FR3038638A1 - CHAINING DEVICE, AS WELL AS A CHAINING DEVICE COMPRISING TWO SUCH DEVICES - Google Patents

Abstract

The chaining device comprises an elongate lateral formwork body (10) for a concrete casting floor slab (100), which is adapted to be attached and secured to a supporting structure (200) so that the longitudinal direction of the body horizontally and one or more concrete bars (30) which extend substantially parallel to the longitudinal direction of the shuttering body, being arranged on the side (101) of the shuttering body facing the slab and to which one or more transverse concrete bars (50) are attached. The formwork body is designed to carry the concrete bars on its side facing the slab and is solidarily provided, on its side facing the slab, with at least one concrete anchor (15), such as a carp tail, as well as vertical stiffeners (14) which are distributed along the formwork body.

Description

Chaining device, as well as chaining assembly comprising two such devices

The present invention relates to a chaining device, and a chaining set comprising at least two such devices. The invention relates to the field of construction of buildings, that they are intended for housing or economic activities. Where such buildings have more than one floor, the floor of each level above the floor shall be made either by means of a joist or a concrete slab. The use of concrete floor slabs is often preferred. Indeed, a concrete slab, bringing mass to the building, provides good sound insulation between floors, while being economical compared to solutions using a stack of successive layers on a joist. In addition, a concrete slab, even thick, is often less bulky in height than an inter-floor structure incorporating joists and a false ceiling, which limits the total height of the building. Furthermore, the use of a concrete slab has other advantages that are, in particular, a better quality of fire resistance compared to a metal or wood joist, a better horizontal bracing of the building, as well as than a better thermal inertia.

In practice, on site, a concrete floor slab is poured into a formwork ad hoc, by coating concrete bars, commonly called rebars or concrete rounds: these concrete bars, which can be in the form of three-dimensional sheets, run horizontally in the plane of the floor slab to be cast and are connected, typically by ligation yarns, to vertical concrete bars, emerging from the walls or, more generally, supported masonry elements. on which the slab is intended to lean. These horizontal concrete bars and ensure the horizontal chaining of the slab vis-à-vis the rest of the building. It is understood that the installation and positioning of concrete bars must be done with care, failing to compromise the compliance chaining.

Moreover, as explained above, the use of horizontal concrete bars is only possible if vertical concrete bars or similar parts have been previously integrated into the underlying masonry, which excludes casting a slab. concrete floor on a supporting structure other than masonry. This also explains why the joist is systematically implemented in buildings with a light structure, such as wood-frame buildings or those with composite walls having a layer of insulation, rigid or semi-rigid, interposed between two facing panels, that is to say the walls called "sandwich" or traditionally designated by the acronym SIP (corresponding to the English expression "Structural Insulated Panel").

The purpose of the present invention is to overcome the drawbacks mentioned above, by proposing a new chaining device which, while adapting to both a masonry structure building and a lightweight structure, allows so easy and efficient to integrate in this building a slab of concrete floor poured. To this end, the subject of the invention is a chaining device, comprising: an elongate lateral formwork body for a concrete floor slab to be cast, which is adapted to be attached and fixed to a load-bearing structure so that the longitudinal direction of the shuttering body extends horizontally, and - one or more concrete bars running, which extend substantially parallel to the longitudinal direction of the shuttering body, being arranged on the side of the shuttering body turned to the slab, and to which are attached one or more transverse concrete bars, which formwork body is adapted to carry the concrete bars on its side facing the slab, and which formwork body is solidarily provided, on its side turned towards the slab, at least one concrete anchor, and vertical stiffeners which are distributed along the formwork body. The invention thus makes it possible to bond a concrete floor slab to a load-bearing structure. To do this, the chaining of the slab vis-à-vis the supporting structure is achieved by horizontal concrete bars, divided into rods, extending in length in the same direction, and in transverse bars, fixed to the rods by any suitable means, for example by folding, welding and / or ligation with wires. In addition, the concrete rods are mechanically held by an elongated body, which is arranged parallel to these rods, serves as lateral formwork to the slab when it is poured, and is provided with both vertical stiffeners, which advantageously carry the concrete bars, and one or more concrete anchors, such as carp tails, which will be anchored in the concrete during casting and thus ensure the sealing the shuttering body with the slab. It is understood that by providing that the shuttering body can be attached and fixed to any type of supporting structure, the invention makes it possible to treat the horizontal and vertical chaining connection between a concrete floor slab and its supporting structure, which this the latter is as well masonry as light. On site, the implementation of the device according to the invention is simple and practical: the formwork body positions "automatically" the concrete bars of the device relative to the supporting structure. In addition, some of these concrete bars, in particular the concrete bars, can advantageously be pre-assembled to the formwork body in the workshop. Also advantageously, the chaining device according to the invention participates in controlling or even overpressure thermal bridges, as explained in more detail later.

