SE506322C2 - Device for feeding stock to an inlet box in a paper machine - Google Patents

Abstract

An arrangement (2) for feeding stock to a headbox (1) in a papermaking machine, which comprises at least one stock header (3) with an inlet for receiving stock into the header and a plurality of stock header outlets (5) permitting stock to leave the header. For each stock header outlet (5) there is a stock conduit (7, 8, 9) downstream of the stock header outlet permitting stock to pass from the stock header outlet (5), through the conduit (7, 8, 9) to the inlet of the headbox. The arrangement includes a dilution header (30) for feeding a diluent such as water to a plurality of stock conduits. The dilution header has an inlet (31) for receiving a diluent into the dilution header (30) and a plurality of outlets (32) permitting the diluent to leave the dilution header. For each dilution header outlet (32), there is a diluent conduit (33) permitting the passage of a diluent from the dilution header (30) into a stock conduit (7, 8, 9). According to the invention, the diluent is fed into a stock conduit (7, 8, 9) at a location immediately downstream of a stock header outlet (5) and the stock header together with the stock header outlets (5) is designed such that the velocity of the stock flowing through the stock header (3a, 3b, 3c) is substantially equal to the velocity of the stock in an upstream end (10, 11, 12) of the stock conduits (7, 8, 9).

Description

506 322 10 15 20 25 30 35 nozzle on a forming wire. On the forming wire, the stock is dewatered so that a path is formed on the wire. The stock is fed to the headbox from an upstream pipe collection pipe, which feeds stock at high pressure to the headbox. When the stock is fed to a headbox in a paper machine, the stock is usually fed from the stock collection tube to the headbox in a number of separate conduits leading to the headbox inlet and connected to the headbox inlet at a plurality of periodically connected locations arranged in a straight line extending across the machine direction. In this way, the stock fed to the headbox will be evenly distributed across the machine direction to ensure that the stock discharged from the headbox is uniformly distributed across the machine direction so that the paper web produced in the paper machine will have uniform properties such as basis weight and fiber orientation. width.

During the process of papermaking, however, shortcomings due to the design of the paper machine as well as physical phenomena will lead to the failure to achieve uniform properties across the web and the paper web produced will have uneven properties across its width. To compensate for such irregularities, it is a general practical measure to regulate the volume of stock discharged from the headbox across the machine direction. A well-known way to achieve this is to use an outlet release in the headbox, which is locally adjustable. By varying the opening of the outlet lip across the machine direction, it is possible to adjust the volume of stock discharged from the headbox across the machine direction. However, this method of regulating stock flow from the headbox has the disadvantage that when the flow of stock changes at a point across the outlet lips, this change will cause transverse flows that will affect both basis weight and fiber orientation. In order to overcome this problem, it has been proposed that the stock fed to the headbox can be selectively diluted in such a way that a diluent is fed into at least some of the conduits through which the stock is fed to the headbox. By regulating the amount of diluent fed into each line, it is possible to compensate for basis weight variations across the machine direction.

Devices for selectively diluting the stock fed to the headbox are described in e.g. U.S. Patents 5,196.09l (Hergert) and 4,897,188 (Weisshuhn et al.).

When such a device is used, a flow of stock will meet and mix with a flow of diluent at a meeting point of the respective flows so that the flow of stock and the flow of diluent will be combined into a: resulting total flow of diluted stock which is the sum of the flows that meet each other, so that Qun = Qs + Qd, where QS is the volume flow of stock, Qd is the volume flow of diluent and Qw is the resulting total volume flow of diluted stock downstream of the meeting point.

As it is expected that the stock in each line will not be diluted to the same extent, it is of utmost importance that the feeding of a diluent into the stock will not affect the total volume flow of stock or diluted stock downstream of the meeting point between respective flows. If the total volume flow of dilute stock reaching the outlet lips is not even across the machine direction, this will cause transverse currents which will affect the fiber orientation.

It has therefore been realized that when a diluent is fed into the stock on its way to the outlet gap, measures must be taken to ensure that the total volume flow of diluted stock in a stock line remains constant regardless of the size of the volume flow of the diluent fed into the stock. so that downstream of the point where a diluent is fed into the stock, the volume flow of diluted stock will be the same in each stock line.

A solution to the above problem is described in U.S. Patent 5,316,638 (Begemann et al.). According to this document, a first volume flow of liquid (eg stock) passing through a first inlet line is met by and mixed with a second volume flow of liquid (eg a diluent such as water or dilute stock) passing through a second inlet line. The two liquids mix with each other at a meeting point and form a resulting total volume flow of mixed liquid. The first inlet line is arranged with a mixing angle relative to the second inlet line and the mixing angle is chosen so that the resulting total volume flow of mixed liquid remains constant. According to this document, the solution to the above problem thus lies in the correct choice of the mixing angle.

The preferred mixing angle for one embodiment is stated as 80 °. This document also describes experiments with different mixing angles which show that at a mixing angle of 90 ° an increase of the second volume flow will result in a decrease of the total volume flow of mixed liquid.

A different solution to the problem of achieving a constant volume flow of mixed liquid is described in the aforementioned U.S. Patent No. 5,196.09l (Hergert).

According to this document, an inlet drawer is provided with a tapered inlet or stock collection pipe for the flow of stock. The upstream end of a pipe assembly having a plurality of tubes for flow of stock, connected to the tapered inlet so that stock flows through the tapered inlet and from the inlet through the upstream end of the pipe assembly to a downstream end of the pipe collection. A plurality of supply lines for a diluent, such as fresh water or backwater, are connected to the upstream end of the pipe collection. Each supply line has an end which is arranged close to and upstream in relation to an upstream pipe in the pipe assembly. In Fig. 6 of U.S. Patent 5,196,091, the end of the supply lines is shown as being located in a wall of the tapered inlet so that a supply line will feed a diluent directly into the stock at a location upstream of it. upstream end of a pipe in the pipe assembly. According to U.S. Patent 5,196,091, when a diluent, such as water, flows through the end and into the stock, the stock flowing through a pipe near the end will be diluted, but the flow rate through the pipe will not change. In this case, the constant maintenance of the flow rate depends on the fact that the diluent is fed into the stock upstream of the pipe. each of the above solutions offers an opportunity to dilute stock flowing through a pipe without affecting the total volume flow of the stock through the pipe. However, the known solutions are not always satisfactory. For example, the solution of U.S. Patent 5,196,091 carries a potential risk that the diluent may not be fed into the stock with complete accuracy, since the diluent is fed directly into the tapered inlet or stock collection tube at a point upstream of the pipe ends where it could possibly avoid reaching the right tube end. In addition, there is a possibility that the feed of a diluent directly into the stock collection pipe could cause pressure variations in the collection pipe which could affect the flow in the stock lines. The solution according to U.S. Patent S, 316,383 requires a specially designed connection between the inlet lines of the respective volume flows, since the flows must meet at the right angle and the required oblique connection is not the simplest to design from a manufacturing point of view. In addition, 506,322 experiments performed by the inventors of the present invention have failed to confirm that the mixing angle is as important as disclosed in U.S. Patent 5,316,383.

