DE19801733A1 - Centrifuge separating biological contaminants, e.g. meat, protein, food residues from waste water - Google Patents

Abstract

the waste water is conveyed into the centrifugal separator (3). Under centrifugal force it moves axially along the separator in one or both directions. It cascades through annular chambers formed by rings (16) projecting from the inner wall. Biological contaminants sediment into the chambers (13). An Independent claim is included for the corresponding centrifugal separator. Preferred features: Centrifugal pressure exerted by the fluid compresses the organic contaminants. The sediment is removed mechanically or manually, after a defined interval. The waste water is introduced centrally, to run parallel to the central axis (15) in both directions. It may be introduced at one end.

Description

The invention relates to a method and an apparatus for the separation of waste water with bio-organic dirt load in solids and liquids as well as in liquid mixtures bio-organic origin in the individual Liquids.

Such devices and methods are already known. A device of such known devices is the so-called decanter centrifuge. The mixture flows continuously through an inlet pipe into a distributor head and will end up through a solids transport screw issued a conical part of a solid jacket drum. There the mixture is distributed over the surface of the Drum. Bearings under the influence of centrifugal force solid on the outer surface. The faster than the solid screw conveyor transports the screw now the solid out of the liquid zone into the Drying zone. There the solid reaches the end of the coni drum and through the discharge device into one Solids scavenger.

Furthermore, a solid-bowl peeling centrifuge is known also for sedimentation of wastewater with bio-organic Dirt load can be used.

A major disadvantage in the treatment of liquids with bio-organic protective cargo of such devices gene is that such devices are very expensive the manufacture and on the other hand, very complex  Easily adjust processes. In addition, they are not always for suitable for simple, concentrated use.

It is therefore the object of the invention to provide a simple sy create a system that allows wastewater with bioorgani high dirt load, for example solids such as organic substances (meat, proteins, leftovers etc.) from rivers to separate liquids such as fats / oils and water as well as rivers Mixtures of liquids, for example oil / fat and water to separate others. The system is designed to be flexible on different Solids and liquid mixtures but also on ver different throughput sizes can be adapted.

The solution principle of the task is a standard modified centrifuge in such a way that the Trom mel or the separating element rotating in the centrifuge ment is divided into several individual chambers, the Individual chambers are formed by ring elements that join the inner wall of the separation element are attached and he is almost vertical in the direction of the axis of rotation stretch and over a defined distance from the Extend inner wall of the separation element. That so in the separation element discharged waste water, the solid contains such as meat, proteins, leftovers etc., which can also be or are compressible at the same time runs like a cascade under the influence of centrifugal force the individual chambers, with a so-called in each chamber te sedimentation takes place by the materials themselves separate from the liquid and deposit there.

The solution to the problem is a method for Ab separate from any solids from liquids create waste water with bio-organic dirt freight in batches or continuously under centrifugal force is applied and so solids from the  Liquid are separated, the wastewater with bioor ganic dirt load by means of a facility in a Drum is introduced and the waste water with bioorgani shear dirt load under the influence of the centrifugal force itself axially in the longitudinal extension of the drum in one or moved in both directions and by one of the In nenwandung to the center of the drum extending and at a defined distance from the inner wall existing ring element formed by cascade runs and the bio-organic dirt load gets into the chimney sedimented.

Furthermore, a Vorrich is used to carry out the method with a separation rotating around a central axis element proposed, the separation element in Axial direction has at least one opening and from the inner wall of the separation element at least one Ring element is arranged such that this at the In nenwandung is fixed and over a defined Län ge extends in the direction of the central axis and so within of the separation element came at least one sedimentation mer is formed.

An advantage of the invention is that with simple Means a system has been created, for example se wastewater containing solids, such as orga are interspersed with high efficiency sedimented. By one or more in the separationse element formed sedimentation chambers succeeds in that a wastewater introduced into the separation element bio-organic dirt load through the action of the centrifuge galkraft from the introduction point over the one or more sedimentation chambers towards in the separation element ment provided opening. During this process is stored in the individual sedimentation chambers  fabrics off. Through the opening, the almost reaches stuffed liquid. The process of separating waste water therefore with bio-organic dirt loads advantage because most of the particles are bioorganic Dirt loads are compressible and so in the chimney easy to deposit. The sewage or what remains in the chambers after sedimentation, "overflows" each ring element (overflow edge) like a cascade up to the opening of the separation element.

