Title of Invention	STIRRING DEVICE FOR ACTIVATED SLUDGES
Abstract	The invention relates to a stirring device for activated sludges comprising a hyperboloid stirring body (2) attached to a shaft (1), wherein a plurality of transport ribs (3) are provided on the top (O) of the stirring body (2) running toward the circumferential boundary (UM) thereof, wherein the transport ribs (3) have an oblique course, at least in sections, relative to a radial direction, and wherein an oblique position of the transport ribs (3) is selected such that, when the stirring body (2) rotates in a predetermined rotational direction (R), a flow is generated that is directed radially outward away from the circumferential boundary (UM) of the stirring body (2).

Title of Invention

STIRRING DEVICE FOR ACTIVATED SLUDGES

Abstract

The invention relates to a stirring device for activated sludges comprising a hyperboloid stirring body (2) attached to a shaft (1), wherein a plurality of transport ribs (3) are provided on the top (O) of the stirring body (2) running toward the circumferential boundary (UM) thereof, wherein the transport ribs (3) have an oblique course, at least in sections, relative to a radial direction, and wherein an oblique position of the transport ribs (3) is selected such that, when the stirring body (2) rotates in a predetermined rotational direction (R), a flow is generated that is directed radially outward away from the circumferential boundary (UM) of the stirring body (2).

