RU2557269C1 - Method to install facade lining and heat insulation from floor slab - Google Patents

Abstract

FIELD: construction.SUBSTANCE: in the method to install facade lining and heat insulation from a floor slab first they install brackets at the end of the slab for fixation of the frame from vertical guides at the floor height and horizontal shapes, on horizontal shapes they install external lining of the facade, after installation of the lining the elements of heat insulation fixation are installed onto horizontal shapes, and onto these elements they place at least one heat insulation material layer, and after fixation of the last heat insulation material layer they install an inner barrier.EFFECT: provision of building facade lining installation and its heat insulation from a floor slab, without use of weight-lifting equipment, with an air gap between facade lining and internal layers of heat insulation, providing for condensate removal, preventing mould and fungi on walls, preliminary damage of facade from moisture, which makes it possible to create microclimate in building premises that is most favourable for a human being.20 cl, 5 dwg

Description

Technical field

The invention relates to the field of construction, and in particular to a method of mounting a facade cladding of a building and thermal insulation from a floor slab (i.e., from the inside of a room), and can be used in the construction of hinged ventilated facades, stained-glass windows and other building structures.

State of the art

Mounted ventilated systems that use a heat-insulating layer can significantly reduce heat loss and, accordingly, reduce the cost of heating the premises, since in this case the walls of the building will be reliably protected from overcooling and overheating. In addition, many heaters are characterized by good soundproofing properties, which increases the degree of sound absorption by the walls of the building. An important factor is the fact that the systems of ventilated facades are distinguished by their excellent appearance due to the wide selection of cladding materials and a wide range of colors. Mounted in accordance with all applicable norms and standards, the hinged facade can last for many years, as he is not afraid of direct sunlight, pollution, precipitation and even acids.

Undoubtedly, the main advantage of the hinged ventilated facade systems is the free circulation of air between the building wall and the protective and decorative structure. It is thanks to the presence of an air gap between them that the condensate is removed, the appearance of mold and fungi on the walls is prevented, and the facade is prematurely destroyed by moisture. In addition, this allows you to create the most favorable microclimate for the person in the building. Installation of the hinged structure can be carried out year-round, since during its implementation there are no works depending on weather conditions.

In the prior art, various methods of erecting walls with a cladding and / or insulation (thermal insulation) are known. In particular, from the RF patent for invention No. 2282697, published on 08.27.2006, a method is known for erecting the outer wall of a multi-storey building, including installing the outer and inner walls separated by an air gap and placing insulation between them, and first, external panels are hung on the building’s frame throughout the facade . For this purpose, it is recommended to use a facade support panel made in the form of a rectangular plate and equipped with four fastening elements in the form of mounting hooks on the side of the inner plane.

The disadvantages of this method are: the ability to manufacture panels only in a horizontal position, which requires significant production areas; the complexity of transportation and storage compared to flat panels due to the presence of protruding parts; complexity of installation due to the fact that you need to hang the panel on the hinges using all four mounting hooks at once.

From the RF patent for invention No. 2122082, published on 11/20/1998, there is a known method of erecting the outer wall of a multi-storey building, including installing the outer and inner walls separated by an air layer, connecting them to each other and placing insulation between them, the outer wall within each floor is installed on reinforced concrete a frame rigidly fixed to the supporting structures of the building after fixing its predetermined butt gap with the underlying outer wall, and floor installation of the outer wall, mainly of concrete panels, pre-installation of internal.

The disadvantages of this method of mounting the wall and insulation are the high cost and complexity of the construction, because first, a reinforced concrete inner layer must be installed in the narrow gap between the mounted outer layer and the ceiling, and then the cavity between the outer and inner layers must be filled with insulation. In addition to the complexity of this process, it cannot be controlled, which leads to a decrease in the quality of the external wall being constructed in terms of its thermal conductivity.

