SE447208B - Rotating filter - Google Patents

Abstract

A rotating filter containing a drum shaped axel, housed in a container for fibre suspension. The axel is edified of axial waste pipes, in which the hollow filter element, forming ring shaped filter sheets is housed. A collector funnel for fibre biscuits extends itself centrally through the axel. According to the invention, the filter is characterised by the axial waste pipe (6) communicates with each and every chamber (9<1>-9<8>) for accumulation of filtrate set up on the drum shaped axel (4); that each accumulator chamber (9<1>-9<8>) is designed for the collection and storage of filtrate, which under the filter's operation flows form the opposite filter element and waste pipe when the accumulator chamber passes a filling zone during rotation (4) of the drum shaped axel; and that each accumulator chamber (9<1>-9<8>) is set up for the emptying of collected filtrate via a stationary lock out device (11<1>, 11<2>, 26) that is dimensioned to receive the filtrate that exists in the accumulator chamber and in the corresponding filter element and waste pipe, when the accumulator chamber passes the given filler zone following the emptying zone during the rotation of the drum shaped axel.<IMAGE>

Description

447 208 the filtrate, which is unfavorable when used in a manufacturing process.

According to the present invention, this inconvenience is reduced. The object of the present invention is to provide a rotatable filter of the initial type comprising a simple drainage system for the filter, in which case vacuum vacuums or downcomers of hitherto required length are not needed, or can be omitted altogether. The filter must also allow a high speed and the consequent high capacity.

According to the invention, such a rotatable filter is characterized in that the axial drain pipes each communicate down a chamber for the accumulation of filtrates arranged on the drum-shaped shaft; that each accumulator chamber 'air arranged for collecting and storing filtrates, which during the operation of the filter flows from the corresponding filter elements and drain pipes near the accumulator chamber passes a filling zone during the axial rotation of the drum; and that each accumulator chamber is arranged for emptying collected filtrate via a stationary shut-off device which is dimensioned to receive the filtrate present in the accumulator chamber and in corresponding filter elements and drain pipes, when the accumulator chamber passes a said filling zone following the filling zone after the rotation zone. .

The idea is thus that each accumulator chamber fills completely with the filter before the corresponding filter elements enter such a position that the accumulator chamber causes the accumulated filtrate to be emptied via the stationary exclusion device, which is so dimensioned and arranged that the filtrate empties quickly through it.

According to the invention, there is provided a rotatable filter which can be operated at a high speed and correspondingly high capacity. Since the discharge device for the filter does not have to be provided with downcomers of the same length as the hose pipes used so far, the pumping work is considerably reduced, which means reduced operating costs. The largest field of application for a rotatable filter according to the invention is in the cellulose and paper industry. 447 208 The reason for the rapid emptying is that a part of the filtrate quantity is accumulated in the secondary lathe chambers, so this quantity does not have to be transported axially during the emptying. This amount of liquid, which is then emptied, in turn entrains the filter which is present in the axial drain pipes and in the filter elements.

If downpipes are to be eliminated or considerably shortened, the total internal volume of the filter elements is lost and the axial drain pipes are made several times larger compared to the total corresponding volume of known filter types, ie. the filtrate is accumulated in said parts, in order to then be 'overturned' via a shut-off device for the filter, which in this position must then be under water ice, thus creating an internal negative pressure. It is inappropriate to increase the volume of the filter elements for several reasons, and then only the internal volume of the axial drain pipes remains to be increased. However, if these are made significantly larger, the problem arises that the openings which the removed pulp cake must pass on from the filter elements and down into the collecting funnel become too small with the result that pulp gets stuck in these openings.

(This problem also applies to a filter variant with the channels arranged in groups).

With the embodiment of the present invention, this problem has been eliminated.

