阅读说明：本技术 机动车辆的悬架止动件 (Suspension stop for a motor vehicle ) 是由 A·博诺代 于 2019-07-25 设计创作，主要内容包括：本发明涉及一种包括上杯(1)和下杯(2)的悬架止动件,所述上杯和下杯布置成其间形成至少一个环形腔室(6),该环形腔室由两个壁(1a,2a)横向限定,该腔室具有形成在分别来自一个壁(1a,2a)的支承表面(1b,2b)之间的外侧部分(6e),所述悬架止动件包括具有两个互补支承表面(13)的外侧密封元件(8e),所述外侧密封元件安装成在外侧部分(6e)中可移动地位于稳定位置和受应力位置之间,在稳定位置,所述互补支承表面与所述外侧部分的支承表面相距一定距离,在所述受应力位置,在所述外侧密封元件上进行支承,其中所述互补支承表面被分别迫使与所述支承表面中的一者相抵,以确保所述外侧部分(6e)在所述外侧部分的界面处的密封。(The invention relates to a suspension stop comprising an upper cup (1) and a lower cup (2) arranged so as to form therebetween at least one annular chamber (6) delimited laterally by two walls (1a, 2a) and having an outer portion (6e) formed between bearing surfaces (1b, 2b) respectively from one wall (1a, 2a), said suspension stop comprising an outer sealing element (8e) having two complementary bearing surfaces (13) mounted so as to be movable in the outer portion (6e) between a stable position at a distance from the bearing surfaces of the outer portion and a stressed position at which bearing is carried out on the outer sealing element, wherein the complementary bearing surfaces are respectively forced against one of the bearing surfaces, to ensure the sealing of the outer portion (6e) at the interface of the outer portion.)

1. A suspension stop for a motor vehicle, comprising an upper cup (1) and a lower cup (2) mounted for relative rotation about an axis (A), the upper and lower cups being arranged to form therebetween at least one annular chamber (6) laterally defined by two walls (1a, 2a) respectively from one of the cups, the chamber having an outer portion (6e) formed between bearing surfaces (1b, 2b) respectively from one of the walls (1a, 2a), the suspension stop being characterized in that it comprises an outer sealing element (8e) having two complementary bearing surfaces (13) mounted so as to be movable in the outer portion (6e) between a stable position and a stressed position bearing on the outer sealing element, in the stable position, the complementary bearing surfaces are arranged at a distance from the bearing surfaces (1b, 2b) of the outer portions, in the stressed position the complementary bearing surfaces being respectively forced against one of the bearing surfaces to ensure sealing of the outer portion (6e) at the interface of the outer portions.

2. The suspension stop according to claim 1, characterized in that the outer portion (6e) is oriented downwards, the outer sealing element (8e) rising in a stressed position.

3. The suspension stop according to any of claims 1 or 2, characterized in that the bearing surfaces (1b, 2b) are each inclined by an angle θ with respect to the axis of rotation (a) ₁And theta ₂。

4. The suspension stop of claim 3, wherein the angle θ ₁And theta ₂Is arranged substantially such that: theta ₁＝-θ ₂。

5. The suspension stop according to any of claims 1-4, characterized in that one of the bearing surface (1b, 2b) and the complementary bearing surface (13) is substantially planar, while the other of the bearing surface (1b, 2b) and the complementary bearing surface (13) is curved.

6. The suspension stop according to any of claims 1-5, characterized in that at least one bearing surface (2b) is delimited by a housing (14), wherein the outer side sealing element (8e) is held in a stable position in the outer side portion (6 e).

7. The suspension stop according to any of claims 1-6, characterized in that the outboard sealing element (8e) has a sealing surface (15) on which the complementary bearing surface (13) is formed.

8. The suspension stop according to claim 7, characterized in that the sealing surface (15) has a convex geometry forming curved complementary bearing surfaces (13) on either side.

9. The suspension stop according to any of claims 7 or 8, characterized in that the outboard sealing element (8e) has a bearing surface (18) opposite the sealing surface (15).

10. The suspension stop according to claim 9, characterized in that the bearing surface (18) has a concave geometry.

11. Suspension stop according to any of claims 1 to 10, characterized in that the outer portion (6e) has an opening (16) formed between two walls (1c, 2c) respectively from the cups (1, 2) forming a reduced blocking gap (17) of the opening therebetween.

12. The suspension stop according to claim 11, characterized in that the two walls (1c, 2c) extend substantially radially to form an axial gap (17) around the outer sealing element (8 e).

13. The suspension stop according to any of claims 11 or 12, characterized in that the opening (16) is located axially below the outer sealing element (8 e).