From the patent of the Russian Federation for utility model No. 85176, published on July 27, 2009, there is known a method of mounting facade panels, in the upper part of which steel loops are installed, with which they are hung on steel hooks placed on the ends of the consoles of monolithic reinforced concrete floors. In the lower part, the panel has a embedded part, which, after installing the panel in the design position, is welded using a steel rod to the embedded part in the foundation beam. The upper and lower edges of the panels are beveled inward, which creates an additional hook. Panels are hung over the entire facade of the building, fill the joints, and then make the laying of the inner wall of small pieces of materials (blocks or bricks). During the laying process, an air gap remains between the inner and outer walls, which is periodically filled with insulating material. In this case, the length (extension) of the console with the hook of the upper floor and the hinges, as well as the additional hook of the upper and lower edges of the panels, fixed by welding embedded parts, provide a layer size sufficient to accommodate the required thickness of insulation. The disadvantages of this method are: the need to use when installing the panel in the design position of the crane equipment; the need to seal butt joints after installation, which is feasible, most likely, in the presence of scaffolds, cradles, etc. fixtures.

From the RF patent for invention No. 2204664, published on 05/20/2003, there is a known method of mounting a multilayer outer wall of a building, which is carried out in two stages with the formation of a ventilated air gap, and at the first stage, the outer layer is in the form of a pre-architecturally designed concrete panel the size of a structural the cell of the building is pivotally attached to the floor slabs using flexible, detachable metal connections. The installation is carried out from the outside of the building, and at the second stage, the intermediate warming and inner layers of individual elements and / or small pieces from the inside of the work building are installed sequentially without using external scaffolding and hanging scaffolds. A ventilated air gap is formed during the installation process between the layer of the outer panels and the intermediate insulation layers. Moreover, the outer panels the size of the cell of the building are attached from the outside of the building to the end of the floor slab with a gap of 5-40 mm, and the air gap is formed by means of retainers in contact with the inner surface of the outer panel. In another embodiment, it is possible to install hinged panels on the frame from the outside of the building, in this case a ventilated gap is formed between the hinged panels and the surface of the intermediate insulation. The main disadvantage of this method is the impossibility of installing external panels from the floor slab, since the external panel has the dimensions of a building cell. With this installation method, condensate can accumulate between the wall panel and the outer insulation layer at the ends of the floors, since the wall outer panels are floor-bearing and the air gap is limited by floor floors, which will lead to the accumulation of condensate in the air gap. In the case of hinged cladding, condensate is removed, which prevents premature destruction of the facade from moisture.

Mounted facade systems are known, during the installation of which, as a rule, mineral insulation is used, which is attached to the wall using connectors (dowels). Stringers (guides) on which the cladding is mounted are mounted on brackets. Brackets are mounted to the wall using connectors. Facing is used the most diverse: natural stone, porcelain stoneware, aluminum panels, fiberglass concrete, etc. The guides are made of galvanized steel or of various aluminum alloys. Widely used facade systems such as "Kraspan", "Hoarfrost", "Wave", "Spidi" and others.

From the RF patent for utility model No. 107237 published on 08/10/2011, the RF patent on utility model No. 76939 published on 10/10/2008, Swiss patent No. 688866 published on 04/30/1998, various fasteners for mounting the cladding by fixing it on the outer surface are known walls of the building. But installation with the help of such fastenings is carried out from the outside of the building, which is ensured by special suspension devices or scaffolding.

From the RF patent for utility model No. 34575, published on December 10, 2003, the Kraspan system of insulated ventilated facade is known, containing a support structure formed by brackets, vertical supporting profiles, fixing brackets to a wall and fixing brackets to vertical bearing profiles, attached to the wall in gaps between the brackets, a layer of insulation elements and a lining of metal elements mounted on vertical supporting profiles with a ventilated gap relative to the layer of elements of the thermal insulation yats.

The disadvantages of hinged facade systems are the complexity of installation and the increase in construction time, due to the following factors:

- work on fixing the heat-insulating layer and installing facade panels is possible only after the complete installation of the inner layer of the wall, which, as a rule, is built of stone materials;

- for the installation of guides, thermal insulation and facade panels, scaffolding or the use of special suspension devices is required, since all these operations are performed from the outside;

- cladding panels are made of materials that practically do not let steam through, so there is a need to organize a ventilated air gap.

