SE537252C2 - Drying box which has blow boxes for drying a web of cellulose pulp - Google Patents

Abstract

SUMMARY A drying tray for drying a web (18) of cellulosic pulp comprises a lower blowing barn (26) which is arranged to blow gas upwards towards the web (18) of cellulose pulp via bubble openings, for drying the pulp according to the principle of airborne web. The lower bladder bar (26) includes a central zone (58) comprising bladder openings (70, 72) of a first perforation type, and at least one first side zone (52) comprising bladder openings (70, 80) of a second perforation type, the second the perforation type differs from the first 10 perforation type.

Description

Fig. 1 is a schematic side view illustrating a drying tray for drying a web of cellulosic pulp.

Fig. 2 is a schematic side view illustrating the area 11 in Fig. I.

Fig. 3 is a front view of a first drying deck seen in the direction of arrow III in Fig. 2.

Fig. 4 is a top view of a first lower bladder.

Fig. 5 is a top view of a first upper blister.

Fig. 6 is a top view of a second lower bladder barrel.

Fig. 7a is a top view of a third lower blister.

Fig. 7b is an enlarged view of a side zone of the third lower bladder.

Fig. 7c is a cross-section of the side zone of Fig. 7b.

Fig. 7d is an enlarged view of an alternative side zone.

Fig. 7e is a cross-section of the side zone of Fig. 7d.

Description of Preferred Embodiments Fig. 1 shows a drying pad 1 for drying cellulosic pulp according to a first embodiment of the present invention. The drying tray 1 comprises a housing 2. Inside a housing 2 in a typical embodiment a first drying zone 4, a second drying zone 6 and a possible cooling zone 8 can be arranged, the first drying zone 4 being arranged in the upper area of the housing 2, the cooling zone 8 being arranged in the lower part of the housing 2 and the second drying zone 6 is arranged between the first drying zone 4 and the cooling zone 8.

At a first end 10 of the housing 2 a first pillar with water rollers 12 is arranged, and at a second end 14 of the housing 2 a second pillar with water rollers 16 is arranged. A wet pulp web 18 is fed into the drying tray 1 via an inlet 20 formed in the housing 2. In the embodiment in Fig. 1, the inlet 20 is formed in the upper part of the housing 2, but in an alternative embodiment the inlet may be formed in the lower the lot of the house. The web 18 is conveyed as shown in Fig. 1 horizontally at Niger in the drying barn 1 until the web 18 reaches a water roller. In the drying tray 1 shown in Fig. 1, the web 18 will first reach a water roller 16 on the second pillar with water rollers. The web 18 travels around the water roll 16 and is then moved horizontally as shown in Fig. 1 to the left in the drying tray 1 until the web 18 reaches a water roll 12 on the first pillar 6 537 252 with water rollers, at which the web 18 travels again. Then the web 18 moves in a zigzag pattern from the top to the bottom of the drying tray 1, as illustrated by the arrows P. The web 18 leaves the drying tray 1 after being dried in the first and second drying zones 4, 6 and after cooling in the cooling zone 8 via an outlet 22, which is formed in the housing 2. In the embodiment in Fig. 1, the outlet 22 is formed in the lower part of the housing 2, but the outlet can in an alternative embodiment be formed in the upper part of the housing.

Typically, air with a temperature of 80 to 250 ° C is used for the drying process. The web 18 of cellulosic pulp fed into the drying pad 1 from an upstream web forming station, which is not shown in Fig. 1, typically has a dry content of 40-60 wt. of typically 85-95% w / v. The web 18 of cellulosic pulp leaving the drying pad 1 typically has a basis weight of 800 to 1500 g / m2, matt at a moisture content of 0.11 kg of water per kg of dry matter, and a thickness of 0.8 to 3 mm.

The first drying zone 4 comprises at least one first drying deck 24 and typically 3-15 first drying decks 24. In the embodiment of Fig. 1, the first drying zone 4 comprises eight first drying decks 24. Each such first drying deck 24 comprises a number of blowers, which will be described. detailed below, and is for drying the web 18 as the web 18 moves horizontally from a water roll 12, 16 to the next water roll 16, 12. Each first drying deck 24 includes a plurality of first lower blades 26 and a plurality of first upper blades 28, which are arranged to blow hot drying gas onto the cellulosic pulp web 18. Typically, each first drying deck 24 includes 20-300 first lower blowing barns 26 and the same number of first upper blowing barns 28, although for the sake of clarity only one fatal blowing barn is shown. The first lower bladders 26 have the function of holding the web 18 in a "floating" and fixed condition, so that the web 18 is airborne at a distance from the first lower bladders 26 during the drying process, which will be described in more detail below.

The second drying zone 6 comprises at least a second drying deck 30 and typically 5-40 second drying decks 30. In the embodiment in Fig. 1, the second drying zone 6 comprises eleven second drying decks 30. Each such second drying deck 30 comprises a number of blowing barns, which will be described in more detail. detailed below, and is 7,537,252 to dry the web 18 below the web 18 moves horizontally than a water roll 12, 16 to the next water roll 16, 12. Each second drying deck 30 includes a plurality of lower blowers 32 and a plurality of other blowers. 34, which are arranged to blow hot drying gas against the cellulosic nasal web 18. Typically, each second drying deck 30 includes 20-300 second lower blowing barns 32 and the same number of other upper blowing barns 34, although only a fatal blowing barn is shown in Fig. 1 for clarity. The second lower bladders 32 have the function of holding the web 18 in a "floating" state, so that the web 18 is airborne at a distance from the other lower bladders 32 during the drying process, which will be described in more detail below.

The first drying decks 24 in the first drying zone 4 have a different mechanical construction than the second drying decks 30 in the second drying zone 6, which will be described in more detail below. Often, the first lower blowing barns 26 in the first drying roofs 24 will have a different mechanical construction than the second lower blowing barns 32 in the second drying roofs 30, which will be illustrated by means of an example below.

