KR20140135555A - A segment CFT column and a making method of a CFT column, a joint structure of a CFT composite column - a RC wide girder used it - Google Patents

Abstract

The present invention is to provide a segment concrete filled steel tube (CFT) column capable of enhancing the rigidity thereof during a top-down construction method of an underground structure, facilitating to manufacture the same, improving constructability, and reducing construction periods; and a method of making the CFT column using the same. In addition, the present invention is to provide a joint structure of a CFT composite column - reinforced concrete (RC) wide girder, configured to facilitate column bar arrangement and concrete placement of a CFT composite column combined with the CFT column and reinforced concrete in a joint which is connected with the RC wide girder.

Description

In this paper, we propose a new CFT column and a CFT composite column with a RC wide girder used.

The present invention relates to a concrete filled steel pipe (CFT) column used for constructing an underground structure by a backfill method, wherein a CFT (concrete filled steel pipe) column is segmented on the ground, and the segmented CFT CFT (Concrete Filled Steel Tube) columns, which are made by joining concrete, are securely embedded in foundation concrete, and column construction is completed to the ground. CFT (Concrete Filled Steel Tube) And a method of manufacturing a column.

The present invention also relates to a CFT (CFT) synthetic column reinforced with a reinforced concrete (CFT) column on a CFT column when an underground structure is constructed by a backfill method, and a CFT Composite RC-wide beam connection structure.

Generally, when an underground structure is constructed by a backfill method, a column of CFT (Concrete Filled Steel Tube) having excellent rigidity and workability is widely used, and the prior art Patent No. 10-1194594 is disclosed in FIGS. 1A and 1B As shown in the figure, a casing 120 is installed in the soil layer to form a perforation hole at a predetermined depth in the ground and to prevent the pore wall of the soil layer from collapsing.

The foundation concrete 140 is installed in the perforation hole excavated on the rock layer and the concrete C is filled in the foundation concrete in order to correspond to the buoyancy of the foundation concrete on the ground and the shear connection member 131 is embedded in the upper part, The column 130 and the upper hollow steel pipe column 110 are welded to each other to fill the bottomed CFT column 100 integrally with the foundation concrete while maintaining the vertical degree, And the filled CFT column 100 is fixed.

After the lower filled CFT column 100 is fixed to the foundation concrete 140, the concrete is filled in the upper hollow steel column 110 by using the trem tube 150 or the like shown in FIG. 2 on the ground, Construction of the column is completed.

However, it is troublesome to manufacture a bottom-filled CFT column considering the buoyancy of the foundation concrete. Also, after the bottom-filled CFT column is fixed to the foundation concrete, Since the concrete is placed step by step by placing the concrete pipe upwards after it is disposed up to the bottom of the upper hollow steel pipe column using the concrete, it takes a long time to place the concrete, and the work of making the length of the concrete pipe should be made several times There is a problem that the workability is lowered.

7A and 7B, the joint between the CFT column 310 and the reinforced concrete combined CFT synthetic column 300 and the RC wide beam 301 is shown in FIGS. The CFT synthetic column 300 is formed by joining a front end connection member 312 to a surface of a CFT column 310 filled with concrete in a hollow steel pipe at predetermined intervals and spacing a predetermined distance from the surface of the CFT column, 311, dowel) Reinforced steel is laid,

The RC wide beam 301 has a reinforcing pipe 314 disposed at a predetermined distance from the column boundary of the CFT synthetic column 300 for pillar concrete placement of the CFT synthetic column 300, And the column concrete is poured through the filling pipe to complete the CFT synthetic column 300.

However, in the junction between the CFT column 310 and the CFT composite column 300 and the RC wide beam 301 combined with the reinforced concrete, a filling pipe must be installed in the RC wide beam for pillar concrete installation, It is not easy to insert concrete into the RC main beam 300 and the dowel reinforcing bars 311 are required to be connected to the main shaft of the column and a back joint is provided on the bottom surface of the RC wide beam 301 which is a junction between the CFT synthetic column 300 and the RC wide beam 301 There is a problem that occurs.

In order to solve the problems of the prior art, the present invention provides a segmented CFT column that increases the rigidity of the CFT column at the time of constructing an underground structure by a backfilling method, is easy to manufacture, improves workability, And a method for manufacturing a CFT column using the same.

The present invention also provides a CFT composite column-to-RC beam connection structure that facilitates pillar placement and concrete piling of the CFT composite columns at the joints where the CFT composite columns combined with the CFT columns and reinforced concrete are combined with the RC wide beams .

