UA109718U - METHOD OF BUILDING / BUILDING - Google Patents

Abstract

The method of erection of the house / structure, according to which excavation of ditches and / or trenches and preparation of the base, erection of the foundation, carry out measures for waterproofing the structural elements of the house of the structure. Reinforced concrete columns are installed on the erected foundation and they form a vertical part of the three-dimensional frame of the building building. Structural elements of the three-dimensional frame of the house / structure are joined; install the floor slabs with their introduction into the three-dimensional frame of the house / structure with a plane perpendicular to the longitudinal axis of the columns. Install reinforced concrete bulkheads or panels for elevator shafts, reinforced concrete ventilation units, reinforced concrete stairways and marches. Exterior and interior walls are fitted by prefabricated panels or brick construction. Installation of sanitary equipment and other engineering systems is carried out. Roofing is installed, and finishing works are carried out at the final stage of the construction of the house / structure. During the erection of the foundation, at the same time, measures are taken on the waterproofing of structural elements of the house / structure at the stage of erection of the basement or basement floor, followed by filling the pit. When installed on a raised base with a pitch step equal to the length of columns in two and a half floors, reinforced concrete columns, which are made with a square cross-section and technological openings at a distance of the height of the floor and are equipped with temporary collars near the openings, immediately on each hose install connecting beams. In this connection

Description

The useful model belongs to the field of construction, in particular to the construction of various types of residential buildings/structures - from low-rise to high-rise buildings, and can be used in the construction of residential buildings using building products and structures made of composite materials, mainly concrete and ceramics.

Many approaches to building a house are known.

For example, taking into account the influence of the Earth's physical field on the materials from which houses are built (application VO Mo 95102301 JSC, IPC ЕО4В 1/02, Е0О4В 1/20). According to the authors' proposal, during construction, they are placed as they were located in nature. This, according to the authors, improves the physiological indicators of the people who will be there, but this approach can be implemented for individual construction, it is not suitable for the construction of houses during mass construction.

A known method of building a house (patent VO Mo 2284395 C1, МПК ЕО4В 1/35, Е0О4В 21/14), which consists in erecting a monolithic frame of a given storey with the help of a lifting crane, cantilever scaffolding and volume-replaceable formwork, in carrying out external masonry with further internal work in the premises until the floor is completely hatched and the roof is erected. After the construction of the last floor of the monolithic frame, the volume-movable formwork is removed from the cantilever scaffolding with a crane and a roof is erected on the upper floor of the monolithic frame, and the materials necessary for the removal of the floors are placed on the cantilever scaffolding, and after external masonry and internal work until complete removal of the upper floor, the cantilever scaffolding is rearranged with a crane into the slots of the lower floor of the monolithic frame, and the work on removing the floor is repeated until the first floor of the building is removed.

This method allows you to exclude getting wet during the period of work after the roof is erected, which improves the quality of work and the conditions for their performance, but it is very time-consuming, requires a technological break during implementation, in addition, the structure of the monolithic frame is rigid, under the influence of significant fluctuations in the elements of the frame, cracks Wind resistance deteriorates.

A known method of building a house/structure (patent KO Mo 2285771 C1, IPC Е04В 1/20 Е04В 5/16Й, which includes preparation of the base, erection of foundations, erection or restoration, or reconstruction of the frame or its part, including columns, connecting beams and slabs

From floors, as well as installation or dismantling and replacement of engineering systems, in which at least part of the constructed or restored, or reconstructed frame is made of prefab monolithic with monolithized column joints and prefab monolithic connecting beams, in which only their lower part is prefab, designed for technological loads from resting, at least by the ends of the mounted floor slabs. The lower prefabricated part is made in the form of an expanded pre-stressed shelf, which forms, at least after the execution of the monolithic upper part of the connecting beam, one or two lateral cantilever overhangs extending along the length, and the upper part of the connecting beam is monolithed to its lower part with simultaneous formation in the transverse cross-sections of the wall and the upper extended shelf with one or two corresponding lower overhangs, which monolith up to at least one floor slab supported on a crossbar, and the prefabricated part is made with releases of longitudinal and transverse reinforcement, while the releases of transverse reinforcement are installed at least in the span part of the connecting beam and are made of clamps or a system of rods, monolithed into the lower assembled part of the connecting beam in the process of its manufacture and connected from above by at least one reinforcing mesh, with their tops protruding above the upper part of the floor slabs resting on the crossbar, at least in the abutment zone connection nuval beam to the column at a length of at least one third of the span of the connecting beam.

