FR3083551A1 - IMPACT PROTECTION SYSTEM - Google Patents

Abstract

Impact protection system comprising: a. a deformable coherent structure having several faces; and B. a set of integral reinforcements configured to distribute the energy of an impact on the deformable coherent structure, in which the set of integral reinforcements is configured so that a stress bulb generated by an impact on the coherent structure is distributed over several faces of the structure, preferably on at least two opposite faces.

Description

IMPACT PROTECTION SYSTEM

The invention relates to the field of road protection and in particular embankments used along the roadway to prevent exits from roads or to absorb the impacts to a vehicle, a landslide or even rocky blocks.

It is known to use a wide variety of massive structures to stop a localized or distributed impact.

Conventionally, protective drifts are used and consist of a stack of individual containers such as bags or gabions, filled with heavy material, generally granular.

Alternatively, it is known to use a reinforced embankment structure, provided with facings which can be stiffened or vertical.

These structures make it possible to stop an impact either by internal energy dissipation, or thanks to the inertia linked to the mobilization of a certain volume of the structure.

However, these massive structures generally have too large a footprint, which can be particularly troublesome in confined contexts.

Structures with a smaller footprint are often very slender, which limits the ability to stop impact. Indeed, a block which would impact this type of structure with a significant energy would be likely to cross the structure by punching it, or at least to cause external instability, for example a tilting or a sliding of the structure.

In addition, structures with a known limited footprint do not allow sufficient internal energy dissipation due to their low deformability.

There is therefore a need for a structure having a reduced footprint compared to known structures capable of absorbing comparable impacts. This problem can be formulated differently: there is also a need for a structure capable of absorbing a greater impact compared to known structures having a comparable footprint.

In this regard, the Applicant has succeeded in developing a new protection system which achieves this by stressing several faces of a deformable structure, and not only the face which is subjected to the impact.

The protection system according to the invention makes it possible in particular to protect roads in a cramped context.

Also, a first object of the present invention consists of an impact protection system comprising:

at. a deformable coherent structure having several faces; and

b. a set of integral reinforcements configured to distribute the energy of an impact on the deformable coherent structure, in which the set of integral reinforcements is configured so that a stress bulb generated by an impact on the coherent structure is distributed over several faces of the structure, preferably on at least two opposite faces.

By coherent deformable structure is meant a structure capable of absorbing mechanical energy, for example by dissipation of internal energy. Advantageous examples of such structures include granular embankments optionally reinforced with metallic or geosynthetic reinforcements.

Advantageously, such structures can easily adapt to the configuration of the site. Preferably, these structures are chosen so that they can be mounted easily and without heavy formwork. They have good durability, given their conditions of use, generally outdoors.

Ideally the structures are chosen so that they can be repaired without difficulty if necessary.

The fact that the structure has several faces does not mean that it is necessarily polyhedral.

Indeed, the notion of face in the sense of the invention corresponds to an external surface of the structure capable of being directly stressed by a given type of impact. The type of impact is assessed according to the use of the invention. Typically, the invention is intended to protect against impact from a vehicle, rocky blocks or landslides along the roadway. These are all types of impact.

A first face of the structure generally corresponds to the whole of the structure liable to be stressed by a direct impact of a given type. For example, in the case of the impact of a vehicle for a structure located at the edge of the roadway, it is the part of the structure likely to be struck by a vehicle which would make a departure from the road without leaving floor.

This face may have roughness or reliefs, we will still call it a face in the sense of this request. The faces are characterized by their propensity to undergo a direct impact of a given type or not.

At least one other side is not likely to be directly stressed by the impact likely to directly stress the first side.

The set of integral reinforcements comprises at least one reinforcement. In the case where it comprises several reinforcements, it is sufficient that each reinforcement is attached to at least one other reinforcement of the assembly so that the reinforcement assembly is considered to be integral within the meaning of the invention.

The reinforcement assembly is configured in such a way that at least part of the reinforcement assembly enters in tension under the effect of an impact on one face of the deformable structure and applies an increment of compression to the structure deformable.

Thus, in the absence of the set of integral reinforcements, an impact would directly solicit one face of the structure and generate a stress bulb from this single face.

Thanks to the set of integral reinforcements, this same impact requests both the face that it impacts directly, but also at least one other face indirectly, which allows the stress to be distributed by mobilizing a larger volume of the deformable structure. and thus increasing the inertia of the mobilized block. Part of the stress generated by the impact can even be transmitted to the foundation soil when the set of integral reinforcements has at least one anchor point in the foundation soil.

Consequently, the same structure can absorb a higher stress for the same footprint, which constitutes a solution to the technical problem which the invention proposed to solve.

Preferably, the stress is distributed between two opposite faces: the set of integral reinforcements is for example anchored on the opposite face of the structure so that the impact causes a tension of the set of reinforcements which transmits a stress on the opposite side. The distribution of the impact on several faces generally applies an increment of compression to the deformable structure.

The set of integral reinforcements advantageously comprises at least one element chosen from a net, a metallic element, a polymeric element, a bar, a cable, a woven or knitted fabric, and preferably a metallic net.

