DE19828171A1 - Carpet-like filter unit for waste water, in which flow is directed towards deep pile to trap particles - Google Patents

Abstract

Before being subjected to reverse flow, the filter cloth is compressed by a force directed towards the supporting fabric. Pressure exerted, exceeds that of the fluid approaching for filtration. An Independent claim is included for the equipment required. This includes the filter cloth (1) with pile (7), suction beam (11), suction slot (17), pressing surface (25, 27) and their relatively sharp edges (35, 37). Preferred features: Force is exerted by compressing the cloth, moving a pressure strip over the pile. The strip is part of a suction beam. By extracting fluid through the cloth, back washing results. Extraction sets up mechanical pressure between strip and cloth.

Description

The invention relates to a method and a device for filtering liquid with the in the preamble of Claims 1 and 4 specified features.

A preferred but not exclusive area of application the invention is wastewater treatment, in particular Filtration of wastewater from post-purification after egg a biological cleaning stage with simultaneous phos phat elimination takes place, so in the so-called third Cleaning stage of a wastewater treatment plant.

A method and an apparatus of the type mentioned are known from WO97 / 48472. They are characterized by two different operating states of the provided with pile threads Filter cloth: During the filtration, the pile threads are removed from the flowed to the liquid to be cleaned and through this in Flattened in the direction of the support fabric, so that lay the pile threads in layers and a depth form the filter between the superimposed pole threads numerous narrow, winding and multi-curved Flow channels, in which solid particles, whose size is smaller than the clear width of the flow channels is partly mechanical and partly by adsorption can be captured. When backwashing, the polarities are the other hand, a liquid directed away from the supporting tissue exposed to the current and are therefore relative to the Support tissue erected and then largely stand together other and parallel to the direction of flow, whereby the Volume of the pole layer greatly increased and that between the flow threads existing flow channels opened and be be graded. On the one hand, the flow resistance is thereby  stood for the backwash liquid reduced so that this flow between the pile threads at high speed men, and on the other hand, they are previously in the through flow channels free mechanically blocked solid particles given so that it from the backwash liquid under over loosened the winding of the adsorption forces and washed away that can.

In the known device, this is the backwash flow generating suction bar on both sides of its suction slot with the surfaces facing the filter cloth, mechanically act on the pile threads and prevent them from rising. As a result, a jerky erection of the pile threads, so soon these have reached the suction slot, favors what beneficial to the release of the between the poles deposited solid particles.

A similar device, but without mechanical intervention The suction beam on the pile threads is from NL-A-8103750 known.

The invention is based, to a method ren and a device of the type mentioned cleaning to further improve the effect of the backwashing process.

The achievement of the object is in the claims Chen 1 and 4 specified. The dependent claims relate refer to further advantageous training of the method or the device.

According to the invention, it was surprisingly found that an additional mechanical compression of the pole layer the filter cloth immediately before reaching the suction slide zes of the squeegee, a loosening of the between the pole causes the deposited solid particles, so that closing in the area of the suction slot when the backwash  flow straightens the pile threads and the ge between them formed flow channels that widened and straightened Dirt particles faster and more completely from the pole the detached and carried away by the backwash flow can be. This will make it better and more complete achieved more cleaning of the filter cloth. It has further proved to be advantageous if the filter cloth after Passing the suction slot of a second mechanical com pression is subjected. This causes a quick and controlled pressing of the pile threads against the support fabric of the filter cloth, so that the pile threads are already in the again laid flat arrangement, and thus in the configuration depth filter before you start again with the Flow of the liquid to be filtered acts on who the.

Both of the above effects have a particular effect partial if the pile threads of the fil tertes around crimped threads or textured multifila acts. Ruffled pile threads form because of their un regular shape and their interlocking a particular effective, fine-pored depth filter. However, they tend to mattify each other and to straighten up hinder so that they are less able to in the backwash flow generated by the suction bar prepare and free the stuck solid particles ben. Crimped pile threads can also mutually prevent them from returning after passing through the suction slot to take up a position pressed against the support fabric. In both cases, the mechanical com Priming the pole layer of the filter cloth advantageous.

An embodiment of the invention is described below the drawing explained in more detail. This shows schematically and greatly simplified a detail of a fil according to the invention trier device.  

According to the single figure, there is a filter cloth 1 in the flow path of a liquid to be filtered, so that the liquid flows through it in the direction of the flow arrows 3 . The devices for generating the flow of the liquid to be filtered and for holding and supporting the filter cloth in the flow are not shown in FIG. 1, since these can be features of a conventional filtering device known to the person skilled in the art. For example, the device can be designed as a disk filter according to FIG. 4 of WO97 / 48472. However, the invention is also applicable to a filter device designed as a drum filter, filter press or the like.

