EA025877B1 - Multi-layer wall structure - Google Patents

Abstract

The invention is related to civil engineering and can be used in erection of new buildings with ventilated facades preferably built concurrently with erection of load-bearing walls. The invention provides a multi-layer wall structure comprising a load-bearing structure with a main support wall consisting of plurality of construction elements and plurality of external cladding elements linked to the load-bearing structure elements by means of fixing means. The external cladding elements are made as blocks having a shape of a rectangular parallelepiped with at least one dovetail slot. Linked to load-bearing structure elements are not all but individual external cladding elements disposed at a preset pitch in the vertical and horizontal directions. The fixing means for the external cladding elements are made in the form of horizontal flexible ties having one end fixed relative to an external cladding element and the other end fixed relative to the respective element of the load-bearing structure. The external cladding elements are disposed with shifting in the horizontal direction relative to respective external cladding elements of adjacent horizontal rows so that plurality of vertical channels is formed by angle zones of dovetail slots of respective sequentially vertically adjacent external cladding elements of all horizontal rows in a definite zone of the facade. Reinforcement bars are installed in at least a part of the vertical channels, the reinforcement bars being joined by an adhesive means with angle zones of respective external cladding elements.

Description

The invention relates to construction and can be used in the construction of new buildings with ventilated facades, preferably equipped in parallel with the construction of load-bearing walls.

Currently, a large number of solutions are known related to the construction of walls of a multilayer structure, ventilated facades, as well as external cladding elements made of various materials (metal, plastic, ceramics, etc.) and having various shapes and structures, including layered. Multilayer wall structures, in which mandatory fixing of each cladding element with appropriate fastening means (screws, screws, etc.) and special holders / clamps on brackets of a special design, which, in turn, are fixed in relation to the supporting wall, are more widely used. . Thus, a multilayer wall structure in the form of a system of insulated ventilated facade [1] is known, containing a support structure formed by brackets, vertical supporting profiles, fixing the brackets to the wall and fixing the brackets to the vertical bearing profiles, a layer of thermal insulation elements attached to the wall in the gaps between the brackets and cladding of metal elements mounted on vertical bearing profiles with a ventilated gap relative to the layer of insulation elements. The system, in addition, is equipped with combs having sections in the form of L-shaped hooks, while the metal elements are made with elongated L-shaped and / or I-shaped butt edges, having dimensions for pairing with L-shaped hooks and forming a labyrinth pair on the junction of adjacent metal elements, and each comb is mounted on a vertical supporting profile with a vertical arrangement of sections in the form of L-shaped hooks. The technical result indicated in the patent is to simplify the installation technology while ensuring the required strength and quality of finish. However, taking into account the number of elements, as well as the complexity of their geometric shape, which leads to complication of their production technology, a significant simplification of the technology cannot be achieved. In the General case, the disadvantage of the known designs of ventilated facades of this type is their rather high complexity and high complexity of installation, which significantly increases the cost of construction work and the total cost of buildings.

The authors previously proposed an original construction of a building block [2], made preferably of vibro-pressed concrete, the use of which when arranging ventilated facades at any stage ensures the achievement of all the above technical results. The said block is made in the form of a rectangular parallelepiped, on the back face of which a vertical groove of depth B is made along the entire height of the block, whose side surfaces are located at an angle α to the bottom surface and form a dovetail in cross section. Dimensions of the unit, in particular the length L _p of the bottom surface of the groove and the length L _{1> 2} parts of the rear faces on both sides of the groove are interconnected certain ratio. In combination with the simplicity, manufacturability and relatively low price of the mentioned building block, the indicated technical results achieved during the implementation of the invention become even more significant. Various variants of wall structures with a ventilated facade using such a block and methods for erecting wall structures were also proposed [3]. In particular, a multilayer wall structure was proposed comprising a main supporting wall and external cladding elements connected to the supporting wall by fastening means and forming a facade located with an air gap in relation to the supporting wall, and, if necessary, a thermal insulation layer placed between the supporting wall and facade. In this design, the outer cladding element is made in the form of the block described above, and the fastening means are made in the form of a plurality of interconnected fastening elements to the supporting wall and mating elements in at least part of the area with the side surfaces of the groove of the outer cladding element. Despite the advantages of such a multilayer wall structure in comparison with other structures of the prior art, it is difficult to perform in parallel mode, i.e. the simultaneous erection of the supporting wall and the installation of the outer cladding elements.

Other building blocks are also known in the art, in particular cladding blocks / panels (external cladding elements) based on the shape of a parallelepiped and which are provided with grooves of various shapes, including a dovetail, as well as corresponding multilayer wall structures.

