EA037678B1 - Reinforced concrete frame without collar beams for seismic areas with combined reinforcement - Google Patents

Abstract

The invention relates to construction, in particular to industrial and civil construction, where the construction height of premises is reduced, the material consumption of the structure and building as a whole becomes lower, and the labor intensity of formwork is reduced. The substance of the invention is that slabs made of cast in-situ reinforced concrete with combined (steel and basalt-plastic) reinforcement are based on the joint work of a slab-beam with a column, which is a rigid assembly of the frame. The solid slab of interfloor and coverings with basalt-plastic reinforcement is divided into the slab-beam, which acts as beams along the axes of columns, and a middle slab. The rigid connection of the slab with the column forms a frame structure where all elements of the flooring are monolithically interconnected. The said slab-beam is reinforced with a combined reinforcement cage that consists of the upper combined working reinforcement, namely two steel bars and two basalt-plastic reinforcements, and is combined into a spatial reinforcement cage using transverse reinforcement and tying wires. The support bracket of the slab joint has only steel reinforcement, which is welded to it, and a composite reinforcement is inserted when the reinforcement cage is created.

Description

The invention relates to construction, namely to industrial and civil construction, in which the building height of the premises is reduced, the material consumption of structures and the entire building as a whole, and the labor intensity of formwork is reduced.

Especially in the construction of residential and public buildings, the absence of protruding ribs of floor beams (crossbars) improves the architectural expressiveness of the premises [1].

It is known that a similar prefabricated monolithic girderless frame [2], consisting of prefabricated slabs - above-column, inter-column and middle, connected to each other and to the column, are used in the Republic of Tajikistan. These designs were developed by NPO Monolit (Moscow, Russian Federation).

The closest are the aforementioned prefabricated monolithic elements of the frame [2], in which the precast column slab is connected to the working reinforcement of the column by welding the embedded metal shell plate with subsequent concreting of the joint cavity.

The disadvantages of this frame made of prefabricated monolithic elements are numerous connections of elements of floor slabs, which require the production of qualified welding and concrete work.

In the proposed invention, numerous connections of elements of floor slabs are absent, in addition, due to the lower material consumption of the structure due to the low density of the reinforcement, the weight of the joint decreases, and the only node in the whole overlap is performed by welding the element of the support table and the working reinforcement of the column (Fig. 3).

The aim of the present invention is to introduce a new type of slab-beam connection with combined reinforcement with basalt-plastic reinforcement of a girder-free frame made of monolithic reinforced concrete with a column (Fig. 3).

The goal is achieved by passing basalt-plastic reinforcement between the working rods of the support reinforcement, which is 50% of the support reinforcement of the hidden beam of the frame and which is subsequently combined into the spatial frame of the hidden beam (Fig. 3), which perceives the supporting bending moment together with the rest of the reinforcement.

A girder-free frame made of monolithic reinforced concrete with combined reinforcement is created as follows:

1) the column of this floor is concreted to the level of the bottom of the monolithic slab;

2) the formwork of the slab is installed at the design level;

3) a factory-made steel support table is put on the working reinforcement of the column;

4) the working reinforcement of the column is welded to the support table;

5) a working combined reinforcement (steel bar reinforcement and basalt-plastic reinforcement) of slab-beams and reinforcing bars of the slab is installed; reinforcement bars are combined into knitted reinforcement cages and reinforcement meshes;

6) after completion of the inspection work and drawing up an act of hidden work, they proceed to concreting the elements.

The principle of operation of the proposed frame made of monolithic reinforced concrete with combined reinforcement (basalt-plastic) is based on the joint work of a slab-beam with a column, which is a rigid node of the frame frame.

