DE102015118887A1 - Axial securing arrangement and axial securing method - Google Patents

Abstract

The present invention relates to an axial securing arrangement (40) for axially securing a component (24) in a vehicle transmission (10), in particular for axially securing a ring (24) of a rolling bearing (20), with an axial securing member (42) which is designed to axially securing the component (24) with respect to a housing (12) or a shaft (14) in an axial securing position; and fixing means (50) for fixing the axial securing member (42) in the axial securing position to the housing (12) or the shaft (14). In this case, the fixing device (50) on a bracket element (52) which engages over a peripheral portion of the axial securing member (42) like a bow.

Description

The present invention relates to an axial securing arrangement for the axial securing of a component in a vehicle transmission, in particular for axial securing of a ring of a roller bearing, with an axial securing member, which is adapted to axially fix the component with respect to a housing or a shaft in an axial securing position, and with a fixing device for fixing the axial securing member in the axial securing position on the housing or the shaft.

Such Axialsicherungsanordnung is from the document DE 10 2011 051 961 A1 known.

Furthermore, the present invention relates to a bearing assembly having a housing, with a rolling bearing having a bearing outer ring and a bearing inner ring and a plurality of rolling elements, and with a shaft which is rotatably supported by means of the rolling bearing with respect to the housing, wherein the bearing outer ring and or the bearing inner ring has a bearing seat surface for insertion into a bearing seat of the housing or the shaft and is axially fixed by means of an axial securing arrangement of the type described above with respect to the housing or the shaft.

The invention further relates to a motor vehicle transmission with such a bearing arrangement and a method for axially securing a component with respect to a housing, in particular by means of an axial securing arrangement of the type described above.

Axialsicherungsanordnungen serve for the axial fixation of a component, in particular with respect to a housing or a shaft. A typical axial securing arrangement includes a groove in a shaft or housing and a radially elastically deformable snap ring (Seeger ring).

Furthermore, it is known to secure a component axially by means of a nut or a screw.

In some cases, an axial securing arrangement serves not only to prevent movement of the component in the axial direction. In some cases, the Axialsicherungsanordnung also serves to axially clamp a roller bearing, in particular, when it is in the rolling bearing is a tapered roller bearing whose play is adjustable.

In some cases, it is also necessary to secure the component in the circumferential direction or in the tangential direction with respect to a housing or a shaft. In some cases, the components may therefore be connected to the shaft or the housing via axial groove arrangements, to give an example of a positive rotation lock. In many cases, however, a ring of a rolling bearing is pressed only frictionally in a bearing seat.

In the axial securing of a component to a shaft or a housing by means of a nut or a hollow screw, it is also possible to realize a chemical backup in the form of a chemical thread lock.

From the document mentioned above DE 10 2011 051 961 A1 It is known to provide a securing element in the form of a locking screw with a plurality of locking levers which engage when screwing into tooth gaps of a tooth geometry in a bore of a housing. To release these locking connections a special tool is necessary (see DE 10 2011 051 960 A1 ).

From the document DE 10 2007 049 049 A1 an assembly for axially and radially securing a bearing outer ring of a rolling bearing on a component is known, wherein on the component a securing element is releasably secured, which is in operative connection with the bearing outer ring. The bearing outer ring has at least one end groove into which the securing element engages. The securing element forms an axial securing member, which can be fixed by means of a screw on the housing.

From the document DE 10 2013 220 834 A1 is a torsional and axial securing a rolling bearing known, wherein a securing device is in operative connection with an outer ring of the rolling bearing and the housing, wherein a first outer-side locking element cooperates with an inner contour of a bearing bore of the housing and wherein a second securing element at least one axially projecting, with the Outer ring forms cooperative approach.

The document DE 101 53 441 A1 discloses a holding element for fixing a machine part, wherein the holding element consists essentially of a flat, annular base body and is fixed along its circumference at least two locations on a housing. In order to optimize the voltage curve in the holding element, it is provided that the holding element has at least one elevation extending in the axial direction at the section which radially overlaps the machine part.