Full Text	FORM 2 THE PATENTS ACT 1970 [39 OF 1970] & THE PATENTS RULES, 2003 COMPLETE SPECIFICATION [see section 10 and rule13] “STIRRING DEVICE FOR ACTIVATED SLUDGES” Name and Address of the Applicant: INVENT UMWELT-UND VERFAHRENSTECHNIK AG, Am Pestalozziring 21, 91058 Erlangen, Germany. Nationality: German The following specification particularly describes the nature of the invention and the manner in which it is to be performed. 2 TECHNICAL FIELD The invention relates to a stirring device for activated sludges. BACKGROUND Such a stirring device is known from DE 42 18 027 A1. Moreover, it is known from the aforementioned document to attach one knife or a plurality of knives to the shaft to chop up coarse materials. The knives can be inclined at an angle of attack. DE 42 18 027 A1 contains no information about how any eventual flow generated with the inclined knives is directed and whether a directed flow is generated with the known plurality of knives. In accordance with prior art, a need exists to further improve the stirring efficiency of the generic stirring device. STATEMENT OF THE DISCLOSURE Accordingly, the present disclosure relates to a stirring device for activated sludges with a hyperboloid-like stirring body (2) attached to a shaft (1), wherein a plurality of transport ribs (3) running towards its circumferential boundary (UM) is provided on an upper side (O) of the stirring body (2), wherein the transport ribs (3) are running inclined at least in sections with respect to a radial direction and wherein an inclination of the transport ribs (3) is selected in such a manner that, when the stirring body (2) rotates in a specified direction of rotation (R), a radial flow pointing away from the circumferential boundary (UM) is generated, characterized in that at least one propeller (6) is attached to the shaft (1) which propeller generates a flow (A) directed towards the upper side (O) of the stirring body (2) during a rotation of the stirring body (2) in the direction of rotation (R). BRIEF DESCRIIPTION OF THE DRAWINGS Figure 1: A partial side view of a stirring device. DETAILED DESCRIPTION The present disclosure relates to a stirring device for activated sludges with a hyperboloidlike stirring body (2) attached to a shaft (1), wherein a plurality of transport ribs (3) running towards its circumferential boundary (UM) is provided on an upper side (O) of the stirring body (2), 3 wherein the transport ribs (3) are running inclined at least in sections with respect to a radial direction and wherein an inclination of the transport ribs (3) is selected in such a manner that, when the stirring body (2) rotates in a specified direction of rotation (R), a radial flow pointing away from the circumferential boundary (UM) is generated, characterized in that at least one propeller (6) is attached to the shaft (1) which propeller generates a flow (A) directed towards the upper side (O) of the stirring body (2) during a rotation of the stirring body (2) in the direction of rotation (R). In one embodiment of the present disclosure, the transport ribs (3) bend towards the circumferential boundary (UM) from an approximate radial direction in an approximately tangential direction directed opposite the direction of rotation (R). In another embodiment of the present disclosure, the transport ribs (3) only extend in an outer radial section of the upper side (O). In another embodiment of the present disclosure, a plurality of essentially radially running shear ribs (4) is provided on an underside (U) opposite the upper side (O). In another embodiment of the present disclosure, the propeller (6) is attached to the shaft (1) in the vicinity of the stirring body (2). In another embodiment of the present disclosure, an end of the shaft (1) extending in the vicinity of the underside (U) of the stirring body (2) is held in a safety bearing. In another embodiment of the present disclosure, another end of the shaft (1) is connected to a gear unit motor. In another embodiment of the present disclosure, the gear unit motor is a submersible motor. 4 In another embodiment of the present disclosure, the gear unit motor is mounted on a frame surrounding the stirring body (2). In another embodiment of the present disclosure, the safety bearing is mounted on the frame or on the bottom (5) of a basin. The object of the present invention is to provide a stirring device with further improved stirring efficiency. The solution to this object results from the features of claim 1. Useful embodiments of the invention result from the features of claims 2 to 10. According to the provisions of the invention, it is provided that at least one propeller is attached to the shaft which generates a flow directed towards the upper side of the stirring body during a rotation of the stirring body in the direction of rotation. Due to this flow, the pressure on the upper side of the stirring body is increased. With the transport ribs a still more efficient flow directed away from the circumferential boundary of the stirring body can be generated in the basin. The suggested solution can be implemented easily and inexpensively. In the sense of the present invention, a "propeller" is understood to mean a flowmechanically optimized device for the generation of an axial flow directed to the upper side of the stirring body, approximately parallel to the shaft. A propeller wing of the propeller can have an angle of attack which decreases radially to the outside. The propeller wing can be made of an elastic material so that the angle of attack increases as the speed increases, in particular in radially outer areas. A wing of the propeller can have a flowmechanically optimized profile similar to the wing of an aircraft wing surface. In particular, a leading edge of the wing can be rounded and a trailing edge can be formed pointed towards the end. In an advantageous embodiment of the invention, it is provided that the transport ribs bend towards the circumferential boundary from an approximately radial direction in an ap5 proximately tangential direction directed opposite the direction of rotation. Due to the suggested bent embodiment of the transport ribs, an acceleration of the flow on the upper side can be achieved and thus a further increase in efficiency of the flow directed away from the circumferential boundary of the stirring body. In a further embodiment, it is provided that the transport ribs only extend in an outer radial section of the upper side. Due to the high angular velocity in the outer radial section, the effect of the transport ribs is particularly great. A plurality of essentially radially running shear ribs can be provided on an underside opposite the upper side. The shear ribs are used to swirl the air supplied on an underside of the stirring body and thus make air bubbles. To further increase the efficiency, it is provided that the propeller is attached to the shaft in the vicinity of the stirring body. A plurality