Paper Machine And Method For Manufacturing Paper

Abstract

Paper machine for manufacturing a fibre web of paper without through air drying (TAD) or pressing, comprising: a wet end, having a wire section with at least one forming wire, a clothing, being air and water permeable, and a dewatering unit for dewatering the fibre web; and a drying section, comprising a drying surface for the fibre web; and also a transfer roll for transferring the fibre web to the drying section, wherein the fibre web is supported by said clothing from the wire section all the way to and over the transfer roll. The clothing has a three dimensional structure for structuring the fibre web.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

In the following, the invention will be described in greater detail with reference to the drawings.

FIG. 1 shows a first embodiment of a paper machine according to the invention.

FIG. 2 shows a second embodiment of a paper machine according to the invention.

FIG. 3 shows an alternative embodiment of a transfer roll for a paper machine according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 is a schematic representation of a paper machine 1 for manufacturing soft crepe paper. The paper machine 1 comprises a wet end 2 and a drying section 3, but has no press section. Accordingly, the paper machine according to the invention is free of dewatering presses, i.e. it has no dewatering nips. The wet end 2 comprises a head box 4 and a wire section 5. The wire section 5, in its turn, comprises a forming roll 6 and two forming wires 7 and 8. Each of the forming wires 7, 8 runs in a closed loop around a plurality of guide rolls 9 and 10, respectively. The forming wires 7, 8 run over the forming roll 6, in a known fashion, and receive a stock jet from the head box 4 there between. Downstream the forming roll 6, there is a forming zone 11, where the stock by means of dewatering creates a continuous fibre web 12, in this position being carried by the inner one of said forming wires 8. For the dewatering, the wire section 5 comprises a steam box 13, on one hand, being arranged outside the inner wire 8 loop in order to heat the fibre web 12, and a suction box 14, on the other hand, being arranged inside the inner wire 8 loop in order to remove water from the fibre web 12 through apertures in the inner wire 8. Accordingly, in principle, the above-described wire section 5 is a conventional twin-wire section, where the fibre web 12 downstream the suction box 14 has a dryness within the interval 20-25%.

Downstream the wire section 5, the wet end 2 comprises a structuring section 15, extending from the wire section 5 all the way to the drying section 3. The structuring section 15 comprises a clothing 16, running in a closed loop around a plurality of guide rolls 17. A transfer box 18 is arranged inside the clothing 16 loop in order to transfer the fibre web 12 from the wire section 5 to the structuring section 15. More precisely, the transfer box 18 is arranged between two of said guide rolls 17 in order to bring the clothing 16 against the inner wire 8 and, by means of negative pressure, pick up the fibre web 12 from the inner wire 8. Preferably, there is a certain negative draw in the transfer section or at the transfer point, i.e. the speed of clothing 16 is preferably arranged for being lower than the speed of the inner wire 8, wherein a wet creping effect is obtained in the transfer section or at the transfer point. The speed difference in the negative draw can be up to 30%, but is preferably within the interval 0-20%, depending on the product which is to be produced.

The clothing 16 is air and water permeable with an air permeability within the interval 100-700 CFM, preferably 400-600 CFM. In this context, CFM refers to cubic feet of air passed through per minute and square foot clothing at a pressure of 127 Pa, which corresponds to a water head of 0.5 inches. Furthermore, the clothing 16 exhibits a three-dimensional and apertured, i.e. open, structure, exhibiting a plurality of through holes in the thickness direction, enabling the clothing 16 to receive the fibre web 12 in order to build up a high bulk. In other words, the three-dimensional structure of the clothing 16 receives the fibre framework of the fibre web 12 and forms a three-dimensional fibre web 12 of a high bulk. Preferably, the clothing 16 is wire-like, i.e. made of woven threads, preferably of polyester. For instance, the clothing 16 can be one of the clothing types known under the designations GST and MST. Trials have demonstrated that a coarseness of 44×30 threads per inch is suitable for the paper grade “towel”, i.e. kitchen roll-like paper, whereas 51×48 threads per inch is suitable for the paper grade “bath room”, i.e. toilet paper. In principle, also so-called TAD-wires or TAD-fabrics can be used but, since the demands for air permeability and heat resistance which are made on TAD-wires or TAD-fabrics do not have to be granted in a paper machine according to the invention, considerably more wire or clothing qualities are usable, something which is reflected by the lower air permeability value, 100 CFM, which is considerably lower than those occurring with TAD-wires or TAD-fabrics. A moulded clothing can be used as an alternative to a woven fabric.

