EA007023B1 - Reinforced concrete frame of multistorey building - Google Patents

Abstract

The invention relates to construction, in particular, to reinforced concrete apartment buildings and social buildings making demands to quality of architectural and volumetric-planning concepts. The inventive technical solution includes construction in seismic zones, as well as simplification of construction technology, labour safe, acceleration of construction pace, providing minimum material capacity of the frame. The building frame (fig.4) comprises columns 1, flat flooring plates 2 of continuous section. Through reinforcement 3 is arranged in two levels along column edges in mutually perpendicular directions. The reinforcement is placed in reinforcement cages 4 of prismatic shape with transverse reinforcement 5. The reinforcement cages include span elements 6 and oversupport inserts 7 with their longitudinal reinforcement arranged overlapped. Each oversupport insert consists of upper and lower parts. The upper part of the insert comprises longitudinal reinforcement 9 and transverse Π-shaped semi-clamps 10, arranged above upper reinforcement of the span element and embraced from above by the Π-shaped semi-clamps 10 overlapped the ends of abutting elements 6. Crossing prismatic reinforcement cages form a box-frame system of carrying joists hidden in plane of flooring plate. Each cell of flat flooring plates limited by said hidden joists represent a plate jammed along the contour in these joists. Within flooring plate cell reinforcement is carried out only from below by single-layer mesh reinfocement.

Description

The invention relates to the construction, in particular, to the reinforced concrete frames of residential buildings and public buildings of different heights, to which they place increased demands on the quality of architectural and space-planning decisions. The construction area with the application of the proposed technical solution includes seismically active regions.

The reinforced concrete frame of multi-storey buildings [1] is well-known, including columns and so-called. non-girded floors. Monolithic slabs of non-slab ceilings are reinforced with flat or rolled welded meshes, while the passage moments perceive the cross-sections of the slab with the meshes laid in the lower zone, and the supporting ones - with the meshes in the upper zone of the slab.

The known frame was most widely used in the former USSR and was the main type of constructive solution in the case of construction using monolithic reinforced concrete frames.

However, the known construction of the frame is inefficient, because requires increased consumption of steel for its reinforcement, and even with such increased consumption of reinforcing steel, the resistance of plates to the punching of the column is insignificant, which requires the construction of capitals. Therefore, the frame due to the presence of capitals does not provide free planning solutions.

A technical solution [2] of a frame building is known, including a frame with flat floor slabs and coverings, some of which are made with consoles, vertical stiffeners and columns placed in plan with different pitch, as well as part of columns placed offset with respect to above or subordinate columns.

A known technical solution is provided for solving the problem of optimal conditions for the planning of interior spaces and a wide choice of alternative construction with the same element base, and is also aimed at reducing the mass of the building through the use of lightweight and hollow liners in floor slabs.

However, in the known construction of the frame of the building, due to the displacement of part of the columns relative to the lower, significantly increases the risk of forcing floors with a force concentrated in the column from the mass located above the building structures. To eliminate this danger, the overlap on which such a column rests must be significantly strengthened, which leads to excessive consumption of materials. Therefore, the known design of the frame is inefficient and causes irrational consumption of materials on the frame and the building as a whole.

The closest to the proposed is adopted as a prototype reinforced concrete frame of the building [3], including columns, floors with through prestressed reinforcement placed in one row according to the diagram of moments along the edges of the columns, and monolithic reinforced concrete floor slabs with channels.

The design of the frame has a relatively low metal content. However, the frame during the construction is busy, and the technology of its construction is multi-stage. First, a slab with channels is made, then, after aging in time (up to 20–25 days) before casting the required strength with monolithic concrete, working reinforcement is strained on the concrete slab, which requires special equipment and technology. Then, formwork is brought down from the bottom of the slab and the channels and monolithic slabs are decontaminated. Such a construction in its implementation is very time consuming, reduces the rate of construction of the building and therefore this technical solution is uneconomical.

The present invention solves the problem of simplifying construction technology, reducing labor costs and increasing the pace of construction, ensuring the minimum metal consumption of the frame compared with the known.

