WO2021023536A1 - Gyratory crushing device and method for crushing material to be crushed, and use of a clamping unit for same - Google Patents

Abstract

The invention relates to a supporting of a crosspiece on a crusher housing in a reversible mounting position. In particular, the invention relates to a gyratory crushing device (100) for crushing material to be crushed, comprising a crusher housing (10) in which a crusher shaft (11) is arranged, which is accommodated in the crusher housing such that it can move in a wobbling motion about a vertical axis (12), wherein a crosspiece (13) is provided for receiving the crusher shaft, which extends diametrically over the crusher housing and is connected to the crusher housing by its crosspiece ends (14), wherein at least one crosspiece end (14) can be detachably mechanically clamped to the crusher housing by means of at least one clamping unit (30), in such a way that the crosspiece (13) can be reversibly connected to the crusher housing in an interlocking and/or force-locking manner, without an integral connection, for the intended operation of the gyratory crushing device. This provides a robust connection that can be easily produced and individually adjusted. The invention also relates to a method for clamping the crosspiece and to the use of clamping units for same.

Description

description

Rotary crusher device and method for crushing crushed material and use of a clamping unit therefor

TECHNICAL AREA

The invention relates to a gyratory crusher device and a method for comminuting crushed material, the gyratory crusher device having a crusher housing on which a cross member is provided for receiving the crusher axis. The invention also relates to the use of a tensioning unit for mounting a traverse on a crusher housing. In particular, the invention relates to a device and a method according to the preamble of the respective independent or subsidiary claim.

BACKGROUND

Rotary crushers are used, for example, for the crushing of crushed material arising from material flow and logistics, when mining materials or when processing or assembling raw materials. For this purpose, the crushed material is fed in in particular by a tumbling movement about a vertical axis. It is also of interest that the crusher axis be supported on the crusher housing as robustly as possible. In many applications it has proven to be advantageous if the bearing can nonetheless be dismantled, in particular for maintenance purposes.

DE 1 290 034 A describes a gyratory crusher for comminuting crushed material with a crusher housing in which a crushing axis is arranged and which is received in the crusher housing in a tumbling motion about a vertical axis. The crusher housing has a round, approximately funnel-like shape, and a traverse is arranged on the upper edge of the crusher housing, in which a roller bushing is accommodated for mounting the crushing axis. On the lower side, the breaking axis is mounted in an eccentric bushing, and a pressure bearing is provided on the underside for the axial support of the breaking axis in the vertical. The traverse is bolted to the top of the crusher housing, and screw bolts are shown connecting the crossbeam to the crusher housing.

A gyroscopic crusher of the generic type is also known from US 2002/088887 A1.

During the operation of a gyratory crusher, very high dynamic process forces arise between the crushing axis and the crusher housing, so that a connection of the crossbeam to the crusher housing by a simple screw connection by means of screw bolts is not sufficient. In particular, when the traverse extends in a longitudinal direction between two traverse ends, and when the traverse is connected to the upper edge of the crusher housing via the traverse ends, force relationships between the traverse and the crusher housing can arise that can no longer be absorbed by the screw bolts .

FIG. 1 shows a rotary crusher 1 for comminuting crushed material according to the prior art, and a cross member 13 is connected to the crusher housing 10 by means of screw bolts 21. The cross member 13 extends diametrically over the crusher housing 10 in a longitudinal direction X and has two opposite cross member ends 14 at the end, which are received in receiving pockets 17 which are integrally formed on the crusher housing 10 on the upper side. A roller bushing 22 is received in the cross member 13, in which the breaking axis 11 is mounted and can perform a wobbling movement about the vertical axis 12.

The high process forces between the crushing axis 11 and the crusher housing 10 require a mechanically highly resilient connection between the traverse 13 and the crusher housing 10. In order to further strengthen the connection between the traverse 13 and the crusher housing 10 by means of the screw bolts 21, the traverse ends 14 are in The receiving pockets 17 on the crusher housing 10 are cast with a hardening epoxy compound 23. This gives the connection between the crusher housing 10 and the traverse 13 sufficient mechanical strength, but there are disadvantages when removing the traverse 13 from the crusher housing 10, which is required, for example, as part of maintenance work on the gyratory crusher 1. To remove the traverse 13 from the crusher housing 10, the connection through the epoxy compound 23 between the Traverse ends 14 and the receiving pockets 17 are laboriously released, and when the traverse 13 is reconnected to the crusher housing 10, the connection through the epoxy compound 23 in addition to the connection through the screw bolts 21 must also be re-established. It is therefore desirable to create a connection between the crossbeam and the crusher housing which is easy to set up and which is designed in such a way that the high mechanical forces can be transmitted between the crossbeam and the crusher housing.