A large portion of the bulk of the fibre web 12 or fibre framework structure of the fibre web 12 is generated already by the transfer box 18, when the negative pressure inside the transfer box 18 forces the fibres or the fibre framework of the fibre web 12 into the three-dimensional structure of the clothing 16. Any negative draw at the transfer from the wire section 5 to the structuring section 15 amplifies this effect. The negative pressure inside the transfer box 18 can be within the high vacuum region, i.e. approx. 60-70 kPa, implying that also a certain dewatering takes place in the transfer section or at the transfer point. As an alternative, the negative pressure can be lower, for example 20-30 kPa, which is preferable when trying to obtain surface softness rather than bulk.

After the transfer box 18, the fibre web 12 is carried openly on the underside of the clothing 16. In this context, the clothing 16 is carrying the fibre web 12 openly means that the fibre web 12 has a free, i.e. uncovered side 19, when the fibre web 12 is carried by the clothing 16. The fact that the fibre web 12 is carried openly ensures that an efficient, bulk-preserving dewatering of the fibre web 12 can take place when the fibre web 12 is passing through the structuring section 15. For dewatering, the structuring section 15 comprises at least one dewatering unit 20, comprising at least one dewatering member or device facing towards the free side 19 of the fibre web 12. In the embodiment according to FIG. 1, the dewatering unit 20 comprises a steam box 21 being arranged outside the clothing 16 loop and facing towards the free side 19 of the fibre web 12, and which, accordingly, constitutes said at least one dewatering member or device, and a suction box 22 being arranged inside the clothing 16 loop opposite and/or downstream the steam box 21. Facing directly towards the free side 19 of the fibre web 12, the steam box 21 can raise the temperature of the fibre web 12 and the water contained therein in an efficient way, something which increases the dewatering capacity of the subsequent suction box 22 due to reducing the viscosity of the water. As an alternative, the dewatering members or devices in the dewatering unit 20 can be based upon another bulk-preserving dewatering technique, for example heating of the fibre web 12 by means of infrared radiation or hot air. Accordingly, the clothing 16 is arranged for carrying the fibre web 12 openly for a predetermined distance between the wire section 5 and the drying section 3, within which distance the free side 19 of the fibre web 12 is accessible to said at least one dewatering member or device. This predetermined distance can be the entire distance between the wire section 5 and the drying section 3 or only a part of this distance.

In the structuring section 15, i.e. from the wire section 5 all the way to the drying section 3, the fibre web 12 is supported or carried by the clothing 16. A smooth and solid transfer roll 23 is arranged inside the clothing 16 loop in order to transfer the fibre web 12 from the clothing 16 of the structuring section 15 to a hot drying surface 24 of the drying section 3. More precisely, the transfer roll 23 is arranged for interacting with the drying surface 24 in order to form a transfer nip 25 for the fibre web 12. In order to facilitate the transfer of the fibre web 12 to the drying surface 24, the clothing 16 exhibits flat portions on its outside surface, which are arranged for creating a contact surface for interaction with the drying surface 24 during the passage of the clothing 16 through the transfer nip 25. Thereby, the flat portions preferably constitute 15-40%, preferably 22-28%, for example 25%, of the clothing's 16 contact surface against the drying surface 24. The flat portions can be obtained, for example, by means of surface grinding or rolling of the clothing 16. Owing to the three-dimensional structure of the clothing 16, in combination with the flat portions, an efficient transfer of the fibre web 12 is obtained while preserving the bulk of the fibre web 12, i.e. while preserving the three-dimensional structure of the fibre framework of the fibre web 12 that was created in the three-dimensional structure of the clothing 16. It is true that the fibre web 12 could be somewhat compacted mechanically in certain spots, where the flat portions are interacting with the drying surface 24, but the linear load in the transfer nip 25 is low on average, and this local effect on less than 50% of the surface of the fibre web 12 does not influence the total bulk value of the fibre web 12. Additionally, no dewatering takes place in the transfer nip 25. It should be emphasized here that the paper machine 1 is entirely free of dewatering pressing nips, something which provides for high bulk values of the produced soft paper.

