ES2914819A1 - Structural sheet system (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Structural sheet system. It consists of a structural sheet system that facilitates a quick assembly and without the use of concrete in the process. This system has 3 versions: structural sheet, structural sheet plus OSB board, structural sheet plus OSB board and interior insulation. The structural, horizontal or inclined system system consists of elements of metal plates in wave, so that all work unions are screwed and/or riveted. The system can be complemented with the use of OSB boards at the top for the support of the floor, with metal omegas at the bottom for the placement of false ceilings and with internal isolation. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Structural Sheet Metal System

TECHNICAL SECTOR

The present invention relates to a structural sheet metal system, intended to offer a structural system that is easy and quick to assemble without the need for concrete in the process.

The invention ranges from a simpler embodiment variant, obtained from a structural sheet, through two other more complex variants consisting of a structural sheet reinforced with OSB boards (Oriented Strand Board) with or without insulation inside.

It is a system of structural panels, horizontal or inclined, based on wave metal plate elements. All on-site joints are screwed and/or riveted.

The system can be complemented with the use of OSB boards in the upper part to support the flooring, with metal omegas in the lower part for the placement of false ceilings and with interior insulation.

The invention is therefore situated within the field of structural systems for building, industry, storage, etc.

The object of the invention is to provide a light system, easy to assemble, safe for the worker, reusable, 100% recyclable and with a high thermal insulation capacity.

BACKGROUND OF THE INVENTION

Currently, the structural systems commonly used in construction are based on reinforced concrete structures, prefabricated concrete (more common in industrial construction), structures with load-bearing masonry walls, steel structures or mixed.

There are others such as systems of wooden structures, with a minority presence.

In the first cases, concrete is used totally or partially and they are structures with an average weight greater than 300.00 kP/m2.

The material consumption is enormous and the execution processes are slow, both due to the “in situ” work procedures (except in the case of prefabricated reinforced concrete) and due to the setting process itself that the concrete requires.

Also, as a general rule, these conventional structural systems are not easily recyclable.

On the other hand, there are sandwich panel-type elements for insulation on the market, but they are not structural elements.

In the present case it is a structural element that, in its version with internal insulation, constitutes an excellent solution for cases in which high thermal insulation is required (thermal envelopes, floors, cold rooms,...) .

EXPLANATION OF THE INVENTION

The structural sheet metal system that is recommended solves the aforementioned problems in a fully satisfactory way, based on a simple but highly effective solution.

For this, and more specifically, according to the simplest embodiment of the invention, it is a steel sheet folded in a W shape with a thickness of 1.5 mm.

This sheet is supported by the vertical load-bearing structure and can be reinforced with an OSB board screwed and/or riveted, as well as fireproofing elements, fire protection (mineral wool, plasterboard,...) and thermal insulation.

It can be used together with metal load-bearing systems or it can be applied in combination with other load-bearing structure systems given its versatility and ease of assembly.

Although the embodiment of these objects and the structural system of the present invention shares some approaches with other systems within the state of the art, it is the only system that presents the following set of advantages:

a) Reduction in the terms of execution of the structural system.

The system of the invention is based on the realization of the structural sheet in the workshop, transport to the work and subsequent assembly of the same. In this way, it is estimated that, in the case of a normal housing structure, the assembly of the horizontal structure would take 1 day per floor. If we compare with a conventional system we can be talking about a saving of 1 week per plant.

The procedure is simple:

All elements are made in the factory.

Once the foundation and the vertical bearing structure (part that does not belong to this system) are perfectly level and with the necessary elements to receive the system of the invention, all the elements are transported to the work and placed according to a procedure and an order perfectly established in advance.

The corrugated sheets are placed, to which a mechanical joint will be applied to the load-bearing subsystem at the lower supports.

As a final step, a board will be included, if desired to have a flat support, on the upper face of the waves, screwed with self-drilling screws to them.

b) Reduction in the manpower required in the execution of the structure as well as the work to be carried out “in situ”.

The system is built in a workshop, protected from the elements, which results in an additional reduction in terms in the case of rainy seasons. This reduces the work that needs to be done on site.

The system is built in the workshop by a highly qualified workforce and with precision machinery. On-site assembly is carried out by specially qualified personnel, estimating only the need for 3 people in the most common case: one person to handle the crane and two people to do the assembly. This reduces the labor required.

c) Elimination of wet work.

The system eliminates the need for a compression layer, thus eliminating the use of concrete. This represents a great advance in terms of weight reduction, time reduction, reduction of personnel on site, increased safety on site and ease of assembly. The function of the compression layer can be performed with OSB boards. In the case of special needs for areas with higher loads, carbon fiber textile reinforcements will be used, both mesh and unidirectional.

d) Reduction in the weight of the structure and, as a consequence, reduction in foundation costs.

The system, due to the geometry of its wave, has very high structural resistance characteristics and weighs between 10 and 20 times less than the usual structural systems. This advantage also affects the foundation, reducing its cost.

e) Reduction of the risk for safety and health at work in the structure phase.