This method partially contributes to shortening the erection period, but the use of monolithic elements, moreover, with pre-tensioned reinforcement, requires technological interruptions during execution.

With this method, the ends of the columns are connected at the mark of each floor of the building, and at the connection points, in addition, connecting beams are attached, thus forming a rigid node, which during operation under the action of external forces shows insufficient flexibility, that is, the structure of of the capacious-spatial frame of the house/building with this construction technology has critical points.

The closest is the method of building a house/building (patent VO Mo 63910, IPC EO4B 1/20, 2048 1/35, 6048 21/00, 048 23/00), in which a complex of technological operations related to the technological process of building houses/buildings , are performed sequentially in time in several stages, according to which pits and/or trenches are first dug and the foundation is prepared, after the foundation is prepared, the foundation is erected, reinforced concrete columns are installed on the erected foundation - a vertical structural element of the frame, which is made of a square or rectangular transverse cross-section or other type of construction products and constructions and form the three-dimensional frame of the house/structure with them, connect the specified structural elements of the frame of the house/structure, install/form floor slabs - a horizontal structural element of the frame, with a thickness of at least 160 mm, with an introduction them into the three-dimensional frame of the house/building in a plane perpendicular to the longitudinal axis of the columns, cut-outs/slots for engineering communications and / for the passage/installation of reinforced concrete volumetric elements or panels for elevator shafts, reinforced concrete ventilation blocks, smoke removal blocks, reinforced concrete staircases and marches are made in the reinforced concrete floor of the house/building frame, installed hinged facade blocks and balcony slabs, install reinforced concrete stairwells, platforms and marches, install reinforced concrete volumetric elements or panels for elevator shafts, reinforced concrete ventilation blocks and smoke removal blocks, place reinforced concrete combined inter-block panels in the specified spatial frame, erect external walls, erect internal walls/partitions, measures are taken to waterproof structural elements of the house/building, installation of sanitary and technical equipment and other engineering systems is carried out, heat supply networks are installed, and at the final stage of construction of the house/building, measures are successively carried out, including plastering exterior and interior surfaces of parts of the house/building, painting and finishing works, and the basement with a ceiling made of the specified slabs is formed with slabs at the level of the foundation. After receiving the finished building structure, measures are taken to test the house/building, while columns with a length of 2500 to 15000 mm, reinforced concrete columns, depending on the number of floors of the house/building and the span width between load-bearing structures, set with the possibility of creating, when assembling a vertical structural element, a three-dimensional frame of calculated strength and a complex shape with a different configuration in the cross section, respectively square, rectangular, angular, cross-shaped and T-shaped cross-section, reinforced concrete combined inter-block panels are installed according to between the specified columns, the external walls are erected by 3 abutments on the horizontal structural element of the frame - on the overlap in various variants of the structural execution depending on the architectural and other requirements, horizontal planar structural elements and the external walls are made/erected either solid or multi-layered, and the columns are placed relative to the horizontal structural elements of the three-dimensional frame with the creation of a "grid" of columns in the range from 6000 to 10000 mm, the vertical rod structural element of the three-dimensional frame of the house/ buildings are assembled either from columns of the same cross-section, or from columns with a cross-section that decreases in accordance with the increase in the floor number of the building, the specified vertical rod structural elements on the first floors of high-rise multi-story buildings/structures are installed with a frequent/small step of no more than 7200 mm , and on the upper floors of the specified buildings/structures - with a wide/large step of no more than 10,000

MM.

Construction practice has shown that the construction of multi-story buildings/buildings with the maximum use of modern products/structures of building industry enterprises is most in demand in the conditions of a large city with the presence of modern enterprises of the building industry: panels, columns, stiffness diaphragms, connecting beams, balcony slabs. Such products, manufactured in the conditions of enterprises of the construction industry, have more stable parameters than those manufactured in the conditions of a construction site.

At the same time, a very important issue is the determination of the method and technological sequence of the installation of structures. The chosen method should ensure ongoing construction with high-quality performance of all works without the need for technological interruptions.

In the mentioned useful model, sufficiently new technological operations were introduced to improve the quality of building a house/building, but this method is not fast, contains long-term operations, are not always technologically justified, requires technological interruptions, and does not provide an optimal structure of the volumetric-spatial framework.

In this method, the ends of the columns are connected by concreting the outlets of the reinforcement of one of the columns into the cavity of the body of the column with which there is a connection. This joint does not work well in tension and compression, because reinforcement and concrete have different properties under the action of forces in tension and compression.

