BR112021008932A2 - structural profile type device for the formation of interfloors in construction. - Google Patents

Abstract

DEVICE OF THE STRUCTURAL PROFILE TYPE FOR THE FORMATION OF INTERFLOORS IN CONSTRUCTION. The present invention corresponds to a device of the structural profile type that has several applications in the field of construction. In particular, the present invention discloses a mechanical device of the structural profile type and specific project that constitutes the basis for the improved conformation of mezzanines in the form of false floors in different types of buildings or constructions. In this way, the device of the present invention constitutes a new alternative in the field of construction, as it allows replacing the conventional shapes or plates to form the floors or ceilings of a building in a simpler and more economical way. Indeed, the device of the present invention can be installed simply in any type of building by any operator to replace traditional tiles or boards, and materials in the construction of roofs and mezzanines of any type of building. In fact, the device of the present invention exhibits particular structural elements and certain technical specifications that have improved flexural and tensile strength properties, which is ideal in a construction because it guarantees earthquake resistance advantages, cost reduction in materials, simple, cheap and easy to install, as it is possible to adapt it to any type of construction without much difficulty.

Description

DEVICE OF THE STRUCTURAL PROFILE TYPE FOR THE TRAINING OF INTERFLOORS UNDER CONSTRUCTION

[001] The present invention is developed in the field of construction. Specifically, the present invention relates to a structural device that constitutes a new invention to form building boards that replace conventional slabs or boards, which can be easily installed in any type of building, and also exhibits flexural and tensile strength characteristics, what it gives has earthquake resistance advantages for buildings.

TECHNICAL STATUS

[002] In the field of civil construction, certain structures are necessary for the conformation of its roofs and floors that provide rigidity, strength and help in maintaining the counterweight of the structures. For example, if you need mezzanines, they have the function of dividing a structure into a large number of equidistant structural elements (called beams), so that each one withstands a portion of the total load. Thus, the mezzanines need the use of these structural devices to form the plates. In this case, both the modulation and the light between the beam supports will be the factors that determine the section of the structural device adopted. Therefore, in general, the beams are oriented in the direction that generates the smallest distance between the supports, so that a structural device with the smallest possible section is necessary.

[003] In the prior art, some construction systems are known for the formation of mezzanines that are applicable to constructions to reinforce tiles, mezzanines or roofs. In particular, the conventional system for forming slabs or slabs that function as mezzanines is well known, which require a large number of structural elements, a greater amount of support material such as concrete or cement is needed, a greater number of operators and, therefore, as a result, installation takes longer and operating costs increase. Furthermore, these systems still have certain disadvantages of earthquake resistance and bending strength that are essential for the building system.

[004] Consequently, there is still in the state of the art the urgent need for a new alternative for the formation of boards or mezzanines that improves the disadvantages and disadvantages of conventional systems based on boards, reducing operating costs, the number of operators needed, promptly available, economical, and that also significantly improves the flexural strength and earthquake resistance properties of buildings.

FIGURES

[005] Figure 1 is a perspective view of a first embodiment of the structural device to form plates or mezzanines, according to the present invention.

[006] Figure 2 is a plan view of the front structural device as shown in Figure 1, the rear being a mirror image, in which slits are present in the side walls and elongated flat base, while the upper ends are straight edges and rounded.

[007] Figures 2A, 2B and 2C are plan views of the front of the structural device, as illustrated in Figure 1, the back being a reflected image, in which the slits are present in the side walls and the elongated flat base, while the upper ends display various geometric shapes.

[008] Figure 3 is a plan view on one side of the structural device as shown in Figure 1, the other side being a mirror image.

[009] Figure 4 is a bottom plan view of the structural device, as shown in Figure 1.

[010] Figure 5 is a top plan view of the structural device, as illustrated in Figure 1.

[011] Figure 6 is a perspective view of a second embodiment of the structural device to form plates or mezzanines, according to the present invention, in which the grooves are present only in the side walls and correspond to a single series of angular lines.

