KR102296125B1 - Joint structure of filled composite beam and reinforced concrete column using core diaphragm - Google Patents

Abstract

The present invention suppresses deformation of the panel zone junction bracket and achieves a stable joint by improving the joint structure of the panel zone junction bracket and composite beam, which are pre-assembled on the reinforced concrete column. Provided is a joint structure of a filled composite beam and a reinforced concrete column using a hollow diaphragm.
The joint structure of the filled composite beam and the reinforced concrete column using a hollow diaphragm according to an appropriate embodiment of the present invention is a panel that is pre-assembled to the reinforced concrete column and connected to the composite beam in the joint structure of the composite beam and the reinforced concrete column Zone bonding brackets are provided; The panel zone joint bracket has a +-shaped plate-like structure and has a lower connection plate having a plurality of lower bolt holes for steel bonding at each end, is horizontally arranged at a predetermined height from the lower connection plate, has a T-shaped cross section and is joined in a + shape An upper connecting plate having a plurality of upper bolt holes for steel joining at regular intervals, vertically positioned between the upper connecting plate and lower connecting plate, joined between the ends, and having vertical bolt holes for steel joining at regular intervals The connecting plate and the lower end are joined to the corners where the vertical connecting plate and the lower connecting plate meet, and the upper end is joined to the central portion of the lower surface of the upper connecting plate, and is characterized in that it consists of a plurality of connecting plate reinforcing yarns arranged in a circle.

Description

Joint structure of filled composite beam and reinforced concrete column using core diaphragm

The present invention relates to a joint structure of a filled composite beam and a reinforced concrete column, and in particular, by improving the joint structure of a panel zone joint bracket and a composite beam that are pre-assembled on a reinforced concrete column, the deformation of the panel zone joint bracket is suppressed and a stable joint is achieved. , relates to a joint structure of a filled composite beam and a reinforced concrete column using a hollow diaphragm that does not require separate joint verification along with the ease of fastening work for workers.

In general, the RC structure is a reasonable structural method that uses cheap concrete with strong compressive strength and high-priced but high-tensile strength reinforcing bars to show composite strength. However, the RC structure has difficulty in shortening the construction period because the standard curing period for concrete is 28 days, although it is burdensome to manufacture and demold the formwork and copper bar for liquid concrete. In order to overcome this problem, reinforcing bars were recently pre-assembled (rebar wire assembly method) in a steel ball factory to become self-reliant during construction, minimizing the formwork retention period and significantly reducing production costs. have.

In this rebar line assembly method, a joint structure is required to connect the composite beam to the reinforced concrete column. Such a joint structure should not only be easy to install when assembling the reinforcing bar, but should also be easy to join with the composite beam. Also, the safety of the joint should be verified.

As the background technology of the present invention, as Korean Patent Registration No. 10-1233693, 'a seismic junction structure of pre-assembled steel frame reinforced concrete columns (PSRC) and steel beams using A-beams' has been proposed. This is to weld a total of four security locks, one each horizontally, between four pairs of vertical A-beams arranged on the left and right of each of the four beams constituting the +-shaped steel joint among the column steels, and then weld the +-shaped steel joint on it. It is a structure in which beams are raised and joined together. Therefore, an ideal seismic junction frame is formed in which columns and beams are continuous without interfering with each other in the panel zone, and a +-shaped steel junction is placed on the security clasp.

However, in the above seismic junction structure, the +-shaped steel joint has a U-shaped channel cross section and each beam has a U-shaped channel section and must be welded at the +-shaped corner, so the possibility of welding defects increases, and there is a limit to the overall weight reduction, and the known I-shaped joint Since it cannot have a structure, separate verification of the joint is required.

Korean Patent Registration No. 10-1233693

The present invention suppresses deformation of the panel zone junction bracket and achieves a stable joint by improving the joint structure of the panel zone junction bracket and composite beam, which are pre-assembled on the reinforced concrete column. An object of the present invention is to provide a joint structure between a filled composite beam and a reinforced concrete column using a hollow diaphragm.

