KR20230114790A - Bracket reinforcement structure of hollow-core column and its construction method - Google Patents

Abstract

The present invention relates to a bracket reinforcement structure of a hollow column and a construction method thereof.
According to this embodiment of the present invention, in the reinforcement structure of the bracket located on the upper side of the pillar and forming a hollow part, penetration through one side and the other side of each side of the bracket that are opposite to each other in a straight line. A ball is formed inside the body of the bracket, and a rod-shaped support enters the inside of the bracket through a through hole formed on one side of the side facing each other of the bracket and passes through the hollow to a through hole on the other side of the opposite side. It is characterized by a configuration that is discharged and fixed.

Description

Bracket reinforcement structure of hollow column and its construction method

The present invention relates to a bracket reinforcement structure of a hollow column and a method of constructing the same, and more particularly, a through hole penetrating one side and the other side of each side of the bracket facing each other in a straight line is formed in the body of the bracket. It is formed inside, and the rod-shaped support enters the bracket through a through hole formed on one side of the side facing each other of the bracket, passes through the hollow part, and is discharged and fixed through the through hole on the other side of the opposite side. It relates to a reinforcement structure of a bracket characterized by a reinforcement and a construction method thereof.

In general, concrete buildings are composed of structures such as columns, walls, beams, and slabs that form floors and ceilings, and these structures are reinforced with reinforcement inside. It is formed by filling the periphery with concrete and curing it.

In particular, in the case of a column, as shown in FIG. 1, in the case of a square column having a rectangular cross section, the main reinforcing bars 1 are disposed in the vertical direction adjacent to the outer edge of the column, and the strip reinforcing bars 2 are in the vertical direction. It is arranged in the horizontal direction in the form of wrapping the main reinforcing bars 1 arranged in, and in some cases, auxiliary strip reinforcing bars 3 that mutually bind between the main reinforcing bars 1 are additionally arranged.

Figure 2a is a cross-section of a square column, showing a state in which the main reinforcing bars 1, reinforcing strips 2, and auxiliary reinforcing bars 3 are disposed, and Figure 2b is a cross-section of a circular column having a circular cross-section, It consists of a structure having only strip reinforcement (2) disposed in the horizontal direction in the form of wrapping (1) and the main reinforcement (1).

On the other hand, concrete structures such as pillars, walls, beams, and slabs constituting a concrete building are usually constructed by a method in which the structure is cast at the building site, but the concrete structure is separately manufactured at an external factory rather than at the building construction site. PC (PRECAST CONCRETE, precast concrete) construction method is also being implemented, which transports the fabricated structure to the site and assembles it on the site to construct the building.

This PC method has the advantage of improving the quality of the structure, simplifying workability at the site, reducing field manpower and minimizing waste, and thereby shortening the construction period. There are also constraints that require large equipment for transport and lift assembly on site.

In particular, in the case of a column among structures to which the PC method is applied, in order to lighten the column so that the structure can be transported and lifted at the site more easily, as shown in FIG. 3, a hollow portion is formed inside the column 5 After manufacturing and transporting in a factory so that (4) is formed, a method of assembling the pillar 5 at the site and pouring concrete into the hollow part 4 of the pillar 5 is used.

Figures 4a to 4c show a conventional embodiment of a pillar in which a hollow part is formed in order to apply the PC method as described above.

Figure 4a shows a column 5 in which a hollow part 4 is formed by embedding a corrugated steel pipe inside the column 5, avoiding interference within the limit of not interfering with the placement of auxiliary reinforcing bars according to the standard. Since the corrugated steel pipe needs to be buried, there is a limit to the diameter of the corrugated steel pipe to be buried, and there is a restriction that the hollow part cannot be formed large.

In addition, FIG. 4B shows a column 5 in which a hollow portion 4 is formed by pouring concrete only on the outside in a state in which an iron plate is disposed inside the column, and the hollow portion without touching the auxiliary steel bar 3 ( 4) has to be blocked with an iron plate every time, so the production difficulty is high and the productivity is low, so the economical efficiency is low.

In addition, although not shown, a technique of forming a hollow using centrifugal force is also known, but as the volume of the pillar increases, the capacity of the rotating equipment providing the centrifugal force increases, so it is difficult to form various types of pillars.

Next, FIG. 4C shows a column 5 in which a hollow part 4 is formed by reinforcing a mixed strip 2 in which square and circular strips are combined and inserting and removing a core mold. After the core mold is buried, the reinforcing bars are placed, concrete is poured into the mold, and when curing is completed, the core mold is pulled out from the mold and the column 5 forming the hollow part 4 is removed from the mold.