Thus, a wall structure is known in which the outer cladding element is made in the form of a block in the shape of a variable width with zigzag side walls forming a double dovetail (two dovetail shaped consecutively located along the depth of the groove) [4]. To fix each such block with respect to the supporting wall, a special U-shaped fixing element with free ends fixed at an acute angle bent outward is provided. The fastener is fastened with threaded fasteners to the supporting wall, and the block is fixed to the fastener by snapping the ends of the clips into the groove of the double dovetail. A significant drawback of this design is its complexity and inseparability, because it is practically impossible to remove a separate block from the fastener (except for the extreme blocks only).

Also known is a multilayer wall structure in which the elements of the outer cladding are also made in the form of a block in the form of a variable width in the form of a dovetail or other similar shape [5]. In such a multilayer wall construction, a special layer is provided for fixing the blocks on the supporting wall - a panel with fixing protrusions, the shape of which corresponds to the shape of a groove fragment in the area of one of the side walls. Thus, the block, in fact, is simply hung on this panel, which cannot provide high reliability of the cladding as a whole and requires a special design of the supporting wall.

According to the totality of common technical features, the aforementioned multilayer wall structure [3] can be adopted as a prototype for the inventive multilayer wall structure. Said multilayer wall structure comprises a main supporting wall of a plurality of building elements, including at least masonry elements and horizontal lintels connected to the foundation and with horizontal floor elements to form a supporting structure, a plurality of external cladding elements associated with the supporting structure elements by means fastenings with the formation of a facade located with an air gap in relation to the supporting wall, and, if necessary, a layer of thermal insulation, ra displacements between the support wall and the facade. At the same time, the elements of the external cladding are made in the form of ordinary blocks in the form of a rectangular parallelepiped, on the back face of which at least one groove is made along the entire height of the block, the side surfaces of which are located at equal angles α and β to the bottom surface and form a dovetail in a horizontal section . As already mentioned above, such a multilayer wall construction is only erected in stages: first, the supporting wall is erected, and then, with various fastening elements, the elements of the outer lining are mounted on it. In addition, given that metal fasteners are used for installation, the cost of such wall structures still remains quite high.

Thus, the object of the invention is the creation of a multilayer wall structure, which, combined with the maximum simplicity of each element separately and the structure as a whole, would have even lower cost, higher manufacturability and would provide the possibility of installing a ventilated facade in parallel with the construction of the main supporting wall. In addition, the proposed multilayer wall structure should provide a significant reduction in the time of its construction, including the external cladding, as well as almost complete safety (eliminating the possibility of falling elements of the external cladding or their fragments due to damage / destruction.

The problem is solved by a multilayer wall structure containing a main supporting wall of a variety of building elements, including at least masonry elements and horizontal lintels connected with the foundation and with horizontal floor elements with the formation of the supporting structure, many external cladding elements associated with the supporting elements constructions by means of fasteners with the formation of a facade located with an air gap in relation to the supporting wall, and, if necessary, a thermal insulation layer placed between the supporting wall and the facade. The elements of the external cladding are made in the form of blocks in the form of a rectangular parallelepiped, on the back edge of which along the entire height of the block at least one groove is made, the side surfaces of which are located at angles α and β to the bottom surface and form a dovetail in a horizontal section. the problem is solved due to the fact that individual elements of the external cladding are located with elements of the supporting structure, located at a given step in the vertical and horizontal direction. In this case, the means of fastening the elements of the external cladding are made in the form of horizontal flexible connections, each of which is fixed at one of its ends with respect to the element of the external cladding, and with the second end with respect to the corresponding element of the supporting structure. The elements of the outer lining of each horizontal row are offset horizontally relative to the corresponding elements of the outer lining of adjacent horizontal rows, so that the corner zones of the grooves dovetail of the corresponding successively adjacent vertically adjacent elements of the outer lining of all horizontal rows forming the facade area between the horizontal elements supporting structure, including horizontal lintels, elements of horizontal overlap and foundations , A plurality of vertical channels is formed, at least part of which is fitted the reinforcing bars, the length of each of which corresponds to the height of said facade zone. In this case, the reinforcing bars are arranged with a step that ensures the fixation of the position of each element of the outer cladding in at least one corner zone of at least one groove dovetail and are connected with the outer cladding element in the specified corner zone by adhesive. The adjacent elements of the outer cladding are interconnected by adhesive, at least from their horizontal surfaces.

In the proposed multilayer wall structure, the number of fastening elements is significantly reduced, since the need to fasten each element of the outer lining is eliminated.

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At the same time, the reliability of the structure is increased due to the fact that due to the horizontal directional displacement of the outer cladding elements in adjacent rows in the vertical direction, channels are formed, when placed in the reinforcing bars, a kind of lock connection is created.

All this leads to a significant simplification of the claimed multilayer wall structure and lower its total cost, including the cost of construction and installation works.