With this method, the ends of the columns are joined at the mark of some floors of the building and at the points where the columns are joined, connecting beams can be attached, thus forming a rigid node,

which during operation under the action of external forces shows insufficient flexibility, that is, the structure of the three-dimensional frame of the house/building with such construction technology has critical points.

The basis of the useful model is the task of building a house using a high-quality, fast method of performing all works that does not require technological interruptions, with a significant improvement of the structure of the three-dimensional frame of the house due to the distribution of nodes connecting the columns and connecting the connecting beams along the height of the columns and reduction of the total load, high bearing capacity, wind resistance, crack resistance, resistance to soil fluctuations in the conditions of a large city, stability of heat supply.

The task is solved by the method of erecting a house/structure, in which a set of technological operations related to the technological process of erecting houses/structures is performed sequentially in time in several stages, according to which the digging of pits and/or trenches and the preparation of the foundation are carried out beforehand, after preparing the base, the foundation is erected; measures are taken to waterproof the structural elements of the building; reinforced concrete columns - the vertical structural element of the frame - are installed on the erected foundation, and they form the vertical part of the three-dimensional frame of the building; connect the specified structural elements of the three-dimensional frame of the house/structure; install floor slabs with their introduction into the three-dimensional frame of the house/building in a plane perpendicular to the longitudinal axis of the columns; install reinforced concrete volumetric elements or panels for elevator shafts, reinforced concrete ventilation blocks; install reinforced concrete staircases and marches; arrange external walls; interior walls are arranged by installing pre-made panels or building them from bricks; carry out installation of sanitary and technical equipment and other engineering systems; a roof covering is installed, and at the final stage of the construction of the house/building, finishing works are carried out. During the construction of the foundation, at the same time, measures are taken to waterproof the structural elements of the house/building at the stage of construction of the basement or basement floor with subsequent backfilling of the pit; when installing reinforced concrete columns, which are made with square

With a cross-section and process openings at the distance of the floor height and equipped with temporary clamps near the openings, connecting beams are immediately installed on the temporary clamps of the columns on each floor, and they are connected to each other exclusively by means of a strapping and a stiffening diaphragm, which completes formation of the three-dimensional frame of the house/structure; after installing the floor slabs on the connecting beams, the temporary clamps are dismantled; arrangement of external walls is carried out by masonry from an artificial hollow ceramic block on a cement-sand solution and fixing in the solution embedded parts of the columns for anchoring the external walls; after installation of sanitary and technical equipment and other engineering systems, installation of an autonomous heat supply device for each block of the house/structure is carried out; and the coupling of the columns is carried out exclusively by connecting the embedded parts of the columns, which during manufacture are welded to the supporting armature of the columns before concreting, with a threaded connection located exclusively in places outside the area of the location of the joints of the floor slabs.

It is better when installing floor slabs with a thickness of 220 mm.

It is better when the columns are installed with a column step with variable reinforcement for the floors, reinforced for the lower floors.

It is better when reinforced concrete columns are installed with a variable step from 1500 mm to 7400 mm in the specified houses/buildings.

It is better when the construction of the foundation is carried out by the non-impact method of sinking piles with the installation of anchors for adjusting the vertical position of the column and reliable fixation with the grid.

It is better when, when installing reinforced concrete columns on a raised foundation, the connections between them are provided with a bolted connection.

It is better when connecting beams are connected by means of strapping in the form of bent reinforcing elements and knitting wire.

Simultaneously with the construction of the foundation, the waterproofing of the structural elements of the house/structure improves the conditions of its future operation, protects against the influence of groundwater, which prevents the occurrence of cracks and unplanned shrinkage.

The use of reinforced concrete columns with the same square cross-section for the vertical structural elements of the frame contributes to the accuracy of the installation of all structural elements of the house, the exclusion of eccentricity when connecting the columns. For this, columns are used with different reinforcement for floors, reinforced for the lower floors.

Usually, the ends of the columns are connected at the mark of each floor of the building, and at the points of connection, in addition, connecting beams are attached, thus forming a rigid node, which in statics has good strength characteristics, but during operation under the influence of external forces of the column shows insufficient flexibility in these places, i.e. the structure of the three-dimensional frame of the house/building with this construction technology has critical points.