The set of integral reinforcements may include elements passing through the deformable structure, for example connecting elements distinct from the non-crossing reinforcements but adapted to transmit a tension between different reinforcements through the deformable structure, or adapted to stress the structure on the interior so as to evenly distribute the stress generated by an impact.

The compression transmission can be done by beams, slabs or other positioned at the top of the set of reinforcements.

Advantageously, the set of integral reinforcements is arranged so as to completely envelop the coherent structure, which can make it possible to stress as many faces as possible for a given impact. The set of integral reinforcements is then preferably in tension.

Advantageously, the set of solidarity reinforcements is pretensioned in order to improve its reactivity under impact.

Advantageously, the system is configured to withstand an energy greater than 1 megajoule. Indeed, the system according to the invention is preferably used in a road context, and must therefore be able to absorb significant impacts.

Preferably, the deformable coherent structure comprises a reinforced granular fill. Reinforced granular embankments have very satisfactory mechanical properties given their ease of production. Ease of low-cost production is particularly critical in road application since very large distances may need to be protected.

The granular backfill can be reinforced with metallic or geosynthetic reinforcements. This type of reinforcement makes it possible to very effectively reinforce the properties of embankments when the structure is likely to undergo greater impacts, for example along high-speed roads.

The set of integral reinforcements preferably has anchor points, and at least one anchor point is housed in the coherent structure or at least one anchor point is housed in a foundation soil. The two anchors can for example be in the foundation soil. The location of the anchor points influences the tensioning of the set of integral reinforcements and therefore the way in which an impact will be distributed on the deformable structure.

The coherent structure can be provided with a flexible facing, preferably a flexible facing chosen from geosynthetic sheets and welded or woven mesh panels. The facing is then preferably separate from the set of integral reinforcements. Alternatively, the set of integral reinforcements can replace the facing of the deformable structure.

Preferably, the set of integral reinforcements has a stiffness greater than 1.3 MN / m. The company GEOBRUGG markets reinforcements of the grid, tablecloth or net type which have this type of characteristic.

Preferably, the set of integral reinforcements has at least two ends connected by at least one connecting element, preferably said at least one connecting element passing through the coherent structure.

Another object of the present invention consists of a method of constructing an impact protection system according to the invention comprising a first step consisting in entirely producing a deformable coherent structure, and a second step consisting in covering said coherent structure d '' a set of integral reinforcements configured to distribute the energy of an impact on the deformable coherent structure.

The construction is done sequentially which is very advantageous because it eventually makes it possible to apply the invention to preexisting deformable structures.

Advantageously, the set of integral reinforcements can be pretensioned before a subsidiary step of anchoring the set of integral reinforcements in the structure and / or in a foundation soil.

Those skilled in the art will be able to adapt the invention according to the specific constraints with which they will be faced. In particular, depending on the type of impact to which the structure of the invention is intended to provide protection, adjustments in the type of structure and the configuration of the set of integral reinforcements may be made without departing from the scope of the present invention .

The invention can be better understood using the non-limiting exemplary embodiments described below, and on examining the appended drawing in which:

FIG. 1 is a simplified representation of a first embodiment of the invention, FIG. 2 is a simplified representation of an alternative implementation of the embodiment of FIG. 1,

- Figure 3 is a simplified representation of the embodiment of Figure 1 with an alternative anchoring system,

FIG. 4 is a simplified representation of the embodiment of FIG. 1 with an anchoring produced directly in the coherent structure,

FIG. 5 is a simplified representation of an alternative embodiment of the invention, and

- Figure 6 is a simplified representation of an alternative implementation of the embodiment of Figure 5.

In a first embodiment illustrated in FIG. 1, a massive structure 10 is provided, consisting of granular embankments such as a reinforced soil, further comprising a vegetated facing, not shown.

This massive structure 10 has several faces. Although it is represented schematically by a rectangular parallelepiped in Figure 1, it can have other shapes. The structure is designed to be placed along a highway, in order to absorb shocks caused in particular by possible exits from the road of vehicles.

On a highway, vehicles with a mass of the order of a tonne travel at a speed of the order of several tens of meters per second.

Crash test experiments allow us to estimate the duration of a collision, that is to say the time during which the body of a vehicle deforms, at around one tenth of a second.

When off the road, the corresponding deceleration is in the order of several hundred kilometers per square second.

The structure according to the invention must therefore make it possible to absorb an impact of several hundreds of thousands of Newton.

In order to distribute such an impact in the mass of the massive structure, it is wrapped in a metallic net 11 tensioned by means of an anchor 12.

Thanks to this tensioned net, in the event of an impact, part of the force is absorbed by the net is exerted directly on other parts of the massive structure, which would not have been stressed in the absence of the net. The fact that the net is in tension makes it possible to limit the force absorbed by the net and to transmit a more substantial part of the impact to other portions of the massive structure.

In the embodiment shown in Figure 1, the anchor 12 is made at ground level of the foundation, on either side of the massive structure 10.

However, anchoring 121 can also be carried out at the base of the structure, under the massive structure, as illustrated in FIG. 3.

Alternatively, as illustrated in FIG. 4, the anchor 122 can be produced directly in the massive structure. In this case, the anchor must be strong enough because the force of the impact will largely be transmitted to its level.

