FR2971803A1 - Concrete prefabricated element e.g. load-bearing wall, for building, has partitions respectively accommodating welded lattices drowned in concrete and connected to each other by bars, where ends of bars are welded with lattices - Google Patents

Abstract

The element e.g. concrete prefabricated wall (M), has two concrete partitions (100a, 100b) separated by an empty insulation space (200) that is not filled with concrete iron bars (300). The partitions are connected together by the concrete iron bars. The partitions respectively accommodate welded lattices (120a, 120b) drowned in the concrete, and are connected to each other by the bars. Ends of the bars are welded with the lattices. Inner faces (110a, 110b) are arranged in face to face to the walls and equipped with panels (400a, 400b) that are made of insulating material. An independent claim is also included for a device for manufacturing a concrete prefabricated element.

Description

PREFABRICATED BUILDING ELEMENTS AND DEVICE FOR MANUFACTURING

FIELD OF APPLICATION OF THE INVENTION The present invention relates to the field of the building and in particular adaptations for making prefabricated concrete building elements in the best conditions.

DESCRIPTION OF THE PRIOR ART There exists in the prior art a plurality of prefabricated concrete building elements such as walls, floors, etc. The new insulation standards have led the designers of such equipment to integrate during the molding of such elements, an insulating material constituting an interlayer between the inner and outer walls forming the element. This configuration defining a succession of layers of different materials all in contact on their larger surface with each other, the insulation characteristics of such elements can be improved. There are also in the prior art prefabricated blocks or elements to bancher which have a hollow core open on the top, hollow core which is filled with concrete once the block or element placed. As for the elements described above, such prefabricated blocks or prefabricated elements can incorporate in their manufacture by molding, the insertion of a layer 30 of insulation. However, the recess likely to serve as an insulating medium between the outer walls is clogged so that the different layers of different materials of the element once installed, are also in contact with each other on their largest area. As a result, the insulation characteristics of such elements can be improved. In addition, such prefabricated hollow elements can not be envisaged without filling by concrete because of their fragility. DESCRIPTION OF THE INVENTION Based on this state of affairs, the applicant has conducted research aimed at proposing a prefabricated element of concrete construction whose insulation characteristics are optimized. This research led to the design and construction of a prefabricated element of the wall, floor, etc. type, made of remarkable concrete in that it comprises two concrete walls separated by an empty volume of insulation. not intended to be filled and interconnected by reinforcing bars, said concrete walls each receiving a welded mesh embedded in the concrete and connected from one wall to the other by said reinforcing bars whose ends are welded to the so-called trellises. This feature is particularly advantageous in that it provides, by the presence of a continuous hollow space not filled between the two walls, an optimized insulation compared to what the prior art proposes. The quality of the insulation obtained corresponds to the standards of low energy buildings. Indeed, as only the concrete irons will achieve the connection between the walls, no significant thermal bridge exists between the two media separated by the prefabricated element of the invention. The presence of a continuous recess separating the inner and outer walls of the wall makes it possible to envisage its exploitation as reception volume of ducts, technical conduits (water, gas, electricity, etc ...). Likewise, it offers the possibility of heating or cooling the building by circulating hot or cold air between the two watertight walls. An air inlet can be made by the crawl space while the outlet can be made by high mouths. Thus according to a particularly advantageous characteristic, at least one of the walls is provided with an orifice allowing the passage of air in the empty interior volume.

Another significant advantage regarding the continuous empty volume of air lies in the concrete economy achieved. This structure welded concrete solves the technical problem of the fragility of such a recessed configuration and allows the use of prefabricated elements of the invention as a carrier element (for example a load-bearing wall). This structure also makes it possible to present an improved antiseismic resistance. In addition, the central recess separating the two walls makes accessible from the outside said concrete rods that will be able to serve as a point of attachment to facilitate the handling of the prefabricated element. The concrete irons that can be dedicated to this function have appropriate dimensions.

According to another characteristic optimizing the rigidity and avoiding any risk of torsion, the prefabricated element of the invention comprises additional reinforcement concrete irons welded connecting the opposite ends of said concrete irons from one row to another. These reinforcing reinforcing bars will thus form the diagonals of the quadrilaterals formed by the irons and the vertical threads of the lattices. In order to optimize the insulation of this double-walled configuration, the internal faces disposed opposite said walls are equipped with a panel of insulating material. These panels are in direct contact with the concrete wall. According to the invention, the empty interior volume separating the two walls is maintained between the two panels. The thermal insulation obtained is exceptional because of the combination: - double concrete walls, - 4 - two insulation panels associated with the two walls, - the air gap separating the two insulating panels on the all the walls of the building (on the height as on the total surface) thus decreasing the possibilities of thermal bridge. This succession of different media allows the prefabricated element of the invention and the building obtained from the latter to present an optimized acoustic insulation.

