RU235716U1 - PROFILE FOR INSTALLING AN EXTERNAL ENCLOSING STRUCTURE - Google Patents

Abstract

The utility model relates to the field of construction, in particular to a profile for fastening a facade, which can be used to install/fasten an external enclosing structure, for example, facades with external cladding made of various materials. A profile for installing an external enclosing structure is proposed, including a first part for attaching to a bearing surface for fastening the profile, a second part for supporting the external enclosing structure on it, and connection elements made with the possibility of connecting to the first part and the second part. In this case, there is an indent between the first part and the second part. The technical result of the utility model is to obtain a profile for installing an external enclosing structure with a high load-bearing capacity with reduced material consumption for producing the profile and reduced heat loss in the building on which the profile is installed.

Description

Field of technology

The utility model relates to the field of construction, in particular to a profile for fastening a facade, which can be used for installing/fastening an external enclosing structure, for example, facades with external cladding made of various materials.

State of the art

From the Russian Federation patent for utility model No. 216180, published on 20.01.2023, a profile for fastening a heavy curtain wall is known, including horizontal and vertical edges, characterized in that the profile is made from a sheet by bending and has an L-shape, in the horizontal edge of which cuts are made, into which ribs are inserted, each of which is provided with bends along two of its edges - the lower and vertical, wherein the bend on the lower edge is made with the possibility of holding the horizontal edge of the L-shaped profile from sagging, and the bend on the vertical edge has an opening coinciding with the opening made in the vertical edge of the L-shaped profile, and an anchor for fastening the profile to the supporting base is passed through said openings. A hole is made in the rib for passing reinforcement in order to connect the cladding to the profile and increase reliability.

The disadvantage of this useful model is high thermal conductivity, high consumption of materials for the production of the profile. When the width of the sheet metal blank is not divided without a remainder by the total width of both edges (shelves), strips of metal remain, which go to scrap metal. In addition, through the horizontal edge of the profile, due to its high thermal conductivity, heat losses occur in the building on which the profile is installed.

From the Russian Federation patent for utility model No. 158675, published on 20.01.2016, a masonry support formwork profile is known, which contains perpendicular faces connected by connecting elements, connecting elements passing through through holes made in the connecting elements and the vertical face of the formwork profile. The connecting elements are braces or rods, the horizontally located face of the formwork profile has holes for fastening self-tapping screws or ordinary bolts.

The disadvantage of this useful model is the high consumption of materials for the production of the profile. When the width of the sheet metal blank is not divided without a remainder by the total width of both edges (shelves), strips of metal remain, which go to scrap metal. In addition, through the horizontal edge of the profile, due to its high thermal conductivity, heat losses occur in the building on which the profile is installed.

The closest analogue is the Russian Federation patent for utility model No. 192524, published on September 19, 2019, which describes a supporting formwork thermal profile containing vertical and horizontal faces connected by connecting elements, elements connecting the connecting elements and the vertical face of the formwork thermal profile, while the horizontal face has perforation made along the intersection line of the vertical and horizontal faces of the formwork thermal profile.

The disadvantage of this useful model is the high consumption of materials for the production of the profile. When the width of the sheet metal blank is not divided without a remainder by the total width of both edges (shelves), strips of metal remain, which go to scrap metal. In addition, through the horizontal edge of the profile, due to its high thermal conductivity, heat losses occur in the building on which the profile is installed.

Disclosure of the essence of the utility model

The following terms are used in this application:

"oblong" - having a length greater than its width;

"face" is a surface that forms an angle with another surface;

“connection” – the presence of a detachable or permanent connection that limits the movement of the connected parts relative to each other in any direction (for example, a bolted/anchor connection, engagement, welding, connection as a single unit, and so on);

"connection element" - an element that allows for the creation of a connection, that is, a relationship of mutual dependence, conditionality;

“along” – predominantly in the direction of the long side, while a deviation of 30° from the line parallel to the direction of the long side is allowed;

"indent" is the space between the profile parts.

The technical result of the claimed utility model is the production of a profile for the installation of an external enclosing structure with a high load-bearing capacity with reduced material consumption for the production of the profile and reduced heat loss in the building on which the profile is installed.

To solve the above problem and achieve the technical result, a profile for installing an external enclosing structure is proposed, including

the first part for attachment to the supporting surface for fastening the profile,

the second part for supporting the external enclosing structure,

and communication elements configured to be connected to the first part and the second part,

characterized in that

There is an indent between the first part and the second part.

