DE102009052954A1 - Spherical roller bearing comprises outer ring, inner ring, and number of spherical rollers, which are arranged between outer ring and inner ring - Google Patents

Abstract

The spherical roller bearing (1) comprises an outer ring (2), an inner ring (3), and a number of spherical rollers (4,5), which are arranged between the outer ring and the inner ring. The spherical rollers are held in the circumferential direction in even distances to each other by a retainer (6,7). An annular groove with diagonal boards and a groove depth is formed in a shoulder surface (11) of the inner ring.

Description

Field of the invention

The present invention relates to a spherical roller bearing, with an outer ring, an inner ring and a number between outer ring and inner ring in two rows of juxtaposed pendulum rollers, which are each held by a cage in the circumferential direction at regular intervals to each other, wherein the inside of the outer bearing ring formed as an outer race and the outer side of the inner bearing ring is provided with two inner raceways for the spherical rollers, wherein a loose guide ring is axially disposed between the inner raceways of the inner ring on a shoulder surface of the inner ring, and wherein the guide ring inclined side surfaces, a radially outer end face and a radially inner end face having.

Background of the invention

In double-row spherical roller bearings with split cages, it is necessary to provide axially between the rows of spherical rollers a guide ring or a fixed centerboard, which guide the spherical rollers axially centered and should absorb in particular incident on the spherical rollers lateral axial forces.

A spherical roller bearing with a firmly connected to the inner ring center board is for example from the DE 2 105 242 B known. Such a fixed center board allows optimal guidance of the spherical rollers and their cages. However, such a solution is associated with very high friction and concomitant wear on the flanks of the mid-board.

Examples of spherical roller bearings with floating guide rings are from the DE 197 42 570 A1 and the DE 10 2004 030 964 A1 known. Such floating or loosely mounted guide rings have the advantage that they are subject to only a slight friction, since they can migrate axially by a certain way when an axial force. However, they have the disadvantage that due to the lack of axial fixation of the guide ring no restoring force can act on the spherical rollers. Therefore, such loosely inserted guide rings do not perform the pendulum rollers or insufficient, which is particularly critical in heavily loaded bearings, for example, in spherical roller bearings of wind turbines makes negative noticeable.

Object of the invention

The invention has for its object to provide a spherical roller bearing, which eliminates the disadvantages described and in particular friction is available and allows sufficient guidance of the spherical rollers.

Summary of the invention

The invention is based on the finding that the stated object can be achieved in that the loose guide ring is inserted at least over part of its radial height in an annular groove in the inner ring.

The invention is therefore based on a spherical roller bearing, with an outer ring, an inner ring and a number between the outer ring and inner ring in two rows of juxtaposed pendulum rollers, which are each held by a cage in the circumferential direction at regular intervals to each other, the inside of the outer bearing ring as Outer track trained and the outside of the inner bearing ring is provided with two inner raceways for the spherical rollers, wherein axially between the inner races of the inner ring, a loose guide ring is disposed on a shoulder surface of the inner ring, and in which the guide ring inclined side surfaces, a radially outer end face and a radial having inner end face. In addition, it is provided that in the shoulder surface of the inner ring an annular groove with oblique edges and a groove depth is incorporated, wherein the guide ring is inserted or inserted into at least a portion of its radial height in the annular groove.

By this construction is advantageously achieved that the loose guide ring is exposed as in conventional spherical roller bearings a low friction, but it is not undefined as previously known floating guide rings axially free. The annular groove, in which the guide ring is inserted, offers through its axial edges of the guide ring an abutment so that the guide ring can exert a restoring moment on the spherical rollers.

The inventively embodied spherical roller bearings thus combines the advantages of a floating guide ring with the advantages of a fixed center board. This loose but not floating guide ring allows through its targeted positioning and design, the leadership of the spherical rollers of both rows and thus selectively prevents the tilting and tilting of trained as spherical rollers rolling elements. This leads to a kinematically optimal bearing sequence and consequently lower friction and wear in the rolling contact.

In contrast to a fixed center board, the loose guide ring can rotate and adjusts to a relative speed between roller set and inner ring. These lower speed differences at the contact points cage / guide ring and inner ring / guide ring and rolling element / guide ring lead to less friction and significantly less wear. Another advantage of the construction over the fixed center board is that the lubricating film on the inner ring is not interrupted.

