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EP 2 531 644 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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02.04.2014 Bulletin 2014/14 |
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Date of filing: 01.02.2011 |
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International Patent Classification (IPC):
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International application number: |
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PCT/FI2011/050079 |
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International publication number: |
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WO 2011/095686 (11.08.2011 Gazette 2011/32) |
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METHOD OF CONTROLLING FILTRATE FLOWS AND STORING OF FILTRATES OF A FIBRE LINE IN A
PULP MILL
VERFAHREN ZUR STEUERUNG VON FILTRATFLÜSSEN UND LAGERUNG VON FILTRATEN EINER FASERSTRASSE
IN EINEM ZELLSTOFFWERK
PROCÉDÉ DE COMMANDE DES ÉCOULEMENTS DE FILTRATS ET DE STOCKAGE DES FILTRATS D'UNE
CHAÎNE DE FIBRES DANS UNE USINE DE PÂTE À PAPIER
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Designated Contracting States: |
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AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL
NO PL PT RO RS SE SI SK SM TR |
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Priority: |
02.02.2010 FI 20100034
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Date of publication of application: |
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12.12.2012 Bulletin 2012/50 |
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Proprietor: Andritz Oy |
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00180 Helsinki (FI) |
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Inventor: |
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- KETTUNEN, Auvo
FI-48800 Kotka (FI)
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Representative: Sorvari, Marjut Riitta Tuulikki |
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Andritz Oy
Patent Department
P.O. Box 500 48601 Kotka 48601 Kotka (FI) |
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References cited: :
EP-A1- 0 573 892 WO-A1-00/49222 WO-A1-2005/061781 US-A- 5 538 597
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EP-A2- 0 269 124 WO-A1-2004/072363 US-A- 4 303 470
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Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
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[0001] The present invention relates to a method of controlling filtrate flows and storing
of filtrates of a fibre line in a pulp mill. Preferably, the method according to the
invention is suitably used in conjunction with a pulp storage tank. As an especially
preferred application could be mentioned different kinds of pulp tanks in a sulphate
cellulose mill, e.g. a blow tank in a digester plant, where the filtrates are arranged
to flow according to the counter-current principle on both sides of the tank.
[0002] At a pulp mill, pulp is treated in several different process stages. After digestion,
impurities are removed from the pulp, the pulp is oxygen-delignified and bleached
with various chemicals in several steps. Between the various steps, the pulp is typically
washed in one or several washing step/-s. The aim here is to keep the amount of clean
wash water as small as possible in order to decrease the evaporation need or the amount
of waste water. For this reason, the wash waters are typically arranged to flow at
least partially according to the counter-current principle. According to the counter-current
principle the wash waters are introduced into the last washer at the end of the washing
line. The filtrate from this washer is introduced countercurrent to the pulp flow
into the next (i.e. the second last) washer to be used as wash water. The filtrate
from this washer is again introduced countercurrently into the next washer. By using
an arrangement of this kind the pulp can be washed clean with a fairly small amount
of wash water and the impurities removed from the pulp are obtained in the form of
a relatively highly concentrated solution. This solution can be further concentrated,
e.g. through evaporation, and then combusted.
[0003] The above-described counter-current principle is utilised in the washing lines of
practically all pulp mills. The amount of wash water moving countercurrently is generally
represented by a dilution factor. When the dilution factor is for instance 2.5, the
amount of wash water supplied to the washing step is 2.5 cubic metres per pulp ton
larger than the amount of water being removed along with the pulp from the washing
step. In order to reach a uniform washing result, the aim is to keep the dilution
factor as steady as possible on the desired level over the entire area of the washing
line. If the dilution factor varies, the cleanliness of the pulp and the concentration
of recovered solution vary.
[0004] The level changes in the pulp storage tanks in a washing line arranged according
to the counter-current principle make it difficult to keep the dilution factor steady.
Traditionally, the aim has been to maintain the consistency of the pulp in the storage
tank as uniform as possible, whereby it is typically about 10 %. Then, there are nine
tons of filtrate in the tank per one pulp ton. Naturally, when the amount of pulp
in the tank changes, the amount of filtrate changes as well. When the amount of pulp
in the tank increases, more filtrate is entrained in the pulp in the pulp tank. This
filtrate originates, in the travel direction of the pulp, from the filtrate taken
from the process stage after the tank, and has thus been introduced into the washer
preceding the pulp storage tank to be used as wash liquid. In this case, the dilution
factor of the process stage after the tank needs to be increased, or even some of
the filtrate introduced into the preceding washer to be used as wash liquid needs
to be introduced directly, i.e. bypassing the washing devices after the tank. When
the amount of pulp in the tank decreases, less filtrate is entrained in the pulp in
the tank, in other words, filtrate is freed from the tank. Consequently, not as much
filtrate can be taken anymore from the process after the tank to be used as wash liquid
in the washer preceding the tank, and the dilution factor in the process stage after
the tank needs to be decreased or excess filtrates need to be taken past the washers
in front of the pulp tank. The variation of the dilution factor due to the fluctuation
of the level in the pulp tank results in variation in the washing result.
