DE8016582U1 - Device for processing manure - Google Patents

Description

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The invention relates to a device for aerating and moving manure in a manure pit around the manure At least and preferably only one point to be supplied with air and set in motion.

A major problem with the storage and use of manure is that disruptive putrefaction processes through Anaerobic bacteria must be avoided. Such putrefaction processes ultimately lead to a decomposition of the manure, which greatly reduces their fertilizer value. For this purpose, the liquid manure - i.e. the manure accumulation - is made litter-free Pens with alluvial manure - ventilated at regular intervals to keep aerobic bacteria in to enable the manure.

For this purpose, a stirring tool has been introduced into the manure and the stirring tool air through a vertical stirrer shaft leading guide tube fed. The stirring tool was a propeller-like construction element with a vertical axis which produced essentially an axial flow. This was an intense one Circulation of the manure and a strong ventilation of the same in the immediate area of the agitator causes.

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Just the circulation of the parts of the remote from the mixer Slurry in the pit remains very little or it is there is no such circulation that the rising air has a strong vertical circulation in the Area of the tool generated. However, this has the disadvantage that considerable amounts of ammonia and nitrogen extracted from the liquid manure with the ventilation air that gushes upwards and released into the atmosphere Are ^ what the fertilizer value of the manure greatly reduced.

The invention solves the problem of creating a device for aerating liquid manure, which is characterized by that even if the manure is stored for a longer period of time, it does not lose its fertilizer value and that none of it is worth mentioning Loss of ammonia and nitrogen occur.

The invention is based on a device with a motor-driven rotating stirring tool and a supply air line ending in the area of the agitating tool, through which the supply air into the area of the agitating tool is brought.

The invention forms the known device to that effect further that on the one hand all the manure in the pit is

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can be rolled over (provided the pit is a usual, for example rectangular, square or round plan and not an angular or star-shaped one Ground plan) and that the manure is also aerated to such an extent and in such a way that the for the Biodegradation of the manure to an optimal fertilizer required amount of air can be supplied without however to to supply a lot of air / which could remove nitrogen and ammonia from the manure.

According to the invention this is achieved in that the agitator of the rotor is a casing pump, the outlet opening is approximately horizontal to - is directed as it is preferable slightly downward, that the supply air in the interior of the pump housing m ^{indet and that a Drosseleinrichtunc / to Regulation of the supply air flow is provided.

The agitating tool according to the invention can and should be in the vicinity of the edge of the manure pit, for example at a distance be arranged from about half a meter from this edge that the outlet opening of the pump housing is directed parallel to the manure pit wall. In this way, the slurry is sucked in by the housing pump and towards ejected from the outlet opening. This creates a rotational flow along the edge of the slurry pit in the manure pit.

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ben, which is slow, but covers all the manure in the pit so that it can be circulated evenly and mixed with air. The fact that the supply air line opens inside the pump housing and that a throttle device is provided to regulate the supply air flow not only ensures that the supply air is distributed very evenly in the liquid manure flow emerging from the housing pump outlet. By this uniform and fine distribution and the slow rotation of the entire slurry in the pit, and also along the walls of an optically] timale fine distribution of the air is ensured, without this immediately rise to the surface of the slurry. The air, which is distributed in the form of very fine bubbles, has enough time to spread over the entire pit in the rotating stream of liquid manure until it reaches the surface of the liquid manure. Since the air only rises in fine bubbles and also takes suspended matter with it, a floating layer forms on top of the manure pit, which primarily consists of the plant residues and air bubbles in the manure. This floating layer not only insulates the manure thermally, especially in winter. The rotting parts of the plant also contribute to the fertilizing effect of the manure and prevent the gases from escaping.

The correct amount of ventilation can be determined relatively easily by the fact that it is normally open

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Slurry pits forming floating cover should only be a light and easily destructible soft cover that is relatively is thin, so only a thickness of the order of 5 to 20 cm - usually from about 10 to 15 cm. Too much ventilation leads to breakthrough and destruction of the floating cover, too little Ventilation leads to a thickening and compression of the floating cover. Because in contrast to the previously known If a horizontal air-bubble-penetrated flow is generated, the flow can achieve what with the previous vertical currents only aimed at, but not achieved, namely a horizontal rotating one Flow. This flow is caused by the slurry jet, which in practice is usually generated by means of a pump will.