Against this background, it is an object of the invention to provide an improved axial securing arrangement, an improved bearing arrangement, an improved motor vehicle transmission and an improved method for axially securing a Specify component, wherein the Axialsicherungsanordnung is simple and preferably with a few components can realize a variety of functions.

The above object is achieved in the axial securing arrangement mentioned above in that the fixing device has a bracket element which engages over a peripheral portion of the axial securing member like a bow.

Furthermore, the above object is achieved by a bearing assembly of the type mentioned, in which the bearing outer ring and / or the bearing inner ring is axially fixed by means of an axial securing arrangement according to the invention with respect to the housing or the shaft. Further, the object is achieved by a motor vehicle transmission with such a bearing assembly and by a method for axially securing a component, in particular with an axial securing arrangement according to the invention, with the steps to use the component in a bearing seat of a housing or a shaft to mount an axial securing member to to secure the component axially with respect to the housing or the shaft, and to mount a stirrup element, such that the stirrup element engages over the axial securing member.

By the measure to provide a stirrup element which engages over a peripheral portion of the axial securing member like a bow, the axial securing arrangement realized thereby can fulfill a multiplicity of functions. On the one hand, the axial securing member can be fixed in the axial securing position. On the other hand, securing functions in the circumferential direction or tangential direction can preferably also be set up via the fixing device implemented in this way. The Axialsicherungsanordnung may include a single bracket element or more ironing elements, which are arranged distributed over the circumference.

The bracket member is preferably U-shaped or U-shaped profile in longitudinal section and extends in the circumferential direction preferably over an angle of less than 45 °. The bracket member is preferably made separately from the axial securing member.

Due to the axial securing arrangement according to the invention, it is not necessary to provide a chemical fuse, in particular no chemical screw lock.

The Axialsicherungsanordnung is simple and quick to assemble, so that the inventive method is inexpensive to implement. A disassembly is possible in a simple manner, without the need for special tools are provided. In addition, in some variants at least two backup functions can be realized.

In general, the axial securing arrangement according to the invention is suitable for axially securing a component to a housing or a shaft. Hereinafter, the description will generally be directed to an axial securing of a component such as a bearing outer ring to a housing. However, all references to an axial securing to a housing should equally be understood to mean axial securing of a component with respect to a shaft. The term of the housing should therefore be able to refer to a shaft in the same way.

The bracket member may be integrally formed, but may also be formed of two or more parts.

The stirrup element can be detachably fixed to the housing or to the shaft. Alternatively, it is possible to fix the bracket element to the axial securing member.

The task is thus completely solved.

According to a preferred embodiment, the stirrup element has a first leg which is adapted to engage a radial surface of the axial securing member.

The radial surface of the Axialsicherungsgliedes is radially aligned, so aligned in particular transversely to a longitudinal axis of the Axialsicherungsanordnung. The radial surface is preferably arranged on the side remote from the component axial side of the axial securing member. A component facing the radial surface is preferably in the axial securing position on the component to be secured.

Consequently, the axial securing member can secure the component axially and the stirrup element can axially secure the axial securing member.

In this case, it is also advantageous if the axial securing member has at least one axial projection which extends from the radial surface and on which the first leg can engage in order to secure the axial securing member against rotation with respect to the housing.

The axial projection preferably extends from that radial surface in the radial direction which is formed on the axial side of the axial securing member facing away from the component. The first leg of the bracket element can attack in this way in the circumferential direction or tangentially to the axial projection and the As a result, secure the axial securing element in a form-fitting manner against rotation with respect to the housing.

Preferably, a plurality of axial projections distributed over the circumference are provided on the axial securing member. Consequently, the first limb preferably engages between two axial protrusions, viewed in the circumferential direction, and can consequently secure the axial securing limb in both circumferential directions against rotation.

