AT398018B - GÜLLER AGITATOR - Google Patents

Description

AT 398 018 B

The invention relates to a slurry mixer with a housing flanged to the front of a submersible motor, which has a conical pipe socket which coaxially surrounds a stirrer rotor with a helical wing arrangement, which is at least conical at the front, with a small radial distance, and with an air intake line which conveys the atmosphere above the liquid level of a slurry tank connects with 5 an outlet pipe in the area of the pipe socket or adjacent to it.

Such a slurry mixer is known from DE-OS 36 21 903. The conical pipe socket surrounds the rear area of the stirring rotor, which is continuously conical with a constant pitch. An annular gap immediately adjoins the rear end of the conical pipe socket, through which the air is sucked in from the air intake line into the stirring area. The known agitator may have a sufficient agitation effect, but the air entry into the medium to be agitated is limited. On the one hand, only a comparatively small amount of air is sucked in and, on the other hand, the negative pressure achieved is low, so that at greater stirring depths, no more air is introduced. A further disadvantage is that when the agitator is at a standstill, solids penetrate through the annular gap into the air intake chamber, which then dry out and stick together, as a result of which the annular gap can become clogged. 15 DE-GM 88 11 813 U1 shows an agitator housing with a retracted, i.e. backward-pointing cylindrical pipe socket, which surrounds the rear region of the conical wing arrangement of the stirring rotor and has a rectangular air outlet opening. With this embodiment, the risk of clogging of the air intake opening can be eliminated. Nevertheless, even in this version, the air intake is restricted, particularly in larger stirring depths. 20 AT-PS 348 454 shows an agitator with a cylindrical pipe socket, which is followed by a conical drill socket. The stirrer rotor consists of a wheel disc body, which is equipped on both sides with a spiral blade for radial outflow. The two blade arrangements are located outside the two drill sockets. The pipe sockets do not affect the stirring effect of the stirring rotor.

DE-OS 29 17 423 shows an agitator with a propeller arrangement which has three axially successively placed propellers of the same size, the first of which is partially surrounded by a conical hood into which a ventilation line opens.

AT-PS 246 480 shows an agitator with a cylindrical pipe socket, in which a spiral stirring screw is arranged. The pipe socket has no air outlet opening. The wing arrangement of the stirring screw and the shape of the pipe socket are not matched to one another. 30 Finally, FR-PS 2 258 351 discloses a conically expanding stirring screw, in one embodiment with a constant pitch of the wing arrangement and, according to an alternative, with a decreasing pitch of the wing arrangement towards the free screw end. The stirring screw runs freely, so it is not surrounded by a pipe socket.

The object of the invention is to improve both the 35 air entry into the slurry and to increase the stirring effect in a slurry mixer of the type mentioned.

To solve this problem it is provided in a slurry agitator of the type mentioned at the outset that a conical pipe socket extending into the housing adjoins the conical pipe socket in the axial direction and that the stirring rotor has a cylindrical rear region assigned to this cylindrical pipe socket and that the pitch of the wing arrangement 40 of the stirring rotor in the rear area is smaller than in the front area.

With the invention, therefore, a novel jacket for the stirring rotor is proposed, which is composed of a rear cylindrical section and an adjoining front conical section. On the other hand, the agitator rotor is also redesigned with regard to the blade arrangement. For the cylindrical pipe socket, the stirrer rotor has a cylindrical design in its rear region, to which a conically widening vane arrangement associated with the conical pipe socket connects to the front. Since the negative pressure for the air intake is generated in the cylindrical pipe socket, the pitch of the wing arrangement of the stirring rotor is made smaller in the rear area than in the front area. The helical windings of the wing arrangement are therefore narrower in the rear area than in the front area. With the new agitator design, on the one hand it is achieved that the air entrainment is improved, in particular at greater stirring depths, and on the other hand it is ensured that the stirring effect compared to the prior art mentioned at the beginning is at least maintained.

