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Title:
METHOD AND EQUIPMENT FOR PULP FRACTIONATION IN A PAPER OR BOARD MACHINE
Document Type and Number:
WIPO Patent Application WO/2002/022947
Kind Code:
A1
Abstract:
The invention concerns a method and equipment for pulp fractionation in a paper or board machine. In the method, virgin stock is conducted to the paper or board machine and further to a centrifugal cleaner installation (12) into its first centrifugal cleaner step (12a¿1?). From the first centrifugal cleaner step (12a¿1?) the accept is conducted into a multi-layer headbox (10) to form a layer of the web determined according to the concerned fraction. From a second step (12a¿2?) and/or from lower steps (12a¿3?, 12a¿4?... 12a¿n?) of the centrifugal cleaner installation (12) a second fraction or more fractions are conducted into the multi-layer headbox (10) to form a second layer or other layers of the web, which are determined according to the pulp fractionation taking place in the concerned second step or lower steps.

Inventors:
KOKKONEN KARI (FI)
Application Number:
PCT/FI2001/000791
Publication Date:
March 21, 2002
Filing Date:
September 12, 2001
Export Citation:
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Assignee:
METSO PAPER INC (FI)
KOKKONEN KARI (FI)
International Classes:
D21D5/24; D21D5/26; D21F1/02; D21F1/66; D21F1/68; (IPC1-7): D21F1/66; D21D5/24; D21D5/26; D21F11/00
Domestic Patent References:
WO2001029311A12001-04-26
Foreign References:
DE19526205A11997-01-30
EP1091040A22001-04-11
US5746889A1998-05-05
US4781793A1988-11-01
Attorney, Agent or Firm:
FORSSÉN & SALOMAA OY (Eerinkikatu 2 Helsinki, FI)
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Claims:
Claims
1. Method for fractionation of pulp in a paper or board machine, whereby in the method virgin stock is conducted to the paper or board machine and further to the first centrifugal cleaner step (12ai) of a centrifugal cleaner installation (12), characterised in that in the method the accept is conducted from the first centrifugal cleaner step (12al) into a multilayer headbox (10) to form a layer of the web determined by the fractionation in question, and that a second fraction or more fractions are conducted from a second step (12a2) and/or from lower steps (12a3,12a4... 12an) of the centrifugal cleaner installation (12) into the multilayer headbox (10) to form a second layer or other layers of the web, which are determined based on the fractionation taking place in the concerned second step or lower steps.
2. Method according to claim 1, characterised in that in the method the accept is conducted from the first step (12al) of the centrifugal cleaner installation (12) into the multilayer headbox (10), which forms the top or bottom layer of a threelayer web, and that the accept is conducted from the second step (12a2) of the centrifu gal cleaner installation (12) into the multilayer headbox (10), which will form the middle layer of the threelayer web.
3. Method according to claim 1 or 2, characterised in that the reject of the first step (12al) of the. centrifugal cleaner installation (12) is conducted at least partly into a fitting (b2, bs) as supply for the second step of the centrifugal cleaner installation (12).
4. Method according to any one of the preceding claims, characterised in that in the method a deaeration tank (11) is used, which is formed of several sections, whereby there is a separate supply and discharge fitting (al, a2 ; a3, a4) to the said deaeration tank for each fraction.
5. Method according to claim 1, characterised in that the water removed from the wire section is conducted into a wire pit (13), from which the tail water is pumped into the deaeration tank (11) and thence the tail water is conducted forward to the virgin stock mixing point and further into the centrifugal cleaner installation (12).
6. Method according to any one of the preceding claims, characterised in that in the method the final fractionation result is finished in a power screen (14al, 14a2, 14a3) fitted in a fitting (a2', a2", a4) in between the deaeration tank and the multi layer headbox, and the accept of the power screen is conducted as supply into the bypass manifold (J1, J2, J3) of the concerned layer in the multilayer headbox, and the reject is conducted back through the wire pit (13) into the centrifugal cleaner installation (12).