According to a further overall preferred embodiment, the stirrup element has a second leg, which is designed to engage in an axial recess of the component in order to secure the component against rotation relative to the housing.

The axial securing arrangement according to the invention also serves in this embodiment to secure the component in a form-fitting manner against rotation.

According to a further overall preferred embodiment, the stirrup element has a base, from which a first and / or a second leg extends in the radial direction and which is designed to be inserted into an axial housing recess.

In this embodiment, the stirrup element can consequently be supported in the circumferential direction on approximately axially extending side surfaces of the axial housing recess in order to realize in this way a tangentially positive connection between the stirrup element and the housing.

According to a further embodiment, which is generally preferred, the stirrup element has an axial bore into which a fastening bolt can be inserted.

In this embodiment, the stirrup element is thus fastened by means of the fastening bolt. The stirrup element can be fastened to the housing (or to the shaft) by means of the fastening bolt. In an alternative embodiment, the stirrup element is fastened to the axial securing element by means of the fastening bolt. Each attachment can already taken by itself include a rotation of the bracket member and / or the Axialsicherungsgliedes relative to the housing. Preferably, however, the bracket member is additionally inserted into an axial housing recess, whereby stresses of the fastening bolt in the direction transverse to its longitudinal axis can be reduced.

The axial securing member may be a ring member which engages a radially aligned surface of the component when the axial securing position is established. The axial securing member can be applied in the simplest case to the component in order to establish the axial securing position, wherein then the bracket member is mounted so that it engages over the axial securing member, and finally the bracket member is fixed to the housing or shaft.

However, it is particularly preferable if the axial securing member has, at an outer peripheral portion or at an inner peripheral portion, a threaded portion which is adapted to be screwed into a counter-threaded portion of the housing (or the shaft).

In this embodiment, the axial securing member can thus be displaced in the axial direction by screwing relative to the housing (or the shaft) in the axial securing position. By the threaded engagement, it is also possible to exert on the component an axial force, for example, to clamp a bearing.

Thus, in this embodiment, the axial securing position is not a fixed position as in a Seeger ring. Rather, the axial securing position can be set in dependence on the rotational position of the axial securing member.

Overall, therefore, by means of the Axialsicherungsanordnung an axial displacement of the component can be prevented. Furthermore, in some preferred embodiments, twisting of the component can be prevented. Finally, in some variants, an axial displacement of the axial securing member can be prevented and / or a rotation of the axial securing member.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description. Show it:

1 a schematic longitudinal sectional view through a section of a Kraffahrzeuggetriebes with an embodiment of an axial securing arrangement according to the invention for a rolling bearing assembly;

2 a view along the line II-II of 1 ;

3 a schematic sectional view taken along the line III-III of 1 ;

4 a schematic longitudinal sectional view taken along the line IV-IV of 3 ;

5 a schematic representation of a drive train of a motor vehicle with a bearing assembly according to the invention;

6 one of the 1 Comparable schematic longitudinal sectional view of another embodiment of an axial securing arrangement according to the invention;

7 a perspective schematic representation of a bracket element part of a bracket element of the Axialsicherungsanordnung the 6 ;

8th a schematic perspective view of another bracket element part of the bracket element of 6 ;

9 one of the 1 comparable schematic longitudinal sectional view through a further embodiment of an axial securing arrangement according to the invention; and

10 a perspective schematic plan view of an axial securing member of the Axialsicherungsanordnung the 9 ,

In the 1 to 4 is in schematic form a part of a vehicle transmission 10 shown that a housing 12 within which is a shaft 14 is stored. A shaft axis is included 16 shown. The wave 14 is with a pinion 18 connected or integrally formed hereby. The pinion 18 For example, it may serve to drive a differential cage of a transverse differential for distributing drive power to driven wheels of an axle, as will be explained below.

