DE102021132664A1 - Plain bearing component, lever bearing, clamping device, vehicle, method of manufacture - Google Patents

Abstract

A plain bearing component (1a, 1b) for a lever bearing (10) with a lever (3) of an application device (20) for a disc brake (30) for a vehicle (100a), in particular for a commercial vehicle (100b), is set up to be supported movably relative to a second plain bearing component (2a) of the lever bearing (10), the plain bearing component (1b) or the second plain bearing component (2a) forming the lever (3), the plain bearing component (1a, 1b) having a coating designed as a sliding layer (5) has.

Description

The invention relates to a plain bearing component for a lever bearing with a lever of an application device for a disc brake for a vehicle, in particular for a commercial vehicle. The invention also relates to a lever bearing with a lever of an application device for a disc brake for a vehicle, in particular for a commercial vehicle, an application device for a disc brake for a vehicle, in particular for a commercial vehicle, a vehicle, in particular a commercial vehicle, and a method for producing a plain bearing component.

Such plain bearing components are known in the prior art. According to the state of the art, functional surfaces, in particular sliding surfaces, are realized by using separate components, particularly in the case of air disc brakes. For example, in the case of a lever bearing, bearing shells typically have the function of reducing sliding friction between the sliding partners of the lever bearing.

In an air disc brake with a pressure plunger according to the prior art, a lever of a lever bearing has two lever arms. Each lever bearing shell is positioned in one of the lever arms via a respective press connection, which leads to assembly costs. A corresponding bore or opening is made in each of the lever arms, into which the special pin geometry of the steel back of a bearing shell is pressed, which leads to manufacturing costs. The sliding surface of the bearing shell is in contact with the surface of the so-called sliding block. For technical reasons, strain hardening is required for the running surface or the surface of the sliding block, which also leads to production costs. According to the prior art, the sliding partners of the lever bearing are the sliding block and the bearing shell. The sliding point in the lever or the plain bearing has a significant influence on the hysteresis of the air disc brake. This is to keep the friction between the sliding partners of the lever bearing, the sliding block and the bearing shell fixed to the lever, as low as possible.

However, the bearing shell, which is provided as a separate component, leads to increased assembly work, since an extra component is provided, to an increased use of material, since a carrier material is required, and to increased production costs for the contact surfaces of the neighboring components as a requirement for the contact surfaces of the plain bearing components or sliding partners .

EP 1 359 337 A2 discloses an application device for a disc brake. A bearing shell for reducing friction is provided between a contour that is internally cylindrically shaped in an application shaft and a head region of a sliding element.

The invention is therefore based on the object of developing a plain bearing component for a lever bearing with a lever of an application device for a disc brake for a vehicle, in particular a commercial vehicle, in such a way that low sliding friction is provided and at the same time increased assembly costs, material use and production costs are avoided. In any case, it is the object of the invention to provide an alternative plain bearing.

The object is achieved by a slide bearing component for a lever bearing with a lever of an application device for a disc brake for a vehicle, in particular for a commercial vehicle, according to claim 1 and by the objects according to the independent claims. The dependent claims specify preferred developments of the invention.

A plain bearing component according to the invention for a lever bearing with a lever of an application device for a disc brake for a vehicle, in particular for a commercial vehicle, is set up to be supported movably relative to a second plain bearing component of the lever bearing. The plain bearing component and the second plain bearing component move relative to one another, i.e. the plain bearing component and second plain bearing component form the sliding partners of the plain bearing. The plain bearing component and the second plain bearing component each have a surface with a geometry, the surfaces being designed in such a way that the plain bearing components are supported so that they can move relative to one another. Thus, the surfaces of the plain bearing component and the second plain bearing component each form a sliding surface.

In this case, the plain bearing component or the second plain bearing component forms the lever. The other plain bearing component, which can be moved relative to the lever, thus forms a plain bearing component that is supported directly on the lever and is also referred to as a sliding block. One of the two plain bearing components is thus the sliding block and the other of the plain bearing components is the lever. The sliding partners are therefore the two plain bearing components or the sliding block and the lever. A lever bearing shell is thus unnecessary. This results in the following advantages: A reduction in the cost of materials due to the omission of a steel band for manufacturing the bearings shell and a carrier material, a reduction in the assembly effort and the number of individual components due to the elimination of the plain bearing shell and the fasteners used for this purpose and a reduction in the manufacturing effort due to a reduction in the technical requirements for the contact points.

