FR3114850A1 - Sealing device for rolling bearing - Google Patents

Abstract

The invention relates to a sealing device (6) for a bearing comprising two members (1, 2) forming between them an interface (3) of relative rotation about an axis, said device comprising a first armature (10) intended to be associated with one of the members (1, 2) and a second armature (11) integral with the other member (1, 2) by forming a passage (12) between the rotation interface (3) and the outside, the first armature (10) carrying a sealing element (16) which comprises a downstream structure (16a) arranged in the passage (12) and an upstream structure (16b) arranged outside of said passage, the structure upstream (16b) having at least one annular projection (22) which extends from the side of the second armature (11), said projection being arranged to cause runoff propagating along said structure to drip away from the passage (12) upstream. Figure 1

Description

Sealing device for rolling bearing

The invention relates to a sealing device for a bearing comprising two bodies, respectively outer and inner, forming between them an interface of relative rotation about an axis, as well as a rolling bearing of which at least one side of the rotation interface is equipped with such a sealing device.

In particular, the invention applies to motor vehicle rolling bearings, in particular to wheel bearings. Advantageously, a bearing according to the invention allows the mounting of a driving or non-driving wheel of a motor vehicle, the inner member being rotating and comprising means for fixing the wheel while the outer member is fixed and comprises fixing means on a suspension element of the vehicle.

Furthermore, to allow the relative rotation of the organs, rolling bodies, in particular in the form of balls, can be arranged in the rotation interface.

To prevent, on the one hand, the leaks of lubricant present in the rotation interface, and on the other hand the contamination of said interface with external pollutants, at least one side of the rotation interface can be equipped with a device sealing.

To do this, sealing devices are known comprising at least one rigid frame intended to be associated with a member by forming, with a frame integral with the other member, a passage between the rotation interface and the outside.

In particular, sealing devices are known in which the two armatures each have an axial wall for association by fitting with a member and at least one wall forming with a wall of the other armature a sealing chamber in which the passage extends, to limit the penetration of external pollutants into the rotation interface.

Furthermore, to further limit the entry of external pollutants into the rotation interface, one of the armatures may be equipped with a sealing element comprising at least one lip arranged in said passage being in frictional contact on a span of the other armature.

To meet increasingly stringent specifications relating to sealing, in particular for the validation of wheel bearings by car manufacturers, this solution leads to a high friction torque which, in addition to the negative impact on energy necessary for the rotation of the bearing, causes a high level of operating temperature and therefore premature wear of the friction lip. In addition, this wear is all the more rapid as pollutants can enter at the level of the friction surface and remain there during rotation.

In an attempt to solve this problem, it is possible to propose adding entry chicanery in the bearing space, thus limiting the exchanges between said space and the outside, in particular at the level of the friction surface.

In particular, the sealing element may have a downstream structure arranged in the passage and carrying at least one sealing lip, as well as an upstream structure arranged outside the passage, being arranged to limit the entry of external pollutants in said passage.

The invention aims to improve the prior art by proposing in particular a rolling bearing equipped with such a device whose sealing is optimized while limiting the induced friction torque.

To this end, and according to a first aspect, the invention proposes a sealing device for a bearing comprising two members forming between them a relative rotation interface around an axis, said device comprising a first armature intended to be associated with one of the members and a second armature integral with the other member by forming a passage between the rotation interface and the exterior, the first armature carrying a sealing element which comprises a downstream structure arranged in the passage and a upstream structure disposed outside said passage, the upstream structure having at least one annular projection which extends from the side of the second armature, said projection being arranged to cause runoff propagating along said structure to drop away from the passage upstream.

According to a second aspect, the invention proposes a rolling bearing comprising two members and rolling bodies arranged in a rotation interface formed between said members to allow their relative rotation around an axis, at least one side of the interface of rotation being equipped with such a sealing device, the first armature being associated with one of the members by forming with the second armature a passage between the rotation interface and the outside.

Other objects and advantages of the invention will appear in the following description, made with reference to the appended figures, in which:

And

are schematic representations in partial axial section of one side of a rolling bearing according respectively to one embodiment of the invention;

is a schematic representation in partial axial section of one side of a rolling bearing according to an embodiment variant of FIG. 1.

In connection with these figures, a rolling bearing is described below, in particular for mounting a driving or non-driving wheel of a motor vehicle.

The bearing comprises two members, respectively outer 1 and inner 2, mounted in relative rotation around an axis via a rotation interface 3 formed between said members. In the description, the terms “exterior” and “interior” are defined with respect to the axis of rotation of the bearing (horizontal in the figures), respectively for a location far from and close to said axis.

In the embodiment shown, the outer member 1 is intended to be fixed, by being associated for example with a suspension element of the vehicle, and the inner member 2 is intended to rotate with the wheel. However, the invention can be applied to another rolling contact bearing configuration, comprising two members 1, 2 in relative rotation, possibly intended for an application other than the mounting of a motor vehicle wheel.

