UA79149C2 - Reinforced-concrete frame of high-raise building - Google Patents

Abstract

The invention relates to the branch of building, in particular to reinforced-concrete frames of dwelling houses and public buildings with any number of storeys. Reinforced, concrete frame of high-raise building includes columns 1, flat floor slabs 2 with continuous cross-section, along the faces of columns in alignment of those in mutually normal directions through armature 3 is placed, this is fixed at the ends of floors in perimeter of the frame. Through armature is placed in two levels in thickness of floor in pre-fabricated frames 4 of prismatic form with transverse armature 5. Frames include span elements 6 and over-support inserts 7 with placement of long armature of those with overlap in joint places. In the placed of intersection of frames, frame of one direction is arranged continuous and through, and frame of crossing direction adjoins its side walls with ends of span elements and has over-support insert. Intersected prismatic frames form frame-crossing system of bearing girth rails hidden in the plane of floors. Each section of flat floor slabs restricted with those hiddengirth rails is a plate pressed in contour in the girth rails. Simplification of technology of building is achieved, with decrease of labor consumption and increase of rate of building, with provision of minimal metal consumption of the frame.

Description

Description of the invention

The invention relates to construction, in particular, to reinforced concrete frames of residential buildings and public 2 buildings of different storeys, which are subject to increased requirements regarding the quality of architectural and volume-planning solutions. The area of construction using the proposed technical solution includes seismically active regions.

A well-known reinforced concrete frame of high-rise buildings |1)|, which includes columns and so-called beamless floors. Monolithic slabs of beamless floors are reinforced with flat or rolled welded grids, while 70 bending moments are perceived by cross-sections of slabs with grids laid in the lower zone, and supporting sections with grids in the upper zone of the slab.

The well-known frame was the most widespread in the former USSR and was the main type of structural solution in construction using monolithic reinforced concrete frames.

However, the known structure of the frame is inefficient, because it requires an increased consumption of steel for its 12 reinforcement, and even with such an increased consumption of reinforcing steel, the resistance of the slabs to being pressed by the column is insignificant, which requires the erection of capitals. Therefore, the frame in the presence of capitals does not provide free planning solutions.

A known technical solution |2| of a frame house, which includes a frame with flat slabs of floors and coverings, part of which is made with consoles, vertical stiffening elements and columns, placed in a plan with 20 different steps, as well as part of the columns, located with an offset relative to the higher or lower columns.

The well-known technical solution is designed to solve the problem of providing optimal conditions for the planning of interior spaces and a wide choice of construction variants with the same element base, and it is also aimed at reducing the weight of the house due to the use of light and hollow inserts in the floor slabs. p. 25 At the same time, in the known design of the frame of the house, due to the displacement of part of the columns relative to the lower ones, the danger of pressing the floors by the force concentrated in the column from the mass of the higher structures of the house increases significantly. To eliminate this danger, the floor on which such a column rests must be significantly strengthened, which leads to an excessive consumption of material. Therefore, the known structure of the frame is inefficient and causes the need for irrational consumption of materials for the frame and the house as a whole. o 30 The closest to the proposed one is the reinforced concrete frame of the house |Z) adopted as a prototype, which "I includes columns, a floor with through-through pre-stressed reinforcement, placed in one row according to the eupura of moments along the faces of the columns, in mutually perpendicular directions, and monolithic reinforced concrete slabs -- overlaps with channels. F

The structure of the frame is characterized by a relatively low metal capacity. However, there is a frame when erected

It is time-consuming, and the technology of its construction is multi-stage. First, a slab with channels is made, then - after waiting for time (up to 20..25 days), until monolithic concrete sets the required strength, working fittings are tensioned on the slab concrete, which requires special equipment and technology. Then the formwork is brought up from below the slabs and the channels and monolithic slabs are concreted. Such a design is quite time-consuming to implement, reduces the rate of construction of the house, and therefore such a technical solution is uneconomical. C 50 The proposed invention solves the problem of simplifying the construction technology, reducing labor costs and increasing the pace of construction, ensuring minimal metal content of the frame compared to known ones.