Preferably, the drying section 3 comprises a Yankee cylinder 26 having a hood 27. Thereby, the shell surface of the Yankee cylinder 26 constitutes said drying surface 24 for the fibre web 12. Preferably, adhesive chemicals, which are applied onto the drying surface 24 by means of nozzles 28 being arranged at the Yankee cylinder 26 before the transfer nip 25, are used in order to ensure the desired adhesion between the fibre web 12 and the drying surface 24. On the hot drying surface 24, the fibre web 12 is dried to a dryness of about 97-98%, whereupon the fibre web 12 is removed from the drying surface 24, for instance by means of a creping doctor 29. The purpose of the adhesive chemicals is also to protect the drying surface 24 from wear.

FIG. 2 is a schematic representation of an alternative embodiment of a paper machine 30 for manufacturing soft paper. The paper machine 30 comprises a wet end 31 and a drying section 32 but, like the previously described embodiment, it lacks a press section. The wet end 31 comprises a head box 33 and a wire section 34. The wire section 34, in its turn, comprises a forming roll 35 and a forming wire 36, running in a loop around a plurality of guide rolls 37 and over the forming roll 35. Furthermore, the wet end 31 comprises a structuring section 38, comprising a clothing 39 of the same type as in the paper machine 1 according to FIG. 1. The clothing 39 runs in a closed loop around a plurality of guide rolls 40, but in this case, however, it also extends into the wire section 34 where it runs around the forming roll 35 instead of the inner forming wire 8 as in FIG. 1. Accordingly, the head box 33 is arranged for delivering a stock jet between the forming wire 36 and the clothing 39, and the stock is dewatered and forms a continuous fibre web 41 in a forming zone 42 directly onto the clothing 39. For the dewatering of the stock, the wire section 34 comprises a dewatering box 43 arranged inside the forming wire 36 loop. Downstream the forming zone 42, a transfer box 44 is arranged inside the clothing 39 loop in order to ensure that the fibre web 41 follows the clothing 39 when the forming wire 36 and the clothing 39 are separated from each other. Accordingly, downstream the transfer box 44, the fibre web 41 is carried openly on the underside of the clothing 39, and the fibre web 41 has a free, uncovered side 45. In order to increase the dryness of the fibre web 41 even more, the wet end 31 comprises a first dewatering unit 46, downstream the transfer box 44, comprising a first dewatering member or device in the form of a steam box 47 and a second dewatering member or device in the form of a so-called “moulding box” 48, i.e. a suction box which is arranged partly for dewatering, and partly for structuring the fibre web 41. Thereby, the steam box 47 is arranged outside the clothing 39 loop, so that it is facing towards the free side 45 of the fibre web 41, and the suction box 48 is arranged inside the clothing 39 loop. Downstream the first dewatering unit 46, the paper machine 30, on the whole, is designed as the paper machine 1 described previously. The fibre web 41 passes through a second dewatering unit 49, corresponding to the dewatering unit 20 in FIG. 1 and comprising a steam box 50 and a suction box 51. Thereby, the steam box 50 is arranged outside the clothing 39 loop in order to be facing directly towards the free side 45 of the fibre web 41. After the dewatering unit 49, the fibre web 41 is transferred, via a smooth, solid transfer roll 52 and a transfer nip 53, to a drying surface 54 in the form of the shell surface of a hood-equipped Yankee cylinder 55. Finally, the fibre web 41 is removed from the shell surface 54, for instance by means of a creping doctor 56.