According to additional advantageous features of the device according to the invention, taken separately or in any technically possible combination: the formwork body is made of a metal sheet, in particular shaped as a "U", angle or flat; - The formwork body is made of a material other than metal, in particular plastic or polymers; the or each concrete anchor piece is a carp tail which is integrated with one of the stiffeners; the stiffeners are adapted to carry the concrete bars; each stiffener delimits a notch for transverse reception and wedging of the one or one of the concrete bars; the shuttering body is furthermore provided with support means adapted to support a concrete element to cast cantilevered or terraced with respect to the slab, such as a concrete base of a balcony or a concrete base of a terrace, which means of support comprise: at least one concrete anchor secured to the side of the shuttering body, turned away from the slab, and one or more bars concrete through, which are secured to the formwork body and cross from one side to the other, extending from its sides respectively turned towards and turned away from the slab; - The formwork body is further integrally provided, on its side facing away from the slab, means for attachment to an element other than concrete, reported cantilevered or terrace vis-à-vis -vis the slab, such as a metal structure of a balcony or a metal structure of a terrace; - The chaining device further comprises a thermal breaker, which is either integrated with the support means so as to be interposed between the side, turned away from the slab, the formwork body and the concrete element, either integrated to the attachment means so as to be interposed between the side, turned away from the slab, the formwork body and the non-concrete element. The invention also relates to a chaining assembly, comprising: two chaining devices, as defined above and arranged in the longitudinal extension of one another, and connecting means adapted to bind securely between them the respective chaining bodies of the two chaining devices. The assembly according to the invention ensures the continuity of the chaining between the two aforementioned devices.

According to additional advantageous features of this assembly: - one of the stiffeners of each chaining device is provided at each longitudinal end of the formwork body, and the connecting means are adapted to, in particular by bolting, bind fixedly between them the stiffeners respective chaining devices provided at the longitudinal ends of their shuttering body abutted to each other; the assembly further comprises one or more connecting concrete bars which each connect the one or one of the concrete bars of one of the two chaining devices to the one or one of the concrete bars of the concrete other chaining device, by overlapping these two concrete bars and being fixed to each of them, for example by a ligation wire. The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the drawings, in which: FIG. 1 is a perspective view of a chaining assembly in accordance with FIG. the invention; - Figure 2 is a perspective view along the arrow II of Figure 1; - Figure 3 is an enlarged view of the circled detail III in Figure 1; - Figure 4 is a section along the plane IV of Figure 1, showing the assembly of chaining of Figure 1 integrated into a building; - Figures 5 and 6 are views respectively similar to Figures 1 and 2, illustrating a variant of the chaining assembly, according to the invention; and - Figure 7 is a view similar to Figure 1, illustrating another variant according to the invention.

In Figures 1 to 3 is shown a chaining assembly 2 comprising several chaining devices 1 identical to each other. In the exemplary embodiment considered in the figures, two of the devices 1 are visible, each of these devices being represented only partially.

Each device 1 comprises an elongated body 10 extending in length in a direction which, when the device is in use, is horizontal. As clearly visible in FIGS. 1 and 3, the body 10 has, in the example considered here, a cross section having a "U" profile whose base extends, in use, vertically. Thus, the body 10 includes a base plate 11, which, in use, extends generally in a vertical geometric plane, as well as lower and upper wings 12 and 12, which are each generally in a geometric plane substantially perpendicular to the plate base 11, respectively from the lower end edge and from the upper end edge of this base plate.

