EP4037839A1

EP4037839A1 - Solid-bowl screw centrifuge

Info

Publication number: EP4037839A1
Application number: EP20785946.3A
Authority: EP
Inventors: Poul-Erik Aagaard
Original assignee: GEA Mechanical Equipment GmbH
Current assignee: GEA Mechanical Equipment GmbH
Priority date: 2019-09-30
Filing date: 2020-09-30
Publication date: 2022-08-10
Also published as: DE102019126325A1; US20220347698A1; WO2021064025A1

Abstract

A solid-bowl screw centrifuge which has a housing (100) and a rotor (200) rotatably mounted in the housing (100) and comprises the following: a rotatable drum (210) with an axis of rotation (D), wherein the drum (210) has a cylindrical portion (211) and a conical portion (212), and also at least one liquid outlet (217), which is arranged in the cylindrical portion (211) of the drum (210), and at least one solid discharge (218), which is arranged in the conical portion (212) of the drum, a screw (230), which is arranged in the drum and can rotate at a differential speed in relation to the rotatable drum (210), wherein the drum (210) and the screw (230) together form the rotor (200), at least two drum bearings (221, 222) for mounting the drum (210) in the housing (100), and at least one screw bearing (236) for mounting the screw (230) in the drum (210), is distinguished by the fact that the drum (210) and the screw mounting (235) are designed in the region of the conical portion (212) or the dry zone in such a way that solid matter Fe is transported with the aid of the screw (230) up to a solid-discharge drum cover (223), which forms the termination of the conical portion (212) in the axial direction of the drum (210), in order to leave the drum (210) through multiple openings (224) in the solid-discharge drum cover (223).

Description

Solid bowl screw centrifuge

The invention relates to a solid bowl screw centrifuge according to the preamble of claim 1.

A solid phase can be separated from a suspension with a solid bowl screw centrifuge (also called a decanter). Optionally, the suspension cleared of solids in this way can be separated into different liquid phases in a design with two liquid outlets. Solid bowl screw centrifuges are very well suited to processing comparatively high solids concentrations in the feed stream, are comparatively robust, achieve a very good separation result and cause good drying of the solids.

Known solid bowl screw centrifuge with a non-rotating or non-rotating frame during operation have a rotatable or rotating Ro tor, which in turn has a drum and a screw rotatable at a differential speed to the drum mel. To discharge the solid material discharge openings that are essentially radially aligned are provided in a conically configured section of the drum.

If the energy loss that is caused when the solids are thrown out of the drum of the solid bowl screw centrifuge is as small as possible, the radius on which the solids discharge openings are located in the drying zone or in the conical section of the drum must be as small as possible .

If a solid bowl screw centrifuge is to be operated in such a way that the so-called pond depth - this results from the difference between the inner diameter of the drum and the diameter of the liquid weir up to which the suspension in the drum reaches inwards - is as large as possible, this requires the solid to be dropped as close as possible to the axis of rotation. For this, too, the radius on which the solids discharge openings are located in the drying zone or in the conical section of the drum must be as small as possible. In this respect, KR 101 422567 B1 is mentioned with regard to the technological background.

In common solid bowl screw centrifuges according to the state of the art - as shown e.g. in DE 102018119279 A1 - the outlet opening for the solid is usually oriented essentially radially in the outer shell of the drum at the end of the drying zone or the conical section of the drum.

One reason for this is that the distance between the drum bearings determines the critical speed of the rotating system and therefore the drum length is limited. In order to use the full length between the bearings for the separation and drying zone of the drum, the solid is usually ejected radially through the conical drum wall.

From WO 2018/202358 A1, screw-in solids discharge sleeves are known, with both the pond depth and the discharge diameter being able to be changed by the screw-in depth of the discharge sleeves.

The disadvantage of the technical teaching of WO 2018/202358 A1 is that no smaller discharge diameter than the smallest diameter of the conical section of the drum can be set.

The object of the invention is to reduce these problems.

The invention solves this problem with the subject matter of claim 1.

According to the code, the drum in the area of the conical section or the drying zone is designed in such a way that solid Fe is transported with the aid of the screw to a solid discharge drum cover, which forms the end of the conical section in the axial direction of the drum exit the drum through a plurality of axially or essentially axially aligned openings in the solids discharge drum cover.

