FI119068B - Calender and Multi-Roll Calender Method and Multi-Roll Calender Calender Roll Bearing Bearing Method and Multi-Roll Calender - Google Patents

Description

119068

The present invention relates to paper and board machines, in particular calenders. The present invention relates to paper and board machines, in particular calenders. More particularly, the present invention relates to a method in the calender according to the preamble of claim 1 and to a multi-roll calender according to the preamble of claim 8.

The invention further relates to a method for loading the bearing of a multi-roll calender calender roll according to the preamble of claim 11 and a multi-roll calender according to the preamble of claim 20 for implementing the method.

Calendering generally aims to improve properties such as smoothness and glossiness of web-like material such as paper or board. In calendering, the web is guided to a nip formed between rolls pressed against each other, i.e. a calendering nip, in which the web is deformed by the effect of temperature, humidity and nip pressure. In the calender, the nips are formed between a smooth-faced press roll, • ·: 20 such as a metal roll, and a roll coated with a flexible coating, such as a polymer ··· ·· »roll. The flexible surface roll conforms to the surface contours of the web and presses the web evenly against the smooth opposing surface of press rolls. In this context ·;;; calender rolls refer to rolls forming the calendering nip, top roll means the top roll of the roll stack, the top nip means the top calendering nip,. 25, formed between the top roll and the calender roll below the top roll, the lower roll ··· "Il means the lowest roll of the roll stack and the alias means the lowest fish roll" * formed between the lower roll and the calender roll above the lower roll. Intermediate nipples mean the calendering nip formed between the top and bottom of the calender by means of calender rolls.

: 1! 30 • · 119068 2

The boundary between paper and board is sliding and can be divided into two classes by basis weight: single-ply paper with a basis weight of 25-300 g / m3 and paperboard made using a multi-layer technology and 150-600 g / m3. As noted, the boundary between paper and board is sliding 5, since the lightest board is lighter than the heaviest paper. Usually paper is used for printing and cardboard for packaging.

The following descriptions are examples of the fiber web values currently in use and may exhibit considerable variations in the given values.

Mechanical pulp or wood-containing printing papers are newsprint, uncoated magazine paper and coated magazine paper.

15 Newsprint paper may either consist entirely of mechanical pulp or may contain low levels of bleached softwood pulp (0-15%) and / or recycled fiber may be used to replace mechanical pulp. General values for newsprint should be as follows: basis weight 40-48.8 g / m2, ash content 0-20%, PPS S10-

III

roughness 3.0 - 4.5 pm, Brendsten roughness 100 - 200 ml / min, density 600 - 750 • * · ··· · 20 kg / m3, brightness 57 - 63% and opacity 90 - 96%.

• · · * • Ml. Uncoated magazine paper (SC - supercalandered) generally has a mechanical pulp of 50-70%, bleached softwood pulp 10-25% and fillers * · · 15-30%. Typical values for calendered SC paper (including, inter alia, SC-C, 25 SC-B and SC-A / A +) are 40-60 g / m 2 basis weight, ash content 0-35%, Hun- [···. ter gloss <20 - 50%, PPS S10 roughness 1.0 - 2.5 µm, density 700 - 1250 kg / m3, lightness 62 - 70% and opacity 90 - 95%.

• · «• ·. Lightweight coated magazine paper (LWC) contains mechanical • ♦ ·. '*! 30 pulp 40-60%, bleached softwood pulp 25-40% and filler and coating agents 20-35%. The general values for LWC paper can be considered as follows: basis weight 3,19068 40-70 g / m2, Hunter gloss 50-65%, PPS S10 roughness 0.8-1.5 µπι (offset) and 0.6-1.0 pm (roto), density 1100 1250 kg / m3, brightness 70-75% and opacity 89-94%.

The general values for machine finished coated MFC paper are: 50-70 g / m2, Hunter gloss 25-70%, PPS S10 roughness 2.2-2.8 pm, density 900-950 kg / m3, lightness 70 75% and opacity 91-95%.

General values for film costed offset (FCO) paper may be as follows: square-10 weight 40-70 g / m2, Hunter gloss 45-55%, PPS S10 roughness 1.5-2.0 pm, density 1000-1050 kg / m3, brightness 70-75% and opacity 91-95%.

General values for MWC (medium weight coated) paper may be as follows: basis weight 70 - 90 g / m2, Hunter gloss 65 - 75%, PPS S10 roughness 0.6 - 1.0 pm, 15 density 1150 - 1250 kg / m3, brightness 70 75% and opacity 89-94%.

