RU88036U1 - UNIFIED REINFORCED CONCRETE REINFORCED MONOLINED COLUMN-WALL BUILDING FRAME - Google Patents

Abstract

1. A unified reinforced concrete prefabricated monolithic column-wall frame of the building, consisting of vertical load-bearing single and / or multi-storey rectangular in the cross section of the middle and outer columns, respectively, of the inner and outer rows and diaphragm walls, united into a single spatial system by horizontal load-bearing floor disks, which are assembled from the middle and extreme crossbars and plates, and in the outer rows of the columns are installed the greater side of the cross section along the building, and in the inner rows of the middle columns - pope rivers of the building, characterized in that in the middle columns for supporting the middle crossbars, consoles with a height not exceeding the thickness of the columns are made, and in the extreme columns for supporting the extreme crossbars there are grooves and bevels for ease of installation and laying of concrete mix, or the console in the extreme columns of the outer frames, the middle and outer columns have the same thickness and the width of the barrel of the middle columns does not exceed the width of the extreme columns, and the joints of single and / or multi-story columns are made flat and laid out above the slabs by at least a quarter and not more than half at the height of the floor, the cross-sectional width of the middle crossbars is not less than the total width of the trunk of the middle column and consoles, and the width of the extreme crossbars is not more than the width of the extreme columns, while the middle crossbars of the inner rows are made with two lateral supporting ribs, between which tensioned reinforcement is installed, and the extreme the crossbars of the outer rows are made from the ends with one middle supporting rib, the sizes of which on the bottom correspond to the support areas in the grooves of the extreme columns, while the middle and extreme crossbars have supporting lower shelves for

Description

The proposed technical solution relates to the field of civil and industrial construction, namely, to the construction of prefabricated frames of buildings for various purposes.

The well-known unified prefabricated reinforced concrete connection frames of the II-04 series for public buildings and 1.020-1 / 83 interspecific applications for public and most industrial buildings, consisting of vertical load-bearing columns and diaphragm walls and horizontal load-bearing disks of ceilings from extreme and medium crossbars and ordinary and connected round hollow and ribbed plumbing plates resting on the lower flanges of the crossbars (Full-frame frame constructions of public buildings: Experience in improving the II-04 series. - M.: Stroyizdat. 1974.-90 pp.).

They are difficult to use for residential and many public buildings difficulties with the free layout of the premises due to the protruding downward of the thick and wide shelves of the crossbars and because of the installation of diaphragm walls, even in buildings with low floors. The reason for this is the lack of rigid jamming of the crossbars in the columns and hence the large height of the crossbars.

Known frame, consisting of prefabricated columns of rectangular cross section and hollow core slabs, combined into a single system not protruding downward monolithic reinforced concrete load-bearing crossbars and beams, which extend in mutually perpendicular directions in mezhplitnyh seams. For this purpose, through openings are made in prefabricated columns to the height of the crossbars at the levels of overlap, and the plates are pushed apart. The support of multi-hollow slabs on the bearing crossbars is provided by means of concrete dowels formed in the cavities open at the ends of the plates during the laying of monolithic concrete crossbars. (Recommendations for the design of constructions of flat prefabricated-monolithic floors "Sochi". - M .: Stroyizdat. 1975.-15 p.).

This frame does not have the required adaptability due to the need to use for its construction inventory mounting equipment, as well as additional material, labor and energy costs for the production of concrete work, especially in winter.

The closest known is the prefabricated monolithic reinforced concrete frame of the building, including columns of extreme and inner rows, equipped with grooves for installing the ends of flat rectangular crossbars, while the crossbars of the inner rows are made with shelves for supporting floor slabs, and the columns are made of rectangular cross-section, columns of extreme rows are installed with the larger side of the section along the wall of the building, and the columns of the inner rows are perpendicular to the length of the building, the crossbars of the extreme rows are made with a width equal to or greater doubling the thickness of the column, and are mounted in grooves columns extreme rows offset with respect to the columns or not, wherein the crossbars extreme series of crossbars mounted below the inner rows on pins thickness (patent RU №2202026, 2003 YG).

The well-known frame is quite material and laborious, has insufficient number of storeys and a small size of overlapping cells, which complicates the free layout of the premises. The unreliable design of the joints of the crossbars with columns does not allow to increase the rigidity and spans of the crossbars and does not provide the required rigidity of the overlap disk in its plane and the strength of the frame during progressive collapse and seismic effects, requires the installation of diaphragm walls even with small spans of the frame cells and low-rise buildings.