In practical tests carried out with a fibrous pulp suspension of abrasive pulp, which is a frequently occurring pulp, it has been found that it is suitable if an accumulator chamber has a volume which is about 40 Z of the volume in the associated drain pipe. the maximum volume available for the filtrate. Of course, the drain pipes are dimensioned with regard to the actual filtrate flow. If the accumulator chambers have a volume of 40 Z of the internal volume of the drain pipes, it has been found that an optimum negative pressure is obtained in the filter elements. Experiments showed that already at a volume of LS Z, an effect of the accumulator chambers began to be felt. 447 208 In other cases with fiber grades of other grades (ling fiber aulfate grade) an optimal result has been obtained in which the accumulator beads have a volume of S-10 times the volume of the axial drain pipes inner (in some isolated cases still have larger cumulative result chamber). ).

The system down accumulator chambers has also been shown to provide great economic benefits in the discs and the axial drain pipes have been standardized in e.g. 3 or 4 dimensions, and the differences in filtrate amount could be taken up by the accumulator chambers. The variation in filtrate flow can for a given filter size be up to about 1:20, (if you compare a hard-dewatered suspension with an extremely light dewatering). During production, there will be a much lower cost if boards and elements are standardized, due to the fact that special tools can be procured. Discs and axial drain pipes are manufactured in larger series and stocked, and according to the order.erhillita dimension: and only the accumulator chambers are manufactured from case to case.

The accumulator chambers are suitably located axially outside the axial drain pipes. In the radial direction, the accumulator chambers can be located outside or inside the drain pipes, or also partly outside and partly inside them.

According to an advantageous embodiment of the invention, the filtration locking device comprises at least one chamber for emptying filtrates located radially inside the accumulator chambers, which emptying chamber is arranged to communicate with the latter via a sliding coupling. It is advantageous to arrange the sliding coupling axially at the level of the radially innermost parts of the accumulator chambers. Another embodiment means that the sliding coupling is located axially outside the accumulator chambers. The exclusion device for the filter is suitably provided with at least one emptying pipe, which opens into a filtrate container. The distance from the center of the filter rotor to the level in the filtrate container should normally be approximately 2.5-3.5 m. The barrel tube does not need to be dimensioned for a certain flow rate but only with regard to the maximum filtrate flow rate. Nor does such a tube need to be straight, which allows a freer placement. Since in various applications it may be advantageous to divide the filtrate into two separate streams, the first of which is usually recycled, it is advantageous that the filter dispensing device comprises two successive discharge channels with separate discharge tubes, seen in the circular axis of rotation. .

In a special embodiment, the accumulator chambers each communicate with a suction channel, which is arranged to during its part of the rotational axis of rotation of the drum shaft with its free end hum under a white surface formed by outgoing filtrate, in that a negative pressure is formed in corresponding accumulator chamber and filter element chamber. during the latter part of the axes rotational turns.

According to an advantageous embodiment, each accumulator chamber has an elongated shape along the direction of rotation of the truncated shaft, its outlet being located in the rear part. As a result, the rotating filter becomes ajilvtake, ie. a naaaakaka is sucked onto the filter element even at a low level of suspension in the filter container.

In some applications, in view of the possibility of releasing the filter cake from the filter element, it may be an advantage if during a thinning zone subsequent part of the three-axis rotation rotation each accumulator cam is arranged to communicate via a connection with a pressure son higher than the atmospheric pressure.

It is particularly advantageous to design a filter according to the invention with the axial drain pipes arranged in groups, as described in SE 443 927. Thereby an extremely high rotational speed of the filter is allowed. He can imagine different variants of this embodiment. Thus, every other drain pipe can be circumferentially displaced backwards in the axis of rotation, or every other drain pipe can be displaced forwards.

In these two cases, it is thus a question of groups, comprising two sewer pipes each. In the embodiments with every other drain pipe displaced backwards, optimal drainage of the filter cake is achieved, on the total volume of the interior of each circumferentially pre-chewed drain pipe and with the latter 447 zos 6 drain pipe communicating filter element and accumulator chamber in the smaller volume chamber. of the non-displaced drain pipe, which is grouped therewith with the displaced drain pipe, and the interior of the filter element and accumulator chamber communicating with the non-displaced drain pipe.