The installation of reinforced concrete columns, which are two and a half stories long, on a raised foundation provides greater flexibility of the three-dimensional frame by reducing the number of column connection points. The presence of technological openings at a distance of the height of the floor and equipping them with temporary clamps near the openings ensures easy and quick installation of connecting beams, which completes the formation of the three-dimensional frame of the house / structure, and subsequently, ensures the installation of floor slabs.

Usually, the places where the columns are connected coincide with the 3 places where the connecting beams are connected to each other, but in this way, very rigid nodes are formed in the frame, which take on the load and quickly collapse, instead of distributing the load. The method ensures a better distribution of the places where the columns are joined and the places where the beams are joined throughout the three-dimensional frame and thus the load is evenly distributed over the frame.

Thus, instead of rigid knots at the joints, this technology allows for a more even distribution of joints on the frame.

Installation of pre-made stiffening diaphragms, which strengthen the load-bearing capacity, allows you to increase the step of installing columns and reduce their number.

Arrangement of external walls is carried out at the expense of masonry of walls made of artificial hollow ceramic blocks with seams on a cement-sand mortar and fixing in the mortar of the seams of the embedded parts of the masonry, which are in the columns. Such fixation of the walls also improves the structure of the three-dimensional frame of the house/building, because it ensures a direct connection of the external walls with the frame, distributes the load on the frame more evenly, creating a new connecting node, and also reduces the load on the frame due to hollowness blocks

The production of products at the factories of the building industry of the required configuration, which do not require the execution of cutouts and other actions on the construction site, contributes to the completion of work in a short time, without technological interruptions.

The installation of an autonomous heat supply device for each block of the house/building allows to ensure its independence from the centralized heat supply, to exclude the operations of digging trenches for heating networks and laying pipes, burying trenches, and subsequently repairing the pipes of the centralized heat supply.

Joining of vertical structural elements of the frame of the house/structure, which is carried out exclusively by means of strapping without the use of welding, makes the joining places and the structure itself flexible, which improves its wind resistance, resistance to soil fluctuations in the conditions of a big city.

In addition, the exclusion of the welding operation improves the safety of work at height.

The utility model is illustrated by drawings that explain its essence, but do not limit the scope of the patent.

Fig. 1 - construction of the foundation with the application of a layer of waterproofing.

Fig. 2 - installation of reinforced concrete columns on the foundation with installation of stiffness diaphragms and connecting beams of the frame with temporary clamps.

Fig. C - connecting reinforced concrete columns.

Fig. 4 - connection of armature releases of connecting beams, which fit to a common column, with L-shaped reinforcing elements and a binding wire.

Fig. 5 - connection of armature releases of connecting beams, which fit to a common column, with U-shaped reinforcing elements and a binding wire.

Fig. 6 - masonry of external walls from artificial hollow ceramic blocks.

Fig. 7 - a view of the projected three-dimensional frame of the house/building.

Fig. 8 - installation of the equipment of the autonomous heat supply source for each block.

Markings on the drawings: 1 - base; 2 - foundation;

C - layer of waterproofing; 4 - reinforced concrete columns; 5 - stiffness diaphragms; 60 6 - connecting beams;

7 - temporary clamps; 8 - releases of armature beams; 9 - floor slabs; 10 - L-shaped reinforcing elements; 11 - U-shaped reinforcing elements; 12 - knitting wire; 13 - bolt connection; 14 - embedded coupling details; 15 - distribution armature; 16 - artificial hollow ceramic block; 17 - three-dimensional frame of the house; 18 - boiler; 19 - heat supply networks; 20 - radiator.

To develop optimal technological solutions for the construction of buildings, technological design is carried out. The optimal solution can be achieved on the basis of the typification of the project, the industrialization of the construction of the frame and the entire cycle of works embedded in it, the use of complex mechanization, modern tools. The designed house is divided by height into several parts, which should ensure the possibility of carrying out technological actions to ensure optimal places for the column connection nodes in the frame of the house and thus determine the design height of the column.

The designed columns in the places where they are connected to each other are equipped with embedded connection parts connected to the distribution armature, which optimally distribute the forces that arise during the load during the operation of the building. A sufficiently functional solution is the implementation of embedded parts in the form of corners of a special shape.

Such columns must meet the requirements for the possibility of transportation, taking into account weight and dimensions.

After the technological design, measures are taken to order and manufacture products by the factories of the building industry.

The method is implemented as follows (Fig. 1-8).

After digging the pit and preparing the base 1, the foundation is erected.

