EP1676950A1 - Headbox for machine for producing a fibrous web, in particular of a paper or cardboard web - Google Patents

Abstract

A headbox for machines for making fibrous sheet, especially paper or cardboard, in which the fluid feed lines open (preferably directly) into the top, bottom and/or front of the upstream part of the intermediate compartment, which is also sub-divided by flow dividers across the machine width so as to form a first (upstream) intermediate compartment with flow channels. A headbox (1) for a machine for the production of fibrous sheet, especially paper or cardboard, with at least one distributor (2) for distributing a pulp suspension (3) over the width of the machine (MB), a guiding device (4) with numerous channels (5), another guiding device (6) with channels (7), an intermediate compartment (8) between, a headbox nozzle (9) connected to (6) and provided with an outlet gap (10) delivering a stream of pulp suspension (11), and several feed lines (12) for a fluid to be added (13), which are distributed over MB. The fluid feed lines (12) preferably open directly into the top, bottom and/or front of the upstream part (14) of compartment (8), which is also sub-divided over at least part of its length by several flow dividers (15) spread over the machine width (MB) and forming flow channels (16) so as to form at least one first (upstream) intermediate compartment (17). An independent claim is also included for a machine for the production of fibrous sheet, especially paper and/or cardboard, with a headbox (1) as described.

Description

The invention relates to a headbox for a machine for producing a fibrous web, in particular a paper or board web, with at least one distributor device for distributing at least one fibrous stock suspension across the machine width, with a first guide device having a plurality of channels, with a second, a plurality of channels having guide means, with an intermediate chamber therebetween, with a headbox adjoining the second guide means, which is provided with an outlet slit supplying a pulp suspension jet, and with a plurality of distributed over the machine width supply lines for a zuzumischendes fluid.

Such a headbox is known for example from German patent application DE 44 16 899 A1. In this embodiment, the admixture of the fluid with multiple distributed over the machine width supply lines directly into the machine-width intermediate chamber of the headbox. There, the added fluid streams mix with the pulp suspension to partial mixing streams. Among other things, this design has the aerodynamic disadvantage that coarse turbulence structures arise in the pulp suspension in the region of the machine-width intermediate chamber which can lead to turbulence of the individual partial mixing streams.

In the context of German Patent DE 40 19 593 C2 has been proposed, the admixture of the fluid sectionally via supply lines in the machine-width intermediate chamber upstream mixing chambers, so-called Dilution facilities to perform. However, it is disadvantageous that the divisions of the dilution devices are not independent of the number of lines. This creates an unequal response breadth.

It is therefore an object of the invention to develop a headbox of the type mentioned in such a way that it no longer has the disadvantages of the prior art. In particular, it should have a reduced and constant effective response width, effect a good mixing of the partial mixing streams in their z-direction, ensure a constancy of the partial volume flow independently of the partial fluid flow and enable retrofitting to existing systems.

This object is achieved according to the invention in that the supply lines preferably open directly on the upper side, lower side and / or front side into the upstream region of the intermediate chamber and that the intermediate chamber is subdivided by means of a plurality of flow dividers arranged across the machine width and forming flow channels at least in sections with respect to their longitudinal direction, in that at least one first intermediate chamber is formed upstream.

The object of the invention is completely solved in this way.

The top, bottom and / or end mouth of the supply lines in the upstream region of the intermediate chamber provides, among other things, a maximum of flexibility in terms of divisions of different construction and functional groups and also allows cost-effective retrofitting to existing facilities, since only minor changes, in particular attachment of Holes ("one-hole dosages") and the like, must be made on the existing system. A reduction and constant maintenance of the response range is also positively supported. The flow channels cause due to the division of the mixed streams in smaller volume partial mixing streams a good mixing of the same in their z-direction. And last but not least, a constancy of the volume partial flow is ensured independently of the partial fluid flow.

The flow divider also causes a pressure drop in the range of 01, to 5 bar, preferably from 0.2 to 1 bar, which in turn results in a largely equalization of the volume partial flows.

In a preferred embodiment it is provided that the supply lines open in the region of the first intermediate chamber on the upper side and / or the lower side in the upstream region of the intermediate chamber. As a result, the at least one pulp suspension and the admixed fluid are given the largest possible time for homogeneous mixing.

