EP4267368A1

EP4267368A1 - Discharge technology for plastic filters

Info

Publication number: EP4267368A1
Application number: EP21835591.5A
Authority: EP
Inventors: Roderich Ettlinger
Original assignee: Ettlinger Kunststoffmaschinen GmbH
Current assignee: Ettlinger Kunststoffmaschinen GmbH
Priority date: 2020-12-23
Filing date: 2021-12-01
Publication date: 2023-11-01
Also published as: US20240051211A1; WO2022135855A1; CN116635205A; DE202020107526U1

Abstract

The invention relates to a discharge device for a filter device for separating impurities from a material melt, in particular a low-viscosity polymer melt. The discharge device comprises a discharge shaft with a pressure conveyor screw and a discharge head. Also disclosed are a filter device having a cylindrical drum filter, a scraper and such a discharge device.

Description

Discharge technology for plastic filters

description

The invention lies in the field of filter devices and discharge devices for filter devices according to the preambles of the independent claims.

Filter devices are used in the processing of plastics in order to increase the purity of the processed plastic and to separate impurities from a starting material. Especially when recycled plastics are reused, filter devices are used to separate contaminants from plastic waste.

In plastics technology, plastics are melted or plasticized, for example, in an extruder for further processing. The material melt can be further processed in different processes. The filter device can, for example, be used after an extruder. In the prior art are various methods and

Filter devices for filtering contaminated polymer melts are known.

A material melt within the meaning of this disclosure preferably designates a plastic melt or polymer melt. Such material melts usually have a melting temperature above 100 °C and are processed hot. The material melt can also be another pasty mass, regardless of the material and/or the melting temperature. The invention is also suitable for pasty masses other than plastic melts. The melting point of the material melt can also be close to or below the usual ambient temperature of about 20 °C, so the material melt would colloquially be called cold or just warm. The material melt can in particular consist of a pasty mass the food sector, cosmetics, everyday consumer goods or pharmaceuticals.

The starting material preferably consists of a material melt of the desired basic plastic (e.g. PE, PP, PS, PA or PET) and additional substances with which the starting material is contaminated. Depending on the material, origin and recycling cycle, the degree of contamination of the starting material can vary and can be 1% to 20% of the mass, for example.

The processing of such contaminated starting materials requires suitable filters and processes, with the different material properties of the various plastics being a particular challenge.

A filter with a filter sieve is used to filter the starting material, through which the melted material is pressed. Impurities settle on the filter surface. The filter screen is designed in such a way that if possible only the pure plastic melt penetrates the filter screen. During the filtering process, the material separated by the filter collects in the filter chamber. In order to prevent the filter from becoming clogged, the excreted material must be discharged, with different discharge techniques being known. The discharge of the separated material from the filter chamber can be done continuously (e.g. by removing it) or at intervals (e.g. by regular rinsing or changing the filter screen).

In the filtered material behind the filter screen, residues of impurities that were not completely eliminated by the filter screen can remain. Filtering reduces the contamination to a sufficiently low level for further processing or eliminates it completely. It is also possible that in the separated and discharged material, also called dirt cake, next to the Filtered impurities also residues of the base plastic remain. The aim of the filtering is to separate the contamination as cleanly as possible with the lowest possible losses of the base plastic.

The continuous removal of the separated material is particularly advantageous for uninterrupted operation of the filter. In particular, rotating filters, e.g. drum filters or disc filters, are known for this purpose from the prior art. The separated material can be continuously removed from the rotating filter surface, e.g. by a scraper, and removed from the filter chamber. Both standing and moving (e.g. rotating) scrapers, which are moved relative to the filter surface, are known for removing the separated material. In drum filters, the starting material is often fed in from the outside, i.e. radially, and pressed through a cylindrical filter into its interior. The contaminants separated by the filter remain on the outside of the filter. Disc filters are also known in which the starting material is pressed in the axial direction through a rotating disc filter.

DE 94 90 017 U1, for example, discloses a filter device with scrapers which are arranged between two disc filters on a rotating disc.

DE 202 10 115 U1 discloses a filter device with a rotating drum filter and a scraper resting on its outer surface.

To discharge the impurities removed by the filter, discharge screws are used in both documents, which carry the material mixture removed directly into the environment, where the material running out can be collected in a continuous stream.