[0005] In the concepts according to prior art the above-mentioned problem is solved by using,
beside the pulp storage tank, a storage tank for filtrate, which is nearly as large
as the one for pulp. When the pulp level in the storage tank rises, the required filtrate
is taken from the filtrate storage tank, in which the filtrate level drops. When the
level in the pulp storage tank drops, the discharged filtrate is led into the filtrate
storage tank. Thereby, the dilution factor can be maintained on the desired level
in the washers on both sides of the storage tank and the variation in the washing
result and the other above-mentioned problems are avoided.
[0006] The above-described filtrate storage tank fulfils its function, but is, nevertheless,
a very expensive structural element. The volume of the pulp storage tanks is typically
several thousands of cubic metres. A filtrate storage tank is typically nearly as
large as, or at least almost a half of, the pulp storage tank. Such a tank is obviously
very expensive and takes a lot of space. Moreover, the tank requires a pump of its
own for pumping the filtrate as well as pipelines and valves for controlling the flows.
[0007] Most of the washers used in pulp mills are provided with a filtrate tank of their
own, but the possibility to use the tanks for controlling filtrate flows is very limited.
There are two practical circumstances that prevent the use of the filtrate tanks of
washers for controlling the flows. Firstly, their volume, which is of the order of
about 50 - 200 m
3, is only a fraction of that of the pulp storage tanks and filtrate storage tanks,
which is of the order of 1000 - 10000 m
3. Secondly, said tanks are in most cases a part of the suction leg utilised by the
washers, whereby the level in the tanks is hardly allowed to vary at all in order
not to change the suction/partial vacuum subjected to the pulp to be washed in the
washer by the suction leg.
US 4303470 describes pulp treatment systems having pulp storage tanks and tanks which act to
store filtrates for further use.
WO 2004/072363 describes a system to dilute pulp in the lower part of a high-consistency pulp tower
which can be used for storage of pulp.
[0008] In the concept according to the present invention it is possible to solve, in the
best case even completely, the above-discussed problem related to the variation of
the dilution factor without any expensive tank and the pumping associated therewith.
[0009] In the concept according to the invention the pulp tank acts at the same time also
as a filtrate storage tank. When the amount of pulp in the tank changes, the consistency
of the pulp in the tank is changed, and not, as traditionally, the volume of the pulp
and the level in the tank. When the amount of pulp in the tank decreases, the level
in the tank is maintained relatively constant, but the consistency of the pulp pumped
into the tank is decreased. Similarly, when the amount of pulp in the tank increases,
the consistency of the pulp therein is increased. Thereby, the amount of filtrate
existing/stored together with the pulp in the tank hardly changes at all and there
is no need to change the dilution factor in the washers around the tank. In the method
according to the invention, it is advantageous to calculate the amount of filtrate
in the tank and aim at keeping it essentially constant. The above terms 'relatively
constant' or 'essentially constant' refer to a situation, in which the range of variation
of the amount of filtrate in the pulp storage tank is +/- 15 %, preferably +/- 10%.
[0010] In the fibre line of a pulp mill there is typically a pulp storage tank between the
digester plant and the washing of brown stock. The next pulp tank is typically between
the treatment of brown stock and bleaching. A third large pulp tank is situated between
bleaching and a paper machine or a pulp drying machine. According to the counter-current
principle, the filtrate circulations continue typically over the pulp tank located
after the digester plant. In most cases, the counter-current washing is situated entirely
in front of the pulp tank prior to bleaching, but there are also several cases, in
which one washing device is located after this pulp tank. In some cases, the filtrates
from bleaching are brought to the washing of brown stock, whereby the filtrate circulations
naturally continue over the pulp tank prior to bleaching. In the last washer at bleaching,
water from the paper machine or pulp drying machine is generally used as wash water.
Thus, the filtrate circulations also continue over the tank for bleached pulp. In
addition to the storage tanks for bleached pulp, there is typically a tank that acts,
as described in the above, as a filtrate or water storage tank. This tank is called,
for instance, a white water tank. Accordingly, there is a plurality of pulp tanks
in a pulp mill, in conjunction with which the method according to the invention may
be applied. When applying the invention, the filtrate storage tanks may be either
omitted completely or replaced with smaller tanks than before. In both cases, substantial
savings are achieved in terms of space requirement and investment costs in the mill.