According to the invention, the plain bearing component has a coating designed as a sliding layer. The surface of the plain bearing component is at least partially formed as a sliding layer by the coating. The invention has recognized that the sliding layer can be integrated directly on a functional component. The sliding block or the lever therefore have a coating designed as a sliding layer. The coating is a solid layer or a solid coating applied to a surface of a volume forming the sliding bearing component or the sliding block or the lever to reduce the friction between the sliding partners. The invention avoids the disadvantages of the prior art by arranging the sliding layer directly on a functional component. Substitution of the so-called lever bearing shell by a sliding layer arranged on the functional component is provided according to the invention, particularly in the field of air disc brakes. The direct arrangement of a sliding layer on the functional component, in particular of air disc brakes, eliminates the need for an additional carrier material, as is the case with a lever bearing shell. To replace the lever bearing shell, the sliding layer is applied or arranged on the sliding block or directly on the lever. A positive cost effect is achieved by reducing the use of materials and the reduction in assembly effort.

The coating designed as a sliding layer is preferably connected to the plain bearing component by a non-detachable joining technique. In this way, the coating designed as a sliding layer and the plain bearing component are permanently connected to one another. A fastener such as a screw or a bolt is unnecessary for arranging the sliding layer. This simplifies the assembly of the lever bearing and serves a more effective use of installation space that is not required for the fastener but can be used for other purposes. Optionally, the coating designed as a sliding layer is connected to the plain bearing component by pressing, gluing and/or forming.

A connecting layer is advantageously arranged below the coating designed as a sliding layer. I.e. a connecting layer is arranged between a volume of the plain bearing component and the coating designed as a sliding layer. The tie layer is a layer that is different in nature and/or composition from the bulk and/or slipping layer. The connecting layer is designed to improve coating of the plain bearing component with the sliding layer. The sliding layer is thus integrated into the functional component through the use of a connecting layer.

The connecting layer is advantageously a sintered layer, a bonded layer and/or a thermally sprayed layer. The connecting layer is optionally applied directly to the plain bearing component. A porous connecting layer is formed by sintering, which makes it easier to apply the coating designed as a sliding layer. A bonded and/or thermally sprayed layer is particularly cost effective. The connecting layer advantageously comprises a particularly sintered bronze layer in order to effectively produce a permanent connection both between the volume of the plain bearing component and the connecting layer and between the coating designed as a sliding layer and the connecting layer.

The connecting layer preferably has a connecting layer thickness of 150 μm to 250 μm. For example, the tie layer has a tie layer thickness of 200 µm to achieve a good balance between durability and cost.

The coating preferably has a sliding layer thickness of 100 μm to 300 μm, in particular 175 μm to 225 μm, in order to achieve a good balance between operational stability and costs.

Advantageously, the coating comprises a plastic to cost-effectively provide low friction between the plain bearing components. The plastic PTFE or polyamide is advantageous in order to provide only low wear and high operational stability at high pressures between the plain bearing components.

The plain bearing component is preferably designed in one piece in order to achieve particularly effective assembly and effective handling of the plain bearing component. The sliding layer is integrated directly into the plain bearing component. The lever and/or the sliding block are designed in one piece.

The sliding bearing component advantageously has a curved sliding surface in order to meet the requirements of a lever bearing. With that the sliding surface designed as a sliding layer also has a curved surface.

The second plain bearing component preferably forms the lever and the plain bearing component forms a sliding block. This means that the coating designed as a sliding layer is arranged on the sliding block. This leads to a reduction in manufacturing and assembly costs, since the lever typically has a more complex geometry than the sliding block. The advantages of this design are the comparatively simple geometry of the sliding block and thus its handling, the reduction in production costs due to the elimination of the work hardening requirement and the fact that the lever can already be case-hardened and ground, and consequently a high-quality running surface can be easily implemented without additional effort. In an alternative embodiment, the sliding layer is directly integrated on the lever. I.e. the plain bearing component forms the lever and the second plain bearing component forms the sliding block.

According to the invention, a lever bearing with a lever of an application device for a disc brake for a vehicle, in particular for a commercial vehicle, has two plain bearing components, one of the plain bearing components being a plain bearing component according to the invention. The plain bearing component can have the advantageous and optional features described in order to achieve the associated technical effects.

