EP2270280B1 - Calender for treating a material web - Google Patents

Abstract

The calender (1) has a web treatment device (7) including two contact surfaces (9, 10) forming a treatment gap (8) and arranged upstream of a nip (3), where one of the surfaces is formed by a band (14) revolving around guide rollers (11-13). Another surface is formed by an outer wall of a heatable roller (4). The band having an elastic surface presses a paper or cardboard web (2) against the heatable roller to increase thermal efficiency of heat exchange. The guide rollers control belt tension forces of the band in the treatment gap. A counter element (5) is formed as a heatable hard roller.

Description

The invention relates to a calender for smoothing a paper or board web according to the preamble of claim 1.

To improve the surface quality, paper or board webs are smoothed. The simultaneously occurring volume loss is usually undesirable. To perform the smoothing with the greatest possible volume protection, calenders with extended nip are used. One speaks in this respect also of a broad nip.

Out WO 01/98585 A1 It is known to use shoe calenders with nip widths between 50 mm and 70 mm and to operate with line loads of up to 400 N / mm. The volume-saving smoothing achieved in this way is achieved by a long residence time in the nip at a high roller temperature above 200 ° C. to 300 ° C. The low temperature resistance of the Belts requires a lot of effort to protect against burns. The high roll temperatures also cause high operating costs. Due to the demand for thickness profile control with simultaneous smoothing of the surface when using the shoe calender another Hartnip- or Softnip calender is required. This causes considerable costs and leads to the reduction of the advantages of the volume-saving smoothing due to the thickness reduction caused by the additional nip.

Out EP 0 141 614 A2 For example, a method of smoothing a paper or board web is known in which the extended nip is formed between a heatable roll and a circulating belt. Along a lap section, the tape is applied to the heatable roller. Guide rollers of the circulating belt control the pressure load in the extended nip via the belt tension and the use as pressure rollers. Roller temperatures of 120 ° C to 315 ° C are also required here for the smoothing.

Out EP 1 478 805 B1 a device for drying a fibrous web is known, which can be used simultaneously for calendering. For this purpose, a metal belt calender with an extended nip is provided. By the belt tension a surface pressure of about 0.01 MPa is maintained. Both the roller and the metal belt can be heated so that both sides of a web can be smoothed. The use of the metal strip allows the application of elevated temperatures of more than 100 ° C and even high up to about 400 ° C. This elevated temperature, along with a long application time and a wide pressure control range, gives a good calendering result. Because of the metal band, however, the effects correspond to those of a Hartnipkalanders, ie, the track tends to Mottling. The use of high temperatures is again cost and energy consuming.

Out DE 10 2007 024 581 A1 For example, a calender and a method for calendering are known in which two wide nips formed with circumferential bands are interrupted by at least one shorter nip. The shorter nip is pressurized usually higher applied. The first wide nip is used in the Essentially the heat supply. The short press nip causes a smoothing pulse on the web. The second wide nip serves to even out the smoothness effect while simultaneously cooling the web. Preference is given to a metal strip, which should be advantageous for the entry of heat because of the high thermal conductivity. The application of high temperatures of up to 300 ° C is provided, and this applies in particular to the first wide nip. The disadvantages of high temperatures already described must therefore also be accepted here. This document shows the features of the preamble of present claim 1.

Object of the present invention is to provide a calender that smoothes a paper or board web volume-saving and thereby can be operated cost and energy saving.

This object is solved by the features of claim 1.

As a result, a calender is provided in which the paper or board web before entering the nip passes through a pre-treatment line for generating an optimum temperature profile when smoothing in the nip. The roll surface temperature of the heated rolls needs to be selected only slightly higher than the plasticizing temperature of the respective paper or board web at a selectable moisture content. For example, it is possible to smooth out with a roller surface temperature which is only about 10 to 30 ° C. higher. Increasing the smoothness effect on soft calenders, multinip calenders and calenders with extended nips is possible.

The extended residence time in conjunction with the elastic surface of the circulating belt significantly improves the heating of the paper or board web. It ensures a good heat transfer, since the paper or board web is pressed evenly to the heatable roller, so that, for example, air cushion, which could hinder the heat transfer, are largely avoided. The advantages of the proposed calender thus arise from the extended dwell for heating the web in conjunction with the Forming the circulating belt, which forms a contact surface of the treatment gap.