In addition, such a hollow volume can advantageously be compartmentalized by lost formwork plates which during construction will allow streaming of bonding volumes between the various elements. Thus, for example when a wall according to the invention supports a slab, the upper part of the hollow volume of the wall is filled with concrete for connection with the slab and the creation of a belt. It is the same with the framing openings in prefabricated elements whose lintel can be poured during the casting of the belt. To complete the formwork, one of said walls of the wall has a height greater than the other wall. Advantageously, the concrete reinforcing bars between the walls are arranged perpendicular to the latter and positioned so as to serve as a support surface for the lost formwork plates. The predisposition of the formwork plates brings a particularly fast implementation on site because the concrete of the pillars, lintels and belt is made in one and the same operation. According to another particularly advantageous characteristic related to the production of a floor, said empty space is compartmentalized by concrete bracing walls poured at the same time as said walls and coming to drown said reinforcing bars, the internal faces arranged in facing direction. with respect to said walls of each compartment being equipped with a panel of insulating material. The manufacturing device of the elements of the invention consists of a vibrated concrete molding operation inside a mold providing external surfaces forming an interior volume accommodating cores or inserts comprising a frame of two connected welded mesh panels between them by concrete irons arranged at least perpendicularly through the two insulating panels. These panels are arranged in the mold parallel to the panels formed by the trellises and spaced apart from each other and with respect to said trellises. These panels constitute the inner walls of the mold, spacers being arranged between these insulating panels and then removed after drying. The operation of the insulating panels as walls of the mold is particularly advantageous in that it allows the removal of the spacers and therefore the complete demoulding. This easy demolding of the prefabricated element allows its realization in a single casting phase with said mold open at the top end and thus said prefabricated element in a vertical position which optimizes the rigidity of the element obtained, accelerates its manufacture and facilitates its handling. .

The basic concepts of the invention having been described above in their most elementary form, other details and characteristics will emerge more clearly on reading the description which follows and with reference to the appended drawings, giving non-limiting example, several embodiments of the prefabricated element and their manufacturing method according to the invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional side view of an embodiment of a wall according to the invention; Figure 2 is a sectional side view of another embodiment of a wall according to the invention; Figure 3 is a sectional side view of an assembly of two load bearing walls according to the embodiment of Figure 2 with a cast floor; Figure 4 is a top view in section of an end-to-end assembly of two walls according to the invention; Figure 5 is a sectional side view of a wall manufacturing mold according to Figure 2; Figure 6 is a sectional side view of a prefabricated floor according to the invention; Figure 7 is an outer perspective view of a preformed wall of a reservation for accommodating an opening.

DESCRIPTION OF THE PREFERRED EMBODIMENTS As illustrated in the drawing of FIG. 1, the prefabricated concrete wall referenced M as a whole comprises an asymmetric structure formed of two concrete walls 100a and 100b separated by an empty volume 200 of insulation. . These walls 100a and 100b are interconnected by reinforcing bars 300 arranged perpendicularly to said walls 100a and 100b and whose ends are embedded in the concrete of said walls 100a and 100b.

