EA012653B1 - Add-on ventilated facade fastener system - Google Patents

Abstract

The invention relates to an add-on ventilated facade fastener system, comprising the brackets with L-shaped cross-section, comprising a base for fastening on a bearing wall and a carrier placed perpendicularly to the base, the channels with T-shaped cross-section, fixed on a carrier by means of appropriate connectors and the capping for the fastening the covering elements mounted on the guides, as well as the fastening elements. The bracket, connector and channel have a complicated channel shape, characterized in detail in the Claims, and providing conjunction and fixation of the connector in relation to the bracket and of the channel in relation to the connector. The suggested system provides at the minimal steel intensity the higher permissible stresses, increase of a step of the brackets mounting on the bearing walls, and can be used for fastening the different covering elements.

Description

The invention relates to the construction, in particular to the structures of wall structures, and can be used for the device ventilated facades.

Traditionally used multilayer wall structures, including external walling structures of buildings, which include suspended ventilated facades, are subject to a number of requirements that are often impracticable by using only one material (layer):

the actual function of the mechanical separation of the internal and external environment by the base of the wall. Here, a sufficiently high strength should be provided for the perception of external mechanical effects (wind loads), its own weight and the weight of embedded elements (windows, etc.) in the case of a self-supporting wall, and in the case of load-bearing walls and the weight of the overlying structures;

thermal separation function of indoor and outdoor spaces. Here, high thermal resistance to heat transfer should be provided to maintain the required indoor temperature with minimal heat loss in the winter and prevent its increase in the summer. The function is performed, as a rule, by a layer of insulation and partially by an air gap;

vapor permeability function, which allows to remove excess against the norm of water vapor from the room to the outside (the so-called ability to "breathe" walls). For the most efficient removal of moisture from the wall material and insulation, a ventilated air gap is used;

the function of protecting the outer layer of the base material of the wall, the layer of insulation (and, accordingly, the internal environment) from precipitation and other negative environmental influences, causing the destruction of the material of the base of the wall and insulation. It should be provided with high moisture and frost resistance, resistance to aggressive atmospheric substances of industrial origin. It is implemented, as a rule, by the outer facing layer, which is most functional to this adapted, made with respect to the insulation, to create an air gap;

architectural requirements for the appearance of buildings. Satisfied with a large variety of shapes, colors and materials lining;

soundproofing function (protection from external noise in cities). It is provided with the whole construction (largely with a layer of insulation);

Additional specific protective functions that can be performed by a multi-layered enclosing structure - lightning protection and protection from electromagnetic radiation. It is provided with a metal substructure and a suitably selected lining.

Practically, to combine in one material (layer) such diverse and sometimes mutually exclusive functions is either physically impossible or not economically viable. Thus, multilayered enclosing structures were developed, in which each layer or element most optimally performs one or several functions. For example, traditional wall materials, concrete and brick, which perform the first function very well, but poorly meet the requirements of thermal protection due to the relatively high thermal conductivity, which increases when the wall material is moistened due to vapor permeability and atmospheric precipitation. At the same time, a layer of insulation, having a high heat-shielding properties, can not perform the carrier function due to low strength.

As a result, multilayer system structures, the so-called suspended ventilated facades, are used in practice to ensure the effective implementation of all necessary functions by wall structures.

The key point of the systems of mounted ventilated facades is the fastening of the cladding to the wall material at a certain distance, performed using an appropriate fastening system.

The fastening system is usually a profile guide, located, as a rule, vertically and used for fastening cladding. Guides are attached to the wall with brackets. A number of requirements are imposed on fastening systems: minimum weight with sufficient strength and rigidity, corrosion resistance, fire resistance, etc. The important point is also the possibility of adjusting the position of the guides relative to the walls in three directions, compensation for linear temperature deformations of the guides and ease of installation.

