DE102010023356A1 - Lifting mechanism for large-diameter bearing, has bearing outer ring and bearing inner ring and multiple rolling bodies, where bearing outer ring is designed axially split and has two individual rings - Google Patents

Abstract

The lifting mechanism (1) has a bearing outer ring (4) and a bearing inner ring (5) and multiple rolling bodies (6). The bearing outer ring is designed axially split and has two individual rings (7,8). Two retainers (20) are evenly dispersed over the periphery of the large-diameter bearing (2). Each retainer has an L-shaped cross-section with an axial long side-piece (21) and a short side-piece (22).

Description

Field of the invention

The invention relates to a lifting device for a slewing bearing, for example, with a pitch circle diameter greater than 500 mm, the slewing bearing consisting of a bearing outer ring and a bearing inner ring and a number of arranged between the bearing rings rolling elements, wherein at least the bearing outer ring is formed axially divided and has two individual rings.

Background of the invention

Rolling bearings are usually referred to as slewing bearings whose outside diameter exceeds about 500 mm. Slewing bearings used in wind turbines to rotatably support the rotor shaft with respect to a housing, may have an outer diameter of, for example, 3000 mm. It is true that with increasing bearing pitch circle more rolling elements can be used, so that the bearing capacity increases. The problem with such a large rolling bearing so far its transport to the installation as well as the mounting of a particular designed as a tapered roller bearing slewing bearing with at least split outer ring. Due to the design of such large rolling bearings can fall apart, since the divided outer rings are not or only insufficiently secured axially.

From the DE 10 2006 008 731 A1 and the DE 10 2008 046 623 A1 already generic slewing bearings are known in which it has been proposed to connect the outer rings consisting of individual rings axially with each other, so that can let such slewing bearings handle better.

From the field of roller bearings, in particular the tapered roller bearings, transport and lifting devices in the form of clamps are already known, which can be better handled especially tapered roller bearings, such as from the DE 10 2006 061 378 B3 , of the DE 295 18 508 U1 , as well as the US 3,696,490 A , However, such solutions are only suitable for roller bearings with small diameters. Already due to the high weight of the large roller bearings in question such clamps are out of the question.

The problem with the assembly preparation of slewing bearings is in particular the need to arrange protective films between the individual rings of the outer ring and the rolling elements at least during the transport of slewing bearings to their mounting location. These protective films are used to protect the slewing bearings before so-called False Brinelling, ie a degeneration of the raceways by high Hertzian pressure of the rolling elements on the raceways due to the large rolling bearing recurrently acting changing loads that inevitably arise during transport of the large rolling bearing and quickly to lubricating film displacement between the Runners and the rolling elements can lead. In order to remove the protective films, the split bearing outer ring must be moved axially relative to the bearing inner ring. So far, these steps have been implemented in large rolling bearings using mounting holes in the bearing inner ring. Due to the occurrence of hardening cracks on the bearing inner rings large tapered roller bearings, these holes are disadvantageous.

Object of the invention

Against this background, the invention has for its object to present a lifting device for a slewing bearing, which does not have the disadvantages described. In particular, a lifting device should be designed with which the split outer ring can be easily moved relative to the bearing inner ring.

Summary of the invention

The invention is based on the finding that the stated object can be achieved in that at least two L-shaped bracket are releasably connected to the radially outer surface of the outer ring, wherein a leg of the bracket abuts against an axially outer end face of a single ring of the bearing outer ring.

The invention is therefore based on a lifting device for a slewing bearing, for example, with a pitch circle diameter greater than 500 mm, wherein the slewing bearing consists of a bearing outer ring and a bearing inner ring and a number of arranged between the bearing rings rolling elements, and in which formed at least the bearing outer ring axially divided is and has two individual rings. In the lifting device is provided that it consists of at least two evenly distributed over the circumference of the slewing bearing brackets, each bracket each having an L-shaped cross-section, with an axial long leg and angled radially inwardly from the long leg short leg, the long leg with a radially inner surface rests on radially outer surfaces of the individual rings of the bearing outer ring and is detachably connected to the bearing outer ring, and wherein the short leg at least partially surrounds an axially outer end face of a single ring of the bearing outer ring.

By this structure, the end user of a slewing bearing an assembly aid offered, with which the entire storage package can be transported, prepared for assembly and assembled in one piece. On a sequential assembly can now be dispensed with. Also on axial fixing elements of the individual bearing components can be dispensed with by the invention. In a surprisingly simple way so sink the manufacturing costs and installation costs for a generic rolling bearing.