According to the invention, an application device for a disk brake has a lever bearing according to the invention. A plain bearing component of the lever bearing of the clamping device can have the advantageous and optional features described in order to achieve the associated technical effects. Such a lever bearing, in particular for air disc brakes with a plunger, has a lever with two lever arms and correspondingly two lever bearing shells. Optionally, the disc brake is a compressed air disc brake with two pressure pistons, such compressed air disc brakes having a lever arrangement with a lever arm and a lever bearing shell.

According to the invention, a vehicle, in particular a commercial vehicle, has an application device according to the invention. A sliding bearing component of a lever bearing of the application device of the vehicle can have the advantageous and optional features described in order to achieve the associated technical effects.

According to the invention, a method for producing a plain bearing component according to the invention has the following steps: providing the plain bearing component, the plain bearing component being set up to be supported movably relative to a second plain bearing component of the lever bearing, the plain bearing component or the second plain bearing component forming the lever; and coating the sliding bearing component with a sliding layer. The surface of the plain bearing component is at least partially coated with the sliding layer, i.e. covered with the sliding layer. The method optionally has further steps in order to produce a plain bearing component with the advantageous and optional features described in relation to the plain bearing component in order to achieve the associated technical effects.

• 1 eine Seitenansicht eines Hebellagers gemäß dem Stand der Technik;
• 2 eine perspektivische Ansicht einer Hebellagerschale gemäß dem Stand der Technik;
• 3 eine als Gleitstein ausgebildete Gleitlagerkomponente gemäß einer Ausführungsform der Erfindung;
• 4 eine als Hebel ausgebildete Gleitlagerkomponente gemäß einer Ausführungsform der Erfindung;
• 5 eine Seitenansicht eines Hebellagers gemäß einer Ausführungsform der Erfindung;
• 6 eine schematische Darstellung eines Schnitts durch eine Gleitlagerkomponente gemäß einer Ausführungsform der Erfindung;
• 7 eine schematische Darstellung eines Fahrzeugs gemäß einer Ausführungsform der Erfindung; und
• 8 eine schematische Darstellung eines Nutzfahrzeugs gemäß einer Ausführungsform der Erfindung.

Further advantages and features of the invention as well as its technical effects result from the figures and the description of the preferred embodiments shown in the figures. show it

• 1 a side view of a lever bearing according to the prior art;
• 2 a perspective view of a lever bearing shell according to the prior art;
• 3 designed as a slide bearing component according to an embodiment of the invention;
• 4 a lever-shaped sliding bearing component according to an embodiment of the invention;
• 5 a side view of a lever bearing according to an embodiment of the invention;
• 6 a schematic representation of a section through a plain bearing component according to an embodiment of the invention;
• 7 a schematic representation of a vehicle according to an embodiment of the invention; and
• 8th a schematic representation of a commercial vehicle according to an embodiment of the invention.

1 12 shows a side view of a lever bearing 10 according to the prior art.

The lever bearing 10 has a lever 3 . Lever 3 has a main lever arm 14 and two lever arms 16, one lever arm 16 in 1 is shown. The lever bearing 10 has a sliding block 4 for each of the lever arms 16 and a lever bearing shell 11 is connected to the lever arm 16 . The lever bearing shell 11 is by means of a Befes tion element 13 attached to the lever arm 16. The lever bearing shell 11 has the running with a pin geometry fastener 13 in a in the 1 not shown hole is pressed on a corresponding contact surface of the lever arm 16 or the lever 3. In this way, the lever bearing shell 11 is fixed to the lever arm 16 . The fastening element 13 of the lever bearing shell 11, which is pressed into a bore in the lever 3, is in 1 Not shown.

The lever bearing shell 11 is arranged between the lever arm 16 or the lever 3 and the sliding block 4 . The lever bearing shell 11 and the sliding block 4 are thus sliding partners of the lever bearing 10, while the lever 3 does not directly contact the sliding block 4 itself, but is only indirectly supported on the sliding block 4 by means of the lever bearing shell 11. The lever bearing shell 11 has a first sliding surface 8 and the sliding block 4 has a second sliding surface 9 . The second sliding surface 9 of the sliding block 4 is formed by the surface of the sliding block 4 . A coating of the sliding block 4 is not provided. When the lever 3 moves, the first sliding surface 8 of the lever bearing shell 11 and the second sliding surface 9 of the sliding block 4 move relative to one another. The sliding block 4 can be fastened by means of a fastening section 18 . The attachment portion 18 according to 1 is used to position the sliding block 4 in a brake caliper, the brake caliper having one or more corresponding bores.

