RU54060U1 - A SET OF WALL UNITS FOR THE CONSTRUCTION OF SMALL BUILDINGS - Google Patents

Abstract

The utility model relates to the field of construction, and specifically to wall blocks that make up the system of structurally-insulating modular wall elements intended for the construction of low-rise buildings in temperate and cold climatic zones. The set of blocks contains sets of three-layer row blocks made in the form of rectangular parallelepipeds and a set of corner blocks. The ordinary blocks are made with a supporting inner layer and a front layer made of concrete, as well as with an internal heat-insulating layer, which are connected by at least one transverse screed. The thickness of ordinary blocks is 398 mm, and the lengths of three sizes are 198, 298 and 398 mm. Two corner blocks are made with a thickness and a length of 398 mm three-layer with a supporting inner layer, a front layer and an internal heat-insulating layer connected by at least one transverse screed. One corner block is made with a shortened front layer and a L-shaped in cross section heat-insulating layer, and the second corner block is made with a shortened supporting inner layer and a L-shaped in cross section heat-insulating layer. The third corner block is made with a L-shaped front layer, the cavity of which is filled with a heat-insulating layer. The thickness of the third corner block is 198 mm, and the length is 398 mm. The set of blocks also provides for a set of opening blocks, a set of pairing blocks and a set of bay window blocks.

Description

The utility model relates to the field of construction, and specifically to wall blocks that make up the system of structurally-insulating modular wall elements intended for the construction of low-rise buildings in temperate and cold climatic zones.

A known system of concrete building blocks made with a front layer, a bearing layer and a heat-insulating layer located between them. The thickness of the layers of the block is selected based on the ratio A: B: C: D = 0.7: 2.3: 3.3: 5.7, where A is the thickness of the front layer; B is the thickness of the binder layer; C is the thickness of the insulating layer; D is the thickness of the carrier layer. The layers of each block are interconnected by metal or plastic jumpers passing through the heat-insulating layer, the ends of which are embedded, respectively, in the front layer and in the carrier layer (RU C1 No. 2208102, IPC 7 E 04 C 1/40, 2003).

When erecting objects from blocks of known construction, it is not possible to comply with the requirements adopted in the construction of a single modular system, since it is not possible to achieve the cross-sectional dimensions of the entire range of blocks required for the construction of buildings using commercially available floor slabs, door blocks and window frames, partition walls and other unified products used in the construction of buildings without the need for their individual adjustment. In addition, during the construction of the enclosing walls of buildings, it is not possible to obtain a single heat-insulating belt in the wall, which excludes the use of these blocks for the construction of buildings in the cold climatic zone.

The technical results, the achievement of which is ensured by this utility model, consist in obtaining a modular system that is a multiple of 100 mm, which allows the use of the entire range of manufactured construction materials in the construction of buildings

materials: floor slabs, partition panels, wall stones, foundation blocks, bricks, standard window frames and door blocks. Eliminates the need for individual fitting of products. Minimized labor costs for direct construction, which reduces the construction time of a two-story cottage-type building to two weeks. During the construction of the enclosing walls of buildings, a continuous heat-insulating belt is provided over the entire length of the walls of almost any configuration, including bay windows. This allows you to erect the enclosing walls of buildings in both temperate and cold climatic zones.

The listed technical results are achieved in that the set of wall blocks contains sets of three-layer ordinary blocks of three types made in the form of rectangular parallelepipeds and a set of corner blocks of three types.

The ordinary blocks are made with a supporting inner layer and a front layer made of concrete, as well as with an internal heat-insulating layer, which are connected by at least one transverse coupler passing through the inner heat-insulating layer and terminated by the ends in the front layer and in the inner bearing layer. The thickness of ordinary blocks is 398 mm, and the lengths are, respectively, 198, 298 and 398 mm.

Two corner blocks made with a thickness and length of 398 mm are also three-layer with a supporting inner layer, a face layer and an internal heat-insulating layer, connected by at least one transverse coupler passing through the internal heat-insulating layer and terminated into the front layer and the inner bearing layer .