The HWC (heacy weight coated) has a basis weight of 100-135 g / m2 and can be coated more than twice.

20 * Pulp wood-free printing papers, i.e. fine papers, are uncoated and coated cellulose-based printing papers with a mechanical pulp * * content of less than 10%.

Uncoated pulp-based printing papers (WFU) contain bleached birch pulp 55-80%, bleached softwood pulp 0-30% and fillers 10-30%.

• · * WFU values range greatly from 50 to 90 g / m2 (up to 240 g / m2), • · * ”Bendtsen roughness 250 to 400 ml / min, lightness 86 to 92% and opacity 83 to 98%.

• · Φ * * In coated pulp-based printing papers (WFCs), the coating amounts vary widely depending on requirements and applications. The following are typical "*** values for single and double coated pulp-based printing papers: 4,119,068 once-coated basis weight 90 g / m2, Hunter gloss 65-80%, PPS S10 roughness 0.75-2.2 pm, brightness 80-88% and opacity 91-94% and double-coated 130 g / m 2, Hunter gloss 70-80%, PPS S10 roughness 0.65-0.95 µm, brightness 83-90% and opacity 95-97%.

5

Release papers having a basis weight of 25 to 150 g / m2.

Other fine papers include: packaging papers (Sackkraft), tissue papers (Tissue) and wallpaper (Wallpaper).

10

Pulp, mechanical pulp and / or recycled pulp are used for the production of paperboard. The cartons can be divided into e.g. to the following main categories according to their intended use.

Corrugated cardboard with a liner and fluting.

15

Boxes are made of boxes, boxes for example. liquid packaging boards (FBB, WLC, SBS).

As regards the prior art, reference is made to Fl Patent 96334, which discloses a method for calendering paper or similar web material in a calender. In the method, the web material to be calendered is passed through the nip formed by the deflection compensated upper roller and the deflection compensated lower roller and the upper and lower rollers. The rolls are imitated by • ♦ * ··· 1 is a vertical roll stack. Intermediate rolls are rolls that have a 25 ′ natural deflection line due to their own weight and are essentially the same • · · * "! manlainen. The nip e · • · 7 small load caused by the masses of the intermediate rolls and associated auxiliaries is substantially alleviated in the method and the adjustable load is applied to the calendering nipple by deflection compensated upper or lower roller and / or external load on the upper or lower roller.

I 30 • 1 5 119068

Typically, compression is accomplished in a multi-roll calender by securing the top or bottom roll of the roll stack and squeezing the stack of rolls against a fixed roll, which may be a top roll, a lower roll, or any of some of the spacers. Alternatively, both the upper and lower rollers are pressed against each other 5 either so that neither of the intermediate rolls is locked in place or at least one of the intermediate rolls is locked in place. The deflections of the rolls can generally be compensated by deflection compensation devices in the upper and lower rolls, for example, so that the roll nipples take a straight line shape.

10 As is known in the roll stack of a multi-roll calender, the center axes of the calender rolls have been parallel. The central axes of the calender rolls have been transverse to the direction of web travel in the CD direction. There is then a web calendering nip between adjacent calender rolls forming a pair of calender rolls with a compression plane parallel to the central axes of the calender rolls of the calender roll pair.

15

Calendering technology is increasingly switching to on-line calendering as the speeds required by paper machines increase. Multi-nip on-line calendering is calendering in a calender unit in which the nips are formed by alternating rolls of a smooth surface, such as a metal roll, and a spring-coated roll, such as: polymer roll, between. Line loading * ·· ···· _ increases in multi-nip calendars from the top nip to the bottom nip due to the pulling power of the earth, unless roller lightening systems are used. The current multi-nip calendars utilize a roller and a roller lever to compensate for the downward movement of the downward slope, to control deflection of the roll, to control the roll deflection line and also to quickly open the roller. apply a reduction. Such a roller lightening system is used in the applicant's well-known multi roller calendars, OptiLoad and TwinLine.

• · • ·. Many roll roll calenders are known in the art, with a roll set consisting of two rolls, each having at least two roll rolls, for example, one roll and roll roll, and the need for online calendering also increases. possibility of carrying out different types of calendering with a calender, which can be accomplished, for example, in a known nip mode known per se, in which the paper web is passed through the calender such that the arrangement is that it is not readily applicable to efficient production machines because in such an arrangement the forces exerted on the calender bearings are very high.

10

As is known in the art, for example from FI-96334 and EP-732444, the calender rolls forming the nip of a multi-roll calender have been rolled bearings, which has given rise to certain problems which require special arrangements to solve.

