KR20150042183A - Modular element in sintered expanded-polystyrene for building reinforced-concrete floors - Google Patents

Abstract

A modular sintered expanded polystyrene element for building a reinforced concrete floor, comprising a polystyrene body having a metal part (A) embedded therein for imparting self-supporting properties to said element, said polystyrene body having an arbitrary length and a bottom (A) has a total height (h) that is equal to or slightly higher than the height of the side wings (4) and has a substantially rectangular portion A sheath (2) is further provided in the polystyrene body in a transverse direction with respect to one of the metal portions (A).

Description

[0001] MODULAR ELEMENT IN SINTERED EXPANDED-POLYSTYRENE FOR BUILDING REINFORCED-CONCRETE FLOORS FOR STRUCTURING REINFORCED CONCRETE FLOOR [0002]

The present invention relates to a modular element made of a heat insulating material used in a floor structure, in particular a sintered expanded polystyrene for constructing a reinforced concrete floor. The present invention also relates to a reinforced concrete floor constructed using a plurality of said modular elements, one of which is disposed in close proximity to the other and remains integral to the floor.

In order to prepare a temporary casting plane, a technique for constructing a floor made of reinforced concrete using elements made of foam plastic material, preferably sintered expanded polystyrene, instead of traditional brick elements has long been known in the building industry.

The bottom construction technique is substantially the same in both cases and is provided to form the casting plane, while being supported by a plurality of self-supporting elements disposed side by side, preferably around the wall or at the pillar at its end by overlapping or mutual engagement do. Before completing the casting, the reinforcing bars are placed entirely in a conventional manner, between a pair of adjacent elements made of expanded polystyrene, and corresponding to the longitudinal channels formed therein, and when the casting is done, Incorporates polystyrene elements and reinforcement rods. Corresponding to the reinforcing bars, a longitudinal joist is so formed that when the concrete is cured it provides the mechanical rigidity of the floor. With respect to the floor formed by brick elements, the bottom with foamed polystyrene elements has a significantly lower weight and a greater thermal insulation coefficient, while having the same mechanical stiffness.

WO-A-98/16703 is an exemplary document of the above-exemplified technique disclosing a prefabricated element made of polystyrene, wherein two Z-shaped longitudinal metal parts are embedded in the manufacture of the element, Self-supporting properties. The lower side of the L-shaped portion is visible and can be placed on the lower portion of the assembly element and used to secure the metal reinforced mesh there by welding. These meshes are intended to facilitate the settlement of a low covering such as a plaster and to ensure the overall mechanical integrity of the structure, even in the case of fires in which the foamed polystyrene material is capable of melting due to high temperatures.

The basic problem of the present invention is that the lateral jaws in addition to the above-described reinforced concrete longitudinal jaws are constructed so that the mechanical stiffness of the bottom is the same as that of the above-mentioned type having the same performance in two directions forming so- To provide a pre-assembled polystyrene element.

In fact, while the same problem has been addressed in the prior art, as shown below, the solution is based on both the structural complexity of this solution and the insufficient assembly level that still requires highly skilled skilled labor I was not satisfied.

WO-A-2005/121467 has a structure very similar to that described above for WO-A-98/16703, which recalls all of its essentials. However, a metal portion for imparting self-support to the polystyrene element has an L-shaped shape, and the top portion of the metal portion itself is folded, resulting in a slight increase in thickness. In the first embodiment, the elements are conceptually identical to those described above, thus allowing only a longitudinal reinforced concrete joist to build the floor provided. In the second embodiment, the metal part is not provided during the manufacturing process of the polystyrene element, but is then inserted into a separate sheet formed on the polystyrene through a mechanical cutting process (e.g. hot thread) of the element. This step-separation manufacturing method also allows a series of transverse grooves to be formed in the polystyrene element and then a reinforcing rod disposed therein to obtain a planar floor having a reinforced concrete joist finally oriented in two mutually perpendicular directions Let's do it.