The connection of the connecting elements with the first and second parts can be carried out both before the installation of the profile to the supporting structure and during installation by any methods known from the prior art, for example, it can be carried out by pressing the connecting element to the surface of each of the parts, for example, with anchor or other connecting elements, by pressing with mortar and brickwork, by engaging with bends on the parts, by engaging grooves on the connecting element with the parts, welding, gluing, as well as combinations of the specified methods.

The indication "connecting elements designed to be connected to the first part and the second part" does not mean that the connecting elements are not connected to the parts when the profile is assembled. This means that the connection to the parts can be detachable or non-detachable. If the connection is detachable, the profile can be assembled at the manufacturing plant, then disassembled for ease of transportation, and then reassembled for installation at the construction site. If the connection is non-detachable, the profile is assembled at the manufacturing plant and is no longer disassembled; it is installed in this form at the construction site.

Separate execution of the first part for connection to the bearing surface for fastening the profile and the second part for supporting the external enclosing structure on it, which are connected by connecting elements with the formation of an indent between them, makes it possible to regulate the width of the platform for installing the external enclosing structure by moving apart/moving the first and second parts and selecting the connecting element of the corresponding width and, accordingly, to ensure obtaining a profile for installing the external enclosing structure with a high bearing capacity with reduced consumption of materials for manufacturing the profile and reduced heat loss in the building on which the profile is installed.

Due to the possibility of adjusting the width of the platform for installing the external enclosing structure by changing the width of the offset, unused strips of standard metal sheets that go to scrap metal are reduced or completely eliminated, while the resulting profile is characterized by high load-bearing capacity due to the fact that the connection elements hold the entire structure together, and the offset is located between the first and second parts, i.e. the edges of the second and first parts, which bear the main load, are connected to the connection elements. In addition, due to the presence of the offset, heat loss through the platform for installing the external enclosing structure in the building on which the profile is installed is reduced.

The above set of essential features is sufficient to achieve the stated technical result.

The characteristics specified below allow the stated technical result to be achieved in the most efficient manner and ensure the production of a profile for the installation of an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for the production of the profile and additionally reduced heat loss in the building on which the profile is installed.

In a preferred embodiment, the indentation width is 1-200 mm, preferably the indentation width is 5-80 mm.

The specified indent width ensures obtaining a profile for installing an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat loss in the building on which the profile is installed. An indent width of 5-80 mm is the most optimal for achieving the stated result.

In the preferred embodiment, the width of the indentation varies in some areas along the length of the profile.

Different widths of the indentation allow making a complex profile contour along its length (tapering at one or two edges, wavy, etc.) and provide a profile for installing an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat loss in the building on which the profile is installed. Manufacturing a profile of a complex and non-standard shape by known methods leads to high material consumption, since unused strips of standard metal sheets remain, which go to scrap metal. The declared profile allows avoiding the said problem.

In a preferred embodiment, the profile is designed in such a way that the width of the indent can be selected to obtain the required width of the platform for installing the external enclosing structure, including the second part and the indent.

This ensures obtaining a profile for installing an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat losses in the building on which the profile is installed. Manufacturing a profile of complex and non-standard shape by known methods leads to high material consumption, since large unused strips of standard metal sheets remain, which go to scrap metal. The declared profile allows avoiding the said problem.

In a preferred embodiment, the first part has a bend at the bottom located at an angle of 80.0-100.0° to the first part, preferably the bend is made in the direction of the second part.

The presence of a bend in the lower part, which is located at an angle of 80.0-100.0° to the first part, creates an additional stiffener and ensures obtaining a profile for installing an external enclosing structure with a high load-bearing capacity with an additionally reduced consumption of materials for manufacturing the profile and additionally reduced heat losses in the building on which the profile is installed. Making a bend in the direction of the second part allows increasing the area of the support platform to increase the load-bearing capacity of the profile with an additionally reduced consumption of materials for manufacturing the profile and additionally reduced heat losses in the building on which the profile is installed.

In a preferred embodiment, the bend has a width of 1-50 mm, preferably 5-45 mm.

The specified bending width is optimal and ensures the production of a profile for the installation of an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for the production of the profile and additionally reduced heat loss in the building on which the profile is installed.

In the preferred embodiment, the first part has a width of 50-250 mm, the second part has a width of 40-200 mm.

