ITUD20090002A1 - CARRYING BEAM WITH MIXED STRUCTURE - Google Patents

Description

Description

"MIXED STRUCTURE BEAM"

FIELD OF APPLICATION

The present invention relates to a bearing beam with a mixed metal-concrete structure, or similar, which can be used in the building sector for the construction of buildings, bridges, buildings or the like.

In particular, the beam according to the present invention, of the prefabricated type, advantageously light and self-supporting, comprises a metal reticular structure partially inserted in a slab, or base, of concrete, and / or of other similar or similar material.

STATE OF THE TECHNIQUE

Prefabricated load-bearing beams are known which are provided with a mixed steel-cement structure, comprising a metal reinforcement and a cement-based slab, for example concrete. The metal reinforcement comprises at least one reticular lattice to which corresponding lower currents are connected below.

The lower beams also comprise at least one respective metal plate fixed at the bottom by welding to a reinforcing metal mesh, completely incorporated in the slab.

Each metal plate is partially incorporated in the slab, and has its own upper support surface outside the slab.

The beams thus created define with the surfaces external to the slab metal plates, respective lateral support surfaces to the reticular trusses, on which the ends of corresponding concrete-based slabs are normally arranged for the construction of floors, in order to contain a final casting of concrete, which incorporates the lattice trusses themselves.

Furthermore, the aforesaid slabs can be placed side by side with the beams and arranged coplanar with the aforesaid support surfaces to guarantee the structural continuity of the floor to be built.

A disadvantage of such known beams is that complex and laborious operations are required to place such plates alongside the beams. In fact, these plates are provided with protruding support elements arranged on their upper surface able to contact the aforementioned support surfaces at the bottom. In addition, provisional vertical support scaffolds are required to simultaneously support the beams and slabs at the junction between the beams and slabs before and during the pouring of concrete. The use of such scaffolding does not always guarantee the necessary structural stability for the beams and slabs during the pouring of concrete and therefore the construction of these floors does not always take place in conditions of complete safety.

A further drawback is that in the event that the slabs for the floors are not all the same size, there is no perfect alignment between them and the beams, so that cracks are formed through which, during the casting of concrete, percolation of concrete occurs, with considerable waste of the same.

The purpose of the present invention is to provide a bearing beam with a mixed structure which allows slabs to be supported quickly and safely, which does not require temporary scaffolding to provide such support and which avoids the percolation of concrete.

In order to obviate the drawbacks of the known art and to obtain these and further objects and advantages, the Applicant has studied, tested and implemented the present invention.

EXPOSURE OF THE FOUND

The present invention is expressed and characterized in the independent claim.

The dependent claims disclose other characteristics of the present invention, or variants of the main solution idea.

In accordance with the aforementioned purpose, a supporting beam with a mixed structure according to the present invention, preferably prefabricated, comprises a metal reinforcement and a cement-based slab, for example concrete.

According to a characteristic aspect of the present invention, the beam also comprises at least one support element arranged laterally outside the overall dimensions of said slab and in a single body with it, and defining a substantially continuous support surface which runs at least for a part substantial length of said slab, or for the part that is affected by the presence of the slab.

According to a variant of the present invention, the aforesaid support element is provided with a plurality of through holes formed in correspondence with the aforesaid support surface.

According to another variant of the present invention, the support element and the slab have structural and geometric continuity so as to define a substantially continuous support plane.

The support element of the beam according to the present invention therefore defines a support plane arranged laterally, for a substantial part, or for the whole length of the concrete-based slab, and outside the overall dimensions of the slab itself. A slab of slab which must be placed side by side with the load-bearing beam for the construction of slabs, is therefore easily and quickly arranged at least partially resting on the aforementioned support element, without the need for temporary support scaffolding.

Furthermore, the through holes obtained on the aforesaid resting surface of the support element perform a transpiring function for the structure that the bearing beam according to the present invention is going to realize. In particular, the through holes avoid the stagnation of humidity, notoriously harmful in the field of building constructions, in correspondence with the support element, which guarantees, substantially in all operating conditions, the maintenance of an effective association between the bearing beam. and the slabs of the attic.

The use of this support element also allows to operate with a tolerance margin on the dimensions of the plates. Therefore slabs for floors with different dimensions can be used. The support element, in fact, acts as a containment element for the concrete casting in correspondence with the possible cracks that are formed between the slabs and the beams. Consequently, the percolation of the concrete and its waste is avoided.

Furthermore, the metal reinforcement of the beam according to the present invention comprises at least one reticular lattice, to which a corresponding reinforcement element is connected at the bottom, such as for example a metal plate. A metal reinforcement mesh completely incorporated in the slab is fixed to the aforesaid reinforcing element and the aforesaid reinforcing element has an upper surface external to the slab.