Depending on the type of plastic and the process parameters, the viscosity of the material melt can vary. The processing relatively thinner Material melts, ie melts with a low viscosity in SI units (eg Pa s) or a high viscosity number in MFI, eg when processing PA or PET plastics, represent a particular challenge for the construction of suitable filter devices. Processability of the plastics depends, among other things, on the viscosity, ie the toughness, of the material melt. In particular, the conveying pressure in the filter device or the feed pressure of an upstream extruder can be significantly lower in the case of low-viscosity material melts (eg PA or PET) than in the case of viscous material melts. The ability to be conveyed by means of friction-dependent conveyors such as screws depends heavily on the internal and external friction of the materials being conveyed, which is expressed in their viscosity.

The filter devices known from the prior art with simple discharge screws, which convey the removed material mixture directly into the environment, have several disadvantages, especially for low-viscosity plastic melts. On the one hand, the opening at the end of the screw allows air to penetrate into the filter chamber, which can lead to undesirable reactions. On the other hand, the material is discharged without metering. Other dosing discharge devices are unsuitable for low-viscosity material melts because of the low pressure.

The object of the present invention is to provide an improved technique for filtering material melts and removing separated material from the filter space.

The present invention is particularly suitable for filtering low-viscosity material melts, such as PA and PET.

Experiments have shown that the pressure in the filter chamber is significantly lower with low-viscosity material melts than with viscous material melts. The pressure in the filter room is below Among other things, from the feed pressure of the feeding machine, for example an upstream extruder. The thinner the melted material is, the less conveying pressure is built up by friction-dependent conveying equipment such as screws in the extruder. In practice, the pressure in the filter room when filtering PA or PET can be a relatively low 10 to 20 bar, for example.

Especially with extruders that are not designed for low-viscosity material melts, the feed pressure for a downstream filter device can be insufficient. The use of special extruders, which provide sufficient feed pressure even with low-viscosity material melts, is often more expensive. A particular advantage of the present invention is its compatibility with widely applicable and/or inexpensive extruders for filtering contaminated material melts.

For the operation of pressure-dependent discharge units, e.g. for dosing units with a piston stroke, the internal pressure of the filter can be too low under certain process conditions to ensure reliable discharge of the filter deposits.

In addition, particularly when processing a hot melt of material, it is desirable not to expose the melt of material to the ambient air in order to avoid undesirable oxidation or other reactions of the material to be processed. When the separated material is discharged from the filter chamber, the sealing of the filter chamber is therefore a particular challenge.

Both a discharge device and an adapted filter device with such a discharge device are disclosed.

A particularly advantageous aspect of the invention lies in the combination of a portioning discharge head with an upstream pressure screw conveyor of the discharge device. The discharge device according to the invention is designed to discharge separated material from a filter chamber of a filter device. The filter device serves to separate impurities from the material melt. The material melt is fed to the filter chamber of the filter device via a material supply under pressure. In the filter chamber, the supplied molten material is pressed under pressure through a filter sieve of the filter.

Impurities are deposited on the surface of the filter screen due to their material properties. The impurities should be removed from the filter room as quickly as possible.

In order to prevent the filter from clogging, the separated material, usually a mixture of separated impurities and pure material, is discharged from the filter chamber with the discharge device. Depending on the starting material, the excreted material has a tough, mushy consistency.

The discharge device includes a discharge shaft with a pressure screw conveyor and a discharge head. The discharge head is advantageously arranged on the discharge shaft with the pressure screw conveyor.

The discharge head of the discharge device is preferably arranged in the conveying direction at the end of the pressure conveyor screw, so that the pressure conveyor screw conveys material from the filter chamber in the direction of the discharge head, thereby increasing the pressure.

By rotating the discharge shaft, the material collected in the filter chamber is conveyed by the pressure screw conveyor in the direction of the discharge head. The pressure screw conveyor is connected between the filter room and the discharge head. If required, one or more further components, eg line sections or deflections, can be arranged between the pressure screw conveyor and the discharge head. In the preferred In this embodiment, the discharge head sits directly on the shaft of the pressure screw conveyor.

The discharge head preferably comprises one or more discharge plungers. The discharge pistons are slidably mounted in the discharge head and have an axial stroke within the discharge head. By moving the discharge piston in the discharge head, separated material can be picked up on one side of the discharge head and discharged through an opening after a partial revolution.