For most of the known fastening systems, the presence of a guide and an arm, as well as, if necessary, an adjusting element connecting the arm and the rail, is typical for which a number of requirements are imposed:

the connection of the rail with the bracket should allow adjustment when mounted in three directions, and also compensate for angular distortions;

the joint of the rail with the anchor bracket after adjustment should be fixed, perceiving horizontal wind and vertical loads from the weight of the lining. In addition, in some cases, the connection of the bending moment from the lining weight is required by the connection (with the appropriately chosen computational scheme);

the connection of the guide with the wind bracket after fixing should ensure the vertical movement of the guide from temperature effects and shrinkage processes at the base of the wall and at the same time ensure the perception of horizontal forces from wind loads.

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Taking into account the design features of the fastening system elements, the existing fastening systems can be grouped into the following groups:

1) U-shaped brackets and guides of rectangular or close to them forms (porazny, omega-shaped, etc.), the so-called PP-system;

2) L-shaped brackets and guides of T-shaped and sections approaching T-shaped, so-called T-systems.

The desire to reduce the metal consumption of fastening systems justifies the fairly widespread use of LT-type systems at low and medium loads, at which the T-shaped guide, having a good construction for connecting adjacent elements of the system, has a relatively low weight with sufficient strength and stiffness characteristics, despite that the distribution of material in the T-section is far from optimal (thin-walled rectangular or I-beam). In the known fastening systems, an optimum mounting step is provided for brackets for light and medium types of guides in the range from 1 to 1.5 m (1.2 m on average), at which the guides have a rather low weight and cold bridges due to the brackets are not yet so strong affect heat engineering. Increasing the pitch of the brackets leads to the need for a sharp increase in the weight of the guide with a relatively slight improvement in heat engineering. In addition, when installing a ventilated facade on walls of cellular concrete, the increase in the installation pitch of the brackets is limited by the effort to pull the dowel out of the wall material, and therefore the pitch is usually chosen to be no more than 1.2 m. Reducing the weight of the guide requires reducing the installation pitch of the brackets, and also reducing the weight is hampered by the requirement of keeping the dimensions of the cross section to provide constructive adjacencies to the guide. With an average bracket installation step of 1.2 m and a multi-span design scheme, as a rule, the defining moment is the strength of the guide, characterized by the geometric characteristic of the section, the so-called moment of resistance \ ν.χ.

It should also be noted that for aluminum profiles with a T-section it is necessary to withstand a certain ratio of the height of the profile to the thickness of its wall depending on the actual stresses [1].

Currently, a large number of solutions are known related to the design of ventilated facades and, above all, with the design of fastening systems for hinged panels / blocks that form the facade [2, 3, 4], for which all the above-mentioned remarks on metal consumption, carrying capacity , installation step, etc.

The closest set of essential features to the claimed is the system of attachment of a hinged ventilated facade, proposed by the Russian company Yukon Engineering [5]. This system has become quite widespread, but it also does not resolve the issues of the possibility of reducing the metal content of structural elements while maintaining the permissible loads, as well as increasing the step of mounting brackets.

Thus, the invention is based on the task of developing a universal design of a fastening system for a hinged ventilated facade, which, with minimal metal consumption, would provide an increase in permissible loads, an increase in the installation pitch of the brackets on the load-bearing walls and ensure the possibility of fastening various cladding elements. At the same time, the possibility of adjusting the position of the guides relative to the walls in three directions and the compensation of linear temperature deformations of the guides should be maintained.

The task is solved by the proposed mounting system mounted ventilated facade, including brackets with b-shaped cross-section, containing the base for mounting on the supporting wall and located perpendicular to the base carrier, guide profiles with T-shaped cross-section, mounted on the carrier by means of appropriate connecting elements and mounted on guides cleats for fastening cladding elements, as well as fasteners. The task is solved due to the fact that the connecting element is designed as a profile element, the shape of which is chosen so that its cross section is formed by a linear interaction section with the bracket and an interaction section with a guide profile containing the first sub-section, which is perpendicular to the linear interaction section with the bracket, and the second sub-site, located parallel to the linear part of the interaction with the bracket offset from its longitudinal axis with the opposite on the first sub-section, a connecting groove with a T-shaped cross section is formed on the first sub-section, and in the end area of the second sub-section in the direction opposite to the linear interaction with the bracket, an L-shaped bend is formed, the guide profile is molded in this way that its cross section contains a section of interaction with the connecting element and two sections of shelves located symmetrically relative to the longitudinal axis of the interaction section Via the connecting member, wherein the end portion area of interaction with the connecting element, the opposed portions of the shelves, has a T-shaped cross section, the shelves portions are interconnected to form the mounting groove with a T-shaped cross section forming

