DE202009011583U1 - bearing arrangement - Google Patents

Abstract

Bearing arrangement (20) for supporting a shaft (16) of an electric motor (10) with
An inner ring (36) circumferentially surrounding a portion of the shaft (16),
An outer ring (38) surrounding the inner ring (36) circumferentially,
A bearing seat (54) on which the outer ring (38) is mounted,
- A plurality of rolling elements (40) which are received between the inner ring (36) and the outer ring (38) for rotatably supporting the inner ring (36) relative to the outer ring (38),
characterized in that
between the inner ring (36) and the shaft (16) an insulating bush (42) is arranged, which is designed such that the inner ring (36) relative to the shaft (16) is electrically insulated.

Description

The The invention relates to a bearing assembly for supporting a shaft of a Electric motor, with an inner ring, which forms a section of the shaft circumferentially surrounds an outer ring, the circumference of the inner ring surrounds a bearing seat on which the outer ring is mounted is, a plurality of rolling elements, between the inner ring and the outer ring are added to the Inner ring rotatably support relative to the outer ring.

Such bearing assemblies serve to radially support shafts of electric motors in a housing. Such a bearing arrangement is known, for example from the DE 198 180 59 A1 , This rolling bearing assembly is mounted in a housing by means of a designed as a plastic flange bearing seat, wherein between the rolling bearing assembly and the bearing seat, a metallic bearing seat ring is arranged. The shaft is arranged axially displaceable in the rolling bearing assembly. An outer ring is biased by a wave spring in the axial direction relative to the bearing seat.

As a result, It is the object of the present invention, an improved and inexpensive bearing assembly for supporting a shaft to provide an electric motor.

at The bearing arrangement mentioned above, this task is characterized solved that between the inner ring and the shaft one Isolation bush is arranged, which is formed so that the Inner ring is electrically isolated from the shaft.

Advantageous It is here that the shaft opposite the bearing assembly and the housing by simple means cost be stored electrically insulated. Due to the electrical insulation can Creepage currents are avoided, as with some electrical Machines can occur in the storage area. Such leakage currents can lead to bearing damage. By The insulation bushing can cost electrical insulation be achieved. The use of hybrid bearings (with ceramic balls) or bearings with coated outer ring can be avoided become.

Besides The insulating bush can also avoid that between the shaft and the inner ring fretting occurs. Furthermore, the isolation socket form a sliding seat for the inner ring. This is a length compensation between the shaft and a housing possible. High bearing loads due to different thermal expansion coefficients can be avoided. In addition, a bearing seat for the outer ring of the bearing then also made of metal be formed, so that increased strength the bearing assembly over the prior art results.

Provided no sliding seat is required, the inner ring can also immobile be stored in the axial direction relative to the insulation sleeve.

The The object of the invention is thus completely solved.

Preferably the insulating bush is at least partially made of plastic.

Thereby can with low material costs a high insulation against the bearing assembly can be achieved.

Preferably the insulating bush is at least partially made of ceramic.

Thereby can be an isolation socket with a very high electrical resistance and a high strength.

Preferably the insulating bush has at least one slot in the axial direction on.

Thereby the insulating bush can be radially expanded during assembly and be mounted on the shaft in a simple way.

Preferably is the isolation socket in a circumferential groove of Wave added.

Thereby Can the isolation socket without additional fasteners be fixed in the axial direction of the shaft.

Farther it is advantageous if the inner ring relative to the insulating bushing is movably mounted in the axial direction.

Thereby can the shaft relative to the bearing assembly in the axial direction be moved, causing mechanical stresses due to temperature fluctuations and avoided the associated longitudinal expansion of the shaft become.

there it is preferred if arranged on the shaft, a wave spring is, which biases the inner ring and thus the shaft bearing axially.

By the axial preload of the inner ring (or alternatively the Outer ring) can set up a sufficient storage base load become. Through this, an axial sliding of the rolling elements be avoided, as is the case in particular at high speed gradients can occur.

Furthermore, it is preferred if at Wel le a support sleeve is arranged, which is supported on the shaft in the axial direction and which has a sleeve portion which surrounds the wave spring circumferentially.

Thereby can be a radial expansion of the wave spring at high speeds be prevented.

there it is preferred if the sleeve portion has an outer diameter which is smaller than an inner diameter of the outer ring.