The solution of the task is achieved by the fact that in the reinforced concrete frame of a multi-storey building, including columns, flat floor slabs, through reinforcement located along the edges of the columns in mutually perpendicular directions in accordance with the curve of bending moments and fixed at the ends of the ceiling along the perimeter of the building frame, the through reinforcement along cross-sections of columns is placed in two levels along the overlap thickness in prefabricated prismatic-shaped armo carcasses equipped with transverse reinforcement. At the same time, the armo frameworks, in turn, are made of spans and nastop inserts composite in length, the longitudinal armature of which is placed overlap at the joints, and at the intersection of the armature carcasses, the armature of one direction is solid and through, and the armature of the transverse direction adjoins its side to the sides with the ends of the flying elements and provided with an overhead insert, forming the integrity of the reinforcement cage of the transverse direction.

In addition, each nadoporny insert is made of a composite of two parts, the top of which includes a longitudinal rod working reinforcement, combined from above by U-shaped semi-bolts, and placed across the intersected through-core reinforcement cage directly above it and overlapped along the end portions of the spliced armature frame with the span of the end-to-end their sections above are U-shaped semi-holders, and the lower part of the insert, including individual reinforcing bars or grids, is placed with an overlap directly above the end tsami bottom reinforcement docked spans armored frame.

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In addition, the span elements of the armature frames can be made of composite, consisting in cross section of at least two separate welded armature frames with wired transverse reinforcement and joined along their length by U-shaped brackets mounted from above.

In addition, span elements armokarkas can be made of one-piece knitted reinforcement.

In addition, the frame of the building is made of monolithic reinforced concrete, and each cell of flat floors in the limits bounded by prismatic reinforcement cages, is provided with lower reinforcing meshes, the reinforcement of which along the contour of each cell is wound with ends into prismatic reinforced frameworks, and directly above the prismatic reinforced frameworks above are installed additional transverse rods, the number of which should be enough to perceive the negative moment along the contour of the cell in sections along the edges of the prismatic frames.

In addition, the cells of flat floors, bounded on all sides by prismatic armo carcasses, can be made rectangular in plan.

In addition, the flat slab cells, bounded on all sides by prismatic armo carcasses, can be made with a wedge-shaped and / or trapezoidal shape in the plan with ensuring the building has a circular and / or curvilinear outline in the plan.

In addition, flat slabs along the contour can be provided with consoles for the outer rows of columns to accommodate balconies and / or bay windows, and in areas where there are no cantilevers along the contour of the floor slab, side beams extending from the floor plane downwards and / or upwards.

Carrying out the frame in the proposed form with through reinforcement along the column sections placed in two levels along the overlap thickness in preformed prismatic-shaped reinforcement cages, equipped with transverse reinforcement, allows creating in the plane of each floor slab a supporting system of crossbars rigidly joined in a cross-frame closed along the contour overlap and supported on columns. Longitudinal through reinforcement of such bolts hidden in the plane of the slab of an overlap can be optimally and concentrated placed along the sections, in which the greatest efforts are exerted that occur in the slab of overlap. The amount of this longitudinal through reinforcement in any section of such beams can be assigned to an adequate amount of these efforts. In addition, the installation of transverse reinforcement in armo frameworks, as compared with the known ones, significantly increases the resistance of floor slabs to column punching. As a result, the load-bearing capacity of floor slabs is sufficiently increased and the opportunity to produce flat slabs of small thickness is created without arranging the capitals of the columns, even without the use of reinforcement through the prestress plates.

In addition, the presence of armo carcasses and, accordingly, the frame system of the crossbars hidden in the plane of the plates, makes it possible to consider each cell of the floor slab bounded by these crossbars as a plate clamped along the contour in these crossbars, taking into account the negative aspects acting in pinching. This can significantly reduce the consumption of steel for the reinforcement of all the cells of the plates.

Thus, creating a clear bearing system in the plane of the slab with the separation of forces between the elements allows, in comparison with the known, not only to minimize the metal consumption for their reinforcement (up to 35-40%), but also to provide high adaptation conditions for combining the frame design with real architectural solutions. Thus, the grid of columns of the proposed frame may be irregular and have different column sizes on any of the building axes; any column of the frame along the entire vertical of the building can be displaced along hidden girders from any junction of armature frames; through openings for the passage of vertical building communications can be made in any place of the floor slab, except for the plan directly occupied by the reinforcement cages.

