EP4192597A1 - Apparatus for continuously filtering a sludge suspension - Google Patents

Abstract

The invention relates to an apparatus for continuously filtering a sludge suspension, having a hollow shaft (2) which is rotatably mounted in a housing (1) and which is fluidically connected to the inner chamber (6), which is surrounded by a filter membrane (5), of a discoid filter element (3) which radially protrudes from the hollow shaft (2), for removing a filtrate. In order to enable a higher throughput of the filtrate, independently of the solids content of the sludge suspension to be filtered, the filter cake thickness and the filtration duration, according to the invention the radius (r) of the filter element (3) increases in the circumferential direction from a low pressure radius r_i to a high pressure radius r_h in order to reduce the free housing cross section. Drawing_references_to_be_translated

Description

Device for the continuous filtration of a sludge suspension

technical field

The invention relates to a device for continuously filtering a sludge suspension with a hollow shaft rotatably mounted in a housing which is flow-connected to the interior of a disc-shaped filter body surrounded by a filter membrane and protruding radially from the hollow shaft for draining off a filtrate. Of course, other suspensions or filterable mixtures can also be separated from one another with such a device.

State of the art

A device for filtering a suspension is known from WO2000047312A1. For this purpose, the cavity of a filter body surrounded by a filter membrane is flow-connected to a hollow shaft. If a suspension flows against the filter body, the solid particles in the suspension are held back by the filter membrane, while a liquid portion of the suspension flows through the interior of the filter body to the hollow shaft and can be discharged as filtrate. With increasing filtration time, the thickness of the filter cake covering the filter membrane increases, which significantly reduces the filtrate flow and thus the filtration efficiency. With several filter bodies mounted one behind the other in the axial direction, the solids content increases in the direction of flow of the device. In order to maintain a constant filtration speed, the pressure on the suspension side can be increased, or the filter cake can be cleaned off the filter membrane at regular intervals. In WO2000047312A1 the cleaning step is made possible by rotating the filter membrane around the hollow shaft. The disadvantage of this, however, is that, especially in the case of suspensions with a high solids content and when strongly attached to the Filter membrane pressed filter cake such a relative movement for cleaning the filter cake is not sufficient, which is why WO2000047312A1 further proposes to provide two mutually parallel hollow shafts, each with a plurality of filter bodies arranged thereon. With a corresponding arrangement of the hollow shafts, the relative movement of the filter bodies arranged on the different hollow shafts can result in mutual shearing of the filter cake on the filter membrane. Naturally, shearing can only take place if the filter cakes of the respective filter membranes are sufficiently thick that there is contact between the respective filter cakes, so that the method is only effective after a certain filtration time or filter cake thickness. In addition, due to the design, only part of the filter cake can be removed by shearing.

Presentation of the invention

The invention is therefore based on the object of creating a device of the type mentioned at the outset, which allows a higher throughput of the filtrate independently of the solids content of the suspension to be filtered, the filter cake thickness and the filtration time.

The invention solves the problem in that the radius of the filter body increases in the circumferential direction from a low-pressure radius to a high-pressure radius in order to reduce the free housing cross-section. As a result of this measure, the suspension in the region of the filter body, which has been set in rotation, is subjected to a pressure profile which changes over time and is preferably sinusoidal. If the free housing cross-section at a reference point, i.e. the cross-section in the housing that is not occupied by the filter body, is reduced by rotating the filter body and thus by moving the high-pressure radius towards this reference point, the suspension is compressed at this reference point. This increases the pressure difference between the suspension side and the filtrate side, which promotes rapid filtration of the suspension. during this filtration the liquid portion of the suspension penetrates the filter membrane, gets into the interior of the filter body and is discharged via the hollow shaft. The solid particles, on the other hand, are held back by the filter membrane and accumulate on it as a compressed filter cake, which forms a resistance for the liquid portion of the suspension, as a result of which the filtrate flow subsequently decreases. Due to the design of the filter body according to the invention, further rotation of the filter body results in an expansion of the free housing cross section at the reference point, as a result of which the pressure exerted on the suspension decreases. This pressure fluctuation promotes the loosening and thus also the detachment of the filter cake from the filter membrane. In addition, the centrifugal forces caused by the rotary motion of the hollow shaft can be used to support the detachment of the filter cake. Due to the pressure increase and pressure reduction according to the invention, constant filter conditions can be created on the filter body even after a long filter period. Complete cleaning can be promoted by strong turbulence in the suspension. This can be achieved by a rapid pressure drop at the reference point. Such a rapid pressure drop is achieved when the filter body has a compression section, which is formed starting from the low-pressure radius by increasing the radius of the filter body up to the high-pressure radius, and an expansion section, which is formed starting from the high-pressure radius by decreasing the radius of the filter body up to Low-pressure radius is formed, the lowering of the radius in the expansion section takes place faster than the increase in the radius in the compression section. Due to the relatively slow increase in pressure at the reference point, the filter cake can be sufficiently drained before it is cleaned off by the sudden pressure drop in combination with the rotary movement of the filter body. In the context of the invention, radius means the distance between the pivot point of the filter body and a point on the circumference of the filter body. The filter body has an interior space surrounded by a filter membrane. In this context, surrounded means that the filter membrane delimits the interior at least in sections. The device according to the invention can easily be subjected to thorough cleaning at regular intervals as part of maintenance work. For this purpose, water or another suitable cleaning agent is pumped from the hollow shaft to the interior of the filter body and then through the filter membrane into the housing of the device. In the process, particularly strongly pressed filter cake residues are released from the filter membrane, which can be flushed out of the housing together with other suspension residues.