The specified width of the first part and the second part is optimal and ensures the production of a profile for the installation of an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for the production of the profile and additionally reduced heat loss in the building on which the profile is installed.

In a preferred embodiment, the first part includes an elongated face and the second part includes an elongated face, said faces being located at an angle of 80.0-100.0° to each other.

The presence in the first part and the second part of elongated edges located at an angle of 80.0-100.0° to each other allows for the formation of a rigid structure of an optimal shape for the installation of an external enclosing structure and ensures the production of a profile for the installation of an external enclosing structure with a high load-bearing capacity with an additionally reduced consumption of materials for the manufacture of the profile and additionally reduced heat losses in the building on which the profile is installed.

In one embodiment, on the outer edge of the second part there is an engagement means, preferably a bend, and the connecting element has a protrusion made with the possibility of at least partially entering the said engagement means.

The outer edge (free edge, edge farthest from the fold) of the second part is understood to be the edge of the second part that is furthest away from the first part.

The bend on the outer edge of the second part, into which the said projection at least partially enters, ensures obtaining a profile for installing an external enclosing structure with a high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat losses in the building on which the profile is installed.

When laid on a brickwork profile, the bend ensures reliable fixation (clamping) of the projection of the connecting element with the second part, thus the connecting element and, accordingly, the entire profile can withstand higher tensile loads and hold a greater weight of the masonry.

In addition, the bend prevents the mortar from leaking and allows the fastening of the external enclosing structure to comply with the requirements of the design documentation, and the bend also creates a stiffening rib for the second part and makes it more resistant to deformation.

In another embodiment, on the outer edge of the first face there is an engagement means, preferably a bend, and the connecting element has a projection made with the possibility of at least partially entering the said engagement means.

The outer edge (free edge, edge farthest from the fold) of the first part is understood to be the edge of the first part that is furthest away from the second part.

The bend on the outer edge of the second part, into which the said projection at least partially enters, ensures obtaining a profile for installing an external enclosing structure with a high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat losses in the building on which the profile is installed.

In addition, when laying on a brickwork profile, the bend ensures reliable fixation (clamping) of the projection of the connecting element with the first part, thus the connecting element and, accordingly, the entire profile can withstand higher tensile loads and hold a greater weight of the masonry, and the bend also creates a stiffening rib for the first part and makes it more resistant to deformation.

In another embodiment, the connecting element has a groove for inserting the second part into it.

The specified groove does not require additional material consumption for connecting the connecting element to the second part, while it ensures obtaining a profile for installing an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat losses in the building on which the profile is installed.

In a preferred embodiment, the connecting element is made from a single piece and is a stiffening rib, a support rib, an angle element, a brace or a rod.

The production of a connection element from a single part ensures the production of a profile for the installation of an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for the production of the profile and additionally reduced heat loss in the building on which the profile is installed.

In a preferred embodiment, the connecting element has a means for attaching to the first part and a means for attaching to the second part, which are bends from the plane of the connecting element.

The presence of bends on the connecting element, which perform the function of a means of attachment to the first and second parts, due to the creation of stiffening ribs increases the load-bearing capacity of the connecting element, accordingly, the entire profile can withstand higher tensile loads and hold a greater weight of the masonry, which ensures the production of a profile for the installation of an external enclosing structure with a high load-bearing capacity with an additionally reduced consumption of materials for the manufacture of the profile and additionally reduced heat losses in the building on which the profile is installed.

In a preferred embodiment, the coupling element has an opening configured to at least partially align with the opening in the first part.

The presence of the specified pre-made holes in the connection element and the first face allows the anchor element (or other connecting element) to be passed through them for fastening to the interfloor ceiling, and also to avoid making holes on site and the corresponding possible deformations, which ensures obtaining a profile for installing an external enclosing structure with a high load-bearing capacity with additionally reduced material consumption for the production of the profile and additionally reduced heat losses in the building on which the profile is installed.

In a preferred embodiment, the connecting elements are located at a distance of 40-1000 mm from each other, preferably at a distance of 50-800 mm from each other, more preferably at a distance of 100-500 mm from each other.

In a preferred embodiment, the first part has openings that are designed to at least partially align with the openings in the connecting elements, wherein the openings in the first part are located at a distance of 40-1000 mm from each other, preferably at a distance of 50-800 mm from each other, more preferably at a distance of 100-500 mm from each other.