The purpose of the reinforcement cage width exceeding the width of the column section allows you to simultaneously solve the following important tasks. Firstly, a sufficiently wide reinforcement cage (usually around two widths of the column section) allows placing the working reinforcement in one layer on top and in one layer at the bottom, thereby maximizing the working height of the plate section as much as possible and thus minimizing the longitudinal flow, including including through reinforcement. Secondly, sufficiently wide armo carcasses make it possible to effectively use the upper horizontal branches of its transverse reinforcement (clamps) to perceive a part of the negative moment acting under the load along the contour to pinch each cell, which reduces the steel consumption for reinforcement of the floor slab on top.

The execution of armo frameworks of composite spans of elements and nadoporny inserts allows in practice to implement a reliable frame system of load-bearing beams, hidden in the plane of the floor slabs. At the same time, such an implementation makes it possible to industrialize the procurement of reinforcement products for the framework, to substantially simplify the technology for the construction of the framework and to reduce the labor costs on the construction site, as well as the construction time.

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The implementation of the longitudinal reinforcement of the spans and the support inserts in the places of their overlapping joints provides a through arrangement of the longitudinal reinforcement and conditions for the full implementation of the above tasks.

Making the intersection of the armature frames so that the armature of one direction is made solid and through, and the armature of the transverse direction adjoins its sides with the ends of the span elements and is equipped with an overhead insert, it forms not only the integrity of the armo-frame of the transverse direction, but also allows you to effectively place the upper working armature both intersecting armo carcasses and maximally use, in operation, its strength characteristics in the most intense sections of the slab at the column us In addition, the proposed implementation of the nodes of the intersection of Armokarkas allows each node to apply only one nadoporny insert, which greatly simplifies its design and execution.

The implementation of each nadoporny insert, a composite of two parts, allows you to reliably combine the lengths of the upper and lower levels into a single through reinforcement and effectively put this reinforcement into operation. This is facilitated by the implementation of the upper part of the nadoporn insert with a longitudinal rod reinforcement, combined on top by U-shaped semi-clamps and placed across the intersected through frame, directly above it and overlapped along the end sections of the joined single-piece armature frame elements with the U-shaped clamps covering the top of the U-shaped clamps. Indeed, under such conditions in the butt assembly of armature frames, negative moments arising under load in one direction successfully perceive sections with the upper reinforcement of the solid frame, and in the transverse direction - sections with longitudinal reinforcement of the upper part of the nodoporn insert fitted with indirect reinforcement in the form of U-shaped clamps, covering the ends of the docked span frames on both sides of the through reinforcement cage.

Completion of spans of skeletons of composite, consisting in cross section of at least two separate welded armature frames with wound transverse reinforcement, united by U-brackets mounted on top of their length, allows using high-quality armature frames obtained with automatic quality control of welded joints, eliminating the effect on the quality of reinforcement products of the subjective human factor, thereby ensuring the production of reinforcement products of increased reliability.

U-shaped brackets installed from above, which unite the individual frames, together with their transverse reinforcement, ensure the effective incorporation of reinforcement cages in the transverse reinforcement to the perception of the transverse bending moment in the cross section of the hidden crossbars, as well as the torque when placing them in the alignment of the outer rows of columns on the edge overlap.

The execution of single-piece armature frame spans from knitted fittings does not require special welding process equipment and makes it possible to manufacture arm cages traditionally on the construction site, which makes construction most independent from suppliers and environmental conditions.

The construction of the monolithic reinforced concrete frame makes the construction conditions most independent of local producers of building products, since construction requires only reinforcing steel, concrete components, a concrete mixer, as well as a concrete pump and formwork system. However, the reinforcement cages can be simply placed in a monolithic slab in accordance with the distribution of forces, and the reinforcement of the slab within each of its cells can be performed only at the bottom with single-layer reinforcing mesh. This allows reducing the steel consumption for reinforcement of the slab by 30-40%, bringing this figure closer to the prestressed floor slabs, and also making the floor slabs flat without parts protruding from them (bees, capitals, etc.) into the building. Placing directly above the prismatic armo carcasses on top of additional transverse rods, the sections of which are sufficient to perceive the negative moment along the contour of the cell in sections along the edges of adjacent frames, eliminates the risk of cracks opening on the top of the slab at the edges of the cells of the overlap.