At the stage of construction of the foundation 2, a layer of waterproofing C is applied to the reinforced concrete columns 4 and the base 1

When installing reinforced concrete columns 4 on the foundation, stiffening diaphragms 5 are simultaneously installed.

The installation of connecting beams 6 is carried out with preliminary equipment of reinforced concrete columns 4 with temporary clamps 7 on each floor.

After installing the connecting beams b, connecting the armature releases 8 of the connecting beams 6, which fit the common column 4, to each other and monopolizing their joints together with the floor plates 9 and hardening the joints, the temporary clamps 7 are dismantled.

Strapping is performed with L-shaped 10 and/or U-shaped reinforcing elements 11 and knitting wire 12.

Reinforced concrete columns 4 are connected to each other with a bolted connection 13 through embedded parts 14, which are pre-welded to the distribution armature 15, with the subsequent monolithization of the joint.

Arrangement of external walls is carried out at the expense of masonry walls made of artificial hollow ceramic blocks 16 with seams on a cement-sand mortar and fixing in the mortar the seams of the embedded parts of the masonry, which are in the columns. Such fixation of the walls also improves the structure of the three-dimensional frame of the house/building, because it ensures a direct connection of the outer walls with the frame. The arrangement of external walls is carried out on each floor gradually, without technological interruptions, even before the completion of the creation of the complete volumetric-spatial frame 17 of the house/building in the form of a three-dimensional spatial lattice, the vertical part of which is formed from reinforced concrete columns 4 connected to each other bolt connection 13, and the horizontal part - connecting beams b, connected to each other by a strap, made by L-shaped 10 and /" or U-shaped reinforcing elements 11 and knitting wire 12.

The installation of the roof covering is carried out after the completion of the creation of the complete volume-spatial frame 17 of the house/building.

Interior walls are arranged by installing pre-made panels or building them from bricks or arranging a metal grid followed by sheathing it with plasterboard sheets.

Installation of sanitary and technical equipment and other engineering systems is carried out.

When installing the equipment of an autonomous source of heat supply, a boiler 18 is installed for each block, a network for heat supply 19 and radiators 20 are installed.

At the final stage of the construction of the house/structure, finishing works are carried out.

The enterprise "UkrSiverBud" CJSC "DSK" builds houses according to the claimed technology, based on the USB-2015-3MK series.

To prepare the base, a non-impact method of sinking piles - soil-cement elements (GCE) is used to a depth of up to 10 m.

At the stage of construction of the foundation 2 and the basement floor, a layer of roll waterproofing is applied

With and insulate the foundation. Further backfilling of the pit is carried out.

In reinforced concrete columns 4 with a cross-section of 400x400 mm and a height of 7600 mm, there are 14 interlocking embedded parts, masonry embedded parts and exposed parts of the columns without concrete to pass the reinforcement outlets of 8 connecting beams 6. The connecting beams would be made with reinforcement outlets 8 in length 190 mm into the body of the column 4. Together with the installation of the connecting beams 6, the balcony beams are mounted.

To temporarily hold connecting beams b, metal temporary clamps 7 are used, which are previously attached to reinforced concrete columns 4. Metal temporary clamps are made from a flat corner 163 x 5. Hollow multi-cavity slabs 9, 220 mm thick, are installed on connecting beams b. Inventory risers are placed under the floor slabs 9 for the time of joint digitization and their hardening.

End beams 6 are made with an additional board to reduce formwork at height.

Reinforced concrete columns 4 are connected to each other by a bolted connection with 13 MI18 bolts, with the subsequent monolithization of the joint.

In total, for the construction of a 10-story building, four reinforced concrete columns are connected in height. The connecting nodes are placed between the floors of the 2nd and 3rd floors, between the floors of the 5th and 6th, and the 8th and 9th floors. The junction nodes of columns 4 do not coincide with

With places of connection of connecting beams 6, which form an overlap.

Arrangement of external walls is carried out at the expense of masonry walls made of artificial hollow ceramic blocks 16 with seams on a cement-sand mortar and fixing in the mortar of the seams of the embedded masonry parts, which are in the columns 4.

The dimensions of hollow ceramic blocks are 14-250x120x140.

Simultaneously with the installation of floor slabs 9, staircases and marches, balconies, vent blocks, diaphragms of rigidity 5 and elevator blocks are arranged.

Interior walls are arranged by installing pre-made panels or building them from bricks or arranging a metal grid followed by sheathing it with plasterboard sheets.

Installation of sanitary and technical equipment and other engineering systems is carried out.