Here and thereby the discharge diameter of the solids discharge can advantageously be designed to be smaller than the smallest inner diameter of the conical section of the drum. In this case, or for this purpose, the effective openings for solid material discharge in the solid material discharge drum cover are located within, preferably completely within, the smallest inner diameter of the conical area of the drum. In this way, the energy loss that is caused when the solid is thrown out of the bowl of the solid bowl screw centrifuge can be kept very low. Furthermore, a solid bowl screw centrifuge according to the invention can advantageously be operated with as great a pond depth as possible.

The axially or essentially axially extending openings in the conical section of the solids discharge drum cover for solids discharge are aligned at a larger angle than the cone angle of the inner conical area of the drum and / or the outer conical area of the screw. Preferably, the angle is even 90 ° to the axis of rotation or more than 45 °, in particular more than 60 °, to the axis of rotation of the drum. It can preferably be provided be that the one or more openings for solids discharge are formed in the conical section of the solids discharge drum cover, whereby it can then be provided that the conical section of the solids discharge drum cover has a cone angle of more than 45 °, especially more than 60 ° , has to the axis of rotation.

It can further be provided that in the conical section of the solids discharge drum cover the openings are arranged on a pitch circle with a diameter d1 which is smaller than the smallest diameter of the inner conical section of the drum.

In a preferred embodiment of the invention, the openings in the solids discharge drum cover are preferably partially (partially) covered by an exchangeable cover element, in particular an exchangeable cover plate in which aperture-like openings can be formed. By means of several cover elements, in particular cover plates with different placed and / or dimensioned openings, a simple and thus advantageous adjustment possibility of the solids discharge openings is created. In this way, the openings of the cover element used, in particular the cover plate, define the “effective” openings through which the solid can leave the drum on the drum cover.

According to one embodiment, the diaphragm-like openings can be arranged in a circle on a pitch circle with a diameter d1 and have an opening diameter d2.

It can then be advantageously provided that both the diameter d1 and the diameter d2 can be changed by exchanging the respective cover plate. For this purpose, cover plates with different opening arrangements must be provided. In this way, the solids outlet can easily be changed over a wide range and thus easily and individually adapted to the specific conditions of the respective application of the solid bowl screw centrifuge. The cover plate can advantageously be arranged on the outside of the drum cover, where it can be easily changed. But it can also be arranged inside.

According to another embodiment of the invention it can be provided that a sleeve or disk is rotatably mounted in each of the openings of the solids discharge drum cover. It can further advantageously be provided that each sleeve or the disk has an opening which is preferably eccentric in the Sleeve / disc is formed. This creates a simple and therefore advantageous possibility of adjusting the solids discharge. It is also advantageous if and that by rotating the respective sleeve / disk about its center point, which is on a diameter d3, the diameter on which the respective opening is located can be changed. As a result, the radius on which the center of the opening of the solids outlet lies can easily be changed over a wide range and thus individually and easily adapted to the specific conditions of the respective application of the solid bowl screw centrifuge.

In a preferred embodiment of the invention, the solids discharge drum cover has a cylindrical section which, after an additional development, can be attached to a drum shaft section. This results in an advantageously simple fastening of the solids discharge drum cover to the drum, which also allows the solids discharge drum cover to be retrofitted on solid-jacket screw centrifuges according to the prior art without major modifications.

According to a variant, it can further advantageously be provided that a screw shaft section or a pin which can be coupled to such a screw shaft section is formed in the conical section of the solids discharge drum cover. In particular, the integrated screw shaft section of the solids discharge drum cover results in an advantageously simple assembly of the screw shaft bearing, which also allows the solids discharge drum cover to be retrofitted on prior art solid bowl screw centrifuges without major modifications. If the screw shaft section is formed in one piece on the conical section of the solids discharge drum cover, the result is a solids discharge drum cover that is advantageously easy to manufacture in terms of manufacturing technology and that can be manufactured, for example, by forging or casting and that can be completely mechanically processed in one clamping.

According to an optional development, the cylindrical section of the drum has a length Li and the conical section of the drum has a length L2, where Li and L2 add up the length LT of the drum and the drum bearings for mounting the drum in the housing are spaced apart by a distance LL are, with the stand LL from the drum bearings to each other is smaller than the length LT of the drum.