The method of forming the hollow part using the above-described mixed stripe and core mold has an advantage in that the hollow part can be formed relatively easily. Furthermore, since the core mold used once can be continuously and repeatedly used, it also has an economical advantage.

However, the hollow column on which the bracket is formed has a disadvantage in that it is difficult to manufacture. When constructing a building, a PC girder is placed on the upper side of the column, and a PC slab structure such as a ceiling is installed on the upper side of the PC beam. If not, the weight of the upper part during construction, including the weight of the PC beam, the PC slab, and the reinforced concrete before hardening, must be supported only by the area where the column contacts the beam. To secure sufficient area to support the beam and prevent the collapse of the superstructure A bracket structure is formed at the top of the column.

5 shows an embodiment in which a bracket 6 is formed on the upper side of a conventional pillar 5, and a tensile reinforcing bar 7 is installed inside the bracket 6 in order to sufficiently respond to the force transmitted to the pillar through the beam. It is formed by arranging the horizontal and vertical lattice shapes and pouring concrete.

Therefore, in the process of manufacturing the column, it is very difficult to insert and remove the cylindrical core mold due to the main tensile reinforcing bar 7 placed inside the bracket 6 of the column 5, so the bracket 6 is formed. There are limitations in making .

On the other hand, as a prior art related to the bracket reinforcement structure of a conventional hollow column, Korean Patent Publication No. 10-2018-114821 of a precast segmental hollow column reinforcement and joint structure and its construction method and Korean Registered Patent No. 10 -1652943, a method for manufacturing a reinforced concrete column of a high-rise building is known.

The present invention was devised to solve all the conventional problems as described above, and the bracket by solving the problem of difficulty in inserting and removing the mold by the main tensile reinforcing bars that are reinforced in the bracket part of the column formed with the hollow part for using the PC method There is a technical problem of the present invention to easily manufacture a column having a hollow portion having.

According to an embodiment of the present invention, in the reinforcement structure of a bracket located on the upper side of a column and forming a hollow part, a through hole penetrating one side and the other side of each side of the bracket that are opposite to each other in a straight line. is formed inside the body of the bracket, and a rod-shaped support enters the bracket through a through hole formed on one side of the side opposite to each other of the bracket and passes through the hollow to be discharged through the through hole on the other side of the opposite side. It is characterized by a fixed configuration. The support may be a bolt, and may be characterized in that the bolt is fixed to the bracket by fastening a nut to an end portion of the bolt discharged through the through hole.

It may be characterized by a configuration in which a washer is placed in the opening of the through hole.

In the construction method of a hollow column to which a bracket reinforcement structure is applied, a core mold embedding step (S1) of embedding a cylindrical core mold (M) in the inner space of a molding mold prepared to integrally form the column and the bracket, After placing the main reinforcing bar and the mixed bar in the part where the column is formed, and placing the tube body so that a through hole is formed in which the bolt performing the support function is inserted in the part where the bracket is formed, concrete is poured into the molding frame for curing and hardening. When the pillar and bracket are cured, the core mold is withdrawn from the mold to form a hollow part in the pillar and bracket, and the pillar is lifted upward In a demolding process (S3) of demolding the pillars from the molding frame, the hollow pillars are transported to the construction site of the building, and bolts as supports of a size and quantity satisfying the structural performance of the building where the pillars are to be installed are passed through through holes. Support interpolation process (S4) of inserting and fixing bolts inside the body of the bracket by entering the bracket and fastening with nuts (S4), assembling process (S5) of lifting the pillar and assembling it in a planned position, inside the hollow part of the assembled pillar It is characterized in that it is configured to include a hollow casting process (S6) of curing and curing after pouring concrete.

According to the bracket reinforcement structure of the hollow column of the present invention and its construction method configured as described above, the entry and exit of the core mold is hindered by the main tensile reinforcing bars that have been placed in a lattice shape on the conventional bracket, whereas the bracket reinforcement of the present invention Since the reinforcing structure does not place the main tensile reinforcing bars on the bracket at all during the manufacturing process of the column, the entry and exit of the core mold is performed freely, so that the production of the hollow column can be obtained very easily.

1 is a view showing a state in which reinforcing bars of a square column having a general square cross section are placed.
Figure 2a is a cross-sectional view of a rectangular pillar having a cross section of a general rectangular shape, Figure 2b is a cross-sectional view of a circular pillar having a cross section of a general circular shape.
3 is a view showing a column in which a hollow part used in the PC method is formed.
4a to 4c are views showing a conventional embodiment of a pillar in which a hollow part is formed in order to apply the PC method as described above.
5 is a view showing a state in which the main tensile reinforcement is placed on a bracket in a conventional square column.
6 is a perspective view of a column forming a hollow portion to which the reinforcement structure of the bracket of the present invention is applied.
7 is a view showing the reinforcing structure of the bracket of the present invention.
8 is a longitudinal cross-sectional view of a column to which the reinforcement structure of the bracket of the present invention is applied.
9 is a view showing the manufacturing state of the hollow column to which the reinforcement structure of the bracket of the present invention is applied.
10 is a flowchart of a construction method of a column to which the reinforcement structure of the bracket of the present invention is applied.

