DE20007849U1 - Radial-axial roller bearings - Google Patents

Description

INA Rolling Bearings Schaeffler oHG, Industriestrasse 1 - 3, 91074 Herzogenaurach

ANR 91 50 099

3629-11-EN

Radial-axial rolling bearings Area of application of the innovation

The innovation relates to a rolling bearing arrangement for absorbing radial and axial loads, consisting of a radial roller bearing and an axial roller bearing, wherein an inner ring of the radial roller bearing is L-shaped so that its axially extending part forms an inner raceway for the radial roller bearing and its radially extending part forms a raceway for the axial roller bearing.

Background of the innovation

Such a combined rolling bearing arrangement is already known from DE 20 54 112 C2. The radial roller bearing is designed as a full complement and consists of a thin-walled drawn outer ring with inward-facing rims and a solid inner ring. The solid inner ring has a flange on one side that extends into the radially outer area of the radial roller bearing, i.e. it is L-shaped. The end face of the solid inner ring, which is enlarged by this flange, forms one running surface of the axial roller bearing, while the opposite running surface is formed by a thrust washer.

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In this context, it is known that in axial roller bearings the lubricant tends to migrate radially outwards due to centrifugal force. This means that after a certain period of operation the lubricant has accumulated so far radially outwards that the rolling elements of the bearing are no longer sufficiently lubricated. The resulting disadvantages due to the rolling elements running dry are well known to those skilled in the art and therefore do not need to be explained in more detail here.

Summary of the innovation

The aim of the innovation is therefore to improve a bearing arrangement consisting of a combined radial and axial rolling bearing in such a way that dry running of the rolling elements is prevented.

According to the innovation, this object is achieved according to the characterizing part of claim 1 in that the end face of the inner ring of the radial roller bearing facing away from the axial roller bearing has at least one first radially extending through-channel which is connected to a second axially extending through-channel located on the inner circumferential surface of the inner ring.

This innovative measure converts the existing conveying effect of the axial roller bearing on the lubricant into a forced, continuous circulation of the lubricant through the entire combined bearing arrangement. The lubricant moves from a gap between the axial roller bearing and the radial roller bearing, first between the rolling elements of the radial roller bearing, then passes through the two interconnected lubricant channels into the raceway area of the axial roller bearing and from there into the gap connecting the two bearing types.

According to the second claim of the innovation, it is provided that the rolling bearing arrangement in a hydraulic machine, for example in an axial

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piston machine. If, for example, such a machine is operated at very high temperatures, intensive bearing flushing is an absolute requirement for the longest possible service life. In addition to its actual task, i.e. lubricating the rolling elements, the lubricant must also ensure heat dissipation, i.e. cool the bearing at the same time.

The innovation is explained in more detail in the following example.
Short description of the drawings

Show it:

Figure 1 shows an axial section through a bearing according to the invention.

arrangement,

Figure 2 is a side view of the bearing according to Figure 1 and

Figure 3 shows a bearing according to the invention in a connecting construction.

Detailed description of the drawings

The new rolling bearing arrangement shown in Figures 1 and 2 consists of the radial roller bearing 1 and the axial roller bearing 2. The inner ring 3 of the radial roller bearing 1 is L-shaped, i.e. it has the axially extending part 4 and the radially extending part 5. The radial roller bearing 1 also includes the outer ring 6, which has the radially inward-facing rim 16 on one side. The axially extending part 4 of the inner ring 3 is also provided with two rims 17 and 18 spaced apart from one another, so that the full complement cylindrical roller set 7 is guided in the axial direction. The associated raceways are designated 8 and 19. The axial roller bearing 2 belonging to the bearing arrangement has cylindrical rollers guided in the cage 9.

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rollers 10, the associated raceways 12 and 20 of which are formed on the one hand by the end face of the radially extending part 5 of the inner ring 3 and on the other hand by the running disk 11. Both bearings 1 and 2 have the common bearing axis 15.
5

As can be further seen from Figures 1 and 2, the end face of the inner ring 3 facing away from the axial roller bearing 2 is provided with four first through-channels 13 spaced apart from one another in the circumferential direction, which in turn are connected to four second through-channels 14 spaced apart from one another, which extend on the inner circumferential surface of the inner ring 3.

The hollow shaft 21 shown in Figure 3 is housed in the housing 22 with the aid of the bearing unit consisting of the radial roller bearing 1 and the axial roller bearing 2. The bearing arrangement is sealed to the outside by the two seals 23 and 24, with the seal 23 being held directly in the housing 22 and the seal 24 being held via the seal carrier 26. In the manner already described, the inner ring 3 is provided with the two through-channels 13 and 14. Figure 3 also shows that no lubricant can flow in due to the seals 23 and 24 present. If the existing lubricant is now thrown outwards by the axial roller bearing 2, it would run dry if the first and second through-channels 13, 14 were eliminated, since no lubricant can be returned.

As the arrows show, the lubricant flows from the free space 25, which is formed by the two bearings 1, 2 and the housing 22, through the rolling element ring 7 of the radial roller bearing 1, then via the first and second through-channels 13, 14 and via the cylindrical rollers 10 guided in the cage 9 back into the free space 25. In this way, a forced circulation of lubricant is realized, so that the raceways 12, 20 of the axial roller bearing and 8 and 19 of the radial roller bearing 1 are constantly supplied with lubricant.

3629-11-EN

Reference symbols

1 Radial roller bearings 5 2 Axial roller bearings 3 Inner ring 4 axially extending part 5 radial part 6 Outer ring 10 7 Cylindrical roller 8th inner career 9 Cage 10 Cylindrical roller 11 Running disc 15 12 career 13 first passage channel 14 second passage channel 15 Bearing axis 16 Board 20 17 Board 18 Board 19 Outdoor track 20 career 21 Hollow shaft 25 22 Housing 23 poetry 24 poetry 25 free space 26 Seal carrier

Claims (2)

1. Rolling bearing arrangement for absorbing radial and axial loads, consisting of a radial roller bearing ( 1 ) and an axial roller bearing ( 2 ), wherein an inner ring ( 3 ) of the radial roller bearing ( 1 ) is L-shaped, so that its axially extending part ( 4 ) forms an inner raceway ( 8 ) for the radial roller bearing ( 1 ) and its radially extending part ( 5 ) forms a raceway ( 12 ) for the axial roller bearing ( 2 ), characterized in that the end face of the inner ring ( 3 ) of the radial roller bearing ( 1 ) facing away from the axial roller bearing ( 2 ) has at least one first radially extending through-channel ( 13 ) which is connected to a second axially extending through-channel ( 14 ) for lubricant located on the inner circumferential surface of the inner ring ( 3 ). 2. Rolling bearing arrangement according to claim 1, characterized in that it is arranged in a hydraulic machine, for example in an axial piston machine.