In addition, the support of wide middle beams in the grooves of wide columns complicates the installation of beams and requires a large height of the grooves and quality control of hard-to-work monolithic concrete in critical joints of the frame. Really large in height and width dimensions of the grooves in the area of bearing of the crossbars and the junction of the columns halves the cross-sectional area of the calculated precast concrete, shuts down about a third of the cross-section made of monolithic concrete from work, requires reinforcing volumetric frames, complex formwork and concrete supply pressure, but gaps still remain in the upper part of the grooves or wide cracks from shrinkage form, therefore, the remaining 20% of the calculated cross-section of cast concrete is ineffective. The large, about a meter, width of the middle columns interferes with the layout of the premises, and the concrete strength in the section is only half used effectively. Despite the large width of the middle crossbars, they have a small span and a large consumption of steel, and the presence of flanges hanging from the columns at the ends of the crossbars makes it difficult to create the continuity of the crossbars and a reliable fire-resistant frame joint with columns, which does not allow to increase the rigidity and span of the crossbars. The height of the wide middle beams, greater than that of the plates, despite the trimming of the ends of the hollow plates, creates an uneven floor, which requires the installation of an additional labor-intensive thick leveling screed. Leaning plates on the extreme rectangular crossbars on top makes it difficult to jam the plates and the hard drive of the floor. Thus, the known frame is not designed for increased spans and for the perception of effort from progressive collapse and seismic effects.

The technical task aimed at eliminating the noted drawbacks is the creation of a unified reinforced concrete prefabricated monolithic column-wall frame of the building with increased spans of the crossbars, ensuring the stability of the frame during progressive collapse and seismic impacts, having low material consumption and requiring a minimum of metal equipment for manufacturing and less its construction by increasing the pitch of the columns, standardizing the size of the supporting structures and constructions su- characteristics of their cross-sections and joints while expanding free space planning capabilities.

