DE102013226748A1 - Inner ring for a radial spherical plain bearing, and method for mounting an inner ring for a radial spherical plain bearing - Google Patents

Abstract

Embodiments relate to an inner ring (1) for a radial spherical plain bearing (2). This comprises at least a first inner ring segment (3) and at least a second inner ring segment (4). The inner ring segments (3, 4) each have a contact surface (5, 6, 7, 8) on which they can be joined together. Furthermore, the inner ring segments (3, 4) each have a peripheral part surface (9, 12), which in an assembled state at least partially form a peripheral surface (13) of the inner ring (1). The inner ring segments (3, 4) each have at least one end face (11, 12) directed in an axial direction (M). The peripheral surface (13) is curved radially outward. Furthermore, the inner ring (1) comprises at least one fastening bore (14). This is adapted to receive a fastener (15) to connect the first inner ring segment (3) and the second inner ring segment (4) together, so that they are joined together at the contact surfaces (5, 6). The mounting hole (14) extends from the end face (1) of the first inner ring segment (3) into the inner ring (1).

Description

Embodiments relate to an inner ring for a radial spherical plain bearing and a method for mounting an inner ring for a radial spherical plain bearing.

Radial spherical plain bearings are used in many applications in which compensating movements between a shaft and a housing are to be compensated. Furthermore, rotating or pivoting movements can be carried out with a radial spherical plain bearing. For this purpose, a radial spherical plain bearing usually has an inner ring and an outer ring. These can be moved along their sliding surfaces to each other. The inner ring has a sliding surface usually a radially outwardly curved peripheral surface. On the outer ring a radially inwardly facing peripheral surface is formed as a sliding surface accordingly. This is also suitably curved radially outward.

In order to enable easy mounting of the radial spherical plain bearing on a shaft, the inner and outer ring are usually divided into two ring segments in conventional solutions. For mounting on the shaft, the inner ring segments are each arranged radially outward on the shaft, so that they touch each other at their contact surfaces. After placing the inner ring segments are connected together. For this purpose, in conventional radial spherical plain bearings fastening elements are introduced into the radially outwardly directed peripheral surface. The radially outwardly directed circumferential surface of the inner ring forms the sliding surface. In conventional split inner rings, therefore, the sliding surface is interrupted by the fastening elements. As a result, if necessary, the bearing capacity of the joint bearing with respect to a joint bearing of the same size, in which the inner ring is not divided and reconnected, be reduced. Undivided inner rings or spherical plain bearings, however, can be replaced with less fitting or with one another.

Therefore, there is a need to find a compromise between a simple mountability of a radial spherical plain bearing and an improvement in the bearing capacity of the bearing.

This requirement, an inner ring according to claim 1, and a method for mounting an inner ring according to claim 10 bill.

Embodiments relate to an inner ring for a radial spherical plain bearing. The inner ring comprises at least a first inner ring segment. Furthermore, the inner ring comprises at least a second Innringsegment. The inner ring segments each have a contact surface on which they can be joined together. The inner ring segments each have a peripheral surface. These peripheral surfaces result in an assembled state at least partially a peripheral surface of the inner ring. Furthermore, the inner ring segments each have at least one end face. This is directed in an axial direction. The peripheral surface is curved radially outward. The inner ring also includes a mounting hole. This is designed to receive a fastener. By means of the fastening element, the first inner ring segment and the second inner ring segment can be connected to one another, so that they are joined together at the contact surfaces. The mounting hole extends from the end face of the first inner ring segment into the inner ring.

The mounting hole and thus later also the fastening element are thus introduced from the end face of the first inner ring segment in the first inner ring segment. As a result, the fastening element or the fastening bore are not introduced on the radially outwardly directed peripheral surface. The radially outwardly directed peripheral surface forms, at least in sections, the conducting surface of the inner ring. Thus, in some embodiments, it may be effected that the sliding surface is not interrupted or reduced by fasteners or mounting holes. In other words, two inner ring segments can be connected to each other from the side or an axial direction. For this purpose, the mounting hole can extend in aligned extension in the second inner ring segment, in the assembled state of the inner ring segments. Thereby, in some embodiments, the entire radially outwardly directed peripheral surface of the inner ring can be used as a sliding surface. Thus, in some embodiments, a compromise between a size, an improvement in mountability and an increase in the load can be improved.