Performing cells of flat slabs, limited by prismatic armo-frames of rectangular shape in plan, allows to obtain a building and its ordinary sections using the proposed framework of any rectangular shape and length in plan.

The execution of cells of flat floors of a wedge-shaped or trapezoidal shape in the plan allows obtaining and realizing the angular and turning sections of the building, as well as the buildings of curvilinear and circular outlines in the plan.

The supply of flat floors along the contour of the building with consoles for the outer rows of columns makes it possible to ensure the architectural diversity of space-planning and artistic solutions for buildings using bay windows, semi-power windows, remote balconies, etc. Execution in alignments of the extreme rows of columns along the contour of the overlap of the side beams protruding from the floor plane downwards and / or upwards, as well as the arrangement of cantilever plate releases for the outer rows of columns, can significantly improve the working conditions under the load of the outermost and corner cells of the floor plate and make they are the same as in the middle cells of the floor slab, treating each cell as a slab,

- 3 007023 along the contour. For the same reason, for the perception of negative moments along the contour of the cells across the reinforcement cages, additional rods are placed directly above them. As a result, it allows to significantly reduce the consumption of steel for the reinforcement of the entire field of the slab, which is formed in sum with all its cells, increase the reliability of the design solution of the whole slab, and reduce the laboriousness of the construction of the building frame as a whole.

Comparative analysis with the prototype allows us to conclude that the claimed technical solution differs from the prototype with new features: (1) the through reinforcement along the columns of the columns is placed in two levels in overlap thickness in (2) prefabricated prismatic-shaped armature frames equipped with transverse reinforcement and with a width in plan greater than the width of the cross section of the columns, (3) the armature frames, in turn, are made of spans and overhead inserts that are composite in length, (4) whose longitudinal reinforcement at the joints meschena overlap. At the same time, at the intersection of the armo carcasses (5), the armo carcasses of one direction are made one-piece and through, and (6) the armo carcass of the transverse direction is adjacent to its lateral sides with the ends of the span elements and is provided with an overhead insert, forming the whole armo carcass of the transverse direction. At the same time, (7) each nadoporny insert is made of a composite of two parts, (8) the upper of which includes a longitudinal rod working reinforcement united from above by U-shaped semi-clamps, and (9) is placed across the intersected through reinforcement cage directly above it and overlapped along the end sections of spliced armature frame spans with a spanning of spliced end sections on top of U-shaped semi-sleeves, and (10) the lower part of the insert, including individual reinforcing bars or grids, is placed with an overlap directly on ends of the lower armature abutting span reinforcement elements. In this case (11), the span elements of the armature frames can be made of composite, consisting in cross section of at least two separate welded armature frames with wound transverse reinforcement, (12) United along their length by the P-shaped brackets installed from above. At the same time (13) the span elements of the armature frames can be made of one-piece knitted reinforcement. At the same time (14) the frame of the building is made of monolithic reinforced concrete, and (15) each cell of flat floor slabs within the limits bounded by prismatic reinforcement cages, is fitted to the bottom with single-layer reinforcing mesh, the reinforcement of which along the contour of each cell is wound with the ends into prismatic reinforced frameworks, and (16) directly above the prismatic armo carcasses, additional transverse rods are installed on top. At the same time, (17) cells of flat floor slabs, limited by prismatic armo carcasses, can be made rectangular in plan. At the same time, (18) cells of flat slabs, bounded on all sides by prismatic armo carcasses, can be made wedge-shaped and / or trapezoidal in plan with the provision of obtaining a circular outline in the building. In this case, (19) flat slabs along the contour are provided with consoles for the outer rows of columns, and (20) in the absence of consoles on the contour of the slab, side beams are made at the same time as the slab protruding from the plane of the slab downwards and / or upwards.

