FR3123875A1 - shock absorber element for a motor vehicle - Google Patents

Abstract

The invention relates to a shock-absorbing element (13) for a motor vehicle. The shock absorber element (13) is intended to be assembled on a rear end of a side member of the motor vehicle. The shock absorber element (13) comprises a strut (14), a fixing member (15) intended to allow the fixing of the strut (14) to the side member of the motor vehicle and a fixing device (16 ) intended to allow the attachment of the strut (14) to a rear panel of the motor vehicle. In the shock-absorbing element (13) according to the invention, the strut (14) comprises a deformable device – called programmed deformation device (18) – configured to allow dissipation of mechanical energy in the event of compression of said strut (14). Figure to be published with abstract: Fig. 2

Description

shock absorbing element for a motor vehicle

The technical context of the present invention is that of the structural elements which make up the rear of motor vehicles and in particular rear protective structures which are configured to absorb an impact occurring at the rear of the motor vehicle. More particularly, the invention relates to a shock absorber element for a motor vehicle.

In the state of the art, there are known rear motor vehicle structural elements configured to improve the safety of the motor vehicle and of its occupants in the event of an impact applied to the rear of the motor vehicle. Among these structural elements and to absorb a mechanical force due to the impact applied to the rear of the motor vehicle, it is known to equip the rear of the motor vehicle with a rear bumper fixed integrally to two rear side rails of a chassis of the motor vehicle. When a rear impact is applied to the motor vehicle, the rear bumper deforms, absorbs the mechanical force due to the impact and transmits it to the side rails in order to limit damage to the rear of said motor vehicle and secure its occupants. .

The disadvantage of these motor vehicle structural elements is that there is a risk of the side rails being biased, during the transmission of the mechanical force from the rear bumper. In particular, there is a risk of buckling by pivoting of the side slats in a vertical plane, otherwise called verticalization.

We also know the invention patent FR3014072_B1 for a structure of the rear part of the body of a motor vehicle. The structure of the rear part of the body of a motor vehicle which is described therein comprises a load floor fixed between two side members made of sheet metal and a rear panel extending transversely between the two respective rear ends of the two side members, this rear panel being distant from each of the two rear ends of the two beams. In accordance with the invention described in patent FR3014072_B1, the gap existing between each of the two beams and the rear panel is filled by a single piece comprising two parts, one of which has the function of extending the beam and the The other has the function of reinforcing the connection between each rail and the rear panel. The single piece thus makes it possible to fill in an existing space between the longeronet and the rear panel while reinforcing the connection between the longeronet and the rear panel.

A disadvantage of these structures lies in the fact that they are not intended to improve any dissipation of energy in the event of a rear impact and that they have no impact on the risk of verticalization of the side member.

The object of the present invention is to propose a new shock-absorbing element for a motor vehicle in order to respond at least in large part to the above problems and also to lead to other advantages.

Another object of the invention is to provide a shock absorber element for a motor vehicle configured to reduce the severity of a rear impact at the level of the motor vehicle that it equips.

Another object of the invention is to provide a shock-absorbing element for a motor vehicle which is inexpensive, so as to limit the cost of such a shock-absorbing element compared with the shock-absorbing element for existing motor vehicles.

Another object of the invention is to provide a shock-absorbing element for a motor vehicle that is compact, guaranteeing the compactness and lightness of the motor vehicle.

Another object of the invention is to provide a shock absorber element for a motor vehicle which is light, so as not to negatively impact the mass of the motor vehicle.

Another object of the invention is to propose a shock absorber element for a motor vehicle configured to satisfy the rear impact protocols.

According to a first aspect of the invention, at least one of the aforementioned objectives is achieved with a shock-absorbing element for a motor vehicle, the shock-absorbing element being intended to be assembled on a rear end of a side member of the motor vehicle, the shock-absorbing element comprising (i) a strut comprising a deformable device – called programmed deformation – configured to allow dissipation of mechanical energy in the event of compression of the said strut, (ii) a fixing member intended to allow the fixing of the strut to the side member of the motor vehicle, (iii) a fixing device intended to allow the fixing of the strut to a rear panel of the motor vehicle.