The bearing represented comprises rolling bodies, in particular in the form of balls 4, which are arranged in the rotation interface 3 to allow the relative rotation of the members 1, 2. To do this, the rotation interface 3 comprises two tracks of bearing 1a, 2a each formed respectively on a member 1, 2, said tracks forming between them a raceway in which is arranged a row of rolling bodies 4.

However, the invention is not limited to one embodiment of the bearing, in particular with respect to the geometry of the rolling bodies 4, to the geometry and/or to the relative arrangement of the fixed 1 and rotating 2 members.

At least one side 5 of the rotation interface 3 is equipped with a sealing device 6 to prevent, on the one hand, the leakage of lubricant present in the rotation interface 3 and, on the other hand, the contamination of said interface with external pollutants, in particular based on sludge.

In the figures, the side 5 of the rotation interface 3 has two substantially axial walls 1b, 2b of respectively a member 1, 2, said walls each extending in the extension of respectively a raceway 1a, 2a.

In the embodiments shown, the side 5 opens out via an annular opening 7 formed between a protrusion 8 of the first member 1 and a wall 9 of the second member 2. In particular, the protrusion 8 is in the form of a ring of rectangular section which extends axially in the direction of the wall 9.

The sealing device 6 comprises a first armature 10 intended to be associated with one of the members 1, 2 and a second armature 11 secured to the other member 2, 1 by forming a passage 12 between the rotation interface 3 and the outside of the landing.

In relation to FIGS. 1 and 2, the second armature 11 is intended to be associated with the other member 1, 2, said armatures possibly being made of metallic material, in particular by bending a stamped sheet.

In the figures, the first armature 10 comprises an axial outer wall 10a which is associated by fitting on an outer axial bearing surface of the protrusion 8, as well as an inner wall 10b which extends substantially radially. In particular, the inner wall 10b has an outer portion 13 bearing axially on the end of the protrusion 8 and an inner portion 14 formed in the radial extension of said outer portion.

In Figures 1 and 2, the second armature 11 comprises an axial inner wall 11a which is associated by fitting on the axial wall 2b, as well as a radial wall 11b which bears axially on a complementary wall 15 of the second member 2. In particular, the second armature 11 comprises an inclined intermediate wall 11c which connects the radial wall 11b to the axial fitting wall 11a.

In relation to FIG. 3, the second armature 11 is formed on the other member 1, 2, in particular by a machined radial wall 30 which is extended externally by an axial projection 31 and is connected internally to the axial wall 2b by a wall radiated 32.

The first reinforcement 10 carries a sealing element 16 which comprises a downstream structure 16a arranged in the passage 12 and an upstream structure 16b arranged outside of said passage. In the description, the terms "upstream" and "downstream" are defined in relation to a direction of circulation from the outside towards the interface 3 of rotation.

Advantageously, the downstream 16a and upstream 16b structures are formed from a single piece, in particular of elastomeric material, which is associated by overmolding with the first armature 10. In particular, the sealing element 16 can be made from nitrile butadiene copolymer (NBR), optionally reinforced mechanically with fillers such as carbon black, hydrogenated NBR (HNBR), fluoropolymer or polyacrylate.

In the embodiments shown, the reinforcements 10, 11 form between them a sealing chamber 17 in which the passage 12 extends, and in which the downstream structure 16a is arranged.

The downstream structure 16a also has at least one lip 19a, 19b, 19c which is in sealing interference with the second armature 11. The downstream structure 16a shown comprises two substantially axial outer 19a and inner 19b lips, the outer lip 19a having a free end disposed axially facing the radial wall 11b (FIGS. 1 and 2) or axially facing the wall 30 (FIG. 3), and the inner lip 19b being disposed in frictional contact on the inclined intermediate wall 11c (FIGS. 1 and 2) or on the wall 32 (FIG. 3).

Furthermore, the downstream structure 16a has an additional lip 19c which extends substantially radially from a free end of the inner portion 14 to come into frictional contact on the axial fitting wall 11a (FIGS. 1 and 2) or on the wall axial 2b (figure 3), in order to prevent leaks into the chamber 17 of lubricant coming from the rotation interface 3.

The passage 12 has an upstream opening 20 formed at the interface between the reinforcements 10, 11, said opening being arranged to limit the entry of external pollutants into said passage.

The second reinforcement 11 comprises an outer wall 11d which, in FIGS. 1 and 2, extends axially in the outer part of the bearing wall 11b and, in FIG. 3, is formed on the projection 30. The opening 20 is bounded at least partially by the outer wall 11d. In particular, the outer wall 11d has a free end which comes axially opposite the bearing portion 13 of the first armature 10, the upstream opening 20 being formed at their interface.

Advantageously, the sealing element 16 comprises a veil 16c which extends over the bearing portion 13, and in particular in the opening 20, in order to limit its axial dimension, and thus reduce the risk of entry of external pollutants through said opening. In Figure 3, the veil 16c includes an axial bead 33 which extends opposite the projection 31 to form the opening at their interface.

