EP2994658A1

EP2994658A1 - Large roller bearing comprising a labyrinth seal

Info

Publication number: EP2994658A1
Application number: EP14719019.3A
Authority: EP
Inventors: Matthias Krebs; Mathias Seuberling
Original assignee: SKF Economos Deutschland GmbH; SKF AB
Current assignee: SKF Economos Deutschland GmbH; SKF AB
Priority date: 2013-05-06
Filing date: 2014-04-24
Publication date: 2016-03-16
Also published as: CN105473881A; DE102013208203A1; US20160108966A1; WO2014180668A1

Abstract

The invention relates to a roller bearing (100), in particular a roller bearing (100) with a diameter greater than 50cm, comprising an inner ring (110), an outer ring (120), a number of rolling elements (130) located between the inner ring (110) and the outer ring (120), and at least one sealing ring (140). The sealing ring (140) is arranged on a surface of the inner ring (110) or of the outer ring (120) and the outer ring (120) or inner ring (110) comprises a corresponding recess. The recess is designed and arranged in such a way that a major part of an exposed surface of the sealing ring (140) is enclosed in a contactless manner, such that, between an interior, used for accommodating the rolling element (130), and an exterior of the roller bearing (100), a labyrinth seal is formed by means of the sealing ring (140) and the recess.

Description

WHEEL BEARING WITH LABYRINTH SEAL

Embodiments relate to rolling bearings and in particular to bearings with a diameter greater than 50 cm.

In rolling bearings, it is crucial for the life of the interior of the rolling bearing, in which the rolling elements are arranged to protect against external environmental influences, such as dust and water. Conversely, lubricants should be prevented from escaping from the rolling bearing.

For this purpose, various sealing systems are known, which differ depending on the type of rolling bearing and the requirements.

For example, in large bearings, such as double row tapered roller bearings (DRTRB, double row taper roller bearing), used radial shaft seals. However, these have high wear and often need to be replaced, resulting in a high maintenance of such bearings.

There is therefore a need to provide a roller bearing which makes it possible to reduce maintenance.

This object is achieved by a rolling bearing according to claim 1.

A rolling bearing according to an exemplary embodiment with a diameter of more than 50 cm comprises an inner ring, an outer ring, a plurality of rolling elements lying between the inner ring and the outer ring and at least one sealing ring. The seal ring is disposed on a surface of the inner ring or the outer ring and, accordingly, the outer ring or the inner ring has a recess. The recess is formed and arranged to surround a majority of an exposed surface of the sealing ring without contact, so that between an interior of the rolling bearing for receiving the rolling elements and an outer space of the rolling bearing is formed by the sealing ring and the recess of a labyrinth seal.

In large bearings, such as roller bearings with a diameter of more than 50 cm, can be achieved by the integration of a labyrinth seal a non-contact seal. As a result, the maintenance of the rolling bearing can be significantly reduced. In this respect, the cost of maintenance but also material costs for new sealing rings can be reduced by a lower wear.

A rolling bearing according to another embodiment comprises an inner ring, an outer ring, a plurality of rolling elements lying between the inner ring and the outer ring and at least one sealing ring. The sealing ring is disposed on a surface of the inner ring or the outer ring and, accordingly, the outer ring or the inner ring has a recess. The recess is formed and arranged to surround a majority of an exposed surface of the sealing ring without contact, so that between a inner ring of the rolling bearing for receiving the rolling elements and an outer space of the rolling bearing through the sealing ring and the recess, a labyrinth seal is formed. The sealing ring consists at least partially of a rubber elastomer or a thermoplastic polymer, such as. As polyurethane. By the use of a sealing ring, which consists at least partially of a rubber elastomer or a thermoplastic polymer, a labyrinth seal can be formed, which is basically a non-contact seal, but in which there can not be too much damage when the sealing ring in operation now and then touches the surface of the recess. In contrast to the use of steel rings as a sealing ring for labyrinth seals, the described concept, the minimum distance between a surface of the recess and the sealing ring can be reduced, so that the sealing effect of the labyrinth seal is increased, and / or it allows the use of a labyrinth seal in rolling bearings large diameters (greater than 50 cm), since steel rings in such large diameters difficult be integrated in the rolling bearing and the movement tolerances are higher in large bearings. By using a labyrinth seal as non-contact seal the maintenance costs can be generally reduced. In addition, when using a sealing ring according to the described concept, a contact of the sealing ring with the surface of the recess can cause far less damage than a contact of a sealing ring made of steel, so that at this point the maintenance can also be reduced.