The shock absorber element according to the first aspect of the invention is configured to equip a mechanical reinforcement system for a motor vehicle. Such a mechanical reinforcement system comprises a rear panel and a motor vehicle side member. In such a mechanical reinforcement system, a rear end of the lateral spar is fixed integrally to the rear panel and the shock-absorbing element comprises zones for attachment to the lateral spar and to the rear panel.

In the shock absorber element according to the first aspect of the invention, the deformable device of the strut is said to have programmed deformation. It is understood that the deformable device of the strut is configured to deform according to an expected configuration in the event of compression of the strut. In the motor vehicle equipped with the invention, the strut of the shock absorber element according to the invention is compressed in particular during a rear impact to the motor vehicle. When the strut is compressed, the deformable device of the strut deforms according to an expected configuration making it possible to dissipate the mechanical energy having induced the compression of the strut and making it possible to transmit the residual mechanical energy in a substantially parallel, advantageously hilly, to the side spar. In the motor vehicle equipped with the invention and thus deformed, the strut, by directing the mechanical energy towards the side spar, preserves said lateral spar from verticalization while limiting the mechanical forces transmitted to the lateral spar.

In the shock absorber element according to the first aspect of the invention, the fixing member is intended to allow the fixing of the strut to the side member of the motor vehicle. In the motor vehicle equipped with the invention, the fixing member secures the strut to the side spar and allows transmission of mechanical force from the shock absorber element to the spar. Thus, the fixing device makes it possible to protect the rear side member from verticalization in the event of a rear impact.

In the shock absorber element according to the first aspect of the invention, the fastening device is intended to allow the fastening of the strut to a rear panel of the motor vehicle. In the motor vehicle equipped with the invention, the fastening device allows a mechanical force coming from the rear of the motor vehicle and transmitted to the rear panel to be transmitted to the strut. By being fixed to the rear panel, the shock-absorbing element according to the first aspect of the invention can dissipate a mechanical force originating from said rear panel.

Such a shock-absorbing element, provided with the strut intended to be fixed both to the rear panel of the motor vehicle and to the side rail of the motor vehicle, makes it possible to limit the risk of the side rails being placed at an angle during a shock occurring at the rear of the motor vehicle equipped with said shock absorber element. Thus, this solution makes it possible to preserve the rear spar from verticalization in the event of a rear impact, while being simple to implement. The shock absorber element according to the invention has the advantage of overcoming the drawbacks mentioned above, without having to make any significant modification to the mechanical reinforcement system and/or to the motor vehicle which it equips.

The shock absorber element in accordance with the first aspect of the invention advantageously comprises at least one of the improvements below, the technical characteristics forming these improvements being able to be taken alone or in combination:

– the strut comprises (i) a lower wall intended to be located facing an underside of the spar, (ii) two side walls located on either side of the lower wall, the strut having a triangular longitudinal profile along a longitudinal direction parallel to an elongation of the spar on which the shock absorber element is intended to be assembled. In the motor vehicle equipped with the invention, such a triangular longitudinal profile promotes transmission of mechanical energy from the rear panel to the side member. It is understood that the lower wall of the strut forms one side of the triangular profile intended to extend transversely between the rear panel of the motor vehicle and the underside of the side member. It is understood that the lower wall of the strut forms one side of the triangular profile intended to extend obliquely with respect to the rear panel of the motor vehicle and to the lower face of the spar;

- the programmed deformation device comprises a first cavity – called concave – formed on the lower wall of the strut. The first cavity is deformable. The first cavity facilitates the programmed deformation of the programmed deformation device. The first cavity makes it possible to absorb a mechanical force of compression of the strut. It is understood that the first cavity forms a hollow space of the programmed deformation device with respect to the lower wall of the strut, which is generally planar. Advantageously, a first “concave” cavity forms a hollow in the longitudinal profile of the strut. In other words, the concave cavity forms a depression oriented in the direction of the side spar on which the shock absorber element according to the invention is intended to be assembled;

