FR2855809A1 - Fender bracket for motor vehicle, has metallic bore with upper part including ribs arranged to stiffen and flash upper part, when fender bracket is mounted on vehicle, and having holes to satisfy pre-defined criteria - Google Patents

Abstract

The bracket has a metallic bore (12) with an upper part (10A) for a fender. The upper part has ribs that are arranged to stiffen and to flash the upper part in case of shock, when the fender bracket is mounted on a vehicle. The bore has holes (22) to reduce its stiffness for satisfying pre-defined deceleration criteria. A rigid lower part (10B) is fixed to the structure of the vehicle and has ribs.

Description

The present invention relates to a wing support for a motor vehicle.

  It is known to fix a motor vehicle wing on the structure of the latter by means of a support, sometimes designated wing support, which is itself fixed to the rigid structure of the vehicle, itself designated body in white.

  Known supports may be fasteners, to which functionalities such as the positioning of the wing, the ability to withstand expansion, the fusibility in the event of an impact to preserve the wing, or even the support of the wing have been added. to avoid blistering.

  An example of wing support provided by the state of the art is described in document EP 0 839 704. This support comprises, on its external face intended to receive a wing, a network of ribs matching the internal shape of the 'wing.

  But these known supports have a deficiency with regard to pedestrian head impacts.

  Such shocks are currently defined by the "Pedestrian" working group (WG 17) 15 of the European Enhanced Vehicle Safety Commitee and by the EuroNCAP procedure. These shocks are directed from top to bottom with a variable angle between the direction of impact and the ground. The impactor which models the pedestrian's head is spherical in shape and has a mass of between 2.5 Kg and 4.7 Kg.

  More generally, the definitions of pedestrian head impacts, present and to come, provide criteria which may change depending on the place and the time.

  Those skilled in the art can easily adapt to it when implementing the present invention.

  The theoretical impact is that of the head of a pedestrian overturned by a vehicle and lying on the front of the vehicle. If the impact of the head is in the central region of the hood, the depression of the latter may be sufficient to absorb enough energy to preserve the pedestrian's head, provided that other specific difficulties with impact are dealt with. hood and outside the scope of this description. On the other hand, if the impact zone concerned coincides with the upper edge of the wing, the risk is that the intrinsic rigidity of the edge of the wing, added to that of the edge of the hood, which is close to the edge 30 of the wing, reduce the possibilities of energy absorption and generate a deceleration too great for the pedestrian's head.

  The present invention aims to provide a new wing support part which, like the known supports, allows easy and precise positioning of the wing on the vehicle structure, as well as with respect to the other body parts of the vehicle, and which , 35 simultaneously, effectively absorbs the shock of a pedestrian's head on the upper edge of the wing.

  In addition, the new wing support part according to the invention makes it possible to effectively comply with the usual constraints of a specification relating to a motor vehicle wing, such as resistance to sunshine, resistance to blistering or to a buttock support.

  In addition to absorbing energy, the support according to the invention aims to provide additional rigidity to the wing, thanks to its particular structure.

  The present invention relates to a motor vehicle wing support comprising a metal core having an upper part provided with fixings for a wing, characterized in that said upper part is provided with ribs arranged to stiffen it during directed stresses according to transverse direction and for flaming during downward shocks, when the wing support is mounted on the vehicle.

  Thus, the support according to the invention has the two characteristics of having a metal core, for example of sheet metal, and of comprising ribs ensuring, on the one hand, a stiffening function in Y, on the other hand a function of absorption in Z by 15 buckling of the ribs and deformation of the core.

  It is recalled that the direction Y is the transverse direction of the vehicle, perpendicular to the vertical Z and to the longitudinal direction X, or rolling direction, of the vehicle.

  Thanks to its ribs, the support of the invention can meet the criterion of Z deceleration for pedestrian head impacts.

  According to a particular embodiment, the metallic core has openings aimed at reducing its stiffness in Z in order to satisfy predefined deceleration criteria.

