FR2896520A1 - ERRIGE WORK IN FRONT OF A PRE-EXISTING WALL, COMPRISING A SIDING AND A FIXTURE BETWEEN THE WALL AND THE SIDING, AND A METHOD FOR CARRYING OUT SAME - Google Patents

Abstract

The structure erected in front of a pre-existing wall (1) comprises a facing (3) erected along a front face of the structure, an embankment (5) occupying an interval between the facing and the wall, and means (6, 7) maintaining the facing relative to the wall, extending into the embankment. The holding means comprise first reinforcing elements (6) attached to the wall (1) and extending into a first zone of the embankment (Z1), and second reinforcing elements (7) connected to the cladding (3) and extending into a second area of the embankment (Z2). The first and second zones (Z1, Z2) have a common portion (Z ') where forces are transmitted between the first and second reinforcement elements by the embankment material.

Description

CONSTRUCTION WORK AND METHOD FOR MAKING THE SAME,

  The invention relates to the construction of civil engineering works using reinforced embankment techniques. The structures concerned by the invention may have various uses such as widening traffic lanes, extending a building space, prevent deterioration, erosion or falling rocks of walls or rock walls, or create a massive aesthetic. They generally comprise a backfill placed vertically or substantially vertically against the solid mass or structure supporting the traffic lane or the building space or whose wall deteriorates. The vertical wall at the front of this embankment consists of a facing connected to the pre-existing structure. However, this preexisting structure may have irregular geometric characteristics.

  Thus the construction of an embankment whose siding must be straight and the rectilinear layout requires taking into account irregularities on the front side of the pre-existing structure. Indeed, the width of the embankment will have to vary in the direction of the height and in the direction of the length. To avoid this difficulty, one solution is to level as far as possible the wall against which the embankment will rest. Thus the organs connecting the facing to this wall will be about the same length. The residual imperfections of the wall are then remedied by pragmatic length adjustments by time-consuming empirical methods.

  Another solution is to provide openings in the facing elements so as to pass the connection members anchored to the wall of the pre-existing structure. The connecting members are then energized with jacks and then anchored to the facing. This solution requires a relatively large amount of handling and time and thus increases the cost of building the embankment. An object of the present invention is to propose another solution that allows the simple and fast construction, and therefore inexpensive, of a backfill having a regularly shaped facing, typically a flat shape, in front of a pre-existing wall whose shape may be irregular.

  The invention thus proposes a construction work erected in front of a wall. The structure comprises a facing erected along a front face of the structure, an embankment occupying an interval between the face and the wall, and the elements for holding the facing relative to the wall, extending into the embankment. According to the invention, the holding members comprise first ~ o reinforcing elements attached to the wall and extending in a first area of the embankment, and second reinforcing elements connected to the facing and extending in a second zone of the embankment which has, with said first zone, a common part where efforts are transmitted between the first and second reinforcement elements by the embankment material. The friction between the reinforcing elements and the embankment material ensures the transmission of forces by the embankment material in the common part between the first and second zones. Such a mode of transmission of efforts has already been proposed in the case of retaining walls (WO2005 / 040506). In the application considered here to the realization of a new wall in front of a pre-existing wall whose profile may be irregular, this mode of transmission of forces ensures the maintenance of the facing relative to the pre-existing wall. An important advantage is that the relative independence between the first and second reinforcement elements makes it possible to attach the first elements to the pre-existing wall without paying particular attention to the relative alignment of the anchoring points with respect to a vertical plane. The first elements will penetrate sufficiently into the embankment to obtain a sufficient thickness of the common part between the first and second zones without the need for precise adjustment of their length. This results in a great simplification in the implementation of reinforcement reinforcement and in the construction of the structure. In preferred embodiments of the structure according to the invention: the facing comprises prefabricated elements in which the second reinforcing elements are partially embedded; these prefabricated elements are preferably made of concrete, the second reinforcing elements being in the form of flexible synthetic reinforcements each having at least one part molded in the concrete of one of the prefabricated elements; this molded portion of the flexible synthetic reinforcement follows a loop in the prefabricated element so as to have two protruding sections in the second area of the embankment, the loop being preferably arranged in the prefabricated element so that the two sections in projection of the flexible synthetic reinforcement emerge from the siding in the embankment at vertically offset positions; the second reinforcing elements comprise layers of geotextile extending in the second area of the embankment. Preferably, the structure then comprises plies of geotextile folded so as to each have a front portion extending along the front face of the structure and forming a portion of the facing, and two layers folded from said front portion and extending substantially horizontally in the backfill to form two of the second reinforcing members; the second reinforcing elements comprise metal reinforcements attached to the facing and extending into the second area of the embankment; there is substantially no direct contact between the first reinforcing elements and the second reinforcing elements; the first and / or the second reinforcing elements are flexible synthetic strips; the first reinforcing elements in the form of flexible synthetic strips are arranged along zigzag paths in the first zone of the embankment. Another aspect of the invention relates to a method of constructing a structure in front of a wall, in which a facing is erected along a front face of the structure delimiting a volume to be backfilled, and material is provided. embankment in an interval between the facing and the wall after having established in said gap of the facing members of the facing relative to the wall, and compacting the backfill material. According to the invention, the holding members comprise first reinforcing elements attached to the wall and extending in a first area of the embankment, and second reinforcing elements connected to the facing and extending into a second area of the embankment which has a common part with said first zone, so that after supply and compaction of the backfill material, efforts are transmitted between the first and second reinforcing elements by the embankment material located in said common part.

