WO2017078567A1

WO2017078567A1 - Connection joint of a column and a floor slab of a girderless building frame without a capital

Info

Publication number: WO2017078567A1
Application number: PCT/RU2016/000428
Authority: WO
Inventors: Евгений Викторович АВТОНОМОВ
Original assignee: Евгений Викторович АВТОНОМОВ
Priority date: 2015-11-03
Filing date: 2016-07-11
Publication date: 2017-05-11
Also published as: RU2591994C1

Abstract

The invention relates to the field of construction, and more specifically to connection joints of columns and floor slabs of a girderless reinforced concrete building frame without a capital. The connection joint of a column and a floor slab comprises an interconnected upper column and lower column and a precast floor slab with a mounting opening to allow the passage of a column. Along the perimeter of the opening, there are anchors of a principal reinforcement of the slab, each of which is made from an angle section. The anchors are interconnected by strengthening angle units, which are mounted at the corners of the mounting opening of the slab. The floor slab is provided with additional reinforcement bars, which are secured to the strengthening angle units. The principal reinforcement of the floor slab is spaced along the full vertical extent in mutually perpendicular directions. The anchors of the principal reinforcement of the columns are designed in the form of loops, and the strengthening angle units are welded to the principal reinforcement of the lower column through metal connecting elements. The technical result is increased rigidity and reliability of the joint.

Description

COLUMN AND CEILING CONNECTION ASSEMBLY

LANDLESS CAPITAL-FREE BUILDING FRAME

Technical field

The invention relates to the field of construction, namely, the nodes of the connection of columns and floor slabs of the bezrigelnogo capless reinforced concrete frame of the building, and can be used in the construction of multi-storey buildings for residential, social and industrial purposes, which are in operating conditions under the action of dynamic and seismic loads.

State of the art

The prior art various designs of nodes connecting columns and floor slabs of buildings. In particular, a knot for connecting a column and a floor slab of a bezelless capless building frame disclosed in patent RU 2203369, published on 04/27/2003, containing a prefabricated floor slab with a rectangular hole in which a steel shell is rigidly mounted, made in the form of two truncated pyramids mated to each other with the other with its small bases, and the column passed through the shell with the exposed reinforcement in the zone of the shell connected to welding with the shell by means of steel trapezoidal connectors s elements.

The disadvantages of this node include low stiffness and reliability of the node when it is working for punching, because the shell does not increase the bursting contour.

Reinforced concrete slab is also known, described in patent CH 635390, published on 03/31/1983. In the design of this floor, the corners of the floor parts are reinforced with load-bearing elements, the shoulders of which are bent at an acute angle. The bisector of the angle passes through the axis of the support. Bearing elements are made of sheet steel, and the shoulders of each element are connected to each other by a steel corner profile to which the supporting reinforcing bars of the ceiling are welded.

In this technical solution, when mounting the frame, the node for connecting the parts of the prefabricated column should be located outside the node of the junction of the column with an overlap, which complicates the process of mounting the frame.

The closest set of essential features to the claimed invention is the node connecting the columns and floor slabs, disclosed in the copyright certificate SU 1114749, published 09/23/1984, containing the team a column made in height with a gap of concrete at the level of overlap, and a prefabricated floor slab equipped with a central hole framed by a casing attached to the slab reinforcement through which the column is passed. The column reinforcement exposed at the concrete break point at the level of overlap is welded using flat steel trapezoidal elements to the upper part of the shell of two adjacent ends of the plate opening. After welding all the elements of the joint, the assembly is monolithic with concrete.

The disadvantage of this technical solution is the insufficiently high rigidity and reliability of the node when it is working for punching.

Disclosure of invention

The task to which the claimed invention is directed is to create a design for a node for connecting columns and floor slabs, which allows this unit to be used in the construction of multi-storey bezelless capless frames of residential, social, and industrial buildings under operational conditions under the action of dynamic and seismic loads.

When solving this problem, a technical result is achieved, which consists in increasing the rigidity and reliability of the connection node of the column and the floor slab when it is punching and increasing the bearing capacity, as well as in increasing the bearing capacity of the floor slab and the joint of the upper and lower columns in the node.