The proposed version of a girder-free frame made of monolithic reinforced concrete with combined reinforcement consists of a slab and a column, which, when working together, form a frame and differs in that a beam is hidden in the slab with a height equal to the height of the slab and a width (conditional) equal to the width of the column section, and reinforced with working combined reinforcement with a cross-section equal to half of the cross-section of the working reinforcement of the slab-beam (steel and basalt-plastic reinforcement). The slab-beam plays the role of a horizontal element of the frame structure, which provides its spatial rigidity and has a rectangular section with a width equal to one fourth of the span on each side of the column axis, and a height equal to the height of the slab section. The area of the working reinforcement of the slab-beam is divided into two equal parts, which are placed in the form of the working reinforcement of the hidden beam (steel and basalt-plastic reinforcement) and the reinforcement mesh of the slab (Fig. 1, 2, Tables 1, 2). The connection of the slab-beam to the column is carried out using a support table with a collar, and the working rods of the slab-beam are connected to this collar from four sides. The number, sizes and classes of fittings are given in table 1-4.

This constructive system was developed and tested at the Department of Industrial and Civil Engineering of the TTU named after academician M.S. Osimi.

The grid of columns in these systems can be used 4.8x4.8, 5.6x5.6, 6.0x6.0, 6.6x6.6 and 7.2x7.2 m. It is also possible to use a rectangular grid of columns within the above limits. The temporary payload on the floor can be in the range from 4 to 12 kN / m ² .

Literature.

1. Sharipov L., Nuraliev K., Iskhakov Ya.Sh. Constructions by ohanubetoni wa sangin. Kursi umumy, kitobi 2, 2016 p., Dushanbe.

2. Dozhvenko S.V. Girder-free reinforced concrete prefabricated monolithic frame of a multi-storey building / RF patent 76051.

- 1 037678

Table 1

Cross-sectional area, number and diameter of the working reinforcement of the slab-beam

Temporary payload, kN / m ² Design section The area of the working reinforcement of the slab - beams, cm ² / <1, n, A500s 4.8x4.8 5.4x5.4 6.0x6.0 6.6x6.6 7.2x7.2 4,00 supporting ll, 4 / 4dl6 + 10dl0 15.3 / 4dl6 + 12dl0 18.5 / 4dl8 + 12dl0 19, l / 4dl8 + 14dl0 26.7 / 4d22 + 16dl0 flyover ll, 4 / 4dl6 + 10dl0 15.3 / 4dl6 + 12dl0 18.5 / 4dl8 + 12dl0 19, l / 4dl8 + 14dl0 26.7 / 4d22 + 16dl0 6.00 supporting 12.7 / 4dl6 + 10dl0 16.4 / 4dl6 + 12dl0 24.0 / 4d20 + 12dl2 24.8 / 4d20 + 14dl2 33.3 / 4d22 + 16dl2 flyover 12.7 / 4dl6 + 10dl0 16.4 / 4dl6 + 12dl0 24.0 / 4d20 + 12dl2 24.8 / 4d20 + 14dl2 33.3 / 4d22 + 16dl2 8.00 supporting 15.3 / 4dl6 + 10dl0 20.2 / 4dl8 + 12dl0 26, l / 4d20 + 12dl2 30.0 / 4d22 + 14dl2 40.0 / 4d28 + 16dl2 flyover 15.3 / 4dl6 + 10dl0 20.2 / 4dl8 + 12dl0 24.0 / 4d20 + 12dl2 30.0 / 4d22 + 14dl2 40.0 / 4d28 + 16dl2 10.00 supporting 16.5 / 4dl8 + 10dl0 25.0 / 4d20 + 12dl2 27.2 / 4d20 + 12dl2 33.3 / 4d22 + 14dl2 44.7 / 4d28 + 16dl4 flyover 16.5 / 4dl8 + 10dl0 25.0 / 4d20 + 12dl2 27.2 / 4d20 + 12dl2 33.3 / 4d22 + 14dl2 44.7 / 4d28 + 16dl4 12.00 supporting 19.0 / 4d20 + 10dl0 25.8 / 4d20 + 12dl2 33.7 / 4d25 + 12dl2 38, l / 4d25 + 14dl4 50.0 / 4d28 + 16dl4 flyover 17.8 / 4d20 + 10dl0 24.6 / 4d20 + 12dl2 31.5 / 4d25 + 12dl2 38, l / 4d25 + 14dl4 48.5 / 4d28 + 16dl4

