DE20005227U1 - Bearing arrangement - Google Patents

Description

SKF GmbH Schweinfurt, 16.03.2000

DE 00 008 DE STP-go.se

Description

Bearing arrangement

The invention relates to a bearing arrangement, in particular for a printing machine, consisting of at least one inner ring, one outer ring and a plurality of rolling elements arranged between the inner ring and the outer ring,

wherein the outer ring has a lateral mounting flange with which it can be fixed to a housing,

wherein the outer ring is adapted to the diameter of the bore of the housing over a first axial extent,

wherein the outer ring is reduced over its remaining axial extent compared to the diameter of the bore of the housing and

wherein in the region of the first axial extension a centering element is arranged in a groove which is machined into the outer circumference of the outer ring.

In the case of bearing arrangements for printing machines, it has proven difficult to insert the bearing elements precisely into the respective holes in the printing machine housing. Due to the required accuracy, extensive

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Staggering of different bearing diameter variants (staggered in the micrometer range) is required, which requires a high level of assembly and adjustment effort, especially when changing a bearing.

For this reason, solutions of the type described above have become known. Here, the bearing forces are absorbed essentially via a lateral fastening flange that is attached to the outer ring. To center the bearing in the housing bore, only a centering section that extends over a defined axial extent is used. To further simplify centering, a groove can be machined into the outer circumference of the outer ring, in which a centering element is attached. This enables the assembly process of the bearing in the housing bore to be further simplified.

It has been recognized as a disadvantage that, despite the centering element being located in the groove in the outer circumference of the outer ring, difficulties can occasionally arise during assembly because the centering element located in the groove becomes jammed.

The invention is therefore based on the object of further developing a bearing arrangement of the type mentioned at the beginning in such a way that the assembly process can be further simplified. In particular, it should be ensured that the centering element cannot become jammed even under unfavorable conditions, which should always ensure that the bearing can be easily installed in the bore. ^!

The solution to this problem by the invention is characterized in that the centering element is a glued-in band made of deformable material with an abrasion-resistant surface or that the centering element is an injected ring made of abrasion-resistant thermoplastic or thermosetting material.

The design according to the invention ensures that the centering element cannot move out of the groove even under unfavorable assembly conditions, but is always held in the place where it is needed. Tilting of the centering element is thus impossible. The assembly process is thus made considerably easier. This is of particular importance when replacing bearing units on site, where working conditions are sometimes less than optimal.

According to the further development, it is provided that the first axial extension is smaller than the remaining axial extension. In particular, it is intended that the first axial extension is smaller than 50%, preferably smaller than 25%, of the sum of the first axial extension and the remaining axial extension.

The first axial extension is preferably arranged so that it is adjacent to the fastening flange. The adaptation of the outer ring to the diameter of the bore of the housing along the first axial extension is advantageously achieved by a clearance fit.

In a particularly preferred embodiment, the outer ring, two inner rings and the rolling elements form a double-row tapered roller bearing.

In the case where the inventive concept is implemented with the glued-in strip of deformable material, it is advantageously provided that a layer of adhesive is arranged between the centering element and the groove side wall and/or the groove base; the thickness of this layer preferably amounts to at most 10% of the groove depth.

The glued-in band can be made of non-ferrous metal or plastic.

Finally, it can be provided that the glued-in band is a tolerance ring, i.e. a slotted ring made of thin sheet metal with many evenly spaced

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It allows relatively large clearances to be bridged and enables simple and economical assembly.

The drawing shows an embodiment of the invention. The figure shows a section through the bearing unit of a printing press.

The bearing consists of two inner rings 1 and 2, the outer ring 3 and rolling elements 4 arranged between them. In this case, it is a double-row tapered roller bearing in an O arrangement, with the outer ring 3 being formed in one piece and interacting with the two inner rings 1 and 2. The bearing must be installed in the housing 6 to transmit the bearing forces. The forces are transmitted via the fastening flange 5 arranged on the side of the outer ring 3. This is attached to the housing with a number of screws.

The bore 7 of the housing 6 has a constant diameter. However, it is provided that the counterpart - i.e. the outer ring 3 of the bearing - does not have a constant diameter over its entire axial extent (as far as this extends into the housing bore 7): Rather, the diameter of the outer ring only corresponds to the housing bore 7 over a first axial extent Li. However, over the remaining axial extent L ₂ the outer diameter of the outer ring is set back so that there is no contact with the housing bore 7, i.e. the outer diameter of the outer ring 3 over the extent L ₁ essentially corresponds to the bore diameter D _B , but is reduced compared to this over the remaining extent L ₂ .

To simplify assembly and to achieve exact centering of the outer ring 3 to the housing bore 7, a centering element 8 is located in the area of the first axial extension Li in a groove 9 which is introduced over the circumference of the outer ring.

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To ensure that the centering element 8 always functions correctly in the groove 9 even under the most difficult installation conditions, the centering element is designed as a glued-in strip made of deformable material with an abrasion-resistant surface. The centering element 8 is preferably glued to the groove side wall 10 or to the groove base using a conventional adhesive (e.g. Loctite).

