OA20367A - Hexagonal hollow section panel used for the construction of floors and other structures - Google Patents

Abstract

The invention is a polymer panel of hexagonal sections or an assembly and a tangle of sections in the form of hollow hexagons arranged to each other and firmly linked according to a mode of interlocking and vice-nut and welding connection. It is used to make concrete slabs without the use of props. Its bearing capacity can reach at least 3,000 mbar/m2. The invention consists of four interlocking systems or blocks (2A, 2B, 2C, 2D) composed of several types of profiles (2', 2", 2"') firmly linked together. The panel according to the invention is deployed by interlocking the male (2B) and female (2C) blocks between two anchoring blocks (2A and 2D) fixed to the load-bearing walls or to the posts. The profiles can be modulated to make a load-bearing panel that can be used as a deck for a bridge, a footbridge or a vehicle chassis or even a decorative ceiling.

Description

DESCRIPTION OF THE INVENTION

Hexagonal hollow section panel used for the construction of floors and other structures

The invention relates to a structural tool made of metal or other material, intended for the field of building and public works for the production of concrete slabs or floors and load-bearing or decorative platforms.

The panel according to the invention is a polymer of metal or other material, consisting of an assembly and a tangle of profiles in the shape of a hollow hexagon, similar to a pattern or a monomer. These profiles are arranged one to another and firmly linked to form a network in the form of a hollow, flat, rigid and solid plate, capable of bearing in certain cases enormous static and dynamic loads.

Floors or slabs are generally reinforced concrete structures used in the process of carrying out civil engineering or building and public works works.

The slab or floor refers to the horizontal load-bearing structures of a building. These horizontal carriers support their own weight as well as that of the coatings, walls, partitions as well as operating loads. They can be made from various materials including concrete. Different types of concrete floors are possible depending on the use of the construction.

The function of the floors is to transmit the loads, among other things, to the walls and columns. They make it possible to separate several levels and serve as rigid supports for floor coverings (parquet, tiles, etc.). In addition, concrete floors have insulating functions: sound insulation, thermal insulation.

There are 5 types of concrete floors: the solid slab, the pre-slab, the floor with beams, the alveolar slab and the composite floor.

- the solid slab: a solid slab is a carrier plate in reinforced concrete poured on site, with a thickness ranging from 12 to 20 cm, which rests on supports: walls or beams. Its thickness is generally equal to the 25th of the staff. The recess on the supports must be 2/3 of the thickness of the wall;

- the pre-slab: it is a thin notched slab composed of steel reinforcements. The pre-slab constitutes the lower part of the floor and serves as formwork for the solid slab and ensures

[21 part of the mechanical strength of the thin floor. Prefabricated in the factory, it has a standard size of 5 to 12 cm thick and a standard width of approximately 2.50 m. The pre-slab is most often used for the construction of collective buildings due to the speed of its implementation and the significant means of the lifting system. It has a range of up to 10 m;

- the floor with beams: the floor with prefabricated beams is most often used for the construction of individual dwellings. There are two types of floors with beams: the floor with reinforced concrete beams and the floor with prestressed beams benefiting from a greater span. It is able to deform and then return to its original position thanks to the steels placed inside;

- the hollow core slab: it is a prefabricated slab in prestressed concrete and comprising cells, in other words a concrete having undergone strong compressions. This procedure then makes it more resistant to the multiple tractions that it will have to withstand. The hollow core slab is also much lighter than a solid slab and it allows the construction of large span floors. This easy-to-install device also ensures space-saving constructions and does not require the installation of a shoring system;

- the composite floor: it is also called "mixed floor" and combines steel and concrete. It consists of ribbed thin sheet steel decks used as formwork, reinforcement and a concrete slab cast in place. Steel and concrete work together to provide strength and high load-bearing capacity. It is then distinguished by its great bearing capacity, its speed of implementation, its resistance to compression and its lower cost. Due to its lightness, the composite floor does not require the installation of joists or joists or additional reinforcement to support its weight.

The present invention relates much more to the implementation of the solid slab, and slabs with beams.

The implementation or the realization of these five types of floors or slabs is done in several stages including partly or entirely according to the case: the laying of the beams, the spreading, the break of the slabs, the break of the welded mesh and the pouring the distribution slab or pouring the concrete.

IP

In short, the production of solid slab floors involves numerous accessories: metallic or makeshift wooden props, plywood and wooden planks that can be used only once, ourds which are all elements which not only increase the cost of the operation but also make its implementation more cumbersome without guaranteeing the quality of the work.