In various forms of implementing the inventive multilayer wall structure, a wide variety of suitable horizontal flexible connections known to those skilled in the art can be used. In preferred embodiments, the horizontal flexible bond can be selected from the group comprising at least polymer flexible bonds, flexible bonds from composite materials, metal U-shaped wire staples, metal anchor plates, metal strips, including perforated. In this case, horizontal connections, flexible connections are preferably installed based on four connections per 1 m ^{2 of} facade.

In those forms of implementation in which the horizontal flexible connection is made in the form of a metal strip or anchor plate, it can be additionally connected with a reinforcing bar.

In preferred embodiments of the inventive multilayer wall structure, the reinforcing bars can be made of a composite material containing a filler selected from the group comprising at least glass fiber and basalt. The use of composite material provides a number of advantages compared to metals: reducing the total mass of the structure, reducing cost, increasing durability, because Corrosion processes that damage valves in traditional structures are excluded. At the same time, the strength remains at a high level, ensuring high reliability of the entire multilayer wall structure as a whole.

To further increase the reliability of the multilayer wall structure in some preferred forms of implementation, the ends of the floor elements from the facade can be equipped with profile protrusions, the shape, size and location of which are selected with the possibility of fixing external cladding elements on them with an end-to-end arrangement with respect to each other. This, as a rule, is achieved due to the fact that with already installed elements of the external cladding, the binder (concrete) is poured at the level of overlap, which, when solidified, forms the above-mentioned protrusions.

In various preferred embodiments of the inventive multilayer wall structure, thermal liners may be provided in the floor elements, which improves the performance of the building.

To prevent the ingress of moisture (precipitation) between the main supporting wall and the facade of the outer cladding elements between the two horizontal rows of the outer cladding elements in the area of horizontal lintels and / or in the area of the ceiling elements can be installed.

To ensure air exchange in the space between the main supporting wall and the facade of the external cladding elements between two horizontal rows of external cladding elements in the zone of the floor elements and / or in the extreme horizontal row from the basement and / or horizontal bridge, ventilation openings can be provided for forming a floor and / or zone ventilation system.

To ensure the reliability (stability) of the facade from the elements of the external cladding, the lower horizontal row of elements of the external cladding of each zone of the facade can preferably be based on the corresponding element of the supporting structure selected from the group including, foundation, horizontal overlap element, horizontal bridge.

In the most preferred general case, the outer cladding element is symmetrical, i.e. α = β. This form of execution is the most technologically advanced from all points of view - both in the manufacture of elements of the external cladding and in the arrangement of the facade. Moreover, the outer cladding element may contain two or more dovetail grooves. In this case, the dimensions and location of the grooves are selected so that the condition of the possibility of forming through vertical channels when displacing the elements of the outer lining in adjacent rows is fulfilled.

As noted above, the versatility of the proposed multilayer wall structure provides ample opportunity to choose fasteners, flexible joints and other structural elements. Using the elements of the external cladding of the above form, depending on the form of the front surface of the blocks, you can get facades with various decorative finishes (textures), including combined, as well as various, including combined, color schemes. Due to their properties, the external cladding elements are not significantly affected by harmful environmental factors, have very high durability and, in fact, do not require restoration, repair, including those associated with the restoration of paint or protective layers, which is typical for known cladding panels, or other maintenance work. Even if there is a cracked element in the finish, the falling out of its parts from the wall lining layer is prevented by the volumetric nature of the cracks: in order to fall out, a fragment of the block must move the adjacent one, which is practically eliminated by the lining design itself.

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Due to the above-mentioned features of the implementation of the fastening elements to the supporting wall in the form of horizontal flexible connections in the inventive multilayer wall structure, it is possible to fasten them between vertically adjacent layers / elements of the supporting wall / supporting structure. This ensures parallelism in the processes of erecting a supporting wall and simultaneous installation of the facade from the elements of the external cladding with the fastening of horizontal flexible connections at a predetermined level between vertically adjacent layers / elements of the supporting wall / supporting structure.

It should also be noted that in the framework of this invention, the term flexible connection does not mean that the fastener has some high elasticity properties. In this case, this term means that the fastening elements in the form of horizontal flexible connections are able to compensate for various deformations (temperature, from horizontal and / or wind loads, etc.) and, as a result, mutual shifts of the main supporting structure and the facade of the elements external cladding while maintaining the strength and integrity of both the facade and the multilayer wall structure as a whole.

To illustrate the advantages and advantages of the claimed invention, a number of examples of the implementation of a multilayer wall structure will be given below, taking into account various forms of horizontal flexible connections. Examples will be illustrated by drawings and, if necessary, accompanied by a more detailed description with reference to the position of the drawings. At the same time, both the graphic image and the text description of the examples should be considered as explanatory, but not limiting the scope of claims.