In order to generate a varying pressure distribution in the axial direction of the device at any time, it is proposed that several filter bodies be arranged on the hollow shaft in the axial direction, the high-pressure radii of which are offset from one another in a circumferential direction. Thus, the successive high-pressure radii form a spiral revolving around the hollow shaft. Due to the pressure differences running in the axial direction, turbulence is forced on the suspension, which further improves the cleaning of the filter membranes and thus the filtration efficiency. It has been found that particularly favorable filtration conditions result when the offset of the high-pressure radii between two filter bodies that follow one another in the axial direction is between 1° and 45° inclusive, preferably between 5° and 20° inclusive. The distance between the filter bodies arranged in the axial direction relative to one another can be constant or variable depending on the mixture to be filtered.

In order to increase the throughput of the device without significantly increasing the production costs and also to create improved filtering efficiency, at least two parallel hollow shafts can be provided in the housing, the filter bodies of which are offset from one another in the axial direction with a gap. It is basically sufficient that only one of the hollow shafts is designed according to the invention, while the other hollow shaft can also be flow-connected to other filter bodies and does not have to be rotatably mounted. As a result of the measures described, varying pressure distributions can also occur in housings with large cross sections whose entire cross-section are established. Due to a relative movement of the hollow shafts to one another, increased turbulence occurs between the filter bodies arranged on them. The filter bodies can advantageously together form a mixer which ensures homogeneous mixing of the suspension, which further promotes uniform filtration.

So that a highly compressed filter cake can also be cleaned from the filter membrane without having to stop the device and thus stopping the filtration, it is recommended in a particularly efficient embodiment of the device according to the invention that the filter bodies of the at least two hollow shafts parallel to one another are located overlap at least partially in the axial direction. As a result, with a corresponding rotary movement of the filter bodies, the filter cake shears off one another between filter bodies that are adjacent in the axial direction. Due to the inventive shape of the filter bodies in combination with the overlapping of the mutually staggered filter bodies of the respective hollow shafts, the filter bodies can act as shredders for sludge lumps in the suspension, which promotes further homogenization.

On an industrial scale, continuous cross-flow filtration is commonly used. This means that the suspension has to be conveyed along the filter membrane, for example by means of pumps. Particularly in the case of suspensions with a high solids content, this requires extremely robust pump systems as well as a large amount of additional energy so that the suspension can be pumped over the entire filtration surface, ie the filter membranes. The arrangement of two parallel hollow shafts with filter bodies offset from one another and at least partially overlapping in the axial direction results in the advantage that the free cross section between the hollow shaft with the filter bodies according to the invention and the other hollow shaft decreases cyclically, so that the offset of the high-pressure radii in the axial direction a displacement of the suspension in the axial direction and thus a promotion of the suspension the device takes place. This means that both suspensions with a low solids content and suspensions with a solids content of up to 98% can be pumped. Depending on the solids content of the suspension, it may be necessary to adjust the housing diameter and the dimensioning of the filter body. To further increase the pressure difference, an additional pump can be provided on the suspension side and/or a vacuum pump on the filtrate side. The displacement effect described can also be used to operate the device according to the invention exclusively with the inherent pressure of the suspension to be filtered, because if the pressure of the suspension to be filtered is sufficient, the filter bodies limiting the free cross section are themselves displaced and the hollow shaft is thus set in rotation. The device can thus be used, for example, for the energy-saving filtration of flowing water, with the flow of the flowing water being used to drive the hollow shaft.