14. The suspension stop according to any of claims 1 to 13, characterized in that the chamber (6) has an inner portion (6i) provided with an inner sealing element (8i) arranged between the walls (1a, 2a) of the cups (1, 2).

15. The suspension stop according to claim 14, characterized in that the wall (2a) has an annular groove (9) in which the crown (10) of the inboard sealing element (6i) is arranged, the inboard sealing element having a segment (11) for interacting with the other wall (1 a).

16. Suspension stop according to claim 15, characterized in that the crown (10) forms an axial and/or radial gap (12) with the annular groove (9) to enable displacement of the crown in the annular groove.

17. The suspension stop according to any of claims 1 to 16, characterized in that the outer sealing element (8e) and possibly the inner sealing element (8i) are made of a rigid thermoplastic material.

Technical Field

The invention relates to a suspension stop for a motor vehicle, which is designed in particular to be integrated in a telescopic suspension strut of a drive wheel of the motor vehicle.

Background

The suspension stopper to which the present invention is applied includes: an upper stationary cup designed to be attached to a body of a vehicle; a lower swivel cup including a bearing for a suspension spring; and rolling bodies disposed between the upper stationary cup and the lower rotating cup to allow the upper stationary cup and the lower rotating cup to relatively rotate. In one variant, the upper stationary cup and the lower rotating cup may be mounted in a smooth manner with respect to rotation, with or without friction washers interposed between them.

In particular, the invention applies to suspension stops in which the upper and lower rotating cups are arranged so as to form between them at least one annular chamber in which a sealing element is arranged, and this prevents, on the one hand, the leakage of lubricant in the space between the cups, and, on the other hand, the contamination of said space by contaminants coming from the outside.

To achieve this, it is known to provide a sealing element in the form of an annular crown which is mounted in an annular groove formed for this purpose in the sealing chamber.

Document WO2009/019340 proposes a sealing element arranged in a sealed chamber in frictional contact with each of the cups and mounted so as to be movable with respect to at least one cup. Thus, even in the case of a deformation of the suspension stop due to the effect of the stresses applied, a compromise between the sealing function and the resulting torque is obtained in a particularly satisfactory manner.

However, suspension stops may be subject to the emission of external contaminants, such as water and/or mud, particularly when the vehicle is used in inclement weather on muddy ground and/or puddle-covered ground.

In such a case, contaminants may be sprayed at high velocity onto the movable sealing element, which may move within the sealed chamber, thereby breaking the frictional contact and allowing contaminants to enter the chamber.

This injection is particularly simulated by introducing a jet of pressurized liquid into the opening of the sealed chamber during the testing phase of the suspension stop.

Disclosure of Invention

The object of the present invention is to improve the prior art by proposing in particular a suspension stop improving the sealing, in particular by protecting the chamber from the entry of such a jet of contaminants.

To this end, the invention proposes a suspension stop for a motor vehicle, comprising an upper cup and a lower cup mounted in relative rotation about an axis, the upper and lower cups being arranged so as to form therebetween at least one annular chamber defined transversely by two walls respectively from one of the cups, the chamber having an outer portion formed between bearing surfaces of the respective walls, the suspension stop comprising an outer sealing element having two complementary bearing surfaces mounted so as to be movable in the outer portion between a stable position, in which the complementary bearing surfaces are at a distance from the bearing surfaces of the outer portion, and a stressed position, in which bearing is carried out on the outer sealing element, wherein the complementary bearing surfaces are forced against a respective one of the bearing surfaces, to ensure sealing of the outer portion at the interface of the outer portion.

Drawings

Other features and advantages of the invention are set forth in the following description with reference to the drawings, in which:

figure 1 shows an axial cross-section of a suspension stop according to an embodiment of the invention,

figure 1a is an enlarged partial view of figure 1 centered on the right side of the sealed chamber,

FIG. 1b is an enlarged partial view of FIG. 1a, wherein FIG. 1b more particularly shows an outer portion of the sealed chamber;

FIG. 2 is a view similar to FIG. 1a of a suspension stop according to another embodiment of the present invention;

figure 3a is a view similar to figures 1a and 2 of a suspension stop according to another embodiment of the invention,

fig. 3B is a partial enlarged view similar to fig. 1B of region B of fig. 3 a.

Detailed Description

In this description, the terms for spatial position are given with reference to the axis of rotation a of the suspension stop (vertical in fig. 1). In particular, the term "inner" relates to an arrangement close to said axis a, and the term "outer" relates to an arrangement at a distance from said axis a. Furthermore, the terms "upper" and "lower" relate to the arrangement of the suspension stop as shown in the figures, and the terms "inner" and "outer" relate to the arrangement relative to the inside of the stop.