There is therefore a need for an easily applied solution to the problem of feeding a volume flow of a diluent into a volume flow of stock so that the flow of stock and the flow of diluent will form a resulting total volume flow of diluted stock where changes in the volume flow of the diluent will not affect the resulting total volume flow of diluted stock. There is also a need for a device for diluting stock that is easy to manufacture. In addition, there is a need for a device for diluting stock that ensures a good mixture of stock and diluent. Furthermore, there is a need for a device for feeding stock to a headbox which allows a simple installation under a number of different conditions.

SUMMARY OF THE INVENTION The main object of the invention is to provide in a device for feeding stock to a headbox a correctly applied solution to the problem of feeding a volume flow of a diluent into a volume flow of stock so that the flow of stock and the flow of diluent will form a resulting total volume of dilute stock where changes in the volume flow of the diluent will not affect the resulting total diluted stock. The main object of the invention is achieved by the present invention, which is directed to a device for feeding stock to a headbox in a paper machine. The device comprises at least one stock collection pipe for feeding stock to an inlet end of a headbox, the stock collection pipe having an inlet for bringing stock into the collection pipe and a plurality of outlets which allow stock to leave the collection pipe. . For each outlet of the stock collection pipe there is a stock line downstream of the outlet of the stock collection pipe which allows stock to pass from the outlet of the stock collection pipe through the conduit to the inlet end of an inlet box to thereby connect the outlet of the stock collection pipe to the inlet end of the inlet pipe. The device further comprises at least one diluent manifold for feeding a diluent to a plurality of stock lines connecting the outlets of a stock collection pipe to the inlet end of the headbox, said dilution manifold having an inlet for introducing a diluent into the diluent collection and dilution manifolds. allows the diluent to leave the dilution manifold. The diluent can be, for example, water, backwater or diluted stock. For each outlet of the dilution manifold, there is a diluent line that allows a diluent to pass from the diluent manifold through the diluent line to one of the plurality of stock lines downstream of the stock collection tube into the stock passing through the stock line. Each diluent line has an upstream end which is connected to an outlet of the dilution manifold and a downstream end which is connected to and leads into one of the stock lines. According to the invention, the downstream end of each diluent line is connected to one of the stock lines at an upstream end of the stock line and at a point immediately downstream of the stock collection pipe or alternatively at a point downstream the outlet of the stock collection pipe and at a nearby stock distance from the stock collection pipe. outlet. Thereby, a diluent can be fed into the stock at a location downstream and at a close distance to or immediately downstream an outlet from the stock collection pipe. Furthermore, the outlets of the stock collection tubes are designed in such a way that the velocity of the stock at the upstream end of the stock lines is substantially equal to the velocity of the stock in the stock collection tube.

The inventors have found that the distance between the outlet from the stockpile and the connection between the diluent line and the stock line is crucial for the possibility of making variations in the flow of diluent to affect the total volume flow of diluted stock downstream of the connection between the stock line and the diluent line. . The relationship between the distance and the possibility of variations in the dilution flow to effect variations in the total volume flow of diluted stock will now be discussed.

When stock passes through the stock lines downstream of the outlets of the stock collection pipe, pressure losses due to friction in the lines will occur. The greater the distance between the outlet from the stock collection pipe and the connection between the diluent line and the stock line, the greater the pressure loss before the diluent is fed into the stock. A large pressure drop will occur at a large pressure difference between the outlet from the stock collection pipe and the point in the stock line where the diluent is fed into the stock. When a volume flow of a diluent is fed into the stock line, this will have a tendency to affect the pressure in the stock line. Since it is expected that different diluent lines will supply different amounts of diluent to their associated stock lines, the pressure in each separate stock line will be affected to a different degree than the pressure in nearby stock lines. As a result, the volume flow downstream of the connection between the stock line and the diluent line will not be the same in all stock lines.

However, the inventors have found that when the distance between the outlet of the stock collection pipe and the connection between the stock line and the diluent line is small, the pressure loss is also small so that the pressure in the stock line at the place where the diluent is fed into the stock is almost the same as the pressure in the stock collection pipe itself, whereby the feeding of a flow of diluent into the stock line will only have a marginal effect on the pressure in the stock line. As a result, the volume flow of diluted stock downstream of the connection between the stock line and the diluent line will be affected only to a marginal extent and the volume flow of diluted stock will remain substantially constant regardless of any variations in the flow of diluent into the stock line. The inventors have found that the smaller the distance and pressure drop between the outlet of the stock collection pipe and the connection between the pipes, the smaller variations in the flow of diluent fed into the stock will be able to cause variations in the volume flow of diluted stock passing through the stock line. In theory, the distance should preferably be zero or close to zero, which would correspond to no pressure drop at all between the outlet of the stock collection pipe and the connection between the stock line, and the diluent line. In practice, however, there will usually be a certain distance between the outlet from the stock collection pipe and the connection between the stock line and the diluent line. However, the inventors have found that this distance should not exceed 0.15 meters, which corresponds to a pressure drop of not more than 1 KPa, when the pressure in the stock collection pipe is of the order of 300 KPa. The term "immediately downstream" should therefore not necessarily be understood in connection with this application as meaning that there is no distance at all between the outlet of the stock collection pipe and the connection between the stock line and the diluent line.

According to the invention, the velocity of the stock at the upstream end of the stock lines should be substantially equal to the speed of the stock in the stock collection itself 506 322 10 15 20 25 30 35. For this purpose, the stock collection pipe is tapered so that the cross-sectional area of the stock collection pipe decreases in the direction of the flow of stock into the stock collection pipe and the diameter of the outlets of the stock collection pipes and the upstream end of the stock lines is selected so that cross-sectional sections a stock line is equal to the decrease in cross-sectional area of the stock collection pipe between two outlets of the stock collection pipe, ie. the difference in cross-sectional area of the stock collection pipe between two outlets of the stock collection pipe is equal to the cross-sectional area of each outlet of the stock collection pipe and equal to the cross-sectional area of the upstream end of each stock line. When the static pressure in the stock collection pipe is substantially the same at both ends of the stock collection pipe, this dimensioning of the taper of the stock collection pipe will result in the velocity of the stock at the upstream end of the stock lines being equal to with the speed of the stock in the stock collection tube. The inventors have found that when the velocity of the stock in the upstream end of a stock line is equal to the speed of the stock in the stock collection tube and more particularly, when the speed of the stock in the stock line at the point where a diluent is fed into the stock is equal to the speed of the stock in the stock head, the feeding of a diluent into the stock will have a relatively small effect on the resulting total flow of diluted stock so that variations in the volume flow of a diluent fed into the volume flow of stock will only cause negligible variations. in the total volume flow of diluted stock.