[0011] From prior art it is known that the aim is to maintain the consistency of the pulp
in the storage tank as uniform as possible so that no consistency fluctuations would
be allowed to interfere the dilution carried out at the bottom of the tank. At the
bottom of the tank, the pulp is traditionally diluted in two steps. A part of the
filtrate received from the process stage after the tank, or of the dilution liquid
arranged to come from elsewhere, is delivered, for instance in proportion to the production,
directly to the vicinity of the mixer at the bottom of the tank, whereby the pulp
is diluted and the mixer functions better. The rest of the filtrate is delivered between
the tank and the pulp pump controlled by consistency control. By means of these two
flows the pulp in the tank at the consistency of about 10 % is diluted to desired
consistency. Thus, the purpose of the filtrate delivered directly to the bottom of
the tank is to dilute the pulp that is being discharged from the tank in the vicinity
of the mixer, whereby the retention time of the filtrate in the tank is a few minutes
at the most. This dilution cannot be compared to the dilution in the method according
to the invention, where the purpose is primarily to store excess filtrate even for
several hours in the pulp storage tank and only secondarily, to allow the consistency
of the pulp stored in the tank to change, whereby the pulp may also be diluted.
[0012] It is a characteristic feature of the method according to a preferred embodiment
of the present invention of controlling filtrate flows and storing of filtrates of
a fibre line in a pulp mill that filtrate is stored in a pulp storage tank regardless
of the amount of pulp in the pulp storage tank by changing the average consistency
of the pulp in the storage tank.
[0013] It is a characteristic feature of the method according to a second preferred embodiment
of the present invention of controlling filtrate flows and storing of filtrates of
a fibre line in a pulp mill that filtrate is introduced into the pulp storage tank,
when the amount of pulp in the pulp storage tank changes, regardless of the amount
of pulp in the storage tank.
[0014] It is a characteristic feature of the method according to a third preferred embodiment
of the present invention of controlling filtrate flows and storing of filtrates of
a fibre line in a pulp mill that the amount of filtrate in the pulp storage tank is
maintained essentially constant, when the amount of pulp in the pulp storage tank
changes.
[0015] Other characteristic features of the method according to the present invention are
disclosed in the appended claims.
[0016] The invention is particularly applicable when the process stage succeeding the pulp
tank is carried out at low consistency, whereby the fluctuation of the consistency
of the pulp in the tank is not deterious, as the pulp will nonetheless be diluted
to a desired low consistency level. Such process stages carried out at low consistency
are for instance knot separation and screening, a reactor or washer operating at low
consistency, such as a traditional drum filter or a wash press.
[0017] In the following, the present invention will be explained in more detail with reference
to the appended figures, of which
Figure 1 shows a fibre line of a pulp mill according to prior art, in which the filtrate
storage tanks are shown side by side with the pulp storage tanks,
Figure 2 shows an arrangement for a fibre line of a pulp mill according to a preferred
embodiment of the invention, in which said filtrate storage tanks are not required,
and
Figure 3 shows an arrangement according to another preferred embodiment of the invention,
in which the embodiment of Figure 2 is completed with a preferable control method
for filtrate flows.
[0018] Figure 1 shows an example of a prior art fibre line of a pulp mill. Pulp is digested
and washed in a continuous digester 1, from which the pulp is blown to a first washer,
i.e. to a pressure diffuser 2. From the pressure diffuser the pulp flows to a first
pulp storage tank, i.e. to a blow tank 3. Adjacent to the pulp storage tank there
is a filtrate storage tank 4, by the changes of the level in which the changes of
the level in the pulp storage tank are compensated. After the first pulp storage tank
3, impurities are typically removed from the pulp at low consistency and subsequently,
the pulp is washed in a next washing device 5. After this step, the pulp is oxygen-delignified
in a reactor 6 and washed in a washing device 7. Next, the pulp is led to second pulp
storage tank 8, adjacent to which there is second filtrate storage tank 9 to compensate
the changes of the level in the storage tank 8. After this, the pulp is washed once
again in a washing device 10 prior to a first bleaching reactor 11. The pulp is bleached
in three steps in reactors 11, 13 and 15, respectively. After each reactor, the pulp
is washed in a washing device 12, 14 and 16, respectively. From the last washer 16
of the fibre line, the pulp is taken to a storage tank 17 for bleached pulp. Especially
if more than one pulp grade is produced by the fibre line, this stage may include
a plurality of adjacent pulp storage tanks. Next to the pulp storage tank or tanks
there is a filtrate or water storage tank 18, by the change of the level in which
the changes of the level in the pulp storage tank 17 are compensated. From the bleached
pulp storage tank 17 the pulp is taken to a paper machine or a pulp drying machine
19, in which the pulp is dewatered almost completely through infiltration, pressing
and evaporation.
[0019] In the following, some typical wash water arrangements according to the counter-current
principle in a fibre line are discussed further with reference to Figure 1 of prior
art. Fresh water 20 is brought to the paper machine or pulp drying machine, which
can, in a way, also be regarded as a pulp washer, which water, after being infiltrated
through the fibre web, passes either directly or via the storage tank 18 to the last
washer 16 of the fibre line. The second arrangement according to the counter-current
principle starts from the washer 10, to which also fresh water or condensate 21 is
supplied. The filtrate displaced by this water or condensate 21 is led either directly
or via the tank 9 to the washer 7. The filtrate displaced in the washer 7 is led to
the washer 5, from which the displaced filtrate is led either directly or via the
tank 4 to the washer 2. The filtrate displaced in the washer 2 is led to the digester
1, in which it displaces black liquor, from which excess water is evaporated before
combustion. The aim with Figure 1 is to show, in a simplified manner, the arrangements
for those waters and filtrates of a fibre line according to prior art that are most
relevant to the method according to the invention. In addition to the shown arrangements,
a fibre line includes a plurality of various other arrangements, such as dilutions
and filtrate tanks for washers, which are not shown in this context.