With the lifting device according to the invention for slewing bearings, the preparation of the bearing on the assembly and the actual bearing assembly on a shaft is significantly facilitated. The end user receives a completely assembled bearing package and only has to remove the False Brinelling protective film between the roller ring and the outer ring raceways before mounting the bearing. For this purpose, the device is particularly easy to use. After removal of the protective films, the bearing pack can be lifted with an additional device, which represents a particularly advantageous embodiment of the invention, and pushed onto the shaft. The bearing components are securely held together axially. Thus, tapered roller bearings with plastic segment cage can be mounted, which would otherwise fall out of the upper roller ring in a sequential assembly.

On mounting holes in the bearing inner ring can now be dispensed with, so that the risk of cracking in the bore area is effectively prevented. For handling the bearings, the brackets according to the invention are used instead of the mounting holes, which embrace only the outer bearing ring, or the entire bearing package. With these brackets, the assembly preparation and the actual bearing assembly can be performed without the risk of cracks in the bearing inner rings.

In addition, it can be provided that each bracket a second L-shaped auxiliary bracket is applied, the auxiliary bracket is releasably secured with a long leg on the long leg of the associated bracket, and wherein a right angle from the long leg of the auxiliary bracket radially inwardly angled short leg at an axially outer End face of the bearing inner ring is present.

According to another practical development can be provided that the individual rings of the bearing outer ring axially in each case on the radially outer edge region of their lateral surfaces have a stepped shoulder on which rests an intermediate ring with a rim astride, wherein the intermediate ring is connected to the individual rings of the bearing outer ring, and wherein a radially outer circumferential surface of the intermediate ring is aligned with the radially outer lateral surfaces of the individual rings of the bearing outer ring.

This embodiment can be supplemented by the fact that the bracket is detachably connected to the intermediate ring.

Further, it can be provided that the long leg of the bracket has at least one radial bore, wherein a screw bolt is guided through at least one bore of the long leg of the bracket, which is screwed into a threaded bore in the intermediate ring.

According to another embodiment of the invention it is provided that the bearing inner ring is formed axially divided and consists of two individual rings. The individual rings of the bearing inner ring can be connected to each other by an intermediate ring.

Although at least two brackets are to be provided for the mounting of the slewing bearing, preferably three to five brackets are used. In addition, it can be provided that a crane hook is screwed into an axially outer end face of the bracket. The lifting device according to the invention is suitable for example for the mounting of a slewing bearing, which is designed as a fixed bearing of a rotor main bearing of a wind turbine.

Brief description of the drawings

The invention will be explained in more detail below with reference to the accompanying drawings. Therein, the single FIGURE shows a radial sectional view through an embodiment of a lifting device for a slewing bearing according to the invention in half view.

Detailed description of the drawing

The single figure shows a lifting device 1 for a double row slewing bearing 2 with a pitch circle diameter greater than 500 mm in radial section in half view. This is the slewing bearing 2 shown rotated in an assembly or transport position by 90 ° against the installation position. Accordingly, the slewing bearing extends 2 on the drawing sheet in the axial direction from bottom to top, and the receiving bore for shaft to be stored can be found in the right half of the drawing in the area of the unshaded inner circumferential surfaces of the bearing inner rings.

The large rotor bearing serving as the main rotor bearing of a wind turbine 2 is as a tapered roller bearing 3 formed in an X-arrangement and consists essentially of a bearing outer ring 4 and a bearing inner ring 5 as well as a number of between the bearing rings 4 and 5 in two rows next to each other on their careers rolling rolling elements 6 in the form of tapered rollers.

The bearing outer ring 4 is split axially and has two individual rings 7 . 8th on. The bearing inner ring 5 tapered roller bearing 3 is also divided axially and consists of two single rings 9 . 10 ,

The single rings 7 . 8th of the bearing outer ring 4 each have axially inwardly on the radially outer edge region of their lateral surfaces 11 . 12 a step-shaped heel 13 respectively. 14 on which an intermediate ring 15 with a border 16 astride. The intermediate ring 15 is in a manner not shown with the individual rings 7 . 8th of the bearing outer ring 4 connected. A radially outer surface 17 of the intermediate ring 15 is aligned with the radially outer lateral surfaces 11 . 12 the single rings 7 . 8th of the bearing outer ring 4 , The intermediate ring 15 serves for a given distance between the individual rings in a specific application 7 . 8th ensure and, where appropriate, the individual rings 7 . 8th of the bearing outer ring 4 to bias against each other. Therefore, the intermediate ring 15 in the embodiment, a part of the bearing outer ring 4 ,

The single rings 9 . 10 of the bearing inner ring 5 are also by an intermediate ring 18 connected with each other. For connecting the individual rings 9 . 10 with the intermediate ring 18 is a plurality of bolts 19 provided, which in the individual rings 9 . 10 and in the intermediate ring 18 are screwed in. The intermediate rings 15 . 18 fix the individual rings 7 . 8th respectively. 9 . 10 axially to each other.