By prolonged heating of the paper or board web in the treatment nip, uniform heating of the paper or board web to the technologically required depth is possible. In addition, roll surface temperatures in the range of 80 ° C to 160 ° C are generally sufficient. The amount of temperature is reduced in favor of extending the period of time of the effect of temperature. The reduction in the height of the temperature for the thermal-mechanical smoothing process is then only essentially determined by the plasticizing temperature of the fibrous materials used in a paper or board web and their moisture content. The elastic surface of the belt thereby ensures a uniform contact pressure and thus a uniform heat transfer from the heated roller to the paper or board web safely.

The contact pressure is adjusted by the tension of the belt. This tangential tension of the belt loads the belt, which usually consists of a plastic, a rubber, a plastic-coated carrier material or a rubber-coated carrier material, far less than a radial tension. With radial stress, the plastic tends to delaminate a layer composite. The thermal stress of the belt is low, so that the belt has a long life.

A volume-smoothing smoothing is thus achieved with a nip upstream treatment gap whose belt has an elastic or soft surface on the paper or board web side facing, said treatment gap in the manner of a broad nip in contrast to the known broad nips in the low temperature range of, for example 80 ° C to 160 ° C is operated. The resulting energy savings result from reduced heat radiation and reduced forced convection.

The nip which adjoins the wide nip for pre-smoothing can then be operated with high compressive stresses, since the lack of penetration of (excess) heat into the paper or board web at low temperatures precludes the effect of smoothing on lower areas of the paper or board web. These remain elastic. The greatest possible volume protection is given. The efficiency of heat transfer is increased because the amount of heat lost is reduced.

With the calender according to the invention, it has been possible to realize the advantages and effects to be expected from a simultaneous use of pressure and temperature in the nip in a cost-effective and energy-saving manner in the smoothing process.

The heat loss is significantly reduced, in particular, when the circulating belt has a closed surface cover on the side facing the paper or board web. The thermally sealing and shielding effect of the circulating belt on the paper or board web in the treatment nip is increased. A further increase can be achieved by the material of the elastic surface, which can act as a thermal insulator. For this purpose, this material preferably has a low thermal conductivity.

A residence time in the treatment gap required for achieving the desired penetration depth of the heat can be optimized by adjusting the contact pressure of the strip to the circumference of the heatable roll by means of guide rolls.

The counter-element forming the nip is preferably arranged directly behind the treatment gap on the heatable roller. Preference is given to the use of a bending adjustment roller for simultaneous control of the property profiles of the web in the transverse direction. The counter-element may be a soft roller or a hard heatable roller if bilateral smoothing is desired. The line load can be adapted to the respective objective.

The calender may have one or more nips, wherein with several nips the treatment gap is preferably arranged upstream of the first nip.

Preferably, a controlled increase in pressure in the treatment gap can be adjusted by guide rollers for the circulating belt additionally work as pressure rollers.

Further embodiments of the invention are described in the following description and the dependent claims.

• Fig. 1 zeigt schematisch eine perspektivische Ansicht eines Kalanders,
• Fig. 2 zeigt eine Seitenansicht des Kalanders gemäß Fig. 1,
• Fig. 3 zeigt schematisch eine Anordnung von zwei Kalandern gemäß einem zweiten Ausführungsbeispiel,
• Fig. 4 zeigt schematisch einen Kalander gemäß einem dritten Ausführungsbeispiel,
• Fig. 5 zeigt schematisch einen Kalander gemäß einem vierten Ausführungsbeispiel.

The invention will be explained in more detail with reference to the embodiments illustrated in the accompanying drawings.

• Fig. 1 shows schematically a perspective view of a calender,
• Fig. 2 shows a side view of the calender according to Fig. 1 .
• Fig. 3 shows schematically an arrangement of two calenders according to a second embodiment,
• Fig. 4 schematically shows a calender according to a third embodiment,
• Fig. 5 schematically shows a calender according to a fourth embodiment.

The invention relates to a calender 1 for smoothing a paper or board web 2 with at least one nip 3, which is formed between a heatable roller 4 and a counter element 5. The counter element 5 is preferably a roller, in particular a bending adjustment roller, for the simultaneous regulation of the property profiles of the web 2 in the transverse direction. The counter element 5 is preferably a soft roller. Alternatively, the counter element 5 is formed as a hard roller, which is then preferably heated in order to smooth the paper or board web 2 on both sides. The nip length of the nip 3 is preferably in the range of 1 to 40 mm, depending on the nature of the counter element 5, for example hard roller, soft roller or shoe roller. The roller 4 as well as the counter element 5 can each be driven, in particular for the online operation of the calender. The heatable roll 4 is heated, for example, to roll surface temperatures of 80 ° C to 160 ° C depending on the plasticizing temperature of the respective paper or board web 2 and their moisture content.

