FR2748042A1 - IMPACT ATTENUATOR DEVICE ON THE EDGE OF A MOTOR VEHICLE TRAFFIC LANE - Google Patents

Abstract

The invention discloses a shock attenuating device consisting of an assembly of elements absorbing the kinetic energy of a collision with the said device, characterised in that the energy absorbing elements are in the form of cylindrical modules (20) which comprise fixing elements (42) each radially disposed and arranged at height levels adapted to an assembly of identical cylindrical modules (20).

Description

DEVICE ATTER'ATEL7R SHOCK PROVIDED IN BORDI, very
OF A TRACK OF CtRCETLATION FOR AUTOMOTIVE VEHICLE
The invention relates to a shock attenuating device arranged on the edge of a lane for motor vehicles, and more particularly on the edge of automobile racing circuits.

For security reasons. protective devices are distributed over a dedicated route. for example. motor vehicle competitions. in order to stop said vehicles when they exit the road and thus protect spectators and all other persons located outside the course. Protective devices also aim to limit the material damage caused to vehicles and to reduce the intensity of the impact on drivers.

In order to stop vehicles it is generally used rails and concrete walls. These obstacles are rigid. it is necessary to precede the latter by a device absorbing part of the intensity of the shock in areas where the likely angle of impact of the vehicle against said rigid obstacles is greater than 30.

Such absorbent devices are generally produced by a stack of tires, and correspond to precise characteristics of maximum height and width limit. In order to create a certain cohesion between the tires. these are grouped in a stack held together by links. Tires are sometimes wrapped in colored plastic film.

heat-shrink, which increases the cohesion between the tires.

The tire stacks are generally connected by means of wire. Implementation. which requires tools. is long and tedious and increases the risk of forgetting objects on the track, such as the tools necessary for said implementation. The plastic films that surround the stacks of tires. are fragile and deteriorate quickly, which requires regular and costly maintenance. Tire stacks must be replaced every three years. When driving off a motor vehicle during a competition, if stacks of tires are destroyed. replacing them requires significant action time.

In order to remedy these drawbacks, the invention relates to a shock attenuating device consisting of identical module which can be assembled to each other without tools.

The invention also relates to a shock attenuating device which requires only spaced and economical maintenance.

The invention also relates to a shock attenuating device which can be repaired very quickly.

According to a characteristic of the invention. the energy absorbing elements are produced in the form of cylinder modules which include radially arranged and arranged fixing groups, each on height levels suitable for an assembly. between them. of identical cylindrical modules.

According to another characteristic of the invention. the cylindrical modules have five fixing groups.

According to another characteristic of the invention. the fixing groups are angularly spaced by 60c.

According to another characteristic of the invention. the fixing groups are formed by at least two fasteners aligned in a direction substantially parallel to the axis of the cylindrical module and spaced by a constant interval X.

According to another characteristic of the invention, each fastener comprises an orifice produced in a direction substantially parallel to the alignment of said fasteners forming a fixing group.

According to another characteristic of the invention, each orifice is of conical shape.

According to another characteristic of the invention. the cylindrical modules receive a content which modifies their capacity for absorbing kinetic energy during a collision against said device.

According to another characteristic of the invention, the cylindrical modules are produced by rotational molding.

According to another characteristic of the invention, the cylindrical modules include a cover.

According to another characteristic of the invention, the cover and the bottom of the cylindrical modules are of complementary shape.

Other characteristics and advantages of the invention will appear on reading the description of exemplary embodiments of a shock attenuating device with reference to the appended drawings in which - FIG. 1 represents an elevation view of a device d 'absorption
shocks according to the state of the art.

- Figure 2 shows a top view of a device for absorbing
shock according to the state of the art.

- Figure 3 shows a perspective view of a stack of tires such
used in a shock absorption device according to the state of the
technical.

- Figure 4 shows a perspective view of a module constituting a
shock attenuation device according to the invention.

- Figure 5 shows a top view of the assembly of the modules
cylindrical according to the invention.

- Figure 6 shows an elevational view of the connection between
cylindrical modules according to the invention constituting an assembly.

- Figure 7 shows an elevational view of a detail of two modules
cylindrical superimposed according to the invention.

- Figure 8 shows an elevational view of a partial section of
connecting means of a module according to the invention.

As shown in Figures l and 2. the safety rails l are generally preceded by a shock attenuating device 2 constituted by stacks of tires 10 which are connected together by links 11, for example wire, now in position said stacks of tires against each other in order to create a compact and homogeneous barrier 2.

The tire stacks 10 in contact with the safety rail 1. can be linked to the latter.

A stack of tires 10. as shown in FIG. 3. comprises a number of tires 12 generally of the same diameter and secured to each other by links 13, such as wire. The tires 12 are wrapped in a thermoformable plastic film 14. usually colored, in order to create an obstacle signaling and to achieve better tire cohesion. These stacks of tires 10 are prepared in advance and assembled together at the place to be protected.

The tire stacks 10 can advantageously be replaced by cylindrical modules 20 receiving a content 30 which can correspond to desired mechanical characteristics. The content 30 may be tires, as shown by way of example in FIG. 4. or any other material which can create sufficient absorption of kinetic energy. The cylindrical module 20 has a closing cover 21. thus protecting the content 30 from external aggressions and making it possible to increase the holding of said module 20.