Various arrangements are conceivable to facilitate the removal of the filter cake from the filter elements. A suitable arrangement comprises two flushing nozzles for high-pressure water or compressed air, which in a removal zone are arranged at each side of each filter disc and which are arranged one after the other in the circumferential direction of the filter disc. The rear flush nozzle in the direction of rotation may be arranged for intermittent flushing and preferably with a frequency which at the rotation of the filter corresponds to the frequency of passing drain pipes or groups thereof, while the other flush nozzle may be arranged for continuous flushing. be suitable if both flushing nozzles are arranged to flush internally, preferably at the same time. The spool nozzle in the direction of rotation is suitably directed forwards in the direction of rotation.

The invention will be described in more detail below with reference to the accompanying drawings, in which Figure 1 shows a rotatable filter according to the invention, in longitudinal section; figure 2 shows a detail in figure 1., according to an alternative embodiment; figure 3 shows a section according to the marking III-III in figure 1; figure 10 shows a section according to the marking IV-IV in figure 1; Figure S shows a view of an exclusion device for the filter; Figures 6, 7 and 8 show some alternative embodiments of accumulator chambers, in longitudinal section; Figure 9 shows a section according to the marking IX-IX in Figure 1, according to an embodiment with the axial drain pipes grouped two and two, on an enlarged scale compared with Figure 1; Figure 10 shows a section according to the marking X-X in Figure 1, according to the same embodiment as in Figure 6; . Figure 11 shows a variant of the embodiment according to Figure 9; 447 208 Figure 12 shows, in length, an embodiment provided with a filtering device comprising filter channels; Figure 13 shows an anite according to the marking XIII-XIII in Figure 12.

Figure 1 denotes a container for fiber suspension with 1 and a horizontal filter rotor mounted therein partially submerged rotatably with 2. The latter is composed of a number of annular filter discs 3, which are mounted substantially parallel on a horizontal, truncated shaft coupled to a drive motor. The filter discs 3 are composed of a number of separate filter elements 5, each of which is formed as a hollow body provided with walls of screen cloth, which communicates through the inner of an axially extending drain pipe 6 through a filtrate outlet opening arranged at the radially innermost end. The drum-shaped shaft 4 is thus built up of the axially extending drain pipes 6 and end portions 7 and 8. The axial drain pipes are fixedly connected to each accumulator chamber 91, which in turn is connected via a sliding coupling 1.01 to a stationary locking device for filtrate III. . The sliding coupling 101 is shown in Fig. 1 in a cylindrical, rotationally symmetrical manner, but can also, as shown in Fig. 2, be designed as a flat sliding coupling 102, which connects an accumulator chamber 92 to a stationary locking device for the found 112.

The filter rotor is caused to rotate by a drive motor (not shown) in a manner known per se. A collecting funnel 12 is inserted into the shaft b through one open end thereof, attracting with its upwardly facing opening all of which gave the shaft 4 supported filter discs 3. The collecting funnel 12 is provided with a discharge screw 13. The filter rotor 2 rotates in a direction indicated by an arrow 14 in Figures 3 and 4 and the level of the fiber suspension in the container 1 is indicated by the number l5.

Apol nozzles located in the removal zone for removal of formed fiber cakes are denoted by 30 and 31.

In order for a rotatable filter of the type shown to function optimally, the negative pressure acting below the level 15 in the outside of the filter element 447 208 pre-applied a negative pressure acting on the inside of the filter elements S 'during certain parts of the rotational revolution.

As shown in Figure 4, the filtration shut-off device 11 comprises four chambers, 16, 17, 18 and 19. In this case, the chamber 16 communicates with the atmosphere via a pipe 20 (see Figure S), the chamber 17 being a first negative pressure chamber, where the negative pressure is communication with an emptying tube 21 opening into a filtrate hopper 22. The filtrate from the latter chamber is usually recycled. The chamber 18 is a second negative pressure chamber, where the negative pressure is obtained by communication via an emptying pipe 23 with a filtrate container 24. The filtrate in this container is cleaner than that in the filtrate container 22 and is usually referred to as "clear filter".