Even if the use or the construction of the composite floor, the pre-slab and the hollow core slab make it possible to dispense with these accessories, it should not be forgotten that these are prefabricated structures made to measure by factories. uncommon and whose handling requires the intervention of a lifting device. This is bearable by large building sites and public works and expensive for individuals.

The object of the present invention is to implement a rapid, secure and non-fungible floor construction tool at a lower cost, without props or wooden planks and easy to use, handling and maintenance.

According to the invention, this objective is achieved with the polymer panel of hexagonal profiles. It is a system consisting of an assembly and a tangle of profiles in the shape of hollow hexagons. These profiles are arranged to each other and firmly linked according to a mode of interlocking and vice-nut and welding connection to constitute a network in the form of a hollow, rigid and solid plate, which can have a considerable bearing capacity.

The invention consists of four interlocking systems or blocks made up of hexagonal profiles or male, female and neutral hexatubes, themselves nested and welded in places. Interlocking blocks are of four types: female blocks, male blocks, edge blocks and anchor blocks.

In one embodiment, the blocks are structured as follows: a female block consists of three rows of steel hexatubes of the same thickness such that a central row of five neutral hexatubes is interposed between two side rows of six hexatubes containing one, three male hexatubes and three neutral hexatubes alternated and the other, three female hexatubes and three neutral hexatubes alternated, with their cavities and claws or spikes facing outwards. A male block has the same configuration but with a central row of seven neutral hexatubes. Each block thus deploys an area of approximately 83.08 cm by 41.5 cm.

14)

An edge block consists of two rows of six hexatubes of different thicknesses; i.e. a row of six female hexatubes 40 cm thick and a row of six hexatubes 80 cm thick. And an inking block is made according to the same configuration with the 80 cm thick hexatubes alternately equipped with three edge keys.

In each block or system of hexagonal pieces, the galvanized steel hexatubes are connected to each other on all edges; top and bottom edges and side edges.

In one embodiment, a hexatube or profile, component part of a male or female block is in the shape of a regular hexagon 3 mm thick, 40 cm high and 8 cm square, which can be inlaid two crowns: one below and another above and a solid cubic piece with a 3 cm edge. Each crown can be provided either with cavities or with threaded claws or studs, aligned on the same side. Thus, a male hexatube can carry a skimming stud about 2 cm long with 1 cm in diameter in its upper part and a screwable bolt in its lower part. A female hexatube can carry two circular cavities 1.2 cm in diameter, the lower cavity being provided with a nut. As for the neutral hexatube, it bears crowns devoid of claws and circular cavities.

To deploy a polymer panel of hexatubes in accordance with the invention, first the anchoring blocks are fixed to the load-bearing walls or to the posts in opposite and well-aligned fashion, then the male and female blocks are successively fitted together. to each other, from one ink block to another. An anchoring block is firmly fixed to the wall, the chaining or the post via the three level keys that equip it.

In one embodiment, the hexatubes or sections are bonded together by welding and the blocks are fitted together like puzzle pieces and then screwed together. In this way, a panel is obtained which may or may not be load-bearing depending on the type of material used, which is horizontal and stable.

The panel thus produced has, thanks to its interlocking and connection system, a colossal double horizontal and vertical bearing capacity which can reach at least 3,000 mbar/m ² , allowing it to withstand enormous stresses without props and to achieve in complete safety and with significant time savings on horizontal and smooth floors.

In another embodiment, the dimensions of the hexagonal pieces as well as the nature of the material can be modulated in order to produce a load-bearing panel that can serve as a deck for a bridge, a walkway or a vehicle chassis or even a decorative ceiling.

[5]

The carrier panel made of polymers of hollow hexagonal parts in accordance with the invention has several advantages: it is non-fungible and easy to maintain and use. It improves the safety and efficiency of work on building and civil engineering sites as well as arts and crafts work, it also helps to fight against deforestation and gives users substantial savings in the long run. term.

The characteristics of the invention will appear more clearly on reading the following description which relates to a non-limiting example of embodiment presented by figures 1, 2, 3 and 4 of plates 1 and 2.

FIG. 1 is a synoptic view of the deployment of the invention, FIG. 2 represents the four interlocking blocks of hexatubes, FIG. 3 represents the embodiment of a hexagonal tube or steel profile or hexatube, as for FIG. 4, it represents the different facades of the level key allowing the fixing of the invention to a load-bearing wall to a post or to the chaining.