- the concave cavity is located close to a rear end of the lower wall of the strut intended to be located on the side of the rear panel of the motor vehicle. Thus located and in the motor vehicle equipped with the invention, the concave cavity promotes deformation of the programmed deformation device directing the mechanical forces towards the underside of the side spar. In particular, a concave cavity in a position proximal to the rear panel makes it possible to initiate the programmed deformation in the direction of the side spar in the motor vehicle equipped with the invention;

- the concave cavity is formed by stamping the lower wall of the strut. Stamping makes it possible to bend the lower wall of the strut to delimit the concave cavity;

- the concave cavity has a bottom delimited by a circular contour;

- the bottom of the concave cavity is flat;

- the bottom of the concave cavity is parallel to the underside of the spar on which the shock absorber element is intended to be assembled;

- The concave cavity has an opening located in the center of said concave cavity. Advantageously, the opening is circular and concentric with the circular contour delimiting the bottom of the concave cavity;

- the programmed deformation device comprises a second cavity – called convex – formed on the lower wall of the strut. The second cavity is deformable. The second cavity facilitates the programmed deformation of the programmed deformation device. The second cavity makes it possible to absorb a mechanical force of compression of the strut. It will be understood that the second cavity forms a hollow with respect to the lower wall of the strut, which is generally planar. Advantageously, a second "convex" cavity forms a bump in the longitudinal profile of the strut. In other words, the convex cavity forms a depression oriented in the opposite direction to the side spar on which the shock absorber element according to the invention is intended to be assembled;

- the convex cavity forms a depression oriented in a direction opposite to the concave cavity. By forming depressions oriented in opposite directions, the convex cavity and the concave cavity contribute to program the deformation of the programmed deformation device;

- the convex cavity is formed by stamping the lower wall of the strut. Stamping makes it possible to bend the lower wall of the strut to delimit the concave cavity;

- the convex cavity has a bottom delimited by a circular profile;

- the bottom of the convex cavity is flat;

- the bottom of the convex cavity is parallel to the underside of the spar on which the shock absorber element is intended to be assembled;

- dimensions of the convex cavity and/or of the circular profile of the convex cavity are equal to the dimensions of the concave cavity and/or of the circular contour of the concave cavity;

- the programmed deformation device comprises an initiation zone configured to allow the strut to bend along a fold line delimited by the initiation zone. When the strut is subjected to compression, the initiation zone makes it possible to initiate the programmed deformation. As such, the initiation zone is a zone particularly sensitive to deformation in the programmed deformation device. In particular, initially, the strut bends along the bend line, so that the programmed deformation device deforms progressively according to the expected configuration. In other words, the initiation zone initiates the programmed deformation when the strut is compressed. In the motor vehicle equipped with the invention, the initiation zone promotes deformation by bending of the programmed deformation device to dissipate the energy of the rear impact and reduce the mechanical forces transmitted to the side member. Such deformation promotes transmission of mechanical forces to the underside of the side spar;

- the priming zone is located between the concave cavity and the convex cavity;

- the bend line delimited by the starting zone extends across the lower wall and between the two side walls of the strut. Advantageously, each point of the fold line is equidistant from the centers of each of the cavities of the programmed deformation device;

- the initiation zone comprises two grooves, each groove being formed at the level of a side edge of the strut formed by a bending zone of the lower wall and of one of the side walls of the strut. Each of the two side edges of the strut joins the bottom wall and one of the side walls of the strut. A groove is understood as a hollow, long and narrow indentation. A transverse profile of the groove is hollow, so that a groove bottom is the deepest part of the groove. The groove is advantageously provided to have its bottom oriented towards the underside of the side spar, that is to say away from the lower wall of the strut. Such a bottom promotes a collapse of the bend zone by positive elevation. In the initiation zone, the two grooves make it possible to initiate the deformation by bending the programmed deformation device at the level of the bending line. It is understood that the fold line extends from one groove to the other. That is, the two grooves form an axis around which the strut is intended to collapse when compressed longitudinally. Advantageously, the two grooves are parallel to each other and advantageously hilly;

- the priming zone is between the two circular profiles delimiting the bottom of each cavity, meaning the concave cavity and the convex cavity;

- each groove is formed by stamping. The stamping makes it possible to bend the lateral edge of the strut to delimit the groove of the starting zone;