The inner faces 110a and 110b disposed opposite said walls 100a and 100b are equipped with a panel of insulating material 400a and 400b traversed by said irons 300. Said walls 100a and 100b further comprise welded mesh 120a and 120b embedded in the concrete walls during their manufacture and connected by welding from one wall to the other by said reinforcing bars 300. As illustrated, reinforcing concrete reinforcing bars 310 are connected by welding the opposite ends of said irons to concrete from one row to another to optimize rigidity. This structure is asymmetrical in that the outwardly disposed wall 100a has an upper end with a height greater than that of the wall 100b disposed inwards. The insulating panel 400a and the mesh 120a associated with this wall 100a also have a greater length. The embodiment of the wall M 'illustrated in the drawing of FIG. 2 has a symmetrical structure with identical walls 100a' and 100b '. The insulating panels 400a and 400b as well as the lattices 120a' and 120b 'associated with these walls. are also identical. According to a preferred embodiment, the prefabricated wall has substantially the following technical characteristics: - The concrete wall 100a and 100b has a thickness of 5 cm (but the desired thickness can be achieved on request); - The insulation board 400a and 400b is extruded polystyrene thickness 6 cros; - The lattice 120a and 120b embedded in the walls 100a and 100b is welded and adopts a mesh of 20 per 20 cros on the entire surface of the walls; - The reinforcing bars 300 have a diameter of 1.4 cm; reinforcing concrete bars 310 have a diameter of 1.4 cros; - An empty volume of separation of the panels of 10 cros of width. The upward projection of one of said walls has the advantage of allowing, in the upper part, the formwork of a volume of concrete as illustrated in the drawing of FIG. 3. As illustrated in this figure, two walls M come to support a concrete slab 500 comprising a prefabricated plate 510 and a cast volume 520. This concrete volume 520 is not only encased by said prefabricated plate 510 which rests on the upper ends of the inner walls 100b of said walls M but also by Said upward projections formed by the walls 100a. So that the concrete does not come to fill the empty volume 200 during the casting of the volume 520, the hollow volume is closed in the upper part by lost formwork plates 600. Thus, the volume 520 is present at its ends, a rib 521 is projecting downwards corresponding to the empty volume compartmentalized by the plate 600. So that the ends of said cast volume 500 can serve as a belt or lintel to the resulting construction, a reinforcement 530 is disposed at said ends to be embedded during the operation of casting. The left wall illustrates a particular embodiment of the prefabricated element of the invention which proposes passage openings 130a and 130b in the concrete walls and in the insulating panels in order to allow the circulation of air at inside the wall. This arrangement makes it possible to provide optimized insulation, a means of heating and / or insulation by the wall, the exploitation of a Canadian well-type heating principle, etc. Another example of use of these plates 600 is illustrated by the drawing of Figure 4. In this figure, two walls M are assembled end-to-end that is to say that they are arranged in the same plane and their hollow core 200 respective communicates. Before the casting operation of the concrete to form the connecting pillar, plates 600 are arranged to compartmentalize the hollow volume 200 and close the volume for the realization of the pillar. Once these plates are put in place, the concrete B can be poured without fear of blocking the volume 200. As illustrated, it is the concrete reinforcing bars 300 between the walls 100a and 100b which, arranged perpendicularly to these position and or These said reinforcing bars, and in particular those close to the periphery of the prefabricated elements, can therefore be positioned accordingly. The presence of these plates allows the realization of pillars, lintels and belts, once the prefabricated elements positioned, and this, pouring concrete B in a single operation and without the hollow volumes separating the walls or openings in these are not filled. The building obtained by the use of prefabricated elements according to the invention has a high antiseismic resistance by combining. - a double reinforcement of the concrete walls, continuous reinforcement on the periphery of the building, - a reinforced concrete belt, - lintels in particular for the openings poured continuously on the upper part of the wall. Figure 5 shows an embodiment of a mold for manufacturing a prefabricated element according to the invention. As illustrated, such a device is particularly simple to manufacture and to implement making the prefabricated elements of the invention easy to manufacture and market. According to the invention for the manufacture of a prefabricated wall element M such as that illustrated by the drawing of Figure 1, the device referenced D comprises a mold 700 whose inner surfaces 710 form the outer surfaces of said wall M and a volume interior accommodating cores or inserts comprising the welded iron frame. This pre-assembled welded reinforcement is formed of two welded mesh panels 120a and 120b interconnected by perpendicularly placed concrete irons 300 which pass through the walls of two insulating panels 400a and 400b. This reinforcement also includes additional reinforcement concrete reinforcing bars 310 which weld the opposite ends of said concrete irons 300 from one row to another. The insulating panels 400a and 400b are arranged between the mesh panels 120a and 120b leaving a gap between them and with respect to the trellises and are crossed by said irons 300 and 310. These panels constitute the inner walls of the mold, spacers 720 being disposed between the insulating panels 400a and 400b and then removed (arrow F1) after drying. The molding of the entire element is performed in a single pouring operation (arrows F2) of concrete from the top of the mold. The latter is also subject to a vibration phase. This simultaneous casting in the two parts of the mold corresponding to the two walls 100a and 100b to be made is made possible due to the rigidity of the welded frame whose two main parts will not move relative to each other during the operation. The presence of reinforcement reinforcing bars 310 is therefore particularly important. As illustrated, said mold 700 is open at the top end and allows molding in the vertical position of the prefabricated element. The embodiment illustrated by the drawing of Figure 6 is more for the realization of a floor 800 prefabricated. This floor 800 comprises two walls 810 and 820 of vibrated concrete and interconnected by said concrete irons 830 and maintaining an empty volume of separation. This floor 800 differs from the arrangements described above in that said empty space is compartmentalized by concrete bracing walls 840 cast at the same time as said walls 810 and 820 and coming walnut row or column, said reinforcing bars 830 , the inner faces disposed opposite said walls of each compartment being equipped with a panel of insulating material 850 and 860. FIG. 7 illustrates a wall M during the molding of which a reservation R has been made without concrete or concrete or trellis irons. The insulating panels are cut after molding according to the open frame formed. The opening is created by fixing to the outer face of the insulator a frame preventing the passage of concrete, said frame having the thickness of the wall in which it integrates and comes into contact with the inner faces of the walls 710 of the mold 700. This reservation R can accommodate woodwork or pre-concrete frames intended to constitute a window.

