Connector with projections of conical or semi - conical section

Abstract

The present invention describes a connector (1) with conical or semi-conical section, with snap-type bayonet coupling mechanism that allows an easy fixation and remotion of a building structure. These connectors can present variable geometry and length. A building structure comprising a plurality of such connectors (1) as well as a process of construction of said building structure is also described here.

Description

FIELD OF THE INVENTION

The present invention relates to a system device linked connector with conical projections of semi-conical section, in particular made of steel and/or thermoplastics composite with high tensile and torsion strength, and to a building structure—building envelope obtained with a plurality of such connectors that comprises a multi faceted insulation panel are dovetail.

BACKGROUND

The document EP 1953303 describes a wall element used in the process of a concrete wall by formwork that characterizes for removing shear strength. The invention presented here comprises a system device linked with a connector that comprises a snap-type bayonet coupling mechanism. This coupling mechanism allows for an easy docking and undocking of such connectors that comprises conical projections of semi-conical section. The connectors described here are_used in a process of building structure formation by insulated concrete formwork in which the formed building structure is resistant to_earthquake, thermal variation (zero energy), sound and humidity

The document EP1486628 describes a truss beam that can be used in precast walls and roofs. The invention described here is not a beam, but a connector used in a system devices of building structures that comprises a snap-type bayonet coupling mechanism. Specifically, these connectors present conical projections of semi-conical section and can be used in the formation of building structures of zero thermal bridges and resistant to earthquake thermal variation, sound protection and humidity resistant.

The document DE8804708 describes reinforcing components for a concrete wall that comprises at least two rods with supports for structural steels and transversal rods welded between this two rods. The invention presented here comprises a system device linked with a connectors that are not welded in the building structure, but that are easily fixed or removed since comprise conical projections of semi-conical section that viabilises_a snap-type bayonet coupling mechanism. The connectors described here can be used in building structures resistant to earthquake, thermal variation, sound resistant and resistance to moisture by capillary action of humidity.

In particular, the building structure monolith of the present invention made as multiple types of decoration monolith moreover that of decorative cornice insulation (the decoration is designed so as to minimize heat transfer across the panel, by using material which forms substantially). The modular structure with variable geometry object of the present invention is particularly designed for the realization of: foundations for supporting earthquakes made integral in capsules insulation, for anti-seismic, heat-insulating, monolithic walls; mono-directional acoustically-insulating roofs and floors with variable geometry, bi-directional acoustically-insulating roofs and floors with variable geometry; external thermal insulation composite systems coats (the coats are designed so as to minimize heat transfer across the panel, by using material which forms substantially), with monolithic longitudinal and reticular structural concrete core for seismic reinforcement to existing building structures to be rehabilitated, also thermally and acoustically; external ventilated thermal insulation composite systems coats; thermo-acoustic ventilated roofs in extrados in metal alloys; thermo-reflective and thermo-acoustic floors with extrados surfaces made of aluminum film, metal alloys, plastic-composite thermoplastic, polystyrene and/or polypropylene, with exclusive breathable characteristics and with thermal and acoustic insulation.

As known for a long time, the realization of modular elements with variable geometry exclusive structural functions that are earthquake-resistant at exclusive thermal resistance and acoustic resistance, such as the above mentioned components, which have high characteristics of mechanical resistance, thermal resistance, acoustic and at the same time guarantee good breathability, has always been a very sensitive issue in civil and industrial buildings all over the world.

Another problem strongly felt is to provide modular monolithic structures with variable geometry that are earthquake-resistant and with thermal and acoustic resistance that are eco-sustainable and can be easily assembled in situ, via a modular and mirror-like interlocking, and put in place easily by any person and in reduced times.

Object of the present invention is providing an anti-seismic building structure combining at the same time the thermal resistance, acoustic, or homogeneous in all its partitions, eco-sustainable which allows providing earthquake-resistant foundations with an integral capsule and thermal insulation, monolithic breathable containment walls or bearing walls, acoustic mono-directional and bi-directional roofs and floors with variable geometry; external thermal insulation, composite systems coats, with longitudinal core and acoustic lattice armed concrete structural reinforcement to existing building structures; external thermal insulation system composite coats that are macro- or micro-ventilated, ventilated acoustic roofs in extrados in metal alloys or plastic-composite thermoplastic or polystyrene, and the like, with exclusive breathable characteristics and thermal and acoustic insulation.