Due to this advantageous arrangement of the drum bearings, the critical speed of the drum can be in a higher speed range than with solid-bowl screw centri fuge according to the prior art. As a result, the separation performance of the Solid bowl screw centrifuge can be advantageously increased without having to increase the volume of the bowl.

Further advantageous refinements of the invention can be found in the subclaims.

The invention is described in more detail with reference to the drawing using Ausfüh approximately examples. Features that are described in connection with these exemplary embodiments can also be used in other - not illustrated presented - exemplary embodiments of the invention and can therefore also be used as features for claims. Show it:

FIG. 1: a schematic view in section of a full-jacket screw centrifuge according to the invention;

FIG. 2: in a) view of the solids discharge drum cover of a first embodiment of the drum of the solid bowl screw centrifuge from FIG. 1, in b) a sectional view of the enlarged detail of the solids discharge drum cover according to FIG. 2a and of the conical section of the drum ;

FIG. 3: in a) view of a solids discharge drum cover of another

Design variant of the drum of the solid bowl screw centrifuge from FIG. 1, in b) a sectional view of the enlarged detail of the solids discharge drum cover according to FIG. 3a and of the conical section of the drum;

FIG. 4: a schematic view in section of a solid bowl screw centrifuge according to the prior art;

First, the construction of FIG. 4 will be described, which is further developed in FIG. 1 according to the invention.

4 shows a solid bowl screw centrifuge with a frame 100 which is not rotatable or does not rotate during operation - which can preferably be designed as a type of housing - and a rotor 200 which can be rotated or rotates during operation. The rotor 200 has a rotatable drum 210 with a horizontal axis of rotation D. The axis of rotation D can, however, also be oriented differently, in particular vertically, in space. The rotor 200 also includes a worm 230 arranged in the drum 210, the axis of rotation of which coincides with the axis of rotation of the drum 210.

The drum 210 has a cylindrical section 211 with a length Li and an axially adjoining conical section 212 with a length L2. The cylindrical section 211 is closed here by a drum cover 213 which extends essentially radially. In the conical section 212 with the length L2, the drum is preferably designed conically on the inside and outside (in relation to the drum jacket).

The screw 230 here also has a cylindrical section 231 and a conical section 232 axially adjoining it. It is arranged inside the drum 210. The screw 230 can be rotated at a speed difference to the drum 210 during operation.

In the drum 210 protrudes a concentric here to the axis of rotation inlet pipe 214 which opens into a distributor 215 through which a suspension Su to be processed can be passed radially into a centrifugal chamber 216 of the drum 210 here. The inlet pipe 214 can either be guided into the drum 210 from the side of the cylindrical drum section 211 or it can be guided into the drum 210 from the side of the conical drum section 212.

One or more liquid drains 217 can be formed in or on the drum cover 213. These can be designed in various ways, such as openings in the drum cover 213, which have a kind of overflow weir, or in other ways, such as peeling discs.

At least one solids discharge 218 is formed at the end of the conical section 212.

The drum 210 is designed as a solid jacket drum. In the rotating drum 210, at least one liquid phase Fl is clarified from solids Fe. The at least one liquid phase F1 exits from the liquid drain 217 at the drum cover 213. In contrast, the solids Fe are transported by the screw 230 in the direction of the solids discharge 218 and there ejected from the drum 210. A first drum shaft section 220 can be axially connected to the drum cover 213 or to the actual drum 210, which is connected to the drum 210 in a rotationally test manner, and a second drum shaft section 219, which is also rotationally fixed to the drum 210, can be connected axially to the conical drum section 212 connected is.

The cylindrical section 231 of the worm 230 is axially adjoined by a first worm shaft section 234, which can be connected to the worm 230 for rotation. The conical section 232 is placed on a bearing 235. This bearing 235 can be placed on a second screw shaft section 233.

A drive device, which can have one or two motors, is used to drive the rotor 200. The drive device 300 can be followed by at least one transmission 310, on which two pulleys 320, 330 are shown schematically here, which indicates that the transmission 310 can have at least two interfaces for feeding a respective torque of the motor or motors into the transmission 310 in order to to drive the drum and the screw. Alternatively (not shown here) the drive of the rotor can also follow in other ways.