  The support according to the invention is particularly suitable for plastic wings, in one piece, which facilitate the treatment of pedestrian head impacts due to their less rigidity in the region of their upper edge.

  In a particular embodiment of the invention, the ribs have no lateral cohesion with the metallic core, so as to be able to flame in the event of an impact.

  Preferably, the ribs extend vertically over 60 to 90 mm, depending on the geometry of the wing and the structure of the vehicle, as well as the desired protection efficiency.

  In this embodiment, the ribs are formed parallel to vertical planes and are connected to the metal core only by their ends, being free over their entire height. Thus, a force applied to the support, mainly in the vertical direction, requires no connection other than supports between the ribs and the core and allows the core to deform and the ribs to buckle, without combining inertias. soul on the one hand, ribs on the other.

  To fulfill their stiffening function in Y, the ribs are advantageously perpendicular to the general vertical plane of the core, that is to say that they are perpendicular to the longitudinal direction of the vehicle. In this way, even without cohesion with the core, the ribs can contribute to the resistance of the support in the event of transverse stress, for example during an impact, a support or a thermal expansion of the wing. .

  In addition, this geometry and this arrangement of the ribs facilitate the maintenance in Y of the wing and limit its possibilities of movement in the transverse direction Y. In another particular embodiment of the invention, compatible with the previous 10, the ribs are overmolded on the metal core, by a technique known in itself of overmolding.

  The support according to the invention comprises, according to another particular embodiment, compatible with the previous ones, a rigid lower part provided for its attachment to the structure of the vehicle.

  This lower part is first of all advantageous as a part used for fixing the support to the structure of the vehicle.

  But it has another advantage, which may prove essential for the effectiveness of the protection in the event of a head impact, namely that it has a variable height, allowing the support to absorb differences in space available in Z between the structure of the vehicle and the upper edge of the wing, while maintaining a constant height, therefore a constant energy absorption efficiency, at the upper part of the support.

  According to other advantageous characteristics of the invention, which can be taken alone or in combination: - The metal core has an S or C section. - The lower part of the metal core comprises a network of stiffening ribs .

  - The metal core has fixing holes for a wing and, possibly, for the structure of the vehicle.

  - Additional fixing forms are overmolded on the metal core, at the same time as the ribs, to add additional functions to the wing support.

  In order to facilitate understanding of the invention, we will now describe embodiments thereof, given by way of nonlimiting examples of the scope of the invention, using the appended drawings in which: - Figure 1 shows, in perspective, an end portion of a wing support according to a first embodiment of the invention, seen from the outside; - Figure 2 is a view similar to Figure 1 showing the support seen from the inside; - Figure 3 is a view similar to Figure 2, the wing support deforming under the effect of vertical compression, - Figure 4 shows, in perspective, the metal core of a wing support according to a second embodiment of the invention, seen from the outside; - Figure 5 is a perspective view in the direction V of Figure 4, the core 10 carrying ribs, - Figure 6 is an enlarged view of the region VI of the support of Figure 5, seen from therein; - Figure 7 is a view similar to Figure 6 when the support is deformed, - Figure 8 shows the support in situation, seen from the inside, between a wing and the structure of the vehicle.

  The support shown in the drawing, designated by a general reference 10, is a hybrid structure, constituted by a sheet metal core 12 with a vertical section in the shape of a C (seen according to FIG. 2) and by ribs 14 made of thermoplastic material.

  More specifically, the metallic core 12 consists of a vertical wall 16 (in the orientation of the drawing) and two substantially horizontal flanges 18 and 20 (in the orientation of the drawing) extending perpendicular to the vertical wall. 16, in the longitudinal direction of the support 10.

  The support 10 is functionally divided into two parts 1 OA and 1 OB, located in the example above and below the step, although this coincidence is fortuitous.

  The upper part 10A has rectangular openings 22 formed in the vertical wall 16. These openings 22 have the function of reducing the stiffness in Z of the metallic core 12 in this upper part 10A, in order to facilitate its deformation in the event of vertical compression , as shown in Figure 3.

