DE102014220823A1 - Roller bearing cage - Google Patents

Abstract

Roller bearing cage (3) with pockets (4) and arranged in the pockets (4) rollers (2), wherein at least one of the pockets (4) perpendicular to the direction of the rollers (2) offset from an adjacent pocket (4) is arranged.

Description

The invention relates to a roller bearing cage with pockets and arranged in the pockets rollers and a roller bearing assembly with a roller bearing having a roller bearing cage.

Background of the invention

Roller bearings are rolling bearings in which the rolling elements are designed as rollers rolling elements. The rollers have substantially cylindrical dimensions and run on substantially cylindrical raceways. The phrase "substantially cylindrical" does not exclude that the rollers and races are crowned or otherwise profiled, which is usually the case.

In ball bearings, however, balls run in circumferentially encircling ball grooves with osculation. With roller bearings can be compared to ball bearings of the same outer dimensions and the same Wälzkörperdurchmesser, bearings with higher load ratings are created because the surface pressure between the rollers and their tracks in line contact is less than the surface pressure between the balls and their raceways. Roller bearings are provided as cylindrical roller bearings, roller sleeves and needle roller bearings in a wide variety of machine and vehicle applications.

As so-called roller sleeves roller bearings are referred to, in which at least the outer ring is a relatively thin-walled sleeve-shaped component. Needle roller bearings are rolling bearings with low radial height, because they have as rolling elements needles and preferably thin-walled bearing rings. Needles are rollers whose length is relatively high relative to their diameter. As needles are usually called rollers whose length is at least two and a half times their diameter. Bearings with needle bearings can be designed for high radial load ratings despite low radial height, because the load capacity, subject to any limits of available axial space and possible deflections of the waves, otherwise almost arbitrarily determined by the length of the needles. In addition, more needles can be arranged on the circumference of the bearing than rollers due to the smaller diameter. As a rule, rollers and needles of roller sleeves and needle bearings roll on the inside directly on the surfaces of shafts, shaft journals, etc., whereby the radial space compared with rotary bearings with inner ring can be further reduced.

Roller sleeves and needle roller bearings have not only higher load ratings compared to ball bearings of the same radial height, but they also differ from them with respect to their axial action. Radial ball bearings can also absorb small axial force components and thus be used as a fixed bearing when the balls rotate in ball grooves. Radial roller sleeves and radial needle bearings can absorb only radial forces and are therefore floating bearing. The floating bearing in this case allows for small axial compensatory movements of the stored elements and the environment against each other.

The aforementioned advantages of roller bearings meant that roller bearings and needle roller bearings in particular as a rotary bearing in vehicle construction, especially in gearbox prevail everywhere where less radial space for the storage of waves, gears and other transmission elements is available, where still rolling bearings with relative high load ratings must be used and where by the (lot) bearing no axial forces must or must be included.

In certain operating conditions arise over long periods between the Wälzlaufbahnen inside and outside relative speeds, that is, the bearing does not rotate and therefore the rollers do not roll over the raceways. However, due to vibration, the rollers may "rock" slightly in place about their axis of rotation. This can, in particular when the bearing is radially loaded, cause the rollers in the load zone to work their line contact with the raceways into the raceway and thus produce small depressions on their surface. This problem is known in the art as so-called "corrugation". At relative speeds of the raceways roll off the rollers and roll over in constant repetition, the wells in succession. This leads to increased wear and premature failure of the bearing. The resulting wear particles can also get into the surrounding structure of the bearing and cause damage there.

As has already been described at the beginning, the roller bearings designed as movable bearings permit small axial movements between the components mounted one on the other or one inside the other. Such compensation can occur, for example, once during assembly to compensate for differences in length due to tolerances. It is also possible that the compensating movement in a direction such. during thermal expansion or contraction when cooling takes place continuously over a longer period. Alternatively, the stored components move relative to each other due to oscillations or alternating deflections of the stored waves with the same or variable frequency in the bearing and with constantly changing axial direction.

The front ends of a roller are usually more heavily loaded than the area between them. In order to avoid overload, the rollers can be made spherical at the ends. Nevertheless, especially when the bearing is radially loaded, friction can cause the rollers located in the load zone of the rotation bearing to create depressions in the surface. As the rolling bearing rotates, the rolling elements repeatedly roll over these irregularities one after the other. This can lead to increased wear and premature failure of the bearing. The resulting wear particles can also get into the surrounding structure of the bearing and cause damage there.

Object of the invention

The object of the invention is to provide means for a roller bearing, with which the disadvantages described above can be avoided. The object is achieved by a roller bearing cage with pockets and rollers arranged in the pockets, which has at least one pocket which is arranged perpendicular to the running direction of the rollers offset from an adjacent pocket.

The object is achieved by a roller bearing cage with pockets and rollers arranged in the pockets, wherein the roller bearing cage is formed as a Axiallagerkäfig and that at least one of the pockets is arranged offset radially to an adjacent pocket. Thus, the centers of the pockets of the roller bearing cage do not all run on the same circular path, but have different radii. This has the consequence that adjacent rolling elements are guided offset in the direction of movement to each other.

