DD295773A5 - Slurry - Google Patents

Abstract

To the housing (14) of a Guelleruehrwerkes (10) closes forward annular an annular shield (34), which continues to the rear in a pipe socket (20). A stirrer rotor (16) has a rear, in the pipe socket (20) immersed wing region of constant diameter and constant pitch and a front, in a conical portion (28) of the radiation shield (34) immersed conical section with steadily vergroezzernder slope. The radiation shield (34) causes a substantial increase in the air intake into the stirring zone, so that it can be stirred even in the case of particularly viscous bales without overloading the engine. Fig. 1 {Gueller watch; Radiation shield; Pipe socket; agitation rotor; conical section; Pitch; Air entry; Motorueberlastung}

Description

For this 4 pages drawings

Field of application of the invention

The invention relates to a slurry agitator with front end flanged to a submersible housing having a pipe socket which surrounds the rear part of a conically formed at least at its front part Ruhr rotor coaxial with small radial distance and with an air intake, which is the atmosphere above the liquid level of a Gulllebehälters with an outlet opening in the region of the pipe socket or adjacent to this connects.

Characteristic of the known state of the art

Such a slurry agitator is known from DE-GM 8811813. The stirring rotor is designed in the form of a stirring screw whose vane arrangement has a uniform conicity along the entire length and also a constant pitch. The pipe socket ends at the front end of the housing. The known mixer has proven itself in practical use. However, the performance of the drive motor can only imperfectly adapt to the power requirement of the stirring rotor, and that is because the consistency of the manure is not always the same. Thick liquid manure requires a higher drive power than low-viscosity liquid manure. For reasons of scope of construction and also of costs, a drive motor is used which is designed correctly for a medium slurry consistency. If this device is used in viscous liquid manure, the current strength rises quickly above a permissible level and the motor protection switch switches off the device. If, on the other hand, a more powerful engine were used, it would be oversized for many applications. This solution would be more reliable, but uneconomical.

Object of the invention

The invention has for its object to improve the known slurry to the effect that once the air intake further improved and on the other hand creates a possibility to reduce the power consumption of the agitator rotor.

Explanation of the essence of the invention

This object is achieved in that adjoins the upper end of the pipe socket in the axial direction of an annular radiation shield, the inner surface expands at least in its front part to the mouth opening out with a conical front part of the agitator corresponding conicity. The prefitted radiation shield helps to improve the air intake capacity. Once more air is sucked in and on the other hand, even at greater depths with sufficient air intake can be stirred. The radiation shield also has the further effect that the stirring rotor operates over a greater axial length in a region in which there is a liquid-air mixture having a high proportion of air. The result is a lower current consumption than would be the case without the presence of the radiation shield. Theoretically, the stirring should be lower because of the lower power consumption of the motor. In practice, however, this disadvantage is not recognizable because the desired axial acceleration of the manure is mainly caused by the front part of the stirring rotor, which is not affected by the radiation shield.

Particularly vorteilhaflt is now the measure that at least the front part of the radiation shield is releasably secured to the housing. This creates a possibility of removing at least the front part of the radiation shield and / or exchanging it for a front part with a different axial length. In the case of low-viscosity liquid manure, the radiation shield or its front part can thus be removed or replaced by a radiation shield with a smaller axial extension in order to utilize the full power of the drive motor. With thick liquid manure, the radiation shield is needed to reduce the power consumption of the engine. In the case of a particularly thick consistency in the presence of significant proportions of solids, a radiation shield with a correspondingly greater axial length can be used according to the invention, which reduces the power consumption of the motor. Thanks to the radiation shield on the mixer, the farmer can therefore ensure that the current consumption does not exceed the permissible maximum. Thus, the stirrer does not switch off, so it can be used in all liquid manure conditions and when a radiation shield of great length is used in particularly problematic cases, the per unit time funded mass decreases, which equates to operation in dünnflüssigerer manure.

An embodiment of the invention is that at least the front part of the radiation shield consists of two half-shells. This training makes it possible to remove the radiation shield with a few simple steps and, if necessary, to replace it with another such axial length, without that the stirring rotor must be dismantled. An alternative solution is that at least the front part of the radiation shield is arranged axially adjustable with respect to the housing. The radiation shield or at least its front part can thus be moved toward the housing, that is, towards the rear, and clamped there when the power consumption can be increased. Adjusting the radiation shield forward, so that a larger part of the stirring rotor is sheathed, so the current consumption decreases. The adjustment can be made stepless. Both alternative solutions can also be combined.

A further embodiment of the invention is that at least the front part of the radiation shield has at its rear end an inner cylindrical guide casing surface which is guided axially displaceably on an outer cylindrical surface of a rear part of the radiation shield or the front end of the pipe socket. It is within the scope of the invention to provide the radiation shield with an outer cylindrical surface on which a further radiation shield is slidably guided with an inside cylindrical guide surface, so that several telescopically extendable radiation shields result in a radiation shield arrangement.