7. Equipment for fractionation of pulp in a paper or board machine, characterised in that the equipment includes means for feeding virgin stock to the tail water, a centrifugal cleaner installation (12) and a multilayer headbox (10), whereby there is a fitting (bl, bl') for the virgin stock admixed with the tail water to the first step (12al) of the centrifugal cleaner installation (12) to conduct the virgin stock admixed with the tail water to the first step (12ai) of the centrifugal cleaner installation (12) as supply, and that from the first step (12ai) of the centrifugal cleaner installation (12) there is a fitting (al) for the accept of the first step (12ai) while the concerned pulp fraction is supplied to the multilayer headbox (10) to form a certain layer of the web, and that the equipment includes at least one other fitting (a3) from the second step (12a2) and/or from some lower step/steps (12a3, 12a4...) of the centrifugal cleaner installation (12) to the multilayer headbox (10) to form a second layer or other layers of the multilayer web.
8. Equipment according to the preceding claim, characterised in that the fitting for accept of the first step of the centrifugal cleaner installation (12) is conducted to the deaeration tank (11), and the fitting (a2) leading out of the deaeration tank (11), along which fitting the accept of the first step (12al) of the centrifugal cleaner installation (12) is moved, is branched off into branch fittings (a2', a2"), which further join with bypass manifolds (Jl, J3) of the multilayer headbox (10) to form the top and bottom layers of the web.
9. Equipment according to claim 7 or 8, characterised in that the equipment includes a fitting (a3) for the accept from the second step (12a2) of the centrifugal cleaner installation (12) to the deaeration tank (11) and thence further through a fitting (a4) into the respective bypass manifold (J2) of the multilayer headbox (10).
10. Equipment according to any one of the preceding claims, characterised in that the fitting (a2', a2" ; a4) between the deaeration tank (11) and the multilayer headbox (10) includes a power screen (14al, 14a2, 14a3), which is used for finishing of the pulp fractionation.
11. Equipment according to any one of the preceding claims, characterised in that from the power screen (14al, 14a2, 14a3) there is a return fitting (fi, f2, f3) for the reject into the wire pit (13).
12. Equipment according to any one of claims 711, characterised in that the deaeration tank (11) is in many sections including a section (llal, lla2) for each pulp fraction and a separate inlet fitting (al, as) conducted from the centrifugal cleaner installation (12) into section (llal, lla2) and a separate outlet fitting (a2, a4) from section (llal, lla2), and that from the deaeration tank (11) there is a return fitting (g) for overflow back to the wire pit (13).
13. Equipment according to claim 7, characterised in that the tail water is conducted from the tail water tank (13) along a fitting (bl) into the deaeration tank (11), where air is removed from the tail water, and after the deaeration tank (11) the tail water is admixed with virgin stock into a fitting (bl'), whereupon the pulp is conducted to the centrifugal cleaner installation (12), into its first step (12al), from which there is a fitting (ai, ai', al") for the accept to the multilayer headbox (10) to form a certain layer in the multilayer web, and that from the first step (12al) the reject is conducted into the second step (12a2) of the centrifugal cleaner installation (12) and that from the second step or lower steps of the centrifugal cleaner installation there is a fitting/fittings for the accept/accepts to the multi layer headbox (10) to form a second layer or other layers of the multilayer web.
Description:
Method and equipment for pulp fractionation in a paper or board machine

