RU2431023C2 - Light insulation building unit - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: light heat-insulation building unit arranged in internal and external walls of a building and formed from bubble synthetic resin, comprises a connecting ledge on the upper side, so that when it is laid, no cavity is formed, a connecting slot in the basement of the unit corresponding to the connecting ledge, and also a protruding section and a section of the slot arranged on the front and rear surfaces of the unit. At the same it is equipped with an auxiliary unit having the same shape as the heat insulation unit, which is cut as "L" on a segment of the upper section of its one surface, and has a ledge of cylindrical shape on the upper section of the cut element, and is joined to one side of the heat insulation unit. Also versions of the units are described.

EFFECT: development of units that make it possible to complete treatment of building walls by attachment of a finishing material to a unit, reduction of costs, simplified process of unit formation.

13 cl, 21 dwg

Description

The present invention relates to a lightweight insulating building block and a method for its manufacture, in particular to a lightweight insulating building block for decorating the internal and external walls of a building by applying finishing material to the main body of the block, including lightweight bubble synthetic resin, thereby reducing material costs , simplifying the process of creating a block and reducing energy consumption by 80-90%, which is comparable to a given room.

The blocks that are used to build walls are usually made by mixing cement and additives in a predetermined proportion, then this mixture is placed in a special frame, from which it is removed after hardening. These blocks are mainly used for construction and easily accessible construction, such as building partitions. Neighboring blocks are connected to each other using a mortar, then stacked, creating the required walls.

In this regard, despite the fact that cement blocks and bricks are known in Korean Lined U.M. Publication Application No. 1992-15206, Korean Registration U.M. Publication of Application No. 346650, etc., when these blocks are laid in the inner and outer walls of the building, a separate heat-insulating material must be installed in the outer wall, because this wall is hollow, and the finishing process must be carried out both inside and outside the building.

According to generally accepted technology, construction efficiency decreases, and the construction of an internal partition is accompanied by a finishing process after laying the blocks. In addition, the blocks are entirely formed from cement mortar, which increases the cost of their production. When constructing the wall surface of a multi-story building, the service life of this building is reduced due to the loading of blocks.

An object of the present invention is to provide a lightweight heat-insulating building block formed of bubble synthetic resin that is laid in the inner and outer walls of a building and contains a connecting protrusion on its upper side, so that when laying the block, a cavity is formed, the connecting groove in the base of the block corresponding to the connecting protrusion as well as a protruding portion and a groove portion on the front and rear surfaces of the block.

The lightweight insulating building block and the method of its manufacture according to the present invention completes the processing of the internal and external walls of the building by attaching the finishing material to the block, including a light bubble synthetic resin; thereby reducing material costs, simplifying the process of forming a block and reducing energy consumption by 80-90%, which is comparable to a given room, in addition, due to the excellent thermal insulation of the block, condensation prevention efficiency, cooling efficiency and heat efficiency are increased, and the small weight of the block prevents reduction building service life.

The above and other features and advantages of the present invention will become more apparent from the detailed description of embodiments of this invention with reference to the attached drawings, where:

Figure 1 is a perspective view of a lightweight insulating building block according to one embodiment of the present invention;

Figure 2 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention;

Figure 3 is a side view on the right of the lightweight heat-insulating building block shown in Figure 2;

Figure 4 is a perspective view of a lightweight insulating building block according to another embodiment of the present invention;

5 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention;

6 is a left side view of the lightweight heat-insulating building block shown in FIG. 5;

Fig.7 is a front view, side view and a top view of the lightweight heat-insulating building block shown in Fig.1;

Fig. 8 is a perspective view of a lightweight heat insulating building block according to another embodiment of the present invention;

Fig.9 is a cross section of a lightweight insulating building block shown in Fig.8, taken along the line aa;

Figure 10 is a partial perspective view of a lightweight heat-insulating building block shown in Figure 8;

11 is a view of a lightweight heat-insulating building block shown in FIG. 8 in a normal state;

12 is a perspective view of a lightweight insulating building block according to another embodiment of the present invention;

Fig.13 is a side view of a lightweight heat-insulating building block shown in Fig.12;

FIG. 14 is a partial perspective view of a lightweight heat insulating building block shown in FIG. 12;

15 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention;

Fig. 16 is a sectional view of a lightweight heat-insulating building block shown in Fig. 15 taken along line BB;

FIG. 17 is a partial perspective view of a lightweight heat-insulating building block shown in FIG. 15;

Fig. 18 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention;

Fig. 19 is a side view of a lightweight heat insulating building block shown in Fig. 18;

Fig. 20 is a partial perspective view of a lightweight heat-insulating building block shown in Fig. 18; and

21 is a perspective view for explaining a method of constructing a lightweight heat-insulating building block according to one embodiment of the present invention.