The joint structure of the filled composite beam and the reinforced concrete column using a hollow diaphragm according to an appropriate embodiment of the present invention is a panel that is pre-assembled to the reinforced concrete column and connected to the composite beam in the joint structure of the composite beam and the reinforced concrete column Zone bonding brackets are provided; The panel zone joint bracket has a +-shaped plate-like structure and has a lower connection plate having a plurality of lower bolt holes for steel bonding at each end, is horizontally arranged at a predetermined height from the lower connection plate, has a T-shaped cross section and is joined in a + shape An upper connecting plate having a plurality of upper bolt holes for steel joining at regular intervals, vertically positioned between the upper connecting plate and lower connecting plate, joined between the ends, and having vertical bolt holes for steel joining at regular intervals The connecting plate and the lower end are joined to the corners where the vertical connecting plate and the lower connecting plate meet, and the upper end is joined to the central portion of the lower surface of the upper connecting plate, and is characterized in that it consists of a plurality of connecting plate reinforcing yarns arranged in a circle.

In addition, the composite beam is made of steel, has a hollow rectangular cross section and a certain length, an opening for pouring concrete is formed on the upper surface, and a body side bolt hole for steel bonding is formed at each end of the upper surface and the lower surface. Wow; At both ends of the box-type composite beam body, an end reinforcement vertical material is erected vertically to be rigidly joined to the panel zone bonding bracket side vertical connection plate, and vertical bolt holes for steel bonding are formed at regular intervals, and one end is an upper end of the end reinforcement vertical material. It is characterized in that it comprises an end reinforcing yarn material that is joined to and the other end is respectively joined to the inner lower corner of the box-shaped composite beam body to form a ∧-shaped structure.

In addition, the composite beam is made of steel, has a hollow rectangular cross section and a certain length, an opening for pouring concrete is formed on the upper surface, and a body side bolt hole for steel bonding is formed at each end of the upper surface and the lower surface. Wow; At both ends of the box-type composite beam body, an end reinforcement vertical material is erected vertically so as to be rigidly joined to the panel zone bonding bracket side vertical connection plate, and vertical bolt holes for steel bonding are formed at regular intervals, and one end is an upper end to the end reinforcement vertical material. It is characterized in that it comprises an end reinforcing yarn joined at a location spaced apart from each other and the other end is respectively joined to the inner lower corner of the box-type composite beam body.

In addition, the composite beam is made of steel, has a hollow rectangular cross section and a certain length, an opening for pouring concrete is formed on the upper surface, and a body side bolt hole for steel bonding is formed at each end of the upper surface and the lower surface. Wow; At both ends of the box-type composite beam body, an end reinforcement vertical material having vertical bolt holes 221 for steel bonding formed at regular intervals and standing vertically so as to be rigidly joined to the panel zone bonding bracket side vertical connection plate, and one end vertical material It is characterized in that it includes an end reinforcing yarn material that is joined to the central part or its periphery and the other end is respectively joined to the inner four corners of the box-shaped composite beam body to form an X-shaped structure.

In addition, the composite beam is characterized in that the composite beam reinforcement plate of a certain thickness is further bonded to the inner bottom side of the box-type composite beam body in the positive moment section to increase the bending strength and suppress buckling.

In addition, the composite beam has a rectangular flange for the end connection of the intermediate beam that is formed to protrude into a hollow rectangular section for strong bonding with the intermediate beam at predetermined intervals in the longitudinal direction. It is characterized in that the flange vertical member vertically joined to the vertical member and the reinforcing yarn material symmetrically joined to the vertical member are further installed.