2 shows a perspective view of a lever bearing shell 11 according to the prior art. The lever bearing shell 11 is also related to 1 described.

As in 2 shown, the lever bearing shell 11 has the fastener designed with a pin geometry, as with reference to FIG 1 described is set up in a in the 1 Not shown hole to be pressed on the corresponding contact surface of the lever arm 16 or the lever 3.

In the manufacture of the lever bearing shell 11 or plain bearing shells, half bearing shells and full bearing shells, a steel strip as raw material is first cleaned and straightened. A sintering process follows, whereby a porous sintered layer is formed. A sliding layer is pressed onto the sintered layer under the action of heat and thus forms the first sliding surface 8 . To produce the final geometry of the lever bearing shell 11, further bearing-type-specific cutting and bending processes are required. In-house handling and transport processes are also part of the manufacturing process of the lever bearing shell 11.

3 shows a plain bearing component 1a designed as a sliding block 4 according to an embodiment of the invention.

The sliding block 4 or the plain bearing component 1a is set up to be connected to a lever 3 or a second plain bearing component (not in 3 shown, see 5 ) for a lever bearing 10 of an application device 20 for a disc brake 30 for a vehicle 100a, in particular for a commercial vehicle 100b, to cooperate. The sliding block 4 or the plain bearing component 1a is set up to be supported in a movable manner relative to the lever 3 or the second plain bearing component 2a of the lever bearing 10 . The second plain bearing component thus forms the lever 3 and the plain bearing component 1a forms the sliding block 4 .

As in 3 shown, the sliding block 4 has a curved sliding surface 9 so that the sliding block 4 can be movably supported relative to the lever 3 . The curved sliding surface 9 is designed as a spherical segment. The sliding block 4 can be fastened by means of a fastening section 18 . The sliding bearing component 1a or the sliding block 4 is designed in one piece.

The sliding block 4 has a coating 5 designed as a sliding layer. The coating 5 is arranged on a volume 17 forming the sliding block 4 . The coating 5 designed as a sliding layer is applied to the curved sliding surface 9 or the ball segment, as indicated by a dashed line. The coating 5 is arranged homogeneously on the sliding surface 9, i.e. with constant quality, composition and sliding layer thickness.

The coating 5 designed as a sliding layer is connected to the sliding bearing component 1a or the sliding block 4 by means of an inseparable joining technique. A connecting layer 6 is arranged underneath the coating 5 designed as a sliding layer (see FIG 6 ). The coating 5 comprises a plastic, for example polyamide and/or PTFE.

4 shows a plain bearing component 1b designed as a lever 3 according to an embodiment of the invention.

The lever 3 or the plain bearing component 1b is set up with a sliding block 4 or a second plain bearing component (not shown) for a lever bearing 10 of a clamping device 20 for a disc brake 30 for a vehicle 100a, in particular for a commercial vehicle 100b, to cooperate. The lever 3 or the plain bearing component 1b is set up to be supported in a movable manner relative to the sliding block 4 or the second plain bearing component of the lever bearing 10 . The second plain bearing component thus forms the sliding block 4 and the plain bearing component 1b forms the lever 3 .

The lever 3 has a lever cap 15 . The lever cap is used 15 to accommodate a plunger of a cylinder, which provides the actuating force of the brake. The lever 3 is rotatably mounted about the sliding block 4 or its axis. The lever 3 has a main lever arm 14 and two lever arms 16 branching off from the main lever arm 14 . So that the lever 3 can be supported in a movable manner relative to the sliding block 4 , the lever 3 has a curved sliding surface 8 on each lever arm 16 . The curved sliding surface 8 is in each case formed as an internal cylindrical contour. The sliding bearing component 1b or the lever 3 is designed in one piece.

The lever 3 has a coating 5 designed as a sliding layer. The coating 5 is arranged on a volume 17 forming the lever 3 . The coating 5 designed as a sliding layer is applied to the curved sliding surface 8 or the inner cylindrical contour, as indicated by a dashed line. The coating 5 is arranged homogeneously on the sliding surface 8 .

The coating 5 designed as a sliding layer is connected to the plain bearing component 1b or the lever 3 by an inseparable joining technique. A connecting layer 6 is arranged underneath the coating 5 designed as a sliding layer (see FIG 6 ). The coating 5 comprises a plastic, for example polyamide and/or PTFE.