In order to achieve the above object, the segmented CFT column 1 (200) embedded in the foundation concrete of the present invention is opened at its upper part and closed at its lower end to form a predetermined length, A hollow steel pipe (220) having semicircular grooves (222) formed at predetermined intervals so as to form pores on an upper portion thereof;

A circular opening 232 is formed at a predetermined depth from the upper end of the hollow pipe 220 so that an opening 231 is formed at four corners and a filling pipe 240 is inserted in the center. A shield plate 230 welded to the inside of the shield plate 230;

The lower end of the hollow pipe is inserted into a circular opening 232 formed at the center of the blocking plate 230 and the upper part is protruded above the hollow pipe 220, (240); And a concrete pipe (C) filled to the shielding plate (230) of the hollow steel pipe (220) by the filling pipe (240).

In addition, the segmented CFT column 2 (210), which is installed as an underground structure on the foundation concrete of the present invention, is opened at its upper part and closed at a predetermined depth from its lower end to have a predetermined length, A hollow steel pipe 220 having an injection port and a semicircular groove 222 formed at predetermined intervals so as to form a pore at an upper portion thereof;

A circular opening 232 is formed at a predetermined depth from the upper end of the hollow pipe 220 so that an opening 231 is formed at four corners and a filling pipe 240 is inserted in the center. A shield plate 230 welded to the inside of the shield plate 230;

The lower end of the hollow pipe is inserted into a circular opening 232 formed at the center of the blocking plate 230 and the upper part is protruded above the hollow pipe 220, (240); And a concrete pipe (C) filled to the shielding plate (230) of the hollow steel pipe (220) by the filling pipe (240).

In the CFT column 260 installed in the foundation concrete for constructing the underground structure of the present invention, one or more segmented CFT columns 210 are continuously installed on the upper part of the segmented CFT column 200, Welding the joints of the segmented CFT columns after the column 3 211 is installed;

Shrinkable mortar is injected into the circular groove 223 formed at the junction of the segmented CFT columns to fill the shrinkage mortar in the segmented CFT column joint and then the one side of the segmented CFT column joint is closed so that the circular groove 223 is closed And welded to the cover plate (224).

The junction between the CFT column 310 and the reinforced concrete combined CFT synthetic column 300 and the RC concrete reinforced concrete wide beam 301 is connected to the CFT column 310 Shaped guide iron plate 317 is joined to the pair of side surfaces of the U-

The column main shaft 318 is laid at a predetermined interval in the opening formed by the C-shaped guide steel plate 317. The opening is used as a concrete inlet so that the column concrete is poured to the bottom of the RC wide beam 301, And the column 300 is formed at a predetermined distance from the end of the C-shaped guide steel plate 317 to the outside.

The segmented CFT columns of the present invention as described above facilitate the pouring and filling of concrete by using a filling pipe inside a steel pipe column, thereby increasing the rigidity and quality of the segmented CFT columns, There is a technical effect that is easy to manufacture and transport in the factory.

In addition, the CFT column of the present invention can be easily manufactured because the segmented CFT columns are welded to each other in the field or in a factory, and the construction of the column members can be improved by being able to be built from the embedding of the foundation concrete to the ground with one column member. There is a technical effect that air is shortened.

In addition, the CFT synthetic column combined with the CFT column and the reinforced concrete is easy to insert the column and the concrete through the guide steel plate joined to the CFT column at the joint where the RC wide beam is coupled, There is a technical effect which is advantageous for maintenance and reinforcement as a joint.

1 (a) is a process drawing showing a process of installing a CFT column as a prior art
1 (b) is a cross-sectional view of a prior art CFT column
FIG. 2 is a flow chart showing a process of placing a concrete of a CFT column according to the prior art
Figure 3 is a cross-sectional view of a segmented CFT column,
Fig. 4 (a) is a cross-sectional view along the line A-A '
4 (b) is a perspective view of a segmented CFT column, which is one embodiment of the present invention.
FIG. 4 (c) is a cross-sectional view of the CFT column connecting the segmented CFT columns of the present invention
FIG. 5 (a) is a side view showing a junction where the segmented CFT columns of the present invention are connected
FIG. 5 (b) is a side view in which a cover plate is provided on the segmented CFT column joint portion of the present invention
6 is a plan view showing a CFT synthetic column and an RC wide beam arranged according to the present invention
7 (a) is a plan view showing a junction between a CFT synthetic column and an RC wide beam in the prior art
7 (b) is a sectional view of Fig. 7 (a)
8 (a) is a plan view showing a junction of a CFT synthetic column and an RC wide beam according to another embodiment of the present invention
8 (b) is a sectional view of Fig. 8 (a)
9 (a) is a plan view showing a joint between a CFT synthetic column and an RC wide beam according to another embodiment of the present invention
9 (b) is a sectional view of Fig. 9 (a)
10 is a perspective view showing that a guide steel plate is joined to a CFT column of the present invention
11 is a perspective view showing a joint between a CFT synthetic column and an RC wide beam according to another embodiment of the present invention;