According to the joint structure of the filled composite beam and the reinforced concrete column using the hollow diaphragm of the present invention, the end of the composite beam and the end of the panel zone junction bracket are I-type joints, so the operator is familiar with the operation and the ease of fastening is provided. In addition, the panel zone joint bracket that supports the composite beam exhibits a stable joint structure that resists vertical and torsional stresses because it has an I-shaped structure at the end and a truss structure made of connecting plate reinforcing yarns.

In addition, since the panel zone bonding bracket has a truss structure, it is possible to economically manufacture it while reducing light weight and exhibiting rigidity.

In addition, when the intermediate beam is connected to the composite beam side through the square flange for the end connection of the intermediate beam, the flange vertical member and the reinforcing yarn are installed on the square flange for the end connection of the intermediate beam, so that the intermediate beam is stably installed.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a connection state diagram of a filled composite beam and a reinforced concrete column using a hollow diaphragm according to an embodiment of the present invention.
Figure 2a is a perspective view of the panel zone bonding bracket applied to Figure 1;
Fig. 2B is a front view of Fig. 2A;
Figure 3a is a perspective view of the composite beam applied to Figure 1;
Fig. 3B is a plan view of Fig. 3A;
Fig. 3c is a cross-sectional view taken along line XX of Fig. 3b;
Figure 3d is a front view of the intermediate beam is connected in the composite beam shown in Figure 3a.
Figure 4 is an exemplary view showing various forms of the composite beam end shown in Figure 3a.
5A is a state diagram before connection between a panel zone junction bracket and a charging type composite interpolation according to an embodiment of the present invention.
5B is an enlarged perspective view of the connection part between the panel zone junction bracket and the filling type composite interpolation in FIG. 5A.
Figure 6a is a modified exemplary view of the intermediate beam joint in the composite beam of the present invention.
Fig. 6b is a front view of the intermediate beam joint shown in Fig. 6a;
Fig. 6c is a cross-sectional view taken along line YY of Fig. 6b;

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

1, in the present invention, the panel zone bonding bracket 40 is used for the bonding structure of the composite beam 20 and the reinforced concrete column 30. The panel zone joint bracket 40 is pre-assembled to the reinforcing bar assembly 32 of the reinforced concrete column 30 and connected to the composite beam 20 .

As shown in Figs. 2a and 2b, the panel zone bonding bracket 40 is made of steel. The panel zone bonding bracket 40 has a +-shaped plate-like structure and has a lower connection plate 41 having a plurality of lower bolt holes 411 for steel bonding at each end thereof, and is horizontal from the lower connection plate 41 at a predetermined height. The upper connecting plate 42, which has a +-shaped plate-like structure and having a plurality of upper bolt holes 421 for steel bonding at each end, is positioned vertically between the upper connecting plate 42 and the lower connecting plate 41 The vertical connection plate 43 is joined between the ends and has a vertical bolt hole 431 for strong bonding at regular intervals, and the lower end is joined to the corner where the vertical connecting plate 43 and the lower connecting plate 41 meet, and the upper end Silver is made of a plurality of connecting plate reinforcing yarns 44 joined to the central portion of the lower surface of the upper connecting plate 42 and arranged in a circle.

In this embodiment, the upper connection plate 42 has a T-shaped cross section and is joined in a + shape, but the lower connection plate 41 also has a T-shaped cross section and is joined in a + shape. Of course, both the lower connecting plate 41 and the upper connecting plate 42 may have a T-shaped cross-section and have a structure in which they are joined in a +-shape.

As such, the panel zone bonding bracket 40 has a plate-like structure in which the lower connection plate 41 and the upper connection plate 42 have a rigid bonding structure with the end of the composite beam 20 . Here, the strong junction structure means a junction structure through fastening coupling between the well-known splice plates 5, 6 and 7 and bolts.

In addition, the connecting plate reinforcing yarn material 44 forms a truss structure with the vertical connecting plate 43 to suppress deformation of the panel zone junction bracket 40 and achieve a stable structure, and to increase the overall rigidity of the panel zone junction bracket 40 It is raised to have a stable connection structure with the composite beam 20 .