The cooling zone 8 comprises at least one cooling deck 36, two such cooling decks 36 being shown in Fig. 2, the usual such deck 36 comprising a number of third lower blowing ladders 38 and third upper blowing ladders 40, which are arranged to blow a cooling gas against the cellulose pulp web 18. the lower bladder blades 38 are arranged to keep the web 18 in a "liquid" state, so that the web 18 becomes airborne during the cooling process. The third lower bladders 38 may, for example, have a construction similar to the construction of the first or second bladders 26, 32, which will be described in more detail below. Typically, air with a temperature of 15 to 40 ° C is used as the cooling gas for cooling. An insulated cradle 42 separates the second drying zone 6 from the cooling zone 8.

Fig. 2 is an enlarged side view of the area II in Fig. 1 and shows a first drying deck 24 of the first drying zone 4 shown in Fig. 1. The first drying deck 24 comprises the first lower blowing ladders 26, which are arranged below the web 18, and the first upper bladders 28, which are arranged over the web 18. The first lower bladders 26 blow hot drying air towards the web 18 both vertically upwards towards the web 18, as shown by the arrows VU in Fig. 2, and on a 8 537 252 angled at an angle of typically 5 to 600 to the horizontal plane, as shown by arrows IU in Fig. 2. Blowing dry air at an angle to the horizontal plane through the first lower blowing ladders 26 gives both forces which force the web 18 upwards away from the blowing ladders. 26 and forces that force the web 18 neatly towards the bladders 26. The latter effect is sometimes called the Coanda effect. This results in bladder wires 26 exerting a fixing force against the web 18, which holds the web in a comparatively selected defined distance from the bladder wires 26. Typically, the average distance, or height H1, is between the underside of the web 18 and the upper surface of the first lower bladder wires 26. when operating the wiper blade 1 1-6 mm. If the web 18 tends to frame upwards, the fixing forces of the blowing blades 26 pull the web 18 downwards, and if the web 18 tends to move downwards, the air biased from the blowing cords 26 forces the web 18 upwards. Consequently, the web 18 is transported horizontally along the first drying deck 24 in a relatively fixed manner, with little movement in the vertical direction, which means that the web 18 is subjected to limited stretching forces. The first type of upper blowers 28 blow hot drying air towards the web 18 vertically downwards in the direction of the web 18, which is illustrated by means of arrows VD in Fig. 2. Typically, the average distance, or height H2, is between the upper side of the web 18 and the lower surface of the first upper bladders 28 10 to 80 mm. The hot drying air which is biased from the blowing barns 26, 28 is evacuated via gaps S formed between horizontally adjacent blowing barns 26, 28.

Fig. 3 is a front view of the first drying deck 24 seen in the direction of the arrow III in Fig. 2. Drying air is supplied from a float, which is not shown for clarity, and enters the interior 44 of the first lower blower 26 at a first end 46 of the lower bladder bar 26, as illustrated by an arrow DA1. The air supplied to the inner 44 of the blower 26 is biased towards the web 18 in the form of the air flow VU and IU via openings, which will be described below with reference to Fig. 4. To return to Fig. 3, drying air is also supplied from the float, not shown. and enters the inner 48 of the first upper bladder dance 28 at the first end 50 of the upper bladder shaft 28, which is indicated by an arrow DA2. The air DA2 is supplied with the inner 48 of the blower blade 28 biased towards the web 18 in the form of the air flow VD via openings, which will be described below with reference to Fig. 5. 9 537 252 For all efficient drying and internal operating problems lower and upper bladder blades 26, 28, respectively, are preferably substantially constant at the heights H1 and H2, shown in Fig. 2, across the width WW of the web. It has been realized that the web in previous kanda dries in some cases can, especially at its side winds, deviate Than the desired heights H1, H2, which is shown in Fig. 3 with broken lines denoted PA. Such a deviation meant that the web 18 was not dried in an optimal way.

The first lower blast barn 26 has a total width WB which can typically be 2-16% larger than the width 18 of the web 18. The width WW of the track 18 can typically be 1-15 meters, more typically 2-12 meters. The first lower bladder bar 26 is divided into zones along its width WB, i.e. along a horizontal direction perpendicular to the direction P in which the web 18 moves over the bladder bar 26. The first lower bladder bar 26 has a first side zone 52 aligned adjacent to the first bladder bar 26. spirit 46, a second side zone 54 disposed adjacent to the second spirit 56 of the blower 26, and a central zone 58 disposed between the first and second side zones 52, 54.

The first upper bladder bar 28 has a first side zone 60 disposed adjacent the first end 50 of the bladder bar 28, a second side zone 62 disposed adjacent the second duct 64 of the bladder bar 28, and a central zone 66 disposed between the first and second side zones 60, 62.

As will be described below with reference to Fig. 4 and Fig. 5, medico !. the side zones 52, 54, and the side zones 60, 62, that the web 18 is moved almost horizontally over the entire width 18 of the web 18, which is shown by an unbroken line in Fig. 3. Consequently, the large deviations from the desired heights H1, H2 , which is shown by broken lines PA, is avoided or at least substantially reduced. It is also acceptable for the web to move at a slightly higher height H1 above the lower bladder bar 26 at the side zones 52, 54, than at the central zone 58 as it does not tend to adversely affect the drying process.

Fig. 4 is a top view of the first lower bladder bar 26 seen in the direction of the arrows IV-IV in Fig. 3. The first lower bladder bar 26 has an upper surface 68 which is directed towards the web 18 and which is, as described above with referring to Fig. 3, divided into the first side zone 52 aligned adjacent to the first spirit 46, the second side zone 54 aligned adjacent the second spirit 56 of the blower 26, and the central zone 58 aligned between the first side zone 52 and the second side zone 54. Consequently, the first and second side zones 52, 54 are aligned on opposite sides of the central zone 58.