The closest set of essential features to the claimed invention is the method of installation of facade panels and insulation, disclosed in the patent of the Russian Federation for invention No. 2399731, published on 09/20/2010, which is characterized in that steel profiles are laid on the console (dowels) of the reinforced concrete slab along the wall, on these horizontal steel runs are supported, with a certain step, by vertical racks of steel profiles. The elements are connected by welding or bolted joints. Thin slabs of materials transmitting air vapor (for example, glass-magnesium sheets, cement-bonded particle boards, etc.) are inserted into the grooves of the uprights that extend beyond the line of the outer edges of the floor consoles from the floor level of the second floor. to the horizontal steel profile, and subsequent to the top of the previous plates. Thus, the front part of the outer multilayer wall of the building is installed within the first floor to the overlap of the second floor. Then, steel profiles are installed on the overlapping keys of the second floor, and then the installation is carried out in the same sequence as was applied within the first floor. On the interfloor overlap, masonry is made from small-piece materials, for example, from concrete blocks. As the inner wall is erected, the space between the wall and the front panel is filled with insulation. A significant difference from the known methods of installation is that the guides in the form of steel racks with grooves are attached not to the load-bearing part of the wall, but to horizontal steel girders installed on the floor consoles; facade panels (cladding) in the form of plates of materials that sufficiently pass air vapor are installed in the design position before installing the inner wall and thermal insulation not from the outside, but from the inside and without the use of load-lifting mechanisms.

The specified method of installation of facade panels (or cladding) and thermal insulation reduces the complexity of installation by carrying out work from a floor plate without scaffolding, scaffolding, etc., which is necessary when installing ventilated facades, the ability to carry out installation work without the use of lifting equipment used when installing reinforced concrete facade panels with mounting hooks. However, there is no air gap between the external facade, thermal insulation and the enclosing masonry, which entails the absence of free air circulation between the building’s front wall and the insulating and enclosing protective structures. As a result, condensate is not removed, which causes mold and fungi to appear on the walls, premature destruction of the facade from moisture. In addition, a microclimate unfavorable to humans is created in the premises of the building.

Disclosure of invention

The problem to which the claimed invention is directed, is to create a method of mounting the facade cladding and insulation for systems of ventilated facades carried out from the floor slab, without scaffolding or the use of special suspension devices, which ensures the presence of an air gap between the facade cladding and the inner layers insulation. Thus, the installation of the building facade structure from the floor slab is carried out from the outside to the inside - first they mount the profile system to the ends of the floor slabs, then fasten the facing material, then heat insulation (insulation) and, lastly, erect the inner wall of the building.

The technical result achieved by using the claimed method is to ensure the installation of the facade cladding of the building and its insulation from the floor slab (inside the room), without the use of lifting equipment, scaffolding, scaffolding, etc., with an air gap between the facade cladding and the inside layers of thermal insulation, providing the removal of condensate, preventing the appearance of mold and fungi on the walls, premature destruction of the facade from moisture, which allows you to form microclimate more favorable for the person. In addition, the facade of the building is mounted in parallel with the monolithic frame, so this method can significantly reduce the construction time of the object, as a result, when the first floors are erected, the building takes on a presentable appearance.

The specified technical result is achieved due to the fact that in the method of installing the facade cladding and insulation from the floor slab, brackets are first installed on the end of the floor slab for mounting the frame from vertical rails to the height of the floor and horizontal profiles, and the external facade cladding is mounted on horizontal profiles, after installation cladding on horizontal profiles install fastening elements of thermal insulation, on which at least one layer of insulation is placed, and after repleniya last layer of insulation installed inside the fence.

The internal fence is in the form of an internal screen or masonry. After mounting the external facade cladding on the vertical rails by means of blind rivets, sliders are additionally installed for fastening as an internal fence of the internal screen. Cement bonded particleboards, magnesite sheets, gypsum plasterboards and other fireproof sheet materials intended for arranging interior partitions are preferably used as the internal screen.

The horizontal profile is installed on the vertical guides of the frame from the inside of the room or on the back of the cladding, depending on the method of fastening the outer cladding of the building’s facade. Horizontal profiles are fixed on vertical rails by means of rivet and bolt joints or self-tapping screws.

Subsequent layers of insulation are installed, providing overlap or tight fit of the seams to each other.

The fastener for the installation of thermal insulation consists of a thermal insulation pin with the possibility of fastening to a horizontal profile, a thermal insulation limiter to fix the air gap between the outer surface of the insulation and the inner surface of the lining, nail and thermal insulation retainer.

The number and step of installing the insulation pins is chosen so that the outer insulation plate is fastened with at least five pins. The installation step of the horizontal profile is determined by the height of the lining and the current loads on it.

The thermal insulation pin is configured to fix a fixation limiter and a thermal insulation nail thereon.

