EP4323581A1 - Machine and method for producing a fibrous web - Google Patents

Abstract

The invention relates to a machine (1) for producing a fibrous web, in particular a paper or cardboard web, comprising a headbox (2); a forming unit (3); a pressing section (4); a smoothing MG-Yankee cylinder (9); a winding (12), wherein the pressing section (4) is made of a first elongated press nip (4.1) and a following second elongated press nip (4.2), and an upper press belt (4.21) and a lower press belt (4.22) are guided through the second press nip (4.2); and a transfer belt (5.1) for transferring the fibrous web (10) in a transfer nip (5) to the heated surface (9.1) of the smoothing MG-Yankee cylinder (9). An upper smoothing MG-Yankee cylinder (9) is provided as the smoothing MG-Yankee cylinder (1), with which the lower face (10.2) of the fibrous web (10) is brought into contact. The invention is characterized in that the fibrous web (10) is received by the transfer belt (5.1) directly from the lower press belt (4.22), or a single drying belt (8.1) is provided which receives the fibrous web (10) from the lower press belt (4.22), guides same over at least one drying cylinder (8), preferably a single drying cylinder, and transfers the fibrous web (10) to an intermediate belt (7); and the fibrous web (10) is received by the transfer belt (5.1) directly from the intermediate belt (7).

Description

Machine and method for manufacturing a fibrous web

The invention relates to a machine for producing a fibrous web, in particular a paper or cardboard web, with a headbox, a forming unit, a press section, a MG smoothing Yankee cylinder and a take-up unit. It also relates to a method for producing a fibrous web, in particular a paper or cardboard web, which can be carried out in particular using such a machine.

In the production of fibrous webs, for example paper that is smooth on one side, the paper web is guided after the press section over a large, steam-heated cylinder, a so-called smooth or Yankee cylinder. Such a cylinder is used on the one hand to dry the paper web. On the other hand, the paper web is smoothed on its side facing the smooth or Yankee cylinder due to the long contact with the smooth and hot surface of the smooth or Yankee cylinder. This is the decisive production step in the manufacture of paper that is smooth on one side, so-called MG (machine glazed) paper. The papers manufactured with MG machines are characterized in particular by their low basis weight, high-quality surface properties, high specific volume, high dimensional stability, high rigidity and high strength.

Special papers (MG) that are predominantly smooth on one side are currently produced on such MG machines. These machines only have one Yankee cylinder to dry the fibrous web. The production capacity and speed of these machines is limited by the size and drying capacity of the Yankee cylinder. The maximum raw paper capacity is up to approx. 45 t/m,d with a Yankee cylinder with a diameter of 6 m and a gas-heated hood and a raw paper weight of 30 - 60 g/m ² . For higher raw paper production capacities, for which a value of 70 - 100 t/m,d is aimed for, a pre-dryer section before the Yankee cylinder and a Yankee cylinder with the largest possible diameter are required. For runability reasons, ie for reasons of the running properties of the machine, the Yankee cylinder placed on top. A film press (SpeedSizer) can also be used to apply a primer to the smooth side facing the Yankee cylinder and starch to the side facing away from the Yankee cylinder. The further optional application of the top coat is carried out with a so-called BladeCoater, ie a coating unit with a coating knife. BladeCoater, and curl control with a so-called LAS (Liquid Application System), ie a special application unit with assigned roller or a nozzle moistener for moistening the back of the web, ie on the side facing away from the coat. The optional calendering also takes place online with two to four soft nips at a line force of up to 400 N/mm or more using thermal rollers with a surface temperature in the range of 150° to 200° on the side facing away from the Yankee cylinder. A currently customary high-performance MG machine is designed for a speed of 1200 m/min for base paper with a basis weight of 20 to 35 g/m ² . Such a MG machine comprises a hydraulic headbox with dilution water technology, a fourdrinier wire with a hybrid former with a fourdrinier wire and an attached top wire and a shaker, a DuoCentri-NipcoFlex press with three press nips, at least one of which is intended as a shoe press nip, or a tandem -NipcoFlex- press with two shoe press nips arranged one behind the other in the direction of web travel, a one-row and/or two-row pre-dryer section, a Yankee cylinder with a diameter of 6.4 m, a post-dryer section with a variable number of drying cylinders in a two-row arrangement, a film press, a BladeCoater and a soft calender with a five-roll stack and four nips.