In some embodiments, the sealing ring is disposed on a surface of the inner ring and the outer ring has the recess. The outer ring comprises a recess-forming component and a lid, which together form the recess. The lid is connected to the recess-forming member by releasable connection means. As a result, the seal is easily accessible and can be replaced by removing the lid. The time required for an exchange of the sealing ring can be significantly reduced.

In a rolling bearing according to an embodiment, in which the sealing ring is arranged on a surface of the inner ring and the outer ring has the recess, the inner ring may have a groove and the sealing ring projecting into the groove bulge. Thereby, the sealing ring can be held in position on the surface of the inner ring, whereby the probability of contact of the surface of the recess can be reduced by the sealing ring.

In some embodiments, the sealing ring has a sealing lip that leads from the remaining sealing ring to a surface of the recess and is in contact with the surface of the recess. By integrating a sealing lip into the labyrinth seal, the benefits of a non-contact labyrinth seal can be combined with the superior sealing properties of a contacting seal. The bias of the sealing lip on the surface of the recess can be chosen so small that the friction losses are negligible and the wear is limited. However, it can be ensured that it is almost impossible for dust or water from the outside to get into the interior of the bearing. In a rolling bearing of an embodiment, it may, for. B. a cylindrical roller bearing or a tapered roller bearing, in particular a double-row or four-row tapered roller bearing, act. These rolling bearing types are mostly used for large bearings (diameter larger than 50 cm). According to the concept described, a labyrinth seal can be used in such large bearings, so that the maintenance effort can be significantly reduced.

Preferred embodiments of the present invention are explained in more detail below, with reference to the accompanying figure. It shows:

Fig. 1 is a sectional view through a part of a rolling bearing.

In the following, in the case of different exemplary embodiments described, the same reference numbers may be used in part for objects and functional units that have the same or similar functional properties. Furthermore, optional features of the various embodiments may be combined with each other or interchangeable.

Fig. 1 shows a sectional view of a rolling bearing 100 as an embodiment. The rolling bearing 100 with a diameter greater than 50 cm comprises an inner ring 110 (IR, inner ring), an outer ring 120 (OR, outer ring), a plurality of between the inner ring 110 and the outer ring 120 rolling elements 130 and at least one sealing ring 140. The sealing ring 140 is disposed on a surface of the inner ring 110 or the outer ring 120, and accordingly, the outer ring 120 or the inner ring 110 has a recess. The recess is designed and arranged to contactlessly surround a predominant part of an exposed surface of the sealing ring 140, so that a labyrinth seal is formed between an interior of the rolling bearing 100 for receiving the rolling bodies 130 and an outer space of the rolling bearing 100 through the sealing ring 140 and the recess ,

By using a labyrinth seal, the maintenance of the rolling bearing can be significantly reduced, since the wear is significantly lower than in contact seals. In other words, for large bearings, such as roller bearings with a diameter of more than 50 cm, the integration of a labyrinth seal can create a contact free seal can be achieved. As a result, the maintenance of the rolling bearing can be significantly reduced. In this respect, the cost of maintenance but also material costs for new sealing rings can be reduced by a lower wear. In the interior of the rolling bearing 100, the rolling elements 130 are arranged. This area of the rolling bearing is to be protected by the labyrinth seal from penetrating dust or water. Conversely, possibly existing lubricants should be prevented from escaping from the interior. The outer space of the rolling bearing 100 is the area that no longer belongs to the rolling bearing 100 and can penetrate through the surrounding environment dust or water in the rolling bearing.