• die Zuführleitungen münden in Verlängerung und/oder annähernd in Verlängerung der Kanäle der ersten Führungseinrichtung und/oder vorzugsweise symmetrisch zwischen den Kanälen der ersten Führungseinrichtung oberseitig und/oder unterseitig in den stromaufwärtigen Bereich der Zwischenkammer;
• die Zuführleitungen münden im vorzugsweise stromaufwärtigen Bereich der Strömungskanäle der Strömungsteiler oberseitig und/oder unterseitig in den stromaufwärtigen Bereich der Zwischenkammer;
• die Zuführleitungen münden mittig oder annähernd mittig zwischen den Strömungskanälen der Strömungsteiler oberseitig und/oder unterseitig in den stromaufwärtigen Bereich der Zwischenkammer, und/oder
• die Zuführleitungen verlaufen zumindest endseitig durch die erste Führungseinrichtung hindurch und münden stirnseitig in den stromaufwärtigen Bereich der Zwischenkammer, wobei die Zuführleitungen in vorteilhafter Weise mittig oder annähernd mittig zwischen den Kanälen der ersten Führungseinrichtung hindurch verlaufen.

With regard to the mouth of the supply lines, several preferred and advantageous possibilities are proposed:

• the supply lines open in the extension and / or approximately in extension of the channels of the first guide means and / or preferably symmetrically between the channels of the first guide means on the top side and / or bottom side in the upstream region of the intermediate chamber;
• the supply lines open in the upstream region of the flow channels of the flow dividers on the upper side and / or the lower side into the upstream region of the intermediate chamber;
• the supply lines open at the center or approximately in the middle between the flow channels of the flow dividers on the top side and / or bottom side into the upstream region of the intermediate chamber, and / or
• the supply lines extend at least at the end through the first guide device and open at the end into the upstream region of the intermediate chamber, wherein the supply lines advantageously extend centrally or approximately centrally between the channels of the first guide device.

All these possibilities have in common that they optimally accomplish the supply of the fluid, still allow a homogeneous mixture of the same with the at least one pulp suspension and allow retrofitting into an existing system with little technical effort.

In a favorable embodiment, the number of supply lines is equal to or approximately equal to the number of channels of the first guide device. This ensures a direct and individual assignment of a supply line to a channel of the first guide device. A partial flow of the supplied fluid is thus assigned to a partial flow of the at least one pulp suspension. An allocation of the partial flows in the ratio of 1: 1 is provided. In this case, both the channels of the first guide device and the flow divider may have a respective pitch, which are the same, approximately the same or different.

In a further favorable embodiment, the number of flow dividers is equal to or approximately equal to the number of channels of the first guide device. With the same number, the flow dividers are preferably arranged in fluidic extension of the channels of the first guide device. This in turn ensures a direct and individual assignment of a flow divider to a channel of the first guide device.

In a third advantageous embodiment, both the flow divider and the channels of the second guide device have a respective pitch, which are the same, approximately the same or different. In one possible difference, the pitch of the channels of the second guide means is preferably a fraction of the pitch of the flow dividers. In this case, the channels of the second guide device may be aligned symmetrically to the flow dividers, so that a fluidically optimal flow path is formed.

The first intermediate chamber preferably has a length in the range of 5 to 500 mm, preferably from 10 to 100 mm, so that a sufficient length for a possible balance in terms of pressure, speed and the like is given.

The flow dividers arranged in the intermediate chamber may extend up to or not as far as the second guide device. In one possible extension, the flow dividers arranged in the intermediate chamber may be components of the second guide device in terms of mechanical engineering, whereas in the case of possible non-extension, the formed second intermediate chamber may have a length in the range from 1 to 500 mm, preferably from 10 to 100 mm.

Furthermore, the first guide device is preferably designed as a perforated plate, whereas the second guide device is preferably formed as a turbulence generator, which preferably has a turbulence insert with a plurality of turbulence channels, which are formed in particular by turbulence tubes. Such embodiments of the guide devices are well known in the prior art and are particularly suitable for the present embodiments.

In a further preferred embodiment, it is provided that the flow dividers forming the flow channels have at least in sections arranged structures for preferably homogeneous mixing of the respective partial mixed streams. Through these structures, the achievement of a homogeneous mixing of the supplied partial streams and pulp suspension and fluid is supported significantly positive.

