DE9204974U1 - Screening plant - Google Patents

Description

Hannesmann Aktiengesellschaft Mannesmannufer 2 29 611

4000 Dusseldorf

5extraction system

The invention relates to a screening system for separating solid substances from a liquid flow, in particular a wastewater flow in a sewage treatment plant, according to the preamble of claim 1.

In order to avoid operational disruptions in the area of a sewage treatment plant, it is necessary to separate solids such as wood, plastics, cans, etc. from the wastewater stream at the entrance to the sewage treatment plant. Various designs of screens are known for this purpose. These usually consist of a screen grid made up of parallel bars in which the solids get caught and which is continuously (e.g. paternoster screen) or discontinuously freed of solids by a screen rake. Jamming of solid particles in the screen often leads to operational disruptions. The gap width of such screens is usually around 10 - 20 mm, so that they are to be regarded as coarse screens that are not suitable for separating smaller solid particles. For finer separation, fine screens in the form of so-called fine screen drums can be used.

A well-known fine sieve drum for wastewater treatment has a roughly cylindrical housing with its longitudinal axis slightly inclined to the horizontal. Inside the housing there is a correspondingly cylindrical sieve that can be rotated around the longitudinal axis by a motor. A worm-shaped self-scraper extends over the entire length of the perforated sieve and can be rotated relative to the perforated sieve drum. The wastewater to be treated is introduced into the interior of the perforated sieve via a pipe, flows through the holes in the perforated sieve, collects at the bottom of the housing and is again drawn off through a pipe at the lowest point. Solids that are larger than the hole width of the perforated sieve are retained inside the perforated sieve and conveyed by the worm-shaped self-scraper to a solids discharge opening in the front area of the highest point of the fine sieve drum. For the continuous cleaning of the salmon sieve, a roller-shaped brush is installed above the perforated sieve in the space between the housing and the perforated sieve. A fine sieve drum is a unit that provides very good liquid separation performance, but is very complex in terms of construction and is therefore costly.

The object of the invention is to propose a filter system of the generic type which is characterized by a simple (inexpensive) flow structure, provides a high separation performance, operates reliably and can be easily installed in an open sewer.

This task is solved according to the invention by the characterizing features of claim 1. Advantageous further developments of the invention are specified in subclaims 2 to 12.

The invention is explained in more detail below with reference to the single figure, which shows an example of a screening system in a sewer.

The sewer has an opening through which the filter system according to the invention is placed at an angle of about 30° against the flow direction in the sewage stream. The filter system essentially consists of an endless fabric belt 1, which runs endlessly in the direction of the arrows shown via a lower deflection roller 7 and an upper deflection roller θ. The fabric belt 1, which is preferably designed as a stainless steel wire mesh or made of plastic, is preferably driven by the upper deflection roller, which is coupled to an electric motor, for example, by means of a frictional connection. The mesh size of the fabric belt 1 is preferably 2 - 8 mm, in particular 4 - 6 mm, so that it also reliably retains relatively small solid particles. By changing the flow of the fabric belt 1, the separation accuracy of the screening system can be adjusted to any value if required. In the case shown, the screening system is positioned against a step in the area of the bottom of the sewage canal and extends over its entire width. In the transition area of the fabric belt 1 to the bottom and to the side walls of the sewage canal, sealing elements 9 (e.g. made of rubber) are arranged to ensure that the entire sewage flow flows through the mesh of the fabric belt 1. Since the fabric belt 1 generates a certain dew pressure, a belt support 2 is expediently provided at least in the submerged area under the upwardly running part of the fabric belt 1, which preferably consists of narrow, rigid support strips running in the conveying direction of the fabric belt 1. The solids carried in the flow of water remain hanging in the fabric belt 1 as screenings and are transported upwards out of the flow of water via its circulating movement. To prevent the collected screenings from sliding back down on the fabric belt 1, an angle of inclination of approximately 40 should not be exceeded.