Before the slewing bearing 2 can be mounted on a shaft, it is necessary, not shown protective films between the rolling elements 6 and the raceways of the individual rings 7 . 8th of the bearing outer ring 4 to remove. These protective films are used to protect the slewing bearings before so-called false brinelling, ie a degeneration of the raceways by high Hertzian pressure of the rolling elements 6 on the raceways due to the slewing bearing 2 recurring changing loads during transport of the slewing bearing 2 arise and quickly for lubricating film displacement between the raceways and the rolling elements 6 being able to lead. To remove the protective films, the bearing outer ring must 4 opposite the bearing inner ring 5 be moved axially. For this purpose, the lifting device is used 1 also.

The lifting device 1 consists of at least two over the circumference of the large roller bearing 2 evenly distributed ironing 20 of which in the figure only a hanger 20 is shown. The coat hanger 20 has an L-shaped cross section and has an axial long leg 21 and a long-legged front 21 radially inwardly angled short leg 22 ,

The thigh 21 is with a radially inner surface 23 against the lateral surfaces 11 . 12 . 17 the single rings 7 . 8th and the intermediate ring 15 of the bearing outer ring 4 directed and lies on these lateral surfaces 11 . 12 . 17 on. The short leg 22 partially matured an axially outer face 24 of the single ring 7 ,

For fixing the bracket 20 at the bearing outer ring 4 is at least one hole 25 radially inward through the bracket 20 guided. Through the hole 25 is a bolt 26 guided, which in a threaded hole 27 in the intermediate ring 15 is screwed. Depending on the width of the strap 20 can have multiple holes 25 be provided so that the hanger 20 with a corresponding number of bolts 26 at the bearing outer ring 4 attach.

To the temple 20 Lift and thus the bearing outer ring 4 To move axially, is a crane hook 28 in an axially outer end face 29 of the temple 20 screwed. By means of a crane hook 28 attached crane rope 30 can the lifting device 1 be raised, resulting in an axial displacement of the bearing outer ring 4 opposite the bearing inner ring 5 leads. Although this displacement is only a few millimeters, this is usually sufficient enough to grab the protective films and out of the slewing bearing 2 to be able to remove.

If necessary, the lifting device 1 also be used to the slewing bearings 2 raise altogether, for example, to the slewing bearings 2 to mount on a shaft. This is to each of the inserted bracket 20 a second L-shaped auxiliary bar 31 created. The auxiliary bracket 31 is with his long thigh 32 by means of bolts 33 to the temple 20 screwed. A right angle from the long thigh 32 radially inwardly angled short leg 34 lies on an axially outer end face 35 of the single ring 9 of the bearing inner ring 5 at. A lifting of the lifting device 1 causes a lifting of the slewing bearing 2 overall, since the outer ring 4 on the short leg 22 of the temple 20 and the bearing inner ring 5 on the short leg 34 of the auxiliary bracket 31 rests so that when lifting the lifting device 1 the bearing outer ring 4 and the bearing inner ring 5 can not move relative to each other. An additional axial fixation of the bearing components can thus be dispensed with.

In deviation from the illustrated embodiment, it is also possible more than two hanger 20 to use. The ideal number is a number of three ironing 20 pointed out, however, it is also within the scope of the invention, four, five or even more hanger 20 to use.

The invention is not limited to slewing bearings with split bearing outer rings and split bearing inner rings, which are axially spaced from each other by intermediate rings. It is also possible to use the lifting device according to the invention also for slewing bearings with at least split outer ring, in which no intermediate ring between the individual rings of the bearing outer ring is used. In this case, the hanger would 20 to the lateral surfaces 11 . 12 the single rings 7 . 8th of the bearing outer ring 4 releasably secured, for example, be screwed.