The central zone 58 is provided with centrally located first kind of air bubble openings 70, which are of the "angled type" which may, for example, be of a type sometimes referred to as "eyelid openings" and which are arranged in the upper surface 68. With openings of the "angled type" means that at least 25% of the air blown from these openings 70 is biased at an angle of less than 600 to the horizontal plane. The eyelid openings 70, which may have a construction similar to the openings called "eyelid perforations 6" in WO 97/16594, and which are described with reference to Fig. 2 and Fig. 3 in WO 97/16594, thereby cause the hot drying air to be biased by a slope resulting in the air flow IU shown in Fig. 2 of the present patent application. At least 30%, often at least 40%, of the total air flow supplied through the first lower bladder barrel is biased via eyelid openings 70.

For the continuation of the description of Fig. 4 of the present patent application, the central zone 58 is provided with a second type of bladder opening 72 which is arranged near the sides 26, 76 of the bladder shaft 26. The second type of bladder openings 72 is of the "non-angled type" distributed over the upper surface 68 within the central zone 58. By "non-angled type" is meant that at least 80% of the air biased through these openings 72 is biased at an angle to the horizontal plane which is at least 70 °. The second type of aperture 72 may be, for example, round, square, or triangular slides. The second type of aperture 72, if round round, may typically have a diameter of 1 to 10 mm. In one example, the second type of aperture is 72 round slides with a diameter of 2.5 mm. The second type of aperture 72 blows hot air upward to form the air flow VU shown in Fig. 2.

For all purposes of Fig. 4, a first degree of perforation of the central zone can be calculated by dividing the total area of the openings 70, 72 of a representative portion of the central zone 58 by the horizontally projected surface 78 of the representative portion of the upper surface 68 within The central zone 58. By "representative portion" is meant a path of the upper surface 66 which is representative with respect to blowing air toward the web 18, i.e., omitting, for example, the inlet air of the blower barn. The degree of perforation of the central zone 58 is typically 0.5-3.0%. In an example pile, the degree of perforation of the central zone 58 is 1.5%. The degree of perforation can be varied to suit the weight, dry content, etc. of the web 18 to be dried. The second type of aperture 82 which is a non-angled type of aperture may typically occupy at least 20% of the total degree of perforation of the first lower bladders 26, and typically 30-70% of the total degree of perforation of the first lower bladders 26. The first the type of apertures 70 which are of the angled type of apertures may typically occupy at least 30% of the total perforation rate of the first lower blow barrels 26, and typically 40-80% of the total perforation rate of the first lower blow barrels 26.

For example, for a surface of the representative portion 78 of 4000 mm 2, and with a degree of perforation of 1.5 (:) / 0, the total area of the openings 70, 72 becomes 60 mm 2. If the first type of Aperture 70 were to occupy 50 (:) / 0 of the degree of perforation, it would correspond to 30 mm2. This meant that the second type of aperture would have a total aperture area corresponding to the remaining 30 mm2, which, with apertures 72 with a diameter of 2.5 mm, would correspond to approximately six apertures 72, each of which has an aperture area of approximately 4 mm2. , 9 mm2.

The first side zone 52 am provided with centrally aligned first type of air bubble openings 70, of the ogonlock type, and of a similar construction to the first type of openings 70 of the central zone 58. Furthermore, the first side zone 52 comprises a third type of air bubble openings 80 which are provided The third type of apertures 80 are of the "non-angled type" and are distributed over the upper surface 68 within the first side zone 52. The third type of air bubble apertures 80 may be round, square or triangular. , and may, if they are round slippery, typically have a diameter of 1 to 10 mm. In one example, the third type of apertures 80 is 3.1 mm in diameter round blowing hot air upward to form the air flow VU shown in Fig. 2. Accordingly, the third type of apertures 80 has the first side zone having a different size than the second type 12 537 252 of bladder openings 72 has the central zone 58. Therefore, the openings 70, 72 of the central zone 58 form a first type of perforation, which differs from a second type of perforation formed by the openings 70 of the side zone 52 , 80. The third type of bladder openings 80 of the first side zone 52 are arranged in a sample similar to the sample of the second type of bladder openings 72 of the central zone 58.

It is possible to calculate a second degree of perforation for the first side zone in a manner similar to that described above with reference to the central zone 58. The degree of perforation of the first side zone 52 is typically 0.8-3.5%. In one example, with the third type of aperture 80 having a diameter of 3.1 mm, the degree of perforation having the first side zone becomes 1.9%. Consequently, the degree of perforation of the first side zone 52 is greater than the degree of perforation of the central zone 58. In one embodiment, the degree of perforation of the first side zone 52 is a factor of 1.1-2.0, preferably 1.1-1.7, greater than the degree of perforation. of the central zone 58. Consequently, if, for example, the degree of perforation of the central zone 58 is 1.5 `) / 0 sa, the degree of perforation of the first side zone 52 is in the range of 1.65 to 3.0 OA.

The second side zone 54 may have a construction similar to the first side zone 52. Accordingly, the second side zone 54 includes, in an example, first type openings 70 of the ogonlock type, and third type of openings 80 which are round and have a diameter of 3.1. mm, resulting in a third degree of perforation of the second side zone 54 of 1.9%. Consequently, the degree of perforation of the second side zone 54 is greater than the degree of perforation of the central zone 58.

During operation of the drying barrel 1, drying air DA1 is supplied to the first lower blowing barrel 26. Since the openings 70, 72 of the central zone 58 form a first type of perforation, which differs from a second type of perforation formed by the openings 70, 80 of the side zone 52. air will be blown from the openings 70, 72 of the central zone 58 in a first river sample different from a second river sample in which air is blown from the openings 70, 80 of the side zone 52. Furthermore, air from the openings 70, 80 of the second side zone 54 will be blown in a third flow pattern different from the first flow pattern in 13 537 252 which air is biased from the openings 70, 72 of the central zone 58. in, for example, the unit m3 of air per hour and mm2 of area upper surface 68, i.e. m3 / (h, mm2), which is biased towards the web 18 through the openings 70, 72 of the central zone 58 to be less than a second relative air flow, in m3 area per hour and mm2 of area upper surface 68, which is biased towards the web 18 through openings 70, 80 of the first side zone 52. Similarly, a third relative air flow, in m3 air, per hour and mm2 of area upper surface 68, i.e. m3 / (h, mm2), which is biased towards the web 18 through the openings 70, 80 of the second side zone 54 to be larger than the first relative air flow of the central zone 58. This entails an improved lifting force on the web 18 at the side zones 52, 54, i.e. an improved lifting force adjacent the side edges 82, 84 of the web 18 so that the web "floats" in the desired manner, as shown in Fig. 3, above the first lower blowing barn 26. Further, drying effect to increase at the side edges 82, 84 due to the greater flow of air at the side zones 62, 54 relative to the central zone 58. According to one embodiment, the second and third relative air flocs are biased by the first and second side zones, respectively. 52, 54 and factor 1.1 2.0, preferably 1.1-1.7, greater than the first relative airflow biased by the central zone 58.

