DE102019112815A1 - Rolling bearing cage - Google Patents

Abstract

A roller bearing cage comprises two side rings (2, 3) which are connected to one another by webs (6) to form roller body pockets (4), with recesses (9, 10) on the side rings (2, 3) each having a flow cross-section for lubricant According to the invention, the recesses (9, 10) are located exclusively in peripheral areas between the webs (6).

Description

Field of invention

The invention relates to a roller bearing cage according to the preamble of claim 1, which is particularly suitable for use in a roller or needle bearing.

Background of the invention

Such a rolling bearing cage is for example from DE 10 2013 226 132 A1 known. The cage has side rings connected to one another by webs, with recesses being located on the outer circumferential surface of each side ring, which are intended to enable a flow of lubricant. The recesses are arranged in a straight extension of the webs. In order to enable the closest possible assembly with rolling elements, the webs of the rolling bearing cage are after DE 10 2013 226 132 A1 arranged on a different diameter than a pitch circle diameter of the roller bearing. The circumferential sections of the side rings lying in the circumferential direction between the recesses are designed as guide surfaces. A planetary gear bearing is mentioned as a possible field of application of the known rolling bearing cage.

A roller bearing cage suitable for a ball bearing with structures for receiving and conveying lubricant is for example in the DE 10 2015 223 510 A1 described. In this case, lubricant pockets are formed on the inside of webs.

An Indian DE 10 2018 115 766 A1 The rolling bearing cage disclosed has a base body with an internal lubricant channel. Thanks to the internal lubricant channel, the flow of lubricant can be metered in a targeted and economical manner.

An Indian DE 10 2008 049 036 A1 The rolling bearing cage described has a lubricating groove which is connected to rolling element pockets via bores.

Object of the invention

The invention is based on the object of specifying a rolling bearing cage which has been further developed in terms of lubrication aspects compared to the prior art mentioned and which is particularly suitable for use in a planetary gear bearing or in a connecting rod bearing.

Description of the invention

This object is achieved according to the invention by a rolling bearing cage with the features of claim 1. The rolling bearing cage comprises two side rings in a basic concept known per se, which are connected to one another by webs to form rolling element pockets, with recesses on the side rings each representing a flow cross section for lubricant , are arranged, in particular in a uniform distribution around the circumference of the side ring. According to the invention, the recesses are located exclusively in peripheral areas between the webs.

Due to the arrangement of the recesses in circumferential sections which lie between the webs, the transition areas between the webs and the side rings are in no way weakened. At the same time, there is an efficient supply of lubricant to the rolling contacts. The number of recesses that are incorporated in a side ring does not necessarily match the number of webs. It is thus possible to provide recesses either between two adjacent webs or only on a part of the circumferential sections lying between two webs.

The recesses, which are also generally referred to as grooves, have, for example, a concavely curved cross-sectional shape or a polygonal shape. Overall, the roller bearing cage is preferably a steel cage. Alternatively, the cage can be made of plastic, in particular fiber-reinforced plastic.

According to one possible geometric configuration, the recesses are located on the outer circumferential surface of each side ring. In this case, the recesses are also referred to as axial grooves. The depth of each recess to be measured in the radial direction of the roller bearing cage must be less than the thickness of the side ring to be measured in the same direction, i.e. the side ring height. The number of axial grooves per side ring can correspond to the number of webs or be less than this number.

According to one possible embodiment, the expansion of each axial groove in the circumferential direction of the side ring is at most 15% less than the expansion of the adjacent rolling element pocket in the corresponding direction. This means that the largest part of the side ring section delimiting a rolling element pocket is weakened by the axial groove, with the result that a correspondingly large flow cross section is released for lubricant. The depth of each axial groove to be measured in the radial direction of the side ring preferably corresponds to a maximum of 35% of the extent of the axial groove to be measured in the circumferential direction of the side ring.

An alternative geometric design provides recesses on the end faces of both side rings. In this case the recesses are referred to as radial grooves. Comparable to the axial grooves, the radial grooves can also be designed, for example, curved or polygonal. In the case of radial grooves, the depth of the grooves to be measured in the axial direction must be less than the width of the side ring to be measured in the same direction. Analogous to the distribution of the axial grooves on the circumference of the side rings, the number of radial grooves can either match the number of webs and the roller body pockets and be below the number of webs. For example - viewed in the circumferential direction of the roller bearing cage - a recess in the form of a radial groove is incorporated into the side ring only after every second or third web.

The extension of each end-face recess, that is to say radial groove, in the circumferential direction of the side ring preferably corresponds to a maximum of 60% of the extension of the adjacent roller body pocket in the same direction.

The maximum depth to be measured in the axial direction of the side ring of each end-face recess preferably corresponds to at least 10% of the extent of the same radial groove to be measured in the circumferential direction of the side ring.

According to an advantageous further development, there are recesses both on the outer circumferential surface of each side ring and on its end face, the different recesses extending over the same circumferential section of the side ring. This means that each radial groove merges into an axial groove and thus forms a constriction of the side ring. As a result of this constriction, the cross section of the side ring is preferably not weakened by more than 40% compared to circumferential sections without recesses.

The roller bearing cage is particularly suitable for connecting rod bearings in internal combustion engines and for planetary gear bearings in gearboxes. In general, the rolling bearing cage is suitable for bearings that are designed for highly dynamic operating conditions. The lubricant to be distributed with the aid of the roller bearing cage can be in the form of oil, oil mist or a two-stroke mixture, for example.