Furthermore, it is advantageous if at least the flow dividers forming the flow channels at least in some areas have a turbulence-generating corrugated surface structure. Of course, the flow guide can all be arranged on the circumference of the straightening channel.

The oppositely arranged in the respective flow channel structures preferably have a preferably opposite course. This measure has a particularly advantageous effect in terms of achieving a homogeneous mixture of the two partial streams and a best possible flow calming in the partial mixing streams. In addition, the desired orientation of the partial mixing streams in the machine direction is favored.
Furthermore, the structures arranged in the flow channels comprise a plurality of flow guide elements, which are aligned at least downstream in the machine direction. This outlet-side alignment of the flow guide elements contributes significantly to the desired flow orientation of the partial mixing streams. An inlet-side alignment of the flow guide in the machine direction is desirable, but not essential.

The flow guide elements preferably have a respective element height in the range of 5 to 95%, preferably 30 to 70% of the respective clear chamber width. In this case, the element heights of at least some, preferably all flow guide elements in the machine direction can increase. These element heights require immersion of the flow guide elements in the partial mixing streams during their mixing, settling and orientation.

The arranged in a flow channel flow guide are offset in height from each other, so that it does not come to any collisions and the respective partial mixing current is continuously performed. Two adjacent flow guide elements can have a spacing in the range from 0.2 to 5 ×, preferably from 0.5 to 2 ×, of the respective clear channel width.

In order to ensure sufficient alignment of the partial mixing streams, the flow guide elements have a respective element length in the range from 1 to 20 ×, preferably from 2 to 10 ×, of the respective element height.

In the region of the flow channels additional guide means may be arranged, which contribute to the generation of a desired pressure loss in the respective flow channel.

The structures in a preferred embodiment in the form of baffles, vanes or the like. However, further fluidically suitable embodiments of the structures are of course possible.

In addition, the flow channels of the flow divider downstream preferably have a respective widening cross-section, so that a gradual transition into the machine-width second intermediate chamber, if present, is given.

The inventive machine for producing a fibrous web, in particular paper and / or board web, is characterized in that it is provided with a head box according to the invention.

Further features and advantages of the invention will become apparent from the following description of preferred embodiments with reference to the drawings.

Figur 1

eine schematische und geschnittene Draufsicht auf einen Stoffauflauf für eine Maschine zur Herstellung einer Faserstoffbahn;

Figur 2

eine teilweise Detailansicht der ersten Zwischenkammer samt angrenzenden Baugruppen der Figur 1;

Figur 3

eine teilweise Detailansicht des Stoffauflaufs der Figur 1;

Figur 4

eine teilweise Detailansicht des Stoffauflaufs der Figur 1 in alternativer Ausgestaltung;

Figur 5:

eine schematische Schnittdarstellung des Stoffauflaufs der Figur 1 gemäß Schnittlinie F-F;

Figuren 6a, 7a und 8a

verschiedene Ansichten eines Strömungskanals in Maschinenlaufrichtung; und

Figuren 6b, 7b und 8b

verschiedene Wandansichten der Strömungskanäle der Figuren 6a, 7a und 8a.

Show it

FIG. 1

a schematic and sectional plan view of a headbox for a machine for producing a fibrous web;

FIG. 2

a partial detail view of the first intermediate chamber together with adjacent components of Figure 1;

FIG. 3

a partial detail view of the headbox of Figure 1;

FIG. 4

a partial detail view of the headbox of Figure 1 in an alternative embodiment;

FIG. 5:

a schematic sectional view of the headbox of Figure 1 according to section line FF;

Figures 6a, 7a and 8a

different views of a flow channel in the machine direction; and

Figures 6b, 7b and 8b

different wall views of the flow channels of Figures 6a, 7a and 8a.

1 shows a schematic and sectional plan view of a headbox 1 for a machine for producing a fibrous web. The fibrous web may in particular be a paper or board web.

The headbox 1 has a distributor 2 for distributing a pulp suspension 3, in particular a highly consistent pulp suspension, across the machine width MB (double arrow). The distributor 2 is in the embodiment of Figure 1, a transverse distribution tube 2.1; In a further embodiment, it can also be designed as a rotary distributor with a plurality of inlet hoses. Furthermore, the headbox comprises a first, a plurality of channels 5 having guide means 4, a second, a plurality of channels 7 having guide means 6 and an intermediate chamber located therebetween 8. The second guide means 6 is followed by a headbox 9, which with a a Pulp suspension jet 11 supplying exit slit 10 is provided. In addition, the headbox 1 has a plurality of across the machine width MB (double arrow) away and only schematically shown supply lines 12 for zuzumischendes fluid 13. The fluid 13 may be a low-consistency pulp suspension, in particular white water, and / or fresh water.