The drawings schematically show:

FIG. 1 is a general view of a fragment of a multilayer wall structure with a supporting structure of building blocks and horizontal flexible connections of composite material;

FIG. 2 is a plan view of the multilayer wall structure of FIG. 1 in the area of the installation of flexible communications made of composite material;

FIG. 3 is a general view of a fragment of a multilayer wall structure with a supporting structure of building blocks and horizontal flexible connections in the form of metal anchor plates;

FIG. 4 is a plan view of the multilayer wall structure of FIG. 3 in the installation area of the metal anchor plates;

FIG. 5 is a general view of a fragment of a multilayer wall structure with a supporting structure of building blocks and horizontal flexible connections in the form of a metal perforated strip;

FIG. 6 is a plan view of the multilayer wall structure of FIG. 5 in the installation area of the metal perforated strip;

FIG. 7 is a general view of a fragment of a separately mounted facade;

FIG. 8 is a general view of a fragment of a multilayer wall structure in one of the forms of implementation.

In FIG. 1 schematically shows a general view of a fragment of a multilayer wall structure with a supporting structure of building blocks and horizontal flexible connections of composite material, and in FIG. 2 is a top view of such a multilayer wall structure in the area of the installation of flexible communications made of composite material. In the drawings, in particular, a main supporting wall of a plurality of building elements — wall blocks 1 and a plurality of external cladding elements of cladding blocks 2 connected with structural elements by means of fastening means with forming a facade located with an air gap in relation to the supporting wall are shown. The facing blocks 2 are made in the form of a rectangular parallelepiped, on the back face of which, along the entire height of the block, two grooves 3 are made in this form of implementation, the side surfaces of each of which are located at equal (for the considered form of implementation) angles α and β to the bottom surface and in a horizontal section form a dovetail.

The facing blocks 2 of each horizontal row are displaced in the horizontal direction relative to the corresponding facing blocks 2 of the horizontal rows adjacent to it. In this case, the angular zones of the grooves 3 dovetail of the corresponding successively adjacent vertical facing blocks 2 of all horizontal rows forming the facade zone between the horizontal elements (not shown in the drawings) of the supporting structure formed a lot of vertical channels 4 (see Fig. 2) in part of which reinforcing bars 5 are installed. The length of each reinforcing bar 5 corresponds to the height of the specified area of the facade. The reinforcing rods 5 are arranged in steps (in the implementation form shown in the drawings, one in each groove 3 of each facing block 2), which ensures the fixation of the position of each facing block 2, in this implementation form, in one corner zone of one groove 3 dovetail. The reinforcing rods 5 are additionally connected with the facing block 2 in the indicated corner zone with an adhesive 6 (see Fig. 7). Adjacent cladding blocks 2 can also be interconnected by adhesive (not shown in the drawings), at least from their horizontal surfaces.

In the embodiment of FIG. 1, 2 form of implementation horizontal flexible communication is made in the form

- 4 025877 flexible connection 7 of a composite material containing a filler selected from the group comprising at least glass fiber and basalt. To enable fixation of the position of the flexible connection 7 of the composite material, as well as to compensate for the diameter of the flexible connection

7, in the area of its installation in the cladding block 2 and in the wall block 1 made shtabi 8 of the corresponding shape and size.

In the embodiment of FIG. 1, 2, the implementation form between the two horizontal rows of facing blocks 2 in the area of the floor elements (not indicated by the position) is set to ebbs 9. In addition, in FIG. 1, position 10 designates ventilation openings provided for forming a floor and / or zone ventilation system and located in an extreme horizontal row from the basement side and / or horizontal bridge (not indicated by positions).

In FIG. 3 schematically shows a general view of a fragment of a multilayer wall structure with a supporting structure of building blocks and horizontal flexible connections in the form of a metal anchor plate, and in FIG. 4 is a top view of such a multilayer wall structure in the area of the flexible connection in the form of a metal anchor plate. In the drawings, in particular, a main supporting wall of a plurality of building elements — wall blocks 11 and a plurality of external cladding elements — cladding blocks 12 connected to structural elements by means of fastening means with forming a facade located with an air gap in relation to the supporting wall are shown. The facing blocks 12 are made in the form of a rectangular parallelepiped, on the back face of which, along the entire height of the block, there are two grooves 13 in this implementation form, the side surfaces of each of which are located at equal (for the considered implementation form) angles α and β to the bottom surface and in a horizontal section form a dovetail.