Within this scope, an object of the invention is to achieve a building structure, or an entire building envelope zero energy, homogeneous in every partition, modular variable geometry eco-sustainable that can be assembled dry interlocking with very few elements, and placed in work easily and quickly by any person.

A further object is to provide an anti-seismic structure and/or building envelope zero energy, homogeneous in every partition, sustainable and thermo acoustic in all its parts, consisting of light materials, even recycled, for easy transport and installation, as well as maintaining exclusive static functionality.

The present building structure and/or building envelope zero energy, for its unique and particular constructive characteristics, is capable of ensuring the greatest assurances of structural reliability in areas of high seismic risk, and safety during assembly and pose in work.

These and other objects, which will become more apparent hereinafter, are achieved by an anti-seismic building structure and/or building envelope, which is thermo acoustic, modular variable geometry eco-sustainable made with connectors as described in claim 1.

Such a modular structure, homogeneous in all its parts and environmentally friendly, comprises at least one modular element, with preferably a honeycomb structure with variable geometry, capable of being joined to different modular components to obtain different embodiments without constraints of structural forms and architectural; the modular element is made of any plastic material, also of composite materials with other polymers or copolymers, natural materials and/or synthetic insulating or any metal alloy, and has a series of passages in which is created the vacuum during manufacture at an industrial level, by molding or extrusion, the modular element itself; said modular element variable geometry constitutes a structural element and has insulating characteristics even in minimum thicknesses, even in the structural the ribs.

The outer surfaces of the modular element with variable geometry have a series of grooves and the ribs, preferably shaped dovetail rib the undercut or circular, which allow to join two or more elements to each other; these modular elements of variable geometry may also be combined head of using different types of pegs male and female or rib to rib horizontal female or male, arranged in correspondence of the passages, thus ensuring the reversibility of the element.

The modular element is linked connector with conical projections of semi-conical section is joined to an insulating panel, preferably a variable geometry metal alloy and/or plastic materials, also of composite materials between them, which has an outer surface ribbed, or substantially smooth and suitable to be mounted at sight or with a corrugated outer surface with the most diverse shapes, which, placed horizontally, serves for the snap engagement of additional modular elements, or for the application of a plurality of steel reinforcement positioned in the longitudinal and/or reticular, the same also positioned in overlapping respecting the minimum concrete cover of 25 millimeter, with eventual jet of a screed to create for example, a slab corresponding structurally, and characterize it by a significant thermal mass and heat-reflecting according to the density.

The system bayonet-clip, in the various elements and/or connectors with conical projections of semi-conical section of the subject invention refers to a joint system snap, of at least two elements inserted easily into one another and then blocked until it engages the release tab or in other conformations of the connectors b rotation of a quarter turn.

All these methods of construction inventive have the same inventive basic connection system device of linking a connector with a projection conical or semi-conical section and the same advantages related to a complete and exclusivity absence of thermal bridges.

The same modular element is linked connector with conical projections of semi-conical section joined a panel variable geometry alloy metal and/or plastic-composite thermoplastic extruded polystyrene foam (XPS), normal and covered with embossed aluminum, Expanded Polystyrene (EPS) preformed shell covering or coating film, which has an outer surface ribbed or substantially smooth and suitable to be mounted in-sight position to the horizontal or vertical, or with a corrugated outer surface, which, placed horizontally, is for making a floor with exclusive thermo-reflective insulation characteristics, which, after staying in the slots necessary tubing where the water flows smoothly care, can be supplemented with a cement to make it a perfect plane coplanar in which they can be laid directly multiple types ceramic floor tiles and all types of finishes without bond.

The same modular element is joined to a panel variable geometry metal alloy which has an outer surface ribbed or corrugated, which, placed vertically to a wall resistant to stresses as can be seen in FIG. 1b, is used, to implement a external thermal insulation composite systems coats -thermo-reflective view, plastered and/or finished with other finishing elements.

The same modular element linked connector with conical projections of semi-conical section is joined to a panel variable geometry in metal alloy, which has a corrugated outer surface, which, placed in a vertical or inclined with respect to a floor or existing slab, serves to provide a macro-ventilated or micro-ventilated thermo-reflective sight, or covered with any-type of finishing elements, such as system photovoltaic panels or multiple types of tiles available in the world market.

Although this invention has been described in its preferred form with a certain degree of particularity, it is understood that the present disclosure of the preferred form has been made only by way of example and that numerous changes in the details of construction and the combination and arrangement of parts may be resorted to without departing from the spirit and scope of the invention.