DESCRIPTION OF THE INVENTION

The object of the invention is to provide a device and a method with the features described at the outset, with which a mechanically highly resilient and at the same time reversibly detachable or mountable connection between the crossbeam and the crusher housing can be provided.

This object is achieved by a device and a method according to the independent patent claims. Advantageous exemplary embodiments are listed in the subclaims.

According to the invention, this object is achieved in particular by a rotary crusher device for crushing crushed material, with a crusher housing in which a crushing axis is arranged, which is received in the crusher housing in a tumbling motion around a vertical axis, with a cross member being provided for receiving the crushing axis, which extends diametrically across the Crusher housing extends and is connected with its traverse ends to the crusher housing, at least one traverse end being dismantled mechanically on the crusher housing by means of at least one tensioning unit in such a way that the traverse is positively and / or non-positively connected to the crusher housing for the intended operation of the gyratory crusher device is reversibly connectable. This provides a robust, resilient connection that can be reversibly established in a particularly simple or rapid manner, in particular also with comparatively low expenditure on equipment. In particular, no hydraulic fittings are required.

According to the state of the art, a largely irreversible material connection (in particular epoxy compound) has taken place in many applications, or hydraulic fittings had to be provided for a reversible connection. Hydraulic clamping already provides numerous advantages compared to a material connection, but it can be further optimized for numerous applications. In contrast, the present invention is also distinguished by the simplicity, variability and robustness of the components.

In the present disclosure, the traverse is described as a traverse with (only) two ends. The invention can also be applied to trusses with e.g. three ends, i.e. to trusses arranged or supported in a star-like manner.

According to one embodiment, both ends of the traverse are mechanically clamped on the crusher housing by means of at least one clamping unit. This also expands the possibilities of bracing and can further increase operational reliability.

The traverse can be braced at least in one spatial direction, preferably in at least two at least approximately orthogonally aligned spatial directions, in particular in a plane at least approximately orthogonally to the crusher axis. In this way, not least, a particularly high strength of the bracing and thus also a particularly play-free support of the crusher housing or support on the crusher housing can be ensured. The forces can be passed on in a consistently good manner, largely regardless of the type of wobbling movement.

According to one embodiment, at least two, three or four clamping units are provided, in particular for each end of the crossbeam, in particular in at least one receiving pocket for receiving the respective end of the crossbeam on the crusher housing. As a result, the bracing or the biasing can be further optimized, in particular also depending on the direction. Scaling can optionally take place, for example in the case of a comparatively large crusher housing through a large number of comparatively small clamping units. Last but not least, this can also increase operational reliability; If, for example, a single clamping unit fails or something comes loose, the required clamping force can still be ensured.

In particular, at least four clamping units are provided for each end of the traverse, which are aligned in pairs in one of two effective directions / spatial directions and are each arranged individually or in pairs in the operative position with a corresponding pressure plate. This configuration has proven to be particularly advantageous in combination with an arrangement of the ends of the crossbar in receiving pockets; In particular, it can be braced against opposite flanks.

According to one embodiment, the at least one tensioning unit has a wedge, which can be positioned relative to a pressure element interacting therewith, for setting a tensioning force, in particular by means of a spindle. As a result, a large clamping force can also be generated by means of robust, simple means and by a comparatively small actuation force (actuating force). A transmission ratio can also be selected individually for the application, in particular as a function of a wedge angle and / or a thread pitch of the spindle. In addition, the force can also be set with good accuracy.

In particular, a / the wedge of the at least one tensioning unit can define an inclined plane which extends at an angle in the range from 1 to 25 °, in particular 2 to 20 °, relative to a base plate. This also enables an exact adjustment of the clamping effect.

The spindle can remain on the respective clamping unit or only be provided for clamping or adjustment when necessary. In the intended arrangement of the respective clamping unit, the spindle preferably protrudes downwards, in particular out of the housing. In the housing, in particular on the respective receiving pocket, openings or recesses for leading through the respective spindle can accordingly be provided. This design also promotes accessibility. According to one embodiment, the at least one clamping unit has a base plate which is fastened to the crusher housing, in particular by means of at least one screw connection. In this way, on the one hand, the force application point on the housing can be predefined. The relative position of the base plate can easily be specified individually for each application, in particular via screw connections in an individual position on the housing.

The traverse can be braced from the inside against the crusher housing in at least one receiving pocket. This provides a particularly good stability effect, especially in the case of very massive housings.