An inner ring for a radial spherical plain bearing can have a spherical surface as a radially outwardly curved surface. This, in combination with an oppositely curved, radially inwardly directed surface of an outer ring, allow the axial and radial guiding mobility of the radial spherical plain bearing. The outer ring slides on the inner ring. With the radial spherical plain bearing, a shaft can be mounted rotatably and pivotally relative to a housing. The shaft is received in the inner ring. To accommodate the shaft, the inner ring has a bore. The bore may for example be arranged concentrically to an axial direction or axis of rotation of the inner ring. The outer ring may for example be pressed into the housing.

In some other embodiments, at least one mounting hole is oriented obliquely to the contact surface. In some embodiments, for example, it may thus be possible for the inner ring segments to be securely connected to one another. For example, the mounting hole may be arranged in an angular range to the contact surface. The angle range has an initial value and a final value. The initial value and / or the end value of the angular range can be, for example, 1 °, 5 °, 10 °, 15 °, 20 °. 30 °, 45 °, 50 °, 70 °, 60 ° or 89 °. In this case, the angle in question is in a plane in which the mounting hole is located, which is arranged parallel to an axial direction of the inner ring and which intersects the contact surface.

In some other embodiments, the contact surface is aligned parallel to the axial direction of the inner ring. Thus, in some embodiments, a simple attachment via a mounting hole which is introduced obliquely from the end face of the first inner ring segment in the inner ring, allows. In other words, the contact surface or an edge of the contact surface, which extends over a width of the inner ring, is aligned parallel to the axial direction of the inner ring. The width of the inner ring is an extension of the inner ring in an axial direction.

Alternatively, in some other embodiments, the contact surface may also be oriented obliquely to the axial direction of the inner ring. An edge of the contact surface extending across the width of the inner ring may be oriented obliquely to the axial direction of the inner ring.

In some other embodiments, the first inner ring segment comprises a centering structure at its contact surface. The second inner ring segment comprises at its contact surface a Gegenzentrierstruktur. This counter-centering structure is configured to cooperate with the centering structure so that the first inner ring segment is centered or aligned with the second inner ring segment. Thus, in some of these embodiments, if necessary, a correct positioning of the inner ring segments during assembly to the shaft to each other can be made possible.

Optionally, in such an embodiment, the centering structure and the counter-centering structure may be formed to effect centering in a radial direction. Thus, in some embodiments, it may be possible to allow the radially outwardly facing peripheral partial surfaces of the inner annular segments to be aligned correctly with one another and to form the sliding surface of the inner ring.

In some embodiments, which allow centering in a radial direction, at least one of the contact surfaces is at least partially opposite a plane extending between the ends of the ring segment, and inclined about the axial direction of the inner ring. For example, the contact surface may be inclined at least in sections to the plane. For example, the plane and the contact surface may include an angle smaller than 90 °. Alternatively, the contact surface may be inclined away from the plane, so that they include an angle greater than 90 °. The Gegenzentrierstruktur can be designed to be inclined in the opposite direction accordingly.

For example, the centering structure may be a V-shaped groove. In this case, the Gegenzentrierstruktur may be a V-shaped survey. For example, the V-shaped groove may be parallel to the axial direction of the inner ring in the contact surface. Similarly, the V-shaped projection may extend parallel to the axial direction of the inner ring in the contact surface.

Additionally or alternatively, in some embodiments, the centering structure may be a recess of any type and shape. For example, the centering structure may be an angular recess or a bore. The Gegenzentrierstruktur may be a corresponding, suitable in the depression survey. For example, the Gegenzentrierstruktur be an angular or pin-shaped survey.

In some other embodiments, the centering structure and the counter-centering structure are formed to cause centering in an axial direction of the inner ring. As a result, it can be made possible in some embodiments for the inner ring segments to be assembled in such a way that the circumferential partial areas are positioned with respect to each other in their width. For example, the contact surface may be at least partially inclined with respect to a plane extending between the ends of the inner segment ring and with respect to the axial direction of the inner ring. The other contact surface which forms the counter-centering structure is then designed correspondingly opposite in this case. For example, the contact surface may be inclined to include an angle with the plane that is less than 90 ° or an angle greater than 90 °.