According to FIG. 4 (and preferably also according to the variants of the invention), the gear 310 rotates the drum 210 on the one hand and the worm 230 on the other hand. For this purpose, the gear 300 can have two output shafts. The first output shaft can be coupled non-rotatably to the first drum shaft section 220 or coupled directly to the drum 210. The second output shaft, on the other hand, can be coupled directly or indirectly to the first screw shaft section 234 in a rotationally fixed manner or directly to the screw 230.

The drum 210 can be rotatably mounted with two axially offset arranged drum bearings 221, 222 in the direction of the axis of rotation. The term “camp” should not be defined too narrowly. Each of the bearings 221, 222 can each consist of one or more individual bearings, which are then arranged axially directly next to one another, so that they can each be viewed functionally as a single bearing.

The drum bearings 221, 222 can advantageously be arranged between the drum 210 and the frame 100 or one or more element (s) connected to the frame, so that the drum 210 can be rotated relative to the frame 100. This also applies to all other variants shown. There are those Drum bearings 221, 222 are preferably arranged radially between the drum 210 and the frame 100 or one or more element (s) connected to the frame.

The screw bearings 235, 236, on the other hand, can be arranged radially between the screw 230 and the drum 210, so that the screw 230 can be rotatable relative to the drum 210.

In one possible embodiment variant (not shown), one of the screw bearings 235 in the area of the solids discharge 218 can be omitted. This can be provided, for example, with a vertical arrangement of the decanter.

Preferably, according to FIG. 4 - as well as according to FIG. 1 and further variants of the invention - one or even both drum bearings 221, 222 can be arranged within the axial area between the solids discharge 218 and the liq sigkeitsflow 217 of the drum 210 or directly adjoins a region of the liquid drain 217 and / or a solids discharge 218 of the drum 210. The drum bearings 221, 222 are then positioned radially on the outside on the drum 210 or radially or axially on the outside on or on the drum cover 213.

If one of the drum bearings 221, 222 is arranged within the axial area that lies between the solids discharge 218 and the liquid discharge 217 of the drum 210, the other of these bearings - the other of the drum bearings 221, 222 - can be arranged outside this axial area.

It can be provided that the drum bearings 221, 222 for mounting the drum (210) in the housing (100) are spaced apart by a distance LL, the distance LL of the drum bearings 210 being smaller than the axial length LT of the drum .

In a preferred embodiment, the above features can also have the Vollman tel screw centrifuge of FIG. 1 and other figures, as well as other variants of the invention. With her, however, the solids discharge and preferably also the storage can be designed in a different way.

In the solid bowl screw centrifuge according to the prior art in FIG. 4, the solids discharge 218 can be designed in such a way that the openings of the solids discharge 218 are directed radially or essentially in the radial direction of the drum 210. In the solid bowl screw centrifuge in FIGS. 1 and 2 and 3, the solids discharge 218 is preferably designed in such a way that the openings 224 of the solids discharge 218 are aligned axially or essentially in the axial direction of the drum 210. They are also preferably within the smallest diameter of the conical area 212 of the drum, based on the inner jacket or inner diameter.

The conical section of the solids discharge drum cover can thus either extend at a right angle to the axis of rotation or be arranged at an angle of more than 45 °, in particular more than 65 °. The openings can also be located in a further conical drum part whose angle of conicity to the axis of rotation is greater than 45 °, in particular more than 65 °.

During operation, solids in the rotating drum are first conveyed from a suspension rotating radially outside in the drum from the cylindrical area into the conical area 212 of the drum 210 and from there further conveyed or pushed further radially inward to the solids discharge 218.

For this purpose, the conical section of the drum 210 is adjoined in the axial direction by a solids discharge drum cover 223, which axially closes the conical section 212 of the drum 210. The solids discharge drum cover 223 can have a conical design in whole or in sections. The angle of conicity of the conical section 226 is larger, in particular by more than 10 ° greater than the angle of conicity in the conical section of the drum. The solids discharge 218 can be designed such that the openings 224 of the solids discharge 218 are aligned axially or essentially in the axial direction of the drum 210.

The solids discharge drum cover 223 can have one or more, for example four, openings 224 which form the solids discharge. These can be designed as window-like, circumferentially closed openings in the conical section of the solids discharge drum cover 223.