The following three plant concepts in particular are known for the production of so-called "flexible packaging" belonging to the specialty papers division. These differ in paper machine design based on basis weight range and speed.

The first line concept is designed for speeds of up to 800 m/min and a basis weight range of 22 to 50 g/m ² . In In this case, the paper web from the press section, which is formed by a SingleNipcoFlexPresse (SNFP) with only one shoe press nip, is placed directly with the underside of the paper web on the MG cylinder, which enables good surface properties (gloss, porosity, smoothness) at relatively low speeds.

The second line concept is designed for speeds of up to 1000 m/min and a basis weight range of 22 to 80 g/m ² . In this case, the paper web coming from the press section, which is also formed by a SingleNipcoFlex press with only one shoe press nip, is pre-dried via a single-tier pre-dryer section on the underside of the paper web and is also placed with the underside of the paper web on the MG cylinder, which results in medium surface properties (gloss, porosity , smoothness) at medium speeds.

The third line concept is designed for speeds of up to 1400 m/min and a basis weight range of 25 to 110 g/m ² . In this case, the paper web coming out of the press section is pre-dried again via a single-row pre-dryer section on the underside of the paper web and then laid again with this underside of the paper web on the MG cylinder. In contrast to the second system concept, the press section is formed on the one hand by a TandemNipcoFlexPresse (TNFP) with two separate shoe press nips and on the other hand the MG cylinder is followed by a two-row after-dryer section to achieve the final dry content. This third system concept enables average surface properties (gloss, porosity, smoothness) at high speeds and productions.

The machines that are currently in increasing demand are designed for speeds > 1000 m/min and have a machine width > 5 m. Accordingly, the second plant concept and the third plant concept are in the economic focus. Both line concepts are designed for high production rates and speeds for a given basis weight range. The necessary high Drying rates are ensured by a pre-dryer section upstream of the MG cylinder. Such large machines are designed for the highest drying rates and mean high investment and operating costs, as well as only moderate runability. In practice, however, such high drying rates are only necessary for papers in the upper basis weight range of the range of paper grades in the plant concept. In addition, the ability of the machine to adapt to the mode of operation of the system concept selected for a specific range of paper types, which is necessary for the production of a desired paper quality and type, is sluggish and limited.

Efforts to date have been aimed at increasing drying capacities further and further in order to enable higher production rates. This can be useful and economical for certain basis weights. However, if the range of paper grades to be produced on the machine is too wide, such high-performance machines for the production of less demanding papers from the range of grades cannot produce them economically, since in this case they are oversized.

In a machine and method for producing a fibrous web known from DE 10 2017 118 218 A1, a single-row pre-dryer section with steam-heated drying cylinders is proposed for drying both the web side facing away from the MG smoothing Yankee cylinder and the web side of the fibrous web facing it. On the one hand, this machine is suitable for the highest production rates, on the other hand, this concept is very complex.

There is therefore a need for a cost-effective machine concept that can be operated economically and has high runnability and the ability to quickly and flexibly adapt the mode of operation of the machine in order to achieve good paper qualities.

The invention is based on the object of specifying a machine and a method of the type mentioned at the outset, in which the disadvantages mentioned above are eliminated. It should be as high as possible Runability, i.e. with good running properties, of the machine and with relatively low basis weights of the fibrous web, in particular enables the most efficient and economical production of high-quality special papers, in particular special papers that are coated on one side.

The object is achieved by a machine having the features of claim 1 and by a method having the features of claim 15.

A machine is proposed for producing a fibrous web, in particular a paper or cardboard web, with a headbox, a forming unit, a press section, a MG smoothing Yankee cylinder and a take-up, the press section being lengthened by a first press nip and a subsequent second one Press nip is formed and an upper press belt and a lower press belt are guided through the second press nip and with a transfer belt for transferring the fibrous web in a transfer nip to the heated surface of the MG smoothing Yankee cylinder and with an overhead MG smoothing cylinder as the MG smoothing Yankee cylinder Yankee cylinder is provided, with which the underside of the fibrous web is brought into contact. According to the invention, it is provided that the fibrous web is taken directly from the lower press belt by the transfer belt or that a single drying belt is provided, which takes the fibrous web from the lower press belt and guides it over at least one, preferably a single, drying cylinder and the fibrous web is transferred to an intermediate belt and that the fibrous web is taken off directly from the intermediate belt by the transfer belt.