When installing the equipment of an autonomous source of heat supply, a boiler 18, which can be gas or electric, is installed for each block, a network for heat supply 19 and radiators 20 are installed.

A flat roof covering is installed.

Finishing works are carried out in the house and in the surrounding area.

It is this sequence of technological actions in a useful model that ensures the construction of a house by a high-quality, fast method of performing work that does not require technological interruptions, with a significant improvement of the structure of the three-dimensional frame of the house, which guarantees high load-bearing capacity, wind resistance, crack resistance, resistance to soil fluctuations in the conditions of a big city, the stability of heat supply. This made it possible to significantly reduce the cost of building a house due to new technologies and modern materials.

Claims (1)

USEFUL MODEL FORMULA 1. The method of erecting a house/structure, in which a set of technological operations related to the technological process of erecting houses/structures is performed sequentially in time in several stages, according to which pits and/or trenches are first dug and the foundation is prepared, after the foundation is prepared, construction of the foundation; measures are taken to waterproof the structural elements of the building; reinforced concrete columns - a vertical structural element of the frame - are installed on the erected foundation, and they form the vertical part of the three-dimensional frame of the building; connect the specified structural elements of the three-dimensional frame of the house/structure; install floor slabs with their introduction into the three-dimensional frame of the house/building in a plane perpendicular to the longitudinal axis of the columns; install reinforced concrete volumetric elements or panels for elevator shafts, reinforced concrete ventilation blocks; install reinforced concrete staircases and marches; arrange external walls; interior walls are arranged by installing pre-made panels or building them from bricks; carry out installation of sanitary and technical equipment and other engineering systems; a roof covering is installed, and at the final stage of the construction of the house/building, finishing works are carried out, which is distinguished by the fact that during the construction of the foundation, at the same time, measures are taken to waterproof the structural elements of the house/building at the stage of the construction of the basement or basement floor with subsequent backfilling of the pit; when installing reinforced concrete columns with a square cross-section and technological openings at a distance of floor height and equipped with temporary clamps near the openings, immediately on the temporary clamps of the columns on each floor connecting beams are installed, and they are connected to each other exclusively with the help of strapping and stiffness diaphragm, which completes the formation of the three-dimensional frame of the house/building; after installing the floor slabs on the connecting beams, the temporary clamps are dismantled; the construction of external walls is carried out by masonry from an artificial hollow ceramic block on a cement-sand solution and fixing in the solution embedded parts of the columns for anchoring the external walls; after the installation of sanitary and technical equipment and other engineering systems, the installation of an autonomous heat supply device for each block of the house/building is carried out, and the coupling of the columns is carried out exclusively by connecting the embedded parts of the columns, which during manufacture are welded to the bearing armature of the columns before concreting, threaded with "joints with the location exclusively in places outside the zone of the location of the joints of the floor slabs. 2. The method according to claim 1, which differs in that the floor slabs with a thickness of 220 are installed MM. Q. The method according to claim 1 or claim 2, which is distinguished by the fact that the columns are installed with column-by-column steps with variable reinforcement for the floors, reinforced for the lower floors. 4. The method according to any of claims 1-3, which is characterized by the fact that reinforced concrete columns are installed with a variable step from 1500 mm to 7400 mm in the specified houses/buildings. 5. The method according to any of claims 1-4, which is characterized by the fact that the construction of the foundation is carried out by a non-impact method of sinking piles with the arrangement of anchors for adjusting the vertical position of the column and reliable fixation with the grid. 6. The method according to any of claims 1-5, which differs in that when installing reinforced concrete columns on a raised foundation, the joints between them are provided with a bolted connection. 7. The method according to any one of claims 1-6, which is characterized by the fact that the connecting beams are connected using a strapping in the form of bent reinforcing elements and a knitting wire. i dok o kdnya EE EN HE SHOCK V KT My EX i U Nu ME iv i i shi o Io p v: shiy o s i VNU i aloe xx B ma zha ov teo nie Z. I xE IZ Vs in still NK: that MAE sk ev You 8 i і х і Her" Ж кВ і і : і і "і ше і WITH . i Z av i - KE Be shchi sh- NI x ЖЖ. I eat and eat : i i i OK a Kn V i OK UK M A dk J yuyu ke KZ xx x kv, Fi. 1 and in and and what else. I STILL VK her HORSE still IN PYSHY scree Y SY SAME ro PMK on SHOMU KNYSH NK WOLF SK HO SHYZHOLYNY in life. 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