From" The solution to the given problem is achieved by the fact that in the reinforced concrete frame of a multi-story building, which includes columns, flat floor slabs, through-reinforcement, located along the faces of the columns in mutually perpendicular directions in accordance with the bending moment diagram and fixed at the ends of the floor along the perimeter of the building frame, through the reinforcement is placed along the columns' beams, in two levels with a thickness of 7 overlaps in pre-made prismatic-shaped rebar frames that have transverse reinforcement. With (That) This, the rebar frames, in turn, are made lengthwise of stringer elements and supporting inserts, the longitudinal reinforcement of which is placed in the overlap at the points of connection, and in the places where the rebar frames intersect, the rebar frame in one direction is made integral and through, and the rebar frame in the transverse direction і" 20 adjoins its lateral sides with the ends of the running elements and has a supporting insert, forming the integrity of the cross-direction armoframe. c In addition, each supporting insert is made of two parts, the upper of which includes a longitudinal rod working armature, united from above by U-shaped half-clamps, and is placed across the through-crossing reinforcing frame, directly above it and indented along the end sections of the running 22 of connecting frame elements, with the coverage of their connecting end sections, U-shaped from above

GF) with semi-clamps, and the lower part of the insert, which includes separate reinforcing bars or meshes, is placed directly above the ends of the lower reinforcement of the connecting reinforcing bars. o In addition, the running elements of the rebar frames can be made folded and consist in the cross section of at least two separate welded rebar frames with coiled transverse reinforcement and united along 60 of their length by U-shaped brackets installed from above.

In addition, the running elements of armokarkas can be made integrally from knitted reinforcement.

In addition, the frame of the house is made of monolithic reinforced concrete, and each section of flat floors, within the boundaries limited by prismatic reinforcement frames, has reinforcing meshes below, the reinforcement of which along the contour of each section is wound by the ends into the prismatic reinforcement frames, and additional transverse rods are installed directly above the prismatic reinforcement frames on the floor , the number of which should be sufficient to absorb the negative moment along the contour of the section in sections along the edges of the prismatic frames.

In addition, the sections of flat ceilings, which are limited on all sides by prismatic frame frames, can be made rectangular in plan.

In addition, sections of flat floors, which are bounded on all sides by prismatic armor frames, can be made wedge-shaped and/or trapezoidal in plan to provide the house with a circular and/or curvilinear outline in plan.

In addition, flat floor slabs along the contour can have consoles that extend beyond the outer rows of columns to accommodate balconies and/or bay windows, and in places where there are no consoles along the contour of the floor slab, together with the 7/0 slab, side beams can be made that protrude from the overlap plane down and/or up.

The execution of the frame in the proposed form with through-reinforcement along the columns, which is placed in two levels along the thickness of the floor in pre-made prismatic-shaped rebar frames that have transverse reinforcement, allows you to create a support system of crossbars, rigidly combined into a cross frame, in the plane of each floor slab , closed along the contour of the ceiling and supported on columns. Long through /5 reinforcement of such cross-beams hidden in the plane of the floor can be optimally and concentratedly placed along the beams, in which the greatest forces acting in the floor slab are acting. The amount of this longitudinal cross-reinforcement in any cross-section of such crossbars can be assigned an adequate value of these efforts. In addition, the installation of transverse reinforcement in rebar frames, in comparison with known ones, significantly increases the resistance of floor slabs to column compression. As a result of this, the load-bearing capacity of the floor slabs increases sufficiently and an opportunity is created to obtain flat slabs of small thickness without forming column capitals, even without the use of prestressing through reinforcement in the slabs.

In addition, the presence of reinforced frames and, accordingly, the frame system of the crossbars hidden in the plane of the floor slabs, allows you to consider each section of the floor slab, limited by these crossbars, as a plate clamped along the contour in these crossbars, taking into account the negative moments acting in the clamping. This allows the company to significantly reduce the consumption of steel for reinforcing all sections of the slabs.

Thus, the creation of a clear bearing system in the plane of the floor slab with the division of forces between elements i) allows, in comparison with the known ones, not only to minimize the consumption of metal for their reinforcement (up to 35..4095 ), but also to provide high adaptation conditions for the combination frame designs with real architectural solutions. Yes, the grid of the columns of the proposed framework can be irregular and have different column pitch sizes along the Ge! from any of the axes of the house, any column of the frame along the entire vertical line of the house can be shifted along the hidden crossbars from any connecting node of the reinforced frames, through-holes for the passage of vertical communications of the house can be made in any place of the floor slab, except for the plan, directly "- occupied by armor frames.