These solutions have the advantage of a simple structure and therefore good runability. The fibrous web can be easily transferred. In addition, this concept can be easily adapted to the requirements in terms of the quality of the fibrous web that are placed on the machine by a wide range of paper grades. Losses in terms of the highest production rates can be accepted, since they can be compensated for in the area of the remaining grades by a driving style that is optimal in terms of quality and advantageous in terms of economy more than compensated. In this way, the best fibrous web qualities, such as luster, smoothness, rigidity, strength, dimensional stability, specific volume and porosity, can be achieved. In addition, this machine concept requires little installation space and is therefore also well suited for conversions of existing machines. Due to the simplicity, the acquisition costs and the operating costs are lower for the machine operator than for the known machines designed for the highest production rates.

One version, in which the fibrous web is taken directly from the lower press belt by the transfer belt, represents the simplest machine concept.

The other embodiment in which a single drying belt is provided, which removes the fibrous web from the lower press belt and guides it over at least one, preferably a single, drying cylinder and transfers the fibrous web to an intermediate belt and that the fibrous web is removed directly from the intermediate belt by the transfer belt is somewhat more complex, but much simpler than the known system concepts with a pre-dryer section. By using a single drying belt, several drying cylinders can be provided as required, forming a maximum of one drying group. This means that the dry content can be increased for heavy paper grades.

In a possible further development, the lower press belt is designed as a smooth transfer belt to smooth the fibrous web. This promotes the smoothness of the underside of the fibrous web that comes into contact with the hot surface of the MG Yankee Yankee cylinder.

The first press nip is double-felted to ensure good dewatering performance.

Preferably, the elongated press nips are each formed by a stand-alone press comprising a shoe roll pressed against a backing roll. Such press arrangements are known and are also referred to as TandemNipcoFlexPress (TNFP). The dry content and the specific volume, also referred to as bulk, of the fibrous web can be set quickly and easily by means of two extended press nips arranged one behind the other. The first press nip and the second press nip are thus each formed by a shoe roll with a counter roll.

In a practical case, the transfer nip is performed by a feed press. The pressure of the feed press ensures the transfer of the fibrous web from the transfer belt to the heated surface of the MG Yankee Yankee cylinder.

The transfer belt is preferably designed as a felt, in particular as a protective felt. To avoid structuring effects, the protective felt can have a fine pile layer on the upper side of the fibrous web.

In an advantageous development, the linear force of the first press nip and the linear force of the second press nip can be controlled or regulated, preferably independently of one another. As a result, an optimization of the dry content and specific volume of the fibrous web at the end of the press section and/or the finished fibrous web can be achieved. This also enables an optimal mode of operation in the production of different fibrous web types from the wide range of types in a simple and quick manner.

In this way, fibrous webs in the basis weight range from 22 g/m ² to 110 g/m ² , in particular in the range from 22 g/m ² to 100 g/m ² , preferably from 22 g/m ² to 80 g/m ² , can advantageously be produced economically and with good fibrous web quality will.

In a further practical embodiment, the fibrous web is assigned a steam blower box, in particular the underside of the fibrous web, in front of the first press nip and/or in front of the second press nip. Furthermore, the transfer belt before the transfer nip can be guided over an internal suction turning roll and the fibrous web in the area of the suction turning roll can be assigned a steam blower box and/or an infrared dryer and/or a moistening device. The steam box and/or the infrared dryer is assigned directly to the free, uncovered underside of the fibrous web. Due to this preheating of the fibrous web to a higher temperature, this energy does not have to be applied by the MG smoothing Yankee cylinder, whose available drying capacity for the fibrous web is thus increased.

A moistening device can also be assigned directly to the free, uncovered underside of the fibrous web. This enables the moisture content in the outermost layer of the underside of the fibrous web to be adjusted to a higher level in order to improve the gloss and smoothness values.

If one steam box is used in the press section and in the area of the suction turning roll, it is conceivable that one steam box, for example the steam box in the press section, is used to increase the dry content and the steam box in the area of the suction turning roll to influence and adjust the moisture cross profile of the fibrous web. The latter has sections that can be adjusted across the width.

In the area where the transfer belt wraps around, the suction turning roller can have a suction zone subjected to negative pressure. The negative pressure can be generated by a vacuum system, for example by connecting it to the suction port of a turbair blower.