For example, the centering structure may have a V-shaped groove, wherein the V-shaped groove is perpendicular or substantially perpendicular to the axial direction of the inner ring. Accordingly, then the Gegenzentrierstruktur be formed as a V-shaped survey. The V-shaped Elevation of the Gegenzentrierstruktur may also extend perpendicular or substantially perpendicular to the axial direction.

In some other embodiments, at least one of the end faces of at least one of the inner ring segments comprises a countersink for a head of the fastener. Thus, it may be possible in some embodiments that the fastening element is completely sunk in the inner ring or its end face. For example, the fastener may be a screw with a screw head, a rivet, a pin, or the like. Possibly. the fastening element may be formed as a self-tapping screw. For example, the mounting hole may have a thread.

In some other embodiments, the inner ring comprises at least one further mounting hole. The second mounting hole may extend from a second end face into the inner ring. The second end face lies axially opposite the first end face. As a result, it can be made possible in some embodiments that the inner ring segments are fixed to one another from two sides. As a result, for example, a centering of the inner ring can be made possible. For example, the second mounting hole may extend from the first inner ring segment into the inner ring. For example, the second mounting hole may be formed symmetrically to the first mounting hole. Additionally or alternatively, the further fastening bore can also extend from the second inner ring segment into the inner ring.

In some other embodiments, each of the inner ring segments at each of its ends or in a region of its contact surfaces on a mounting hole. As a result, for example, in some embodiments it may be possible to connect them to each other at all areas where contact surfaces abut one another. Alternatively, in other embodiments, two inner ring segments may abut one another only at one point on the two contact surfaces.

In some other embodiments, the inner ring may have a plurality of inner ring segments. As a result, in some embodiments, for example, a very large inner ring, be broken down into better transportable sections. For example, the inner ring may be three, four, five, or more. Having inner ring segments. The inner ring segments can each be connected at their contact surfaces with an adjacent inner ring segment.

Some embodiments relate to a radial spherical plain bearing with an inner ring according to at least one of the described embodiments. The radial spherical plain bearing includes a distant outer ring. The outer ring may have a bore. This can be aligned concentrically to an axial direction of the joint bearing. In the bore, the inner ring can be accommodated. The outer ring is movable relative to the inner ring in the axial and in the radial direction. For this purpose, the outer ring on a radially inwardly directed peripheral surface. This is curved radially outward. The inner ring has a radially outwardly directed peripheral surface. This is curved radially outward. The inner ring and the outer ring are arranged to each other so that their curved peripheral surfaces can slide along each other. Thereby, for example, a housing which is attached to the outer ring, movable relative to a shaft which is fixed to the inner ring, are stored.

Some embodiments relate to a method for mounting an inner ring for a radial spherical plain bearing. In the method, a first inner ring segment is arranged on a shaft in one operation. The arrangement of the inner ring segment on the shaft is such that an end face of the inner ring segment faces in an axial direction. In a further process, a second inner ring segment is arranged on the shaft. Also, the second inner ring segment is arranged so that an end face of the inner ring segment faces in the same axial direction. Both the first inner ring segment and the second inner ring segment have a contact surface. The second inner ring segment is arranged on the shaft such that the second contact surface of the second inner ring segment is joined to the first contact surface of the first inner ring segment. Both inner ring segments each have a peripheral surface. The peripheral part surfaces of the inner ring segments at least partially form a circumferential surface of the inner ring in an assembled state. In a further process, the first inner ring segment are connected to one another about the second inner ring segment from an end face of the inner ring.

Thus, in some embodiments, for example, be made possible that a peripheral surface of the inner ring, which forms the sliding surface in the radial spherical plain bearing, is not reduced by introduced therein fasteners, but is completely available as a sliding surface. As a result, in radial spherical bearings of some embodiments, the load capacity can be increased compared to the size. In other words, the inner ring segments can be connected to each other after arranging and assembling on the shaft from the end face, without injuring or damaging a radially outwardly directed escort surface.