In a horizontal direction perpendicular to the longitudinal direction of the body 10, this body has two opposite sides, namely an inner side 101, which is turned towards the reader in Figures 1 and 3, and which, in use, is intended to be turned inward of a building incorporating the device 1, and an outer side 10E, which is turned towards the reader in Figure 2. In Figure 4, the inner side 101 of the body 10 is turned to the left, while that its outer side 10E is turned to the right. The lower wings 12 and upper 13 of the body 10 are located on the inner side 101 of the body.

Within the assembly 2, the respective bodies 10 of the devices 1 are arranged in the longitudinal extension of each other, their inner side being turned towards the inside of the building integrating this assembly 2. As can be seen in FIGS. 3, the devices 1 succeed each other in pairs so that the longitudinal end of the body 10 of one of the devices 1 abuts against the longitudinal end of the body 10 of the device 1 succeeding it.

As can be seen clearly in FIGS. 1 and 3, the body 10 of each chaining device 1 is provided, on its inner side 101, with several stiffeners 14. In the embodiment considered here, each stiffener 14 is in the form of a plate, arranged transversely to the base plate 11 and connecting to each other the lower wings 12 and upper 13. Each stiffener 14 thus extends, in use, vertically.

In a manner not shown in detail in the figures, each of the stiffeners 14 is fixedly secured to the body 10, by any appropriate means. By way of example, each stiffener 14 is welded to the body 10, in particular to the base plate 11 and to the wings 12 and 13.

The stiffeners 14 are distributed substantially uniformly along the body 10, that is to say along the longitudinal direction of this body. The spacing between two successive stiffeners in the longitudinal direction of the body 10 is not limiting of the invention, as long as, for a given body 10, the stiffeners 14 are provided in sufficient number, in other words with a spacing between two successive stiffeners sufficiently small to avoid, in use, the deformation of the body 10, in particular by substantially reinforcing the torsional strength of the body 10. Thus, for purely illustrative purposes, the spacing between two successive stiffeners is of the order of a few tens of centimeters, for example about 60 cm.

According to an advantageous arrangement, which is implemented in the embodiment considered in the figures, one of the stiffeners 14 is provided at each longitudinal end of the body 10 of each device 1. In this way, within the assembly 2 devices 1, the stiffeners, respectively provided at the longitudinal ends of each body 10, are used to allow to bind together the respective bodies 10 of two devices 1 succeeding one another. To do this, by way of example, each stiffener is provided, in its upper part, with one or more through holes 14A, so that at the respective longitudinal ends of the bodies 10 of two devices 1 succeeding one another, or the through holes 14A of the stiffener provided at one of these two ends are aligned, in the longitudinal direction of the body 10, with the or through holes of the stiffener provided at the other end, so that a system of bolting 20 can be engaged with these through holes 14A, as clearly visible in Figure 3, so as to firmly bind together the two aforementioned stiffeners and thereby the bodies 10 of the associated chaining devices 1. Of course, all or part of the holes 14A and the associated bolting system or systems 20 may be provided further along the stiffeners. Similarly, other means than the bolting systems 20 may be envisaged for binding together the respective bodies 10 of two chaing devices 1 succeeding within the assembly 2, both via their stiffener provided at the respective longitudinal ends abutting each other, corresponding bodies 10, that, more generally, at these abutting ends of the bodies 10.

For reasons which will appear below, each stiffener 14 delimits, advantageously in its lower part, a notch 14B, having, in projection in a geometrical plane perpendicular to the longitudinal direction of the body 10, an "L" profile turned downwards. , in other words turned towards the lower wing 12, and having a substantially constant width. As clearly visible in FIG. 3, each notch 14B opens on the edge of the stiffener 14, turned away from the body 10, more precisely opposite its base plate 11. Thus, each notch 14B includes a horizontal branch and a vertical branch, the horizontal branch connecting the aforesaid edge of the stiffener 14 to the upper end of the vertical branch, while the vertical branch extends downwards from the end of the horizontal branch, opposite the outlet of this last on the outside of the stiffener.

Furthermore, as shown in FIG. 1, the body 10 is provided, on its inner side 101, with one or more concrete anchoring pieces, such as carp tails 15. extends generally perpendicular to the base plate 11 of the body 10, its opposite end to the body 10 being shaped generally "V" pointing towards the body, which gives the tail of carp 15 a fish tail shape, explaining so his name. Other forms than those of the carp tails 15 may be envisaged for the aforementioned anchoring pieces. The end of each carp tail, opposite that of "V", is fixedly secured to the body 10 of each device 1, and this by any appropriate means, for example by welding. According to a practical and economical embodiment, which is implemented in the exemplary embodiment considered in the figures, the aforementioned end of each carp tine 15 is advantageously secured to one of the stiffeners 14, or even material with this stiffener: the carp tails 15 are thus integrated with the stiffeners 14.