15

In some cases, multi-roll calendars are driven with line loads that cause very little load on the roller bearings of the calender roll, even so-called. zero load. This is very problematic for the roller bearings, because • ·· *. * *, Under zero load, the roller bearings have a considerable amount of sliding • · • * ·: 20 relative to the bearings instead of rolling, resulting in a relatively rapid breakdown of ··· · * ·: In the case of a rolling bearing with zero load, the contact points between the rolling bearing rolling elements and the bearing surfaces of the roller bearings are adversely vague and interchangeable because the bearing rollers do not regularly squeeze the rolling elements between them in any direction. 25 power.

It is an object of the present invention to provide a method in a multi-roll calender and a multi-roll calender that can implement different types of driving modes, i.e., partial nip driving.

It is an object of the present invention to eliminate the above problems and drawbacks, or at least to reduce the aforesaid and drawbacks, and to prevent the zero loading of the roller calender roller bearing, or at least to reduce the line load. an area where the load on the calender roller bearings would be too low.

In order to achieve the object of the invention, the method of the invention is essentially characterized by what is set forth in the characterizing part of claim 1.

The multi-roll calender according to the invention, in turn, is essentially characterized by what is stated in the characterizing part of claim 8.

In the method of the invention applied to a two-roll multi-roll calender, each track having at least two rolls, preferably one track having more than three and the other track having more than five rolls, and wherein the upper two rolls of the second track are preferably arranged to form a mat the rollers are soft-surface calender rolls 15, and provide a possibility for the fish blades to perform different types of calendering on the fibrous web being run in the calender by using a partial nip in the calender.

*** · V * According to the invention, the track can, for example, carry out seven different driving modes. These partial nip drives are implemented by locking the lower or second lower intermediate roller of each roller with a hydraulic cylinder to the lower position, thereby loading the rolls above or below the locked roller to provide the required number of nipples. In this case, the track export is the same regardless of the driving mode. If the calender is to be applied to provide a matte web, the web is only exported. For example, a second roller is passed through a mat formed between the two upper rollers.

• · • · · ····· | The method according to the invention for loading the roller bearing of the multi-roll calender caliper roll is mainly characterized by what is stated in the characterizing part of claim 11.

• IMI • * 8 119068

The multi-roll calender according to the invention, in turn, is essentially characterized by what is stated in the characterizing part of claim 20.

In the context of the invention, it is preferred that the central axis 5 of the at least one calender roll is arranged inside or outside the nip plane in a single or dual roll multi roll calender and according to one embodiment the central axis of at least one calender roll is fixed to the inside or outside of the nip plane. Preferably, in the roll stack of the multi-roll calender, the center axis of the top roll is arranged fixed inside the nip plane to provide a horizontal force component to the top roll roll bearings when the top roll is in nip contact.

According to one embodiment of the invention, the center axis of the at least one calender roll is moved inside or outside the nip plane, wherein the center axis motion can be circular or linear or a combination of the above.

15

Preferably, the center axis of the intermediate roller above the lower roller is moved aside from the nip plane to provide a horizontal force component to the bearings of said intermediate roller when the intermediate roller is in nip contact.

The invention provides significant advantages over prior art solutions, and among these benefits, the following may be mentioned. Because the center axis of the calender roller of the multi-channel ***** lantern calender is located or can be offset from the nip plane formed by the center axes of the other calender rollers, the horizontal force component dependent on the line load is applied to the bearings of this # • · * ··· . This horizontal force clamps the bearing rollers and roller surfaces aaa * · "against each other and prevents the roller elements from sliding on the roller surfaces. Using said • · • · *" horizontal force can significantly reduce the line load area where *** "calender roller bearing loadings are too low. The so-called calendering nip. In the case of a load of zero m *, the rolling elements of the rolling bearing cannot slide with respect to the bearing rings instead of rolling, which results in an improvement of the bearing life and of the fiber web machine in general. Thus, replacement times of damaged bearings 9 119068 and cooling and warming times of heated calender rolls can be avoided and more time spent on the actual fish sharpening process. In addition, bearings do not have to be stored to such an extent for bearing damage.

5

The invention will now be described with reference to the accompanying principal figures, which illustrate the method and the multi-roll calender according to the invention, without, however, limiting the invention to those shown in the figures.

Figures 1-7 schematically illustrate some application examples for implementing the method of the invention in a two-roll multi-roll calender to provide different driving modes.

Figure 8 schematically illustrates a preferred embodiment of a roll locking fluid 15.

Figure 9 shows a five-roll and four-nip roll stack of a multi-roll calender in which the center axis of one of the calender rolls can be located substantially inside the nip plane formed by the center axes of the other fish roll rolls.

