RU2693071C1 - Structure from foamed concrete and structural reinforcement mesh and method of its erection - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction materials and construction methods using said materials, particularly to a structure of cellular concrete and structural reinforcement mesh and a method for erection thereof. Structure of cellular concrete and structural reinforcement mesh, consisting of structural reinforcement mesh made of laid sheets of metal mesh and arranged around it prefabricated blocks of cellular concrete; wherein the above prefabricated blocks are filled with cellular concrete to form a monolithic structure of prefabricated blocks of cellular concrete and structural reinforcement mesh, wherein said cellular concrete used for casting has porosity of 10–70 %, which increases after erection of erected structure. Besides, its erection method is described.

EFFECT: thus, use of this invention allows reducing the total weight of the structure in comparison with using the traditional reinforced concrete or steel structure by more than 60 %, as well as considerably enhance the anti-seismic and energy-saving characteristics of the structure.

12 cl, 12 dwg

Description

TECHNICAL FIELD TO WHICH INVENTION RELATES.

[0001] This invention relates to building materials and methods of construction using these materials, in particular to the construction of cellular concrete and structural reinforcing mesh and the method of its construction.

BACKGROUND

[0002] Reinforced concrete structures are structural models that are most often used in the field of modern engineering construction, which occupy more than 85% of the total building area of modern construction projects. The stability of the reinforced concrete structure is ensured by the adhesion stress, which is formed due to the characteristics of the rigidity of the concrete and the friction force of the reinforcement cage. The higher the hardness of the concrete, the greater the weight of the structure and the better the stability of the structure; However, this leads to a significant increase in the internal stress and thermal conductivity of the materials of the monolithic structures of the structure, which adversely affects its antiseismic, environmental and energy-saving characteristics. Construction of a building structure is usually carried out by forming a reinforcement cage by tying or welding reinforcing elements, followed by pouring concrete into the reinforcement structure formation section or by connecting prefabricated building modules, for example, building blocks or prefabricated beam plates. Obviously, since traditional reinforced concrete structures form the structural strength and stability of the building mainly due to the adhesion stress arising from the interaction of the concrete with the reinforcement cage, in order to achieve the adhesion stress sufficient to provide the necessary characteristics of the load intensity and stability of the building, increase the use of reinforcement and concrete; however, this leads to a decrease in overall weight

[0003] construction and significant internal stress of the structure, reducing seismic characteristics, and given the possible lack of thermal conductivity properties of the materials used, this can lead to insufficient environmental and energy saving characteristics of the building. As a result, modern reinforced concrete structures as a whole are difficult to rationally correlate with modern requirements for anti-seismic and energy-saving building characteristics. To date, technical solutions for the manufacture of lightweight building blocks of steel mesh filled with foam concrete have been published in this area, for example, Chinese patent CN 2332765 Y, notice dated August 11, 1999, describing a technical solution for making lightweight wall panels using steel mesh and foam concrete which includes the presence of two layers of steel mesh inside the concrete slab, around which reinforcement is installed on all sides; pouring two layers of steel mesh with concrete solution, which includes cement, sand, slag and a foaming agent in appropriate proportions; the presence on the four surfaces of the concrete slab connection of several iron plates for the welded joint device, which are fixed on the reinforcement cage of the slab; welding of wall plates to each other during construction works. Thus, this technical solution changes the basic principle of connection through the tension of adhesion of concrete to the reinforcement cage, using to connect the force of holding the reinforcing mesh with lightweight concrete and the resulting complex equivalent effect of materials. However, such a technical solution as a reinforcement cage uses only reinforcing mesh having a cellular structure, and can only be used to a limited extent for erecting surfaces of non-bearing walls or for manufacturing roofing materials and in no aspect satisfies the strength requirements imposed during the erection of structures; the location of the reinforcing mesh is a complicated process, it requires a device supporting the structure using a frame of reinforcing rods, when erecting a building between the blocks, a device of welded joints is needed, and there is no reliable structural method of joining. International application WO 2005108704 A1, the international publication of which took place on November 17, 2005, describes the building blocks used for wedge joints of flooring panels, partitions and ceiling tiles, which are mainly used for the construction of functional (having natural lighting) structures and are not intended to create lightweight, convenient and durable connection.

[0004] Thus, all the technical solutions closest to the prior art that have been published so far have drawbacks with regard to the materials used and the principles of construction. They do not provide an effective combination of lightness, convenience, high strength and rational distribution of mass, and, as a result, are not able to fully meet the increasingly serious requirements for anti-seismic, energy-saving, environmental and fire-fighting characteristics.