Moreover, as clearly visible in FIGS. 1 to 3, the assembly 2 of the devices 1 includes concrete bars which will be detailed below. It will be noted that each of these concrete bars is a piece known as such, also being designated by the expressions "concrete bar" or "concrete bar": it is a rebar, commonly made of steel, which is used for reinforcing concrete, which is then called reinforced concrete. Generally, although not shown in the figures, such a concrete bar has a ribbed outer surface, in particular to improve its adhesion with the concrete.

Of the concrete rods of each device 1, one or more concrete rods 30 are said to be arranged on the inner side 101 of the body 10 and each extend substantially parallel to the longitudinal direction of the body 10, over substantially the entire dimension. longitudinal of this body. In the embodiment considered here, each of these rods 30, which are provided in duplicate for each device 1, is located vertically between the lower wings 12 and upper 13 of the body 10, passing right through the stiffeners 14 at their notch 14B. Providing that the notches 14B of the stiffeners 14 have a width equal to or slightly greater than the diameter of the rods 30, it is understood that each device 1 is designed so that each of the rods 30 is received laterally in the horizontal branch of the notches 14B, in being introduced from the outlet of these notches on the outside of the stiffeners, until reaching the vertical branches of the notches 14B, at the bottom of which each bar 30 is wedged opposite the body 10. More generally, the stiffeners 14 of each device 1 are designed to carry the rods 30 belonging to this device, the connection between the stiffeners and the rods can be reported, typically by welding and / or ligation, or this connection may result from developments stiffeners allowing them to cooperate by complementarity of shapes with the rods to retain them, co even this is the case for the notches 14B. Of course, other arrangements of shape, that the notches 14B, are possible for the stiffeners 14, such as, for example, aligned through holes, inside which the rods 30 are threaded from one of the ends Longitudinal of the body 10. In all cases, by carrying the rods 30, the stiffeners 14 of each device 1 predeterminedly position these rods 30 relative to the body 10.

Among the concrete bars of the assembly 2, one or more bars 40 of said connection are each provided for connecting one of the concrete bars 30 of a device 1 to one of the concrete bars 30 of the device 1 succeeding the aforementioned device. In the exemplary embodiment considered here, as clearly visible in FIG. 3, these connecting bars 40 are provided in duplicate at each abutment two by two of the respective bodies 10 of the devices 1 succeeding one another, being noted that, on 3, one of these two connecting bars 40 is shown in phantom for visibility reasons: each of these connecting bars 40 is received transversely in the notch 14B of the respective stiffeners 14 provided for in FIG. butted ends of the two bodies 10, extending on either side of the two stiffeners 14 bolted to each other. In variant not shown, the connecting bars 40 are threaded into dedicated holes of the stiffeners. Each of these connecting bars 40 overlaps the respective ends, adjacent to one another, of the rods 30 respectively belonging to the two devices 1 succeeding one another: each of these connecting bars 40 thus makes it possible to connect one to the other. other these two rods 30, by means of their attachment to each of these rods, for example by welding and / or a ligature wire, not shown in the figures. In practice, the length of the connecting bars 40 is not limiting. Whatever the form of their attachment with the two rods 30, respectively belonging to the two devices 1 successively within the assembly 2, each of the connecting bars 40 connects to one another, these bars of link 40 transmit, at the respective ends, abutted to each other, the respective bodies 10 of the two devices 1 succeeding each other, the stresses between the bars belonging respectively to these two devices 1.

Among the concrete bars of each device 1, so-called transverse bars 50 are fixed to the rods 30, extending both horizontally and transversely to the rods 30. In the embodiment shown in FIGS. each transverse bar 50 is shaped as a "U" whose branches are disposed respectively above and below the two rods 30 and whose base extends vertically, the side of the rods 30 facing the plate Of course, other embodiments are possible for the transverse bars 50 which form a so-called reinforcement system, well known as such.