of propellers can also be provided on top of each other on the shaft. This enables further acceleration of the flow generated with the propellers and directed to the upper side of the stirring device. In a further embodiment, it is provided that an end of the shaft extending in the vicinity of the underside of the stirring body is held in a safety bearing. Another end of the shaft is usefully connected to a gear unit motor. Because of the suggested two-sided holder of the shaft at the end, a precise rotary movement around an axis is achieved. Undesired swinging or precession movements of the stirring body are avoided. In a further embodiment, the gear unit motor can be a submersible motor. In this case, the stirring device is designed as a submersible device. The gear unit motor is usefully mounted on a frame surrounding the stirring body. In this case, the safety bearing is usefully mounted on the frame. This enables the device to be used in the basin as a mounting unit. 6 The frame can also be designed like a tower so that a gear unit motor mounted on its pointed top is above the level of the medium to be stirred. That makes the maintenance of the gear unit motor easier. Naturally, it is also possible to mount the safety bearing on the bottom of the basin. An exemplary embodiment will now be used to describe the invention in more detail based on the only drawing. The only drawing shows a partial side view of a stirring device. An attached, hyperboloidlike designed stirring body generally referred to with the reference sign (2) is mounted on a shaft (1). A plurality of transport ribs (3) are provided on an upper side (O) of the stirring body (2). The transport ribs (3) only extend over a radial, outer section of the upper side (O). They bend towards a circumferential boundary (UM) of the stirring body (2) from an approximate radial direction to an approximate tangential direction directed opposite the direction of rotation marked with the arrow (R). Essentially radially running shear ribs (4) are provided on an underside (U) of the stirring body (2). Reference sign (5) indicates a bottom of a basin (not shown here). A propeller (6) attached to the shaft (1) in the vicinity of the stirring body (2) has two wings (7) here. A leading edge (8) of each of the wings (7) has a curve running in the radial direction opposite the direction of rotation (R). Besides, the leading edge (8) can be rounded in design. A trailing edge (9) is usefully designed pointed at the end. The function of the stirring device shown is as follows: With a rotation of the stirring body (2), simultaneously the propeller (6) mounted on the shaft (1) is rotated and, as a result, an axial flow indicated with the arrows (A) is generated in the direction to the upper side (O) of the stirring body (2). The axial flow (A) is diverted by the hyperboloid-like embodiment of the upper side (O) in an essentially radial direction. It is additionally accelerated by the effect of the transport ribs (3) so that a particularly ef7 fective flow directed away from the circumferential boundary (UM) is generated which flow runs essentially parallel to the bottom (5). Naturally, a plurality of propellers can be mounted on top of each other on the shaft (1) instead of the one propeller (6) shown here. In this connection, the propellers (6) can have two, three, four or five wings (7). The wings (7) can be staggered. A diameter of the propellers (6) is usefully selected so that it is smaller than the diameter of the stirring body (2). Usefully, the diameter of a propeller (6) is the 0.2 to 0.8-fold, preferably the 0.3 to 0.5- fold, of the stirring body (2). The edges of attack (8) of the propeller blades (7) can have a saber-like curve opposite the direction of rotation (R) to avoid catching braid-creating impurities. A pitch of the propeller blades (7) can be different in a direction radial to the outside. To the extent that the propeller blades (7), for example, are made of an elastic plastic material, the pitch can change depending on the speed due to an elastic deformation of the propeller blades (7). With this, a particularly effective, speed-adjusted, axial flow (A) can be achieved. 8 List of reference signs 1 Shaft 2 Stirring body 3 Transport rib 4 Shear rib 5 Bottom 6 Propeller 7 Wing 8 Leading edge 9 Trailing edge A Axial flow O Upper side R Direction of rotation U Underside UM Circumferential boundary 9 We Claim 1. Stirring device for activated sludges with a hyperboloid-like stirring body (2) attached to a shaft (1), wherein a plurality of transport ribs (3) running towards its circumferential boundary (UM) is provided on an upper side (O) of the stirring body (2), wherein the transport ribs (3) are running inclined at least in sections with respect to a radial direction and wherein an inclination of the transport ribs (3) is selected in such a manner that, when the stirring body (2) rotates in a specified direction of rotation (R), a radial flow pointing away from the circumferential boundary (UM) is generated, characterized in that at least one propeller (6) is attached to the shaft (1) which propeller generates a flow (A) directed towards the upper side (O) of the stirring body (2) during a rotation of the stirring body (2) in the direction of rotation (R). 2. The stirring device as claimed in claim 1, wherein the transport ribs (3) bend towards the circumferential boundary (UM) from an approximate radial direction in an approximately tangential direction directed opposite the direction of rotation (R). 3. The stirring device as claimed in one of the preceding claims, wherein the transport ribs (3) only extend in an outer radial section of the upper side (O). 4. The stirring device as claimed in one of the preceding claims, wherein a plurality of essentially radially running shear ribs (4) is provided on an underside (U) opposite the upper side (O). 5. The stirring device as claimed in one of the preceding claims, wherein the propeller (6) is attached to the shaft (1) in the vicinity of the stirring body (2). 10 6. The stirring device as claimed in one of the preceding claims, wherein an end of the shaft (1) extending in the vicinity of the underside (U) of the stirring body (2) is held in a safety bearing. 7. The stirring device as claimed in one of the preceding claims, wherein another end of the shaft (1) is connected to a gear unit motor. 8. The stirring device as claimed in one of the preceding claims, wherein the gear unit motor is a submersible motor. 9. The stirring device as claimed in one of the preceding claims, wherein the gear unit motor is mounted on a frame surrounding the stirring body (2). 10. The stirring device as claimed in one of the preceding claims, wherein the safety bearing is mounted on the frame or on the bottom (5) of a basin. Dated this 20th day of January, 2010 Signature: Name: DURGESH MUKHARYA To: K&S Partners The Controller of Patent Agent for the Applicant The Patent Office, at Chennai

