DE102015219563A1 - Bolt cage for a rolling bearing - Google Patents

Abstract

The invention relates to a pin cage for a rolling bearing with a first cage side disc (1), with a second cage side disc (2), with a plurality of bores (3, 4) in the cage side discs (1, 2) attached, the two cage side discs (1 , 2) connecting and holding at a predeterminable distance cage pin (5, 10), and with a plurality of guided by means of the bolt cage Wälzkörperrollen, wherein the cage pin (5, 10) by means of at least at one end of the cage pin (5, 10) engaging locking pins (14) are attached to at least one cage side disc (1, 2). The invention has for its object to provide alternatives to the known Schraubverbindungskonzepten that do not require welding for bolt safety and no attachment of holes during assembly of the pin cage, and therefore avoid the associated disadvantages and a simple, independent assembly of items with reduced expenditure of time enable. This problem is solved in that the securing pins (14) are arranged in securing bores (12) extending tangentially to the bores (3, 4) for the cage bolts (5, 10) in the cage side discs (1, 2) and engage with the cage bolts ( 5, 10) interact positively and / or non-positively.

Description

The invention relates to a pin cage for a rolling bearing with a first cage side disc, with a second cage side disc, with a plurality of fastened in holes in the cage side discs, connecting the two cage side discs and holding at a predeterminable distance cage pin, and guided by a plurality of means of the pin cage Wälzkörperrollen, wherein the cage bolts are secured by at least one end of the cage bolt engaging locking pins on at least one cage side plate.

Such a pin cage for a rolling bearing is in the DE 1 722 510 U1 disclosed. The cage bolts are screwed into one of the cage side windows. When the cage pins are tightened in one cage side disc, the second cage side disc, which is provided with corresponding holes, is slid over the free ends of the cage pins. Thereafter, this cage side plate and arranged in their holes free ends of the cage bolts are radially pierced, after which dowel pins are driven into the radial holes thus produced, which fix the cage pin on this second cage side plate and secure against loosening of the cage pin in the threaded holes of this cage side disc.

A disadvantage of this pin cage, in particular, when it comes to a roller bearing cage with pierced, guided on the cage pin rollers that the production of the holes for the dowel pins can be done after assembly of the roller bearing cage and the assembly of the rollers on the cage pin so that the chips generated during drilling can get into the holes of the rollers in the gap between the rollers and the cage bolt, which can lead to damage to the rolling bearings and affects the life of such roller bearings.

Such pin cages are mainly used in large bearings in the form of cylindrical roller bearings, tapered roller bearings or spherical roller bearings, which are used in rolling mills or in wind turbines. The rollers of these bearings may be pierced with the cage pins forming the axes for the rollers, or the rollers may be disposed between the cage pins and guided at their peripheral surfaces by the cage pins. Both embodiments are in the DE 198 45 747 C2 shown and described. In the embodiments according to the local 1 to 4 . 8th to 11 such as 13 and 14 the rollers are pierced, and the cage bolts form their axes. According to the 5 and 6 the rollers are guided between the cage bolts. Almost all embodiments show with a threaded end in one of the cage side plates screwed cage pin, which are fastened with a second, opposite threaded end by means of a nut on a second cage side plate. Subsequently, the nut is secured by means of a weld on the second cage.

Such a pin cage is very expensive to manufacture and assemble large bearings. Since such a pin cage must be welded directly to the bearing during final assembly, there is a risk of polluting or even pre-damaging the rolling bearing by means of welding slag or welding beads. Furthermore, a distortion of the side windows can be adjusted by the welding process and the associated heat input. Also, due to the heat input by the welding method, the hardness of the surface hardened bolt may be lowered by a starting effect, resulting in increased pin wear in the peripheral area in a near-side zone.

Due to the welding work also results in a long installation time for equipped with pin cages large bearings, which includes the welding and the cleaning work after the welding process.

Against this background, the invention has the object to provide an alternative to the known and mentioned Schraubenverbindungskonzepten, which requires no welding for cage bolt securing and no attachment of holes in the assembled bearings and which avoids the associated disadvantages and a simple, independent assembly of items reduced time required.

This object is achieved by a pin cage with the features of claim 1. Advantageous further developments are defined in the subclaims.

The invention relates to a pin cage for a rolling bearing with a first cage side disc, with a second cage side disc, with a plurality of fixed in bores in the cage side discs, connecting the two cage side discs and holding at a predeterminable distance cage pin, and a plurality by rolling elements guided by means of the pin cage, wherein the cage bolts are fastened to at least one cage side disk by means of securing pins acting on at least one end of the cage bolts.