The net 11 can consist of a two-dimensional network with a mesh of rectangular shape, for example, as illustrated in FIG. 1, such as a metal grid. However, any network allowing the transmission of force is suitable for implementing the invention. In particular, the net may consist of a one-dimensional network 111 oriented so as to connect two series of anchors and making it possible to urge several faces of the structure, as illustrated in FIG. 2. The net then consists of disjoint and substantially linear sections mutually parallel, such as reinforcing strips. These strips are for example made of steel, or of any suitable material.

The impact can also be transmitted via a complex structure 112 made up of several modules, for example a first net 113 made of polymer material connected to a rigid slab 114 connected itself to a second net 115, as illustrated in FIGS. 5 and 6. The slab is for example a concrete slab, which can be integral with the massive structure. The first and second nets can have identical networks, as illustrated, or not. This network can consist of a regular parallelepiped mesh as in Figure 5, or a more irregular structure, for example a linear structure stretched in a zigzag between two edges of the solid structure, as illustrated in Figure 6. The choice of network depends the geometry of the massive structure, the availability of materials used, and the most likely direction of impact on the structure.

Indeed, the structures according to the invention being for example intended to border a motorway, they will be arranged over many kilometers so that the quantity of materials used can quickly be a limiting data.

Furthermore, depending on the geometry of the massive structure and the direction of the impact, this or that network geometry will allow a more or less effective distribution of the impact.

The two nets must be linked to the slab in such a way as to transfer the impact force from the first network to the slab and from the slab to the second network. One can for example provide connecting means 14 such as steel loops.

The slab is preferably made of a material which is not likely to break when it is stressed in the most likely direction of impact. It can for example be an oriented fibrous material, or an anisotropic concrete. The slab can be designed to absorb part of the force of an impact, for example by deformation, whether in a plastic or elastic regime.

As illustrated in FIG. 6, it is possible to provide an anchor 122 passing under the massive structure and connecting the first thread and the second thread so as to be able to stress the whole of the massive structure in compression.

The various embodiments illustrated are the subject of a sequential installation.

In the case of the structures illustrated in Figures 3 and 6, we begin by providing the anchoring means located under the structure. Then, we install the massive structure.

In the case of the other structures illustrated in FIGS. 1, 2, 4, and 5, one begins by providing the massive structure. It can be a structure created for the occasion or, alternatively, it can be pre-existing structures that need to be improved.

In a final step, the structure is therefore covered by the net or the complex structure configured to distribute a possible impact on the massive structure. The net is for example unwound from the crest of the massive structure, using ad hoc equipment.

It is understood that the modes and that it is possible to bring 5 frame of it.

Unless otherwise and and / or. Similarly, the word "one" is contrary is clarified.

of embodiments described are not limiting improvements to the invention without departing from being specified, the word "or" is equivalent to equivalent to "at least one" unless the

Claims (12)

1. Impact protection system comprising: at. a deformable coherent structure (10) having several faces; and b. a set of integral reinforcements (11) configured to distribute the energy of an impact on the deformable coherent structure (10), in which the set of integral reinforcements is configured so that a stress bulb generated by a impact on the coherent structure is distributed over several faces of the structure, preferably on at least two opposite faces. 2. Impact protection system according to claim 1, in which the set of integral reinforcements (11) comprises at least one element chosen from a net, a metallic element, a polymeric element, a bar, a cable, a textile. woven or knitted, and preferably a metallic net. 3. Impact protection system according to one of claims 1 or 2, wherein the set of integral reinforcements is arranged so as to completely envelop the coherent structure. 4. Impact protection system according to any one of claims 1 to 3, in which the system is configured to withstand an energy greater than 1 megajoule 5. An impact protection system according to any one of claims 1 to 4, wherein the deformable coherent structure comprises a reinforced granular fill. 6. Impact protection system according to claim 5, in which the granular backfill is reinforced by metallic or geosynthetic reinforcements. 7. Impact protection system according to any one of the claims! to 6, in which the set of integral reinforcements has anchor points (12), and in which at least one anchor point (122) is housed in the coherent structure or at least one anchor point (12 ) is housed in a foundation soil. 8. Impact protection system according to any one of claims 1 to 7, in which the coherent structure is provided with a flexible facing, preferably a flexible facing chosen from geosynthetic layers and panels of welded or woven mesh. 9. Impact protection system according to any one of claims 1 to 8, in which the set of integral reinforcements has a stiffness greater than 1.3MN / m 10. Impact protection system according to any one of claims 1 to 9, in which the set of integral reinforcements has at least two ends connected by at least one connecting element, preferably said at least one connecting element. crossing the coherent structure. 11. Method for constructing an impact protection system according to claim 1, comprising a first step consisting in completely producing a deformable coherent structure, and a second step consisting in covering said coherent structure with a set of solidarity reinforcements configured to distribute the energy of an impact on the deformable coherent structure. 12. Method according to claim 11, in which the set of integral reinforcements is pretensioned before a subsidiary step of anchoring the set of integral reinforcements in the structure and / or in a foundation soil.