DE20208107U1 - Device for processing solids - Google Patents

Description

BOCKERMANN * KSOLL * GRIEPENSTÜÖH

PO Box 102450
D-44724 Bochum

PATENT ATTORNEYS Telephone: + 49 (0) 2 34 / 51957

Fax: + 49 (0) 2 34 / 51 05

E-mail: [email protected]

ROLF BOCKERMANN* DIPL.-ING.

DR. PETER KSOLL*
DR.-ING. DIPL.-ING.

JOERG GRIEPENSTROH

DIPL.-ING.

EUROPEAN TRADEMARK ATTORNEYS

-APPROVED BY
EUROPEAN PATENT OFFICE EUROPEAN PATENT ATTORNEYS MANDATAIRES AGREES EUROPEEN

23.05.2002 XG/an

Our reference: 58/40202-001

Neuenhauser Maschinenbau GmbH, Ladestrasse 5,
D-49828 Neuenhaus

Device for processing solids

The invention relates to a device for processing solid materials, such as earth, cohesive soils, loose rock, compost or similar pourable and/or free-flowing materials according to the features in the preamble of claim 1.

DE 199 28 034 A1 states that a crushing and/or screening device for bulk materials is part of the state of the art, which comprises at least one rotor mounted in a housing, which has several rotor disks held on a rotor shaft. Cutting teeth are held between the rotor disks in conically tapering receptacles and are secured by means of a clamping element in the form of a screw bolt that passes radially through the rotor shaft. This well-known machine has proven itself to be extremely useful in separation technology for screening and crushing a wide variety of materials.

The throughput of such a crushing and/or screening device depends crucially on the drive power, drive speed and

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the geometric design of the device. Important geometric parameters are the distance between the shafts and their diameter. Of course, the throughput also depends on the available screen area and the separation distance determined by the processing elements. For structural reasons, these parameters often cannot be changed easily, as this would in many cases require a completely new design.

Based on this, the object of the invention is to provide a device for processing solids which has a higher throughput without having to make changes to the aforementioned parameters.

The invention solves this problem by the features specified in claim 1.

The essential feature of the device according to the invention is that several of its adjacent waves are combined to form wave packets, with the directions of rotation of the wave packets being in opposite directions to one another. Tests have shown that the opposite direction of rotation of the wave packets makes it possible to increase the throughput without having to change basic geometric parameters, such as the shaft diameter or the design of the processing elements. The opposite direction of rotation of the wave packets means that the solids to be processed are loosened up even more, particularly when the solids are transported towards one another by the wave packets and are intensively mixed when they come into contact.

Each wave packet comprises at least two waves that are connected together in the same direction of rotation, whereby several adjacent wave packets always work in opposite directions to each other.

-3-

The device according to the invention can be either a mobile or a stationary unit, regardless of the design of the processing elements. It is considered particularly advantageous to use it with blade separators.

In an advantageous embodiment of the inventive concept, the wave packets are arranged directly adjacent to one another (protection claim 2). However, it is also conceivable that an intermediate shaft is arranged between adjacent wave packets (protection claim 3). Such an intermediate shaft does not necessarily have to be rotatably mounted, but can also be positioned in a fixed position. It does not necessarily have to have a cylindrical outer contour, but can also be provided with fixed processing elements that, for example, mesh with the processing elements of the adjacent rotating shafts. The processing elements can be arranged in such a way that the entire screening and/or crushing surface of the device has a constant separation dimension.

Of course, it is also possible for the intermediate shaft to have a cylindrical shape without additional processing elements being provided on it (protection claim 4).

To process the solids, each shaft packet can be assigned a single drive unit (protection claim 5). However, it is also conceivable that several shaft packets are driven together by one drive unit, with the opposite direction of rotation being implemented by interposing gear elements (protection claim 5). The inventive concept also includes that not only each shaft packet, but optionally each individual shaft is assigned a separate drive unit if a particularly high drive power is to be transmitted to the shafts. In this case, the drive units are synchronized with regard to the direction of rotation and rotation speed so that separately driven

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neighboring shafts with the same direction of rotation are combined to form rotation direction packages in the sense of the invention.

According to claim 6, the directions of rotation of the wave packets are switchable. This means that the device according to the invention can be adjusted to the individual processing requirements of a wide variety of solid types. In addition, the switchable wave packets can prevent and also eliminate caking or blockages in the device according to the invention without further manual intervention.

In the embodiment according to claim 7, the processing elements are designed as support arms with impact heads at the end, which are arranged on the shafts in a spiral-shaped manner offset from one another in their longitudinal direction. Tapered oval or teardrop-shaped disc-like support arms, on whose free ends the impact heads are provided, are particularly suitable. This geometry contributes significantly to achieving a high throughput and to reducing caking or blockages.

This specific design of the device according to the invention is ideally suited for loosening and aerating compost, sludge and soil. It can be used to break up cohesive soils such as loam, clay and wet soils. Its advantages also come into play when breaking up stuck bulk materials such as salts, for example road salt, ashes and similar materials.

