Has. The separate damping elements are here arranged side by side. 7b shows an embodiment in which the vibration damping arrangement is a vibration element or piece 7.4 having. Different zones 20.1 and 20.2 with different loss coefficients have been accomplished in the construction of this single element. 7c shows a preferred embodiment of the vibration damping arrangement according to the present invention, the at least two damping zones 20.1 and 20.2 having properties that differ from each other at least in that respect that they have different loss coefficients. Here, too, there are separate damping elements or pieces 7.1 , 7.2 present of which the piece 7.2 of the piece 7.1 is surrounded. 7c also shows how pieces 7.1 and 7.2 in connection with a support plate 20.4 are arranged that they share with each other. According to one embodiment, the piece is 7.1 the vibration damping arrangement 20th for example butyl rubber and is the other piece 7.2 for example from epoxy. Preferably, both pieces are connected to the support plate in connection with vulcanization.

7c shows how a vibration damping arrangement according to an embodiment of the present invention, a protective housing 20.5 having. The rest of the anti-vibration assembly is off 7c is similar to in 7d .

It will be apparent to those skilled in the art that the shape and locations and other detailed properties and characteristics of the individual pieces and / or zones may vary from case to case.

It should be noted here that only a few most preferred exemplary embodiments of the present invention are described here. It is thus obvious that the present invention is not restricted to the exemplary embodiments shown above, but can be applied in many different ways within the scope defined by the appended claims. The features disclosed in connection with the various exemplary embodiments can also be used in conjunction with other exemplary embodiments within the basic idea of the present invention and / or the various features can be combined with different units, if this is desired and the technical possibilities for this exist.

Claims (14)

Roll support arrangement (10) for a fiber web machine, which has a bearing housing (16) at both ends of the roll, the bearing housing (16) having a securing arrangement (22) via which the roll is supported on the frame or foundation (18) of the fiber web machine can, wherein the securing arrangement (22) of the bearing housing has a vibration damping arrangement (20) between the bearing housing and the frame or the foundation of the fiber web machine, and wherein the vibration damping arrangement (20) has at least two damping zones (20.1, 20.2) which are mutually at least in the Respect are different in that they have different loss coefficients , characterized in that of the at least two different damping zones, the proportion of the first damping zone and the proportion of the second damping zone in the vibration damping arrangement is such that at frequencies of 5 0.1 Hz the influence of the second Damping zone on the overall stiffness of the Schwingu The damping arrangement is greater than that of the first zone, and at frequencies> 5 Hz the influence of the first zone on the Overall stiffness of the vibration damping arrangement is greater than the influence of the second zone. Roll support arrangement of a fiber web machine according to Claim 1 , characterized in that the at least two different damping zones are made of different materials. Roll support arrangement of a fiber web machine according to Claim 1 or 2 , characterized in that the roller vibration damping zones (20.1, 20.2) of the vibration damping arrangement (20) are divided symmetrically relative to the normal (32) of the roller mounting surface on both sides of the roller center axis (30). Roll support arrangement of a fiber web machine according to Claim 1 , 2 or 3 , characterized in that the damping zones (20.1, 20.2) of the roller vibration damping arrangement (20) between the bearing housings (16) are divided symmetrically relative to the roller center (34) parallel to the direction of the center axis of the roller. Roll support arrangement of a fiber web machine according to one of the preceding Claims 1 to 4th , characterized in that the damping zones are separate elements arranged in connection with one another. Roll support arrangement of a fiber web machine according to one of the preceding Claims 1 to 3 , characterized in that the damping zones are formed from an element which is provided with zones having different properties. Roll support arrangement of a fiber web machine according to one of the preceding Claims 1 to 6th , characterized in that the loss coefficient of the first damping zone is> 0.1. Roll support arrangement of a fiber web machine according to one of the preceding Claims 1 to 7th , characterized in that the loss coefficient of the second damping zone is <0.3. Roll support arrangement of a fiber web machine according to Claim 8 , characterized in that the loss coefficient of the second damping zone is <0.1. Roll support arrangement of a fiber web machine according to Claim 7 , characterized in that the loss coefficient of the first damping zone is> 0.3. Roll support arrangement of a fiber web machine according to Claim 1 , characterized in that at frequencies> 10 Hz, the influence of the first zone on the overall rigidity of the vibration damping arrangement (20) is greater than that of the second zone. Roll support arrangement of a fiber web machine according to one of the preceding Claims 1 to 11 , characterized in that the vibration damping arrangement (20) is formed from a plate-like structure. Roll support arrangement of a fiber web machine according to one of the preceding Claims 1 to 12th , characterized in that the roller (12) is a roller in the winding section of a winder. Partial web winder (11) of a slitter winder for a fiber web, which has a winding cylinder and / or a support roller, characterized in that the winding cylinder and / or a support roller of the partial web winder also has a roller support arrangement (10) according to one of the preceding Claims 1 to 13th having.

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