RU86629U1 - PANEL FOR FACING FACADES OF BUILDINGS (OPTIONS) - Google Patents

Abstract

The invention relates to the field of construction, reconstruction or repair of buildings and structures. The inventive panel comprises an outer insulating layer 1 and an inner heat-insulating layer in the form of a plate 2 of polyurethane foam with a pair of cantilevered protrusions 3 on its sides having an upper (left) and lower (right) location along the plate 2. Specified layer 1 made of non-combustible fiber-cement sheet, inextricably connected with the upper side 4 of the plate 2 over its entire area. The upper side 4 of the plate 2, which is part of the thickness of the panel 2, is displaced along the length of the plate 2 up or down in a vertical plane by an estimated value relative to its lower side 5, which is another part of the thickness of the panel 2, with the possibility of formation of any second of these displacements a pair of cantilevered protrusions 6 from the end sides of the plate 2, respectively having an upper and lower arrangement with the first pair relative to each other, causing the circuit of the panel to close when docked with other similar panels. The width "a" of the upper 4 and lower 5 sides of the plate 2 is half the length "l" of the indicated sides 4 and 5, which corresponds to the execution of their rectangular shape. Moreover, when positioned with an offset along the length of the plate 2 up or down its upper side 4 relative to the lower side 5, the plate 2 in longitudinal and transverse sections corresponding to these displacements either and mating profiles, or and mating profiles. According to these profiles, the cantilevered protrusions 3 and 6 have smooth sealing surfaces 7, as well as the same width "b", determined by the operating requirements for the panel, a thickness "h" equal to half the thickness "H" of the plate 2 and the same lengths, but only in pairs. So the length of one pair of cantilevered protrusions 3, oriented in the longitudinal direction of the plate 2, is the length "l" of the upper 4 and lower 5 sides of the plate 2, and the length of the second pair of cantilevered protrusions 6, oriented in the transverse direction, is the width of "a", respectively, of the upper 4 and the lower 5 sides of the plate 2. The adopted geometric parameters of the cantilevered protrusions 3 and 6 will allow their sealing surfaces 7 to be mutually mated when mounted with the sealing surfaces 7 of the cantilevered protrusions 3 and 6 of another similar panel, forming p vnoprochnoe connection in places docking panels. The difference between the second option and the first is that the upper 4 and lower 5 sides of the plate 2 have the same width "a" and length "l" in each of them, i.e. they have the shape of an equilateral rectangle (square). Another difference follows from this, in addition to the fact that the cantilevered protrusions 3 and 6 have the same width “b” and thickness “h”, they also have the same length, which is, respectively, the length “l” (width “a”) of the upper 4 and lower 5 sides of the plate 2. The technical result of the inventions is to increase the insulating properties of the panel by improving the tightness of the connection of the panels when they are mated with each other, simplifying the design of the castle connection and, accordingly, the technology of assembly of panels on the walls of the building. 2 sec and 3 z.p. f-ly, 10 ill.

Description

The inventions are a group of inventions, encompassed by a single inventive concept, and generally relate to the field of construction, reconstruction or repair of buildings and can be used to clad the exterior, preferably facade surface of buildings.

The wall panel containing the outer structural layers and the inner layer of the sheet insulation in the form of a polystyrene foam plate, the outer structural layers made of polystyrene concrete, is taken as an analogue in both versions. The thickness of the layer of expanded polystyrene plate is greater than or equal to the thickness of the outer layers of polystyrene concrete (1)

The well-known panel, despite a number of advantages over other claddings, consisting in simplicity of design, high strength, reliable thermal insulation of cladding surfaces, still requires a comprehensive solution to the issue of sealing joints of cladding panels along their entire contour, as well as the use of special devices during their installation due to the large mass , which increases the complexity of installation work.

Also, in both versions, the system of insulation of external walls is adopted as an analogue, including load-bearing elements fixed to the wall, an effective insulation installed on the wall surface, a waterproofing layer in the form of film strips, vertical mounting profiles and cladding plates fixed to them, additionally between the external a vapor barrier layer in the form of film strips is located on the wall surface and an effective heater; an effective sealant is mounted on the wall with vertical mounting profiles pressed against it with a facing plate, and the waterproofing layer is located between the facing plates and the effective sealant, while the facing plates are vertically mated by cantilever sections (2).