DETAILED DESCRIPTION

[012] The present invention provides a first object that corresponds to a structural device for forming boards or mezzanines, characterized in that it consists of an elongated flat base that is folded at its ends inwards to form two fin structures, which subsequently extend to top to form two-sided walls; said side walls extend to form two upper ends, which correspond to ends folded back upon themselves in a U-shape; wherein said elongated flat base exhibits a series of diamond-shaped internal slits formed by a series of crisscross lines at angles between 10 to 100°, respectively, running through the entire body of said elongated flat base, and where each of said flat base the side walls exhibit internal diamond-shaped slits formed by a series of lines that intersect at angles between 10 and 100°, respectively, which run along said side walls along their longitudinal direction.

[013] In another preferred embodiment of the present invention, the structural device is characterized in that either the base or the side walls present only a row of internal grooves in the form of angular lines or lattices.

[014] In another preferred embodiment of the present invention, the structural device is characterized in that the diamond-shaped or lattice-shaped internal grooves of the elongated flat base or side walls are formed by a series of lines that intersect at an angle of 90° .

[015] In another preferred embodiment of the present invention, the structural device is characterized in that the diamond-shaped or lattice-shaped internal grooves of the elongated flat base or side walls are formed by a series of lines that intersect at an angle of 45° .

[016] In another preferred embodiment of the present invention, the structural device is characterized in that the base is completely smooth and does not have internal grooves.

[017] In another preferred embodiment of the present invention, the structural device is characterized in that each of the side walls is completely smooth and does not have internal grooves.

[018] In another preferred embodiment of the present invention, the structural device is characterized by the fact that the elongated flat base and each of the side walls exhibit the inner grooves and the upper ends display a series of inner grooves that run longitudinally throughout. the body of said upper extremities.

[019] In another preferred embodiment of the present invention, the structural device is characterized in that each of the upper ends exhibit from one to four longitudinal grooves.

[020] In another preferred embodiment of the present invention, the structural device is characterized in that the slits at the upper ends are straight, rounded, semicircular, triangular, elliptical, rolled, polyhedral or mixtures thereof.

[021] In another preferred embodiment of the present invention, the structural device is characterized in that the upper ends display edges of straight shapes, rounded, square, triangular, semi-rounded, trapezoidal, elliptical, wavy, polyhedral or mixtures thereof.

[022] In another preferred embodiment of the present invention, the structural device is characterized by being made of steel, galvanized steel, cold-rolled steel (commonly known as cold-rolled (CR) or hot-rolled steel (commonly known as cold-rolled) hot (HR) ) or aluminum.

[023] The structural device of the present invention exhibits a completely specific design that, when coupled to other simple structural components, significantly improves the properties of earthquake resistance and bending resistance in any construction that incorporates it, whether as a mezzanine or roof.

[024] Its specific design is due to an elongated element with two extreme faces, in the form of a flat rectangular base with extreme lateral edges that fold over themselves in the form of fins. Said fins are subsequently extended perpendicularly upwards to form the side walls, which continue to extend until two corresponding upper ends are formed for each wall, which are configured as ends folded on themselves in an inverted U-shape, as in the figures illustrate. A characteristic feature of the structural device of the present invention is its possibility to combine completely flat or smooth surfaces or with diamond-shaped notches or angular lines as a "lattice" in the base or side walls. Likewise, the device of the present invention contemplates the possibility of including longitudinal slits in the upper ends, where these slits can have edges of different geometric shapes, and completely traverse the body of said upper ends, as shown in Figure 2B.

[025] Thus, the device of the present invention 'can exhibit any of the above combinations in terms of the presence or absence of grooves in the base, walls or upper ends. This new combination of the structural device of the present invention allows it to exhibit superior flexural strength properties compared to conventional devices of this type, which makes it an efficient alternative to replace traditional systems for forming covers, plates or mezzanines.