Fig. 10 shows the nip force acting on the calendering nip divided into horizontal * * horizontal and vertical components when the center axis of one calender roll is positioned ·· * · "! Substantially inside the nip plane formed by the center axes of the other calender rolls. - • * '··· * side.

25 • · ·

Figure 11 shows a multi-roll calender with two roll stacks.

Fig. 12 shows a roll stack of a multi-roll calender in which the center axis of the calender roll can be moved by linear motion with substantially the other axes of the other roll rolls; 30 inside and out.

• · 119068 ίο

In the following Figures 1-12, the same reference numerals and reference numerals are used for substantially similar parts and structures, unless otherwise indicated.

Figures 1-7 schematically illustrate some application examples for implementing a method according to the invention in a two-roll multi-roll calender to provide different driving modes. The multi-roll calender 150 shown in Figures 1-7 comprises two rolls 20A and 20B, in which the fiber web W is calendered in the nipples between the roll rolls. From above, the rollers of the track 20B are designated 21B-26B and the track numbers 21A-25A of the track 20A. In the exemplary embodiments shown in Figures 10, rolls 21A, 25A, 22B, 26B are soft-surface (polymer-coated) rolls, rolls 22A, 24A, 23B, 25B are steel rolls, either heated and / or cooled rolls, rolls 23A, 23B are polymeric rolls and roll 21B is a polymer coated roll. The partial nip drives provided by the invention are implemented in such a way that the lower or second lowest 15 intermediate rolls of each roller 20A, 20B can be locked by a hydraulic cylinder to a lower position, thereby loading the rolls above or below the locked roll to provide the required number of nips. In the embodiments shown in Figures 1-6, the export of web W is the same regardless of the driving mode. Figure 7 shows an application for providing a matte run, where M »

according to the embodiment shown in the figure, the web W is only introduced into the roller 20B

• · ·, · * 20 through a matte nipple formed by the two upper rollers.

«·· ···· ***** The driving method shown in Figure 1 provides a driving method where calendering

...! are rolled on each track with five rolls, i.e. track 20B with rolls 21B-26B

• · · • * * ··· 'and track 20A with rollers 21A-25A. In the figure, a 5 + 5 driving mode application is shown and in the embodiment shown in the figure, rolls 24A and 25B are locked. This method of driving is • • · · ;;; specializes in SC paper grades, coated paper and board.

*: *: **: Fig. 2 shows a driving mode in which track 20B uses five rolls, i.e., rolls * * 22B-26B, and track 20A uses three rolls, i.e., rolls 23A-25A. In this figure, the driving mode application 5 + 3 shown in ϊ / · ί 30 and the rollers 24A and 25B are locked. This mode of driving is particularly suited to SC types.

119068 n

Figure 3 shows a driving mode in which three rollers, i.e. rollers 24B-26B, are used in the track 20B and all five rolls, i.e. rolls 21A-25A, in the track 20A. The figure thus shows a 3 + 5 driving mode application and the rollers 24A and 25B are locked. This mode of driving is particularly suitable for SCs.

5

Fig. 4 shows an application example in which the three lower rollers, i.e. rollers 24B-26B and 23A-25A, are used for calendering in each track 20A, 20B. The figure shows a 3 + 3 driving mode application and the rollers 24A and 25B are locked. This method of driving is well suited to SC grades, especially SC-B grades.

10

In Figure 5, the calender 150 is formed as a two-nip soft calender, i.e. the two lower rolls 25B-26B and 24A-25A of each track 20B, 20A are used. The driving mode application shown in the figure is typically suitable for the Optisoft-type calender type driving mode in the case of a double nip calender-15 ri and the locked rolls are rolls 24A and 25B. This method of driving is particularly suitable for uncoated board calendars and news paper grades.

Fig. 6 illustrates a driving mode in which calender 150 is configured to have a single nipple • · · '·' / soft calender operating mode using the two lower rollers 9B ** 26 * of roller 20B, i.e. rollers 25B-26B. The driving mode application shown in the figure is a kind of one · · · ****. the Optisoft type calipers drive mode and the locked roll is roll 25B.

• «, This mode of transport is advantageous for uncoated board and news grade" ··. Paper grades.

The application example shown in Fig. 7 provides a matte driving mode using * · * ·. ···, soft-surface rollers placed in the two upper rolls of the track 20B. 2IB, 22B. The driving mode application shown in the figure is in a way similar to • Optisoft type calender for matte grades. This mode of operation is thus suitable for use in the production of • * matte paper grades, especially when used for coated paper grades such as • · · ** * j 30 LWC, MWC and WFC.