Due to the centrifugation process, a liquid pressure built up, which minimizes the bio-organic dirt load at least partially compressed. There is a sediment tion in the sedimentation chambers in such a way that in in the first chamber the larger particles con center and sediment, then in the further one Chamber the larger particles of the remaining particles and in the following chambers the larger particles the remaining particles in the same way and Way to concentrate and sediment.

Another advantage is that the separations element can be used variably. The basic idea is that Ring elements are provided within the separation element are defined by the inner wall of the separation elements are spaced. This will make the flow of the wastewater with bio-organic dirt load a so-called called cascade formed, being in the axial direction to the outside the degree of sedimentation in the respective chamber takes and only small particles are deposited there. An arrangement of several chambers means a crate the degree of sedimentation.

In another embodiment of the invention in the cylindrical separation element two  Openings provided. Both are on the end faces of the Se arranged paration element. This ensures that when the wastewater is introduced with bio-organic dirt loads two flows in the middle of the separation element directions of the mixture are formed, namely a Flow direction axially in the direction of the first opening and a flow towards the second opening. With the same Efficiency as in the first embodiment can the introduction of wastewater with bio-organic dirt freight can be increased.

The arrangement and the number of sedimentation chambers agree with the solids content in the wastewater bio-organic dirt load. By determining the resp gen chamber sizes, by determining the number of Kam by defining the separa used here tion elements in combination with the type of chamber, Kam number and the compilation of various chambers ten and by determining the speed of the separation units time, length of stay and the amount of freight brought in can be an optimal result of wastewater dematerialization can be achieved with bio-organic dirt.

So that better pre-sedimentation before introduction the mixture can take place in the sedimentation element, can wastewater with bio-organic dirt load Flocculants and / or precipitants are added. This allows the suspended and solid matter to be bound and can already sediment in the first chambers. To achieve a higher effect of sedimentation is advantageously provided that the ring elements with are of different widths. Under the width is the distance between the inner wall and the center axis of the separation element pointing end  To understand (overflow edge) of the ring element. Preferably takes the width to the respective opening of the separation elements.

Further advantageous embodiments are given in the claims chen and the following description and claims forth. Show it

Figure 1 is a schematic side view of a centrifuge ge together with the separation selement invention.

Fig. 2 is a schematic view of an exemplary embodiment of the separation element according to the invention;

Fig. 3 is a schematic view of another exemplary embodiment of the separation element according to the invention;

Fig. 4 is a schematic view of another exemplary embodiment of the separation element according to the invention.

In Fig. 1 a centrifuge 1 is shown. This centrifuge 1 comprises a drive device 2 and a separation element 3 coupled to the drive device. Both parts are combined in a housing 4 . Furthermore, at least one fluid guide with an outlet opening 5 is provided in the housing 4 . This fluid guide serves to ensure that the liquid emerging from the separation element passes through the housing 4 via a flow path shown in the drawing with arrows 6 to the outlet opening 5 . The separation element 3 is anchored in a device 7 , the separation element 3 being easily removable from it in the axial direction.

Via a opening 8 shown in this exemplary embodiment in the separation element 3 , a device 9 can be guided. This device 9 is on the one hand hen for bringing the wastewater with bio-organic dirt into the separation element. For this purpose, the mixture flows through a tube 10 in the axial direction 11 and arrives at the end of the tube 10 via nozzles 12 in the separation element 3 . On the other hand, the device 9 for clearing the sedimentation chambers 13 arranged in the separation element 3 is provided.

In the embodiment shown in FIG. 1, the cylindrical separation element 3 has only one opening 8 provided on the end face. Via this opening, the liquid comes out of the separation element 3 after the cascade, which are formed by the individual sedimentation chambers 13 , have been passed through.