The camera 19 communicates via a connection 25 with an overpressure source and has the purpose of creating overpressure in the filter elements so that the fiber cakes are quickly detached from the filter elements. In some cases only a negative pressure chamber is needed, and even the positive pressure chamber can sometimes be BVVBIBS- Figure 6 shows an embodiment of the accumulator chamber 93, where this is located substantially - radially - outside the agile drain pipes.

This design gives the highest capacity then. the filter was used for dewatering.

Figure 7 shows an embodiment in which the accumulator chamber 94 is located substantially radially inside the axial drain pipes. This design provides the lowest fiber losses when the filter is used for fiber capture. Figure 8 shows an embodiment in which the accumulator chamber 95 - radially speaking - is located both inside and outside the drain pipes. This embodiment is used in special cases.

In Figures 9 and 10, which show an embodiment where every other drain pipe is displaced backwards, i.e. If the drain pipes are arranged in groups of two and two, the filter elements are denoted by 52 and -53 and the drain pipes by 62 and 62, respectively. 63 while the accumulator chambers connected to the drain pipes are denoted by 96 and 97. 447 208 The pre-displacement of the azile drain pipes means that the hydrostatic pressure difference on the downside side of the filter elements becomes slightly smaller over the screen of the filter elements which communicate with it. by making the total internal volume of the filter elements, the drain pipes and the accumulator chambers V 52 + V 62 + V 96 slightly smaller for these compared with the corresponding total internal volume in connection with the non-displaced drain pipes.

An alternative embodiment with the drain pipes arranged in groups is shown in figure 11, the door - seen in the direction of rotation - every other axial drain pipe is displaced forwards. Thereby, the interior of a first filter element 54 will communicate with the interior of a first axial drain pipe 64, which is located, seen in the direction of rotation of the shaft 4, after this first filter element or in the rear part thereof, while the interior of a second filter element S5, with the same approach, after the first filter element, in connection therewith, communicates with the interior of a second axial drain pipe 65, arranged in group with the first drain pipe.

This embodiment, comprising the said arrangement of the axial drain pipes and accumulator storage chambers has proved to be particularly favorable, since such a rotatable filter can be operated with an extra high rotational speed and thereby still obtain a high dry content in the outgoing fiber mass. Figure 12 shows an embodiment of the rotatable filter according to the invention with an alternative embodiment of the exclusion device for the filter. The accumulator chamber 98 is suitably designed according to Figure 6, but the negative pressure is created there in such a way that each accumulator chamber communicates with its own emptying channel, suitably in the form of a suction channel 26 bent back in the direction of rotation. This suction channel mouth 27 is in certain positions during rotation under water trap (the liquid surface is denoted by 28), which leads to a negative pressure being created in the accumulator chamber and in the interior of the drain pipes and filter elements communicating with it. Accumulator chamber: 98 volume dimensions pi as previously described.

The suction channel 26 can have a number of different embodiments. In all of these, the mouth of the suction duct is in certain positions under water lock. The mode of operation of a filter according to Figures I-S is as follows: When - during the rotation - a filter element 5 turns into the suspension, it is successively filled up internally with the filter and on the outside of the element a cake is formed. The filtrate also successively fills the interior of the drain pipes and the accumulator chambers 9, before these are brought into communication with the first pressure chamber 17 of the shut-off device. Since this communication is at hand, the filter is emptied from the filter extension S via the drain pipes 6 and via the accumulator chambers 9 through the chamber 17 and the emptying pipe 21 to the filtrate container 22. The function of communication with the chamber 18 'is analogous. Upon subsequent communication with the overpressure connection 25, the filter elements 5 are subjected to internal overpressure, whereby the fiber cakes loosen rapidly to fall via the opening 33 into the collecting funnel 12 and are then discharged by the discharge screw 13.

The function according to the embodiment shown in Figures 9 and 10 is analogous to the one just described, but since the openings between the axial drain pipes in this case are larger and thus allow faster rotation of the filter rotor, this relationship can be optimally utilized by the mulator chambers considerably shorten the ignition time of the filter.