The wheels, in particular the drive wheels, of a motor vehicle are mounted on the chassis by means of suspension struts which enable the suspension of the vehicle body to be suspended relative to the ground. For this purpose, the suspension strut usually comprises a shock absorber, a suspension spring and a suspension stop, on which the spring is supported directly or indirectly.

With reference to the figures, the following describes a suspension stop comprising a fixed upper cup 1, designed to be connected to the bodywork of a vehicle by means of a filter unit, and a rotating lower cup 2, comprising a support 3 for a suspension spring, said upper and lower cups being mounted in rotation with respect to each other about an axis a. Thus, when the spring is tensioned in compression and braking, the winding of the lower cup's coil spring onto itself changes, which results in rotation of the lower cup 2. Furthermore, the rotation of the wheel also causes the rotation of the lower cup 2.

In a known manner, the suspension stop may comprise rolling bodies arranged between the upper and lower cups to enable the upper and lower cups to rotate relatively about the axis a. For this purpose, the upper cup 1 and the lower cup 2 can each comprise a washer, in particular made of stamped sheet metal, which is provided with a lower roller table and an upper roller table, respectively, for the rolling bodies. In one variant, the upper cup 1 and the lower cup 2 may be mounted in a smooth manner with respect to each other in rotation, with or without friction washers interposed between them.

The suspension stop also comprises two covers, in particular covers made by moulding a rigid thermoplastic material (for example made of polyamide 6.6). These are respectively a cover 4 connected to the upper washer to be interposed between the chassis and said upper washer, and a support 5 connected below the lower washer, said support comprising a spring support 3. These covers 4, 5 can in particular restore the spring force and possibly the crash stop.

The upper and lower cups 1, 2 are arranged so as to form therebetween at least one annular chamber 6, this annular chamber 6 being delimited laterally by two walls 1a, 2a, respectively, from one of said cups.

In the embodiment shown, the cap 4 comprises an annular outer skirt 7 on which extends an axially outer wall 1a, the support 5 having an axially outer wall 2a defining with the axially outer wall 1a of said outer skirt an annular sealing chamber 6.

In particular, the annular chamber 6 has a radial clearance so as to enable the lower cup 2 to rotate with respect to the upper cup 1 without any interference between the upper and lower cups.

In order to prevent leakage of lubricant provided in the space between the upper cup 1 and the lower cup 2 on the one hand and contamination of said space by external contaminants on the other hand, at least one sealing element 8i, 8e is arranged in the annular chamber 6.

According to one embodiment, the chamber 6 may comprise a viscous substance to improve the sealing effect provided by the sealing elements 8i, 8 e. In particular, the substance may also have a lubricating function for the displacement of the sealing elements 8i, 8e in the chamber 6.

In the figure, the chamber 6 has an inner portion 6i equipped with an inner sealing element 8i, the inner sealing element 8i being arranged between the walls 1a, 2a of the upper and lower cups 1, 2.

In an advantageous manner, the inner sealing element 8i is mounted so as to be movable with respect to each of the upper and lower cups 1, 2, which makes it possible to achieve a particularly satisfactory compromise between the sealing function and the torque induced, even in the case of deformation of the suspension stop under the influence of the stresses applied.

According to another embodiment, the inner sealing element 8i may be in frictional contact with the upper and lower cups 1, 2 in order to improve the sealing function of the elements 8i, 8 e.

One of the axial walls 1a, 2a has an annular groove 9 in which a crown 10 of an inner sealing element 8i is arranged, said inner sealing element having a segment 11 interacting with the other of said walls 1a, 2 a.

In the embodiment shown, an annular groove 9 is formed in the axial wall 2a of the lower cup 2. In a variant, the groove 9 may be formed on the axial wall 1a of the upper cup 1.

The crown 10 forms an axial and/or radial gap 12 with the slot 9, so as to enable free displacement of said crown in said slot. To achieve this, the crown 10 may in particular have a geometry that is complementary in particular to the geometry of the slot 9, with a reduced radial and/or axial dimension.

In the embodiment shown, the crown 10 and the trough 9 form a gap 12 which extends in a U-shape at the interface between said crown and said trough, thereby forming a sealing barrier.

The groove 9 and the crown 10 have a radial depth and a length, respectively, which are sufficiently large to ensure a good effect of sealing the septum. Furthermore, the interacting section 11 is radially supported on the axial wall 1a of the outer cup 1.

When the vehicle is used in bad weather on muddy ground and/or on ground covered by puddles, the jet of water and/or mud may be ejected at high speed onto the sealing element 8i, which, due to its movability, may be displaced in the sealing chamber 6, resulting in a break of the frictional contact, so that said contaminants can subsequently enter said chamber.

In order to protect the sealing element 8i from such a jet of external contaminants, the sealing chamber 6 has an outer portion 6e formed between the bearing surfaces 1b, 2b of the respective walls 1a, 2a and wherein the outer sealing element 8e is arranged in this outer portion.