A positive feature of this design is that it allows you to improve the conditions for pairing mating facing plates with each other compared to the technical solution (1), achieved due to the vertical mating of the plates using the console sections. However, the question of the compatibility of facing plates on its end surfaces remains unresolved, which reduces the efficiency of operation of such plates, especially when used in conditions of high atmospheric precipitation, since there is no sealing of the plates in these places.

Closest to the proposed technical solution for both options is a panel for cladding building facades (3). This panel is made with two parallel flanges, vertically connected to each other on the building facade, with a sealed lock, the panel has foamed polyurethane foam as an internal heat-insulating layer, and also a mirror aluminum foil as an insulating layer, and the panel protrusion has a ribbed surface and enters the groove of another panel, and the insertion groove of the groove has a convex shape facing the inside of the panel, in addition, the insertion collar has a protrusion in the form of a nose, which, when mounted, is the input um under the clamping collar, creating a tight and tight connection in the spike-groove system.

A disadvantage of the known panel, as well as the technical solution (2), is the inability to achieve tightness of the panel joints when they are connected to each other by end surfaces due to the inability to form tight locks when panels are joined, and this requires additional measures (for example, adhesive coating) to ensure density connections of end joints of panels.

Moreover, due to equipping the panel with an insertion collar in the form of a spout for insertion during installation under the clamping collar, although a tight connection is achieved in the “thorn-groove” system, this assembly is a weak link in the airtight lock, since the possibility of breakage of the spout due to due to its small size in relation to the thickness of the panel and, accordingly, it is impossible to achieve the designed tight lock connection.

Another disadvantage of the known panel is that the locking joint has low strength due to the inability to ensure its equal strength in height of the panel due to the difference in the structural dimensions of the cantilevered protrusions.

In addition, the presence of a shoulder complicates the design of the castle joints and, accordingly, the technology of manufacturing panels and assembling them on the walls of the building.

Therefore, these disadvantages of the known panel (3) reduce the tightness of the connection panels with each other along their entire circuit and, accordingly, the thermal insulation of the cladding as a whole.

Also a significant disadvantage of the known panel is low fire resistance, which is impractical to use it for cladding building facades.

From the above it follows that the use of the known panel is not effective and not reliable, and also technologically difficult when assembling the panels on the wall surface.

In connection with the presence of these shortcomings, the well-known panel should be improved.

The objective of the invention is to eliminate the above disadvantages, i.e. the creation of such a panel design for cladding facades of buildings and structures, which would improve the efficiency of its use by comprehensively addressing the issue of improving the heat-insulating properties of the wall cladding of the building, as well as increasing the fire safety of the cladding.

The technical result, the achievement of which provides a solution to the problem, is expressed in improving the tightness of the connection of the panels when they are docked with each other, while the simplicity of the design of the castle connection, as well as in simplifying the technology of assembly of panels on the walls of the building.

To achieve the task with the claimed technical result according to the first embodiment, in the panel for cladding building facades, made with the possibility of fastening to building structures of buildings, connected to each other on the facade of the building and containing an external insulating layer and an internal heat-insulating layer made in the form of a plate of polyurethane foam those are a pair of cantilevered protrusions on its lateral sides, in which one cantilevered protrusion has an upper arrangement along the plate on the left and the other has a lower arrangement in according to the invention, on the right side of the slab, the outer insulating layer of the panel is a non-combustible fiber-cement sheet, which is inseparably connected to the upper side of the panel over its entire area, while to ensure that the panel is mated along its entire perimeter with similar adjacent panels, the upper side of the plate, which is part the thickness of the plate, is located with an offset along the length of the plate up or down in the vertical plane by the calculated value relative to its lower side, which is another part of the thickness of the plate, with the possibility of at any of these displacements, the second pair of cantilevered protrusions from the end faces of the plate, respectively having the upper and lower sides with the first pair, relative to each other, the width of the upper and lower sides of the plate is half the length of the indicated sides, moreover, when positioned with an offset along the length of the plate up its upper side relative to the lower side of the plate in longitudinal and transverse sections, respectively, has and mating profiles or respectively has and mating profiles when positioned offset along the length of the plate downward of its upper side relative to the lower side, while the cantilevered protrusions in both pairs have the same width determined by the operating requirements for the panel and a thickness equal to half the thickness of the plate, the length of one pair of cantilevered protrusions oriented in the longitudinal direction of the plate, is the length of the upper and lower sides of the plate, respectively, and the length of the second pair of cantilevered protrusions oriented in the transverse direction of the plate is respectively, the upper and lower sides of the plate, and the sealing surfaces of each cantilevered protrusion, regardless of whether it belongs to any of the two pairs of cantilevered protrusions, are mutually mated when installed with the sealing surfaces of the cantilevered protrusions of another similar panel, forming an equal strength locking joint at the joints of the panels.

