EP2060675A2 - Sheet formation procedure and wet part for producing a sheet of fibrous material - Google Patents

Abstract

A sheet forming method involves supplying a fluid laterally, downstream of a turbulence block (3) of the material run-up (1), through openings (9) to a fiber material suspension in the wet batch, the paper-or cardboard-machine comprising the material run- up (1) and a sieve edge limit (7). An independent claim is given for a wet batch of a fiber material web fabrication machine.

Description

The subject of this invention is a sheet forming process for producing a fibrous web in a paper or board machine with improved fiber orientation, as well as a corresponding wet end for performing the sheet forming process.

To form a fibrous web in a paper machine, a pulp suspension is applied to a sieve with the aid of a headbox. The headbox consists of a distribution device for distributing the pulp suspension over the machine width, from a turbulence block, which is formed by a plurality of turbulence tubes and from a headbox. For good foliation, it is important that the pulp suspension jet impinge on the wire as evenly as possible over the entire width of the machine. However, the jet from the headbox expands after exiting the headbox nozzle, and there is an additional expansion of the jet after the impingement of the free jet on the wire. To guide the free jet and the pulp suspension on the screen therefore a Siebrandbegrenzung is necessary. Without the Siebrandbegrenzung the suspension would flow off the side of the screen, which would lead to a reduction of the basis weight and a disturbance of the fiber orientation in the edge region.

The Siebrandbegrenzung causes but also undesirable effects. On the one hand, the edge friction between the lateral headbox nozzle wall or the screen edge boundary and the pulp suspension leads to fiber orientation disturbances or to the formation of an uneven velocity profile in the suspension, wherein the speed in the machine direction is greater in the center of the screen than in the edge areas. On the other hand, the Siebrandbegrenzung causes a reflection wave to Siebmitte out when the suspension impinges on the Siebrandbegrenzung. This undesirable effect is reduced by screen edge limitations that expand in the machine direction. However, the pulp suspension flows into the areas exposed by the expansion, forming a pulp mat with a thinner edge.

Various solutions for these two problems are known from the prior art. So revealed the EP 1 619 298 A2 a headbox in which the marginal turbulence channels of the turbulence generator are each separated from the remaining turbulence generator area. These lateral turbulence channels each have supply lines for an edge current, through which the fiber orientation profile can be influenced. The EP 0 857 816 B1 describes a headbox with an integrated edge feed arrangement in the region of the turbulence block.
However, a supply of an edge stream in the turbulence block has the disadvantage that very large amounts of edge stream must be supplied so that the subsequent edge friction effects can be compensated or reduced. This strong overdose leads to a disruption of the flow before the steel outlet from the headbox and thereby to disrupt the fiber orientation.

The invention is therefore based on the object to provide an improved sheet forming method and a suitable wet end of a paper or board machine that circumvents the above-mentioned disadvantages and thereby reduces Faserorientierungsstörungen and leads to the formation of a pulp mat with improved basis weight distribution over the entire machine width.

This object is achieved by a sheet forming method in which a fluid is fed laterally through openings to the pulp suspension in the wet end after a turbulence block of a headbox. This leads to an improved suspension management and to a reduction or compensation of the edge friction. In addition, should the Siebrandbegrenzung have an expansion, the areas exposed by the expansion areas are filled with the fluid and thus prevents the flow of the suspension in these edge areas.
It is preferred to use white water as the fluid, which allows a particularly simple process, since a large amount of white water is obtained in the wet end anyway.

In another favorable embodiment, a pulp suspension is used as the fluid, which may also have a lower or higher consistency than the pulp suspension fed to the headbox distributor. This additional pulp feed makes it easier to compensate for the differences in basis weight across the machine direction. In a Siebrandbegrenzung widening in the machine direction is filled by this additional pulp feed the gap formed by the expansion with pulp suspension, thus achieving a uniform suspension height on the wire. This favors a uniform basis weight distribution over the entire fibrous web width.

As the fluid, a gas, in particular air can be used. As a result, it is likewise possible to achieve a reduction of the edge friction without having to supply additional liquid to the fibrous mat which forms.

It is advantageous if the fluid is already supplied to the suspension within the headbox nozzle, thereby conventional Siebrandbegrenzungen can be maintained.

But it is also possible that the fluid is supplied only in the Siebrandbegrenzung, thereby the edge friction can be reduced particularly well directly in the field of sheet formation.