The facing blocks 12 of each horizontal row are displaced in the horizontal direction relative to the corresponding facing blocks 12 of adjacent horizontal rows. Moreover, the angular zones of the grooves 13 dovetail of the corresponding successively adjacent vertical facing blocks 12 of all horizontal rows forming the facade zone between the horizontal elements (not shown in the drawings) of the supporting structure formed a lot of vertical channels 14 (see Fig. 4) in part of which reinforcing bars 15 are installed. The length of each reinforcing bar 15 corresponds to the height of the specified area of the facade. The reinforcing bars 15 are arranged in steps (in the embodiment form shown in the drawings in one groove 13 of the cladding block 12 through one), which fixes the position of the cladding blocks 12 through one, in this form of implementation, in one corner zone of one dovetail groove 13. The reinforcing rods 15 are additionally connected to the facing block 12 in the indicated corner zone by the adhesive 16 (see Fig. 7). Adjacent cladding blocks 12 can also be interconnected by adhesive (not shown in the drawings), at least from their horizontal surfaces.

In the embodiment of FIG. 3, 4 of the embodiment, the horizontal flexible connection is made in the form of a metal anchor plate 17. To enable additional fixation of the position of the flexible connection in the form of an anchor plate 17, it is additionally connected to the reinforcing bar 15. For these purposes, at the end of the anchor plate 17 from the side of the facing block 12, an inclined locking groove 18 is provided. In this case, in an horizontal row, the anchor plates 17 are arranged in an alternating direction of inclination of the locking groove 18.

In the embodiment of FIG. 3, 4, the implementation form between the two horizontal rows of cladding blocks 12 in the area of the floor elements (not denoted by the position), ebbs 19. In addition, in FIG. 3, numeral 20 denotes ventilation openings provided for forming a floor and / or zone ventilation system and located in an extreme horizontal row from the basement side and / or horizontal lintel (not indicated by positions).

In FIG. 5 schematically shows a general view of a fragment of a multilayer wall structure with a supporting structure of building blocks and horizontal flexible connections in the form of a metal perforated strip, and in FIG. 6 is a top view of such a multilayer wall structure in the area of the flexible connection in the form of a metal perforated strip. In the drawings, in particular, a main supporting wall of a plurality of building elements — wall blocks 21 and a plurality of external cladding elements — cladding blocks 22 connected to structural elements by means of fastening means with forming a facade located with an air gap in relation to the supporting wall is shown. The facing blocks 22 are made in the form of a rectangular parallelepiped, on the back face of which, along the entire height of the block, two grooves 23 are made in this form of implementation, the side surfaces of each of which are located at equal (for the considered form of implementation) angles α and β to the bottom surface and in a horizontal section form a dovetail.

The facing blocks 22 of each horizontal row are displaced in the horizontal direction relative to the corresponding facing blocks 22 of adjacent horizontal rows. Moreover, the angular zones of the grooves 23 dovetail corresponding in series

- 5,025,877 vertically adjacent facing blocks 22 of all horizontal rows forming the facade zone between the horizontal elements (not shown in the drawings) of the supporting structure, a plurality of vertical channels 24 are formed (see Fig. 6), some of which have reinforcing bars 25. The length of each the reinforcing bar 25 corresponds to the height of the specified zone of the facade. The reinforcing rods 25 are arranged in steps (in the implementation form shown in the drawings in each groove 23 of each facing block 22), which ensures that the position of each facing block 22, in this implementation form, is fixed in one corner zone of one groove 23 of the dovetail. The reinforcing rods 25 are additionally connected to the facing block 12 in the indicated corner zone by an adhesive 26 (see Fig. 7). Adjacent cladding blocks 22 can also be interconnected by adhesive (not shown in the drawings), at least from their horizontal surfaces.

In the embodiment of FIG. 5, 6, the form of implementation of the horizontal flexible connection is made in the form of a metal perforated strip 27. To enable additional fixation of the position of the flexible connection in the form of a metal perforated strip 27, it is installed on the adhesive (not indicated in the drawings).

In the embodiment of FIG. 5, 6, an implementation form between two horizontal rows of cladding blocks 22 in the area of the floor elements (not denoted by position) is provided with ebbs 28. In addition, in FIG. 5, 29 indicates ventilation openings provided for forming a floor and / or zone ventilation system and located in an extreme horizontal row from the foundation and / or horizontal lintels (not indicated by positions).

In FIG. 7 shows a general view of a fragment of a separately mounted facade from the back. The drawing shows the cladding blocks 30. The cladding blocks 30 are made in the form of a rectangular parallelepiped, on the back edge of which along the entire height of the block are made, in this form of implementation, two grooves 31, the side surfaces of each of which are located at equal (for the considered form of implementation) angles α and β form a dovetail to the bottom surface and in horizontal section.