Whatever their embodiment, the transverse bars 50 are distributed substantially evenly along the rods 30. As a purely illustrative example, the spacing between two successive transverse bars is of the order of 20 cm approximately .

The attachment of the transverse bars 50 to the rods 30 is not limiting. This attachment can thus be made by folding, by welding or by ligation by reported threads.

An example of use of the assembly 2 of the chaining devices 1 will now be described, in particular in connection with FIG. 4. In this example of use, the assembly 2 makes it possible to bond a concrete floor slab 100 perpendicular to a partition 200 of a building. As shown in FIG. 4, the partition 200 considered comprises, one on top of the other, a lower composite wall 210 and an upper composite wall 220. Each of these walls 210 and 220 comprises an insulation layer 211. , 221, rigid or semi-rigid, typically foam such as polyurethane foam, sandwiched between two facing panels, parallel and aligned, typically metal or derived from wood, plaster, concrete or rockwool, namely an inner facing panel 212, 222, which faces the interior of the building to which the partition 200 belongs, and an outer facing panel 213, 223. In addition, each of the composite walls 210 and 220 is provided, in its insulating layer 211, 211, of structural bearing inserts 214, 224, one of which is schematically and in phantom lines in FIG. 4. These inserts 214, 224 extend vertically between the horizontal songs opposite sides of the composite wall 210, 220.

On site, while the lower composite wall 210 of the partition 200 is in place, as well as, if appropriate, the upper composite wall 220, the devices 1 of the assembly 2 are installed along the upper horizontal edge of the wall composite 210: for this purpose, the body 10 of each device 1 is attached and attached to the inserts 214 and, where appropriate, to the inserts 224, by any appropriate means. In the example considered in FIG. 4, the base plate 11 of each body 10 is bolted directly to the upper end of the inserts 214, as well as, if appropriate, to the lower end of the inserts 224, by means of The body 10 of each device 1 is thus fixed to the partition 200 so that its longitudinal direction extends horizontally and that its inner side 101 is turned towards the interior of the building. The carp tails 15 thus extend horizontally, inside the building. The same is also true for the concrete bars 30, concrete bars 40 and transverse concrete bars 50, all or part of which may have been advantageously pre-assembled with the bodies 10 of the devices 1 in workshop, that is to say before building site, it being understood that for the concrete bars which would not be so pre-assembled, they are reported directly on site.

The concrete of the slab 100 can then be poured, after having boxed and supported the bottom of the casting space of this slab 100. As shown in FIG. 4, the poured concrete drowns the concrete bars 30, 40 and 50, as well as the carp tails 15 and the lower part of the stiffeners 14, reaching both the lower flange 12, the lower part of the base plate 11 and, where appropriate, at least some of the bolting systems 20. It is thus understood that the body 10 of each device 1 participates in the casing of the cast slab 100, ensuring the lateral formwork of this slab 100. The slab thus cast is bonded to the inserts 224 of the partition 200 or, more generally, to the supporting structure.

Once the concrete slab 100 is taken, the formwork and props, located below the slab, are removed, while, of course, the devices 1 remain in place because they are permanently integrated to the cast slab 100, arming the concrete of the latter.

Thus, the devices 1 accumulate the lateral shuttering function for the cast slab 100 thanks to the bodies 10, the arming function of the concrete of the slab thanks to the body tails 15 and the concrete bars 50, and the chaining function both horizontal, thanks to concrete bars 30 and 40, that vertical, through the attachment of the formwork body 10 to the partition 200. Moreover, it is understood that the embodiment of the partition 200 or, more generally, the carrier structure to which the formwork body 10 is attached and fixed is not limiting: this carrier structure may as well be light, as is the case for the wall 200 composite walls, that traditional, that is to say said masonry, as long as the casing body 10 can be attached and fixed, for example by bolting systems, such as the systems 300 of Figure 4, but, more generally, by any suitable fastening means.

Taking into account the foregoing explanations, it is understood that other conformation than that in "U" are possible for the formwork body 10, for example "C" or "L", the body 10 being similar then at an angle. In other words, the formwork body may be devoid of upper wing similar to the wing 13 of the example in the figures. Or this upper wing can be dimensioned differently than in the figures and / or be inclined relative to the base plate 11. As for the lower wing 12, which participates in the formwork of the slab 100, it can alternatively not shown, not be integral with the base plate 11, but be reported to it.