The seal ring 140 is disposed on a surface of the inner ring 110 or the outer ring 120. As such, the sealing ring 140 has a non-exposed surface (a surface in contact with the inner ring or the outer ring). The remaining part of the surface of the sealing ring 140 may be referred to as an exposed surface. This exposed surface of the sealing ring 140 is surrounded for the most part without contact by the recess. That is, a surface of the recess over a majority of the exposed surface of the seal ring 140 is closer to the exposed surface of the seal ring 140 than the interior or exterior of the roller bearing 100. With a majority of the exposed surface, at least 50% (or 70th , 80 or 90%) of the exposed surface of the sealing ring 140.

The seal ring 140 may be disposed on a cylindrical surface of the inner ring 110 or the outer ring 120 (which is, for example, rotationally symmetric to a rotation axis of the rolling bearing), the cylindrical surface being disposed between the inner space and the outer space of the rolling bearing 100. Accordingly, in this example, the seal ring 140 would be circular in its longitudinal extent (and in its cross-section, for example, substantially rectangular or square).

The sealing ring 140 may extend over the entire circumference of the inner ring 110 (circular, annular) and, accordingly, the recess may extend over the entire inner circumference of the outer ring 120 (circular, annular). The sealing ring 140 (or labyrinth seal) may for example be made of a metal, such as. As steel. Preferably, however, the sealing ring 140 is at least partially (or completely) of a rubber elastomer (eg, nitrile rubber), or a thermoplastic elastomer (eg, polyurethane).

By the use of a sealing ring, which consists at least partially of a rubber elastomer or a thermoplastic polymer, a labyrinth seal can be formed, which is basically a non-contact seal, but in which there can not be too much damage when the sealing ring in operation now and then touches the surface of the recess. In contrast to the use of steel rings as a sealing ring for labyrinth seals, the described concept, the minimum distance between a surface of the recess and the sealing ring can be reduced, so that the sealing effect of the labyrinth seal is increased, and / or it allows the use of a labyrinth seal in rolling bearings large diameters (greater than 50 cm), since steel rings in such large diameters are difficult to integrate in the rolling bearing and the movement tolerances are higher in large bearings.

The recess may surround the sealing ring 140, for example, in a U-shape. If the sealing ring 140 is e.g. substantially rectangular or square, the U-shaped recess surrounds the majority of the three exposed sides of the sealing ring. With the fourth side of the seal ring 140 is then disposed on the inner ring 110 or the outer ring 120.

The rolling bearing 100 of FIG. 1 shows, in addition to the already mentioned elements for a concrete embodiment, additional optional and combinable details such. B. a groove 112, a recess-forming member 150 (seal carrier), a lid 160, a hose spring 142, a sealing lip 144, a releasable connection means 170 or a second sealing ring 180. These optional elements will be discussed below. One or more of these optional elements may be combined with the general concept described.

The seal ring 140 may be disposed on a surface of the outer ring and the inner ring 110 may have the recess. Preferably, however, the sealing ring 140 is disposed on a surface of the inner ring 110 and the outer ring 120 has the Recess, since in this example, the sealing ring 140 can be easily held on the surface of the inner ring in position. For example, then, the sealing ring 140 may include a sealing body and a spring, such as a tubular spring 142. The seal body and the tube spring 142 may be arranged so that the seal body is pressed by the tube spring 142 against the inner ring 110. Thereby, the seal ring 140 can be easily held in position on the surface of the inner ring.

Optionally, the inner ring 110 (or alternatively the outer ring 120) may have a groove 112 and the sealing ring 140 may have a bulge projecting into the groove 112 such that the sealing ring 140 is held in position on the surface of the inner ring 110 (or alternatively the outer ring 120) , Conversely, the sealing ring 140 could also have a groove and the inner ring 110 could have a bulge protruding into the groove. Especially against forces acting parallel to the surface of the inner ring 110 on the sealing ring 140, the groove 112 can prevent slippage of the sealing ring 140.