DISCLOSURE OF THE INVENTION

[0005] Considering the foregoing drawbacks of the prior art, the object of the present invention is to provide a cellular concrete structure and structural reinforcement mesh and a method for its construction. This invention, despite the fact that reinforcing rods and cement are used as basic building materials, does not apply to reinforced concrete in its usual meaning, and also has distinctive mechanical principles in comparison with steel structures.

[0006] The construction of cellular concrete and structural reinforcement mesh mentioned in the present invention fully utilizes the holding force created by the relatively high viscosity cellular concrete with respect to the structural mesh made of metal mesh sheets, forms the complex resultant strength of materials to ensure structural stability and at the same time acquires sufficient bearing capacity.

[0007] In accordance with the above purpose, the structure of cellular concrete and structural reinforcement mesh referred to in the present invention is made of structural reinforcement mesh and cellular concrete. The aforementioned cellular concrete includes, but is not limited to, the basic material in the form of cement, lightweight aggregate, hard aggregate, and additives that form cellular and porous lightweight concrete with entrained air.

[0008] The said structural reinforcement mesh is made from metal mesh sheets that are laid in a certain shape, pre-made of cellular concrete blocks (the functional use of which in practice is similar to the functional use of construction formwork used in traditional reinforced concrete monolithic structures), after which the cellular tones for the formation of a monolithic structure of prefabricated blocks of cellular concrete and structural reinforcement mesh. Thus, the construction of cellular concrete and structural reinforcement mesh mentioned in this invention is created. Between the prefabricated blocks, special connecting structures are used, such as tongue-and-groove joints, grooves-protrusion joints, seamless wedge joints, couplings; by adjusting the distribution of the density of the material, especially adjusting the density of the material and rationally choosing its weight in different parts of monolithic structures, it is possible to more scientifically and rationally distribute the total mass of the structure and the load requirements.

[0009] In accordance with the above purpose, the construction of cellular concrete and structural reinforcement mesh, consisting of structural reinforcement mesh, made of stacked sheets of metal mesh, and pre-fabricated blocks of cellular concrete arranged around it; Cellular concrete is poured into the above-mentioned prefabricated blocks to form a monolithic structure of prefabricated cellular concrete blocks and structural reinforcement mesh.

[0010] Further, the intersection points of said metal mesh are a welded structure.

[0011] Further, said welded structure is made by contact welding.

[0012] Further, said structural reinforcement mesh includes reinforcement mesh elements, the cross section of which has the shape O, the shape U, the shape C, the square shape and the rectangular shape.

[0013] Further, the composition of the above-mentioned cellular concrete includes a base material in the form of cement, lightweight aggregate, solid aggregate, and additives.

[0014] Further, the said prefabricated blocks include blocks with paired matching protrusions and grooves, blocks with slots, corner blocks, beam case blocks, variable diameter blocks, beams and plates; Grooved structures are used at the junctions between these prefabricated blocks for their seamless structural connection.

[0015] The method for erecting said cellular concrete construction and structural reinforcement mesh, comprising the following sequence:

[0016] Step 1: in accordance with the requirements for the load at the site of a particular use and the shape of the structure of the structure, select a metal mesh of an appropriate size and cross-section from which the structural reinforcement mesh is made;

[0017] Step 2: prefabricated cellular concrete blocks;

[0018] Step 3: the cellular concrete used for casting is prepared;

[0019] Step 4: in accordance with the load requirements at the site of the specific use and construction form of the structure, said structural reinforcement mesh is installed and the said prefabricated blocks are installed;

[0020] Step 5: cellular concrete is poured into the cavities covered by prefabricated blocks to complete the building structure.

[0021] Further, the porosity used for casting the above-mentioned cellular concrete is consistently increased following the increase in the number of floors of the erected structure.

[0022] Further, the packing density of the above mentioned structural reinforcement mesh during the erection of structures with a relatively low number of floors is greater than the density of the reinforcement mesh during the construction of structures with a relatively high number of floors.

[0023] Further, the types of reinforcement mesh layouts mentioned include layer-by-layer filling with reinforcement, combined reinforcement placement, internal reinforcement installation.

[0024] Further, in the four mentioned steps of the sequence, the structural reinforcement mesh and the prefabricated blocks may be arranged in several rows in accordance with the shape of the structure and the load requirements.