To achieve the task with the claimed technical result according to the second embodiment, in the panel for facing building facades, made with the possibility of fastening to building structures of buildings, connected to each other on the building facade and containing an external insulating layer and an internal heat-insulating layer made in the form of a plate of polyurethane foam with a pair of cantilevered protrusions on its lateral sides, in which one cantilevered protrusion has an upper arrangement along the plate on the left, and the other has a lower arrangement in the rear For the plate on the right, according to the invention, the outer insulating layer of the panel is a non-combustible fiber-cement sheet, which is inseparably connected to the upper side of the panel over its entire area, while to ensure that the panel is mated along its entire perimeter with similar adjacent panels, the upper side of the plate, which is part the thickness of the plate, is located with an offset along the length of the plate up or down in the vertical plane by the calculated value relative to its lower side, which is another part of the thickness of the plate, with the possibility of the formation at any of these offsets of the second pair of cantilevered protrusions from two other lateral sides of the plate having respectively the upper and lower sides of the plate with the first pair, the upper and lower sides of the plate have the same width and length in each of them, and when placed with an offset along the length of the plate up its upper side relative to the lower side of the plate in longitudinal and transverse sections, respectively, has and and mating profiles or accordingly has mating profiles when positioned offset along the length of the plate downward of its upper side relative to the lower side, while the cantilevered protrusions in both pairs have the same width, determined by the operational requirements for the panel, a thickness equal to half the thickness of the plate, and the length, the length of the cantilevered protrusions is the length (width) of the upper and lower sides of the plate, respectively, and the sealing surfaces of each cantilevered protrusion on the sides of the plate are mutually mated during installation with sealing erhnostyami corbels another similar panel to form a tool joint strength balance in places docking panels.

Moreover, in the dependent claims, claimed in two versions, it is advisable to include the following features:

- the inner heat-insulating layer of polyurethane foam has a compressive strength of at least 200 kPa and a thermal conductivity of not more than 0.028 W / [m · K);

- the bottom side of the plate facing the building is equipped with a waterproofing layer made of polystyrene foam sheet, the density of which is not more than 25 kg / m ³ and the thickness is not less than 20 mm;

- a decorative layer is applied to the outer surface of the fiber-cement sheet, for example marble or granite chips, or other non-combustible coating.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention in two versions, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed invention in two options. The determination from the list of identified analogues of the prototype as the closest in the set of essential features of the analogue allowed us to identify the set of essential distinctive features to the claimed panel in relation to the claimed applicant in the two versions set forth in the claims of each option. Therefore, the claimed invention in two versions meets the condition of patentability of the invention of "novelty."

A causal relationship between the set of essential features of the claimed invention according to the first embodiment and the technical result achieved is as follows.

The sign - “the outer insulating layer of the panel is a non-combustible fiber-cement sheet, inseparably connected to the upper surface of the slab over its entire area” - indicates the execution of the outer layer of non-combustible material, thereby solving the problem of environmental and fire safety of wall cladding of buildings.

The sign is “at the same time, to ensure that the panel is mated along its entire perimeter with similar adjacent panels, the upper side of the plate, which is part of the thickness of the plate, is displaced along the length of the plate up or down in the vertical plane by an estimated value relative to its lower side, which is another part of the thickness plates, with the possibility of formation at any of these displacements of a second pair of cantilevered protrusions from the end faces of the plate, respectively having the upper and lower positions relative to each other with the first pair "-Characterizes the novelty of the design of the plate and indicates the formation of a second pair of cantilevered protrusions on the end sides of the plate, the sealing surfaces of which together with the sealing surfaces of the cantilevered protrusions on the sides of the plate create a tight locking connection on the end and sides of the plate, which increases the thermal insulation properties of the panel compared with the prototype (3), in which there is no castle connection on the end sides of the plate.

The sign - “the width of the upper and lower sides of the plate is half the length of the indicated sides” - indicates the dependence of the width of the indicated sides of the plate on their length, which ensures mutual compatibility of the panels and, accordingly, the versatility of their assembly with each other, and this, as a result, simplifies installation technology.