Such a system foundation beams, wall floors and roofs ;element with two or plus insulating panel layer, may locally with a manufacturing method of a foundation beans wall floors and roofs device—in particular according to one of claims 1 to 20—are prepared according to claim 21. For this purpose the connecting elements are inserted in the cavity a (T) through the insulating panel layer such that the connection elements on both sides of the into inside in the insulating panel layer and plus panel linked in the face insulated concrete formwork ICF.

Preferably, the connecting elements are arranged distributed at least substantially uniformly in regions of the wall in the system device linked with a connector with projection conical or semi-conical section. In particular, in each case adjacent connecting elements have horizontal and/or vertical direction pre-determinable, substantially equal and or different distant for assembly pillars distances from one another on. An appropriately dense distribution or arrangement of the connecting elements can be guaranteed for a system foundation beams, system wall, system floors and roofs component of a predetermined size and a predetermined required tension between the concrete layers. In general, a symmetrical arrangement of the connection elements, each in the horizontal and/or vertical direction a pre-determinable arrangement will be provided in each case adjacent connecting elements have substantially equal distances to each other.

In a very particularly preferred embodiment, a with a connector with projection conical or semi-conical section linked the connection element and/or an anchor component plastic with unidirectional or multidirectional fibers arranged, which comprise in particular, glass, basalt or carbon fibers, preferably boron-free silicate glass fibers, wherein the plastic material, in particular polyester, vinyl ester, or polyurethane. These materials have a high tensile strength and are thus particularly suitable for this application. In the selection of a material for the connecting element and/or the anchor member is to be considered that they are resistant to moisture and/or environments with a high pH. In particular, the low thermal conductivity of these materials especially advantageous, since this the envelope building has ZERO thermal bridges and a very high thermal insulation effect is possible.

Further characteristics and advantages of the present invention will become more apparent from an examination of the description of a preferred, but not exclusive, embodiment of the invention, illustrated only by way of non-limitative example in the accompanying drawings, in which:

FIG. 1 is a view in detail of a series of connectors inventive (1) of the present invention mounted in a transversal manner in a building structure;

FIG. 1b is a detail of FIG. 1 in which it can be seen a detail of the engagement of the connector of the present invention (15) in a snap-type bayonet.

FIG. 2 is a view similar to FIG. 1 with a variant of assembly. The connectors inventive (1) are also positioned in a transversal manner;

FIG. 3 is a perspective view of a possible embodiment of the inventive structure with the connectors inventive (1) engaged;

FIG. 4 is a detail of FIG. 3, a view similar to FIG. 1 with a further variant of assembly in which the connectors inventive (1) are positioned in a longitudinal manner and follow the shape of the external structure. The connectors inventive (A, B and C) are different in the folding shape;

FIG. 5 is a side view in detail of some connectors of the invention that has the same folding shape and are positioned in a longitudinal manner relative to the external structure;

FIG. 6 is a side sectional view of a molding with decorations;

FIG. 7 is a side sectional view of a molding with decorations;

FIG. 7A is an example of foundation with plastic and steel connectors of the present invention

FIG. 7B is an example of a modular wall element according to the present invention.

FIGS. 8 to 13 are perspective views of various stages of assembly of the structure of FIG. 3;

FIG. 8A is a detail of FIG. 8 showing a foundation with several monolithic walls.

FIGS. 14 to 24 show several embodiments of seats (3) for reinforcing irons (5);

FIGS. 16, 17 and 18 refer to the elements and/or individual connectors with multiple form projection that are associated advantageously with each other to firmly engage any size or diameter of the tower and/or steel bar in order to obtain the true armor widespread.

FIG. 19 clearly shows that the device with multiple form projection firmly engages polyhedral for example a profile (T) forming a 90° angle.

FIGS. 20, 21, 22, 23 and 24, refer to the elements and/or individual connectors with projection of multiple form section that are associated advantageously with each other to firmly engageable (in the device) any type of structural profile obtained industrially by extrusion and/or means for bending sheet structure.

The system device of FIG. 24 is a device with projection conical or semi-conical section that when connected, connects and engages in it at least two profiles in the preferred embodiment, for example a (T) at 90° as can be seen easily in FIG. 19.

FIGS. 25 to 32 show several embodiments of connectors according to the present invention and uses of the same.

The device of FIG. 27, is a versatile and modular building structure that can be engaged easily and advantageously in combination with the system device of the FIGS. 29 and 28 in a preferred form, not necessarily in a mandatory form, in fact it is possible to get the system device shown in FIG. 25 or 28 as some examples.