It is expedient if the fluid is supplied essentially in the machine direction, since this favors the formation of a fluid film between Siebrandbegrenzung and pulp suspension. It is advantageous if the fluid when viewed in the machine direction as viewed has a greater flow velocity, as the pulp suspension. It can be supplied to the fluid in the machine direction at several successively arranged locations, while the fluid in the individual points with different flow rates or quantities be supplied. Preferably, the amount or flow rate of the fluid in the individual points in the machine direction then increases, since the pulp suspension thickened by the dewatering process on the wire and thus increases the cost of Randreibungskompensation.

The invention also provides a wet end for sheet formation, in which after a turbulence block in the screen edge boundary and / or the headbox feed channels are provided with openings for supplying a fluid to the pulp suspension. The fluid emerging from the openings reduces edge friction and improves sheet formation.

The openings may be arranged either in a side wall of the headbox or in a side wall of the Siebrandbegrenzung. A fluid supply in the headbox has the advantage that existing Siebrandbegrenzungen need not be modified, whereas a supply via the Siebrandbegrenzung allows improved edge friction minimization to the fixation of the sheet.

In an advantageous embodiment, the supply channels open into the side wall substantially parallel to the machine direction. This has the advantage that the flow direction of the fluid has substantially in the machine direction.

It is advantageous if the openings are provided for supplying fluid on both sides of the wet end, as this minimizes the edge friction on both sides and a symmetrical basis weight profile is formed.

It makes sense if the side wall after the opening has at least one recess which decreases in cross-section in the machine direction, wherein the side wall in the region of the recess serves as a guide surface for the supplied fluid. By this special design of the side wall, the fluid is approximately in the machine direction of the pulp suspension fed and favors the formation of a friction-reducing fluid film.

In a favorable embodiment of the wet end a plurality of outlet openings are provided, preferably in the machine direction seen one behind the other. By supplying the fluid at several points of the wet end, the area of the edge friction reduction or the pulp feed can be increased.

• Fig. 1 eine schematische Draufsicht einer erfindungsgemäßen Nasspartie;
• Fig. 2 eine schematische Draufsicht einer weiteren Variante einer erfindungsgemäßen Nasspartie;
• Fig. 3 eine schematische Seitenansicht von Fig. 1;
• Fig. 4 eine perspektivische Detailansicht von Fig. 1;

In the following two embodiments of the invention will be described with reference to drawings. Show it:

• Fig. 1 a schematic plan view of a wet end according to the invention;
• Fig. 2 a schematic plan view of another variant of a wet end according to the invention;
• Fig. 3 a schematic side view of Fig. 1 ;
• Fig. 4 a detailed perspective view of Fig. 1 ;

In the FIG. 1 The arrangement shown comprises a headbox 1 comprising a distributor 2, a turbulence block 3, which consists of a plurality of turbulence tubes 4 and a following headbox nozzle 5, through which the pulp suspension fed through the distributor 2 exits onto a sieve 6. The machine direction is indicated by an arrow 15. At Siebrand is a Siebrandbegrenzung 7, which prevents the impinging on the sieve 6 pulp suspension flows laterally from the wire 6. In the side wall 8 of the Siebrandbegrenzung 7 are openings 9 of supply channels 10. Through these supply channels 10, a fluid, for example water, dilution water, pulp suspension, air or a mixture of these components is supplied. By this fluid supply, the edge friction between the pulp suspension and the side wall 8 of the Siebrandbegrenzung 7 decreases because the fluid forms a boundary film between the suspension and the side wall 8. In this case, the fluid is injected substantially in the machine direction, wherein the flow rate of the fluid is greater than the flow rate of the pulp suspension on the screen. The openings 9 in the side wall 8 of the Siebrandbegrenzung 7 are located in recesses 11. Through these recesses 11, the fluid is injected as parallel as possible in the machine direction between the side wall 8 of the Siebrandbegrenzung 7 and emerging from the headbox 1 pulp suspension.

FIG. 2 represents a further embodiment of the invention, wherein the reference numerals used to those in Fig. 1 correspond. In this embodiment, however, the fluid is supplied via supply channels 10 'through openings 9' in the side wall 8 'of the headbox nozzle 5. The openings 9 'are arranged in recesses 11' of the side wall 8 ', thereby promoting the fluid supply in the machine direction.

FIG. 3 shows a side view of FIG. 1 , it is particularly well recognized the sieve 6, which is deflected under the headbox 1 by a breast roll 12. The pulp suspension emerging from the headbox nozzle 5 impinges on the wire 6 in the jet impact point 13. The opening 9 and the recess 11 in the side wall 8 of the Siebrandbegrenzung 7 are indicated.