Due to its lightness, the system can be manipulated on site without even needing machinery (3 people can move a 6 m long by 0.5 m wide wave without difficulty), which results both in the speed of execution as in a increased safety on site.

Once the system is in place, it can be walked on, increasing safety on site.

f) Totally recyclable structural system.

Being a steel structure, the system is fully recyclable.

g) Structural system with high thermal insulation.

By having internal insulation (in its most complex variant) insulation thicknesses ranging from 110 mm. up to 248mm. of insulation, the only structural system with these characteristics on the market.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that is going to be made below and in order to help a better understanding of the characteristics of the invention, according to a preferred example of its practical embodiment, a set of plans is attached as an integral part of said description. where, by way of illustration and not limitation, the following has been represented:

Figure 1.- Shows an axonometric perspective view of the simplest embodiment variant of the present invention.

Figure 2.- Shows a section/profile view of the device in Figure 1.

Figure 3.- Shows a side view of the device of the previous figures.

Figure 4.- Shows an axonometric perspective view of a second embodiment variant of the system of the invention, in which the sheet metal is complemented by a board. Top and bottom OBS and self-drilling screws.

Figure 5.- Shows a section/profile view of the device in figure 4.

Figure 6.- Shows a side view of the device of figures 4 and 5.

Figure 7.- Shows an axonometric perspective view of a third embodiment variant of the system of the invention, in which the plate is complemented by an upper and lower OBS board, self-drilling screws and an internal insulator.

Figure 8.- Shows a section/profile view of the device of figure 7.

Figure 9.- Shows a side view of the device of figures 7 and 8.

PREFERRED EMBODIMENT OF THE INVENTION

In view of the figures outlined, and according to the simplest embodiment of the invention, the one shown in figures 1 to 3, it can be seen how the invention is constituted from a steel sheet with a thickness of the order of 1.5 mm that folds into a "W" shape, which can be manufactured in different dimensions, with a length always less than 6 meters, and which in the variant of execution chosen, merely as an example, has a height that can go from 110 to 248 mm and a width between 485 and 742 mm, where the number of folds can vary between 2 and 3 per piece.

As has been said previously, this sheet is supported by the vertical load-bearing structure, so that, according to the variant of figures 4 to 6, it can be reinforced with both upper (3) and lower (4) OSB boards. which are fixed to it by means of screws and/or rivets (2), boards that in the chosen embodiment have a thickness of the order of 15mm.

This structure can be completed, according to the embodiment variant of figures 7 to 9, with an inner core (5), as a fireproofing element, protection against fires (mineral wool, plasterboard,...) and thermal insulation.

This core can have thicknesses ranging between 110 and 248mm.

The system thus described can be used in conjunction with metal bearing systems or it can be applied in combination with other bearing structure systems given its versatility and ease of assembly.

From this structuring, once the foundation and the vertical bearing structure (part that does not belong to this system) are perfectly level and with the necessary elements to receive the system of the invention, all the elements are transported to the work and they are placed according to a procedure and an order perfectly established in advance.

Next, you can opt for an “in situ” assembly, placing the corrugated sheets, to which a mechanical joint will be applied to the load-bearing subsystem at the lower supports, so that, as a final step, a board will be included, if desired. to have a flat support, on the upper face of the waves, screwed to them with self-drilling screws, or opt for the most appropriate option, which is to transport the assembled system from the factory in any of its three options: structural sheet metal system, of structural veneer and OSB board or structural veneer system, OSB board and insulation and/or fire retardant material.

This structuring eliminates the need for a compression layer, thus eliminating the use of concrete, reducing weight, deadlines and personnel on site, as well as increasing safety and facilitating assembly.

The function of the compression layer can be performed with OSB boards. In the case of special needs for areas with higher loads, carbon fiber textile reinforcements will be used, both mesh and unidirectional.

Claims (7)

1§.- Structural sheet metal system, which being of the type made up of a series of elements that rest on a vertical load-bearing system, to which they are fixed by means of mechanical joints, is characterized in that it is made up of a steel sheet with a thickness of around 1.5 mm that is folded in a "W" shape. 2§.- Structural sheet metal system, according to claim 1§, characterized in that it has a length of less than 6 meters, a height that can range from 110 to 248 mm and a width between 485 and 742 mm, where the number of folds can vary between 2 and 3 per piece. 3§.- Structural sheet metal system, according to claims 1§ and 2§, characterized in that it includes both upper (3) and lower (4) boards of OSB that are fixed to the sheet metal by means of screws and/or rivets (2). 4§.- Structural sheet metal system, according to claim 3§, characterized in that the upper (3) and lower (4) boards of OSB have a thickness of around 15mm. 5§.- Structural sheet metal system, according to claims 1§ to 4§, characterized in that it includes an inner core (5), made of fireproof and/or thermal insulating material. 6§.- Structural sheet metal system, according to claim 5§, characterized in that the core (5) has a thickness between 110 and 248mm. 7§.- Structural sheet metal system, according to claims 1§ to 6§, characterized in that it is complemented by a finishing board on its upper face that defines a flat support surface, screwed with self-drilling screws to the sheet metal.