LIST OF REFERENCE NUMBERS

1

hoist

2

slewing bearings

3

Tapered roller bearings

4

Bearing outer ring

5

Bearing inner ring

6

rolling elements

7

single ring

8th

single ring

9

single ring

10

single ring

11

lateral surface

12

lateral surface

13

paragraph

14

paragraph

15

intermediate ring

16

edge

17

lateral surface

18

intermediate ring

19

bolts

20

hanger

21

long legs

22

Kurzschenkel

23

area

24

front

25

drilling

26

bolts

27

threaded hole

28

crane hook

29

front

30

crane rope

31

auxiliary clip

32

long legs

33

bolts

34

Kurzschenkel

35

front

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 102006008731 A1 [0003]
• DE 102008046623 A1 [0003]
• DE 102006061378 B3 [0004]
• DE 29518508 U1 [0004]
• US 3696490 A [0004]

Claims (10)

Lifting device ( 1 ) for a slewing bearing ( 2 ), the slewing bearing ( 2 ) consisting of a bearing outer ring ( 4 ) and a bearing inner ring ( 5 ) and a number of between the bearing rings ( 4 . 5 ) arranged rolling elements ( 6 ), wherein at least the bearing outer ring ( 4 ) is formed axially divided and two individual rings ( 7 . 8th ), characterized in that the lifting device ( 1 ) of at least two over the circumference of the large rolling bearing ( 2 ) evenly distributed ironing ( 20 ), each bracket ( 20 ) each having an L-shaped cross section, with an axial long leg ( 21 ) and one of the long thigh ( 21 ) radially inwardly angled short leg ( 22 ), whereby the long leg ( 21 ) with a radially inner surface ( 23 ) on radially outer lateral surfaces ( 11 . 12 ) of the individual rings ( 7 . 8th ) of the bearing outer ring ( 4 ) rests and releasably connected to the bearing outer ring ( 4 ) and the short leg ( 22 ) at least partially an axially outer end face ( 24 ) of a single ring ( 7 ) of the bearing outer ring ( 4 ) surrounds. Lifting device according to claim 1, characterized in that on each bracket ( 20 ) a second L-shaped auxiliary bow ( 31 ), whereby the auxiliary bow ( 31 ) with his long thigh ( 32 ) on the thigh ( 21 ) of the bracket ( 20 ) is releasably attached, and being at right angles to the long leg ( 32 ) of the auxiliary bracket ( 31 ) radially inwardly angled short leg ( 34 ) on an axially outer end face ( 35 ) of the bearing inner ring ( 5 ) is present. Lifting device according to claim 1 or 2, characterized in that the individual rings ( 7 . 8th ) of the bearing outer ring ( 4 ) each axially inwardly on the radially outer edge region of their lateral surfaces ( 11 . 12 ) a stepped shoulder ( 13 . 14 ), on which an intermediate ring ( 15 ) with a border ( 16 ) rests astride, wherein the intermediate ring ( 15 ) with the individual rings ( 7 . 8th ) of the bearing outer ring ( 4 ), and wherein a radially outer surface ( 17 ) of the intermediate ring ( 15 ) with the radially outer lateral surfaces ( 11 . 12 ) of the individual rings ( 7 . 8th ) of the bearing outer ring ( 4 ) flees. Lifting device according to claim 3, characterized in that the bracket ( 20 ) detachable with the intermediate ring ( 15 ) connected is. Lifting device according to claim 4, characterized in that the long leg ( 21 ) of the bracket ( 20 ) at least one radial bore ( 25 ), wherein through the at least one bore ( 25 ) of the long leg ( 21 ) of the bracket ( 20 ) a bolt ( 26 ), which in a threaded hole ( 27 ) in the intermediate ring ( 15 ) is screwed. Lifting device according to one of the preceding claims, characterized in that the bearing inner ring ( 5 ) is formed axially divided and consists of two individual rings ( 9 . 10 ) consists. Lifting device according to claim 6, characterized in that the individual rings ( 9 . 10 ) of the bearing inner ring ( 5 ) by an intermediate ring ( 18 ) are interconnected. Lifting device according to one of the preceding claims, characterized in that the number of brackets ( 20 ) is between three and five. Lifting device according to one of the preceding claims, characterized in that in an axially outer end face ( 29 ) of the bracket ( 20 ) a crane hook ( 28 ) is screwed. Lifting device according to one of the preceding claims 2 to 9, characterized in that the large rolling bearing ( 2 ) is a fixed bearing of a rotor main bearing a wind turbine.

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