- 2,012,653 bottom of the mounting groove wall from the side of the interaction section of the guide profile with the connecting element is provided with L-shaped projections in the direction of the interaction section with the connecting element made in the form of continuation of the sections of the corresponding walls of the installation groove, with the formation of two opposite locking grooves with the L-shaped cross-sectional shape, located symmetrically relative to the longitudinal axis of the section of interaction of the guide profile with the connecting element, at The dimensions of the end zone of the interaction section of the guide profile with the connecting element are selected in accordance with the dimensions of the connecting groove formed in the first sub-section of the connecting element, the shape and dimensions of the interaction area of the guide profile with the connecting element are selected in accordance with the shape and dimensions of the second sub-section of the connecting element, and the dimensions A bent bend made in the end zone of the second sub-section of the connecting element is selected in accordance with the dimensions and the corresponding locking groove guide profile.

In preferred forms of implementation, the middle zone of the area of interaction of the guide profile with the connecting element is made with thickening, while the second sub-section of the connecting element in the zone corresponding to the thickening of the area of interaction of the guide profile with the connecting element has a stepped shape.

Preferred are forms of implementation in which zones are provided on the carrier bracket and on the linear portion of the connecting element, provided with additional fixing elements made in the form of corrugations of the appropriate shape and size, while the means of fastening the connecting element to the bracket include corrugated washers.

Also preferred are forms of implementation in which the end zone of the linear portion of the connecting element is made with a hook-shaped cross-sectional shape.

In addition, the implementation forms are preferred in which on the carrier bracket in the area of its base from the side opposite to the base of the bracket, two L-shaped protrusions are made towards each other with the formation of an additional groove with a T-shaped cross-section, made in the form of a continuation of the base of the bracket, while the bracket is provided with an additional base, made in the form of a removable element containing the base of the removable element and the lock of the removable element, the shape and dimensions which is selected in accordance with the shape and size of the additional groove with the possibility of forming together with the base of the bracket a common base with a linear cross-sectional shape.

As a result of the preliminary calculations and further tests and studies of the proposed fastening system, a special form of the interface of elements was developed. Thus, the proposed form of the guide profile of the T-shaped section, characterized by the above-mentioned features, which, when the efficiency of the cross section is almost doubled compared to the conventional T-section, ensures the engagement along the profile grooves of the connecting element, which also performs the function of adjusting and compensating for thermal deformations. The end zone of the area of interaction of the guide profile with the connecting element, designed in such a way that its shape and dimensions are chosen in accordance with the shape and dimensions of the connecting groove formed on the first sub-section of the connecting element, in other words, performed with a thickening of a certain shape, performs a triple function:

at compressive stresses in extreme fibers from bending, local wall stability is provided in the end zone of the interaction with the connecting element, which allows the entire section to be included in the work (according to the recommendations of the book by EI Belen and NN Streletsky “Metal structures. Special course. Moscow. Build 1982, p. 139);

the thickening in the end zone of the section of interaction with the connecting element leads to a shift of the center of gravity of the section closer to the middle of the section (wall), which increases the moment of resistance Шх. Both factors increase the efficiency of the cross section by almost two times compared with the usual T-profile;

the thickening also performs the function of engagement with the connecting groove formed on the first sub-portion of the connecting element.

