WO2005030659A1 - Device and method for the treatment of a medium such as effluent clarifier sludge or similar - Google Patents

Abstract

A device and a method are disclosed, for the treatment of a medium containing thread- and flake-forming microorganisms, such as effluent, clarifier sludge or similar, by means of at least one shear field (34) for treating the microorganisms in the medium with mechanical stress, whereby the at least one shear field (37) is defined and limited by a pair of planar elements (28, 32), separated from each other by a shear gap and which may be driven relative to each other by means of a drive device (30) to generate the shear field (34). One of the planar elements (32) comprises a medium inlet (38), provided for the introduction of the medium for treatment into the shear gap. The medium inlet (38) is or may be connected to a feed pump (14), such that the device (10) does not siphon with at least a reduction, or an avoidance of cavitation in the shear gap of the shear field (34). At least one of the planar elements (28, 32) comprises a surface structuring (76) on the inner face thereof, facing the other planar element (32, 28) which increases the energy dissipation.

Description

Device and method for treating a medium such as waste water, sewage sludge or the like

The invention relates to a device and a method for treating a medium containing filamentous and flocculating microorganisms, such as waste water, sewage sludge, or the like, with at least one shear field for subjecting the microorganisms of the medium to mechanical stress. The invention is also suitable, for example, for organic substrates used in biogas plants, at least for reducing or avoiding the formation of expanded sludge, floating sludge and / or foam.

In sewage treatment plants with biological purification stages, there are always operating problems that can be attributed to non-sedimenting or floating sludge aggregates, particularly in the aeration tank and in the secondary clarification tank. For a sewage treatment plant to operate stably, it is necessary for the biomass used for cleaning the waste water, which comprises the microorganisms used for cleaning, to be separated from the cleaned waste water. In the aeration process, the biomass is usually separated in a secondary clarifier by sedimentation and partially or completely returned to the aeration tank. Trouble-free operation of a sewage treatment plant with a biological cleaning stage consequently requires a well sedimenting biomass or a well sedimenting activated sludge.

The biomass used in the aeration tank is a mixed biocenosis of various microorganisms. The mixed biocenosis contains, among other things, filamentous bacteria or filamentous bacteria and flake-forming bacteria. The formation of non-sedimenting or floating sludge aggregates results in an increased growth of filamentous bacteria, which aggregate into a thread network. Such a thread mesh significantly impedes the thickening and settling process of the activated sludge. The floating sludge aggregates consist mainly of expanded sludge, floating sludge and foam. Bulking sludge, floating sludge and foam can also be formed if the wastewater contains finely divided gas bubbles, hydrophobic wastewater contents and / or cell structures as well as surface-active substances.

A stable operation of a biological sewage treatment plant is difficult or not possible with the formation of expanded sludge, floating sludge or foam.

Shear fields can generate mechanical stress on long-filament structures and cause particle size reduction under high mechanical loads. In a shear field, a shear stress is generated in a manner known per se by a pair of forces. The forces act on planes parallel to one another and act along these planes in the opposite direction. The medium in the shear field is sheared laterally. Shear fields in fluids are characterized by velocity gradients between the neighboring layers. These shear fields are opposed by the viscosity of the medium, which opposes the corresponding resistance. In order to reduce the particle size, the shear stress generated must exceed the tensile strength of the structures, ie the solid particles, in order to cause the long-stranded structures to tear. If the thread-like structures are not oriented along the direction of tension of the shear field, lower shear stresses are sufficient to crush the particles, since the entered shear stresses create an overlay of shear and torsional stress and cut or torture the particles. The lysed cell components released in this way act as biological flocculants, for example in the form of released cell membrane components, DNA, RNA, or the like and subsequently improve them Sedimentation properties, for example of activated sludge. As a result, the microorganisms tend to agglomeration and flake formation after leaving the shear field. This has a positive effect on the subsequent sedimentation.

