FR3117941A1 - Sealed suspension stopper device - Google Patents

Abstract

The device comprises a lower support cover 16, an upper support cover 14, and at least one bearing 18 disposed between said covers. The device further comprises at least one seal 19 arranged radially between a skirt of the support cover and the support cover 16. The seal 19 is mounted on one of the covers while being axially integral with said cover. . The seal 19 comprises a hooking portion 19b capable of cooperating by diametral interference with the other cover to ensure the axial retention of said other cover relative to said seal Reference: Figure 1

Description

Sealed suspension stopper device

Technical field of the invention

The present invention relates to the field of suspension thrust bearing devices used in particular for motor vehicles in the suspension struts of the steered wheels.

State of the prior art

A suspension thrust bearing device generally comprises a bearing forming an axial thrust bearing and upper and lower covers forming a housing for the rings of the bearing and making it possible to provide the interface between said rings and the neighboring elements.

The suspension thrust bearing device is arranged in the upper part of the suspension strut between a suspension spring and the vehicle body. The suspension spring is mounted around a shock absorber piston rod, the end of which is linked to the vehicle body. The suspension spring, of the helical spring type, bears axially directly or indirectly on the lower cover of the suspension thrust bearing device.

The suspension thrust bearing device makes it possible to transmit axial and radial forces between the suspension spring and the body of the vehicle while allowing a relative rotational movement between the lower cover and the upper cover resulting from a turning of the steering wheels of the vehicle and/or compression of the suspension spring.

Generally, the upper cover of the suspension thrust bearing device is provided with a plurality of hooks arranged on an external or internal skirt and adapted to interfere diametrically with a plurality of hooks of the lower cover. The hooks of each cover are spaced from each other in the circumferential direction.

The hooks form retaining means making it possible to axially retain the upper and lower cowls relative to each other. These hooks also form narrow passages in order to limit the intrusion of polluting particles radially between the outer or inner skirt of the upper cowl and the lower cowl.

However, a bump stop device is generally exposed to various types of pollution.

With such a device, the polluting particles can easily infiltrate between the external or internal skirt of the upper cover and the lower cover, then be directed towards the bearing and be introduced inside the latter.

The present invention aims to remedy this drawback.

The invention relates to a suspension thrust bearing device comprising a lower support cover, an upper support cover, and at least one bearing arranged between said covers.

According to a general characteristic, the device further comprises at least one seal disposed radially between a skirt of the upper support cover and the lower support cover.

The seal is mounted on one of the lower support and upper support covers, being axially integral with said cover.

By “axially integral with said cover”, it is meant that the seal is fixed with respect to said cover in the axial direction.

The seal comprises a hooking portion capable of cooperating by diametral interference with the other cover to ensure the axial retention of said other cover relative to said seal.

The seal limits the intrusion of dust, water and other types of polluting particles inside the bearing.

In addition, the seal makes it possible to ensure the axial retention of said other cover relative to the cover on which the seal is mounted. The shape of this cover is therefore simplified since it is no longer necessary to provide hooks on it for the axial retention of said other cover, this function being ensured by the seal.

Preferably, the attachment portion of the seal is capable of cooperating with at least one abutment surface of said other cowl extending in the direction of said cowl.

In a particular embodiment, the free end of the attachment portion of the seal is arranged axially above said abutment surface of said other cowl and dimensioned so as to be able to interfere diametrically with said abutment surface. In an alternative embodiment, the free end of the attachment portion of the seal is arranged axially below said abutment surface of said other cowl and dimensioned so as to be able to interfere diametrically with said abutment surface.

Said other cover may comprise at least one hook defining said abutment surface.

In one embodiment, said abutment surface forms an upper surface of said hook, in particular a radial upper surface. In an alternative embodiment, said abutment surface forms a lower surface of said hook, in particular a radial upper surface.

Said other cover may comprise an annular hook. In this case, said abutment surface of said other cover is annular in shape. Alternatively, said other cover may comprise a plurality of hooks spaced apart from each other in the circumferential direction, preferably in a regular manner. In this case, said other cover comprises a plurality of abutment surfaces.

