DE102015213176A1 - Bearing arrangement for a shaft - Google Patents

Abstract

The invention relates to a bearing arrangement, in particular for a shaft (1) of a turbocharger with two axially spaced rolling bearings (4, 5), each having at least one thrust bearing function, and with a in two or more sleeve members (8, 9, 10 ), in the axial direction (3a) expandable and collapsible bearing sleeve (3), the outer bearing rings and / or raceways (4b, 5b) carries both rolling bearings and in the expanded position, both rolling bearings (4, 5) covered. The object to achieve a play-free arrangement of the bearings with the rolling elements and other parts of the bearing is achieved in that the bearing sleeve (3) has a magnet arrangement (6, 7, 18, 19), the repulsion between at least two sleeve elements ( 8, 9, 10) in the axial direction.

Description

The invention is in the field of mechanical engineering and relates to bearing arrangements for shafts with multiple bearings.

The invention can be used with particular advantage in turbochargers for internal combustion engines, in particular in the field of automotive engineering. However, it is also an application for other shaft bearings conceivable that must meet similar requirements.

Turbocharger devices for internal combustion engines usually have a turbine wheel, which is driven in the exhaust gas stream of the internal combustion engine, and a compressor wheel that pre-compresses the intake air for the internal combustion engine. The turbine wheel usually drives the compressor wheel directly by means of a shaft fixedly connected thereto. The shaft rotates at high revolutions of a few thousand revolutions per minute, but the number of revolutions is also highly variable in that the engine is used in different demand situations. Since at each end of the shaft in each case a paddle wheel is fixed, which interacts under variable conditions with a gas flow, a wide variety of axial forces can act alternately on the shaft in both directions.

On the storage of the shaft thus, especially with regard to the high required service life in the automotive sector, highest demands.

It has naturalized a bearing for such a turbocharger shaft comprising at least two rolling bearings, which are axially spaced from each other on the shaft. These rolling bearings must at least partly absorb axial forces in addition to their radial bearing function, that is to say they are at least partially to be regarded as thrust bearings or have a thrust bearing function.

A particular challenge in this context is the assembly of the bearing assembly, since usually both bearings interact with a common bearing sleeve, which carries the outer raceways of the bearings directly or with the interposition of bearing outer rings. Due to the required thrust bearing function, such a bearing assembly can be mounted only with increased effort.

A particular additional challenge which arises in the present invention is that the two rolling bearings are alternately stressed in the axial direction, ie, usually each of the rolling bearings absorbs an axial load of the shaft in one of the two axial directions, thereby resulting in the circumstance that usually only one of the rolling bearings is loaded in the axial direction at a particular time.

Without a load on a bearing can occur by mechanical tolerances, the state that the rolling elements do not roll despite a rotation of the shaft, but are in a sliding state with respect to one of the two bearing rings. Such a condition is to be avoided by the present invention.

The object is achieved by a bearing arrangement having the features of patent claim 1. The claims 2 to 10 include advantageous embodiments of the invention. The subject of claim 11 is a method for mounting a bearing assembly according to the invention.

Accordingly, the invention relates to a bearing arrangement for a shaft with two axially spaced rolling bearings, each having at least one thrust bearing function, and with a divided into two or more sleeve members, axially extendable and collapsible (compressible) bearing sleeve, the outer Bearing rings and / or raceways both rolling bearings and covers both bearings in the extended position.

Such bearing arrangements are already known from the prior art to solve the problem of mounting such arrangements. During the assembly process, the bearing sleeve can be at least partially pushed together in the axial direction in this way, to be pulled apart axially to the completion of the assembly until it covers both rolling bearings.

To improve such arrangements, in particular with regard to a reliable rolling of the rolling elements in different load situations, it is provided according to the present invention that the bearing sleeve has a magnet arrangement which causes a repulsion between at least two sleeve members in the axial direction.