A method and a device of the type mentioned at the outset is known, for example, from DE 42 41 299 A1. This known method and the device provided therefor are intended for treating liquid, such as contaminated soil material suspended in water and / or waste water, by producing a fine suspension or emulsion, the

Liquid is exposed to shear forces in a gap formed between a rotor arranged in an inner container and a stator. The stator is formed by at least a portion of the bottom and / or the lower edge region of the inner container. The liquid is removed by the rotor from the bottom area of the inner container through those present in the stator

Breakthroughs driven into the bottom area of an outer container. In this known method and in the device provided for this purpose, the liquid is conveyed in the circuit in a self-sucking manner through the shear field between the rotor and the stator. The energy required to drive the rotor is accordingly large. However, the energy dissipation in the fluid is insufficient.

DE 200 01 795 U1 describes a device for controlling sludge on biological wastewater treatment plants with at least one sludge removal / conveying device, one

Treatment tank with at least one inlet, a dispersing device, an outlet and a degassing opening, the floating sludge in the treating tank being crushed by the high shear force of the dispersing device and the gases contained in the floating sludge being released. The energy dissipation is also unsatisfactory in this known device. A shear field reactor with a number of mutually spaced and mutually parallel shear fields is known, for example, from EP 1 005 391 A1. This known Scherfeld reactor is used to produce gas-containing vesicles.

The invention has for its object to provide a device and a method of the type mentioned, wherein an optimal energy dissipation into the filamentous and flocculating microorganism-containing medium takes place with negligible or no medium promotion caused by the shear field.

This object is achieved in accordance with the device in that the at least one shear field is determined and limited by a few surface elements, which are spaced apart from one another by a shear gap and which can be moved relative to one another by means of a drive device for generating the shear field, one of the surface elements for introducing the one to be treated Medium in the shear gap has at least one medium inlet, which can be connected or is connected to a feed pump for the medium, so that the device is not self-sucking when there is at least a reduction or avoidance of cavitation in the shear gap, and at least one of the surface elements on it the inner surface facing the other surface element has a surface structuring which increases energy dissipation. Cavitation is preferably not generated.

The effect that the device in the shear gap is not self-sucking is due to the so-called hydrodynamic paradox. A radially inward flow is induced in the shear gap, which is why the reactor is not self-sucking.

Due to the hydrodynamic paradox there is an extremely effective, almost complete, preferably complete energy dissipation of the energy input. The device according to the invention therefore preferably has an efficiency of at least 70%, more preferably of at least 90%.

By combining the at least one shear field with one

Feeding pump for the medium has the advantage that the medium delivery effect is negligibly small or eliminated by the at least one shear field and the energy dissipation into the medium to be treated is optimal.

In addition, part of the pumping energy is converted into dissipation energy. This advantageously further increases the efficiency of the device according to the invention.

With the help of the device according to the invention, the advantage of

Generation of highly turbulent flow conditions with small Kolmogoroff diameters of the turbulence vortex. The energy dissipation into the medium is optimized or maximized, and the necessary stress for the microorganisms contained in the medium is generated.

According to the present invention, the wastewater, preferably activated sludge or a mixed biocoenosis, is subjected to a shear stress in a shear field by hydrodynamically generated shear fields. The shear fields are created in the wastewater, preferably activated sludge or a mixed biocenosis, as described above.

The device according to the invention can therefore also be referred to as a shear field reactor. The shear stress leads to a comminution or fragmentation of sludge aggregates or thread meshes formed from long-stranded microorganisms. Furthermore, trapped or adhering finely divided gas bubbles are released in these sludge aggregates. These gas bubbles contained in the untreated sludge aggregates contribute to a deterioration in the sedimentation behavior of the sludge aggregates.

Finally, the shear stress partially destroys the filamentous bacteria and shortens the filament length of the filamentous bacteria.

The stress exerted on the filamentous bacteria contained in the mixed biocenosis by the generated shear field leads in particular to changes in the metabolism of the filamentous bacteria, which leads to a change in the growth kinetics of the filamentous microorganisms or bacteria. The growth of filamentous microorganisms is significantly reduced.

The change in the metabolism of filamentous microorganisms is due in particular to the stimulation of protective mechanisms against the stress generated by the applied shear stress. This leads to to a secretion of extracellular polymeric substances, which are also referred to as EPS, mainly by the filamentous microorganisms. The secreted extracellular polymeric substances advantageously bring about an adhesion of the sludge aggregates crushed in the shear field. This adhesion counteracts the formation of too small sludge particles, which do not sediment or sediment too slowly, and leads to an advantageous flocculation and thus to the desired sedimentation of the mixed biocenosis.