[0020] Figure 2 shows a few preferable embodiments of the invention for a fibre line according
to Figure 1. Pulp is digested and washed in a continuous digester 1, from which the
pulp is blown to a first washer 2, which is nowadays often a pressure diffuser. From
the washer 2, the pulp flows to a first storage tank, i.e. to blow tank 3. Adjacent
to the pulp storage tank 3 there is no filtrate storage tank, but possible excess
filtrates from a washer 5 are returned through a pipe line 22 either directly or entrained
with the pulp, or both ways, to the pulp storage tank 3. After the first pulp storage
tank 3, impurities are typically removed from the pulp at low consistency and subsequently,
the pulp is washed in a next washing device 5. After this step, the pulp is oxygen-delignified
in a reactor 6 and washed in a washing device 7. Next, the pulp is led to a second
pulp storage tank 8. Adjacent to this pulp storage tank either, there is no filtrate
storage tank, but possible excess filtrates from a washer 10 are returned through
a pipeline 23 either directly or entrained with the pulp, or both ways, to the tank
8. After this, the pulp is washed once again in the washing device 10 prior to a first
bleaching reactor 11. The pulp is bleached in three steps in reactors 11, 13 and 15,
respectively. After each reactor, the pulp is washed in a washing device 12, 14 and
16, respectively. From the last washer 16 of the fibre line, the pulp is taken to
a bleached pulp storage tank 17. Especially if more than one pulp grade is produced
by the fibre line, this stage may include a plurality of adjacent pulp storage tanks.
Adjacent to these pulp storage tanks either, there are no filtrate storage tanks,
but possible excess filtrates from a paper machine or pulp drying machine 19 are returned
through a pipeline 24 either directly or entrained with the pulp, or both ways, to
the storage tank 17. From the bleached pulp storage tank the pulp is taken to the
paper machine or pulp drying machine 19, in which the pulp is dewatered almost completely
through infiltration, pressing and evaporation.
[0021] The wash waters are arranged in the concept according to Figure 2 in a similar way,
i.e. according to the counter-current principle, as in the prior art concept according
to Figure 1. Fresh water 20 is brought to the paper machine or pulp drying machine,
which can, in a way, be also regarded as a pulp washer, which water passes either
directly or via the pulp storage tank 17 to the last washer 16 of the fibre line.
The second arrangement according to the counter-current principle starts from the
washer 10, to which also fresh water or condensate 21 is supplied. The filtrate displaced
by this water or condensate 21 is led directly to the washer 7. In addition to this,
filtrate is led to the pulp storage tank 8, if so required. The filtrate displaced
in the washer 7 is led to the washer 5, from which the displaced filtrate is led directly
to the washer 2. In addition to this, filtrate is led to the pulp storage tank 3,
if so required. The filtrate displaced in the washer 2 is led to the digester 1, in
which it displaces black liquor, from which excess water is evaporated before combustion.
The aim with Figure 2 is to show, in a simplified manner, those arrangements for the
waters and filtrates of a fibre line, that are most relevant to the method according
to the invention, in three positions of the fibre line. It is to be noted that the
present invention is applicable in all shown positions of the fibre line or, if so
required, only in some of said positions. In addition to the shown arrangements, a
fibre line includes a plurality of various other arrangements, such as dilutions and
filtrate tanks for washers, which are not shown in this context.
[0022] As mentioned in the above, in the concept according to the invention the excess filtrate
is returned, either entrained with the pulp or directly, to the pulp storage tank.
