Stirrer

Abstract

A stirrer having a motor; a hollow shaft that is drivable via the motor and is provided with at least one additive outlet opening, via which an additive passed through the hollow shaft can be discharged; and a rotor arranged on the hollow shaft and having rotor blades, characterized in that a second rotor having rotor blades is provided on the hollow shaft at a distance from the first rotor, and in that the at least one additive outlet opening is provided between the two rotors, wherein the rotors are designed and drivable such that, during operation, a negative pressure and a centrifugal force are generated in the intermediate space defined between the rotors.

Claims

1. A stirrer comprising: a shaft disposed at least partially within a medium; a first rotor having a first rotor blade and a second rotor blade each attached to the shaft, wherein the first and second rotor blades are spaced apart from one another about a circumference of the shaft so as to define a gap between the first and second rotor blades, and wherein the first rotor is configured when driven to draw the medium from above the first rotor through the gap between the first and second rotor blades; a second rotor spaced axially along the shaft from the first rotor so as to define an intermediate space between the first and second rotors, the second rotor having a third rotor blade and a fourth rotor blade each attached to the shaft, wherein the third and fourth rotor blades are spaced apart from one another about a circumference of the shaft so as to define a gap between the third and fourth rotor blades, and wherein the second rotor is configured when driven to draw the medium from below the second rotor through the gap between the third and fourth rotor blades; and a first additive outlet opening, defined by the shaft, at the intermediate space between the first and second rotors.

2. The stirrer of claim 1, further comprising a second additive outlet opening defined by the shaft at the intermediate space between the first and second rotors, wherein the second additive outlet opening is spaced from the first additive outlet opening about the circumference of the shaft.

3. The stirrer of claim 1, further comprising: a motor configured to drive the shaft, wherein the shaft defines a first axial end portion and a second axial end portion opposite the first axial end portion, wherein the motor is coupled to the shaft at or near the first axial end portion and the first, second, third, and fourth rotor blades are attached to the shaft at or near the second axial end portion disposed within the medium, and wherein the first, second, third, and fourth rotor blades extend out from the shaft.

4. The stirrer of claim 3, further comprising: a feed tube extending within the shaft from the first axial end portion to the second axial end portion, wherein the shaft and feed tube are configured to be non-co-rotating.

5. The stirrer of claim 4, wherein the feed tube terminates in the second axial end portion of the shaft at the first additive outlet opening.

6. The stirrer of claim 1, wherein the first and second rotor blades are attached to the shaft at a first angle in a first direction with respect to the shaft, and wherein the third and fourth rotor blades are attached to the shaft at a second angle in a second direction with respect to the shaft, the second direction being generally opposite the first direction.

7. The stirrer of claim 1, wherein the first additive outlet opening is an elongate cutout extending in a direction of a longitudinal axis of the shaft.

8. A stirrer comprising: a shaft disposed at least partially within a medium; a first rotor having a first rotor blade and a second rotor blade each attached to the shaft, wherein the first and second rotor blades are spaced apart from one another about a circumference of the shaft so as to define a gap between the first and second rotor blades, and wherein the first rotor is configured when driven to draw the medium from above the first rotor through the gap between the first and second rotor blades; a second rotor spaced axially along the shaft from the first rotor so as to define an intermediate space between the first and second rotors, the second rotor having a third rotor blade and a fourth rotor blade each attached to the shaft, wherein the third and fourth rotor blades are spaced apart from one another about a circumference of the shaft so as to define a gap between the third and fourth rotor blades, and wherein the second rotor is configured when driven to draw the medium from below the second rotor through the gap between the third and fourth rotor blades, and wherein the first and second rotors are configured when driven to push the medium radially outward from the intermediate space; and a first outlet located at the intermediate space between the first and second rotors to deliver an additive between the first and second rotors.

9. The stirrer of claim 8, wherein the first outlet is defined by the shaft at the intermediate space between the first and second rotors, and wherein the first and second rotors are configured when driven to draw the additive from the first outlet.

10. The stirrer of claim 9, wherein the first and second rotors are configured when driven to push the medium and the additive radially outward from the intermediate space.

11. The stirrer of claim 9, wherein the first outlet is an elongate cutout extending in a direction of a longitudinal axis of the shaft.