The shafts can in turn be part of a so-called bucket separator, which is used as a bucket of a loading machine.

The support arms can be permanently installed on the shaft or installed as a clip-on or slide-on system, with the impact heads preferably being held in place in an exchangeable manner, for example by means of screws. The impact heads can also be permanently installed, however.

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The number of support arms equipped with impact heads is variable and depends on the working width and the screening area of the device.

The impact heads are preferably held in holders at the free ends of the support arms (protection claim 8). The impact heads can be fixed in place in different ways. Impact heads that have an anchoring section that positively engages undercuts at the free end of the support arms are considered to be particularly suitable for practical use (protection claim 9). In this way, an assembly-friendly and stable dovetail connection is created. With this type of connection, the impact heads can be replaced quickly and easily. The impact heads can be tightened using bolts that pass through the shaft and the support arms, which also fixes the support arms to the shaft if they are not permanently connected to the shaft.

Depending on the design of the device, the shafts can be solid or hollow (protection claims 10 and 11). The shafts have at least two impact heads that are offset from one another in the circumferential direction. The arrangement of the impact heads is chosen so that the outer shafts of adjacent wave packets mesh with one another. Such meshing is only possible with a spirally offset arrangement of the support arms if the individual support arms do not interfere with one another. One possible solution is that only every second support arm position is occupied on the outer shafts of adjacent wave packets.

The invention is described in more detail below by means of exemplary embodiments shown in the drawings. They show:

Figure 1 shows a schematic representation of a sieve arrangement of a

device according to the invention, with wave packets immediately adjacent to one another;

Figure 2 in the representation of Figure 1 an embodiment with

an intermediate wave between indirectly adjacent wave packets;

Figure 3 is a rear view of the screen and/or crusher arrangement of a blade separator with intermediate shaft and

Figure 4 shows a simplified perspective view of two immediately adjacent and intermeshing wave packets of a screening and/or crushing arrangement.

Figure 1 shows a highly simplified representation of a screening and/or crushing arrangement which is part of a device (not shown in detail) for processing solids, in particular bulk and/or free-flowing goods. The screening and/or crushing arrangement 1 comprises two wave packets 4, 5 each made up of three shafts 2, 2a, 3, 3a. On each shaft 2, 2a, 3, 3a of the wave packets 4, 5, schematically indicated disk-shaped processing elements 6 are distributed at a uniform distance over their longitudinal extent. The processing elements 6 of two adjacent shafts 2, 3 are each placed offset from one another and thus form a screening and/or crushing arrangement.

The shafts 2, 2a of the first shaft packet 4 all have the same direction of rotation L, while the shafts 3, 3a of the second shaft packet 5 have the opposite direction of rotation R. As a result, the directions of rotation of the shaft packets 4, 5 designated I and II are also opposite. The shafts 2a and 3a of the shaft packets 4, 5 that are immediately adjacent to one another mesh with one another. This is not a problem as long as the processing elements 6 are arranged in a disk shape and do not interfere with one another even when they rotate in opposite directions.

For a full filling of the individual shafts 2, 2a with sieve elements, according to the embodiment shown in Figure 2, a sieve and/or breech

cher arrangement 7, an intermediate shaft 8 can be arranged between the indirectly adjacent wave packets 4, 5. For the rest, reference is made to the description of Figure 1.

A practical embodiment of this variant is shown in Figure 3. The device 9 shown there in the form of a blade separator has two shaft packages 10, 11 with three shafts 12 on the one hand and four shafts 13 on the other. The number of shafts 12, 13 in adjacent shaft packages 10, 11 can therefore vary. Each of the processing elements 14 is designed as a support arm 15 with a hammer-shaped impact head 16 at the end, the support arms 15 being arranged on the shafts 12, 13 in a spiral manner offset from one another in their longitudinal direction. The two shaft packages 10, 11 are separated from one another by an intermediate shaft 17 extending in the longitudinal direction of the shafts 12, 13.

In this design, the shafts 12, 13 are completely occupied by processing elements 14, which are arranged in a spiral shape such that they do not hinder each other. However, this would be the case in counter-rotating operation if the intermediate shaft 17 were also designed as a driven shaft 12.

Figure 4 shows a solution in which the processing elements 14 shown in Figure 3 can be directly connected without the interposition of an intermediate shaft 17.

mesh with one another. This is achieved by the fact that the adjacent shafts 18a, 19a of the screening and/or crusher arrangement 20 are not completely occupied with processing elements 14 like the other shafts 18, 19 of the corresponding shaft packages 21, 22, but only in a mutual offset at every second position. This enables a meshing engagement of the adjacent shafts 18a, 19a. An intermediate shaft is not required.

From Figure 4 it is clear that the impact heads 16 are held in receptacles 23 at the free ends 24 of the support arms 15. The impact heads 16 engage with

an anchoring section 25 into an undercut 26 at the free end of the support arm 15.