FIG. 3 is a schematic representation of an alternative embodiment of a transfer roll for a paper machine according to the invention. The transfer roll 57, being a suction roll, utilises the pressure increase which after all is present in the transfer nip 58, in order to increase the dryness of the fibre web 59 even more before it is transferred to the drying surface 60. The transfer roll 57 comprises a low vacuum zone 61, and a high vacuum zone 62, being located downstream the former and being arranged just opposite the transfer nip 58. A steam box 63 is arranged directly opposite the transfer roll 57 for increasing the temperature of the fibre web 59 to about 80-90° C. before the fibre web 59 runs over the low vacuum zone 61. This temperature increase results in two advantages; that the viscosity of the water inside the fibre web 59 is reduced, which increases the dewatering in the subsequent vacuum zones, and that the cooling of the drying surface 60 by the fibre web 59 is reduced, which increases the drying capacity of the Yankee cylinder. In the low vacuum zone 61, the pressure is relatively low, approx. 20-30 kPa. The purpose of the low vacuum zone is to initiate the steam flow path out from the clothing. In the high vacuum zone 62, the negative pressure is higher, approx. 60-70 kPa. The actual dewatering, when steam and water is removed from the fibre web 59 through the clothing, takes place in this zone. Furthermore, the pressure in the transfer nip 58 is utilised for achieving so-called “flashing” of the steam, something which increases the dryness of the fibre web 59 even more.

Primarily, the paper machine according to the invention is intended for manufacturing the paper grades “towel” and “bath room”. In “towel” grade, preferably 70-100 per cent by volume of softwood pulp and 0-30 per cent by volume of hardwood pulp are utilised, wherein 0-30 per cent by volume of the pulp consists of chemi-thermomechanical pulp (CTMP). In “bath room” grade, preferably 20-60 per cent by volume of softwood pulp and 40-80 per cent by volume of hardwood pulp are utilised. The average length of the fibres is 0.5-3.0 millimetres both in the softwood and hardwood pulp. In both paper grades, between 0 and 100% of the pulp can consist of recycled fibres. Before converting, the manufactured paper grade “towel” has a bulk within the interval 15-20 cubic centimetres per gram and a grammage of approx. 20 grams per square metre, whereas the paper grade “bath room” has a bulk within the interval 12-18 or 14-18 cubic centimetres per gram and a grammage between 15 and 24 grams per square metre.

A paper machine according to the invention with a 12 foot Yankee cylinder can be operated at the speed 480 m/min with the paper grade “towel”, and with a 23 foot Yankee cylinder at the speed 1200 m/min with the paper grade “bath room”.

In the foregoing, the invention has been described starting from a few specific embodiments. It will be appreciated, however, that modifications and alternative embodiments are possible within the scope of the invention.

Claims

1. A paper machine (1, 30) for manufacturing a fibre web (12, 41) of paper without through air drying (TAD) or pressing, comprising: a wet end (2, 31), comprising a wire section (5, 34) comprising at least one forming wire (7, 8, 36) for forming the fibre web (12, 41), a clothing (16, 39), being air and water permeable, and at least one dewatering unit (20, 46, 49) for dewatering the fibre web (12, 41),a drying section (3, 32), comprising a drying surface (24, 54) for drying the fibre web (12, 41), anda transfer roll (23, 52), being arranged for interacting with the drying surface (24, 54) at a transfer nip (25, 53) for transferring the fibre web (12, 41) from the wet end (2, 31) to the drying section (3, 32),

2. A paper machine (1, 30) according to claim 1, characterized in that the clothing (16, 39) is arranged for carrying the fibre web (12, 41) openly, so that the fibre web (12, 41) has a free side (19, 45), and that said at least one dewatering unit (20, 46, 49) comprises at least one dewatering member (21, 47, 50), being arranged for facing towards the free side (19, 45) of the fibre web (12, 41).

3. A paper machine (1, 30) according to claim 1, characterized in that said drying surface (24, 54) is coated with adhesive chemicals.

4. A paper machine (1, 30) according to claim 1, characterized in that said at least one dewatering member or device comprises a steam box (21, 47, 50).

5. A paper machine (1) according to claim 1 characterized in that the clothing (16) is arranged for picking up the fibre web (12) from said at least one forming wire (8), and that the speed of the clothing (16) is arranged for being 0-30%, preferably 0-20%, lower than the speed of the forming wire (8).