Designating the width of the reinforced frame, which would exceed the width of the column section, allows Me to simultaneously solve the following important tasks. First of all, a fairly wide reinforcing frame (as a rule, about twice the width of the cross-section of the column) allows you to place the working reinforcement in one layer of the floor and one layer below, thus it is possible to increase the working height of the slab cross-section as much as possible and at the same time minimize the consumption of longitudinal, including through fittings. Secondly, fairly wide reinforced frames allow you to effectively use the upper horizontal branches of its transverse reinforcement (clamps) to absorb part of the "negative moment acting under the load along the contour in the pinching of each section, which allows you to reduce the consumption of steel for reinforcing the floor slab from c.

The execution of reinforced frames composed lengthwise of running elements and supporting inserts allows for ;" in practice, implement a reliable frame system of load-bearing crossbars, hidden in the plane of the floor slabs. At the same time, this implementation allows to industrialize the procurement of reinforcement products of the frame, to significantly simplify the technology

Erection of the frame and to the same extent reduce labor costs on the construction site, as well as construction time. -I The execution of longitudinal reinforcement of running elements and support inserts in the places of their docking in the opening ensures the through arrangement of longitudinal reinforcement and conditions for the full implementation of the specified and above tasks. - Making the crossing points of the rebar frames in such a way that the rebar frame of one direction is made integral and through, and the rebar frame of the transverse direction adjoins its sides with the ends of the running elements and has a supporting insert, will form not only the integrity of the rebar frame of the transverse direction, but also allows

It is important to effectively place the upper working reinforcement of both intersecting reinforcement frames and to use its strength characteristics in the most stressed cross-sections of the slab in the column as fully as possible during operation.

In addition, the proposed implementation of the nodes of the intersection of the rebar frames allows the use of only one supporting insert in each node, which significantly simplifies its design and implementation.

The execution of each supporting insert made of two parts allows you to reliably combine the

Ф) length into a single through reinforcement of the rods of both the upper and lower level, and effectively include this ka reinforcement in the work. This is facilitated by the execution of the upper part of the supporting insert with longitudinal rod reinforcement, which is united on the surface by U-shaped half-clamps and distributed across the through-crossing reinforcing frame, which intersects, directly above it and indented along the end sections of the connecting integral girder elements of the reinforcing frame, covering their end connecting areas, from above with U-shaped clamps.

Indeed, under such conditions, in the joint node of the reinforced frames, the negative moments in one direction arising under the load are successfully perceived by sections with the upper reinforcement of the solid frame, and in the transverse direction by sections with the longitudinal reinforcement of the upper part of the support insert, which has an intermediate 65 reinforcement in in the form of U-shaped clamps, which cover the ends of the connecting frames from above, on both sides of the through-frame armature frame.

The execution of the truss elements of the frames as folded and composed in the cross-section of at least two separate welded rebar frames with coiled transverse reinforcement, united along their length by U-shaped brackets installed on top, allows the use of high-quality rebar frames obtained with automatic quality control welded joints, which excludes the influence of the subjective human factor on the quality of reinforcement products, thus ensuring the production of reinforcement products of increased reliability.

U-shaped brackets installed from above, which unite individual frames, together with their transverse reinforcement, provide effective inclusion in the operation of the transverse reinforcement of the frame frames for the perception of the transverse 7/0 Bending moment in the cross-section of the hidden crossbars, as well as the torque when placing them in create extreme rows of columns on the edge of the overlap.

The execution of the running elements of the rebar frames integrally from knitted reinforcement does not require special welding technological equipment and allows the production of rebar frames traditionally on the construction site, which makes the construction to the greatest extent independent of suppliers and environmental conditions.

The execution of the frame of the house from monolithic reinforced concrete makes the construction conditions largely independent of local manufacturers of construction products, since only reinforcing steel, concrete mixture components, a concrete mixer, as well as a concrete pump and a formwork system are required for construction. At the same time, reinforced frames can be simply placed in a monolithic slab according to the distribution of forces, and reinforcement of the slab within each of its sections can be performed only from the bottom with single-layer reinforcing meshes. This makes it possible to reduce the cost of steel for slab reinforcement by 2o by 30...407o, bring this indicator closer to prestressed floor slabs, as well as make floor slabs flat without parts protruding from them (butts, capitals, etc.) in the volume of the house . Placing additional transverse rods directly above the prismatic armor frames of the floor, the cross-section of which is sufficient to absorb the negative moment along the contour of the section in the sections along the edges of the adjacent frames, allows you to exclude the danger of cracks opening on the top of the slab at the edges of the overlapping sections.