The relative proportions of flocculating microorganisms to filamentous microorganisms in the mixed biocenosis or sewage sludge change in favor of the flocculating microorganisms. An increase in Ratio of flocculating bacteria to filamentous bacteria in the mixed biocenosis favors sedimentation of the sludge aggregates.

In contrast to filamentous microorganisms, flake-forming microorganisms show good sedimentation behavior.

It has proven to be expedient in the device according to the invention if the surface elements of the pair of surface elements determining the shear field are designed as disks provided one above the other, the upper disk forming a stator and the lower disk forming a rotor which is connected to a drive motor forming the drive device is.

According to the invention, it is also possible, for example, not only to form a shear field by an upper-side stator and a lower-side rotor, but, for. B. to design the device with two superimposed shear fields, wherein a stator is provided between two spaced rotors, which is spaced from the two rotors in each case by a corresponding shear gap.

The stator or the stators or the rotor or the rotors are preferably designed as disks. The disks are preferably arranged one above the other. It is preferred that the disks form pairs of disks, the disks or disk pairs preferably being arranged horizontally. In a preferred embodiment, the surface element pairs specified below are therefore each a pair of disks.

According to the invention, the device is designed such that the / each shear field is located above the level of the medium to be treated. The at least one shear field is therefore not immersed in the medium to be treated, so that the respective shear field is not self-sucking or none As already mentioned, it has a promotional effect. The energy input takes place in the shear field in the medium to be treated, the energy input is optimally dissipated.

Preferably the disks or pairs of disks, i.e. the rotor stator

Combination (s) spaced substantially parallel to the surface of the medium to be treated.

In a device according to the invention of the above-mentioned type with a pair of surface elements, the medium inlet is expediently connected to and opens into the stator, and the drive motor is attached under the rotor, preferably in a hanging manner. The drive motor can be immersed in the medium to be treated in order to be cooled by the medium to be treated. Another possibility is for the drive motor to flow around and cool the treatment medium emerging from the shear field. In the former case, the cooling is better than in the latter case.

The fact that, according to the invention, the at least one shear field is above the level of the medium to be treated results in the advantage that no back pressure is generated in the medium by the shear field, so that energy dissipation into the medium to be treated is also optimal from this point of view , Another advantage is the simplified maintainability of the device.

According to the invention, the pair of surface elements can be arranged in a housing, wherein the drive motor can be attached to a base element of the housing. The housing can be designed as an open or as a closed housing, which is advantageous from a safety point of view. It has proven to be advantageous if the distance between the two surface elements of the respective shear gap can be adjusted. In this way, a variable process parameter for the treatment of the medium is available.

In a device of the last-mentioned type, it has proven to be advantageous if the surface element forming the stator is provided such that it can be adjusted in height in relation to the surface element forming the rotor. For this purpose, the medium inlet opening into the stator can be formed with an externally threaded section and the housing

Have internal thread element through which the medium inlet is screwed with its external thread section.

To cool the drive motor for the rotor of the device according to the invention, the shear field formed by the stator and the rotor can be surrounded by an annular impact device, which is spaced from the peripheral edge of the stator and the rotor. In order to further improve the action of mechanical stress on the microorganisms of the medium, the impact device can have flow shear elements facing the shear gap between the stator and the rotor.

For the targeted steering of the treated medium emerging from the shear field towards the drive motor, it is expedient if the impact device has a flow steering section that directs the medium against the drive motor.