The insulation pin is made of aluminum alloy, galvanized or corrosion-resistant steel, carbon steel, wood, polypropylene or its copolymers, polyamide, glass-filled polyamide, polyvinyl chloride.

The thermal insulation limiter is made of polypropylene or its copolymers, polyamide, glass-filled polyamide, polyvinyl chloride, aluminum alloys, steel, wood.

The thermal insulation retainer is configured to be fixed to the nail by means of gears, thread or wedge.

The bracket on the end of the floor slab is fixed by means of an anchor connection with the installation of a thermal pad made of polypropylene, a copolymer of polypropylene, paronite.

The method of installation of the facade cladding is carried out by means of clips fixed in special grooves of horizontal profiles, agraphs, “mom-dad” profiles, by fastening horizontal profiles pre-installed on the back side of the cladding to vertical rails using rivets or bolts or self-tapping screws.

Vertical guides, horizontal profiles and carcass brackets are made of aluminum alloy profiles, galvanized or corrosion-resistant sheet steel, hot rolled or bent carbon steel profiles, and wooden structures.

As the cladding use plates, panels made of porcelain, glass, plastic, natural stone, fiber cement, agglomerate-granite, composite materials, panels made of aluminum and / or steel sheet.

As insulation use plates, blocks, panels of non-combustible mineral wool panels on a synthetic binder or plates of glass staple fiber on a synthetic binder.

Brief Description of the Drawings

The invention is illustrated by drawings, where:

in FIG. 1 and FIG. 2 shows a general installation diagram of the facade cladding and thermal insulation;

in FIG. 3 shows a fastener for assembling the heat insulation assembly;

in FIG. Figure 4 shows the general installation diagram of the facade cladding and thermal insulation with the installation of a slider for attaching the internal screen.

The implementation of the invention

The method of mounting the bracket on the end of the floor slab is determined by the type of floor structure. For example, the bracket is fixed to reinforced concrete floors by anchor joints, the brackets are bolted to metal structures. The vertical rail is attached to the brackets with bolted or riveted joints.

Vertical guides and brackets of the frame are made of aluminum alloys, and the frame can also be assembled from profiles made of galvanized or corrosion-resistant steel sheet, hot rolled or bent profiles made of carbon steel, wooden structures.

Under the metal bracket install a thermal pad made of polypropylene, a copolymer of polypropylene, paronite.

Horizontal profiles are fixed to vertical rails by rivets, bolts, and self-tapping screws. Facing the building facade is attached to the horizontal profile.

Depending on the type of cladding, various profiles of aluminum alloys are used, the profiles can be made of galvanized or corrosion-resistant steel sheet, hot rolled or bent profiles made of carbon steel, wooden structures.

The installation step of the horizontal profile is determined by the height of the facing panel and the current loads (wind, weight, etc.). Types of cladding panels: porcelain stoneware, natural (natural) stone, fiber cement boards, agglomerate-granite plates, HPL panels (plastic), cassettes of composite materials and panels of aluminum and / or steel sheet, glass plates, facade textile mesh. The sizes of the facing panels are various and are selected based on the functional purpose of the building structure, as well as the aesthetic requirements for it.

In FIG. 1 and FIG. 2 shows a general installation diagram of the facade cladding and thermal insulation.

The lining (facing plates) 7 is mounted by means of fasteners. In FIG. 1 shows a fastening diagram using a clip 8 and a horizontal profile (bolt) 2.

Installation of the cladding is possible in the following ways:

1. Using clips made of stainless steel. Clips paws fix the facing panel from the outside or in cuts on the horizontal ends of the cladding, while the clips themselves are fixed in special grooves of horizontal profiles (crossbars).

2. With the help of landowners. Agraphs are pre-fixed on the back of the cladding with anchor joints or self-tapping screws. Cladding panels with mounted agraphs are mounted by hanging them on horizontal profiles.

3. Using the profiles “mom-dad”. On the back side of the cladding plate along the upper and lower faces fix special cladding profiles with anchor joints, riveted joints or self-tapping screws. A profile “dad” is fastened along the upper edge, and a profile “mother” along the bottom. Cladding plates with horizontal profiles fixed to them are mounted, fixing them on the vertical guides of the frame. The “dad” profile from the side of the upper edge of the facing plate is attached to the vertical guide using riveted or bolted joints or self-tapping screws. The “mother” profile from the side of the lower edge of the facing panel engages with the “father” profile of the underlying facing panel without the use of fasteners.