Preferably, the attachment portion of the seal is annular in shape. This helps to obtain a good seal. Alternatively, however, it remains possible to provide a hooking portion comprising tongues spaced apart from each other in the circumferential direction, preferably in a regular manner.

Preferably, the attachment portion of the seal extends in the direction of said other cover to form a seal with said other cover. This sealing can be of the labyrinth or friction type.

According to a particular design, the attachment portion of the seal can extend obliquely in the direction of said other cover.

Preferably, the attachment portion of the seal is capable of cooperating with an upper surface of said hook of said other cover, in particular a radial upper surface.

According to a particular design, the seal may comprise a centering portion held axially between an abutment surface and a bearing surface of said cover. Retention of the seal is ensured by axial locking against said cover. It is not necessary to use an additional specific element to secure the seal to said cover.

In one embodiment, the bearing surface of said cowl is radial, and the abutment surface is also radial.

In another embodiment, the bearing surface of said cover is frustoconical or toroidal, and the abutment surface is radial. The bearing surface of said cover has an outer diameter which decreases on the side of the radial abutment surface.

Contact between the seal and the bearing surface of said cowl generates an axial force directed towards the radial abutment surface of the cowl which tends to maintain permanent axial contact between this abutment surface and the gasket. This favors the axial blocking of the seal and the maintenance of a good seal between the seal and said cover.

According to another design, the centering portion of the seal be maintained on said cover by diametrical interference.

According to a particular design, said cowl may comprise at least one hook extending radially in the direction of said other cowl and delimiting said radial abutment surface. Alternatively, the hook or hooks can delimit the support surface.

The centering portion of the seal may be annular in shape. Alternatively, the centering portion of the seal may comprise tabs spaced apart from each other in the circumferential direction, preferably in a regular manner.

In one embodiment, the lower free end of the centering portion of the seal bears against said cover. Alternatively, the upper free end of the centering portion of the seal bears against said cover.

In a first embodiment, the seal is arranged radially between the support cover and an outer skirt of the support cover which radially surrounds the support cover at least in part. The gasket thus forms an external seal. In this case, the centering portion of the seal radially surrounds the support cover.

Alternatively, in a second embodiment, the seal is arranged radially between the support cover and an internal skirt of the support cover which extends at least partially into the bore of said support cover. The gasket thus forms an internal seal.

In a third embodiment, the device comprises both an external seal and an internal seal as described above.

Brief description of figures

The present invention will be better understood on studying the detailed description of the embodiments, taken by way of non-limiting examples and illustrated by the appended drawings in which:

is a sectional view of a suspension thrust bearing device according to a first embodiment of the invention,

is a detail view of the ,

is a sectional view of a suspension thrust bearing device according to a second embodiment of the invention, and

is a detail view of the .

Detailed description of the invention

The suspension thrust bearing device 10 represented on the is adapted to be installed between a cup or upper support seat coming into contact against an element of the fixed frame of a motor vehicle, and a suspension spring of the helical type. On the , the device 10 is shown in an assumed vertical position.

The device 10, with axis 12, comprises an upper support cover 14, a lower support cover 16, and a rolling bearing 18 interposed axially between said covers. In the example illustrated, the covers 14, 16 are mounted in direct contact with the bearing 18 without the interposition of an intermediate element. Alternatively, the covers 14, 16 can be mounted in indirect contact with the bearing 18 with the interposition of an intermediate element.

As will be described in more detail below, the device 10 further comprises an external seal 19 to prevent the intrusion of pollutants towards the bearing 18. In the example illustrated, the seal 19 is fixed on the lower support cover 16.

As will also be described in more detail below, the seal 19 is capable of ensuring the axial retention of the upper support cover 14.

The upper support cover 14 may be made of a single piece, for example of plastic material, for example such as a polyamide PA 6.6, which may or may not be reinforced with glass fibers.