In fact, this last device for its special conformation polyhedral thus obtained by the assembly system device of the various types of connectors with projection conical or semi-conical section tapered (FIG. 25) becomes more obvious that in turn binds and integrates in a modular way and perfect the classic reinforcing bars used for in construction with the obvious aim of ensuring advantageously distances of concrete cover from at least 25 mm as reciting the rule Eurocodice 2-8-ASTM international.

It should be clarified that this last device for its special conformation thus obtained by way of its simple and fast in situ assembly the system device of the various types of connectors with projection conical or semi-conical section, which also performs the function of hook perfectly at least inside two panels that form the insulated concrete formwork ICF, this last essential to obtain a whole building structure and/or building envelope in situ from earthquake-proof foundations and zero thermal bridges, as these are encapsulated in a uniform manner.

The system devices and/or connectors with projection conical or semi-conical section shown in FIGS. (30)-(31) and (32) are advantageously molded of different shapes to demonstrate the versatility of the system and are easily associated with the device of FIG. 26.

It can be noted that the device of FIG. 26 is advantageously versatile in addition to being characterized by the steel wire of all closed tangentially to only able to be used in its multiple applications within each system insulated concrete formwork ICF to create an internal set of brackets grid placed in a modular measure, and it goes without saying that once immersed in the concrete becomes a building structure and/or building envelope truly seismic.

That said system device associated with a connector with projection conical or semi-conical section thanks to its modular taper advantageously staying firmly longitudinal and vertical reinforcement bars (FIG. 25) and it goes without saying that by its structural strength thus obtained, being completely closed profile, advantageously replaces the well-known steel bracket that arises containment of steel bars to obtain a conventional a cage armed.

Referring to the Figures, it is possible to note that the connector (1) for the building structure of the invention, made of steel and/or thermoplastics composite with high tensile and torsion strength, has as its general characteristic being of a conical or semi-conical section, with variable geometry.

In one embodiment, the connector (1) for building structure of the invention is composed of a steel bar (6) folded so as to obtain at least a first projection (7) and at least a firs protrusion (9) having lateral section of conical semi-conical and having a first longitudinal extent.

In particular, the inventive connector (1) is equipped with at least one (but preferably two) seat (3) for accommodating at least one reinforcing iron (5).

In one embodiment, the reinforcing iron (5) is positioned in the top of the seat (3) as are shown in FIGS. 16 and 18

In one embodiment, there is more than one reinforced iron (5) positioned in the top of the seat (3) as shown in FIG. 17.

In one embodiment, the reinforcing iron (5) is positioned in the base of the seat (3).

In one embodiment, there is more than one reinforcing iron (5) positioned in the base of the seat (3) as is shown in FIGS. 17 and 18.

In one embodiment, there is at least one reinforcing iron (5) positioned in the top of the seat (3) and at least one reinforcing iron (5) positioned in the base of the seat (3) as is shown in FIGS. 16, 17 and 18.

In one embodiment, the inventive connector presents more than one reinforcing iron (5) from different thickness as is shown in FIG. 17. In one embodiment, the inventive connector presents more than one reinforcing iron (5) that have the same thickness as is shown in FIGS. 16 and 18.

Furthermore, the inventive connector (1) is constituted by a bar (for example of steel) (6) refolded to obtain at least one (and preferably two) first tapered projection (7) of a first extension. Preferably, the inventive connector 1 is then constituted by a steel bar bent so as to obtain at least one (and preferably two) second tapered projection (9) of a second extension, the second extension which is less than the first extension as is shown in FIGS. 5 (9a and 9b).

Furthermore, the inventive connector (1) is equipped with at least one element of quick coupling bayonet (11) for its easy installation in site into the cavity is a(T) of the panel insulator.

With the use of a plurality of such connectors (1) as described above, it is possible to obtain a series of building structures and/or enclosures of anti-seismic construction homogeneous in all partitions.

In one embodiment, the building structure that it is obtained is the structure (12) illustrated in FIG. 3.

This structure (12) is a decorative molding insulation, of the type with continuous skin and homogeneous for a best answer anti-seismic and thermo-acoustic, or the type equipped with special coupling via connectors polypropylene which fit into one another in bayonet fitting to stay firmly and easily open U-brackets structural 14 (FIGS. 14-15, 20-24), wherein these brackets 14 are adapted to be laid through an overlap compulsory, when closed a first bracket 14, with a subsequent bracket 14 which rests from above once positioned the iron bars (5) on the connectors tapered (7,9) steel.