  Other features and advantages of the present invention will appear in the following description of nonlimiting exemplary embodiments, with reference to the accompanying drawings, in which: - Figure 1 is a schematic side sectional view of an example of work according to the invention; FIG. 2 is a schematic view from above of the structure of FIG. 1; - Figure 3 is a schematic side sectional view of an alternative embodiment of a structure according to the invention; - Figure 4 is a schematic top view of the work of Figure 3; and - Figures 5 and 6 are partial perspective views of other embodiments of a structure according to the invention. FIGS. 1 to 5 illustrate the nonlimiting application of the invention to the construction of a rectilinear vertical wall at the front of a mass of ground 1 on which a road 2 is built. irregular profile wall on its front side.

  The front face of the structure comprises a facing 3, for example composed of prefabricated elements juxtaposed 4 reinforced concrete. A compacted fill 5 fills the gap between the facing 3 and the wall formed by the front side of the solid 1.

  Referring to Figures 1 and 2, reinforcing elements 6, 7 are buried in the embankment 5 to maintain the facing 3 relative to the solid 1. In the example shown, the reinforcing elements 6, 7 are linear elements such as than rolled steel reinforcements or geotextile tapes. The elements 6 are anchored to the wall on the front side of the solid 1 by means of conventional anchoring members 8 such as for example expansion pins, sealed tabs or nails. The elements 7 are attached to the back of the facing 3 which is for example provided with metal rings to receive them.

  In the example of Figures 1 and 2, the reinforcing elements 6, 7 are placed approximately in horizontal planes and perpendicular to the facing 3. The elements 6 attached to the solid 1 reinforce the embankment 5 in a zone Z1 which extends over more than half of the width of the backfilled interval. Similarly, the elements 7 attached to the cladding 3 reinforce the embankment 5 in a zone Z2 which extends over more than half the width of the backfilled interval. These two zones Z1, Z2 thus overlap in a common part Z ', the thickness of which is sufficient for the friction between the elements 6, 7 and the cohesion of the backfill material 5 to maintain the facing 3 by relative to the solid mass 1. In this common part Z ', the material of the embankment 5 has a high resistance because it is reinforced by the elements 6 and 7. It is thus able to support the forces due to gravity and the application of possible loads at the top. Depending on the dimensions of the structure, the materials used and the spacings between the reinforcing elements 6, 7 (spacings that can be reduced if necessary), the structural calculation allows to evaluate a minimum thickness -6- to respect for the common part Z '. The irregularities of the wall of the massif 1 may locally vary this thickness of the zone Z ', but it is easy to ensure that one is never below the minimum thickness determined.