To increase the temperature of the fibrous web before the transfer nip, the exhaust air from the hood assigned to the MG smoothing Yankee cylinder can also be used in such a way that it is blown through a blow box onto the underside of the fibrous web. In addition to the actual measurable dryness, the moisture gradient, ie the moisture distribution in the z-direction of the paper web, is also decisive for achieving a high surface quality. This moisture gradient (in z-direction between the top and bottom of the web) intensifies when the basis weight increases, but this now entails a higher dry content on the underside of the paper web pressed against the MG Yankee Yankee cylinder. For optimum gloss and smoothness results, however, the moisture on the underside of the paper web that comes into contact with the MG Yankee cylinder should be as high as possible. Therefore, better qualities of the fibrous web result with relatively low basis weights. As already described, a moistening device can be assigned to the fibrous web to increase the moisture content.

It is advantageous if the MG smoothing Yankee cylinder for further drying of the fibrous web is followed by a post-drying section with at least one, preferably a two-row, drying group.

The object is also achieved by a method for producing a fibrous web, in particular a paper or cardboard web, in particular using a machine according to one of the preceding claims, in which a fibrous suspension supplied by means of a headbox is dewatered in a forming unit to form a fibrous web and in a Press section is further dewatered and dried and smoothed in an MG Yankee cylinder and wound up in a take-up unit, the press section being formed by a first extended press nip and a subsequent second extended press nip, and an upper press belt and a lower press belt being guided through the second press nip and the fibrous web is guided with a transfer belt through a transfer nip and is thereby transferred to the heated surface of the MG smoothing Yankee cylinder and an overhead MG smoothing Yankee cylinder is provided as a MG smoothing Yankee cylinder with which the Underside of the fibrous web is brought into contact. According to the invention, in a first embodiment, the fibrous web through the transfer belt directly from io removed from the lower press belt or, in a second embodiment, a single drying belt is provided, which removes the fibrous web from the lower press belt and guides it over at least one, preferably a single, drying cylinder and transfers the fibrous web to an intermediate belt and that the fibrous web passes through the transfer belt taken directly from the intermediate belt.

The fibrous web is preferably dewatered to a dry content in the range between 48% and 60% before the transfer nip. This improves the gloss and smoothness values of the fibrous web.

In a possible practical case, for transferring the fibrous web in the first embodiment, an edge strip is cut, preferably in the forming unit, and this is guided without interruption to a scraper, by which the fibrous web is removed from the surface of the MG smoothing Yankee cylinder .

In the second embodiment, it is advantageous if, in order to transfer the fibrous web, it is guided web-wide over the at least one drying cylinder and then directly into a pulper and then an edge strip is cut in the area of the at least one drying cylinder and this is cut at least up to a scraper which the fibrous web is taken off the surface of the MG Yankee cylinder.

In a preferred practical embodiment, the fibrous web is guided without free draws from the forming unit to a doctor by which the fibrous web is removed from the surface of the MG Yankee Yankee cylinder.

The invention also expressly extends to those embodiments which are not given by combinations of features from explicit back references of the claims, with which the disclosed features of the invention - insofar as this is technically meaningful - can be combined with one another as desired. Further features and advantages of the invention result from the following description of preferred exemplary embodiments with reference to the drawings.

Show it

FIG. 1 shows a first embodiment of a machine according to the invention in a simplified representation;

FIG. 2 shows a second embodiment of a machine according to the invention in a simplified representation;

FIG. 3 shows the area of the suction turning roller as a section from the second embodiment according to FIG. 2 in a simplified representation;

