KR20060072394A - Connection structure of concrete filled steel tube column and flat plate slab - Google Patents

Abstract

The present invention is a junction structure between the CFT column and the flat plate bottom structure, a plurality of holes that can be inserted into the reinforcing bar is formed on either side of the two sides facing the CFT column 100, the flat plate bottom structure 400, A pair of steel sheets 410 each of which is welded and joined to each other so as to extend outward from a corner portion of the outer surface of the CFT pillar, and located in the center of a pair of steel sheets positioned on the same side, correspond to the steel sheet outward from the CFT pillar A plurality of H-shaped steel 420, one side of each of which is welded to the CFT pillar, and a plurality of connecting bars 430 for connecting a pair of steel sheets and H-shaped steel located on the same side so as to extend in a length to It includes a plurality of reinforcing bars 440 are penetrated to extend from the inside of the CFT pillar to the outside of the connecting bar through a plurality of holes formed in one side of the. The present invention effectively prevents the punching shearing phenomenon by securing the joint portion between the CFT column and the flat plate bottom structure and secures the strength beyond the RC flat plate structure of the same size as well as improves the workability.

Description

Connection Structure of Concrete Filled Steel Tube Column and Flat Plate Slab}

1A and 1B schematically illustrate the structure of a conventional reinforced concrete (RC) flat plate,

Figures 2a to 3b is a view schematically showing the bonding structure between the CFT column and the flat plate bottom structure according to the prior art, respectively

4A and 4B schematically illustrate a joint structure between a CFT pillar and a flat plate bottom structure according to an embodiment of the present invention.

  ♠ Explanation of symbols on the main parts of the drawing ♠

100: CFT pillar 400: flat plate bottom structure

410: steel sheet 420: H-shaped steel

430: connecting bar 440: rebar

The present invention relates to a joint structure between a CFT column and a flat plate bottom structure, and in particular, by effectively reinforcing the joint between the CFT column and the flat plate bottom structure to prevent the punching shear phenomenon and joining more than the same size RC flat plate structure The present invention relates to a joint structure between a CFT column and a flat plate bottom structure that secures site strength.

CFT (Concrete Filled Steel Tube) column is a composite column that has improved strength and rigidity by filling concrete inside the steel pipe. In particular, since the load acting on the column at the lower floor or the basement floor of the building is maximum, the adoption of the CFT pillar is often considered.

In the construction of the building, the basement air makes up a very large portion of the air. Therefore, efforts have been made to minimize the cost of excavation by lowering the height of the basement if possible. For this reason, it is a general tendency to employ the structure of RC flat plates (Reinforced Concrete Flat Plate) as shown in Figs. 1A and 1B. In other words, by constructing the RC flat plate instead of the RC flat slab containing the drop panel, construction is possible, as well as reducing the height of the floor and the trench, and greatly reducing the air.

In addition, joining flat plate floor structures that can significantly reduce floor height to CFT columns that can receive high force is emerging as a more rational solution. However, since the CFT column is composed of steel pipes on the outside, and the flat plate floor structure is an RC structure to be cast in-situ, it is technically very difficult and complicated to implement a detailed configuration relationship to secure the integrity between the two.

Since the CFT structure has been developed since early in Japan, the detailed structural relationship for securing the integrity between the CFT column and the flat plate floor structure was first proposed in Japan and introduced in Korea, but when the axial force acting on the column increases, The technology is insufficient to prevent the punching shear of the flat plate bottom structure due to the axial force. That is, the current design technology for economically designing the joints between the CFT column and the flat plate floor structure has a stability has been rarely presented in domestic and abroad.

In particular, since most of the domestic CFT structure uses a thick plate of 40mm or more, the size of the column is significantly reduced compared to the general RC column of the CFT column. In proportion to this, the area for preventing the punching shear phenomenon formed on the outer circumferential surface of the column is also significantly reduced, so that the vulnerability to the punching shear is rather increased.

2A to 3B are diagrams schematically illustrating a joint structure between a CFT column and a flat plate bottom structure according to the prior art, respectively.

2a and 2b respectively weld the reinforcement 210 to the outer surface of the CFT column 100, and welds and reinforces a plurality of reinforcement 220 to the reinforcement 210 to the flat plate bottom structure 200 In the form of a configuration to have a junction structure between the CFT column 100 and the flat plate bottom structure 200.