The stock lines connected to a diluent line advantageously comprise a throttle valve which is arranged at a point downstream of the connection between the stock line and the diluent line in order to generate turbulence and thereby ensure that the stock and the diluent is mixed correctly with each other. To further ensure a good mixture between the stock and the diluent, the stock lines are given such a length that friction losses in the lines will cause further turbulence.

All stock pipes preferably comprise flexible hoses, which allow the stock pipe to be placed in many different places in relation to the headbox and thereby it is possible to install the device with great ease.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic side view of a headbox with a device for feeding stock to the headbox.

Fig. 2 is a schematic top view of the headbox and part of the stock feeding device shown in Fig. 1.

Fig. 3 is a cross-sectional view through a stock collection pipe showing in more detail the stock collection pipe, an outlet from the stock collection pipe and the connection between a stock collection line and a diluent line.

Fig. 4 is a cross-sectional view taken on the line IV-IV in Fig. 1.

Fig. 5 is a view similar to Fig. 3 and shows in more detail some of the elements found in Fig. 3.

Fig. 6 is a schematic top view showing in more detail some of the elements shown in Fig. 3. 506 322 10 15 20 25 30 35 12 DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to Fig. 1 and Fig. 2, there is shown an inlet drawer with a device for feeding stock to the headbox. A headbox, generally designated 1, is supplied with stock with a device 2 for feeding stock to the headbox. The device for feeding stock to the headbox comprises at least one stock collection pipe 3a, 3b, 3c for feeding stock to an inlet end of the headbox. Fig. 1 shows three stock collection pipes 3a, 3b, 3c in a device for feeding stock to a three-layer headbox. In this case, each stock collection tube is arranged to supply stock which is intended only for one of the three layers of the web produced by the paper machine using the three-layer headbox.

Each stock collection pipe 3a, 3b, 3c has an inlet 4 for receiving stock to the collection pipe and a plurality of outlets 5 of the stock collection pipes which allow stock to leave the collection pipe and enter an upstream end 10, 11, 12 of a plurality of stock lines 7. , 8, 9, each of which is connected to an outlet 5 of the stock collection pipe. Each outlet 5 of the stock collection pipe is thus connected to the inlet end 6 of the headbox by means of a line 7, 8, 9 which is located downstream of the outlet of the stock collection pipe, which lines 7, 8, 9 allow stock to be carried from the outlet of the stock collection pipes, through the stock collection pipes. to the inlet end 6 of the inlet drawer 1, and the outlet 5 of the stock collection pipe 3a, 3b, 3c is thereby connected to the inlet end of the inlet drawer 1 so that stock can be led from the stock collection pipe 3a, 3b, 3c, through the stock line 7, 8, 9 to the inlet end Each stock line 7, 8, 9 has an upstream end 10, 11, 12 which is connected to an outlet 5 of a stock collection pipe and a downstream end 14, 15, 16 which is connected to or adapted to be attached to the inlet end 6 of the headbox. . The upstream end of each stock line has an intended general direction of the stock flow from the outlet 5 of the stock collection pipe towards the inlet end 6 of the inlet drawer and each upstream end 10, 11, 12 of a stock line 7, 8, 9 have a cross-sectional area A3 which is perpendicular to the intended general flow direction through the upstream end 10, 11, 12 of the stock line 7, 8, 9 and which cross-sectional area is equal to the cross-sectional area of the outlet 5 of the stock collection pipe. The conduits 7, 8, 9 comprise pipes or pipe elements 17, 18, 19, which have an inner wall delimiting a channel for passage therethrough of stock or diluted stock. Each pipe or pipe element 17, 18, 19 has an upstream end 20, 21, 22 and a downstream end 23, 24, 25. The pipes or pipe elements are all advantageously flexible hoses which have a length of at least A 2 meters. The fact that the stock collection pipes 3a, 3b, 3c are all connected to the headbox 1 by means of flexible hoses 17, 18, 19 ensures that the stock collection pipes 3a, 3b, 3c can be easily installed in a large number of different positions relative to the headbox 1. Since they bend If the hoses 17, 18, 19 have a length of at least 2 meters, considerable pressure losses will occur during the passage of the diluted stock therethrough, which in turn will cause turbulence which ensures a good mixture of the stock and the diluent. The length of the hoses 17, 18, 19 also contributes to a simple installation of the stock collection pipes 3a, 3b, 3c with a number of different positions in relation to the inlet drawer 1. With reference to Fig. 3, each stock line 7, 8, 9 comprises at its upstream end a tubular coupling 26, which tubular coupling 26 has an upstream end 27, which is connected to the outlet 5 of the stock collection pipe 3a, 3b, 3c, and a downstream end 28, which is connected to an associated tubular element 17 Fig. 3 shows the tubular coupling 26 as made of three elements 26a, 26b and 26c, where the element 26a is located at the upstream end 27 of the tubular coupling 26 and fixed to the wall 29 of the stock assembly. the pipe 3a, 3b, 3c at the outlet 5 of the stock collection pipe 506 322 10 15 20 25 30 35 14. The element 26c is located at the downstream end 28 of the coupling 26 and connects the coupling 26 to an associated tubular element 17, 18, 19. The element 26b is an intermediate element between the elements 26a and 26c and connects the elements 26a and 26c to each other.

The element 26b may be adapted to be connected to the downstream end of a conduit for feeding a diluent into the stock passing through the stock line. For this purpose, the intermediate coupling 26b is made as a T-connection.

Referring to Fig. 1 and Fig. 2, there is shown a dilution manifold 30. The diluent manifold 30 has an inlet 31 for introducing a diluent into the diluent manifold 30 and a plurality of outlets 32 allowing the diluent to exit the diluent manifold 30.

The dilution collection pipe 30 is intended to supply a diluent to a plurality of stock lines 7, 8, 9, which connect the outlets of a stock collection pipe 3a, 3b, 3c to the inlet end 6 of the headbox. For each outlet 32 of the diluent manifold there is a diluent line 33 downstream of the diluent manifold outlet 32 which allows a diluent to pass from the diluent outlet 32 of the diluent manifold 33 to one of the stock lines 7, 8, 9 downstream, in the stock passing through the stock line 7, 8, 9. each of said diluent lines 33 has an upstream end 34 which is connected to an outlet 32 of the dilution manifold and a downstream end 35 which is connected to one of the stock lines 7, 8, 9 via a connection 26b at the upstream end 10, 11, 12 of the stock line 7, 8, 9. The connection is preferably in the form of a T-connection 26b. According to the invention, the downstream end 35 of each diluent line is connected to the upstream end 10, 11, 12 of a stock line 7, 8, 9 at a place immediately downstream of the outlet 5 belonging to the special. 596 322 separate stock line so that the diluent can pass from the dilution manifold 30 through the diluent line 33 and into the stock line 7, 8, 9 at a location immediately downstream of the outlet 5 from the stock collection pipe 3a, 3b, 3o.