Figure 1 shows a first embodiment of a machine 1 for producing a one-sided smooth fibrous web 10 with a headbox 2, a forming unit 3, a press section 3, a MG Yankee cylinder 9 and a take-up unit 12. The forming unit 3 is a hybrid former with a top wire and formed a bottom sieve. The fiber suspension jet coming from the headbox 2 strikes the bottom wire of the forming unit 3 . There the suspension is dewatered and guided through the zone between the top wire and bottom wire and further dewatered. The fibrous web 10 formed is then fed into the press section 4 and dewatered. This is formed by two individually standing presses, each with an extended press nip 4.1, 4.2. The first press nip 4.1 is double-felted. An upper press belt 4.21 and a lower press belt 4.22 are guided through the second press nip (4.2), the lower press belt 4.22 being designed as a smooth, preferably impermeable transfer belt and coming into contact with the underside 10.2 of the fibrous web 10. After the second press nip 4.2, the fibrous web 10 is continued on the transfer belt 4.22 and taken from there directly by a transfer belt 5.1, which is designed as a low-marking protective felt, and around a within a formed by the protective felt Loop lying and sucked suction turning roller 6 passed and then passed through a transfer nip 5 a feed press. In the transfer nip 5, the fibrous web 10 is transferred to the heated, smooth cylindrical surface 9.1 of the MG smoothing Yankee cylinder 9 and, in the further course, both through the MG smoothing Yankee cylinder 9 on the underside 10.2 and through one of the MG smoothing Yankee cylinders 9 associated, with steam and / or hot air applied hood 9.2 dried on the top 10.1. After this drying zone, the fibrous web 10 is removed by a scraper 9.3 applied to the MG smoothing Yankee cylinder 9 and guided through a post-dryer section 11 and then wound up by a winder 12 to form a paper roll. The fibrous web 10 is constantly supported by the forming unit 3 up to the scraper 9.3.

FIG. 2 shows a second embodiment of a machine according to the invention in a simplified representation. It differs from the first embodiment only in that a drying belt 8.1, which partially wraps around a drying cylinder 8, and an intermediate belt 7 are arranged between the press section 4 and the transfer belt 5.1. In this case, the fibrous web 10 is removed from the lower press belt 4.22 by the drying belt 8.1 and guided over the drying cylinder 8 to increase the dry content and then transferred to the intermediate belt. From there, the fibrous web 10 is removed by the transfer belt 5.1 and transported further in accordance with the first embodiment shown in FIG. The fibrous web 10 is constantly supported by the forming unit 3 up to the scraper 9.3. The drying cylinder is in contact with the underside 10.2 of the fibrous web 10. A pulper 13 is arranged below the drying cylinder 8 . The fibrous web 10 is guided into these in the event of a break in the fibrous web 10 during operation or during transfer.

FIG. 3 shows the area of the suction turning roller as a detail from the second embodiment according to FIG. 2 in a simplified representation. The fibrous web 10 is in the area of suction turning roller 6 aspirated Moistening device 14 and/or a steam blower box 14 or an infrared dryer 14 or a blower box 14 for the preferably sectional application of hot air to the underside 10.2 of the fibrous web 10. Through the moistening device, the moisture content of the heated surface 9.1 of the MG smoothing Yankee cylinder 9 coming into contact underside 10.2 of the fibrous web can be positively influenced to achieve improved gloss and smoothness values.

Corresponding elements of the exemplary embodiments in the figures are provided with the same reference symbols. The functions of such elements in the individual figures correspond to one another unless otherwise described and it does not lead to contradictions. A repeated description is therefore omitted. It is also pointed out that the different features of the exemplary embodiments shown can be exchanged for one another and combined with one another. The invention is therefore not limited to the combinations of features shown in the exemplary embodiments shown.

List of reference symbols Machine Headbox Forming unit Press section First extended press nip Second extended press nip Upper press belt Lower press belt Transfer nip Transfer belt, protective felt Suction turning roller Intermediate belt Drying cylinder Drying belt MG smoothing Yankee cylinder Heated surface Hood Doctor fibrous web Top side of the fibrous web Bottom side of the fibrous web After-dryer section Winding up Pulper Steam blower box, infrared dryer, moistening device

Claims

Machine and method for manufacturing a fibrous web

patent claims

1. Machine (1) for producing a fibrous web, in particular a paper or cardboard web, with a headbox (2), a forming unit (3), a press section (4), a MG Yankee cylinder (9) and a take-up ( 12), wherein the press section (4) is formed by a first extended press nip (4.1) and a subsequent second extended press nip (4.2) and an upper press belt (4.21) and a lower press belt (4.22) are guided through the second press nip (4.2). and with a transfer belt (5.1) for transferring the fibrous web (10) in a transfer nip (5) to the heated surface (9.1) of the MG smoothing Yankee cylinder (9) and being the MG smoothing Yankee cylinder

(9) an overhead MG smoothing Yankee cylinder (9) is provided, with which the underside (10.2) of the fibrous web (10) is brought into contact, characterized in that the fibrous web (10) is conveyed through the transfer belt (5.1) directly from the lower press belt (4.22) is removed or that a single drying belt (8.1) is provided, which the fibrous web

(10) from the lower press belt (4.22) and guides it over at least one, preferably a single, drying cylinder (8) and transfers the fibrous web (10) to an intermediate belt (7) and that the fibrous web (10) passes through the transfer belt ( 5.1) is removed directly from the intermediate belt (7).