The cylindrical module 20. as shown in FIGS. 4 and 5, comprises connection means 40 produced in the form of five groups 42 of fasteners angularly spaced by 60 ". The fasteners 41 are grouped in pairs, in our example of embodiment Each fastener 41 forming part of a group 40 is aligned in a direction parallel to the space of the cylindrical module 20 and spaced at a constant interval X. Each group 40 of fasteners 41 is located at a particular height which can allow a cooperation with fasteners 41 carried by an identical neighboring cylindrical module 20. For example, the five groups 40 of fasteners 41 of a cylindrical module 20 are distributed according to three levels of different height - the upper level S - the intermediate level I - the lower level F
As shown in FIG. 5, the fasteners 41 are distributed so that a set of identical cylindrical modules 20. can be assembled and form a shock attenuating device made up of two rows of module 20.

The arrangement of the fasteners 41 shown in Figures 1 and 5. was chosen from several possible combinations. in order to illustrate the invention. The other combinations of fasteners 41 arranged in the same spirit are to be considered as obvious variants of the invention.

In the choice of the arrangement of the fasteners 41, for example - the fasteners 41 of the group, of the module 20a. located on level I come together with those of the group. of module 20c, located on level F.

- the group attachments, module 20b. located on level S come together with those of the group. of module 20a, located at level I and of the group, of module 20c, located at level F.

This distribution into three levels makes it possible to make the various fasteners 41 cooperate with one another, as shown in FIG. 6.

A clearance Y is provided between the clips 41. in order to facilitate the assembly of the modules 20.

Each fastener 41 has an orifice 43. which can receive a connection means 44 as shown in FIG. 6. The connection means 44 can be a pin.

In order to increase the height of the shock attenuating device 2. provision has been made for the possibility of superimposing the cylindrical modules 20, as shown in FIGS. 6 and 7. The covers 21 of the cylindrical modules 20 as well as their bottom 22 can be shaped so as to be able to cooperate during the superposition of two cylindrical modules 20 and to be linked in their relative lateral displacement.

The cylindrical module 20 can advantageously be made of high density polyethylene by rotational molding. allowing a constant thickness to be obtained. This material allows good resistance over time and mechanical characteristics adapted to the function. In this case, the replacement period for the modules 20 is estimated at ten years. As shown in Figure 8. the orifices 43 of the fasteners 41 are conical in order to create draft for the release of the latter during manufacture. The small bases of cones facing each other.

The thickness of a module 20 is determined according to the desire to involve the structure of said module 20 in the rigidity of the shock attenuating device 2. If it is desired to use the modules 20 as a means of packaging a content and connection of said modules 20 with one another. said modules 20 can be satisfied with a thickness allowing them sufficient hold. empty of their content. for their storage and transport. In the case where it is desired to use empty modules 20 in the shock attenuating device 2. said modules 20 must have a sufficient thickness in order to correspond to the criteria of resistance and deformation required.

In order to be able to maintain a certain flexibility of the module 20. the additional load created by the superimposed modules 50 will be mainly supported by the content of said modules 20 located below. The cover 21 being. for example. in contact with the content 30. of the tires in our example.

The assembly of the modules 20 according to the invention by means of an A4 pin, without using a tool. makes it possible to produce a shock attenuating device 2 very quickly without the risk of forgetting any tool or assembly material on the track.

On a part 45 of the circumference of the cylindrical modules 20. as shown in FIG. 5. fasteners 41 have not been provided in order to limit the aggressive zones. It has been estimated. that a shock attenuating device 2 consisting of such modules 20 could meet the expectations of protection.

with only two rows of said modules 20. For these different reasons it is therefore not desirable to create fasteners 41 on the part 45 of the cylindrical module 20.

Claims (10)

1) shock attenuating device constituted by a set of elements  kinetic energy absorbers of a collision against said  device, characterized in that the energy absorbing elements  are produced in the form of cylindrical modules (20) which  have radially arranged fixing groups (42) and  each arranged on height levels suitable for an assembly.  between them. identical cylindrical modules (20).  fixing (42).  the fact that the cylindrical modules (20) have five groups of  2) shock attenuating device according to claim 1. characterized by 3) shock attenuating device according to claim 2. characterized by  the fact that the fixing groups (42) are angularly spaced by 60 ". 4) shock attenuating device according to any one of  Claims 1 to 3. characterized in that the fixing groups  (42) are formed by at least two fasteners (41) aligned in a  direction substantially parallel to the axis of the cylindrical module (20) and  spaced by a constant interval X. 5) shock attenuating device according to claim 4. characterized by  the fact that each fastener (41) comprises an orifice (43) produced according to  a direction substantially parallel to the alignment of said fasteners  (41) forming a fixing group (42). 6) shock attenuating device according to claim 5. characterized by  the fact that each orifice (43) is conical in shape. 7) shock attenuating device according to claim 1. characterized by  the fact that the cylindrical modules (20) receive content (30) which  modifies their capacity to absorb kinetic energy during a  collision against said device. 8) shock attenuator device according to claim 1. taken  combination with one of claims 2, 3 or 4. characterized by  the fact that the cylindrical modules (90) are produced by rotational molding. 9) shock attenuating device according to claim 1. characterized by  the fact that the cylindrical modules (20) have a cover  (21). 10) shock attenuating device according to claim 8. characterized by  the fact that the cover (21) and the bottom (22) of the cylindrical modules  (20) are of complementary shape.