  To have a good control of the frictional forces, it is preferably made that there is no direct contact between the first and second reinforcing elements 6, 7. FIGS. 3 and 4 illustrate an embodiment variant in which which the reinforcing elements 16, 17 are flexible synthetic armatures in ~ o form bands. By way of example, these reinforcements are synthetic reinforcement strips based on polyester fibers such as those sold under the trademark "Freyssissol". In the example of FIGS. 3 and 4, the strip reinforcement 16 attached to the solid mass are arranged along zigzag paths along horizontal planes in the zone Z1 of the embankment 5. The anchoring members 8 are used to fix the mass 1 of the rings or hooks 9 in which is passed the band which will constitute the frame 16. The front side of the strip is advanced towards the facing so as to ensure the sufficient thickness of the transmission zone Z 'efforts. On the side of the facing 3, the reinforcements 17 are partly molded in the concrete of the prefabricated elements, which ensures their joining to the facing. The molded portion of the flexible synthetic reinforcement 17 follows a loop in the prefabricated element 4, and thus has two protruding portions in the zone Z2 of the embankment 5. These two protruding portions of a frame 17 emerge from the facing 3 at vertically offset positions. One of the reinforcements 16 attached to the solid enters the gap between the two projecting portions of the same frame 17. Another of the frames 16 attached to the solid is inserted between the upper portion of a frame 17 embedded in a cladding element 4 and the lower portion of the frame 17 30 embedded in the cladding element 4 located just above. It will be appreciated that, in the context of the present invention, the possible arrangements of the reinforcing strips in the gap separating the wall 1 from the facing 3 are very numerous. Similarly, all kinds of facings can be used: prefabricated elements slab-shaped, block, ..., wire mesh, planter, etc. On the other hand, it is perfectly conceivable to build the facing 3 by molding it in situ from concrete or special cements, taking care to connect the reinforcing elements 7, 17. The three-dimensional configurations retained for the elements of reinforcement within the embankment 5 can also be very diverse: the patterns may be other than zigzag or comb; elements 6, 16 and 7, 17 can be found in the same horizontal plane (preferably avoiding contact between them); we can have in the common part Z 'a variable ratio between the density of the elements 6, 16 and that of the elements 7, 17; etc. To build a structure according to the invention, one can for example proceed as follows: a) install the anchoring members 8 on the wall at the front of the massif to be covered; b) set up part of the facing elements 4 in order to be able to then bring backfill material to a certain height. In known manner, the mounting and positioning of the facing elements can be facilitated by assembly members placed between them; c) install a layer of reinforcement elements 6, 16 on the embankment already present. The elements 6 are attached to the anchors 8 in an embodiment according to Figures 1 and 2. In an embodiment according to Figures 3 and 4, the reinforcing strip 16 is laid zigzag by passing through the rings 9 and a slight traction is exerted at the line of crawling of the band forward, for example by means of a bar disposed along this line and around which the band is folded at each cusp point; D) providing backfill material over the layer of reinforcement elements 6, 16 which has just been installed, to the next level of the reinforcing elements 7, 17 on the back side of the facing elements. 4. This backfill material is compacted as it is added; e) placing on the embankment the reinforcing elements 7, 17 located at said level, exerting a slight pull on them; f) providing fill material above this level and progressively compacting it to the next specified level for placement of reinforcing members 6, 16; g) Repeat steps b) to f) until the top level of the embankment is reached. Another embodiment of the invention is illustrated in FIG. 5. The facing elements as well as the reinforcing elements connected thereto, as previously described, are replaced by geotextile. The geotextile is disposed on the ground or on a layer of backfill material, and is then folded on itself to the bedrock so as to cover and retain a new layer of backfill material and extend into an area of the backfill Z1. The reinforcement elements anchored in the solid mass cross the layer of backfill material and extend over a zone Z2. The zones Z1 and Z2 share a common zone Z 'thus allowing the transmission of forces between the reinforcement elements anchored in the solid mass and the layers of geotextile 27 by the backfill material situated in this common zone. Each layer of geotextile 30 folded on itself thus has a front portion 24 extending along the front face of the work and forming a portion of the facing 23. From this front portion 24, the two folded layers 27 ' extend horizontally in the second zone Z2 of the embankment to form two reinforcing elements for maintaining the facing.