According to one embodiment of the invention, at least the front part of the conical pipe socket is releasably attached to the housing. With this feature it is achieved that this front part is interchangeable with such a different axial length can be removed without having to disassemble the agitator. The length of the interchangeable front part influences the stirring effect and thus also the required drive power. Is e.g. the drive power of the engine for a 2nd

AT 398 018 B particularly viscous slurry consistency too low, the stirrer can still be used by extending the conical pipe socket without causing motor overload.

According to claim 7, the pitch of the wing arrangement is constant in the rear area, while it increases continuously in the front area towards the rotor front end. This feature also contributes to the improvement of the air intake behavior, especially at greater stirring depths.

The drawing illustrates some embodiments.

Figures 1 to 4 show cross sections through the slurry mixer and differ in the design of the conical pipe socket protruding from the housing.

A slurry agitator 10 consists of a submersible motor 12, a housing 14 flanged to the front of the latter and a stirring rotor 16 penetrating the housing, which is driven by the drive shaft (not shown) of the submersible electric motor 12. The submersible motor 12 is mounted on a bracket, not shown, which can be moved up and down on rails on the edge of a slurry tank. The housing 14 has a conically tapering outer casing 18, at the front end of which is connected a cylindrical pipe socket 20 which extends from the front end of the casing 18 to the rear end of the casing and presses against an annular rubber washer 22 which presses on the front end face of the submersible motor 12 is present. The conical jacket 18 has an approximately rectangular opening 24 through which an air intake box 26 extends with both side walls 28 as far as the pipe socket 20. In the area of the suction box 26, the rear part of the pipe socket 20 is cut out, so that there is an air inlet opening 30 here is formed, which is, however, only in the rear area of the suction box 26. An air suction line in the form of a flexible hose opens into a cover bore 32 of the suction box 26 and extends upward above the liquid level.

At the front of the housing 14 is a coaxial screen 34, which has a cylindrical pipe socket extension 36 and a front conical pipe socket 38. This screen 34 is made of cast iron and is formed in one piece with the housing.

The stirring rotor 16 has a vane arrangement 40 which has a constant outer diameter and a constant pitch in the rear area 42, but has a conical outer shape in the front area 44 and a pitch which increases continuously towards the front. The two areas 42, 44 of the wing arrangement 40 adjoin one another where the cylindrical pipe socket extension 36 of the screen 34 merges into the conical pipe socket 38. The cylindrical pipe socket extension continuously adjoins the cylindrical pipe socket 20, particularly on the inside. The rear region 42 of the wing arrangement 40 has a constant outer diameter slightly smaller than the corresponding inner diameter of the pipe socket 20 and its extension 36. This results in a gap between the rear region of the wing arrangement and the surrounding jacket, which is just sufficient for the running play. The taper of the conical pipe socket 38 of the screen 34 roughly corresponds to the taper of the wing arrangement 40 in its front region 44.

The housing stem generated by the screen 34 causes an extension of the coated area of the stirring rotor 10 with the result that an increased amount of air is sucked in and stirred into the liquid manure in fine bubbles. The stirring rotor 10 thus works in a liquid / air mixture of lower density and requires less drive power. Such a large amount of air is not required in less fluid manure. The air intake can be throttled by means of an inlet valve at the upper end of the air intake line, so that correspondingly less air gets into the stirring zone. By regulating the air supply, the density of the stirring medium in the region of the stirring rotor can thus be adjusted and adapted to the drive power of the submersible motor 10.

The training according to FIG. 2 differs from the above-described embodiment in that the shield 34 welded together from cylindrical pipe socket extension 36 and conical pipe socket 38 is removably screwed onto the housing 14 by means of four angled tabs 46. The stirring rotor 16 coincides with that according to FIG. 1 match.