The term "immediately downstream" shall not be construed in connection with this application as meaning that the distance between the outlet of the stock collection pipe and the connection between the diluent line and the stock line 7, 8, 9 is necessarily zero. In practice, a certain distance is usually needed between said connection and the outlet of the stock collection pipe. However, this distance should be kept as small as possible and not exceed 0.15 meters. It is also possible to describe the connection between the diluent line 33 and the stock line 7, 8, 9 as being located downstream of the outlet 5 of the stock collection pipe and with a distance adjacent to the outlet of the stock collection pipe.

The pressure loss which thereby occurs in the stock line between the outlet 5 from the stock collection pipe 3a, 3b, 3c and the connection between the stock line 7, 8, 9 and the diluent line 33 will be kept low and not exceed 1 KPa. With a pressure in the stock collection pipe 3 of the order of approximately 300 KPa, the pressure at the point where a diluent is fed into the stock line 7, 8, 9 will therefore be the same or only a small fraction less than the pressure in the stock collection pipe 3a, 3b, 3c. . This means that variations in the flow of diluent will not be able to affect the total volume flow of the diluted stock flowing through the stock line 7, 8, 9.

Referring to Fig. 1, each diluent conduit 33 comprises a tube 36 through which the diluent is intended to flow, said conduit 36 having an upstream end 36a located adjacent an associated outlet of the dilution manifold and a downstream end 35 which is connected to and discharged to the upstream end of a stock line so that a diluent can flow through the tube into a flow of stock passing through the stock line. The diluent line 33 also comprises a valve member 37 upstream of the tube 36 and downstream of the associated outlet of the dilution manifold. The valve means 37 has a channel, through which the diluent is intended to flow from the dilution collection pipe to the pipe, which valve means thereby forms a connection between the outlet of the dilution collection pipe and the pipe. The channel of the valve member 37 has a cross-sectional area which is variable in a manner which is well known so that the flow of diluent through the valve member 37 to the pipe can be varied as required. For this purpose there is an actuator 38 for each valve means 37, the actuator 38 being arranged to vary a flow of diluent from the dilution manifold 3b to the stock line 8 by varying the cross-sectional area of the channel through which the diluent is intended to flow.

Each actuator 38 will increase or decrease the flow of diluent through the diluent line 8 in response to signals from a central unit (not shown) such as a computer, the signals from the actuators passing through, for example, a line denoted by the numeral 39 in FIG. 2. During operation of the paper machine, a scanning unit (not shown) located at a location downstream of the headbox 1 will monitor any variations in the properties of the paper web across the machine direction. When such irregularities are detected, a signal will be sent to the central unit, which in turn emits a signal to one or more of the actuators. In response, the actuator or actuators 38 will act to reduce or increase a flow of diluent at one or more locations so that a paper web with uniform properties will be obtained.

According to the invention, it is also important that the speed of the stock in the upstream end of the stock lines is equal to the speed of the stock in the stock collection pipe. The inventors have found that when the velocity of the stock, which flows through each outlet 5 of the stock collection pipe and the upstream end 10, 11, 12 of each stock line 7, 8, 9, is equal to the speed of the stock in the stock collection tube 3a, 3b, 3c, variations in a volume flow of a diluent fed into the volume flow of the stock will have less ability to cause variations in the total volume flow of diluted stock.

The reason for this is not fully understood, but experiments and flow simulations performed by the inventors have confirmed that this is the case. The device for feeding stock to a headbox is therefore designed in such a way that the speed of the stock flowing through the outlets 5 of the stock collection pipes and the upstream end 10, 11, 12 of the stock lines 7, 8, 9 can be made equal to the speed of the stock. in the inlet box 3a, 3b, 3c.

Referring to Fig. 3 and Fig. 6, the stock collection tube 3a, 3b, 3c has a first end 40 and a second end 41 and has a longitudinal extension from the first end 40 to the second end 41, where the inlet 4 to the stock The stock tube, which allows stock to enter the stock collection tube 3a, 3b, 3c from a pressurized stock of stock, is located at the first end 40 of the stock collection tube 3a, 3b, 3c. A recirculation outlet 42 is located at the other end 41 of the stock collection tube which allows stock to leave the stock collection tube and enter a recirculation line 43, through which approximately 5% of the stock is recycled. A recirculation valve means 44 is located at the recirculation outlet 42 or immediately downstream of the recirculation outlet inside the recirculation line 43, which valve means can be adjusted to allow regulation of the static pressure at the other end 41 of the stock collection tube 3a. 3b, 3c. During the operation of the stock for feeding stock, stock will flow from the first end 40 of the stock collection tube 3a, 3b, 3c to the second end 41 of the stock collection tube, while at each outlet 5 of the stock collection tube. part of the stock will leave the collection pipe via the outlet 5 of the stock collection pipe. The outlets 5 of the stock collection tube are of course located in a row from the first end 40 of the stock collection tube to the second end 41 of the stock collection tube and the outlets 5 of the stock collection tubes are arranged at uniform distances from each other. The outlets of the stock collection pipe all have a cross-sectional area A3 which is equal for all outlets 5 of the stock collection pipe. The stock will thus have a general flow direction from the first end 40 of the stock collection tube 3a, 3b, 3c to the second end 41 of the stock collection tube 3a, 3b, 3c in such a way that the stock collection tube can be described as having an intended general flow direction of the stock from the first end 40 of the stock collection tube to the second end 41 of the stock collection tube and the stock flowing through the stock collection tube will have a velocity. When the stock flows through the stock collection tube 3a, 3b, 3c, measures are taken to ensure that the velocity of the stock remains substantially constant from the first end 40 of the stock collection tube to the second end 41 of the stock collection tube 3a, 3b, 3c. This can be achieved by setting the valve means 44 at the outlet 42 for recirculation in such a way that the static pressure at the second end 41 of the stock collection pipe 3a, 3b, 3c is equal to the static pressure at the first end 40 of the stock collection pipe. By using Bernoulli's equation one can show that if the static pressure is the same at both the first end 40 of the stock collection tube 3a, 3b, 3c and the second end 41 of the stock collection tube 3a, 3b, 3c and about the pressure losses due to friction in If the stock collection tube is small enough to be ignored, the velocity of the stock will be substantially unchanged from the first end 40 of the stock collection tube to the second end 41 of the stock collection tube. Referring to Fig. 6, the stock collection tube has a cross-sectional area in a plane perpendicular to the intended general flow direction of the stock through the stock collection tube. The stock collection tube 3a, 3b, 3c tapers so that the cross-sectional area of the stock collection tube decreases from the first end 40 of the stock collection tube to the second end 41 of the stock collection tube 3a, 3b, 3c. As shown in Fig. 6, at the point where one of the outlets 5 of the stock collection pipe is located, the stock collection pipe has a first cross-sectional area A1 and at the following outlet 5 of the stock collection pipe a second cross-sectional area A2 which is smaller than the first cross-sectional area A1. Each outlet 5 of the stock collection pipe and the upstream end 10, 11, 12 of its associated stock line 7, 8, 9 has a cross-sectional area A3, which is perpendicular to the general flow direction of 12 of the stock line 7, 8, 9. Along the length of the stock collection tube stock through the upstream end 10, 11, 3a, 3b, 3c is the taper of the stock collection tube 3a, 3b, 3c from the first end 40 of the stock collection tube to the second end 41 of the stock collection tube such that A1-A2 = A3. In other words, between each two adjacent outlets 5 of the stock collection tube, the cross-sectional area of the stock collection tube 3a, 3b, 3c is reduced, and the decrease in cross-sectional area is equal to the cross-sectional area of each outlet 5 of the stock collection tube which in turn is equal to the cross-section upstream end 10, ll, 12 of each stock line 7, 8, 9.