4. Also, horizontal profiles can be attached to the back of the cladding with riveted joints or self-tapping screws. The panel assembly with horizontal profiles is mounted by fastening the horizontal profiles to the vertical rails using rivet or bolt connections or self-tapping screws.

In FIG. 4 shows a diagram when the construction of the outer cladding is not provided, and the heat-insulating layer 9 is closed from the inside by an inner shield 14, which is fixed on the sliders with rivets 16. For subsequent fastening of the inner insulation shield (the last step), the sliders 12 are fixed on the vertical guides 11 by blind rivets 13 with a vertical pitch of 300 ... 600 mm. The vertical installation step of the slider 11 is determined depending on the type of the inner screen 14. Under the slider 12, a thermal pad 15 is always installed. In the case when the masonry is provided, the installation of the slider is not required.

Slider 12 is made of aluminum alloys AlMgSi 6060, AlMg0,7Si 606, AD31, as well as of sheet galvanized or corrosion-resistant steel, hot rolled or bent profiles made of carbon steel, wood, polypropylene or copolymers of propylene, polyamide, glass-filled polyamide, polyvinyl chloride.

Thermal pad 15 is made of polypropylene or copolymers of propylene, polyamide, glass-filled polyamide, polyvinyl chloride, wood.

The stages of installing the lining on the horizontal guides 1 and the installation of the sliders on the vertical guides 11 can be interchanged. The inner screen of thermal insulation is closed with an internal enclosing structure 17.

The fastener for mounting the thermal insulation 9 is mounted on horizontal profiles 1 by means of self-tapping screws 2 or rivets.

In FIG. 3 shows a general view of a fastener for mounting thermal insulation. On the horizontal profiles (guides) 1, mounted on the vertical guides of the building frame, install thermal insulation pins (bearing the L-shaped element) 3 using an exhaust rivet or a self-tapping screw (possibly by hanging) 2.

The thermal insulation pin is made of aluminum alloys AlMgSi 6060, AlMg0,7Si 606, AD31, as well as of galvanized or corrosion-resistant sheet steel, hot rolled or bent profiles made of carbon steel, wood, polypropylene or copolymers of propylene, polyamide, glass-filled polyamide, polyamide.

The number and step of installing the insulation pins is chosen so that the outer insulation plate is fastened with at least five pins. The number of pins for attaching thermal insulation is selected according to the recommendations of the manufacturer of insulation plates.

Next, heat insulation pins 4 are installed on the heat insulation pins 3.

The insulation limiter 4 fixes the air gap between the outer surface of the insulation and the inner surface of the cladding. The limiter of thermal insulation 4, for example, can be installed in special protrusions-grooves on pin 3 or with another method. The thermal insulation limiter is made of polypropylene or copolymers of propylene, polyamide, glass-filled polyamide, polyvinyl chloride, aluminum alloys, steel, wood.

On the heat insulation pin 3, a heat insulation nail 5 is mounted, for example, by means of a protrusion on the pin or other fixing method. The heat insulation nail is made of polypropylene or copolymers of polypropylene, polyamide, glass-filled polyamide, polyvinyl chloride, wood.

On the thermal insulation nail 5, insulation plates are installed as far as the stop in the thermal insulation limiter. The number of layers of insulation boards is at least one.

As insulation use plates, blocks, panels, non-combustible mineral wool boards on a synthetic binder, glass staple fiber boards on a synthetic binder, non-combustible mineral wool boards on a synthetic binder, for example Rockwool LIGHT BATTS, Rockwool VENTI BATTS. It is also possible to use insulation boards made of glass staple fiber on a synthetic binder. In the case of two or three-layer insulation, first install the plates of the outer layer of insulation, after installing the outer layer of insulation, install the plates of the inner layers of the insulation, while ensuring overlapping joints and a snug fit to each other.

The thermal insulation pin 3 is configured to fix the thermal insulation limiter 4 and the thermal insulation nail 5 thereon.

The thermal insulation latch 6 is made with the possibility of its fixation on the nail 5 by means of gears, thread or wedge.

Next, the insulation from the inside is closed with a building envelope (enclosing masonry or the inner screen of the insulation). The type of enclosing structure under the insulation is determined by the construction project.