• ·, 2 «90« β

1-7, according to the invention, the web can be freely introduced into the first upper or lower nip according to the layout and the needs of the manufacturing line.

Fig. 8 shows a schematic example of a locking roller 5 of a lockable roll using a hydraulically lockable relief cylinder. The hydraulic locking system is designated by reference numeral 42 and the relief cylinder by reference numeral 43.

9-12, the term nip plane refers to the plane formed by the central axes of the calender rolls, some of which are also referred to as 10 nip lines. The term "inside the nip plane" as used herein refers to the position on the side of the nip plane that is on the side of the body of the multi-roll calender.

Figures 9 to 11 schematically show multi-roll calendars 100 and Figure 12 schematically shows multi-roll calendars 200. In particular, the figures show roll stacks 10a, 15 10b, 10c, 10d including upper roll 11 and lower roll 15 and three intermediate rolls 12, 13 and 14 wherein the upper, lower and intermediate rolls form the calender rolls 11-15 of each roll stack. In multi roll calendars, no fiber to be calendered is shown. In the stack piles, adjacent calender rolls 11.12; 12.13; 13,14 • · and 14,15 form the calender roll pairs, wherein the calender rolls form the respective • · ”'** of each of the nipples 1, 2, 3 and 4 of the fiber calender nip 1, 2, 3 and 4. In this context, the invention has been illustrated using a gold roll, such as a five roll and four nip roll stack, but also something else. ···, the number of roll rolls and nipples in a roll stack may be just as relevant. also applying the roll stack described in connection with the present invention in the single stack multi roll calender 100 in a two or more stack multi roll roll lantern, and applying the roll stack described in the two stack multi roll roll calender 200 in a single stack or multiple stack roll roll calender.

• «• ·

In a multi-roll calender, compression of the fibrous web can be accomplished by either attaching * * · '* Ί 30 the top roll 11, bottom roll 15, or one of the intermediate rolls 12, 13, 14 of the roll stack relative to the calender body described by the dotted, F1, and squeezing the roll stack / single roll relative to the stationary roll relative to the body F, which may be a top roll 11, a lower roll 15, or even one or some of the intermediate rolls 12, 13, 14. Alternatively, both the top roll and the lower roll are pressed against each other. that none of the spacer 5 jaws are locked in place or that at least one of the spacer rolls is locked in place. In many solutions, the compressive forces of the upper roller 11 and / or the lower roller 15 can be independently adjusted. In the multi-roll calender, the upper roll and / or lower roll may be provided with a loading apparatus tracked inside the jacket and / or the top roll may be loaded with an overhead loading cylinder and / or the lower roll 10 may be loaded with a lower loading Deflection compensating devices are typically provided in the upper and / or lower roll, but also one of the intermediate rolls may be provided with deflection compensating means.

15

9-12, the roll stacks of the multi-roll calenders 100, 200 are shown in a position where the top nipple 1 and spacer nip 2 are closed, the spacer nip 3 is open and the bottom nip 4 is closed, wherein the fibrous web is calendered in closed nipples 1, 2 and 4.

In Figure 9-11, the lowest intermediate roll 14, in particular the central axis C14 of the intermediate roll 14, is tracked * · · to be moved along a circular path T. The center of the circular path T is pivot 17 on body F of multi-roll calender For example: • 1 1 * ;;; the intermediate roll 14 is mounted on the multi-roll calender body F by a support and load arm pivoting about the joint 17, not shown in more detail.

. The lowest intermediate roll 14 can also be nip-contacted with the intermediate intermediate roll 13 above, illustrated by the dashed station 14 'of the intermediate roll 14.

• 1

In the roll rolls of the multi-roll calendars 100, 200, the central axes of the calender rolls are parallel to 1 · 30. According to the invention, the central axis 1 of the at least one calender roll is either present or can be located inside or outside the nip plane formed by the central axes of the other calender rolls when said at least one calender roll is in nip contact. The center axes of the calender rolls are denoted by a reference mark C and a subscript corresponding to the roll reference number in each case.

9, the center axis C14 of the intermediate roll 14 is brought into the nip plane P formed by the other central axes Cu, C12, C13 and C15 of the calender rolls 11a, 12, 13 and 15 of the roll stack 10a when the intermediate roll 14 is in contact with the upper intermediate roll 13, e.g. is designated C14 '. The central axis C14 of the intermediate roll 14 is arranged to be moved along a circular path 10 of motion. The central axis C m of the intermediate roll 14 is also adjustable to be inside the nip plane P when the intermediate roll 14 is in contact with the upper intermediate roll 13 and the lower lower roll 15. The central axis C14 of the intermediate roll 14 can be made to be inside the nip plane P when the intermediate roll 14 is in contact with the lower roll 15 exclusively in the nip.