By analyzing the flows in the stock collection tube 3a, 3b, 3c and the stock collection lines 7, 8, 9, it can be shown that if the velocity of the stock flowing from the first end 40 of the stock collection tube 3a, 3b, 3c to the second end 41 of the stock collection tube is substantially constant and if the cross-sectional area of each outlet 5 of the stock collection pipe and the cross-sectional area of the upstream end 10, 11, 12 of each stock line 7, 8, 9 is equal to the decrease of the cross-sectional area of the stock collection pipe 506 322 10 15 20 25 30 35 Between each two adjacent outlets 5 of the stock collection tube, the velocity of the stock flowing through the upstream end 10, 11, 12 of each stock line 7, 8, 9 will be substantially equal to the velocity of the stock in the stock collection tube. when the stock flows from the first end 40 of the stock collection tube 3a, 3b, 3c to the second end 41 of the stock collection tube. It should be noted that the term "equal to" is to be understood as meaning "equal in size", since the velocity of the stock flowing through the stock collection tube 3a, 3b, 3c will have a direction which is substantially normal to the direction. the velocity of the stock flowing through the upstream end 10, 11, 12 of a stock line 7, 8, 9.

Thus, in order to achieve that a volume flow of a diluent can be fed into a volume flow of stock in such a way that variations in the size of the volume flow of the diluent will not cause variations in the resulting volume flow of dilute stock, the inventors have first found that the diluent should be fed into the stock at a location immediately downstream of the outlets 5 of the stock collection tubes or at a location downstream of the outlets 5 of the stock collection tube and at a distance near the outlets 5 of the stock collection tube and secondly that the stock collection tube 3a, 3b, 3c so designed that the velocity of the stock at the upstream end 10, 11, is equal to the velocity of the stock in the stock collection pipe 12 of the stock lines 7, 8, 9 being in main 3a, 3b, 3c. Each of these properties will itself contribute to the desired result. However, in the preferred embodiment of the invention, both of these properties are combined with each other and it is believed by the inventors that the combination of these properties has a synergistic effect so that they will reinforce each other. 10 15 20 25 30 35 506 322 21 When a diluent is fed into the flow of stock, it is important that the diluent will mix properly with the stock. As previously mentioned, the length of the tubular elements 17, 18, 19 will contribute to the achievement of a good mixture between the two liquids. In addition, the coupling 26 connecting the stock collection tube 3a, 3b, 3c to the tubular member 17, 18, 19 downstream of the stock collection tube 3a, 3b, 3c comprises a throttle valve 26d downstream of the connection 26b connecting the diluent line 33 to the stock line 7. 8, 9. The throttle valve 26d will cause turbulence in the flow of diluted stock, thereby ensuring that the diluent will mix well with the stock. Referring to Fig. 3 and Fig. 5, the throttle valve 26d is located in the downstream coupling member 26c and forms part thereof.

Fig. 5 also shows in more detail the connection between the downstream end 35 of a diluent line 33 and an upstream end 10, 11, 12 of a stock line.

As shown in Fig. 5, the intermediate member 26b of the coupling 26 is formed as a 90 ° T connection so that the member 26b has a longitudinal extent and a longitudinal axis in the general flow direction of the stock through the member 26b (from right to left in Figs. 5) and the member 26b comprises a short tubular member 26e extending across the longitudinal axis of the intermediate member 26b. The downstream end 35 of a diluent line 33 is connected to the short tubular member 26e so that a diluent can enter therethrough and into the stock line 7, 8, 9. The intermediate member 26b thereby forms a connection between the downstream end 35 of a diluent line 33 and an upstream end 10, 11, 12 of a stock line (7, 8, 9) - In a preferred embodiment of the invention three stock collection tubes 3a, 3b, 3c are used which allow stock to be fed to a multilayer headbox 1 of the type 226 designed to produce a fibrous web (not shown) having three layers. in this embodiment, each stock collection pipe 3a, 3b, 3c with its associated stock lines 7, 8, 9 downstream of the outlets 5 of the stock collection pipe is arranged to feed stock which is only intended for one of the three layers of the fibrous web. There is thus a first stock collection tube 3a, which together with its associated stock lines 9 is arranged to feed stock which is only intended for a first top layer of the fibrous web, a second stock collection tube 3b, which together with its associated stock lines 8, is arranged to feed stock which is intended only for a second middle layer of the fibrous web and a third stock collection pipe 3c, which together with its associated stock lines 7 is arranged to feed stock which is only intended for a third bottom layer of the fibrous web. In the preferred embodiment, the dilution collection tube is arranged to feed stock only to the stock lines 8 connected to the second stock collection tube 3b, which is arranged to feed stock intended only for the second middle layer of the fibrous web so that that a diluent can be fed only to the stock lines 8 through which the stock intended for the second middle layer of the fibrous web passes.

The properties of the web in the transverse direction of the machine will thus be regulated exclusively by regulating the consistency of the stock intended for the middle layer of the web.