The feed lines 12 now preferably open directly on the upper side into the upstream region 14 of the intermediate chamber 8 and the intermediate chamber 8 is divided by means of several across the machine width MB (double arrow) away and flow channels 16 forming flow dividers 15 at least in sections with respect to their longitudinal direction L (arrow) such that upstream of at least a first intermediate chamber 17 is formed. The flow dividers 15 divide the pulp suspension stream and optionally also the fluid stream into common individual streams.

In the embodiment according to FIG. 1, the supply lines 12 open centrally and upstream between the flow channels 16 of the flow dividers 15 into the first intermediate chamber 17.

The first guide device 4 is designed as a perforated plate 18, whereas the second guide device 6 is designed as a turbulence generator 19 (see FIG. 5) which preferably has a turbulence insert 20 with a multiplicity of turbulence channels 21, which are formed in particular by turbulence tubes 22. The second guide means 6 designed as a turbulence generator 19 is shown only schematically, since such a turbulence generator 19 is well known in the art.

FIG. 2 shows a partial detail view of the first intermediate chamber 17 together with adjacent assemblies of FIG. 1, namely the first guide device 4 with the channels 5, the first intermediate chamber 17 and the flow divider 15 with the flow channels 16.

This figure shows an example of the possible mouth locations of the supply lines 12, which preferably open directly on the top, bottom and / or end into the upstream region 14 of the intermediate chamber 8.

The supply line 12 may be in extension and / or approximately in extension of the channel 5 of the first guide means 4 (dashed position A) and / or preferably symmetrically between the channels 5 of the first guide means 4 (dashed position B) on the top and / or bottom in the upstream Area 14 of the intermediate chamber 8 open. Also, the supply line 12 in the preferably upstream region 23 of the Flow channel 16 of the flow divider 15 (dashed position C) open on the upper side and / or underside in the upstream region 14 of the intermediate chamber 8. It can also open centrally or approximately centrally between the flow channel 16 of the flow divider 15 (position D) on the upper side and / or the lower side in the upstream region 14 of the intermediate chamber 8. And finally, the supply line 12 can extend at least at the end through the first guide device 4 and open at the end into the upstream region 14 of the intermediate chamber 8 (dashed position E). In this case, it can run centrally or approximately centrally between the channels 5 of the first guide device 4.

FIG. 3 shows a partial detail view of the headbox 1 of FIG. 1.

In this case, both the channels 5 of the first guide device 4 and the flow divider 15 have a respective pitch T _KEF , T _s , which are the same or approximately equal. Of course, the two divisions T _KEF , T _{s can} also be different. As a result of the same or approximately equal divisions T _KEF , T _s , the number of flow dividers 15 is equal to or approximately equal to the number of channels 5 of the first guide means 4. Further, the flow divider 15 are arranged in fluidic extension of the channels 5 of the first guide means 4, so that for the pulp suspension 3 baffles 24 are formed on the flow dividers 15.

Furthermore, both the flow divider 15 and the channels 7 of the second guide means 6 have a respective pitch T _s , T _KZF , which are equal or approximately equal. Of course, the two pitches T _s , T _KZF , as seen in the embodiment of Figure 3, also be different. The pitch T _{KZF of} the channels 7 of the second guide means 6 is a fraction of the pitch T _{s of} the flow divider 15, more precisely half. The channels 7 of the second guide means 6 are aligned symmetrically to the flow dividers 15.

The number of supply lines 12 corresponds to the number of channels 5 of the first guide device 4 plus 1.

Furthermore, the first intermediate chamber 17 has a length L _Z1 in the range of 5 to 500 mm, preferably from 10 to 100 mm. The flow dividers 15 arranged in the intermediate chamber 8 do not extend to the second guide device 6, so that at least one second intermediate chamber 25 is formed downstream. This second intermediate chamber 25 has a length L _Z2 in the range of 1 to 500 mm, preferably from 10 to 100 mm.

The flow dividers 15 forming the flow channels 16 have structures 26 arranged at least in sections for preferably homogeneous mixing of the respective partial mixing streams (compare FIGS. 6a to 8b).

