FR2838462A1 - Chain link fence, as a dynamic barrier to restrain rock avalanches, is composed of interlaced rings where each ring is interlaced with at least four neighboring rings for strength without weak points - Google Patents

Abstract

The chain fence (12), as a dynamic barrier to restrain rock avalanches, is composed of a number of interlaced circular rings (30-44) so that each ring is interlaced with at least four other neighboring rings. Each ring is formed of a cable with a number of twisted strands, shaped into rings with a diameter of 200-600 mm. The cables for the rings are of metal or polymer materials.

Description

shot blasting (21).

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  The present invention relates to protective barriers against falling rocks on the mountainsides and relates in particular to a barrier comprising a formed net.

of intertwined stitches.

  The protective barriers against falling rocks or boulders consist of a net held by guyed posts across the predictable path of the rocks on sloping ground. When a block of rock falls, there is, at the time of impact with the net, absorption of part of the energy of the block by deformation

of the file.

  It is therefore necessary to have available deformable nets suitable for the absorption of kinetic energy, which is far from being the case with nets simply comprising square or rectangular meshes. The ideal is that the deformation of the net allowing the absorption of energy is mainly

  due to the deformation of the meshes themselves.

  A net meeting this requirement has been described in document EP 0. 370.945. It is made up of intertwined circular meshes, each mesh being interlaced with four adjacent meshes. Unfortunately, each mesh consists of a steel cable with several strands closing on itself, and the junction point of the two ends

  of the cable is produced by an aluminum ring or sleeve.

  This ring constitutes a weak point of the mesh insofar as all the force exerted on the mesh during the fall of a block, is exerted entirely on the ring which thus undergoes a significant tensile force tending to bring out the ends of the cable of the connecting ring. In addition, there is a significant probability that the rock block will crush the ring on impact with the net. It then constitutes a weak point of the mesh which may not resist during the next impact if it has not already been

destroyed by the first impact.

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  This is why the object of the invention is to provide a protective barrier against falling rocks or boulders, the net of which is formed of deformable circular meshes comprising no junction point capable of being weakened or breaking at the following the rock falls suffered by the net. The object of the invention is therefore a dynamic protective barrier against rock falls comprising a net composed of circular meshes interlaced with each other so that each mesh is interlaced with at least four other adjacent meshes, each mesh consisting of a cable composed of n twisted strands in which a single strand looped so

  helical n times on itself forms the n strands.

  The aims, objects and characteristics of the invention

  will appear more clearly on reading the description

  which follows made with reference to the drawings in which: - Figure 1 is a schematic representation of a dynamic protective barrier according to the invention, - Figure 2 is a representation of part of the net according to the invention showing the meshes circulars without junction point interlaced one inside the other constituting the net, and FIG. 3 is a representation of the cable forming the mesh showing the strands constituting the cable coming from a

single strand.

  A dynamic barrier according to the invention, illustrated in FIG. 1, is generally installed on sloping ground 10 along a contour line. A mesh netting 12 is secured to the ground by means of two posts 14 and 16 anchored to the ground and held by guy wires anchored to the ground by means of anchoring plates or other anchoring means. The net 12 which is used to dissipate the energy due to the fall of boulders

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  is fixed to the two posts by means of bordered cables. The net 12 according to the invention is formed from a multitude of interlaced meshes as illustrated in FIG. 2 which represents a preferred embodiment of the invention. Each mesh such as the mesh 30 is interleaved with four adjacent meshes 32, 34, 36 and 38 although it is possible that each mesh is interlaced with a larger number of meshes, for example 6 meshes. Each mesh is circular and does not have a crimping ring as explained above, unlike the meshes described in document EP 0.370.845. The meshes constituting the edge of the net such as meshes 40, 42 or 44 are interlaced

  with the cable 46 forming the edge of the net.

  In general, the cable constituting the mesh

  illustrated in Figure 3 consists of several strands.

  In a preferred embodiment, the cable consists of six strands surrounding a space which may or may not be occupied by a core. The strands are twisted so as to each form a helix of a determined pitch. In a conventional cable, the strands constituting the cable are separate strands. But in the context of the invention, the six strands are in fact a single strand which is looped back on itself and therefore has a length equal to six times the circumference of the mesh if the two ends of the strand are placed end to end as it is better. The braiding of the cable constituting a mesh is done by twisting on itself a strand whose length is equal to six mesh circumferences, the strand having to be passed six times through each adjacent mesh so as to intertwine the

  mesh in formation with adjacent meshes.