In combination, in addition to the groove 112, a tubular spring can also be used to press the sealing ring 140 against the inner ring 110 to prevent the sealing ring 140 from slipping out of the groove 112 due to forces acting orthogonally to the surface of the inner ring 110 (eg. Centrifugal forces due to the rotation of the rolling bearing).

Further, the outer ring 120 (or the inner ring 110) may optionally include a recess forming member 150 and a lid 160 which together form the recess. In this case, the cover 160 can be connected to the recess-forming component 150 by means of detachable connecting means (eg screws). This makes it possible to replace the sealing ring 140 with little effort by removing the cover 160. The maintenance effort can be further reduced significantly. In one possible embodiment, the recess-forming component 150 lies in an L-shape opposite the sealing ring 140 on two sides and the lid 160 faces the sealing ring 140 on a third side, so that the recess-forming member 150 and the lid 160 the sealing ring 140 U-shaped surround. The open side The U-shaped recess then lies, for example, opposite the surface of the inner ring 110 on which the sealing ring 140 is arranged.

In a U-shaped configuration of the recess, the gap of the labyrinth seal extends in a U-shape around the sealing ring 140. For example, only a gap between the surface of the inner ring 110 and a first side of the U-shaped recess is the interior of the rolling bearing 100 and a second gap between the surface of the inner ring 110 and a second side of the recess to the outer space of the rolling bearing 100 which are interconnected via the U-shaped gap of the labyrinth seal. In other words, the recess may be formed so that the exposed surface of the seal ring 140 is completely surrounded except for a gap to the interior of the rolling bearing 100 for receiving the rolling elements 130 and a gap to the outer space of the rolling bearing 100 of the recess. In this case, a maximum distance of a point of the exposed surface of the sealing ring 140 to a closest point on a surface of the recess may be less than 2 cm (or less than 1 cm, 0.8 cm or 0.5). The smaller the maximum distance, the better the sealing effect of the labyrinth seal. Conversely, however, increases the probability that it comes to a contact of the sealing ring 140 and a surface of the recess during operation.

Optionally, the sealing ring 140 has a sealing lip 144 which leads from the remaining sealing ring 140 to a surface of the recess and is in contact with the surface of the recess. For example, the sealing lip 144 may include an acute angle with the surface of the recess such that a contact surface of the sealing lip 144 with the surface of the recess along the labyrinth of the formed labyrinth seal is farther from the interior of the rolling bearing 100 to receive the rolling elements 130 as a terminal region In other words, the sealing lip 144 may be formed so as to approach and touch obliquely from the remaining sealing ring 140 to the surface of the recess, so that lubricant from the interior of the rolling bearing 100 is more likely can escape as dust or water from the outer space of the bearing can penetrate into the interior of the bearing 100. In this case, in one embodiment, the recess may be formed such that it surrounds the sealing ring 140 with no contact with the surface of the recess except for the contact of the sealing lip 144 or, conversely, the sealing ring 140 may be designed such that it is in contact with the sealing lip 144 Surface of the recess does not touch the recess.

In the specific embodiment of Fig. 1, several of the described optional embodiments are combined. The sealing ring 140 has a substantially rectangular basic shape in this example. From the basic shape, however, by a bulge on the side surface with which the sealing ring 140 is disposed on the inner ring 110, a sealing lip on an orthogonal to the surface of the inner ring 110 side surface of the sealing ring 140 and an obliquely leading into the sealing ring 140 notch in which a Hose spring 142 is arranged. In this case, the notch between the sealing lip 144 and the remaining sealing ring 140 is formed and leads from the sealing lip 144 having the side of the sealing ring 140 in the direction of that side surface of the sealing ring 140 with which the sealing ring 140 is disposed on the inner ring 110. As already mentioned, the smaller the distance between the recess and the sealing ring 140, the better the sealing effect of the labyrinth seal. For example, the recess and the seal ring 140 may be formed such that a smallest distance of a surface of the recess from the seal ring in the axial direction of the rolling bearing 100 is smaller than 5 mm (or 3 mm, 1 mm or 0.5 mm), especially between 0 , 5 mm and 3 mm, and is less than 1 cm (or less than 7 mm, 5 mm or 3 mm) in the radial direction. Since the deformation of the rolling bearing 100 in operation in the axial direction (in the direction parallel to the rotation axis of the rolling bearing) is normally smaller than in the radial direction (orthogonal to the rotational axis of the rolling bearing), a rolling bearing in the axial direction a smaller smallest distance of the surface of the recess of the Sealing ring than in the radial direction.