The execution of sections of flat ceilings, limited by prismatic frame frames of a rectangular shape in i) plan, allows you to get a house and its regular sections using the proposed frame of any rectangular shape and length in plan.

Execution of sections of flat floors of a wedge-shaped or trapezoidal shape in plan allows you to get Ge! to implement corner and turning sections of the house, as well as to make a house with a curvilinear and joint outline in plan. -

The presence of consoles for the outer rows of columns in flat ceilings along the contour of the house allows to ensure "- architectural diversity of volumetric planning and artistic solutions of buildings with the use of bay windows, semi-bay windows, removable balconies, etc. The construction of the extreme rows of columns along the contour of the overlap of side me) with 5 beams protruding from the overlap plane downwards and/or upwards, as well as the execution of cantilever releases of the slab for the outer rows of columns, allows to significantly improve the working conditions under extreme and corner loads sections of the floor slab and make them the same as in the middle sections of the floor slab, treating each section as a slab clamped along the contour. For the same reason, additional rods are placed directly above them to absorb negative moments along the contour of the cross-sections. As a result, this allows you to significantly reduce the cost of steel for reinforcing the entire field of the floor slab, which is formed in the sum of all its sections, as well as to increase the reliability of the structural solution of the entire floor slab, to reduce the complexity of erecting the frame of the house as a whole. ;" A comparative analysis with the prototype allows us to conclude that the declared technical solution differs from the prototype in new features: (1) through-reinforcement along the column beams is placed in two levels according to the thickness of the overlap in (2) pre-made rebar frames of a prismatic shape, which have transverse reinforcement and with - And the width in the plan, which exceeds the width of the cross-section of the columns, (3) reinforced frames, in turn, are made lengthwise from running elements and supporting inserts, (4) the longitudinal reinforcement of which is placed in the joints at the joints. At the same time, in the places where the reinforcement frames cross, . (5) the armoframe of one direction is made integral and - through, and (6) the armoframe of the transverse direction adjoins its sides with the ends of the running elements and 5o has a supporting insert, forming the integrity of the armoframe of the transverse direction. At the same time, (7) each supporting insert is made of two parts, (8) the upper of which includes a longitudinal rod working

Ge) the reinforcement, united from above by U-shaped half clamps, and (9) is placed across the through-crossing reinforcing frame, directly above it and overhanging along the end sections of the connecting members of the reinforcing frame, with the coverage of the end sections that are joined, on top of P - similar semi-clamps, and (10) the lower part of the insert, which includes separate reinforcing rods or meshes, is placed directly above the ends of the lower . armatures of the running elements of the armoframe, which are connected. At the same time, (11) driving elements

F) rebar frames can be made folded and consist in cross-section, at least, of two separate welded rebar frames with coiled transverse reinforcement, (12) united along their length installed on top

U-shaped brackets. At the same time, (13) running elements of armorkares can be made whole from knitted reinforcement. At the same time, (14) the frame of the house is made of monolithic reinforced concrete, and (15) each section of flat floor slabs within the limits limited by prismatic reinforcement frames has a single-layer reinforcing mesh below, the reinforcement of which along the contour of each section is wound by the ends into prismatic reinforcement frames, and (16) ) additional transverse rods are installed directly above the prismatic frameworks of the floor. At the same time, (17) . sections of flat floor slabs, which are bounded by prismatic frame frames, can be made rectangular 65 in plan. At the same time, (18) sections of flat floor slabs, bounded on all sides by prismatic armor frames, can be made wedge-shaped and/or trapezoidal in plan to provide a circular outline of the house in plan. At the same time, (19) flat floor slabs along the contour have consoles that protrude beyond the outer rows of columns, and (20) in places where there are no cantilevers on the floor contour, together with the floor slab, side beams are made, protruding from the plane of the floor slab downwards and/or up.