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a cross-sectional view of a segmented CFT column according to an embodiment of the present invention, FIG. 4 (a) is a cross-sectional view taken along line A-A 'of FIG. 3, and FIG. 4 (b) is a perspective view of a segmented CFT column And FIG. 4 (c) is a cross-sectional view of the CFT column connecting the segmented CFT columns of the present invention.

3, the segmented CFT column 1 200 embedded in the foundation concrete has a shielding plate 230 installed inside the hollow steel pipe 220, a filling pipe 240 inserted into the shielding plate 230 to inject concrete, And a pair of fixed steel plates 250 are installed in the hollow steel pipe 220 to maintain the verticalness of the filling pipe 240. [

The hollow steel pipe 220 is opened at its upper part and closed at its lower part to form a predetermined length, and one side iron plate at the upper part is formed with a semicircular groove part 222 at a predetermined interval so that an injection port is formed at the lower part and pores are formed at the upper part.

4A, the blocking plate 230 is formed in a rectangular shape at a predetermined depth from the upper end of the hollow steel pipe 220, and a fan-shaped opening 231 is formed at four corners, and a charging pipe 240 is inserted A circular opening 232 is formed so as to be welded to the inside of the hollow steel pipe 220.

The filling pipe 240 is inserted into a circular opening 232 formed at the center of the shielding plate 230 and the upper part protrudes above the hollow steel pipe 220, And is formed to have a predetermined length.

The concrete pipe C is injected to the shielding plate 230 of the hollow steel pipe 220 by the filling pipe 240. A plurality of concrete pipes C are arranged outside the opposite side of the lower portion of the hollow steel pipe 220, A pair of fixed steel plates 250 are installed in the hollow pipe 220 so as to fix the filling pipe 240 to the inside of the hollow pipe 220, And is welded and fixed to the inside of the hollow steel pipe 220.

The segmented CFT column 210 installed as an intermediate column member of the underground structure on the foundation concrete has a shield plate 230 inside a hollow steel pipe 220 formed with semicircular grooves 222 at predetermined intervals on one upper and lower steel plates, And a filling pipe 240 inserted into the blocking plate 230 to inject concrete into the hollow pipe 220. In order to maintain the verticalness of the filling pipe 240, A fixed steel plate 250 is installed.

The hollow steel pipe 220 is opened at its upper portion and closed at a predetermined depth from its lower end to form a predetermined length. One half of the upper and lower steel plates has a semicircular groove 222, Are formed at predetermined intervals.

The shielding plate 230 is formed in a rectangular shape at a predetermined depth from the upper end of the hollow steel pipe 220 and has a fan-shaped opening 231 at four corners, An opening 232 of the hollow pipe 220 is welded to the inside of the hollow steel pipe 220.

The filling pipe 240 is inserted into a circular opening 232 formed at the center of the shielding plate 230 and the upper part protrudes above the hollow steel pipe 220, And is formed to have a predetermined length.

The concrete pipe C is injected to the shielding plate 230 of the hollow steel pipe 220 by the filling pipe 240 and a pair of A fixed steel plate 250 is installed on the outside of the filling pipe 240 and welded and fixed to the inside of the hollow steel pipe 220.

The divided CFT column 3 211 installed at the uppermost part of the underground structure is provided with a shield plate 230 inside a hollow steel pipe 220 in which a semicircular groove 222 is formed at a predetermined interval on one lower side steel plate, A pair of fixed steel plates 250 are installed in the hollow steel pipe 220 to maintain the verticality of the filling pipe 240 .

The hollow steel pipe 220 is opened at its upper portion and its lower portion is closed at a predetermined depth from a lower end to have a predetermined length, and one semicircular groove portion 222 is formed at a predetermined interval .

The shielding plate 230 is formed in a rectangular shape at a predetermined depth from the upper end of the hollow steel pipe 220 and has a fan-shaped opening 231 at four corners, An opening 232 of the hollow pipe 220 is welded to the inside of the hollow steel pipe 220.

The filling pipe 240 is inserted into a circular opening 232 formed at the center of the shielding plate 230 and the upper part protrudes above the hollow steel pipe 220, And is formed to have a predetermined length.