In order to provide a further variable process parameter in the device according to the invention, it is expedient if the speed of the drive motor is adjustable. The same purpose, ie the provision of variable process parameters, is useful if the volume flow and / or the delivery pressure of the charging pump can be set in the device according to the invention. The diameter of the rotor and the volume flow of the feed pump influence the duration of the medium to be treated in the shear field. The speed of the drive motor, ie the speed of the rotor and the gap width of the shear gap, ie the distance between the stator and the rotor, predominantly determine the maximum shear gradient of the shear field. The degree of energy dissipation into the medium to be treated can be decisively influenced by appropriate surface design of the rotor. The rotor can therefore preferably be designed with a surface structuring. This surface structuring can be formed by labyrinth-like rib sections which run radially and in the circumferential direction of the rotor. Another possibility is that at least one of the surface elements, preferably the rotor, is designed with a perforation in order to influence the degree of energy dissipation into the medium to be treated accordingly. Since it is not known from the outset for the respective application of the device according to the invention how large the energy input for deselecting long-stranded microorganisms by means of shear and shear stresses is, the device according to the invention advantageously has a reference to the volume flow and / or the delivery pressure of the feed pump , the gap distance between the rotor and the stator, the speed of the rotor and its diameter, and the surface structure of the rotor such a variability that the mechanical load situation for the microorganisms and the hydrodynamic conditions can be covered according to the invention in a wide range. This flexibility is achieved in particular by decoupling the at least one shear field from the conveying device, ie the feed pump for the medium which is separate from the shear field. It can be advantageous here if a throttle device is provided in a pipeline connecting the feed pump to the medium inlet of the shear field. Such a throttle device is particularly useful when the feed pump is not variable in speed in order to be able to adjust the volume flow and / or the delivery pressure of the feed pump. In the device according to the invention, the housing can be designed as an open housing with a cage or as a closed housing with ventilation openings on the top and a medium outlet funnel on the underside. In the former case, the device can be immersed in the medium to be treated to such an extent that the shear field of the device protrudes from the mirror of the medium; in the latter case, the housing can also be immersed in the medium to such an extent that the shear field projects from the mirror of the medium. Such a device with a closed housing can also be arranged free-standing. Such a closed system can be useful from a safety point of view.

The object on which the invention is based is achieved in the method according to the invention for the treatment of a medium containing filamentous and flocculating microorganisms, such as waste water, sewage sludge or the like, the microorganisms of the medium being present in at least one shear field which is determined and limited by a few surface elements which can be moved relative to one another, are subjected to a mechanical stress, according to the invention solved in that the medium to be treated is introduced through one of the surface elements into the shear gap with at least one reduction or avoidance of cavitation in the shear field by means of a feed pump, at least one of the surface elements on its other surface element facing inner surface has a surface structuring which increases energy dissipation. In this case, one of the surface elements is expediently driven in rotation by means of a drive motor, so that this surface element forms a shear field rotor which is at a certain distance from a stationary immovable shear field stator. In order to avoid a promotional effect through the shear field and to bring about optimal energy dissipation, the shear field is arranged according to the invention above the level of the treated medium. Surprisingly, the flake-forming bacteria are not destroyed by the process according to the invention. Furthermore, there is no significant change in the cell metabolism, so that the growth kinetics of the flocculating microorganisms are not significantly impaired or are not significantly changed. With regard to the different growth kinetics of filamentous and flake-forming microorganisms, the method according to the invention thus leads to an advantageous change in the composition of the mixed biocenosis. This change in the bacterial composition caused by the method according to the invention therefore leads to a recovery of the sewage sludge.

It is preferred if the distance between the surface elements of the shear gap is adjustable. This adjustability can be realized in that the surface element forming a shear field stator is adjusted in height in relation to the surface element forming the shear field rotor.

The shear field can be surrounded by an annular impact device, which is spaced from the peripheral edge of the shear field and on which the medium emerging from the at least low-cavitation or cavitation-free shear field rebounds, whereby the mechanical stress of the medium is further increased.

The medium can be directed against the drive motor driving the shear field rotor by means of a flow steering section of the impact device. This makes it possible to cool the drive motor. It is preferred if the rotational speed of the drive motor for the shear field rotor can be adjusted, because in this way an adaptation to the particular conditions relating to the medium to be treated is possible. The same purpose is useful if it is possible to adjust the volume flow and / or the delivery pressure of the feed pump. To optimize the energy dissipation in the medium to be treated, it is expedient if at least one of the surface elements which define and delimit the shear field is designed with a surface structuring on its inner surface facing the other surface element. It is preferred if the rotor with such

Surface structuring is formed. This surface structuring can be formed by labyrinth-like rib sections which run, for example, radially and in the circumferential direction of the rotor. The labyrinth-like rib sections can also have spiral rib structures, which can be continuous or interrupted. A rotor designed in this way can be used for suspensions whose solids content is relatively low, so that there is no risk of clogging.