To put it more accurately, the excess filtrate can be returned to the pulp storage
tank either as pure filtrate, whereby it is advantageous that it is spread evenly
on top of the pulp layer in the tank in order to avoid the development of significant
differences in the consistency, or together with the pulp by introducing it into the
feeding device for pulp. The excess filtrate can also be mixed with the pulp earlier,
for instance by bringing it to the outlet (usually a screw) of the washer or to some
other position on the suction side or discharge side of the feed pump for pulp. This
returned filtrate dilutes the pulp in the tank, whereby there is more filtrate in
the tank in proportion to the amount of pulp therein and the average consistency of
the pulp decreases. Thus, it is possible to store a required amount of filtrate in
the tank, even if varying amounts of pulp were stored therein. It is preferable to
provide the dilution according to the invention so that it is mixed with the pulp
flowing into the tank, whereby the pulp flowing in the pulp line is diluted and the
pipe resistance due to the flow is decreased, thus diminishing the required pumping
efficiency. At the same time it is ensured that the provided dilution is mixed with
the pulp evenly. If the filtrate is introduced directly into the tank, it is advantageous
to introduce it so that it is mixed with the pulp as evenly as possible. To this end,
it would be advantageous to spray the filtrate above the pulp surface by means of
nozzles. The filtrate can also be delivered to one point from the side of the tank,
but then the filtrate is not mixed with the pulp too evenly, especially if the pulp
surface is situated above the delivery point. If the filtrate is not mixed evenly,
some pulp at a lower consistency than required by the next process stage may pass
to the bottom of the tank. This could interfere the next process stage and is therefore
an unwanted phenomenon. If the consistency of the pulp in the tank changes relatively
slowly and remains above the consistency of the next process stage, it is easy to
dilute the pulp leaving the tank to a desired consistency level. If the consistency
of the pulp in the tank varies, there is no use to deliver filtrate to the bottom
of the tank in proportion to the production. It is advisable to deliver filtrate controlled
by a consistency controller. As soon as the consistency control requires more filtrate
between the pulp tank and the pulp pump, the filtrate flow directly to the bottom
of the pulp tank is also increased at the same time. Consequently, the pulp consistency
remains on a suitable level in the vicinity of the mixer and the consistency of the
pulp flowing to the next process stage remains on the desired level.
[0023] As for the method according to the invention, it is thus essential that the average
consistency of the pulp in the pulp storage tank can be affected. Sometimes the pulp
flow channels through the pulp tank, whereby the pulp entering the tank flows relatively
fast to the bottom of the tank and out therefrom. Then, most of the pulp in the tank
remains immobile. This is, from the viewpoint of the method according to the invention,
an unwanted phenomenon, since in this case the changes of the consistency of the incoming
pulp are hardly allowed to affect the average consistency of the pulp in the storage
tank. The channelling in the pulp tank can be prevented for instance by a device that
spreads the pulp evenly over the cross-sectional area of the tank. It is advisable
to use a device of this kind in conjunction with the method according to the invention,
if there is any risk or tendency for channelling in the pulp storage tank.
[0024] Figure 3 shows in more detail a concept that applies the method according to the
present invention with related level and flow controls. Pulp 31 is led to a washer
32, in which the pulp is washed by wash water 33. The washed pulp 34 leaving the washer
32 at a consistency of about 10 % is led to a pulp storage tank 37. The filtrate 35
displaced in the washer 32 is led to a filtrate storage tank 36. The pulp 39 leaving
the storage tank 37 is diluted with the filtrate from the washer 32 to a low consistency
and led to a washer 40. The washer 40 may be, for instance, a wash press or a drum
filter, to which the pulp is typically fed at a consistency of 1 - 4 %. The pulp 39
is washed in the washer 40 with wash water 41, the filtrate 43 displaced by which
is led to a filtrate storage tank 44. The washed pulp 42 is led to the subsequent
process stages. The filtrate collected in the filtrate storage tank 44 of the washer
40 is used as wash water 33 in the washer 32 and for diluting 38 the pulp 39 leaving
the storage tank. If excess filtrate is collected in the filtrate storage tank 44
of the washer 40 after these primary purposes of use and the level in the filtrate
tank 44 tends to rise, this excess filtrate is led, controlled by a level controller
47, either directly via a valve 45 to the pulp storage tank 37 or via a valve 46 into
the pulp 34 entering the storage tank 37, or both ways 45 and 46. The set value in
the level controller 47 is relatively high, for instance about 80 % of the height
of the filtrate tank 44, whereby it removes from the filtrate tank 44 of the washer
40 only the excess filtrate that enters it. The filtrate tanks 36, 44 of both washers
32, 40, respectively, are provided with respective level controllers 55, 54 to monitor
the level of the filtrate so that it is not allowed to sink too low during the operation.
The level controller 55 monitors the bottom level in the filtrate tank 36 and the
level controller 54 monitors the bottom level in the filtrate tank 44. The aim is
to maintain the dilution factor as steady as possible in the washer 32. A dilution
factor controller 48 controls the amount of wash water 33 entering the washer 32 so
as to achieve the desired dilution factor. The aim is to maintain the consistency
of the pulp 39 introduced into the washer 40 as uniform as possible on a desired low
level. A consistency controller 49 controls the filtrate 38 mixed with the pulp 39
so that the desired consistency is achieved. A level controller 50 measures the amount
of filtrate in the pulp storage tank and aims at keeping it as uniform as possible
by controlling the set value of the dilution factor controller 51 of the washer 40.
As soon as the value of the dilution factor 51 rises, more filtrate enters the filtrate
tank 44, and therethrough the pulp storage tank 37, and the level 50 tends to rise,
and vice versa. If the total amount of filtrate taken by the wash water 33, dilution
filtrate 38 and the level controller 55 is higher than the amount 43 of filtrate entering
the filtrate tank 44, the level in the filtrate tank 44 tends to drop. In order to
prevent excessive drop of the level, the level controller 52, the set value of which
is lower than that of the level controller 47 and higher than that of the level controller
54, controls also the set value of the dilution factor controller 51 of the washer
40. The selector 53 for maximum value selects the higher one of the values controlled
by the level controllers 50 and 52 to be used as a set value for the dilution factor
controller 51. In order to prevent excessive fluctuation of the dilution factor 51,
the values controlled by the level controllers 50 and 52 are limited to a suitable
range around the normal set value.