According to one embodiment, the clamping action of at least one clamping unit of the gyratory crusher device is oriented in the circumferential direction and / or in the radial direction, in particular orthogonally and / or parallel to the longitudinal direction of the crossbar. This also ensures good stability with regard to numerous (tumbling) movement patterns and numerous reaction forces.

According to one exemplary embodiment, at least one traverse guide is configured on the crusher housing, in particular two traverse guides for both traverse ends, in particular one traverse guide aligned in the vertical direction (z). This simplifies assembly, and the support on the housing can be further improved.

A plurality of form-fitting contours can be configured on the traverse to correspond to the crusher housing in such a way that the traverse can be guided along these contours in the vertical direction (z) or mounted in a centered manner in the crusher housing or on the crusher housing. Last but not least, this also favors a stability-promoting interaction (form fit and / or force fit) with the clamping units.

According to one embodiment, screw bolts are provided with which the crossbar ends are screwed into (the) receiving pockets of the crusher housing (in addition to the clamping effect of the at least one clamping unit), in particular from below (accessibility for fastening or loosening the screw bolts from below). In this way, operational safety can also be further optimized.

According to one embodiment, at least one pressure plate is provided on the crusher housing to form a counter-bearing for the at least one clamping unit, in particular a pressure plate that can be adjusted in terms of thickness / depth by means of compensating elements. This also enables fine adjustment. A force flow path can also be predefined comparatively precisely by means of the pressure plates. Stress peaks or pressure maxima can be flattened or avoided.

According to the invention, the above-mentioned object is also achieved in particular by a gyratory crusher device for crushing crushed material, with a crusher housing in which a crushing axis is arranged, which is received in the crusher housing such that it can wobble about a vertical axis, a cross member being provided to accommodate the crushing axis extends diametrically over the crusher housing and is connected with its traverse ends to the crusher housing, with at least one traverse end being dismantled / braced mechanically on the crusher housing by means of at least one tensioning unit in such a way that the traverse is positively and / or non-positively locked with the crusher housing for the intended purpose Operation of the gyratory crusher device is reversibly connectable, with both ends of the traverse being mechanically braced on the crusher housing so as to be removable by means of at least one tensioning unit, and the traverse in at least two at least approximately ortho gonally aligned spatial directions is clamped, in particular in a plane at least approximately orthogonal to the crusher axis, the respective clamping unit having a wedge which can be positioned relative to a pressure element interacting therewith, for the individual adjustment of a clamping force per clamping unit, the crossbar ends each in a receiving pocket are braced from the inside against the crusher housing. This results in a particularly large number of the aforementioned advantages.

According to the invention, the aforementioned object is also achieved, in particular, by a method for connecting a crossbeam to a crusher housing Gyroscopic crusher, in particular in a previously described gyratory crusher device, for crushing crushed material, in which a crushing axis is arranged, which is received in the crusher housing in a tumbling motion about a vertical axis, the crossbeam being provided for receiving the crushing axis, and the crossbeam extending diametrically over the crusher housing extends and is connected with its traverse ends with the crusher housing, the traverse being mechanically braced by means of at least one tensioning unit acting or arranged on at least one traverse end in such a way that the crossbeam is positively and / or non-positively locked with the crusher housing for the intended operation the gyratory crusher device is reversibly connected. This results in the aforementioned advantages.

According to one embodiment, the traverse is braced in the crusher housing at both traverse ends, in particular by means of at least one clamping unit with a wedge structure. In this way, a largely symmetrical, equally effective introduction of force on both sides on opposite sides of the housing can also be ensured.

According to one embodiment, the connection of the traverse to the crusher housing is established by at least the following steps: inserting the traverse into the crusher housing, in particular into at least one receiving pocket;

-Tensioning of at least one end of the traverse in the crusher housing, in particular in at least one spatial direction in each case in the at least one receiving pocket, in particular by means of at least one individual clamping unit in each spatial direction;

-Optionally, additionally: Securing, in particular screwing the crossbeam in the braced operating position. This also significantly simplifies (dis) assembly.

According to one embodiment, the bracing takes place by translational displacement of an inclined plane or a wedge, in particular individually for each spatial direction. In this way, the clamping force can also be precisely adjusted. According to one embodiment, the clamping force is built up both in the circumferential direction and in the radial direction (longitudinal direction of the cross member), in particular sequentially one after the other up to a respectively predefined minimum or maximum clamping force. This also enables tension-free insertion or assembly and, subsequently, a very controlled clamping according to predefined threshold values.

According to one embodiment, the traverse is additionally screwed by means of screw bolts via at least one end of the traverse for connection to the crusher housing. This also provides additional operational reliability.