In order to achieve uniform filter conditions over the cross section of the housing and at the same time enable energy-efficient conveyance of suspensions with a high solids content, it is proposed that the hollow shafts with the filter bodies arranged thereon are mirrored to one another about a common plane of symmetry. With this arrangement, the suspension can be actively pressed from filter body to filter body across the cross section, with the cyclically decreasing, largest free cross section between the filter bodies and the housing being enlarged, so that even suspensions with a high solids content that are difficult to convey are transported in the direction of the outlet can be carried out without having to rely on pumps or other conveying devices. This also enables the dimensioning of particularly long devices for the continuous filtration of suspensions, the length of which was limited in previously known devices due to the energy-intensive conveyance with the solids content of the suspension increasing with the length of the device. This robust conveyance of the suspension means that a significantly higher solids content can be achieved in the continuous process. So that the device according to the invention can be used to make up the suspension, it is proposed that downstream of the filter body, a pelletizing device be installed, which is driven by the hollow shaft. The pelletizing device can be, for example, a pelletizing disk, which agglomerates the dewatered sludge.

In order to be able to implement filter bodies with particularly large diameters and at the same time to facilitate their assembly on the hollow shaft, a filter body can comprise a plurality of filter body segments which are preferably connected to one another in a form-fitting, detachable manner. The filter body segments can be connected to one another, for example, via tongue and groove connections running in the radial direction, which facilitates consecutive arrangement of the individual filter body segments on the hollow shaft for assembling the filter body. The cavities of the filter body segments can be separated from one another, so that a fluid connection between different filter body segments of a filter body can only take place via the hollow shaft. In order to form the radii of the filter body according to the invention, the filter body segments of a filter body have different geometric configurations, it being possible for the radii of adjacent filter body segments to be essentially the same in the border region.

Lightweight and durable filter body segments can be created if they are made of porous plastic. As a result, no separate filter membranes have to be provided, since the filtration is achieved through the porosity of the plastic. In addition, the filter body segments can be designed in one piece. This means that the filter body segments form a one-piece plastic part together with any tongue and groove connections for connecting several filter body segments, with connection nipples for connecting the filter body segments with the hollow shaft and/or other filter body segment parts. For example, polyethylene (PE), polypropylene (PP), polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), polyurethane (TPU), ethylene vinyl acetate (EVA), polycarbonate (PC), polyamide (PA ) and polyethersulfone (PES) can be used. Synthetic rubbers mixed with urea can also be used for this purpose.

In order to reduce the filter membrane surface to be cleaned, it is proposed that the filter membrane has two filter membrane discs arranged at a distance parallel to one another. The filtered suspension enters the interior of the filter body between the filter membrane discs through these filter membrane discs, so that the filter membrane discs preferably run transversely to the axial direction of the hollow shaft.

So that cleaning of the filter body segments is simplified, the filter membrane discs can be inserted into a fluid-impermeable base body of the filter body segment. In this way, the filter membrane discs can be removed from the filter body segment and cleaned independently of the base body, without having to dismantle the filter body segments or even the filter body from the hollow shaft. The base body is impermeable to fluids, so it does not have a filter function and therefore has to be cleaned much less frequently. The base body can, for example, be made of plastic, in particular natural or synthetic rubber, whereby a fluid-tight connection is achieved between the base body and the insertable filter membrane disks, which can preferably be inserted radially to the hollow shaft. In addition, there is the advantage that the filter membrane discs are mounted particularly gently, so that sensitive filter materials such as ceramics can also be used at high rotational speeds. A similar effect is achieved when the base body has a metallic core and is covered with plastic.

In principle, various materials are conceivable as filter membrane discs, but particularly robust conditions result if the filter membrane discs are made of porous plastic. For example, polyethylene (PE), polypropylene (PP), polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), polyurethane (TPU), ethylene vinyl acetate (EVA), Polycarbonate (PC), Polyamide (PA) and Polyethersulfone (PES) can be used. Synthetic rubbers mixed with urea can also be used for this purpose.

In order to increase the filter performance of the filter membrane disks, it is proposed that the filter membrane disks have a ceramic core. The ceramic cores can be enclosed by a porous plastic, so that the filter performance is further increased and the sensitive ceramic cores are at the same time protected by the porous plastic against vibrations or the like.

Brief description of the invention

In the drawing, the subject of the invention is shown as an example. Show it

1 is an exploded plan view of the device according to the invention,

Fig. 2 is a detail view of the partially cutaway device in a perspective view on an enlarged scale,

Fig. 3 is a section on an enlarged scale along the line III-III of Fig. 1,

Fig. 4 shows a section along the line IV-IV of Fig. 3,

5 shows a diagram of the pressure profile in the suspension along an axial flow line and in the filtered filtrate in the axial direction of the device,

6 shows a section corresponding to FIG. 3 of a second embodiment of the device according to the invention,

7 shows a vertical section through the filter body of the second embodiment of the device according to the invention and

Fig. 8 shows a section along the line VIII-VllI of Fig. 7.

