This application is a National Stage Entry of International Application No. PCT/FR2016/051698, filed Jul. 5, 2016, and claims the benefit of and priority to French Application No. 15 56425, filed Jul. 7, 2015, all of which are hereby incorporated by reference in their entirety for all purposes as if fully set forth herein.
The present invention relates to civil-engineering structures of the reinforced ground type, for example a fill, a dyke, a gravity dam, a supporting block, a fluid-retention catchment bank, a bridge pier, etc. This type of structure normally comprises a facing and a fill in which reinforcements connected to the facing are installed.
The present invention relates in particular to the facing elements, often in the form of prefabricated concrete blocks, the constitution thereof and the method for obtaining such facing blocks.
More precisely, the concern is with the areas where the fill reinforcements are attached to the inside of the facing block.
Various solutions and configurations for attaching to the facing a continuous reinforcement with an outward length, a loop that passes around an anchoring core in the facing block and a return length are known from the prior art. The documents U.S. Pat. Nos. 5,839,855 and 8,790,045 can in particular be cited.
According to the known art, a plastic moulding insert is placed in a mould intended for manufacturing a facing block, and then concrete is poured in liquid form into the space provided for the facing block, part of the concrete coming to occupy a space corresponding to the anchoring core designed to hold the fill reinforcement, but without occupying a cavity reserved for the passage of the fill reinforcement.
In addition, in some cases, this moulding insert fulfils a sealing role and prevents the liquid concrete arriving in the cavity in which the reinforcement will pass through once installed. The contact between the concrete and the reinforcement could cause premature degradation of the latter. In some other cases, this moulding insert also fulfils the role of sealing in the finished structure.
The inventors remarked firstly that the manufacture of such moulding inserts presented certain difficulties and proved to require complex moulds. Moreover, the inventors remarked that these known moulding inserts, which must be transported from their own manufacturing site to the site where the facing blocks are prefabricated, occupy a large amount of space compared with the volume of material (in other words the void fraction is high in the packages).
There therefore exists a need to further optimise the moulding inserts, the manufacture thereof and the installation thereof in the block prefabrication mould, while keeping good properties of mechanical strength required for the connection/binding between the facing blocks and the reinforcements in the fill and therefore for good coherence of the structure to be erected.
To this end, according to the invention, a moulding insert is proposed, configured so as to be inserted in a mould for manufacturing a concrete facing block intended for a reinforced-ground structure, said reinforced-ground structure comprising a facing formed by such facing blocks and a fill in which reinforcements are installed, preferably in the form of bands, connected to the facing, the moulding insert comprising:
the shell having a first lateral face pierced with a first orifice in which a first end portion of the core envelope is fitted,
characterised in that the core envelope is in the general form of a truncated cone.
By virtue of these provisions, before assembly, a plurality of core envelopes can be stacked on top of one another, and a plurality of shells can be stacked in one another, which considerably reduces the void fraction in the packages transporting these pieces, which makes the solution overall less expensive. In addition, such a core envelope can easily be assembled in such a shell in order to form a moulding insert intended to create a cavity used subsequently as a connection with a reinforcement.
In various embodiments of the invention, it is optionally possible to have recourse also to one or other or all of the following provisions:
Moreover, the invention also relates to a method for producing a moulding insert:
Other aspects, aims and advantages of the invention will emerge from a reading of the following description of several of the embodiments thereof, given by way of non-limitative examples. The invention will be better understood with regard to the accompanying drawings, in which:
In the various figures, the same references designate identical or similar elements.
By way of example, a civil-engineering structure according to the invention may be a dam, a dyke, a fluid-retention structure, a canal bank, a construction intended to widen or raise an existing structure, a slope circumscribed by a facing, a bridge pier or more generally any other civil-engineering structure.
The reinforcements 3 fulfil the role of mechanical stabilisation of the fill 92 and provide structural cohesion between the fill 92 and the facing 9, as is known per se.
The facing 9 is substantially vertical as illustrated in
In a Cartesian reference frame, the facing extends generally in a plane YZ with a normal along the axis X, which is perpendicular to the plane. Moreover, a reference plane P is defined at the rear surface 96 of the facing.
In the example illustrated, the facing 9 is a concrete wall, the wall preferably being produced in a modular fashion, as illustrated in
It should be noted that the facing 9 may be inclined and that the front face may be planted with vegetation. The space facing the front face may be open to the air or filled with a liquid to be retained.
The fill 7 of the structure may be done with earth and/or stony aggregates, these materials being compacted with a roller in strata. The fill 7 contributes through its weight to the stability of the civil-engineering structure 90 in question.
The fill 7 is produced by installing successive layers from the ground or foundation 91 as far as the top end of the structure. Between each layer, a plurality of reinforcements 3 are disposed substantially in a horizontal plane over the entire surface. The reinforcements 3 can be disposed at a distance from each other along Y and parallel to one another, and in this case they extend from the rear of the facing substantially in the direction X. According to another configuration, the reinforcements 3 may extend aslant with respect to the direction X (cf. below and
By means of the inclusion of the reinforcements 3 in the fill 7, in this way what is referred to as a “reinforced ground” is formed.