The connecting element of the proposed design simultaneously performs the function of the adjusting element. It, as a rule, provides threaded holes for temporarily fixing them in the necessary places on the guide profile for ease of installation, as well as other means (a channel for a self-tapping screw, etc.) to facilitate installation, in particular for holding the guide profile.

The guide profile, due to its characteristics, in particular, bearing capacity and low metal consumption, is universal and can be used in arranging ventilated facades with the use of various types of panels and porcelain tiles as cladding elements.

As mentioned above in the proposed system on the carrier bracket in the area of its base from the side opposite the base of the bracket, two projections of L-shape are made towards each other with the formation of an additional groove with T-shaped transverse

- 3 012653 section, which can be installed additional base for the bracket to increase the bearing capacity of the dowel mount (to install an additional dowel) brackets on the walls of cellular concrete (for such walls are usually calculated dowel to pull out approximately 60 kg). In the implementation forms with an additional base for the bracket, in addition to increasing the carrying capacity by increasing the attachment points, the operation of the dowel attachments also improves by eliminating the asymmetry of the load application. This makes it possible to reduce the number of brackets on the weak bases of the walls as compared to conventional b-brackets, which improves the thermal performance.

Structurally, the proposed brackets are made universal and can be used not only in the proposed systems, but also for mounting the usual T-shaped guide profile in a simplified way. In this case, the perception of horizontal wind loads by a rivet (for fastening a T-shaped guide profile of the usual shape) in a vertical oval hole of the bracket is carried out, for example, through a grooved washer.

The above and other advantages and advantages of the proposed fastening system for a hinged ventilated facade will be discussed in more detail in some preferred, but non-limiting, examples of implementation with reference to the positions of the figures of the drawings, which present:

FIG. 1 is a general view of the assembly of the inventive system (without a clamp and cladding element) in the area of the anchor bracket;

FIG. 2 is a general view of the assembly of the inventive system (without a clamp and cladding element) in the zone of the wind bracket;

FIG. 3 is a schematic depiction of a cross section of individual elements of the inventive system of FIG. one;

FIG. 4 is a schematic depiction of the inventive system with a connecting element in one of the possible positions (in cross section);

FIG. 5 is a schematic depiction of the inventive system with a connecting element in a different position (in cross section).

FIG. 1 shows a general view of the inventive fastening system of a hinged ventilated facade in one of the possible forms of implementation, including brackets 1 (anchor) with an L-shaped cross section and a guide profile 2 with a T-shaped cross section, associated with the bracket 1 by means of a corresponding connecting element 3. The connecting element 3 is fixed relative to the bracket 1 in this form of implementation by means of rivets 4 and corrugated washers 5, and the guide profile 2 is fixed relative to the connecting element ment 3 by means of rivets 6 (for fixing in a vertical position). Holes 7 are provided in the connecting element for mounting a screw for fixing the position of the guide profile 2 and the connecting element 3 for the time of installation. In the bracket 1, oval-shaped holes 8 are provided for mounting dowels 9 for fastening the bracket 1 and, accordingly, the entire system as a whole with respect to the supporting wall. Bracket 1 is also provided with an additional base 10.

FIG. 2 shows a general view of the inventive fastening system of a hinged ventilated facade in the area of the wind bracket 11 with an L-shaped cross-sectional shape, which also includes a guide profile 12 with a T-shaped cross-sectional shape, connected to the bracket 11 by means of a corresponding connecting element 13. As in the described above the case, the connecting element 13 is fixed relative to the bracket 11 by means of rivets 14 and corrugated washers 15, and the guide profile 12 is fixed relative to the connecting element 13 by means of ohm rivets 16. In the connecting element has holes 17 for mounting screws for fixing the position of the guide profile 12 and the connecting element 13 at the time of installation. In the bracket 11, oval-shaped holes 18 are provided for mounting dowels 19 for fastening the bracket 11 and, accordingly, the entire system as a whole with respect to the supporting wall. The bracket 11 is also provided with an additional base 20.