For example, for connecting the inner ring segments from the end face in some embodiments, a mounting hole can be introduced into the inner ring. This may extend from the end face of the first inner ring segment of the first inner ring segment into the second inner ring segment. For example, a fastening element, for example a screw, can be introduced into this bore. For example, the mounting hole may have a thread. Alternatively, in some embodiments directly from the end face of a fastener for connecting the two inner ring segments are introduced into the inner ring.

In some other embodiments, the inner ring segments can be centered when joining to each other. Thereby, for example, it can be made possible that the peripheral partial surfaces are joined to a peripheral surface forming the sliding surface. For this purpose, if necessary, the centering structure on the first inner ring segment and a corresponding Gegenzentrierstruktur on the second inner ring segment can be used.

The radial spherical plain bearing is a plain bearing. For example, a further sliding layer can be introduced between the outer ring and the inner ring. The sliding layer may, for example, be any material having lubricating properties, for example a polymer, graphite or the like. Furthermore, it can for example also be a plain bearing with a steel-steel material pairing in the sliding bearing.

Further advantageous embodiments will be described in more detail below with reference to exemplary embodiments illustrated in the drawings, to which exemplary embodiments are not restricted.

Thus, the figures show schematically the following views.

1 shows a schematic representation of a plan view with a section shown region of a radial spherical plain bearing with an inner ring according to an embodiment;

2 shows a further schematic representation of a plan view with partially cut portions of the radial spherical plain bearing with the inner ring according to an embodiment of the 1 ;

3 shows a schematic representation of a side view of the radial spherical plain bearing with the inner ring according to the embodiment of the 1 and 2 ;

4 shows a flowchart of a method for mounting an inner ring for a radial spherical plain bearing according to an embodiment.

In the following description of the accompanying drawings, like reference characters designate like or similar components. Further, summary reference numbers are used for components and objects that occur multiple times in one embodiment or in one representation, but are described together in terms of one or more features. Components or objects which are described by the same or by the same reference numerals may be the same, but possibly also different, in terms of individual, several or all features, for example their dimensions, unless otherwise explicitly or implicitly stated in the description.

1 shows a schematic representation of a plan view with a section shown region of a radial spherical plain bearing with an inner ring according to an embodiment.

As in 1 shown, includes an inner ring 1 for a radial spherical plain bearing 2 at least a first inner ring segment 3 and at least one second inner ring segment 4 , The inner ring segments 3 and 4 each have a contact surface 5 and 6 on. The inner ring segments 3 and 4 are at the contact surfaces 5 and 6 joined together. Furthermore, the inner ring segments 3 and 4 each a peripheral surface 9 and 10 on. The peripheral areas 9 and 10 form in an assembled state at least partially a peripheral surface 13 of the inner ring 1 out. Furthermore, the inner ring segments 3 and 4 each at least one pointing in an axial direction end face 11 on. The peripheral surface 13 is curved radially outward. Furthermore, the inner ring comprises 1 at least one mounting hole 14 , The mounting hole 14 is designed to be a fastener 15 take. So can the at least two inner ring segments 3 and 4 be connected to each other. In an assembled state, the contact surfaces touch 5 and 6 , The mounting hole 14 extends from the face 11 of the first inner ring segment 3 out in the inner ring 1 ,

In the embodiment of the 1 are the contact surfaces 5 and 6 parallel to an axial direction M of the inner ring 1 and substantially perpendicular to a circumferential direction of the inner ring 1 aligned. The mounting hole 14 extends from the front side 11 of the inner ring segment 3 up to the contact surface 5 of the inner ring segment 3 , From there, the mounting hole extends 14 further from the contact surface 6 of the inner ring segment 4 in the inner ring segment 4 , The mounting hole 14 or the parts of the mounting hole in the inner ring segment 3 and in the inner ring segment 4 are aligned with each other.

Furthermore, the inner ring 1 Also, a mounting hole, not shown, into which another fastener 16 is introduced. The further mounting hole into which the fastener 16 is introduced, is substantially analog and symmetrical to the mounting hole 15 educated. The further mounting hole is from an end face 17 of the inner ring 1 that the face 11 of the inner ring segment 3 in the axial direction M, introduced.

The joint bearing 2 also includes an outer ring 18 , The outer ring 18 is from a first outer ring segment 19 and a second outer ring segment 20 composed. The outer ring segments 19 and 20 each have a peripheral surface, which is a peripheral surface of the outer ring 18 form. The outer ring 18 has a radially inwardly directed peripheral surface which is a mating surface to the peripheral surface 13 of the inner ring 1 formed.