The surface structuring supports a, preferably essentially radial, shear effect, the information relating radially to the radius of the disk forming the surface element. The medium to be treated is therefore preferably subjected to an essentially radial shear stress, whereby the hydrodynamic paradox, i.e. supports the desired flow reversal and thus optimizes energy dissipation.

The rotor can also be designed with a perforation forming the surface structure, as has already been explained above.

A good variability and adaptability to the given conditions is achieved if the flow rate of the medium in a pipeline connecting the feed pump to the medium inlet can be adjusted by means of a throttle device, i.e. is adjustable.

The invention is also suitable, for example, for particle comminution of filamentous structures, which is essential for the co-fermentation of organic raw materials. For this purpose, the surface structure of the rotor must be dimensioned accordingly in order to keep the tendency to clog as low as possible. Such a device could, for example, also be used in a processing step of the raw substrate in the biogas fermentation.

The device according to the invention and the method according to the invention were tested over a longer period of time for the deselection of long-stranded microorganisms from activated sludge by generating shear fields from a sewage treatment plant under practical conditions. The results of these investigations show the operability of the device and the method according to the invention, i.e. Expandable and floating sludge and foam in sewage treatment plants can be at least reduced or avoided in the long term. Another advantage is that the invention can be infinitely adapted to the particular requirements. That there is a wide range of effects depending on the energy input, the speed, the gap distance and the rotor geometry.

Further details, features and advantages result from the following description of two exemplary embodiments of the device according to the invention for carrying out the method according to the invention shown in the drawing.

Show it:

FIG. 1 shows a block diagram of the device in combination with a feed pump and a throttle device between the latter and the device,

FIG. 2 shows a section through a first embodiment of the device,

FIG. 3 shows a section through a second embodiment of the device, FIG. 4 shows a view of a rotor with a surface structuring of the device according to FIG. 2 or according to FIG. 3, and

FIG. 5 shows a diagram of the course over time of the foam volume index ISV of a sewage treatment plant which was operated during a first period without and during a subsequent second period with a device according to FIGS. 2 or 3.

FIG. 6 shows a simulated flow profile (velocity vectors) over the longitudinal section of the device

FIG. 7 shows a simulated flow profile (velocity vectors) of a shear field generated between the stator and rotating rotor in a top view.

FIG. 8 shows a schematic representation of the influence of the method according to the invention on the growth kinetics of flake-forming microorganisms and filamentous microorganisms,

FIG. 1 schematically shows a device 10 for treating a medium containing filamentous and flocculating microorganisms, such as waste water, sewage sludge or the like. Formations of the device 10 are described in more detail below in connection with FIGS. 2 and 3.

The device 10 is connected by means of a pipeline 12 to a

Feed pump 14 fluidically connected. A throttle device 16 is provided in the pipeline 12.

Figure 2 shows a sectional view of a first embodiment of the embodiment 10, in which the housing 18 as an open housing with a Base plate 20, a cover plate 22 and the base plate 20 with the cover plate 22 connecting cage bars 24 is formed.

On the base plate 20 of the housing 18, a drive motor 26 is attached, which for a surface element 28 that forms a rotor

Drive device 30 forms. A surface element 32, which forms a stator, is provided at a distance from the rotor 28. A shear field 34 is delimited and determined by the stator 32 and by the rotor 28, which is used to act on the microorganisms of a to be treated, i.e. medium supplied by the feed pump 14 to the device 10, which is in the wastewater, sewage sludge or the like, serves with mechanical stress.

The device 10 is immersed in a liquid, the mirror of which is designated by the reference number 36 in FIG. The device 10 is immersed in the liquid to such an extent that the drive motor 26 is in the liquid in order to be cooled by it, but the shear field 34 is above the liquid level 36.

The shear field 34 is in any case positioned with respect to the liquid level 36 in such a way that it is at most adjacent to or positioned above the liquid level 36.

A medium inlet 38 for the medium to be treated opens into the shear field 34 between the stator 32 and the rotor 28. The medium inlet 38 has a tubular sleeve 40 which is formed with an externally threaded section 42. A ring element 44 is fastened on the cover plate 22 and has a through hole with an internal thread 46. The tubular sleeve 40 is screwed with its external thread section 42 through the ring element 44, so that it is possible to set the shear gap of the shear field 34 between the stator 32 and the rotor 28 as desired. A lock nut 48 secures the respective setting of the shear gap of the shear field 34. The tube sleeve 40 is provided with a connecting flange 50, which serves to connect the pipeline 12 (see FIG. 1).