As advantages over only floating arranged guide rings could be determined in practical tests of the invention, a better axial guidance of the spherical rollers with combined load, as well as a better defined position of the rolling elements. It was also possible to determine an advantageous generation of a restoring moment with excessive restriction of the roll. Other benefits include reduced friction, lower bearing temperature, defined Schränkwinkel when entering the load zone, improved management of less loaded roller row, lower cage wear, lower friction torque and better noise performance. As a result, this results in a longer service life of the spherical roller bearing.

In particular, lower relative speeds between the inner ring and the guide ring and between the guide ring and the cages, a significantly lower friction and thus lower bearing temperature, lower wear and lower friction and wear of the guide ring and roller stems have proven to be advantages over the fixed center board. Also it comes now to no interruptions of the lubricating film.

According to an advantageous embodiment of the invention can be provided that an upper groove width of the annular groove is axially larger than a lower groove width, resulting in a longitudinal section, a trapezoidal groove geometry.

In other practical developments can be provided that the width of the guide ring and the groove widths are dimensioned so that a distance between the shoulder surface and the radially inner end face of the guide ring and a distance between the side surfaces of the guide ring and the edges of the annular groove.

Another embodiment of the invention provides that there is a radial distance between the radially outer surface of the guide ring and the side rings of the cages.

Likewise, it is within the scope of the invention to provide that there is a distance between the side surfaces of the guide ring and the axially inner end faces of the spherical rollers.

In a particularly practical embodiment of the invention, it is provided that the distance between the side surfaces of the guide ring and the edges of the annular groove is the same size as the distance between the side surfaces of the guide ring and the axially inner end faces of the spherical rollers.

Further, it is preferably provided that the said distances are filled with a lubricant.

It is also within the scope of the invention to provide that the guide ring is integrally formed. This embodiment can also be supplemented by the fact that the guide ring is slotted axially. Alternatively, it can be provided that the guide ring is formed radially divided.

Other practical embodiments of the invention are characterized in that a groove angle of the annular groove is between 90 ° and 130 °.

Finally, an embodiment of the invention is particularly advantageous, which is characterized in that the height of the guide ring corresponds to twice to six times the groove depth of the annular groove.

Brief description of the drawings

The invention will be explained in more detail below with reference to the accompanying drawings. It shows

1 a half-radial section through an embodiment of a spherical roller bearing according to the invention, and

2 a detail A of the spherical roller bearing according to 1 in an enlarged view.

Detailed description of the drawing

In 1 is an embodiment of a spherical roller bearing according to the invention 1 shown in radial section in half view. The spherical roller bearing 1 serves as a floating bearing of a wind turbine, not shown. The spherical roller bearing 1 has an outer ring 2 and an inner ring 3 on, between which two rows of spherical rollers 4 . 5 are arranged. The pendulum rollers 4 . 5 are each in a cage 6 . 7 held and roll with their peripheral surfaces on one on the inside of the outer ring 2 formed curved outer raceway 8th and on two on the outside of the inner ring 3 molded curved inner raceways 9 . 10 from. On a shoulder surface 11 between the inner raceways 9 . 10 of the inner bearing ring 3 is also a loose leadership ring 12 arranged. Its axial side surfaces 13 . 14 are inclined and form guide surfaces for the spherical rollers 4 . 5 , The radially outer surface 15 of the guide ring 12 serves as a support surface for axially inner side rings 16 . 17 the cages 6 . 7 ,

In a radially outer surface 18 of the outer ring 2 is in the middle a circumferential annular groove 19 let in, which serves as a lubrication groove for lubricant. Through the annular groove 19 is a hole 20 guided by which lubricant for lubrication of the spherical rollers 4 . 5 in the interior of the spherical roller bearing 1 arrives.

In 2 is a Ausrissvergrößerung according to the circle A of 1 shown. In this Ausrissvergrößerung in particular the bearing of the guide ring 12 to recognize. In the shoulder area 11 of the inner bearing ring 3 is an annular groove 21 with radially sloping ribs 22 . 23 let in, so that an upper groove width b1 is greater than a lower groove width b2. A groove depth is indicated by t, a groove angle by α.