In general, the proposed technical solution, according to the authors, meets the criterion of novelty, since the listed features in the above amount are unknown, and the technical results of this solution ensure the achievement of the task, surpass the known ones, and the implementation of the proposed technical solution achieves a super-total result. This allows us to consider the proposed technical solution to the relevant requirements of the inventive step.

The essence of the proposed technical solution is illustrated by drawings. FIG. 1 shows the proposed frame, plan view; in fig. 2 - the same, sections A-A (BB) in FIG. one; in fig. 3 is a plot of moments in sections of a flat slab of the proposed framework, in the alignment of the columns (A), and in the middle between the rows of columns (B); in fig. 4 - the proposed frame at the stage of installation of prismatic reinforced frames on the floor slab, view in plan; in fig. 5 is the same section bb in FIG. four; in fig. 6 - the same, section G-D in FIG. four; in fig. 7 is the same, node A in FIG. 4, the junction of the reinforcement cage and reinforcement of the column; in fig. 8 - the upper part of the supra-insert with longitudinal reinforcement and U-shaped semi-clamps; in fig. 9 - knitted span of arm-carcass, end view; in fig. 10 - composite span element of the reinforcement cage, end view; in fig. 11 - section DD in FIG. 4, in the case of a solid knitted prismatic reinforcing cage, with the placement of the upper part of a nastop insert over it; in fig. 12 is the same, the DD section in FIG. 4 in the case of composite reinforced cage with wound transverse reinforcement; in fig. 13 is a section E-E of FIG. 7, the armature frame mate is mutually transverse in the direction of assembly, plan view with a fragment of the overlap.

The proposed frame (Fig. 1-13) includes columns 1, flat plates 2 floors of solid section. Through the sides of the columns 1 in their alignment in mutually perpendicular directions in two levels along the height is placed through fittings 3. The through fittings 3 are placed in armature frames 4 of a prismatic shape with transverse armature 5. Armature frames 4 are made composite in length and include flying elements 6 and nodopornye inserts 7 The longitudinal reinforcement 8 of the spans 6 and the longitudinal reinforcement 9 of the nodal inserts 7 are placed overlapped at the joints, integrating the reinforcement 8 and 9 into the through reinforcement 3. At the intersection of the reinforcement cages 4 (Fig. 4) the reinforcement cage one direction in the form of the flying element 6 is placed through. Span elements 6 other direction primo

- 4 007023 cabins to the end-to-end and are provided with a retaining insert 7, forming the integrity of the reinforcement cage 4 of the transverse direction. Each retaining insert 7 consists of upper and lower parts. The upper part of the insert 7 includes longitudinal reinforcement 9 and transverse U-shaped semi-sleeves 10. The lower branches of the P-shaped semi-sleeves 10 along the edges of the nadvodny insert 7 are equipped with anchor rods 11 that are welded to them from the outside 11. The lower part of the nadvorno insert is made of separate reinforcing rods 12 or rebar (not shown) placed overlapping directly above the ends of the lower reinforcement of the spliced spans 6. The spans 6 of the armature frames 4 can be made (Fig. 10, 12) with components consisting of, at a minimum, from two separate welded reinforcement cages 13 with wound transverse reinforcement 14, combined by U-shaped brackets 15. At the end sections such a composite span element is also covered from above by U-shaped semi-grommets 10 of the upper part of the nodoporn insert 7. The spacing elements 6 of the armature frames 4 can be made (Fig. 9, 11) solid in the form of a single knitted reinforcement cage with a through 3 and an additional 8 reinforcement installed according to the plot of moments, united by fully closed clamps 5.

Each cell of flat slabs 2 floors, bounded by prismatic armo carcasses 4, is provided with lower single-layer reinforcing meshes 16, the armature of which along the contour of the cell is wound with ends 17 in the volume of prismatic reinforcers 4. Directly above the prismatic reinforcers 4 above, additional transverse rods 18 are mounted, anchored along both ends in the concrete slab 2 using anchor reinforcing bars 19. The cross section of reinforcing bars 18 are selected with the calculation of the magnitude of the negative moment acting along the contour cells along the edges of prismatic reinforcement cages 4.