[0025] By means of the arrangement and control model according to the invention shown in
Figure 3, the dilution factors of the washing line can be maintained relatively steady,
even if the amount of pulp in the pulp storage tank would vary a lot. As soon as the
amount of pulp in the storage tank 37 decreases, the amount of pulp entering the washer
40 will be higher than the amount of pulp leaving the washer 32. Entrained with the
pulp entering the washer 40 there is also a lot of filtrate and the level in the filtrate
tank 44 of the washer 40 tends to rise, whereby the level controller 47 leads the
excess filtrate back to the tank 37 and thereby the amount of filtrate therein hardly
changes at all. As soon as the amount of pulp in the storage tank 37 increases, less
pulp will enter the washer 40 than leaves the washer 32. The high amount of pulp leaving
the washer 32 entrains a lot of filtrate and the level in the filtrate tank 44 of
the washer 40 tends to drop, whereby the level controller 47 decreases the excessive
dilution led into the tank 37. Then the consistency and amount of the pulp in the
tank increases, but the amount of filtrate therein hardly changes at all. When the
amount of pulp leaving the washer 32 is substantially higher than the amount of pulp
entering the washer 40, it may happen that the tank 44 runs out of excess filtrate
and the control of the level controller 47 reaches zero. Should the level in the filtrate
tank 44 continue to drop in this situation, the level controller 52 will set a higher
dilution factor for the washer 40, whereby more filtrate will enter the filtrate tank
44. Not even this is necessarily enough, if the difference between the productions
is significant or hardly any pulp is discharged from the storage tank 37, and therefore
the level in the filtrate tank 44 will continue to drop. In this situation, the level
controller 54 ensures that the filtrate level does not drop too low. It is extremely
rare, however, that the production levels differ so much from one another around the
pulp tank 37 that the result is this situation. If no new pulp enters the storage
tank 37 at all, all the pulp in the tank can be discharged through the washer 40.
Then, all the filtrate entering the filtrate tank 44 is returned to the tank 37 and
the amount of filtrate therein hardly changes at all. If, for some reason, the amount
of filtrate in the storage tank 37 differs from normal, the level controller 50 guides
the dilution factor 51 of the washer 40 so that the amount of filtrate eventually
settles on the desired level.
[0026] In the concept according to Figure 3, the desired dilution factor is applied in the
washer preceding the pulp storage tank and the dilution factor of the washer succeeding
the storage tank is fine-adjusted, as required, in order to maintain the total amount
of filtrate substantially constant. The adjustment can also be performed the other
way around. In this case, an external constant dilution factor is maintained in the
washer succeeding the storage tank and the dilution factor in the washer preceding
the storage tank is fine-adjusted, as required. This is advantageous for instance
in the case of a bleached pulp storage tank, when the "washer" succeeding the tank
is a paper machine or a pulp drying machine. Then, such an amount of water is supplied
to the paper machine or pulp drying machine that is advantageous and necessary for
the operation thereof. The excess water collected in the filtrate tank is stored in
the pulp storage tank. If the total amount of water in the pulp storage tank and in
the filtrate tank changes, the dilution factor in the last washer at bleaching can
be fine-adjusted so that the total amount remains on the desired level. In this case,
it is more advantageous to perform the adjustment this way around, since it is substantially
easier to change the dilution factor in the washer than e.g. the amounts of water
delivered to a paper machine. If there are washers on both sides of the storage tank,
it is more or less a matter of taste to decide which way to perform the adjustment.
[0027] As appears from the above, the control model according to the invention works correctly
as long as the process on both sides of the storage tank 37 is run on such production
levels that are fairly close to one another and the amount of pulp in the tank does
not change rapidly. The control model works properly also in situations, in which
the amount of pulp in the storage tank 37 decreases rapidly. In situations, in which
the amount of pulp in the storage tank 37 increases rapidly, it is necessary to bypass
the washer 40, whereby the efficiency of the operation of the washing line is compromised.
In practise, such periods are, however, always fairly short.
[0028] As can be observed from the above, a method of new type for controlling the filtrates
of a fibre line of a pulp mill, arranged according to the counter-current principle,
has been developed. The method simplifies and intensifies the processes of said industrial
sector substantially. Likewise, it is worth noticing that the method according to
the invention may also be utilised in several other connections and arrangements than
in the above-mentioned ones. For instance in such arrangements, in which the number
and positions of the washers differ from the above, if there are other process steps
between the washers, and in connections between a batch digester and various washers
and tanks, just to mention a few cases. The method according to the invention can
be used in conjunction with all pulp tanks of the fibre line or in conjunction with
only a few, desired ones. When applying the invention, the filtrate storage tanks
can be either omitted completely or replaced with considerably smaller tanks than
before.