The support cover 14, with axis 12, comprises a radial portion 14a, an annular axial inner skirt 14b, and an annular axial outer skirt 14c radially surrounding the inner skirt. The radial portion 14a has an upper surface 15 intended to come opposite the upper bearing seat, and an opposite lower surface 17 in contact with the bearing 18. The upper and lower surfaces 15, 17 define the thickness of the radial portion 14a. In the example illustrated, the radial portion 14a has a stepped shape.

The outer skirt 14c of the support cover radially partly surrounds the lower support cover 16. The outer skirt 14c extends axially. The outer skirt 14c extends axially from the radial portion 14a. In the example shown, the outer skirt 14c extends a large diameter edge of the radial portion 14a.

The inner skirt 14b of the support cover extends inside the bore of the lower support cover 16. The inner and outer skirts 14b, 14c extend axially downward from the radial portion 14a. The inner skirt 14b extends a small diameter edge of the radial portion 14a.

The upper support cover 14 further comprises a plurality of outer hooks 14c disposed on the outer skirt 14c and extending radially inwards towards the lower support cover 16. In the example shown, the hooks 14d are spaced from each other in the circumferential direction. Alternatively, it might be possible to provide a ring hook. In the example shown, the eighth notes 14d are located axially at the free end of the outer skirt 14c. As a variant, the hook or hooks 14d could be located axially at a distance from this free end.

The bearing 18 is located entirely radially between the skirts 14b, 14c of the upper support cover 14. The bearing 18 comprises an upper ring 20 in contact with the upper support cover 14, a lower ring 22 in contact with the lower support cover 16, and a row of rolling elements 24, here balls, arranged between the tracks bearings formed on the rings. In the example shown, the bearing 18 is of the angular contact type. The upper ring 20 is in contact with the lower surface 17 of the radial portion 14a of the upper support cover. The lower ring 22 is in contact with an upper surface of the lower support cover 16.

The lower support cover 16 may consist of a single piece, for example of plastic material, for example such as a polyamide PA 6.6, which may or may not be reinforced with glass fibers.

The support cover 16, with axis 12, comprises an annular radial portion 28 in the form of a plate, and an annular axial skirt 30 which extends an edge of small diameter of the radial portion 28. The skirt 30 extends axially at the opposite the upper support cover 14 and the bearing 18. The skirt 30 allows the centering of the suspension spring. The radial portion 28 has a lower annular radial surface 28a delimiting a bearing surface for the suspension spring, and an upper surface 28b in contact with the lower ring 22 of the bearing and of complementary shape.

The support cover 16 comprises an annular outer hook 34 extending radially outwards in the direction of the outer skirt 14c of the upper bearing cover. The hook 34 extends here at the upper free end of the radial portion 28 of the support cover. Alternatively, the support cover 16 could comprise a plurality of outer hooks spaced from each other in the circumferential direction.

As indicated above, the external seal 19 is fixed to the lower support cover 16. The seal 19 is integral with the support cover 16. The seal 19 is annular. Seal 19 radially surrounds support cover 16. Seal 19 is mounted radially around the outer surface of support cover 16. Seal 19 is mounted radially around radial portion 28 of the support cover.

The seal 19 closes the radial space existing between the lower support cover 16 and the outer skirt 14c of the bearing cover.

As illustrated more visibly in , in this exemplary embodiment, a radial assembly clearance 35 remains between the seal 19 and the support cover 16. The radial clearance 35 is defined between the bore of the seal 19 and the cylindrical outer surface of the support cover 16 around which the gasket is mounted. In the free state, the inner diameter of the seal 19 is greater than the outer diameter of this cylindrical outer surface of the support cap. In other words, there is no radial interference between the seal 19 and this cylindrical outer surface of the support cover.

The seal 19 is mounted axially between the lower radial surface 34a of the hook 34 and a frustoconical surface 36 made on the outer surface of the support cover. The frustoconical surface 36 has an outer diameter which decreases on the side of the lower surface 34a. The tapered surface 36 is provided on the radial portion 28 of the support cover.

The seal 19 is held axially between the frustoconical surface 36 and the lower surface 34a of the hook. The frustoconical surface 36 forms a lower bearing surface for the seal 19 and the lower surface 34a of the hook forms an upper abutment surface.