[026] This is possible because the structural device is coupled with other structural components to form the roofs, plates or mezzanines, according to the area specifications required by users. In this way, the structural device of the present invention is arranged longitudinally in the form of ordered rows spaced from one another, to fit rectangular Styrofoam-type elements or blocks in their fin portions, so that they fit one after the other in the structural devices of the present invention. For the arrangement of the structural devices of the present invention, both the modulation and the light between the beam supports must be taken into account, as they will be the factors that determine the section of the adopted structural devices. Therefore, in general, the beams are oriented in the direction that generates the smallest distance between the supports, so that a structural device with the smallest possible section is necessary. Once this structure has been formed between the structural devices of the present invention and the rectangular support elements, the operator proceeds to arrange an additional support element made of steel bars or mesh. Finally, the operator allows concrete or cement to be poured over the top of this device support element structure until the entire area is covered and allowed to dry. This dry system allows you to form a roof, building board or mezzanine with excellent earthquake resistance and bending strength properties that replace conventional building systems.

[027] The upper portions of the structural device of the present invention have various configurations in their design, as long as it is possible for the filling material to enter the interior of said device. These modifications enable various shapes in their edges and longitudinal cracks, which can be straight, triangulated, semi-straight, semi-oval, semi-elliptical, polyhedral, curly, among others, as can be seen in the plans of the figures.

[028] The structural device of the present invention can exhibit various combinations between its three main components: base, side walls or upper ends. For example, the base can be completely smooth, while the walls can display diamond or lattice-shaped carvings and the upper edges are smooth; o The base may include diamond or lattice notches, while the side walls and top ends have a smooth surface, or both the base and side walls include diamond or lattice notches, while the top ends include one to four longitudinal grooves . Likewise, the edges of the top ends that are bent in an inverted U-shape can exhibit one or more longitudinal grooves, while the walls and base can be smooth; or the ends may display one to four longitudinal notches while either the base or walls may display diamond or lattice-type notches. In any case, the person skilled in the art will understand that any of the bases, walls or ends may or may not include further cutouts; the resulting combination of these notches in the base, walls or upper edges will depend on market needs or the required technical specifications.

[029] These cutouts along the walls, the upper portions and the base of the structural device of the present invention are largely responsible for the improved properties of earthquake resistance and bending strength compared to conventional devices, since their specific arrangement confers greater rigidity and strength to the structural device of the present invention.

[030] In addition, the ends of the top edges (4) can have various shapes on their edges to meet market needs. For example, depending on the number of indentations present or not present, these upper end edges may exhibit between some of these shapes straight, rounded, triangulated, trapezoidal, wavy, oval, semi-elliptical, or semi-circular edges, as shown. Illustrated. in Figures 2 to 2C. However, the person skilled in the art will understand that various shapes are possible for these upper end edges.

[031] In any case, the person skilled in the art will understand that, for practical purposes, the upper end of the structural device of the present invention must exhibit an opening that allows the entry of the contributing material, which may be a mixture of cement, concrete , between others. Thus, in the case of straight edges of the upper ends, the person skilled in the art will understand that the distance between said edges can vary, so that the opening is larger or smaller. Technical specifications

[032] The structural device according to the present invention is specifically configured to achieve the required earthquake resistance and bending strength.

[033] The structural device of the present invention can be manufactured in various materials that are common to materials used in the mechanical sector, such as steels, galvanized steel, cold-rolled steel (commonly known as cold-rolled (CR) or cold-rolled steel. hot (commonly known as hot-rolled (HR)) or aluminum, among others. Although the person skilled in the art will understand that another variety of materials can be used to manufacture these components, provided the expected results are achieved to improve earthquake resistance and bending strength of constructions that incorporate the structural device.

[034] Regarding the weights and measures of the structural device of the present invention, the person skilled in the art will understand that said device can be manufactured in such a way that it fits and meets the standard standards established in accordance with each local legislation for the field of construction . In this way, although the structural device of the present invention can be manufactured to comply with market needs, the person skilled in the art will understand that the necessary modifications can be made in weight, measurements and materials, as long as they maintain the necessary technical specifications for the structural device of the present invention of improved earthquake resistance and bending strength.

