The invention relates to a calender for calendering a paper web, in particular made from paper suitable for gravure printing, in accordance with the preamble of claim 1.
Paper webs are calendered in order to improve the surface quality. Papers which are suitable for gravure printing and belong to the high quality papers require a particularly great smoothness. EP 0 886 695 B1 has disclosed a calender for treating a paper web, which calender has a plurality of rolls which form what are known as soft nips between in each case one hard and one soft roll as working nips. The plurality of working nips make calendering possible to high smoothness values which are crucial for a satisfactory printed result.
At high machine speeds during online or offline operation, however, high temperatures have to be selected to this end. Said high temperatures can lead to hornification on the surface of the paper web which has a disadvantageous effect on the gravure printing. Furthermore, great heat losses to the surroundings occur at high temperatures of the roll surface of the heated rolls.
It is therefore an object of the present invention to provide a calender which calenders a paper web to a great extent and in the process can be operated in a manner which saves costs and energy.
This object is achieved by the features of claim 1.
As a result, a calender is provided, in which, before entering the first working nip, the paper web runs through a pretreatment section in order to produce an optimum temperature profile during calendering in the working nips. To this end, the roll surface temperature of the heated rolls of a roll stack needs only to be selected to be slightly higher than the plasticization temperature of the respective paper web at a selectable moisture content. For example, calendering can be carried out in the working nips at a roll surface temperature which to this extent is higher only by from 10 to 30° C.
The greater diameter of the end roll which delimits the respectively first nip in comparison with a hard, heated intermediate roll makes it possible to construct a treatment section, the length of which is great in comparison with the nip length. As a result, the increase of the calendering effect in multinip calenders with soft nips and with extended soft nips (broad nip) is possible. This applies, in particular, to SC-A, SC-B and LWC paper. The energy saving results from reduced heat emission and reduced forced convection of the heated rolls. In addition, the degree of efficiency of the heat transfer is increased, since the amount of heat loss is reduced.
The increased dwell time in the web treatment nip in conjunction with a preferably elastic surface of the circulating belt improves the heating of the paper web considerably. Satisfactory heat transfer is ensured, since the paper web is pressed uniformly against the heated roll, with the result that, for example, air cushions from unevennesses of the paper web which might impede the heat transfer are avoided largely. The advantages of the proposed calender therefore result from the extended dwell section for heating the web in conjunction with the configuration of the circulating belt, immediately before the paper web runs through the working nips of a roll stack.
As a result of extended heating of the paper web in the web treatment nip, uniform heating of the paper web down to the technologically required depth is possible. To this end, roll surface temperatures in the range from 80° C. to 160° C. are generally sufficient. The level of the temperature is reduced in favor of an extension of the time period of the temperature action. The reduction in the level of the temperature for the thermomechanical calendering operation is then determined substantially only by the plasticization temperature of the fibrous materials used of a paper web and their moisture content. Here, the preferably elastic surface of the belt ensures a uniform contact pressure and therefore uniform heat transfer from the heated roll to the paper web.
The contact pressure is preferably set by the tensioning of the belt. This tangential tensioning of the belt loads the belt, which usually comprises a plastic, a rubber, a plastic coated carrier material or a rubber coated carrier material, to a far lesser extent than radial tensioning. In the case of radial tensioning, the plastic tends toward delamination of a layer assembly. The thermal loading of the belt is low, with the result that the belt has a long service life.
The calender according to the invention has succeeded in realizing the advantages and effects to be expected by a simultaneous use of pressure and temperature in the nip in a manner which saves costs and energy in the calendering operation.
A dwell time in the web treatment nip required to achieve the desired penetration depth of the heat can be optimized by adjusting the pressing length of the belt against the circumference of the heated roll by means of guide rolls.
A controlled local pressure increase in the web treatment nip can preferably be set by guide rolls for the circulating belt additionally working as pressing rolls.
Further refinements of the invention can be gathered from the following description and the subclaims.
In the following text, the invention will be explained in greater detail using the exemplary embodiments which are shown in the appended figures, in which:
The invention relates to a calender 1 for calendering a paper web 2, in particular made from paper which is suitable for gravure printing.
The web treatment nip 8 preferably extends along an angle of the wrap of the hard, heated end roll 4.1. The circulating belt 14 has an elastic surface on the side which faces the paper web 2. The guide rolls 11, 12, 13 control belt tensioning of the belt 14 for pressure loading of the paper web 2 in the web treatment nip 8.