5 12 shows a side view of a lever bearing 10 according to an embodiment of the invention.

The lever bearing 10 includes a plain bearing component 1a which is designed as a sliding block 4, as with reference to FIG 3 described. The lever bearing 10 includes a second sliding bearing component 2a, which is designed as a lever 3. The sliding block 4 or the plain bearing component 1a is designed to be supported in a movable manner relative to the second plain bearing component 2a or the lever 3 .

The lever 3 assigns analogously as with reference 4 described a in 5 Lever cap 15, not shown. The lever 3 can be movably mounted on the spherical cap 15 . The lever 3 has a main lever arm 14 and two lever arms 16 branching off from the main lever arm 14 . So that the lever 3 can be supported in a movable manner relative to the sliding block 4 , the lever 3 has a curved sliding surface 8 on each lever arm 16 . The curved sliding surface 8 is in each case formed as an internal cylindrical contour.

The coating 5 designed as a sliding layer is applied to the sliding block 4 . A sliding layer on the curved sliding surface 8 of the lever 3 and a bearing shell are not required. The coating 5 designed as a sliding layer is applied to the sliding block 4 where the sliding surface 8 of the lever 3 can be supported on the sliding surface 9 of the sliding block 4, taking into account a potential movement of the lever 3.

6 shows a schematic representation of a section through a plain bearing component 1a, 1b according to an embodiment of the invention.

The plain bearing component 1a, 1b has a volume 17, a connecting layer 6 and a coating 5 designed as a sliding layer.

The connecting layer 6 is arranged below the coating 5 designed as a sliding layer. That is, the connecting layer 6 is arranged between the volume 17 of the plain bearing component 1a, 1b and the coating 5 designed as a sliding layer. The volume 17 is the material of the plain bearing component 1a, 1b that gives the plain bearing component 1a, 1b a shape. For example, the volume 17 of the sliding block 4 or the plain bearing component 1a comprises a spherical segment with a fastening section 18. For example, the volume 17 of the lever 3 or the plain bearing component 1b comprises a spherical cap 15, a main lever arm 14, two lever arms 16 branching off from the main lever arm 14 and on each lever arm 16 has a curved surface which is shaped as an inner cylindrical contour. The volume 17 is made of steel, for example, or includes steel and/or another metallic material.

The connecting layer 6 is a sintered layer, ie a sintered layer made of bronze, for example. The connection layer 6 is porous, as in 6 indicated schematically by the cavities between the components of the sintered layer shown as circles.

The connecting layer 6 has a connecting layer thickness dv of 150 μm to 250 μm. The coating 5 has a sliding layer thickness db from 100 μm to 300 μm, in particular 175 μm to 225 μm.

In order to produce the plain bearing component 1a, 1b, the volume 17 of the plain bearing component 1a, 1b is first provided. This is followed by a generally mechanical activation of the surface of the volume 17, for example by grinding, in preparation for the subsequent sintering process. The application of the coating 5 designed as a sliding layer on the plain bearing component 1a, 1b takes place through the use of the connecting layer 6, which is applied to the plain bearing component 1a, 1b or its volume 17 by sintering. A porous bronze layer is produced on the volume 17 made of steel. Alternatively, the method of thermal spraying or gluing to produce a connecting layer 6 is conceivable. Subsequently, the coating 5 designed as a sliding layer is pressed onto the plain bearing component 1a, 1b, advantageously under the action of heat. The coating 5 designed as a sliding layer is optionally present for this purpose in the form of a film material. The porous sintered layer creates a sufficient connection between the coating 5 designed as a sliding layer and the volume 17 . If required, it is also possible to press lubricating pockets into the coating 5 designed as a sliding layer. The coating process and the pressing process of the coating 5 designed as a sliding layer are adapted according to the geometry of the plain bearing component 1a, 1b. The coating process can be integrated into the manufacturing process of the plain bearing component 1a, 1b or the sliding block 4 or lever 3 and does not necessarily have to be the last processing step.

7 10 shows a schematic representation of a vehicle 100a according to an embodiment of the invention. The vehicle 100a has a plurality of disc brakes 30 . In the exemplary embodiment shown, vehicle 100a has four disc brakes 30 . The disc brakes 30 are in particular air disc brakes. According to another exemplary embodiment, which is not shown, vehicle 100a has six, eight or another number of disc brakes 30 . Each of the disc brakes 30 has an application device 20 . Each of the application devices 20 has a lever bearing 10 . Each of the lever bearings 10 has a lever 3 and a sliding block 4 . The lever 3 is designed as a plain bearing component 1b according to the invention or the sliding block 4 is designed as a plain bearing component 1a according to the invention, on which in particular a coating 5 designed as a sliding layer is provided, which reduces the friction between the lever 3 and the sliding block 4.