table 2

Percentage of reinforcement of slab-beam

Temporary payload, kN / m ² Design section Percentage of plate reinforcement - beams for a grid of columns, μ% 4.8x4.8 5.4x5.4 6.0x6.0 6.6x6.6 7.2x7.2 4,00 supporting 0.94 0.86 0.82 0.71 0.85 flyover 0.59 0.53 0.51 0.44 0.54 6.00 supporting 0.37 0.40 0.5 0.42 0.51 flyover 0.38 0.40 0.5 0.42 0.51 8.00 supporting 0.45 0.50 0.54 0.50 0.62 flyover 0.45 0.50 0.50 0.50 0.62 10.00 supporting 0.49 0.62 0.57 0.56 0.70 flyover 0.50 0.62 0.57 0.56 0.69 12.00 supporting 0.56 0.64 0.70 0.64 0.77 flyover 0.53 0.60 0.66 0.64 0.75

Table 3

Prefabricated steel support table (collar) of the joint between the slab-beam and the column of the girder-free frame with combined reinforcement

Angle number and diameter of supporting working reinforcement with combined reinforcement

Column grid, m Temporary payload on the floor, kN / m ² 4.0 6.0 8.0 10.0 12.0 Coal number, mm / number and diameter of steel and basalt-plastic reinforcement, n, d, mm 4.8x4.8 50 / 2dl6 + 2d8 50 / 4dl6 + 2d8 63 / 4dl8 + 2dl0 75 / 4dl8 + 2dl0 100 / 4d22 + 2dl2 5.6x5.6 63 / 4dl6 + 2d8 75 / 4dl8 + 2dl0 75 / 4d20 + 2dl2 90 / 4d20 + 2dl2 100 / 4d25 + 2dl2 6.0x6.0 63 / 4dl8 + 2d8 75 / 4d20 + 2dl0 80 / 4d22 + 2dl2 90 / 4d25 + 2dl2 100 / 4d28 + 2dl4 6.6x6.6 75 / 4dl8 + 2d8 75 / 4d20 + 2dl0 80 / 4d22 + 2dl2 90 / 4d25 + 2dl4 100 / 4d28 + 2dl4 7.2x7.2 75 / 4d20 + 2dl0 80 / 4d22 + 2dl2 90 / 4d25 + 2dl2 100 / 4d28 + 2dl4 100 / 4d28 + 2dl4

- 2 037678

Table 4

Prefabricated steel support table contour dimensions and weight with combined reinforcement

Temporary payload on the floor, kN / m ² Dimensions of the supporting steel table with a grid of columns, m 4.8x4.8 5.6x5.6 6.0x6.0 6.6x6.6 7.2x7.2 2.4x2.4 2.8x2.8 3.0x3.0 3.3x3.3 3.6x3.6 Prefabricated steel support table weight, kg 4.0 36.88 38.56 50.15 59.35 76.01 6.0 36.86 51.36 64.66 70.58 105.78 8.0 40.56 60.72 83.85 86.01 120.72 10.0 44.96 63.72 102.22 111.47 154.62 12.0 61.53 91.46 131.4 143.01 154.62

CLAIM

Claims (1)

CLAIM The girder-free frame made of monolithic reinforced concrete with combined reinforcement consists of the following structural elements - a slab-beam, a steel support table and a column, which, when working together, form a frame in two directions, characterized in that the connection of the beam slab with the column is carried out using a support table with a collar, to which working rods are welded on four sides, basalt-plastic reinforcement was carried out between the working rods of the supporting reinforcement, which makes up 50% of the supporting reinforcement in the hidden beam of the frame, and is combined into the spatial frame of the hidden beam, and the slab-beam acts as a horizontal element of the frame structure and has a rectangular a section with a width equal to one fourth of the span on each side of the axis of the columns, and a height equal to the height of the slab section.