The magnet arrangement causes at least two of the sleeve elements to repel each other in the axial direction, so that a magnetic force acts on a further axial expansion of the bearing sleeve. As a result, both rolling bearings are subjected to a minimum force in opposite axial directions with minimal design effort, which leads to continuous contact between the rolling elements and the bearing rings, overcoming mechanical tolerances, so that a constant rolling of the rolling elements in the Storage is ensured during the movement of the shaft.

For this purpose, at least one magnetic element can be arranged on each of the sleeve elements, wherein the magnetic elements face each other repellent. Magnetic elements can be formed by partial magnetization of the material of the respective sleeve element, but also by arranging magnets on the sleeve elements. There are also mixed solutions are conceivable in which a magnet is attached to one of the sleeve members, while the magnet is formed on another sleeve member by magnetization of parts of the sleeve member.

By the magnetic repulsive forces acting in the axial direction expansion force is generated on the bearing sleeve. In order to ensure a symmetrical force generation in the axial direction in a particularly good manner, each pair of magnets can be distributed to a plurality of sleeve elements on the circumference of the sleeve. Thus, for example, two magnetic elements can be provided at opposite locations of the circumference of each sleeve element, or three or more magnetic elements can be distributed uniformly around the circumference.

It can be provided in the axial direction more than two sleeve members which form the bearing sleeve, in which case a corresponding magnet arrangement between at least two of the sleeve members is formed. However, corresponding magnet arrangements may also be provided along the bearing sleeve on a plurality of pairs of sleeve elements.

To realize the invention can thus be advantageously provided that the bearing sleeve carries at least one permanent magnet, in particular at least two permanent magnets. The permanent magnets may be provided in corresponding recesses on the circumference of the bearing sleeve in one or more of the sleeve members. The permanent magnets may for example consist of a ferrite material, but also of a rare earth-containing material. The permanent magnets can be formed as a cuboid, but also as a hollow cylinder section, and each of the magnets can cover a peripheral portion of the bearing sleeve, which corresponds for example to at least 5%, 10% or 20% of the circumference of the respective bearing sleeve. The permanent magnets can also be glued in corresponding recesses of the bearing sleeve or a sleeve member or pressed into such recesses frictionally.

It can further be provided that at least part of a sleeve element, in particular parts of at least two sleeve elements, consist of magnetic material and in particular is / are magnetized. As a result, separate permanent magnets can be saved and sections of the sleeve elements can be used as magnets.

It may also be advantageously provided that at least one of the sleeve elements has a guide element, in particular a guide tube, on which another sleeve member slides in the axial direction telescopically. In this way, it is ensured that the movement of the sleeve elements in the axial direction relative to each other in the context of the axial pulling apart or pushing together of the bearing sleeve is defined and reproducible.

A further advantageous embodiment of the invention provides that at least three mutually axially movable sleeve members are provided, of which an axially disposed between two outer sleeve members middle sleeve member carries at least one magnet. In this way it can be provided that the central sleeve part is held for example in a bearing holder and that repel the outer sleeve members of this in the axial direction through the magnet assembly.

It may further and more specifically be provided for this purpose that both a first sleeve element pair, comprising the middle sleeve element and a first outer sleeve element, and a second sleeve element pair, comprising the middle sleeve element and a second outer sleeve element, in each case at least one guide element, in particular in the form of a guide tube, which is fastened to a respective one of the sleeve elements of a sleeve element pair and to which in each case a different sleeve element of the respective sleeve element pair is slidably guided. Thus, the outer sleeve members can each repel one another in opposite axial directions of the central sleeve member, so that total is moved towards a pulling apart of the bearing sleeve in both axial directions. Since the bearing sleeve respectively provides the outer parts of the bearings in the form of separate outer bearing rings or raceways for the bearings directly to the bearing sleeve itself, this causes a pressure on the respective outer parts of the rolling bearings axially from the central sleeve member outwardly, through the the rolling elements are brought into permanent engagement with the raceways. Through several guide tubes while the relative movements of the pairs of sleeve elements are guided in a defined manner in the axial direction.