  In the advantageous embodiment illustrated in FIG. 6, the facing 33 is made of welded wire mesh, and the reinforcing elements 37 consist of metal reinforcements in the form of rolled steel strips. Alternatively, these frames 37 could be replaced by strips of welded mesh. The embankment may not be homogeneous between the wall 31 and the facing 33. 11 may for example comprise stones on the front side, retained by the trellis and imparting an aesthetic appearance to the completed work, and sand or other material of filling between the wall and the layer of stones. Alternatively, the sand may extend to the wire mesh face 37 being held in place by a geotextile placed on the back side thereof.

1G Figure 6 also shows that the pre-existing wall 31, on which the structure is backed, may not consist of a massive field, but also an artificial structure, for example masonry or concrete.

Claims (14)

  1. Construction structure, erected in front of a pre-existing wall (1; 31), the structure comprising a facing (3; 23; 33) erected along a front face of the structure, an embankment (5) occupying an interval between the facing and the wall, and means (6, 7; 16, 17; 27; 37) for maintaining the facing relative to the wall, extending in the backfill, characterized in that the holding means comprise first elements reinforcement (6; 16) attached to the wall (1; 31) and extending into a first area of the backfill (Z1), and second reinforcing members (7; 17; 27; 37) connected to the facing (3; 23; 33) and extending into a second zone of the embankment (Z2) which has, with said first zone, a common part (Z ') where forces are transmitted between the first and second reinforcing elements by the material of the embankment.   2. Work according to claim 1, wherein the cladding (3) comprises prefabricated elements (4) in which the second reinforcing elements (17) are partially embedded.   3. A structure according to claim 2, wherein the prefabricated elements (4) are made of concrete and the second reinforcing elements are flexible synthetic reinforcements (17) each having at least one molded part in the concrete of one of the prefabricated elements.   4. Work according to claim 3, wherein the molded part of the flexible synthetic reinforcement (17) follows a loop in the prefabricated element (4) so as to have two protruding sections in the second zone of the embankment (Z2). .   5. Work according to claim 4, wherein the loop is disposed in the prefabricated element (4) so that the two protruding portions of the flexible synthetic armature (17) emerge from the facing (3) in the embankment (5). ) at vertically offset positions.-11-   The structure of claim 1, wherein the second reinforcing members comprise layers of geotextile (27) extending into the second area of the backfill (Z2).   7. A structure according to claim 6, comprising geotextile plies (30) folded so as to each have a front portion (24) extending along the front face of the structure and forming a portion of the facing (23), and two layers (27) folded from said front portion and extending substantially horizontally into the backfill (5) to form two of the second reinforcing members.   8. The structure of claim 1, wherein the second reinforcing members comprise metal reinforcements (37) attached to the facing (33) and extending into the second area of the embankment (Z2).   A structure according to any of the preceding claims, wherein there is substantially no direct contact between the first reinforcement members (6; 16) and the second reinforcement members (7; 17; 27; 37). .   A work as claimed in any one of the preceding claims, wherein the first reinforcing members comprise flexible synthetic strips (16). 20   11. The structure of claim 10, wherein the flexible synthetic strips (16) are arranged along zigzag paths in the first area of the embankment (Z1).   12. A work according to any one of claims 1 to 5 and 9 to 11, wherein the second reinforcing members comprise flexible synthetic strips (17).   13. Work according to any one of claims 1 and 8 to 12, wherein the facing comprises a wire mesh (33).   14. A method of constructing a structure in front of a pre-existing wall (1; 31), in which a facing (3; 23; 33) is erected along a front face of the structure delimiting a volume to be backfilled. backfill material (5) in a gap between the facing and the wall after setting in said gap means (6, 7; 16, 17; 27) for maintaining the facing relative to the wall, and compacting the backfill material, characterized in that the holding means comprise first reinforcing elements (6; 16) attached to the wall (1; 31) and extending into a first zone of the embankment (Z1), and second elements reinforcement ~ o (7; 17; 27) connected to the facing (3; 23) and extending into a second zone of the embankment (Z2) which has a common portion (Z ') with said first zone, so that after supply and compaction of the backfill material (5), efforts are transmitted between the first and second elements reinforcement by the embankment material located in said common part.