  In this figure, the upper arrow represents the force exerted on the support 10 by the upper edge of a wing receiving the impact of a pedestrian head and the lower arrow represents the reaction of the structure of the vehicle, so that the support 10 is well compressed vertically.

  The lower part 10B of the support 10, devoid of openings, is more rigid than the upper part 1 OA and does not deform during this compression.

  This difference in behavior between the upper 10A and lower 10B parts of the support 10 is accentuated by the ribs 14 which will now be described.

  The ribs 14 are, like the metallic core 12, divided into two groups, 14A and 14B, one upper and the other lower.

  The ribs 14A of the upper group extend vertically (in the orientation of the drawing), that is to say perpendicular to the flanges 18 and 20, and perpendicular to the vertical wall 16 of the core 12. They are distributed over the length of the support 10 at the rate of one every two openings 22.

  The upper 10A and lower 10B parts of the support are separated by a plane 10 24 molded with the ribs 14, arranged substantially parallel to the edge 18 of the metal core 12.

  This plane 24 serves to support the ribs 14A of the upper group by its upper face, and the ribs 14B of the lower group by its lower face.

  The ribs 14 are produced by overmoulding of the metallic core 12 and adhere to the inner face of the core 12. However, by exception, the ribs 14A of the upper group are detached from the vertical wall 16 and are therefore not connected to the metallic core 12 only by their upper edges which adhere to the lower face of the upper rim 18.

  It follows that the ribs 14A of the upper group have a very low inertia in the vertical direction and that the vertical compression of the support causes the crushing of its upper part, the ribs 14A being able to easily buckle without being retained by the vertical wall 16 of the metallic core 12, as clearly appears in FIG. 3.

  In other words, the ribs 14A of the upper group do not hinder the deformation of the upper part 10A of the support in the event of impact with the head of a pedestrian.

  On the other hand, these ribs 14A have a stiffening function for the support 10 in the event of transverse force, that is to say in the direction Y of the vehicle, in the event of lateral stress against the wing, because their inertia in the direction Y is higher for two reasons: on the one hand, they are integral by their ends with the upper edge 18 of the metal core 12 and the separation plane 24, so that their buckling is prevented, and on the other hand, they are shorter in this transverse direction Y than in the vertical direction Z, and consequently, with equal radius of curvature, they could less easily be crushed, even if they were free to do so.

  The separation plane 24 is also integral with the vertical wall of the wing.

  The ribs 14B of the lower group are arranged in a honeycomb, being inclined relative to the lower edge 20 of the core 10 and to the separation plane 24, and crossed between them. Their edges are integral with the lower part 10B of the metal core 10, that is to say the lower edge 20 and the lower part of the vertical wall 16, as well as the separation plane 24 between the two groups of ribs .

  Thus arranged and maintained in a network, the ribs 14B of the lower group constitute a rigid structure adapted to withstand the stresses transmitted by the wing in the event of an accident.

  In addition, their orientation gives them a great inertia in the direction Y, which allows them to play a role of absorber in the event of lateral stress against the wing, and at least to ensure a lasting maintenance of the wing. in the transverse direction Y of the vehicle.

  The lower part 10B of the support, stiffened by the ribs 14B, can therefore comprise means 26 for fixing to the structure of the vehicle.

  Thus, the entire support 10 constitutes a means of placing the wing in a durable position, in particular in the vertical position Z. In a variant not shown, the plane of separation between the two groups of ribs consists of a metal sheet secured to the metal core, attached to the latter by any suitable means, for example by welding.

  In another embodiment, illustrated by FIGS. 4 to 8, the metal core 12 ′ 20 has a cross section in S and not in C. In this case, the vertical wall 16 ′ is located for one half of the inside the support 10 'and for the other half outside the support 10' and the separation plane 24 'consists of a horizontal portion of the core 12' connecting the two halves of the vertical wall 16 '. Preferably, the upper part 16'A of the vertical wall 16 'is external and its lower part 16'B is internal, which makes it possible to provide fixing holes 26' for the support 10 'on the structure of the vehicle and provides a simple means of mounting the support 10 'on this structure. In addition, the upper part 16 ′ A may also include orifices 28 ′ for fixing the wing.