The calender 1 comprises a device 6 for generating a predetermined pressure in the nip 3. The device 6 for generating a predetermined pressure is here for example a loading cylinder. Alternatively or additionally, the counter element 5 may be formed with an inner stroke, whereby a pressure load in the nip 3 is adjustable.

The nip 3 is in the web running direction L, a web treatment device 7 with two treatment gap 8 forming contact surfaces 9, 10 upstream. The contact surface 9 is a circumferential contact surface, which is formed by a belt 14 circulating on guide rollers 11, 12, 13. The other contact surface 10 is formed by the circumferential outer wall of the heatable roller 4. The treatment gap 8 extends along a degree 15 of the wrapping of the heatable roller 4. The degree 15 of the wrap for varying the length of the treatment gap 8 is adjustable depending on a desired penetration depth of the heat into the paper or board web 2. By adjusting the Anpresslänge of the belt 14 on the circumference of the heated roller 4, the selectable residence time by means of the guide rollers 11, 12, 13 is optimized. The Anpresslänge on the circumference of the roller 4 is preferably adjustable from 0.25 to 2.5 m.

The circulating belt 14 presses with an elastic surface to increase the thermal efficiency of heat transfer the paper or board web 2 to the heatable roller 4. The guide rollers 11, 12, 13 control Trumkräfte the circulating belt 14 in the treatment gap. 8

The contact pressure in the treatment gap 8 is due to the tension of the belt 14th set. 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 treatment gap 8 can, for example, assume a value in the range from 0.01 MPa to 0.5 MPa. This depends on the belt tension and the dimensions of the heatable roller 4.

Before entering the treatment gap 8, the web 2 can wrap around the heatable roller 4 along a partial section.

The surface temperature of the heatable roller 4 is preferably controlled so that within the residence time of the web 2 below the belt 14, the glass transition temperature is achieved in an optimum for the respective objective of the smoothing process penetration depth. For volume-saving smoothing such warming is required only to a depth of about 10 microns. The surface temperature and the length of the pretreatment path of the treatment nip 8 are optimized to allow operation at a temperature that does not significantly exceed the glass transition temperature of the surface area of the web 2 to be plasticized. The thus pretreated web 2, which can be moistened before the calender 1 beforehand with nozzle and / or steam humidifier, is smoothed directly behind the pretreatment section in the nip 3, in particular a soft or hard nip. The nip 3 forming counter-element 5, preferably a roller is disposed immediately behind the looped portion of the heatable roller 4. Moistening behind the calender 1 or between two calenders 1 is also possible if this is technologically necessary.

If the counter element 5 is a roller, its diameter is preferably less than or equal to 90% of the diameter of the heatable roller 4. In this way, the distance between the end of the treatment gap 8 and the inlet into the nip 3 should be kept as small as possible.

The circumferential band 14 has an elastic surface for securing a uniform contact pressure, which is adjustable by the tension of the belt 14. For a thermal effect of the belt 14 on the paper or board web 2, the circulating belt 14 on the paper or board web 2 side facing an elastic surface having a closed surface cover. The heat transfer from the heated roll 4 to the paper or board web 2 is thermally shielded from the environment in the treatment nip 8 by the circulating belt formed in this way. The introduction of heat into the paper or board web 2 is improved because heat dissipation to the environment is reduced. If the elastic surface is a thermal insulator, the introduction of the heat into the paper or board web 2 is further improved. 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 band 14 is preferably made of a material having a thermal conductivity less than or equal to 1 W / mK. The hardness of the elastic surface is preferably in the range of 50 Shore A to 92 Shore D.

The band 14 is preferably made of a flat substrate provided with one or more elastic layers. Such a plastic composite material has a high tensile strength. To increase the mechanical strength of the band, a support fabric or support band can be incorporated. The circulating belt 14 may further consist of a substrate provided with an elastic layer, wherein the carrier material may also consist of a metal. The hardness of the metal can provide for a sufficiently thin elastic layer for a smoothing of the circumferential band 14 facing side of the paper or board web 2. The roughness of the elastic surface of the band 14 is preferably in the range of 0.5 to 5 microns. The then given smoothness of the elastic surface of the belt 14 may be reflected as smoothness on the paper or board web 2. The tape 14 has, for example, a heat-resistant surface coating, for example made of silicone. The heat-resistant coating provides high wear resistance and a smooth surface.

The pretreatment path of the treatment gap 8 also serves, in particular, for pre-smoothing the web 2.