The hook 34 of the support cover has an outside diameter greater than the inside diameter of the seal 19, in this case the diameter of the bore of the seal. The hook 34 ensures the axial retention of the seal 19. The seal 19 is mounted on the support cover 16 by axial thrust from top to bottom. So as to facilitate this assembly, the upper surface of the hook 34 is of frustoconical shape.

The seal 19 is provided with an annular centering portion 19a mounted radially around the support cover 16. The seal 19 is also provided with an annular hooking portion 19b which extends in the direction of the outer skirt 14c of the support cover. The attachment portion 19b here extends obliquely downwards.

The free end of the attachment portion 19b is arranged axially above the hooks 14d of the outer skirt of the upper support cover. The hooking portion 19b has an outer diameter greater than the inner diameter of the hooks 14d so as to be able to interfere diametrically with the hooks 14d in the event of relative axial displacement of the support cover 14 and the support cover 16.

The attachment portion 19b of the seal thus cooperates with means for retaining the support cover 16 formed by the hooks 14d. Each hook 14d comprises an upper abutment surface 38 which comes axially opposite the free end of the attachment portion 19b of the seal. In the event of relative axial displacement of the bearing cap 14 and of the support cap 16, the axial retention of these two elements is achieved by the axial contact between the free end of the attachment portion 19b of the seal and the abutment surface 38 of each hook 14d which exists given the diametral interference existing between the hooking portion 19b and the hooks.

The abutment surface 38 of each hook 14d is oriented axially upward. In this example, the abutment surface 38 of each hook 14d is radial. Alternatively, the abutment surface could have another shape, for example frustoconical.

In the illustrated embodiment, the attachment portion 19b of the seal remains axially at a distance from the abutment surfaces 38 of the hooks of the upper support cover. As a variant, the attachment portion 19b of the seal could come axially to bear against the hooks 14d of the upper support cover.

As indicated above, the hooking portion 19b extends in the direction of the outer skirt 14c of the support cover. The attachment portion 19b extends in the direction of the outer skirt 14c up to the vicinity thereof to form a labyrinth seal with said skirt. In this example, the attachment centering portion 19b therefore remains radially at a short distance from the outer skirt 14c of the support cover. Alternatively, the attachment portion 19b could cooperate by friction with the outer skirt 14c.

The attachment portion 19b of the seal radially surrounds the centering portion 19a. The centering portion 19a is mounted radially around the radial portion 28 of the support cover. The centering portion 19a extends axially. The centering portion 19a delimits the bore of the seal 19.

The centering portion 19a bears axially against the tapered surface 36 of the support cover. The lower free end of the centering portion 19a bears against the frustoconical surface 36. The centering portion 19a is in static sealing contact with the frustoconical surface 36 of the support cover over 360°.

Axially on the opposite side, the centering portion 19a of the seal is axially in abutment against the lower surface 34a of the hook of the support cover. The upper end of the centering portion 19a abuts axially against the lower surface 34a. In the illustrated embodiment, the centering portion 19a is in static sealing contact with the lower surface 34a of the hook of the support cover over 360° given the annular shape of the hook 34.

The seal 19 is also provided with an annular heel 19c from which the centering portion 19a and the hooking portion 19b project. In other words, the heel 19c connects the centering portion 19a and the attachment portion 19b. Centering portion 19a extends radially inward from heel 19c and axially downward. The hooking portion 19b extends obliquely downwards from the heel 19c in the direction of the outer skirt 14c of the support cover. The centering portion 19a and the hooking portion 19b extend projecting downward relative to a lower surface of the heel 19c.

In this embodiment, the centering portion 19a and the attachment portion 19b of the seal radially delimit an outer annular chamber 40. The chamber 40 is open axially downwards, i.e. axially on the side of the support cover. The chamber 40 is oriented axially downward. The chamber 40 is delimited axially by the heel 19c.

The chamber 40 delimited by the seal 19 makes it possible to limit the intrusion of polluting particles between the support 16 and support 14 caps likely to be directed towards the bearing 18. In addition, the chamber 40 makes it possible to obtain a recirculation of the water directed upwards in the direction of the bearing 18 which is returned downwards by the hooking portion 19b.