The outer ring segments 19 and 20 are at a contact surface 21 and 22 together. Around the outer ring segments 19 and 20 connect to each other, are in an outer peripheral surface 23 of the outer ring 19 which is directed radially outward fasteners 24 and 25 brought in. With the fasteners 24 and 25 are the outer ring segments 19 and 20 fixed to each other. This may possibly be done without affecting the load, because the outer peripheral surface 23 of the outer ring 18 only for connection of the outer ring 18 with a housing and the fasteners 24 and 25 or openings or grooves for introducing the fasteners 26 and 27 Do not affect the sliding surface.

Furthermore, the outer ring comprises 18 on its radially outwardly directed circumferential surface a lubricating groove 28 , The lubrication groove 28 extends in a circumferential direction U of the radial spherical plain bearing 2 , In the lubrication groove is a plurality of holes 29 arranged. Through this, for example, a lubricating medium in a region between the outer ring 18 and the inner ring 1 of the joint warehouse 2 be introduced. Complement or alternatively can from the bore 29 also a lubricant from the spherical plain bearing 2 escape.

In some other embodiments, not shown, the outer ring may be integrally formed. Alternatively, the outer ring segments may be connected, for example, analogously to the inner ring. Additionally or alternatively, the outer ring may be formed in some embodiments without lubrication and / or without holes.

2 shows a further schematic representation of a plan view shown with partially cut portions of the radial spherical plain bearing with the inner ring according to an embodiment according to 1 ,

As in 2 is also shown on a radially inwardly facing peripheral surface 30 of the inner ring a groove 31 educated. The groove 31 is with the peripheral surface 13 of the inner ring 1 over a hole 32 connected. The hole 32 extends in the radial direction from the peripheral surface 13 in the inner ring 1 , The hole 32 is radially under a hole 29 of the outer ring 18 arranged. Inside- 1 and outer ring 19 can be twisted to each other. Therefore, some relubricated bearings may also have a circumferential groove on the sliding surface of the inner and / or outer ring. Ie. when the inner ring is twisted to the outer ring, the hole is 32 no longer aligned with the hole 29 of the outer ring 18 arranged, nevertheless, a lubrication of the groove is possible.

In some other embodiments, not shown, the inner ring is formed without the groove and / or without the bore.

3 shows a schematic representation of a side view of the radial spherical plain bearing with the inner ring according to the embodiment of the 1 and 2 ,

As in 3 shown have the inner ring segments 3 and 4 also at their ends, the contact surfaces 5 and 6 opposite, one contact surface each 7 respectively. 8th on. At this they are also joined together. Analogous to the situation at the contact surfaces 5 and 6 are the inner ring segments 3 and 4 also in the area of the contact surfaces 7 and 8th via a fastening element 33 connected. The fastener 33 is introduced into a mounting hole, which is essentially analogous to the mounting hole 14 is aligned and formed.

To center the inner ring segments 3 and 4 simplify each other, has the contact surface 5 as centering structure 34 a V-shaped groove on. The groove is parallel to the axial direction M of the inner ring 2 aligned. The contact surface 6 points as Gegenzentrierstruktur 35 a V-shaped Collection on. The elevation is also parallel to the axial direction M of the inner ring 2 aligned. In the assembled state, the V-shaped projection engages in the V-shaped groove. As a result, a centering of the inner ring segments 3 and 4 in the radial direction R causes each other. Analog have the contact surfaces 7 and 8th also a V-shaped elevation as a centering and Gegenzentrierstruktur on.

In some other embodiments, not shown, the contact surfaces may be formed without centering. Alternatively, the contact surfaces may have an otherwise formed centering structure. In some embodiments, a centering structure may be formed to allow centering of the inner ring segments in a radial and / or axial direction.

Also the outer ring 18 or its outer ring segments 19 and 20 show at their contact surfaces 21 and 22 a V-shaped recess 36 and at the opposite contact surface a V-shaped elevation 37 on. The V-shaped recess is in the outer ring segment 19 introduced, that over the inner ring segment 3 This is a V-shaped survey 35 having.