The discharge head is preferably designed to produce a portioned, i.e. dosed, discharge. Depending on the size and stroke of the discharge head, a predetermined volume is discharged per revolution. For example, with one revolution of the discharge shaft, each discharge piston can complete a double stroke and, with two discharge pistons, four times the stroke volume per revolution can be discharged from the filter device.

A particular advantage of the discharge head lies in the portioned, ie controllable discharge of material from the filter chamber that can be sealed off from the environment. In the case of relatively low-viscosity material melts, however, it may be that the pressure present in the filter chamber is not sufficient to actuate the discharge head, in particular the discharge piston. The discharge device disclosed here combines a pressure screw conveyor on the discharge shaft with a portioning discharge head. With the pressure screw conveyor, the conveying pressure applied to the discharge head can be increased sufficiently to ensure portioned discharge from the discharge head.

The pressure conveying properties of the pressure conveying screw can be designed by suitably designing the screw, in particular the pitch and the volume flow conveyed in the screw. Advantageously, the discharge head, in particular with a discharge housing, forms a storage volume at the end of the pressure screw conveyor. The discharge device is designed to convey separated material into the storage volume of the discharge head and thereby to increase the pressure of the material to be discharged at the discharge head compared to the filter chamber.

The pressure within the delivery space is preferably increased from 10 to 20 bar to a discharge pressure of 40 to 50 bar.

The combination of the continuously conveying pressure screw conveyor with a portioning discharge discharge head is particularly advantageous in order to

To continuously remove deposits on the surface of the filter screen and at the same time to control the material discharge and to seal the filter chamber from ambient air.

The present invention can be designed both as a separate discharge device, for example for retrofitting or converting a filter device, or as a complete filter device with such a discharge device. The discharge device is particularly suitable for use in a filter device with a filter, in particular a rotating drum filter or disc filter, and a scraper. With the scraper, the separated material is preferably scraped off the surface of the rotating filter screen and collected on the scraper.

The pressure conveyor screw of the discharge device is preferably arranged in the area of the scraper, so that the scraped-off material is fed to the pressure conveyor screw and removed by it. The filter device for separating impurities from a material melt comprises a housing, a filter and a filter space on the surface of the filter, as well as a discharge device. The discharge device with the discharge shaft, the pressure screw conveyor and the discharge head is arranged on the filter of the filter device in such a way that a Material flow from the filter chamber into the conveying chamber of the pressure screw conveyor is possible. The discharge device, in particular the pressure screw conveyor, is preferably arranged on the outside of a drum filter in a wall of the housing of the filter device. This arrangement enables the separated material to be reliably discharged from the filter chamber and the components to be easily exchanged for maintenance purposes.

Further advantageous features and embodiments of the invention are disclosed in the subclaims and drawings. The features disclosed for the discharge device are also to be understood as direct features of the filter device. A detailed description of the invention and the embodiments follows with reference to the drawings.

DRAWING DESCRIPTION The invention is shown as an example and schematically in the drawings. Show it:

Figure 1: a longitudinal section through a filter device (20) with a

Filter (30) and a discharge device (10);

Figure 2: a cross section of the filter device (20) along the section line A-A;

Figure 3: a cross section through the discharge device at the level of

discharge head (13) along the cutting line B-B.

Detailed description

FIG. 1 shows a preferred embodiment of a filter device (20). The filter device (20) comprises a housing (21), a filter (30) with a filter shaft (31) and a discharge device (10). The filter (30) is preferably designed as a rotating drum filter. The filter space (27) is formed on the surface of the filter (30) within the housing (21) of the filter device. The typical material flow for filtering the material melt can be seen in FIGS. The starting material is conveyed under pressure into the filter chamber (27) by a material feed (25). The material is preferably supplied from the outside, for example via a radial supply through the housing (21). The supplied material is distributed in the filter chamber (27) on the surface of the filter (30). The filter (30) preferably comprises a permeable filter screen (32) which sits on a rotating filter shaft (31).

The material melt is pressed through the filter screen (32) under pressure, with impurities in the material remaining on the surface of the filter screen in the filter chamber (27) due to their material properties. The filtered material penetrates the filter screen (32) and flows in the direction of the material outlet (26). In the preferred embodiment, the filtered material is discharged through the filter shaft (31). For this purpose, the filter shaft (31) comprises suitable channels between the contact surface of the filter screen (32) and the internal material discharge (26). The material flow (28) of the filtered material, starting from the material supply (25) via arrows towards the material discharge (26), is indicated in FIG.