Also taking into account the explanations developed so far, it is understood that the formwork body 10 can be made of various materials, as long as the latter are able to, on the one hand, form the concrete poured laterally to the slab 100 and on the other hand, ensure the chaining of the slab 100 with the rest of the building in which the devices 1 are used. Thus, in the exemplary embodiment considered in the figures, the formwork body 10 is advantageously made of a metal sheet, but it can also be made of a commercially rolled section, such as the "UPN" or "UAP" sections. , etc. As a variant not shown, the formwork body may be made of a material other than metal, in particular plastic or polymers, for example high strength polymers.

According to a first optional arrangement which is illustrated in the exemplary embodiment considered in FIGS. 1 to 4, each chaining device 1 of the assembly 2 also makes it possible to support a casting concrete element 400, such as a base in concrete of a balcony or terrace, which is cantilevered or terraced vis-à-vis the slab 100. For this purpose, the body 10 of each device 1 is provided on its outer side 10E, one or more spades 60 anchored in the concrete element 400. As clearly visible in Figures 2 and 4, each anchor 60 extends generally horizontally and substantially perpendicular to the longitudinal direction of the body 10, being fixedly secured to the outer side 10E of the latter by any appropriate means, typically by welding. In practice, the embodiment of the spades 60 is not limiting: for example, each spade is a profile in the form of "N", "Z", "I", "U", tube, etc. In a manner known per se, the spades 60 take up the seismic forces applied to the concrete element 400.

Optionally, concrete bars 61 are provided to arm the concrete of the element 400.

Also for the purpose of supporting the concrete element 400 by the devices 1, each of them comprises one or more concrete rods 70 said through, which pass through the formwork body 10 from one side to the other, connecting one to the other its inner sides 101 and outer 10E. Thus, as shown in FIGS. 1 and 2 and as clearly visible in FIG. 4, each through bar 70 extends horizontally, in part, from the inner side 101 of the body 10 and, for the remainder, from the outer side 10E of this body: the part, facing inwards, of the bar 70 is embedded in the concrete slab 100, while the portion of this bar 70, turned outward, is embedded in the concrete of the element 400.

In the exemplary embodiment considered in the figures, each of the traversing bars 70 extends substantially rectilinear, and in the upper part of the slab 100 and the element 400. As a variant not shown, one or more of these through bars 70 may be provided in the lower part of the slab 100 and the element 400. Another variant not shown is that one or some of the busbars 70 are bent in the intermediate part, so that their part turned inward extends in the upper part of the slab 100, while their outwardly facing portion extends in the lower part of the element 400.

Whatever their embodiment, the through bars 70 can hold the element 400, both downwards, under the effect of its weight and its cantilever or terrace arrangement, as upwards , under the influence of wind and in case of earthquake.

Advantageously, a thermal breaker 80 is integrated in each device 1, being inserted horizontally between the inner side 10E of the body 10 and the element 400. This avoids a direct thermal bridge between the slab 100 and the element 400.

According to a second optional arrangement of the devices, which is shown in FIGS. 5 and 6 and which is alternative to the first optional arrangement described above, each device 1 makes it possible to attach to its shuttering body 10 an element 500 other than concrete, cantilevered or terraced to slab 100.

Typically, this element 500 is a metal beam or, more generally, a metal structure of a balcony or terrace or a similar structure. For this purpose, as clearly visible in FIG. 6, the shuttering body 10 of each device 1 is integrally provided, on its outer side 10E, with angles or bolted plates 90 or, more generally, with mechanical fastening means to the element 500, the embodiment of these attachment means not being limiting. As a variant not shown, a thermal interrupter, functionally similar to the switch 80 described above, can be integrated with the aforementioned fastening means, such as bolted plates 90, so as to be interposed between the outer side 10E of the body formwork 10 and the element 500.