The sign - "and when located with an offset along the length of the plate up its upper side relative to the lower side of the plate in longitudinal and transverse sections has and mating profiles or respectively has and mating profiles when positioned with an offset along the length of the plate downward of its upper side relative to the lower side "is fundamental and, as follows from the profiles of the cross sections of the plate, each cantilevered protrusion has smooth and smooth sealing surfaces, which leads to the formation of a locking joint of a simple design compared to the prototype (3), in which the castle connection has a complex structure, because formed by a protrusion having a ribbed surface and falling into the groove of another panel, and a spout in the form of a nose, which is inserted during installation under the clamping collar.

The sign - “in this case, the cantilevered protrusions in both pairs have the same width determined by the operational requirements for the panel and a thickness equal to half the thickness of the panel, and the length of one pair of cantilevered protrusions oriented in the longitudinal direction of the plate is the length of the upper and lower sides of the plate, and the length of the second pair of cantilevered protrusions oriented in the transverse direction of the plate is the width of the upper and lower sides of the plate, respectively ”- is fundamental and governs the conditions boron of geometrical dimensions of cantilevered protrusions according to their width, thickness and length. Such an approach to determining the geometric parameters of cantilevered protrusions can significantly increase the density of the locking joints during the installation of panels and, together with the second feature mentioned above, will enhance the technical effect, thereby improving the tightness of the joints of the panels when docking with each other.

The sign - “wherein the sealing surfaces of each cantilevered protrusion, regardless of whether it belongs to any of the two pairs of cantilevered protrusions, are mutually mated when mounted with the sealing surfaces of the cantilevered protrusions of another similar panel, forming an equally strong locking joint at the joints of the panels” - indicates that Regardless of the possible options for interconnecting the cantilevered protrusions of the panel (along the length or width, or along the length and width), a reciprocal connection is formed, providing strength AMCOW compounds of the plate thickness, which increases the operational reliability facing assembled from the inventive panel. In addition, this feature allows you to implement a number of structural schemes for laying panels in the cladding, which increases the artistic expressiveness of the walls of the building.

The second variant of the claimed panel differs from the first in that, due to the width of the upper and lower sides of the plate equal to their length, the cantilevered protrusions have the same geometric dimensions not only in width and thickness, as in the first embodiment, but also in length, the length of the cantilever the protrusions is the length (width) of the upper and lower sides of the plate, respectively.

Despite the fact that these differences give the contour of the upper and lower sides of the plate the shape of an equilateral rectangle (square) and differ in one of the geometric dimensions (length) of the cantilevered protrusions, a technical result is achieved in comparison with the first option, which consists in improving the tightness of the connection of the panels when docking them with each other along their entire perimeter while simplicity of the castle connection, i.e. as in the first embodiment.

Moreover, since the cantilevered protrusions have the same dimensions in length, this makes it possible to dock the panels by any of their sides, which significantly, in comparison with the first option, simplifies the technology of assembling them on the walls of the building.

Thus, it follows from the foregoing that the second option allows the joints to be completely sealed both vertically and horizontally and, accordingly, to achieve the task - to increase the efficiency of the use of the claimed invention by increasing the thermal insulation properties of the building wall cladding.

In addition, when implementing the claimed panel according to both options, if in each of them the features included in the dependent claims are used, an additional technical result can be achieved.

So, the sign - “... in it (in the panel), the internal heat-insulating layer of polyurethane foam has a compressive strength of at least 200 kPa and a thermal conductivity of not more than 0.028 W / (m · K)” - allows you to fulfill one of the requirements for the panels, used in construction, namely due to the adopted technical indicators, to give the panel high strength while enhancing the effect of thermal insulation of the walls of buildings.

The sign - “the lower side of the plate facing the building is equipped with a waterproofing layer made of polystyrene foam sheet, whose density is not more than 25 kg / m ³ and thickness not less than 20 mm” - allows to reduce heat loss through the walls of the building. In addition, due to the accepted density of the polystyrene foam sheet, the need for special preparation of the wall surface to eliminate unevenness in it is eliminated.

The sign - “a decorative layer is applied to the outer surface of the fiber-cement sheet, for example marble or granite chips, or other non-combustible coating” - provides a sufficiently high artistic expression of the walls of buildings - while increasing the service life of the cladding.