One corner block is made with a shortened front layer and a L-shaped in cross section heat-insulating layer, and the second corner block is made with

a shortened supporting inner layer and a L-shaped in cross section heat-insulating layer.

The third corner block is made with a L-shaped front layer, the cavity of which is filled with a heat-insulating layer. The layers of this block are also connected by at least one transverse screed passing through the inner heat-insulating layer and sealed with the end into the front layer. The thickness of the third corner block is 198 mm, and the length is 398 mm.

Alternatively, the protruding parts of the insulating layers of the first and second corner blocks are made in the form of extensions to the main part of the insulating layer. The extension of the first corner block is connected by a screed to the main part of the heat-insulating layer, and the extension of the second corner block is connected by a longitudinal screed with the inner supporting layer.

The thicknesses of the front layer, the heat-insulating layer and the inner bearing layer of the ordinary blocks and the first and second corner blocks are preferably 78, 200 and 120 mm, respectively.

The extension length of the first corner block in the best embodiment is 120 mm, and the extension length of the second corner block is 80 mm.

The thickness of the face layer of the third corner block is preferably 78 mm.

To create openings, the set of blocks must contain a set of three types of rectangular blocks of openings made with front, heat-insulating and internal bearing layers, as well as with protrusions formed by the continuation of the front layer.

Two blocks of openings are made with protrusions on one side, and the third with protrusions on two opposite sides. The thickness of all blocks of the openings is

398 mm, the lengths of the front layer of the first and second blocks are 398 and 198 mm, and the length of the third block of the opening with two protrusions along the front layer is 398 mm.

The width of the protrusions of the blocks of the openings is preferably equal to the thickness of the front layer, and the height of the protrusions is 50 mm At the same time, the thicknesses of the front layer, the heat-insulating layer and the inner bearing layer of the opening blocks are also 78, 200 and 120 mm, respectively.

Most optimally, taking into account the fire safety requirements of buildings, when the heat-insulating layer of the first and second blocks of openings on the side of the protrusions is closed with a concrete layer, while its thickness is 50 mm.

The supporting inner layer, the face layer and the heat-insulating layer of the first opening block are connected by at least one transverse coupler passing through the inner heat-insulating layer and terminated by the ends in the face layer and in the inner bearing layer.

For the construction of buildings with a complicated configuration, including internal right angles, the set of blocks must contain a set of four types of paired parallelepiped blocks made of heat-insulating and concrete layers connected by at least one screed, the end of which is embedded in a concrete layer and passes through a heat-insulating layer.

The length of all the interface blocks is 398 mm, the first interface block is made with a front layer of concrete and a width of 198 mm, and the second interface block has a square section with an inner bearing layer of concrete. The third interface unit is also made of square cross section with a L-shaped inner bearing layer of concrete, in the cavity of which a heat-insulating layer is located. The fourth interface unit is made with a L-shaped heat-insulating layer, in the cavity of which there is a front layer of concrete.

The thickness of the concrete front layer of the first coupler, by analogy with the blocks described above, is 78 mm.

The thickness of the inner supporting layer of concrete of the second interface unit is 278 mm.

The thickness of the inner supporting layer of concrete of the third conjugation unit is 278 mm, and the width of its protrusion is 78 mm.

The thickness of the front layer of concrete of the fourth interface unit is 78 mm, and the width of the protrusion of the insulating layer is 80 mm.

To expand the possible configuration of the building’s enclosing walls, the kit includes a set of five types of bay windows.

Four bay windows are made with a thickness of 398 mm with the front, heat-insulating and supporting inner layers, also connected by at least one transverse coupler passing through the inner heat-insulating layer and terminated by the ends in the front layer and in the inner bearing layer.

The fifth bay window block has a thickness of 320 mm and layers of concrete and heat-insulating material are connected by at least one screed, the end of which is embedded in the concrete layer and passes through the heat-insulating layer.