The invention concerns a method and equipment for pulp fractionation in a paper machine or such, such as a board machine Multi-layer headboxes are already in use with many board grades and they are also on their way to printing paper machines. Layering has traditionally been done by layering the supply of either filler or retention agents. It is a weakness of this system that the pulp itself is entirely similar in all layers, so the drainability, fibre content and quantities of fines in the layers are not different. This of course limits the efficiency of layering.

Alternatively with e. g. tissue or board machines the different raw material components, such as short and long fibre, are treated separately from each other all the way from pulp treatment to the headbox. In such a system a double pulp system must of course be built all the way from pulp treatment to the paper machine.

Fractionation plants are used also in the production of pulp. Pressurized screens are generally used in the fractionation, and the fractionation is performed already at the pulp plant. In this case too a double pulp system must be built for the paper machine.

In the system according to the invention, the pulp is brought mixed into the short circulation of the paper machine. For example, in a machine using 100 % recycled fibre, there is only one raw material, whereby pulp layering without fractionation cannot be done at all.

The centrifugal cleaners traditionally used in the short circulation of the paper

machine have been used only to separate sand. The centrifugal cleaner installation separates pulp e. g. according to its density, size, shape and surface roughness. In the system according to the invention, the fractionation done by centrifugal cleaners is utilised in such a way that the accept of a certain centrifugal cleaner is conducted into a certain bypass manifold of the multi-layer headbox to form a certain web layer. In the system according to the invention, the fractionation ability of centrifugal cleaners is utilised e. g. in such a way that the fraction having more fines or long fibres is guided into the bottom and/or surface layer of the headbox.

In the first step of centrifugal cleaning, the pulp is divided roughly in a suitable proportion between the various layers. The final fine control of proportioning takes place only at the pump of the headbox. Surplus of pulp is circulated back to the input of the centrifugal cleaner.

Compared with filler layering, the quality of the pulp itself in the various layers can also be varied, and desired fibre fractions can be guided either to the surface or into the middle layer as required.

There is no need for any separate pulp systems before the centrifugal cleaners, but all pulp is brought in only one line all the way to the short circulation.

The equipment already in the short circulation is utilised and there is no need for any new partial processes. Only the operation of step 1 of the centrifugal cleaning is changed in such a way that the so-called reject ratio will correspond with the quantity of fibres needed in the various layers.

According to the invention, the pulp is conducted from the wire pit to the centrifugal cleaner, and from the first stage, that is, from step 1, of the centrifugal cleaner installation the pulp is conducted forward, in one embodiment of the invention into a deaeration tank, the reject of step 1 is conducted further into the

second stage of the centrifugal cleaner installation and thence the accept is conducted forward into the second part of the deaeration tank.

An advantageous embodiment of the invention is as follows. The accept arrived from the first stage of centrifugal cleaning into the deaeration tank is conducted from the deaeration tank into the part of the headbox forming the bottom and surface layers of the web, preferably through power screens. The pulp conducted as accept from the second stage, that is, from step 2, of the centrifugal cleaner into the deaeration tank is conducted through a power screen located in between the deaeration tank and the headbox into the bypass manifold of the headbox, through which bypass manifold the pulp is conducted on to the formation wire to form the middle layer of the web.

Thus, in fractionation according to the invention, the centrifugal cleaner installa- tion is utilised and the fractionation is carried out from various stages of the centrifugal cleaner installation in such a way that the pulp conducted from the first stage into the deaeration tank is conducted further after deaeration to form top layers of the web, and the pulp conducted as accept from the second stage or from other stages is moved further from the concerned stage/stages of the centrifugal cleaner installation to form other layers of the web, such as the middle layer of a three-layer web. However, it is not a purpose to limit the invention to the manner of forming a three-layer web described above. With the equipment according to the invention it is also possible to form two-layer paper or paper or board grades having even more layers instead of three-layer paper.

The system thus utilises a centrifugal cleaner installation and its fractionation in the making of multi-layer paper. The system may be applied to such short circulations already in use, which include a centrifugal cleaner. One stock is conducted into short circulation and it is treated in such a way in the centrifugal cleaner installation that the desired fraction can be conducted further through a deaeration tank to the multi-layer headbox into the pulp bypass manifold

corresponding with each layer. In the system according to the invention, a power screen may also be used in between the deaeration tank and the headbox in order to achieve the final fractionation result. Such an embodiment is also possible within the scope of the invention, where there is no deaeration from the pulp. In a system where there is no deaeration from the pulp, the accepts of centrifugal cleaning may be taken directly to the suction side of the headbox's feed pump. In other respects the structure of the system is similar to the one in the embodiment shown in Figure 1.

Such an embodiment may also be possible within the scope of the invention, wherein water leaving the wire section is conducted into the wire pit, from which wire pit the tail water is pumped into the deaeration tank and harmful air is removed from the tail water in the deaeration tank. Then the tail water is admixed with high-consistency pulp, which is conducted further into the centrifugal cleaner installation and further according to the invention from the centrifugal cleaner installation to the multi-layer headbox.

In an embodiment containing a deaeration tank this is preferably in two parts.

From the deaeration tank there are discharge fittings for each desired fraction. The pulp fraction can then be branched off to form several layers or conducted without branching in order to form one layer containing the concerned fraction.

The method and equipment for pulp fractionation according to the invention are characterised by the features defined in the claims.