- the shock absorber element is monolithic. The term “monolithic” means the fact that the elements forming the shock-absorbing element according to the invention cannot be separated from each other without affecting all or part of their integrity. Thus the shock-absorbing element according to the invention forms an assembly qualified as one-piece consisting of one and the same continuous part, made in one piece and obtained during the same manufacturing process. The invention in accordance with its first aspect thus advantageously makes it possible to obtain a prefabricated shock-absorbing element, the manufacture of which is simplified since it does away with any assembly, as well as the presence of fastening means. In addition, a one-piece shock absorber member can be machined in a variety of different sizes so as to be adapted to different models of motor vehicles. Such a shock-absorbing element is moreover more rigid and lighter;

- the shock absorber element is formed by stamping. Stamping makes it possible to bend a plate forming the shock absorber element to delimit the strut, the fixing member and the fixing device. Thus, stamping makes it possible in particular to form the device with programmed deformation of the strut, the lower wall of the strut and the side walls of the strut;

- the shock absorber element is made of sheet metal. In general, the shock absorber element is formed by bending the metal sheet;

- a thickness of the metal sheet forming the shock absorber element is between 1 mm and 2 mm. The metal sheet forming the shock absorbing element comprises two surfaces, a first surface opposite a second surface, and the thickness of the metal sheet forming the shock absorbing element according to the first aspect of the invention is the distance shorter between the first surface and the second surface of the metal sheet. Preferably, the metal sheet forming the shock absorber element has a thickness equal to 1.2 mm;

- the shock absorber element is made of a metallic material. The shock absorber element is preferably formed of steel.

According to a second aspect of the invention, there is proposed a mechanical reinforcement system for a motor vehicle, the mechanical reinforcement system comprising (i) a rear panel, (ii) a motor vehicle side member, one rear end of which is fixed integrally with the rear panel, (iii) a shock-absorbing element in accordance with the first aspect of the invention or according to any one of its improvements, the shock-absorbing element comprising zones for attachment to the side sill and to the rear panel.

The mechanical reinforcement system according to the second aspect of the invention is configured to equip a motor vehicle.

Such a mechanical reinforcement system, provided with the shock-absorbing element in accordance with the first aspect of the invention, makes it possible to limit the risk of the side member becoming skewed during an impact occurring at the rear of the motor vehicle equipped said mechanical reinforcement system. Thus, this solution makes it possible to preserve the rear side member from verticalization in the event of a rear impact.

The mechanical reinforcement system for a motor vehicle in accordance with the second aspect of the invention advantageously comprises at least one of the improvements below, the technical characteristics forming these improvements being able to be taken alone or in combination:

- the shock absorber element is fixed integrally to the side spar by welding a first side wall of the strut to an outer side face of said lateral spar. In general, the first side wall of the strut of the shock absorber element is fixed integrally to the outer side face of the side rail by a permanent fixing means. Such attachment ensures that the rear spar and the shock absorber element are secured to each other despite compression of the shock absorber element and deformation of the deformable device. When the first side wall of the shock-absorbing element strut is firmly fixed to the outer side face of the side spar by welding, the residual impact energy is transmitted from the shock-absorbing element to the spar;

- the shock-absorbing element is fixed integrally to the rear spar by welding a second side wall of the strut to the underside of the said rear spar, the second side wall comprising fixing lugs. In general, the fixing lugs of the second side wall of the strut of the shock absorber element are fixed integrally to the underside of the side member by a permanent fixing means. Such attachment ensures that the rear spar and the shock absorber element are secured to each other despite compression of the shock absorber element and deformation of the deformable device. When the second side wall of the shock-absorbing element strut is firmly fixed to the underside of the side spar by welding, the residual impact energy is transmitted from the shock-absorbing element to the spar;

- the shock absorber element is fixed to the rear panel by welding said rear panel to the strut assembly lugs. In this case, the shock absorbing element is attached directly to the rear panel. In general, the assembly lugs of the strut of the shock absorber element are fixed integrally to the rear panel by a permanent fixing means. Such attachment ensures that the rear panel and the shock absorber element are secured to each other at the time of an impact occurring at the rear of the rear panel. When the shock-absorbing element strut assembly tabs are integrally attached to the rear panel by welding, impact energy is transmitted from the shock-absorbing element. Alternatively, the shock absorber element is attached to the rear panel via a side sill attachment plate securing the side sill to the rear panel, with strut assembly tabs being welded to the fixing the side rail. In this case, the shock-absorbing element is attached indirectly to the rear panel.