8th shows a schematic representation of a commercial vehicle 100b according to an embodiment of the invention. The commercial vehicle 100b assigns as referred to 7 described a plurality of disc brakes 30 on. How related to 7 the lever 3 is designed as a plain bearing component 1b according to the invention or the sliding block 4 is designed as a plain bearing component 1a according to the invention, on which a coating 5 designed as a sliding layer is provided in particular, which reduces the friction between the lever 3 and the sliding block 4.

Reference List

1a, 1b

plain bearing component

2a

second plain bearing component

3

lever

4

sliding block

5

coating

6

connection layer

8th

first sliding surface

9

second sliding surface

10

lever bearing

11

lever bearing shell

13

fastener

14

main lever arm

15

lever dome

16

lever arm

17

volume

18

attachment section

20

clamping device

30

disc brake

100a

vehicle

100b

commercial vehicle

dv

compound layer thickness

db

sliding layer thickness

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• EP 1359337 A2 [0005]

Claims (14)

Plain bearing component (1a, 1b) for a lever bearing (10) with a lever (3) of an application device (20) for a disc brake (30) for a vehicle (100a), in particular for a commercial vehicle (100b), wherein - the plain bearing component (1a , 1b) is set up to support itself movably relative to a second plain bearing component (2a) of the lever bearing (10), wherein - the plain bearing component (1b) or the second plain bearing component (2a) forms the lever (3), characterized in that - the plain bearing component (1a, 1b) has a coating (5) designed as a sliding layer. Plain bearing component (1a, 1b) after claim 1 , characterized in that the coating (5), designed as a sliding layer, is connected to the plain bearing component (1a, 1b) by an inseparable joining technique. Plain bearing component (1a, 1b) according to one of the preceding claims, characterized in that a connecting layer (6) is arranged between a volume (17) of the plain bearing component (1a, 1b) and the coating (5) designed as a sliding layer. Plain bearing component (1a, 1b) after claim 3 , characterized in that the connecting layer (6) is a sintered layer, a glued and/or a thermally sprayed layer. Plain bearing component (1a, 1b) after claim 3 or 4 , characterized in that the connecting layer (6) has a connecting layer thickness (dv) of 150 µm to 250 µm. Plain bearing component (1a, 1b) according to one of the preceding claims, characterized in that the coating (5) has a sliding layer thickness (db) of 100 µm to 300 µm, in particular 175 µm to 225 µm. Plain bearing component (1a, 1b) according to Claim one of the preceding claims, characterized in that the coating (5) comprises a plastic. Plain bearing component (1a, 1b) according to one of the preceding claims, characterized in that the plain bearing component (1a, 1b) is designed in one piece. Plain bearing component (1a, 1b) according to one of the preceding claims, characterized in that the plain bearing component (1a, 1b) has a curved sliding surface (8, 9). Plain bearing component (1a, 1b) according to one of the preceding claims, characterized in that the second plain bearing component (2a) forms the lever (3) and the plain bearing component (1a) forms a sliding block (4). Lever bearing (10) with a lever (3) of an application device (20) for a disc brake (30) for a vehicle (100a), in particular for a commercial vehicle (100b), the lever bearing (10) having two plain bearing components (1a, 1b, 2a ), wherein one of the plain bearing components (1a, 1b, 2a) has a plain bearing component (1a, 1b, 2a) according to one of Claims 1 until 9 is. Clamping device (20) for a disc brake (30), having a lever bearing (10). claim 11 . Vehicle (100a), in particular commercial vehicle (1 00b), having a clamping device (20) after claim 12 . Method for producing a plain bearing component (1a, 1b) according to one of Claims 1 until 10 , the method comprising the steps: - providing the plain bearing component (1a, 1b), the plain bearing component (1a, 1b) being set up to be supported movably relative to a second plain bearing component (2a) of the lever bearing (10), the plain bearing component ( 1b) or the second plain bearing component (2a) forms the lever (3); and - coating the sliding bearing component (1a, 1b) with a sliding layer.

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