FI80772C - Procedure in a bend controlled roller and a bend controlled roller - Google Patents

Description

80772 1 Method in deflection-controlled roll and deflection-adjusted roll Förfarande 1 en böjningsreglerad Vals och en böjningsreglerad Vals 5

The invention relates to a method in a deflection-controlled roll comprising a solid central shaft and a roll jacket arranged to rotate thereon, the space between the central shaft and said jacket being fitted with sliding shoe-loading piston devices or a similar pressure fluid chamber or a series thereof for controlling a counter roll with said tk roll. a nip profile and which sliding piston device or the like is arranged substantially at the plane of said nip and which roll shell is rotatably mounted in the vicinity of both ends at the bearing holes on said fixed shaft and which fixed shaft is supported outside the bearing points of the roll shell.

The invention further relates to a deflection-adjustable roll comprising a solid central shaft and a roll jacket rotatably mounted thereon, the space between the central shaft and said jacket being fitted with slip-load piston devices or a corresponding pressure fluid chamber or a series thereof adjustable with the counter roll of said tk roll. profile and which sliding piston device or the like is arranged substantially at the plane of said nip and which roll shell is rotatably mounted in the vicinity of both ends by bearings on said fixed shaft and which fixed shaft is supported outside the bearing points of the roll shell.

In paper machines, rolls are generally used which are formed with a counter roll of a dewatering press nip, a leveling nip or a calendering nip. For these applications, it is important that the line pressure distribution of the nip, i.e. the profile in the axial direction of the rolls, is made constant or that this profile is adjustable as desired to control, for example, the transverse moisture profile and / or thickness profile (caliber) of the web. For this purpose, various deflection-compensated or deflection-controlled rollers 2 80772 ^ (hereinafter abbreviated as both rolls tk-roll) are already known, which are intended to influence the distribution of the line pressure of the nip.

Several different paper machine tk rolls are already known. These rollers 5 generally comprise a solid or tubular, stationary roll shaft and a roll hub arranged to rotate around it. Between said shaft and the jacket are arranged sliding shoe arrangements acting on the inner surface of the jacket and / or a chamber or a series of chambers of pressurized fluid so that the axial profile of the jacket at the nip can be adjusted or adjusted as desired.

In general, nips formed by such rolls, such as press nips or calendering nips, are loaded with loading forces applied to the shaft pins of the tk roll and its counter roll.

The counter roll of the Tk roll generally has rotating shaft pins 15 fixedly connected to the roll shell, from which the roll is mounted. The Tk roll, in turn, is mounted on the solid shaft of the solid. The bearing spacings of the counter roll and the tk roll are generally different in size, so that the bearing spacing of the tk roll is substantially smaller than the bearing spacing of the counter roll, which results in certain drawbacks.

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It is already known that the difference in the shape of the deflection due to the mutual difference between the bearing spacing of the counter roll and the tk roll casing has been solved e.g. by the following means. The rollers are bombarded, but in this way a uniform nipple profile is achieved with only one load.

In particular, in the calendula, heating devices have been used to heat the roll jacket relative to the environment at those points where a higher line pressure is desired. This means also has its own limitations and disadvantages. The Tk roll uses an extended bearing spacing, which solves the problems in the frame structures of the paper machine. It is also known to use an overlapping pivot bearing and a rolling bearing in the bearing of the tk-te-30 and the counter roll. This known solution is very space consuming. It is also known that the so-called self-acting counter-torque rollers.

It is already known to use a tk roll 35 with an extended jacket so that the bearing gaps between the tk roll and the counter roll are made equal.

In this way, a deflection line is provided for the tk roll, which corresponds to the deflection flux of the counter-roll, which in turn results in the

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The caliber profile of the nip formed by 3 80772 ^ is substantially flat. However, there are numerous drawbacks to this extension of the mantle.

In the prior art tk rolls, the treatment of the end regions 5 of the adjustable casing has caused problems, so that most of the adjustment space of the hydraulic load elements often has to be used to correct the deflection deviation of the end regions of the roll. Due to this drawback, the actual adjustment range is often too small.

10 The so-called load-free tk rolls in which the stroke length of the piston-cylinder elements of the hydraulic load elements is adjusted so large that it is also sufficient to provide a nip opening movement and a closing movement, respectively, without the need for force-loaded loading arms acting on the roller shaft ends. In such load-free tk rolls, the hydraulic load elements, which act against the inner surface of the roll shell, provide not only deflection compensation and profiling, but also the actual nip pressure load. The disadvantages of the previously known load-free tk rolls are the complexity of the structure and the difficulties 20 of arranging the stroke length of the stationary central shaft and the piston-cylinder elements of the roll shell to a sufficient stroke and to provide sufficient nip load and compensation loads. The end regions of the roll shell in particular have proved to be particularly problematic in this respect.

