EP0068095A2 - Pusher centrifuge - Google Patents

Abstract

In a push centrifuge, at least one rotatable sieve drum (2) is mounted in a housing (1). In this, a back and forth sliding floor (4) for pushing a filter cake to discharge openings (7) for the product is arranged. To process thin suspensions with the pusher centrifuge, the pusher floor (4) is arranged to be oscillatable between turning points (5 and 6), preferably close to the imaginary center line (3) of the screening drum (2). A feed pipe (8) for supplying a suspension to be separated leads coaxially to the screening drum (2), and its outflow opening (9), pointing radially outwards, lies in the middle between the turning points (5 and 6) of the moving floor (4). This has a central opening (10) which opens a passage for the feed pipe (8). When the pushing floor (4) oscillates back and forth relative to the outflow opening (9), the outflow opening is alternately on one or the other side of the moving floor. There are discharge openings (7) for the product on both sides of the screening drum (2).

Description

The application relates to a pusher centrifuge with at least one sieve drum rotatably mounted in a housing and with a disk-shaped sliding floor arranged in and coaxially with the sieve drum, which is rotatable and can be moved back and forth between turning points relative to the sieve drum and for coating one Longitudinal section of the filter surface of the screen drum and for pushing a filter cake along the screen drum in the direction of discharge openings for the filter cake is provided.

Such push centrifuges are known for example from DE-AS 1 065 333.

The general advantages of the push centrifuge, such as high throughput and low residual moisture, are associated with the disadvantage that the centrifuge can only be fed with relatively high solids concentrations. If the inlet concentration decreases, there is a risk of being washed up. Flooding is the operating state when the drainage time between two strokes of the moving floor is not sufficient to drain the swamp in front of the moving floor to such an extent that the cake can be transported. The sump is the longitudinal section of the screening drum that is swept by the moving floor. If the drainage is not sufficient, there is still a suspension in the swamp when the moving floor returns, which cannot be moved as a cake, which leads to the above-mentioned flooding.

In order to solve this problem, ie to achieve adequate drainage in the sump, various attempts have been made to install additional sieve surfaces in the centrifuge on the path of the suspension to be separated towards the sump. However, these measures have not succeeded to expand the range of use of the push centrifuge towards thin suspensions.

In the case of suspensions that are relatively easy to sediment, such thin suspesions are first thickened by static sedimentation and only then introduced into a batch centrifuge. In the case of poorly sedimenting suspensions, other machines may be used for pre-thickening, e.g. Centrifugal decanters with which it is also possible to process thin suspensions. These systems are structurally quite complicated and accordingly expensive and problematic in terms of operation.

The invention has for its object to provide a push centrifuge with which thin suspensions can be processed.

This object is achieved according to the invention in that the turning points are preferably on both sides of the imaginary center line of the sieve drum and that a feed pipe is arranged coaxially to the feed drum for feeding the suspension to be separated, the outlet opening, pointing radially outwards, in the middle between is the two turning points of the moving floor, the moving floor having a central opening, which opens a passage through the feed pipe through the moving floor, so that the outflow opening of the feed pipe alternately at one or the other when the push floor is pushed back and forth relative to the outflow opening Side of the moving floor, and that there are discharge openings for the filter cake on both sides of the sieve drum.

With this arrangement according to the invention, it is possible to carry out a new method when using a pusher centrifuge: the flow of the suspension flowing in is only allowed into the sump when the sump section has been exposed by moving the push floor, so that the cleared sieve surface is the liquid of the entering Can pass suspension. The suspension to be separated is distributed automatically to the two drum sections by moving the moving floor, but the flow of the suspension through the feed pipe remains uninterrupted, so that there are no pressure surges in the pipeline carrying the suspension.

According to one embodiment of the push centrifuge according to the invention, it is provided with a washing device for washing the filter cake on the sieve surface of the sieve drum.