The seal 19 can for example be made of a rigid material, for example polyoxymethylene (POM). Alternatively, the seal 19 can also be made of a less rigid material, for example nitrile or elastomer. The seal 19 is advantageously made in one piece, for example by molding.

The exemplary embodiment illustrated in , on which the identical elements bear the same references, differs in particular from the first embodiment by the design of the seal.

Seal 50 radially surrounds support cover 16. Seal 50 is mounted radially around the outer surface of support cover 16. Seal 50 is mounted radially around radial portion 28 of the support cover.

The seal 50 closes the radial space existing between the lower support cover 16 and the outer skirt 14c of the bearing cover.

As illustrated more visibly in , a radial assembly clearance 60 remains between the seal 50 and the support cover 16.

The seal 50 is mounted axially bearing against a radial surface 52 of an annular protuberance 54 provided on the outer surface of the support cover. The protrusion 54 is formed on the radial portion 28 of the support cover.

The seal 50 is provided with an annular centering portion 50a mounted radially around the support cover 16. The seal 50 is also provided with an annular hooking portion 50b which extends in the direction of the outer skirt 14c of the support cover. The attachment portion 50b here extends obliquely downwards.

The layout and arrangement of the attachment portion 50b of the seal relative to the hooks 14d and to the outer skirt 14c of the support cover are identical to those described for the first example.

The attachment portion 50b of the seal radially surrounds the centering portion 50a. The centering portion 50a is mounted radially around the radial portion 28 of the support cover. The centering portion 50a here extends obliquely inwards and axially upwards.

The centering portion 50a extends obliquely inwards and axially upwards. The centering portion 50a is flexible in the radial direction.

The centering portion 50a of the seal bears against a protrusion 58 of the support cover which extends radially outwards in the direction of the outer skirt 14c of the upper support cover. The protrusion 58 extends here at the upper free end of the radial portion 28 of the support cover. The protrusion 58 here has a rounded shape.

The upper free end of the centering portion 50a bears against the protuberance 58. The upper free end of the centering portion 50a bears radially against the protuberance 58. In this example, the upper free end of the centering portion 50a delimits the bore of the seal 50. The centering portion 50a is in static sealing contact with the protrusion 58 of the support cover over 360°.

Axially on the opposite side, the centering portion 50a of the seal is axially in abutment against the radial surface 52 of the protuberance 54 of the support cover. The lower end of the centering portion 50a abuts axially against the radial surface 52.

The seal 50 is also provided with an annular heel 50c from which the centering portion 50a and the hooking portion 50b project. In other words, the heel 50c connects the centering portion 50a and the hooking portion 50b. The centering portion 50a extends obliquely inwards from the heel 50c and axially upwards. The attachment portion 50b extends obliquely downwards from the heel 50c in the direction of the outer skirt 14c of the support cover.

The seal 50 is mounted on the support cover 16 by axial thrust from top to bottom. After assembly, the upper free end of the centering portion 50a of the seal is deformed radially outwards by contact against the protuberance 58 of the support cover. In the free state, the inner diameter of the centering portion 50a of the seal is smaller than the outer diameter of the protuberance 58. In this embodiment, the seal 50 is axially secured to the support cover by radial interference between the centering portion 50a of the seal and the protuberance 58 of the support cover, and not by axial abutment between two abutment and bearing surfaces of the support cover as is the case in the first example of achievement. Alternatively, the seal could be secured axially to the support cover by any other appropriate means, for example by overmoulding, etc.

In this example, the radial assembly clearance 60 is defined between the part of the centering portion 50a of the seal 50 which remains at a distance from the outer surface of the support cover 16 and this outer surface. The radial assembly clearance 60 extends axially over the entire axial height of the centering portion 50a of the seal, with the exception of the bearing zone of the upper free end of the centering portion 50a with the support cover.

The seal 50 can be made of a material of the same nature as the seal 19.