Normally, a roller bearing on two sides on which the interior of the rolling bearing 100 in which the rolling elements 130 are arranged to be sealed against the outer space of the rolling bearing 100. At the two sides different che sealing concepts are used. Usually, however, essentially the same sealing concept will be used on both sides. In such an example (as also shown in FIG. 1), the rolling bearing 100 has a second sealing ring 180. The second sealing ring 180 is arranged on a surface of the inner ring 110 or the outer ring 120 and correspondingly, the outer ring 120 or the inner ring 110 has a further recess. The further recess is formed and arranged to surround a majority of an exposed surface of the second seal ring 180 without contact, so that between an interior of the rolling bearing 100 for receiving the rolling elements 130 and an outer space of the rolling bearing 100 through the second sealing ring 180 and the further recess a labyrinth seal is formed and the interior of the rolling bearing 100 for receiving the rolling element 130 on both (two) sides of the rolling bearing 100 is sealed by the formed labyrinth seals. For the second sealing ring 180 and the further recess, optionally one or more of the previously described possible embodiments of the first sealing ring 140 and its recess can be realized.

The described concept with its optional designs is an interesting sealing concept for large bearings. As a large bearing can be called a rolling bearing from a diameter of for example 50 cm. However, some embodiments also relate to the implementation of the described concept for rolling bearings with a diameter of more than 1 m, more than 1.8 m, more than 2.5 m or even more than 4 m. The diameter of a roller bearing can be defined, for example, by an inner diameter of the inner ring, a center diameter of the inner space of the rolling bearing or an outer diameter of the outer ring or in a similar manner.

The rolling bearing may be, for example, a cylindrical roller bearing or a tapered roller bearing and in particular a double row or four row tapered roller bearing. But not only in large warehouses an implementation of the described sealing concept is interesting. 1 also shows an example of a rolling bearing 200 having an inner ring 110, an outer ring 120, a plurality of rolling elements 130 located between the inner ring 110 and the outer ring 120, and at least one sealing ring 140. The sealing ring 140 is attached to a surface of the inner ring 110 or the outer ring 120 arranged and correspondingly, the outer ring 120 or the inner ring 110 has a recess. The recess is formed and arranged to surround a majority of an exposed surface of the sealing ring 140 without contact, so that between an inner space of the rolling bearing 100 for receiving the rolling elements 130 and an outer ring of the rolling bearing 100 through the sealing ring 140 and the recess a labyrinth seal is formed. Furthermore, the sealing ring 140 is at least partially made of a rubber elastomer or a thermoplastic polymer, in particular polyurethane. By the use of a sealing ring, which consists at least partially of a rubber elastomer or a thermoplastic polymer, a labyrinth seal can be formed, which is basically a non-contact seal, but in which there can not be too much damage when the sealing ring in operation now and then touches the surface of the recess. In contrast to the use of steel rings as a sealing ring for labyrinth seals, the described concept, the minimum distance between a surface of the recess and the sealing ring can be reduced, so that the sealing effect of the labyrinth seal is increased, and / or it allows the use of a labyrinth seal in rolling bearings large diameters (greater than 50 cm), since steel rings in such large diameters are difficult to integrate in the rolling bearing and the movement tolerances are higher in large bearings. By using a labyrinth seal as non-contact seal the maintenance costs can be generally reduced. In addition, when using a sealing ring according to the described concept, a contact of the sealing ring with the surface of the recess can cause much less damage than a contact of a sealing ring made of steel, so that at this point the maintenance can also be reduced.