The substances separated from the starting material collect on the surface of the filter screen (32). The rotation of the filter shaft (31) and the filter screen (32) conveys the separated material in the direction of the discharge device (10) and the scraper (22). The scraper (22) presses on the surface of the filter screen (32). The scraper (22) is arranged like a scraper on the surface of the filter screen (32). Due to the rotation of the filter shaft (31), the material adhering to the surface of the filter screen (32) is removed by the scraper (22). Advantageously the discharge device (10) is arranged in the area of the scraper (22) on the filter chamber (27), so that the scraped-off material is picked up and conveyed away by the pressure screw conveyor (12).

The pressure screw conveyor (12) of the discharge device (10) is preferably formed by a circumferential helix on the surface of the discharge shaft (11). By rotating the discharge shaft (11) and the screw formed thereon, the material is conveyed in the axial direction of the discharge axis (A) from the filter chamber (27) in the direction of the discharge head (13).

The discharge head (13) is preferably arranged in a discharge housing (14). The discharge housing (14) can be designed both as part of the housing (21) of the filter device and as a separate discharge housing (14). The separate design of the discharge housing (14) is particularly advantageous for the maintainability and the replacement of parts of the discharge device (10). The discharge housing (14) is preferably fastened tightly to the housing and/or a cover of the housing (21) of the filter device.

The discharge head (13) is preferably mounted in the discharge housing (14) such that it can slide and is sealed against the ambient air. The discharge unit (10) forms a storage volume (18) in the area of the discharge head (13). The separated material is conveyed into the accumulation volume (18) by the pressure screw conveyor (12). In the storage volume (18), the pressure is increased to a sufficient level to overcome the static friction of the discharge piston (16) in the discharge head (13).

In the case of low-viscosity material melts in particular, the movement of the discharge piston for metered material discharge can only be ensured by increasing the dynamic pressure at the discharge head (13).

FIG. 3 shows the lifting movement of the discharge piston (16) in a cross section of the discharge head (13). Depending on the desired discharge volume and Depending on the periodicity of the discharge per revolution, one or more discharge pistons (16) can be provided.

With one revolution of the discharge shaft (1 1) and the discharge head (13), the discharge head takes up a stroke volume (H) from the storage volume (18), conveys this over a partial revolution in the direction of a discharge opening (17) and pushes the volume through an opposite one Hub through the discharge opening (17) to the environment. The discharge opening (17) and the storage volume (18) are advantageously arranged opposite one another or slightly offset from one another, so that the dynamic pressure in the storage volume (18) ensures that the dirt cake is ejected through the discharge opening (17). With the stroke of the discharge piston (16), material is taken up from the storage volume (18) and a corresponding volume is discharged through the discharge opening (17) on the opposite side. The bores in the discharge head (13) and the discharge housing (14) are preferably designed in such a way that the discharge piston (16) is held in the discharge head (13) with a positive fit and cannot exit through the discharge opening (17).

The discharge housing (14) preferably includes a cover (15). The discharge housing (14) can advantageously include an overflow channel on the bearing surface of the discharge head (13) in the discharge housing (14). Leakage material can flow off through the overflow channel.

In a particularly advantageous embodiment, the discharge device (10) has a modular structure. The discharge device (10) preferably comprises a modular connection interface (19) between the pressure screw conveyor (12) and the discharge head (13).

The discharge head (13) is preferably releasably attached to the discharge shaft (11). In a particularly advantageous embodiment different pressure screw conveyors (12) and discharge heads (13) can be combined with one another. The different embodiments of the pressure screw conveyor (12) and the discharge head (13) have a uniform connection interface (19) for this purpose. In this way, for example, different discharge volumes and pressure gradients can be achieved by selecting and combining different pressure screw conveyors and discharge heads.

The discharge head (13) is preferably arranged detachably on the discharge shaft (11). Alternatively, the discharge shaft can also be made in one piece with the pressure conveyor screw (12) and the discharge head (13).

A particular advantage of the embodiment shown in FIG. 1 lies in the separation of the filter shaft (31) and the discharge shaft (11). The discharge shaft (11) is preferably parallel and offset radially to the filter shaft (31). With the separate discharge shaft (11), the material discharge through the discharge device (10) can be controlled separately from the rotational speed of the filter (30) and its filter shaft (31).

The combination of a rotating filter (30), in particular a drum filter, with a discharge device (10) with a discharge shaft (11) is particularly advantageous for a precisely controllable filter process.

