This is a Non-Provisional Patent Application, filed under the Paris Convention, claiming the benefit of Europe (EP) Patent Application Number 14306532.4, filed on 30 Sep. 2014 (30.09.2014), which is incorporated herein by reference in its entirety.
The invention concerns a suspension bearing device, in particular of the MacPherson type (“MacPherson Suspension Bearing” or MSBU). The invention also concerns a motor vehicle equipped with such a suspension bearing device. The invention also concerns a method for manufacturing such a suspension bearing device. The field of the invention is that of suspension systems, particularly for motor vehicles.
In a known manner, a suspension system comprises a strut supporting an axle and a wheel of a vehicle. A suspension bearing device is placed in the top portion of the strut, opposite to the wheel and the ground, between a suspension spring and an upper member secured to the body of the vehicle. The spring is placed around a damper piston rod of which the end may be secured to the body of the vehicle.
WO-A-2011/012484 discloses an example of a suspension bearing device, comprising a rolling bearing, a lower cup and an upper cup. The suspension bearing device is configured for transmitting loads between a suspension spring and the body of the vehicle, while allowing a relative angular movement between the races of the rolling bearing. The lower cup includes a metal stiffening insert to have a high enough rigidity and to allow the transmission of high axial and radial loads. The lower cup also includes a flexible member, comprising an annular ring and two seals connected to the annular ring by axial studs.
The seals are designed to protect the bearing against infiltrations of water or pollutant particles, while the annular ring is designed to absorb in part the vibrations and shocks generated by the suspension spring. However, inconvenient noise can be generated in case of important vibrations. In that case, the axial damping effect of the annular ring is not fully satisfactory due to its small thickness. Besides, the suspension spring can radially collide with the rigid body of the lower cup. Consequently, the car manufacturer usually arranges an additional damping component, namely a rubber insulator, between the suspension bearing device and the suspension spring.
The aim of the invention is to provide an improved suspension bearing device.
To this end, the invention concerns a suspension bearing, comprising a suspension bearing device, comprising a bearing, a lower cup and an upper cup centered on a central axis, the lower cup having a body including a tubular axial portion and an annular outward radial portion, the lower cup being provided with at least one seal disposed in sealing contact with the upper cup, characterized in that the lower cup is provided with a damper pad having a cambered shape delimited by: an inner portion which is connected to the seal through the radial portion of the body ; and a convex outer portion for bearing a suspension spring.
Thanks to the invention, the behavior of the suspension bearing device is improved under important vibrations. The damper pad absorbs the vibrations generated by the suspension ring more efficiently than a thin plane ring. The overall performance of the suspension bearing device is improved, with a better load repartition. Moreover, the invention avoids using an additional damping component, which reduces the assembly costs for the car manufacturer.
According to further aspects of the invention which are advantageous but not compulsory, the suspension bearing device may incorporate one or several of the following features:
The invention also concerns a motor vehicle, equipped with a suspension bearing device as mentioned here-above.
The invention also concerns a method for manufacturing a suspension bearing device as mentioned here-above. The method includes at least the following steps:
According to further aspects of the invention which are advantageous but not compulsory, the manufacturing method may incorporate one or several of the following features:
The invention will now be explained in correspondence with the annexed figures, and as an illustrative example, without restricting the object of the invention. In the annexed figures:
Strut 1 supports an axle and a wheel of a vehicle, not shown for simplification purposes. Strut 1 extends along a central axis X1 placed in a substantially vertical direction when the wheel of the vehicle rests on a flat ground. Strut 1 comprises a damper rod 2, a suspension spring 3 and the suspension bearing device 10. Rod 2 and spring 3 are partially and schematically shown on
Device 10 has an overall a shape of revolution about axis X1. Device 10 comprises a rolling bearing 20, a lower cup 30 and an upper cup 40. Bearing 20 is positioned in a chamber 12 delimited between cups 30 and 40. Device 10 forms a compact assembly, which is practical to handle.
Bearing 20 is an angled-contact rolling bearing. Bearing 20 includes a bottom and outer race 21, a top and inner race 22, rolling elements 23 and a cage 24. Rolling elements 23 are balls placed in cage 24, in angled contact between the outer race 21 and the inner race 22. As an alternative example, rolling elements 23 may be rollers. Races 21 and 22 are preferably made of metal and formed by stamping. In this case, each of the races 21 and 22 forms a raceway for the rolling elements 23 within bearing 20. Bearing 20 forms an axial stop within device 10, between cups 30 and 40. Thus, device 10 forms an axial stop within strut 1. Bearing 20 allows, on the one hand, a relative pivoting between races 21 and 22 about the axis X1 and, on the other hand, an inclination of rod 2 relative to the body of the vehicle.