Sinking parts (straws and the like) are contaminated with air, then rise to the floating cover and become aerobic there Bacteria are broken down and largely converted into liquid and gaseous substances. This creates a sludge almost entirely avoided.

Because the slurry jet is directed horizontally to slightly downwards - the angle can be down to 30 ° be directed - it is expediently about 20 ° - it is ensured / that at least in dent following the beam

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Part of the rotating flow is the buoyancy of the air bubbles in the horizontally flowing part through the nacL below directed kinetic energy is compensated. Since the jet sucks in the liquid manure surrounding it, it creates after A few minutes of operation the desired rotating flow, which covers practically the entire pit contents. Relieved this is due to the fact that the beam generation is necessarily connected to a suction, which is also contributes to the generation of the rotating flow.

Preferably the pump is placed near the bottom of the pit. In practice, the distance from the floor is

j about 1/2 m proven. This opens the path of the fine air

large vesicles as they rise, furthermore the rotation of the entire volume of liquid is favored, since a rotation

for the lower-lying slurry parts to rotate above

Slurry parts located, especially if the lower-lying parts of the slurry are rotating at the same time strive to rise due to the air they contain.

The method according to the invention makes do with relatively short circulation and ventilation times. For normal pits with a volume of up to e * wa 300 m ³ , it is sufficient if the circulation and aeration are carried out two to three times a day for 8 to 15 minutes each time. Has proven itself in practice

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with continuous operation a circulation and ventilation time of around two minutes per day and livestock unit.

It is of course essential in the invention that the housing pump outlet and the inlet of the same are not arranged in such a way that a short-circuit flow from the outlet

trains to enter. Accordingly, the in-

opening not only locally at a distance from the outlet

opening, but also in a ^ n considerable angular difference

be arranged with respect to the outlet opening. That will

in the preferred embodiment of the invention thereby

;; achieves that the pump is a centrifugal pump with a central

axial entry - preferably from below - and tangential

Exit is.

From a structural point of view, the design of the device according to the invention is particularly simple if you have the The pump rotor directly on one of the supply air ducts

\. the hollow shaft is supported. The hollow shaft then connects the drive motor, which is located extremely half of the liquid manure, with the pump

rotor.

That the air is introduced into the pump housing, is important in the invention that it there 'flow under the inlet of the pump rotor to bubbles having a diameter

of less than 1 mm, better less than 0.5 mm very fine

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Distributed in the slurry flow | leaving the pump housing Is fed. According to the invention, this is particularly easy ^l and reaches advantage / by the pump rotor
essentially the shape of a circular disk receives / which on
one side several / preferably four, in the axial direction
from the disk and in the radial direction from the shaft protruding blades / in which from the interior of the supply air ^
Line coming supply air ducts that run between the hub of the rotor and the blade end at one or more
Bodies flow. Tests have shown that this results in a | very fine air distribution is achieved. The jj disk should be placed on top and the blades under the disk
be. The power consumption of the pump is reduced if
the blade diameter is kept about 1/2 to 1 centimeter f smaller than the disk diameter.

At least with - as is preferred - vertically | arranged hollow shaft sits the inlet opening of the pump; housing advantageous at the bottom. This makes the |

required spatial and angular spacing of the entry | Guaranteed opening from the outlet opening. In order to make the distance here particularly large, the AuslaJ
Form the channel of the pump housing relatively long.

As set out above, it is essential for the invention that

the air fed into the manure by the device i.

quantity is neither too small nor too large «in particular is there a danger here? Feed elnei? too big Air volume. In order to optimally solve the functional and technical conditions present here / it is advantageous to the agitating tool shaft guided in a sleeve carrying the pump housing on its facing away from the agitating tool To provide the end with an air inlet opening to which an adjustable throttle element is assigned. The throttle element can, for example, be in an airtight connection between the upper end of the sleeve and the drive motor Encapsulation should be provided and consist of a bore with a diameter of e.g. 10 mm, into which a conical throttle member can be screwed in more or less as required, so that the free flow cross-section decreases, the more the conical throttle member is screwed in and vice versa.