Since control of the properties of the web is achieved only by controlling the amount of diluent fed to the stock intended for the second middle layer, it is important that fine adjustments for the middle layer can be made in sections of the headbox 1 which have a small extent in the transverse direction of the machine. . Therefore, the tubular elements 18 of the stock lines 8 connected to the second stock collection tube 3b, which are arranged to feed stock which is intended only for the second middle layer of the fibrous web, are , of larger number and smaller diameter than the tubular elements nos the stock lines 7, 9 which are connected to the first and third stock collection pipes 3a, 3c which are arranged to feed stock intended for the first top layer of the web and the third bottom layer of banana. Referring to Fig. 1, Fig. 3 and Fig. 4, the tubular elements 17, 18, 19 of the stock lines 7, 8, 9 connected to the outlets 5 of each stock collection pipe 3a, 3b, 3c constitute flexible hoses 17, 18, 19, which have an inner and an outer diameter, and all the flexible hoses 17, 19 of the stock lines 7, 9, which are connected to the outlets of the Å first and third stock collection pipes 3a, 3c, which are arranged to feed stock to the first and third layers of the fibrous web, have the same inner and outer diameters, and the flexible hoses 18 of the stock lines 8, which are connected to the outlets 5 of the second stock collection pipe 3b, which are arranged to feed ground to the second layer of the fibrous web, all have the same inner diameter and the same outer diameter. The inner diameter of the flexible hoses 18 of the stock lines 8, which are connected to the second stock collection pipe 3b, which is arranged to feed stock to the second layer of the fibrous web, is smaller than the inner diameter of the flexible hoses 17, 19 of the stock lines 7, 9, which are connected to the first and third stock collection pipes, which are arranged to feed stock to the first and third layers of the fibrous web.

Referring to Fig. 3 and Fig. 4, it can be seen that at the inlet end 6 of the headbox 1, the downstream end of each flexible hose 17, 18, 19 of the stock lines 7, 8, 9 is connected to the inlet end of the headbox at a connection point 45, 46, 47. The connection points 45 for the downstream end of the flexible hoses 19 of the stock lines 9 of the first stock collection pipe 3a are arranged in a straight horizontal row extending transversely to the machine direction so that at the inlet end 6 of the headbox 1, the downstream end of the flexible hoses 19 of the stock lines 9, which are connected to the first stock collection pipe, are arranged in a first straight row extending in the transverse direction of the machine. Similarly, the connection points 46 for the downstream end of the flexible hoses 18 of the stock lines 8 of the second stock collection pipe 3b are arranged in a straight horizontal row extending in the transverse direction of the machine so that at the inlet end 6 of the headbox 1 the downstream the end of the flexible hoses 18 of the stock lines 8, which are connected to the second stock collection pipe 3b, arranged in a second straight row extending across the machine direction. Similarly, the connection points 47 for the downstream ends of the flexible hoses 17 of the stock lines 7 of the third stock collection pipe 3c are arranged in a straight horizontal row extending across the machine direction so that at the inlet end 6 of the headbox 1 is the downstream end. of the flexible hoses 17 of the stock lines 7, which are connected to the third stock collection pipe 3c, arranged in a third straight row extending across the machine direction. The first, second and third rows are arranged vertically at a distance from each other with the first row placed vertically above the second and third rows, the second row placed vertically below the first row and vertically above the third row and the third the row placed vertically below the first and second rows.

As can be seen from Fig. 4, each of the above-mentioned first, second and third rows is arranged so that for each row the downstream ends of the flexible hoses 17, 18, 19 at the connection points 45, 46, 47 between the inlet end 6 of the headbox and the downstream end of the flexible hoses 17, 18, 19 arranged at a distance from each other across the machine direction. In each row, the downstream end of the flexible hoses 17, 18, 19 is arranged at an even distance from each other. The distance between the downstream end of the flexible hoses 18 in the second row, i.e. the flexible hoses 18 through which dilute stock passes are less than the distance between the downstream end of the flexible hoses 17, 19 in the first and third rows. The smaller distance between the downstream end of the flexible hoses 18 of the second row allows for fine adjustments of the stock consistency in sections which have a small extent across the machine direction. In practice, the distance between the connection points of the flexible hoses of the second row is approximately 50-70 mm and the inner diameter of the flexible hoses is approximately 45 mm.

The invention allows a volume flow of a diluent to be fed into a volume flow of dilute so that a resulting total volume flow of dilute stock will be constant regardless of variations in the volume flow of the diluent.

Thus, variations in the volume flow of the diluent occur. not to cause variations in the resulting total volume flow of dilute stock. The components can be manufactured in a simple manner and to a certain extent the invention can be easily applied to existing equipment. The invention also results in an excellent mixture of the diluent and the stock. In addition, the invention allows a simple installation of a device for feeding stock to a headbox, since the stock collection pipes can be placed in a number of different positions relative to the headbox thanks to the long flexible hoses used to connect the stock collection pipes to the headbox.

Claims (7)