The closer the value of the distance between the holes in the first edge to the interval of 100-500 mm, the better the conditions for maintaining the integrity of the profile and the sufficiency of the holes for holding the profile in the place of fastening. This ensures obtaining a profile for installing an external enclosing structure with a high load-bearing capacity with an additionally reduced consumption of materials for the manufacture of the profile and additionally reduced heat losses in the building on which the profile is installed.

In a preferred embodiment, the profile is a profile used as part of the formwork or a profile installed on a finished surface.

The above-mentioned methods of fastening the profile are the most optimal in terms of the profile's load-bearing capacity and the ease of its installation, which ensures that a profile is obtained for installing an external enclosing structure with a high load-bearing capacity with an additionally reduced consumption of materials for the production of the profile and additionally reduced heat loss in the building on which the profile is installed.

Brief description of the drawings

The drawings are presented for a better understanding of the utility model, however, it will be obvious to a specialist in this field of technology that the disclosed utility model is not limited to the variant shown in them.

Fig. 1 shows a schematic front view of the claimed profile.

Fig. 2 shows a schematic sectional view along line 1-1 of the claimed profile.

Fig. 3, 4 shows a schematic volumetric view of the declared profile assembled according to the best option.

Fig. 5 shows a schematic three-dimensional exploded view of the claimed profile.

Fig. 6 shows an enlarged image of the first face.

Fig. 7 shows an enlarged image of the second face.

Fig. 8 shows a three-dimensional view of the communication element.

Fig. 9, 10, 11 shows a schematic volumetric view of an alternative assembly of the claimed profile.

Implementation of a utility model

The described examples of implementation are given solely for illustrative purposes. It will be obvious to a specialist that other implementation options are possible without changing the essence of the utility model.

The figures show a profile for fastening an external enclosing structure, including a first part 1 connected to each other for joining to a supporting surface for fastening the profile, a second part 2 for supporting the external enclosing structure on it, and a connecting element 3.

The coupling element 3 has a means of connection 3a to the first part 1 and a means of connection 3b to the second part 2.

The means for connecting 3a to the first part 1 is a bend from the plane of the connecting element 3 with a projection 3a ₁ and an opening 11 for inserting a connecting element connecting the connecting element 3 to the first part 1.

The means of connection 3b to the second part 2 is a bend from the plane of the connecting element 3 with a projection 3b ₁ and an opening 10 for inserting a connecting element connecting the profile with the lower formwork in the case of using the profile as a formwork, i.e. using it as a formwork wall for pouring concrete for an interfloor ceiling.

The first part 1 has a section 1a for connection to the supporting surface to which the profile will be attached (the end surface of the interfloor ceiling, a wall, etc.), as well as a bend 1b in the lower part, which is a stiffening rib and is located at an angle A1 to section 1a.

Angle A1 is also the angle at which section 1a of the first part 1 and the second part 2 are located in relation to each other.

Section 1a for connection to the bearing surface has openings 11a, the distance between adjacent openings 11a is S, and the distance from the edge of the profile to the nearest opening 11a is a.

Also the first part 1 has a means 12 for engaging with the projection 3a ₁ .

The second part 2 has a surface 2a for supporting an external enclosing structure (in particular containing mortar and bricks).

Also, the second part 2 has a means 22 for engaging with the protrusion 3b ₁ .

In a particular embodiment, the means of connection 3a and 3b have projections 3a ₁ and 3b ₁ , which, respectively, are inserted into the means of engagement 12, 22 of the first part 1 and the second part 2, which are bends.

Section 1a of the first part 1 has a width H, bend 1b of the first part 1 has a width B1b.

Surface 2a of the second part 2 has width B2.

When the profile is assembled between the second part 2 and the first part 1 there is an indent 9, the width of which is Bо, and the width of the platform for installing the external enclosing structure is B.

The profile length is L.

Options for profile assembly at the manufacturing plant:

The width B of the platform for installing the external enclosing structure is adjusted by changing the width Bо of the indent 9.

Assembly option 1. Connecting element 3 is spot welded to the first 1 and second 2 parts.

Assembly variant 2. The connecting element 3 is connected to the second part 2 by inserting the projection 3b ₁ into the bend 22. The connecting element 3 is connected to the first part 1 by means of a bolted (anchor) connection passing through the opening 11, made with the possibility of at least partial alignment with the opening 11a in the first part 1.