Ways to carry out the invention

As can be seen from FIG. 1, a device for continuously filtering a suspension has a housing 1 in which a hollow shaft 2 is rotatably mounted. As is disclosed in particular in FIG. 4, the hollow shaft 2 is provided with several disc-shaped, radially projecting from the hollow shaft 2 filter bodies 3 flow-connected. This can be achieved in that the hollow shaft 2 is flow-connected via openings 4 to an interior space 6 surrounded by a filter membrane 5 . If a suspension flows to the filter body 3 , the solid particles are held back by the filter membrane 5 , while the liquid portion penetrates the filter membrane 5 , flows into the interior 6 and leaves the device as filtrate via the hollow shaft 2 . The driving force behind filtration is the pressure difference between the suspension side and the filtrate side. The higher this pressure difference, the faster the filtration takes place. To further increase the pressure difference, an additional pump can be provided on the suspension side and/or a vacuum pump on the filtrate side. In the course of the filtration, a filter cake forms on the filter membrane 5 due to the retained solid particles, which forms a flow resistance and therefore reduces the filtration performance or filtration efficiency with increasing thickness. Therefore, the filter cake must be cleaned regularly. However, an increase in the pressure on the suspension side, which is desirable in order to generate a large driving force for the filtration, also causes the resulting filter cake to be compressed, making it more difficult to clean it off. Therefore, in order to enable a large driving force of filtration and thus a high filtration efficiency, the radius r of the filter body 3 increases in the circumferential direction from a low-pressure radius n to a high-pressure radius m to reduce the free housing cross section, as is disclosed in FIG. 3 . As a result, the free cross-section of the housing changes when the filter body rotates, as a result of which the suspension is subjected to a pressure profile that changes over time at a reference point that is fixed in space. With a narrowing free cross-section, the pressure difference between the suspension side and the filtrate side increases, which promotes rapid filtration. With an increasing free cross-section, the pressure difference between the suspension side and the filtrate side decreases. Due to these constant pressure fluctuations, the filter cake is loosened and can detach from the filter membrane. The cleaning effect can be further improved by the centrifugal force generated by the rotation of the filter bodies 3 . A rapid drop in pressure can also promote cleaning. This can be achieved if the filter body 3 has a compression section 7, which is formed starting from the low-pressure radius n by increasing the radius r of the filter body 3 up to the high-pressure radius m, and an expansion section 8, which is formed starting from the high-pressure radius m by reducing the radius r of the filter body 3 down to the low pressure n, with the reduction in the radius r in the expansion section 8 taking place faster than the increase in the compression section 7. The expansion section 8 therefore occupies a smaller sector of the disc-shaped filter body 3 than the compression section 7.

So that there is also a varying pressure distribution in the axial direction, a plurality of filter bodies 3 can be arranged on the hollow shaft 2, the high-pressure radii m of which are offset relative to one another in a circumferential direction. As can be seen from FIG. 3 , a filter body 3 is always offset in the same circumferential direction as the previous filter body 3 , so that the filter bodies 3 form a spiral running around the hollow shaft 2 . Particularly favorable conditions result when the offset of the high-pressure radii m between two filter bodies 3 following one another in the axial direction is between 1° and 45°. The offset can be 10°, for example, as is shown in the exemplary embodiment. 5 shows the schematic pressure profile generated by the offset of the filter bodies 3 along an axial exemplary flow line (not shown) running over the length of the device at a specific point in time. While the pressure 9 on the filtrate side remains constant, the pressure 10 on the suspension side has a wave-like profile due to the offset of the filter bodies 3 in the axial direction and thus due to the different sizes of the free cross-sectional areas. The increasing pressure over the length goes hand in hand with the increasing solids content of the suspension. The areas with a large pressure difference öph favor a high

filtration speed. The areas with a small pressure difference <5pi promote effective cleaning of the filter cake. In addition, the regular change in pressure differences creates turbulence, which further intensifies the cleaning of the filter cake, resulting in an overall increase in filter cake filtration efficiency results. It should be noted that the pressure profile shown in FIG. 5 corresponds to the pressure profile along a flow line at a fixed point in time. Due to the constant rotation of the hollow shaft 2, there is naturally a phase shift in the pressure curve over time.