The discharge device (10) is preferably arranged on the outside of a drum filter that is acted upon from the outside. The combination of the discharge device (10) with a filter device with a static scraper (22) on a rotating filter screen (32) is particularly advantageous. With the discharge device (10) according to the invention and the filter device (20), even polymer melts that are difficult to filter, in particular PA or PET, can be filtered reliably and in a precisely controllable manner. Compared to a previously known discharge device, the discharge device (10) disclosed here has the advantage that the continuously discharged pressure screw conveyor (12) delivers against a storage volume (18) which is formed by the discharge head (13), the discharge housing (14) and the discharge piston (16). is sealed from the ambient air.

The sole use of a discharge head with discharge piston without an upstream pressure screw conveyor would not build up sufficient internal pressure to actuate the discharge head with low-viscosity polymer melts. A discharge screw alone, on the other hand, would not adequately seal the filter chamber (27) from the ambient air. In the case of low-viscosity polymer melts in particular, conveying against a sealed storage volume is particularly advantageous.

Another particular advantage of the discharge device (10) disclosed here lies in the separation of the stripping function and the discharge function. The scraper (22) in contact with the rotating filter screen (32) is subject to particular mechanical loads. A static wiper that is easy to position and replace is particularly advantageous here. In the proposed invention, the discharge device (10) and the scraper (22) can be adjusted and serviced separately and/or together.

The scraper (22) preferably extends over the entire axial length of the filter screen (32). Preferably, the scraper (22) separates the filter space (27) in the tangential direction of flow of the material along the surface of the filter screen (32) at approximately three quarters of the circumference, starting from the material feed. In this way, the material separated on the filter surface is collected along a large part of the filter rotation and reliably discharged by the discharge device (10). The filter sieve is behind the scraper (22) in the direction of rotation (32) again free of deposited substances when the material supply (25) is reached.

The features and embodiments of the discharge device (10) and filter device (20) shown and/or described can be used individually or in combination with one another. In particular, the invention is not limited to the embodiment shown. Individual features can be added, omitted or replaced with the other features disclosed here. The invention is preferably designed as a filter device with the discharge device according to one of the claims. However, the discharge device can also be used as a separate assembly, for example for retrofitting or converting a filter device. Therefore, both a discharge device and a filter device are claimed.

Reference List

10 discharge device

11 discharge shaft

12 pressure screw conveyor

13 discharge head

14 discharge housing

15 lids

16 discharge piston

17 discharge opening

18 storage volume

19 connection interface

20 filter device

21 housing

22 wipers

25 Material Feed

26 material removal

27 filter room

28 material flow

30 filters

31 filter shaft

32 filter screen

F filter axis

A discharge axis

H hub

Claims

patent claims

A discharge device for a filter device (20) for separating impurities from a material melt, in particular a polymer melt, the discharge device (10) being designed to discharge separated material from a filter chamber (27) of the filter device (20), the discharge device (10 ) comprises a discharge shaft (11) with a pressure screw conveyor (12) and a discharge head (13).

2 discharge device according to claim 1, wherein the discharge device (10) comprises a metering discharge head (13).

3 discharge device according to claim 1 or 2, wherein the discharge head (13) is arranged at the end of the pressure screw conveyor (12).

4 discharge device according to one of the preceding claims, wherein the discharge head (13) seals the filter chamber (27) and / or the pressure screw conveyor (12) from the environment.

5 Discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) is designed to promote material while increasing the pressure in the discharge head.

6 Discharge device according to one of the preceding claims, wherein the discharge head (13) is designed to generate a portioned and / or intermittent material discharge.

7 Discharge device according to one of the preceding claims, wherein the discharge head (13) comprises at least one discharge plunger (16).

8 discharge device according to claim 7, wherein the discharge piston (16) is slidably mounted in the discharge head (13).

9 discharge device according to claim 7 or 8, wherein a determined discharge volume is formed by the stroke of the discharge piston (16) in the discharge head (13).

10 Discharge device according to one of the preceding claims, wherein the material discharge can be controlled, in particular metered, by the rotational speed of the discharge shaft (11) and/or by the stroke of the at least one discharge piston (16) in the discharge head (13).

11 Discharge device according to one of the preceding claims, wherein the discharge device (10) comprises a discharge housing (14).