The first block of bay windows is made rectangular with two faces along one of the ends located at an angle of 45 °. The rib of conjugation of one face with the rear surface of the block along the inner supporting layer is located at a length of 198 mm, and the rib of conjugation of another face with the front surface of the block along the front layer is located at a length of 363 mm, and the face layer is extended along this face.

The second block of bay windows is made rectangular and also with two faces along one of the ends located at an angle of 45 °. The edge of conjugation of one face with the rear surface of the block along the inner bearing layer is located at a length of 363 mm with the continuation of the bearing inner layer along this face. Mating rib

another face with the front surface of the block along the front layer is located at a length of 198 mm

The third block of bay windows is made rectangular with two faces along one of the ends located at an angle of 45 °. The interface rib of one face with the rear surface of the block along the inner bearing layer is located at a length of 148 mm. The interface rib of the other face with the front surface of the block along the front layer is located at a length of 363 mm. The face layer is continued along this face, and the continuation of the face layer on the other side of the block forms a protrusion.

The fourth block of bay windows is made rectangular with two faces along one of the ends located at an angle of 45 °. The edge of conjugation of one face with the rear surface of the block along the inner bearing layer is located at a length of 313 mm with the continuation of the bearing inner layer along this face. The interface rib of the other face with the front surface of the block along the front layer is located at a length of 198 mm. A continuation of the face layer on the other side of this block also forms a protrusion.

The fifth block of bay windows is made in cross section in the form of an isosceles triangle and an isosceles trapezoid, joined by large bases 303 mm long. The angle between adjacent lateral conjugate faces of the triangle and the trapezoid is 90 °, and the angle at the apex of the triangle is 135 °.

The heat-insulating layer of the fifth block of bay windows is located in section from the trapezoid side and its thickness is less than the height of the trapezoid.

In a preferred embodiment, the width of the protrusions of the third and fourth blocks of the openings is equal to the thickness of the front layer, and the height of the protrusions is 50 mm The thicknesses of the front layer, the heat-insulating layer and the inner bearing layer of the first, second, third and fourth bay window blocks outside the beveled edges are 78, 200 and 120 mm, respectively. The length of the smaller base of the isosceles trapezoid in the section of the fifth block is 92 mm, the thickness of the block as a whole is 320 mm, the distance

from the top of the section triangle to its base is 63 mm, and the distance from the base of the section trapezoid to the interface plane of the heat-insulating layer and the concrete layer is 73 mm.

In the best embodiment of the utility model, the height of the blocks is 190 mm. Screeds are made in the form of rods of plastic mass, which can be reinforced. The front and inner bearing layers are made of porous concrete. The thermal insulation layer is made of foam.

In figures 1, 2 and 3 of the drawings shows three sizes of three-layer row blocks, and in figures 4, 5 and 6 - three sizes of corner blocks.

The ordinary blocks are made with a supporting inner layer 1 and a front layer 2 of concrete. The inner heat-insulating layer 3 is made of foam. The layers are connected by transverse screeds 4 passing through the heat-insulating layer 3. The ends of the screeds 4 are embedded in the front layer 1 and in the inner carrier layer 2.

The thickness of ordinary blocks is 398 mm, and the lengths are, respectively, 198, 298 and 398 mm. The thicknesses of the front, heat-insulating and inner bearing layers are 78, 200 and 120 mm, respectively.

Two corner blocks shown in figures 4 and 5 are made with a thickness and length of 398 mm three-layer with a supporting inner layer 1, the front layer 2 and the heat-insulating layer 3. The layers are connected by transverse ties 4 passing through the heat-insulating layer 3 and the ends are embedded in the front layer 2 and into the inner carrier layer 1.

Shown in figure 4, the first corner block is made with a shortened front layer 2 and L-shaped in cross section of the insulating layer 3.

The second corner block shown in FIG. 5 is made with a shortened supporting inner layer 1 and a L-shaped in cross section heat-insulating layer 3.