The reinforcements 3 are produced in the form of reinforcing bands made from synthetic fabric or plastics material, “geotextile band” is also spoken of, a known example is given in the document EP2247797. Each band forming a reinforcement typically has a generally rectangular cross section with a width of 3 to 10 cm, typically 5 cm, and a thickness of between 2 and 6 mm, typically 4 mm; in addition the reinforcement extends over a relatively great length in its so-called longitudinal direction X′, namely several metres or even several tens of metres. The reinforcement works essentially in traction along its longitudinal direction, for which it has good strength. The reinforcement can flex in the direction perpendicular to its plane, so as to form a loop around the anchoring core. Twisting about the longitudinal axis is also possible.
In some configurations, the reinforcement 3 is installed in a given horizontal plane forming zigzags, that is to say it enters and leaves the facing block at the attachment zone along X′ with a certain angle vis-à-vis the normal direction X.
The interface and the attachment between the reinforcements 3 and the facing 9 is described below in detail, with reference to
Each of the slabs 4 of the facing comprises at least one attachment zone 5 for receiving and anchoring a reinforcement 3. This attachment zone 5 comprises a cavity 50 forming a recess inside said slab 4, and emerging on the rear surface 96 of the facing 9. Preferably, the cavity 50 emerges only the rear surface 96. The cavity has an anchoring core 6 passing through it along the axis Y, an anchoring core around which the reinforcement 3 passes and is held thereon.
The anchoring core 6 delimits and separates a top opening 51 and a bottom opening 52 of the cavity 50.
A reinforcement 3 is installed by fitting one end of the reinforcement through one of the openings, for example the bottom opening. The reinforcement is then pushed so that it turns in the bottom 53 of the cavity and emerges at the top opening. Thus the reinforcement makes a loop around the core with outward length 31, a loop portion 33 held by the anchoring core and a return length 32.
It should be noted that the facing blocks have an overall thickness (along X) denoted D1 (typically in the range [10 cm-50 cm]) and that the depth of the cavity from the rear of the facing is denoted D2, D2 being able to be typically between ⅕ and ⅗ of D1.
Facing blocks are fabricated by pouring liquid concrete into a prefabrication mould 47, and then it is waited until the concrete sets/cures in order to remove it from the mould and move the facing block to the site and install it on the facing being constructed in the structure.
A mould 47 with a roughly parallelepipidal shape in the example illustrated is disposed, and one or more moulding inserts 8 by means of which the aforementioned attachment zones 5 are formed are placed inside the moulding form.
As illustrated in
Each of these parts (core envelope and shell) is obtained by moulding, independently of each other, usually on a site remote from the work site, where they will be assembled for use. Then, on the site where the facing blocks are prefabricated, a core envelope 2 is assembled in a shell 1 in order to form a moulding insert 8 that is placed in the mould 47.
The shell 1 delimits a general space of the connection connecting a reinforcement 3 to the facing block, said general volume opening up by splaying towards the reference plane P, or in other words this space forms a splayed bowl open towards the opening 51, 52 to the outside.
The core envelope is intended to delimit the volume of the concrete anchoring core 6 already mentioned.
It should be noted that the core envelope 2 advantageously has the general shape of a truncated cone centred on the axis denoted W, a conicity the usefulness of which will be seen below. The generatrix base of this truncated cone form is in the example illustrated an ellipse, but naturally any other form could suit.
Generally, the core envelope 2 is summarised as a simple tubular form with a thin wall with a void inside and the two open ends. However, by virtue of the general truncated cone form, it should be noted that the first end portion 21 of the core envelope has dimensions a little less than those of the second end portion 22.
The shell 1 comprises a first lateral face 15 pierced with a first orifice 11, a second lateral face 16 pierced with a second orifice 12, and two other so-called longitudinal faces 13, 14 that join continuously in the bottom zone 83 of the shell (the bottom zone 83 intended to form the bottom of the cavity).
It will be noted that the lateral faces 15, 16 are not parallel; the bottom is narrower and an opening angle (respectively denoted θ1 and θ2) are provided, which gives a general splay to the shell in the direction of the main opening, which is intended to be arranged in the vicinity of the aforementioned reference plane P. Likewise, the longitudinal faces 13, 14 diverge outwards (with an angle denoted β1, cf.
Advantageously, by virtue of such a splayed form, a plurality of shells 1 can be stacked in one another as illustrated in
It will be noted that the core envelopes 2 also can be stacked in one another as illustrated in
It is thus possible firstly to transport many shells in a reduced space and secondly to transport many core envelopes in a reduced space from production sites which may be separate and moreover very distant from the site of the structure 90.
At the time of assembly of the moulding insert 8, the core envelope 2 is fitted with its end portion with the smallest dimension before the movement (as illustrated in
The result is that the first end portion 21 is fitted in the first opening 11 of the core envelope, and that the second end portion 22 is fitted in the second opening 12 of the core envelope.