The filter cloth 1 consists of a support or base fabric 5 and in the support fabric integrated pile threads 7 , which protrude from the support fabric to one side and form a pile of the filter cloth. The term support fabric is also intended to encompass textile fabrics which are not produced by weaving but, for example, by knitting or knitting or in a mixed technique. The mesh size of the supporting tissue 5 , or the resulting effective pore size, is preferably considerably larger than the particle size of the solid particles to be filtered from the liquid. It is advantageous in the context of the invention if a polypropylene fabric known per se for other purposes is used as the fabric, the supporting fabric of which has a mesh size of at least 0.2 mm or more, optionally also in the range of 1 mm. Dirt particles are then practically finally retained by the pile layer of the filter cloth, but not in the support fabric.

The pile threads 7 are integrated into the supporting fabric 5 in any manner known to the person skilled in the art.

As indicated in the drawing, the pile threads 7 are in front of preferably crimped or textured threads, specifically in front of preferably crimped multifilaments, which can dissolve into individual filaments at least in the area of their ends. The pile threads are preferably arranged so densely that they partially interlock with their crimps and form a very homogeneous, fine-pored layer.

The filter cloth 1 is arranged so that the pile threads 7 flow against it by the liquid to be filtered. Due to the inflowing liquid, the pile threads 7 are flipped over and pressed onto the supporting fabric 5 , so that they take a schematically indicated position in area A, in which adjacent pile threads 7 lie one above the other in several layers and form a filter-active layer in the manner of a random fiber fleece , ie a Tiefenfil ter that forms numerous narrow, long and winding flow channels. It is important for this desired behavior of the filter cloth that the length, stiffness and density of the pile threads be selected appropriately. The length of the pile threads 21 will generally be at least 10 mm. Shorter pile threads are either too stiff or do not give the desired layer thickness of the spatial filter layer in the filtering operation.

A suction bar 11 , which is arranged on the pole side of the filter cloth 1 , is used for cleaning and backwashing the filter cloth. By suitable means, not shown, the suction bar 11 can be moved in its transverse direction and parallel to the filter cloth, as indicated by the arrow 13 in the drawing. Alternatively or additionally, the filter cloth 1 can be moved in the opposite direction according to the arrow 15 . The suction bar 11 has a suction slot 17 , the width of which is indicated in the drawing with B. Via a suction connection 16 , the suction bar is connected to a suction device (not shown), so that it can generate a backwash flow in the area of its suction slot through the filter cloth 1 , which is indicated by the arrows 19 .

Due to the relative movement between the suction bar 11 and the filter cloth 1 in accordance with the arrows 13 and 15 , successive regions of the filter cloth 1 are successively achieved in the effective range of the suction slot 17 and the backwashing flow 19 . The backwashing flow 19 exerts on the pile threads 7 a force directed away from the supporting fabric 1 , through which the pile threads 7 are partially erected and straightened. This results in a large increase in the volume of the pile layer of the filter cloth 1 , whereby the flow channels formed between the pile threads are expanded and straightened. The dirt particles 23 stuck between the pile threads 7 are thereby released and can be transported away from the backwashing flow 19 .

On the side of the suction bar 11 facing the filter cloth 1, contact strips 25 , 27 are formed on both sides of the suction slot 17 . The suction bar 11 is, as indicated schematically in the drawing, about a to the filter cloth 1 par allelic axis 29 supported so that it can accordingly move the arrow 31 to the filter cloth 1 to or away from it. The filter cloth 1 is not taut on its (not shown) holding structure, son somewhat loosely, so that it has a certain freedom of movement towards the squeegee 1 . This ensures that the suction bar 11 and the filter cloth 1 are pulled towards each other by the suction force exerted by the suction bar, whereby the pole layer of the filter cloth 1 is pressed against the contact strips 25 , 27 of the suction bar 11 . This has the effect that the pole layer of the filter cloth 1 on both sides of the suction slot 17 of the suction beam 11 is mechanically compressed by pressing against the contact strips 25 , 27 . This compression of the pole layer of the filter cloth in the areas designated C and D in the figure is stronger than the compression of the pole layer outside the suction beam, e.g. B. in areas A and E, caused by the inflowing liquid to be filtered. Due to the relative movement of the suction bar to the filter cloth, the front contact strip 25 in the direction of movement 13 has the effect of continuously "ironing" the pile threads 7 .

Another advantageous effect of the pressing against the pole layer of the filter cloth contact strips 25 , 27 consists in a sealing effect that prevents unfiltered suspension from the squeegee in a short circuit flow through the gap between the contact strips and the filter cloth is sucked.