The specified technical result is achieved due to the fact that the connection node of the column and the floor slab of the bezelless non-storage frame of the building includes interconnected upper and lower columns and a prefabricated floor slab with a mounting hole for the passage of the column, along the perimeter of which there are anchors of the working reinforcement of the plate, each of which made of an angular profile, interconnected by reinforcing angular elements installed at the corners of the mounting hole of the plate, the floor slab is equipped with With reinforcing rods attached to reinforcing corner elements, the working reinforcement of the floor slab is spaced apart in height in mutually perpendicular directions by an amount not less than the diameter of the rod of the working reinforcement, and in the joined upper and lower columns, the anchors of the working reinforcement of the columns are made in the form of loops. Reinforcing angular elements of the anchors of the working plate reinforcement welded to the working reinforcement of the lower column through metal connecting elements. In this case, the anchors of the working reinforcement of the plate and the reinforcing corner elements can be made in the form of an equal-shelf or unequal-angle profile.

This technical result is also achieved due to the fact that additional reinforcing bars can be located parallel to the working reinforcement of the plate or diagonally between the working reinforcement of the plate in mutually perpendicular directions, and the working reinforcement of the plate can be attached to the inner surface of the anchors by welding or passed through holes with subsequent welding from the outside of the anchor, and the axis of the openings for the working reinforcement on opposite anchors can be shifted to the horizon Flax and vertical planes is not less than the value of the diameter of the rebar.

The anchors of the working reinforcement of the plate can be interconnected with the formation of a continuous edging of the mounting hole of the floor slab or with the formation of intermittent edging in the case of autonomous installation of the anchors of each of the working rods. The mounting hole of the floor slab in its shape is performed by the corresponding cross-sectional profile of the column, mainly of rectangular section: in the form of a square or in the form of an elongated rectangle. But, regardless of the presence of the connection of the working reinforcement anchors to each other on the sides of the plate mounting hole, the working reinforcement anchors are necessarily connected to each other by reinforcing angular elements, which not only increase the stiffness of the assembly as a whole on the perception of bending moment, including under seismic loads, but also allow you to install additional working reinforcing bars that increase the bearing capacity of the floor slab. The problem of additional reinforcement of the floor slab in accordance with the current regulatory requirements is quite tangible, since the distance between the working rods of the longitudinal and transverse reinforcement is normalized, and the installation of additional rods in compliance with the established requirements is impossible. In this regard, the supply of floor slabs with reinforcing corner elements allows to solve the problem of additional reinforcement with a corresponding increase in the bearing capacity of the floor slab while maintaining a minimum cross section.

Anchors installed in the mounting hole of the floor slab at an angle to the column plane provide maximum compression of the concrete in the assembly after the assembly has been concreted and increase the bearing capacity of the assembly as a whole, loop anchors in the lower and upper columns increase the strength of the joint of the columns in the assembly. In addition, the location of the working reinforcement has a significant effect on the stiffness of the floor slab and its bearing capacity. To ensure high bursting strength in the support zone and increase the bearing capacity of the floor slab, the working reinforcement of the floor slab should be spaced in height in mutually perpendicular directions by an amount not less than the diameter of the rod of the working reinforcement, which will provide the maximum distance between the upper and lower working rods with installed transverse reinforcement rods in the support zone for punching, subject to the protective layers.

The plate working reinforcement is attached to the inner surface of the anchors by welding, but for the convenience of quality control in the manufacture of floor slabs in production, the plate working reinforcement is passed through the holes made in the anchors and is welded to the outside of the anchor, and the axis of the holes for the working reinforcement on opposite anchors are displaced in the horizontal and vertical planes by at least the value of the diameter of the reinforcing bar, which ensures the installation of working reinforcement with carrying height in mutually perpendicular directions by an amount of not less than the diameter of the rod of the working reinforcement.

Brief Description of the Drawings

The invention is illustrated by drawings, where:

figure 1 shows the connection node of the upper and lower columns and slabs of the non-bezelless capless building frame (front view);

figure 2 is a section 1-1 in figure 1;

on Fig.3 shows the connection node of the upper and lower columns and floor slabs of the non-bezelless capless building frame (side view);

in Fig.4 is a section 2-2 in Fig.Z;

figure 5 shows the connection node of the lower column with loop reinforcement outlets and floor slabs bezrigelnogo capless frame of the building;

in Fig.6 is a section 3-3 in Fig.5;

in Fig.7 shows the connection node of the lower column with the mounting loop and the slab of the bezelless coreless frame of the building;

on Fig - section 4-4 in Fig.7; figure 9 shows the connection node of the upper and lower columns and slabs of the non-bezelless capless building frame with the working reinforcement of the plate connected to the welding anchors (front view);

figure 10 is a section 5-5 in figure 9;

figure 11 shows the connection node of the upper and lower columns and slabs of the non-bezelless capless building frame with the working reinforcement of the plate connected to the welding anchors (side view);