For storage of the shaft 14 in relation to the housing 12 serves a camp 20 , The warehouse 20 is designed as a rolling bearing and has an inner ring 22 on, which in this case is designed in several parts, with a first inner ring part 22a and a second inner ring part 22b axially offset from each other. The warehouse 20 also has an outer ring 24 on. Furthermore, the warehouse includes 20 a plurality of rolling elements 26 , The rolling elements 26 are designed as tapered rollers. The camp is more exact 20 designed as a double-row bearing, with a first row of first rolling elements 26a that is between the first inner ring part 22a and the outer ring 24 are arranged, and with a second row of second rolling elements 26b between the second inner ring part 22b and the outer ring 24 are arranged.

The rolling elements 26a . 26b are aligned in an X-arrangement and designed to accommodate high radial forces, as well as high axial forces, as with the meshing of the pinion 18 may occur.

The second inner ring part 22b lies axially on an axial stop 28 the wave 14 at. At the axially opposite end is the first inner ring part 22a by means of an axial lock nut 30 axially with respect to the shaft 14 secured. The axial lock nut 30 can on an unspecified external thread of the shaft 14 be screwed on. An anti-rotation lock of the axial lock nut 30 can be achieved in different ways.

For the outer ring 24 is on the case 12 an axial stop 32 formed, against which the outer ring 24 is pushed. Specifically, the outer ring 24 on its outer periphery a bearing seat surface 36 on, which may be cylindrical, for example. In a corresponding manner is on the housing 12 a camp seat 34 formed with a substantially cylindrical shape. The outer ring 24 can consequently in the axial direction in the bearing seat 34 be used until the outer ring 24 against the axial stop 32 strikes.

The housing 12 , the wave 14 and the camp 20 form a bearing assembly 38 ,

For axial securing of the outer ring 24 is also an axial securing arrangement 40 intended.

The axial securing arrangement 40 serves to the outer ring 24 in a first axial direction A ₁ in the bearing seat 34 has been used to secure against movements in the opposite axial direction A ₂ .

The axial securing arrangement 40 includes an axial securing member 42 , As it is in particular in 4 can be seen, the axial securing member has 42 on its outer circumference a male threaded portion 44 on. Between the camp seat 34 and a mounting opening of the housing 12 is at an inner peripheral portion of the housing 12 an internal thread 46 educated. The axial securing member 42 will be in one of the 1 to 4 offset axial position shown offset, wherein the axial securing member, which is formed in the manner of an annular hollow screw in the internal thread 46 is screwed until a radial surface 48 of the axial securing member 42 at a corresponding radial surface of the outer ring 24 is appropriate, as it is in particular in 4 you can see.

In operation, such an axial securing member could become loose, even if the axial securing member 42 with a certain force in the internal thread 46 is screwed to the camp 20 to tense.

For fixing the axial securing member 42 in the axial securing position is a fixing device 50 ,

The fixing device 50 has a bracket element 52 on that, as in particular in 1 it can be seen, an outer periphery of the axial securing member 42 overlaps.

More specifically, the bracket element 52 One Base 54 from, in the radial direction, a first leg 56 and a second leg 58 axially spaced from each other. The inside distance between the thighs 56 . 58 corresponds to the axial width of the axial securing member 42 ,

The axial securing member 42 has one of the outer ring 24 facing radial surface 48 axially opposite radial surface 57 on. The first leg 56 lies in the fixing position on the radial surface 57 at.

The base 54 has an axial bore 60 on, through which a fastening bolt 62 is plugged. The fastening bolt 62 is in a threaded hole 64 in the case 12 screwed. A head 66 of the threaded bolt 64 is at the base 54 on the case 12 opposite side of the base 54 at.

The axial fixing of the axial securing member 42 in the Axialsicherungsposition thus takes place in that the first leg 56 at the radial surface 57 abuts, so that the axial securing member 42 no longer out of the internal thread 46 unscrew.