In the following, the invention will be described with reference to the embodi- ments in the appended figures, but the intention is not to limit the invention to these only.

Figure 1 is a schematic view of the fractionation system according to the inven- tion.

Figure 2A is a schematic side view of the centrifugal cleaner of the first step of the centrifugal cleaner installation.

Figure 2B is a sectional view along line I-I in Figure 2A.

Figure 3 shows a second advantageous embodiment of the invention, wherein tail water is conducted into a deaeration tank and then virgin stock is admixed with the flow conducted from the deaeration tank, and the flow is conducted further into the centrifugal cleaner installation and through this according to the invention to the multi-layer headbox.

Figure 1 shows schematically the equipment according to the invention for pulp fractionation. The equipment includes a multi-layer headbox 10 and a deaeration tank 11, which is preferably in many sections, being a two-section tank in this embodiment of the invention. In addition, the system according to the invention includes a centrifugal cleaner installation 12, which includes at least two steps, steps 12al and 12a2, that is, centrifugal cleaning degrees. In addition, the system according to the invention includes a wire pit 13 and a fitting bi leading from this to the first centrifugal cleaning step 12al of the centrifugal cleaning installation 12. From the first step 12ai of the centrifugal cleaning installation 12 there is a further fitting al for the accept into the deaeration tank 11, into the first section 11 al of the said tank. From tank 11 ai there is another fitting a2, which branches off to form fittings a2'and a2". The fittings a2'and include power screens 14al and 14a2, from which the accept is conducted further along fittings a2'and a2"to a multi-layer headbox 10 and into its bypass manifolds Ji and J3, from which the pulp is divided further into the headbox's set of pipes, through an intermediate chamber and a turbulence generator to the formation wire Hi and to form the top and bottom layers of the web. The fittings, such as channels or pipes a2'and a2", include pumps P2 and Pi and, correspondingly, a pump P3 is located in a fitting a4. Using the pumps, the pulp fractions are pumped into each bypass

manifold Ji, Ja, J3 of the multi-layer headbox 10.

From the first step 12al of the centrifugal cleaner installation 12 there is a fitting b2 for the reject, and further to fitting bs, which leads to the second stage of centrifugal cleaner installation 12, that is, to second step 12a2, from which there is further a fitting a3 for the accept into the second section lla2 of the deaeration tank 11, and further a fitting a4, e. g. a pipe, into bypass manifold J2 of the multi- layer headbox 10 to form the middle layer of the web. In this application, virgin stock is understood as being the new stock conducted to wire pit 13. The stock includes fillers and additives and fibres. Thus, from the first step 12al of the centrifugal cleaner installation 12 there is a fitting ai into multi-section deaeration tank 11, into its first section llal, from which after the deaeration the fraction is transferred further into fitting a2, which branches off to form branch fittings a2', a2", which lead further into corresponding pulp bypass manifolds Ji and J3 of the multi-layer headbox 10. Branch fittings a2', include power screens 14a3 and 14al, from which the accept is conducted further to the corresponding bypass manifolds Ji, J3 of the headbox, and the reject is conducted along channels tl, t3 back to the wire pit 13. Correspondingly, from the second step 12a2 of the centrifugal cleaner installation 12 the accept is conducted into multi-section deaeration tank 11, into its section lla2 along fitting a3, and after the deaeration the said fraction is conducted to fitting a4, which is conducted further into the middle bypass manifold J2 of the multi-layer headbox 10 to form the middle layer of the web. Fitting a4 includes a power screen 14a2, from which the accept is conducted into bypass manifold J2 of the multi-layer headbox 10, and the reject is conducted along fitting t2 as a back flow back to wire pit 13.