According to a further embodiment, it is possible to design the push centrifuge as a two-stage centrifuge.

• Fig. 1 im Längsschnitt die Schubzentrifuge, in der sich der Schubboden an einem Wendepunkt befindet,
• Fig. 2 dieselbe Schubzentrifuge, bei welcher jedoch der Schubboden an dem anderen Wendepunkt steht,
• Fig. 3 eine Ausführung des Speiserohres im Längsschnitt und in einem dazugehörenden Querschnitt gemäss Linie I/I,
• Fig. 4 einen Teil der Zentrifuge in vergrössertem Massstab,
• Fig. 5 einen anderen Teil der Zentrifuge in vergrössertem Massstab,
• Fig. 6 ein weiteres Ausführungsbeispiel im Längsschnitt,
• Fig. 7 eine anwendbare Siebtrommel im Längsschnitt,
• Fig. 8 schematisch, eine zweistufige Schubzentrifuge.

The subject matter of the invention is explained in more detail below on the basis of the description of some exemplary embodiments. The description refers to drawings in which:

• 1 is a longitudinal section of the push centrifuge in which the push floor is at a turning point,
• 2 shows the same pusher centrifuge, but with the push floor at the other turning point,
• 3 shows an embodiment of the feed pipe in longitudinal section and in an associated cross section according to line I / I,
• 4 shows a part of the centrifuge on an enlarged scale,
• 5 shows another part of the centrifuge on an enlarged scale,
• 6 shows another embodiment in longitudinal section,
• 7 an applicable screen drum in longitudinal section,
• Fig. 8 schematically, a two-stage pusher centrifuge.

A screen drum 2 is rotatably mounted in a housing 1 of the pusher centrifuge. In the screening drum 2 and coaxially with it is arranged a disc-shaped moving floor 4 which is rotatable and can be moved back and forth in the longitudinal direction between two turning points, 5 in FIG. 1 and 6 in FIG. 2, relative to the screening drum 2. During this back-and-forth movement, the push floor 4 sweeps a longitudinal section between the turning points 5 and 6 of the filter surface of the screening drum 2 and in each case moves a filter cake along the screening drum 2 in the direction of discharge openings 7, which are provided for the filter cake to be let out. Each time after the filter cake has been moved in the direction of the discharge openings and after the pushing floor has been moved to the respective turning point, an empty space is created between the filter cake and the moving floor, the sump, which is designated here by 28.

The turning points 5 and 6 are preferably on both sides of the imaginary center line 3, in FIG. 1, the sieve drum 2, the push floor 4 thus oscillates in a longitudinal section of the sieve drum about this imaginary center line 3. For feeding a suspension to be separated into the sieve drum 2 there is a Provided feed tube 8 which is arranged coaxially with the sieve drum. An outflow opening 9 of the feed pipe 8 lies in the middle between the two turning points 5 and 6 of the push floor 4 and points the flow of the suspension radially outwards, ie in the radial direction to the screen surface of the screen drum 2. The push floor 4 has a central opening 10 that clears a passage for the feed tube through the moving floor as it reciprocates relative to the orifice. In this way, the outflow opening 9 of the feed pipe 8 is alternately on one or the other side of the moving floor 4 when the pushing floor 4 is pushed back and forth relative to the outflow opening. Thus, the inflow of the suspension to be separated is introduced into the sump 28, when the sieve bottom 4, after pushing the filter cake away to the next turning point has moved and thus exposed the longitudinal section of the filter surface, so that the liquid of the suspension, not hindered by any filter cake layer, is discharged through the sieve surface of the drum 2. In this way, the filter cake is pushed along the screen drum 2 in both longitudinal directions. To discharge the filter cake of the product from the sieve drum, there are 2 discharge openings 7 for the product on both sides of the sieve drum.