Thanks to the detachable fastening of the screen 34 to the housing 14, it can also be retrofitted to existing slurry agitators. FIG. 3 shows a modification of a screen 34 insofar as its cylindrical pipe socket extension 36 is separated from the conical pipe socket 38. The extension 36 is connected by means of the tabs 46 as shown in FIG. 2 is attached to the casing t8 of the housing 14 and the conical pipe socket 38 consists of two halves 38 'and 38', each of which has a rear semi-cylindrical shell 48 which encompass the cylindrical extension 36 and are screwed to it. The two half-shells 38 ′, 38 ″ form the conical pipe socket 38, the inner of which adjoins the inner cylindrical lateral surface of the pipe socket extension 36 without a step from the expanding conical lateral surface. The stirring rotor 16 is the same as in the embodiments according to FIGS. 1 and 2. 3

Claims (2)

AT 398 018 B Thanks to the split arrangement of the conical pipe socket 38, it can be removed from the pipe socket extension 36 in a few simple steps and also be reassembled without having to remove the stirring rotor 16. A quick exchange for such a larger or smaller axial length is therefore possible in order to adapt to the constancy of the slurry. It goes without saying that the tabs 46 for screwing the screen 34 onto the housing 14 are only necessary when retrofitting existing housings. In new buildings, this extension 36 is integrally integrated into the housing as a cast part. In the execution according to FIG. 4, the pipe socket extension 36 is constructed in exactly the same way as in the embodiment according to FIG. 3, however, the conical pipe socket 38 has a short rear cylindrical guide jacket 50, the cylindrical inner surface of which fits on the cylindrical outer surface of the pipe socket extension 36, there are several circumferentially distributed clamping screws in this cylindrical jacket section 50, after the loosening of which the conical pipe socket 38 can be moved axially steplessly , the radial distance to the conical part of the stirring rotor 16 on the one hand and the length of the axial overlap on the other hand being changed. A rear sliding end position is shown in FIG. 4 indicated by dashed lines. If stirring is to take place in liquid manure, the conical pipe socket 38 can be pushed back into the dashed position and clamped. If, on the other hand, the permissible current consumption of the motor was exceeded in the case of viscous liquid manure, it is sufficient to push the conical pipe socket 38 forward and fix it there, the entire adjustment range not necessarily being required depending on the dimensions. Experience has shown that the conical pipe socket 38 should be adjustable in the range from 5 mm to approximately 35 mm. This adjustment range is less than 20% of the total length of the stirring rotor. Nevertheless, thanks to the change in the effective length of the screen 34, a power adjustment which is completely sufficient for the operation of liquid manure plants can be achieved. 1. Slurry agitator with a flange-mounted housing on the front of a submersible motor, which has a conical pipe socket that coaxially surrounds a stirrer rotor with a helical wing arrangement, at least in the front area, with a small radial spacing, and with an air intake line that carries the atmosphere above the liquid level of a liquid manure container connects an outlet opening in the area of the pipe socket or adjacent to it, characterized in that a cylindrical pipe socket (20) extending into the housing (14) in the axial direction to the rear is connected to the conical pipe socket (38) in such a way that the stirring rotor (16 ) has a cylindrical rear area (42) assigned to this cylindrical pipe socket (20) and that the pitch of the wing arrangement (40) of the stirring rotor (16) in its rear area (42) is smaller than in its front area (44). 2. Slurry agitator according to claim 1, characterized in that at least the front part of the conical pipe socket (38) on the housing (14) is releasably attached. & Slurry agitator according to claim 1 or 2, characterized in that at least the front part of the conical pipe socket (38) is arranged to be exchangeable for such a different axial length. 4. Slurry agitator according to one of claims 1 to 3, characterized in that at least the front part of the conical pipe socket (38) is composed of two half-shells (38 ', 38 "). 5. Slurry mixer according to one of claims 1 to 4, characterized in that at least the front part of the conical pipe socket (38) with respect to the housing (14) is arranged axially adjustable. 6. Güiler agitator according to one of claims 1 to 5, characterized in that at least the front part of the conical pipe socket (38) has at its rear end an inner cylindrical guide surface (50) on an outer cylindrical surface of the cylindrical pipe socket (20) or one cylindrical pipe socket extension (36) is guided axially displaceably 4 AT 398 018 B 7. Slurry agitator according to one of claims 1 to 6, characterized in that the pitch of the wing arrangement (40) in the rear area (42) is constant and in the front area ( 44) steadily enlarged towards the front end. Including 4 sheets of drawings 5