The present invention relates to a cross-member system with shell of the type comprising a cross-member having a lower face, and an upper face that is intended to receive a rail fastening system, and a shell.
In the present document, a cross-member refers to any type of wood, metal, concrete piece, placed perpendicular to the railway track, and intended to support the rails, maintain their separation, and distribute loads. This may thus be a single-piece cross-member supporting two rails with two lines of rails, or a dual-block cross-member including two concrete rail supporting blocks, each concrete rail supporting block supporting a rail of one of the lines of rails, the two concrete rail supporting blocks being secured, or not secured, by a spacer.
Document FR 2,906,269 A1 discloses a system of the aforementioned type, in which, as shown in
The system is supplied assembled on the railway track production worksite. It is kept in position suspended from the rails for the time needed to pour the concrete of a support apron of the track. Once the concrete has set, the system is wedged in position. If the liner is secured to the apron, the cross-member can move sideways and elastically relative to the liner, owing to the soleplate 17. This makes it possible to absorb vibrations upon passage of the vehicles.
A sealing gasket 8, or more generally an element forming a sealing gasket, is provided between the upper rim of the peripheral wall of the liner 6 and the side walls of the cross-member 12. The purpose of this seal is to prevent water or fine particles from infiltrating inside the liner, between the liner and the cross-member, risking blocking the possibility of movement of the cross-member.
The placement of this seal is a step in the manufacturing method of such a system that requires labor. This results in a high cost of the obtained system and a placement quality of the seal that depends on the operator.
Furthermore, during the transport and handling of the system, deformations of the system may result in loosening the seal from the cross-member. Once the system is fixed in the apron, it is then necessary to use a large quantity of adhesive to fasten the seal to the cross-member again so as to reestablish the sealing. Here again, this is an operation whose performance quality depends on the dexterity of the operator.
The invention therefore aims to resolve these problems.
To that end, the invention relates to a system of the aforementioned type, characterized in that the shell envelops substantially the entire cross-member so as to define an inner volume for receiving the cross-member that is sealed against outside attacks.
According to other optional features of the invention:
The invention also relates to a railway track segment, characterized in that it comprises an apron, a plurality of cross-member systems with shells according to the system described above and a pair of rolling rails that bears on each of these systems.
The invention will be better understood upon reading the following description, provided as an example, and in reference to the drawings, in which:
In reference to
The rigid cross-member 12 (or crosspiece) is for example made from concrete. In the described example, it has a substantially parallelepiped shape. The cross-member 12 thus includes a lower face 20, an upper face 22 and four side faces 21 connecting the lower and upper faces to one another.
The upper face 22 of the rigid cross-member 12 includes an installation zone 23 for the rail fastening system 14. In the embodiment of
The rail fastening system 14 makes it possible to keep a rail 15 in position on the cross-member 12. The rail fastening system 14 includes lag screws 42, 43 screwed into the cross-member 12 to fasten the base 41 on the latter.
The base 41 is a rectangular plate having a width smaller than that of the cross-member 12 and a thickness substantially equal to the height of the indentation defining the installation zone 23 of the system 14 on the cross-member 12. Such a plate is generally made from metal, but rigid plates made from a composite material are now commercially available. It is inserted between the rail 15 and the cross-member 12. The rail fastening system is therefore called an indirect fastening system.
The rail fastening system 14 also includes a pair of fasteners 44, 45 making it possible, by screwing the lag screws 42, 43, to jam the shoe of the rail 15 between the fastener and the base. The two fasteners 44 and 45 are placed on either side of a transverse plane of the railway track and median plane of the cross-member 12.
Alternatively, other rail fastening systems, known by those skilled in the art, may also be implemented. For example, the fastener holding the rail can be fixed differently than by the lag screw maintaining the base.
The shell 13 envelops substantially the entire cross-member 12 so as to define an inner volume for receiving the cross-member 12 that is sealed against outside attacks.
In the considered embodiment, the shell is made up of the vertical assembly of two half-shells. Below, the lower half-shell is called liner and the upper half-shell is called cover.
The liner 16 is configured to receive the lower portion of the cross-member 12.
The liner 16 includes a substantially flat bottom 60, and a peripheral wall 61 rises from the bottom 60 and ends with a free rim 63.
The cover 18 is configured to cover the upper portion of the cross-member 12. The cover 18 includes a substantially flat ceiling 82, and a peripheral wall 81 that falls from the ceiling 82 and ends with a rim 85.