Device (2) A device (2) for feeding stock to an inlet (1) of a paper machine, the device comprising: at least one stock collection tube (3a, 3b, 3c) of stock to an inlet end (6) of a headbox 3b, 3c) has an inlet (4) for introducing stock into the collection feed (1), which at least one stock collection pipe (3a, the pipe and a plurality of outlets (5) allows stock to leave the manifold (3a, 3b, 3c), a stock line (7, 8, 9) for each outlet (5) of the stock collection pipe, which stock line is located downstream of the outlet (5) of the stock collection pipe and allows stock to pass from the outlet (5) of the stock collection pipe (3a, 3b, 3c) via the stock line (7, 8, 9) to the inlet end (6) of the headbox, each stock line (7, 8, 9) having an upstream end (10, 11, 12) ) which is connected to the outlet (5) of the stock collection pipe and a downstream end (14, 15, the inlet end (6) of the inlet drawer so that thereby 16) which is adapted to be attached to a close the outlet (5) of the stock collection pipe (3a, 3b, 3c) to the inlet end (6) of the headbox (1) so that stock can pass from the stock collection pipe, through the stock line (7, 8, 9) to the inlet end (6) of the headbox, a dilution manifold (30) for feeding a diluent to a plurality of stock lines (7, 8, 9) connecting the outlets (5) of said at least one stock collection pipe (3a, 3b, 3c) to the inlet end (6) of the headbox (1), which diluent manifold (30) has an inlet (31) for introducing a diluent into the diluent manifold (30) and a plurality of outlets 10 d 20 2. 506 322 27 (32) which allow the diluent to leave diluent the diluent manifold (30), a diluent conduit (33) for each outlet (32) of the diluent manifold, which diluent conduit is located downstream of the diluent manifold outlet (32) and allows a diluent to pass from the diluent dilution manifold outlet (32) (33) to one of 8, 9) downstream s stock collection tube (3a, 3b, 3c) and into the stock as said plurality of stock lines (7, passing through the stock line (7, 8, 9), each of said diluent lines (33) having an upstream end (34 ) which is connected to an outlet (32) of the dilution manifold (30) and a downstream end (35) which is connected to one of the stock lines (7, 8, 9) of said plurality of stock lines (7). , 8, 9) through a connection at the upstream end (10, 11, 12) of the stock line (7, 8, 9) at a point downstream and at a close distance from or immediately downstream of the outlet (5) from the stock collection tube (3a, 3b, 3c) so that the diluent can pass from the dilution collection tube (30) through the diluent line (33) into the stock line (7, 8, 9) and thereby be fed into the stock at a location downstream and on a nearby distance from or immediately downstream of the outlet (5) from the stock collection pipe (3a, 3b, 3c). Device according to claim 1, wherein each of said stock lines (7, 8, 9), which are connected to the outlet (5) of a stock collection pipe (3a, 3b, 3c), comprises: a) a tubular element (17, 18 , 19), through which stock is intended to flow, which tubular element (17, 18, 19) has an upstream end (20, 21, 22) which is located near the stock collection pipe and a down 506 522 10 15 20 25 28 upstream end (23, 24, 25) located near the inlet of the headbox (1), b) a tubular coupling (26) at the upstream end of the stock line (7, 8, 9) which coupling has an upstream end (27) connected to the outlet (5) of the stock collection tube (3a, 3b, 3c) and a downstream end (28) connected to the upstream end (20, 21, 22) of the tubular member - tet (17, 18, 19), which forms part of the stock line (7, 8, 9), the tubular coupling (26) connecting the outlet of the stock collection pipe (3a, 3b, 3c) to the upstream end (20, 21, 22) of the said r ear-shaped elements (17, 18, 19) in such a way that stock can pass from the outlet (5) of the stock collection pipe through the tubular coupling (26) and into the tubular element (17, 18, 19). Device according to claim 2, wherein said tubular coupling (26) of the stock lines (7, 8, 9), which are connected to the downstream end (35) of a diluent line (33), has a connection (26b, 26e) , such as a T-joint (26b), which connects the downstream end (35) of said diluent line (33) to the tubular coupling (26) so that diluent can be fed from the diluent line (33) into the stock as the stock passes through the tubular coupling (26) from the outlet (5) of the stock collection tube to the tubular element (17, 18, 19) of the stock line (7, 8, 9). Device according to any one of the preceding claims, wherein all tubular elements (17, 18, 19) are flexible hoses having a length of not less than 2 meters. Device according to any one of the preceding claims, wherein each diluent line (33) for allowing a diluent to pass from an outlet (32) of one of the dilution tubes (30) to a stock line (30) 7, 8, 9) downstream of the stock collection pipe (3a, 3b, 3c) to allow stock to pass from the outlet (5) of the stock collection pipe (3a, 3b, 3c) to the inlet of the inlet drawer (1) comprising: a) b ) c) A tube (36) through which the diluent is intended to flow, said tube (36) having an upstream end located adjacent an outlet (32) of the dilution manifold and a downstream end connected to and discharging to the upstream located end of a stock line (7, 8, 9) so that a diluent can flow through the tube (36) into a flow of stock passing through the stock line (7, 8, 9), a valve means (37) upstream of said pipe and downstream said at least one outlet of the dilution manifold, said valve means (37) forming a connection between an outlet of the dilution manifold and the upstream end of said pipe, said valve means (37) having a channel through which the diluent is intended to flow from the dilution manifold to said tube, which channel has a variable cross-sectional area, an actuator (38) for said valve means (37), which actuator (38) is arranged to be able to vary a flow of diluent from the diluent manifold (30). ) geno m to vary the cross-sectional area of the channel through which the diluent is intended to flow. Device according to any one of the preceding claims, wherein the connections (26) connecting the outlets (5) of a stock collection pipe (3a, 3b, 3c) to the stock lines (7, 8, 9), which allow stock to pass from the outlets (5 ) of the stock collection pipes (3a, 3b, 3c) to the inlet side of the headbox (1) comprises a throttle valve (26d) downstream of the connection (26b) which connects a diluent line to the stock line (7, 8, 9). ) downstream of the stock collection pipe (3a, 3b, 3c) to allow stock to pass from the outlet of the stock collection pipe to the inlet of the headbox. A) b) Device according to any one of the preceding claims, wherein three stock collectors (3a, 3b, 3c) are used which allow stock to be fed to a multilayer headbox (1) of the type designed to produce a fibrous web which has three layers, and each stock collection pipe (3a, 3b, 3c) with its associated stock lines (7, 8, 9) downstream of the outlets (5) of the stock collection pipe is arranged to feed stock which is only intended for one of said three layers so that a first stock collection pipe (3a) together with its associated stock lines (9) is arranged to feed stock intended for a first top layer of the fibrous web, a second stock collection pipe (3b) together with its associated stock lines ( 8) is arranged to feed stock intended for a second middle layer of the fiber web and a third stock collection pipe (3c) together with its associated stock lines (7) is intended to feed stock intended for a third bottom layer of the fiber web, a dilution collection pipe ( 30) used which dilution manifold (30) has a plurality of outlets (32), each outlet (32) being connected to a pipe (36) for transferring diluent to a stock line (8), which is connected to the second stock pipe (3b), which is arranged to feed stock to the second middle layer of the fibrous web so that a diluent will only be fed to the stock lines (8) through which stock is passed which is intended for the second middle layer of the fiber web, C) d) 506 322 31 the tubular elements (17, 18, 19) of the stock lines (7, 8, 9) connected to the outlets of each stock collection pipe (3a, 3b, 3c) are flexible hoses having an inner and an outer diameter and wherein the flexible hoses (17, 19) of the stock lines (7, 9) connected to the outlets of the first and third stock collection pipes (3a, 3c), which are arranged to feed stock to the first and third layers of the fibrous web, all having the same inner diameter and the same outer diameter, and where they The shaft hoses (18) of the stock lines (8) connected to the outlets of the second stock collection pipe (3b) arranged to feed stock to the second middle layer have the same inner diameter and the same outer diameter, and where the inner diameter of the flexible hoses (18) of the stock lines (8) connected to said second stock collection pipe (3b) are smaller than the inner diameter of the flexible hoses (17, 