According to a third aspect of the invention, a motor vehicle is proposed comprising a mechanical reinforcement system in accordance with the second aspect of the invention or according to any one of its improvements.

Various embodiments of the invention are provided, integrating according to all of their possible combinations the various optional characteristics set out here.

Other characteristics and advantages of the invention will become apparent through the description which follows on the one hand, and several embodiments given by way of indication and not limiting with reference to the appended diagrammatic drawings on the other hand, on which :

illustrates a schematic view of a motor vehicle according to the third aspect of the invention;

illustrates a schematic view of a shock absorber element for a motor vehicle according to the first aspect of the invention, seen from below;

illustrates the motor vehicle shock absorber element shown in , seen from above;

illustrates the motor vehicle shock absorber element shown in , fitted to a mechanical reinforcement system for a motor vehicle according to the second aspect of the invention according to a first angle of view, lateral;

illustrates the motor vehicle shock absorber element shown in , according to a second angle of view, from below;

illustrates an implementation of the shock absorbing element according to the first aspect of the invention.

Of course, the characteristics, the variants and the different embodiments of the invention can be associated with each other, according to various combinations, insofar as they are not incompatible or exclusive of each other. In particular, variants of the invention may be imagined comprising only a selection of characteristics described below in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention from to the state of the prior art.

In particular, all the variants and all the embodiments described can be combined with each other if nothing prevents this combination from a technical point of view.

In the figures, the elements common to several figures retain the same reference.

There illustrates a schematic view of a motor vehicle 1 according to the third aspect of the invention. In the remainder of the description, a frame of reference is defined in which a longitudinal axis OX, a transverse axis OY and a vertical axis OZ are defined. The longitudinal axis OX corresponds to a trajectory of the motor vehicle when it is in forward motion, in a straight line and on a flat road. The longitudinal axis OX corresponds to a direction running from the front to the rear of the motor vehicle, and it is oriented from the front to the rear of the motor vehicle. A longitudinal direction parallel to the longitudinal axis OX is also defined, the adjectives "front", "rear" or "front" refer to this reference direction, the term "length" also. The transverse axis OY corresponds to the axis around which the wheels of the motor vehicle rotate, and the direction of the axis OY is oriented from a passenger side to a driver's side, in the non-Anglo-Saxon standard. A transverse direction parallel to the transverse axis OY is also defined, and the adjectives “lateral” or “transverse” refer to this reference direction, the term “width” also. The vertical axis OZ is an axis perpendicular simultaneously to the axis OX and to the axis OY, and which is oriented from a floor of the motor vehicle towards a roof of said motor vehicle, the adjectives "upper" and "lower" refer to this reference direction, the term "height" also.

There shows that the motor vehicle 1 in accordance with the third aspect of the invention comprises a system 2 of mechanical reinforcement in accordance with the second aspect of the invention, in this case two systems 2 of mechanical reinforcement. The motor vehicle 1 further comprises two side rails 3 extending longitudinally on either side of a rear compartment 4 of the motor vehicle 1, the rear compartment 4 being between a rear bumper 5 of the motor vehicle 1 and a cabin 6 of the motor vehicle 1.

There shows that each of the side rails 3 of the motor vehicle 1 according to the third aspect of the invention comprises a rear end 7 opposite a front end 8. The rear end 7 of the side rail 3 considered is located in a position proximal to a panel rear 9 of the system 2 of mechanical reinforcement according to the second aspect of the invention. In this case, the rear end 7 of each of the side rails 3 is fixed to the rear panel 9 of the system 2 of mechanical reinforcement according to the second aspect of the invention. An elongation 10 of each of the side rails 3 of the motor vehicle 1 extends in the longitudinal direction. In addition, each of the side rails 3 of the motor vehicle 1 comprises an outer side face 11 opposite an inner side face 12.