All of the listed technical effects will improve the efficiency of using the inventive panel when mounting it on the surface of the walls of buildings.

In the present application for the grant of a patent, the requirement of unity of invention is met, since both options are intended for the manufacture of panels for cladding building facades, they solve the same problem - improving the heat-insulating properties of the wall cladding of the building by achieving the same technical result in the implementation of the claimed inventions - improving the tightness of the connection of the panels when docking them with each other, while simplicity of the design of the castle joints and simplifying the technology of assembly of the panels.

Thus, the essential features of each of the claimed panel are in a causal relationship with the achieved technical result and from the analysis of the prior art in this field are not obvious in an obvious way for a specialist. Therefore, each of the claimed inventions meets the condition of patentability "inventive step".

The industrial applicability of the claimed invention in two versions is justified by the following description of the invention and the drawings thereto.

The claimed invention in two versions is illustrated by drawings, in which:

figure 1 shows the inventive panel, a perspective view (shown waterproofing layer in accordance with paragraph 4 of the claims), the first option;

figure 2 is a section along aa of figure 1;

figure 3 is a section along BB of figure 1;

figure 4 shows the inventive panel, a perspective view (shown waterproofing layer in accordance with paragraph 4 of the claims), the second option;

figure 5 is a section along bb In figure 4;

figure 6 presents a section of the assembled panels according to the first embodiment;

in Fig.7 is a section along G-D of Fig.6;

in Fig.8 is a section along DD DD of Fig.6;

figure 9 presents a section of the assembled panels according to the second embodiment;

figure 10 is a cross section on EE of Fig. 8.

In the first embodiment, the panel for cladding building facades contains an outer insulating layer 1 and an inner heat-insulating layer made in the form of a plate 2 made of polyurethane foam with a pair of cantilevered protrusions 3 on its lateral sides, in which one cantilevered protrusion has an upper arrangement along the slab 2 on the left and the other - has a lower location along the plate 2 on the right. In turn, the outer insulating layer 1 of the panel is a non-combustible fiber-cement sheet, inextricably connected with the upper side 4 of the plate 2 over its entire area.

To ensure that the panel is mated along its entire perimeter with similar adjacent panels, the upper side 4 of plate 2, which is part of the thickness of plate 2 (see the definition of the word “side” in source 4), is displaced along the length of plate 2 up or down in a vertical plane on the calculated value relative to its lower side 5, which is the other part of the plate 2, with the possibility of formation at any of these displacements of a second pair of cantilevered protrusions 6 from the end sides of the plate 2. Therefore, the specified location with an offset of the upper side 4 2 lits on its lower side 5 determines the possibility of creating two structural schemes.

In this case, the cantilevered protrusions 6 of the second pair, regardless of the direction of the location with an offset (up or down) of the upper side 4 of the plate 2 relative to its lower side 5, have respectively an upper and lower arrangement with the first pair of cantilevered protrusions 3 relative to each other. Due to this, one of the sealing surfaces 7 of each cantilevered protrusion 6 of the second pair is in the same horizontal plane with the sealing surface 7 of each cantilevered protrusion 3 of the first pair (Fig. 1). This causes a short circuit of the panel when docking it with other similar panels.

One of the first two structural diagrams of the panel is shown in FIG. 1, which shows the upward offset of the upper side 4 of the plate 2 relative to its lower side 5 with the upper arrangement of the cantilevered protrusions 3 along the plate 2 on the left and the lower arrangement of the cantilevered protrusions 3 along the plate 2 on the right . Moreover, in the second structural diagram of the panel, the indicated position of the cantilevered protrusions 3 is stored, i.e. when the upper side 4 of the plate 2 is located with an offset downward relative to its lower side 5.

Moreover, in each of the mentioned structural diagrams of the panel, the width “a” of the upper 4 and lower 5 sides of the plate 2 is half the length “l” of the indicated sides, respectively. This ratio of the width "a" and the length "l" of the mentioned sides 4 and 5 corresponds to the execution of their rectangular shape.

In the case of a location with an offset along the length of the plate 2 upwards of its upper side 4 relative to the lower side 5, the plate 2 in longitudinal and transverse sections, respectively, has and mating profiles, as shown in figure 2 and 3, or respectively has mating profiles in the case of a location with an offset along the length of the plate 2 down its upper side 4 relative to the lower side 5.