However, such a bonding structure is difficult to prevent the punching shear phenomenon of the flat plate bottom structure 200 due to the axial force applied to the CFT pillar 100 because the bonding portion is not strong.

3A and 3B respectively weld the reinforcing steel 310 to the outer surface of the CFT pillar 100 and reinforce the plurality of reinforcing bars 320 in the form of completely penetrating the reinforcing steel 310 and the CFT pillar 100. The flat plate bottom structure 300 was configured to have a junction structure between the CFT column 100 and the flat plate bottom structure 300.

However, such a joint structure has a lot of difficulties in construction because it reinforces the plurality of reinforcing bars 320 in the form of completely penetrating the reinforcing steel 310 and the CFT pillar 100, it is also insufficient to prevent the punching shear phenomenon.

Therefore, the present invention has been made to solve the problems of the prior art as described above, by effectively reinforcing the joint between the CFT column and the flat plate bottom structure to prevent the punching shear phenomenon and more than the strength of RC flat plate structure of the same size The purpose is to provide a joint structure between the CFT column and the flat plate bottom structure to secure the construction and improve the construction.

The present invention for achieving the above object is a joint structure between the CFT column and the flat plate bottom structure, either side of the two sides facing the CFT column is formed with a plurality of holes that can be inserted into the rebar, the flat plate bottom The structure is located in the center of a plurality of pairs of steel sheets, one side of each of which is welded and welded so as to extend outward from the edge portion of the outer surface of the CFT pillar, and a pair of steel sheets located on the same side and outward from the CFT pillar A plurality of H-bars, each of which is welded to the CFT pillar, one side of each of which is extended to a length corresponding to the steel plate, a plurality of connecting bars connecting the pair of steel plates and the H-beam, respectively located on the same side, and the CFT pillar Through the plurality of holes formed in one side to extend from the inside of the CFT pillar to the outside of the connecting bar It is characterized in that it comprises a plurality of reinforcement.

In the following, with reference to the accompanying drawings a preferred embodiment of the bonded structure between the CFT column and the flat plate bottom structure according to the present invention will be described in detail.

4A and 4B schematically illustrate a joint structure between a CFT pillar and a flat plate bottom structure according to an embodiment of the present invention.

As shown in Figures 4a and 4b, the present invention is configured to have a junction structure between them by forming a flat plate bottom structure 400 in the following form in a conventional CFT column 100. That is, the flat plate bottom structure 400 of the present invention is the same as the four pairs of steel sheets 410, each of which is welded to one side thereof so as to extend a predetermined length outward to the edge portion of the outer surface of the conventional CFT pillar 100, Four H-shaped steels located at the center of the pair of steel plates 410 located on the side and welded to the CFT pillars 100 on one side thereof so as to extend outwardly from the CFT pillars 100 to the lengths corresponding to the steel sheets 410 ( 420, a plurality of connecting bars 430 connecting the pair of steel plates 410 and the H-shaped steel 420 located on the same side, and the CFT pillar 100 through one side of the CFT pillar 100, respectively. It is composed of a plurality of reinforcing bars 440 are arranged to extend from the inside of the connection bar 430 to the outside.

The steel plate 410 has the same or similar thickness as that of the CFT pillar 100 and is configured to have a size of about 2/3 of the width of the CFT pillar 100 to be welded vertically of the CFT pillar 100. In this case, the steel sheet 410 may be set in consideration of the fact that the total thickness of the flat plate bottom structure 400 is about 200 mm or more.

One side of the H-shaped steel 420 is welded to the CFT pillar 100 so as to extend to a length corresponding to the steel plate 410, both flanges are welded in a form located in the height direction of the CFT pillar 100, respectively.

The connection bar 430 connects the pair of steel sheets 410 and the H-shaped steel 420 located on the same side to have a pair of the steel sheets 410 and the H-shaped steel 420.

In the CFT column 100 of the present invention, a plurality of holes are drilled on either side of the two sides facing each other. Therefore, when reinforcing the reinforcing bar 440, the reinforcing bar 440 is inserted along the hole formed on one side of the CFT column 100 until the end is in contact with the other side of the CFT column 100 facing I'm going to work out. At this time, since the reinforcing bars 440 in the same form as above through another side of the CFT column 100, a plurality of reinforcing bars 440, each end of which is not fixed to the inside of the CFT column 100 This is arranged in the shape of crossing each other.