In addition, the flow channels 16 downstream of a respective expanding cross-section. The extension can be continuous and / or unsteady.

FIG. 4 again shows a partial detail view of the headbox 1 of FIG. 1, but in an alternative embodiment.

The alternative embodiment consists in that the flow dividers 15 arranged in the intermediate chamber 8 extend up to the second guide device 6 and thus no second intermediate chamber is formed. The arranged in the intermediate chamber 8 flow divider 15 are preferably mechanical engineering components of the second guide means 6. Otherwise, the present embodiment corresponds to the embodiment of Figure 3, to which reference is hereby made to this.

5 shows a schematic sectional view of the headbox 1 of Figure 1 according to section line FF. With regard to the general description of the illustrated headbox 1, reference is made to the description of Figure 1.

It can be clearly seen that the possible supply lines 12 can preferably open into the upstream region 14 of the intermediate chamber 8, preferably directly on the upper side, the lower side and / or the front side. The over the machine width MB (arrow) away and flow channels 16 forming flow divider 15 can effectively derive forces, which act on the limiting surfaces of the channel structure, for example, by means of attached connecting elements 27, in particular screws under the prevailing requirement.

The flow dividers 15 forming the flow channels 16 have structures 26 arranged at least in sections, for preferably homogeneous mixing of the respective partial mixed streams. In this case, they have, at least in regions, a turbulence-generating corrugated surface structure 28.

The first guide device 4 is formed as a perforated plate 18, whereas the second guide device 6 is formed as a turbulence generator 19, which preferably has a turbulence insert 20 with a plurality of turbulence channels 21, which are in particular formed by turbulence tubes 22.

Furthermore, the first intermediate chamber 17 has a length L _Z1 in the range of 5 to 500 mm, preferably from 10 to 100 mm. The flow dividers 15 arranged in the intermediate chamber 8 do not extend to the second guide device 6, so that at least one second intermediate chamber 25 is formed downstream. This second intermediate chamber 25 has a length L _Z2 in the range of 1 to 500 mm, preferably from 10 to 100 mm.

FIGS. 6a, 7a and 8a show different views of a flow channel 16 lying between two flow dividers 15 in the machine direction M (arrow), whereas FIGS. 6b, 7b and 8b show different wall views of the flow channels 16 of FIGS. 6a, 7a and 8a.

The flow dividers 15 forming the flow channels 16 have structures 26 arranged at least in sections, for preferably homogeneous mixing of the respective partial mixed streams. In this case, they have, at least in regions, a turbulence-generating corrugated surface structure 28, which in the flow channel 16 arranged opposite structures 26, 28 find a preferably opposite course.

The flow guide elements 29 shown in these figures have a respective element height H _s in the range of 5 to 95%, preferably 30 to 70% of the respective clear channel width B _K. In this case, the element heights H _{s of} at least some, preferably all, of the flow guide elements 29 in the machine direction M (arrow) increase.

Furthermore, the flow guide elements 29 arranged in the flow channel 16 are arranged at least on the two lateral flow dividers 15. Of course, the flow guiding elements 29 can all also be arranged on the circumference of the flow channel 16. The flow guiding elements 29 can also have different courses: they can run in a straight line (FIGS. 6a and 6b), curved (FIGS. 7a, 7b, 8a and 8b) or combined.

In addition, two adjacent flow guide elements 29 have a distance G in the range from 0.2 to 5 ×, preferably from 0.5 to 2 ×, of the respective clear channel width B _K.

The arranged in a flow channel 16 Strömungsleitelemente 29 are equal in height (Figure 6a) or height offset from each other (Figures 7a and 8a) arranged. Of course, further combinations of arrangements are possible, whether in a flow channel 16 or in a group of preferably adjacent flow channels 16.

The flow guide elements 29 have a respective element length L _s in the range from 1 to 20 times, preferably from 2 to 10 times, the respective element height H _s . The structure 26 forming the flow guide 29 have the shape of baffles, vanes or the like.
Furthermore, the structures 26 arranged opposite one another in the respective flow channel 16 have a preferably opposing course (FIGS. 7b and 8b). In this case, the structure 26 of a flow divider 15 may have an upward course, whereas the structure 26 of the other flow divider 15 may have a downward course. The curves can be made straight or curved here.