The circulating belt 14 further preferably has only a small elongation which is less than or equal to 7%. The strain occurring when adjusting the belt tension in the belt 14 due to tension in the belt 14 then does not disturb the smoothing. The band 14 has at least the same width as the web 2. The thickness of the band 14 depends on its width and length and may be between 4 and 20 mm.

At least one of the guide rollers 12 has a device 16 for selectively tensioning the belt 14. The guide roller 12 for tensioning the belt 14 is in each case displaceably or pivotably mounted on the end by means of a guide 18. Fig. 2 shows as a guide 18 a lever system. On the lever system acts a drive element 20, which is associated with a not shown path measuring device.

At least one of the guide rollers 11, 13 may be formed as a pressure roller, which presses the web 14 in the treatment gap 8 along a portion in the direction L by additional radial pressure load. A guide roller 11, 13 is preferably formed on the inlet and / or outlet side of the treatment gap 8 as a pressure roller. The radial pressure load can be set lower on the inlet side than the outlet side or vice versa. Such a pressure roller may be a Biegeeinstellwalze.

Fig. 1 and Fig. 2 show a calender 1, in which the band 14, the heatable hard roll 4 wraps more than 180 °. Preferably, the degree 15 of the wrap is at values between 90 ° and 270 °, with the values greater than or equal to 120 ° being particularly preferred. The circulating, endless belt 14, which is also referred to as belt, is guided by three guide rollers 11, 12, 13 in a loop around the heatable roller 4. The belt 14 is tensioned here by the guide roller 12. By this voltage, the contact pressure of the belt 14 is determined to the web 2. A higher tension of the belt 14 also results in a higher contact pressure of the web 2 and favors the leveling of the web surface, ie the pre-smoothing.

The path 2 conditioned in the treatment gap 8 is then finally finished in a nip 3 immediately following and formed with the same heatable roller 4. The line load in nip 3 can be adapted to the smoothness effects to be achieved. Medium compressive stresses with paper or cardboard in the nip 3 of 2 N / mm ² to 55 N / mm ² are adjustable. The compressive stresses in the lower area of said area are used for thickness correction in cardboard. The compressive stresses in the upper area of said range allow the smoothing of high-quality papers, such as SC, LWC and MWC papers or wood-free coated papers. By a direct contact pressure of the two rollers, without a belt 14 between these two rollers 4, 5 is guided, an exact profile control is possible. Any existing differences in thickness of the belt 14 due to manufacturing tolerances or thermal expansion do not affect the smoothing result.

Since the temperature of the heated roller 4 and the length of the treatment section formed under the belt 14 are adjusted so that substantially only the near-surface region of the web 2 is heated, a conditioning section is formed, in which the interior of the web 2 below the plastification or Glass transition temperature remains. As a result, a volume-smoothing smoothing is possible. The thickness of the near-surface layer of the web 2, which is brought above the plasticizing temperature, is several times the largest unevenness of the paper or board web surface. The thickness of the layer to be heated is thus dependent on the roughness of the web 2 to be treated. The length of the treatment gap 8 and the speed of the web 2 in the direction L determine the residence time of the web 2 in the treatment gap 8 and thus also the penetration depth of the heat into the web 2 and the layer thickness which is heated to a deformation temperature.

The ambient air entrained with the web 2 in the boundary layer deteriorates the heat transfer from the heated roller 4 to the web 2. A substantial improvement of the heat transfer is achieved by removal of the boundary layer. This can be done, for example, by a contact path for an adhesive contact between the outer wall of the heatable roller 4 and the surface of the paper or board web 2 upstream of the web treatment device 7. Also suitable is the pressing of a guide roller 11 against the heated roller 4. By these measures, the interfering boundary layer displaced against the direction of the web 2 and the heat transfer in the treatment gap 8 can be further increased.

Fig. 3 shows a calender arrangement with two in the direction of the web 2 successively arranged calenders 1. This is a two-sided smoothing of the web 2 possible. In the calender arrangement shown, first the lower web side in the first calender 1 is smoothed and then the upper web side in the second calender 1. The temperatures of the two heatable rollers 4 and the line loads in the two calenders 1 are independently adjustable. As a result, the two-sidedness of the web 2 with respect to the smoothness result (different smoothness of the two sides of a web) can be minimized or, if desired, a targeted two-sidedness can also be set. Alternatively, first the upper side of the track can be smoothed.

The calenders 1 according to the described embodiments can be operated online or offline. For the rollers 4 drives can be provided. The calender 1 makes it possible to impart a high degree of smoothness to the surface of the web 2, wherein the circulating belt 14 is subjected to low mechanical and thermal stress.