The concrete pipe C is injected to the shielding plate 230 of the hollow steel pipe 220 by the filling pipe 240 and a pair of A fixed steel plate 250 is installed on the outside of the filling pipe 240 and welded and fixed to the inside of the hollow steel pipe 220.

The hollow steel tubes of the segmented CFT columns 1, 2, and 3 may be formed in a rectangular shape or a circular shape. The shield plate may be formed in a rectangular shape or a circular shape depending on the shape of the hollow steel pipe.

As shown in FIG. 3 and FIG. 4 (c), the CFT column 260 installed in the foundation concrete for constructing the column member of the underground structure has the segmented CFT column 200 installed at the lowermost part of the column member , One or more continuous segmented CFT columns 210 are installed on the segmented CFT column 1 200 and the segmented CFT columns 3 211 are disposed on the uppermost segment and the joints of the segmented CFT columns 200 are welded And they are joined and integrated.

FIG. 5 (a) is a side view showing a junction where the segmented CFT columns of the present invention are connected, FIG. 5 (b) is a side view of the segmented CFT column junction of the present invention, Shrinkage mortar is injected into the circular groove 223 formed at the junction of the segmented CFT column and the circular groove 223 is closed when the shrinkable mortar is filled in the segmented CFT column joint, And welding one side of the CFT column joint to the cover plate 224.

8 (a) is a plan view showing a junction between a CFT synthetic column and an RC wide beam according to another embodiment of the present invention, and FIG. 8 (b) is a cross- 8 (a). Fig.

The CFT column 310 is connected to the RC wide beam 301 at one side of the RC wide beam 301 at the junction between the CFT column 310 and the RC composite beam 300 and the RC wide beam 301, The steel plate 317 is joined to face each other.

A front end connection member 312 is joined to the surface of the CFT column 310 and the C-shaped guide steel plate 317 at a predetermined interval to be integrally coupled with the RC wide beam 301, The dowel reinforcing bars 311 are spaced apart from each other at predetermined intervals and the column main shaft 318 is laid at a predetermined distance in the opening formed by the C-shaped guide steel plate 317.

The opening formed by the C-shaped guide steel plate 317 is used as a concrete inlet so that column concrete is poured to the bottom of the RC wide beam 301. The column boundary line 316 of the CFT synthetic column 300 is inserted into the C- And are spaced apart from each other at the ends of the steel plate 317 by a predetermined distance.

9 (a) is a plan view showing a joint between a CFT synthetic column and an RC wide beam according to another embodiment of the present invention. FIG. 9 (b) is a sectional view of the CFT column 310 and a reinforced concrete A C-shaped guide steel plate 317 is opposed to the side surface of the CFT column 310 in the direction of one side of the RC wide beam 301 at the junction of the combined CFT composite column 300 and the RC wide beam 301 .

A front end connection member 312 is joined to the surface of the CFT column 310 and the C-shaped guide steel plate 317 at a predetermined interval to be integrally coupled with the RC wide beam 301, The dowel reinforcing bars 311 are spaced apart from each other at predetermined intervals and the column main shaft 318 is laid at a predetermined interval in the opening formed by the C-shaped guide steel plate 317.

The opening formed by the C-shaped guide steel plate 317 is used as a concrete charging port to pour column concrete to the bottom of the RC wide beam 301. The CFT synthetic column 300 supports the C- And a hitch 319 for supporting the RC wide beam 301 is formed at an upper portion of the CFT synthetic column 300. The hitch 319 for supporting the RC wide beam 301 is formed at a predetermined distance from the other end of the CFT synthetic column 300, , haunch are formed.

100: bottom charge type CFT column 110: upper hollow steel pipe column
120; Casing 130: Lower CFT column
140: foundation concrete 150:
200; Segmented CFT Columns 1 210: Segmented CFT Columns 2
211: segmented CFT column 3 220: hollow steel pipe
131, 221: shear connector 222: semicircular groove
223: circular groove 230: shield plate
231, 232: opening 240: filling pipe
250: Fixed steel plate 260, 310: CFT column
300: CFT composite column 301: RC wide beam
311: dowel reinforcement 312: shear connector
313: stirrup root 314: filling pipe
315: girder 316: CFT composite column boundary
317: C-shaped guide steel plate 318:
319: haunch C: concrete

Claims (8)