The present invention will be described more fully with reference to the accompanying drawings.

Figure 1 presents a perspective view of a lightweight heat-insulating building block according to one embodiment of the present invention, Figure 2 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention, Figure 3 is a side side view of a lightweight heat-insulating building block, shown in FIG. 2, FIG. 4 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention, FIG. 5 is a perspective view ve lightweight thermal insulation building block according to another embodiment of the present invention, FIG. 6 is a left side view of the lightweight thermal insulation building block shown in FIG. 5, and FIG. 7 is a front view, side view and a top view of a lightweight thermal insulation building block, shown in figure 1.

In FIG. 1-7, the heat-insulating block 1, which is laid in the internal and external walls of the building, is formed of lightweight bubble synthetic resin and contains a connecting protrusion 11 on its upper side, so that due to the cavity that is formed during installation, the thermal bridge and migration are not observed moisture, a connecting groove 12 formed in the base and corresponding to the connecting protrusion 11, the protruding portion 13 and the groove portion 14 formed on the front and rear surfaces.

The auxiliary unit 6, which is made in the same shape as the heat-insulating unit 1, is cut in the form of “на” on a part of the upper portion of one of its surface and has a protrusion 15 of a cylindrical shape on the upper portion of the cut out element, attached to one side of the heat-insulating unit 1.

Section 17 of the notched groove is formed in the center of the upper portion of the heat-insulating block 1. A protrusion 15 of a cylindrical shape is formed on the upper portion of the cut out element.

Cross block 7, in which a connecting protrusion 11 is made, having one bent end and continuing in the upper section of the block, a connecting groove 12 formed at the base of the block, a protruding section 13 and a groove section 14 formed on the front and rear surfaces of the block, part of the section the base of the block, cut in the shape of "┐", a groove 16 of a cylindrical shape, made on the upper portion of the cut out element and connected to the heat-insulating block 1 having a protrusion 15 formed in the longitudinal direction or at right angles .

The heat-insulating block 1, the auxiliary block 6 and the cross block 7 are connected to each other by vertical introduction of the connecting protrusion 11 into the vertical connecting groove 18 located perpendicular to one side of their base.

The protruding portion 13 formed on the front and rear surfaces of the heat-insulating unit 1, the auxiliary unit 6 and the cross unit 7 expands towards the outer sides and has a wedge-shaped shape so that zones for cement mortar are formed on both sides of the protruding portion 13.

The protruding portion 13 and the groove portion 14 formed on the front and rear surfaces of the heat insulating unit 1, the auxiliary unit 6, and the cross unit 7 are lattice-shaped.

A number of sections of the groove 14, which blocks and divides the front or rear surfaces of the heat-insulating block 1, the auxiliary block 6 and the cross block 7, are made so that the finishing materials are poured into the sections 14 of the groove, and also supported and fixed in the front or rear surfaces.

On the upper section of the connecting protrusion 11 of the heat-insulating unit 1, a trough 111 for pouring a binder material filled with an adhesive is used, which is used for a strong connection.

A wire mesh (not shown) is inserted into the heat-insulating block 1 to increase adhesion and strengthen the internal strength of the bandaged hand-masonry wall perpendicularly and horizontally.

Fillable groove 19 is formed horizontally in the corners of the front and rear plates of the heat-insulating block 1.

A fillable groove 19 is formed in each corner of the heat-insulating unit 1 in the longitudinal direction; cementing substance is poured into it, which fastens stackable heat-insulating blocks together. This cementitious substance can be either glue, or cement, or plaster, or steel and plastic, or a vice, etc.

Blocking grooves 112 are formed at both ends of the upper portion of the connecting protrusion 11 of each heat-insulating block 1 so as to fix the steel blocking tool.

Finishing material, which is represented either by cement, or plaster, or a steel panel, or wallpaper, or yellow soil, or cement mixed with crumb stone, can be formed on the front and back surfaces of the blocks and have different colors.