The separation element 203 shown in FIG. 2 differs from the first embodiment shown in FIG. 1 in that the separation unit 203 has two end openings 208 a, 208 b. In addition, the sedimentation chambers 213 are arranged such that a large sedimentation chamber 213 and therefrom to the starting end openings toward small chambers 213 are easily seen in the central region of the separation element 203rd The wastewater with bio-organic dirt load is introduced via a unit 209 and the nozzles 212 located at the end of the unit 209 at the height of the large sedimentation chamber 213 . The solid-liquid mixture introduced here is now pressed by the action of a centrifugal force to the two openings 208 a, 208 b, the mixture being positively guided in a cascade manner over the ring elements 216 and solids settling in each chamber 213 .

The ring elements 216 themselves are also attached to the inner wall 214 of the separation element 203 and extend over a defined distance from the central axis 215 of the separation element 213 .

For the removal of the deposited in the chambers 213 Se diments, as shown in Fig. 1 in part, a with the unit 9 forming a unit is seen before. In addition, fixed, vane-shaped elements 318 , which can be set parallel to the central axis, are provided, which bring the sediment out of the chambers 213 by rotating the separation chamber and lead it to the transport screw.

The third embodiment of a separation element 303 shown in FIG. 3 also has a plurality of sedimentation chambers 313 which are formed by ring elements 316 which are attached to the inner wall 314 and extend to the central axis 315 . However, the distance between the Innenwan extension 314 and the end of the extension of the ring element in the direction of the central axis is different. The width of the ring elements 316 decreases towards the openings 308 a, 308 b and thus also forms a cascade for the wastewater flowing through with bio-organic dirt load.

Also provided are clearing elements which are adapted to the respective chamber sizes and are moved for use par allel (arrow 319 ) to the central axis 315 .

The embodiment of a separation element 403 shown in FIG. 4 is provided for separating liquids with a high density from liquids with a lower density, for example oil / fat and water. For this, the mixture is brought into the middle sedimentation chamber 413 . By the action of the centrifugal force, the mixture in the middle chamber shown in the drawing is pressed against the inner wall 414 , from where it then passes through adjacent passages 417 provided in the ring elements 416 . Due to the fact that the mixture is positively guided along the inner wall 414 through the respective passages 417 , the liquid with the lower density increases in the adjacent chamber. Here, for example, the oil / fat can be extracted or tapped with a corresponding device 409 , in particular a suction element or a clearing element 418 from the surface of the usual liquid in the direction of the arrows 420 shown in FIG. 4.

Depending on the formation of the wastewater with bio-organic Dirt loads can be specified for the application real arrangements of the individual sedimentation chambers sieren, so that an effective separation of waste water with bio-organic dirt load or a liquid ge mixing takes place in individual liquids.

Claims (13)

1. A method for separating essentially biological solids from wastewater and wastewater mixes into the respective individual liquids by batchwise or continuously placing a wastewater with bio-organic dirt load under the action of centrifugal force and thus separating solids from the liquid, characterized in that that the waste water with bio-organic dirt load is introduced by means of a device ( 9 ; 209 ; 309 ; 409 ) into a separation element ( 3 ; 203 ; 303 ; 403 ) and the waste water with bio-organic dirt load is almost axially elongated under the action of the centrifugal force the separating element (3, 203; 303; 403) moves in one or in both directions, by one or more of the inner wall (14; 214; 314; 414) projecting from the ring element (16; 216; 316; 416) chamber formed ( 13 ; 213 ; 313 ; 413 ) or in chambers cascading and thereby bioorganically e Dirt load in the respective chamber ( 13 ; 213 ; 313 ; 413 ) sedimented. 2. The method according to claim 1, characterized in that the liquid caused by the centrifugation process pressure the bioorganic dirt load at least partially compressed. 3. The method according to claim 1, characterized in that the solids or liquid proportions that are after a defined period of centrifuge exposure have separated gas power from the rest of the wastewater in the Chambers deposit and through a funding unit or manually transported out of the chambers.   4. The method according to any one of the preceding claims, characterized in that the wastewater with bioorgani cal dirt load in the middle of the separation element ( 3 ; 203 ; 303 ; 403 ) is introduced and thereby the flow of wastewater is almost parallel to the central axis ( 15 ; 215 ; 315 ; 415 ) spreads in both directions. 5. The method according to any one of claims 1 to 4, characterized in that the waste water with bio-organic dirt load at one end of the separation element ( 3 ; 203 ; 303 ; 403 ) can be introduced. 6.Device for carrying out the method for separating essentially biological solids from waste water and waste water mixtures into the respective individual liquids, by placing waste water with bio-organic dirt load in batches or continuously under the action of centrifugal force and thus separating solids from the liquid, with a separating element ( 3 ; 203 ; 303 ; 403 ) rotating about a central axis ( 15 ; 215 ; 315 ; 415 ), characterized in that