[0025] The beneficial effects of the present invention: the reinforcing mesh and cellular concrete used in the present invention can be used in the erection of building structures and are not limited to traditional use solely for the erection of non-bearing structures (partitions, roofing); The structural reinforcement mesh used in this invention, made by a technical method from a metal mesh, replaces the traditional framework, made by means of armature binding, and a simple metal mesh, harmoniously combining the lightness and mobility of the metal mesh with high strength and high withstand load intensity of the reinforcement cage; as the main force of adhesion, the retention force of the structural reinforcement mesh with cellular concrete is used, which also creates a complex net effect of the materials of the construction of cellular concrete and structural reinforcement mesh, thereby forming a building structure that has sufficient bearing capacity; the size, diameter of the wire, the size and shape of the metal mesh cell used in the structural reinforcement mesh is determined in a rational manner depending on the requirements for the load and the shape of the various sections of the erected structure, while the size and the used volumes of steel wire (reinforcement) are much smaller than the sizes and volumes steel wire (reinforcement) used in the manufacture of the construction of a traditional reinforcement cage; at the same time, cellular concrete poured into the enclosing cavities of the structural reinforcement mesh is used primarily to form the holding force of the structural reinforcement mesh and, unlike traditional concrete, does not require the presence of high levels of withstand load intensity; cellular concrete has a higher ductility, its impact strength greatly exceeds that of traditional solid concrete, has exceptional anti-seismic, thermal insulation, energy-saving characteristics, and also allows to significantly reduce the total weight of the structure. The reinforcing mesh is convenient in operation and allows you to pre-fabricate the appropriate form of construction, the combination of various ways of fitting reinforcement allows you to rationally meet the load requirements of various elements of the structure, extremely effectively reduces the overall stress of the building material, significantly reduces its total weight and allows you to more efficiently distribute the weight of the structure. According to the calculations, the total mass of the structure is lighter than a traditional reinforced concrete structure or steel structure of similar size by more than 60%. At the same time, the internal stress of the structure decreases, the overall flexibility of the structure increases, and its seismic resistance increases significantly; This invention by providing universal blocks of cellular concrete, pre-made on the principle of "tangram" according to the requirements of the relevant building structure, between which seamless structural joints are used, using tongue and groove structures in the form of spikes and teeth, fully uses the breaking strength of the material to eliminate "vulnerable Places "of traditional cement mortar, which are its poor binding characteristics; In addition to this, the present invention allows the use of the filling of columnar sections with cellular concrete instead of the traditional gluing by means of tape filling with a solution, which guarantees the adhesion strength of cellular concrete and structural reinforcement mesh; The use of a porous material as a base material in the construction of a structure also allows a significant increase in its energy-saving characteristics. Thus, this invention completely eliminates the problem of combining the counter-radiation energy-saving and anti-seismic characteristics of traditional reinforced concrete structures, especially in relation to the construction of civilian objects and ordinary multi-storey buildings, significantly increases the construction efficiency and the anti-seismic efficiency of the structures.

BRIEF DESCRIPTION OF THE DRAWINGS

[0026] FIG. 1 is the process of forming a profile (beam) of structural reinforcement mesh and cellular concrete, manufactured in accordance with this invention by forming a metal mesh, followed by pouring cellular concrete;

[0027] FIG. 2 is a type of reinforcement laying for creating a structural reinforcement mesh using a combination of reinforcement with a C-shaped profile and reinforcement for layer-by-layer filling;

[0028] FIG. 3 is a type of reinforcement laying to create a structural reinforcing mesh, using reinforcement with a U-shaped profile and internal styling;

[0029] FIG. 4 is a schematic representation of the process of laying reinforcement, building blocks and pouring concrete;

[0030] FIG. 5 represents the basic configurations of prefabricated building blocks of cellular concrete, including under the designation (A) a block with paired matching protrusions and slots matching each other, under the designation (B) there is a block with slots, under the designation (C) the corner block is represented, the beam case block is represented under the designation (D), the block with a changeable diameter is represented under the designation (E), the beam is represented under the designation (F), the plate is represented under the designation (G);

[0031] FIG. 6 is a schematic representation of the method of using the slotted unit shown in FIG. five;

[0032] FIG. 7 is a schematic representation of the method of applying the corner block shown in FIG. five;

[0033] FIG. 8 is a schematic representation of the method of application of the beam case unit shown in FIG. five;

[0034] FIG. 9 is a schematic representation of the method of applying the one shown in FIG. 5 blocks with variable diameter, in case of its use in low-rise buildings;

[0035] FIG. 10 is a schematic representation of the method of applying the one shown in FIG. 5 blocks with a variable diameter, in case of its use in the construction of multi-storey or high-rise buildings;

[0036] FIG. 11 is a schematic representation of the method of application shown in FIG. 5 beams, in case of its use when roofing;

[0037] FIG. 12 is a schematic representation of the use of structural reinforcement mesh for the construction of a monolithic roof of a building.