As is shown in particular in FIG. 2, at least two hollow shafts 2 running parallel to one another can be provided in the housing 1, the filter bodies 3 of which are offset from one another in the axial direction with a gap. As a result, particularly large housing cross-sections can also be used for a high throughput without the need for special production with regard to the size of the filter body 3 . Furthermore, this means that geometrically more complex housing cross-sections can also be used and equipped with filter bodies.

The filter bodies 3 which are offset from one another with a gap can also at least partially overlap, forming an overlapping region 11 which can change over time as a result of the rotation. As a result, with a corresponding relative movement of the hollow shafts 2, the filter cakes of adjacent filter bodies 3 located on the filter membranes 5 can shear off one another, and the turbulence in the suspension can increase. The filter bodies 3 arranged according to the invention also act as a crushing or mixing unit for any inhomogeneities in the suspension.

So that the suspension can also be actively and evenly conveyed through the device according to the invention, the hollow shafts 2, as shown for example in FIGS. 1 to 3, with the filter bodies 3 arranged thereon relative to one another around a common plane of symmetry. If the hollow shafts move at the same speed but in opposite directions, the suspension is actively pushed in the axial direction, which means that no further conveyor devices are required. A pelletizing plate 12 can be used for preparing the filtered suspension, which is arranged downstream of the filter body 3 and is also driven by the hollow shaft 2 .

The suspension can be introduced or discharged via connection pieces 13 .

As can be seen from FIG. 6, each filter body 3 can comprise a plurality of filter body segments 14 . To form the filter body 3 , the filter body segments 14 can be releasably connected to one another via a form fit. For example, the filter body segments 14 can be releasably connected to one another via a tongue and groove connection 15, 16 running in the radial direction.

As from the figs. 6 to 8, in particular from Figs. 7 and 8, a filter body segment 14 can have a fluid-impermeable base body 17 into which two filter membrane discs 20 acting as top and bottom surfaces 18, 19 are inserted. The base body 17 spans the cavity 6 of the filter body segment 14 together with the filter membrane discs 20 . The filter body segments 14 can be detachably flow-connected to the hollow shaft 2 via connection nipples 21 . The filter membrane discs 20 can in turn be detachably connected to the base body 17 via a tongue and groove connection 22, 23 (FIG. 8).

The filter membrane disks 20 can be made of porous plastic. In addition, the filter membrane disks 20 can include a ceramic core 24 .

Claims

patent claims

1 . Device for continuously filtering a sludge suspension with a hollow shaft (2) rotatably mounted in a housing (1), which is connected to the interior (6), surrounded by a filter membrane (5), of a disk-shaped filter body (3) protruding radially from the hollow shaft (2). for discharging a filtrate, characterized in that the radius (r) of the filter body (3) increases in the circumferential direction from a low-pressure radius n to a high-pressure radius m in order to reduce the free housing cross-section.

2. Device according to claim 1, characterized in that on the hollow shaft (2) in the axial direction a plurality of filter bodies (3) are arranged, the high-pressure radii are offset from one another in a circumferential direction.

3. Device according to claim 2, characterized in that the offset of the high-pressure radii (rh) between two filter bodies following one another in the axial direction is between 1° and 45°.

4. Device according to one of claims 1 to 3, characterized in that in the housing (1) at least two mutually parallel hollow shafts (2) are provided, the filter body (3) are offset in the axial direction to each other with a gap.

5. The device according to claim 4, characterized in that the filter bodies (3) of the at least two mutually parallel hollow shafts (2) overlap at least partially in the axial direction.

6. Apparatus according to claim 4 or 5, characterized in that the hollow shafts (2) with the filter bodies (3) arranged thereon are arranged mirrored to one another about a common plane of symmetry.

7. Device according to one of claims 1 to 6, characterized in that downstream of the filter body (3) a pelletizing device (12) is arranged downstream, which is driven by the hollow shaft (2).

8. Device according to one of claims 1 to 7, characterized in that a filter body (3) comprises a plurality of filter body segments (14) which are detachably connected to one another.

9. The device according to claim 8, characterized in that the filter body segments (14) are made of porous plastic.

10. Device according to one of claims 1 to 9, characterized in that the filter membrane (5) has two spaced-apart parallel arrangement

Has filter membrane discs (20).

11 . Device according to Claim 10, characterized in that the filter membrane discs (20) are inserted into a fluid-impermeable base body (17) of the filter body segment (14).

12. The device according to claim 10 or 11, characterized in that the

Filter membrane discs (20) are made of porous plastic.

13. Device according to one of claims 10 to 12, characterized in that the filter membrane discs (20) have a ceramic core (24).