25 With regard to the state of the art, special reference is made to CH-614502 and FI-68709. These publications disclose tk rolls provided with support devices on both sides of the nip plane which rest on the inner surface of the roll shell. However, the solutions according to these publications cannot reduce the load peaks of the roll or lighten the edge loads.

The object of the present invention is to avoid the disadvantages which appear above. More particularly, it is an object of the invention to provide a method in a deflection-controlled roll as well as a deflection-controlled roll operating according to the method, which achieves a substantial improvement over previously known solutions. To achieve this, the method according to the invention is mainly characterized in that in the edge areas of the roll shell a 80772 where load peaks occur in the nip between the tk roll and the counter roll, the tk roll roll is pressed outwards from the central axis of the tk roll substantially perpendicular to the nip plane with additional hydraulic loading devices acting on the inner surface of the roll shell and supported on the central 5 axis of the roll to stretch the roll shell in a plane perpendicular to said nip plane and to reduce the load peak.

The deflection-controlled roll according to the invention is in turn mainly characterized in that in the edge areas of the tk roll where load peaks are present in the nip, additional hydraulic loading devices acting on the inner surface of the roll shell and supported on the central shaft are arranged to press the inner shaft. in a plane substantially perpendicular to the plane of the nip on both sides of the plane of the nip to reduce the edge load, reduce the load peak and stretch the roll shell in said plane perpendicular to the plane of the nip.

As already stated above, in particular, the edge areas in the deflection-20 rolls form a problematic point of adjustment, because the edge areas require more roll deflection adjustment than the roll otherwise. Due to the load on the roll and the counter roll, load peaks due to thermal peaks or so-called "Gullwing-phenomenon". The hydraulic loading devices of the roll thus often have to use a fairly large part of the control margin to correct said load peaks. In this case, the adjustment means of the loading devices are often not sufficient to adjust the roll profile to a suitable level.

However, the method according to the invention and the deflection-controlled roll achieve a substantial improvement in this respect, since the load at the peaks in the roll according to the invention is pressed oval so that the entire adjustment range of the actual load devices can be used to correct the roll profile. The only possible condition for the solution according to the invention to work is that a rather thin-walled roll jacket has to be used in the invention. In principle, the solution according to the invention can be used at any point on the tk roll, if the need for additional adjustment also exists or is expected in the roll in addition to the edge areas.

In the following, the invention will be described in detail with reference to an embodiment of the invention shown in the figures of the accompanying drawing, to which, however, the invention is in no way narrowly limited.

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Figure 1 schematically shows a tk roll according to the invention in a partial axial vertical section, which tk roll forms a nip with a counter roll.

Fig. 2 schematically shows a partial cross-sectional view of the solution according to Fig. 1 for additional loading devices.

In the figures of the drawing, the tk roll is generally denoted by the reference number 10. The tk roll 10 comprises a stationary central shaft 11 on which a roll shell 12 is rotatably arranged. The roll shell 12 is supported on the central shaft 11 by hydraulic loading devices comprising sliding shoes 13 acting on the inner surface 12a of the roll shell. and load pistons 14 arranged in the bores formed in the central shaft 11, which are loaded by means of a pressurized fluid, e.g. oil. The hydraulic loading devices 20, 14, 14 are arranged in a nip plane so that the axial profile of the roll shell 12 of the tk roll can be adjusted by means of hydraulic loading devices. In the embodiment of Fig. 1, the roll shell 12 is rotatably supported at its ends on the central shaft 11 by bearings 15. The bearings 15 are protected by end plates 16 arranged at the roll ends and the central shaft 25 11 of the tk roll is supported on the machine frame structures by nlv bearings 17.

The outer surface 12b of the roll shell of the Tk roll 10 together with the outer surface 23 of the counter roll 20 forms a nip N through which the web of material passes. The counter roll 20 is mounted by means of its shaft pins 21 with bearings 22 on the machine frame structures. The arrow and reference numeral F in Fig. 1 have a loading force acting in the direction of the nip plane, with which the counter roll 20 is loaded against the tk roll 10.