According to the invention, the aforementioned object is also achieved in particular by using at least one clamping unit for the removable, reversible assembly of a traverse on a crusher housing of a gyratory crusher and for bracing at least one end of the traverse on the crusher housing in such a way that the traverse is positively and / or non-positively connected to the crusher housing for the intended operation of the gyratory crusher device is reversibly connected, in particular in a gyratory crusher device described above, in particular in a method described above. This results in the aforementioned advantages.

FIGURE DESCRIPTION

Further features and advantages of the invention emerge from the description of at least one exemplary embodiment on the basis of drawings and from the drawings themselves

Fig. 1 is a sectional side view of a truss attachment in a

Prior art gyro crusher;

Fig. 2 in a side view of a clamping unit for use in a

Gyroscopic crusher device according to an embodiment; 3, 4 each in a perspective side view a gyratory crusher device according to an embodiment.

DETAILED DESCRIPTION OF THE FIGURES

In the case of reference symbols that are not explicitly described with reference to an individual figure, reference is made to the other figures.

For the sake of easier understanding, the figures are first described together with reference to all reference symbols. Details or special features shown in the respective figures are described individually.

A gyratory crusher 1 has a crusher housing 10 with a crushing axis 11 and can be rotated about a vertical axis (z). A traverse 13 is fastened with traverse ends 14 in receiving pockets 17 by means of screw bolts 21 on the crusher housing 10. The rolling bush 22 defines the movement tolerance.

A gyratory crusher device 100 has traverse guides 101, pressure plates 102 and compensation elements 103.

1 illustrates in particular the adhesive or cohesive fastening of the traverse 13 by means of epoxy compound 23.

2 shows a mechanical clamping unit 30 which can be used for the clamping connection according to the invention. A spindle 31 acts in a translatory manner on a wedge 32 which is supported by a pressure element 34 and on a base plate 33.

Fig. 3 shows the traverse 13 in an aligned arrangement above the receiving pockets 17, in each of which four clamping units 30 are arranged, namely in pairs in the diametrical direction (traverse longitudinal direction), and each laterally individually in an opposite position orthogonal to the traverse longitudinal direction (two-dimensional bracing in the horizontal Spatial plane, or in a plane at least approximately orthogonal to the crusher axis). This arrangement makes it possible, on the one hand, to achieve a tensioning effect on every available flank or surface (good wedging effect in several spatial directions), and on the other hand, enables it in pairs Arrangement of the tensioning units on the front side of the cross member also means that each tensioning unit can be subjected to at least approximately the same torque or the same tensioning force, which also facilitates assembly and minimizes the risk of incorrect operation.

4 shows, in a further perspective, the pressure plates 102 arranged in the pockets 17 with compensating elements 103 on which the clamping elements 30 can each be supported. The pressure plates 102 are set up and designed to receive and transmit the tension forces in at least one spatial direction into the housing, preferably in at least two spatial directions.

List of reference symbols:

I Rotary crusher 10 crusher housing

I I refractive axis

12 vertical axis (z)

13 traverse

14 end of the traverse 17 holding pocket

21 screw bolts

22 roller bushing

23 epoxy compound

30 mechanical clamping unit

31 spindle

32 wedge

33 base plate

34 pressure element

100 gyratory crusher device

101 Traverse guide

102 pressure plate

103 Compensation element x longitudinal direction y transverse direction z vertical direction

Claims

Expectations

1. Rotary crusher device (100) for the crushing of crushed material, with a crusher housing (10) in which a crushing axis (11) is arranged, which is received in the crusher housing in a tumbling motion about a vertical axis (12), with a cross member (13 ) is provided, which extends diametrically over the crusher housing and is connected with its traverse ends (14) to the crusher housing, characterized in that at least one traverse end (14) can be dismantled mechanically on the crusher housing by means of at least one clamping unit (30) in such a way that the Traverse (13) can be reversibly connected to the crusher housing for the intended operation of the gyratory crusher device in a form-fitting and / or force-fitting manner without material connection.

2. The gyratory crusher device according to claim 1, wherein both ends of the traverse (14) are each mechanically clamped on the crusher housing by means of at least one clamping unit (30) so that they can be removed; and / or wherein the traverse is braced at least in one spatial direction, preferably in at least two at least approximately orthogonally aligned spatial directions, in particular in a plane at least approximately orthogonal to the crusher axis (11).