The variant shown in Figures 11 and 1.2 functions in the same way as the embodiment just described, with the exception that after the accumulator chamber 98 has been filled with the filter, the suction leg 26 begins to be filled with filtrate. The suction leg is then successively completely filled with the filter.

The mouth 27 of the suction leg then comes below the liquid surface 28, whereby on the outlet side of the filter a negative pressure is formed in the accumulator chamber, and the interior of the drain pipes and filter elements communicating therewith.

When - during the root station - the mouth 27 of the suction leg leaves the water trap, air goes backwards through the suction legs and the negative pressure in the filter element ceases. Of course, other embodiments are conceivable within the scope of the invention. In some cases it is suitable to arrange accumulator chambers at both ends of the filter rotor, etc. The length of the emptying pipes can of course also vary, and emptying pipes of the barometric downpipe type are also conceivable in special cases. 447 208 ll For all embodiments shown, the accumulator chamber allows a higher rotational speed and thus a higher capacity. In order to be able to fully utilize this advantage, a new arrangement for the removal spraying (removal spraying) is arranged.

In filters according to SE 387 546, a flushing nozzle has previously been arranged in the removal zone on each side of the filter discs and which flushes continuously. The previously known method has been found to give certain problems in connection with higher rotational speeds, as often a larger or smaller amount of mass hangs over the axial drain pipes. However, this disturbance has been eliminated by arranging on each side of the filter elements two flushing nozzles 30 and 31: in peripheral direction one after the other as shown in figure 3 and figure 9 and that in the direction of rotation the rear flushing nozzle 30 is made to work intermittently, i.e. it suitably comes into operation approximately when an axial drain pipe or group of drain pipes passes the apol nozzle, below which the second flush nozzle is directed forward in the rocatxonazikning (vinxeinof-> o °).

The flushing nozzles viaaa in a longitudinal section in figure 6.

An alternative way which has also been found to work is that both flushing nozzles 30 and 31 apolar intermittently and preferably substantially simultaneously. Each time they come into operation, a certain part of the fiber cake is washed away.

The above-mentioned rinsing nozzles normally work with water under high pressure. In cases where a higher outgoing pulp concentration is required, use compressed air instead of high pressure water.

Claims (20)