Masonry can be made of cellular concrete blocks, expanded clay concrete, solid or hollow ceramic bricks, etc.

When the construction of the outer walling is not provided, the heat-insulating layer is closed from the inside by the internal shield of the insulation, which is fastened to the rivets or self-tapping screws fixed in advance on the vertical sliders. As an internal shield of thermal insulation, TsSP boards, magnesite sheets, plasterboard sheets and other fireproof sheet materials intended for the installation of interior partitions can be used. Further, the internal screen of thermal insulation can be closed, but not necessarily (depending on the location of the object, the requirements for heat efficiency), with an external enclosing structure of cellular concrete blocks, expanded clay concrete, solid or hollow ceramic bricks, etc.

Claims (20)

1. The method of installation of the facade cladding and insulation from the floor slab, characterized in that the brackets are first installed on the end of the floor slab for mounting the frame from vertical rails to the height of the floor and horizontal profiles, on the horizontal profiles, the outer facade lining is mounted, after the lining is installed on horizontal profiles install heat insulation fastening elements, on which at least one layer of insulation is placed, after which it is installed inside rennee fence. 2. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the internal fence is made in the form of an internal screen or masonry. 3. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that after installing the external facade cladding on the vertical rails by means of blind rivets, sliders are additionally installed for fastening as an internal fence of the internal screen. 4. The method of installation of the facade cladding and thermal insulation according to claim 3, characterized in that cement bonded boards, magnesite sheets, gypsum plasterboards and other fireproof sheet materials intended for installing interior partitions are used as the internal screen. 5. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the horizontal profile is installed on the vertical guides of the frame or on the back side of the cladding. 6. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the horizontal profiles are fixed on vertical rails by means of rivets and bolts or self-tapping screws. 7. The method of installation of the facade cladding and insulation according to claim 1, characterized in that the subsequent layers of insulation are installed, providing overlap and tight fit of the seams to each other. 8. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the fastener for installing thermal insulation consists of a thermal insulation pin with the possibility of fastening to a horizontal profile, a thermal insulation limiter to fix the air gap between the outer surface of the insulation and the inner surface of the cladding, nail and thermal insulation retainer. 9. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the bracket at the end of the floor slab is fixed by means of an anchor connection with the installation of a thermal pad made of polypropylene, a polypropylene copolymer, paronite. 10. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the cladding is mounted by means of clips fixed in special grooves of horizontal profiles, agraphs, “mom-dad” profiles, by attaching horizontal profiles pre-installed on the back of the cladding to vertical rails with rivets or bolts or self-tapping screws. 11. The method of mounting the facade cladding and thermal insulation according to claim 1, characterized in that the vertical guides, horizontal profiles and carcass brackets are made of aluminum alloy profiles, galvanized or corrosion-resistant steel sheet, hot rolled or bent carbon steel profiles, wooden structures. 12. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that plates, blocks, panels are used as insulation. 13. The method of installation of the facade cladding and insulation according to claim 1, characterized in that the number and step of installing the insulation pins is chosen so that the outer insulation plate is fastened with at least five pins. 14. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the step of installing the horizontal profile is determined by the height of the cladding and the current loads on it. 15. The method of mounting the facade cladding and thermal insulation according to claim 1, characterized in that the thermal insulation pin is made of aluminum alloy, galvanized or corrosion-resistant steel, carbon steel, wood, polypropylene or its copolymers, polyamide, glass-filled polyamide, polyvinyl chloride. 16. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the thermal insulation limiter is made of polypropylene or its copolymers, polyamide, glass-filled polyamide, polyvinyl chloride, aluminum alloys, steel, wood. 17. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the thermal insulation pin is configured to fix a fixation limiter thereon, and a thermal insulation nail. 18. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the thermal insulation latch is made with the possibility of its fixation on the nail by means of gears, thread or wedge. 19. The method of installation of the facade cladding and thermal insulation according to Claim 1, characterized in that non-combustible mineral wool boards with a synthetic binder and glass staple fiber boards with a synthetic binder are used as insulation. 20. The method of installation of the facade cladding and thermal insulation according to claim 1, characterized in that the cladding is made of plates, panels of porcelain stoneware, glass, plastic, natural stone, fiber cement, agglomerate-granite, composite materials, panels of aluminum and / or steel sheet.

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