Further advantageous embodiments of the invention emerge from the following description of the example in FIG Preferred embodiment of the device shown in the drawing according to the invention.

Fig. 1 shows the device according to the invention in a view partially in section;

Fig. 2 shows in comparison to FIG. 1 enlarged compared to the

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the actual dimensioning is still significantly reduced in scale according to the invention in an axial section with respect to the hollow shaft carrying the pump rotor;

Fig. 3 shows the bottom view of the rotor of the pump of the device;

Fig. 4 shows the view from the left of Fig. 3;

Fig. 5 shows the view from below of that at the lower end of the protective sleeve carrying and surrounding the hollow shaft subsequent pump housing.

The device shown schematically in FIG. 1, partially in section, consists essentially of a drive motor 1, a protective and guide sleeve 2 connected airtight to the drive side of the motor, a pump housing 3 adjoining the guide sleeve at the bottom, and one on the drive shaft of the motor 1 mounted coupling 4, one connected to the coupling rotatable in the guide sleeve 2 mounted drive shaft 5 and a pump rotor 6 rotating in the pump housing 3. The device is a matter of course also with electrical connections for the motor, fastening means for fastening the same, for example on the edge a manure pit and whatever else should be provided.

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As can be seen from the drawing / is the guide sleeve 2 by means of a conically widened upper part 7 connected to the electric motor 1. This expediently runs at a speed of the order of 1000 revolutions per minute when the diameter of the pump rotor is 25 to 30 cm.

In the enlarged part 7 there is a only schematically indicated throttle valve 8, which is an exact Regulation of the through the pump rotor 6 via the interior of the hollow shaft 5 a bore located at the upper end thereof 9 and the amount of air sucked in through the interior of the extension 7 is allowed.

The guide sleeve 2 and the hollow shaft 5 are as needed, for example, a length of 3 or 4 m, the length should be selected such that the pump is about 0.5 m above the ^v -.> Oden the manure pit can be attached. In this connection it should be pointed out that a pump according to the invention manages with an extremely short operating time. It has been shown that in manure pits with a total volume of about 250 m, a twice daily operating time of a device according to the invention of about 8 to 15 minutes, depending on the amount of fresh manure, is completely sufficient.

As mentioned, the hollow shaft 5 is in the guide sleeve 2

guided and stored »The lower bearing is indicated at 10 in FIG.

At the lower end of the hollow shaft 2, a check valve 11 is also provided within the same, which only is indicated schematically and prevents the liquid manure from entering the interior of the hollow shaft 5 from bottom to top. This is particularly important in winter operation.

At the lower end of the hollow shaft 11 protruding into the housing 3 of the pump, the hub 12 of the pump rotor 6 is seated is pinned there in a manner not shown. The hub 12 is closed at the bottom by means of a plug 13. The support disk 14 of the rotor 6, which is welded to the hub during normal operation, sits on the hub, for example in a vertical hollow shaft 5 rotates in a horizontal plane. To the support plate 6 are evenly over the Circumference distributed four blades extending in axial planes 15, 16, 17 and 18 arranged, which with the disk 14 and the hub 12 are welded. As can be seen from FIG. 3, the blades are not exactly in the axial planes of the rotor arranged, but in the manner shown in Fig. 3 with respect to these Axlalebenen parallel in the direction of rotation moved forward. The inner ends of the blades 15 to 18 each abut the hub 12. To a clog

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To avoid fibrous material and plant debris from the pump, the paddles are located in their interior near the hub Parts, as can be seen from FIGS. 2 and 4, set back obliquely over the area of the inlet opening 27 of the pump housing 3. With this training, there is no risk of blockages, as tests have shown. Basically, a different number of blades is of course also possible. However, four blades have been tried well proven.

Advantageously, the blades do not extend radially outward to the outermost edge of the circular support disk, but rather end a short piece of, for example, 2 to 10 mm within the outermost edge of the disc, surprisingly a considerable reduction in the required drive energy is achieved with such a design.