The bracket element 52 thus serves for axial securing of the axial securing member 42 However, as described below, it also serves to prevent rotation of the outer ring 24 and / or axial securing member 42 ,

The housing 12 has an axial housing recess 68 on how they are in particular 2 can be seen.

The axial housing recess 68 has a circumferential width, the circumferential width of the bracket element 52 equivalent. The bracket element 52 will be with the base 54 axially in the axial housing recess 68 pushed in to the bracket element 52 by means of the fastening bolt 62 on the housing 12 set.

Furthermore, the outer ring 24 on its the axial securing link 42 facing radial surface at least one axial recess 70 on how it is in particular in 1 and in 3 can be seen. In the axial securing position, the second leg engages 58 of the bracket element 52 in the axial recess 70 , The circumferential width of the axial recess 70 corresponds to that of the second leg 58 , This, that the ironing element 52 with the housing 12 is screwed, therefore, a rotation for the outer ring 24 reached. This, that the ironing element 52 in the circumferential direction in the axial housing recess 68 is secured, can any torsional forces of the outer ring 24 in relation to the housing 12 Well supported, so these forces are not from the threaded bolt 64 must be included.

Consequently, a rotation of the outer ring 24 realized in a first circumferential direction T ₁ and in an opposite second circumferential direction T ₂ .

Furthermore, it is also possible to prevent rotation for the axial securing member 42 to set up. For this purpose, the axial securing member 42 one or more axial projections 72 have, extending from the radial surface 57 in the axial direction of the outer ring 24 extend away. In the axial securing position, consequently, the first leg can 56 in the circumferential direction of such an axial projection 72 support, in this way an anti-rotation device for the axial securing member 42 to set up. In general, the axial securing 42 a plurality of distributed over the circumference arranged axial projections 72 spaced apart such that the distance is substantially the circumferential width of the first leg 56 corresponds, as shown schematically in 3 is indicated.

Consequently, the stirrup element serves 52 also to the axial securing member 42 To secure in the circumferential direction or in a tangential direction against rotation.

Above was an axial securing arrangement 40 described in which an outer ring 24 a rolling bearing 20 in terms of a housing 12 is secured axially. However, it is equally possible, an inner ring 22 in this way axially with respect to a shaft 14 to secure. Furthermore, it is conceivable in the same way to axially secure an outer ring on a shaft, and / or an inner ring of a rolling bearing on a housing.

Accordingly, in carrying out a method for axially securing a component such as an outer ring (or an inner ring) of a rolling bearing, the following steps are preferable First, the component is inserted into a bearing seat or a bearing seat of a housing or a shaft (the term of insertion is intended to include the term of fitting); in a next step, the axial securing member is mounted to secure the member axially with respect to the housing or shaft. Subsequently, the stirrup element is mounted, such that the stirrup element engages over the axial securing member. Finally, the bracket member is fixed to the housing or the shaft.

The overlapping of the axial securing member by means of the bracket element is preferably carried out so that two legs of the bracket element are arranged on axially opposite sides of the axial securing member.

In 5 is in schematic form a drive train 80 represented for a motor vehicle. The powertrain 80 includes a drive motor 82 , whose output with a coupling arrangement 84 connected is. An output of the clutch assembly 84 is with a vehicle transmission 10 connected. The vehicle transmission 10 may be, for example, a dual-clutch transmission. The coupling arrangement 84 may in this case be a dual clutch arrangement.

An output of the vehicle transmission 10 is with a differential 86 connected. The differential 86 can be inside the case 12 of the vehicle transmission 10 be arranged and serves driven wheels 88L . 88R to drive the motor vehicle, or distribute drive power to these wheels.

An unspecified drive basket or other drive element of the differential 86 stands with a pinion 18 connected to a wave 14 is fixed, which is designed as a pinion shaft and by means of a bearing 20 rotatable with respect to the housing 12 is stored. The warehouse 20 can be a bearing as it is with reference to the above 1 to 4 has been described.