Full Text

FORM 2
THE PATENTS ACT 1970
[39 OF 1970]
&
THE PATENTS RULES, 2003
COMPLETE SPECIFICATION
[see section 10 and rule13]
“STIRRING DEVICE FOR ACTIVATED SLUDGES”
Name and Address of the Applicant: INVENT UMWELT-UND
VERFAHRENSTECHNIK AG, Am Pestalozziring 21, 91058 Erlangen, Germany.
Nationality: German
The following specification particularly describes the nature of the invention and the
manner in which it is to be performed.
2
TECHNICAL FIELD
The invention relates to a stirring device for activated sludges.
BACKGROUND
Such a stirring device is known from DE 42 18 027 A1. Moreover, it is known from the
aforementioned document to attach one knife or a plurality of knives to the shaft to chop
up coarse materials. The knives can be inclined at an angle of attack. DE 42 18 027 A1
contains no information about how any eventual flow generated with the inclined knives is
directed and whether a directed flow is generated with the known plurality of knives.
In accordance with prior art, a need exists to further improve the stirring efficiency of the
generic stirring device.
STATEMENT OF THE DISCLOSURE
Accordingly, the present disclosure relates to a stirring device for activated sludges with a
hyperboloid-like stirring body (2) attached to a shaft (1), wherein a plurality of transport
ribs (3) running towards its circumferential boundary (UM) is provided on an upper side
(O) of the stirring body (2), wherein the transport ribs (3) are running inclined at least in
sections with respect to a radial direction and wherein an inclination of the transport ribs
(3) is selected in such a manner that, when the stirring body (2) rotates in a specified direction
of rotation (R), a radial flow pointing away from the circumferential boundary (UM) is
generated, characterized in that at least one propeller (6) is attached to the shaft (1) which
propeller generates a flow (A) directed towards the upper side (O) of the stirring body (2)
during a rotation of the stirring body (2) in the direction of rotation (R).
BRIEF DESCRIIPTION OF THE DRAWINGS
Figure 1: A partial side view of a stirring device.
DETAILED DESCRIPTION
The present disclosure relates to a stirring device for activated sludges with a hyperboloidlike
stirring body (2) attached to a shaft (1),
wherein a plurality of transport ribs (3) running towards its circumferential boundary (UM)
is provided on an upper side (O) of the stirring body (2),
3
wherein the transport ribs (3) are running inclined at least in sections with respect to a radial
direction and
wherein an inclination of the transport ribs (3) is selected in such a manner that, when the
stirring body (2) rotates in a specified direction of rotation (R), a radial flow pointing away
from the circumferential boundary (UM) is generated, characterized in that
at least one propeller (6) is attached to the shaft (1) which propeller generates a flow (A)
directed towards the upper side (O) of the stirring body (2) during a rotation of the stirring
body (2) in the direction of rotation (R).
In one embodiment of the present disclosure, the transport ribs (3) bend towards the
circumferential boundary (UM) from an approximate radial direction in an approximately
tangential direction directed opposite the direction of rotation (R).
In another embodiment of the present disclosure, the transport ribs (3) only extend in an
outer radial section of the upper side (O).
In another embodiment of the present disclosure, a plurality of essentially radially running
shear ribs (4) is provided on an underside (U) opposite the upper side (O).
In another embodiment of the present disclosure, the propeller (6) is attached to the shaft
(1) in the vicinity of the stirring body (2).
In another embodiment of the present disclosure, an end of the shaft (1) extending in the
vicinity of the underside (U) of the stirring body (2) is held in a safety bearing.
In another embodiment of the present disclosure, another end of the shaft (1) is connected
to a gear unit motor.
In another embodiment of the present disclosure, the gear unit motor is a submersible motor.
4
In another embodiment of the present disclosure, the gear unit motor is mounted on a
frame surrounding the stirring body (2).
In another embodiment of the present disclosure, the safety bearing is mounted on the
frame or on the bottom (5) of a basin.
The object of the present invention is to provide a stirring device with further improved
stirring efficiency.
The solution to this object results from the features of claim 1. Useful embodiments of the
invention result from the features of claims 2 to 10.
According to the provisions of the invention, it is provided that at least one propeller is
attached to the shaft which generates a flow directed towards the upper side of the stirring
body during a rotation of the stirring body in the direction of rotation. Due to this flow, the