15

It is also possible for the center axis C14 of the intermediate roll 14 for the nip contact of the intermediate roll 14 to be in the same nip plane P as the central axes of the other calender rolls. As shown in Figure 8, the curved movement path T of the central axis C14 of the intermediate roll 14 touches the nip plane P

When the central axis C14 is at the same height as the joint 17.

: 20 · · · ···· The rotation T of the center axis of the nip plane P or the inner calender roll can be influenced in various ways, such as by appropriately selecting the position of the joint 17 in the body F, the distance Cm of the center axis from the joint • · · · angular position with respect to frame F. The trajectory of the center axis Cm need not be a pattern. As shown in FIG. 9, it is circular in shape but essential to the trajectory T is] * · *, a geometry such that the center axis Cm can be placed inside the nip plane P or to the nip contact 14 of the intermediate roll 14. The straight line of motion of a calender roll center axis] is illustrated in Figure 12 and its associated spine. * with satisfaction.

V *: 30 • · u 11906ε

Naturally, the curved trajectory T of the calender roll and its central axis can also be determined as shown in Fig. 10, whereby the highest point of the trajectory T is a lateral and intersection point with nip plane P and, for example, a circular arc of trajectory T continues below said intersection. In the arrangement of Fig. 10 5, it is possible to track the nip contact of the intermediate roll 14 'with the upper intermediate roll 13 in the nip plane P, whereby the central axis C 1 of the intermediate roll 14' is in the same horizontal plane as the joint 17 .

10 illustrates the nip force Fn particularly acting on the calendering nip divided into a horizontal force component Fh and a vertical force component Fv when the calender roll is disposed substantially aside from the center plane of the other axes formed by the central axis of the other roller calender rolls. Inside the nip plane P formed by the center axes Cn, C12, C13 and C15 of the calender rolls 11,12,13,15 of the 15 den roll stack 10b.

The method of the invention and the multi-roll calender can prevent a zero-load position of the rolling roller 14 of the intermediate roll 14, such a situation may occur when it is desired to drive with line loads that cause rolling bearings. · "*** 'at a very low load. At zero load, the roller bearing members would slide with respect to the bearing frames instead of rolling, resulting in" "a rather rapid breakage of the bearing. The calendering nip can be known to be lightened by actuators such as cylindrical actuators acting on, for example, the multi-roll calender body and the supporting and loading arms. • 14 drug lines are subjected to a line load ri The dripping horizontal force component Fh. The method of the invention and the multi-roll calender can reduce the line loading range * * · * · '1 30, whereby the load on the rolling bearings of the intermediate roll 14 would be too low.

• · 119068 16

Figure 11 shows a multi-roll calender 200 with two roll stacks. The left roll stack 10a has already been described earlier in this specification in connection with Figure 9. The right-hand roll stack 10c of the dual-stack multi-roll calender 200 comprises a single calender roll having a central axis substantially located inside the nip plane P of the three axes 5 of the calender rolls 10c and another calender roll whose center axis

10 The central axis Cu of the upper calender roll 11 of the right roll stack 10c of the multi roll calender 200 is disposed substantially inside the nip plane P formed by the three calenders rolls 12, 13, 15 of the roll stack 10c. The top calender roll is a fixed top roll 11, which is fixed to the body F of the multi-roll calender, e.g. Alternatively, the central axis Cu may lie outside the nip plane P. Due to the positioning of the central axis Cu at the side, the nip plane P has bearings with a linear force component dependent on the line load, which is dependent on the line load. Taking into account said horizontal force component, the line loading area whereby the load on the roller bearings of the upper roller 11 is * * · * · * 'too small and thus allows the roller bearings' roller bearings to roll instead of sliding, whose »* · * * * *. slipping would cause the bearing to break quite quickly.