In this case, it can also be provided that at least two sleeve elements which are directly adjacent to one another in the axial direction between two various stop positions in the axial direction are mutually displaceable and have stop elements which limit an axial movement of the sleeve members relative to each other in the stop positions. In this case, it is especially provided that in each case both stop elements limit the axial movement of the sleeve elements relative to each other in the same axial direction.

The various stop positions can be achieved in different angular positions of the two sleeve elements to each other. In a first angle of rotation of the two sleeve elements relative to one another, a different axial stop position can thus be achieved than in a second relative angle of rotation of the two sleeve elements. In the two stop positions thus different axial lengths of the bearing sleeve are achieved stable.

It can also be provided in a particular embodiment of the invention, that at least two sleeve member in the axial direction immediately adjacent sleeve members between two different stop positions in the axial direction against each other and have stop elements which limit an axial movement of the sleeve members relative to each other in the stop positions ,

In general, it can be provided for this purpose that the sleeve elements are rotatable relative to each other for displacement between the two stop positions.

To stabilize the respective adjacent sleeve elements in both axial stop positions can be advantageously provided that each two axially adjacent axially adjacent sleeve elements in each case at least one stop position, in particular in two stop positions, are positively joined together. The two sleeve elements of a pair can therefore be positively connected to each other in a manner of a bayonet connection in a stop position at a first axial distance from each other. On this basis, they can be moved in a bayonet-type movement, which consists of a combination of a twisting and a sliding movement against each other to be brought to a second relative axial position to each other, in which the two sleeve members also positively abut each other, but in a second axial distance relative to each other.

An inventive method for mounting a bearing assembly may provide that first a first roller bearing is mounted, then that the bearing sleeve is pushed axially over the first roller bearing, that in an axially compressed state of the sleeve members, a part of the second rolling bearing is mounted, that then the sleeve members be moved apart so far axially that the second roller bearing is covered by the bearing sleeve, and that by the action of a magnet assembly, a force is generated on the sleeve members, which acts on a further expansion in the axial direction.

In the following the invention will be shown by means of embodiments in figures of a drawing and subsequently explained. It shows

1 a side view of a shaft of a turbocharger with a turbine wheel and a bearing sleeve in cross section,

2 a detail from 1 .

3 a perspective view of three sleeve members of a bearing sleeve,

4 a bearing sleeve element after inserting the permanent magnets,

5 a bearing sleeve element in a perspective view with permanent magnets before insertion into corresponding recesses,

6 . 7 . 8th Longitudinal sections through a bearing sleeve in mounted on a shaft shape in different load conditions,

9 the operation of a magnet assembly on a bearing sleeve, which is shown in a longitudinal section,

10 a perspective view of a turbocharger shaft with a turbine wheel during the assembly process,

11 the arrangement 10 during a later assembly step,

12 - 17 Side views of a bearing sleeve in different positions of rotation and displacement of the sleeve members relative to each other and

18 - 23 a bearing sleeve assembly in a perspective view, also in different positions of rotation and displacement of the sleeve members against each other.

1 shows a side view of a shaft 1 a turbocharger device for an internal combustion engine, wherein the shaft 1 at her first end 1a a turbine wheel 2 wearing. The turbine wheel 2 is drivable in the exhaust stream of the internal combustion engine and rotationally fixed to the shaft 1 connected. By the wave 1 a rotary motion is transmitted to a compressor wheel at the second end 1b the wave 1 is provided, in the present figure, however, is omitted for clarity.

The wave 1 is mounted in a bearing assembly radially and axially rotating, wherein the bearing assembly is a bearing sleeve 3 which has a first rolling bearing 4 and a second rolling bearing 5 covered in the axial direction. The bearing sleeve forms 3 also each functional elements of the bearings. rolling elements 4c of the first camp and 5c of the second bearing are shown in the form of spheres.

The two camps 4 . 5 are each designed as a combined radial / thrust bearing, so that in each case an axial force can be absorbed by each of the bearings.