Further, for the rolling bearing 200, one or more of the optional implementation s described above may be realized.

Some embodiments relate to a non-contact seal (labyrinth) for a DRTRB (Nautilus, double-row tapered roller bearing) with integrated dust lip (sealing lip). According to the concept described, for large bearings, in particular double row tapered roller bearings, a (useful) labyrinth seal can be easily realized. This Seal concept is feasible in terms of cost and feasibility. Compared to previously used radial shaft seals can be provided by the described labyrinth seal a non-contact system. By the described concept, for example, a simple, inexpensive labyrinth seal can be produced. Bearing, seal carrier (recess forming component) and cover can be serial parts. The labyrinth ring (sealing ring), z. As polyurethane, can be installed with a spring preload (eg., With a hose spring). For example, the seal can be realized by a single change to the series (the inner ring) by a radial groove on the inner ring. As a result, it may be that no fundamental design changes to the series part are necessary. Thus, this would have a minor impact on the process chain. The seal can be replaceable (through the removable cover) without having to disassemble the bearing. A sealing lip can be integrated on the labyrinth ring (sealing ring). This is a safeguard against environmental influences (dust, water). Alternatively, this can be solved with an additional V-ring. With this implementation (sealing lip on the sealing ring), this function is integrated in the labyrinth ring.

The features disclosed in the foregoing description, the appended claims and the drawings may be significant to the realization of the invention in its various forms both individually and in any combination thereof.

Although some aspects of the present invention have been described in the context of an apparatus, it will be understood that these aspects also constitute a description of a corresponding method such that a block or device of a device may also be considered a corresponding method step or feature of a method step , For example, a method for producing or operating a filter cartridge to understand. Similarly, aspects described in connection with or as a method step also represent a description of a corresponding block or detail or feature of a corresponding device.

The embodiments described above are merely an illustration of the principles of the present invention. It is understood that modifications and variations are tions of the arrangements and details described herein will be apparent to others skilled in the art. Therefore, it is intended that the invention be limited only by the scope of the appended claims and not by the specific details presented with the description and explanation of the embodiments.

LIST OF REFERENCE NUMBERS

100/200 rolling bearings

110 inner ring

112 groove

120 outer ring

130 rolling elements

140 sealing ring

142 hose spring

144 sealing lip

150 recess-forming component

160 lids

170 releasable connection means

180 second sealing ring

Claims

P a n t a n s p r e c h e

roller bearing

Rolling bearings (100) with a diameter greater than 50 cm, with the following

Features: an inner ring (110); an outer ring (120); a plurality of rolling elements (130) located between the inner ring (110) and the outer ring (120); and at least one sealing ring (140), wherein the sealing ring (140) on a surface of the inner ring (110) or the outer ring (120) is arranged and corresponding to the outer ring (120) or the inner ring (110) has a recess, wherein the recess is formed and arranged to surround a majority of an exposed surface of the sealing ring (140) non-contact, so that between an interior of the rolling bearing (100) for receiving the rolling elements (130) and an outer space of the rolling bearing (100) through the sealing ring (140 ) and the recess a labyrinth seal is formed.

Rolling bearing according to claim 1, wherein the sealing ring (140) consists at least partially of a rubber elastomer or a thermoplastic polymer, in particular polyurethane. Rolling bearing according to one of the preceding claims, wherein the recess surrounds the sealing ring (140) in a U-shape.

Rolling bearing according to one of the preceding claims, wherein the sealing ring (140) is disposed on a surface of the inner ring (110) and the outer ring

(120) has the recess, wherein the outer ring (120) comprises a recess-forming component (150) and a cover (160) which together form the recess, wherein the cover (160) with the recess-forming member (150) by again detachable connection means (170) is connected.

Rolling bearing according to claim 4, wherein the recess-forming member (150) is substantially in an L-shape opposite the sealing ring (140) on two sides and the lid (160) the sealing ring (140) on a third side opposite, so that the recess-forming member (150) and the lid (160) surrounding the sealing ring (140) U-shaped.