In one embodiment, the carrier panel (figure 1) according to the invention is made of several profiles in the shape of hexagons, in galvanized and lacquered steel (2', 2” and 2'”). It is a metal system consisting of an assembly and a tangle of steel profiles, in the shape of hexagons and hollow. These parts are linked to each other by a mode of interlocking and vice-nut and welding connection to give a network in the form of a hollow, flat, rigid and solid metal fabric, having a minimum bearing capacity of 3,000 mbar/m ² .

The load-bearing panel according to the invention consists of four systems of interlocking hexatubes or blocks of hexatubes made up of hexagonal steel sections or male, female and neutral steel hexatubes (2', 2" and 2"') , themselves nested and welded in places; they are a female block (2C), a male block (2B), an edge block (2A) and an anchor block (2D).

In one embodiment, the blocks are structured as follows: a female block (2C) consists of three rows of steel hexatubes of the same thickness such that a central row of five neutral hexatubes (2'”) is interposed between two side rows of six hexatubes containing one, three male hexatubes (2') and three neutral hexatubes (2'') alternately and the other, three female hexatubes (2") and three neutral hexatubes (2' ”) alternate, with their cavities (4) and claws or spikes (3) facing outwards. A male block (2B) has the same configuration but with a central row of seven neutral hexatubes (2').

[6]

An edge block (2A) consists of two rows of six hexatubes of different thicknesses; i.e. a row of six female hexatubes 40 cm thick (2”) and a row of six hexatubes 80 cm thick (2””). And an inking block (2D) is made according to the same configuration with the 80 cm thick hexatubes alternately equipped with three level keys (figure 4-A-B-C).

In one embodiment, a steel hexatube constituting a male or female block is obtained from a sheet of galvanized steel 40 cm wide and 3 mm thick, folded 5 times on itself- even every 8 cm to give a regular hexagon of galvanized steel 3 mm thick, 40 cm high and 8 cm square (2', 2” and 2'”). The hexatube or steel profile thus produced will be embedded as shielding, with two crowns (1 and 7); one below and another above and each crown inlaid with a solid metal cube (9) having 3 cm of edge and serving as a base for the claw. Each crown is also provided either with two cavities (4) or with two threaded claws or studs (3), which are aligned on the same side of the hexagonal steel tube. Thereby :

- a male hexatube (2') carries two threaded claws or clamps (3) touching by about 2 cm and 1 cm in diameter, firmly welded to the solid cubic steel tube (9). The lower clamp being screwable. The male hexatube is therefore pierced with two cavities allowing the threaded claws (3) to touch;

- a female hexatube (2) carries two circular cavities (4) 1.2 cm in diameter, the lower cavity being provided with a nut;

- a neutral hexatube (2'''), has crowns devoid of claws and circular cavities.

In one embodiment, the crown (1 and 7) is a part which consists of two parts with a double internal and external welding to increase its resistance:

- a lower part in a flat steel hexagon 3 cm high and 3 mm thick, obtained by folding in on itself a metal sheet of steel 3 cm wide according to a side measurement which is fits perfectly into the hexagonal steel tube of 8 cm sides (2', 2” and 2''');

- an upper part also in flat steel preferably cut in the shape of a hollow hexagon to cover the lower part like a lid to give the profile a hexagonal angle strength.

[7]

The 80 cm (2”) hexatubes constituting the edge and anchor blocks are designed using the same process. Only, three 80 cm thick (2”) hexatubes of the inking block (2D) are equipped with a fixing system consisting of a level key (4-A, 4-B, 4-C) which consists of several elements wrapped in a support plate (10): a locking handle (13), having at each of its ends a washer (11), is actuated, and presses on a ball joint (15) to control a piston (14) integral with a wrapped tube (16) of square steel, interposed between 4 cavity flanges (12). This device makes it possible to block or unblock this block fixed on a support (carrying wall, post, chaining).

To deploy a panel in pieces of hexatubes or of steel profile according to the invention (figure 1), two anchoring blocks (2D) are first fixed on the load-bearing walls or on the posts in an opposite way and well aligned, then the male (2B) and female (2C) blocks, each of which has a surface area of approximately 83.04 cm x 41.5 cm, are successively fitted together with an inking block (2D ) to the other. An anchoring block (2D) is firmly fixed to the wall, to the chaining or to the post via the three level keys (figure 4A) which equip it.