2. Machine according to claim 1, characterized in that the lower press belt (4.22) is designed as a smooth transfer belt for smoothing the fibrous web (10).

3. Machine according to claim 1 or 2, characterized in that the first press nip (4.1) is felted twice. 4. Machine according to one of the preceding claims, characterized in that the first press nip (4.1) and the second press nip (4.22) are each formed by a shoe roll with a counter roll.

5. Machine according to one of the preceding claims, characterized in that the transfer nip (5) is executed by a feed press.

6. Machine according to one of the preceding claims, characterized in that the transfer belt (5.1) is designed as a felt, in particular as a protective felt.

7. Machine according to one of the preceding claims, characterized in that the linear force of the first press nip (4.1) and the linear force of the second press nip (4.2) can be controlled or regulated, preferably independently of one another, in order to optimize the dryness and specific volume of the fibrous web .

8. Machine according to one of the preceding claims, characterized in that the fibrous web (10) is assigned a steam blower box before the first press nip (4.1) and/or before the second press nip (4.2).

9. Machine according to one of the preceding claims, characterized in that the transfer belt (5.1) is guided in front of the transfer nip (5) over an internal suction turning roller (6) and the fibrous web (10) in the area of the suction turning roller (6) has a moistening device (14 ), and/or a steam blower box (14) and/or a blower box and/or an infrared dryer (14) is assigned. 10. Machine according to one of the preceding claims, characterized in that the MG smoothing Yankee cylinder (9) is followed by an after-dryer section (11) with at least one, preferably two-row, drying group.

11. A method for producing a fibrous web (10), in particular a paper or cardboard web, in particular using a machine according to one of the preceding claims, in which a fibrous stock suspension fed by means of a headbox (2) is used in a forming unit (3) to form a fibrous web (10) is dewatered and further dewatered in a press section (4) and dried and smoothed in a MG smoothing Yankee cylinder (9) and wound up in a take-up (12), the press section (4) being extended by a first press nip 4.1 and a subsequent second extended press nip (4.2) and an upper press belt (4.21) and a lower press belt (4.22) are guided through the second press nip (4.2) and the fibrous web (10) with a transfer belt (5.1) through a transfer nip (5) is performed and it is passed to the heated surface (9.1) of the MG smoothing Yankee cylinder (9) and as a MG smoothing Yankee cylinder (9) a top left ing MG smoothing Yankee cylinder (9) is provided, with which the underside (10.2) of the fibrous web (10) is brought into contact, characterized in that in a first embodiment the fibrous web (10) is conveyed through the transfer belt (5.1) directly from is removed from the lower press belt (4.22) or that, in a second embodiment, a single drying belt (8.1) is provided, which removes the fibrous web (10) from the lower press belt (4.22) and transports it via at least one, preferably a single, drying cylinder (8 ) leads and transfers the fibrous web (10) to an intermediate belt (7) and that the fibrous web (10) is removed directly from the intermediate belt (7) by the transfer belt (5.1). 12. The method according to claim 11, characterized in that the fibrous web (10) before the transfer nip (5) is dewatered to a dry content in the range between 48% and 60%.

13. The method according to any one of claims 11 and 12, characterized in that for transferring the fibrous web (10) in the first embodiment, an edge strip, preferably in the forming unit (3), is cut and this up to a scraper (9.3) through which the fibrous web (10) is removed from the surface (9.1) of the MG Yankee cylinder (9) without interruption.

14. The method according to one of claims 11 and 12, characterized in that for transferring the fibrous web (10) in the second embodiment, it is guided web-wide over the at least one drying cylinder (8) and then directly into a pulper (13) and an edge strip is then cut in the area of the at least one drying cylinder (8) and this at least up to a scraper (13) by which the fibrous web (10) is removed from the surface (9.1) of the MG Yankee cylinder (9), to be led.

15. The method according to any one of claims 11 to 14, characterized in that the fibrous web (10) without free draws from the forming unit (3) to a scraper (9.3) through which the fibrous web (10) from the surface (9.1) of the MG smoothing Yankee cylinder (9) is removed.