The first side zone 52 may typically extend a distance DZ1 of approximately 50 to 600 mm into the web 18 from the side edge 82. Similarly, the second side zone 54 may extend a distance DZ2 of approximately 50 to 600 mm into the web 18 from the side edge. 84. Blasladan 26 has, as described above, a width WB which is larger than the width WW of the web 18. The first side zone 52 preferably has a total width LZ1, seen from the first spirit 46, of 100 to 950 mm, and the second side zone 54 has a total width LZ2, seen Than the second spirit 56, of 100 to 950 mm. The central zone 58 is preferably at least as wide as each of the side zones 52, 54. Consequently, if the side zones 52, 54, for example, have the widths LZ1 and LZ2, respectively, of 400 mm, then the central zone is at least 400 mm wide.

In one example, the bladder bar 26 has a width WB of 5000 mm, the web 18 a width WW of 4600 mm, each of the first and second side zones 52, 54 14 537 252 has a width LZ1 and LZ2 of 500 mm, respectively, and the central zone 58 has a width LC of 4000 mm, which means that the first side zone 52 extends below the web 18 a distance DZ1 of approximately 300 mm from the side edge 82, and the second side zone 54 extends below the web 18 a distance DZ2 of approximately 300 mm from the side edge 84.

Fig. 5 is a top view of the first upper bladder bar 28 seen in the direction of the arrows VV in Fig. 3. The first upper bladder bar 28 has a lower surface 86 which is directed towards the web 18 and which is, as described above with reference to Fig. 3, divided into the first side zone 60 aligned adjacent to the first spirit 50, the second side zone 62 aligned adjacent the second end 64 of the blower, 28, and the central zone 66 aligned between the first side zone 60 and the second side zone 62.

The central zone 66 is provided with a fourth type of air bladder openings 88 distributed over the lower surface 88 of the bladder bar 28 within the central zone 66. The fourth type of openings 88 is of the "non-angled type" and may be round, square or triangular. slippery, and can, if round slippery, typically have a diameter of 1 to 10 mm. In one example, the fourth type of aperture is 88 round slides with a diameter of 5 mm which blow hot air downwards to form the air flows VD shown in Fig. 2.

In a manner similar to that described above with reference to the central zone 58, it is possible to calculate a fourth degree of perforation for the central zone 66. The degree of perforation of the central zone 66 is typically 0.5-3.0%. In one example, with the fourth type of aperture 88 having a diameter of 5 mm, the fourth degree of perforation of the central zone 66 is 1.5 .mu.m.

The first upper zone 60 of the first upper blow dance 28 has no openings ails. A fifth degree of perforation of the first side zone 60 is therefore 0%. Consequently, the fifth degree of perforation of the first side zone is less than the fourth degree of perforation of the central zone 66. Similarly, the second side zone 62 of the first upper blast layer 28 has no openings. Accordingly, a sixth degree of perforation of the second side zone 62 is less than the fourth degree of perforation of the central zone 66. In accordance with an alternative embodiment, the first and / or the second side zone 60, 62 may be provided with openings, for example round openings of 537 252 such size and to such an extent that the first and / or the second side zone 60, 62 still has a lower degree of perforation than the central zone 66.

During operation of the drying barn 1, the first upper blowing barn 28 is supplied with drying air DA2. Since the degree of perforation of the first and second side zones 60, 62 is lower than the degree of perforation of the central zone 66, a fourth relative air flow is biased, in the unit: m3 of air per hour and mm2 of area lower surface 86, towards the web 18 through the openings 88 of the central zone 66 to be higher than a fifth relative air flow of the side zones 60, 62. This results in a reduced drying effect of the side zones 60, 62 at the edges 82, 84 of the web 18, which at least partially compensates for the increased drying effect caused by the first lower blow dance 26. side zones 52, 54, as described above. Such compensation, with reduced drying action at the side zones 60, 62 of the upper blast layer 28, 62 reduces the risk of the web 18 being over-dried near its side edges 82, 84 which can give quality problems. Furthermore, the forces pushing the web 18 downward toward the first lower bladder bar 26 decrease somewhat at the edges 82, 84 because no airflow is biased downward into the side zones 60, 62, further improving the "floating" progress of the web 18.

The side zones 60, 62 can typically extend below the web 18 a distance DZ1 and DZ2 of approximately 50 to 600 mm. Man and side edges 82, 84, respectively. 100 to 950 mm. The central zone 66 has a width LC which depends on the width WB of the bladder dance 28 and on the width of the side zones 60, 62 between which the central zone is located.

According to an alternative embodiment, a first upper blowing barn may be arranged to have a single zone of openings through which drying air is biased towards the web 18. Such an alternative first blowing barn would not involve flake compensation for the increased drying effect of the lower blowing barn 26 side zones 52. , 54.

The second upper bladder bar 34 of the second drying deck 30 of the second drying zone 6 shown in Fig. 1 may have a similar construction to the first upper bladder bar 28 shown in Fig. 5. Fig. 6 is a top view of the the second lower blowing barn 32 seen in a similar perspective to the first lower blowing barn 26 in Fig. 4. The second lower blowing barn 32 has an upper surface 168 which is arranged to be water against the web 18 and is divided into a first side zone 152 arranged adjacent to a first spirit 146 of the bladder bar 32, a second side zone 154 aligned adjacent to a second spirit 156 of the bladder bar 32, and a central zone 158 disposed between the first and second side zones 152, 154. Consequently, the first and second side zones 152, 154 are aligned on opposite sides of the central zone 158.