The sleeve 3 is not shown in detail and will be explained in more detail below. It can be seen, however, that the sleeve 3 consists of several parts in the form of sleeve elements, one of which is the first bearing 4 and another the second camp 5 assigned.

It is on the bearing sleeve 3 also magnets recognizable with 6 and 7 are designated and represent the permanent magnets, which in recesses on the bearing sleeve 3 are included.

In 2 is a detail from 1 shown enlarged, namely the magnet 7 and its inclusion in a sleeve element 9 as well as the positioning on another sleeve element 8th , The more detailed shape of the individual sleeve elements will be explained below.

In 3 is a three-dimensional overview of the composition of the bearing sleeve 3 from three sleeve elements 8th . 9 . 10 shown, the respective axial sections of the bearing sleeve 3 form, which overlap each other in the axial direction. There are two outer sleeve elements 8th . 10 and a middle sleeve member 9 that the permanent magnets 6 . 7 carries, provided. The composition of the bearing sleeve are the three sleeve elements 8th . 9 . 10 in the axial direction 3a composable and at least partially in the axial direction against each other. In this case, the first outer sleeve member forms 8th a guide tube 11 out, on which the middle sleeve element 9 and the second outer sleeve member 10 are guided in the axial direction.

5 shows the middle sleeve member 9 in a three-dimensional representation, wherein the recesses 12 . 13 for the magnets 6 . 7 are still empty. The magnets 6 . 7 themselves are also outside of the sleeve element 9 shown.

The magnets 6 . 7 for example, in the recesses 12 . 13 glued or pressed into this non-positively. Also, a positive joining, for example by introducing the magnets and subsequent deformation in the recesses, is conceivable.

In 4 is the assembled, assembled state of the middle sleeve member 9 with the permanent magnets 6 . 7 shown.

In 6 is a part of the shaft in a longitudinal section 1 with the camps 4 . 5 and a bearing sleeve 3 shown. It is the three sleeve elements 8th . 9 . 10 as well as magnets 6 . 7 in the middle sleeve element 9 recognizable.

In the respective camps 4 . 5 are the rolling elements 4c . 5c on the inner treads 4a . 5a arranged through subareas of the shaft 1 themselves are formed.

The rolling elements 4c . 5c are each in bearing cages 4d . 5d arranged. The outer treads 4b . 5b are by radially inner surfaces of the sleeve members 8th . 9 educated.

Inside the sleeve elements 8th . 9 permanently magnetized areas are respectively provided, which form magnet elements by the magnetization, which with the magnet 6 . 7 interact. This will cause a repulsion of the first outer sleeve member 8th from the middle sleeve member 9 in the direction of the force arrow 14 causes. At the same time, a repulsion of the second outer sleeve member 10 from the middle sleeve member 9 in the direction of the force arrow 15 causes. By this force effect, the outer sleeve elements can 8th . 10 in each case by a tolerance range in different axial directions of the central sleeve member 9 remove, so that at least one axial gap between an outer sleeve member 8th . 10 and the middle sleeve member 9 arises. At the same time the rolling elements 4c . 5c axially outwardly from the central sleeve member 9 pushed away and with the inner and outer treads of the bearings 4 . 5 brought into contact.

In 7 is the situation with a force acting in the axial direction on the shaft in the direction of the arrow 16 shown. The arrow 16 indicates a force that pushes the shaft from the turbine wheel in the direction of the Kompressionsrads. In this case, the outer sleeve member 10 backlash against the middle sleeve element 9 pressed and fixed there in the axial direction. At the same time wins the camp 4 At first some play, however, the magnetic effect causes the outer sleeve element 8th in the direction of the arrow 14 from the middle sleeve member 9 path pressed until the rolling elements 4c free of play on the bearing surfaces of the bearing 4 issue.

In 8th is that too 7 opposite situation in which the shaft 1 in the direction of the arrow 17 from the compressor wheel is pushed in the direction of the turbine wheel. The first outer sleeve member 8th is due to the displacement of the shaft 1 first so far in the direction of the arrow 17 pushed that on the middle sleeve element 9 strikes. The warehouse 4 captures the corresponding axial load.