According to a variant that is structurally simple to implement, it can advantageously be provided that the solids discharge 218 is located in the axial direction relative to the cylindrical section 211 of the drum 210 behind the drum bearing 221 in the conical section 212 of the drum 210. It can also advantageously be provided that the solids discharge 218 is located behind the screw bearing 235 in the axial direction with respect to the cylindrical section 211 of the drum 210. In Fig. 2a and Fig. 2b, a variant embodiment of the solids discharge 218 is Darge, which has openings 224 which are aligned in the axial or essentially axial direction Rich.

A cover plate 225 is attached to the solids discharge drum cover 223 on the inside or preferably on the outside. The cover plate 225 can be exchangeable, in particular it can be attached to the rest of the drum 210, in particular the drum cover 223 for solid discharge. The cover plate 225 can be fastened to the solids discharge drum cover 223 exchangeably with fasteners such as screws. The cover plate 225 can have a conical shape.

The solids discharge drum cover 223 has openings 224 with a surface F1. Corresponding openings 229 are formed in the cover plate 225. This means that the openings wholly or at least partially overlap and are aligned with one another. These openings 229 can have an area that is smaller than the area F2. The cover plate 225 configured in this way acts like a screen.

The size and / or the location of the solids discharge 218 or the size and / or location of its openings 229 - when the drum is at a standstill - can thus be changed in a simple manner by placing the cover plate 225 with the openings 229 against a cover plate with openings 229 on a different surface and / or arrangement is exchanged.

The diaphragm-like openings 229 are arranged on a pitch circle with a diameter d1 and have an opening diameter d2. Depending on the requirements, both the diameter d1 and the diameter d2 can be changed by exchanging the respective cover plate 225. Through these diaphragm-like openings 229, the solid Fe emerges from the drum 210 at a variable diameter in the axial direction of the drum 210 when the cover plate 225 is replaced.

According to optional developments, the solids discharge drum cover 223 can have one or more further advantageous features.

Thus, the solids discharge drum cover 223 can have a conical section 226 in which the openings 224 - here the four openings 224 - can be formed. The solids discharge drum cover 223 can also be attached to the Conical section 226 preferably have a cylindrical section 227 adjoining the cylindrical section of the drum axially.

Thus, in addition to a conical section 226, it can have a cylindrical section 227. According to an advantageous further development, it can then be fastened with the cylindrical section 227 on the drum shaft section 219, specifically preferably axially next to the drum bearing 221.

On the inside of the conical section 226, there can be an axial pin which can be inserted into the worm shaft section 233 or which can even serve as the worm shaft section 233 in a simple and surprisingly compact and practical configuration.

In a further embodiment variant according to the invention of the solids discharge 218 according to FIGS. 3a and 3b, a plurality of openings 224 are again formed in the solids discharge drum cover 223. A sleeve or diaphragm or disk 228 can be rotatably mounted in one or more, in particular each of the openings. The outer diameter of the sleeves 228 thus preferably corresponds to the inner diameter of the preferably circular openings 224. The sleeves 228 are preferably rotatably arranged in the openings 224. This rotational position can be fixed by fixing means (not shown). Preferably, each sleeve or diaphragm or disk 228 has an opening 229 'which can be arranged / formed / aligned ex centrically in the preferably circular sleeve or disk 228. By rotating the respective sleeve 228 about its center point, which can lie on a diameter d3, the diameter on which the center point of the respective opening 229 ‘lies can be changed. Through the respective opening 229 in the respective sleeve 228, the solid Fe thus exits the drum 210 at a variable diameter in the axial direction of the drum 210.

The solids discharge drum cover 223 can otherwise be designed like the solids discharge drum cover of FIG. 2. List of reference symbols