Assembly variant 3. Connecting element 3 is connected to the second part 2 by inserting protrusion 3b ₁ into bend 22. Connecting element 3 is connected to the first part 1 by inserting protrusion 3a ₁ into bend 12.

Assembly option 4. The connecting element 3 is connected to the second part 2 by inserting it into the groove 3d of the connecting element 3 in such a way that the second part 2 rests on the connecting element 3.

The connecting element 3 is connected to the first part 1 by means of a bolted (anchor) connection passing through an opening 11, made with the possibility of at least partial alignment with the opening 11a in the first part 1.

Assembly option 5. Connecting element 3 is connected to the second part 2 by inserting it into the cutout 3d in such a way that the second part 2 rests on connecting element 3. Connecting element 3 is spot welded to the first part 1.

Assembly option 6. Connecting element 4 is connected to the second part 2 and the first part 1 by means of adhesive bonding.

There may be other options for assembling the declared profile.

The profile may be a profile used as part of the formwork, or the profile may be a profile installed on a finished surface.

The profile works as follows.

When installing the profile on a finished interfloor ceiling, surface 1a of the first part 1 is fastened to the supporting structure (e.g., interfloor ceiling) using fastening means known from the prior art (drive-in anchors, wedge anchors, screw anchors, rod anchors, embedded anchors, etc.). Then, facing brick is placed on surface 2a of the second part 2.

When installing a profile as part of the formwork, first the second part 2 of the profile (support face, bearing face) is temporarily fastened to the lower part of the formwork using connecting elements (self-tapping screws or regular bolts) through holes 10, which can be made of a sheet of plywood or other sheet material.

Surface 1a of the first part 1 of the profile is used as one of the walls of the formwork (form, container) for pouring concrete that forms the interfloor ceiling.

The reinforcement frame is placed into the formwork and concrete is poured.

Using connection elements (embedded anchors, anchor bolts), the first part 1 is attached to the floor slab. In this case, the connection elements are monolithically embedded in the slab structure after pouring the concrete mixture and ensure the profile is fixed.

After the concrete has acquired the required strength, the connecting elements that temporarily attached the second part 2 to the lower part of the formwork are removed.

The profile is attached to the concrete floor, with the first part 1 and the second part 2 forming a corner into which the facing material is laid, after which horizontal expansion joints are made.

The specified method of fastening (as part of the formwork) is preferable, since it provides a higher load-bearing capacity of the profile, since the profile in this case fits most tightly to the interfloor ceiling, regardless of the curvature of the interfloor ceiling.

Brick, natural and/or artificial stone, cement and/or ceramic blocks, glass blocks can be used as facing materials.

The claimed technical solution ensures the production of a profile for the installation of an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for the production of the profile and additionally reduced heat loss in the building on which the profile is installed.

Table 1. Profile parameters

Profile settings Prototype (RU 192524) Options for the declared technical solution 1 2 3 4 5 6 7 8 9 (variable platform width) Part One 1a                   Plot 1a                   width H, mm 200 200 200 200 200 200 200 200 200 length L, mm 2500 2500 2500 2500 2500 2500 2500 2500 2500 Bend 1b                   width B1b, mm 0 0 0 30 0 45 0 12.5 0 length L, mm 0 0 0 2500 2500 2500 2500 2500 2500 Bend 12                   width W12, mm 12.5 12.5 12.5 12.5 12.5 12.5 5 15 5 length L, mm 2500 2500 2500 2500 2500 2500 2500 2500 2500 Part 2 2                   width B2, mm 100 120 140 50 80 40 40 70 40 length L, mm 2500 2500 2500 2500 2500 2500 2500 2500 2500 Bend 22                   width W22, mm 12.5 12.5 12.5 12.5 12.5 12.5 5 15 5 length L, mm 2500 2500 2500 2500 2500 2500 2500 2500 2500 Indent 9                   width Bo, mm 0 0 0 20 40 55 60 57.5 60 length L, mm 0 0 0 2500 2500 2500 2500 2500 2500 Width B of the platform for installation of the external enclosing structure 100 120 140 100 120 140 100 140 from one edge 100 mm from the other edge 120 mm Unfolding of a solid part, total width (sum of H+B1b+W12+B2+W22+Bo), mm 325 345 365 325 345 365 310 370 310 Material consumption for manufacturing a part (sum of H+B1b+W12+B2+W22), mm 325 345 365 305 305 310 250 312.5 250 The result of dividing the standard sheet width of 1250 mm by the material consumption 3.85 3.62 3.42 4.10 4.10 4.03 5.00 4.00 5.00 The number of solid parts made from sheet metal with dimensions of 1250×2500 mm (1250 mm divided by material consumption and rounded down to the next whole number) 3.00 3.00 3.00 4.00 4.00 4.00 5.00 4.00 5.00 Metal waste from a sheet with dimensions of 1250×2500mm along a side of 2500 mm, mm 275,00 215,00 155,00 30,00 30,00 10.00 0,00 0,00 0,00 General information about the profile design                   Load-bearing capacity of the profile (maximum stress in the beam rib with a masonry thickness of 120 mm and a height of 4.2 m), N/ ^mm2 (maximum standard 230 N/ ^mm2 ) 47.3 47.3 47.3 47.3 47.3 47.3 47.3 47.3 47.3 Thermal resistance R, ^m2 *degree C/W (the higher the R number, the better the energy saving performance) 0.6 0.6 0.6 0.65 0.65 0.65 0.65 0.65 0.65