As shown in FIGS. 3 and 4 (c) and (d), one type of composite beam 20 is made of steel, has a hollow rectangular cross section and a certain length, and an opening 211 for pouring concrete is formed on the upper surface, and the upper surface A box-shaped composite beam body 21 having a body-side bolt hole 212 for strong bonding is provided at each end of the and the lower surface. In addition, at both ends of the box-type composite beam body 21, vertical bolt holes 221 for strong joining are formed at regular intervals so as to be rigidly joined to the vertical connecting plate 43 on the side of the panel zone joining bracket 40. Reinforcing vertical material 22, one end is joined to the central part of or around the end reinforcement vertical material 22, and the other end is joined to the four inner corners of the box-shaped composite beam body 21 to form an X-shaped structure ( 23) is installed.

As such, the composite beam 20 has an I-shaped joint structure with the panel zone joint bracket 40 as shown in FIGS. 5A and 5B because the end reinforcement vertical member 22 is installed. Therefore, the operator is familiar with the fastening work, so the assembly work is easy, and the I-shaped joint structure is a joint structure that has already been verified in the steel frame joint structure, thus ensuring the reliability and safety of the joint.

In addition, the end reinforcing yarn material 23 is joined to the end reinforcing vertical material 22 in an X-shaped structure, thereby increasing the flexural rigidity of the end reinforcing vertical material 22 to improve bonding performance.

On the other hand, the composite beam 20 is a deformed form, and as shown in FIG. It may be installed to form a ∧-shaped structure by bonding to each of the inner lower corners of the body 21 .

In addition, the composite beam 20 is a deformed form, and as shown in FIG. 4 (b), one end of the end reinforcing yarn 23 is joined to the end reinforcing vertical material 22 at a position spaced apart by a certain distance (G) from the upper end, and the other end can be manufactured by joining each of the inner lower corners of the box-type composite beam body 21 .

On the other hand, the composite beam 20 has a composite beam reinforcement plate 25 of a certain thickness to the inner bottom side of the box-type composite beam body 21 in the positive moment section (+L) to increase bending strength and suppress buckling. . At this time, the thickness of the composite beam reinforcing plate 25 is equal to or greater than the thickness of the steel plate of the composite beam 20 .

Here, as shown in FIGS. 3a to 3d, the composite beam 20 has a rectangular flange 27 for connecting the end of the intermediate beam protruding into a hollow square cross-section for strong bonding with the intermediate beam 200 at predetermined intervals in the longitudinal direction. joint is installed. At this time, it is preferable that the rectangular flange 27 for connecting the end of the intermediate beam is further provided with a flange vertical member 271 vertically joined to the inner center and a reinforcing yarn material 272 joined by tilting symmetrically to the vertical member 271 . . Here, the intermediate beam 200 may be understood as a 'small beam'.

The panel zone bonding bracket 40 configured in this way is assembled to the reinforcing bar wire assembly 32 of the reinforced concrete column 30 in the factory.

Thereafter, after the reinforcing bar wire assembly 32 of the reinforced concrete column 30 is erected on the plinth of the site, the composite beam 20 is rigidly joined to the panel zone junction bracket 40 and connected. At this time, as shown in Figure 5b, the end of the composite beam 20 is in contact with the end of the panel zone joining bracket 40, and then is strongly joined with bolts to be interconnected. Here, the end of the composite beam 20 and the end of the panel zone bonding bracket 40 are I-type joints, so the operator is familiar with the operation, so that the ease of fastening is provided. In addition, since the panel zone joint bracket 40 supporting the composite beam 20 has an I-shaped structure at the end and a truss structure by the connecting plate reinforcing yarn material 44, it exhibits a stable joint structure that resists vertical stress and torsional stress. will do

In addition, the intermediate beam 200 is installed on the side of the composite beam 20 through a square flange 27 for connecting the end of the intermediate beam. Even in this case, since the vertical flange member 271 and the reinforcing yarn material 272 are installed on the square flange 27 for connecting the end of the intermediate beam, the intermediate beam 200 is stably installed.