The central zone 158 is provided with a fourth type of air bladder openings 172 distributed over the upper surface 168 of the bladder shaft 32 within the central zone 158. The fourth type of openings 172 is of the "non-angled type" and may, for example, be round, square or triangular hall. The fourth type of Openings 172, while round slippery, can typically have a diameter of 1 to 10 mm. In one example, the fourth type of aperture is 172 round slides with a diameter of 2.5 mm.

The degree of perforation of the central zone 158 is typically 0.5-3.0%. In one example, the perforation rate of the central zone 158 is 1.5%. For example, for an area of 4000 mm 2 of a representative portion 178 of the bearing surface 168 within the central zone 158, and with a degree of perforation of 1.5%, the total area of the openings 172 becomes 60 mm 2. A total area of 60 mm2 and a diameter of each opening 172 of 2.5 mm would represent approximately twelve openings 172, each having an opening area of approximately 4.9 mm2.

The first side zone 152 is provided with a fourth type of air blower openings 172 distributed over the upper surface 168 of the lower blower shaft 32 opposite the first side zone 152. The fourth type of openings 172 of the first side zone 152 may be of similar size and shape as the the openings 172 of the central zone 158. Consequently, the fourth type of openings 172 of the first side zone 152 may be, for example, round slides with a diameter of 2.5 mm.

The degree of perforation of the first side zone 152 may typically be 0.83.5%. In one example, the perforation rate of the first side zone 152 is 2.0%. Consequently, the degree of perforation of the first side zone 152 is greater than the degree of perforation of the central zone 158. In one embodiment, the degree of perforation of the first side zone 152 is a factor of 1.1-2.0, preferably 1.1-1.7. greater than the degree of perforation of the central zone 158. For example, for a surface of 4000 mm 2 of a representative portion 179 of the upper surface 168 forms the first side zone 152, and with a degree of perforation of 2.0%, the total area of the openings 172 becomes 80 mm 2. A total area of 80 mm2 and a diameter of each aperture 172 of 2.5 mm would correspond to about sixteen apertures 172, each having an aperture area of about 4.9 mm 2. Accordingly, the first side zone 152 has a different number of bladder openings 172 per m2 of upper surface 168 blown than the central zone 158. In this embodiment, the first side zone 152 has more bladder openings 172 per m2 of upper surface 168 blown than the central zone 158. The first side zone 152 b16 openings 172 are aligned with a pattern different from the pattern of the central zone 158 blast apertures 172 are aligned I. Consequently, the apertures 172 of the central zone 158 form a first type of perforation, which differs than a second type of perforation formed by the side zone 152 openings 172.

The second side zone 154 may have a construction similar to the first side zone 152. Accordingly, the second side zone 154 includes, in one example, fourth type openings 172 which are round and have a diameter of 2.5 mm, resulting in a degree of perforation having the other side zone 154 of 2.0%. Consequently, the degree of perforation has the second side zone 154 is greater than the degree of perforation of the central zone 158.

The openings 172 in the second lower bladder bar 32 have the same size and shape in all zones, but the concentration of openings 172, i.e. the number of openings per surface 168, is higher in the side zones 152, 154 than in the central zone 158, which means that the side zones 152, 154 has a higher degree of perforation.

During operation of the drying tray 1, drying air DA3 is supplied to the second lower blowing barn 32. The average distance, or height H1, between the underside of the web 18 and the upper surface 168 of the second lower blowing barn 32 is typically 2-8 mm in operation. Since the openings 172 of the central zone 158 form a first type of perforation, which differs from a second type of perforation formed by the openings 172 of the side zone 152, air may be blown than the openings 172 of the central zone 158 into a first river pattern which differs from a second river sample in which air is diverted from the openings 172 of the side zone 152. and mm2 of area upper surface 168 which is biased towards the web 18 through the openings 172 of the central zone 158 to be less than a second relative air flow, in m 3 area per hour and mm 2 of area upper surface 168 which is biased towards the web 18 through openings 172 of the first and second side zones 152, 154, which results in an improved lifting force on the web 18 at the side zones 152, 154, i.e. an improved lifting force adjacent the side edges of the web 18 82, 84 said that the path "floats" in the desired way.

Each side zone 152, 154 can typically extend a distance DZ3 and DZ4, respectively, of approximately 50 to 600 mm into the web 18 Than and the side edge 82, 84, respectively. The first and second side zones 152, 154 preferably have a respective total width LZ3, LZ4, seen Than and spirit 146, 156 of 100 to 950 mm, respectively.

The distances DZ3 and DZ4 of the second lower bladder bar 32 may be the same or different than the distances DZ1 and DZ2 of the first lower bladder barrel 26, respectively.

Fig. 7a is a top view of an alternative second blowing barn 232 seen in a similar perspective to the second lower blowing barn 32 in Fig. 6. The alternative second lower blowing barn 232 has an upper surface 268 which is arranged to be water against the web 18 and is divided into a first side zone 252 disposed adjacent a first spirit 246 of the bladder bar 232, a second side zone 254 disposed adjacent a second spirit 256 of the bladder bar 232, and a central zone 258 disposed between the first and second side zones 252, 254.

The central zone 158 is provided with a fourth type of air bubble openings 172 distributed over the upper surface 268 of the blow ring 232 within the central zone 258. The fourth type of openings 172 are of the "non-angled type" and may, for example, be round, square or triangular hall. In one example, the fourth type of aperture is 172 round halves with a diameter of 3.0 mm.

The degree of perforation of the central zone 258 is typically 0.5-3.0%. In one example, the perforation rate of the central zone 258 is 1.5%.