  It can therefore be seen that the mesh of the object of the invention has no crimping ring. There is therefore continuity of the cable all along the mesh without a

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  weak point constituted by a ring due to the fact that the latter would be subjected to a significant force which is exerted on the mesh during the fall of a rock and which, moreover, could be crushed by the rock considerably reducing the resistance of the mesh. Unlike the classic mesh with ring, the force undergone by the mesh when falling from a rock, is balanced along the cable by the

  friction that the strand exerts on itself.

  Although the cable made up of six strands resulting from the same strand looped back six times on itself is the preferred embodiment, the cable could be made up of a number of strands n different, the strands being always formed using of a single strand. However, it goes without saying that the fewer the strands, the less the frictional force between strands absorbing the tensile force resulting from the fall of a rock. Therefore, the minimum number of strands cannot be less than three. Likewise, the number of strands constituting the cable cannot be too large because too many twisted strands, although increasing the frictional force between strands, results in a cable of too large diameter which decreases the flexibility of the mesh. It should not be forgotten that, when a rock falls, a large part of the energy is dissipated thanks to the flexibility of the net when the meshes lose their circular shape and rather take the form of a ellipse in shock. The number of strands n is therefore preferably less than or

equal to 8.

  Preferably, the diameter of the meshes can be between 200mm and 600mm without the maximum being limited. Note that it is possible to have rows whose meshes are of variable diameter depending on their proximity to the edge cable. For example, the meshes of the first row could have a diameter of 300mm while the meshes of the second row could have a diameter of

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  350mm. But in this case, it is necessary not to provide a mesh (that is to say leave an empty space) after each

  sequence of six stitches in the second row.

  According to the importance of the rock falls which varies according to the ground, the diameter of the cable constituting each mesh can be different, a larger diameter allowing to dissipate a greater energy than a smaller diameter. Also the cable diameter can be understood from

preferably between 5mm and 20mm.

  According to an important characteristic of the inventlon, with an equal mesh diameter, the diameter of the cable constituting the

  mesh can be variable depending on its location in the net.

  It is found in fact that the forces exerted on the meshes are greater on the edge of the net, for example the meshes 40, 42 and 44 intertwined with the edge cable 46, than those which are exerted at the center of the net. It is therefore advisable to increase the diameter of the cable constituting the mesh when going from the center of the net to its edges. We can thus provide a cable diameter increasing from: - 12mm in the center to 20mm at the edge - 8mm in the center to 16mm at the edge

- 5mm in the center to 12mm at the edge.

  The material used for the cables constituting the meshes is preferably metal and in particular galvanized or stainless steel. However, it is possible to make the net using a material made of synthetic polymer fibers, for example polyester or polyamide

and in particular in Kevlar or Dyncema.

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Claims (9)

REVENDI CAT IONS   1. Dynamic protective barrier against falling rocks comprising a net (12) composed of circular meshes (30 to 44) interleaved with each other so that each mesh is interlaced with at least four other adjacent meshes, each of the mesh consisting of a cable (50) composed of n twisted strands; characterized in that the cable constituting each of said meshes is composed of a single strand looped so helical n times on itself.   2. dynamic protective barrier according to claim 1, in which the cable (50) constituting each mesh comprises a number of strands n formed from a single strand included between 3 and 8.   3. Dynamic protective barrier according to claim 2, in which the number n of strands forming said cable (50) is equal to 6.   4. dynamic protective barrier according to claim 1, 2 or 3, wherein said net (12) is surrounded by an edge cable (46) secured to ground anchor posts (14, 16), the meshes are finding at the edge of the net being intertwined with said border cable.   5. Dynamic protective barrier according to claim 4, in which the diameter of the meshes (30 to 44) is included between 200mm and 600mm.   6. Dynamic protective barrier according to claim 5, in which the diameter of the meshes is variable according to their proximity with respect to the border cable, the meshes of a row of meshes further from said border cable having 7 2838462   a diameter larger than the meshes of a row which is less distant. 7. Dynamic protective barrier according to claim 4, 5 or 6, in which the diameter of the cable constituting the   mesh is between 5mm and 20mm.   8. Dynamic protective barrier according to claim 7, in which the diameter of said cable has an increasing value according to the location of the meshes, the meshes closest to said edge cable being made up of a cable whose diameter is greater than that of the cable constituting the   stitches near the center of the net.   9. Dynamic protective barrier according to any one of   previous claims, wherein the material   constituting the mesh of the net is chosen from metals and in particular galvanized or stainless steel and synthetic polymer fibers such as polyester or