As is shown in Figure 1, centrifugal cleaner installation 12 may include several steps. In the embodiment shown in Figure 1, there are two actual fractionation steps, which are steps 12ai and 12a2, which are used for forming a three-layer web. Step 12al includes centrifugal cleaner cones 120, of which there are five in the step and the accept outlets of which are joined together, while, correspond-

ingly, the reject outlets are joined together. There is a corresponding arrangement in the other steps. The number of cones 120 in step 12a2 is four, in step 12a3 there are three, in step 12a4 two and in the last step 12as there is one cone 120. The reject outlet fitting b2 of step 12al is connected to supply channel b3 of the second step 12a2. The reject outlet b4 of step 12a2 is connected to supply fitting bs of the third step 12a3 and reject outlet b6 of step 12a3 is connected to supply fitting b7 of step 12a4, reject outlet fitting bs of step 12a4 is connected to supply fitting bs of the last step 12as. The accepts of steps 12a3,12a4 and 12as, for which there is a fitting dl, d2, d3, are connected in such a way to the system that the accept of step 12a3 is made to flow along fitting di to the second step 12a2, into its fitting b3 to the suction side of feed pump Ps. Correspondingly, accept fitting d2 of step 12a4 is connected with supply channel bs of step 12a3 on the suction side of feed pump PP6 and, correspondingly, accept fitting d3 of step 12as is connected with supply fitting b7 of step 12a4 on the suction side of pump P7. The reject taken from the last step 12as is moved entirely to the discharge or to further treatment in connection with another installation.

Fitting bl from wire pit 13 includes a feed pump P4, and there is an input fitting f for virgin stock to the wire pit. For the tail water of the wire section there is a return fitting e to wire pit 13, and as is shown in the figure, from deaeration tank 11 between the end walls of sections 1 lai and 11 la2 there is a return fitting g for overflow to wire pit 13. Negative pressure pump arrangements in connection with deaeration tank 11 for bringing about a negative pressure in the top section of the deaeration tank are not shown. Air is removed from the fractionated pulp with the aid of a high negative pressure brought about in the deaeration tank by a negative pressure pump.

Such an embodiment is also possible within the scope of the invention, where there is no deaeration of the pulp. In systems with no deaeration of the pulp the accept of the centrifugal cleaning may be taken directly to the suction side of the headbox's feed pump. In other respects the system is similar to the one in the

embodiment shown by Figure 1.

Figure 2A shows one centrifugal cleaner of the first step 12ai of a centrifugal cleaner installation. There may be several centrifugal cleaner cones 120 in each step 12al, 12a2... The accepts of the cones 120 in each step are combined with each other and the rejects are also combined and then conducted along their respective fittings al, b2 ; a2, b4... As is shown schematically in the figure, the heaviest particles move along a helical path downwards in the centrifugal cleaner cone 120 and further out of the cone 120, and from the middle at the top the accepts are conducted forward into the deaeration tank and further into that bypass manifold of the multi-layer headbox, which relates to the concerned fraction.

Thus, the fractionation of the centrifugal cleaner is characterised in that fractiona- tion takes place in the said cleaner especially as regards the pulp, whereby the heavier particles move along a helical path to the following step or stage of the centrifugal cleaning, and thus the fractionation takes place also in regard to fillers and additives and not only in regard to fibres.

Figure 2B is a sectional view along line I-I of Figure 2A. Fitting bi is joined tangentially to cone 120. The centrifugal force thus separates the heavier particles from the pulp flow Li in the space 0 shaped like a truncated cone inside cone 120, while the lighter particles and the pulp fraction separated from the other pulp are conducted (arrow L2) into deaeration tank 11 of the deaeration equipment by way of fitting al.

Figure 3 shows an embodiment of the invention, wherein the tail water is conducted to wire pit 13 along fitting e and the tail water is conducted further from wire pit 13 pumped by pump Plo along fitting bl into deaeration tank 11, from which deaeration tank 11 the tail water is conducted further along fitting bi' pumped by pump P20 to the centrifugal cleaner installation 12. High-consistency pulp, that is, virgin stock, is fed into channel bl'to the suction side of pump P20.

From the first step 12al of the centrifugal cleaner installation 12 the accept is

conducted along fitting al into branch fittings ai', al", which include feed pumps Pi and P2, and the pulp is conducted further through power screens 14al and 14a3 into bypass manifolds J1 and J3 of the multi-layer headbox 10. From the first step 12al of the centrifugal cleaner installation 12 the reject is conducted along fitting b2 to the second step 12a2 of centrifugal cleaner installation 12 as supply, and from the said step the accept is conducted along fitting as pumped by pump P3 to power screen 14a2 and further to the central bypass manifold J2 of the multi-layer headbox 10 to form the middle layer of the web.