Figure list

The rolling bearing cage designed according to the invention is explained in more detail below in three preferred embodiments with reference to the accompanying drawings. Show:

• 1 a first embodiment of a roller bearing cage in perspective view,
• 2 a second embodiment of a roller bearing cage in perspective view,
• 3 a third embodiment of a roller bearing cage in a perspective view,
• 4th a detail of the roller bearing cage 3 as well as associated surrounding components in a simplified sectional view.

Detailed description of the drawings

Unless otherwise stated, the following explanations relate to all exemplary embodiments. Parts or contours that correspond to one another or have the same effect are identified in all figures with the same reference symbols.

A roller bearing cage 1 is designed for use in a needle or roller bearing and has two side rings 2 , 3 on that with the formation of rolling element pockets 4th for rolling elements 5 through bars 6th are connected to each other. When the rolling bearing cage is installed 1 roll the rolling elements 5 , i.e. needles or rollers, between bearing parts 7th , 8th from. In the exemplary embodiments, the roller bearing cage is 1 made of steel.

Every side ring 2 , 3 is in all embodiments by recesses 9 , 10 weakened, which have a concave curved shape and free flow cross-sections for lubricant.

In the design according to 1 are as recesses 9 Radial grooves on the face of the side rings 2 , 3 available. In the circumferential direction of the side ring 2 , 3 considered, there is every radial groove 9 in the middle between two bars 6th . In the circumferential direction of the side ring 2 , 3 is the radial groove 9 less extended than the adjacent rolling element pocket 4th . The depth of the radial groove to be measured in the axial direction 9 corresponds to more than 10% but less than 30% of that in the circumferential direction of the side ring 2 , 3 Dimension of the radial groove to be measured 9 .

In the design according to 2 are recesses 10 exclusively on the outer circumferential surfaces of the side rings 2 , 3 available. In this case the recesses are 10 designed as axial grooves. In contrast to the radial grooves 9 as they do with the rolling bearing cage 1 after 1 are present, each axial groove extends 10 over most of the circumferential direction of the rolling bearing cage 1 Expansion of a rolling element pocket to be measured 4th . Only in the transition areas between the webs and the side rings 2 , 3 are the side rings 2 , 3 not through axial grooves 10 weakened. The extent to be measured in the circumferential direction of the Axial groove 10 corresponds to at least 85% of the expansion of the rolling element pocket to be measured in the same direction 4th . The one in the radial direction of the roller bearing cage 1 depth to be measured of each axial groove 10 corresponds to less than half of the side ring height of the side ring to be measured in the same direction 2 , 3 . At the same time, the mentioned depth corresponds to the axial groove 10 maximum 35% of that in the circumferential direction of the side ring 2 , 3 Axial groove expansion to be measured 10 .

The roller bearing cage 1 after 3 and 4th has both radial grooves 9 as well as axial grooves 10 on. In this case there is a radial groove 9 and an axial groove 10 in the same peripheral section of the side ring 2 , 3 so that one of the number of webs 6th corresponding number of constrictions 11 in the side ring 2 , 3 is formed. The direct connection of one axial groove each 10 to a radial groove 9 enables the rolling bearing designated as a whole by 12, which the rolling bearing cage 1 comprises a diversion of radially flowing lubricant in the axial direction, which means a supply of lubricant to the rolling contacts between the rolling elements 5 and the stock parts 7th , 8th favored. In the arrangement according to 4th it concerns the warehouse parts 7th , 8th around a crankshaft 7th and a connecting rod 8th .

List of reference symbols

1

Rolling bearing cage

2

Side ring

3

Side ring

4th

Rolling element pocket

5

Rolling elements

6

web

7th

Bearing part, crankshaft

8th

Bearing part, connecting rod

9

Recess, radial groove

10

Recess, axial groove

11

Constriction

12

roller bearing

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102013226132 A1 [0002]
• DE 102015223510 A1 [0003]
• DE 102018115766 A1 [0004]
• DE 102008049036 A1 [0005]

Claims (9)

Rolling bearing cage, with two side rings (2, 3) which are connected to one another by webs (6) to form rolling element pockets (4), with recesses (9, 10) on the side rings (2, 3) each having a flow cross-section for lubricant represent, are arranged, characterized in that the recesses (9, 10) are located exclusively in peripheral areas between the webs (6). Roller bearing cage Claim 1 , characterized in that there are recesses (9) on the outer peripheral surface of each side ring (2, 3). Roller bearing cage Claim 2 , characterized in that the extension of each recess (9) in the circumferential direction of the side ring (2, 3) is at most 15% less than the extension of the adjacent rolling element pocket (4) in the corresponding direction. Roller bearing cage Claim 3 , characterized in that the depth of each recess (9) to be measured in the radial direction of the side ring (2, 3) corresponds to a maximum of 35% of the extent of the recess (9) to be measured in the circumferential direction of the side ring (2, 3). Roller bearing cage Claim 1 or 2 , characterized in that there are recesses (10) on the end faces of both side rings (2, 3). Roller bearing cage Claim 5 , characterized in that the extent of each end-face recess (10) in the circumferential direction of the side ring (2, 3) corresponds to a maximum of 60% of the extent of the adjacent rolling element pocket (4) in the same direction. Roller bearing cage Claim 5 or 6th , characterized in that the maximum depth to be measured in the axial direction of the side ring (2, 3) of each end-face recess (9) corresponds to at least 10% of the extent of the same recess (9) to be measured in the circumferential direction of the side ring (2, 3). Roller bearing cage Claim 2 and 5 , characterized in that there are recesses (9, 10) both on the outer circumferential surface of each side ring (2, 3) and on its end face, the different recesses (9, 10) being located over the same circumferential section of the side ring (2, 3) ) extend. Roller bearing cage Claim 8 , characterized in that the cross section of the side ring (2, 3) by the recesses (9, 10) is not weakened by more than 40%.

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