Fig. 4 shows a multi-pin calender for smoothing high quality papers. The treatment gap 8 is then preferably provided in front of the first nip. As described above, the Umschlingungsgrad 15 and the applied contact pressure is variable here as well. The applied contact pressure is determined by the belt tension with the help of at least one adjustable guide roller 12. Thus it is possible to adapt to different pulp materials and the types of treatment. For preheating, the web 2 can be applied to the outer surface of the heatable roller 4 before the treatment gap 8.

Fig. 5 shows a multinip calender for smoothing high quality papers with two roller stacks, as in Fig. 4 shown. The second stack preferably serves for smoothing a second paper web side. The end roller 4, on which the treatment gap 8 is formed, is now the lower end roller. For the rest, the above statements apply accordingly.

According to an embodiment not shown, for a straight running of the belt, the two-sided guides a control roller via a transversely to the direction of the belt provided sensor means controlled to each other can be aligned. The sensor device detects the position of the belt 14 toward the center of the heatable roller 4.

Claims (15)

1. Calender (1) for calendering a paper or board web (2), having at least one nip (3), which is formed between a heatable roll (4) and a mating element (5), a device (6) for producing a predetermined pressure in the nip (3), and a web treatment device (7) arranged upstream of the nip (3) and having two contact surfaces (9, 10) forming a treatment nip (8), one of which is a circulating contact surface (9) which is formed by a belt (14) circulating on guide rolls (11, 12, 13), the other contact surface (10) is formed by the circulating surface of the heatable roll (4), and the treatment nip (8) extends along an angle (15) of the wrap of the heatable roll (4) to produce a temperature profile during the calendaring in the nip (3), characterized in that, in order to increase the thermal efficiency of the transfer of heat, the circulating belt (14) uses a resilient surface to press the paper or board web (2) onto the heatable roll (4), and the guide rolls (11, 12, 13) control sectional forces of the circulating belt (14) in the treatment nip (8).
2. Calender (1) according to Claim 1, characterized in that the circulating belt (14) has a resilient surface, which has a closed surface cover, on the side facing the paper or board web (2).
3. Calender (1) according to Claim 1 or 2, characterized in that the circulating belt (14) has a resilient surface, which forms a thermal insulator delimiting the treatment nip (8), on the side facing the paper or board web (2).
4. Calender (1) according to one of Claims 1 to 3, characterized in that the resilient surface consists of a material having a thermal conductivity of less than or equal to 10 W/mK.
5. Calender (1) according to Claim 4, characterized in that the resilient surface consists of a material having a thermal conductivity of less than or equal to 1 W/mK.
6. Calender (1) according to one of Claims 1 to 5, characterized in that the angle (15) of wrap for adjusting the length of the treatment nip (8) can be set as a function of a penetration depth of the heat into the paper or board web (2).
7. Calender (1) according to one of Claims 1 to 6, characterized in that the mating element (5) is a soft roll, the diameter of which is less than or equal to 90 % of the diameter of the heatable roll (4).
8. Calender (1) according to one of Claims 1 to 7, characterized in that the circulating belt (14) has a resilient surface of a plastic having a hardness in the range from 50 Shore A to 92 Shore D.
9. Calender (1) according to one of Claims 1 to 8, characterized in that at least one of the guide rolls (11, 12, 13) has a device (16) for tensioning the belt (14) as desired.
10. Calender (1) according to Claim 9, characterized in that the guide roll (12) for tensioning the belt (14) is mounted at the ends in each case by means of a guide (18) such that it can be displaced or pivoted.
11. Calender (1) according to Claim 10, characterized in that, for a straight run of the belt (14), the guides (18) can be adjusted in relation to each other via a sensor device provided transversely with respect to the running direction of the belt (14).
12. Calender (1) according to one of Claims 1 to 11, characterized in that at least one guide roll (11, 13) is constructed as a pressure roll which presses the web in the treatment nip (8) along a section in the running direction by means of the use of additional radial pressure.
13. Calender (1) according to one of Claims 1 to 12, characterized in that a contact section for adhering contact between the outer wall of the heatable roll (4) and the surface of the paper or board web (2) is arranged upstream on the inlet side of the web treatment device (7).
14. Calender (1) according to one of Claims 1 to 13, characterized in that the calender (1) is a multinip calender, which provides the treatment nip (8) before the first nip (3).
15. Calender (1) according to one of Claims 1 to 14, characterized in that the nip (3) is a soft or hard nip, which has a nip length in a range from 1 to 40 mm.

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