The first pair of mating profiles follows from Fig. 1 according to the sections of the plate 2 along A-A and B-B, the arrows of which are respectively directed from the lower location of the cantilevered protrusions-3 to the right and from the direction of the arrangement with an offset along the length of the plate 2 upwards of the upper side 4 plate 2 relative to its lower side 5. According to the second structural diagram of the panel (not shown conditionally), the second pair of mating profiles corresponds to the indicated sections, respectively, with arrows from the side also of the lower location of the console s projections 3 and on the side toward the location of offset, but on the length of the plate 2 down the upper side 4 of the plate 2 relative to the lower side 5. However, according to said sealing surface profiles 7 of each cantilever projection 3 and 6 have a flat and smooth surface.

To form a tight locking connection when joining the panels, the cantilevered protrusions 3 and 6 in both pairs have the same width "b", determined by the operating requirements for the panel, and a thickness "h" equal to half the thickness "H" of the plate 2. Since the length of the cantilevered protrusions 3 and 6 of each pair is determined by the ratio of the width “a” and the length “l” of the upper 4 and lower 5 sides of the plate 2, so the length of one pair of cantilevered protrusions 3 oriented in the longitudinal direction of the plate 2 is the length “l” of the upper 4 and lower 5 sides plate 2, and the length of the second pair of cantilevered protrusions 6, oriented in the transverse direction of the plate 2, is the width "a", respectively, of the upper 4 and lower 5 sides of the plate 2. Moreover, the width "b" of the cantilevered protrusions 6 is the calculated value of the location with an offset along the length of the plate 2 up or down of its upper side 4 of the plate 2 relative to its lower side 5 (figure 1)

According to the accepted geometric dimensions of the cantilevered protrusions, the sealing surfaces 7 of each of them, regardless of whether it belongs to the first pair of cantilevered protrusions 3 or the second pair of cantilevered protrusions 6, are mutually mated when mounted with the sealing surfaces of the cantilevered protrusions of another similar panel, forming an equal strength joint at the joints of the panels. This increases the operational reliability of the panel.

In the manufacture of the panel according to the second structural scheme, the geometric dimensions of its cantilevered protrusions correspond to the geometric dimensions of the cantilevered protrusions of the panel made according to the first structural scheme.

A distinctive feature of the second option compared to the first option is that the upper 4 and lower 5 sides of the plate 2 have the same width "a" and length "l" in each of them, which corresponds to the execution of the mentioned sides 4 and 5 in the shape of an equilateral rectangle ( square). Therefore, in FIGS. 4 and 5, one side of the square is shown with the corresponding width “a”, and the other side of the square with the corresponding length “l”, and the numbering of the positions in FIGS. 4 and 5 coincides with the numbering of the positions in FIG. 1. This leads to another difference, in addition to the fact that the cantilevered protrusions 3 and 6 have the same width "b" and the thickness "h", as in the first embodiment, they also have the same length, which is respectively the length "l" (or width "a" ) the upper 4 and lower 5 sides of the plate 2 (Fig.4, 5).

It is advisable in both versions of the claimed invention to increase the rigidity of the panel to use the polyurethane foam from which the plate 2 is made, with a compressive strength of at least 200 kPa and with a thermal conductivity of not more than 0.028 W / (m · K}, to ensure reliable thermal protection of the building walls.

It is also advisable in both versions of the claimed invention, the bottom side 5 of the plate 2, facing the building when installing the panels, to be equipped with a waterproofing layer made of polystyrene foam sheet 8 (shown in figures 1-5), the density of which is not more than 25 kg / m ³ and thickness not less than 20 mm. The need to equip the plate 2 with such a layer arises if the panel is used for cladding the walls of buildings in conditions of high atmospheric precipitation. In addition, the specified layer is equipped with a plate 2, when it is necessary to eliminate the surface roughness of the walls of the building.

In addition, it is advisable in both versions of the claimed invention to apply a decorative layer, for example marble or granite chips, or other non-combustible coating to the outer surface of the fiber-cement sheet, which in addition to improving the artistic perception of the building increases its fire resistance.

Moreover, regardless of the orientation of the upper side of the plate relative to its lower side, according to the indicated structural diagrams of their mutual arrangement, the formula of the claimed panel according to both of its variants is fulfilled.