The feed pipe 8 can be provided with a baffle plate to direct the flow in the radially outward direction, e.g. 1 and 2 can be seen at the end of the tube 8. However, it would also be possible, as shown in FIG. 3, to close the feed pipe 8 with a cover and to arrange openings 9 for the outflow of the suspension to be supplied.

As can be seen particularly clearly in FIG. 4, the wall delimiting the central opening 10 in the moving floor 4 has a wedge-shaped cross section 11 which points against the direction of the flow direction of the suspension flowing out radially and for distributing the flow of the suspension serves.

Advantageously, a friction disc 12 or 13 arranged coaxially and parallel to the moving floor is attached to the moving floor 4 on both sides. The attachment is provided by a few rods 24, which are each arranged between the moving floor and the respective friction disc 12 or 13. Between the sliding floor 4 and the friction disk 12 or 13 there is in each case a space for a flow of the suspension to be separated in the direction of the screening surface of the screening drum 2. The friction disk 13 attached to the side of the sliding floor 4 facing the feed pipe 8 is provided with a central opening 14 provided for the passage of the feed pipe. These friction disks 12 and 13 thus direct the flow of the suspension into the space of the sump 28 and ver prevent the suspension from spraying into the other interior of the sieve drum 2. Together with the wall of the moving floor 4, they accelerate the suspension in the radial direction.

The structure fastened together, consisting of the sliding floor 4 and the friction disks 12 and 13, is supported, rotated and displaced by means of a shaft 25 which is fastened to the friction disk 12.

1 and 2, the screen drum 2 is overhung in the housing 1, the embodiment according to FIG. 6 shows storage on both sides of the screen drum 2 in the centrifuge housing 1.

According to the example according to FIG. 7, a push centrifuge according to the invention can be built, in which the sieve drum has a cylindrical part 15 in the middle, which merges on both sides into a conical part 16 that widens in the direction of the discharge openings 7 on both sides of this sieve drum. This screen drum is mounted on both sides in the housing. The push floor 4 is slidably arranged along the cylindrical part 15. With a sieve drum of this type, on the one hand an extension of the sieve surfaces of the drum is made possible and at the same time the transport of the filter cake and its discharge through the discharge openings 7 along such an elongated sieve surface are facilitated.

The pusher centrifuge, as shown in FIGS. 1, 2 and 5, is provided with a washing device 17 and 18 for washing the filter cake on the sieve surface of the sieve drum 2. The washing device 17 has a body 21 which is built into the interior of the screening drum 2 and is fastened to the wall of the screening drum. Lines 22 lead through this body to nozzles 23, through which a washing liquid is thrown out in the direction of the filter cake on the sieve surface of the sieve drum 2. The Washing liquid is fed through a line 19 and is passed into a channel 20 on the wall of the screening drum 2, from which the lines 22 lead to the nozzles 23. The body 21 can, as is particularly clearly shown in FIG. 5, serve for an additional mounting of the shaft 25, which carries the structure from the sliding floor 4 and the two friction disks 12 and 13. On the other side of the pusher centrifuge, it is possible to wash the filter cake by means of a few pipes 18, through which the washing liquid is fed into the interior of the sieve drum 2.

A two-stage centrifuge according to the invention is shown schematically in FIG. Two nested drum 2 ¹ and 2 ² forming a two-stage centrifuge are provided. The outer screening drum 2 ² is rotatable by means of a shaft 26 which is attached to its end wall. The structure consisting of the sliding floor 4 and the friction disks 12 and 13 is also fastened to this end wall by means of the rods 29. The push floor 4 is arranged in the middle of the screening drum 2 ² . The screening drum 2 ¹ is nested in the screening drum 2 ² and can be displaced axially relative to the latter. For this longitudinal axial, oscillating displacement pull rods 27 are used, which lead through slots 30 in the screen drum 2 ² and are connected to the screen drum 2. The structure of the moving floor 4 and the friction disks 12 and 13 rotates together with the sieve drum 2 ² and is axially immovable relative to the sieve drum 2 ² . A relative displacement between the sliding floor 4 and the screening drum of the first stage 2 ¹ is achieved by moving this screening drum by means of the tie rods 27. This longitudinally axial, oscillating displacement of the sieve drum 2 ¹ on the one hand transports the filter cake on the sieve surface of the sieve drum 2 ¹ , so that it is pushed onto the sieve surface of the sieve drum of the second stage 2 ² , and at the same time it is also along the sieve surface of the sieve drum the second stage 2 ² in the direction of the discharge openings 7, on both sides of the screening drum 2 ² , and falls there as a product.