Two air supply channels are used to bring in and distribute the air, that of the lower surface of the support disk 14, one surface of the two blades 16 and and one flat iron 19 each welded at an angle between the support disk 14 and the corresponding blade 16 or 18 and 20 are formed. The between the support disk 14, the blades 16 or 18 and the inclined flat iron 19 or 20 formed triangular channels are, as can be seen from Fig. And 4, each evil? a boom 22 or 23

connected to the inside of the hollow shaft / so that with Rota-

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tion of the pump rotor air via the throttle point 8, the Bore 9 of the hollow shaft 5, the hollow shaft 5, the bores 22, 23 and the triangular channels mentioned in the area the blades 16 and 18 is sucked in. The air emerges from these triangular channels not only in relation to them on the hollow shaft radially outer ends, but also from further outlet openings, each of approximately in the center of the flat iron 19 and 20 provided cutouts 24 and 25 are formed. Has such training has proven itself well in practice.

At the lower end of the sleeve 2, the housing Z of the pump is fixedly connected to it. This housing is a conventional spiral housing which has an outlet opening centrally below the hub 12, the diameter of which is approximately equal to half the diameter of the support disk 14. The distance between the pump rotor and the housing is small in the axial direction. It is here, for example, 5 to 15 mm. In the radial direction, the distance between the circumferential wall of the housing widens in the usual way up to the outlet channel 28, which is expediently directed downwards at a slight angle of, for example, 20 °. Because the outlet channel is directed slightly downwards, the outflowing manure receives a downward movement component, which increases the tendency of the manure, which has been made lighter by the admixture of air, upward

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counteracts rise. This makes a particularly good one Aeration also achieved near the ground.

End of description.

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Claims (6)

DR, BERG DIPL.-ING. SCHWABE '' 'DR'. 'DR, SaNDMÄIR PATENTANWÄLTE Postfach 860245 ■ 8000 Munich Lawyers' files 31 Protection claims: 1. Device for aerating and moving manure in a manure pit with a motor-driven rotating agitator and a supply air line ending in the area of the agitator through which the supply air is brought into the area of the stirring tool, characterized in that that the stirring tool is the rotor (6) of a housing pump, the outlet opening (28) of which is approximately horizontal to is directed slightly downwards, that the air supply line opens inside the pump housing (3), and a throttle device (.8) for regulating the supply air flow is provided. 2. Apparatus according to claim 1, characterized in that the pump (3, 6) a Centrifugal pump with central axial inlet (27) and tangential «=«! Outlet (28) is. »(089) 988272 988273 98 82 W 98 j j 10 /away Telegram: BEKGSfAPFPATENf Munich Öi245a> BBftOd < ; J ", '" .. ·'. , ' Öinkkonten: flypcBank Manchen 44IO122850 (BLZ 7OO2OO11) Swift C «te HYPO DE MM fliyet Vcrelnsbank MUfichcn 45) 100 (BLZ 70050270) Posischeck Munich 65341-808 (BLZ 7001OO80) τ I. 3. Apparatus according to claim 1 or 2, characterized I g e ke nn shows that the pump rotor (6) is carried by a hollow shaft (5) f forming the air supply line. 4. Device according to one of claims 1 to 3, characterized in that the pump rotor (6) essentially has the shape of a circular t disc (14), which on one side has several, front I preferably four in the axial direction from the disc and in ^: Blades protruding in radial direction from the shaft (15 to 18), in which air ducts coming from inside the air supply line run, which run between the hub (12) of the tube (6) and the blade end open at one or more points. I. 5. Device according to one of claims 1 to 4, d a - • characterized by the fact that at - how which is preferred - the inlet opening (27) of the pump housing (3) on the vertically arranged hollow shaft (5) j bottom sits. 6. Device according to one of claims 1 to 5, characterized in that the in a sleeve (2) carrying the pump housing it * «tif · · ·· ' ■ 1 (1 111 «II * «• 14 # 11« III «·« I III Il * ■ · '* II * · - 3 The agitator shaft (5) has an air inlet opening (9) at its end facing away from the agitator (6), del? an adjustable throttle member (8) vöifge ^ switched is *