The presented panel options are intended for external cladding of building facades and are aimed at expanding their standard sizes by giving the upper and lower sides of the plate a rectangular shape or a square shape. Despite the differences in these options for one of the geometric parameters of the cantilevered protrusions, namely, along their length, high efficiency of their use is achieved due to the tight sealing of the panels along their entire contour. The panel is easy to install and can be used in a wide range of climatic and time factors.

The assembly of panels on the walls of buildings according to the first embodiment is as follows.

Consider the order of laying panels made according to the first structural scheme, realizing one of the possible options for combining panels with each other in the lining (Fig.6-8).

After fastening the first panel to the wall of the building using dowels, a second panel is brought to it so that their cantilevered protrusions 3 are mutually mated along the length of the plate 2, thereby obtaining a tight lock in the form of a spike-groove. After that, the second panel is attached to the wall with dowels. Next, the process of joining the panels to each other with their long sides vertically as necessary continues, thus forming a series of assembled panels. Then collect another row of panels. For this purpose, the next panel is brought to the two vertical panels of the first row previously installed vertically, turning it 90 ° relative to the last, and they are conjugated using the cantilevered protrusions 3 with the cantilevered protrusions 6 of the two panels of the first row located along their width. Next, the described cycle of docking each panel with two previously installed panels in the first row is repeated, realizing the described artistic design of the cladding on the walls of the building. Moreover, regardless of the intended artistic design of the cladding, due to the mutual conjugation of the sealing surfaces 7 of each cantilevered protrusion of any of the two pairs of cantilevered protrusions with the sealing surfaces 7 of the cantilevered protrusions, any dense reciprocal connection of the cantilevered protrusions to each other and, correspondingly, equal strength locking connection in places of joining of panels. If there are significant irregularities (roughnesses) on the surface of the walls of the building, before the start of the cladding work, the lower surface 5 of the plate 2 is equipped with a polystyrene sheet 8.

And in order to improve the artistic expressiveness of the walls of the building, either marble (granite) chips are preliminarily applied to the outer surface of the fiber-cement sheet in the manufacture of panels, or other non-combustible coating after their installation.

The assembly order of panels made according to the second structural scheme is similar to the described assembly order of panels made according to the first structural scheme.

Moreover, when facing the walls of the building with panels made according to one or another structural scheme, the convenience of their installation is ensured due to the universality of the lock connection of the panels to each other.

The principle of assembling panels on the walls of the building in the second embodiment is similar to the principle of assembling panels in the first embodiment, except that after installing the first row of panels, since they are in the form of an equilateral rectangle, the next row of panels is mounted under each previously installed panel with the formation of a tight lock between them (Fig.9, 10).

As a result, the cladding made in both cases differs from each other in the layout of the panels in the cladding while maintaining a tight seal between adjacent panels.

Due to the presence of cantilevered protrusions 3 and 6 with dimensions specified separately for each variant of the claimed panel, their height difference during installation of panels is excluded, as a result, a flat surface is formed, and the lines of the joints of the panels are almost invisible.

The inventive panel in both versions provides the following advantages compared to the prototype (3):

- improves the tightness and strength of the connection of the panels to each other along their entire perimeter, while the simplicity of the design of the castle connection;

- simplifies the technology of assembling panels on the walls of the building due to the versatility of the process of laying panels;

- increases the effect of thermal protection of wall cladding of buildings;

- improves fire safety of wall cladding of buildings.

It follows from the foregoing that the thermal insulation properties of the wall cladding of buildings are increased, and, consequently, the efficiency of using panels is increased.

Sources of information taken into account when drawing up the description of the invention:

1. Certificate of the Russian Federation for the full model No. 16005, class. E04C 2/26, 2000

2. RF patent for utility model No. 45745, cl. EB04 1/74, 2004

3. Certificate of the Russian Federation for utility model, No. 29076, class. E04F 13/00, 2001 (prototype).

4. V.I. Dal. Explanatory dictionary of living Great Russian language. Volume Four Moscow, Russian Language Publishing House, 1998, pp. 313-332.