The form of execution of clamps and cladding elements in the context of the inventive system is not significant and will not be considered in detail, as any expert in the field of technology will be able to select the above-mentioned elements whose design will be suitable for installation, in particular, on the proposed guide profile 2. In connection With this, to simplify the graphic materials, the clamp (s) and facing element (s) are not shown in the drawings.

In more detail, the form of execution of each of the essential elements of the inventive system (bracket, connecting element and guide profile) is shown in FIG. 3, a description of which will be given with reference to the positions of FIG. 1, but is also valid for the implementation form in accordance with FIG. 2

Thus, the bracket 1 contains a base 21 for mounting on a carrier wall and a carrier 22 located perpendicular to the base. On the carrier 22 of the bracket 1, an area is provided with additional fixing elements, in this case made in the form of corrugations 23. On the carrier 21 of the bracket 1 in the zone of its base from the side opposite the base of the bracket 1, you

- 4 012653 full two protrusions 24 and 25 L-shaped in direction to each other with the formation of an additional groove 26 with a T-shaped cross-section for installing an additional base 10. The first protrusion 24 is made in the form of continuation of the base 21 of the bracket 1. Additional base 10, made in the form of a removable element, contains the base 27 of the removable element and the latch 28 of the removable element, the shape and dimensions of which are selected in accordance with the shape and dimensions of the additional groove 26 with the possibility of forming a joint with a base common base bracket 21 with the linear cross-sectional shape.

The connecting element 3 is made in the form of a profile element whose shape is chosen in such a way that its cross section is formed by a linear interaction section 29 with a bracket 1 and an interaction section with a guide profile 2 containing the first sub-section 30 located perpendicular to the linear interaction section 29 with a bracket 1, and the second sub-section 31, located parallel to the linear section 29 of interaction with the bracket 1 with an offset relative to its longitudinal axis 32 from the opposite side, refer Before the first sub-site 30, the first sub-site 30 formed a connecting groove 33 with a T-shaped cross section from the second sub-section 31, and in the end zone of the second sub-section 31 in the direction opposite to the linear section 29 of the interaction with the bracket 1, a L-shaped bend 34 was made. On the linear section 29 of the interaction with the bracket 1 on the side of the first sub-site 30 there is a zone provided with additional fixation elements, made in this case in the form of corrugations 35, the shape and size of which are selected in in accordance with the shape and size of the corrugations 23, made on the carrier 22 of the bracket 1, and the corrugations made on the corrugated washers 5. The second sub-section 31 of the connecting element 3 may have a stepped shape. The end zone 36 of the linear section 29 of the connecting element 3 can be made with a hook-shaped cross-sectional shape.

The guide profile 2 is formed in such a way that its cross section contains a section 37 of interaction with the connecting element 3 and two sections 38 and 39 of the shelves arranged symmetrically with respect to the longitudinal axis 40 of the section 37 of interaction with the connecting element 3, with the end zone 41 of the section 37 of the interaction with the connecting element 3, the opposite sections 38 and 39 shelves, has a T-shaped cross-section, sections 38 and 39 shelves are interconnected with the formation of the installation groove 42 with a T-shaped cross The section forming the bottom of the mounting groove wall 43 from the side 37 of the interaction of the guide profile 2 with the connecting element 3 is provided with protrusions 44 and 45 b-shaped in the direction of the section 37 of the interaction with the connecting element 3, made in the form of continuation of the sections of the corresponding walls of the mounting groove 42, with the formation of two opposite locking grooves 46 and 47 with an L-shaped cross-sectional shape, located symmetrically with respect to the longitudinal axis 40 of the section 37 of the guide profile 2 of the interaction Via the connecting member

3. The middle zone of the section 37 of the interaction of the guide profile 2 with the connecting element 3 can be made with a thickening 48.

FIG. 4 and 5 schematically in cross section depicts the inventive fastening system in various forms of implementation, differing in the choice of the position of the connecting element 3 relative to the bracket 1 with the formation of various gaps 1 ₁ and 1b between the facing elements (not shown) and the supporting wall 49.