In the drawings, the length and dimensions of the layers and zones may be exaggerated for clarity. In addition, all the terms mentioned in this description are generally defined based on the functions that they represent in the present invention, therefore, their definitions may vary, depending on the purpose of the consumer or customer. Therefore, these terms should be defined based on the content of the present invention presented in the present description.

However, this invention can be implemented in many different forms and is not limited to the embodiments proposed in this document. Rather, these embodiments are provided so that this description is thorough and complete, and fully conveys the scope of the invention to those skilled in the art.

In Fig. 1, the heat-insulating block 1, which is laid in the internal and external walls of the building and formed of bubble synthetic resin, contains a connecting protrusion 11 formed on its upper side, so that when laying, a cavity is not formed, the connecting groove 12 in the base of the block corresponding to the connecting the protrusion 11, the protruding portion 13 and the groove portion 14 formed on the front and rear surfaces.

The connecting protrusion 11 of the heat insulating unit 1 is formed horizontally and attached to its corresponding connecting groove 12, but the present invention is not limited to this. The connecting protrusion 11 and the connecting groove 12 may have various shapes, namely, triangular, rectangular, semicircular, etc.

The connecting protrusion 11 is formed on the upper side of the heat-insulating unit 1, the connecting groove 12 corresponding to the connecting protrusion 11 is made in the base, so that the heat-insulating blocks 1 are formed in a perpendicular position.

The heat-insulating block 1 is formed of a bubble synthetic resin, i.e. from bubble polyethylene, which reduces the cost of material and disposal of unit 1.

In Fig. 2, the auxiliary unit 6, formed from a bubble synthetic resin, comprises a connecting protrusion 11 formed on its upper side so that a cavity is not formed during laying, as well as a connecting groove 12 formed at the base of the block and corresponding to the connecting protrusion 11, protruding section 13 and section 14 of the groove formed on the front and rear surfaces, as in the heat-insulating unit 1.

In Fig. 5, the cross block 7 comprises a connecting protrusion 11 having one end of the upper portion, perpendicularly curved in the “┐” shape, a connecting groove 12 formed at the base, a protruding portion 13 and a groove portion 14 formed on the front and rear surfaces.

A portion of the base portion of the cross block 7 is cut in the shape of “┐”, and a cylindrical groove 16 is formed in the upper portion of the cut out element.

Thus, the auxiliary unit 6, in which the cut-out section in the form of "└" is formed, as shown in FIG. 2, the heat-insulating unit 1, in which the section 17 of the notch groove is formed in the center of the upper section, as shown in FIG. 4, and cross block 7, in which the groove 16 is formed, as shown in FIGS. 5 and 6, are connected to each other, thereby creating various shapes, such as the connection structure of the block in the form of a "T" or "+".

One surface of the cross block 7 on which the groove 16 is formed has a rounded shape, and the groove 16 connected to the protrusion 15 is rotated and molded in order to adjust the angle of connection, whereby the cross block 7 can be connected to the heat-insulating block 1.

In Fig. 7, the heat-insulating block 1 contains a plurality of groove sections 14 for blocking and separating the front or rear surfaces of the block, so that the finishing materials are poured into the groove sections 14, and also are held or attached to the front or rear surface of the block. This is necessary in order to prevent cement mortar used as a finishing material (not shown) from falling from the front or back surfaces of the heat-insulating block 1, which will be described later, during the application or hardening of finishing materials in this block, and also to prevent peeling hardened finishing materials from the heat-insulating block 1, so that the cement mortar is poured into many groove sections 14, held and firmly fixed in them.

A fillable groove 19 is formed in each corner of the heat-insulating block 1 in the longitudinal direction, and a cementitious substance is poured into it, so that the stacking heat-insulating blocks can be bonded to each other both in the longitudinal direction and in the up and down directions.

In the meantime, the finishing materials can be fixed to the front or rear surfaces of the heat-insulating block 1 using cement mortar. They can be in the form of a cement panel formed during the hardening of a cement mortar and the addition of various dyes to the plaster, a steel plate, wallpaper, yellow soil, cement mixed with stone chips, etc.

Finishing materials are not limited to plaster, steel panel, wallpaper, yellow soil and cement mixed with stone chips, but can be attached to the front or rear surfaces of the heat-insulating block 1, so as to protect it and at the same time give it an aesthetic appearance.