In some other embodiments, not shown, the survey may also be formed as a depression. The Erodierschnitt in inner and outer ring may be formed co-rotating or opposite.

The inner ring 11 also has on its radially inwardly facing peripheral surface 30 a groove 41 on. The groove 41 is parallel to an axial direction M and has a substantially rectangular cross section. For example, the groove is used 41 for axial and / or radial securing of the inner ring to a shaft, not shown.

Analog has the outer ring 18 on a radially outwardly facing peripheral surface 23 a groove 42 on. The groove 42 extends parallel to an axial direction M across the width of the outer ring 18 , The groove 42 also has a substantially rectangular shape and is used, for example, to secure the outer ring 18 in the circumferential direction in its housing.

In further embodiments, not shown, the inner and / or outer ring may have other elements for securing in the circumferential direction and / or be formed without a groove.

4 shows a schematic representation of a flowchart of a method for mounting an inner ring for a radial spherical plain bearing according to an embodiment.

A procedure 50 for mounting an inner ring for a radial spherical plain bearing comprises a plurality of operations. In one operation 51 a first inner ring segment is arranged with an end face pointing in an axial direction and with a first contact face on a shaft. In another process 52 a second inner ring segment is arranged with a contact surface and an end face pointing in the axial direction on a shaft. The arrangement is made so that the contact surfaces of the two inner ring segments touch. The inner ring segments each have a peripheral part surface, which in an assembled state at least partially form the peripheral surface of the inner ring. In a final process, the first inner ring segment and the second inner ring segment are connected to one another from the end face of the inner ring.

The inner ring segments are thus arranged on the shaft so that they enclose the shaft in the radial direction at least in sections. As a result, for example, a radial spherical plain bearing can be provided with an axial separation. If necessary, the radial spherical plain bearing can each have an axially divided inner and outer ring, whose individual segments are screwed together. In other words, the radial spherical plain bearing has an inner ring and an outer ring that are axially split and braced. As a result, a simplified bearing replacement may possibly be possible. Furthermore, in some embodiments, bearing replacement may also be possible with a continuous shaft.

In some embodiments, because the sliding surface of the inner ring is not reduced by fasteners or mounting holes, may be possible that no larger storage space compared to a comparable standard storage in which the inner ring is not shared, is necessary. The described centering and Gegenzentrierungsstrukturen the individual components, so the inner ring segments and / or the outer ring segments can be centered in some embodiments to each other. It may be possible in some embodiments, for example, the assembly of the bearing in an installation position without rotation of the bearing components to each other. For example, it can be avoided in some embodiments that, as in conventional solutions, the screw from a split inner ring by an additional flange or ring component.

Expressed in other words, for example, by the oblique arrangement of the fastening elements, which may be, for example, dowel screws for connecting the inner ring segments or inner ring halves, the countersinking from the side surfaces of the inner rings or rings made. By a V-shaped erosion cut, for example, the centering of the ring halves and the force distribution to each other can be supported. Furthermore, the screwing of the inner ring halves from the side surfaces, for example, allow better utilization of the inner ring width. As a result, complete or almost complete utilization of the spherical surface may possibly be made possible in some embodiments. As a result, in some embodiments, if necessary, a larger sliding surface and / or a bearing with a higher load capacity can be provided.

Inner rings for radial spherical plain bearings according to the described embodiments can be used for example in any application for plain bearings. Examples of such applications may be vehicles, work machines, conveying elements or, for example, also a distributor trough for a multi-strand billet installation.

The embodiments disclosed in the foregoing description, the appended claims and the appended figures, as well as their individual features, may be relevant and implemented both individually and in any combination for the realization of an embodiment in its various forms.