To limit the entry of external pollutants into the opening 7, the upstream structure 16b has a radial deflector 21 which is interposed between the outside and the upstream part of said opening, in order to form a baffle for the entry of external pollutants. .

Furthermore, the upstream structure 16b has at least one annular projection 22 which extends from the side of the second armature 11, said projection being arranged to cause runoff propagating along said upstream structure to drop away from passage 12.

Thus, the external pollutants streaming along the upstream structure 16b are recovered by the projection 22 at a distance from the passage 12 in order to be able to be evacuated by recirculation due to gravity before being able to enter said passage.

In the embodiments shown, the projection 22 is arranged outside the opening 20, and has a clearance with the second reinforcement 11 whose dimension is greater than the dimension of said opening. In particular, the projection 22 thus does not form a sealing baffle upstream of the opening 20.

In Figures 1 and 3, the projection 22 is arranged radially opposite the outer wall 11d of the second frame 11. Thus, the projection 22 drips a runoff on the wall 11d and the evacuation of pollutants can then be done by centrifugation along said wall without being able to enter through opening 20.

The upstream structure 16b has a lip 23 on which the projection 22 is formed. In particular, the lip 23 extends along an axial dimension while being inclined outwardly, the projection 22 extending along a radial dimension inside said lip.

The lip 23 has an axial dimension which is sufficient to allow it to form a reduced clearance at the interface with the wall 9 of the second member 2. Furthermore, the wall 9 has a concave shape, which makes it possible to form a baffle between the upstream structure 16b and the wall 9.

In FIG. 2, the upstream structure 16b comprises at least two concentric projections 22, and in particular three concentric projections 22, which are interconnected by a groove 24. In particular, the recirculation of the pollutants can then take place by gravity along throat 24.

In the embodiments shown, the upstream structure 16b further comprises a bead 25 which is placed bearing on the protuberance 8 to form a static seal, said bead being connected to the deflector 21 by a web 26 extending over an outer surface. of the fitting wall 10a.

Claims (15)

Sealing device (6) for a bearing comprising two members (1, 2) forming between them an interface (3) of relative rotation around an axis, said device comprising a first armature (10) intended to be associated with the one of the members (1, 2) and a second armature (11) integral with the other member (1, 2) by forming a passage (12) between the rotation interface (3) and the outside, the first armature (10) carrying a sealing element (16) which comprises a downstream structure (16a) disposed in the passage (12) and an upstream structure (16b) disposed outside of said passage, said sealing device being characterized in that the upstream structure (16b) has at least one annular projection (22) which extends from the side of the second armature (11), said projection being arranged to cause a stream propagating to drip at a distance from the passage (12) along said upstream structure. Sealing device (6) according to Claim 1, characterized in that the second armature (11) is intended to be associated with the other member (1, 2). Sealing device (6) according to Claim 1, characterized in that the second armature (11) is formed on the other member (1, 2). Sealing device (6) according to any one of Claims 1 to 3, characterized in that the passage (12) has an upstream opening (20) formed at the interface between the reinforcements (10, 11), the projection (22) being disposed externally to said opening. Sealing device (6) according to Claim 4, characterized in that the projection (22) has a clearance with the second reinforcement (11) whose dimension is greater than the dimension of the upstream opening (20). Sealing device (6) according to any one of Claims 1 to 5, characterized in that the projection (22) is arranged radially opposite an outer wall (11d) of the second armature (11). Sealing device (6) according to Claim 6 when dependent on Claim 4, characterized in that the opening (20) is delimited at least partially by the outer wall (11d). Sealing device (6) according to one of Claims 6 or 7, characterized in that the outer wall (11d) extends axially. Sealing device (6) according to any one of Claims 1 to 8, characterized in that the upstream structure (16b) has a lip (23) on which the projection (22) is formed. Sealing device (6) according to Claim 9, characterized in that the lip (23) extends along an axial dimension, the projection (22) extending along a radial dimension on the said lip. Sealing device (6) according to Claim 10, characterized in that the lip (23) is inclined externally, the projection (22) extending inside the said lip. Sealing device (6) according to any one of Claims 1 to 11, characterized in that it comprises at least two concentric projections (22) which are connected by a groove (24). Sealing device (6) according to any one of Claims 1 to 12, characterized in that the reinforcements (10, 11) form between them a sealing chamber (17) in which the passage (12) extends , the downstream structure (16a) of the sealing element (16) being disposed in said chamber. Sealing device (6) according to Claim 13, characterized in that the downstream structure (16a) has at least one lip (19a, 19b, 19c) which is in sealing interference with the second reinforcement (11). Rolling bearing comprising two members (1, 2) and rolling bodies (4) arranged in a rotation interface (3) formed between said members to allow their relative rotation around an axis, at least one side (5) of the rotation interface (3) being equipped with a sealing device (6) according to any one of claims 1 to 14, the first armature (10) being associated with one of the members (1, 2) by forming with the second armature (11) a passage (12) between the rotation interface (3) and the outside.