The width of the guide ring 12 in the area of the annular groove 21 and the widths b1 and b2 of the annular groove 21 are sized so that the guide ring 12 with play in the ring groove 21 is arranged so that a distance or a game s1 between the shoulder surface 11 of the inner bearing ring 3 and a radially inner end face 24 of the guide ring 12 , as well as a distance or a play s2 between the side surfaces 13 . 14 of the guide ring 12 and the Borden 22 . 23 of the inner bearing ring 3 results.

One through the radially outer end face 15 and through the radially inner end face 24 defined height h of the guide ring 12 is greater than the groove depth t and also greater than the sum of groove depth t and play s1.

In other words, the guide ring is formulated 12 only to a small part of its height h in the annular groove 21 used.

Furthermore, in the installed state, in the best case, there is a radial clearance or a clearance s3 between the radially outer circumferential surface 15 of the guide ring 12 and the side rings 16 . 17 the cages 6 . 7 ,

Also, when installed, there is a clearance or clearance s4 between the side surfaces 13 . 14 of the guide ring 12 and axially inner end faces 25 . 26 the pendulum rollers 4 . 5 , where advantageously the game s4 corresponds to the game s2.

The said distances or games s1, s2, s3, s4 are filled with a lubricant, so that the guide ring 12 during operation of the spherical roller bearing 1 floating on the lubricant, so to speak, whereby friction is largely avoided. Unlike conventional spherical roller bearings, in which the guide ring rests more or less loosely on the shoulder surface of the inner ring, the guide ring 12 through the ring groove 21 and through the shelves 22 . 23 held axially so that the guide ring 12 only limited axial migration can.

The loosely arranged between the two rows of rollers guide ring 12 So it is tuned in width so that it is a targeted game to Rollestirnradius the spherical rollers 4 . 5 having. The contact between the spherical rollers 4 . 5 and the guide ring 12 In case of unfavorable operating conditions as well as the resulting setting and tilting stabilizes the spherical rollers 4 . 5 , In addition, by means of targeted positioning of the guide ring 12 the lightly loaded row of rolling elements is guided inside and outside the load zone. Furthermore, the guide ring supports 12 the cages 6 . 7 over the inner ring 3 as in the previously known arrangements. For this purpose, the groove depth t on the inner ring 3 be exactly matched with the game values s1 and s3. The following conditions apply here:
s1 <s3
(s1 + s3) <t
h> t
h> (t + s1)

The groove width b1 or b2 is with a corresponding axial dimension to the guide ring 12 provided, this allows a targeted, but limited axial board game.

The guide ring 12 can, as in the 1 and 2 is shown, in one piece, but also - which is not shown - be formed in two parts. A radially split guide ring 12 can be installed in two segments or by appropriate joining techniques DIN 8593 then in the spherical roller bearing 1 to be united in a ring.

The one-piece guide ring 12 represents a very good solution in terms of guiding accuracy and concentricity. The one-piece guide ring 12 can be made axially slotted and thus by slight expansion in the annular groove 21 be admitted. Another advantage of this variant is a Verklemmsicherung with excessive expansion of the inner ring 3 during installation.

In practical trials of a spherical roller bearing designed according to the invention 1 the following values have proven to be particularly advantageous: Groove width b2: 0.001 to 0.15 times the width of the inner ring 3 Groove depth t: 0.001 to 0.07 times the bore diameter of the inner ring 3 Groove angle α: 90 ° to 130 ° Game s1: 0 to 0.01 times the bore diameter of the inner ring 3 Game s2: 0 to 0.1 times the length of the spherical rollers 4 . 5 Game s3: 0 to 0.02 times the bore diameter of the inner ring 3 Game s4: 0 to 0.1 times the length of the spherical rollers 4 . 5 Height h: 2 to 6 times the groove depth t