Hereinafter, the configuration of the bracket reinforcement structure and the construction method of the hollow column of the present invention will be described with reference to the drawings.

However, the disclosed drawings are provided as examples to sufficiently convey the spirit of the present invention to those skilled in the art.

Accordingly, the present invention may be embodied in other shapes without being limited to the drawings presented below.

In addition, unless otherwise defined, the terms used in the specification of the present invention have meanings commonly understood by those of ordinary skill in the art to which the present invention belongs, and the gist of the present invention is described in the following description and accompanying drawings. Detailed descriptions of well-known functions and configurations that may be unnecessarily obscure are omitted.

6 is a perspective view of a column forming a hollow portion to which the reinforcement structure of the bracket of the present invention is applied.

Referring to FIG. 6, the reinforcement structure of the bracket of the present invention is applied to the bracket 20 formed on the upper side of the pillar 10 having the hollow part 30 formed therein.

As described above, the bracket 20 is to support the weight of the upper structure during construction when a girder is placed on the upper side of the column and a slab structure such as a ceiling is installed on the upper side of the beam. It is a structure formed to prevent the collapse of the upper structure by ensuring sufficient contact area between the beam and the column placed on the column.

At this time, the reinforcement structure of the bracket of the present invention does not use the main tensile reinforcement (see FIG. 5), which was placed in a lattice shape in the conventional bracket, and instead inserts a rod-shaped support at the position where the main tensile reinforcement is placed inside the bracket. After arranging the pipe body to form a through hole, concrete is poured, cured and hardened, and after the cured and hardened pillar is removed from the mold, supports are inserted and fixed in a size and quantity that satisfy the structural performance of the building where the pillar will be installed. , It is a reinforcement structure of a bracket that responds to the tensile force and shear force due to its own weight given to the bracket.

As described above, the reinforcing structure of the bracket of the present invention does not use the main tensile reinforcement inside the bracket, thereby solving the problem that the entry and exit of the core mold is blocked by the main tensile reinforcement in the process of manufacturing the column having the bracket. do.

Hereinafter, an embodiment of the present invention as described above will be described in more detail.

7 is a view showing a reinforcement structure of the bracket of the present invention, Figure 8 is a longitudinal cross-sectional view of a column to which the reinforcement structure of the bracket of the present invention is applied.

Referring to each figure, the reinforcement structure of the hollow column bracket of the present invention is a reinforcement structure applied to the bracket 20 formed on the upper side of the column 10, and the main reinforcing bar 1 is the column 10 and the bracket 20 ) is placed in the vertical direction inside the body and exposed to the outside through the upper surface 22 of the bracket 20, and the structure in which the hollow part 30 is formed inside the bracket 20 and the pillar 10 is the same as the prior art. do.

At this time, the reinforcement structure of the bracket of the present invention is a through hole passing through one side and the other side of each side facing each other in a straight line among the side surfaces 21 constituting the front, rear, left and right sides of the bracket 20. (23) is formed inside the body of the bracket (20).

Then, through the through hole 23 formed on one side of the side facing each other of the bracket 20, enters the inside of the bracket 20, passes through the hollow part 30, and passes through the through hole 23 on the other side of the opposite side. ) It is a structure in which a rod-shaped support that is discharged and fixed to the bracket 20 is inserted into the bracket 20.

As described above, the support interpolated into the body of the bracket 20 serves to replace the main tensile reinforcing bars that have been placed in a lattice shape in the conventional bracket, and the beams and slabs disposed above the bracket 20 ( slab) and pre-hardened overlay concrete must have enough tension to sufficiently respond to the tensile force and shear force caused by its own weight during construction.

Preferably, the rod-shaped support is a conventional bolt 40 having a head and a body extending in the longitudinal direction from the lower part of the head, and enters the inside of the bracket 20 through one side to the other side. A nut 50 is fastened to the distal end of the discharged bolt 40 to insert the bolt 40 into the body of the bracket 20.

At this time, by placing a washer 60 in the opening of the through hole 23, the bolt 40 entering and exiting the through hole 23 can be secured more firmly.

Hereinafter, a construction method of a column to which the reinforcement structure of the bracket of the present invention configured as described above is applied will be described in a modified manner.