According to a variant of the present invention, the support element is associated with said reinforcement element and arranged laterally to said metal mesh.

According to another variant of the present invention, the support element is laterally associated with the reinforcing metal mesh.

ILLUSTRATION OF DRAWINGS

These and other characteristics of the present invention will become clear from the following description of a preferential embodiment, given by way of non-limiting example, with reference to the attached drawings in which:

- fig. 1 is a perspective view from below of a portion of a bearing beam according to the present invention;

- fig. 2 is a cross section of the beam of figure 1 in an operative condition; And

- fig. 3 is a cross section of a variant of a detail of figure 2. DESCRIPTION OF A PREFERENTIAL FORM OF PRODUCTION

TION

With reference to fig. 1, a bearing beam 10 according to the present invention is of the type with a mixed metal - concrete structure, or similar, and is used in the building sector for the construction of buildings, bridges, buildings or the like.

The bearing beam 10 comprises at the top a metal reinforcement 11, advantageously made of steel, and at the bottom a slab 12, usually made of concrete. In this case the slab has two layers, of which the upper 12a comprises cement and the lower 12b comprises polystyrene, or other similar or similar material. The lower layer 12b besides giving greater lightness to the structure also allows to realize thermally insulating structures.

According to a variant embodiment of the present invention, the lower layer 12b is made of brick.

The armature 11 comprises two reticular lattices 13,14, each of which is constituted by a plurality of diagonal rods, 15 and 16 respectively, which form triangular meshes.

The reticular lattices 13,14 have respective upper portions 13a, 14a, converging and fixed to each other, for example by welding, by means of one or more upper currents 17, in this case three.

The lattice trusses 13,14 also have respective lower portions 13b, 14b each welded to a relative reinforcement element, in the case of a metal plate 18 and 19. It is understood that the reinforcement element can also be of any known type .

The slab 12 comprises a self-supporting prestressed and / or vibrated concrete conglomerate 20 and is also provided with carbon fibers and / or other mineral reinforcing component.

The conglomerate 20 is made by means of a cast of cementitious concrete which is poured into a corresponding containment formwork in which the metal plates 18 and 19 of the lattice trusses 13,14 are arranged.

In particular, the two metal plates 18,19 are arranged in such a way as to emerge from the conglomerate 20, so as to have the upper surface external to the slab 12.

In this way the slab 12 develops downwards with respect to the two metal plates 18 and 19, thus being able to substantially exploit its entire thickness for fire resistance. Therefore the beams 10 according to the present allow to realize structures which are resistant to fire.

According to a variant of the present invention, other elements of active armature, of a known type and not shown in the figures, can also be associated with the metal plates 18 and 19.

The supporting beam 10 also comprises two rod-shaped elements 21,22, protruding with respect to the slab 12, respectively fixed to the upper external surface of the metal plates 18,19, arranged inside the reinforcement 11 and also fixed, respectively, to the lower portions 13b, 14b of the lattice pylons. To these rod-shaped elements 21,22 is associated transversely with respect to the longitudinal development of the bearing beam 10 a support bar 23, made of metal material, suitable for allowing the bearing beam 10 to rest on reinforcement profiles for the installation of the beam carrier 10.

The supporting beam 10 also comprises support elements 24 arranged laterally outside the overall dimensions of the slab 12. These support elements 24 comprise metal sections 25 shaped so as to define an at least partially L-shaped support. Advantageously the aforementioned sections 25 they are made of material having characteristics of stainless, such as for example galvanized steel, stainless steel, or other similar materials which are also suitable for conferring architectural value. The sections 25 can also be made of aluminum or other similar materials, and subjected to protective treatments of a known type, for example, but not limited to, anti-rust treatments or other similar treatments.

The sections 25 are associated with the metal plates 18, 19 (fig. 2) by means of a plurality of metal elements 28, having a length greater than the overall dimensions of the slab 12. In particular, these metal elements 28 are arranged transversely with respect to the longitudinal extension of the beam. bearing 10 and have the ends associated with the sections 25 and portions associated with the metal plates 18,19. These metal elements are associated with the sections 25 and with the metal plates 18,19 for example by welding.

According to a variant of the present invention shown in Figure 3, the sections 25 have an upper extension 30, which defines a fixing plane for the metal element 28.

According to a non-limiting variant, the bearing beam 10 comprises inside the conglomerate 20 a reinforcing metal mesh 29, capable of defining a structural support to the slab 20 and guaranteeing the solid connection between the latter and the reinforcement 11.

According to another variant, the reinforcing metal mesh 29 is welded below to the two metal plates 18,19 and the sections 25 are associated with this reinforcing metal mesh 29.

According to a further variant, the reinforcing metal mesh 29 is associated with the aforementioned metal elements 28.

