LU81521A1 - CONCRETE ELEMENTS, ESPECIALLY HOURDIS FOR CONSTRUCTION AND PROCESS FOR THEIR PRODUCTION - Google Patents

Description

The present invention relates to a composite element, suitable in particular as slabs intended for all types of construction and which may find in particular applications for the production of construction bases.

Oh, we know that slabs are widely used in construction for the realization of horizontal partitions, that is to say floors.

These slabs are prefabricated reinforced concrete elements. Different types of reinforcement can be provided during manufacture and the slabs are generally of trapezoidal v section.

* The slabs are placed by their largest base on fixed supports (exterior or interior walls) and on temporary supports (props) as much as possible contiguous and are then covered with a concrete, called filling which is poured on the site and which is intended to fill the V-shaped grooves formed between the neighboring slabs. Then, after setting the filling concrete, we proceed to the finish which includes the overlap. using a screed on the upper side forming the floor of the upper level and a covering on the lower side which constitutes the ceiling of the lower level.

The major drawback of conventional slabs lies in their weight, which limits achievable spans, makes transport expensive and makes handling of slabs on site difficult. The exterior finish they require is also an unfavorable factor. Finally, their manufacture, even industrialized, is not very profitable and not very fast, owing to the fact that it is necessary to wait for a suitable setting of the concrete before their demolding.

The present invention essentially aims to remedy the drawbacks described of conventional slabs and their laying method.

This is achieved by a composite self-supporting concrete element, in the form of slabs, characterized in that it consists of a light insulating concrete in which a conventional heavy concrete has been poured. Said heavy concrete is preferably heavy reinforced concrete.

Heavy concrete is understood to mean a concrete having the usual densities of concrete used in construction sites.

The light insulating concrete used is a product obtained by injecting a rigid foam into a concrete in order to obtain a cellular concrete which is characterized by its properties of combined lightness. good mechanical resistance properties and thermal and phonic conductivity coefficients ensuring good insulating qualities of light concrete.

A product which has proved to be particularly interesting is the product "NEOPOR" sold by the company NEOPOR VERFAHREN TECNIK GmbH, at D-7440 Nuertingen (R.F.A.),

Advantageously, the light insulating concrete used 3 v has a density of the order of 300 to 600 kg / m, preferably 3 of the order of 450 kg / m.

The achievable composite elements can reach spans of 9 meters or more.

Their width can vary from 0.40 m to 2 (4o m. It should therefore be noted that the concept of "slabs" used in the description applies generally, to elements which may reach, by the very fact of the way they are designed, large widths.

A particularly advantageous embodiment of the composite elements according to the invention is that of a light insulating concrete provided with grooves in which a conventional heavy concrete has been poured in the form of a reinforced ribbed slab.

The invention also relates to a method of manufacturing composite elements in self-supporting concrete according to the invention characterized in that a light insulating concrete is used in order to produce a formwork mold, in that it is optionally placed in this mold reinforcements and pours a classic heavy concrete forming a composite and joined together.

The most advantageous form of application of the invention consists in providing a light insulating concrete provided with grooves, in which there are reinforcing elements, after which a% concrete is poured into the mold of light insulating concrete. heavy classic in order to produce a one-piece composite element.

These composite elements are interesting because of their reduced self-weight> their adaptability to standards, their high thermal insulation, their self-supporting properties and their good thermal and sound insulation.

By their design, there is great flexibility in range and overload, in particular in the embodiment providing for the use of a light insulating concrete provided with grooves in which are housed the ribs of a ribbed slab. Indeed, by modifying the height of the ribs, one can adapt to. variable spans, for normal house overloads.,.

Said elements are self-supporting and this offers the advantage of being able to carry out constructions very quickly, without resorting to conventional formwork, and without resorting to. intermediate props.

In addition, it is possible to continue construction immediately without waiting for the concrete to set, a usual practice, however, for conventional slabs. The use of a -. r »t r ~ 7 =. ~, \ suitably, immediately obtaining a smooth shape, thanks to which it is possible to immediately realize ceilings that will suffice to sand.

By an adequate design of the composite elements of the invention, it is also possible to reduce to 10% the quantity of filling concrete required.