The installation and operation of the inventive fastening system of a hinged ventilated facade will be described with reference to FIG. 1, 3 and 5.

To enable the installation of the inventive system during manufacturing, it is necessary to observe a number of conditions for matching the sizes and shapes of the mating sections of the various elements of the system.

Thus, in particular, the shape and dimensions of at least the end zone 41 of the section 37 of the interaction of the guide profile 2 with the connecting element 3 and the connecting groove 33 formed in the first sub-section 30 of the connecting element 3;

section 37 of the interaction of the guide profile 2 with the connecting element 3 and the second sub-section 31 of the connecting element 3;

L-shaped bend 34, made in the end zone of the second sub-section 31 of the connecting element 3 and the locking groove 46 or 47 of the guide profile 2;

the middle zone of the section 37 of the interaction of the guide profile 2 with the connecting element 3 - thickening 48 and the corresponding zone of the second sub-section 31 of the connecting element 3;

the latch 28 of the additional base 10 and the additional groove 26, made on the carrier 22 of the bracket 1.

The fastening system is mounted as follows.

On the brackets 1 install additional base 10, for which the latch 28 of the additional base 10 is installed in an additional groove 26, made on the carrier 22 of the bracket 1. The brackets 1 are fixed on the supporting wall in accordance with a given step (vertically and horizontally) by means of dowels 9, installed in holes 8 oval.

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On the guide profiles 2, an appropriate number of connecting elements 3 are installed, for which an end zone 41 of the section 37 of the interaction of the guide profile 2 with the connecting element 3 is placed in the connecting grooves 33 formed in the first sub-sections 30 of each connecting element 3. At the same time, L-shaped bends 34, made in the end zones of the second sub-parts 31 of each connecting element 3, is placed in the locking groove 46 or 47 (for the implementation forms shown on the drawings) of the guide profile 2. Thus Therefore, taking into account the fact that the thickening 48 in the middle zone of the section 37 of the interaction of the guide profile 2 with the connecting element 3 and the corresponding “stepped” zones of the second sub-parts 31 of each connecting element 3 fit end to end, a very strong and reliable structure is formed that can withstand a sufficiently high load.

Each of the connecting elements 3 is temporarily fixed in a predetermined vertical position on the guide profile 2 by means of screws mounted in holes 7 made in the connecting element 3. The design of “guide profile 3 - connecting elements 2” is installed and fixed on brackets 1 as follows. Linear section 29 of each connecting element 3 is aligned with the carrier 22 of the corresponding bracket 1. Depending on the specified installation conditions (design dimensions of the ventilated facade) in the horizontal direction perpendicular to the supporting wall 49, each connecting element 3 extends a predetermined distance 1 (1 ₂ ). Then the connecting elements 3 are rigidly fixed with respect to the corresponding brackets by means of rivets 6 and corrugated washers 5. The presence of corrugations 23 on the carrier 22 of bracket 1, corrugations 35 on the linear section 29 of the connecting element 3, as well as the use of corrugated washers 5 prevents the elements from shifting in different directions. After fixing the connecting elements 3 on the brackets 1, loosen or remove the screws temporarily installed in the holes 7 for fastening the connecting elements 3 on the guide profile 2, carry out the final positioning of the connecting elements 3 and the guide profile 2 and finally fix the guide profile 2 on the connecting elements 3 (rigidly for anchor brackets or with the possibility of vertical movement for wind brackets).

On the guide profiles 2 through clamps install the cladding elements. Depending on the design used clamps for mounting relative to the guide profile can be used installation groove 42.

The proposed design of the mounting system for a ventilated facade mounted in combination with a fairly high installation processability and low metal consumption (low weight) has a very high bearing capacity, reliability and durability, provides the ability to adjust the size of the air gap and can be used with almost any kind of cladding elements.

Literature.

1. E.I. Belen and N.N. Streletsky "Metal constructions. Special course. Moscow: stroiizdat, 1982, p. 139.

2. The system of facade insulation from the outside with a ventilated layer. Wall insulation

The site of OJSC “MAKSMIR” [found 27.04.2006]. Found from the Internet:

1Shr: // \ y \ y \ y.i1sr1tss1.gi / \ ua115_14.111t1.