Claims (8)

1. The panel for cladding building facades, made with the possibility of fastening to building structures of buildings, connected to each other on the facade of the building and containing an external insulating layer and an internal heat-insulating layer made in the form of a plate of polyurethane foam with a pair of cantilevered protrusions on its sides, in which one cantilevered protrusion has an upper location along the plate on the left, and the other has a lower location along the plate on the right, characterized in that the outer insulating layer of the panel is not an combustible fiber-cement sheet, which is inseparably connected with the upper side of the slab over its entire area, while to ensure the panel is compatible along its entire perimeter with similar adjacent panels, the upper side of the slab, which is part of the slab thickness, is displaced along the length of the slab up or down to a vertical plane by a calculated value relative to its lower side, which is another part of the thickness of the plate, with the possibility of formation at any of these displacements of a second pair of cantilevered protrusions from the end faces of the plate, having an upper and lower arrangement with the first pair, respectively, with respect to each other, the width of the upper and lower sides of the plate is half the length of the indicated sides, moreover, when positioned with an offset along the length of the plate up its upper side relative to the lower side, the plate in longitudinal and transverse sections respectively has mating profiles or respectively has mating profiles when positioned with an offset along the length of the plate down its upper side relative to the lower side, while cantilever The projections in both pairs have the same width, determined by the operational requirements for the panel, and a thickness equal to half the thickness of the plate, the length of one pair of cantilevered protrusions oriented in the longitudinal direction of the plate is the length of the upper and lower sides of the plate, respectively, and the length of the second pair of cantilevered the protrusions oriented in the transverse direction of the plate, is the width of the upper and lower sides of the plate, respectively, and the sealing surfaces of each cantilever protrusion, regardless STI it to any of the two pairs of cantilever projections mutually mate during assembly with the sealing surfaces of the console ledges another similar panel to form a tool joint strength balance in places docking panels. 2. The panel for cladding building facades according to claim 1, characterized in that in it the internal heat-insulating layer of polyurethane foam has a compressive strength of at least 200 kPa and a thermal conductivity of not more than 0.028 W / (m · K). 3. The panel for cladding building facades according to claim 1, characterized in that the lower side of the plate facing the building is equipped with a waterproofing layer made of polystyrene foam sheet, the density of which is not more than 25 kg / m ³ and the thickness is not less than 20 mm. 4. The panel for cladding building facades according to claim 1, characterized in that on the outer surface of the fiber-cement sheet a decorative layer is applied, for example marble or granite chips, or other non-combustible coating. 5. A panel for cladding building facades, made with the possibility of fastening to building structures of buildings, connected to each other on the facade of the building and containing an external insulating layer and an internal heat-insulating layer made in the form of a plate of polyurethane foam with a pair of cantilevered protrusions on its sides, wherein one cantilevered protrusion has an upper location along the plate on the left, and the other has a lower location along the plate on the right, characterized in that the outer insulating layer of the panel is a non a fibrous cement-cement sheet, which is inseparably connected to the upper side of the slab over its entire area, while to ensure the panel is compatible along its entire perimeter with similar adjacent panels, the upper side of the slab, which is part of the thickness of the slab, is displaced along the length of the slab up or down to a vertical plane by a calculated value relative to its lower side, which is another part of the plate thickness, with the possibility of formation at any of these displacements of a second pair of cantilevered protrusions from two other lateral sides he plates having respectively the first pair of upper and lower relative to each other, the upper and lower sides of the plate have the same width and length in each of them, and when placed with an offset along the length of the plate up its upper side relative to the lower side of the plate in the longitudinal and cross sections respectively has mating profiles or respectively has mating profiles when positioned offset along the length of the plate down its upper side relative to the lower side, while the cantilever protrusion in both pairs they have the same width determined by the operational requirements for the panel, a thickness equal to half the thickness of the plate, and the length, the length of the cantilevered protrusions being the length (width) of the upper and lower sides of the plate, the sealing surfaces of each cantilevered protrusion on the sides of the plate they are mutually mated during installation with the sealing surfaces of the cantilevered protrusions of another similar panel, forming an equally strong locking joint at the joints of the panels. 6. The panel for cladding building facades according to claim 5, characterized in that in it the inner heat-insulating layer of polyurethane foam has a compressive strength of at least 200 kPa and a thermal conductivity of not more than 0.028 W / (m · K). 7. The panel for facing building facades according to claim 5, characterized in that the lower side of the plate facing the building is equipped with a waterproofing layer made of polystyrene foam sheet, the density of which is not more than 25 kg / m ³ and the thickness is not less than 20 mm. 8. The panel for cladding building facades according to claim 5, characterized in that a decorative layer, for example marble or granite chips, or other non-combustible coating is applied to the outer surface of the fiber-cement sheet.