3. Rotary crusher device according to claim 1 or 2, wherein at least two, three or four clamping units (30) are provided, in particular for each crossbeam end (14), in particular in at least one receiving pocket (17) for receiving the respective crossbeam end on the crusher housing; and / or wherein at least four clamping units are provided for each end of the crossbar, which are aligned in pairs in one of two spatial directions and are each arranged individually or in pairs in the operative position with a corresponding pressure plate (102).

4. Gyroscopic crusher device according to one of the preceding claims, wherein the at least one clamping unit (30) has a wedge (32) which can be positioned relative to a pressure element (34) interacting therewith, for setting a clamping force, in particular by means of a spindle (31); and / or a / the wedge (32) of at least one tensioning unit (30) defines an inclined plane which runs at an angle in the range from 1 to 25 °, in particular 2 to 20 °, relative to a base plate (33) of the tensioning unit.

5. Rotary crusher device according to one of the preceding claims, wherein the at least one clamping unit (30) has a / the base plate (33) which is attached to the crusher housing (10), in particular by means of at least one screw connection; and / or wherein the traverse (13) is braced from the inside against the crusher housing in at least one receiving pocket (17).

6. Rotary crusher device according to one of the preceding claims, wherein the clamping effect of at least one clamping unit (30) of the gyratory crusher device is oriented in the circumferential direction and / or in the radial direction, in particular orthogonally and / or parallel to the longitudinal direction of the traverse.

7. Rotary crusher device according to one of the preceding claims, wherein at least one traverse guide (101) is configured on the crusher housing, in particular two traverse guides for both traverse ends, in particular one traverse guide aligned in the vertical direction (z); and / or wherein a plurality of form-fitting contours are designed corresponding to the crusher housing on the traverse (13) such that the traverse can be mounted along these contours in the vertical direction (z) into the crusher housing or on the crusher housing (10).

8. Gyroscopic crusher device according to one of the preceding claims, wherein screw bolts are provided with which the traverse ends are screwed into (the) receiving pockets (17) of the crusher housing, in particular from below.

9. Rotary crusher device according to one of the preceding claims, wherein at least one pressure plate (102) is provided on the crusher housing (10) to form a counter bearing for the at least one clamping unit (30), in particular a pressure plate adjustable in depth by means of compensating elements (103).

10. A method for connecting a traverse (13) to a crusher housing (10) of a gyratory crusher (1; 100), in particular in the case of a gyratory crusher device (100) according to any one of the preceding claims, for comminuting crushed material, wherein a crushing axis (11) in the crusher housing is arranged, which is received tumbling about a vertical axis in the crusher housing, wherein the traverse is provided for receiving the crushing axis, and wherein the traverse extends diametrically over the crusher housing and is connected with its traverse ends (14) to the crusher housing, characterized in that the Traverse by means of at least one tensioning unit (30) acting or arranged on at least one traverse end (14) is clamped mechanically in such a way that the traverse (13) is positively and / or non-positively connected to the crusher housing (10) for the intended operation of the The gyratory crusher is reversibly connected.

11. The method according to the preceding method claim, wherein the cross member is clamped at both cross member ends (14) in the crusher housing, in particular by means of at least one clamping unit (30) with a wedge structure.

12. The method according to any one of the preceding method claims, wherein the connection of the traverse (13) to the crusher housing (10) is established by at least the following steps:

-Insertion of the crossbeam in the crusher housing, in particular in at least one receiving pocket (17);

- Tensioning at least one end of the cross member (14) in the crusher housing, in particular in at least one spatial direction in each of the at least one receiving pocket (17), in particular by means of at least one individual tensioning unit (30) for each spatial direction;

-Optionally, additionally: Secure, in particular screwing, the crossbeam (13) in the clamped operating position.

13. The method according to any one of the preceding method claims, wherein the bracing takes place by translatory displacement of an inclined plane or a wedge (32), in particular individually for each spatial direction.

14. The method according to any one of the preceding method claims, wherein the clamping force is built up both in the circumferential direction and in the radial direction, in particular sequentially one after the other up to a respectively predefined minimum or maximum clamping force.

15. The method according to any one of the preceding method claims, wherein the crossbeam (13) is additionally screwed by means of screw bolts via at least one crossbeam end (14) for connection to the crusher housing (10).

16. Use of at least one tensioning unit (30) for the removable, reversible assembly of a traverse (13) on a crusher housing (10) of a gyratory crusher (1; 100) and for bracing at least one end of the traverse (14) on the crusher housing (10) in such a way that the traverse positively and / or non-positively connected to the crusher housing for the intended operation of the gyratory crusher, in particular in a gyratory crusher device (100) according to one of the preceding device claims, in particular in a method according to one of the preceding method claims.