The inventive structure (12) provides that the U-brackets open structural (14), over that of the conventional type indicated above, are produced on an industrial scale, in which these brackets (14) are equipped with a variable bending (Community European-in the rule Eurocodice N° 2-8-ASTM International) which also operates by further containment of the rebar (5) cutlery horizontally from above, before putting the same bracket (14) to closure to form a cage of steel reinforced according to the structural needs.

Moreover, these structural brackets (14) are adapted to be cutlery in an inclined position (FIGS. 3 and 4), preferably at 45°, to respond effectively to shear forces.

Thus, the innovative structure (12) is adapted to be subjected to a system formwork for containment bars armor by means of said special connectors, and of course become a decoration simultaneously, without being propped to support the concrete casting integrative.

FIGS. 8 to 13 are perspective views of the different stages of assembly of the inventive structure (12); in particular, the phases are:

arranging a first constructive element (30) as minimum base, for example in this case of triangular shape (FIG. 8);

joining at least one second construction element (32) to the first construction base element (30): for example, in this case, the union structure generates the shape of a square (FIG. 9);

joining a first construction wall element (34) around the first construction base element (30) (FIG. 10);

joining a second construction wall element (36) around the second construction base element (32) (FIG. 11);

joining a construction cover element (38) above the first and second construction wall elements (34, 36) (FIG. 12); and

joining a third construction wall element (40) above said construction cover element (38) (FIG. 13).

The joining of the third construction wall element (40) above said cover element (38) is an optional embodiment since the present invention is efficient with an embodiment that comprises only the base element (30), the walls elements (34, 36)and the cover element (38).

The system are positioning in situ of the insulating panels modular inventive, acts to form a insulated concrete formwork ICF from the base to achieve a insulating effect of the foundation and/or plinth blocks to our system zero thermal bridges. Moreover, by the fact of not being in direct contact with the ground advantageously does not allow that the humidity goes back by capillarity to the reinforced concrete structural part being this last fully encapsulated and insulated

Integration in the insulated concrete formwork ICF thus obtained with the devices and/or connectors in a conical shape and semi-conical shape shown in FIGS. 30, 31 and 32 are advantageously molded of different form, however, still associated to the device of FIG. 26 or essential elements to form the assembly in FIG. 25 which fit tightly all the reinforcing bars according to the rule—ASTM international—and Community European calculation in Euro Code 2-8.

The insulating base made from modular panel having dovetails in its facades and/or recesses in the male and female heads (30) (12) (32) to pair mutually cut in order to form such a foundation and/or plinth encapsulated thermally via insulated concrete formwork ICF thus obtained variable geometry as can be seen easily in the structures numbers (34) and (36) the latter and the same panel multifaceted coupled mutually to create the vertical side of the formwork concrete insulating ICF.

In addition, the (38) and the same panel multifaceted (30) coupled mutually with others to create the site closure horizontal insulated concrete formwork ICF

The insulating panel modular polyhydric wall (34) is coupled mutually and advantageously for through dovetails to the male and female (30) and, moreover, the same insulating panel.

Also the versatile modular insulating panel of the wall (32) is coupled mutually and advantageously for through dovetail male and female to the insulating base (30) and, moreover, the same insulation panel with the same male and female recesses, or conformation essential for joint mutually one to another with the aim of creating advantageously easily in situ insulated concrete form ICF in zero thermal bridges.

Claims

1. Connector (1) for building structure, characterized in that it is composed of a bar (6) folded so as to obtain at least a first projection (7) and at least a first protrusion (9) having a lateral section of a conical or semi-conical shape and having a first longitudinal extent being that said connector (1) comprises a snap-type bayonet coupling element (11), linked in these structural bracket (14) are adapted to be cutlery in inclined position (2-4) preferably at 45°, to respond effectively to shear force and point loads.

2. Connector (1) according to claim 1, characterized in that the bar (6) is made of steel.

3. Connector (1) according to claim 1, characterized in that the bar (6) is made with thermoplastic composite materials having high tensile and torsion strength.

4. Connector (1) according to claim 1, characterized in that it is equipped with at least one seat (3) or bracket (14) for housing of at least a reinforcing iron (5).

5. Connector (1) according to claim 4, characterized in that comprises more than one reinforcing iron (5) of different thickness.