There shows that the mechanical reinforcement system 2 in accordance with the second aspect of the invention comprises the rear panel 9, one of the side rails 3 of the motor vehicle 1 in accordance with the third aspect of the invention and a shock absorber element 13 in accordance with first aspect of the invention.

FIGURES 2 and 3 illustrate a schematic view of the shock absorber element 13 for a motor vehicle 1 according to the first aspect of the invention. The shock absorber element 13 is seen from a low angle view and is seen from above . FIGURES 4 and 5 illustrate this same shock-absorbing element 13 placed in the motor vehicle 1 according to the third aspect of the invention and included in the mechanical reinforcement system 2 according to the second aspect of the invention.

FIGURES 2 and 3 show that the shock absorber element 13 comprises a strut 14, a fixing member 15 intended to allow the fixing of the strut 14 to one of the side rails 3 of the motor vehicle 1 and a fixing device 16 intended to allow the fixing of the strut 14 to the rear panel 9 of the motor vehicle 1. In FIGURES 4 and 5, the fixing member 15 fixes the strut 14 to the rear end 7 side rail 3 of the motor vehicle 1 and the fixing device 16 fixes the strut 14 to the rear panel 9.

FIGURES 2 and 3 show that the shock absorber element 13 is monolithic, formed of a sheet metal 17 shaped by stamping.

FIGURES 2 and 3 show that the strut 14 comprises a deformable device called device 18 with programmed deformation. The programmed deformation device 18 is configured to allow the dissipation of mechanical energy in the event of compression of the strut 14. In particular, the programmed deformation device 18 is configured to allow the dissipation of mechanical energy in the event of a shock. applied to the rear of the motor vehicle 1 equipped with the shock absorber element 13 according to the invention.

There shows that the strut 14 has a triangular longitudinal profile 19 along the longitudinal direction. The triangular longitudinal profile 19 is schematically represented in dotted lines in . The triangular longitudinal profile 19 is formed of three sides: a rear side 20 intended to be oriented vis-à-vis the rear panel 9 of the motor vehicle 1, an upper side 21 intended to be oriented vis-à-vis the spar side 3 and a lower side 22.

FIGURES 2 and 3 show the strut 14 comprises a bottom wall 23 and two side walls 24, 25 located on either side of the bottom wall 23, an outer side wall called the first side wall 24 and an inner side wall said second side wall 25, located in the background on the . Two side edges 26, 27 of the strut 14, a first side edge 26 and a second side edge 27 connect the lower wall 23 to one of the side walls 24, 25 of the strut 14, respectively to the first side wall 24 and second side wall 25.

FIGURES 2 and 3 show that the lower wall 23 of the strut 14 comprises a rear end 28 and a front end 29. The front end 29 is transverse with respect to the rear end 28 and coplanar with the upper side 21 of the triangular longitudinal profile 19. The front end 29 of the lower wall 23 the strut 14 is included in the fixing member 15. In FIGURES 4 and 5, the lower wall 23 the strut 14 is located in view of a lower face 30 of the lateral spar 3. The front end 29 of the lower wall 23 the strut 14 is fixed to the lateral spar 3.

FIGURES 2 and 3 show that the programmed deformation device 18 comprises a first cavity 31 and a second cavity 32, both formed on the lower wall 23 of the strut 14. The first cavity 31, located near the end rear 28 of the lower wall 23 of the strut 14, is called cavity 31 concave. The second cavity 32, located in front of the first cavity 31 in the longitudinal direction, is called convex cavity 32. In this case, the dimensions of the convex cavity 32 are equal to the dimensions of the concave cavity 31. FIGURES 4 and 5 show that the concave cavity 31 is located proximal to the rear panel 9 of the motor vehicle 1 and the convex cavity 23 is located distal to the rear panel 9 of the motor vehicle 1. FIGURES 4 and 5 show that the concave cavity 31 forms a depression oriented in the direction of the side spar 3 on which the shock absorber element 13 is assembled. The convex cavity 32 forms a depression oriented in a direction opposite to the side spar 3 on which the shock absorber element 13 is assembled.