The protruding parts 5 and 6 of the insulating layers of the first and second corner blocks are made in the form of extensions to the main part of the insulating layer. The extension 5 of the first corner block is connected by a screed 7 with the main part of the insulating layer. The extension 6 of the second corner block is connected by a longitudinal screed 8 with the inner supporting layer. The length (in cross section) of the extension (5) of the first corner block is 120 mm. The extension (6) of the second corner block is 80 mm long. The thicknesses of the front layer 2, the heat-insulating layer 3 and the inner carrier layer 1 are 78, 200 and 120 mm, respectively.

Figure 6 shows a third corner block with a L-shaped face layer 2, the cavity of which is filled with a heat-insulating layer 3. The layers of this block are also connected by transverse ties 4 passing through the heat-insulating layer 3 and embedded in the face layer 2. The thickness of this corner block is 198 mm and the length is 398 mm. The thickness of the front layer of the third corner block is 78 mm.

In figures 7, 8 and 9 of the drawings shows three types of rectangular blocks of openings made with front 2, thermal insulation 3 and bearing 1 layers.

For fastening and sealing the frame boxes, these blocks are made with protrusions 9 formed by the continuation of the front layer 2.

In figures 7 and 8 shows blocks made with protrusions on one side. Figure 9 shows a block with protrusions 9 from two opposite sides.

The bearing inner layer 1, the front layer 2 and the inner heat-insulating layer 3 of the first block of the opening are connected by a transverse coupler 4 passing through the layer 3 and terminated by the ends in the face layer 2 and in the bearing layer 1.

The heat-insulating layer of the blocks of the openings on the side of the protrusions is covered by a layer of concrete 10, the thickness of which is 50 mm

The width of the protrusions of 9 opening blocks is equal to the thickness of the front layer, and the height of the protrusions is 50 mm. The thickness of the opening blocks is 398 mm. Lengths by

the front layer of the first and second blocks are 398 mm (Fig. 7) and 198 mm (Fig. 8). The length of the third block of the opening (Fig. 9) along the front layer is 398 mm. The thicknesses of the face layer 2, the heat-insulating layer 3 and the inner bearing layer 1 of the opening blocks make up a single system with the above-described blocks, 78, 200 and 120 mm, respectively.

Figure 10, 11, 12 and 13 shows four types of pairing unit in the form of rectangular parallelepipeds made of heat-insulating 3 and concrete layers connected by a screed 4, the end of which is embedded in a concrete layer and passes through the heat-insulating layer 3.

The lengths of all interface blocks are 398 mm.

The first block (figure 10) of the interface is made with a front layer 2 of concrete and a width of 198 mm Its thickness is 78 mm.

The second block (11) of the interface is made of square cross-section with the carrier layer 1 having a thickness of 278 mm

The third conjugation block (Fig. 12) is also made of a square section with a L-shaped carrier layer 1, in the cavity of which a heat-insulating layer 3 is located. The thickness of the carrier layer 1 of the third conjugation block is 278 mm, and the width of its protrusion is 11-78 mm.

The fourth block (Fig. 13) of the interface is made with a L-shaped heat-insulating layer 3, in the cavity of which the face layer 2 is located. The thickness of the face layer 2 is 78 mm, and the width of the protrusion is 12-80 mm. Screed 12 reinforces the insulating layer 3.

Figures 14-18 show bay window blocks.

Four of the bay window blocks (Figs. 14-17) have a thickness of 398 mm with front 2, heat-insulating 3 and load-bearing 1 layers connected by a screed 4 passing through the heat-insulating layer 3 and terminated by the ends in the front layer 2 and in the carrier layer 1.

The first block of bay windows (Fig. 14) is made rectangular with two faces 13 and 14 along one of the ends located at an angle of 45 °. The interface between the face 13 and the rear surface 15 of the block along the carrier layer 1 is located at a length of 198 mm. The interface between the face 14 and the front surface 16 of the block along the front layer 2 is located at a length of 363 mm, and the front layer 2 is continued along the side 14.