Each cell of flat slabs of 2 floors, bounded by prismatic armo carcasses 4 and, in turn, forming a kind of frame-cross system of bolts hidden in slab 2, is a plate, clamped by the edges in the specified crossbars, according to the static scheme of work. These cells in the plan can be made square, rectangular, trapezoidal, and any other shape, which is determined by the general layout of the building.

Slabs 2 on the contour can be equipped with consoles 20 for the outer rows of columns 1 to accommodate balconies and / or bay windows (not shown), and in areas where there are no cantilevers 20 on the contour of the floor, side beams 21 projecting from the plane Plate 2 down and / or up.

The proposed building framework works under load as a single, repeatedly statically indeterminate spatial frame structure with flat floor slabs. This design, together with the vertical diaphragms (or cores) of stiffness (not shown) fully ensures the spatial rigidity and stability of the entire building as a whole.

Placing in the columns of columns 1 of armo frames 4 creates, in the plane of the slab 2 of the overlap, a hidden system of cross-bearing beams (crossbars) in which the panels of the slab 2 within each cell are trapped at the edges. At the same time, the vertical load on each floor is perceived by the floor slab 2 and redistributes this load to the columns 1. If there are cantilevers 20 or side beams 21, the slab 2 within each frame cell bounded by the alignments of the columns 1, regardless of its position (in the middle of the frame, edge or corner), works under load in about the same conditions. In this case, the slab of each cell overlap (frame) is trapped on all four sides, along which a negative sign bending moment also acts. Indeed, this is confirmed by the test results when, under the action of the vertical load applied to the slab, by the time before destruction, it is dissected within the cells into separate panels by the upper cracks at the edges and lower in the middle of the cells. In the presence of side beams 21 or consoles 20, the working conditions under load of all panels (cells), regardless of their position in the floor, are about the same, unlike flat floors that do not have side beams 21 or consoles 20. In the latter case, in the absence of elements 20 and 21 in the extreme and, especially, in the corner panels, deformations under load develop more intensively, and their bearing capacity is lower than the middle panels, and the bearing capacity of the frame as a whole is found to be too low. As a result of such placement of the working reinforcement of the plate 2, adequate to the distribution of the greatest values of efforts in its sections, the strength properties of the entire working reinforcement of the plate 2 are most fully used and its bearing capacity and rigidity significantly increase.

The presence of armo carcasses 4 along the column sections 1 allows concentrating the longitudinal expansion forces along the hidden girders arising in them under load after the formation of the first cracks. These strut forces lead to the formation of reactive bending moments in the most stressed sections of the conditional crossbars (in the middle of the spans and at the columns) with the sign opposite to the sign of the moments acting on the load in the same sections. The presence and consideration of the expansion effect in flat slabs of monolithic and precast monolithic slabs allows reducing by 20-35% the efforts acting in the calculated sections of the slabs, and accordingly, by 15-30% to further reduce the need for reinforcing steel for their reinforcement. The proposed design of the frame allows you to fully realize the specified spacer efforts and to achieve the specified effect.

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The proposed frame is erected in the following sequence. For the overwhelming majority of cases of engineering-geological situation, the skeleton and the building based on it are erected on a solid flexible or rigid base plate (not shown in the drawing). When arranging foundations, they arrange the issues of reinforcement of columns and walls of diaphragms of rigidity, then install the working reinforcement of these frame elements with vertical releases of reinforcement to the next floor. Collect formwork and concreted columns and walls to the height of the first floor or the underground underfound part of the building. Then install a solid formwork (deck) of the slab and side stiffeners on the pre-mounted support devices (not shown in the drawings). The outer wall of the building erected under the ceiling can also be used as supporting devices for the onboard elements. On the deck, in column sections 1, first, full-span elements 6 with longitudinal and transverse reinforcement are installed and fixed, and reinforcing meshes 16 are placed between full-span elements 6 of armature frames 4 with overlap with lower longitudinal reinforcement within the framework cells, and then the nodal inserts 7 are superimposed over the ends of the transverse joined elements 6. After the completion of laying and fixing to the design position of the entire reinforcement of the plate 2, concrete pumps or buckets are served and laid on the deck monolithic concrete slabs and side beams.