On the other hand, in the present invention, as shown in Figs. 6a to 6c, the box-shaped composite beam body 21 has an intermediate beam end connection formed to protrude into a hollow square cross-section for strong bonding with the intermediate beam 200 at predetermined intervals in the longitudinal direction. A square flange 27 is further jointly installed, but in the inner region of the square flange 27 for connecting the end of the intermediate beam, the reinforcement and the middle passing through the composite beam 20 for continuous filling of the reinforcement and concrete of the reinforcement 210 An opening 207 for the continuation may be further formed and configured. At this time, the opening 207 for reinforcing reinforcement and intermediate beam continuation has an area corresponding to the square cross-section of the square flange 27 for connecting the end of the intermediate beam, or while minimizing the cross-sectional loss as in this embodiment, the reinforcement and It may have a smaller area than this in consideration of the intermediate beam continuity. As such, by forming the opening 207 for continuous reinforcement and intermediate beams in the box-type composite beam body 21, reinforcement of the reinforcement 210 and continuous filling of concrete are possible, thereby realizing continuous beams.

At this time, the reinforcing angle 220 which is located on the inner upper part of the opening 207 for reinforcing reinforcement and intermediate beam continuation and joined to the box-type composite beam body 21 may be further installed. The reinforcing angle 220 uses an L-shaped steel in this embodiment, but may also be a C-shaped steel. In addition, the upper reinforcing steel plate 230 positioned between the square flanges 27 and 27 for connecting the end of the intermediate beam and joined to the opening 211 for pouring concrete may be further installed. In this way, by installing the reinforcing angle 220 and the upper reinforcing steel plate 230, the opening 207 for reinforcing reinforcement and intermediate beam continuity is further reinforced, which is advantageous in realizing a stable continuous beam.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

20: composite beam
21: box-type composite beam body
22: end reinforcement vertical material
23: end reinforcement material
25: composite beam reinforcement plate
27: Square flange for connecting the end of the intermediate beam
30: reinforced concrete columns
40: panel zone joint bracket
200: middle beam
207: opening for reinforcement and intermediate beam continuation
220: reinforcement angle
230: upper reinforcing steel plate

Claims (8)