6. A paper machine (1, 30) according to claim 1, characterized in that the clothing (16, 39) is apertured.

7. A paper machine (1, 30) according to claim 6, characterized in that the clothing (16, 39) has an air permeability which is about 100-700 CFM.

8. A paper machine (1, 30) according to claim 7, characterized in that the clothing (16, 39) has an air permeability which is about 400-600 CFM.

9. A paper machine (1, 30) according to claim 1, characterized in that the clothing (16, 39) has, on one of its sides, flat portions being arranged for interacting with the drying surface (24, 54) in the transfer nip (25, 53).

10. A paper machine (1, 30) according to claim 9, characterized in that the area of said flat portions constitutes 15-40% of the clothing's (16, 39) contact surface against the drying surface (24, 54).

11. A paper machine (1, 30) according to claim 10, characterized in that the area of said flat portions constitutes 22-28%, preferably 25%, of the clothing's (16, 39) contact surface against the drying surface (24, 54).

12. A paper machine (1, 30) according to claim 1, characterized in that the transfer roll (23, 52) is smooth and homogenous.

13. A paper machine (1, 30) according to claim 1, characterized in that the transfer roll (57) is a suction roll.

14. A paper machine (1, 30) according to claim 1, characterized in that the wet end (2, 31) is free of dewatering presses.

15. A paper machine (1, 30) according to claim 1, characterized in that the drying section (3, 32) comprises a creping doctor (29, 56) for creping the fibre web (12, 41).

16. A paper machine (1, 30) according to claim 1, characterized in that said three-dimensional structure of the clothing (16, 39) is arranged on the side of the clothing (16, 39) facing towards the fibre web (12, 41).

17. A method for manufacturing paper in a paper machine (1, 30) without through air drying (TAD) or pressing, said method comprising the steps of: forming a fibre web (12, 41) in a wire section (5, 34),supporting the fibre web (12, 41) by an air and water permeable clothing (16, 39) from the wire section (5, 34) to a drying section (3, 32), and dewatering the fibre web (12, 41) within this distance by at least one dewatering unit (20, 46, 49),transferring the fibre web (12, 41) from the clothing (16, 39) to a drying surface (24, 54) of the drying section (3, 32), andremoving the fibre web (12, 41) from the drying surface (24, 54),

18. A method according to claim 17, characterized by the step of carrying the fibre web (12, 41) openly by the clothing (16, 39), so that the fibre web (12, 41) has a free side (19, 45), and by the step of dewatering the fibre web (12, 41) by means of a dewatering device (21, 47, 50) being arranged facing towards the free side (19, 45) of the fibre web (12, 41).

19. A method according to claim 17, characterized by the step of coating said drying surface (24, 54) with adhesive chemicals.

20. A method according to claim 17, characterized by the step of transferring the fibre web (12) from a forming wire (8) of the wire section (5) to said clothing (16), the speed of the clothing (16) being 0-30%, preferably 0-20%, lower than the speed of the forming wire (8).

21. A method according to claim 17, characterized by the step of creping the fibre web (12, 41) and removing it from the drying surface (24, 54) by a creping doctor (29, 56).

22. A method according to claim 17, characterized by forming a three-dimensional structure of the fibre web (12, 41) on the side of the fibre web (12, 41) facing the clothing (16, 39).

23. A creped tissue paper manufactured in accordance with a method according to claim 17, characterized in that it has a bulk, before converting, within the interval 15-20 or 12-18 cubic centimetres per gram.

24. A paper according to claim 23, characterized in that it has a grammage within the interval 15-24 grams per square metre.

25. A paper according to claim 23, characterized in that it is made of 70-100 per cent by volume of softwood pulp and 0-30 per cent by volume of hardwood pulp.

26. A paper according to claim 25, characterized in that 0-30 per cent by volume of the pulp consists of chemi-thermomechanical pulp (CTMP).

27. A paper according to claim 23, characterized in that it is made of 20-60 per cent by volume of softwood pulp and 40-80 per cent by volume of hardwood pulp.

28. A paper according to claim 23, characterized in that its average fibre length is within the interval 0.5-3.0 millimetres.