Rolling bearing according to one of the preceding claims, wherein the sealing ring (140) on a surface of the inner ring (110) is arranged and the outer ring (120) has the recess, wherein the inner ring (110) has a groove (112) and the sealing ring (140 ) has a bulge projecting into the groove (112) so that the sealing ring (140) is held in position on the surface of the inner ring (110).

Rolling bearing according to one of the preceding claims, wherein the sealing ring (140) on a surface of the inner ring (110) is arranged and the outer ring (120) has the recess, wherein the sealing ring (140) comprises a sealing body and a hose spring (142), wherein the sealing body and the hose spring (142) are formed and arranged so that the sealing body is pressed by the hose spring (142) against the inner ring (110).

Rolling bearing according to one of the preceding claims, wherein the sealing ring (140) has a sealing lip (144) of the remaining sealing ring (140) to a surface of the recess leads and is in contact with the surface of the recess.

9. rolling bearing according to claim 8, wherein the sealing lip (144) with the surface of the recess forms an acute angle, so that a contact surface of the sealing lip (144) with the surface of the recess along the labyrinth of the formed labyrinth seal further from the interior of the rolling bearing (100 ) is removed for receiving the rolling elements (130) as a connection region of the sealing lip (14) to the remaining sealing ring (140).

10. Rolling bearing according to claim 8 or 9, wherein the recess is formed so that it surrounds the sealing ring (140) without contact to the contact of the sealing lip (144) with the surface of the recess.

11. Rolling bearing according to one of the preceding claims, wherein a smallest distance of a surface of the recess of the sealing ring (140) in the axial direction of the rolling bearing (100) is less than 5mm, in particular between 0.5 mm and 3mm, and smaller in the radial direction than 1cm, especially between 3mm and 5mm.

12. Rolling bearing according to one of the preceding claims, wherein the recess is formed so that the exposed surface of the sealing ring (140) except for a gap to the interior of the rolling bearing (100) for receiving the rolling elements (130) and a gap to the outside of the Rolling bearing (100) is completely surrounded by the recess, wherein a maximum distance of a point of the exposed surface of the sealing ring (140) to a closest point on a surface of the recess is smaller than 2cm.

13. Rolling bearing according to one of the preceding claims, wherein the rolling bearing (100) is a cylindrical roller bearing or a tapered roller bearing, in particular a double-row or four-row tapered roller bearing.

14. Rolling bearing according to one of the preceding claims, wherein the rolling bearing (100) has a second sealing ring (180), wherein the second sealing ring (180) is disposed on a surface of the inner ring (110) or the outer ring (120) and corresponding to the outer ring (120) or the inner ring (110) has a further recess, wherein the further recess is formed and arranged to a major part of an exposed surface the second sealing ring (180) to surround without contact, so that between an interior of the rolling bearing (100) for receiving the rolling elements (130) and an outer space of the rolling bearing (100) through the second sealing ring (180) and the further recess a labyrinth seal is formed and the interior of the rolling bearing (100) for receiving the rolling elements (130) on two sides of the rolling bearing (100) is sealed by the formed labyrinth seals.

Rolling bearing (200), comprising: an inner ring (110); an outer ring (120); a plurality of rolling elements (130) located between the inner ring (110) and the outer ring (120); and at least one sealing ring (140), wherein the sealing ring (140) on a surface of the inner ring (110) or the outer ring (120) is arranged and corresponding to the outer ring (120) or the inner ring (110) has a recess, wherein the recess is formed and arranged to surround a majority of an exposed surface of the seal ring (140) non-contact, so that between an interior of the rolling bearing (100) for receiving the rolling elements (130) and an outer space of the rolling bearing (100) through the sealing ring (140 ) and the recess a labyrinth seal is formed, wherein the sealing ring (140) at least partially made of a rubber elastomer o- a thermoplastic polymer, in particular polyurethane.