The shear field 34 formed by the stator 32 and the rotor 28 is surrounded by an annular impact device 52. The impact device 52 is at a defined distance from the peripheral edge 54 of the shear field 34.

FIG. 3 shows an embodiment of the device 10, which differs from the device 10 according to FIG. 2 in particular in that the housing 18 is not designed as an open housing with a cage, but rather as a closed housing 18 with an upper part 56 and a lower part 58 , which each have a circumferential fastening flange 60, by means of which the upper and lower parts 56 and 58 are connected to one another to form the housing 18. The upper part 56 is formed with ventilation openings 64 and the lower part 58 has an underside medium outlet funnel 66.

The same details are denoted in FIG. 3 with the same reference numerals as in FIG. 2, so that it is not necessary in connection with FIG. 3 to describe all these details again in detail.

The drive motor 26 for the rotor 28 of the shear field 34 is attached to a truss device 68 which extends through the lower part 58 of the housing 18.

The impact device 52 surrounding the shear field 34 at a defined distance is designed with a flow-directing section 70 directed against the drive motor 26. With the aid of the flow-directing section 70, the medium which is discharged from the shear field 34 and is subjected to mechanical stress is directed against the drive motor 26 in order to effect cooling thereof. The baffle 52 is also with Flow breaker elements 72 are formed to increase the stress on the medium with mechanical stress.

Legs 74 stand down from the lower part 58 of the housing 18 in order to be able to set up the device 10 at a suitable location.

FIG. 4 shows a plan view of an embodiment of the rotor 28 which is provided with a surface structuring 76 on its side facing the stator 32. The surface structuring 76 is formed by iabyrinth-like rib sections 78, which run in the circumferential direction of the rotor 28, and by rib sections 80, which are oriented in the radial direction of the rotor 28. Of course, the surface structuring 76 can also be designed differently. Turbulence eddies in the shear field 34 (see FIGS. 2 and 3) are generated in particular by the vertical stomata 82. Tests have shown that there is a strong dependence of the energy input into the shear field 34 and thus a strong dependence of the energy dissipation on the respectively set horizontal gap distance between the rotor 28 and the stator 32.

FIG. 5 illustrates the operating data of a diagram

Wastewater treatment plant, i.e. the temporal dependency of the foam volume ISV. The foam volume index ISV is the ratio of sludge volume to sludge weight over time t in months. The left area 84 illustrates an operation of the sewage treatment plant without the device 10 according to the invention, i.e. without a shear field reactor, and the right area 86 illustrates the operation of the

Sewage treatment plant with the device according to the invention. It can be seen from FIG. 5 that when the shear field reactor is in operation, the flake structure increases in its compactness and dimension and the sedimentation properties are positively influenced.

The measurements were carried out on a wastewater treatment plant with 12,000 equivalent residents. The rotor drive and the Feed pumps each had an output of 4 kW. The speed of the rotor was approximately 750 revolutions / minute.

The rotor and the stator each had a plate diameter of 480 mm, the gap distance being 4 mm between the upper edge of the ribs and the stator. The stator had a smooth surface. The surface of the rotor had a textured surface with rib sections, as shown in Figure 4. The height of the rib sections was 18 mm.

The parameters speed, power of the rotor drive, gap distance,

Plate diameter, surface design of rotor and stator, feed quantity, feed pressure, etc. can be set independently of one another in accordance with the external framework conditions (e.g. viscosity of the waste water, mechanical resistance of the thread-like microorganisms, etc.).

FIG. 6 shows the flow profile in a longitudinal section through the device on the basis of speed vectors. The medium flowing in the inlet 38 reaches the shear gap formed between the rotor 28 and the stator 32. The rotor 28 has rib sections 80 and 78. When the rotor 28 is rotating, it occurs in the shear gap

Medium for forming a shear field 34. It can be seen that it is opposite to the main flow direction, ie in the direction of the outer circumference of rotor 28 or stator 32, for a reversal of the flow direction, ie in the direction of the inlet 38, parallel to and along the surface element of the stator 32 comes. This counterflow in the shear gap creates a suction of ambient air into the shear gap of the device, which is possible since the rotor 28 and stator 32 are arranged above the medium level, preferably waste water level. This creates an air-wastewater mixture, which increases the turbulence in the shear field. Furthermore, dispersed gas bubbles, usually air bubbles, dampen any cavitation that may occur. In a preferred embodiment of the device, there is no cavitation. The reversal of the flow direction is due to that so-called hydrodynamic paradox. Due to the hydrodynamic paradox, there is an improved and effective energy dissipation and an improved turbulence through the generation of a preferably air-waste water mixture.