The second block of bay windows (Fig. 15) is also rectangular with two faces 17 and 18 along one of the ends located at an angle of 45 °. The interface rib of the face 18 with the rear surface 19 of the block along the carrier layer 1 is located at a length of 363 mm with the continuation of the carrier layer along this face 18. The edge of the interface of the face 17 with the front surface 20 of the block along the front layer 2 is located at a length of 198 mm.

The third block of bay windows (Fig. 16) is made rectangular with two faces 21 and 22 along one of the ends located at an angle of 45 °. The interface between the face 21 and the rear surface 23 of the block along the bearing layer 1 is located at a length of 148 mm. The interface between the face 22 and the front surface 24 of the block along the front layer 2 is 363 mm long, and the face layer 2 is extended along this face, and the extension of the front layer from the other end of the block forms a protrusion 25.

The fourth block of bay windows (Fig. 17) is made rectangular with two faces 26 and 27 along one of the ends located at an angle of 45 °. The interface rib of the face 26 with the rear surface of the block 28 along the inner carrier layer 1 is located at a length of 313 mm with the continuation of the carrier layer 1 along the edge 26. The rib of interface between the edge 27 and the front surface 29 of the block along the front layer 2 is located at a length of 198 mm. The continuation of the face layer 2 from the other end of the block forms a protrusion 30.

The width of the protrusions of the third (25) and fourth (30) blocks of the openings is equal to the thickness of the front layer 2, and the height of the protrusions 25 and 26 is 50 mm

The thicknesses of the front layer 2, the heat-insulating layer 3 and the carrier layer 1 of the first, second, third and fourth bay window blocks (Figs. 14-17) outside the borders of the beveled edges, respectively 14, 18, 22 and 26, are respectively 78, 200 and 120 mm

The heat-insulating layer 3 of the third and fourth bay window blocks from the side of the protrusions 25 and 30 is covered with a concrete layer 31, the thickness of which is 50 mm.

The fifth block of bay windows (Fig. 18) has a thickness of 320 mm with a layer of concrete 31 and a heat-insulating layer 3 connected by a screed 4, the end of which is embedded in concrete layer 32 and passes through the heat-insulating layer 3. The block is made in cross section in the form of paired with large bases of length 303 mm of an isosceles triangle and an isosceles trapezoid, the angle between adjacent side faces 33 and 34 of which is 90 °, and the angle 35 at the apex of the triangle is 135 °.

The thermal insulation layer 3 of the fifth block of bay windows is located (in cross section) on the trapezoid side and its thickness is less than the height of the trapezoid. The length of the smaller base of the isosceles trapezoid in cross section is 92 mm. The thickness of the block as a whole (vertical dimension in FIG. 18) is 320 mm. The distance from the top of the triangle 35 to its base is 63 mm, and the distance from the base of the section trapezoid to the interface plane 36 of the heat-insulating layer 3 and the concrete layer is 32-73 mm.

All blocks in the best embodiment of the utility model have a height of 190 mm.

Ties 4 are made in the form of rods of plastic mass, reinforced plastic mass or of metal reinforcement. Preference should be given to reinforced plastics, for example fiberglass.

Porous concrete is used for concrete layers, however, other types of lightweight concrete may be used depending on specific options. Thermal insulation layers are foam.

For the manufacture of blocks, collapsible forms with precisely sustained dimensions and angles are used. Any deviations are not allowed. The mold is filled with concrete to form the first layer, on top of which a heat-insulating foam block is laid, through which screeds are passed. After that, part of the mold above the foam block is filled with concrete of the bearing layer. Concrete preparation, molding and curing of concrete are carried out by traditional methods, taking into account the type of concrete used. After curing the concrete, the mold is disassembled and the finished block is removed. If necessary, a relief front surface is formed on the blocks. To do this, the corresponding matrix is preliminarily laid at the bottom of the form.

The erection of the walls of buildings is carried out in the usual way. To connect the blocks, a cement-sand mortar is used into which various additives are introduced. The solution is applied on the side surfaces of the front and supporting layers. The gaps between the blocks in the mating zones of the insulating layers can be filled with a foaming composition.