Lower cup 30 forms bearing means for suspension spring 3. Lower cup 30 comprises a body 50 and a flexible member 60, which are centered on axis X1. Lower cup 30 forms a two-part assembly devoid of stiffening inserts. Alternatively, body 50 of lower cup 30 may include one or several stiffening inserts.
Body 50 comprises a tubular axial portion 51 and an annular outward radial portion 52. Portion 52 extends from portion 51 opposite axis X1. Spring 3 is received in a rounded corner 53, formed between axial portion 51 and radial portion 52. Portion 51 forms a guide for spring 3, both axially and radially, while portion 52 forms an axial support for spring 3, with pad 70 interposed between body 50 and spring 3. Several axial channels 58 and 59 are formed through portion 52, each in a direction D1 parallel to axis X1. Those channels 58 and 59 are distributed around axis X1, such that a same radial plane includes both an external channel 58 and an internal channel 59 on each side of axis X1, as shown on
Flexible member 60 comprises a damper pad 70 and two seals 80 and 90, which are made in a same molding operation and of a same material. Preferably, flexible member 60 is overmolded onto body 50 of lower cup 30. Alternately, flexible member 60 can be vulcanized on body 50. Member 60 is made of a flexible material, for example an elastomer such as rubber, polyurethane or thermoplastic elastomer.
Pad 70 includes an inner portion 71, an outer portion 72, an annular recess 73, a tubular axial portion 74 and a small annular outward radial portion 75. Portion 71 is located at the inner upper side of pad 70 and is disposed against the annular outward radial portion 52 of body 50. More precisely, portion 71 is tightly fastened to portion 52, so that pad 70 is fastened to body 50. Portion 71 has a curved convex shape. Portion 72 is located at the outer bottom side of pad 70, opposite portion 71, for receiving spring 3 in bearing contact. Portion 72 has a convex shape, including two different slopes 76 and 77. Portion 72 forms a localized axial protrusion extending from portion 71. Pad 70 has a cambered shape delimited by portion 71 and 72, allowing a more efficient absorption of vibrations than a thin plane ring. Recess 73 is an annular groove formed in portion 72, beside portion 74. Recess 73 is opened on the outside of portion 72. Recess 73 is designed for receiving a creep of material of pad 70 when portion 72 is constrained by spring 3. Thus, recess 73 further improves the flexibility of pad 70. Recess 73 is located closer to portion 51 than to portion 52, to guide the creep toward portion 51. Portion 74 extends from portion 72 along the tubular axial portion 51 of body 50. In other words, portion 74 is an extension of pad 70 interposed between portion 51 and spring 3. Thus, portion 74 allows avoiding contact of spring 3 with portion 51. Portion 75 is a small overflow obtained when molding pad 70.
Pad 70 has different measurements defined in a direction D1 parallel to axis X1, as shown on
Seals 80 and 90 are designed to protect chamber 12 and bearing 20 against infiltrations of water or pollutant particles. Seal 80 is arranged on the outer side of chamber 12, while seal 90 is arranged on the inner side of chamber 12. Seal 80 comprises several stubs 82 connected to portion 71 of pad 70 through channels 58, while seal 90 comprises several stubs 92 connected to portion 71 of pad 70 through channels 59. Stubs 82 and 92 are distributed around axis X1, as channels 58 and 59. Seal 80 comprises two sealing lips 84 and 86, while seal 90 comprises one sealing lip 94, disposed in contact with inner sealing surfaces of upper cup 40.
Spring 3 is wound around rod 2 and axis X1. Spring 3 is placed so as to rest between device 10 on the top side and the body of the damper piston on the bottom side. More precisely, spring 3 is positioned in the rounded corner 53 of lower cup 30, in bearing contact with portions 72 and 74 of pad 70. Spring 3 is elastically deformable according to the stresses exerted on the suspension system of the vehicle. When the suspension system is in service, spring 3 exerts upward axial forces against pad 70, which transmits these forces to lower cup 30, which transmits these forces within device 10.
Thanks to the invention, the contact area between spring 3 and damper pad 70 is increased in comparison with known prior art devices. Portions 72 and 74 are designed for bearing spring 3, respectively axially and radially. The vibrations absorption, noise reduction and load repartition between spring 3 and device 10 are improved.
Other non-shown embodiments can be implemented within the scope of the invention. By example, elements 20, 30 or 40 may have different configurations. According to another example, device 10 may comprise several bearings 20 located between cups 30 and 40. According to another example, portion 71 may be flat instead of being convex.
Whatever the embodiment, the lower cup 30 is provided with a damper pad having a cambered shape delimited by an inner portion 71 which is connected to the seal through the radial portion 52 of the body 50; and a convex outer portion 72 for bearing a suspension spring 3.
In addition, technical features of the different embodiments can be, in whole or part, combined with each other. Thus, the suspension bearing device 10 can be adapted to the specific requirements of the application.
Number | Date | Country | Kind |
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14306532.4 | Sep 2014 | EP | regional |