The second outer sleeve member 10 is caused by the magnetic forces in the direction of the arrow 15 pushed onto the turbine wheel until the rolling elements 5c the inner and outer running surfaces / raceways of the bearing 5 touch. In this condition, there is usually an axial gap between the second outer sleeve member 10 and the middle sleeve member 9 available. It is in this state as well as in the 7 illustrated condition ensures that both bearings 4 . 5 are engaged in such a way that the rolling elements 4c . 5c lie against both running surfaces and unroll.

Based on 9 is shown in an overview, such as the magnetizations of the permanent magnets 6 . 7 and the magnetized portions of the outer sleeve members 8th . 10 aligned with each other. The field line diagrams show that the polarization of the magnetic elements in the outer sleeve elements 8th . 10 are formed, the polarization of the permanent magnets 6 . 7 is opposite, so that each adjacent magnetic elements each other in the axial direction 3a repel. A magnetized area in the first outer sleeve member 8th is in 9 With 18 while in the second outer sleeve member 10 a magnetized area by way of example 19 is designated.

10 shows in a perspective view of the shaft 1 a turbocharger with bearing elements 4d . 5d . 8th . 9 . 10 at the beginning of the assembly. First, the bearing cage 5d on the wave 1 pushed and in the position of the camp 5 brought. On the sleeve elements can 8th . 9 . 10 together or one after the other on the wave 1 be pushed until the sleeve element 10 the bearing cage 5d axially covered and the bearing 5 is composed. The sleeve elements 8th . 9 are before mounting the bearing cage 4d compressed axially, ie pushed together so that the bearing sleeve 3 overall has a minimal axial extent, so that the inner tread 4a of the camp 4 exposed and the bearing cage 4d with the rolling elements, as in 11 shown, can be pushed axially. Then lie the rolling elements with the bearing cage 4d on the inner tread 4a on, so can the sleeve element 8th together with the sleeve element 9 from the sleeve element 10 axially withdrawn and transferred to a second stable position in which the bearing sleeve 3 is expanded and stabilized and in the sleeve element 8th the warehouse 4 covered. Inside the sleeve element 8th is the outer running surface of the rolling elements of the bearing 4 educated.

In the 12 to 17 is gradually the movement of the sleeve elements 8th . 9 . 10 shown relative to each other when pulling the bearing sleeve.

In 12 is shown the axially compressed state in which the L-shaped fitting 20 (see also 5 ), which is part of the middle sleeve element 9 forms, in a same shape recess of the sleeve member 10 along the axis 3a is inserted.

In 13 is shown a state in which the sleeve member 10 in the axial direction 3a from the sleeve member 9 a little way in the direction of the arrow 21 has been deducted.

In contrast, the state of the 14 essentially the result of a rotational movement of the sleeve element 10 around the axis 3a in the direction of the arrow 22 ,

15 shows the state after a continuation of the rotational movement relative to the 14 in the same direction 22 ,

In 16 is shown a state in which the sleeve 10 has been further rotated in the same sense. The long leg of the L-shaped fitting 20 is now on the upper edge 23 of the sleeve element 10 on which a stop in the axial direction for the fitting 20 forms.

17 shows the bearing sleeve in the expanded state, wherein the axial position of the sleeve members 8th . 9 . 10 is fixed to each other and also a further rotation of the sleeve member 10 in the direction of the arrow 22 through the L-shaped fitting 20 and in the sleeve element 10 formed Gegenform is blocked. The sleeve element 10 is thus in a kind of bayonet movement of the middle sleeve member 9 axially removable and brought by a rotation in a stable position.

The 18 to 23 show the same process as in the 12 to 17 is illustrated, in a perspective view. The condition corresponds to the 18 in about the state of 12 while the 23 the state of 17 reproduces. The 19 . 20 . 21 . 22 show the intermediate states.

The design according to the invention thus achieves good mountability of a bearing arrangement with an expandable bearing sleeve and connected with an effective mechanism for an elasticity of the bearing sleeve in the axial direction.