• · «• · ·

The central axis C14 of the lowest intermediate roll 14 of the multi-roll calender 200 roll stack 10c may be located substantially inside the nip plane P formed by the central axes C12, C13 and 25 C15 of the three calender rolls 12,13,15 at position C14 or outside, ·· *. Ci4-. In other words, the spacer roll 14 may be tracked into a nip contact with the upper spacer roller, namely, for example, at position 14, 'aside from the nip plane P and the spacer ···· «! Sat 14 may be arranged in a nip contact with underside lower roll 15 to the side • ·. from the nip plane P, for example to position 14. In Fig. 11, the trajectory T of the roll stack 10c differs from the calender roll rotations shown in Figs. 9 and 10 so that the curved trajectory T of Fig. 11 intersects the nip plane P and continues nip-119068 17 from inside of plane P to outside. Due to the positioning of the center axis Cu of the intermediate roll 14 at the side due to the nip plane P, the bearings of the intermediate roll 14 are subjected to a linear force component dependent on the line load. Taking into account said horizontal force component, the line loading area whereby the load on the rolling roller bearings of the intermediate roll 14 may be too low can be reduced, thereby enabling the rolling roller rollers to roll with respect to the bearings rather than slipping.

Fig. 12 shows a roll stack 10d of a multi-roll calender in which the calender roll 10 can be moved in a linear motion such that the center axis of the calender roll can be brought substantially inside or outside the nip plane formed by the center axes of other calender rolls. In the example of Fig. 12, the lowest intermediate roll 14 can be displaced by a linear motion substantially aside from the nip plane formed by the central axes Cu, C12, C13 and Q5 of the other calender rolls 11,12,13,15. The said linear motion may be horizontal according to the path of motion Lh or the linear motion may be inclined with respect to the horizontal plane, for example according to the path of motion LA. Essential for the trajectories Lh, La is that the central axis C14 of the intermediate roll 14 may be brought inside or inside the nip plane P for nip contact of the intermediate roll 14. In this case, the positioning of the center axis Cm of the central roller may cause the bearings of the intermediate roll 14 to have a horizontal force component FH dependent on the linear load of the 20 roller calendars, thus avoiding a zero load situation or . * tus would be too small, • · «

Ml * «« · * · • ·

Of course, it is possible to form combinations of curved and linear motions as shown, or any other moving path that brings the nip plane P aside, so that at least. · * ·. The center axis of one calender roll is arranged by the center axes of t in or out when said at least one calender roll is in nip contact to provide a horizontal force component to the bearings of said at least one fish roll.

• 1 18 1 1 9068

The invention has been described above by way of example with reference to the figures in the accompanying drawings. However, the invention is not limited to what is described in the description and figures, but various embodiments of the invention may vary within the scope of the inventive idea defined in the appended claims.

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Claims (28)