The fitting is preferably done without clearance so that the interface between the first end portion and the first orifice 11 forms a continuous closed joint; for this purpose, it is possible to provide a certain flexibility of the material that contributes to taking up any possible dispersion in manufacture. Likewise, at the second orifice 12, the fitting is preferably done without clearance.
Advantageously, in order to obtain good fitting, in other words good wedging of the core envelope 2 in the orifices 11, 12 of the shell, a conicity α1 of between 1° and 10° is provided, preferably around 5°.
In the example illustrated, the core envelope 2 forms an exact truncated cone, that is to say the first elliptical end portion is homothetic with respect to the second end portion.
In addition, provision is made for the ratio of the size of the first and second orifices (11, 12) to correspond to the ratio of the cross sections of the first and second end portions (21, 22), which guarantees simultaneous placement at the two orifices during the insertion movement.
To prevent the core envelope excessively projecting beyond the lateral faces 15, 16 of the shell, provision is also made for the axial ends of the core envelope to be truncated, each following a bevel on the planes P1′ and P2′, adjacent and offset towards the outside with respect to the planes P1 and P2 in which respectively the first lateral face 15 and the second lateral face 16 lie.
In
On the other hand, in
When liquid concrete 45 is poured into the prefabrication mould 47, which is vibrated with vibrators 48, the concrete 45 enters the void space in the middle of the core envelope 2 in order to form the anchoring core 6, and in addition concrete follows the lateral faces 15 and 16 and the longitudinal faces 13, 14 of the shell, without however entering the cavity 50 provided for the passage and anchoring of the reinforcement. Inserting a metal reinforcement (not shown) in the core along the axis W is also possible.
Furthermore, a stop collar 24 may be provided on the second end (and therefore the larger one) of the core envelope 2, as can be seen in
Moreover, notches (not shown), which serve for snapping on, and which provide a sensory feedback for the operator inserting the core envelope in the shell, may be provided.
Advantageously, alignment marks may be provided, on the shell 1R and on the envelope 2R, which enable the operator to correctly orient the core envelope about its axis W during the insertion operation (cf.
Furthermore, a minimum filling mark 49 for the mould is provided on the shell 1, corresponding to a marked level PR0 in
Naturally, the moulding insert 8 is set in the concrete and forms an integral part of the finished facing block 4 ready for use on the facing.
In addition, at the rear of the facing block, a sealing membrane 19 is provided, which may be produced from plastics material, for example high-density polyethylene (PEHD) or other thermoplastic polymer. This sealing membrane 19 (or “sealing sheet”) is adjacent to the rear surface 96 of the concrete facing proper.
This sealing membrane 19 is welded to the rim 10 of the shell by a heat-welding bead 17.
It should be noted that the joint 17 between the sealing membrane 19 and the rim 10 of the shell may be achieved by adhesive bonding or heat welding or any other means known in the art.
The sealing membrane 19 is preferably already installed on the facing part before installation on the structure.
This is because, as illustrated in
The method for assembling the civil-engineering structure 90 according to the invention is not described in detail here since it is known per se. The fill material is installed in strata up to a level where the attachment zones are provided; then tamping is carried out with a compactor; then the reinforcements are installed; then this recommences for the following layer, and so on up to the top of the structure.
Concerning the facing, it can also be erected in strata at the same time as the fill and the reinforcements, or can be erected in advance.
With regard to the arrangements on the sealing of the whole of the facing in service, the operations for making the sealing connections at the interface of the facing blocks are described in the document EP 2567032 (case 564).
Concerning the materials, the shell and the core envelope 2 are moulded from injectable thermoplastic material, of the polyethylene, polyolefin or polypropylene type or any other equivalent material. The thickness of the wall will typically be between 0.5 mm and 2 mm.
It should be noted that the wall thickness and the strength of these parts will be calculated so as to satisfy their assembly and up to the operation of pouring concrete inclusive, since, once the concrete is poured, it is the concrete that gives the rigidity to the whole, and the shell and the core envelope then merely have a role of protection against contact vis-à-vis the reinforcement 3. It would be possible to provide small reinforcing ribs in order to optimise the overall thickness of the shell 1 and of the core envelope 2.
Number | Date | Country | Kind |
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15 56425 | Jul 2015 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2016/051698 | 7/5/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/006043 | 1/12/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5839855 | Anderson et al. | Nov 1998 | A |
8790045 | Cariou | Jul 2014 | B2 |
8985900 | Freitag et al. | Mar 2015 | B2 |
20110044771 | Freitag et al. | Feb 2011 | A1 |
Number | Date | Country |
---|---|---|
2 247 797 | May 2012 | EP |
2 567 032 | Jun 2014 | EP |
Entry |
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International Search Report from PCT/FR2016/051698, dated Sep. 15, 2016. |
Number | Date | Country | |
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20180195251 A1 | Jul 2018 | US |