The solution of the technical problem is achieved by the fact that in a unified reinforced concrete prefabricated monolithic column-wall frame of the building, consisting of vertical load-bearing single and / or multi-storey rectangular in the cross section of the middle and outer columns, respectively, of the inner and outer rows and diaphragm walls, united in a single spatial system by horizontal bearing disks of ceilings, which are assembled from middle and extreme crossbars and plates, moreover, in the outer rows of the columns are installed the larger side along the building, and in the inner rows the middle columns are across the building, in the middle columns for supporting the middle crossbars, consoles with a height of not more than and the offset of at least the thickness of the columns are made, and in the extreme columns for supporting the extreme crossbars there are grooves and bevels for ease of installation and laying of concrete mixture, while the middle and outer columns have the same thickness and the width of the barrel of the middle columns does not exceed the width of the extreme columns, the joints of one- and / or multi-story columns are made flat and laid out above the slabs by at least a quarter and not more than half the height of the floor, the cross-sectional width of the middle crossbars is not less than the total width of the trunk of the middle column and consoles, and the width of the extreme crossbars is not more than the width of the extreme columns and at least two column thicknesses, while the middle crossbars of the inner rows are made with two lateral supporting ribs, and the extreme crossbars of the outer rows are made from the ends with one middle supporting rib, the dimensions of which correspond to the support areas in the grooves of the extreme columns, the middle and extreme crossbars have supporting lower shelves with the same reach for piranha of plates, the latter being supported by middle beams with undercutting, the sizes of which correspond to the dimensions of the shelves in the middle beams, and on the extreme beams of the plate are supported in full height, which corresponds to the height of the wall of the crossbar, and the width of the wall and the height of the crossbars are not less than the thickness of the columns, while for combining on the installation of crossbars and columns in the inner row of the frame at the ends of the crossbars, the concrete of the lower shelves is cut, and horizontal metal plates are produced from the supporting ribs from below, which are welded to the embedded plates in the consoles of columns, Plates are also installed on top of the supporting ribs, and to create continuity of the middle crossbars, metal bonds are welded to the lower and upper plates, and both plates are combined as a single embedded part together with vertical strips, which, like the plates, are connected by welding to the upper and lower longitudinal working rods of vertical reinforcing cages, in the middle part along the width of the crossbar between the supporting ribs installed tensioned reinforcement, while for joining the mounting of crossbars and columns in the outer rows of the frame lower weldable embedded parts are provided in the grooves of the columns and in the supporting ribs of the crossbars, and to create a frame on top of the supporting ribs and grooves, plates are also welded using reinforcing spacers, for the convenience of welding of which the upper face of the grooves is made with slopes in the form of a wedge, and the size slope does not exceed _^1/2. In addition, in order to reduce the area of cold bridges and insulate the extreme crossbars, the outer lower shelf was made with a thickness and overhang of no more than that of the inner shelf, while the outer shelf was insulated with thermal liners, and the wall and the supporting rib of the crossbars, as well as the columns, were insulated with thermal screens. In addition, when the facade cladding of external walls is installed, the overhang of the outer flange of the extreme crossbars is increased by the thickness of the facing layer of bricks or blocks plus the thickness of the ventilated gap, while the width of the extreme crossbars does not exceed the width of the columns. Also, to increase the rigidity and strength of the floor disks in the inter-plate joints and in the joints between the crossbars and the ends of the plates, intermittent concrete keys are provided, and on top of the crossbars and at the corners of the plates there are additionally embedded plates combined by welding metal plates in the form of plates. In addition, at the junction, the middle columns and girders of the inner rows have the same width with overlapping from the bottom at the junction of the side support ribs and lower shelves, and the column thickness is greater than or equal to the thickness of the crossbar, the thickness of which, in turn, is greater than or equal to the thickness of the plate. Also, to create a frame in the inner rows of the frame on the upper surface of the ends of the middle crossbars, in the area between the supporting ribs and, accordingly, on the column barrel, metal embedded plates are provided, combined by welding metal plates, to the lower metal plates in the supporting edges of the shelves more powerful reinforcing bonds are welded to the crossbars, and the vertical joints between the column barrel and the ends of the crossbars are carefully monolithic with non-shrink concrete. In addition, with limited spans of crossbars to reduce floor thickness and weight of floors by aligning the marks of the top of the slabs and middle crossbars, the thickness of the latter is taken to be equal to the thickness of the plates. Also, with limited spans of crossbars and number of storeys of buildings, to improve the layout and reduce metal shapes, the column thicknesses and the height of the middle crossbars are made equal to the thickness of the plates, but not less than the thickness of the walls of the diaphragms. In addition, with limited spans of crossbars and number of storeys of the building, in order to reduce the area of “cold bridges” in the outer walls and to reduce the consumption of concrete and insulation in the outermost columns of the outer frames, consoles are arranged instead of grooves, while the column barrel width is not less than the plate thickness and not more than the column thickness and to create the frame of the joint in the column on the trunk, above the consoles, embedded plates are installed, which are joined by welding plates with the upper embedded plates in the supporting ribs of the crossbars.

The adopted technical solutions due to the use of prestressing reinforcement in the middle beams and an increase in the stiffness and strength of the joints of the frame and floor disks allow us to design buildings with increased spans of the beams taking into account the progressive collapse and seismic effects.

If necessary, instead of arranging grooves, the trunk of the outermost columns is already made, and the crossbars rest on the console of the columns, while the grooves disappear and wet, time-consuming and responsible processes for their monolinging are not required.

Figure 1 is a top view of a fragment of a unified precast-monolithic reinforced concrete frame-wall frame of the building.

Figure 2 is a section along aa.

Figure 3 is a section along BB.

Figure 4 is a fragment of the middle column.

Figure 5 is a fragment of the extreme columns.

Figure 6 is an end view of the middle bolt.

In Fig.7 is a view of the extreme bolt from the end.

On Fig is a longitudinal section of a plate.

Figure 9 is a fragment of the junction of the middle crossbar with the column.

Figure 10 is a fragment of the junction of the extreme crossbars with the column.

Figure 11 is a section along BB.

In Fig.12 is a section along G-G.

On Fig is a top view of a fragment of the overlapping disk near the middle column of the unified precast-monolithic reinforced concrete frame-wall frame of the building.

On Fig - section on DD.

On Fig - a fragment of a unified reinforced concrete precast monolithic column-wall frame, where the barrel width "b ₃ " of the column is not less than the thickness of the plate "h _p " and not more than the thickness of the column "h".