However, the solution proposed in WO-A-2005/121467, in addition to the obvious complexity and high cost of the two-stage manufacture, also has two significant technical disadvantages. The first disadvantage is due to the fact that the metal part is no longer firmly secured to the foam material (as the foam material occurs instead of a simultaneous manufacturing process in which the fluid material is pierced through the hole present on the wing of the metal part) . Thus, there is a lack of close connection between the metal part and the foam material, which is the only characteristic that is likely to cause an even and accurate distribution of the mutual load during the transfer and laying operations and during the floor construction step. A second significant operational disadvantage is that the work of laying reinforcement rods in the transverse channels is further accomplished after the metal part is positioned, resulting in the fact that it creates a plurality of barriers in the channel. It is therefore not possible to place the rods in the channels from above in accordance with standard building site procedures and instead the rods must be introduced laterally one by one into the holes provided on the wings of the other metal parts which interfere with the continuity of the channels. Thus, because of the obvious need to have a free space next to the floor under construction at least having a size corresponding to the size of the floor itself, and because of the very long, difficult and labor intensive work in any case, none.

WO-A-2006/040624 addresses the same problem, but provides another type of solution in which the polystyrene elements are divided into two separate layers that are mounted only during field installation. The first base layer forms a continuous plane of small thickness and incorporates a metal part to provide self-supporting properties thereto. Instead, the second layer consists of separate parallelepipedic elements positioned one after the other along the lattice-like pattern on the base layer, forcing them into a part of the metal part protruding from the base layer, And both of the transverse channels. This solution eliminates the abovementioned disadvantage associated with patent WO-A-2005/121467, namely lateral insertion of the reinforcing rod, but instead of insufficient fixing of the upper polystyrene layer to the metal part and remarkable installation complexity of such layer With disadvantage, these individual parallelepipedic elements must be precisely positioned longitudinally using a suitable template so as to ensure that the transverse channel thus formed has a constant width and perfect alignment.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to solve the above-mentioned problems by constructing a flat floor including reinforced concrete joist in two mutually perpendicular directions, and it is an object of the present invention to provide a self- Polystyrene < / RTI >

Thus, in particular, it is a first object of the present invention to provide a prefabricated polystyrene element of the type described above in which a reinforcing metal portion is completely embedded within the foam material during the assembly process.

It is already fully completed and is modularly available to extend longitudinally to the desired length and which allows for the creation of the desired transverse channel while not requiring any other additional mounting or finishing operations or insertion of additional bodies, It is a second object of the present invention to provide a prefabricated polystyrene element of the type described above that can be installed directly side by side on similar elements.

This goal is achieved through modular polystyrene elements having features defined in the main claims appended hereto. The dependent claims describe other desirable features of the present invention.

Other features and advantages of the invention will be apparent from the following detailed description of a preferred embodiment given in purely non-limiting examples and illustrated in the accompanying drawings.

1 is a schematic perspective view of a modular polystyrene element according to the present invention.
Figure 2 is a cross-sectional view of the enlarged ratio of the modular element of Figure 1;
Figure 3 is a schematic perspective view of a plurality of modular elements lined side-by-side to provide a casting plane to the structure of the floor.

As is clearly shown in Figures 1 and 2, each modular element (E) of the present invention is described in the aforementioned International Patent Publication WO-A-98/16703, the entire contents of which are incorporated herein by reference, And a single sintered, expanded polystyrene body in which two metal parts (A) are embedded inside to impart a self-supporting property to the elements, in a manner totally similar to the reference known technology constituting the arc. Specifically, the polystyrene body has a substantially rectangular portion with a lateral wing 4 protruding at any length and below, and the wing 4 has a reduced thickness compared to one major internal portion 1 of the body .