1. Method of controlling filtrate flows and storing of filtrates of a fibre line in a
pulp mill, characterised in that filtrate is stored in a pulp storage tank (3, 8, 17, 37) regardless of the amount
of pulp in the pulp storage tank (3, 8, 17, 37) by changing the average consistency
of the pulp in the storage tank (3, 8, 17, 37).
2. A method according to claim 1, characterised in that filtrate is introduced into the pulp storage tank (3, 8, 17, 37), when the amount
of pulp in the pulp storage tank (3, 8, 17, 37) changes.
3. A method according to claim 1, characterised in that the amount of filtrate in the pulp storage tank (3, 8, 17, 37) is maintained substantially
constant, when the amount of pulp in the pulp storage tank (3, 8, 17, 37) changes.
4. A method according to anyone of the preceding claims, characterised in that filtrate is returned to the storage tank (3, 8, 17, 37), when the amount of pulp
in the storage tank (3, 8, 17, 37) decreases, so that the average consistency of the
pulp in the storage tank (3, 8, 17, 37) decreases.
5. A method according to claim 4, characterised in that the amount of filtrate returned from a washer (5, 10, 19, 40) succeeding the pulp
storage tank (3, 8, 17, 37) is increased.
6. A method according to claim 4 or 5, characterised in that filtrate is returned to the pulp storage tank (3, 8, 17, 37), to its inlet, to the
discharge screw of a washer (2, 7, 16, 32) or to the suction side or discharge side
of the feed pump of the pulp storage tank (3, 8, 17, 37).
7. A method according to anyone of the preceding claims 1 - 3, characterised in that the increase of the amount of filtrate collected in the storage tank (3, 8, 17, 37)
is prevented by increasing the average consistency of the pulp in the storage tank
(3, 8, 17, 37), when the amount of pulp increases.
8. A method according to claim 7, characterised in that the amount of filtrate returned from the washer (5, 10, 19, 40) succeeding the pulp
storage tank (3, 8, 17, 37) is decreased.
9. A method according to anyone of the preceding claims, characterised in that the excess liquid collected in the filtrate tank (44) of the pulp washer (40) is
led to the pulp storage tank (37) with the help of a level controller (47).
10. A method according to anyone of the preceding claims, characterised in that the amount of filtrate collected in the pulp storage tank (37) is measured and maintained
substantially constant with the help of a level controller (50).
11. A method according to anyone of the preceding claims, characterised in that a special spreader is used when pulp and/or filtrate is introduced into the pulp
storage tank (3, 8, 17, 37), by which spreader the pulp and/or filtrate is spread
over the cross-sectional area of the entire tank (3, 8, 17, 37) in order to prevent
channelling.
1. Verfahren zur Regelung der Filtratflüsse und Lagerung der Filtrate einer Faserlinie
in einer Zellstofffabrik, dadurch gekennzeichnet, dass Filtrat in einem Zellstofflagertank (3, 8, 17, 37) unabhängig von der im Zellstofflagertank
(3, 8, 17, 37) vorhandenen Stoffmenge durch Änderung der durchschnittlichen Stoffkonsistenz
im Lagertank (3, 8, 17, 37) gelagert wird.
2. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass Filtrat in den Zellstofflagertank (3, 8, 17, 37) eingeleitet wird, wenn sich die
Stoffmenge im Zellstofflagertank (3, 8, 17, 37) ändert.
3. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass die Filtratmenge im Zellstofflagertank (3, 8, 17, 37) im Wesentlichen konstant gehalten
wird, wenn sich die Stoffmenge im Zellstofflagertank (3, 8, 17, 37) ändert.
4. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass Filtrat in den Lagertank (3, 8, 17, 37) rückgeführt wird, wenn die Stoffmenge im
Lagertank (3, 8, 17, 37) sinkt, sodass die durchschnittliche Konsistenz des Zellstoffs
im Lagertank (3, 8, 17, 37) sinkt.
5. Verfahren nach Anspruch 4, dadurch gekennzeichnet, dass die Menge des aus einem auf den Zellstofflagertank (3, 8, 17, 37) folgenden Wäscher
(5, 10, 19, 40) rückgeführten Filtrats erhöht wird.
6. Verfahren nach Anspruch 4 oder 5, dadurch gekennzeichnet, dass Filtrat in den Zellstofflagertank (3, 8, 17, 37), zu dessen Einlauf, zur Austragsschnecke
eines Wäschers (2, 7, 16, 32) oder auf die Saugseite oder die Förderseite der Speisepumpe
für den Zellstofflagertank (3, 8, 17, 37) rückgeführt wird.
7. Verfahren nach einem der vorhergehenden Ansprüche 1 bis 3, dadurch gekennzeichnet, dass die Erhöhung der im Lagertank (3, 8, 17, 37) gesammelten Filtratmenge dadurch verhindert
wird, dass die durchschnittliche Zellstoffkonsistenz im Lagertank (3, 8, 17, 37) erhöht
wird, wenn die Stoffmenge zunimmt.