The relative displacement between the outflow opening 9 of the feed pipe 8 and the sliding floor 4, which is arranged here axially axially immovable, that is to say remaining in its longitudinal axial position, is achieved by longitudinally axially, oscillating displacement of the feed pipe 8 ¹ . The two displacements: the displacement of the sieve drum 2 ¹ relative to the moving floor 4 and the displacement of the feed pipe 8 ¹ relative to the moving floor 4 take place in the same cycle.

Similarly, it would also be possible to build multi-stage centrifuges in the manner of the invention.

Claims (6)

1.Push centrifuge with at least one sieve drum rotatably mounted in a housing and with a disc-shaped sliding floor arranged coaxially in the sieve drum, which can be rotated and displaced in the longitudinal direction between turning points relative to the sieve drum, and for coating a longitudinal section of the Filter surface of the screening drum and for pushing a filter cake along the screening drum in the direction of discharge openings for the filter cake is provided,
characterized,
that the turning points are preferably on both sides of the imaginary center line (3) of the sieve drum and that a feed pipe (8 or 8 ¹ ) is arranged coaxially to the feed drum (2) for feeding the suspension to be separated, the outlet opening (9) , pointing radially outwards, lies in the middle between the two turning points (5 and 6) of the moving floor (4), the moving floor having a central opening (10) which opens a passage for the feed pipe through the moving floor, so that the outflow opening of the feed pipe when the pushing floor (4) is pushed back and forth relative to the outflow opening (9) is alternately on one or the other side of the pushing floor, and that on both sides of the sieve drum (2) there are discharge openings (7) for the filter cake available. 2. A pusher centrifuge according to claim 1, characterized in that the wall defining the central opening (10) in the pusher floor (4) for distributing the flow of the radially outward flowing suspension has a wedge-shaped cross section (11) pointing against the direction of the flow direction. 3. A push centrifuge according to claim 1, characterized in that on the push floor (4) on both sides a coaxial and parallel to it arranged friction disc (12 or 13) is fixed, in each case between the push floor (4) and the friction disc (12, or 13) leaving a space for a flow of the suspension to be separated in the direction of the sieve surface of the sieve drum (2), the friction disc (13) attached to the side of the sliding floor facing the feed pipe (8) having a central opening (14 ) is provided for the passage of the feed pipe. 4. A pusher centrifuge according to claim 1, wherein the sieve drum has a - cylindrical part (15 in Fig. 7) which merges on both sides into a conical part (16) which widens in the direction of the discharge openings (7), the sieve drum opening is mounted on both sides in a housing, and in which the sliding floor (4) is arranged to be displaceable along the cylindrical part (15). 5. pusher centrifuge according to claim 1, which with a washing device (17 or 18) for washing the filter cake on the sieve surface of the Siebtrom-. mel (2) is provided. 6. A pusher centrifuge according to claim 1, comprising two nested, a two-stage centrifuge forming sieve drums (2 ¹ and 2 ² in _F ig. 8) at which the sieve drum of the first stage (2 ¹⁾ to the sliding base (4) and at a relatively the sieve drum of the second stage (2 ² ) is displaceable in the axial direction, with this relative movement also the filter cake being movable along the second stage, and in which the feed tube (8 ¹ ) relative to that in the axial direction in its longitudinal axial position remaining moving floor (4) is displaceable.

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