The diameter of the end roll 4.1 which delimits the first working nip 3 lies in the range from 1.2 m to 2.0 m. The diameter of a hard, heated intermediate roll 5.2 lies in the range from 0.6 to 1.2 m. The end rolls 4.1, 4.2 are preferably controlled deflection rolls for the simultaneous regulation of the property profiles of the web 2 in the transverse direction. All the rolls 4.1, 4.2, 5.1, 5.2 preferably have a dedicated power drive. The stacking of the rolls of a roll stack can be arranged vertically, horizontally or obliquely.
The roll stack can be loaded by at least one end-side loading cylinder and/or by individual loading elements which act on the rolls 4.1, 4.2, 5.1, 5.2 and by way of which the respective line load in the working nips can be set. The calender can be used online or offline.
The nip length of the soft nips 3 preferably lies in the range from 3 to 40 mm, depending on the type of roll as a soft roll or as a shoe roll with an elastic belt. The heated end roll 4.1 is heated, for example, to roll surface temperatures from 80° C. to 160° C. as a function of the plasticization temperature of the respective paper web 2 and its moisture content.
The contact face 9 is a circulating contact face which is formed by a belt 14 which circulates on the guide rolls 11, 12, 13. The other contact face 10 is formed by the circulating outer wall of the hard, heated roll 4.1. The web treatment nip 8 extends along an angle of the wrap of the heated roll 4.1. The angle of the wrap for varying the length of the web treatment nip 8 can be set as a function of a desired penetration depth of the heat into the paper web 2. The selectable dwell time is optimized by means of the guide rolls 11, 12, 13 by adjustment of the pressing length of the belt 14 on the circumference of the heated end roll 4.1. The pressing length on the circumference of the roll 4.1 can preferably be set variably from 0.25 to 5.0 m.
The circulating belt 14 presses the paper web 2 against the heated roll 4.1 with an elastic surface in order to increase the degree of thermal efficiency of the heat transfer.
The contact pressure in the web treatment nip 8 is set by the tensioning of the belt 14. The maximum tensile stress of the belt 14 is limited to preferably 200 kN/m. The compressive stress which can be achieved in the pretreatment zone of the web treatment nip 8 can assume, for example, a value in the range from 0.01 MPa to 0.5 MPa. This depends on the belt tensioning and the selected dimensions of the heated end roll 4.1.
Before entry into the web treatment nip 8, the web 2 can wrap around the heated end roll 4.1 along a part section.
The surface temperature of the heated end roll 4.1 is preferably regulated in such a way that, within the dwell time of the web 2 below the belt 14, the glass transition temperature is achieved in an optimum penetration depth for the respective aim of the calendering operation. For high calendering, a penetration depth of approximately 10 μm is sufficient. The surface temperature and the length of the pretreatment section of the web treatment nip 8 are optimized in such a way that operation is made possible at a temperature which does not substantially exceed the glass transition temperature of the surface region to be plasticized of the web 2. The web 2 which has been pretreated in this way and can be dampened upstream of the calender 1 with nozzle and/or steam moisteners is calendered directly behind the pretreatment section in the nip 3 and the following nips. The nip 3 is arranged immediately behind the wrapped section on the heated end roll 4.1. Moistening behind the calender 1 or between two calenders 1 is also possible if this is required technologically.
The circulating belt 14 preferably has an elastic surface for ensuring a uniform contact pressure which can be set by the tensioning of the belt 14. The heat transfer emanating from the heated end roll 4.1 to the paper web 2 is shielded thermally in the web treatment nip 8 with respect to the surroundings by the circulating belt 14 which is configured in this way. The introduction of heat into the paper web 2 is improved, since heat dissipation to the surroundings is reduced. If the elastic surface is a thermal insulator, the introduction of the heat into the paper web 2 is improved further. The elastic surface of the circulating belt 14 therefore preferably consists of a material with a thermal conductivity of less than or equal to 10 W/mK, in particular less than or equal to 5 W/mK, very preferably less than or equal to 1 W/mK. The hardness of the elastic surface preferably lies in the range from 50 Shore A to 92 Shore D.