8. Verfahren nach Anspruch 7, dadurch gekennzeichnet, dass die Menge des aus dem auf den Zellstofflagertank (3, 8, 17, 37) folgenden Wäscher
(5, 10, 19, 40) rückgeführten Filtrats gesenkt wird.
9. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass die im Filtrattank (44) des Zellstoffwäschers (40) gesammelte, überschüssige Flüssigkeit
mittels eines Niveaureglers (47) in den Zellstofflagertank (37) geführt wird.
10. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass die Menge des im Zellstofflagertank (37) gesammelten Filtrats gemessen und mittels
eines Niveaureglers (50) im Wesentlichen konstant gehalten wird.
11. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass ein spezieller Verteiler eingesetzt wird, wenn Zellstoff und/oder Filtrat in den
Zellstofflagertank (3, 8, 17, 37) eingeleitet werden, wobei der Zellstoff und/oder
das Filtrat mit diesem Verteiler über die Querschnittsfläche des gesamten Tanks (3,
8, 17, 37) verteilt wird/werden, um die Bildung von Kanälen zu verhindern.
1. Procédé pour le contrôle des courants de filtrat et pour le stockage des filtrats
d'une ligne de production de fibres dans une usine de pâte à papier, caractérisé en ce que du filtrat est stocké dans un réservoir de stockage de pâte (3, 8, 17, 37) indépendamment
de la quantité de pâte présente dans le réservoir de stockage (3, 8, 17, 37) en changeant
la concentration moyenne de la pâte dans le réservoir de stockage (3, 8, 17, 37).
2. Procédé selon la revendication 1, caractérisé en ce que du filtrat est introduit dans le réservoir de stockage de pâte (3, 8, 17, 37) quand
la quantité de pâte dans le réservoir de stockage (3, 8, 17, 37) change.
3. Procédé selon la revendication 1, caractérisé en ce que la quantité de filtrat dans le réservoir de stockage de pâte (3, 8, 17, 37) est essentiellement
maintenue à une valeur constante quand la quantité de pâte dans le réservoir de stockage
de pâte (3, 8, 17, 37) change.
4. Procédé selon l'une des revendications précédentes, caractérisé en ce que du filtrat est retourné dans le réservoir de stockage (3, 8, 17, 37) quand la quantité
de pâte dans le réservoir de stockage (3, 8, 17, 37) diminue, de façon que la concentration
moyenne de la pâte dans le réservoir de stockage (3, 8, 17, 37) diminue.
5. Procédé selon la revendication 4, caractérisé en ce que la quantité de filtrat retourné d'un laveur (5, 10, 19, 40) qui suit le réservoir
de stockage (3, 8, 17, 37) est augmentée.
6. Procédé selon la revendication 4 ou 5, caractérisé en ce que du filtrat est retourné dans le réservoir de stockage (3, 8, 17, 37), à son entrée,
à la vis de décharge d'un laveur (2, 7, 16, 32) ou au côté d'aspiration ou de refoulement
d'une pompe d'alimentation pour le réservoir de stockage de pâte (3, 8, 17, 37).
7. Procédé selon l'une des revendications précédentes 1 à 3, caractérisé en ce que l'augmentation de la quantité de filtrat ramassé dans le réservoir de stockage (3,
8, 17, 37) est prévenue en augmentant la concentration moyenne de la pâte dans le
réservoir de stockage (3, 8, 17, 37) quand la quantité de pâte augmente.
8. Procédé selon la revendication 7, caractérisé en ce que la quantité du filtrat retourné du laveur (5, 10, 19, 40) qui suit le réservoir de
stockage de pâte (3, 8, 17, 37) est diminuée.
9. Procédé selon l'une des revendications précédentes, caractérisé en ce que le surplus de liquide ramassé dans le réservoir de filtrat (44) du laveur de pâte
(40) est mené dans le réservoir de stockage de pâte (37) à l'aide d'un contrôleur
de niveau (47).
10. Procédé selon l'une des revendications précédentes, caractérisé en ce que la quantité du filtrat ramassé dans le réservoir de stockage (37) est mesurée et
maintenue essentiellement constante moyennant un contrôleur de niveau (50).
11. Procédé selon l'une des revendications précédentes, caractérisé en ce qu'un distributeur spécial est utilisé quand de la pâte et/ou du filtrat est/sont introduit(e)(s)
dans le réservoir de stockage (3, 8, 17, 37), la pâte et/ou le filtrat étant distribué(e)(s)
à travers la superficie de la section transversale du réservoir entier (3, 8, 17,
37) pour prévenir la formation de canaux.
REFERENCES CITED IN THE DESCRIPTION
This list of references cited by the applicant is for the reader's convenience only.
It does not form part of the European patent document. Even though great care has
been taken in compiling the references, errors or omissions cannot be excluded and
the EPO disclaims all liability in this regard.
Patent documents cited in the description