As can also be seen from the drawing, the filter cloth 1 is somewhat drawn into the suction slot 17 in the area of the suction slot 17 due to its flexibility and its loose tension and forms a flat bulge or shaft in this area. This leads to the fact that the pile 7 of the filter cloth 1 is particularly strongly compressed in the region of the edges of the contact surfaces 25 , 27 which delimit the suction slot 17 . These edges 35 , 37 are preferably not rounded, but ausgebil det as sharp edges, whereby a jerky erection of the pile threads 7 in the region of the suction slot 17 is favored. This Kom priming the pile threads 7 of the filter cloth 1 is particularly important in the area C lying in the direction of movement in front of the suction slot 17 , since this promotes mechanical locking of the solid particles sitting between the pile threads, so that after reaching the suction slot 17 and straightening the pile threads 7 can be easily released and rinsed out in this area. After passing through the suction slot 17 in the loading area D there is a new compression of the pile threads 7 in order to force an accelerated flattening of the pile threads into the configuration most favorable for the filtration.

The width of the suction slot 17 indicated B can, as shown in the drawing, be greater than the length of the pile threads 7 and z. B. be twice or a multiple of this length. Depending on the type of pile layer, in particular on the extent of the crimp and mutual felting of the pile threads, it can also be advantageous if the width B of the suction slot is equal to or even less than the length of the pile threads. In this case, there may not be a full erection and parallel alignment of the pile threads in the area of the suction slits, but a partial uprighting of the pile threads and thus a significant loosening and volume increase of the pile layer may still take place. This leads to an effective release of the dirt particles already loosened by the previous compression.

Claims (10)

1. A method for filtering liquid, in which the liquid to be filtered is passed through a filter cloth which has a supporting fabric and a pile of pile threads ( 21 ) on the front face against which the liquid flows, the length, rigidity and density of which are dimensioned in this way that the pile threads ( 21 ) are pressed against the supporting fabric ( 20 ) by the inflowing liquid and form a depth filter with angled and multi-curved flow channels, and in which the filter cloth is backwashed at intervals by successive areas of the filter cloth successively a backwash flow directed away from the support fabric, which causes an at least partial erection of the pile and an increase in the volume of the pile, characterized in that each loading area of the filter cloth, before it is set to the backwash flow, by a force directed towards the support fabric effect is compressed, the force per unit area being greater than the pressure exerted by the inflowing liquid to be filtered. 2. The method according to claim 1, characterized records that the force is generated by pressing the filter cloth against each other and one over its pole side moving pressure bar. 3. The method according to claim 2, characterized records that the pressure bar is part of a suction bar moved over the pole side of the filter cloth is by sucking liquid through the filter cloth through the backwash flow generated, and that the Ge  press the filter cloth and the pressure bar against each other is generated by the suction effect. 4. Apparatus for filtering liquid, with a filter cloth ( 1 ) in the flow path of the liquid to be filtered, which has a pile of pile threads ( 7 ) on its front face from the liquid, and with one on the pole side of the filter cloth ( 1 ) arranged suction bar ( 11 ) with suction slot ( 17 ), which generates a backwash flow by sucking liquid through the filter cloth through in the area of the suction slot, which causes a partial erection of the pile threads and a volume increase in the pile, characterized in that Suction bar ( 11 ) at least on the front of the suction slot ( 17 ) in the direction of movement has a filter cloth facing pressure surface ( 25 ) that the suction bar ( 11 ) and / or the filter cloth ( 1 ) are movable in the direction of each other , and that means for generating a contact force between the pressure surface ( 25 ) of the suction beam ( 11 ) and the Filter cloth ( 1 ) are provided, through which the pile of the filter cloth ( 1 ) is compressed. 5. The device according to claim 4, characterized records that the output force by the of Suction bar created in the area of the suction slit pressure is generated. 6. Apparatus according to claim 4 or 5, characterized in that on the rear side in the direction of movement of the suction slot ( 17 ) a further pressure surface ( 27 ) of the suction beam ( 11 ) is provided, on which also a compression of the pile of the filter cloth takes place . 7. Device according to one of claims 4 to 6, characterized in that the or each pressure surface ( 25 , 27 ) with a sharp edge ( 35 , 37 ) merges into the suction slot ( 17 ). 8. Device according to one of claims 1 to 7, characterized in that the filter cloth ( 1 ) is held so loosely and / or has such a low bending strength that it is len-shaped in the region of the suction slot ( 17 ) and into the suction slot is drawn in. 9. Device according to one of claims 1 to 8, characterized in that the suction bar ( 11 ) about an axis parallel to the filter cloth ( 1 ) ( 29 ) is pivotally mounted. 10. Device according to one of claims 1 to 9, characterized in that the width (B) of the suction slot ( 17 ) is smaller than the length of the pile threads ( 7 ).