As can be seen from the table, in the prototype from a standard sheet (dimensions 1250×2500 mm) a maximum of 3 profiles are obtained, and 155-275 mm from each sheet goes to waste, and according to the declared technical solution, 4, 5 profiles are obtained with zero or minimal metal waste while maintaining the load-bearing capacity of the profile and reduced heat loss in the building.

Thus, the utility model ensures obtaining a profile for installing an external enclosing structure with high load-bearing capacity with additionally reduced material consumption for manufacturing the profile and additionally reduced heat loss in the building on which the profile is installed.

Claims (17)

1. A profile for installing an external enclosing structure, including a first part for attaching to a supporting surface for fastening the profile, a second part for supporting the external enclosing structure on it, and connecting elements connecting the first part and the second part, characterized in that there is an indentation between the first part and the second part. 2. The profile according to item 1, characterized in that the width of the indent is 1-200 mm, preferably the width of the indent is 5-80 mm. 3. The profile according to item 1, characterized in that the width of the indentation varies in some areas along the length of the profile. 4. The profile according to paragraph 1, characterized in that the profile is made in such a way that the width of the indent is selected to obtain the required width of the platform for installing the external enclosing structure, including the second part and the indent. 5. The profile according to item 1, characterized in that the first part in the lower part has a bend located at an angle of 80.0-100.0° to the first part, preferably the bend is made in the direction of the second part. 6. The profile according to item 5, characterized in that the bend has a width of 1-50 mm, preferably 5-45 mm. 7. The profile according to item 1, characterized in that the first part has a width of 50-250 mm, the second part has a width of 40-200 mm. 8. The profile according to item 1, characterized in that the first part includes an elongated edge and the second part includes an elongated edge, said edges being located at an angle of 80.0-100.0° to each other. 9. The profile according to claim 1, characterized in that on the outer edge of the second part there is a means of engagement, preferably a bend, and the connecting element has a protrusion made with the possibility of at least partially entering the said means of engagement. 10. The profile according to claim 1, characterized in that on the outer edge of the first face there is a means of engagement, preferably a bend, and the connecting element has a protrusion made with the possibility of at least partially entering the said means of engagement. 11. The profile according to item 1, characterized in that the connecting element has a groove for inserting the second part into it, wherein the connecting element is connected to the second part by inserting it into the groove of the connecting element. 12. The profile according to item 1, characterized in that the connecting element is made from a single part and is a stiffening rib, a support rib, a corner element, a brace or a rod. 13. The profile according to item 1, characterized in that the connecting element has a means of attachment to the first part and a means of attachment to the second part, which are bends from the plane of the connecting element. 14. The profile according to claim 1, characterized in that the connecting element has an opening at least partially aligned with the opening in the first part. 15. The profile according to item 1, characterized in that the connecting elements are placed at a distance of 40-1000 mm from each other, preferably at a distance of 50-800 mm from each other, more preferably at a distance of 100-500 mm from each other. 16. The profile according to claim 1, characterized in that the first part has openings made at least partially aligned with the openings in the connecting elements, wherein the openings in the first part are located at a distance of 40-1000 mm from each other, preferably at a distance of 50-800 mm from each other, more preferably at a distance of 100-500 mm from each other. 17. The profile according to item 1, characterized in that the profile is a profile used as part of the formwork, or a profile installed on a finished surface.