pressure on the upper side of the stirring body is increased. With the transport ribs a still
more efficient flow directed away from the circumferential boundary of the stirring body
can be generated in the basin. The suggested solution can be implemented easily and inexpensively.
In the sense of the present invention, a "propeller" is understood to mean a flowmechanically
optimized device for the generation of an axial flow directed to the upper
side of the stirring body, approximately parallel to the shaft. A propeller wing of the propeller
can have an angle of attack which decreases radially to the outside. The propeller
wing can be made of an elastic material so that the angle of attack increases as the speed
increases, in particular in radially outer areas. A wing of the propeller can have a flowmechanically
optimized profile similar to the wing of an aircraft wing surface. In particular,
a leading edge of the wing can be rounded and a trailing edge can be formed pointed
towards the end.
In an advantageous embodiment of the invention, it is provided that the transport ribs bend
towards the circumferential boundary from an approximately radial direction in an ap5
proximately tangential direction directed opposite the direction of rotation. Due to the suggested
bent embodiment of the transport ribs, an acceleration of the flow on the upper side
can be achieved and thus a further increase in efficiency of the flow directed away from the
circumferential boundary of the stirring body.
In a further embodiment, it is provided that the transport ribs only extend in an outer radial
section of the upper side. Due to the high angular velocity in the outer radial section, the
effect of the transport ribs is particularly great.
A plurality of essentially radially running shear ribs can be provided on an underside opposite
the upper side. The shear ribs are used to swirl the air supplied on an underside of the
stirring body and thus make air bubbles.
To further increase the efficiency, it is provided that the propeller is attached to the shaft in
the vicinity of the stirring body. A plurality of propellers can also be provided on top of
each other on the shaft. This enables further acceleration of the flow generated with the
propellers and directed to the upper side of the stirring device.
In a further embodiment, it is provided that an end of the shaft extending in the vicinity of
the underside of the stirring body is held in a safety bearing. Another end of the shaft is
usefully connected to a gear unit motor. Because of the suggested two-sided holder of the
shaft at the end, a precise rotary movement around an axis is achieved. Undesired swinging
or precession movements of the stirring body are avoided.
In a further embodiment, the gear unit motor can be a submersible motor. In this case, the
stirring device is designed as a submersible device.
The gear unit motor is usefully mounted on a frame surrounding the stirring body. In this
case, the safety bearing is usefully mounted on the frame. This enables the device to be
used in the basin as a mounting unit.
6
The frame can also be designed like a tower so that a gear unit motor mounted on its
pointed top is above the level of the medium to be stirred. That makes the maintenance of
the gear unit motor easier.
Naturally, it is also possible to mount the safety bearing on the bottom of the basin.
An exemplary embodiment will now be used to describe the invention in more detail based
on the only drawing.
The only drawing shows a partial side view of a stirring device. An attached, hyperboloidlike
designed stirring body generally referred to with the reference sign (2) is mounted on a
shaft (1). A plurality of transport ribs (3) are provided on an upper side (O) of the stirring
body (2). The transport ribs (3) only extend over a radial, outer section of the upper side
(O). They bend towards a circumferential boundary (UM) of the stirring body (2) from an
approximate radial direction to an approximate tangential direction directed opposite the
direction of rotation marked with the arrow (R). Essentially radially running shear ribs (4)
are provided on an underside (U) of the stirring body (2). Reference sign (5) indicates a
bottom of a basin (not shown here).
A propeller (6) attached to the shaft (1) in the vicinity of the stirring body (2) has two
wings (7) here. A leading edge (8) of each of the wings (7) has a curve running in the radial
direction opposite the direction of rotation (R). Besides, the leading edge (8) can be
rounded in design. A trailing edge (9) is usefully designed pointed at the end.
The function of the stirring device shown is as follows:
With a rotation of the stirring body (2), simultaneously the propeller (6) mounted on the
shaft (1) is rotated and, as a result, an axial flow indicated with the arrows (A) is generated
in the direction to the upper side (O) of the stirring body (2). The axial flow (A) is diverted