Advantageously, the structures 26 arranged in the respective flow channel 16 have a preferably opposite course to structures arranged upstream.

Moreover, in the region of the flow channels 16, additional guide devices 30 (FIGS. 8 a and 8 b) are arranged in the respective flow channel 16 for generating a desired pressure loss. These guide devices 30 are generally in the channel space protruding elements of different geometry and size and they are at least individually arranged between two flow guide 29.

In summary, it should be noted that the invention provides a headbox of the type mentioned, which no longer has the mentioned disadvantages of the prior art. In particular, it has a reduced and constant effective response width, causes a good mixing of the partial mixing streams in their z-direction, ensures a constancy of the volume partial flow independent of the partial fluid flow and allows retrofitting to existing systems.

LIST OF REFERENCE NUMBERS

1

headbox

2

distributor

2.1

transverse distribution

3

Fibrous suspension

4

First management facility

5

channel

6

Second guide device

7

channel

8th

intermediate chamber

9

headbox

10

exit slit

11

Fibrous suspension beam

12

feed

13

fluid

14

Upstream area

15

flow divider

16

flow channel

17

First intermediate chamber

18

perforated plate

19

turbulence generator

20

turbulence generator

21

turbulence channel

22

turbulence tube

23

Upstream area

24

baffle

25

Second intermediate chamber

26

structure

27

connecting element

28

surface structure

29

flow guide

30

guide

A, B, C, D, E

position

B _K

channel width

F-F

intersection

G

distance

H _s

element height

L

Longitudinal direction (arrow)

L _s

element length

L _Z1

length

L _Z2

length

M

Machine direction (arrow)

MB

Machine width (double arrow)

T _KEF

division

T _KZF

division

T _S

division

Claims (34)