447 208 12 Claims "_ A rotatable filter, preferably intended for separating fibers from a fiber suspension, comprising annular filter discs (3), each composed of a plurality of hollow filter elements (5) provided with walls of screen cloth, one in a container (1) with for example fiber suspension rotatably arranged horizontal trough-shaped shaft (4), on which the annular filter discs are mounted substantially parallel and axially in line with each other, drain pipes (6) for filtrates, which extend axially long mantle of the trumpet-shaped shaft (4) and are connected to the filter element (5) via outlets at the latter: radially innermost parts, the interior of the filter elements, which are located axially in line with each other along the drum-shaped shaft (4), being arranged to communicate with the interior of one and the same axial drain pipe (6), and a collecting funnel (12) for fiber cakes, which extends centrally through the drum-shaped shaft (4) along all the filter discs (3), k 3 nnetec k- fl lt ÄV - that the axial drain pipes (6) communicate with respective chambers (91-98) for accumulating the filter arranged on the drum-shaped shaft (4). that each accumulator chamber (91-198) is arranged for collecting and storing filtrates flowing from the corresponding filter elements and drain pipes during the operation of the filter, when the accumulator chamber passes a filling zone during the rotation of the drum-shaped shaft (4), and - that each accumulator chamber (91 -98) is arranged for emptying collected filtrate via a stationary shut-off device (III, 112, 26), amine deionized to receive the filtrate present in the accumulator canary and 1 corresponding filter element and drain pipe, when the accumulator chamber passes a said filling zone subsequently emptying zone during the rotation of the drum-shaped shaft. 447 208 13 A rotatable filter according to claim 1, wherein the accumulator channels (91-98) are located axially outside the axial drain pipes (6). A rotatable filter according to claim 2, wherein the accumulator channels (91, 92, 93) are located substantially radially outside the axial drain pipes (6). A rotatable filter according to claim 2, characterized in that the accumulator chambers (94) are located substantially radially inside the axial drain pipes (6). Rotatable filter according to claim 2, characterized in that the accumulator chambers (95) are located partly radially inside, dividing radially outside the axial drain pipes (6). A rotatable filter according to any one of claims 1-5, characterized in that the filtration discharge device (111) comprises at least one emptying chamber located radially inside the emulsifier chambers (91), which emptying chamber is arranged to communicate with the latter via a sliding coupling (101). ). A rotatable filter according to claim 6, wherein the sliding coupling (101) is located axially flush with the radius of the accumulator chambers (91): innermost parts. A rotatable filter according to claim 6, characterized in that the sliding coupling (102) is located axially outside the accumulator chambers (92) - A rotatable filter according to any one of claims 6-8, wherein the filter filtration device (111, llí) is provided with at least one barrel tube (21, 23) opening into a filtrate container (22, 24). 447 208 14 A rotatable filter according to claim 9, characterized in that the dispensing device for the filter (111, 112) comprises two successive barrel chambers (17, 18) with separate discharge pipes (21, 23) seen in the drum-shaped shaft: ( 4) direction of rotation. A rotatable filter according to any one of claims 1-5, wherein the accumulator chambers (98) each communicate with their eye channel (26), which is arranged to rotate with a free end under a part of the drum-shaped shaft (4). resulting in a white surface (28) formed by the outgoing filter, in that a negative pressure is formed in the corresponding accumulator chamber, drain pipe and filter element during the latter part of the rotational rotation of the shaft. A rotatable filter according to any one of claims 1-11, characterized in that each accumulator chamber (96, 97) has a ht-knitted shape along the true-to-shape axis (4) direction of rotation, its outlet being in the rear part. A rotatable filter according to any one of claims 1 to 12, characterized in that during an emptying zone the following part of the drum-shaped shaft: (4) rotational turns, each accumulator chamber (91, 98) is arranged to communicate via a connection ( 25) with a pressure which is higher in atmospheric pressure. A rotatable filter according to any one of claims 1-13, characterized in that the axial drain pipes (6) seen in a cross section through the drum-shaped shaft (4) are arranged in groups of at least two drain pipes (sz, 63, e , 65). A rotatable filter according to claim 14, characterized in that seen in a cross section through the truncated shaft (4), every second drain pipe (62) is circumferentially displaced rearwardly in the axis (4) in the direction of rotation, so that groups of two drain pipes (62, 63) in each group is formed. 447 208 15 A rotatable filter according to claim 16, characterized in that seen in a cross section through the triangular shaft (6), every other drain pipe (65) is circumferentially offset forward in the direction of rotation of the shaft (4), so that groups of two drain pipes (64, 65) in each group are formed. A rotatable filter according to claim 15, characterized in that the total volume of the interior of each circumferentially offset drain pipe (62) and the interior of the filter element (52) and accumulator jug (96) communicating with the latter drain pipe is smaller than the total volume of the interior of the non-displaced drain pipe (62) grouped with the displaced drain pipe (63), and the interior of the filter element (53) and accumulator chamber (97) communicating with the non-displaced drain pipe. 18. A rotatable filter according to any one of claims 1-17, characterized in that in a removal zone on each side of each filter disc are two flushing nozzles (30, 31) for high pressure water or compressed air arranged one after the other in the circumferential direction of the filter disc to remove formed fiber cakes . - * _ A rotatable filter according to claim 18, characterized in that the rear flushing nozzle (SE) seen in the direction of rotation at each side of the filter discs is arranged for internal flushing, preferably with a frequency son at the rotation of the filter corresponding to the frequency of passing drain pipes (6) or groups of these (62, 63-64, 65) while the second rinsing nozzle (31) is arranged for continuous rinsing. A rotatable filter according to claim 18, characterized in that the two flushing nozzle pieces (30, 31) at each side of the filter discs are arranged to flush internally, preferably substantially simultaneously. Zl. A rotatable filter according to any one of claims 18-20, characterized in that the rear coil piece (30) seen in the direction of rotation is directed forwards in the direction of rotation at each side of the filter discs.