In this pin cage is provided according to the invention that the locking pins in tangential to the holes for the cage bolts in the cage side windows extending securing holes are arranged and cooperate with the cage pin form and / or non-positively.

The tangential to the holes for the cage bolts in the cage side discs extending locking holes for receiving the locking pins can be in the cage side windows together with the holes for the cage bolts produce before mounting the pin cage, so that the chips produced during mounting of the holes can be easily removed and The cage side windows can be easily assembled with the cage bolts and possibly with the rollers pushed onto the cage bolts.

The cage side windows can be detachably connected in this way by means of the cage bolts, wherein it is both possible to fix the cage bolts in both cage side discs by means of the locking pins, as well as to provide the cage bolts at one of its ends with a thread extending into corresponding threaded holes in screw the first side windows, while only the opposite ends of the cage bolts are positively and / or non-positively connected by means of the locking pins with the second side window.

The holes for the cage bolts and the securing holes for the locking pins are arranged so that they have at least such a distance from each other that between the surfaces of the cage pin and the locking pins at least a frictional engagement is effected. For this purpose, in bolt cages for large bearings, especially in wind turbines, the overlap of the holes for the cage bolts and the securing holes for receiving the locking pins should be 0.2 mm to 1.2 mm.

The securing holes for receiving the locking pins can be made cylindrical, wherein the locking pins can be designed as a cylindrical pins without or with a wedge-shaped depression, or as dowel pins or grooved pins. The locking holes can also be tapered, the locking pins are made as taper pins with the same cone angle.

In order to achieve a positive cooperation between the cage bolt and the locking pins, the cage bolts may at least partially have a puncture that can be designed as a circumferential groove or as a sink or notch, with a relevant overlap of 0.2 mm to 1.2 mm at Rolling bearings for wind turbines refers to the bottom of the circumferential groove or the sink or notch in the cage bolt.

The variant with puncture is more robust compared to the without puncture, but the variant without puncture manufacturing technology is cheaper and easier to implement from tolerance considerations or tolerance adjustment.

Various embodiments of cylindrical pins, dowel pins, grooved pins or taper pins are known in the art as basic knowledge.

The invention will be explained below with reference to an embodiment shown in the accompanying drawings. In this drawing shows

1 a cross section through a bolt cage according to the invention,

2 a radial section through a side window of the pin cage according to 1 showing the attachment of a cage bolt by means of a safety pin,

3 a perspective view of a cage bolt with a recess at an axial end of the bolt in the form of a circumferential groove, and

4 a perspective view of a cage bolt with a recess in the form of a depression at an axial bolt end.

From a bolt cage for a rolling bearing is in 1 a cross section through a first cage side window 1 and a second cage side window 2 shown, with the first cage side window 1 , like out 2 seen, a hole 3 for receiving an axial end of a cage bolt 5 and the second cage side window 2 a hole 4 have in the form of a threaded bore designed as a blind hole. The cage bolt 5 is with its threaded end 7 in the bore formed as a threaded bore 4 in the second cage side window 2 screwed. The extreme end of the cage bolt 5 indicates an exemption phase 9 and a face stop on the front 8th on, by means of which the cage bolt 5 in the trained as a blind hole 4 can be fixed against rotation and positioned. At the opposite axial end of the cage bolt 5 is a groove in the form of a circumferential groove 6 attached in 3 is clearly visible.

The first cage side window 1 is approximately centered and perpendicular to the hole 3 for the cage bolt 5 with safety holes 12 for receiving a respective security pin 14 provided, these backup holes 12 tangential to the puncture 6 in the cage bolt 5 in the form of a circumferential groove and tangential to the bore 3 for the cage bolt 5 in the first cage side window 1 with an overlap of 0.2 mm to 1.2 mm. The securing holes 12 can be designed as a blind hole or, as shown, as through holes. One axial end of the locking holes 12 has a thread 13 in, in each case a grub screw 16 is screwed. The securing holes 12 and the locking pin 14 are cylindrical with a press fit.

The assembly of the pin cage takes place in a cylindrical roller bearing in such a way that the cage bolts 5 with its threaded end 7 into the threaded holes 4 the second cage side window 2 up to the stop of the end stop 8th in the correspondingly formed threaded holes 4 screwed in and braced. Thereafter, pierced rollers on the cage bolts 5 pushed axially, if so provided, and then with a puncture 6 in the form of a circumferential groove provided cage pin 5 in the assigned holes 3 the first cage side window 1 introduced so far that the recesses formed as a circumferential groove 6 in alignment with the securing holes 12 are located. Then the locking pins 14 in the securing holes 12 pressed and jammed with the cage bolts 5 in the formed as a circumferential groove punctures 6 due to the above-mentioned overlap of 0.2 mm to 1.2 mm, depending on the size of the bearing. For securing and positioning the locking pins 14 in the securing holes 12 are threaded pins 16 with hexagon socket 18 in threaded holes 13 at the entrance of the securing holes 12 screwed. These grub screws 16 can in the tapped holes 13 be secured in a known manner by marking or gluing.