A load-bearing panel (figure 1) is then obtained, with a considerable load-bearing capacity, both horizontal and vertical, thanks to its interlocking, screwing and welding system. It is thus possible to lay a metal mesh and warpings and mold concrete, without using props to make a solid slab.

In another embodiment, the dimensions of the hexagonal steel tubes are modulated to increase or reduce their bearing capacity in order to produce a load-bearing panel that can be used as a deck for a bridge, a footbridge or a vehicle chassis or even a decorative ceiling. or a false ceiling.

Claims (13)

1 - Panel intended for the field of building and public works for the production of concrete slabs or floors and load-bearing or decorative platforms, characterized in that the said panel consists of polymers of hollow hexagonal profiles, made of steel or other material forming blocks by welding or another type of connection, which blocks are assembled by a system of interlocking and screwing to form a network in the form of a flat, rigid and solid hollow plate, capable of possessing a bearing capacity of at least less than 3000 mb/m ² . 2- Panel consisting of hexagon-shaped sections strongly linked together according to claim 1, characterized in that said panel consists of four interlocking systems or blocks which are the male block (2B), the female block (2C) , the edge block (2A) and the anchoring block (2D). 3- Panel consisting of hexagon-shaped profiles strongly linked together according to claims 1 and 2, characterized in that the interlocking blocks consist of hexagonal profiles or male hexatubes (2 '), female (2 ") and neutral ( 2'”), welded on all edges. 4- Panel consisting of hexagon-shaped profiles strongly linked together according to claims 1 and 2, characterized in that a female block (2C) consists of three rows of hexatubes or profiles of the same thickness such as a central row of five neutral hexatubes (2'”) between two side rows of six hexatubes containing one, three male hexatubes (2') and three alternate neutral hexatubes (2'”) and the other three female hexatubes (2” ) and three alternate neutral hexatubes (2'''), having their cavities (4) and claws or studs (3) facing outwards. 5- Panel consisting of hexagon-shaped sections strongly linked together according to claims 1 and 2, characterized in that a male block (2B) has the same configuration as a female block (2C), but has a central row of seven neutral hexatubes (2'”). [9] 6- Panel consisting of hexagon-shaped profiles strongly linked together according to claims 1 and 2, characterized in that an edge block (2A) consists of two rows of six hexatubes of different thicknesses; i.e. a row of six female hexatubes 40 cm thick (2) and a row of six hexatubes 80 cm thick (2''''). 7- Panel consisting of hexagon-shaped profiles strongly linked together according to claims 1 and 2, characterized in that an inking block (2D) consists of two rows of six hexatubes of different thicknesses, or a row of six 40 cm thick (2”) female hexatubes and a row of six 80 cm thick (2'”') hexatubes alternately equipped with three level spanners (figure 4). 8- Panel consisting of hexagon-shaped profiles strongly linked together according to the preceding claims, characterized in that a profile or hexatube is a regular hexagon 3 mm thick, 40 cm high and 8 cm wide. side, inlaid with two crowns (1 and 7), i one below and another above and with a solid cubic piece (9) having 3 cm of edge, each crown carrying either a cavity (4), or threaded claws or studs (3), aligned on the same side. 9- Panel consisting of hexagon-shaped sections strongly linked together according to the preceding claims, characterized in that a male hexatube (2 ') carries a clamp (3) touching about 2 cm long with 1 cm of diameter in its upper part and a screwable bolt in its lower part. 10- Panel consisting of hexagon-shaped profiles strongly linked together according to the preceding claims, characterized in that a female hexatube (2 ") carries two circular cavities (4) of 1.2 cm in diameter, the lower cavity being fitted with a nut. 11 - Panel consisting of hexagon-shaped profiles strongly linked together according to the preceding claims, characterized in that a neutral hexatube (2 '”) carries crowns devoid of claws and circular cavities. [10] 12- Panel consisting of hexagon-shaped profiles strongly linked together according to the preceding claims, characterized in that the panel is deployed by first fixing the anchor blocks (2D) on the load-bearing walls or on the posts of opposite way and well aligned, thanks to the level keys (FIG. 4) and then the male (2B) and female (2C) blocks are successively fitted together from one inking block (2D) to the other screwing them together. 13- Panel consisting of hexagon-shaped sections strongly linked together according to all the preceding claims, characterized in that the dimensions of the hexagonal ίο parts as well as the nature of the material can be modulated in order to produce a panel that can serve as an apron for a bridge, catwalk or vehicle chassis or even a decorative ceiling.