LIST OF REFERENCE NUMBERS

1

Spherical roller bearings

2

outer ring

3

inner ring

4

Spherical roller

5

Spherical roller

6

Cage

7

Cage

8th

Outer race

9

Inner raceway

10

Inner raceway

11

shoulder surface

12

guide ring

13

Side surface of the guide ring

14

side surface

15

radially outer surface

16

Side ring of the cage 6

17

Side ring of the cage 7

18

Radially outer surface of the outer ring 2

19

ring groove

20

drilling

21

Ring groove on the inner ring

22

Board on the inner ring

23

Board on the inner ring

24

Radial inner face of the guide ring 12

25

Front side of the pendulum roller 4

26

Front side of the pendulum roller 5

A

Cutout, circle

b1

Upper groove width

b2

Lower groove width

H

Height of the guide ring 12

s1

game

s2

game

s3

game

s4

game

t

groove depth

α

groove angle

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• DE 2105242 B [0003]
• DE 19742570 A1 [0004]
• DE 102004030964 A1 [0004]

Cited non-patent literature

• DIN 8593 [0036]

Claims (12)

Spherical roller bearings ( 1 ), with an outer ring ( 2 ), an inner ring ( 3 ) and a number between outer ring ( 2 ) and inner ring ( 3 ) in two rows of juxtaposed spherical rollers ( 4 . 5 ), each by a cage ( 6 . 7 ) are held in the circumferential direction at regular intervals to each other, wherein the inside of the outer bearing ring ( 2 ) as an external career ( 8th ) and the outside of the inner bearing ring ( 3 ) with two inner raceways ( 9 . 10 ) for the spherical rollers ( 4 . 5 ), wherein axially between the inner races ( 9 . 10 ) of the inner ring ( 3 ) a loose guide ring ( 12 ) on a shoulder surface ( 11 ) of the inner ring ( 3 ) is arranged, and wherein the guide ring ( 12 ) inclined side surfaces ( 13 . 14 ), a radially outer end face ( 15 ) and a radially inner end face ( 24 ), characterized in that in the shoulder surface ( 11 ) of the inner ring ( 3 ) an annular groove ( 21 ) with sloping ribs ( 22 . 23 ) and a groove depth (t) is incorporated, wherein the guide ring ( 12 ) at least to a part of its radial height (h) in this annular groove ( 21 ) is admitted. Spherical roller bearing according to claim 1, characterized in that an upper groove width (b1) of the annular groove ( 21 ) is greater than a lower groove width (b2) of the annular groove ( 21 ). Spherical roller bearing according to claim 2, characterized in that the width of the guide ring ( 12 ) and the groove widths (b1, b2) are dimensioned so that a distance (s1) between the shoulder surface ( 11 ) and the radially inner end face ( 24 ) of the guide ring ( 12 ) and a distance (s2) between the side surfaces ( 13 . 14 ) of the guide ring ( 12 ) and the Borden ( 22 . 23 ) of the annular groove ( 21 ) consists. Spherical roller bearing according to one of the preceding claims, characterized in that a radial distance (s3) between the radially outer surface ( 15 ) of the guide ring ( 12 ) and side rings ( 16 . 17 ) of the cages ( 6 . 7 ) consists. Spherical roller bearing according to one of the preceding claims, characterized in that a distance (s4) between the side surfaces ( 13 . 14 ) of the guide ring ( 12 ) and axially inner end faces ( 24 . 25 ) of the spherical rollers ( 4 . 5 ) consists. Spherical roller bearing according to claim 5, characterized in that the distance (s2) between the side surfaces ( 13 . 14 ) of the guide ring ( 12 ) and the Borden ( 22 . 23 ) of the annular groove ( 21 ) is the same as the distance (s4) between the side surfaces ( 13 . 14 ) of the guide ring ( 12 ) and axially inner end faces ( 24 . 25 ) of the spherical rollers ( 4 . 5 ). Spherical roller bearing according to one of the preceding claims, characterized in that the distances (s1, s2, s3, s4) are filled with a lubricant. Spherical roller bearing according to one of the preceding claims, characterized in that the guide ring ( 12 ) is formed in one piece. Spherical roller bearing according to claim 8, characterized in that the guide ring ( 12 ) is axially slotted. Spherical roller bearing according to one of claims 1 to 7, characterized in that the guide ring ( 12 ) is formed radially divided. Spherical roller bearing according to one of claims 1 to 10, characterized in that a groove angle (α) of the annular groove ( 21 ) is between 90 ° and 130 °. Spherical roller bearing according to one of claims 1 to 11, characterized in that the height (h) of the guide ring ( 12 ) twice to six times the groove depth (t) of the annular groove ( 21 ) corresponds.

Images