[035] Thus, the person skilled in the art interested in the fabrication of the structural device of the present invention can design it in a calculation table in which the device specifications are standardized based on different variables, including weight, dimensions, maximum supported load ( flexural strength), earthquake resistance, among others. From these specifications, the person skilled in the art can combine said variables and perform the calculations necessary to determine the technical specifications of the structural device resulting from the present invention with improved properties of earthquake resistance and bending strength.

[036] However, as an illustrative example, the table shown below is presented, which describes some typical technical specifications for a structural device, such as the one of the present invention: Property Technical specification Width 10 -14 cm Height 7-10 cm Weight 3.00 - 4.00 Kg

[037] The above dimensions are not restricted to the structural device of the present invention, but are illustrative of some measures commonly required in the market of structural devices and, therefore, may vary according to user or market requirements. Experimental Tests

[038] An illustrative structural device of the present invention, exhibiting straight upper edges and diamond-shaped grooves in the base and side walls, was subjected to several laboratory tests to measure its resistance to bending or maximum supported load. The results are shown in the table below.

Description Test Unit 1 Identification Device of the present invention with diamond-like wall cutouts Material HR Gauge 1 Base width Mm 114 Height Mm 70 Maximum load kN 16.96 Maximum load N 1729.6 Maximum load Kgf 1729 Test Speed (mm/min) 3.0 Tests performed by the Testing Division – CONCRELAB, Headquarters Bogotá, Colombia. The test corresponds to a FLEXION TEST, performed following the procedure described in the Colombian technical standard NTC 3353-97.

[039] The above results conclusively demonstrate that the structural device of the present invention with grooves in the base and side walls, with straight edges, presents a significantly greater resistance to bending, since it is capable of supporting a maximum load of 16.96 kN (1729 kgf), which makes it absolutely ideal for forming slabs or mezzanines in various constructions. Additional tests performed on other structural devices, which are within the scope of the present invention, demonstrate that the presence of notches in the walls, base or upper ends, or the combination of notches with smooth surfaces, exhibit superior flexural strength results, making it a highly desirable device to replace conventional mezzanine construction systems.

[040] Thus, the previous tests confirm that the structural device of the present invention, which combines the presence or not of cracks in the forms described in this document, effectively represent an advance in the field of construction and an innovative alternative in the conformation of slabs, coverings or floor slabs, as it is able to withstand a very high maximum load as well as to give properties of flexural strength and seismic resistance compared to conventional systems. manufacturing

[041] The structural device of the present invention can be configured and manufactured using several techniques of the state of the art well known by any experienced person. For example, the technique consisting of cold rolled (called “cold rolled” in the conventional market) and hot rolled is well known. Another technique that can be used to configure the structural device of the present invention is the extrusion of material, which may include steel or aluminum, until the specific design of the structural device is achieved. The procedure used must allow the design projected for the structural device of the present invention with the required technical specifications.

BENEFITS

[042] The structural device of the present invention has the following advantages that make it suitable to replace conventional systems for forming slabs, floor slabs or roofs:  It presents excellent properties of resistance to bending and seismic resistance in any type of construction , as it has a specific configuration that provides improved rigidity, with light weight, particularly due to the presence of cracks in the walls, the base and the upper edges;  It's simple, because it doesn't require molds or uncomfortable accessories;  It is versatile because it can be easily adapted to any area and is aesthetically pleasing due to its excellent finish;  It is easy to install, as it does not require installation equipment and special tools, which significantly reduces construction costs;  It is obtained through simple manufacturing processes, which remarkably reduces your production costs;  It has applications in the conformation of slabs and roofs of any construction;  It is a product with easy availability for the user, in sheds and locksmiths.

[043] Anyone experienced in the construction technique will understand without difficulty that it is possible to carry out several modifications or variations on the device

Claims (1)

structure disclosed herein, without departing from the scope and purpose of the invention. The embodiments and variations set forth in the present invention are not to be understood as limiting the scope of the invention, which is determined by the content of the following claims.