FIG. 7 shows a simulated flow profile of a shear field on the basis of speed vectors between a rotating rotor 28 and stator 32 in a top view. It can be clearly seen that there is no significant acceleration of the treated medium radially outwards. This suppression of radial acceleration of what is in the shear gap

Medium, preferably wastewater, counteracts cavitation formation extremely advantageously. In a preferred embodiment of the device, the formation of cavitation is completely suppressed due to the hydrodynamic paradox.

FIG. 8 shows the influence of the method according to the invention on the

Growth kinetics of flake-forming microorganisms and filamentous or thread-like microorganisms. FIG. 8 shows that the growth rate of flake-forming microorganisms is not, or not significantly, influenced by the method according to the invention.

In contrast, the method according to the invention has a significant influence on the growth rate of filamentous microorganisms. Due to the shear field created in the device according to the invention, the growth of filamentous microorganisms is significantly suppressed compared to flake-forming microorganisms. This leads to a desired change in the relative composition of the mixed biocenosis. The relative ratio of filamentous microorganisms to flake-forming microorganisms is reduced.

Claims

Expectations :

1. Device for treating a medium containing filamentous and flocculating microorganisms, such as waste water, sewage sludge or the like, with at least one shear field (34) for subjecting the microorganisms of the medium to mechanical stress, which indicates that the at least one shear field (34) is determined and limited by a pair of surface elements (28, 32) which are spaced apart from one another by a shear gap and which can be moved relative to one another by means of a drive device (30) for generating the shear field (34), one of the surface elements (32) for initiating the medium to be treated in the

Shear gap has at least one medium inlet (38) which can be connected or is connected to a feed pump (14) for the medium, so that the device (10) is not self-sucking in the event of at least a reduction or avoidance of cavitation in the shear gap, and wherein at least one of the surface elements (28, 32) on the other

Surface element (32, 28) facing inner surface has a surface structuring (76) which increases energy dissipation.

2. Device according to claim 1, characterized by the fact that the surface elements (28, 32) of the pair of surface elements determining the shear field (34) are designed as superposed discs, the upper disc being a stator (32) and the lower disc forms a rotor (28) which is connected to a drive motor (26) forming the drive device (30).

3. Device according to claim 1 or 2, characterized in that the device (10) is provided such that the shear field (34) is above a liquid level (36).

4. The device according to claim 2, characterized in that the medium inlet (38) is connected to the stator (32) and opens into the shear field (34), and that the drive motor (26) under the rotor

(28), preferably hanging, is attached.

5. The device according to claim 2 to 4, characterized in that the pair of surface elements is arranged in a housing (18), the drive motor (26) being attached to a base element (20; 68) of the housing (18).

6. Device according to one of claims 1 to 5, characterized in that the distance between the two surface elements (28, 32) of the shear field (34) is adjustable.

7. The device according to claim 6, characterized in that the stator (32) forming surface element is provided with adjustable height in relation to the surface element forming the rotor (28).

8. The device according to claim 7, characterized in that the in the stator (32) opening medium inlet (38) is formed with an external thread section (42) and the housing (18) has an internal thread element (44) through which the medium -Inlet (38) is screwed with its external thread section (42).

9. Device according to one of claims 2 to 8, characterized in that the shear field (34) formed by the stator (32) and the rotor (28) is surrounded by an annular impact device (52) which is surrounded by the peripheral edge of the shear field ( 34) is spaced.

10. The device according to claim 9, characterized in that the impact device (52) has the shear gap between the stator (32) and the rotor (28) facing flow breaker elements (72).

11. The device according to claim 9, characterized by the fact that the impact device (52) has a flow-directing section (70) which directs the medium against the drive motor (26).