Thereby the sleeve section can be guided under the outer ring be, whereby an axially more compact design is possible.

Farther it is preferred if the sleeve portion has an inner diameter which is larger than the outer diameter of the inner ring.

Farther it is preferred if the bearing seat with a housing the electric motor is connected.

Thereby is a solid bearing of the bearing assembly and the shaft feasible.

Farther it is preferred that a rotor of the electric motor the Surrounds the shaft circumferentially and rotatably connected to the shaft is.

Thereby is an overall compact design of the electric motor in the housing realizable.

It it is understood that the above and the following yet to be explained features not only in each case specified combination, but also in other combinations or can be used in isolation, without the scope of the present To leave invention.

embodiments The invention are illustrated in the drawings and in the explained in more detail below description. It demonstrate:

1 a schematic sectional view through a shaft of an electric motor with two radial bearings; and

2 a schematic sectional view of a bearing assembly with insulation bushing and wave spring.

In 1 is an electric motor assembly generally with 10 designated.

The electric motor assembly 10 has a rotor arrangement 12 on that a wave 14 surrounds circumferentially. The wave 14 is designed as a hollow shaft, but may also be a solid shaft. The wave 14 is at opposite axial ends 16 . 18 by means of a respective bearing arrangement 20 . 22 on a housing 24 stored. The bearing arrangement 22 is designed as a fixed bearing. The bearing arrangement 22 has an inner ring 26 and an outer ring 28 on, between which rolling elements 30 are included. The inner ring 26 is on the wave 16 pressed. The bearing arrangement 22 has a first snap ring 32 for axial securing of the inner ring 26 up in a groove of the shaft 16 is fixed. The bearing arrangement 22 has a second snap ring 34 for axial securing of the outer ring 28 on that in a groove of the housing 24 is stored.

The bearing arrangement 20 at the other axial end has an inner ring 36 and an outer ring 38 on, between which rolling elements 40 are included. The inner ring is on the shaft 16 established. The outer ring is on the housing 24 established. Between the inner ring 36 and the wave 16 is an isolation socket 42 arranged. The isolation socket 42 is in a circumferential groove 44 the wave 16 stored. Between the runner arrangement 12 and the bearing assembly 22 is a paragraph 46 on the shaft 16 educated. At the heel 46 is a support sleeve 48 arranged in the axial direction on the heel 46 supported. In the axial direction between the support sleeve 48 and the inner ring 36 is a wave feather 50 arranged. The wave spring 50 rests in the axial direction on the support sleeve 48 and tensions the inner ring 36 in the axial direction. Due to the axial bias of the bearing assembly 20 issued a bearing load, whereby, especially at high speed gradients sliding of the rolling elements 40 of raceways of the bearing assembly 20 is prevented. The support sleeve 48 has an axially extending sleeve portion 52 on, the wave feather 50 surrounds circumferentially.

The inner ring 36 is over the isolation socket 42 on the shaft 16 mounted axially displaceable (sliding seat). The isolation socket 42 serves for electrical insulation between the shaft 16 and the inner ring 36 , Furthermore, the insulating bushing is used 42 in addition, fretting corrosion on the shaft 16 or the inner ring 36 to avoid. The isolation socket 42 is in the groove 44 the wave 16 taken up and in the axial direction on the shaft 16 fixed. The sleeve section 52 the support sleeve 48 extending in the axial direction on the heel 46 the wave 16 supports, serves to the wave spring 50 Surround circumferentially and to prevent expansion of the wave spring at high speeds. The isolation socket 40 It also makes it possible that at high temperatures, the shaft 16 can expand in the axial direction, without stress in the bearing assembly 20 occur.

Alternatively to the bearing of the outer ring 38 directly on the housing 24 can the outer ring 38 also be mounted on a bearing seat, not shown (eg made of metal), which is connected to the housing 24 or the like is connected.

In 2 is a schematic detail view of the bearing assembly 20 shown. The same elements are designated by the same reference numerals, wherein below essentially differences from 1 are explained.