The unified reinforced concrete prefabricated monolithic column-wall reinforced concrete frame of the building consists of vertical load-bearing single, multi-storey rectangular cross-sections of the middle 1 and extreme 2 columns of the inner and outer rows and diaphragm walls 3, combined into a single spatial system by horizontal bearing discs of the floors 4, assembled from middle 5 and extreme 6 crossbars and plates 7, moreover, in the outer rows the outer columns 2 are installed with the larger side of the cross section along the building, and in the inner rows the middle columns 1 are p perek building (1).

A distinctive feature of this technical solution is that in the middle columns 1 for supporting the middle crossbars 5 there are consoles 8 with a height not exceeding the thickness of the columns “h”, and in the extreme columns 2 for supporting the extreme crossbars 6 there are grooves 9 of small height to increase the stiffness of the columns and reducing the amount of monolithic concrete and bevels 10 for the convenience of installing and laying concrete mixture, while the middle 1 and extreme 2 columns have the same thickness "h" and the barrel width "b _c " of column 1 does not exceed the width "b" of column 2, and the joints 11 one and many GOVERNMENTAL columns 1 and 2 are flat and convenience for welding plates rendered higher by at least a quarter and at most half the height of the floor (2, 3, 4, 5).

The width “b _p ” of the cross section of the middle crossbars 5 is taken to be not less than the total trunk width “b _c ” of the middle columns 1 and two overhangs of the arms 8, and the width “b ₂ ” of the extreme crossbars 6 is not more than the width “b” of the extreme columns 5 (FIG. .5, 6). The middle crossbars of the 5 inner rows are made with two lateral supporting ribs 12, between which tensioned reinforcement is installed, and the extreme crossbars of the outer rows are made from the ends with one middle supporting rib 13, the dimensions of which on the bottom correspond to the support areas “a × h” in the grooves 9 of the extreme columns 2 (FIGS. 5, 6, 7). In the middle 5 and extreme 6 crossbars, there are supporting lower flanges 14 and 15. Moreover, the middle crossbars 5 of the plate 7 are supported by clippers 16, and the extreme crossbars 6 - in full height, while the height of the extreme crossbars 6 should not be less than the thickness “h” columns 2. The sizes of the undercuts 16 in the plates 7 correspond to the sizes of the shelves 14 in the middle crossbars, and the wall height of the extreme crossbars corresponds to the height of the plate "h _p ", and its width is not less than the thickness of the column "h" (6, 7, 8).

To combine at the assembly in the inner row of the frame at the ends of the crossbars 5, the concrete of the lower shelves 14 is trimmed, and from the support ribs 12, horizontal metal plates 17 are produced from below, welded to the insert plates 18 in the consoles of 8 columns 1. Plates are also installed on top of the support ribs 12 19. To create continuity of the middle crossbars 5, metal bonds 20 and 21 are welded to the lower 17 and upper 19 plates. Moreover, both plates are combined into a single embedded part 22 together with vertical strips 23, which are connected by welding to upper and lower longitudinal working rods 24 of the vertical reinforcing cages (Fig.9).

For joining the mounting of crossbars and columns in the outer rows of the frame in the grooves of 9 columns 2 and in the supporting ribs 13 of the crossbars 6, lower weldable embedded parts 25 and 26 are provided, and to create a frame in the crossbars 6 and grooves 9, the upper plates 27 and 28 are installed, which are welded to the reinforcing assembly 29. for ease of connection links 29 and the welding grooves 9 omonolichevaniya upper face 10 of the latter and the plate 28 are formed with a slope in the form of a wedge, and the value of i deviations should not exceed _^1/2 (10, 11, 12) .

To reduce the area of cold bridges and warm the outer crossbars 6, they have an external lower shelf 30, which is insulated with thermal liners 31, and wall 32, ribs 13 of the crossbars and columns 2 are insulated with thermo screens 33. Thermal liners and thermo screens are made of durable effective mineral insulation, their thickness is determined thermophysical calculation, but should not exceed the departure of the inner shelf 15.

When installing the facade cladding of external walls, the overhang of the outer shelf 30 of the extreme crossbars 6 should not exceed the total thickness of the insulation layer and the facing layer of panels, bricks or blocks plus the thickness of the ventilated gap, while the width “b” of the extreme crossbars 6 should not exceed the width “b” columns 2.