The cementitious substance may be a cement mortar, a binder, a synthetic resin, a steel or plastic locking tool, plaster, etc. and can give an aesthetic appearance by adding a pattern or dye to it.

As for the installation process of the lightweight heat-insulating building block according to the present embodiment, in order to complete the finishing of the surfaces of the inner and outer walls of the building, the heat-insulating block 1 is fixed to the ground in order to adjoin to a place adjacent to the surfaces of the inner or outer wall, and formed at the base of the heat-insulating block 1, the connecting groove 12 is inserted into the connecting protrusion 11 on the upper side of the heat-insulating block 1, then the heat-insulating block 1 is sequentially bias towards upwardly and longitudinally cementing agent is poured into the filled groove 19 is secured to a binder, etc., so that the heat insulating blocks arranged one fastened to each other in the direction of up, down and longitudinally.

The block in which the cut-out portion having the “┐” shape is formed, and the block in which the cut-out groove portion 17 is formed in the center are attached to the block in which the insertion groove is formed, thereby creating various shapes, such as a block connection structure in form “T” or “+”. If you need a predetermined angle of connection, one surface of the heat-insulating unit 1, in which the groove 16 for insertion is rounded, the groove 16 and the protrusion 15 are connected to each other, and the connection angle is adjustable.

Fig. 8 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention. Fig.9 is a cross section of a lightweight insulating building block shown in Fig.8, taken along the line aa. FIG. 10 is a partial perspective view of a lightweight heat-insulating building block shown in FIG. 11 is a view of a lightweight heat-insulating building block shown in FIG. 8 in a normal state.

In FIG. 8-11, the heat-insulating building block 1, laid in the internal and external walls of the building, contains a connecting protrusion 11 formed on its upper side, so that when laying a number of heat-insulating blocks, a cavity is formed, a connecting groove 12 formed at the base of the block and corresponding to the connecting protrusion 11, cross groove sections 3, curved from the edge of the containing portion 2 of the heat-insulating block 1 on its front and rear surfaces, a heat-resistant panel 4 formed from one of the lists spliced materials: a plasterboard, spar or glass wool coating, which is inserted into the internal groove section 31 located in the cross groove section 3, the finishing panel 5, formed from one of the following materials: stone, concrete reinforced with steel fibers, drive, PVC , metal inserted externally into a groove portion 32 located in a cross groove portion 3 and having a filler channel 321 on one side.

The heat-insulating block 1 is formed of a light bubble synthetic resin, i.e. made of bubble polyethylene, and serves as the finish of the internal and external walls of the building, reducing material costs, simplifying the workflow and reducing the duration of construction.

The distance between the cross groove portion 3 in the heat insulating unit 1 and the internal groove portion 31 may be greater than the distance between the cross groove portion 3 and the outer groove portion 32.

The heat-resistant panel 4, inserted into the internal groove section 31, is made of light heat-resistant material and has the characteristics of waterproof, sound insulation and heat performance. At the same time, as stucco, spar and glass wool coating are widely known, the present invention does not duplicate their specific characteristics.

The characteristics of the stone material reinforced with steel fibers of concrete and driveite, which differ from the characteristics of PVC and metal, which are usually used as finishing materials, will now be briefly described.

Despite the fact that stone material is relatively expensive to use as a material for an external wall, it is often used as a decorating component due to its high strength and unprocessed uneven texture of the external wall. Although this stone material is used for the entire exterior wall, the stone wall can be partially mixed with other substitute material to reduce construction costs and individual presentation.

Concrete reinforced with steel fibers unevenly places a single-phase steel fiber instead of traditional steel and disperses it in concrete to prevent tearing and increase wear resistance. Since this panel is mixed with steel fiber and has increased wear resistance, it does not deform from rain, wind, heat and has good indicators of proportional intensity and compression force.

Drayvit is a material that has a different texture and has good wear resistance without changing color. It is formed by mixing 100% polyacrylate, a chemical material and special quartz sand. If the drive is used to decorate an external wall, there is no need for additional heat-resistant and waterproof structures, and the wall has a light structure, which reduces the cost of structuring. Drivit has a different texture and colors, preventing cracks, due to its prevention of condensation, normal temperature and wet effect, and also maximizes water resistance and wear resistance.