This angle should not be less than 20°, so that the required length of the conveyor belt is not too large. The screenings that are taken along reach a screenings discharge 3 at the upper reversing claw B, i.e. they fall downwards from the fabric belt 1. They can fall directly into a collecting container or, as in the present example, onto a conveyor belt 10, which can lead to waste recycling (e.g. composting plant). A self-stripping device is expediently provided in the area of the screenings discharge 3, which makes it easier to separate the screenings from the fabric belt 1. Since paper or other fibrous materials can still stick to the mesh of the fabric belt, a belt cleaning device is arranged in the direction of the belt behind the screenings discharge 3, i.e. in the return path of the fabric belt 1. This can, for example, consist of a brush arranged under the fabric belt, preferably a driven roller brush 4. A pressurized water spray device 5 can also be used, which flushes adhering parts downwards. Preferably, roller brush 4 and pressurized water spray device 5 are provided in combination; for example, rinsing water can be taken from behind the screening system using a suitable pump. The used rinsing water is then collected (not shown) via a collecting device and returned to the rinsing water flow in front of the screening system, so that the rinsed-out screenings can be picked up again by the fabric belt 1. Cleaning the fabric belt 1 is particularly useful because it allows the hydraulic pressure loss through the screening system to be kept comparatively small. To facilitate maintenance or repair work, it is recommended that the screening system be mounted in a suitable bearing block 6 in the upper third, so that it can be rotated around a horizontal axis, so that it can be easily swung upwards out of the waste water flow if necessary.

The screening system according to the invention represents an extremely simple and therefore cost-effective screen for wastewater treatment, which, despite a possible high separation performance, also ensures a very high level of operational reliability for small-scale screenings, since jamming of coarse and solid screenings, which would block conventional screens, is practically impossible. Maintenance and operating costs are low.

Claims (12)

Protection claims 1. Screening system for separating solids from a liquid flow, in particular for removing solids from a wastewater flow in a sewage treatment plant, with a screen surface through which the liquid flow can flow, with a drive device for moving the screen surface relative to the liquid flow, with a conveying device for conveying separated solids and with a cleaning device for cleaning the screen surface, characterized, that the screen surface is designed as an endlessly rotating fabric belt (1) and is at the same time a functional part of a belt conveyor system with a lower (7) and an upper deflection roller (β), whereby the screen surface is placed at an angle in the liquid flow during operation, and that a device for cleaning the belt is provided in the area of the part of the fabric belt (1) running into the liquid flow (return flow). 2. Screening plant according to claim 1,
characterized, that the belt cleaning device comprises a cleaning brush (4) which is arranged below the returning fabric belt (1). 3. Screening plant according to claim 2,
characterized, daQ the cleaning brush (4) is a driven rotating brush. 4. Screening system according to one of claims 1 to 3, characterized in that the belt cleaning device comprises a pressurized water spray device (5) which is arranged in the space between the forward and the return fabric belt (1) and the spray direction is directed downwards. 5. Screening system according to one of claims 1 to 4, characterized in that the screening system is rotatably mounted on a bearing block (6) with a horizontal axle and can be swung out of the liquid flow. 6. Screening system according to one of claims 1 to 8, characterized in that the inclination of the fabric belt (1) relative to the horizontal is approximately 20 - 40°, preferably 30°. 7. Screening system according to one of claims 1 to 6, characterized in that a stripping device is arranged in the area of the upper deflection roller (B). 6. Screening system according to one of claims 1 to 7, characterized in that the front side of the fabric belt (1) exposed to the flow is supported at least in the region below the liquid level on the underside by a rigid, liquid-permeable wall support (2). 9. Screening system according to claim β, characterized in that the belt support (2) is designed in the form of support strips running in the conveying direction. 10. Screening system according to one of claims 1 to 9, characterized in that the fabric belt (1) is made of stainless steel wire. 11. Screening system according to one of claims 1 to 9, characterized in that the fabric band (1) is made of plastic. 12. Screening system according to one of claims 1 to 11, characterized in that the gap width of the fabric belt (1) is 2 - β mm, preferably 4-6 mm.