In the 6 to 10 Further embodiments of Axialsicherungsanordnungen are shown, which generally in terms of structure and operation of the Axialsicherungsanordnung 40 correspond in terms of the 1 to 4 has been described. Also, the application may be a similar as it is in terms of 5 has been described. The same elements are therefore provided with the same reference numerals. The following section essentially explains the differences.

A first variant of the Axialsicherungsanordnung the type described above is in the 6 to 8th shown and generally with 40 ' designated.

In the axial securing arrangement 40 ' of the 6 to 8th is the stirrup element 52 ' formed in two parts and includes a first bracket element part 94 and a second bracket member part 96 , The first ironing element part 94 includes the base 54 ' as well as the first leg 56 , The second bracket element part 96 can be between the base 54 ' and the case 12 can be used and includes the second leg 58 , The general function of the bracket element 52 ' is identical to that of the bracket element 52 of the 1 to 4 ,

The bipartite of the bracket element 52 ' allows the first bracket member part 94 with an axial bore 60b to be provided, which is formed in the circumferential direction as an elongated hole, as in particular in 8th can be seen. The second bracket element part 96 has an axial bore 60a with a circular cross section. The fastening bolt 62 is through the axial bore 60b . 60a inserted through, and the fastening bolt 62 becomes over the above embodiment in the housing 12 screwed.

The axial securing function is over the legs 56 . 58 the same as in the above embodiment. Also the tangential securing or circumferential securing of the component (outer ring) 24 by means of the second leg 58 is identical to the above embodiment. Through the slot 60b in the first bracket element part 94 However, it is possible, the first bracket element part 94 to a limited extent in different circumferential positions relative to the second bracket member part 96 to position. This makes it possible for the first bracket element part 94 so position the first leg 56 adapted to the rotational position of the axial securing member 42 between two axial projections 72 of the axial securing member 42 can be arranged as it is in 8th is shown schematically.

In other words, the rotation by means of the elongated hole 60b be made variable.

In the 9 and 10 is another embodiment of an axial securing arrangement 40 '' shown.

The axial securing arrangement 40 '' has an axial securing member 42 '' on the inside on the side of the radial surface 57 an annular recess 100 having. At the annular recess are outside a plurality of axial recesses 102 arranged, whose radial position that of a fastening bolt 62 '' equivalent. In the axial securing arrangement 40 '' becomes the fastening bolt 42 '' through an axial bore 60 '' in the first leg 56 '' passed. A pointed end of the fastening bolt 62 '' then pick one of the axial grooves 102 facing the radial surface 57 axially recessed. As a result, an anti-rotation device for the axial securing member 42 '' be set up. By the measure that the screw radially within an outer circumference of the annular recess 100 is arranged, is the stirrup element 52 '' also radially captive on the axial securing member 42 '' assembled.

In the axial securing arrangement 40 '' it is not necessary the bracket element 52 '' via a bolt element on the housing 12 set.

In the axial securing arrangement 40 '' is further provided that on the radial inside of the base 54 '' the internal thread section 46 '' is trained in the one in 9 unspecified external thread section 44 '' of the axial securing member 42 '' attacks. In other words, the thread becomes 46 '' integrated in this solution in the rotation. The axial positioning of the axial securing member 42 '' , which may be a hollow screw, can be variable. The rotation in the form of the bracket element 52 '' is independent of the position of the axial securing member 48 '' ,

The axial securing member 42 '' can be made of aluminum. The top of the fastening bolt 62 '' can be in the axial direction in the axial securing member 42 '' impress, and thus provide a fixation, so that a relative rotation between axial securing member 42 '' and ironing element 52 '' is no longer possible.