This prevents the centering element 8, which is made of non-ferrous metal, for example, from springing up during the assembly process, which could otherwise lead to the centering element becoming jammed during assembly.

The same effect can be achieved by injecting a ring made of abrasion-resistant thermoplastic or thermosetting material into the groove 9. In this case, the cavity of an injection mold is closed around the groove 9 on the outer circumference of the outer ring 3 in such a way that the groove is filled with thermoplastic or thermosetting material and extends slightly beyond the outer diameter of the outer ring 3 in the area of the first axial extension Li. When the outer ring 3 is later pushed into the housing bore 7, the element 9 produces the desired centering function and ensures that the bearing can be mounted in the housing bore without jamming.

A tolerance ring can also be used as a glued-in band, and this is well known in the art. With this slotted ring made of thin sheet metal, in which longitudinal beads are evenly distributed around the circumference, there is basically the same risk as with an inserted band that the ring will spring back and become jammed during assembly. This is prevented by the tolerance ring being glued in in the same way.

SKF GmbH Schweinfurt, 16.03.2000

DE 00 008 DE STP-go.se

List of reference symbols Inner rings 1.2 Outer ring 3 Rolling elements 4 Mounting flange 5 Housing 6 Drilling of the housing 7 Centering element 8th Groove 9 Groove side wall 10

Db Bore diameter of the housing
Li first axial extension
L ₂ remaining axial extension

Claims (12)

1. Bearing arrangement, in particular for a printing machine, comprising at least one inner ring ( 1 , 2 ), one outer ring ( 3 ) and a plurality of rolling elements ( 4 ) arranged between the inner ring ( 1 , 2 ) and the outer ring ( 3 ),
wherein the outer ring ( 3 ) has a lateral fastening flange ( 5 ) with which it can be fixed to a housing ( 6 ),
wherein the outer ring ( 3 ) is adapted to the diameter (D _B ) of the bore ( 7 ) of the housing ( 6 ) over a first axial extension (L ₁ ),
wherein the outer ring ( 3 ) is reduced over its remaining axial extent (L ₂ ) compared to the diameter (D _B ) of the bore ( 7 ) of the housing ( 6 ) and
wherein in the region of the first axial extension (L ₁ ) a centering element ( 8 ) is arranged in a groove ( 9 ) which is machined into the outer circumference of the outer ring ( 3 ),
characterized in that
the centering element ( 8 ) is a glued-in strip made of deformable material with an abrasion-resistant surface. 2. Bearing arrangement, in particular for a printing machine, comprising at least one inner ring ( 1 , 2 ), one outer ring ( 3 ) and a plurality of rolling elements ( 4 ) arranged between the inner ring ( 1 , 2 ) and the outer ring ( 3 ),
wherein the outer ring ( 3 ) has a lateral fastening flange ( 5 ) with which it can be fixed to a housing ( 6 ),
wherein the outer ring ( 3 ) is adapted to the diameter (D _B ) of the bore ( 7 ) of the housing ( 6 ) over a first axial extension (L ₁ ),
wherein the outer ring ( 3 ) is reduced over its remaining axial extent (L ₂ ) compared to the diameter (D _B ) of the bore ( 7 ) of the housing ( 6 ) and
wherein in the region of the first axial extension (L ₁ ) a centering element ( 8 ) is arranged in a groove ( 9 ) which is machined into the outer circumference of the outer ring ( 3 ),
characterized in that
the centering element ( 8 ) is an injected ring made of abrasion-resistant thermoplastic or thermosetting material. 3. Bearing arrangement according to claim 1 or 2, characterized in that the first axial extension (L ₁ ) is smaller than the remaining axial extension (L ₂ ). 4. Bearing arrangement according to claim 3, characterized in that the first axial extension (L ₁ ) is less than 50%, preferably less than 25%, of the sum of the first axial extension (L ₁ ) and the remaining axial extension (L ₂ ). 5. Bearing arrangement according to one of claims 1 to 4, characterized in that the first longitudinal extension (L ₁ ) adjoins the fastening flange ( 5 ). 6. Bearing arrangement according to one of claims 1 to 5, characterized in that the adaptation of the outer ring ( 3 ) to the diameter (D _B ) of the bore ( 7 ) of the housing ( 6 ) along the first longitudinal extension (L ₁ ) is accomplished by a clearance fit. 7. Bearing arrangement according to one of claims 1 to 6, characterized in that the outer ring ( 3 ), two inner rings ( 1 , 2 ) and the rolling elements ( 4 ) form a double-row tapered roller bearing. 8. Bearing arrangement according to claim 1, characterized in that a layer of adhesive is arranged between the centering element ( 8 ) and the groove side wall ( 10 ) and/or the groove base. 9. Bearing arrangement according to claim 8, characterized in that the layer of adhesive has a thickness which corresponds to at most 10% of the groove depth. 10. Bearing arrangement according to claim 1, characterized in that the glued-in band consists of non-ferrous metal. 11. Bearing arrangement according to claim 1, characterized in that the glued-in band consists of plastic. 12. Bearing arrangement according to claim 1, characterized in that the glued-in band is a tolerance ring.