DE19932804A1 - Shaft bearing system comprises two reduced friction bearings connected by clamping component which passes through longitudinal bore in shaft - Google Patents

Abstract

The shaft bearing system comprises first (20) and second (30) reduced friction bearings which can rotate in seatings (12, 29). The bearings are connected by a clamping component (50) which passes through a longitudinal bore (40) in the shaft (10).

Description

The present invention relates to an arrangement for supporting a shaft which a first and a second roller bearing rotatably on a first and a second Bearing seat is stored.

For example, for storing shafts in a gearbox or motor Use of tapered roller bearings is common. These are assembled in pairs and require axial preload. The housing of the gearbox is therefore vertical divided to the shaft axis, with a bearing seat of the shaft to be supported in each housing part is provided. The two parts of the housing during assembly assembled and screwed against each other, so the tapered roller bearings with the required axial preload.

In order to set the exact size of the preload, before installing the Housing adjusting washers inserted between the housing and the tapered roller bearing. To do this the length of the shaft and the depth of the housing parts are measured by the to be able to determine the required thickness of the adjusting washers. This attitude of Bearing is extremely complex and prone to failure. If the setting is incorrect, it may be too Bearing and gear damage come.

In addition, the use of magnesium as the housing material due to the greatly different coefficients of thermal expansion of steel and magnesium Bearing preload is very temperature-dependent. This leads to the low Warm creep resistance of magnesium to a decrease in bearing preload during the service life of the gearbox.

Setting and checking the preload is also made more difficult if several shafts must be stored in one gear or motor.  

DE 41 33 649 describes a method for adjusting the bearing friction torque Helical roller support for the bearing of wheel axles. A wheel hub is in constant rotary movement offset, the drive torque measured and the bearing in Dependence on the measured value set. However, this method does not come for waves of gearboxes or motors. This procedure also only applies to the Determination of the correct preload, but does not offer any help for its generation.

DE 41 35 565 describes a bearing arrangement with the aid of which the rolling resistance of a Angular contact ball bearings should be varied. For this, two are arranged on a shaft Rolling bearing via a screw nut screwed onto the shaft under the desired preload set. However, this version has the disadvantage that the Screw nut is difficult to access when assembled.

The problem of the present invention is therefore the development of the known generic state of the art, so that a precise and easy adjustment of the Preload is possible.

This problem is solved with the features of claim 1. A separate one Clamping element allows separate adjustment of the shaft assembly Roller bearing. The implementation of the clamping element through the shaft allows one simple and space-saving connection of the braced against each other Roller bearing. In addition, an automatic change in the preload by loosening counteracted by screw connections, since the clamping element does not with the shaft co-rotates.

The preload can be taken into account without taking into account the exact axial position of the Simply adjust the rolling bearing and the length of the shaft if at least one of the Rolling bearing axially displaceable relative to its bearing seat and / or to the shaft and the Bearing preload by changing the distance between the two Rolling bearings is adjustable. Additional unwanted voltages due to imprecise Positioning are avoided.

The axial position of the shaft can be easily and clearly defined if one of the Rolling bearing is clamped against one of the bearing seats via the clamping element.  

If the clamping element is a screw bolt, this enables easy adjustment the preload with common tools and a control of the preload z. B. about Torque wrench. There are also both compressive and tensile forces above the bolt applicable.

If the arrangement is surrounded by a housing, it is appropriate that the Clamping element runs through an opening provided in the housing in order to Allow adjustability. This facilitates a subsequent adjustment and one separate handling of several shafts.

In the case of a transmission with several shafts, it is advantageous if at least one of the shafts is stored via an arrangement according to the invention. This allows several Optimally adjust the shafts independently and the assembly of the gearbox facilitate.

The invention is then further described using an exemplary embodiment, the following explanations are only to be regarded as examples.

Fig. 1 shows a transmission having a housing 2. The housing 2 has two housing walls 4 and 6 that are spaced apart from one another. A first shaft 10 is mounted between them. Its longitudinal axis is perpendicular to the housing walls 4 and 6 .

For supporting the shaft 10 on the housing wall 4 is a cylindrical recess provided in the housing wall 4 12th This recess 12 serves as the first bearing seat of the shaft 10 and receives a first roller bearing 20 .

The roller bearing 20 has an axially outer bearing ring 22 with respect to the shaft 10 . "Axially outside" is used hereinafter to mean "along the longitudinal axis of the shaft and away from the section of the shaft located between the two bearings". "Axially inside" is used in the following meaning "directed in the direction of the shaft longitudinal axis on the section of the shaft located between the two bearings".

The bearing ring 22 abuts the housing 4 . A multiplicity of rolling elements 24 are arranged on its inside around the circumference of the bearing ring 22 . An axially inner bearing ring 28 is provided to fix them radially inwards. The bearing ring 28 is seated on one end of the shaft 10 in a rotationally fixed manner. It is supported axially inwards on a shaft shoulder 13 .

To mount the shaft 10 on the housing wall 6 , a cylindrical recess 29 is provided in the housing wall 6 at the opposite end of the shaft 10 . The depression 29 serves as the second bearing seat of the shaft 10 . It receives an axially outer bearing ring 32 of a second roller bearing 30 . This is closed like a lid on its side facing the housing wall 6 .