However, the modular elements of the present invention are not limited to the prior art in that the metal part A has a Ω feature and preferably includes flat sides connected by edges, Is substantially equal to or slightly larger than the thickness of the blade (4) of the blade (E). Due to this particular construction it is possible to provide a series of transverse recesses 2 with depths extending into the top of the metal part A in each element E. [ Thus, the recess 2 may have a generally equal size in width and depth as the longitudinal cavity 3 formed in the connection point between two adjacent elements E, and according to the teachings of the prior art, The recesses 2 and cavities 3 are formed in the interior portion 1 of the modular element E having a square or rectangular shape depending on whether the pitch of the recesses 2 is equal to or different from the width of the portion 1 ).

It is easy and immediate to place the reinforcing rods F from above on the inside of the plurality of elements E because a network of orthogonal channels 2 or 3 is formed when one is placed close to the other, The metal reinforcing mesh R can be simply placed on the inner part 1 of the element E. [ At this time, the concrete castings C reach the object of the present invention by constructing the preferred planar floors in which the reinforced concrete joist is provided both longitudinally and laterally on the casting plane constituting the element E positioned side by side .

As described above, the metal portion A has a Ω shaped portion, which includes five flat sides, which are precisely connected by edges. The two distal sides and the one central portion are parallel to the lower surface of the element E while the two intermediate sides are perpendicular or inclined appropriately to the lower surface. In addition, one of the terminal side portions may be located near and outside the expanded polystyrene body, and may be used to fix the metal reinforced mesh in a manner known per se, while the other terminal side is embedded in a foamed polystyrene body.

As is evident from the previous description, the modular, expanded polystyrene element (E) of the present invention achieves the planned goal perfectly. In practice, this is an element that can be quickly and easily installed in an automatic manner, with all the details of a given length being manufactured entirely prefabricated. In this element (E), the metal part (A) providing the self-supporting property is completely embedded in the expanded polystyrene body, so that it is completely integrated with the expanded polystyrene body. Thus, the arrangement of the plurality of proximity elements E can be achieved by simply laying the reinforcing bars F from above in a conventional manner, without additional work, to create a flat floor with bidirectional reinforcing joists, .

It should be understood, however, that the invention is not to be considered as being limited to the specific configurations shown and described, but only by way of illustration and example, without departing from the scope of protection of the invention as defined by the appended claims. It should be understood that variations are possible.

Claims (7)

A modular sintered expanded polystyrene element for building a reinforced concrete floor, comprising a polystyrene body having a metal part (A) embedded therein for imparting self-supporting properties to said element, said polystyrene body having an arbitrary length and a bottom Has a substantially rectangular portion from which a side wing (4) of small thickness protrudes,
Characterized in that the metal part A has a total height h equal to or slightly higher than the height of the side wings 4 and one or more recesses 2 are arranged in a transverse direction with respect to one of the metal parts A. [ A modular sintered expanded polystyrene element characterized in that it is further provided in a polystyrene body. The method according to claim 1,
Wherein the metal part (A) has an Ω shape with flat sides connected by corners. 3. The method according to claim 1 or 2,
Characterized in that the transverse recess (2) has substantially the same size as the cavity (3) formed on the side wings (4) corresponding to the connecting area of two adjacent elements (E) Element. The method of claim 3,
Wherein the transverse recess (2) has a direction perpendicular to the metal portion (A). 5. The method of claim 4,
Wherein the distance between two adjacent recesses (2) is equal to the width of the inner part (1) of said element (E). 6. The method according to any one of claims 1 to 5,
The metal part A having an Ω feature with flat sides with edges connected has two end sides parallel to the bottom face of the element E and the sides are adjacent to the foam polystyrene body, Wherein the sintered expanded polystyrene beads are located in the sintered expanded polystyrene matrix. A casting plane consisting of a plurality of modular expanded polystyrene elements according to any one of claims 1 to 6 arranged in proximity to one another and arranged in the longitudinal cavity (3) and the transverse recess (2) (R) arranged on the inner part (1) of the polystyrene body of the element (E), if possible.

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