12. The stirrer of claim 8, further comprising a second outlet located at the intermediate space between the first and second rotors, wherein the second outlet is spaced from the first outlet.

13. The stirrer of claim 8, further comprising a feed tube extending within the shaft and terminating at a location of the first outlet, wherein the feed tube and the shaft are configured to be non-co-rotating.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a perspective view of a stirrer according to one embodiment of the present invention;

(2) FIG. 2 is a side view of the stirrer illustrated in FIG. 1 and

(3) FIG. 3 is a side view of the stirrer illustrated in FIGS. 1 and 2, which has been dipped into a wastewater channel.

DETAILED DESCRIPTION

(4) FIGS. 1 to 3 show a stirrer 10 according to one embodiment of the present invention. The stirrer 10 comprises an electric motor 12 fastened to a mounting plate 11 and a hollow shaft 14 that is drivable via the motor 12. The hollow shaft 14 is formed entirely from plastics material or from metal material, e.g. a steel, having a coating that is resistant to the additive, in particular a plastics coating. In the region of its free end, the hollow shaft 14 is provided with a multiplicity of additive outlet openings 16. Via these additive outlet openings 16, an additive can be discharged through the hollow shaft 14, said additive being fed via a non-co-rotating feed tube 40 which is guided within the hollow shaft 14, the upper end of said feed tube 40 projecting upwardly as an additive feed line 18 and being attached on the opposite side of the motor 12 from the hollow shaft 14. The end of the feed tube 40 opens out at the level of the additive outlet openings 16. The additive outlet openings 16 are axial elongate cutouts which are arranged in a regularly distributed manner along the circumference of the hollow shaft 14 and extend in each case in the direction of the hollow shaft axis 20.

(5) Furthermore, the stirrer 10 comprises a first rotor 22, which has four rotor blades 24, and also a second rotor 26, which is provided with four rotor blades 28. The rotors 22 and 26, which are produced from plastics material, are connected to the hollow shaft 14 so as to rotate therewith and are arranged at a distance from one another so that they define between one another an intermediate space 30, in which the additive outlet openings 16 are positioned. The rotor blades 24 of the first rotor 22 and the rotor blades 28 of the second rotor 26 are arranged so as to move in opposite directions, that is to say are inclined in opposite directions, so that they generate substantially opposite flows during operation.

(6) The mode of operation of the stirrer 10 is explained in the following text with reference to FIG. 3.

(7) If the free end of the hollow shaft 14 having the rotors 22 and 26 retained thereon is dipped into a wastewater channel 34 filled with wastewater 32, as is illustrated in FIG. 3, and the hollow shaft 14 is then driven with the aid of the motor 12 in the direction of rotation indicated by the arrow 36, the flow A is generated within the wastewater 32 by the first rotor 22 and the flow B is generated by the second rotor 26, as is indicated by the corresponding arrows. In other words, by driving the first rotor 22 wastewater is sucked into the intermediate space 30 from above, while the second rotor 26 sucks or guides wastewater into the intermediate space 30 from below, thereby producing a negative pressure in the intermediate space 30. The wastewater sucked into the intermediate space 30 is then pushed radially outward out of the intermediate space 30, so that a centrifugal force is additionally generated in the intermediate space 30. In this way, good intermixing of the wastewater 32 to be treated is achieved. In addition, the additive fed via the hollow shaft 14 is sucked continuously out of the additive outlet openings 16, as is indicated by the arrows 38, thereby ensuring uniform admixture of the additive.

(8) The additive may be for example iron chloride (FeCl3), which is used for phosphate elimination in the wastewater.

(9) The above-described structure of the stirrer 10 is advantageous in particular to the extent that, with a very simple structure, very good intermixing of the medium to be treated and proper introduction of the additive can be ensured.

LIST OF REFERENCE SYMBOLS

(10) 10 Stirrer 11 Mounting plate 12 Motor 14 Hollow shaft 16 Additive outlet opening 18 Additive feed line 20 Hollow shaft axis 22 First rotor 24 Rotor blade 26 Second rotor 28 Rotor blade 30 Intermediate space 32 Wastewater 34 Wastewater channel 36 Arrow 38 Arrow 40 Feed tube