After the concrete columns 1 and the interfloor plate 2 overlap with the required strength, the supporting devices and the formwork are dismantled from the structures of the lower tier (floor) of the building and rearranged to the specified finished floor, and the cycle repeats on the next tier (floor). Floor-supported exterior walls of the building can be arranged simultaneously with the construction of the frame and use them as supporting devices and formwork for side beams.

The presented technology of the construction of the frame complements the advantage of the design, provides all-weather capability and a high rate of construction of a multi-storey building. The building with the proposed frame can be erected in areas remote from the production bases, since there is practically no need for prefabricated prefabricated products.

The proposed technical solution will find wide application in the construction industries of Belarus, Russia and other CIS countries. Its use will ensure the competitiveness of civil engineering in these countries.

Information sources

1. Kudzis A.P. Reinforced concrete and stone structures: A textbook for building. specialist. universities. In 2 parts. Part 2. Constructions of industrial and civil buildings and structures. - M .: Higher School 1989. p. 45-47, fig. 2, 12a.

2. RF patent №2173750, cl. Е04В 1/18, BI№26, 20.09.2001.

3. RF patent №2166032, cl. Е04В 1/18, BI№12, 04.27.2001 (prototype).

Claims (8)

CLAIM 1. Reinforced concrete frame of a multistory building, including columns, flat slabs, through reinforcement located along the faces of the columns in mutually perpendicular directions in accordance with the diagram of bending moments and fixed at the ends of the floors along the perimeter of the building frame, characterized in that the through reinforcement along the columns is placed in two levels over the thickness of the overlap in the prefabricated prismatic-shaped armo carcasses, equipped with transverse reinforcement, and with a width in the plan exceeding the width the column sections, armo carcasses, in turn, are made of composite elements of spans and overhead inserts, the longitudinal armature of which is placed overlapped at the joints, while at the intersection of the armature carcasses, the armature of one direction is made integral and through, and the armature of the transverse direction adjoins its sides with the ends of the span elements and provided with a nadoporny insert, forming the integrity of the reinforcement cage of the transverse direction. 2. Building frame according to claim 1, characterized in that each nadoporny insert is made of two parts, the upper of which includes a longitudinal rod working reinforcement, combined from above by U-shaped semi-slips, and placed across the crossed through reinforcement cage directly above it and overlapped along the end portions of the spliced armature frame spans with the overlap of the end portions being joined at the top are U-shaped half-sleeves, and the lower part of the insert, including individual reinforcing bars or grids, is placed inside Lest directly above the ends of the lower armature abutting span reinforcement elements. 3. Building frame according to claims 1, 2, characterized in that the spans of the armature frames are made of composite, consisting in cross section of at least two separate welded armature frames with wired transverse reinforcement, joined by U-shaped brackets mounted on top of them. 4. Building frame according to claims 1, 2, characterized in that the spans of the armature frames are made from knitted fittings. - 6 007023 5. Building frame according to claims 1-4, characterized in that it is made of monolithic reinforced concrete, and each cell of flat floor slabs within the limits bounded by prismatic reinforced frames is provided with lower single-layer reinforcing meshes, the reinforcement of which along the contour of each cell is wound with ends into prismatic reinforced frameworks, and directly above the prismatic reinforcement frames, additional transverse rods are installed on top, the number of which should be sufficient to perceive the negative moment along the contour of the cell in the section Barrier-along the edges of the prismatic reinforcement. 6. The frame of the building according to claims 1-5, characterized in that the cells of the flat floor slabs, bounded by prismatic reinforcement cages, are rectangular in plan. 7. Building frame according to claims 1-5, characterized in that the cells of flat floor slabs, bounded on all sides by prismatic reinforcement cages, are made of a wedge-shaped and / or trapezoidal shape. 8. Building frame according to claims 1-7, characterized in that the flat floor slabs on the contour are equipped with consoles for the outer rows of columns, and in the absence of consoles on the contour of the floor, side beams are made at the same time as the floor slabs protruding from the floor slab plane / or up.