19) of the stock lines (7, 9) which are connected to said first and third stock collection tubes (3a, 3c), and wherein the outer diameter of the flexible hoses (18) of the stock lines (8) connected to said second stock collection tubes (3b) is smaller than the the outer diameter of the flexible hoses (17, 19) of the stock lines (7, 9) connected to said first and third stock collection pipes (3a, 3b), the downstream end of the flexible hoses (19) of the stock lines (9) of said first stock collection pipe (3a) are connected at the inlet to the headbox (1) a to the headbox (1) at a connection point (45), the connection points (45) for the downstream ends of the flexible hoses (19) being arranged in a straight row extending transversely to the machine direction so that at the inlet end (6) ) of the headbox (1), the downstream 322 10 15 20 25 30 35 e) 32 is the downstream end of the flexible hoses (19) of the stock lines (9) connected to said first stock collection pipe (3a), arranged in a first straight row extending transversely to the machine direction, and where the downstream end of the flexible hoses (18) of the stock lines (8) connected to said second stock collection pipe (3b) are connected to the headbox (1) of a similar to the downstream end of the flexible hoses (19) of the stock lines (9) connected to said first stock collection pipe (3a) so that at the inlet end (6) of the headbox (1) they are arranged in a second straight row, which extends across the machine direction and the bottom the end of the flexible hoses (17) of the stock lines (7) connected to said third stock collection pipe (3c) are connected to the inlet end (6) of the headbox (1) in a manner similar to that of the downstream the end of the flexible hoses (19, 18) of the stock lines (9, 8) which are connected to said first and second stock collection pipes (3a, 3b) so that at the inlet end (6) of the headbox (1) they are arranged in a third straight row extending across the machine direction, the first, second and third rows being arranged vertically at a distance from each other with the first row placed vertically above the second and third rows, the second row placed vertically below the first row and vertically above the third row and the third row is placed vertically below the first and second rows, at each of said first, second and third rows the downstream end of the flexible hoses (17, 18, 19) are arranged at the connection point a (45, 46, 47) between the inlet of the headbox (1) and the downstream end of the flexible hoses (17, 18, 19) spaced apart across the machine box a) 50-6 2, 2 33 33, the downstream end of the flexible hoses (17) in the first row being arranged at equal distances from each other, the downstream end of the flexible hoses (18) in the second row being arranged at an equal distance from each other which is less than the distance between the downstream end of the flexible hoses (19) in the first row and the downstream end of the flexible hoses (17) in the third row are arranged on even surfaces distances greater than the distance between the downstream end of the flexible hoses (18) in the second row. Device (2) for feeding stock to an inlet (1) in a paper machine, wherein the device comprises: at least one stock collection pipe (3a, 3b, 3c) for feeding stock to an inlet end (6) of a headbox (1), which at least one stock collection pipe (3a, 3b, 3c) has a first end (40) and a second end (41) and a longitudinal extension from the first end (40) to the second end (41), an inlet (4) which is located at the first end (40) for introducing stock into the manifold (3a, 3b, 3c) and a plurality of outlets (5) of the stock collection pipe which allow stock to leave the collection pipe (3a, 3b, 3c) and be introduced into an upstream end (10, 11, 12) of a plurality of stock lines (7, 8, 9), each of which is connected to an outlet (5) of the stock collection pipe and which stock lines (7, 8, 9) lead to an inlet end (6) of the stock box (1), a circulation outlet (42) being located at the other end (41) of the stock collection tube (3a, 3b, 3c) which allows stock to leave the stock collection tube (3a, 3b, 3). c) and is inserted into a circulation line (43), a circulation valve means (44) located at the circulation outlet 506 522 10 15 20 25 30 35 b) 34 (42), which allows regulation of the static pressure at the other end (41) of the stock collection tube (3a, 3b, 3c), which outlets (5) of the stock collection tube are located in a row from the first end (40) of the stock collection tube (3a, 3b, 3c) to the second end (41) of the stock collection tube (3a, 3b, 3c) and the outlets (5) of the stock collection pipe are arranged at equal distances from each other, and the outlets (5) of the stock collection pipe have a cross-sectional area (A3) which is equal for all outlets (5) of the stock collection pipe, which stock collection tubes (3a, 3b, 3c) further have an intended general flow direction for the stock through the stock collection tube (3a, 3b, 3c) from the first end (40) of the stock collection tube (3a, 3b, 3c) to the second end (41) of the stock collection tube (3a, 3b, 3c), the stock collection tube (3a, 3b, 3c) further having a cross-sectional area in a plane which is angular. further to the general flow direction of the stock in the stock collection tube (3a, 3b, 3c) and the stock collection tube (3a, 3b, 3c) is further tapered in such a way that the cross-sectional area of the stock collection tube decreases from the first end (40) of the stock collection tube (3a, 3b, 3c) to the other end (41) of the stock collection tube (3a, 3b, 3c) so that between two adjacent outlets (5) of the stock collection tube the cross-sectional area of the stock collection tube is reduced and where the reduction (A1-A2) of the cross-sectional area of the stock collection tube (3a, 3b, 3c) between two adjacent outlets (5) of the stock collection tube is equal to the cross-sectional area (A3) of the outlets (5) of the stock collection tube and the upstream end (10, 11, 12) of the stock lines (7, 8, 9), a stock line (7, 8, 9) for each outlet (5) of the stock collection pipe, which stock line is located downstream of the outlet (5) of the stock collection pipe and allows stock to pass from the outlet ( 5) in 10 15 20 25 30 35 c) d) 50-62 322 35 stock collection tube (3a, 3b, 3c) g through the stock line (7, 8, 9) to the inlet end (6) of the headbox (1), each stock line (7, 8, 9) having an upstream end (10, 11, 12) connected to the outlet (5) of the stock collection tube and a downstream end (14, 15, 16) adapted to be attached to the inlet end (6) of the headbox (1) for therein "by connecting the outlet (5) of the stock collection tube (3a, 3b, 3c) to the inlet end ( 6) of the headbox (1) so that stock can pass from the stock collection pipe (3a, 3b, 3c), through the stock line (7, 8, 9) to the inlet end (6) of the headbox (1), the upstream end (10, ll, 12) of each stock line (7, 8, 9) has a intended general flow direction for the stock from the outlet (5) of the stock collection pipe towards the inlet end (6) of the headbox (1) and each upstream end (10 , ll, 12) of a stock line (7, 8, 9) has a cross-sectional area (A3) which is perpendicular to the intended general flow direction through the upstream end (10, 11, 12) of the stock line (7, 8, 9) o ch which is equal to the cross-sectional area (A3) of the outlet (5) of the stock collection pipe, a dilution collection pipe (30) for supplying a diluent to a plurality of stock lines (7, 8, 9) connecting the outlets (5) of the at least one stock manifold (3a, 3b, 3c) to the inlet end (6) of the headbox (1), said dilution manifold (30) having an inlet (31) for introducing a diluent into the dilution manifold (30) and a plurality of outlets (32) allowing that the diluent can leave the diluent manifold (30), a diluent conduit (33) for each outlet (32) of the diluent manifold, which diluent conduit is located downstream of the outlet (32) of the diluent manifold and allows a diluent to 506 322 36 passing from the dilution collection pipe outlet (32) through the diluent line (33) to one of said plurality of stock lines (7, 8, 9) downstream of the stock collection pipe (3a, 3b, 3c) and into a flow of 9), each of the said majority of diluent joints passing through the stock line (7, 8, nings (33) has an upstream end (34) connected to an outlet (32) of the dilution manifold (30) and a downstream end (35) connected to one of the stock lines (7, 8, 9) of said plurality of stock lines (7, 8, 9) through a connection (26b, 26e) at the upstream end (10, 11, 12) of the stock line (7, 8, 9). Device according to claim 8, wherein each diluent line (33) is connected to the upstream end (10, 11, 12) of a stock line (7, 8, 9) at a location immediately downstream of the outlet (5) of the stock collection pipe, to which outlet the stock line (7, 8, 9) is connected or at a place downstream and at a close distance from the outlet (5).