In the embodiments illustrated, the attachment portion 19b, 50b of the seal extends obliquely downwards. Alternatively, depending on the arrangement of the hook or hooks 14d on the outer skirt 14c of the support cover, the hooking portion 50b could extend radially in the direction of this skirt.

In the embodiments illustrated, the seal 19, 50 comprises the hooking portion 19b, 50b which extends in the direction of the support cap 14 to cooperate with the latter and fulfill a sealing function in addition to the axial restraint function of the support cover. Alternatively, the seal 19, 50 may further comprise at least one additional sealing lip extending in the direction of the bearing cap 14 to form a labyrinth type and/or friction seal.

In the embodiments illustrated, the external seal 19, 50 is mounted on the support cover 16. Alternatively, the external seal could be mounted on the support cover. In this case, the seal is axially secured to the bearing cap, and the attachment portion of the seal is capable of cooperating with the support cap, for example with one or more hooks of the support cap, to ensure the axial retention of the support cover relative to the support cover. In this variant, the free end of the attachment portion of the seal is arranged axially below the hook or hooks of the support cover and cooperates with the lower surface or surfaces of this or these hooks.

In the embodiments illustrated, the device comprises a single external seal located radially between the support cover 16 and the outer skirt 14c of the support cover. Alternatively or in combination, the device may comprise an internal seal located radially between the support cover 16 and the internal skirt 14c of the support cover. This internal seal can be of a similar design to the external seal or of a different design. This internal seal can be mounted on the support cover 16, or alternatively on the internal skirt 14c of the support cover.

In the embodiments illustrated, the upper surface 15 of the support cover is oriented perpendicular to the axis 12 of the device. As a variant, the upper surface 15 of the support cover could be oriented perpendicularly with respect to an axis forming a non-zero angle with the axis 12 of the device.

In the embodiments illustrated, the device comprises an angular contact rolling bearing provided with a row of balls. The device may include other types of rolling bearings, for example a bearing with four contact points and/or with at least two rows of balls. The rolling bearing may include other types of rolling elements, for example rollers. In another variant, the bearing of the device may comprise a sliding bearing devoid of rolling elements and provided with one or more rings.

Claims (10)

Suspension thrust bearing device comprising a lower support cover (16), an upper bearing cover (14), and at least one bearing (18) arranged between the said covers, characterized in that it further comprises at least one seal (19; 50) disposed radially between a skirt of the upper support cover and the lower support cover (16), the seal (19; 50) being mounted on one of the support covers lower and upper support while being axially integral with said cover, the seal (19; 50) comprising a hooking portion (19b; 50b) capable of cooperating by diametrical interference with the other cover to ensure axial retention said other cover relative to said seal. Device according to Claim 1, in which the attachment portion (19b; 50b) of the seal is capable of cooperating with at least one abutment surface (38) of the said other cover extending in the direction of the said cover. Device according to Claim 2, in which the free end of the gripping portion (19b; 50b) of the seal is arranged axially above, or below, the said abutment surface (38) of the said other cover and dimensioned so as to be able to interfere diametrically with said abutment surface (38). Device according to Claim 2 or 3, in which the said other cover comprises at least one hook (14d) defining the said abutment surface (38). Device according to any one of the preceding claims, in which the hooking portion (19b; 50b) of the seal extends in the direction of the said other cover to form a seal with the said other cover. Device according to any one of the preceding claims, in which the attachment portion (19b; 50b) of the seal extends obliquely in the direction of the said other cover. Device according to any one of the preceding claims, in which the seal (19; 50) comprises a centering portion (19a; 50a) held axially between an abutment surface (34a) and a bearing surface (36 ) of said cover. Device according to any one of the preceding claims, in which the seal (19; 50) is arranged radially between the support cover (16) and an outer skirt (14c) of the support cover which radially surrounds at least partly the support cover (16). Device according to Claim 8 dependent on Claim 7, in which the centering portion (19a; 50a) of the seal radially surrounds the support cover (16). Device according to any one of Claims 1 to 7, in which the seal is arranged radially between the support cover (16) and an internal skirt (14b) of the support cover which extends at least partly into the bore of said support cover (16).