Headbox (1) for a machine for producing a fibrous web, in particular a paper or board web, with at least one distributor (2) for distributing at least one fibrous stock suspension (3) across the machine width (MB), with a first, a plurality of channels (5) having guide means (4), with a second, a plurality of channels (7) having guide means (6), with an intermediate intermediate chamber (8), with a to the second guide means (6) adjoining headbox (9) provided with a discharge slit (10) delivering a pulp suspension jet (11) and with a plurality of feed lines (12) for mixing a fluid (13) distributed across the machine width (MB);
characterized,
in that the supply lines (12) preferably open into the upstream area (14) of the intermediate chamber (8), preferably directly on the upper side, the lower side and / or the front side, and
in that the intermediate chamber (8) is subdivided at least in sections relative to its longitudinal direction by means of a plurality of flow dividers (16) arranged across the machine width (MB) and such that at least one first intermediate chamber (17) is formed upstream. Headbox (1) according to claim 1,
characterized,
in that the supply lines (12) open into the upstream region (14) of the intermediate chamber (8) in the region of the first intermediate chamber (17) on the upper side and / or the lower side. Headbox (1) according to claim 2,
characterized,
that the supply lines (12) in extension and / or approximately in extension of the channels (5) of the first guide means (4) and / or preferably symmetrically between the channels (5) of the first guide means (4) on the upper side and / or lower side in the upstream Area (14) of the intermediate chamber (8) open. Headbox (1) according to one of the preceding claims,
characterized,
in that the supply lines (12) in the preferably upstream region (23) of the flow channels (16) of the flow dividers (15) open on the upper side and / or lower side into the upstream region (14) of the intermediate chamber (8). Headbox (1) according to claim 4,
characterized,
in that the supply lines (12) open centrally or approximately centrally between the flow channels (15) of the flow dividers (15) on the top side and / or bottom side into the upstream region (14) of the intermediate chamber (8). Headbox (1) according to one of the preceding claims,
characterized,
in that the supply lines (12) run through the first guide device (4) at least at the end and open into the upstream region (14) of the intermediate chamber (8) at the end. Headbox (1) according to claim 6,
characterized,
in that the supply lines (12) extend centrally or approximately centrally between the channels (5) of the first guide device (4). Headbox (1) according to one of the preceding claims,
characterized,
in that the number of supply lines (12) is equal to or approximately equal to the number of channels (5) of the first guide device (4). Headbox (1) according to one of the preceding claims,
characterized,
in that both the channels (5) of the first guide device (4) and the flow dividers (15) have a respective pitch (T _KEF , T _s ) which are the same, approximately the same or different. Headbox (1) according to one of the preceding claims,
characterized,
in that the number of flow dividers (15) is equal to or approximately equal to the number of channels (5) of the first guide device (4). Headbox (1) according to one of the preceding claims,
characterized,
in that the flow dividers (15) are arranged in fluidic extension of the channels (5) of the first guide device (4). Headbox (1) according to one of the preceding claims,
characterized,
in that both the flow dividers (15) and the channels (7) of the second guide device (6) have a respective pitch (T _S , T _KZF ) which are the same, approximately the same or different. Headbox (1) according to claim 12,
characterized,
that the pitch (T _KZF) of the channels (7) of the second guide means (6) is a fraction of the pitch (T _S) is the flow divider (15). Headbox (1) according to claim 12 or 13,
characterized,
in that the channels (7) of the second guide device (6) are aligned symmetrically with respect to the flow dividers (15). Headbox (1) according to one of the preceding claims,
characterized,
in that the first intermediate _chamber (17) has a length (L _z1 ) in the range from 5 to 500 mm, preferably from 10 to 100 mm. Headbox (1) according to one of the preceding claims,
characterized,
in that the flow dividers (15) arranged in the intermediate chamber (8) do not extend as far as the second guide device (6), that at least one second intermediate chamber (25) is formed downstream. Headbox (1) according to claim 16,
characterized,
in that the second intermediate chamber (25) has a length (L _Z2 ) in the range from 1 to 500 mm, preferably from 10 to 100 mm. Headbox (1) according to one of claims 1 to 15,
characterized,
that disposed in the intermediate chamber (8) a flow divider (15) extend up to the second guide device (6). Headbox (1) according to claim 18,
characterized,
that disposed in the intermediate chamber (8) a flow divider (15) are machine structural components of the second guide means (6). Headbox (1) according to one of the preceding claims,
characterized,
that the first guide means (4) is designed as a perforated plate (18). Headbox (1) according to one of the preceding claims,
characterized,
in that the second guide device (6) is designed as a turbulence generator (19), which preferably has a turbulence insert (20) with a multiplicity of turbulence ducts (21), which are formed in particular by turbulence tubes (22). Headbox (1) according to one of the preceding claims,
characterized,
in that the flow dividers (15) forming the flow channels (16) have structures (26), arranged at least in sections, for the preferably homogeneous mixing of the respective partial mixed streams. Headbox (1) according to claim 22,
characterized,
in that at least the flow dividers (15) forming the flow channels (16) at least in some areas have a turbulence-generating corrugated surface structure (28). Headbox (1) according to claims 22 to 23,
characterized,
that in the respective flow channel (16) arranged opposite structures (26) have a preferably opposite course. Headbox (1) according to one of claims 22 to 24,
characterized,
that arranged in the flow channels (16) structures (26) comprise a plurality of flow guide elements (29), which are at least on the outlet side oriented in the machine running direction (M). Headbox (1) according to claim 25,
characterized,
that the flow guide elements (29) have a respective element height (H _s) in the range of 5 to 95%, preferably from 30 to 70% of the respective bright chamber width (B _K). Headbox (1) according to claim 26,
characterized,
that the element heights (H _S) of at least some, preferably all flow guiding elements (29) increase in the machine running direction (M). Headbox (1) according to one of claims 25 to 27,
characterized,
in that the flow guide elements (29) arranged in a flow channel (16) are arranged offset in height relative to one another. Headbox (1) according to one of claims 25 to 28,
characterized,
in that two adjacent flow guide elements (29) have a spacing (G) in the range from 0.2 to 5 ×, preferably from 0.5 to 2 ×, of the respective clear channel width (B _K ). Headbox (1) according to one of claims 25 to 29,
characterized,
that the flow guide (29) x a respective element length (L _s) in the range of 1 to 20, preferably from 2 to 10 x the respective element height (H _s) have. Headbox (1) according to one of the preceding claims,
characterized,
that in the region of the flow channels (16) additional guide means (30) are arranged. Headbox (1) according to one of claims 22 to 31,
characterized,
in that the structures (26) are in the form of baffles, guide vanes or the like. Headbox (1) according to one of the preceding claims,
characterized,
in that the flow channels (16) have a respective widening cross-section downstream. Machine for producing a fibrous web, in particular paper and / or board web, with a headbox (1) according to one of the preceding claims.

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