Claims (11)

Bearing arrangement for a shaft ( 1 ) with two axially spaced rolling bearings ( 4 . 5 ), each having at least one thrust bearing function, and with one in two or more sleeve members ( 8th . 9 . 10 ), in the axial direction ( 3a ) expandable and collapsible bearing sleeve ( 3 ), outer bearing rings and / or raceways ( 4b . 5b ) of both rolling bearings ( 4 . 5 ) and in the expanded position covers both rolling bearings, characterized in that the bearing sleeve ( 3 ) a magnet arrangement ( 6 . 7 . 18 . 19 ) having a repulsion between at least two sleeve elements ( 8th . 9 . 10 ) in the axial direction. Bearing arrangement according to claim 1, characterized in that the bearing sleeve ( 3 ) at least one permanent magnet ( 6 . 7 ), in particular at least two permanent magnets carries. Bearing arrangement according to claim 1 or 2, characterized in that at least part of a sleeve element ( 8th . 9 . 10 ), in particular parts ( 18 . 19 ) consist of at least two sleeve elements, of magnetic material and in particular is magnetized / are. Bearing arrangement according to Claim 1 or one of the following, characterized in that at least one of the sleeve elements ( 8th . 9 . 10 ) a guide element, in particular a guide tube ( 11 ), on which another sleeve element ( 8th . 9 . 10 ) in the axial direction ( 3a ) slides telescopically. Bearing assembly according to claim 1 or one of the following, characterized in that at least three mutually axially movable sleeve members ( 8th . 9 . 10 ) are provided, one of which axially between two outer sleeve elements ( 8th . 10 ) arranged middle sleeve part ( 9 ) at least one magnet ( 6 . 7 ) wearing. Bearing assembly according to claim 5, characterized in that both a first sleeve element pair ( 8th . 9 ), comprising the middle sleeve member and a first outer sleeve member, and a second sleeve member pair ( 9 . 10 ), comprising the middle sleeve element and a second outer sleeve element, in each case at least one guide element, in particular in the form of a guide tube ( 11 ), which is fastened to a respective one of the sleeve elements of a sleeve element pair and on which in each case a different sleeve element of the respective sleeve element pair is slidably guided. Bearing arrangement according to Claim 1 or one of the following, characterized in that at least two sleeve elements which are directly adjacent one another in the axial direction ( 8th . 9 . 10 ) between two different stop positions in the axial direction ( 3a ) are mutually displaceable and have stop elements which limit an axial movement of the sleeve members relative to each other in the stop positions. Bearing assembly according to claim 6, characterized in that in each sleeve element pair ( 8th . 9 ) at least two in the axial direction directly adjacent sleeve elements between two different stop positions in the axial direction against each other are displaceable and stop elements ( 23 ), which limit an axial movement of the sleeve members relative to each other in the stop positions. Bearing arrangement according to claim 7 or 8, characterized in that the sleeve elements ( 8th . 9 . 10 ) are rotatable against each other for displacement between the two stop positions. Bearing arrangement according to claim 1 or one of the following, characterized in that in each case two directly axially adjacent sleeve elements ( 8th . 9 . 10 ) in each case at least one stop position, in particular in two stop positions, are positively joined together. Method for mounting a bearing arrangement according to one of claims 1 to 10, characterized in that first a first rolling bearing ( 5 ) is mounted, that then the bearing sleeve ( 3 ) is pushed axially over the first roller bearing, that in an axially compressed state of the sleeve elements ( 8th . 9 . 10 ) a part of the second rolling bearing ( 4 ) is mounted, then that the sleeve elements ( 8th . 9 . 10 ) are moved apart so far axially that the second rolling bearing ( 4 ) from the bearing sleeve ( 3 ) and that by the action of a magnet arrangement ( 6 . 7 . 18 . 19 ) a force on the sleeve elements ( 8th . 9 . 10 ) is generated, which acts on a further expansion in the axial direction.

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