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 102011051961 A1 [0002, 0010]
• DE 102011051960 A1 [0010]
• DE 102007049049 A1 [0011]
• DE 102013220834 A1 [0012]
• DE 10153441 A1 [0013]

Claims (11)

Axial securing arrangement ( 40 ) for the axial securing of a component ( 24 ) in a vehicle transmission ( 10 ), in particular for the axial securing of a ring ( 24 ) of a rolling bearing ( 20 ), with - an axial securing member ( 42 ), which is designed, in an axial securing position, the component ( 24 ) with respect to a housing ( 12 ) or a wave ( 14 ) axially fix; and a fixing device ( 50 ) for fixing the axial securing member ( 42 ) in the axial securing position on the housing ( 12 ) or the wave ( 14 ); characterized in that the fixing device ( 50 ) a stirrup element ( 52 ) having a peripheral portion of the axial securing member ( 42 ) like a bow. Axialsicherungsanordnung according to claim 1, characterized in that the bracket element ( 52 ) has a first leg ( 56 ), which is adapted to a radial surface ( 57 ) of the axial securing member ( 42 ) attack. Axialsicherungsanordnung according to claim 2, characterized in that the axial securing member ( 42 ) at least one axial projection ( 72 ) extending from the radial surface ( 57 ) and on which the first leg ( 56 ) to attack the axial securing member ( 42 ) with respect to a rotation (T ₁ , T ₂ ) with respect to the housing ( 12 ). Axialsicherungsanordnung according to one of claims 1 to 3, characterized in that the bracket element ( 52 ) a second leg ( 58 ), which is designed to be in an axial recess ( 70 ) of the component ( 24 ) to grasp the component ( 24 ) against twisting (T ₁ , T ₂ ) relative to the housing ( 12 ) or the shaft. Axialsicherungsanordnung according to one of claims 1 to 4, characterized in that the bracket element ( 52 ) has a base ( 54 ), from which a first and / or a second leg ( 56 . 58 ) extends in the radial direction and which is adapted to in an axial Gehäuseausnehmung ( 68 ) to be used. Axialsicherungsanordnung according to one of claims 1 to 5, characterized in that the bracket element ( 52 ) an axial bore ( 60 ), into which a fastening bolt ( 62 ) is insertable. Axialsicherungsanordnung according to any one of claims 1 to 6, characterized in that the axial securing member ( 42 ) at an outer peripheral portion or at an inner peripheral portion of a threaded portion ( 44 ), which is designed to be in a counter-threaded portion ( 46 ) of the housing ( 12 ) or the shaft to be screwed. Bearing arrangement ( 38 ) with a housing ( 12 ), with a rolling bearing ( 20 ), which has a bearing outer ring ( 24 ) and a bearing inner ring ( 22 ) and a plurality of rolling elements ( 26 ), and with a shaft ( 14 ), which by means of the rolling bearing ( 20 ) rotatable with respect to the housing ( 12 ), wherein the bearing outer ring ( 24 ) and / or the bearing inner ring ( 22 ) a bearing seat surface ( 36 ) for insertion into a bearing seat ( 34 ) of the housing ( 12 ) or the shaft and by means of an axial securing arrangement ( 40 ) according to one of claims 1 to 7 axially with respect to the housing ( 12 ) or the wave is fixed. Bearing assembly according to claim 8, wherein the rolling bearing ( 20 ) an axially tensionable tapered roller bearing ( 20 ). Motor vehicle transmission ( 10 ) with a bearing arrangement ( 38 ) according to claim 8 or 9. Method for axially securing a component ( 24 ), in particular by means of an axial securing arrangement ( 40 ) according to one of claims 1 to 7, comprising the steps of: - inserting the component ( 24 ) in a bearing seat ( 34 ) of a housing ( 12 ) or a wave; - mounting an axial securing member ( 42 ) to the component ( 24 ) axially with respect to the housing ( 12 ) or to secure the shaft; and - mounting a bracket element ( 52 ), such that the bracket element ( 52 ) the axial securing member ( 42 ) overlaps.

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