The first side zone 252 is provided with a first type of air-bubble openings 70, which are of the "angled type" which may, for example, be of a type sometimes referred to as "eyelid openings" and which are arranged in the upper surface 268. The eyelid openings 70 , which may have a construction similar to the openings called "eyelid perforations 6" in WO 97/16594, and which are described with reference to Fig. 2 and Fig. 3 in WO 97/16594, in that the hot drying air is thereby biased by a slope .

The degree of perforation of the first side zone 252 is typically 0.5-3.0%. In one example, the degree of perforation of the first side zone 252 is 1.5%. Accordingly, the degree of perforation of the first side zone 252 is the same as the degree of perforation of the central zone 258.

For example, for a surface of the representative portion 278 of 4000 mm 2 of the upper surface 268 within the central zone 258, and a surface of the representative portion 279 of 4000 mm 2 of the upper surface 268 forms the first side zone 252, and with a degree of perforation of 1.5%, the total area of the openings 170 and 70, 60 mm2, respectively, in the habit becomes a representative portion 278, 279.

In alternative embodiments, the degree of perforation of the first side zone 252 may be either greater or less than the degree of perforation of the central zone 258.

The second side zone 254 may have a construction similar to the first side zone 252. In the alternative second lower bladder bar 232, the side zones 252, 254 have the same degree of perforation as the central zone 258, but different perforation patterns, with apertures 172 of the non-angled type in the central zone 258 and angles 70 of angled type in the side zones 252, 254.

Each side zone 252, 254 may typically extend the distances DZ3 and DZ4, respectively, which are the same ranges as the distances DZ3, DZ4 described above with reference to the blade barn 32, below the path 18. Similarly, the first and second side zones 252, 254 ha total widths LZ3 and LZ4, respectively, which lie within similar ranges as the total widths LZ3, LZ4 described above with reference to the blast barn 32. 537 252 During operation, drying air DA4 is supplied to the second lower blast barn 232. Since the openings 172 of the central zone 258 form a first type of perforation, which differs Than a second type of perforation formed by the openings 702 of the side zone 252, air will be blown Than the openings 172 of the central zone 258 in a first river pattern different from a second river pattern in which air is diverted from the side zone 252 openings 70. Air cushions which provide improved lifting forces on the web 18 at the side zones 252, 254, i.e. an improved lifting force acting on the web 18 adjacent its side edges 82, 84 so that the web "flows" in the intended manner, is formed due to the arrangement with the openings 702, 254 of the side zones 252, 254.

Fig. 7b and Fig. 7c show the arrangement of Fig. 7a with the openings of the first side zone 252 in more detail, where Fig. 7b is an enlarged view from above, and Fig. 7c shows a cross section along the line VlIc-VIIc in Fig. 7b. The second side zone 254 may have a similar construction to the first side zone 252. As shown in Fig. 7b, the apertures 70 are of the angled type, for example of the above-mentioned aperture type apertures, and aligned in a first row 273 adjacent a first side 274 of blasladan 232, and in a second row 275 adjacent a second side 276 of blasladan 232. through the side zone 252 the openings 70 are aligned so that the habit opening 70 in the first row 273 is opposite an opening 70 in the second row 275. Consequently "collides" air which is inclined obliquely from the openings 703 of the first row 273, as indicated by the arrows IUI, with air which is inclined obliquely from opposite openings 70 in the second row 275, which is indicated by the arrows IU2. Such a collision between the air rivers IU1 and IU2 above the center of the upper surface 268 of the bladder bar 232 produces a static pressure Pstat which lifts the web 18 in Fig. 7a at the side zones 252, 254, so that the web 18 "floats" in the desired manner, as shown bast of Fig. 7c.

Fig. 7d and Fig. 7e show an alternative first side zone 352 and a portion of a central zone 358 of a further alternative lower bladder bar 332, where Fig. 7d is an enlarged view from above and Fig. 7e is a cross section along the line Vile-Vile in Fig. 7d. It will be appreciated that the lower bladder bar 332 may be provided with two side zones arranged on opposite sides of the central zone 358, although this is not shown in the drawings. The further alternative bladder barrel 332 comprises a central groove 377 arranged in an upper surface 368 of the bladder barrel 332. The groove 377 is provided with a first side cradle 373 and a second side cradle 375. Blazer openings 370 of angled type are arranged in the side cradles 373 of the groove 377. , 375. In the central zone 358, the openings 370 are arranged in the first and second side cradles 373, 375 in an alternating manner. In addition, the central zone 358 is provided with apertures 372 of the non-angled type arranged in a horizontal portion of the upper surface 368. The side zone 352 has no such apertures of the non-angled type. Apertures 370 aligned with the first side cradle 373 of the groove 377 in the side zone 352 are aligned opposite openings 370 of the second side cradle 375 of the spar 377. to "collide" with air which is biased in an angular manner, which is indicated by arrows IU2, Than the opposite openings 370 in the second side wall 375. Such collision between the air flow IUI, IU2 above the groove 377 in the bladder bar 332 produces a static pressure Pstat within the side zone 352 which acts as an air cushion for lifting the web 18 at the side zones 352 so that the web 18 "floats" in the intended manner.

The degree of perforation of the central zone 358 is typically 0.5-3.0%. In one example, the degree of perforation of the central zone 358 is 1.5%. The degree of perforation of the side zone 352 is typically 0.4-2.7%. Since the side zone 352 in this embodiment is not provided with any openings 372 of the angled type, the degree of perforation of the side zone 352 is lower than the degree of perforation of the central zone 358. In one example, the perforation rate of the central zone 358 is 1.5% and the perforation rate of the side zone is 1.3%. In the alternative second lower bladder bar 332, the side zone 352 has a lower perforation margin than the central zone 358, and another perforation pattern. Consequently, a first relative flow biased by the openings 370 370 of the central zone 358 is 372 larger than a second relative flow biased by the openings 370 370 of the side zone 352.

It will be appreciated that many variants of the embodiments described above are possible within the scope of the appended claims.