100 cases

200 rotor

210 drum

211 cylindrical section

212 conical section

213 drum cover

214 inlet pipe

215 distributors

216 centrifugal chamber

217 Liquid drainage

218 solids discharge

219 drum shaft section

220 drum shaft section

221 drum bearings

222 drum bearings

223 solids discharge drum cover

224 opening

225 cover plates

226 conical section

227 cylindrical section

228 sleeve

229, 229 ‘opening

230 snail

231 cylindrical section

232 conical section

233 worm shaft section

234 worm shaft section

235 screw bearings

236 worm bearings

300 Drive device 310 Gear 320 Pulley 330 Pulley

Ai distance A2 distance D axis of rotation

Li length L2 length

LL Distance drum bearing LT Length drum

Su suspension Fe solids

Fl liquid phase

F1 area

F2 area d1 diameter pitch circle d2 opening diameter d3 diameter

Claims

Expectations

1. Solid bowl screw centrifuge with a housing (100) and a rotor (200) rotatably mounted in the housing (100) and having at least the following: a. a rotatable drum (210) with an axis of rotation (D), the drum (210) having a cylindrical section (211) and a conical section (212), b. at least one liquid drain (217) which is arranged in the cylindrical section (211) of the drum (210) and c. at least one solids discharge (218) which is arranged in the conical section (212) of the drum (210), d. a relative to the rotatable drum (210) with a differential speed ble, arranged in the drum screw (230), wherein the drum (210) and the screw (230) together form the rotor (200), e. at least two drum bearings (221, 222) for mounting the drum (210) in the housing (100), f. at least one first screw bearing (236) for mounting the screw (230) in the drum (210), characterized in that G. the drum (210) in the area of the conical section (212) or the drying zone is designed in such a way that solids Fe with the aid of the screw (230) up to a solids discharge drum cover (223), which closes off the conical section (212 ) forms in the axial direction of the drum (210), is transported to leave the drum (210) through a plurality of axially or essentially axially aligned openings (224) in the solid discharge drum cover (223), and h. that the openings (224) in the solids discharge drum cover (223) lie within, preferably completely within the smallest inner diameter of the conical area (212) of the drum (210).

2. Solid bowl screw centrifuge according to claim 1, characterized in that the solids discharge drum cover (223) has a conical section (226).

3. Solid bowl screw centrifuge according to claim 1 or 2, characterized in that the solids discharge drum cover (223) has a cylindrical section (227).

4. Solid bowl screw centrifuge according to claim 2 or 3, characterized in that the one or more openings (224) for solids discharge are formed in the conical section (226) of the solids discharge drum cover (223).

5. Solid bowl screw centrifuge according to claim 2, 3 or 4, characterized in that the conical section (226) of the solids discharge drum cover (223) has a cone angle which is greater than the inner cone angle of the conical section of the drum.

6. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the conical section (226) of the solids discharge drum cover (223) has a cone angle of more than 45 °, in particular more than 60 °, to the axis of rotation (D) .

7. Solid bowl screw centrifuge according to one of claims 2 to 6, characterized in that in the conical section (226) of the solid discharge drum cover (223) the openings (224) of which are arranged on a pitch circle with a diameter d1 which is smaller than the smallest diameter of the conical section (212) of the drum (210).

8. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that on the solids discharge (218) have the solids discharge drum cover (223), in particular on its conical section, a cover element, in particular a cover plate (225), with openings (229) is attached, which correspond to the openings (224) of the solids discharge drum cover, in particular of the conical section (226).

9. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the cover plate (225) is interchangeably designed.

10. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the openings (224) in the solids discharge drum cover (223) have a larger diameter than the openings (229) of the cover plate (225).

11. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that in the conical portion (226) of the Solid discharge drum cover (223) a screw shaft section (233) is formed or that it can be coupled to such.

12. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the diaphragm-like openings (229) are arranged circularly on a pitch circle with a diameter d1 and have an opening diameter d2, so that by replacing the respective cover plate (225) both the Diameter d1 as well as the diameter d2 can be changed.

13. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that a screw shaft section (233) is formed in the conical section (226) of the solids discharge drum cover (223) or that it can be coupled to one.

14. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the cylindrical section (226) of the solids discharge drum cover (223) is placed on a drum shaft section.

15. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that a rotatable sleeve (228) is rotatably mounted in one or more of the openings (224).

16. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that each sleeve (228) has an opening (229 ') which is arranged eccentrically in the sleeve (228) and that by rotating the respective sleeve (228) its center point, which lies on a diameter d3, the diameter on which the center point of the respective opening (229 ') lies, can be changed.

17. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the cylindrical section (211) of the drum (210) has a length Li and the conical section (212) of the drum (210) has a length L2, where Li and L2 adds the length LT of the drum (210).

18. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the drum bearings (221, 222) for supporting the drum (210) in the housing (100) are spaced apart at a distance LL, the distance LL between the drum bearings (210) being smaller than the length LT of the drum.

19. Solid bowl screw centrifuge according to one of the preceding claims, characterized in that the solids discharge (218) is located axially outside the two drum bearings of the drum.