12. Device according to one of claims 2 to 11, characterized in that the speed of the drive motor (26) is adjustable.

13. The device according to one of claims 1 to 12, dadu rch characterized that the volume flow and / or the delivery pressure of the feed pump (14) is adjustable.

14. Device according to one of claims 1 to 13, characterized in that the rotor (28) is formed with a surface structure (76).

15. Device according to one of claims 1 to 14, characterized in that the surface structuring (76) is formed by labyrinth-like rib sections (78, 80).

16. The apparatus according to claim 15, characterized in that the rib sections (78, 80) run radially and in the circumferential direction of the rotor (28).

17. The apparatus according to claim 15, characterized in that the rib sections are arranged in a spiral.

18. The apparatus according to claim 13, characterized by the fact that at least one of the surface elements (28, 32), preferably the

Rotor (28) is formed with a perforation.

19. Device according to one of claims 1 to 18, characterized in that a throttle device (16) is provided in a pipeline (12) connecting the feed pump (14) to the medium inlet (38).

20. Device according to one of claims 5 to 19, characterized in that the housing (18) is designed as an open housing with a cage.

21. Device according to one of claims 5 to 19, characterized in that the housing (18) is designed as a closed housing with ventilation openings (64) on the top and a medium outlet funnel (66) on the underside.

22. Device according to one of claims 1 to 21, characterized in that the surface elements are designed as disks.

23. The device according to claim 22, characterized in that the surface elements are designed as a pair of discs or pairs of discs.

24. The device according to claim 22 or 23, characterized in that the discs are arranged one above the other and preferably substantially horizontally.

25. A method for treating a medium containing filamentous and flocculating microorganisms, such as waste water, sewage sludge or the like, the microorganisms of the medium being present in at least one shear field (34) which can be moved relative to one another by a few

Surface elements (28, 32) are determined and limited, are subjected to mechanical stress, characterized in that the medium to be treated in at least one of the surface elements (28, 32) in the shear gap of the shear field (34)

Reduction or avoidance of cavitation in the shear gap is initiated by means of a feed pump (14), at least one of the surface elements (28, 32) having a surface structure (76) on its inner surface facing the other surface element, by means of which the energy dissipation in the medium is increased.

26. The method according to claim 25, characterized in that one of the surface elements (28) is driven in rotation by means of a drive motor (26).

27. The method according to claim 25 or 26, characterized in that the shear field (34) is arranged above a liquid level (36).

28. The method according to any one of claims 25 to 27, characterized in that the distance between the two surface elements (28, 32) of the shear gap is set.

29. The method according to claim 28, characterized in that the height of the surface element (32) forming a shear field stator is adjusted with respect to the surface element (28) forming the shear field rotor.

30. The method according to any one of claims 25 to 29, characterized in that the shear field (34) is surrounded by an annular impact device (52) which is spaced from the peripheral edge of the shear field (34), and on which that from the shear field (34 ) emerging medium rebounds.

31. The method according to claim 30, characterized in that the medium is directed against the drive motor (26) by means of a flow steering section (70).

32. The method according to any one of claims 26 to 31, characterized in that the speed of the drive motor (26) is set.

33. The method according to any one of claims 25 to 32, characterized in that the volume flow and / or the delivery pressure of the feed pump

(14) is set.

34. The method according to any one of claims 25 to 33 dadu rch characterized in that the rotor (28) is formed with a surface structure (76).

35. The method according to any one of claims 25 to 34, characterized in that the surface structuring (76) is formed by labyrinth-like rib sections (78, 80).

36. The method according to claim 35, characterized in that the rib sections (78, 80) run radially and in the circumferential direction of the rotor (28).

37. The method according to claim 35, characterized in that the rib sections are arranged spirally.

38. The method according to any one of claims 25 to 37, characterized in that the flow rate of the medium in a pipeline (12) connecting the feed pump (14) to the medium inlet (38) is set by means of a throttle device (16) becomes.

39. The method according to any one of claims 25 to 38, characterized in that the surface elements are designed as disks.

40. The method according to claim 39, characterized in that the surface elements are designed as a pair of discs or pairs of discs.

41. The method according to claim 39 or 40, characterized in that the disks are arranged one above the other and preferably essentially horizontally.