In a tapered roller bearing whose mounting is done so that initially the bearing inner ring is placed on a mounting table. Then the larger diameter cage side disc is placed centrally over the inner ring. Subsequently, the conical rolling elements are placed on the raceway of the inner ring. Now, the smaller diameter cage side disc is positioned radially inward on the inner ring. Subsequently, the mounting of the cage bolts 5 by passing these through the holes 3 inserted in the larger diameter cage side disc and into the associated blind holes 4 the smaller diameter cage side disc are screwed in so far, until the end face stop 8th the cage bolt 5 at the bottom of the blind holes 4 comes to the plant and is braced there. Finally, the cage bolts 5 in the larger diameter cage side disc by means of the in the securing holes 12 used locking pins 14 fixed as described. To tighten the cage bolts 5 facilitate in the smaller diameter cage side window, these have at the first free end on a hexagon socket for engagement of a suitable tool.

In 2 is on the security pin 14 a wedge-shaped, axially aligned flattening 15 shown, in particular in conjunction with a cage pin 10 who in 4 is shown, is usable. This threaded bolt 10 has a puncture 11 in the form of a sink into which the locking pin 14 with its wedge-shaped flattening 15 engages and a positive fixation and positioning of the cage pin 10 causes and at the same time a positive rotation for the cage pin 10 against a loosening of the threaded end 7 generated.

Although the cage bolts 5 . 10 according to 3 and 4 only at one end with a puncture 6 in the form of a circumferential groove or a groove 11 provided in the form of a sink and have at the opposite end in each case a thread 7 but it is also possible to have both axial ends of the cage bolts 5 . 10 with punctures 6 . 11 in the form of a circumferential groove or a depression and to provide the cage bolts 5 in both cage side windows 1 . 2 by locking pins 14 to fix. Especially when using a cage bolt 10 with two punctures 11 in the form of sinks can be achieved by precise processing of the punctures 11 and the locking holes 12 in the cage side windows 1 . 2 a precise distance between the two cage side windows 1 . 2 reach each other without the use of spacers during assembly. This also applies to an embodiment of a cage bolt 5 according to 3 with punctures 6 in the form of circumferential grooves at each end of the cage bolt 5 ,

1 shows a dashed elliptical deformation shown 17 of the cage bolt 5 or 10 if these are not punctures 6 . 11 have and the cage bolts 5 . 10 with the second cage side window 2 or with both cage side windows 1 . 2 by means of the locking pins 14 be tightened and fixed. In this case, the overlap between the holes 3 and the securing holes 12 also 0.2 mm to 1.2 mm, depending on the size of the rolling bearing. The surface of the cage bolts 5 . 10 is when driving the locking pins 16 in dashed, as elliptical deformation 17 shown deformed, and thus results in a frictional to form-locking fixation of the cage pin 5 . 10 in the first cage side window 1 and / or in the second cage side window 2 , In this case, there is no clear definition of the distance between the first cage side window 1 and the second cage side window 2 given, so when mounting between the first cage side window 1 and the second cage side window 2 Spacers are to be arranged in sheet metal in a known manner, after driving the locking pins 14 be removed. In this case, touch the locking pins 14 the surfaces of the cage bolts 5 . 10 and deform this plastically, resulting in the elliptical deformation 17 of the cage bolt 5 . 10 results.

The securing holes 12 for receiving the locking pins 14 are preferably so with respect to the holes 3 for the cage bolts 5 . 10 in the first cage side window 1 arranged that the cage bolts 5 . 10 when pressing in the locking pins 14 in the screwing in the threaded holes 4 in the second cage side window 2 be tense and therefore can not relax. In addition, prevent the means of the screws 16 secured locking pins 14 a loosening of the cage bolts 5 in the threaded holes 4 in the second cage side window 2 ,

The illustrated embodiment shows a locking pin 14 in the form of a cylindrical pin, which is a wedge-shaped flattening 15 may have or may be formed as a cylindrical clamping pin or grooved pin. If the locking pin 14 is designed as a taper pin and the associated locking hole 12 is also designed as a tapered bore with the same cone angle, the overlap can be greater, and the contact pairing between the cage bolt 5 and the locking pin 14 is improved.