Claims (25)

1. A set of wall blocks for the construction of low-rise buildings, containing sets made in the form of rectangular parallelepipeds of three-layer row blocks of three types and a set of corner blocks of three types, row blocks made with a bearing inner layer and a front layer made of concrete, as well as with an internal heat-insulating layer which are connected by at least one transverse coupler passing through the inner heat-insulating layer and terminated by the ends in the front layer and in the inner supporting layer, the thickness of the ordinary forks is 398 mm and lengths are 198, 298 and 398 mm, respectively, two corner blocks are made with a thickness and a length of 398 mm are also three-layer with a supporting inner layer, a face layer and an internal heat-insulating layer connected by at least one transverse coupler passing through the inner heat-insulating layer and the ends embedded in the face layer and in the inner bearing layer, while one corner block is made with a shortened front layer and a L-shaped cross-section of the heat-insulating layer, and the second corner block is made with a short with a supporting inner layer and a L-shaped cross-sectional heat-insulating layer, the third corner block is made with a L-shaped front layer, the cavity of which is filled with a heat-insulating layer, and the layers of this block are also connected by at least one transverse coupler passing through the internal heat-insulating layer and sealed with the end into the front layer, while the thickness of the third corner block is 198 mm, and the length is 398 mm. 2. The kit according to claim 1, characterized in that the protruding parts of the insulating layers of the first and second corner blocks are made in the form of extensions to the main part of the insulating layer, while the extension of the first corner block is connected by a screed to the main part of the insulating layer, and the extension of the second corner block connected by a longitudinal screed with the inner supporting layer. 3. The kit according to claim 1, characterized in that the thicknesses of the front layer, the insulating layer and the inner bearing layer of the ordinary blocks and the first and second corner blocks are 78, 200 and 120 mm, respectively. 4. The kit according to claim 1, characterized in that the extension length of the first corner block is 120 mm 5. The kit according to claim 1, characterized in that the extension length of the second corner block is 80 mm 6. The kit according to claim 1, characterized in that the thickness of the front layer of the third corner block is 78 mm 7. The kit according to claim 1, characterized in that it is equipped with a set of three types of rectangular blocks of openings made with front, internal heat-insulating and internal bearing layers, as well as with protrusions formed by the continuation of the front layer, and two blocks are made with protrusions with one sides, and the third with protrusions on two opposite sides, the thickness of all blocks of the openings is 398 mm, the lengths of the front layer of the first and second blocks are 398 and 198 mm, and the length of the third block of the opening with two protrusions along the front layer is 398 mm. 8. The set according to claim 7, characterized in that the width of the protrusions of the blocks of the openings is equal to the thickness of the front layer, and the height of the protrusions is 50 mm 9. The kit according to claim 7, characterized in that the thicknesses of the front layer, thermal insulation layer and the inner bearing layer of the opening blocks are 78, 200 and 120 mm, respectively. 10. The kit according to claim 7, characterized in that the heat-insulating layer of the first and second blocks of the openings on the side of the protrusions is closed with a layer of concrete. 11. The set of claim 10, characterized in that the thickness of the concrete layer covering the heat-insulating layer is 50 mm. 12. The kit according to claim 7, characterized in that the supporting inner layer, the front layer and the inner heat-insulating layer of the first opening block are connected by at least one transverse coupler passing through the inner heat-insulating layer and terminated by the ends in the front layer and in the inner carrier layer. 13. The kit according to claim 1, characterized in that it is equipped with a set of four types of interface blocks in the form of rectangular parallelepipeds made of heat-insulating and concrete layers, connected by at least one screed, the end of which is embedded in a concrete layer and passes through the heat-insulating layer, the length of all the interface blocks is 398 mm, the first interface block is made with a front layer of concrete and a width of 198 mm, the second interface block is made of square cross-section with an internal bearing layer of concrete, the third interface block is made the flax is also of square cross section with an L-shaped inner bearing layer of concrete, in the cavity of which a heat-insulating layer is located, and the fourth interface unit is made with a L-shaped heat-insulating layer, in the cavity of which a front layer of concrete is located. 