35 Since the external loading forces F cause a bending moment of the counter roll 20 and consequently a relatively large load peak on the nip between the rollers 6 80772 1 on the edge areas of the nip, the adjustment space of the hydraulic loading devices 13,14 would not always be sufficient to repair the nip. As a result, in the embodiment of Figures 1 and 2, additional loading devices 5 are arranged on the edge areas of the tk roll 10 close to the ends of the roll, which act in a direction substantially perpendicular to the nip plane. Said additional loading devices 5 correspond in structure substantially to the actual hydraulic loading devices and thus comprise sliding shoes 6 acting on the inner surface 12a of the roll shell, which are pressed against the inner surface 12a of the roll shell by loading pistons 7 arranged in holes formed in the central shaft 11 of the tk roll 10. The additional loading devices 15 are arranged in pairs so that they are located at the same point in the axial direction of the roll and act in opposite compression directions. Said additional loading devices 5 thus aim to compress the roll shell 12 from the inside so that at the points of the additional loading devices 5 the roll shell stretches oval in a direction perpendicular to the nip plane. In the area of influence of the additional loading devices 5, the load acting on the nip N is thus substantially relieved. The dotted line 1a and the reference mark B have been used to illustrate the effect of the additional loading devices 5. In reality, the effect of said additional loading devices 5 on the oval elongation of the roll shell 12 is only of the order of 0.001 mm. In the figures of the drawing, it is shown that the additional loading devices 5 are arranged in the edge areas of the tk roll 10. However, said additional loading devices 5 can be used in the axial direction anywhere towards the roll, provided that it can be assumed that there is a need for further adjustment in the roll at said point.

The following are claims within the scope of which the various details of the invention may vary within the scope of the inventive idea.

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Claims (4)

A method of bending controlled roll, comprising a solid center shaft (11) and a roll sheath (12) arranged rotatably above it, wherein sliding shoe load piston devices (12) are arranged in the space between the center shaft (11) and said sheath (12). 13,14) or a corresponding pressure fluid chamber or a series thereof, which controls the profile of the nip (N) which can be formed by said bk roll (10) and a counter roll (20) and which sliding piston arrangement (13, 14, or the like, is disposed substantially at the plane of said nip (N) and said roller sheath (12) is rotatably mounted in proximity to both ends thereof with bearings (15) above said stationary shaft (11) and which stationary shaft (11) is supported outside the storage locations of the roller sheath (12), characterized in that at the edge areas of the roller sheath (12), where the loading peaks appear in the nip (N) between the bk roller (10) and the counter roller (20). the roller sheath (12) is pressed out of the bk roller from the bk roller's center shaft (11) substantially in a plane perpendicular to the plane of the nip (N) perpendicular to the plane of the nip by hydraulic additional loading devices (5) acting on the inner surface (12a) of the roller sheath and supported against the center axis of the roller to extend 20 out the roller sheath (12) in said perpendicular to the plane of the nip (N) and to reduce the load peak. 1 Patent claim 2. Bending controlled roller, comprising a solid center shaft (11) and a roller sheath (12) arranged rotatably on top thereof, wherein sliding shoe load piston devices (13) are arranged in the space between the center shaft (11). 14) or the corresponding pressurized liquid chamber or a series of seeds with which the profile of the nip (N) which can be formed by said bk roll (10) with a counter roll (20) can be controlled and which sliding piston arrangement (13,14) or the corresponding is disposed substantially at the plane of said nip (N) and said roller sheath (12) is rotatably supported in proximity to both ends by bearings (15) above said stationary shaft (11) and which stationary shaft is supported outside the storage location of said shaft (12) , characterized in that at the edge regions of the bk roller (10), where load peaks appear in the nip (N), hydraulic supplementary loading devices (5) are arranged in the space between the center shaft (11) and said sheath (12). are formed on the inner surface (12a) of the roller sheath and which abut against the center shaft (11), which are arranged to press against said inner surface (12a) of the bk roller in a plane perpendicular to the plane of the nip (N) on both sides of the plane of the nip (N) to lighten the edge load, reduce the load stop and extend the roller sheath (10) in a plane perpendicular to the plane of said nip. 3. Vais according to claim 2, characterized in that said hydraulic load piston devices (5) comprise sliding shoe load piston devices (6,7), whose slides (6) are arranged to act on the inner surface by means of an oil film. (12a) of the roller sheath and whose load pistons (7) are supported against cylinder bores formed in the center shaft (11). 4. Vais according to Claim 2 or 3, characterized in that said additional loading devices (5) are arranged in pairs in the axial direction of the roller at the same location to act in opposite directions. 20 25 30 35 II