by the hyperboloid-like embodiment of the upper side (O) in an essentially radial direction.
It is additionally accelerated by the effect of the transport ribs (3) so that a particularly ef7
fective flow directed away from the circumferential boundary (UM) is generated which
flow runs essentially parallel to the bottom (5).
Naturally, a plurality of propellers can be mounted on top of each other on the shaft (1)
instead of the one propeller (6) shown here. In this connection, the propellers (6) can have
two, three, four or five wings (7). The wings (7) can be staggered. A diameter of the propellers
(6) is usefully selected so that it is smaller than the diameter of the stirring body (2).
Usefully, the diameter of a propeller (6) is the 0.2 to 0.8-fold, preferably the 0.3 to 0.5-
fold, of the stirring body (2). The edges of attack (8) of the propeller blades (7) can have a
saber-like curve opposite the direction of rotation (R) to avoid catching braid-creating impurities.
A pitch of the propeller blades (7) can be different in a direction radial to the outside. To
the extent that the propeller blades (7), for example, are made of an elastic plastic material,
the pitch can change depending on the speed due to an elastic deformation of the propeller
blades (7). With this, a particularly effective, speed-adjusted, axial flow (A) can be
achieved.
8
List of reference signs
1 Shaft
2 Stirring body
3 Transport rib
4 Shear rib
5 Bottom
6 Propeller
7 Wing
8 Leading edge
9 Trailing edge
A Axial flow
O Upper side
R Direction of rotation
U Underside
UM Circumferential boundary
9
We Claim
1. Stirring device for activated sludges with a hyperboloid-like stirring body (2) attached
to a shaft (1),
wherein a plurality of transport ribs (3) running towards its circumferential boundary
(UM) is provided on an upper side (O) of the stirring body (2),
wherein the transport ribs (3) are running inclined at least in sections with respect
to a radial direction and
wherein an inclination of the transport ribs (3) is selected in such a manner that,
when the stirring body (2) rotates in a specified direction of rotation (R), a radial
flow pointing away from the circumferential boundary (UM) is generated, characterized
in that
at least one propeller (6) is attached to the shaft (1) which propeller generates a
flow (A) directed towards the upper side (O) of the stirring body (2) during a rotation
of the stirring body (2) in the direction of rotation (R).
2. The stirring device as claimed in claim 1, wherein the transport ribs (3) bend towards
the circumferential boundary (UM) from an approximate radial direction in
an approximately tangential direction directed opposite the direction of rotation
(R).
3. The stirring device as claimed in one of the preceding claims, wherein the transport
ribs (3) only extend in an outer radial section of the upper side (O).
4. The stirring device as claimed in one of the preceding claims, wherein a plurality of
essentially radially running shear ribs (4) is provided on an underside (U) opposite
the upper side (O).
5. The stirring device as claimed in one of the preceding claims, wherein the propeller
(6) is attached to the shaft (1) in the vicinity of the stirring body (2).
10
6. The stirring device as claimed in one of the preceding claims, wherein an end of the
shaft (1) extending in the vicinity of the underside (U) of the stirring body (2) is
held in a safety bearing.
7. The stirring device as claimed in one of the preceding claims, wherein another end
of the shaft (1) is connected to a gear unit motor.
8. The stirring device as claimed in one of the preceding claims, wherein the gear unit
motor is a submersible motor.
9. The stirring device as claimed in one of the preceding claims, wherein the gear unit
motor is mounted on a frame surrounding the stirring body (2).
10. The stirring device as claimed in one of the preceding claims, wherein the safety
bearing is mounted on the frame or on the bottom (5) of a basin.
Dated this 20th day of January, 2010
Signature:
Name: DURGESH MUKHARYA
To: K&S Partners
The Controller of Patent Agent for the Applicant
The Patent Office, at Chennai

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Patent Number

278853

Indian Patent Application Number

397/CHENP/2010

PG Journal Number

01/2017

Publication Date

06-Jan-2017

Grant Date

31-Dec-2016

Date of Filing

20-Jan-2010

Name of Patentee

INVENT UMWELT-UND VERFAHRENSTECHNIK AG

Applicant Address

Am Pestalozziring 21 91058 Erlangen Germany

Inventors:

#	Inventor's Name	Inventor's Address
1	MARCUS HÖFKEN	PLATEUSTRASSE 22A 91054 ERLANGEN

PCT International Classification Number

B01F 7/00

PCT International Application Number

PCT/EP2008/005924

PCT International Filing date

2008-07-18

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10 2007 037 586.9	2007-08-09	Germany