The rim 85 is provided with a collar 86 widely covering the rim 63 of the liner. This makes it possible to greatly, or even completely, limit the entry of water or dust into the inner volume defined by the shell 13.
Advantageously, the collar 86 makes it possible to secure the cover 18 of the liner 16 by snapping. In this way, the shell formed by the liner and the cover defines a sealed volume protecting the rigid cross-member 12.
To produce this snapping, the liner and the cover have a certain rigidity. The cover 18 and the liner 16 are for example made by thermoforming a suitable plastic material, for example polyvinyl chloride (PVC), or acrylonitrile butadiene styrene (ABS).
Thus, in this embodiment, the system 10 does not include a sealing gasket between the rim 63 of the liner 16 and the side faces 21 of the cross-member 12.
Advantageously, the cover 18 is secured to the cross-member 12. In the first embodiment of
Preferably, the cross-member system with shell 10 includes a resilient sole plate 17 inserted between the bottom 60 of the liner 16 and the lower surface 20 of the cross-member 12. Also preferably, a plurality of resilient segments 19 are inserted between the peripheral wall either of the liner 16 or of the cover 18 and the side faces 21 of the cross-member 12.
The sole plate 17 and the segments 19 make it possible to absorb vibrations upon passage of trains.
The shell has a relative rigidity allowing it to follow the deformations of the cross-member 12.
Advantageously, a sealing gasket, not shown, is kept compressed between the rim 85 of the peripheral wall 81 of the cover 18 and the rim 63 of the peripheral wall 61 of the liner 20.
Alternatively, the cover 18 is fixed to the liner 16 by riveting of their rims.
In this second embodiment, the manner in which the cover is associated with the liner is modified.
Thus, the rim 163 of the peripheral wall 161 of the liner 116 includes a planar portion 162 inclined outward, a substantially horizontal edge 165 and a falling rim 166.
The rim 185 of the peripheral wall 181 of the cover 118 is intended to cooperate with the rim 163 of the peripheral wall 161.
It therefore includes a portion forming a transom 187, a substantially horizontal edge 184 and a fallen rim 186.
The portion forming a transom 187 has an outer face 188, intended to be pressed against the planar portion 162 of the rim 163 of the liner 116. It consequently has an incline identical to that of this planar portion 162.
The outer face 188 is provided with a slot, which is open toward the planar portion 162. This slot is intended to receive a sealing gasket 190.
In the assembled position of the cover 118 on the liner 116, the sealing gasket 190 is deformed by compression. The transom configuration of the rim 185 makes it possible, by playing on the elasticity of the material making up the cover 118, makes it possible to apply a suitable compression force.
The edge 184 is intended to be pressed against the edge 165. To keep the cover on the liner, rivets 195 are positioned regularly over the entire periphery of the shell. These rivets are inserted into piercings provided on the edges 184 and 165.
In the assembled position, the fallen rim 186 is intended to widely cover the fallen edge 166.
Independently of how the cover and the liner are associated, the method of securing the cover 118 to the cross-member 12 is modified. In this second embodiment, the ceiling 182 of the cover 118 includes an aperture 183. The contour of the aperture 183 is curved inwards so as to cooperate with the edge of the indentation defining the installation zone 23 of the rail fastening system 14.
The cooperation of the contour 183 with the edge of the indentation defining the zone 23 and the association of the liner and the contour makes it possible to guarantee maintenance in position of the cover 118.
More generally, the contour of the aperture 183 is configured to engage in a slot, and for example the edges of a slot, provided on the upper face of the cross-member 12 around the installation zone 23 of the rail fastening system 14. The slot corresponds to the aforementioned indentation.
In the embodiments described here in detail, the liner and the cover are made from a rigid material. Alternatively, the liner and the cover are made from a flexible material, for example rubber.
In the embodiments described here in detail, the liner and the cover are two separate parts made independently of one another, then associated to form the sealed shell. Alternatively, the liner and the cover form a single integral piece making up the shell substantially completely enveloping the cross-member. For example, the shell is then made from a flexible and elastic material making it possible, by deformation, to insert the cross-member inside the shell.
Number | Date | Country | Kind |
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16 52356 | Mar 2016 | FR | national |
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Number | Date | Country | |
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20170268179 A1 | Sep 2017 | US |