The bearing ring 32 is axially displaceably received in the recess 29 and spaced apart from the housing wall 6 . A multiplicity of rolling elements 24 'are arranged on its inside around its circumference. An axially inner bearing ring 35 is provided to fix them radially inwards. The bearing ring 35 is seated on the second end of the shaft 10 in a rotationally fixed manner. It is supported axially inwards on a shaft shoulder 15 .

Between its two ends, the shaft 10 carries gears 17 or other devices required to perform its function.

A clamping element in the form of a bolt 50 is provided to generate the bearing preload. This extends through a longitudinal bore 40 which extends concentrically to the longitudinal axis of the shaft 10 and protrudes at both ends thereof.

At one end, the bolt 50 penetrates the housing 2 at a bore 42 in the housing wall 4 that is aligned with the longitudinal bore 40 . At its end piece protruding from the housing 2 , a nut or screw head 52 is provided, which is seated on the housing wall 4 .

Its opposite end penetrates a bore 44 in the axially outer bearing ring 32 that is aligned with the longitudinal bore 40 of the shaft 10 . At this end, the bolt 50 has an external thread which is screwed to an internal thread of the bore 44 .

The transmission has a second shaft 10 ', which corresponds to the structure of its mounting of the shaft 10 . However, instead of the cover-like bearing ring 32, an annular bearing ring 32 'is provided, which is covered with a cover 51 of approximately the same outside diameter. Both together have the same shape as the bearing ring 32 . This division allows the use of standard rolling bearings. The cover 51 can be inexpensively manufactured as a cold extrusion.

The gearbox can be completely assembled during its manufacture and the housing 2 can be closed. To set the preload of the roller bearings 20 , 30 of the first shaft 10 , the bolt 50 is acted on its nut head 52 with a fixed torque or angle of rotation. As a result, the bearing ring 32 of the roller bearing 30 screwed to the bolt 50 is drawn onto the housing wall 4 . He presses on the rolling elements 24 'of the rolling bearing 30 . These transmit the contact pressure to the axially inner bearing ring 35 and the shaft shoulder 15 . Since the roller bearing 30 is axially displaceably received in the recess 29 , the shaft 10 is pressed axially in the direction of the housing wall 4 . As a result, the shaft shoulder 13 presses onto the axially inner bearing ring 28 of the roller bearing 20 . The rolling elements 24 pass the pressure on to the axially outer bearing ring 22 , which is pressed against the housing wall 4 .

On the one hand, this causes the shaft 10 to be axially fixed to the housing wall 4 . On the other hand, a defined, temperature-independent preload of the two roller bearings 20 , 30 is guaranteed.

The setting of the second shaft 10 'is carried out analogously.

In the present example, the rolling elements 24 , 24 'have a conical shape. However, they can also be round or cylindrical.

The tensioning element could also be formed by a wire rope instead of a bolt.

The clamping element could also attack the inside of the rolling bearings and axially push outwards.

Instead of displaceability of the bearing relative to its bearing seat, one could also Movability relative to the shaft to be supported can be provided.  

REFERENCE SIGN LIST

2nd

casing

4th

Housing wall

6

Housing wall

10th

first wave

10th

'second wave

12th

deepening

13

Wave shoulder

15

Wave shoulder

20th

roller bearing

22

Bearing ring

24th

,

24th

Rolling elements

28

Bearing ring

29

deepening

30th

roller bearing

32

,

32

'' Bearing ring

35

Bearing ring

40

Longitudinal bore

42

drilling

44

drilling

50

First shaft bolt

50

'' Second shaft bolt

51

cover

52

Nut or screw head

Claims (6)

1. Arrangement for mounting a shaft ( 10 , 10 ') which is rotatably mounted on a first and a second bearing seat ( 12 , 29 ) via a first and a second roller bearing ( 20 , 30 ), characterized in that the two roller bearings ( 20 , 30 ) are biased against each other by means of a tensioning element ( 50 ) running axially through a longitudinal bore ( 40 ) of the shaft ( 10 , 10 '). 2. Arrangement according to claim 1, characterized in that at least one of the rolling bearings ( 20 , 30 ) relative to its bearing seat ( 12 , 29 ) and / or to the shaft ( 10 , 10 ') is axially displaceable and the preload of the rolling bearings ( 20 , 30 ) can be adjusted by changing the distance between the two roller bearings ( 20 , 30 ). 3. Arrangement according to one of the preceding claims, characterized in that one of the rolling bearings ( 20 , 30 ) via the clamping element ( 50 ) against one of the bearing seats ( 12 , 29 ) is clamped. 4. Arrangement according to one of the preceding claims, characterized in that the clamping element ( 50 ) is a screw bolt. 5. Arrangement according to one of the preceding claims, characterized in that the arrangement is surrounded by a housing ( 2 ) and the clamping element ( 50 ) through an opening in the housing ( 2 ) provided opening ( 42 ) to adjust the bias from the outside to enable. 6. Transmission with several shafts ( 10 , 10 '), characterized in that at least one of the shafts ( 10 , 10 ') is mounted on an arrangement according to one of the preceding claims.