The facing blocks 30 of each horizontal row are displaced in the horizontal direction relative to the corresponding facing blocks 30 of adjacent horizontal rows. In this case, the angular zones of the grooves 31 of the dovetail of the corresponding successively adjacent vertical facing blocks 30 of all horizontal rows formed a lot of vertical channels (not indicated in this figure), some of which are equipped with reinforcing bars 32. The reinforcing bars 32 are arranged in steps (in the on the drawings, the implementation form in each groove 31 of each facing block 30), which ensures the fixation of the position of each facing block 30, in this implementation form, in one corner zone 31-stand of the slot dovetail. Reinforcing rods 32 are additionally connected to the facing block 30 in the indicated angular zone by adhesive 6 (16, 26). Adjacent cladding blocks 30 can also be interconnected by adhesive (not shown in the drawings), at least from their horizontal surfaces.

In FIG. 8 schematically shows a General view of a fragment of a multilayer wall structure in one of the forms of implementation. In the drawing, in particular, the main supporting wall of a plurality of building elements - wall blocks 33 and a plurality of external cladding elements - various cladding blocks is presented: chipped ordinary 34, smooth ordinary 35, smooth corner wall 36, smooth corner window 37, smooth corner window fitting 38 associated with structural elements by means of fasteners with the formation of the facade, located with an air gap relative to the supporting wall. The facing blocks 34, 35 are made in the form of a rectangular parallelepiped, on the back face of which, along the entire height of the block, two grooves 39 are made in this form of implementation, the side surfaces of each of which are located at equal (for the considered form of implementation) angles α and β to the bottom surfaces and in horizontal section form a dovetail. The remaining cladding blocks 36, 37, 38 have an angular shape of horizontal section, but are also equipped with grooves of a swallow tail (one or two), made on the back face along the entire height of the block.

The facing blocks 34, 35 of each horizontal row are displaced in the horizontal direction relative to the corresponding facing blocks 34, 35 of adjacent horizontal rows. In this case, the angular zones of the grooves 39 dovetail of the corresponding successively adjacent vertical facing blocks 34, 35 of all horizontal rows forming the facade zone between the horizontal elements of the supporting structure (floor slab 40) formed a lot of vertical channels (not indicated in Fig. 8) in part of which reinforcing bars 41 are installed. The length of each reinforcing bar 41 corresponds to the height of the specified area of the facade. The reinforcing rods 41 are arranged in steps (in the implementation form shown in the drawings, one in each groove 39 of each facing block 34, 35 and, if necessary, facing blocks 36, 37, 38), which fixes the position of each facing block

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34, 35 and, if necessary, facing blocks 36, 37, 38, in this form of implementation, in one corner zone of one groove 39 dovetail. The reinforcing rods 41 are additionally connected with the facing block 34, 35 and, if necessary, the facing blocks 36, 37, 38 in the indicated corner zone with adhesive (the position in Fig. 8 is not indicated). Adjacent cladding blocks 34, 35, 36, 37, 38 can also be interconnected by adhesive 42, at least from their horizontal surfaces.

In the embodiment of FIG. 8, the horizontal flexible connection is made in the form of a metal U-shaped wire bracket 43.

In the embodiment of FIG. 8, an ebb 44 is installed between two horizontal rows of cladding blocks 34, 35 in the area of the floor slab 40. In addition, in FIG. 8, reference numerals 45 indicate ventilation openings provided for forming a floor and / or zone ventilation system and located in an extreme horizontal row from the side of the floor slabs 40.

In the embodiment of FIG. 8 in the implementation form, the ends of the floor elements (floor slabs 40) on the facade side are provided with profile protrusions, the shape, size and location of which are selected with the possibility of fixing external cladding elements on them with an end-to-end arrangement with respect to each other. As already mentioned above, this is usually achieved due to the fact that when the elements of the external cladding are already mounted on the formwork, the binder (concrete) is poured at the level of overlap, which, when solidified, forms the above-mentioned protrusions.

In this implementation form, thermal liners 46 are also provided in the floor elements (floor slabs 40). Tightness and thermal insulation of the structure is achieved through the use of mounting foam 47 in the installation area of structural elements in the form of window, doorways, etc., as well as mineral wool seal 48.

49 in FIG. 7 indicates the horizontal jumper of the window opening.

The lower horizontal row of cladding blocks 34 of each area of the facade is supported by the corresponding element of the supporting structure, in particular the slab 40.

The operation of the multilayer wall structure will be described in more detail below with reference to the positions of the figures of the drawings, in particular FIG. 8, corresponding to some forms of implementation of the claimed multilayer wall structure. For those forms of implementation that are not illustrated by the drawings or which are not mentioned in the text of the description, but are possible in the claimed scope of claims, all conclusions about the achieved technical results and advantages and advantages also remain valid.