FIGURES 2 and 3 show that the concave cavity 31 comprises a flat bottom 33, delimited by a circular outline 35 and a circular opening 37, the opening 37 being centered on said bottom 33 and concentric with the circular outline 35. FIGURES 4 and 5 show that the bottom 33 of the concave cavity 31 is parallel to the lower face 30 of the side spar 3.

FIGURES 2 and 3 show that the convex cavity 32 has a flat bottom 34 delimited by a circular profile 36. FIGURES 4 and 5 show that the bottom 34 of the convex cavity 32 is parallel to the lower face 30 of the side spar 3.

FIGURES 2 and 3 show that the programmed deformation device 18 comprises an initiation zone 38 located between the concave cavity 31 and the convex cavity 32. The initiation zone 38 is configured to allow the strut 14 to bend along a fold line 39 bounded by the initiation zone 38. The fold line 39, shown in dotted lines, bounded by the priming zone 38 extends across the lower wall 23 of the strut 14 and between the two side walls 24, 25 of the strut 14.

FIGURES 2 and 3 show that the boot zone 38 has two grooves 40, each groove 40 being formed at one of the side edges 26, 27 of the strut 14. Only one of the grooves 40 is visible in .

There shows that the shock-absorbing element 13 according to the invention comprises fixing zones 41 to the side spar 3. The first side wall 24 of the strut 14 of the shock-absorbing element 13 forms one of the fixing zones 41 to the lateral spar 3. The second side wall 25 of the strut 14 of the shock absorber element 13 comprises fixing lugs 42, 43 of the fixing member 15 which form fixing zones 41 to the lateral spar 3 The fixing lugs 42, 43 of the fixing member 15 extend perpendicularly to the main extension plane of the second side wall 25 of the strut 14. There are in this case two fixing lugs 42, 43, a front bracket 42 and a rear bracket 43. The shows that the first side wall 24 of the strut 14 is fixed integrally, by welding, on the outer side face 11 of the said side spar 3. The shows that the front fixing lug 42 and the rear fixing lug 43 of the second side wall 25 of the strut 14 are fixed integrally, by welding, to the underside 30 of the side spar 3.

There shows that the shock absorber element 13 according to the invention comprises fixing zones 44 to the rear panel 9. Assembly lugs 45, 46 of the strut 14 of the shock absorber element 13, a lug lower assembly 45 and two side assembly lugs 46 form one of the attachment zones 44 to the rear panel 9. FIGURES 4 and 5 show that the assembly lugs 45, 46 of the strut 14 are fixed integrally to the rear panel 9, via a fixing plate 50 of the side spar 3 fixing the lateral spar to the rear panel 9. The assembly tabs 45, 46 of the strut 14 are fixed by welding to the fixing 50. The fixing plate 50 of the side rail 3 is fixed to the rear panel 9 by screws 51.

FIGURES 2 and 3 show that a rear edge 47 connecting the lower wall 23 of the strut 14 to the lower assembly bracket 45 comprises two stiffeners 48. The stiffeners 48 make it possible to prevent deformation of the strut from force 14 in the longitudinal direction.

FIGURES 2 and 3 show that the fixing member 15 comprises an orifice 49 formed in the front end 29 of the lower wall 23 of the strut 14. The orifice 49 is intended to fix the strut 14 to the side spar 3 of the motor vehicle 1, the side member 3 considered being perforated concentrically to the orifice 49 to house therein a rivet for fixing the strut 14 to the side member 3 of the motor vehicle 1.

There schematically shows a kinetics of deformation initiated by the strut 14 of the shock absorber element 13 according to the invention following an impact occurring behind the rear panel 9. In a first insert 601 of the , a mechanical force due to the rear impact is represented by a first arrow 611. This mechanical force is transmitted to the side spar 3 and to the shock absorber element 13 according to the invention. A second insert 602 of the shows that the boot zone 38 tends to deform by folding along the folding line 39, thanks to the two grooves 40, not shown. By bending along the fold line 39, the strut 14 absorbs part of the mechanical force due to the impact. The strut 14 undergoes a programmed deformation corresponding to an elevation of the fold line 39 as represented by a second arrow 612. In other words, the boot zone 38 allows the strut 14 to collapse in the direction of the lateral spar 3. By collapsing in the direction of the lateral spar 3, the strut 14 allows the mechanical forces due to the impact to be dissipated, and the residual mechanical forces transmitted to the lateral spar 3 to be oriented parallel and to colinear way to the side beam 3 so as to compress it horizontally and avoid its verticalization. A third arrow 613 represents the mechanical forces transmitted to the side spar 3 after dissipation at the level of the shock absorber element 13 according to the invention. To facilitate the reading of the , only the bending deformation initiated by the grooves 40 is shown. It is understood that the strut 14 undergoes other deformations, not shown.