  Other structural differences between the support of FIGS. 4 to 8 and that of FIGS. 1 to 3 can be underlined: - the ribs 14'A of the upper group are distributed on the basis of one between two successive openings 22 ', - the openings 22 'extend on the upper edge 18' of the metallic core 12 '.

  The behavior of the support 10 ′ according to this second embodiment is substantially the same as the behavior previously described according to the first embodiment.

  In FIG. 5, it can be seen that the lower part of the support has a decreasing height towards the front of the vehicle, while its upper part has a constant height.

  Thus, the effectiveness of the protection in the event of a head impact is the same whatever the point of impact of the head of a pedestrian along the upper edge of the wing.

  In FIG. 8, the arrangement of the support is seen between a wing 30 and the structure of the vehicle, here constituted by an upper spar 32.

  The structure of the vehicle is then high and low. It is composed of two upper beams 32 lowered compared to a conventional architecture and the 10 conventional beams (not shown).

  In particular, in the event of a vertical impact with the head of a pedestrian, as seen in FIG. 7, the ribs 14'A of the upper group blaze and do not hinder the crushing of the upper part 10'A of the support 10 ', thus absorbing the energy of the shock and preserving as far as possible the head of the pedestrian.

  It is understood that the embodiments which have just been described have no limiting character and that they can receive any desirable modification without departing from the scope of the invention.

Claims (12)

  1. Motor vehicle wing support (10; 10 '), comprising a metal core (12; 12') having an upper part provided with fixings for a wing, characterized in that said upper part is provided with ribs ( 14A; 14'A) arranged to stiffen it during stresses directed in the transverse direction and to flame during impacts directed downwards, when the wing support (10; 10 ') is mounted on the vehicle.   2. Motor vehicle fender support (10; 10 ') according to claim 1, in which the metallic core (12; 12') has openings (22; 22 ') aimed at reducing its rigidity to satisfy predefined deceleration criteria.   3. Motor vehicle wing support (10; 10 ') according to any one of claims 1 and 2, in which the ribs (14A; 14'A) have no lateral cohesion with the metallic core ( 12; 12 '), so that it can burn in the event of an impact.   4. Motor vehicle wing support (10; 10 ') according to any one of the preceding claims, in which the ribs (14A; 14'A) extend vertically over 60 to 90 mm, depending on the wing geometry and vehicle structure.   5. Motor vehicle wing support (10; 10 ') according to any one of the preceding claims, in which the ribs (14A; 14'A) are formed parallel to vertical planes.   6. Motor vehicle wing support (10; 10 ') according to any one of the preceding claims, in which the ribs (14A; 14'A) are perpendicular to the general vertical plane of the core.   7. Motor vehicle wing support (10; 10 ') according to any one of the preceding claims, in which the ribs (14A; 14'A) are overmolded on the metallic core (12; 12').   8. Motor vehicle fender support (10; 10 ') according to any one of the preceding claims, comprising a rigid lower part (10B; 10'B) for fixing to the structure of the vehicle.   9. Motor vehicle wing support (10; 10 ') according to any one of the preceding claims, the rigid lower part of which has a variable height, allowing the support to absorb differences in space available in Z between the structure of the vehicle and the upper edge of the wing, while maintaining a constant height at the upper part of the support.   10. Motor vehicle wing support (10; 10 ') according to any one of claims 8 and 9, in which the rigid lower part of the support (lOB; 10'B) comprises a network of stiffening ribs (14B ; 14'B).   11. Motor vehicle fender support (10; 10 ') according to any one of the preceding claims, in which the metallic core (12; 12') has an S or C section. 12. Motor vehicle wing support (10; 10 ') according to any one of the preceding claims, in which the fasteners for a wing on the metal core (12; 12') are fixing holes (28; 28 '). 10