In the embodiment shown, both sealing elements 8i, 8e have an annular geometry. Furthermore, the sealing elements 8i, 8e are made in particular of a rigid thermoplastic material, for example of polyoxymethylene, polyethylene, polypropylene, polyamide 6, polyamide 6.6, polyamide 11 or polyamide 12.

The outer sealing element 8e has a sealing surface 15 on which two complementary bearing surfaces 13 are formed, and is mounted so as to be movable in the outer portion 6e between a stable position, in which the complementary bearing surfaces 13 are arranged at a distance from the bearing surfaces 1b, 2b, and a stressed position, in which bearing (in particular caused by a jet of external contaminants) is carried out on said outer sealing element 8e, wherein the complementary bearing surfaces 13 are pressed against the bearing surfaces 1b, 2b, respectively, to ensure sealing of the outer portion 6e at the interface of said outer portions.

Therefore, as shown, the outer sealing element 8e is in contact with only one of the upper and lower cups 1, 2 without the spray of external contaminants, so as not to cause additional friction torque to the hang-off stop. Furthermore, the sealing element 8e in the stable position forms a further sealing barrier in the chamber 6, which further improves the sealing of said chamber.

When the jet of external contaminants comes into contact with the outer sealing element 8e, it moves to the stressed position to make a sealing contact and form a barrier against said jet of external contaminants.

Furthermore, after the pollutant jets, the outer sealing element 8e is no longer stressed and then returns to the stable position, which makes it possible to break the sealing contact between the bearing surfaces 1a, 2a and the complementary bearing surface 13, thus not causing a friction torque between the two jets. Furthermore, in the event of contaminants passing over the outer portion 6e, the return of said outer sealing element to a stable position enables these potential contaminants to flow out of the chamber 6.

In the embodiment shown, the outer portion 6e is oriented downwards and the sealing element 8e is raised in a stressed position. The return of the sealing element 8e to the stable position is therefore performed by gravity.

At least one bearing surface 1b, 2b is delimited by a housing 14, wherein a sealing element 8e is held in a stable position in an outer portion 6e to ensure centering thereof in said outer portion while limiting displacement thereof. In the figure, the housing 14 is formed on the axial wall 2a of the lower cup 2 so as to extend below the support surface 2 b. Furthermore, another bearing surface 1b is formed on the free end of the skirt 7.

With respect to FIGS. 1b and3b, the bearing surfaces 1b, 2b are respectively inclined by an angle theta relative to the rotation axis A ₁And theta ₂. In an advantageous manner, the angle θ ₁And theta ₂Is substantially arranged so that theta ₁＝-θ ₂This makes it possible to ensure symmetry between the respective supports of the complementary bearing surfaces 13 on each bearing surface 1b, 2 b.

One of the bearing surfaces 1b, 2b and the complementary bearing surface 13 is substantially planar and the other of the bearing surfaces 1b, 2b and the complementary bearing surface 13 is curved. Thus, when the element 8e is in the stressed position, sealing is ensured by forcing the toroidal surface against the frustoconical surface. In particular, the sealing element 8e may be slightly deformable so as to be able to displace at a position where the bearing surfaces 1b, 2b and the complementary bearing surface 13 are forced together.

In fig. 1, 1a, 1b and 2, the bearing surfaces 1b, 2b are substantially planar and the complementary bearing surface 13 is curved. In particular, the sealing surface 15 has a convex geometry so as to form curved complementary bearing surfaces 13 on either side.

In fig. 3a and 3b, the bearing surfaces 1b, 2b are curved and the complementary bearing surface 13 is substantially planar.

The outer portion 6e has an opening 16 formed between the two respective walls 1c, 2c of the cups 1, 2. In particular, the walls 1c, 2c form a reduced baffle gap 17 of the opening 16 between them, so as to form a barrier designed to reduce the speed and/or energy of the pollutant jets entering through said opening.

The walls 1c, 2c extend substantially radially to form an axial gap around the outer sealing element 8 e. Furthermore, the outer sealing element 8e has a support surface 18 opposite the sealing surface 15, and the opening 16 opens inwardly towards the support surface. Preferably, the opening 16 is positioned axially below the outer sealing element 8 e.

Thus, when a jet of external pollutants enters through the opening 16, the position of the gap 17 makes it possible to direct said jet onto the support surface 18, concentrating the pressure on said support surface, so as to be able to correctly position the element 8e in its stressed position.

In an advantageous manner, as shown in fig. 1, 1a, 1b, 3a and 3b, the support surface 18 has a concave geometry, which makes it possible to improve the guidance of the jet of pollutants on this geometry.