9 is a view showing the manufacturing state of the hollow column to which the reinforcement structure of the bracket of the present invention is applied, and FIG. 10 is a flowchart of the construction method of the column to which the reinforcement structure of the bracket of the present invention is applied, illustrating each process Please refer to 9.

1) Core mold embedding process (S1)

First, a cylindrical core mold (M) is buried in the inner space of the mold (B) prepared to integrally form the pillar 10 and the bracket 20.

2) Bar arrangement and concrete casting process (S2)

In addition, the main reinforcement 1 and the mixed strip are reinforced at the part where the column 10 is formed, and the bolt 40 that serves as the support of the bracket 20 can be interpolated at the part where the bracket 20 is formed. After arranging the tubular body to form a through hole, concrete is poured into the forming mold (B) and cured and cured to form the pillar 10 and the bracket 20 integrally.

3) Demolding process (S3)

When the curing of the pillar 10 and the bracket 20 is completed, the core mold (M) is withdrawn from the mold (B). When the core mold (M) is withdrawn, a hollow part 30 is formed in the pillar 10 and the bracket 20, and the pillar 10 having the hollow part 30 is lifted upward and removed from the mold B. The column 10 is demoulded.

At this time, the conventional bracket had a problem in that it was difficult to manufacture the hollow column itself because the entry and exit of the core mold (M) was hindered by the main tensile reinforcing bars (7), which were arranged in a lattice shape, but the bracket reinforcement structure of the present invention In the manufacturing process, since the main tensile reinforcement is not placed on the bracket at all, the core mold (M) embedded in the mold (B) is freely moved in and out, so that the production of the hollow column can be obtained very easily.

4) Support interpolation process (S4)

Then, the pillar 10 forming the hollow part 30 manufactured as described above is transported to the construction site of the building, and the bolt 40 as a support body of a size and quantity that satisfies the structural performance of the building to be installed is passed through. Enter the bracket 20 through the ball 23 and fasten with the nut 50 to insert and fix the bolt 40, which is a support member, inside the body of the bracket 20.

The bolt 40 interpolated and fixed to the bracket 20 in this way acts to correspond to the tensile force and shear force due to its own weight given to the bracket 20 .

5) Assembly process (S5)

Lift the pillar 10 and assemble it at the planned location. At this time, the planned location may be a location where the pillar 10 is installed.

6) Hollow part casting process (S6)

After the bolt 40 is interpolated and fixed as described above, concrete is poured into the hollow part 30 of the column 10, cured and cured to complete the construction of the column to which the reinforcement structure of the bracket of the present invention is applied. do.

10: pillar 20: bracket
21: side 22: top
23: through hole 40: bolt
50: nut 60: washer
M: core mold B: mold

Claims (4)

In the reinforcement structure of the bracket located on the upper side of the column and forming a hollow part,
Forming a through hole in the body of the bracket that passes through one side and the other side of each side of the bracket that are opposite to each other in a straight line,
A bracket characterized by a configuration in which a rod-shaped support enters the bracket through a through hole formed on one side of the side facing each other of the bracket, passes through the hollow part, and is discharged through the through hole on the other side of the opposite side to be fixed. reinforcement structure of reinforcement.
The method of claim 1,
The support is a bolt,
Reinforcement structure of the bracket, characterized in that the bolt is fastened to the bracket by fastening the nut to the distal end of the bolt discharged through the through hole.
in claim 2
Reinforcing structure of the bracket, characterized in that the washer is placed in the opening of the through hole.
In the construction method of a column to which the reinforcement structure of the bracket according to any one of claims 1 to 3 is applied,
A core mold embedding process (S1) of embedding a cylindrical core mold (M) in an inner space of a molding mold prepared to integrally form the pillar and the bracket;
After placing the main reinforcing bars and mixed bands in the part where the pillar is formed, and placing the tube body to form a through hole in which the bolt performing the support function is inserted in the part where the bracket is formed, concrete is poured into the forming frame for curing and hardening. A reinforcement and concrete pouring process (S2) of forming a pillar and a bracket integrally by doing so;
When the curing of the pillar and the bracket is completed, a mold removal step (S3) of withdrawing the core mold from the mold, forming a hollow part in the pillar and the bracket, and lifting the pillar upward to remove the mold from the mold;
The pillar formed with the hollow part is transported to the construction site of the building, and bolts as a support body of a size and quantity satisfying the structural performance of the building to be installed are entered into the bracket through the through hole and fastened with a nut to the inside of the bracket body. A support interpolation step of interpolating and fixing the bolt (S4);
an assembling process (S5) of assembling the pillar at a planned location; and
The construction method of the column, characterized in that it comprises a hollow casting step (S6) of pouring concrete into the hollow of the column and then curing and curing.