3. Patent No. 19934451, publ. 31.10.2001.

4. Patent number 0869231 B1, publ. 10/07/1998.

5. I-koi system. Classification of I-koi systems. Systems Ь-147, Т-247. The site of the company Yukon Engineering [found 10.04.2007]. Found from the Internet: yr: //tete.i.kop.gi/gi/rgob / 114/793.

Claims (5)

CLAIM 1. The mounting system of a ventilated facade mounted, including brackets with an L-shaped cross-sectional shape, containing a base for mounting on a bearing wall and a carrier located perpendicular to the base, guide profiles with a T-shaped cross-section, mounted on the carrier by means of corresponding connecting elements and installed on guides clamps for fastening cladding elements, as well as fasteners, characterized in that the connecting element is designed as a profile an element whose shape is chosen in such a way that its cross section is formed by a linear interaction section with a bracket and an interaction section with a guide profile containing the first sub-section located perpendicular to the linear interaction section with the bracket, and the second sub-section located parallel to the linear interaction section with an offset bracket relative to its longitudinal axis from the opposite side relative to the first sub-site, and in the first sub-section from the second th sub-portion is formed with a connecting groove Tobraznym cross-section, and in the end zone of the second sub-portion in a direction opposed to the linear section of interaction with the bracket, configured L-shaped bend, the guide profile is shaped so that its cross section has a portion interacting with Cpd - 6 012653 carrying element and two sections of the shelves located symmetrically relative to the longitudinal axis of the section of interaction with the connecting element, the end zone of the section of interaction with the connecting element opposite to the sections of the shelves has a T-shaped cross-section, the sections of the shelves are interconnected with the formation of the installation groove with a T-shaped cross-section, forming the bottom of the mounting groove wall from the side of the interaction section of the guide profile with the connecting element L-shaped protrusions in the direction of the interaction area with the connecting element, made in the form of continuation of the sections of the corresponding walls of the installation groove, with the formation of two opposite locking grooves with the L-shaped cross-sectional shape located symmetrically relative to the longitudinal axis of the section of the interaction of the guide profile with the connecting element , while the dimensions of the end zone of the area of interaction of the guide profile with the connecting element are selected in accordance with the dimensions of the connecting groove formed on the first sub-section of the connecting element, the shape and dimensions of the area of interaction between the guide profile and the connecting element are selected in accordance with the shape and dimensions of the second sub-section of the connecting element, and the dimensions of the L-shaped bend made in the end zone of the second sub-section of the connecting element, selected in accordance with the dimensions of the corresponding locking groove guide profile. 2. The system according to claim 1, characterized in that the middle zone of the area of interaction of the guide profile with the connecting element is made with thickening, while the second sub-section of the connecting element in the zone corresponding to the thickening of the area of interaction of the guide profile with the connecting element has a stepped shape. 3. System according to any one of claims 1 or 2, characterized in that the carrier bracket and the linear portion of the connecting element are provided with zones provided with additional fixing elements made in the form of corrugations of the appropriate shape and size, with the means of fastening the connecting element to the bracket Includes grooved washers. 4. A system according to any one of claims 1 to 3, characterized in that the end zone of the linear portion of the connecting element is made with a hook-shaped cross-sectional shape. 5. The system according to any one of claims 1 to 4, characterized in that on the carrier bracket in the area of its base from the side opposite to the base of the bracket, two projections of the b-shaped form are made towards each other with the formation of an additional groove with T-shaped cross-sectional shape, with the first protrusion made in the form of continuation of the base of the bracket, while the bracket is provided with an additional base, made in the form of a removable element containing the base of the removable element and the lock of the removable element, the shape and dimensions of which He was chosen in accordance with the shape and size of the additional groove with the possibility of forming, together with the base, a common base bracket with a linear cross-sectional shape.