To increase the stiffness and strength of the floor disks 4 in the interplate seams 34 and in the joints 35 between the crossbars and the ends of the slabs, intermittent concrete keys 36 are provided, and on the crossbars and at the corners of the plates, embedded plates 37 are additionally mounted by welding metal plates in the form of plates 38 (Fig.13, 14).

In the overlap disk 4, after welding of embedded parts and welding of reinforcing ties and overlays to them, grooves 9 in columns 2, as well as seams 34 and joints 35 with dowels 36 are monolithic with non-shrink concrete.

At the junction, the middle columns 1 and crossbars 5 of the inner rows can have the same width b _k = b _p , so that the ribs 12 and the shelves 14 are closed at the junction from below the fire and make the joint more rigid, and the column thicknesses “h” and crossbars “h _p ” and plates "h _p " have the ratio h≥h _p ≥h _p .

To create a frame in the inner rows of the frame on the upper surface of the ends of the middle bolts 5, in the area between the supporting ribs 12 and, respectively, on the barrel of the columns 1, metal embedded plates 39 and 40 are provided, which are combined by welding metal plates 41, while lower metal plates 17 in the supporting ribs of the shelves of the crossbars are welded more powerful reinforcing ties 20, and the vertical seams 42 between the barrel of the columns and the ends of the crossbars are carefully monolithic non-shrink concrete (Fig.13, 14).

With limited spans of the crossbars to reduce the floor thickness and the weight of the floors by aligning the marks of the top of the slabs and the middle crossbars 5, the thickness "h _p " of the latter is taken equal to the thickness of the plates "h _p ".

With limited spans of the crossbars and the number of storeys of buildings to improve the layout and reduce metal shapes, the thickness "h" of the columns 1, 2 and the height "h _p " of the middle crossbars 5 can be taken equal to the thickness of the plates "h _p ", but not less than the thickness of the walls-diaphragms 3 .

With limited spans of the crossbars and the number of storeys of the building, in order to reduce the area of “cold bridges” in the outer walls and to reduce the consumption of concrete and insulation in the outer columns of the 2 outer frames, instead of the grooves 9, consoles 8 are made with the dimensions of the support area “a × h”, with the trunk width “ b ₃ "of the column must be at least the thickness of the column" h ", and to create the frame of the junction in the column on the barrel, above the consoles, mortgage plates similar to 40 are installed, which, by means of plates 41, are combined by welding with the upper mortgage plates 27 in the support p The bolts of the crossbars 13 (Fig. 15).

The adopted technical solutions due to the use of prestressing reinforcement in the middle beams and an increase in the stiffness and strength of the joints of the frame and floor disks make it possible to design fire-resistant structural systems of reinforced concrete buildings with increased spans of the crossbars taking into account the progressive collapse and seismic effects.

If necessary, instead of arranging grooves, the trunk of the outermost columns is already made, and the crossbars rest on the console of the columns, while the grooves disappear and wet, time-consuming and responsible processes for their monolinging are not required.

Claims (8)