6. Connector (1) according to claim 4, characterized in that said seats or brackets (3,14) are for housing two reinforcing iron (5).

7. Connector (1) according to claim 1, characterized in that said steel or plastic bar (6) is adapted to be folded so as to obtain at least a second protrusion (9) having a lateral section of a conical or semi-conical shape and having a second longitudinal extension, said second extension being smaller than said first extension.

8. Connector (1) according to any one of the preceding claims, characterized in that snap-type bayonet coupling element (11) comprises a joint system snap, of at least two elements inserted easily into one another and then blocked until it engages the release tab or in other conformations of the connectors b rotation of a quarter turn.

9. Connector (1) according to claims 1 to 8 characterized for being used in building structures as an anti-seismic building structure combining at the same time the thermal resistance, acoustic, or homogeneous in all its partitions, eco-sustainable which allows providing earthquake-resistant foundations with an integral capsule and thermal insulation, monolithic breathable containment walls or bearing walls, acoustic mono-directional and bi-directional roofs and floors with variable geometry; external thermal insulation, composite systems coats, with longitudinal core and acoustic lattice armed concrete structural reinforcement to existing building structures; external thermal insulation system composite coats that are macro- or micro-ventilated, ventilated acoustic roofs in extrados in metal alloys or plastic-composite thermoplastic or polystyrene, and the like, with exclusive breathable characteristics and thermal and acoustic insulation.

10. Building structure (12), characterized for being obtained with a plurality of connectors (1) according to claims 1 to 9.

11. Building structure (12), according to claim 10, wherein the connectors are arranged in a longitudinal manner.

12. Building structure (12), according to claim 10, wherein the connectors are arranged in a transversal manner.

13. Building structures (12), according to claims 11 or 12 wherein the connectors have different folding shape.

14. Building structure (12) according to claim 10, wherein is a decorative cornice insulator, said decorative cornice insulator being preferably of the type with continuous skin and homogeneous.

15. Building structure (12) according to claim 10, wherein is a decorative cornice insulator, said decorative cornice insulator being of the type equipped with special coupling means of connectors in polypropylene which are inserted one into the other bayonet snap firmly and easily to accommodate said open structural seats (3).

16. Building structure (12), according to claim 15, wherein said seats (3) are adapted to be laid by a compulsory overlap, with a subsequent seat (3) which rests from above once positioned the bars (5) on the steel conical connectors (7,9).

17. Building structure (12) according to claim 15 or 16, characterized in that said seats (3) are structurally open and produced at an industrial level, said seats (3) being equipped with a variable bending which also operates as further containment of reinforcement bars (5) horizontally from above, before putting the same seats (3) to closure to form a cage of steel reinforced according to structural needs.

18. Building structure (12) according to claim 15 or 16, characterized in that said structural seats (3) are adapted to be placed in an inclined position, preferably at 45°, to respond to shear forces.

19. Building structure (12) according to claim 15 or 16, characterized in that it is adapted to be subjected to encapsulated decoration and simultaneously, without being propped to support, for each concrete pumping operation.

20. Building structure, according to claims 10 to 19 wherein is an anti-seismic building structure combining at the same time the thermal resistance, acoustic, or homogeneous in all its partitions, eco-sustainable which allows providing earthquake-resistant foundations with an integral capsule and thermal insulation, monolithic breathable containment walls or bearing walls, acoustic mono-directional and bi-directional roofs and floors with variable geometry; external thermal insulation, composite systems coats, with longitudinal core and acoustic lattice armed concrete structural reinforcement to existing building structures; external thermal insulation system composite coats that are macro- or micro-ventilated, ventilated acoustic roofs in extrados in metal alloys or plastic-composite thermoplastic or polystyrene, and the like, with exclusive breathable characteristics and thermal and acoustic insulation.

21. Process for assembling of a building structure comprising a building structure described according to any one of claims 10 to 20, said process comprising the steps of:

i. arranging a first construction element (30) as minimum base;

ii. joining at least one second construction element (32) compatible with the first construction base element (30);

iii. joining a first construction wall element (34) around the first construction base element (30);

iv. joining a second construction wall element (36) around the second construction base element (32);

v. joining a construction cover element (38) above the first and second construction wall elements (34, 36); and

vi.

vii.

22. Process, according to claim 21, wherein optionally comprises a further step of joining a third construction wall element (40) above the construction cover element (38).

23. Process, according to claims 21 and 22, wherein the junction forms described in all the steps are a dovetail male and female.