In accordance with the project of the building, a multi-layer wall structure is erected from a variety of building elements, including masonry elements in the form of wall blocks 33 (1, 11, 21) and horizontal lintels 49, connected with the foundation and with horizontal floor elements in the form of a floor slab 40 with the formation of a carrier designs. In parallel mode, the installation of the facade, located with an air gap relative to the supporting wall, from the cladding units 34, 35 (2, 12, 22, 30), 36, 37, 38 is carried out. At the same time, the cladding units 34, 35 (2, 12 , 22, 30) and, if available, 36, 37, 38 of each horizontal row are displaced in the horizontal direction relative to the corresponding facing blocks 34, 35 (2, 12, 22, 30) and, if present, 36, 37, 38 horizontal rows adjacent to it. Due to such a shift by the angular zones of the grooves 39 (3, 13, 23, 31), the dovetail of the corresponding successively adjacent vertically facing blocks 34, 35 (2, 12, 22, 30) and, if there are 36, 37, 38 of all horizontal rows in the area of the facade between, in the considered form of implementation, slabs 40 overlap is formed many vertical channels (4, 14, 24). As a rule, to fix the relative position of the facing blocks 34, 35 (2, 12, 22, 30) and, if there are 36, 37, 38 adjacent, both vertically and horizontally, the masonry of the blocks is carried out using appropriate adhesive means 42. For additional fixation of the mutual position of the facing blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38, in accordance with the calculations, part of the vertical channels (4, 14, 24) install reinforcing bars 41 (5 , 15, 25, 32). The length of each reinforcing bar 41 (5, 15, 25, 32) is chosen in accordance with the height of the specified zone of the facade. The step with which the reinforcing bars 41 (5, 15, 25, 32) are installed is calculated in such a way that the position of each cladding blocks 34, 35 (2, 12, 22, 30) is secured and, if available, 36, 37, 38. To give the structure even greater rigidity, the reinforcing bars 41 (5, 15, 25, 32) are connected with the corresponding facing blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38 in the corner zone groove 39 (3, 13, 23, 31) with adhesive (6, 16, 26).

In addition, when erecting the inventive multilayer wall structure in parallel, in accordance with the calculations, horizontal flexible connections are established that connect the individual (calculated) cladding blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38 with the corresponding element of the supporting structure (wall block 33 (1, 11, 21)). Flexible connections can be selected by experts in the field of technology in accordance with the project (calculations) and can be flexible connections 7 made of composite materials, anchor plates 17, metal shaped brackets 43, metal perforated strips 27, etc. On average, horizontal 7 025877 flexible connections establish four connections per 1 m ^{2 of} facade. Horizontal flexible connections are fixed at one end with respect to the facing block 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38 or directly (mounted on adhesive, like metal perforated strips 27; embedded in the facing a block, like metal U-shaped staples; recessed into the grooves 8, as flexible connections 7 from a composite material, etc.), or through a reinforcing rod 41 (5, 15, 25, 32), as in the case of an anchor plate 17 with the fixing groove 18. The second end of the horizontal flexible ties are fixed in relation to the corresponding element depending on the type of flexible connection (clogged into the wall block 33 (1, 11, 21), like anchor plates 17 and metal U-shaped wire brackets 43; mounted on adhesive, like metal perforated strips 27; recessed into 8, as flexible connections 7 of composite material, etc.).

Thus, only individual cladding blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38, located at a given step in the vertical and horizontal direction, are connected with structural elements through horizontal flexible connections, which significantly simplifies, speeds up and reduces the cost of installation of the structure as a whole. In addition, due to a significant reduction in the number of fasteners, the mass of the structure is also reduced. In this case, the strength of the claimed multilayer wall structure, as well as its resistance to various kinds of deformations, do not decrease. Operational characteristics are also improved through the use of thermal liners 46, mounting foam 47, mineral wool seal 48, as well as through the installation of ebbs 44 (9, 19, 28) and ventilation holes 45 (10, 20, 29).

As wall blocks 33 (1, 11, 21) during the construction of the supporting structure, building blocks can be used, preferably made of cellular or expanded clay concrete. It should be borne in mind that other construction methods and other materials (reinforced concrete panels, concrete, brick, etc.) can be used.

Facing blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38 are made in the considered forms of implementation symmetrical with two grooves 39 (3, 13, 23, 31), the dovetail is preferably made of vibro-pressed concrete. Due to the form of execution of the cladding blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38 and the above-mentioned features of their fastening with respect to the load-bearing wall between the load-bearing wall and the facade formed from the cladding blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38, air gaps are created, which allows you to use this design as a ventilated facade.

The result is a very reliable, stable and durable (taking into account the material from which the cladding blocks 34, 35 (2, 12, 22, 30) are made and, if available, 36, 37, 38, horizontal flexible connections 43 (7, 17 , 27) and reinforcing bars 41 (5, 15, 25, 32), taking into account the means for ventilation (45 (10, 20, 29)), water drainage (44 (9, 19, 28)) provided in the design, and t .d.) design.