In FIG. 4 is a perspective detail view of FIG. 1 illustrated and illustrates the shape of the recess 11 in the side wall 8. The pulp suspension exits from the nozzle opening 14 of the headbox 5 and strikes in Strahlauftreffpunkt 13 on the sieve 6. The fluid exits from the opening 9. The opening 9 is arranged perpendicular to the machine direction in the recess 11 of the side wall 8 and formed as a slot. The recess 11 decreases continuously in cross section in the machine direction.

In operation, a pulp suspension is fed to the headbox 1 via the distributor 2. In this case, a part of the suspension in a return 2 'are deducted. The pulp suspension flows in the headbox 1 through a plurality of turbulence tubes 4 in the headbox 5. From the pulp nozzle 5, the pulp suspension hits in the Strahlauftreffpunkt 13 on the sieve 6. By supply channels 10, 10 'in the Siebrandbegrenzung 7 and headbox 5 is a fluid for Influenced influencing the velocity profile of the pulp suspension. The fluid preferably has a higher flow velocity in the machine direction than the pulp suspension, and optionally a lower viscosity and lower consistency than the pulp suspension. Due to the higher flow velocity of the fluid, the pulp suspension is accelerated in the edge regions in the machine direction. As a result, a uniform velocity profile is formed over the entire width of the pulp suspension.

The embodiments shown in the drawings represent only a preferred embodiment of the invention. The invention also includes other embodiments, e.g. the injection of a fluid over the side wall 8 'of the headbox nozzle 5 and the side wall 8 of the Siebrandbegrenzung 7. There are also several openings 9, 9' conceivable, which are arranged in machine direction. In this case, the fluid can be supplied at different speeds or different amounts through the respective openings. It is advantageous if the speed of the fluid supplied through the individual openings 9, 9 'increases in the machine direction, since the pulp suspension thickened by the dewatering process on the wire 6 and thus the effort for edge friction compensation increases.

Claims (15)

Sheet forming method for producing a fibrous web in a paper or board machine having a wet end comprising a headbox (1) and a Siebrandbegrenzung (7), characterized in that in the wet end after a turbulence block (3) of the headbox (1), a fluid laterally through openings (9, 9 ') is fed to the pulp suspension. Sheet forming method according to claim 1, characterized in that white water is used as the fluid. Sheet forming method according to claim 1, characterized in that a pulp suspension is used as the fluid. Sheet forming method according to claim 1, characterized in that a gas, in particular air, is used as the fluid. Sheet forming method according to one of claims 1 to 4, characterized in that the fluid is supplied in the machine direction substantially. Sheet forming method according to one of claims 1 to 5, characterized in that the fluid is fed in the machine direction in succession at several points with different flow rates and / or amounts. Sheet forming method according to claim 6, characterized in that the amount and / or flow rate of the fluid in the individual points in the machine direction increases. Wet end of a machine for producing a fibrous web, with a headbox (1) and a sieve edge limiter (7), wherein the headbox (1) has a distributor (2), a turbulence block (3) and a headbox nozzle (5) and wherein the Siebrandbegrenzung (7) directly adjacent to the headbox nozzle (5), characterized in that after the turbulence block (3) in the Siebrandbegrenzung (7) and / or the headbox feed channels (10, 10 ') with openings (9, 9 ') are provided for supplying a fluid to the pulp suspension. Wet end according to claim 8, characterized in that the openings (9 ') in a side wall (8') of the headbox nozzle (5) are arranged. Wet end according to claim 8, characterized in that the openings (9) in a side wall (8) of the Siebrandbegrenzung (7) are arranged. Wet end according to one of claims 8 to 10, characterized in that in the side wall (8, 8 '), the supply channels (10, 10') open substantially parallel to the machine direction. Wet end according to one of claims 8 to 11, characterized in that the openings (9, 9 ') are arranged on both sides of the wet end seen in the machine direction. Wet end according to one of claims 8 to 12, characterized in that the side wall (8, 8 ') after the opening (9, 9') at least one recess (11, 11 ') which decreases in cross-section in the machine direction, wherein the Side wall (8, 8 ') in the region of the recess (11, 11') serves as a guide surface for the supplied fluid. Wet end according to one of claims 8 to 13, characterized in that a plurality of openings (9, 9 ') are provided. Wet end according to claim 14, characterized in that the openings (9, 9 ') are arranged one behind the other as viewed in the machine direction.

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