LIST OF REFERENCE NUMBERS

1

inner ring

2

Radial spherical plain bearings

3

Inner ring segment

4

Inner ring segment

5

contact area

6

contact area

7

contact area

8th

contact area

9

Peripheral part surface

10

Peripheral part surface

11

face

12

face

13

peripheral surface

14

mounting hole

15

fastener

16

fastener

17

face

18

outer ring

19

Outer ring segment

20

Outer ring segment

21

contact area

22

contact area

23

Outer circumferential surface

24

fastener

25

fastener

26

mounting hole

27

mounting hole

28

lubrication

29

drilling

30

peripheral surface

31

groove

32

drilling

33

fastener

34

centering structure

35

Gegenzentrierstruktur

36

V-shaped elevation

37

V-shaped recess

38

The End

39

The End

41

groove

42

groove

50

method

51

arrange

52

arrange

35

Connect

M

axial direction

U

circumferentially

R

radial direction

e

level

Claims (10)

Inner ring ( 1 ) for a radial spherical plain bearing ( 2 ) having the following features: at least one first inner ring segment ( 3 ) and at least one second inner ring segment ( 4 ); wherein the inner ring segments ( 3 . 4 ) each have a contact surface ( 5 . 6 . 7 . 8th ), on which they can be joined together and wherein the inner ring segments ( 3 . 4 ) each have a peripheral surface ( 9 . 12 ), which in an assembled state at least partially a peripheral surface ( 13 ) of the inner ring ( 1 ), wherein the inner ring segments ( 3 . 4 ) each at least one in an axial direction (M) directed end face ( 11 . 12 ) exhibit; and wherein the peripheral surface ( 13 ) is curved radially outward; and at least one mounting hole ( 14 ) which is designed to be a fastener ( 15 ) to receive the first inner ring segment ( 3 ) and the second inner ring segment ( 4 ) so that they are at the contact surfaces ( 5 . 6 ) are joined together, with the mounting hole ( 14 ) from the end face ( 1 ) of the first inner ring segment ( 3 ) out into the inner ring ( 1 ). Inner ring according to claim 1, wherein the at least one fastening bore ( 14 ) obliquely to the contact surface ( 5 ) is aligned. Inner ring according to one of the preceding claims, wherein the contact surface ( 5 . 6 . 7 . 8th ) parallel to the axial direction (M) of the inner ring ( 1 ) is aligned. Inner ring according to one of the preceding claims, wherein the first inner ring segment ( 3 ) at its contact surface ( 5 ) a centering structure ( 34 ) and the second Innringsegment ( 4 ) at its contact surface ( 6 ), one with the centering structure ( 34 ) cooperating Gegenzentrierstruktur ( 35 ). Inner ring according to claim 4, wherein the centering structure ( 34 ) and the Gegenzentrierstruktur ( 35 ) are formed to effect a centering in the radial direction. Inner ring according to claim 4, wherein the centering structure ( 34 ) and the Gegenzentrierstruktur ( 35 ) are formed to cause a centering in the axial direction (M). Inner ring according to one of the preceding claims, wherein at least one end face ( 11 ) at least one of the inner ring segments ( 3 . 4 ) a countersink for a head of the fastener ( 15 ). Inner ring according to one of the preceding claims, wherein the inner ring ( 1 ) comprises a second mounting hole, wherein the second mounting hole of one of the first end face ( 11 ), in the axial direction (M) opposite the second end face ( 17 ) in the inner ring ( 1 ). Radial spherical plain bearings ( 2 ) having the following features: an inner ring ( 1 ) according to one of claims 1 to 8, an outer ring ( 18 ); where the outer ring ( 18 ) in relation to the inner ring ( 1 ) is movable in the radial and in the axial direction (M). Procedure ( 50 ) for mounting an inner ring ( 1 ) for a radial spherical plain bearing ( 2 ), the procedure ( 50 ) comprising: arranging ( 51 ) of a first inner ring segment ( 3 ) with an end face pointing in an axial direction (M) ( 11 ) and with a first contact surface ( 5 ) on a shaft; Arrange ( 52 ) of a second inner ring segment ( 4 ), with an in the same axial direction (M) facing end face ( 12 ) and with a second contact surface ( 6 ) on the shaft so that the inner ring segments ( 3 . 4 ) in an assembled state at the contact surfaces ( 5 . 6 ) touch; wherein the inner ring segments ( 3 . 4 ) each have a peripheral surface ( 9 . 10 ), and which in the assembled state, at least partially a peripheral surface ( 13 ) of the inner ring ( 1 ) train; Connect ( 53 ) of the first inner ring segment ( 3 ) and the second inner ring segment ( 4 ) from an end face ( 11 ) of the inner ring ( 1 ) out.

Images