[0038] Explanations to the designations in the drawings: metal mesh 1, structural reinforcement mesh 2 with a profile in the shape of C, profile 3 made of structural reinforcement mesh and cellular concrete, reinforcement for layer-by-layer filling 4, structural reinforcement mesh 5 with a profile in the shape of U, liner 5 'structural reinforcement mesh with a U-shaped profile, square structural reinforcement mesh 6, a block with paired matching lugs and grooves 7, a block with slots 8, a corner block 9, a beam case block 10, a block with variable m in diameter 11, beam 12, plate 13.

IMPLEMENTATION OF THE INVENTION

[0039] The construction of cellular concrete and structural reinforcement mesh, consisting of structural reinforcement mesh, made of sheets of metal mesh, and blocks of cellular concrete located around it; Porous material is poured into the aforementioned cellular concrete blocks to form a monolithic construction of cellular concrete blocks and structural reinforcement mesh.

[0040] FIG. 1 right to left shows the process of forming a profile (beam) of structural reinforcing mesh and cellular concrete, produced by pouring cellular concrete with pre-forming metal mesh 1 (the process is depicted from right to left); metal mesh 1 consists of resistance welding of steel wire rods (reinforcement) connected by resistance, dimensions, wire diameter, size and shape of the metal mesh cell are determined depending on the requirements for the load and the shape of different sections of the erected structure.

[0041] In the form of one of the types of conventional structures in FIG. 2 shows the type of reinforcement laying using a combination of structural reinforcement mesh 2 with a profile in the shape of C and reinforcement for layer-by-layer filling 4; in FIG. 3 shows the type of reinforcement laying using a structural reinforcement mesh 5 with a U-shaped profile and an additional liner 5 'of a structural reinforcing mesh with a U-shaped profile; These elements of the structural reinforcement mesh are filled with cellular concrete to cover the structural reinforcement mesh with cellular concrete and to form a holding force.

[0042] FIG. 4 shows the structural connection between the structural reinforcing mesh 6 and the prefabricated blocks; the prefabricated blocks are used as formwork used to construct traditional reinforced concrete monolithic sections; cellular concrete is poured into the cavity covered by the prefabricated blocks to form a monolithic structure that is uniform with the structural reinforcement mesh ;

[0043] FIG. 5 shows the main configurations of prefabricated building blocks of cellular concrete, including a block with paired matching protrusions and grooves under designation (A); a block with slots is represented under designation (B); the block, under the designation (D) is the beam case block, under the designation (E) is the block with a variable diameter, under the designation (F) is the beam, under the designation (G) is the plate;

[0044] FIG. 4 shows a constructional type of erection of a wall of blocks 7 with paired matching protrusions and grooves matching each other, while its supporting structure (represented in the example as a pillar) is erected from a structural reinforcement mesh 6, girdled with units with variable diameter 11; the supporting structure is formed by pouring into the space around the reinforcing mesh an appropriate volume of cellular concrete.

[0045] FIG. 6-8 illustrate methods for using slotted blocks, corner blocks, and beam case blocks shown in FIG. five.

[0046] Methods for using a variable diameter unit 11 are shown in FIG. 9 and FIG. ten; in FIG. 9 a unit with a variable diameter of 11 is used to erect a low-rise structure, each bearing pillar uses a structural reinforcement mesh to ensure that the load requirements are met, and the prefabricated blocks can be laid in rows in accordance with the shape of the structure and the load requirements; in FIG. 10 presents just such a method of using several groups of blocks with a variable diameter 11, covering several structures made of reinforcing mesh, for the construction of a composite supporting structure, which can also be used as a supporting structure for lower floors in the construction of multi-storey and high-rise buildings;

[0047] FIG. 11 is a schematic representation of the method of application shown in FIG. 5 beams, in case of its use when roofing:

[0048] Shown in FIG. 12 structural reinforcement mesh is a type of construction of a monolithic roof slope, where the roof slope consists of a metal mesh 1, beams 12 and plates 13; Laying structural reinforcement mesh 6 with a square cross-section are used as a frame of strapping beams.