In general, the proposed technical solution, according to the authors, meets the criterion of novelty, because the listed features in the given amount are unknown, and the obtained technical results of this solution ensure the achievement of the set task, surpass the known ones, and when implementing the proposed technical solution, a supertotal result is achieved. This allows us to consider the proposed technical solution as meeting the requirements of the inventive level. 70 The essence of the proposed technical solution is explained by drawings. Figure 1 shows the proposed frame, plan view; in Fig. 2 - the same, sections A-A (B-B) in Fig. 1; Fig. 3 shows the moments in the cross-sections of the flat slab of the proposed framework, at the center of the columns (A), and in the middle between the rows of columns (B); in Fig. 4 - the proposed framework at the stage of installation of prismatic reinforcement frames on the floor slab, plan view; in Fig. 5 - the same, section B-B in Fig. 4, in Fig. b - the same, section GG in Fig. 4; in Fig. 7 - the same / 5 Same, node A in Fig. 4, the node of joining armoframes and armature of the column; in Fig. 8 - the upper part of the supporting insert with longitudinal reinforcement and U-shaped half clamps; in Fig. 9 - the end view of the knitted running element of the armor frame; in Fig. 10 - a folded running element of the armor frame, end view; on

Fig. 11 - cross-section D-D in Fig. 4, in the case of a single knitted prismatic armoframe with the upper part of the supporting insert placed above it; in Fig. 12 the same, cross-section D-D in Fig. 4 in the case of a folded 2o frame with coiled transverse reinforcement; in Fig. 13 - cross-section E-E in Fig. 7, the unit of connection of mutually transversely assembled rebar frames, a plan view with a fragment of the overlap.

The proposed frame (Fig. 1-13) includes columns 1, flat slabs 2 ceilings of solid section. Through-reinforcement 3 is placed along the faces of columns 1 in their cross-section in mutually perpendicular directions at two levels in height. Through-reinforcement C is placed in rebar frames 4 of a prismatic shape with cross-member reinforcement 5. Rebar frames 4 are made lengthwise and include running elements 6 and supporting elements inserts 7. The longitudinal reinforcement 8 of the running elements 6 and the longitudinal reinforcement 9 of the supporting inserts 7 in places i) of the joints are placed overlapping, combining the reinforcement 8 and 9 into the through reinforcement 3. At the intersections of the frames 4 (Fig. 4), the reinforcing frame of one direction in in the form of a running element 6 is placed through. Running elements b of the other direction are adjacent to the through ends and have a supporting insert 7, forming the integrity of Ge! from the armoframe 4 of the transverse direction. Each support insert / consists of upper and lower parts.

The upper part of the insert 7 includes longitudinal reinforcement 9 and transverse U-shaped half-clamps 10. The lower branches of the U-shaped half-clamps 10 along the edges of the supporting insert 7 have anchor rods 11 welded to them from the outer side. The lower part of the supporting insert is made of separate reinforcement rods 12 or reinforcing meshes (not shown), placed directly above the ends of the lower armature of the connecting me) elements 6. The running elements b of the armoframes 4 can be made (Fig. 10, 12) composite, consisting, at least, of two separate welded reinforcing frames 13 with coiled transverse reinforcement 14, united along the length by U-shaped brackets 15. in the end sections, such a folded running element is also covered from above by U-shaped half-clamps 10 of the upper part of the supporting insert 7. Running elements 6 of the reinforcing frames 4 can be made (Fig. 9, 11) integrally in the form of a single knitted reinforcement "

A frame with a cross-section Z and additional reinforcement 8 installed according to the moment chart, combined -ptsh) with fully closed clamps 5.

Each section of flat slabs 2 floors, which is surveyed by prismatic frame frames 4, has below;" single-layer reinforcing meshes 16, the reinforcement of which is wound along the contour of the section by the ends 17 into the volume of the prismatic reinforcing frames 4, additional transverse rods 18 are installed on the floor, anchored at both ends in the concrete of the slab 2 with the help of anchoring reinforcing rods 19. Cross-sectional reinforcing rods 18 are selected by - And calculation of the magnitude of the negative moment acting on the contour of the section along the edges of the prismatic armor frames 4.