14. The kit according to item 13, wherein the thickness of the concrete front layer of the first interface unit is 78 mm. 15. The kit according to item 13, wherein the thickness of the inner bearing layer of concrete of the second interface unit is 278 mm 16. The set according to item 13, characterized in that the thickness of the inner bearing layer of concrete of the third interface unit is 278 mm, and the width of its protrusion is 78 mm. 17. The kit according to item 13, wherein the thickness of the front layer of concrete of the fourth interface unit is 78 mm, and the width of the protrusion of the insulating layer is 80 mm. 18. The kit according to claim 1, characterized in that it is equipped with a set of bay window blocks of five types, four of which are made 398 mm thick with a front, heat-insulating and bearing inner layers connected by at least one transverse coupler passing through the internal heat-insulating the layer and the ends embedded in the front layer and in the inner supporting layer, and the fifth with a thickness of 320 mm with a layer of concrete and a heat-insulating layer connected by at least one screed, the end of which is embedded in a concrete layer and passes through the heat-insulating oh, while the first block of bay windows is made with two faces along one of the ends located at an angle of 45 °, the rib of conjugation of one face with the rear surface of the block along the inner bearing layer is 198 mm long, and the rib of mating of the other face with the front surface of the block along the front layer is located at a length of 363 mm, and the front layer is extended along this face, the second bay window block is also made with two faces along one of the ends located at an angle of 45 °, the interface rib of one face with the back surface of the block along the inner the bearing layer is located at a length of 363 mm with the continuation of the bearing inner layer along this face, and the interface between the other face and the front surface of the block along the front layer is 198 mm long, the third bay window block is made with two faces along one of the ends located at an angle of 45 °, the interface rib of one face with the rear surface of the block along the inner supporting layer is located at a length of 148 mm, the interface rib of the other face with the front surface of the block along the front layer is located at a length of 363 mm, and along this face longer n is the front layer, and the continuation of the front layer from the other end of the block forms a protrusion, the fourth block of bay windows is also made with two faces along one of the ends located at an angle of 45 °, the rib of conjugation of one face with the rear surface of the block along the inner bearing layer is located at a length of 313 mm with the continuation of the bearing inner layer along this face, and the interface between the other face and the front surface of the block along the front layer is 198 mm long, the continuation of the front layer from the other end of this block also forms a protrusion, the fifth the bay window block is made in cross section in the form of an isosceles triangle and an isosceles trapezoid, joined by large bases 303 mm long, the angle between adjacent side faces of which is 90 °, and the angle at the apex of the triangle is 135 °, while the heat-insulating layer of this block is located in the section from the trapezoid side and its thickness is less than the height of the trapezoid. 19. The kit according to p. 18, characterized in that the width of the protrusions of the third and fourth blocks of bay windows is equal to the thickness of the front layer, and the height of the protrusions is 50 mm 20. The kit according to p. 18, characterized in that the thickness of the front layer, thermal insulation layer and the inner bearing layer of the first, second, third and fourth bay window blocks outside the beveled edges are 78, 200 and 120 mm, respectively. 21. The kit according to claim 18, characterized in that the length of the smaller base of the isosceles trapezoid in the section of the fifth block is 92 mm, the thickness of the block as a whole is 320 mm, the distance from the top of the triangle of the section to its base is 63 mm, and the distance from the base of the trapezoid sections to the interface plane of the insulating layer and the concrete layer - 73 mm. 22. The kit according to claim 1, characterized in that the height of the blocks is 190 mm 23. The kit according to claim 1, characterized in that the couplers are made in the form of rods of plastic mass reinforced with plastic mass. 24. The kit according to claim 1, characterized in that the front and inner bearing layers are made of porous concrete. 25. The kit according to claim 1, characterized in that the heat-insulating layer is made of foam.