In the segmented CFT column 1 (200) embedded in the foundation concrete,
The segmented CFT column 1 200 has an upper part opened and a lower part closed to be formed in a predetermined length, and a semi-circular groove part 222 is formed at a predetermined interval so as to form a pore at an upper part of the upper iron plate, A steel pipe 220;
A circular opening 232 is formed at a predetermined depth from the upper end of the hollow pipe 220 so that an opening 231 is formed at four corners and a filling pipe 240 is inserted in the center. A shield plate 230 welded to the inside of the shield plate 230;
The lower end of the hollow pipe is inserted into a circular opening 232 formed at the center of the blocking plate 230 and the upper part is protruded above the hollow pipe 220, (240); And
And a concrete (C) filled to the shielding plate (230) of the hollow steel pipe (220) by the filling pipe (240). In the segmented CFT column 2 (210) installed as an underground structure on the foundation concrete,
The segmented CFT column 2 (210) is opened at the upper part and closed at a predetermined depth from the lower end to form a predetermined length. One of the upper and lower iron plates has a semi-circular groove portion 222 are formed at predetermined intervals;
A circular opening 232 is formed at a predetermined depth from the upper end of the hollow pipe 220 so that an opening 231 is formed at four corners and a filling pipe 240 is inserted in the center. A shield plate 230 welded to the inside of the shield plate 230;
The lower end of the hollow pipe is inserted into a circular opening 232 formed at the center of the blocking plate 230 and the upper part is protruded above the hollow pipe 220, (240); And
And a concrete (C) filled to the shielding plate (230) of the hollow steel pipe (220) by the filling pipe (240). In the segmented CFT column 3 (211) installed at the top of the underground structure,
The segmented CFT column 3 (211) is open at its upper part and its lower part is closed at a predetermined depth from its lower end to have a predetermined length, and one of the lower iron plates has a semicircular groove part (222) A hollow steel pipe 220 formed at predetermined intervals;
A circular opening 232 is formed at a predetermined depth from the upper end of the hollow pipe 220 so that an opening 231 is formed at four corners and a filling pipe 240 is inserted in the center. A shield plate 230 welded to the inside of the shield plate 230;
The lower end of the hollow pipe is inserted into a circular opening 232 formed at the center of the blocking plate 230 and the upper part is protruded above the hollow pipe 220, (240); And
And a concrete (C) filled to the shielding plate (230) of the hollow steel pipe (220) by the filling pipe (240). The segmented CFT column according to claim 1, wherein a plurality of shear connectors (221) are installed at predetermined intervals on the outside of opposite sides of the lower portion of the hollow steel pipe (220). The method as claimed in any one of claims 2 to 4, wherein a pair of fixed steel plates (250) are arranged on the outside of the filling pipe (240) so as to fix the filling pipe (240) And welded to the inside of the hollow steel pipe (220). In the CFT column 260 installed in the foundation concrete to construct an underground structure,
The CFT column 260 is provided with one or more continuous segmented CFT columns 210 of claim 2 above the segmented CFT column 1 200 of claim 1 and includes segmented CFT columns 3 211 of claim 3 Welding the joints of the segmented CFT columns;
Shrinkable mortar is injected into the circular groove 223 formed at the junction of the segmented CFT columns to fill the shrinkage mortar in the segmented CFT column joint and then the one side of the segmented CFT column joint is closed so that the circular groove 223 is closed And welding and joining the cover plate (224) to the CFT column (224). At the junction of the RC wide beam 301 and the CFT composite column 300 where the CFT column 310 and the reinforced concrete are combined,
A C-shaped guide steel plate 317 is opposed to a side surface of the CFT column 310 in one direction of the RC wide beam 301,
The column main shaft 318 is laid at a predetermined interval in the opening formed by the C-shaped guide steel plate 317. The opening is used as a concrete inlet to pour column concrete to the bottom of the RC wide beam 301, And the column (300) is formed to be spaced apart from the end of the C-shaped guide steel plate (317) by a predetermined distance from the end of the C-shaped composite column-RC wide beam connection structure. At the junction of the RC wide beam 301 and the CFT composite column 300 where the CFT column 310 and the reinforced concrete are combined,
A C-shaped guide steel plate 317 is opposed to a side surface of the CFT column 310 in one direction of the RC wide beam 301,
The column main shaft 318 is laid at a predetermined interval in the opening formed by the C-shaped guide steel plate 317. The opening is used as a concrete inlet to pour column concrete to the bottom of the RC wide beam 301, The column 300 is spaced a predetermined distance inward from one end of the C-shaped guide steel plate 317 and spaced a predetermined distance from the other opposite end in the opposite direction,
And a hammock (319) for supporting the RC wide beam (301) is formed on the upper part of the CFT synthetic column (300).

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