A particularly advantageous feature according to the invention consists in the fact that the pipe socket is formed circular cylindrical and that the agitator rotor has a helical wing assembly whose rear part has a constant outer diameter over at least the length of the pipe socket. The gap between the pipe socket and the outer edges of the wing assembly is therefore constant over the entire length of the pipe socket and possibly on this subsequent forward cylindrical rear portion of the radiation shield. This gap is extremely small and just dimensioned so that the stirring rotor can run without contact in the pipe socket. The immediate consequence of this feature is a particularly high air suction, which is not lost even in large stirring depths.

The stirring rotor used in accordance with the invention has a helical wing arrangement comprising several threads, the pitch of which is smaller in the rear area than in the front area. The length of the rear area

is determined by the length of the surrounding the Rührrotor cylindrical shell, which comprises at least the length of the pipe socket, but in the case of a subsequent to this cylindrical portion of the radiation shield also extends over this cylindrical portion. In this rear region of the agitator rotor, therefore, the vane arrangement is cylindrical and has a small pitch there, while in the adjoining front region the vane arrangement widens conically and has a greater pitch. In the rear area, the pitch of the wing assembly according to an embodiment of the invention is constant, while it increases steadily in the front area toward the front end.

This new form of agitator rotor takes once the conditions that prevail in the pipe socket and is designed in its front part for the strongest possible uniform axial flow of the liquid. The smaller pitch of the wing assembly in the pipe socket area and possibly adjacent forward region of the cylindrical portion of the radiation shield is relevant for a highly effective air suction, not only a large amount of air is sucked, but also provided a correspondingly high negative pressure, for the Stirring at great depths is significant.

embodiment

The drawing illustrates some embodiments.

FIGS. 1 to 4 show cross sections through the slurry agitator and differ in the design of the radiation shield projecting from the housing.

A slurry agitator 10 consists of a submersible motor 12, a housing 14 flanged thereto at this end and a stirring rotor 16 penetrating the housing, which is driven by the drive shaft, not shown, of the electric submersible motor 12. The submersible motor 12 is mounted on a holder, not shown, which can be moved up and down rails on the edge of a slurry tank. The housing 14 has a forward tapered outer sheath 18, at the front end of a cylindrical pipe socket 20 connects, which extends from the front end of the shell 18 to the rear end of the housing and presses against an annular rubber disc 22 which on the front end face of the submersible motor 12th is applied. The conical jacket 18 has an approximately rectangular peripheral opening 24, through which an air intake box 26 extends with both side walls 28 to the pipe socket 20. In the region of the suction box 26, the rear part of the pipe socket 20 is cut out, so that here an air outlet opening 30 is formed, but which is only in the rear region of the suction box 26. In a cover bore 32 of the suction box 26 opens an air intake in the form of a flexible hose, which extends above the liquid level upwards. To the housing 14, a coaxial radiation shield 34 connects to the front, having a rear cylindrical portion 36 and a front conical portion 38. This radiation shield 34 is made of cast iron and is formed integrally with the housing 14.

The agitator rotor 16 has a vane assembly 40 which has a constant outer diameter and a constant pitch in the rear region 42, but a conical outer shape and a forwardly steadily increasing slope in the front region 44. The two areas 42,44 of the wing assembly 40 are spaced apart where the cylindrical portion 36 of the radiation shield 34 merges into the conical portion 38. The cylindrical portion 36 of the radiation shield 34 represents a front continuous extension of the pipe socket 20. In particular, the inner diameter of this cylindrical portion 36 coincides with that of the pipe socket 20. The rear portion 42 of the wing assembly 40 has a constant outer diameter slightly smaller than the inner diameter of the pipe stub 20 and cylindrical portion 36. Thus, there is a gap between the rear portion of the wing assembly and the surrounding shell that is just sufficient for running clearance. The conicity of the conical section 38 of the radiation shield 34 coincides with the conicity of the wing assembly 40 in the front region 44 approximately.

The caused by the radiation shield 34 housing stem causes an extension of the coated portion of the agitator rotor 10, with the result that an increased amount of air sucked and stirred into the manure fine bubbles. The stirring rotor 10 thus operates in a liquid-air mixture of lower density and requires a low drive power. In thinner liquid manure such a large air intake is not needed. By means of an inlet valve at the upper end of the air intake line, the air intake can be throttled, so that correspondingly less air enters the stirring zone. By controlling 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 embodiment according to FIG. 2 differs from the previously described embodiment in that the radiation shield 34 is welded together from a cylindrical ring 36 and a conical ring 38. On the cylindrical ring 36 four tabs 46 extend at an angle to the rear, which corresponds to the conicity of the outer housing shell 18 to which they are screwed. In contrast to the embodiment according to FIG. 1, the radiation shield 34 according to FIG. 2 can be removed from the housing 14. The agitator rotor 16 is consistent with that of FIG.

Thanks to the detachable attachment of the radiation shield 34 on the housing 14, this can also be subsequently grown in existing slurry hoppers.