The invention will be described in more detail with reference to the accompanying drawings, of composite elements according to the invention and intended for the production of a construction. In the drawings - FIG. 1 represents a partial plan view of the installation of 'elements according to the invention, for the realization of a dwelling house; - Figure 2 shows a partial section A-A to distinguish the shape and design of the composite elements of the invention? - Figure 3 shows a detail of the element surrounded by a circle in Figure 2 and r- Figures 4 and 5 respectively show a perspective view and a sectional view of the realization of the joint between the elements Referring to Figure 1, there is shown four composite elements according to claim, bearing the general reference 1 which are laid, jointi.vement on exterior walls 3 and interior walls 4 .. Note that some of '. elements are provided with either an opening 5 intended for example to. a stairwell, or an opening 6 intended for a chimney. Holes can also be provided from the outset. in composite elements. They can be used for WC pipes (7) or sanitary pipes (8,8 ').

Elements 1 are simply laid contiguously like slabs. Their length can vary for example from /// Π Rn '3 10 τη Πη nnnrni t- mip la nnecihilitô do nncov pl-an— çons, elements that can reach heights of 10 m can significantly speed up erection of buildings .

Referring to FIG. 2, it can be seen that the composite element consists of a light concrete 10 which in the particular case has grooves 11, and a heavy concrete 12.

The light concrete is first poured on a table of sufficient size with raised edges, constituted for example by a smooth sheet metal with raised lateral edges. If a particular finish of the exterior surface is desired, prior to the pouring of the light concrete, it is possible to deposit a plaster, in particular a plastering (plaster) or a cement or a mixture of cement and sand in order '' obtain a smooth and even exterior surface. After pouring the concrete, "tubs" can be placed in the still liquid mass in order to spare the grooves 11 in which the ribs of the heavy concrete will be poured later.

After the setting of the light concrete, the heavy concrete 12 is poured which occupies on the one hand the grooves 11 by forming a groove 13 as well as a flat upper surface 14. Preferably, a frame 16 has been previously disposed in the groove 11 and on the flat surface of the light concrete 10 so as to obtain a ribbed and reinforced slab.

The arrangement of the reinforcement 16 in the light concrete 11 before the pouring of the heavy concrete 12 is indicated in FIG. 3 :.

t · ** ·

Figures 4 and 5 illustrate how the joints between the elements are made.

Note that the light concrete part 10 is provided at its two lateral ends with a fillet 17 which will be 7 "‘ v

The ends of the. slabs are also bevelled, forming a hollow 19 into which the ends of the reinforcements of juxtaposed slabs are sufficient and which are sufficient to receive a filling concrete.

Although particular embodiments of the invention have been described, it should be understood that it is not limited to the embodiments shown, and in particular is not limited to the dimensions indicated.

. Quite the contrary, numerous variants and modifications are possible while remaining within the scope of the invention as defined by the claims which follow.

Claims (10)

1. Self-supporting concrete composite element, in the form of slabs, characterized in that it consists of a light insulating concrete in which a conventional heavy concrete has been poured. 2. Composite element according to claim 1 characterized in that said heavy concrete is a reinforced heavy concrete. 3. Composite element according to claim 1 or 2 characterized in that the light insulating concrete used is a product obtained by injecting a rigid foam into a concrete in order to obtain a cellular concrete. 4. Composite element according to claim 3 characterized in that the light insulating concrete used has a 3 density of the order of 300 to 600 kg / m, preferably of the order of 450 kg / m3. 5. Composite element according to any one of claims 1 to 4 characterized in that the composite elements can reach -portées of 9 meters and more. 6. Composite element according to any one of claims 1 to 5 characterized in that the light insulating concrete is provided with grooves and that therein has been poured a conventional heavy concrete in the form of a reinforced ribbed slab. 7. A method of manufacturing concrete composite elements according to any one of claims 1 to 6 characterized in that a light insulating concrete is used in order to produce a formwork mold, in that it is optionally placed in this mold reinforcements and in that a conventional heavy concrete is then poured, forming a composite and secured element. 8. Method according to claim 7 characterized in that dans'un lightweight insulating concrete provided with grooves, there are reinforcing elements, after which it is poured into the mold of insulating concrete lécror ·. a concrete loirrd nlassîmip so rlp -realize *% 9. Method according to claim 7 or 8 characterized in that the light insulating concrete is poured on a table with raised edges previously covered with a plaster or cement coating intended to be secured to the composite element giving it an appearance smooth. 10. Application of the composite elements according to any of claims 1 to 6 or obtained by the method of any of claims 7 to 9 to the production of floors in construction. m 4r V7 · '