A method in a multi-calender, or which method a fiber web, in particular a paper or cardboard web (W), is calendered in a multiple calender (150) comprising two roll sets (20A, 20B), each roll set having at least two calender rolls. , characterized in that the lower or second lowest intermediate roll in each roll set (20A, 20B) in the plurality scales is read in a lower position, whereby a necessary number of calendering nip is in use by loading the rollers above or below the loaded roll. 10 2. A method according to claim 1, characterized in that in the method the fiber web (W) is calendered in a multiple roll calender where one roll set (20A) comprises more than three rolls (21A-25A) and the other roll set (20B) more than five. rollers (21B-26B). 15 Method according to claim 1 or 2, characterized in that in the method the fiber web (W) is calendered in a multiple roll calender (150) with two roll sets (20A, 20B), in which two top rolls (21B, 22B) in the second roll set - The 1 · 1: (20B) rollers are provided which form a matte nip to provide a matte driving method. * · »L1M •: ** i Method according to any one of claims 1-3, characterized in that in the method the fiber web (W) is run through nip formed between the five lowest rollers in each roll set (20A, 20B). 25 A method according to any of claims 1-4, characterized in that in the process the fiber web (W) is calendered with the five lowest rollers in the first roll: set (20B) and in the nip. formed between the three lower rollers of the second *? **: the roller set (20A) or vice versa. : 30 • · · ♦ ♦♦ »· 119068 Method according to any one of claims 1-5, characterized in that in the process the fiber web (W) is calendered between calender nips formed by the three bottom rollers ΐ each calender roll set (20A, 20B). 5 Process according to any of claims 1-6, characterized in that in the method the fiber web (W) is calendered in a calendering nip formed between the two lower rollers in at least one roll set (20B; 20A). Multiple roll calender for calendering a fiber web (W) comprising two roll sets (20A.20B), each roll set (20A, 20B) indicating at least two calender rolls, characterized in that the lower or the second lower middle roll in each roll set (20A, 20B) of the calender (150) comprises devices arranged therewith for reading it in a lower position, whereby a necessary number of calender nips are put into service by loading the rollers above or below the Iastä roll. Multiple roll calender according to claim 8, characterized in that one calender roll set (20 A) comprises more than three rollers (21A-25A) and the other Σ roll set (20B) more than five rollers (21B-26B). 20 Multiple roll calender according to claim 8 or 9, characterized in that the two upper rollers (21B, 22B) in the second roll set (20B) are provided with soft surface calender rolls which form a matte nip. ***** • · ··· 25 11. A method of loading the bearings for a calender roll (11,12,13,14,15) one · · · ·; · / multiple roll calender (100,200), wherein the multiple roll calender comprises one or more roll bars (10a, 10b, 10c, 10d), in which the center axes (Ci2, Ci3) of at least two calender rolls form a key plane (P), characterized in that the center axis (Cn, Ci4) of * at least one calender roll (11,14) in a roll stack (10a, 10b, 10c, 10d) in multiple rolls;: landem (100,200) is arranged on the side Mn the plane (P) formed by the center axes (Ci2, Ci3, Ci5) of the the other calender rolls (12,13,15) in this roll stack for providing a horizontal force component (Fh) on the bearings of the calender roll when said at least one calender roll is in pinch contact. Method according to claim 11, characterized in that the central axis (Cu, Cm) of at least one calender roll (11, 14) is arranged inside or outside the key plane (P) · Method according to Claim 11 or 12, characterized in that the central axis (Ch, Cm) of at least one calender roll (11, 14) is fixedly fixed inside or outside the key plane (P). Method according to Claim 13, characterized in that the center shaft (Cu) of an upper roller (11) is fixedly fixed inside the socket plane (P). Method according to Claim 11 or 12, characterized in that the center axis (Ch, Cm) of at least one calender roll (11, 14) is moved inside or outside the nip plane (P). ··· ν ' 16. A method according to claim 15, characterized in that the center axis of a calender roll is displaced along a circular motif (T). m • · ···· 17. A method according to claim 15, characterized in that the center axis of a calender roll is displaced along a linear path of movement (Lh, La). • · · • · • · * ·· 25 18. A method according to claim 15, characterized in that the center axis of a calender roll is displaced along a path of movement which is a combination of a circular orbital path (L) and a linear path of motion (Lh, La). . • · • at • ·· • · Method according to any of claims 15-18, characterized in that the center axis (Cm) of an intermediate roller (14) above a lower roller (15) is displaced laterally from the nip plane (P). 27 1 1 9068 Multiple roll calender (100,200) for carrying out the method of claim 1 comprising one or more roll bars (10a, 10b, 10c, 10d), in which the center axes (C12, C13) of at least two calender rolls (11,12,13,14 15) forms a key plane (P), characterized in that the center axis (Cn, Ci4) of at least one calender roll (11,14) in a roll stack (10a, 10b, 10c, 10d) in the plurality calendar (100,200) is arranged. on the side of the key plane (P) formed by the center shafts (C12, C13, Cis) of the other calender rolls (12,13,15) in this roll stack, said at least one calender roll strengthening in nip contact. 10 21. Multiple roll calender according to claim 20, characterized in that the center axis (Cn, Ci4) of at least one calender roll (11, 14) is arranged inside or outside the key plane (P). 22. Multiple roll calender according to claim 20 or 21, characterized in that the central axis (Cu, Cu) of at least one calender roll (11, 14) is arranged firmly inside or outside the key plane (P). 23. Multiple roll calender according to claim 22, characterized in that the central shaft (Cu) of an Upper roll (11) is arranged firmly inside the key plane (P). Multiple roll calender according to claim 20 or 21, characterized in that the m • Φ · ···· 'center axis (Cn, Cu) of at least one calender roll (11,14) is movable inside · »· • · * * · · * or outside the key plane (P). 25 * * · 25. Multiple roll calender according to claim 24, characterized in that the path of movement of the center axis of a calender roll is a circular motif (T). • · • · «• · e • t Multiple roll calender according to claim 24, characterized in that the path of movement of the center axis of a calender roll is a linear path of movement (Lh, La). φ * · „„ 119068 Multicolor calender according to claim 24, characterized in that the movement path of the central axis of a calender roll is a combination of a circular motif (T) and a linear movement path (Lh, La). Multicolor calender according to any of claims 24-27, characterized in that the central axis (Cu) of an intermediate roller (14) above a lower roller (15) is displaceable in the side from the nip plane (P). 10 ·· «• · 1 • · a • · • · · · · · ···« * • Φ · • · • · · • M · ··· • f • · · ♦ · • · • · ♦ • · ♦ · ♦ · · ··· t · · · · · · · · · · 1 t · • · • Φ · Φ Φ Φ Φ # Φ Φ Φ Φ Φ