It has been described above that the drying barrel 1 comprises a first drying zone 4 and a second drying zone 6 which comprises different kinds of lower blowing barrels 26 22 537 252 and 32, respectively. successive drying zones where everyone can have the same or different types of drying pads. Furthermore, a drying rack can also be constructed with a single drying zone which comprises a kind of drying pads. According to such an alternative embodiment, a drying hut may be constructed with a single drying zone and comprise only lower blowing ladders 26 of the type described above with reference to Fig. 4. According to a further such alternative embodiment, a drying hut may be constructed with a single drying zone and comprise only lower blades 32 of the type described above with reference to Fig. 6.

It has been described above that the upper blow blades 28 of the softener described above with reference to Fig. 5 can be used in both the first and the second drying zone 4, 6. It will be appreciated that also other types of upper blow blades 28 can be used in one or more of these. drying zones 4, 6. Furthermore, it is also possible to use as an upper blowing barn in one or more of the drying zones an upper blowing barn which is not zoned along its length. With such a non-zoned upper blower, flake compensation for the higher drying action in the side zones 52, 54, 152, 154 of the lower blowers 26, 32 will not be achieved, but it may be acceptable in some cases.

It has been described above that the first drying zone 4 comprises only lower blowing barns 26 of the type described with reference to Fig. 4, and byre blowing barns 28 of the kind described with reference to Fig. 5, and that the second drying zone 6 only comprises lower bladders 32 of the type described with reference to Fig. 6, and upper bladders 34 similar to the upper bladders 28 described with reference to Fig. 5. It will be appreciated that other combinations are also possible, for example to use a combination of first lower blowers 26 and other lower blowers 32 in one and the same drying deck of a drying zone. For example, a drying deck may be arranged so that every second lower bladder is a first lower bladder 26 and every other lower bladder is a second lower bladder 32.

It has been described above that the size of the openings in the central zone 58 and the side zones 52, 54 may be different, as described with reference to Fig. 4, or that the concentration of openings per m2 of area of the central zone 158 and of the side zones 152, 154 may be different, the zone was described with reference to Fig. 6. It will be appreciated that in a side zone it is also possible to use both a different size and concentration of openings, in relation to the central zone. Furthermore, in a side zone it is also possible to use openings which have a different shape in relation to the openings in the central zone. For example, round apertures can be used in the central zone and square apertures can be used in the side zone.

It has been described above that the upper and lower blowing blades 26, 28, 32 extend over the entire width WW of the web 18, so that drying air is supplied from a spirit 46, 50, 148 located near a first side edge 82 of the web 18. It will be appreciated that it would also be possible to arrange, as an alternative to a full-length blowing barn, two blowing barns each having about half the width 18 of the web 18 and extending from each of the two side edges 82, 84 of the web 18 and adjacent to each other at the web central part, with air supplied at the openings adjacent to each of the edges 82, 84. Each such half-length bladder would then have a central zone and a first side zone arranged below the respective edge 82, 84 of the web 18.

It has been described above that gas supplied to the blow racks 26, 28, 32 is air. It is understood that in some special cases the gas may be another type of gas, for example air mixed with combustion gases.

It has been described above that an air cushion effect is provided by the air flow biasing through adjacent bladder openings 70, 370 in the bladder 232, 332 side zones 252, 352 "colliding" with each other so that a static pressure Pstat is provided. It will be appreciated that an air cushion effect can also be achieved with other arrangements of openings.

It has been described above that a second relative air flow biased by the openings 70, 32 of the respective side zones 252, 352 is equal to or less than a second relative air flow biased by the respective central zone 258, 358 openings 170, 370, 372. It will be appreciated that it can often be possible to achieve the intended air cushion effect also by supplying a second relative air flow supplied by the side zones 252, 352, which is larger than the first relative air flow supplied by the central zone 258, 358.

In summary, a drying tray for drying a web 18 of cellulosic pulp comprises a lower blowing barn 26 which is adapted to blow gas upwards towards the web 18 of cellulosic pulp via bubble openings, for drying the pulp according to the principle of airborne web. The lower bladder bar 26 includes a central zone 58 comprising bladder openings 70, 72 of a first perforation type, and at least one first side zone 52 comprising bladder openings 70, 80 of a second perforation type, the second perforation type being different from the first perforation type.

Claims (20)