In the joint structure of the composite beam 20 and the reinforced concrete column 30,
A panel zone bonding bracket 40 is provided which is pre-assembled on the reinforced concrete column 30 and connected to the composite beam 20;
The panel zone bonding bracket 40,
A lower connecting plate 41 having a +-shaped plate-like structure and having a plurality of lower bolt holes 411 for steel bonding at each end, and horizontally arranged at a certain height from the lower connecting plate 41 and having a T-shaped cross section The upper connecting plate 42 having a plurality of upper bolt holes 421 for steel joining at regular intervals and vertically positioned between the upper connecting plate 42 and the lower connecting plate 41 and joining between the ends and a vertical connecting plate 43 having vertical bolt holes 431 for strong bonding at regular intervals, the lower end is joined to the corner where the vertical connecting plate 43 and the lower connecting plate 41 meet, and the upper end is the upper connecting plate A joint structure of a reinforced concrete column and a filled composite beam using a hollow diaphragm, characterized in that it consists of a plurality of connecting plate reinforcing yarns 44 that are joined to the central part of the lower surface of (42) and arranged in a circle. The method of claim 1,
The composite beam 20 is
A box-type composite beam made of steel, having a hollow rectangular cross section and a certain length, with an opening 211 for pouring concrete on the upper surface, and bolt holes 212 on the body side for steel joining at each end of the upper and lower surfaces. a body 21;
At both ends of the box-type composite beam body 21, vertical bolt holes 221 for strong joining are formed at regular intervals so as to be rigidly joined with the vertical connecting plate 43 on the side of the panel zone joining bracket 40. End reinforcement vertical material 22, one end is joined to the upper end of the end reinforcement vertical material 22, and the other end is bonded to the inner lower edge of the box-shaped composite beam body 21 to form an ∧-shape structure. A joint structure of a filled composite beam and a reinforced concrete column using a hollow diaphragm, characterized in that it comprises a. The method of claim 1,
The composite beam 20 is
A box-type composite beam made of steel, having a hollow rectangular cross section and a certain length, with an opening 211 for pouring concrete on the upper surface, and bolt holes 212 on the body side for steel joining at each end of the upper and lower surfaces. a body 21;
At both ends of the box-type composite beam body 21, vertical bolt holes 221 for strong joining are formed at regular intervals so as to be rigidly joined with the vertical connecting plate 43 on the side of the panel zone joining bracket 40. The end reinforcement vertical material 22 and one end are joined to the end reinforcement vertical material 22 at a position spaced apart from the upper end by a certain distance (G) and the other end is respectively bonded to the inner lower corner of the box-shaped composite beam body 21. A joint structure of a filled composite beam and a reinforced concrete column using a hollow diaphragm, characterized in that it includes a reinforcing yarn material (23). The method of claim 1,
The composite beam 20 is
A box-type composite beam made of steel, having a hollow rectangular cross section and a certain length, with an opening 211 for pouring concrete on the upper surface, and bolt holes 212 on the body side for steel joining at each end of the upper and lower surfaces. a body 21;
At both ends of the box-type composite beam body 21, vertical bolt holes 221 for strong joining are formed at regular intervals so as to be rigidly joined with the vertical connecting plate 43 on the side of the panel zone joining bracket 40. End reinforcement vertical material 22, one end is joined to the central portion or the periphery of the vertical end vertical material 22, and the other end is bonded to the four inner corners of the box-shaped composite beam body 21, respectively, to form an X-shaped end reinforcement material ( 23), the joint structure of the filled composite beam and the reinforced concrete column using a hollow diaphragm, characterized in that it includes. 5. The method according to any one of claims 2 to 4,
The composite beam 20 has a composite beam reinforcement plate 25 of a certain thickness to the inner bottom side of the box-type composite beam body 21 in the positive moment section (+L) to increase bending strength and suppress buckling, characterized in that it is installed Joint structure of filled composite beam and reinforced concrete column using type diaphragm. 3. The method of claim 2,
The box-type composite beam body 21 has a rectangular flange 27 for connecting the end of the intermediate beam protruding into a hollow square cross-section for strong bonding with the intermediate beam 200 at predetermined intervals in the longitudinal direction. Hollow, characterized in that the rectangular flange 27 for end connection is further provided with a flange vertical member 271 vertically joined to the inner center and a reinforcing yarn material 272 symmetrically joined to the vertical member 271 is installed. Joint structure of filled composite beam and reinforced concrete column using type diaphragm. 3. The method of claim 2,
The box-type composite beam body 21 has a rectangular flange 27 for connecting the end of the intermediate beam protruding into a hollow square cross-section for strong bonding with the intermediate beam 200 at predetermined intervals in the longitudinal direction. In the inner region of the square flange 27 for end connection, an opening 207 for continuous reinforcement and intermediate beams penetrating through the composite beam 20 for continuous filling of the reinforcement and concrete of the reinforcement 210 is further formed. A joint structure of a filled composite beam and a reinforced concrete column using a hollow diaphragm. 8. The method of claim 7,
The reinforcing angle 220 that is located on the inner upper portion of the opening 207 for reinforcing reinforcement and the intermediate beam continuation and joined to the box-type composite beam body 21 is installed, and between the square flanges 27 and 27 for connecting the intermediate beam end. A joint structure of a reinforced concrete column and a filled composite beam using a hollow diaphragm, characterized in that the upper reinforcing steel plate 230 that is located in the opening 211 for concrete pouring is further installed.

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