The belt 14 preferably consists of a flat carrier material which is provided with one or more elastic layers. High strength plastic fibers, glass fibers or carbon fibers can be used as carrier material. A composite material of this type has a high tensile strength. In order to increase the mechanical strength of the belt, a supporting fabric or supporting belt made from the abovementioned fibers can also be incorporated. Furthermore, the circulating belt 14 can consist of a carrier material which is provided with an elastic layer, it also being possible for the carrier material to consist of a metal or metal strip. In the case of a sufficiently thin, elastic layer, the hardness of the metal can ensure calendering of that side of the paper web 2 which faces the circulating belt 14. The roughness of the elastic surface of the belt 14 preferably lies in the range from 0.5 to 5 μm. The smoothness then existing of the elastic surface of the belt 14 can be reproduced as smoothness on the paper web 2. The belt 14 has, for example, a heat resistant surface coating, for example made from silicone. The heat resistant coating affords high wear strength and a smooth surface.
The pretreatment section of the web treatment nip 8 also serves, in particular, to presmooth the web 2.
Furthermore, the circulating belt 14 preferably only has a low expansion which is less than or equal to 7%. The expansion which occurs during setting of the belt tension in the belt 14 on account of tensile stress in the belt 14 then does not disrupt the calendering. The belt 14 has at least the same width as the web 2. The thickness of the belt 14 depends on its width and length and can be between 4 and 20 mm.
At least one of the guide rolls 11, 13 can be configured as a pressing roll which presses the web 14 in the web treatment nip 8 along a section in the running direction L by way of additional radial pressure loading. A guide roll 11, 13 is preferably configured as a pressing roll on the inlet and/or outlet side of the web treatment nip 8. Here, the radial pressure loading can be set to be lower on the inlet side than on the outlet side, or vice versa. A pressing roll of this type can be a controlled deflection roll.
The web 2 which is conditioned in the web treatment nip 8 is finally calendered in a directly following nip 3 which is formed with the same heated roll 4.1 and in the following nips, formed by the rolls 5.1, 5.2 and 4.2. The line loads in this nip sequence can be adapted to the calendering effects to be achieved. Mean compressive stresses with paper in the nip from 2 N/mm2 to 55 N/mm2 can be set. The compressive stresses in the upper region of the stated range make the calendering of high quality papers possible, such as SC, LWC and MWC papers or wood-free coated papers. Exact profile regulation is possible by direct pressing of the two rolls 4.1 and 5.1, without a belt 14 being guided between them. Any possibly existing thickness differences of the belt 14 on account of production tolerances or thermal expansion do not affect the calendering result.
Since the temperature of the heated end roll 4.1 and the length of the treatment section which is formed under the belt 14 are set in such a way that substantially only that region of the web 2 which is close to the surface is heated, a conditioning section is produced, in which the interior of the web 2 remains below the plasticization or glass transition temperature. The thickness of that layer of the web 2 which is close to the surface and is heated above the plasticization temperature is many times greater than the largest unevennesses of the paper web surface. The thickness of the layer to be heated is therefore dependent on the roughness of the web 2 to be treated. The length of the web treatment nip 8 and the speed of the web 2 in the running direction L define the dwell time of the web 2 in the web treatment nip 8 and therefore also the penetration depth of the heat into the web 2 and the layer thickness which is heated to a deformation temperature.
The surrounding air which is entrained with the web 2 in the boundary layer impairs the heat transfer from the heated end roll 4.1 to the web 2. A substantial improvement of the heat transfer is achieved by removal of the boundary layer. This can take place, for example, by way of a contact section for adhering contact between the outer wall of the heated end roll 4.1 and the surface of the paper web 2 on the inlet side upstream of the web treatment device 7. Furthermore, pressing a guide roll 11 against the heated end roll 4.1 is suitable. As a result of these measures, the disruptive boundary layer can be displaced counter to the running direction of the web 2 and the heat transfer in the web treatment nip 8 can be increased further.
According to a further exemplary embodiment (not shown), an additional web treatment nip can be provided at a heated intermediate roll 5.2, 5.4.
In the case of exemplary embodiments described in the preceding text, the belt 14 can be cooled outside the web treatment nip 8. The return region of the belt 14 can be provided as a position for the cooling.
Number | Date | Country | Kind |
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09 008 506.9 | Jun 2009 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/003900 | 6/25/2010 | WO | 00 | 12/20/2011 |