• - The separation element ( 3 ; 202 ; 303 ; 403 ) has at least one opening ( 8 ; 208 a, 208 b; 308 a, 308 b; 408 a, 408 b) in the axial direction and
• - On the inner wall ( 14 ; 214 ; 314 ; 414 ) of the separation element ( 3 ; 203 ; 303 ; 403 ) at least one ring element ( 16 ; 216 ; 316 ; 416 ) is arranged such that it on the inner wall ( 14 ; 214 ; 314 ; 414 ) and extends over a defined length in the direction of the central axis ( 15 ; 215 ; 315 ; 415 ) and thus within the separation element ( 3 ; 203 ; 303 ; 403 ) at least one sedimentation chamber ( 13 ; 213 ; 313 ; 413 ) is formed.

7. The device according to claim 6, characterized in that in the separation element ( 3 ; 203 ; 303 ; 403 ) attached ring elements ( 16 ; 216 ; 316 ; 416 ) at the same chem distance from the inner wall ( 14 ; 214 ; 314 ; 414 ) of the separation element ( 3 ; 203 ; 303 ; 403 ) are spaced apart. 8. The device according to claim 6, characterized in that in the separation element ( 3 ; 203 ; 303 ; 403 ) attached ring elements ( 16 ; 216 ; 316 ; 416 ) at different distances from the inner wall ( 14 ; 214 ; 314 ; 414 ) of the separation element ( 3 ; 203 ; 303 ; 403 ) are detached. 9. The device according to claim 6, characterized in that the discharge of the ring elements ( 16 ; 216 ; 316 , 416 ) to the central axis ( 15 ; 215 ; 315 ; 416 ) in the axial direction towards the opening ( 8 ; 208 a; 208 b; 308 a; 308 b; 408 a; 408 ) decreases. 10. The device according to claim 6, characterized in that the ring elements ( 16 ; 216 ; 316 ; 416 ) in the region of the inner wall ( 14 ; 214 ; 314 ; 414 ) of the separation element ( 3 ; 203 ; 303 ; 403 ) at least one passage ( 417 ) for fluid communication from one chamber to another. 11. The device according to claim 6, characterized in that for removing the sedimented solid from the sedimentation chambers ( 13 ; 213 ; 313 ; 413 ) a device ( 9 ; 209 ; 309 ; 409 ) is provided which axially into the separation element ( 3 ; 203 ; 303 ; 403 ) protrudes and perpendicular to the central axis ( 15 ; 215 ; 315 ; 415 ) of the device ( 9 ; 219 ; 319 ; 419 ) there are blade-like elements ( 318 ; 418 ) provided by rotation of the separation element ( 3 ; 203 ; 303 ; 403 ) clear out the individual sedimentation chambers ( 13 ; 213 ; 313 ; 413 ). 12. The apparatus according to claim 6, characterized in that the individual ring elements ( 16 ; 216 ; 316 ; 416 ) within the separation element ( 3 ; 203 ; 303 ; 403 ) are axially displaceable. 13. The apparatus according to claim 6, characterized in that at least one further ring element between the sedimentation chambers ( 3 ; 203 ; 303 ; 403 ) forming ring elements ( 16 ; 216 ; 316 ; 416 ) for discharging the waste water with bio-organic dirt to the openings ( 8 ; 208 a, 208 b; 308 a, 308 b; 408 a, 408 b) is seen in front.