The outer ring 38 is at a camp seat 54 mounted, which is fixed to the housing, not shown. The outer ring 38 and the inner ring 36 each have a career 56 . 58 on, in which the rolling elements 40 are included. The career 56 is on the inner peripheral surface of the outer ring 38 educated. The career 58 is on the outer peripheral surface of the inner ring 36 educated. The rolling elements 40 roll on the raceways 56 . 58 off to the inner ring 36 rotatably support relative to the outer ring.

The isolation socket 42 In both embodiments, preferably has an axial slot, not shown. Through the axial slot is a radial expansion of the insulation bushing during assembly 44 possible to the isolation socket 42 in the groove 44 to assemble. The isolation socket 42 can be made of plastic. In an alternative embodiment, the insulating bush 42 be formed of ceramic.

The rolling elements 40 may also be included in a Wälzkörperkäfig. It is understood that the rolling elements 40 are generally understood and may be formed, for example, as balls, cylinders or needles.

The sleeve section 52 the support sleeve 48 has an inner diameter that is larger than the outer diameter of the inner ring 36 , and an outer diameter that is smaller than the inner diameter of the outer ring 38 , This allows the sleeve section 52 with large length expansion of the shaft 16 in an area between the inner ring 36 and the outer ring 38 protrude without touching the bearing assembly. With a small extension of the shaft 16 can thereby the sleeve section 52 the wave spring 50 surround completely circumferentially and at high speeds widening of the wave spring 50 avoid. The wave spring 50 and the support sleeve 48 are inside the case 24 or between the bearing assembly 20 and the rotor assembly 12 arranged, whereby a particularly compact design can be realized.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 19818059 A1 [0002]

Claims (12)

Bearing arrangement ( 20 ) for storing a shaft ( 16 ) of an electric motor ( 10 ) with - an inner ring ( 36 ), which covers a section of the shaft ( 16 ) circumferentially surrounds, - an outer ring ( 38 ), the inner ring ( 36 ) circumferentially surrounds, - a bearing seat ( 54 ), on which the outer ring ( 38 ), - a plurality of rolling elements ( 40 ) between the inner ring ( 36 ) and the outer ring ( 38 ) are received to the inner ring ( 36 ) relative to the outer ring ( 38 ) rotatably, characterized in that between the inner ring ( 36 ) and the wave ( 16 ) an isolation socket ( 42 ) is arranged, which is formed such that the inner ring ( 36 ) opposite the shaft ( 16 ) is electrically isolated. Bearing arrangement according to claim 1, characterized in that the insulating bushing ( 42 ) is at least partially made of plastic. Bearing arrangement according to claim 1 or 2, characterized in that the insulating bushing ( 42 ) is formed at least partially of ceramic. Bearing arrangement according to one of claims 1 to 3, characterized in that the insulating bushing ( 42 ) has at least one slot in the axial direction. Bearing arrangement according to one of claims 1 to 4, characterized in that the insulating bushing ( 42 ) in a circumferential groove ( 44 ) the wave ( 16 ) is recorded. Bearing arrangement according to one of claims 1 to 5, characterized in that the inner ring ( 36 ) relative to the isolation socket ( 42 ) is movably mounted in the axial direction. Bearing arrangement according to one of claims 1 to 6, characterized in that on the shaft ( 16 ) a wave spring ( 50 ) is arranged, which the inner ring ( 36 ) opposite the shaft ( 16 ) and thereby biases the shaft bearing axially. Bearing arrangement according to claim 7, characterized in that on the shaft ( 16 ) a support sleeve ( 48 ) arranged on the shaft ( 16 ) is supported in the axial direction and the one sleeve section ( 52 ), which the wave spring ( 50 ) surrounds circumferentially. Bearing arrangement according to claim 8, characterized in that the sleeve section ( 52 ) has an outer diameter which is smaller than an inner diameter of the outer ring ( 38 ). Bearing arrangement according to claim 8 or 9, characterized in that the sleeve section ( 52 ) has an inner diameter which is larger than an outer diameter of the inner ring ( 36 ). Bearing arrangement according to one of claims 1 to 10, characterized in that the bearing seat ( 54 ) with a housing ( 24 ) of the electric motor ( 10 ) connected is. Bearing arrangement according to one of claims 1 to 11, characterized in that a runner ( 12 ) of the electric motor ( 10 ) the wave ( 16 ) circumferentially and with the shaft ( 16 ) is rotatably connected.