The heat-resistant panel 4 and the finishing panel 5 of the present invention can be selected from a panel having the appropriate characteristics necessary for consistency with the structure of the building.

Next, the assembly process of the lightweight heat-insulating building block of the present invention will be described.

The heat-resistant panel 4 is inserted into the internal groove section 31 located in the cross groove section 3 of the heat-insulating unit 1. After that, the finishing plate 5 is inserted into the external groove section 32.

An inorganic binder is poured into the filler channel 321 formed on one side of the finish plate 5, so that the finish plate 5 is firmly attached to the heat-insulating block 1. A series of heat-insulating blocks 1, in which the heat-resistant panel 4 and the finish panel 5 are sequentially fixed to the front and rear surfaces , stacked by placing the connecting groove 12 of the heat-insulating unit 1 in the connecting protrusion 11 of the main heat-insulating unit 1.

Before describing lightweight heat-insulating building blocks according to the following embodiments of the present invention, it should be noted that since the characteristics of the heat-resistant and finishing panels, as well as the assembly process of the blocks according to the following embodiments, are similar to those described with reference to FIG. 8-11, their specific description will not be repeated.

12 is a perspective view of a lightweight insulating building block according to another embodiment of the present invention. Fig. 13 is a side view of a lightweight heat insulating building block shown in Fig. 12. Fig. 14 is a partial perspective view of a lightweight heat insulating building block shown in Fig. 12.

In FIG. 12-14, the heat-insulating block 1, which is laid in the inner and outer walls of the building and made of bubble synthetic resin, contains a connecting protrusion 11 on its upper side, so that during the laying of a number of heat-insulating blocks there is no cavity, and the connecting groove 12 formed in it the base and corresponding to the connecting protrusion 11, the protrusion 15 of a cylindrical shape, cut in the form of "└" from a part of one surface of the upper section of the block, and located on the upper section of the cut out element, cross groove sections 3 that are cross-curved from the edge of the heat-insulating block 1 portion containing them 2 on its front and rear surfaces, a heat-resistant panel 4 formed from one of the following materials: a plasterboard, spar or glass wool coating inserted into the internal groove section 31, located in the cross-groove section 3, the finishing panel 5, formed from one of the following materials: stone, concrete reinforced with steel fibers, drive, PVC, metal, inserted externally into the groove section approx 32 disposed in a cross-section grooves 3 and having one side filler chute 321.

A perpendicular connecting groove 18 is formed perpendicularly in one of the lower sides of the base of the heat-insulating unit 1 and is attached to its connecting protrusion 11.

15 is a perspective view of a lightweight insulating building block according to another embodiment of the present invention. Fig. 16 is a sectional view of the lightweight heat insulating building block shown in Fig. 15 taken along line BB. FIG. 17 is a partial perspective view of a lightweight heat-insulating building block shown in FIG.

In FIG. 15-17, the heat-insulating block 1, which is laid in the internal and external walls of the building and formed of bubble synthetic resin, contains a connecting protrusion 11 formed on its upper side, so that when laying a number of heat-insulating blocks, a cavity, a connecting groove 12, formed at the base block and corresponding to the connecting protrusion 11, the section 17 of the notch groove formed in the center of the upper section of the heat-insulating block 1, the round protrusion 2 formed in the upper section is cut out about the element, cross groove sections 3, curved from the edge of the heat-insulating block 1 section containing them 2 on its front and rear surfaces, heat-resistant panel 4 formed from one of the following materials: a plasterboard, spackled or glass wool coating that is inserted into the internal groove section 31, located in the cross-groove section 3, the finishing panel 5, formed from one of the following materials: stone, concrete reinforced with steel fibers, drive, PVC, metal, inserted externally into a groove portion 32 located in the cross groove portion 3 and having a filler channel 321 on one side.

A perpendicular connecting groove 18 formed perpendicularly in one of the lower sides of the base of the heat-insulating unit 1 and attached to its connecting protrusion 11.

Fig. 18 is a perspective view of a lightweight heat-insulating building block according to another embodiment of the present invention. Fig. 19 is a side view of a lightweight heat-insulating building block shown in Fig. 18. FIG. 20 is a partial perspective view of a lightweight heat-insulating building block shown in FIG.