This design (unlike, for example, from widespread ventilated facades made of porcelain stoneware) is several times cheaper and practically does not require replacement for any reason of cracked elements (cladding units 34, 35 (2, 12, 22, 30) and, if available , 36, 37, 38), since the latter cannot fall out of the cladding system due to the volumetric shape of the split and their installation on adhesive 6 (16, 26).

In addition, the facing blocks 34, 35 (2, 12, 22, 30) and, if available, 36, 37, 38 can have different texture of the front surface, as well as different color designs. This ensures the multivariance of the execution of facades both from the point of view of a specific texture (or combination of textures), and from the point of view of the possibility of obtaining drawings, including ornamental, etc.

Information sources.

1. Patent KI No. 49864 and publ. 12/10/2005.

2. Patent EA No. 008961 B1, publ. 10/26/2007.

3. Patent EA No. 009754 B1, publ. 04/28/2008.

4. Patent ΟΝ No. 2634003 Υ, publ. 08/18/2004.

5. Application DR No. 200297518 A, publ. 10.24.2000.

Claims (9)

CLAIM 1. A multilayer wall structure comprising a main supporting wall of a plurality of building elements, including at least masonry elements and horizontal lintels connected to the foundation and with horizontal floor elements to form the supporting structure, a plurality of external cladding elements associated with the supporting structure by means of fasteners with the formation of a facade located with an air gap in relation to the supporting wall, and, if necessary, a layer of thermal insulation, is placed between the supporting wall and the facade, while the elements of the outer cladding are made in the form of blocks in the form of a rectangular parallelepiped, on the back face of which at least one groove is made along the entire height of the block, the side surfaces of which are located at angles α and β to the bottom surface and a dovetail is formed in a horizontal section, characterized in that a part of the outer cladding elements located at a predetermined pitch in the vertical and horizontal direction is connected with the elements of the supporting structure, while and the fastenings of the elements of the external cladding are made in the form of horizontal flexible connections, each of which is fixed at one end to the element of the external cladding, and the second end to the corresponding element of the supporting structure, and the elements of the external cladding of each horizontal row are displaced in the horizontal direction relative to the corresponding elements the outer lining of adjacent horizontal rows in such a way that the angular zones of the grooves dovetail corresponding vertical adjacent whether there are elements of the external cladding of all horizontal rows forming the facade zone between the horizontal elements of the supporting structure, including horizontal lintels, horizontal overlapping elements and the foundation, many vertical channels have been formed, at least some of which have reinforcing bars, the length of each of which corresponds to the height of the specified areas of the facade, while the reinforcing bars are arranged in steps that ensure that the position of each element of the outer cladding is fixed at least in one corner zone of at least one groove, dovetail, and are connected to the outer cladding element in the specified corner zone by adhesive, and adjacent outer cladding elements are connected by adhesive, at least from their horizontal surfaces. 2. The wall structure according to claim 1, characterized in that the horizontal flexible connection is selected from the group comprising at least polymer flexible connections, flexible connections from composite materials, metal U-shaped staples, anchor plates, metal strips, including including perforated, while horizontal flexible ties are installed based on four ties per 1 m ^{2 of} facade. 3. The wall structure according to claim 2, characterized in that the horizontal flexible connection in the form of a metal strip and an anchor plate is additionally connected to the reinforcing bar. 4. Wall structure according to any one of claims 1 to 3, characterized in that the reinforcing bars are made of a composite material containing a filler selected from the group comprising at least glass fiber and basalt. 5. Wall structure according to any one of claims 1 or 2, characterized in that the ends of the horizontal overlapping elements on the facade side are provided with profile protrusions, the shape, size and location of which are selected with the possibility of fixing external cladding elements on them with an end-to-end arrangement with respect to to a friend. 6. Wall construction according to any one of claims 1 or 2, characterized in that thermal elements are provided in the elements of horizontal ceilings. 7. Wall structure according to any one of claims 1 or 2, characterized in that low tides are installed between two horizontal rows of elements of the external cladding in the area of horizontal lintels and / or in the area of elements of horizontal ceilings. 8. Wall structure according to any one of claims 1 or 2, characterized in that between the two horizontal rows of elements of the external cladding in the zone of the elements of horizontal ceilings and / or in the extreme horizontal row from the basement and / or horizontal bridge are provided ventilation holes for forming a floor and / or zone ventilation system. 9. The wall structure according to any one of claims 1 or 2, characterized in that the lower horizontal row of elements of the external cladding of each area of the facade is supported by the corresponding element of the supporting structure selected from the group including the foundation, horizontal overlap element, horizontal jumper.