In this embodiment, three support arms 15 are arranged on each of the adjacent shafts 18a, 19a, while seven support arms 15 are provided on each of the other shafts 18, 19. The support arms 15 are designed like disks and have an almost oval shape. Their wide and round base section 27 is penetrated by the shafts 18, 18a, 19, 19a. The support arms 15 taper towards the impact heads 16. The support arms 16 are offset from one another by 120° in the circumferential direction on the adjacent shafts 18a, 19a. The support arms 16 on the other shafts 18, 19 are offset from one another by 60° in the circumferential direction.

The shafts 18, 18a, 19, 19a are each accommodated at their ends in a bearing 28. At their lower ends, the shafts 18, 18a, 19, 19a are each provided with chain wheels 29 and are driven by drive units and link chains (not shown in detail) with respect to the shaft package 21 in the direction of rotation symbolized by I. The shaft package 22 has the opposite direction of rotation II.

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Reference symbols:

1 - Screening and/or crushing arrangement

2- wave v. 4.4a 2a- wave v. 4, 4a

3- Wave v. 5, 5a 3a- wave v. 5, 5a

4 - wave packet v. 4a - wave packet

5 - wave packet v. 5a - wave packet

6 - Preparation element

7 - Screening and/or crushing arrangement

8 - Intermediate shaft v.

9 - Device 10- Wave packet v. 11 - Wave packet v.

12- Wave of 10

13- Wave of 12

14- Preparation element on 12, 15 - Support arm

16- Impact head

17 - Intermediate shaft

18- Wave of 22 18a- Wave of 22

19- Wave of 21 19a- Wave of 21

20 - Screening and/or crushing arrangement

21 - Wave packet v. 22 - Wave packet v. 23 - Recording of

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24 - free end of 15

25 - Anchoring section

26 - Undercut

27 - Base section

28 - Warehouse

29- Sprockets

L - direction of rotation of 2, 2a

R - direction of rotation of 3, 3a

I - Direction of rotation of 4

Il - Direction of rotation of 5

Claims (13)

1. Device for processing solids , such as earth, cohesive soils, sludge, loose rock, compost and similar pourable and/or free-flowing goods, comprising several rotatably mounted shafts ( 2 , 2a ; 3 , 3a ; 12 , 13 ; 18 , 18a; 19 , 19a ) provided with processing elements ( 6 , 14 ) and forming a screening and/or crushing arrangement ( 1 , 7, 20), characterized in that at least two adjacent shafts (2, 2a; 3, 3a; 12, 13; 18a, 19a) are combined to form a shaft package (4 , 4a ; 5 , 5a ; 11 , 12 , 21 , 22 ) , wherein the directions of rotation (L, R) of the waves ( 2 , 2 a; 3 , 3 a; 12 , 13 ; 18 , 18 a; 19 , 19 a) within a wave packet ( 4 , 4 a; 5 , 5 a; 11 , 12 ; 21 , 22 ) are in the same direction and the directions of rotation (I, II) of the wave packets ( 4 , 4 a; 5 , 5 a; 11 , 12 ; 21 , 22 ) are opposite to one another. 2. Device according to claim 1, characterized in that the wave packets ( 4 , 5 ; 21 , 22 ) are arranged directly adjacent to one another. 3. Device according to claim 1, characterized in that an intermediate shaft ( 8 , 17 ) is arranged between adjacent wave packets ( 4a , 5a ; 11 , 12 ). 4. Device according to claim 3, characterized in that the intermediate shaft ( 8 , 17 ) has a cylindrical shape. 5. Device according to one of claims 1 to 4, characterized in that each wave packet ( 4 , 4a ; 5 , 5a ; 10 , 11 ; 21 , 22 ) is assigned a drive unit. 6. Device according to one of claims 1 to 5, characterized in that the directions of rotation (I, II) of the wave packets ( 4 , 4a ; 5 , 5a ; 10 , 11 ; 21 , 22 ) are switchable. 7. Device according to one of claims 1 to 6, characterized in that the processing elements ( 14 ) are designed as support arms ( 15 ) with end-side impact heads ( 16 ), wherein the support arms ( 15 ) are arranged on the shafts ( 12 , 13 , 18 , 18a , 19 , 19a ) in a spiral-shaped manner offset from one another in their longitudinal direction. 8. Device according to claim 7, characterized in that the impact heads ( 16 ) are held in receptacles ( 23 ) at the free ends ( 24 ) of the support arms ( 15 ). 9. Device according to claim 8, characterized in that the impact heads ( 16 ) engage with an anchoring section ( 25 ) in a form-fitting manner in an undercut ( 26 ) at the free end ( 24 ) of the support arms ( 15 ). 10. Device according to one of claims 1 to 9, characterized in that the shafts are solid. 11. Device according to one of claims 1 to 9, characterized in that the shafts are hollow. 12. Device according to one of claims 7 to 11, characterized in that the shafts ( 12 , 13 ; 18 , 18a , 19 , 19a ) have at least two impact heads ( 16 ) arranged offset from one another in the circumferential direction. 13. Device according to one of claims 1 to 12, characterized in that the outer shafts ( 2 a, 3 a; 18 a, 19 a) of adjacent shaft packets ( 4 , 5 ; 21 , 22 ) mesh with one another.