By pouring concrete into the CFT pillar 100 and the flat plate bottom structure 400 configured as described above, the bonding between the CFT pillar and the flat plate bottom structure of the present invention is completed.

In the following, the bonding process between the CFT column and the flat plate bottom structure of the present invention configured as described above will be described in detail.

First, in processing a hole in the CFT pillar 100, a hole through which the rebar 440 can penetrate into any one of both sides facing each other. Then, in order to prevent the punching shear fracture of the flat plate bottom structure 400 due to the high compressive force, weld the H-shaped steel 420 having low dancing to the center of each outer surface of the CFT pillar, and the edge portion of the CFT pillar. The steel plate 410 is vertically welded.

In addition, the H-shaped steel 420 and the pair of steel plates 410 located on the same side are connected by a plurality of connection bars 430 similar to reinforcing bars. This connection ensures the integrity between the steel plate 410 and the H-shaped steel 420 bonded to the outer surface of the CFT pillar to form a mechanism that strongly resists punching shear failure. At this time, the steel plate 410, the H-shaped steel 420 and the connecting bar 430 is previously welded integrally manufactured in the field, it is also possible to join only such integral hardware to the outer surface of the CFT pillar, respectively.

Then, the rebar 440 is reinforced. It is not easy to penetrate the holes on both sides facing the rebar 440 to pass through the CFT pillar. Therefore, the present invention adopts a very simple operation of drilling a plurality of holes in either side of the two sides facing each other, inserting the reinforcing bar 440 into the hole until the end is in contact with the other side of the opposite side. At this time, the plurality of reinforcing bars 440 has a form in which the ends thereof are not fixed in the interior of the CFT pillar, but are automatically fixed when the concrete is placed in the interior of the CFT pillar later.

When the reinforcement of the reinforcement 440 is completed, the remaining slab reinforcement is also reinforced. Then, the concrete is filled in the interior of the CFT pillar, and the concrete is also poured into the flat plate bottom structure to cure integrally to complete the bonding between the CFT column and the flat plate bottom structure of the present invention.

As described in detail above, the present invention effectively prevents the punching shearing phenomenon by effectively reinforcing and joining the joint portion between the CFT column and the flat plate bottom structure, and has the effect of improving the constructability as well as securing the strength beyond the RC flat plate structure of the same size. .

In addition, the present invention has the effect of improving the workability because the desired strength can be exhibited even if the field welding in the reinforcement of the reinforcing bars reinforcing the joints.

In addition, the present invention can easily be applied to the practical application of the RC flat plate design method (for example, direct design method, equivalent frame design method or design method based on finite element analysis using commercial program) which can be absorbed intact as it is. Do.

In the above description, the technical details of the joint structure between the CFT column and the flat plate bottom structure of the present invention have been described together with the accompanying drawings, which illustrate the best embodiment of the present invention by way of example and do not limit the present invention.

In addition, it is obvious that any person skilled in the art can make various modifications and imitations within the scope of the appended claims without departing from the scope of the technical idea of the present invention.

Claims (2)

The joint structure between the concrete filled steel tube (CFT) column and the flat plate floor structure, A plurality of holes into which reinforcing bars can be inserted is formed on either side of both sides facing the CFT pillar, The flat plate bottom structure is located in the center of a plurality of pairs of steel sheets each side welded to each other so as to extend outward from the edge portion of the outer surface of the CFT pillar, and a pair of steel sheets located on the same side from the CFT pillar A plurality of H-bars, each of which is welded to the CFT pillar, one side of each of which is welded to the CFT pillar so as to extend to a length corresponding to the steel plate to the outside, and a plurality of connecting bars respectively connecting a pair of steel sheets and H-beams located on the same side; Joining structure between the CFT column and the flat plate bottom structure, characterized in that it comprises a plurality of reinforcing bars to penetrate the plurality of holes formed on one side of the CFT column to extend from the inside of the CFT column to the outside of the connecting bar . The joint structure between the CFT column and the flat plate bottom structure according to claim 1, wherein the H-beams are welded such that both flanges are positioned in the height direction of the CFT column.

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