FIG. 3 shows a modification of a radiation shield 34 insofar as its cylindrical rear part 36 is separated from the front part 38. The rear portion 36 is secured by means of the tabs 46 as in Fig. 2 on the jacket 18 of the housing 14 and the front part 38 of the radiation shield 34 consists of two halves 38 'and 38 ", each having a rear semi-cylindrical shell 48, which has the cylindrical rear part The two half shells 38 ', 38 "form the front part of the radiation shield 34, whose inner conical lateral surface, which widens forward, adjoins the inner cylindrical outer surface of the rear part 36 of the radiation shield 34 without any abutment. The stirring rotor 16 is the same as in the embodiments according to FIGS. 1 and 2.

Thanks to the split arrangement of the front part 38 of the radiation shield 34, this front part 38 can be removed from its rear part 36 with a few simple steps and assemble again without having to remove the stirring rotor 16. The front part 38 can thus be quickly replaced by such a larger or smaller axial length in order to achieve an adaptation to the consistency of the manure.

It is understood that the cylindrical rear portion 36 of the radiation shield 34 is provided with the tabs 46 for screwing on the housing 14 only if it is a retrofit kit for existing housing. In new buildings, this rear part 36 of the radiation shield 34 is integrally integrated as a casting in the housing 14.

In the embodiment of Figure 4, the rear portion 36 of the radiation shield 34 is formed the same as in the embodiment of Figure 3, however, the front part 38 is provided with only a short rear cylindrical guide casing 50, the cylindrical inner surface on the cylindrical outer surface of the rear part 36 fits. In this cylindrical shell portion 50 are a plurality of circumferentially distributed clamping screws, by means of which the front part 38 is clamped on the rear part 36. After loosening the screws, the front part 38 can be moved axially steplessly, so that its shielding effect is reduced, since the radial distance to the conical part of the stirring rotor 16 is increased and the length of the axial overlap is reduced. A rear shift position is indicated by dashed lines in Figure 4.

If it is intended to be stirred in low-viscosity liquid manure, the radiation shield front part 38 can be pushed back into the dashed position and clamped tight. If, however, the permissible power consumption exceeded in thick liquid manure, it is sufficient to push the front part 38 forward and set there, which, depending on the dimensions, not necessarily the entire adjustment area is needed.

Experience has shown that the length of the radiation shield should be adjustable in the range of 5 mm to about 35 mm. This adjustment range is thus less than 20% of the total length of the stirring rotor. Nevertheless, thanks to a change in the effective length of the radiation shield, it is possible to achieve a power control which is completely adequate for the operation of slurry agitators.

Claims (10)

1. slurry agitator with flanged to a submersible motor housing housing having a pipe socket which surrounds the rear part of a conically formed at least at its front part agitator coaxial with small radial distance and with an air intake, the atmosphere above the liquid level of a slurry tank with a Outlet opening in the region of the pipe socket or adjacent to these connects, characterized in that adjoins the front end of the pipe socket (20) in the axial direction, an annular radiation shield (34), the inner lateral surface at least in its front part (38) to the mouth opening out with a the tapered front part (44) of the mixing rotor (16) corresponding conicity widened. 2. slurry agitator according to claim 1, characterized in that at least the front part (38) of the radiation shield (34) on the housing (14) is releasably attached. 3. slurry agitator according to claim 1 or 2, characterized in that at least the front part (38) of the radiation shield (34) is arranged exchangeably against such a deviating axial length. 4. slurry agitator according to one of claims 1 to 3, characterized in that at least the front part (38) of the radiation shield (34) consists of two half-shells (38 ', 38 ") is composed. 5. slurry agitator according to one of claims 1 to 4, characterized in that at least the front part (38) of the radiation shield (34) with respect to the housing (14) is arranged axially adjustable. 6. slurry agitator according to one of claims 1 to 5, characterized in that at least the front part (38) of the radiation shield (34) at its rear end an inner cylindrical guide surface (50), which on eienr outer cylindrical surface of a rear part (36) of the Radiation shield (34) or the front end of the pipe socket (20) is guided axially displaceable. 7. slurry agitator according to one of claims 1 to 6, characterized in that the pipe socket (20) is formed kreiszylindrisch and in that the stirring rotor (16) has a helical wing assembly (40) whose rear part (42) over at least the length of the pipe socket (20) has a constant outer diameter. 8. slurry agitator with flanged on a submersible motor housing, which has a pipe socket which surrounds the rear part of a conically formed at least at its front part agitator coaxial with small radial distance and with an air intake, the atmosphere above the liquid level of a slurry tank with a Outlet opening in the region of the pipe socket or adjacent to this connects, characterized in that the agitator rotor (16) comprises a multi-thread helical vane assembly (40) whose pitch in the rear region (42) is smaller than in the front region (44). 9. slurry agitator according to claim 8, characterized in that the pitch of the wing assembly (40) in the rear region (42) is constant and in the front region (44) increases steadily toward the front end. 10. slurry agitator according to claim 8 or 9, characterized in that the diameter of the wing assembly (40) in its rear, in the pipe socket (20) dipping region (42) is constant.