1. A unified reinforced concrete prefabricated monolithic column-wall frame of the building, consisting of vertical load-bearing single and / or multi-storey rectangular in cross section of the middle and outer columns, respectively, of the inner and outer rows and diaphragm walls, united into a single spatial system by horizontal load-bearing floor disks, which are assembled from middle and extreme crossbars and plates, and in the outer rows of the columns are installed the greater side of the cross section along the building, and in the inner rows of the middle columns are installed rivers of the building, characterized in that in the middle columns for supporting the middle crossbars, consoles with a height not exceeding the thickness of the columns are made, and in the extreme columns for supporting the extreme crossbars there are grooves and bevels for ease of installation and laying of concrete mix, or the console in the extreme columns of the outer frames, the middle and outer columns have the same thickness and the width of the barrel of the middle columns does not exceed the width of the extreme columns, and the joints of single and / or multi-story columns are made flat and laid out above the slabs by at least a quarter and not more than half at the height of the floor, the cross-sectional width of the middle crossbars is not less than the total width of the barrel of the middle column and consoles, and the width of the extreme crossbars is not more than the width of the extreme columns, while the middle crossbars of the inner rows are made with two lateral supporting ribs, between which tensioned reinforcement is installed, and the extreme the crossbars of the outer rows are made from the ends with one middle supporting rib, the sizes of which on the bottom correspond to the support areas in the grooves of the extreme columns, while the middle and extreme crossbars have supporting lower shelves for bearing plates, the latter are supported by middle beams with undercutting, the dimensions of which correspond to the dimensions of the shelves in the middle beams, and on the extreme beams of the plate are supported in full height, which corresponds to the height of the wall of the crossbar, and the width of the wall and the height of the crossbars are not less than the thickness of the columns, while for joining on the installation of crossbars and columns in the inner row of the frame at the ends of the crossbars, the concrete of the lower shelves is cut, and horizontal metal plates are produced from the supporting ribs from below, which are welded to the embedded plates in the column consoles and plates are also installed on top of the supporting ribs, and to create continuity of the middle crossbars, metal bonds are welded to the lower and upper plates, and both plates are combined as a single embedded part together with vertical strips, which, like the plates, are connected by welding to the upper and lower longitudinal working rods of vertical reinforcing cages, while for welding on the mounting of crossbars and columns in the outer rows of the frame in the grooves of columns and in the supporting ribs of the crossbars, lower weldable embedded mortars are provided hoist, and creating ramnosti from above on the supporting ribs and grooves also mounted plate via welded reinforcing ties, for the convenience of welding which the upper face is formed with grooves deviations in the shape of a wedge, the slope value is less than ^_1/2. 2. The unified reinforced concrete precast-monolithic column-wall frame of the building according to claim 1, characterized in that for the insulation and reduction of the area of the cold bridges in the extreme crossbars, an external lower shelf is made, which is insulated with thermal liners, and the wall, the supporting rib of the crossbars and columns are insulated with thermo screens in this case, the departure of the outer shelf of the extreme crossbars does not exceed the total thickness of the insulation layer and the layer of facade cladding of panels, bricks or blocks plus the thickness of the ventilated gap, and the width of the extreme crossbars does not exceed w irins of the extreme columns. 3. The unified reinforced concrete prefabricated monolithic column-wall frame of the building according to claim 1, characterized in that to increase the rigidity and strength of the floor disks in the interplate joints and in the joints between the crossbars and the ends of the slabs, intermittent concrete keys are provided, and at the top of the crossbars and at the corners plates are additionally equipped with embedded plates combined by welding metal plates in the form of plates. 4. A unified reinforced concrete prefabricated monolithic column-wall frame of a building according to any one of claims 1 to 3, characterized in that at the junction the middle columns and crossbars of the inner rows have the same width so as to provide a bottom overlap at the junction of the side support ribs and lower shelves, and the thickness of the column is greater than or equal to the thickness of the crossbar, the thickness of which, in turn, is greater than or equal to the thickness of the plate. 5. A unified reinforced concrete precast-monolithic column-wall frame of a building according to any one of claims 1 to 3, characterized in that to create a frame in the inner rows of the frame on the upper surface of the ends of the middle crossbars, in the area between the supporting ribs and, accordingly, on the trunk columns, metal embedded plates are provided, combined by welding metal plates, while more powerful reinforcing bonds are welded to the lower metal plates in the supporting ribs of the crossbars of the crossbars, and vertical joints between scrap of columns and ends of crossbars are carefully monolithic by non-shrink concrete. 6. Unified reinforced concrete prefabricated monolithic column-wall frame of a building according to any one of claims 1 to 3, characterized in that, with limited spans of crossbars, to reduce floor thickness and weight of floors by aligning the marks of the top of the slabs and middle crossbars, the thickness of the latter is taken to be equal to the thickness of the slabs . 7. A unified reinforced concrete precast-monolithic column-wall frame of a building according to any one of claims 1 to 3, characterized in that, with limited spans of crossbars and number of storeys of buildings, to improve the layouts and reduce metal shapes of the thickness of columns and the height of the middle crossbars is made equal to the thickness of the plates, but not less than the thickness of the wall-diaphragms. 8. A unified reinforced concrete prefabricated monolithic column-wall frame of a building according to any one of claims 1 to 3, characterized in that, with limited spans of crossbars and number of storeys of the building, to reduce the area of "cold bridges" in the outer walls and reduce the consumption of concrete and insulation in the extreme instead of grooves, the columns of the outer frames have consoles, the width of the trunk of the outer columns of the outer frames having the consoles being no less than their thickness, and to create a rigid joint in the column above the consoles there are embedded plates that are combined LadKom mortgage with the upper plates in the support ribs.