If the rollers of a roller bearing of the prior art are subjected to bending in the bearing point when tilted, edge loads on the rolling elements and extreme surface pressures can result. If this affects all roles equally, the roles can become unwanted in the career path. In a roller bearing with a roller bearing cage according to the invention, however, a fatigue of the raceways is reduced or avoided by the track offset of the rollers, because even the tracks with the load peaks are radially offset from one another. The invention is thus particularly suitable for bearings that do not experience a uniform force load, but are applied eccentrically.

According to the invention, provision is made for all or only a subset of the pockets to be offset relative to one another, wherein in the latter case the load is only partially reduced. The fact that the rollers are not arranged exactly one behind the other in the direction of rotation, a high smoothness is also achieved because the support points are distributed uniformly over the surface of the bearing rings.

The pockets may be formed as simple slots and have retaining lugs for the rollers.

In one embodiment of the invention, each roller has its own career. For this purpose, the pockets are arranged offset from each other.

In another embodiment, there are two or more groups of pockets, each having the same radial distance about the axis of rotation, wherein each two adjacent pockets of the roller bearing cage are selected from different groups. Especially with narrow roller bearing cages, it is also envisaged that not every roll unrolls in the direction of movement on an individual track. The effect of less stress on the track body is also achieved when the rollers of each second, third or fourth pocket roll on the same track and only the balls in the pockets are interposed on other tracks.

The rollers in the roller bearing cage may be formed as cylindrical rollers, barrel rollers or needles.

As a material for the roller bearing cage plate is provided, in which the pockets can be punched, for example. Alternatively, the roller bearing cage may be made of plastic, for example.

An embodiment of the invention provides that the roller bearing is sealed on one side or on both sides by means of one or more sliding or non-contact seals. The seal is preferably located in or on a bearing ring of the rotary bearing. A preferred embodiment of the roller bearing is formed from a first bearing ring, rollers and the cage. The second raceway is preferably formed in the bearing directly on the surface of a second bearing ring.

The invention is particularly suitable for applications in which the rolling body is predetermined solely by the cage.

Brief description of the drawings

The invention will be described below with reference to figures of an embodiment. Show it:

1 a perspective view of a roller bearing cage according to the invention with rollers in the formation of a Axialnadelkranzes,

2 a view of the Axialnadelkranz after 1 and

3 a view of the roller bearing cage of the axial needle ring after 1 ,

Detailed description of the drawings

1 shows an axial needle ring 1 with roles 2 and a roller bearing cage 3 , Axially offset to the rollers 2 is an unillustrated bearing ring with an outer raceway 4 arranged for storage of a component, not shown. The roller bearing cage 3 is movably received in the circumferential direction and has pockets 4 each for receiving a roll 2 on.

In the circumferential direction are the roles 2 in the respective bag 4 with those for roller bearing cages 3 usual tight games rotatable relative to the roller bearing cage 3 kept freely movable.

The respective bag 4 of the roller bearing cage 3 extends lengthwise groove-shaped so that the rollers can be in contact with two axially adjacent bearing rings in the direction of movement.

Several of the bags 4 are circumferentially about the axis of rotation 6 arranged adjacent to each other and aligned in the radial direction. The roller bearing cage 3 is, subject to a minor assembly and tolerance-related game or a movement clearance for the circumferential rotational freedom of the roller bearing cage 3 axially held relative to the bearing ring against an axial support almost immovable. The roles 2 are not guided in grooves of the raceways, but run on substantially internally and externally cylindrical Wälzlaufbahnen.

How out 3 can be seen, are in the illustrated embodiment, three groups of bags 4 formed, wherein the pockets within a group the same distance from the edges of the roller bearing cage 3 but differ in groups. A first bag 4 ' is thus radially in the most obvious inside, a second bag 4 '' offset to the first radially outward and a third pocket 4 ''' even further offset radially outward. The circumferentially arranged behind each other three pockets 4 ' . 4 '' and 4 ''' repeat themselves periodically.

LIST OF REFERENCE NUMBERS

1

 needle roller thrust bearing

2

 roll

3

 Roller bearing cage

4

 bag

5

6

 axis of rotation

Claims (7)

Roller bearing cage ( 3 ) with pockets ( 4 ) and in the pockets ( 4 ) arranged rollers ( 2 ), characterized in that at least one of the pockets ( 4 ) perpendicular to the running direction of the rollers ( 2 ) offset to an adjacent pocket ( 4 ) is arranged. A roller bearing cage according to claim 1, characterized in that the roller bearing cage ( 3 ) is formed as an axial bearing cage and that at least one of the pockets ( 4 ) offset radially to an adjacent pocket ( 4 ) is arranged. Roller bearing cage according to claim 2, characterized in that each pocket ( 4 ) offset to their circumferentially adjacent pockets ( 4 ) is arranged. Roller bearing cage according to claim 3, characterized in that all pockets ( 4 ) form two, three or four pocket groups with different radial pocket centers. Roller bearing cage according to one of the preceding claims, characterized in that the rollers ( 2 ) are designed as cylinders, barrel rolls or needles. Roller bearing cage according to one of the preceding claims, characterized in that the roller bearing cage ( 3 ) is formed as a stamped part made of sheet metal, plastic or brass. Roller bearing assembly with a roller bearing having a roller bearing cage ( 3 ) according to one of the preceding claims, characterized in that the roller bearing is loaded eccentrically.

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