In summary, the invention relates to a shock absorber element 13 for a motor vehicle 1. The shock absorber element 13 is intended to be assembled on a rear end 7 of a side member 3 of the motor vehicle 1. The shock absorber element shock 13 comprises a strut 14, a fixing member 15 intended to allow the fixing of the strut 14 to the side member of the motor vehicle 1 and a fixing device 16 intended to allow the fixing of the strut 14 to a rear panel 9 of the motor vehicle 1. In the shock absorber element 13 according to the invention, the strut 14 comprises a deformable device – called device 18 with programmed deformation – configured to allow dissipation of mechanical energy in the event of compression of said strut 14.

Of course, the invention is not limited to the examples which have just been described and many adjustments can be made to these examples without departing from the scope of the invention. In particular, the different characteristics, forms, variants and embodiments of the invention may be associated with each other in various combinations insofar as they are not incompatible or exclusive of each other. In particular, all the variants and embodiments described above can be combined with each other.

Claims (10)

Shock-absorbing element (13) for a motor vehicle (1), the shock-absorbing element (13) being intended to be assembled on a rear end (7) of a side sill (3) of the motor vehicle (1), the shock absorber element (13) comprising:
- a strut (14) comprising a device (18) deformable - said programmed deformation - configured to allow dissipation of mechanical energy in case of compression of said strut (14);
- a fixing member (15) intended to allow the fixing of the strut (14) to the side member (3) of the motor vehicle (1);
- a fixing device (16) intended to allow the fixing of the strut (14) to a rear panel (9) of the motor vehicle (1). Shock-absorbing element (13) according to the preceding claim, in which the strut (14) comprises:
- a bottom wall (23) intended to be located opposite a bottom face (30) of the side beam (3),
- two side walls (24, 25) located on either side of the lower wall (23), the strut (14) having a triangular longitudinal profile (19) along a longitudinal direction parallel to an elongation (10) of the side beam (3) on which the shock absorber element (13) is intended to be assembled. Shock-absorbing element (13) according to the preceding claim, in which the programmed deformation device (18) comprises a first cavity (31) – called concave – formed on the lower wall (23) of the strut (14). Shock-absorbing element (13) according to the preceding claim, in which the device (18) with programmed deformation comprises a second cavity (32) – called convex – formed on the lower wall (23) of the strut (14). Shock absorbing element (13) according to the preceding claim, in which the convex cavity (32) forms a depression oriented in a direction opposite to the concave cavity (31). A shock absorbing element (13) according to any preceding claim, wherein the programmed deformation device (18) has an initiation zone (38) configured to allow the strut (14) to bend the along a fold line (39) bounded by the priming zone (38). Shock-absorbing element (13) according to the preceding claim taken in combination with claim 4 or 5, in which the ignition zone (38) is located between the concave cavity (31) and the convex cavity (32). Shock-absorbing element (13) according to the preceding claim, in which the initiation zone (38) comprises two grooves (40), each groove (40) being formed at the level of a lateral edge (26, 27) of the strut (14) formed by a folding zone of the lower wall (23) and of one of the side walls (24, 25) of the strut (14). Mechanical reinforcement system (2) for a motor vehicle (1), the mechanical reinforcement system (2) comprising:
- a rear panel (9);
- a side rail (3) of the motor vehicle (1), one rear end (7) of which is fixed integrally to the rear panel (9);
- a shock-absorbing element (13) according to any one of the preceding claims, the shock-absorbing element (13) comprising zones for fixing (41, 44) to the side rail (3) and to the rear panel (9) . Motor vehicle (1) comprising a mechanical reinforcement system (2) according to the preceding claim.