Each section of flat slabs 2 of the floor, which is limited by prismatic frame frames 4, which, in turn, form a kind of frame-cross system of crossbars hidden in the slab 2, is, according to the static scheme - working under load, a plate clamped by the edges in the specified crossbars . These sections in the plan can be square, rectangular, trapezoidal and of any other shape, which is determined by the general decision on the layout of the house.

Ge) Floor slabs 2 on the contour can have consoles 20 behind the outer rows of columns 1 for placing balconies or bay windows (not shown), and in places where there are no consoles 20 on the floor contour together with slab 2, side beams 21 protruding from the plane can be made plates 2 down and/or up." 5B The proposed frame of the house works under load as a single multiple statically indeterminate spatial frame structure with flat floor slabs. This structure together with vertical

F) stiffening diaphragms (or cores) (not shown) fully ensures the spatial rigidity and stability of the entire building as a whole.

Placement of armoframes 4 in the cross sections of columns 1 creates a hidden system of cross-bearing beams (crossbars) in the plane of the slab 2 of the ceiling, in which the panels of the slab 2 within each section are clamped at the edges. At the same time, the vertical load on each floor is perceived by the floor plate 2 and redistributes this load to the columns 1. In the presence of consoles 20 or side beams 21, the plate 2 within each section of the frame, which is limited by the spans of the columns 1, regardless of its position (in the middle of the frame , on the edge or in the corner), works under 65 load under approximately the same conditions. In this case, the slab of each floor section (frame) is clamped on all four sides, along which a negative bending moment also acts.

Indeed, this is confirmed by the results of the tests, when under the action of the vertical load applied to the plate until the moment before the collapse, it turns out to be fragmented within the sections into separate panels with cracks that are upper at the edges and lower in the middle of the sections. In the presence of side beams 21 or consoles 20, the operating conditions under the load of all panels (sections), regardless of their position in the floor, are approximately the same, in contrast to 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 of the overlaps, the deformations under the load develop more intensively, and their bearing capacity is lower than that of the middle panels, and the bearing capacity of the frame as a whole is underestimated. As a result of such placement 70 of the working armature of plate 2, which is adequate for the distribution of the largest values of forces in its sections, the strength properties of all the working armature of plate 2 are most fully used and its bearing capacity and rigidity increase significantly.

The presence of reinforcing frames 4 along the beams of the columns 1 allows you to concentrate along the hidden crossbars the longitudinal expansion forces that arise in them under load after the formation of the first cracks. These expansion forces 7/5 lead to the formation of reactive bending moments in the most stressed cross-sections of conventional cross-sections (in the middle of the spans and near the columns) with a sign that is the opposite of the sign moments acting from the load in the same cross-sections. The presence and accounting of the spacer effect in the flat slabs of monolithic and prefabricated monolithic floors allows to reduce by 20...3590 the forces acting in the calculated cross-sections of the floors, and, accordingly, to additionally reduce the need for reinforcing steel for their reinforcement by 15...3095 . Offered

The design of the frame allows you to fully implement the specified spacer forces and achieve the specified effect.

The proposed frame is erected in the following sequence. For the vast majority of cases of an engineering and geological situation, the frame and the house based on it are erected on a continuous flexible or rigid foundation slab (not shown in the drawing). During the execution of the foundations, the reinforcement of the columns and walls of the stiffening diaphragms is arranged to be released from them, after which the working reinforcement of these frame elements is installed with Ч2г5 Vertical reinforcement releases to the next floor. The formwork is assembled and the columns and walls are concreted to the height of the first floor or the underground above-foundation part of the house. Then, a continuous i) formwork (deck) of the floor slab and side stiffeners are installed on pre-mounted support devices (not shown in the drawings). The external wall of the house, which is erected under the ceiling, can be used as a support device for the onboard elements. Ge! zo First, continuous elements 6 with longitudinal and transverse reinforcement are fixed, and within the frame section between continuous elements 6, reinforced frames 4 with an overhang with lower longitudinal reinforcement - the latter are placed with reinforcing meshes 16, and then support inserts 7 are laid, with an overhang above the ends of the transverse (ho) elements b, which are connected. After the completion of laying and fixing in the design position all the reinforcement of plate 2, concrete pumps or buckets are used to feed and lay monolithic concrete of the plate and side beams on the deck. (22)

After filling the columns 1 and the interfloor slab 2 with concrete of the required strength, the supporting devices and the formwork are dismantled from the structures of the lower tier (floor) of the building and rearranged on the specified finished floor, and the cycle is repeated on the next tier (floor). The outer walls of the house, which are supported from floor to floor, 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 erecting frames complements the advantage of the structure, ensures all-weather and with a high pace of construction of a multi-story building. A house with the proposed frame can be built in

And in areas remote from production bases, since there is practically no need for factory-made prefabricated products.