In FIG. 18-20, the heat-insulating block 1, laid in the internal and external walls of the building and formed of bubble synthetic resin, contains a connecting protrusion 11 formed on its upper side, so that when laying a number of heat-insulating blocks, a cavity, a connecting groove 12, formed at the base block and corresponding to the connecting protrusion 11, the protrusion 15 of a cylindrical shape, cut in the form of "┐" from part of one surface of the base portion of the block and located on the upper portion of the cut out ele ment, cross groove sections 3, cross-curved from the edge of the containing portion 2 of the heat-insulating block 1 on its front and rear surfaces, heat-resistant panel 4 formed from one of the following materials: a plasterboard, slagged or glass wool coating inserted into the internal groove section 31, located in the cross-groove section 3, the finishing panel 5, formed from one of the following materials: stone, concrete reinforced with steel fibers, drive, PVC, metal, inserted from the outside into a basic section 32 located in a cross groove section 3 and having a flood channel 321 on one side.

At the same time, FIG. 21 is a perspective view for explaining a method of constructing a lightweight heat-insulating building block according to one embodiment of the present invention. In this drawing, the method of construction of a lightweight heat-insulating building block comprises the principle of constructing the installation process of a number of steel profiles 9 perpendicular to the floor 8 of the base of the building; laying a number of heat-insulating blocks 1 formed of foam material between these profiles 9; the creation of finishing material on the inner and outer surfaces of the laid heat-insulating blocks 1; applying the desired color to the surface of the finishing material built on the outer surface of the heat-insulating blocks 1.

In principle, the construction process, a number of steel profiles 9 is installed perpendicular to the base of the floor 8 of the building. The base of the floor 8 is usually made of concrete and leveled in such a way as to evenly lay the insulating blocks 1.

Steel profiles 9 refer to bars in the form of a bar having various transverse shapes, and may be steel forms H, which are mainly used in the construction of a building.

Additionally, this method comprises applying a binder to the upper side of the heat-insulating block 1 located in its lower section, so as to strengthen the connection of the heat-insulating blocks 1 during their installation, thus preventing the movement of a number of stacked blocks and increasing their binding force.

When a series of thermal insulation blocks 1 is completely laid, the finishing material is built on the internal and external surfaces of these blocks in order to protect the building from various external influences and give it a good appearance.

Finishing material is one of the following materials: cement, plaster, wallpaper, yellow soil and cement mixed with stone chips.

And finally, when applying the desired color to the surface of the finishing material built on the outer surface of the heat-insulating blocks 1, partial painting and drawing are performed in order to bring people aesthetic pleasure when viewing the building from the outside.

While the present invention has been shown and described in detail with reference to examples of its implementation, it will be understood by those of ordinary skill in the art that various changes in form and detail can be made here without departing from the spirit and scope of this invention as defined in the appended claims. These examples of implementation should be taken into account only in a descriptive sense, and not for purposes of limitation. Therefore, the scope of the present invention is determined not by a detailed description of the invention, but by the appended claims, and all discrepancies with the scope of this invention will be construed as being included in the present invention.

Claims (13)

1. A lightweight heat-insulating building block located in the inner and outer walls of the building and formed from bubble synthetic resin containing a connecting protrusion on the upper side, so that when it is laid, a cavity is not formed, the connecting groove in the base of the block corresponding to the connecting protrusion, and also protruding a section and a section of a groove located on the front and rear surfaces of the block, while the auxiliary block having the same shape as the heat-insulating block is cut out in the form "

"On the segment of the upper section of one of its surface, and has a protrusion of a cylindrical shape on the upper section of the cut out element, and is attached to one side of the heat-insulating block. 2. A lightweight heat-insulating building block located in the inner and outer walls of the building and formed of bubble synthetic resin containing a connecting protrusion on the upper side, so that when it is laid, a cavity is not formed, the connecting groove in the base of the block corresponding to the connecting protrusion, and also protruding a section and a section of a groove located on the front and rear surfaces of the block, in which the cut groove section is located in the center of its upper section, and the protrusion of the cylindrical we are made on the upper section of the cut-out element, in which a cross block is formed with a connecting protrusion having one curved end and continuing in the upper section of the heat-insulating block, a connecting groove made in the base of the block, a protruding section and a groove section formed on the front and rear surfaces of the block , part of the section of the base of the block, cut in the shape of "