[0049] Between all the previously described prefabricated blocks, there are sheet piling structures used to form a structural seamless connection between the prefabricated blocks, unlike traditional brick masonry, the erection of which only uses the joint by gluing bricks with mortar.

[0050] Based on the preparation of the above-described structural elements, said method of construction according to this invention, comprising the following sequence:

[0051] Step 1: preparation of structural reinforcement mesh; first, contact welding is used to fabricate a metal mesh; in accordance with the actual height of the floor and load requirements, calculate the diameter of the wire used, the type and number of steel mesh cells; for example, the usual wire diameter is set to 01, after the completion of the welding, the mesh may be square in size 8 × 8. In a typical situation, the larger the diameter of the wire used, the larger the mesh size, and the worse the holding capacity of the porous material, the specific size of the metal mesh should be determined by performing calculations and experimentally followed by examining the results;

[0052] Step 2: the manufacture of blocks of cellular concrete, which, in accordance with the commonly used types of structures, are made in the form of basic block configurations: a block with matching connecting lugs and grooves matching each other, a block with slots, a corner block, a beam case block , unit with variable diameter, beam and plate; in the joints between the prefabricated blocks, sheet piling structures are used for the seamless structural connection of the blocks;

[0053] Step 3: the preparation of the cellular concrete used for pouring the mortar using conventional foamed concrete or foam concrete manufacturing techniques, the prepared mortar contains irregular cellular pores, the composition of the mortar usually includes base material in the form of cement, lightweight aggregate, solid aggregate and additives; including the lightweight aggregate mentioned includes volatile spherical inclusions, vermiculite, polypropylene granules and / or pulverized fly ash; the additives mentioned include cellulose, powdered glue, short fiber and a water reducing additive. His particular method of preparation does not apply to the protection requirements of this invention and is not described here. This invention in relation to the use of cellular concrete mainly changes the overall density and mass of the concrete solution by adjusting the size and distribution of pores in the above-mentioned cellular concrete, and therefore the porosity of said cellular concrete is controlled in a controlled range of 10-70%; accordingly, relatively low porosity indices are used for foam concrete used in low-rise buildings; For concrete used for casting during the construction of buildings of relatively high altitude, relatively high porosity indices are used. The above measures lead to the formation of a distinctive feature in the structure, which is expressed in reducing the mass of the mortar to be used, which is used in the construction of each subsequent floor of the structure; for example, during the construction of a ten-story building, the mass of the mortar used to fill the first floor is 100%; then the mass of the solution used to fill the second floor will be 95%, the mass of the solution used to fill the third floor will be 90%, the mass of the structure will be reduced by 5% during the construction of each subsequent floor of the structure; at the same time, the combination with the following choice of structural strength of structural reinforcement mesh and the choice of shape allows to achieve highly efficient rational requirements for load distribution.

[0054] Step 4: in accordance with the requirements for the load at the site of a specific use and the form of the structure of the structure, said structural reinforcement mesh is laid and said prefabricated units are installed; structural reinforcement mesh can be made of a flat metal mesh by bending it and giving it a section of shape O, shape U, shape C, square shape to meet the various requirements in bearing capacity and shape of the structure; Also, in accordance with the actual requirements for the load of the structure construction, the direct use of a flat metal grid is allowed, for example, in the construction of non-bearing roofs or walls; Further, for a greater gain of carrying capacity, you can use both a simple type of reinforcement installation and a combined reinforcement installation, internal reinforcement installation and layer-by-layer filling of the cavity filled with reinforcement. A simple type of reinforcement laying implies laying the reinforcement in one row using unshaped metal reinforcement mesh; and for supporting structures such as beams or pillars, a molded structural reinforcement mesh is used using combined or internal types of installation. As shown in FIG. 1, the reinforcement mesh with a cross section in the form With the sides with a cutout interconnects, forming a combined form of reinforcement laying; a simple sheet of reinforcement mesh is placed inside the specified reinforcement packing form for layer-by-layer filling (as shown in Fig. 2) to increase the structural strength and carrying capacity; two elements of the reinforcing mesh, bent into an element with a cross section in the U shape, with cut sides are interconnected (as shown in Fig. 3), forming a reinforcement structure with a cross section in the U shape, reinforced by an internal type of laying, which can also be used to increase the structural strength and bearing capacity.