It is understood that the prefabricated element and its manufacturing device, which have just been described above and shown, have been for the purpose of disclosure rather than limitation. Of course, various arrangements, modifications and improvements may be made to the example above, without departing from the scope of the invention. Thus, the invention leaves full freedom regarding the thickness of the concrete and its dosage to vary the mechanical strength characteristics. The same applies to the insulation characteristics which may vary according to the thickness of the air gap 200 and the panel and the type of insulating material 400a and 400b.

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Claims (10)

REVENDICATIONS1. Prefabricated wall element (M, M '), concrete floor (800), etc., CHARACTERIZED BY THE FACT THAT it comprises two concrete walls (100a and 100b) separated by an empty volume of insulation ( 200) being not intended to be filled and interconnected by reinforcing bars (300), said concrete walls (100a and 100b) each accommodating a welded mesh (120a and 120b) embedded in the concrete and connected to one wall to the other by said reinforcing bars (300) whose ends are welded to said lattices (120a and 120b). 2. Element according to claim 1, CHARACTERIZED BY THE FACT that the inner faces (110a and 110b) disposed vis-à-vis said walls (100a and 100b) are equipped with a panel of insulating material (400a and 400b). 3. Element according to claim 1, CHARACTERIZED BY THE FACT that the hollow volume (200) is compartmentalized by lost formwork walls (600) which during construction will allow to flow continuously bonding volumes between the various elements. 4. Element according to claim 1, CHARACTERIZED BY THE FACT THAT the reinforcing bars (300) connecting the walls (100a and 100b) are arranged perpendicular thereto and positioned so as to serve as a support surface to the formwork walls lost (600). 5. Element (800) according to claim 1, CHARACTERIZED BY THE FACT THAT said empty volume (200) is compartmentalized by concrete spacing partitions (840) cast at the same time as said walls (810 and 820) and coming from embedding said reinforcing bars (830), the inner faces disposed opposite said walls of each compartment being provided with a panel of insulating material (850, 860). 6. Element according to claim 1, CHARACTERIZED BY THE FACT THAT one of said walls (100a) has a height greater than the other wall (100b). 10 15 20 25- 13 - 7. Element according to claim 1, CHARACTERIZED BY THE fact that it comprises additional reinforcement concrete irons (310) coming to weld the opposite ends of said concrete irons (300) from one row to another. 8. Element according to claim 1, CHARACTERIZED BY THE FACT THAT at least one of the walls (100a and 100b) is provided with an orifice (130a and 130b) allowing the passage of air in the empty volume inside (200) . 9. Device (D) for manufacturing a prefabricated concrete element according to claims 1 and 2, CHARACTERIZED BY THE FACT THAT it comprises a mold (700) providing outer surfaces (710) forming an interior volume hosting nuclei or inserts comprising an armature of two welded mesh panels (120a and 120b) connected together by concrete rods (300) arranged at least perpendicularly which pass through the walls of two insulating panels (400a and 400b) which, arranged between the mesh (120a and 120b) and spaced from each other and relative to the lattices (120a and 120b) constitute the inner walls of the mold (700), spacers (720) being arranged between the insulating panels (400a and 400b) then removed after drying. 10. Device according to claim 9, CHARACTERIZED BY THE FACT THAT said mold (700) is open at the top end and allows molding in the vertical position of the prefabricated element. 35