", And a groove of cylindrical shape for insertion, located in the upper portion of the cut-out element, is attached to the heat-insulating block, in which the protrusion is formed in the longitudinal direction or at right angles. 3. The lightweight heat-insulating building block according to claim 1 or 2, in which the connecting protrusion of the blocks is placed in a vertical connecting groove formed perpendicular to one side of the base of the blocks. 4. The lightweight heat-insulating building block according to claim 1 or 2, wherein the protruding portion formed on the front and rear surfaces of the blocks expands to the outside and has a wedge-shaped shape so that zones for pouring mortar are formed on both sides of the protruding portion. 5. The lightweight heat-insulating building block according to claim 1 or 2, in which the protruding portion and the groove portion formed on the front and rear surfaces of the blocks are lattice-shaped. 6. The lightweight heat-insulating building block according to claim 1, wherein the gutter horizontally filled with a binder is located in the upper portion of the connecting protrusion of the heat-insulating block. 7. The lightweight heat-insulating block according to claim 1, into which a fully-shaped wire mesh is inserted to increase traction. 8. The lightweight heat-insulating building block according to claim 1, wherein the fillable trough is located horizontally in the corners of the front and rear panels of this block. 9. A heat-insulating block located in the inner and outer walls of the building, comprising: a connecting protrusion formed on its upper side, so that when laying a number of heat-insulating blocks, a cavity does not form, a connecting groove made in the base of the block and corresponding to the connecting protrusion;
cross groove sections cross-curved from the edge of the heat-insulating block portion containing them on its front and rear surfaces;
heat-resistant panel formed from one of the following materials:
a plasterboard, slag or a glass wool coating that is inserted into an internal groove section located in a cross groove section; and
a finishing panel formed from one of the following materials: stone, concrete reinforced with steel fibers, drive, PVC, metal, inserted externally into a groove section located in a cross groove section and having a flood trough on one side. 10. A heat-insulating block placed in the internal and external walls of the building, formed from bubble synthetic resin and containing:
a connecting protrusion located on its upper side, so that when laying a series of heat-insulating blocks, a cavity does not form, a connecting groove in the base of the block corresponding to the connecting protrusion; protrusion of a cylindrical shape, cut in the form of "

"On the part of one surface of the upper section of the block, and located on the upper section of the cut out element, cross groove sections that are cross-curved from the edge of the heat-insulating block section containing them on its front and rear surfaces; and
a heat-resistant panel formed from one of the following materials: a plasterboard, slag or a glass wool coating inserted into an internal groove section located in a cross groove section, a finishing panel formed from one of the following materials: stone, concrete reinforced with steel fibers, drive, PVC, metal, inserted externally into a groove section located in a cross groove section and having a flood trough on one side. 11. A heat-insulating block located in the internal and external walls of the building, formed of bubble synthetic resin and containing a connecting protrusion on its upper side, so that when laying a number of heat-insulating blocks, a cavity is formed, a connecting groove located at the base of the block and corresponding to the connecting protrusion; a section of a notch groove located in the center of the upper portion of the heat-insulating block and a protrusion of a cylindrical shape formed in the upper portion of the notch element;
cross groove sections, cross-curved from the edge of the heat-insulating block section containing them on its front and rear surfaces, heat-resistant panel formed from one of the following materials:
a plasterboard, slag or a glass wool coating that is inserted into an internal groove section located in a cross groove section, a finishing panel formed from one of the following materials:
stone reinforced with steel fibers concrete, drive, PVC, metal inserted externally into a groove section located in a cross groove section and having a flood trough on one side. 12. A heat-insulating block located in the inner and outer walls of the building, formed from bubble synthetic resin and containing a connecting protrusion on its upper side, so that when laying a series of heat-insulating blocks a cavity is formed, a connecting groove located at the base of the block and corresponding to the connecting protrusion;
protrusion of cylindrical shape, carved in the shape of "

»On a segment of one surface of the base portion of the block and formed in the upper portion of the notched element;
cross groove sections, cross-curved from the edge of the heat-insulating block section containing them on its front and rear surfaces, heat-resistant panel formed from one of the following materials:
a plasterboard, slag or a glass wool coating that is inserted into an internal groove section located in a cross groove section, a finishing panel formed from one of the following materials:
stone reinforced with steel fibers concrete, drive, PVC, metal inserted externally into a groove section located in a cross groove section and having a flood trough on one side. 13. A lightweight heat-insulating building block according to claim 9, wherein the inorganic mortar is poured into the flood trough.

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