12 Discharge device according to claim 11, wherein the discharge housing (14) comprises at least one discharge opening (17).

13 Discharge device according to claim 12, wherein the discharge opening (17) is associated with a discharge piston (16). 14 Discharge device according to one of claims 11 to 13, wherein the discharge housing (14) is designed to be sealingly and / or releasably attached to a housing (21) of the filter device (20).

15 Discharge device according to one of claims 11 to 14, wherein the discharge head (13), in particular sealingly with respect to the environment, is arranged in the discharge housing (14).

16 Discharge device according to one of the preceding claims, wherein the discharge device (10) forms a storage volume (18), in particular on the discharge head (13).

17 Discharge device according to one of the preceding claims, wherein the discharge device (10), in particular the discharge head (13) and / or the discharge housing (14) and / or the at least one 19

Discharge piston (16) is designed to seal off a back pressure on the discharge head (13), in particular in the back-up volume (18), from the environment.

18 Discharge device according to one of the preceding claims, wherein the discharge device (10), in particular the discharge head (13) and/or the discharge housing (14) and/or the at least one discharge piston (16), is designed to especially against penetrating air to seal against the environment. 19 Discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) is designed to promote separated material out of the filter chamber (27).

20 discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) is designed to promote separated material from the filter chamber (27) to a metering and / or sealing discharge head (13).

21 Discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) is designed to discharge a continuous stream of material from the filter chamber (27). 22 Discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) between the filter chamber (27) and the discharge head (13), in particular the storage volume (18) on the discharge head (13), is connected.

23 Discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) is designed to create a pressure gradient between the filter chamber (27) and the discharge head 20

(13), in particular from a filter pressure in the range of 10 to 20 bar to a discharge pressure in the range of 40 to 50 bar. Discharge device according to one of the preceding claims, wherein the pressure screw conveyor (12) is designed as a helix on the discharge shaft (1 1). Discharge device according to one of the preceding claims, wherein the discharge head (13) on the discharge shaft (11), in particular at one end of the discharge shaft (1 1), is arranged. Discharge device according to one of the preceding claims, wherein the discharge head (13) is releasably attached to the discharge shaft (11), in particular screwed. Discharge device according to one of the preceding claims, wherein the discharge head (13) and the pressure screw conveyor (12) can be combined in a modular manner in several embodiments, in particular for several pressure levels or conveying capacities, and/or a uniform connection interface (19) between the discharge head (13) and the pressure screw conveyor (12) have. Discharge device according to one of the preceding claims, wherein the discharge unit (10), in particular the pressure conveyor screw (12), is designed to generate a dynamic pressure on the discharge head (13), in particular on the at least one discharge piston (16). Discharge device according to one of the preceding claims, wherein the stroke of the discharge piston (16) is actuated by a dynamic pressure at the discharge head (13) built up by means of the pressure conveyor screw (12), in particular increased compared to the filter chamber (27). 21 Filter device for separating impurities from a material melt, in particular a polymer melt, with a housing (21), a filter (30) and a filter chamber (27) on the surface of the filter (30), the filter device (20) having a discharge device ( 10) according to any one of the preceding claims. Filter device according to claim 30, wherein the filter device (20) comprises a filter (30) with a drum-shaped filter screen (32). Filter device according to claim 30 or 31, wherein the filter device (20) comprises a scraper (22) which is designed to scrape deposited material on the rotating filter (30). Filter device according to one of the preceding claims, wherein the filter device (20) comprises a static scraper (22) which is in particular adapted to be arranged on the outside of a rotating filter screen (32). Filter device according to claim 32 or 33, wherein the scraper (22) is replaceable and / or through the housing (21) into the filter chamber (27) can be inserted. Filter device according to one of the preceding claims, wherein the filter (30) has a filter shaft (31) and the discharge device (10) has a separate discharge shaft ( 11 ). Filter device according to one of the preceding claims, wherein the discharge axis (A) of the discharge shaft (11) of the discharge device (10) is arranged parallel, in particular radially offset, to the filter axis (F) of the filter shaft (31) of the filter (30). 37 Filter device according to one of the preceding claims, wherein the pressure screw conveyor (12) is arranged in a wall of the housing (21) of the filter device (20) and/or projects into the filter chamber (27), in particular in the area of the scraper (22). 38 Filter device according to one of the preceding claims, wherein the filter chamber (27) is sealed off from the ambient air by the housing (21) and the discharge device (10).