In addition, various arrangements and variants of the chaining device 1 and the assembly 2 considered so far can be considered. As examples rather than the mechanical support function of the concrete bars 30 is provided by the stiffeners, the inner side of the formwork body may have dedicated arrangements for this purpose, distinct from the stiffeners, in particular carried directly by the shuttering body, in particular by its base plate 11; the connecting bars 40 can be omitted in the case where, on the one hand, the abutting ends of the formwork bodies 10 of the assembly 2 are firmly bonded to one another and, on the other hand, the longitudinal ends of the concrete bars 30 are also firmly bonded to their corresponding form body 10, in particular by welding; - As indicated above, the arrangements of the chaining device 1, to support elements cantilevered or terrace are optional; thus, Figure 7 illustrates the variant of the device 1 in which these arrangements are absent; this FIG. 7 also schematically illustrates the variety of supporting structures to which the formwork body 10 of the device 1 is intended to be fixed in use, since in this FIG. 7 is shown, as an alternative to the partition 200, a wall masonry or concreted 200 'and a pillar 200 "whose constitutive nature is indifferent; and / or the device 1 can be adapted to the angular conformation of the corner or slit zones of the slab 100.

Claims (12)

A chaining device (1), comprising: - an elongated lateral formwork body (10) for a pourable concrete floor slab (100), which is adapted to be attached and secured to a supporting structure (200; 200 ', 200 ") so that the longitudinal direction of the form body extends horizontally, and - one or more concrete bars (30) which extend substantially parallel to the longitudinal direction of the formwork body. shuttering body (10), being arranged on the side (10I) of the shuttering body facing the slab, and to which are attached one or more transverse concrete bars (50), which shuttering body (10) is adapted to carry the concrete bars (30) on its side (101) facing the slab, and which formwork body (10) is integrally provided, on its side (101) facing the slab, of at least one piece of concrete anchor (15), as well as vertical stiffeners (14) which are distributed along the formwork body. 2. - Device according to claim 1, characterized in that the shuttering body (10) is made of a metal sheet, in particular shaped "U", angle or flat. 3. - Device according to claim 1, characterized in that the formwork body is made of a material other than metal, in particular plastic or polymers. 4. - Device according to any one of the preceding claims, characterized in that the or each concrete anchor is a carptail (15) which is integrated with one of the stiffeners (14). 5. - Device according to any one of the preceding claims, characterized in that the stiffeners (14) are adapted to carry the concrete rods (30). 6. Device according to claim 5, characterized in that each stiffener (14) defines a notch (14B) for transverse reception and wedging of the or one of the concrete rods (30). 7. - Device according to any one of the preceding claims, characterized in that the shuttering body (10) is further provided with support means (60, 70) adapted to support a concrete casting element (400) in cantilevered or terraced with respect to the slab (100), such as a concrete base of a balcony or a concrete base of a terrace, which means of support comprise: - at least a concrete anchor (60) secured to the side (10E) of the shuttering body (10), facing away from the slab (100), and - one or more concrete bushing (70), which are secured to the formwork body and pass through from one side, extending from its sides (101, 10E) respectively turned towards and turned away from the slab (100). 8. - Device according to any one of claims 1 to 6, characterized in that the shuttering body (10) is further integrally provided on its side (10E) facing away from the slab (100), means (90) for fastening to an element (500) other than in concrete, attached cantilevered or terraced with respect to the slab (100), such as a metallic structure of a balcony or a metal structure of a terrace. 9. - Device according to any one of claims 7 or 8, characterized in that the chaining device (1) further comprises a thermal breaker (80), which is either integrated with the support means (60, 70) of to be inserted between the side (10E), turned away from the slab (100), the shuttering body (10) and the concrete element (400), is integrated with the attachment means (90) so as to be interposed between the side, turned away from the slab (100), the formwork body and the non-concrete element (500). 10. - Chaining unit (2), comprising: -two chaining devices (1), according to any one of the preceding claims and arranged in the longitudinal extension of one another, and - connecting means (20) adapted to bind together the respective chaing bodies (10) of the two chaing devices (1). 11. - assembly according to claim 10, characterized in that one of the stiffeners (14) of each chaining device (1) is provided at each longitudinal end of the formwork body (10), and in that the means of connection (20) are adapted, in particular by bolting, to bind together the respective stiffeners (14) of the chaining devices (1) provided at the longitudinal ends of their shuttering body (10) abutting one another . 12, - assembly according to one of claims 10 or 11, characterized in that the assembly further comprises one or more connecting concrete bars (40) which each connect one or one of the concrete bars (30). ) of one of the two chaining devices (1) to the one or one of the concrete bars of the other chaining device, overlapping and being fixed to each of these two concrete concrete bars, for example by a ligation wire.