in Fig.12 is a section 6-6 in Fig.11;

in Fig.13 shows an intermediate node connecting the columns and slabs of the bezelless capless building frame with the working reinforcement of the column connected to the reinforcing corner elements by welding (front view);

on Fig - section 7-7 in Fig.13;

on Fig shows an intermediate node connecting the columns and slabs of the bezelless capless building frame with the working reinforcement of the column connected to the reinforcing corner elements by welding (side view);

in Fig.16 is a section 8-8 in Fig.15;

in FIG. 17 shows the continuous connection of the anchors of the working reinforcement with holes displaced clockwise by an amount equal to the diameter of the reinforcing bar;

on Fig and Fig - offset holes in the anchors vertically by an amount equal to the diameter of the working reinforcement.

The implementation of the invention

The node for connecting the column and the slab of the non-bezelless non-drip frame of the building includes interconnected columns: the top 1 (column of the upper tier) and the lower 2 (column of the lower tier) and the prefabricated floor slab 3. In the slab 3 there is a mounting hole for the passage of columns formed by anchors 4 of the working reinforcement 5 of the floor slab 3. Anchors 4 are mainly interconnected to form a continuous angular profile that borders the mounting hole of the floor slab. The working reinforcement 5 is either rigidly attached to the anchors 4 by welding, or is passed into the corresponding holes 6 made in the anchors. At the corners of the mounting hole of the floor slab, reinforcing angular elements 7 are installed, welded with anchors 4 of the working reinforcement 5. Anchors 4 through reinforcing corner element 7 by means of metal connecting elements 8 are welded to the working fittings 10 of the lower 2 columns. Advantageously, the connecting elements 8 are flat trapezoidal in plan view.

Additional reinforcing bars 9 are welded to the reinforcing corner elements 7, which can be installed parallel to the working reinforcement 5 and / or at an angle to it.

Between the upper and lower working reinforcement 5 of the floor slab 3 in the punching zone, working rods 14 are welded.

Anchors of the working reinforcement 10 of the upper 1 and lower 2 columns can be made loop 11 and 12, respectively. In addition, the completion of the lower column can be made in the form of a mounting loop 13.

Installation site at the construction site is as follows.

After the lower column 2 is installed in the design position using the mounting loop 13, the floor slab 3 is installed on it in the design position using a special mounting device (not shown in the drawings) so that the lower 2 column passes through the mounting hole formed by the working armature anchors slabs. At the junction of the floor slab and the column, the reinforcement of the column is exposed and by means of metal connecting elements 8, the anchors of the working reinforcement of the plate are attached to the working reinforcement of the column, after which the upper column is installed in the design position, having a channel corresponding to the mounting loop 13 (not shown in the drawing), and the assembly concreted.

Since one column can be installed for several floors, the intermediate joint of the floor slab and columns at the level of each floor and the last joint of the floor slab and columns are performed in the same sequence, but without installing the upper column.

Claims

CLAIM

1. A node for connecting a column and a floor slab of a bezelless capless building frame, including interconnected upper and lower columns and a prefabricated floor slab with a mounting hole, characterized in that around the perimeter of the mounting hole of the plate there are anchors for the working reinforcement of the plate, each of which is made of a corner profile and is located at an angle to the plane of the column, interconnected by reinforcing corner elements installed at the corners of the mounting hole of the plate, the slab is equipped with With additional reinforcing rods attached to reinforcing corner elements, the working reinforcement of the floor slab is spaced apart in height in mutually perpendicular directions by an amount not less than the diameter of the rod of the working reinforcement, the anchors of the working reinforcement of the columns are made in the form of loops, and the reinforcing corner elements are welded with the working reinforcement of the bottom columns through metal fittings.

2. The node according to claim 1, characterized in that the anchors of the working reinforcement of the plate are made in the form of an equal-shelf or unequal-angle profile.

3. The node according to claim 1, characterized in that the reinforcing corner elements are made in the form of equal or unequal corners.

4. The node according to claim 1, characterized in that the additional reinforcing bars can be located parallel to the working reinforcement of the plate or diagonally between the working reinforcement of the plate in mutually perpendicular directions.

5. The node according to claim 1, characterized in that the working reinforcement of the plate is attached to the inner surface of the anchors by welding.

6. The assembly according to claim 1, characterized in that the working reinforcement of the plate is passed through the holes made in the anchors and is welded to the outside of the anchor.

7. The assembly according to claim 6, characterized in that the axis of the openings for the working reinforcement on opposite anchors is offset in the horizontal and vertical planes by no less than the diameter of the reinforcing bar.