The proposed technical solution will be widely used in the construction industries of Belarus, Russia and others

CIS countries. Its use will ensure the competitiveness of civil construction in these countries. -I Sources of information: 1 Kudzis A.P. Reinforced concrete and stone structures: Textbook for buildings. specialists, universities In 2 parts. ik Part 2. Constructions of industrial and civil buildings and structures. - M.: Higher school. 1989. p. 45... 47, fig. 2.12a. - 2. Patent of the Russian Federation Mo2173750, kl, E0481/18, BIMOo26, 20.09.2001.

Z. Patent of the Russian Federation Mo2166032, cl, E0481/18, BIMOo12, April 27, 2001 (prototype). sh» p

Claims (1)

The formula of the invention 1. The reinforced concrete frame of a multi-story building, which includes columns, flat floor slabs, through-reinforcement located along the faces of the columns in mutually perpendicular directions in accordance with (Ф) curve of bending moments and fixed on the ends of the floors along the perimeter of the frame of the building, GI, which differs in that through-reinforcement along the columns is placed in two levels along the thickness of the overlap in pre-made rebar frames of a prismatic shape, which have transverse reinforcement and width in plan, because What exceeds the width of the cross-section of the columns, the rebar frames, in turn, are made of lengthwise composites of thrust elements and supporting inserts , the longitudinal reinforcement of which is placed in the overlap at the joints, while at the intersections of the rebar frames, the rebar frame of one direction is made continuous and through, and the rebar frame of the transverse direction adjoins its sides with the ends of the thrust elements and has a supporting insert, forming the integrity of the rebar frame of the transverse direction. 65 2. The frame of the house according to claim 1, which is characterized by the fact that each supporting insert is made of two parts, the upper of which includes a longitudinal rod working armature, united on top by U-shaped half clamps, and is placed across a through-frame reinforcing frame that intersects, directly above it and overhanging along the end sections of the joining members of the rebar frame, with the coverage of the end sections joining from above with U-shaped half clamps, and the lower part of the insert, which includes individual reinforcing rods or meshes, is placed overhanging directly above the ends of the lower reinforcement of the overhanging elements of the reinforcing frame that are connected. C. The frame of the house according to claim 1 or 2, which differs in that the thrust elements of the reinforcing frames are made folded and consist in cross-section of at least two separate welded reinforcing frames with coiled transverse reinforcement, united along their length by U-shaped ones installed on top staples 70 4. The frame of the house according to claim 1 or claim 2, which is distinguished by the fact that the hinged elements of the frame are made integrally from knitted reinforcement. 5. The frame of the house according to any of claims 1-4, which is characterized by the fact that it is made of monolithic reinforced concrete, and each section of flat floor slabs within the limits limited by the prismatic reinforcement frames has a single-layer reinforcing mesh below, the reinforcement of which is along the contour of each section the ends are wound into the prismatic reinforcement frames, and additional transverse rods are installed directly above the prismatic reinforcement frames from above, the number of which should be sufficient to absorb the negative moment along the contour of the section in sections along the edges of the prismatic reinforcement frames. 6. The frame of the house according to any of claims 1-5, which is characterized by the fact that the sections of the flat slabs of the floors, which are limited by the prismatic frame frames, are rectangular in plan. 7. The frame of the house according to any of claims 1-5, which is characterized by the fact that the sections of the flat slabs of the floors, which are limited on all sides by prismatic frame frames, are made of a wedge-shaped and/or trapezoidal shape. 8. The frame of the house according to any of claims 1-7, which is characterized by the fact that the flat floor slabs on the contour have consoles that extend beyond the outer rows of columns, and in places where there are no cantilevers on the floor contour, side panels are made integral with the floor slab beams protruding from the plane of the floor slab downwards and/or upwards. o (o) « «- (o) and - - and? -i se) - sh» 3e) ime) 60 b5