[0055] Step 5: pouring cellular concrete with a corresponding indicator of porosity into the cavity formed by the said prefabricated unit, to create a monolithic structure from the said prefabricated unit and structural reinforcement mesh and complete the construction of the building structure.

[0056] Thus, unlike traditional reinforced concrete structures and steel structures, a cellular concrete structure and structural reinforcement mesh and the method of its construction according to this invention have the distinctive features listed in Table 1 (See next page).

[0057] Table 1: Comparison of structural characteristics of cellular concrete and structural reinforcement mesh with the characteristics of structures made of traditional reinforced concrete and the characteristics of steel structures

Claims (17)

1. Construction of cellular concrete and structural reinforcement mesh, consisting of structural reinforcement mesh, made of laid sheets of metal mesh, and pre-manufactured blocks of cellular concrete arranged around it; moreover, inside the previously mentioned pre-fabricated blocks, cellular concrete is poured to form a monolithic structure of pre-fabricated blocks of cellular concrete and structural reinforcement mesh, and the cellular concrete used for casting has a porosity of 10-70%, increasing after an increase in the number of floors of the building being constructed. 2. The construction of cellular concrete and structural reinforcement mesh according to claim 1, characterized in that the intersection points of the above-mentioned metal mesh are a welded structure. 3. The construction of cellular concrete and structural reinforcement mesh according to claim 2, characterized in that said welded structure is made by the method of contact welding. 4. The design of cellular concrete and structural reinforcing mesh according to any one of paragraphs. 1-3, characterized in that the said structural reinforcement mesh includes reinforcement mesh elements, the cross section of which has the shape O, the shape U, the shape C, the square shape and the rectangular shape. 5. The construction of cellular concrete and structural reinforcing mesh according to claim 1, characterized in that the composition of the above-mentioned cellular concrete includes the main material in the form of cement, lightweight aggregate, solid aggregate and additives. 6. The construction of cellular concrete and structural reinforcement mesh according to claim 5, characterized in that said lightweight aggregate includes volatile inclusions of spherical shape, vermiculite, polypropylene granules and / or pulverized coal ash; the additives mentioned include cellulose, powdered glue, short fiber and a water reducing additive. 7. The construction of cellular concrete and structural reinforcement mesh according to claim 1, characterized in that the said prefabricated blocks include blocks with paired matching protrusions and grooves matching each other, slotted blocks, corner blocks, frame case blocks, blocks with variable diameter, beams and slabs; Grooved structures are used at the junctions between these prefabricated blocks for their seamless structural connection. 8. The method of construction of the above construction of cellular concrete and structural reinforcing mesh according to any one of paragraphs. 1-7, which includes the following successive steps: Step 1: in accordance with the requirements for the load at the site of a specific use and the form of the structure of the structure, select a metal mesh of an appropriate size and cross-section, from which the structural reinforcement mesh is made; step 2: prefabricated blocks are made of cellular concrete; Step 3: prepare the cellular concrete used for casting; step 4: in accordance with the requirements for the load at the site of a specific use and the form of the structure of the structure, said structural reinforcement mesh is laid and the above-mentioned prefabricated units are installed; Step 5: Cellular concrete is poured into the cavities covered by prefabricated blocks to complete the building construction device, and the porosity used for casting the aforementioned cellular concrete is increased following an increase in the height of the erected structure, while the porosity used for casting cellular concrete is adjusted in the range of 10-70 % 9. The method of construction of the above construction of cellular concrete and structural reinforcement mesh according to claim 8, characterized in that the packing density of the structural reinforcement mesh in the construction of structures with a relatively low number of floors is greater than the density of installation of a reinforcing mesh in the construction of structures with a relatively high number of floors. 10. The method of construction of the above construction of cellular concrete and structural reinforcement mesh according to claim 9, characterized in that the types of reinforcement mesh layouts include layer-by-layer filling of the reinforcement cavity, combined reinforcement placement, internal reinforcement installation. 11. The method of construction of the above-mentioned structure of cellular concrete and structural reinforcement mesh according to claim 8, characterized in that in the four successive steps mentioned, the structural reinforcement mesh and prefabricated blocks can be arranged in several rows in accordance with the shape of the structure and the load requirements. 12. The method of construction of the above construction of cellular concrete and structural reinforcing mesh according to any one of paragraphs. 8-11, characterized by the fact that during the construction of multi-storey buildings, the weight of structural materials of each subsequent floor is reduced by 5% compared with the weight of the previous floor.

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