537 252 CLAIMS 1. Dried sheets for drying a web (18) of cellulosic pulp, wherein the drying paper (1) comprises lower blowing sheets (26; 32) which are arranged all the blowing gas upwards towards the web (18) of cellulosic pulp via bubble openings, for drying of the mass according to the principle of airborne web, it may be that the drying barrel (1) comprises at least one lower blowing barrel (26; 32) which comprises, seen in a horizontal direction perpendicular to a direction (P) in which the web (18) move Over the lower blasIklan (26; 32); I. a central zone (58) comprising bladder openings (72) of a first perforation type, and at least one first side zone (52) comprising bladder openings (80) of a second perforation type, the second perforation type being different from the first perforation type, wherein the bladder openings (72) in the central zone (58) of the lower bladder (26; 32) form a first degree of perforation and the bladder openings (80) in the lower bladder (26; 32) named at least one first side zone (52) form a second degree of perforation, wherein the second degree of perforation is greater than the first degree of perforation, and wherein the lower bladder dance (232: 332) first side zone (252; 352) includes bladder openings (70; 370) adapted to form an air cushion above the side zone (252; 352) for lifting the web (18) of cellulosic pulp adjacent to its side edge (82). The dryer according to claim 1, wherein the lower blister (26, 32) further comprises a second side zone (54) comprising blister openings (80) of a third perforation type different from the first perforation type of the central zone (58), the central zone (58) is arranged between the first side zone (52) and the second side zone (54), Dryed according to any one of the preceding claims, wherein the blister openings (72) of the central zone (58) of the lower blasia dance (26; 32) have a first degree of perforation, and the blister openings (80) of the first side zone of the lower blasladas (26; 32) (52) has a second degree of perforation, the second degree of perforation being greater than the first degree of perforation, preferably a factor of 1 1-2.0 greater than the degree of first perforation. A drying barn according to any one of the preceding claims, wherein the drying barn 5 further comprises at least one owe blowing barn (28) comprising, seen in a horizontal direction perpendicular to a direction (P) in which the web (18) is to move below the upper blowing barn ( 28); i. a central zone (66) comprising blister orifices (88) having a fourth degree of perforation, and II. at least one first side zone (60) having a fifth degree of perforation, the fifth degree of perforation being less than the fourth degree of perforation. The drying tray of claim 4, wherein said upper blast barn (28) further comprises a second side zone (62) having a sixth degree of perforation less than the fourth degree of perforation of the central zone (66), said central zone (28) blowing barn (28). 66) is arranged between the first side zone (60) and the second side zone (62). A dryer according to any one of the preceding claims, wherein the first side zone (252; 352) of the lower bladder dance (232; 332) comprises bladder openings (70; 370) arranged to form an air cushion above the side zone (252; 352) for lifting the web (18 ) of cellulose pulp next to the dosing side edge (82). The dryer according to claim 6, wherein the first side zone (252; 352) further comprises two rows (273; 275) with angled type blow openings (70; 370) arranged to blow the air flow (IU1; IU2) towards each other. Cloth according to any one of the preceding claims, wherein the first side zone (52: 152) of the lower blast layer (26; 32) has a width (LZ1, LZ3), seen in the horizontal direction perpendicular to a direction (P) which the web (18) should move over the lower bladder bar (26; 32), of 100 to 950 mm. 27 537 252 A dryer according to any one of the preceding claims, wherein the first side zone (52; 152) of the lower blast layer (26; 32) is arranged to extend below the web (18) a distance (DZ1; DZ3) of approximately 50 to 600 mm from a side edge (82) of the web (18). A dryer according to any one of the preceding claims, wherein the drying tray comprises a first drying zone (4) comprising a first type of lower blowing barrels (26), and a subsequent second drying zone (6) comprising a second type of lower blowing barrels (32). ), A dryer according to any one of the preceding claims, wherein at least some of the bladder openings (80) of the first side zone (52) have a different size than the bladder openings (72) of the central zone (58). A dryer according to any one of the preceding claims, wherein the first side zone (52) has a different number of blister openings (80) per m2 of blister cell surface (168) than the central zone (158). A dryer according to any one of the preceding claims, wherein at least one of said at least one lower bladder (26; 232; 332) comprises a mixture of angled type bladder openings (70; 370) and non-angled type bladder openings (72; 172). ; 372). A drying tray according to any one of the preceding claims, wherein at least one of said at least one lower blowing tray (32) comprises only blasting openings of non-angled type (172). A drying tray according to any one of the preceding claims, wherein the drying tray comprises at least one drying deck (24; 30) in which at least 90% of the total number of lower blades (26; 32) of the drying deck comprises the central zone (58; 158) and the first side zone (52; 152). 28 537 252 A method of drying a web (18) of cellulosic pulp by means of lower blowing ladders (26; 32) arranged to blow gas upwards towards the web (18) of cellulosic pulp via blowing orifices, in order to dry the pulp in accordance with the principle of an airborne web. net e ck n at of using at least one lower blasiada (26; 32) which comprises, seen in a horizontal direction perpendicular to food a direction (P) in which the web (18) is to move Over the lower blasiladan (26; 32) , a central zone (58) comprising bladder openings (70, 72), and at least one first side zone (52) comprising bladder openings (70, 80), blowing a first reactive gas flow in a first flow pattern toward the web (18) through the central zone (18). 58) blowing openings (70, 72), and blowing a second relative gas flow in a second flow pattern, which differs from the first flow pattern, toward the web (18) through the blowing openings (70, 80) of the first side zone (52), the second Relative gas flow is the first relative gas flow or the second relative gas flow is biased in the second river sample toward the web to form an air cushion that lifts a side edge (82) of the cellulosic pulp web. The method of claim 16, further comprising using in said lower bladder bar (26; 32) a second side zone (54) comprising bladder tips (70; 80), the central zone (58) being disposed between the first side zone (52) and the second side zone (54), and blowing a third relative gas flow in a third river sample, which differs from the first river sample, toward the path (18) through the blast openings (70, 80) of the second side zone (54). A method according to any of claims 16-17, wherein the second relative gas flow is greater than the first relative gas flow, wherein the second relative gas flow is preferably a factor of 1.1-2.0 more rigid than the first relative gas flow. 29 537 252 A method according to any of claims 16-18, further comprising blowing the second relative gas stream into a second flow pattern towards the web to form an air cushion for lifting a side edge (82) of the web (18) of cellulosic pulp. A method according to any one of claims 16-19, further comprising using at least one Owe bias: Ma (28) comprising, viewed in a horizontal direction perpendicular to a direction (P) in which the web (18) is to move during the upper bladder (28), a central zone (66) comprising bladder openings (88), and at least one first side zone (60), and blowing a fourth relative gas flow toward the web through the bladder openings (88) of the central zone (66), and blowing a fifth relative gas flow, which is less than the fourth relative gas flow, toward the path through the first side zone (60). 28 nrf: 11 = 3rMtnrnitfi 1:; 3 EZ.3 CL] CO Z3 1 = 1 EZ: 1 EZ3 = IEZ11 r = 1 rf3 c = 1 r: = 3 C ;; 1 CO ED CD II M1M = IM C; ; 1 CO ED CD II In En En = I En EZ3 EZ3 1 = 3 EZ3 In En En En En En En rZ3 CD CD CD I = 1 C: 1 F = 1 r = i En CZ / rZ3 r;: 3 CZKZI I = 1 Ff: 1 En En En En En C ;; 1 CO ED II 1Z11 C ;; 3 r ;;: irZ: 1 C ;; 3 In rf3 En En En IC:; 1 EZ3 EZ3 lEn En En En in EZ3 EZI EZ3 CD ED EZ: 3 En En En En En En En zZ: 3 EZ3rZ1 1 = 1 c23 C3 C: 3 C21 C = I En CIEn in 36 EZZE E ;; 11 r: 3 38 12 42 537 252 1/6 22