The support elements 24 have structural continuity with the slab 12 and define a support surface 25a, corresponding to the horizontal section of the L-shaped profile of the section 25. Advantageously, the support surface 25a is provided with a plurality of through holes 31. Up this support surface 25a is arranged substantially coplanar with respect to the slab 12, the lateral ends of slabs 26, of a slab 27 in order to contain a final casting of concrete, which incorporates the lattice lattices 13,14 themselves. The through holes 31 are suitable for avoiding the stagnation of humidity, in particular in the resting areas between the slabs 26 and the supporting beam 10, causing a transpiring effect.

Furthermore, when finishing the floor, in particular, but not only, when the lower layer 12b is made of brick, the through holes 31 allow better adhesion of the plaster to the profiles 25, determining an advantageous gripping effect. This therefore allows to obtain a uniform, compact and stable plaster coating, ie not subject to detachment and / or cracking.

These slabs 26 are of the fire resistant type and are typically made of cement. The slabs 26 can also comprise, in association with this cement-based layer, also a layer of polystyrene, wood or other similar or similar materials. The use of the aforesaid sections 25, in fact, allows an easy support also of plates 26 having this mixed composition. Advantageously, the dimensions of the aforementioned sections 25 vary according to the weight of the plates 26 which they must support.

The presence of this support surface 25a allows to operate with a tolerance margin on the dimensions of the slabs 26. In fact, in the final casting of concrete, it is not necessary for these slabs 26 to be perfectly placed side by side with the slab 12, in order to avoid the formation of cracks, since the supporting surface 25a, in particular in correspondence with the portions D, contains the cast concrete and prevents it from percolating. This type of association between the bearing beam 10 and the slabs 26 also makes it possible to avoid the use of temporary scaffolding and therefore allows coplanar floors to be created quickly and easily.

According to a variant of the present invention, it is possible to provide an extension of the sections 25 in correspondence with structural pillars, so as to guarantee the continuity of the profile bearing the floor also in correspondence with these pillars, thus providing a better executive and architectural result.

It is clear that modifications and / or additions of parts can be made to the bearing beam 10 described up to now, without thereby departing from the scope of the present invention.

It is also clear that, although the present invention has been described with reference to some specific examples, a person skilled in the art will certainly be able to realize many other equivalent forms of supporting beam 10, having the characteristics expressed in the claims and therefore all falling within the scope of the scope of protection defined by them.

Claims (12)

CLAIMS 1. Load-bearing beam with mixed structure comprising a metal reinforcement (11) and a concrete-based slab (12), characterized in that it also comprises at least one support element (24) arranged laterally outside the overall dimensions of said insole (12) integral with it, and defining a support surface (25a) which runs for at least a substantial part of the length of said insole (12). 2. Bearing beam as in claim 1, characterized in that said support element (24) is provided with a plurality of through holes (31) obtained in correspondence with said support surface (25a). 3. Bearing beam as in claim 2, characterized in that said support element (24) and said slab (12) have structural and geometric continuity, so as to define a continuous support plane. 4. Bearing beam as in claim 1, wherein said metal reinforcement (11) comprises at least one reticular lattice (13,14) to which a corresponding reinforcement element (18,19) is connected below, in which said reinforcement element (18,19) has an upper surface external to said slab (12), characterized in that said support element (24) is associated with said reinforcement element (18,19). 5. Bearing beam as in claim 4, characterized in that it also comprises a plurality of metal elements (28), having a length greater than the overall dimensions of said slab (12), suitable for achieving the association between said support element ( 24) and said reinforcement element (18,19), arranged transversely with respect to the longitudinal extension of said supporting beam, and having an end associated with said support element (24) and at least one section associated with said reinforcement element ( 18.19). 6. Bearing beam as in claim 5, characterized in that said metal elements (28) are welded to said support element (24) and to said reinforcement element (18,19). 7. Bearing beam as in claim 4, further comprising a reinforcing metal mesh (29) fixed below said reinforcement element (18,19) and completely incorporated in said slab (12), characterized in that said reinforcing element support (24) is associated and arranged laterally to said reinforcing metal mesh (29). 8. Bearing beam as in any one of the preceding claims, characterized in that said support elements (24) comprise metal profiles (25) shaped so as to define an L-shaped support at least partially. 9. Load-bearing beam as in any one of the preceding claims, characterized in that said support elements (24) are preferably made of material having characteristics of rust resistance. 10. Bearing beam as in any one of the preceding claims, characterized in that said slab (12) comprises a conglomerate (20) made of vibrated and / or prestressed concrete. 11. Beam as in any one of the preceding claims, characterized in that said insole (12) comprises fibers of carbon and / or of other mineral reinforcing component. 12. Bearing beam as in any one of the preceding claims, characterized in that said slab (12) comprises a first layer (12a) in cement-based material and a second layer (12b) in polystyrene and / or in wood and / or brick and / or material other than concrete,