All the features mentioned in the preceding description of the figures, in the claims and in the introduction to the description can be used both individually and in any combination with one another. The invention is thus not limited to the described and claimed feature combinations, but all feature combinations are to be regarded as disclosed.

LIST OF REFERENCE NUMBERS

1

 First cage side window

2

 Second cage side window

3

 Hole for cage pin in the first cage side disc

4

 Bore, threaded hole in the second cage side disc

5

 Cage bolt with groove as peripheral groove

6

 Groove in the form of a circumferential groove

7

 Threaded end of the cage bolt

8th

 backstop

9

 Exemption bevel on the cage bolt

10

 Cage bolt with recess as sink

11

 Groove in the form of a sink

12

 Locking hole for locking pin

13

 Thread at the entrance of the locking hole

14

 safety pin

15

 Wedge-shaped flattening on the locking pin

16

 Set screw

17

 Elliptical deformation of the cage bolt

18

 Hexagon socket on the threaded pin

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 1722510 U1 [0002]
• DE 19845747 C2 [0004]

Claims (10)

Bolt cage for a roller bearing with a first cage side plate ( 1 ), with a second cage side disc ( 2 ), with a plurality of holes ( 3 . 4 ) in the cage side windows ( 1 . 2 ), the two cage side discs ( 1 . 2 ) and holding at a predeterminable distance holding cage bolt ( 5 . 10 ), and with a plurality of roller bodies guided by means of the bolt cage, wherein the cage bolts ( 5 . 10 ) by means of at least one end of the cage bolts ( 5 . 10 ) engaging locking pins ( 14 ) on at least one cage side disc ( 1 . 2 ), characterized in that the locking pins ( 14 ) in tangential to the holes ( 3 . 4 ) for the cage bolts ( 5 . 10 ) in the cage side windows ( 1 . 2 ) extending securing holes ( 12 ) and with the cage bolts ( 5 . 10 ) interact positively and / or non-positively. Bolt cage according to claim 1, characterized in that the bores ( 3 . 4 ) for the cage bolts ( 5 . 10 ) and the securing holes ( 12 ) for receiving the locking pins ( 14 ) have at least such a distance from one another that between the surfaces of the cage bolts ( 5 . 10 ) and the locking pins ( 14 ) At least one frictional engagement is effected. Bolt cage according to claim 2, characterized in that the pin cage for large bearings, for example, for wind turbines, is determined, and that the overlap of the holes ( 3 . 4 ) for the cage bolts ( 5 . 10 ) and the securing holes ( 12 ) Is 0.2 mm to 1.2 mm. Bolt cage according to claim 3, characterized in that the securing bores ( 12 ) are cylindrical, and that the locking pins ( 14 ) as cylindrical pins without or with a wedge-shaped flattening ( 15 ) are executed, or that the locking pins ( 14 ) are designed as dowel pins or grooved pins. Bolt cage according to claim 3, characterized in that the securing bores ( 12 ) are tapered, and that the locking pins ( 14 ) are designed as conical pins with the same cone angle. Bolt cage according to one of claims 1 to 5, characterized in that the cage bolts ( 5 . 10 ) in both cage side windows ( 1 . 2 ) by means of the locking pins ( 14 ) are positively and / or frictionally secured. Bolt cage according to one of claims 1 to 5, characterized in that the cage bolts ( 5 . 10 ) at one of its ends a thread ( 7 ) and thus into corresponding threaded holes ( 4 ) in one of the cage side windows ( 1 . 2 ) and that the threadless, opposite ends of the cage bolts ( 5 . 10 ) into corresponding holes ( 3 ) of the other cage side window ( 1 . 2 ) and there by means of the on the cage bolt ( 5 . 10 ) tangentially engaging locking pins ( 14 ) are positively and / or non-positively attached. Bolt cage according to one of claims 1 to 7, characterized in that the cage bolts ( 5 . 10 ) for positive engagement with the locking pins ( 14 ) at least partially a puncture ( 6 . 11 ) exhibit. Bolt cage according to claim 8, characterized in that the groove as a circumferential groove ( 6 ) or as a sink ( 11 ) or as a notch, and that the overlap of 0.2 mm to 1.2 mm at the bottom of the circumferential groove ( 6 ) or the sink ( 11 ) or notch. Bolt cage according to one of claims 1 to 9, characterized in that the securing bores ( 12 ) for receiving the locking pins ( 14 ) at the entrance a thread ( 13 ) for a set screw ( 16 ) for pressing in and securing the locking pins ( 14 ) exhibit.

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