KR20240029538A - Partial reflection composite girder and column connection structure construction method and girder and column connection structure constructed thereby - Google Patents

Abstract

A method of constructing a connection structure of a partial reflection composite girder and a column is disclosed. The method of constructing a connection structure between a partial reflection composite girder and a column according to the present invention includes a first construction step of preparing a partial reflection composite girder by combining a socket reinforcement member in the center of the girder where sagging occurs, and attaching a foundation column to the foundation. The second construction step of setting and fixing, the third construction step of installing the first covered connection on the top of the foundation column, connecting the partial reflection composite girder to the first cover type connection, respectively, and connecting the top of the foundation column or the upper column. The fourth construction step is to connect the foundation column and the partial reflection composite girder by providing a second cover-type connection at the bottom, and the first step is to pour concrete after placing the deck plate and slab reinforcement on the floor where the partial reflection composite girder is installed. Includes 5 construction stages.

Description

Construction method of connection structure of partial reflection composite girder and column and connection structure of girder and column constructed thereby {PARTIAL REFLECTION COMPOSITE GIRDER AND COLUMN CONNECTION STRUCTURE CONSTRUCTION METHOD AND GIRDER AND COLUMN CONNECTION STRUCTURE CONSTRUCTED THEREBY}

The present invention relates to a method of constructing a connection structure between a partial reflection composite girder and a column and a connection structure between a girder and a column constructed thereby. More specifically, the present invention relates to an on-site steel frame assembly by providing a connection structure between a reflection composite girder and a column. It relates to a method of constructing a connection structure between a partially preflexed composite girder and a column, which can be simplified, the floor height can be reduced, and constructability improved, and a connection structure between a girder and a column constructed thereby.

In general, the PC composite method refers to a method of manufacturing part or all of the main structural members such as reinforced concrete columns, beams, and slabs at the factory, assembling and installing them on site, and pouring on-site concrete at the joints between members and the top of the slab to integrate the structure. .

This method is a complex construction method that combines factory production and field construction methods. It is a joint structure using a wet joint system. It is manufactured in a factory and assembled on site, so the quality of the structure is good, construction is easy, and construction is easy. It can be completed early, shortening the construction period, and has the advantage of reducing the risk of disasters due to less input of manpower and temporary materials.

Meanwhile, steel structure is a structural method in which steel members are assembled using joining methods such as rivets, bolts, and welding. It has good construction efficiency, can be usefully applied to high-rise buildings and large-span buildings, and has excellent design and internal plan configuration. It has the advantage of being free and easy to expand or remodel.

An end moment (bending) occurs in a steel girder connected to a column, and as a result, the upper part of the steel girder is in tension and the lower part is compressed at the end of the steel girder. The end of such a steel girder is usually referred to as the negative moment section.

To solve the problem of inefficient design of steel girders, when the absolute value of the negative moment is greater than the positive moment, the entire steel girder is designed as a member that can resist the positive moment, while an inverted T-beam is installed at the bottom of the end of the steel girder. Additionally, it was reinforced.

However, this method had significant visual problems due to excessive movement of the steel girder at the end, and also complicated flange joining work.

As an alternative to this problem, in a structure consisting of the first and second beams and columns that are vertically connected to each other as shown in Figure 1, the part where the second beam is connected to the column and the first beam was designed to be reinforced, but the construction cost was reduced by using a lot of steel. As it increases, it is economically undesirable, and there is a problem in that the floor height increases due to the increase in the amount of steel used.

The present invention was developed to solve the problems of the prior art described above, and is a method of constructing a connection structure between a partial reflection composite girder and a column, which can reduce the amount of steel used and improve constructability and economic efficiency, while also increasing structural safety, and This is to provide a connection structure between the girders and columns constructed by this.

The method of constructing a connection structure between a partial reflection composite girder and a column according to an embodiment of the present invention to solve the above-described technical problem is to prepare a partial reflection composite girder by combining a socket reinforcement member at the center of the girder where sagging occurs. First construction stage; A second construction step of setting and fixing foundation pillars in the foundation; A third construction step of installing a first cover-type connection on the upper part of the foundation pillar; A fourth connection that connects the partial reflection composite girders to the first cover-type connection parts, and provides a second cover-type connection part at the top of the foundation pillar or the lower part of the upper pillar to connect the foundation pillar and the partial reflection composite girder. Construction stage; And a fifth construction step of placing concrete after placing deck plates and slab reinforcement on the floor where the partial reflection composite girder is installed.

The first construction step includes mounting the girder and allowing sagging to occur in the girder due to the girder's own weight and reflection load; And a step of synthesizing a socket reinforcing member at the center of the girder where maximum deflection occurs, wherein the girder on which the socket reinforcing member is synthesized is turned over 180 degrees and erected in the fourth construction step.

The socket reinforcement member has a 'ㄷ'-shaped or 'ㅁ'-shaped cross-section, is manufactured to correspond to the shape of the girder in which sagging occurs, and is coupled between the upper flange and the lower flange of the girder.

The foundation pillar and the upper pillar are precast reinforced concrete pillars, and a first cover-type connection part provided in an 'ㄱ' shape at the lower part spaced apart by a preset length from the upper end of the foundation pillar connects a part of the foundation pillar. It is characterized by being prepared to surround it.

A second cover-type connection part provided in an 'ㄴ' shape at the upper part spaced apart from the lower end of the upper pillar by a preset length is provided to surround a part of the upper pillar, and the side portion of the first and second cover-type connection parts It is characterized in that it is provided to interview the reinforcement plate that reinforces the pillar.

A plurality of vertical reinforcing bars protrude from the upper part of the foundation pillar and are coupled to vertical reinforcing bar insertions previously provided in the upper pillar, the foundation pillar and the first covered connection part, the upper pillar and the first covered connection part, The first cover-type connection part, the girder, and the second cover-type connection part are connected by bolting.

In order to solve the above-described technical problems, a connection structure of a girder and a column constructed by a partial reflection composite girder and column connection structure construction method can be provided.

According to the present invention, when connecting pillars to pillars or pillars to beams, constructability can be improved by connecting by bolting using a cover-type connection, economic efficiency can be improved by excluding components that do not contribute structurally, the number of pillars is reduced, and the neatness of the beam can be improved. By reducing the cross-section of the ment section, the visual openness of the connection structure between columns and beams can be increased.

Figure 1 shows the connection structure of beams and columns according to the prior art;
Figure 2 is a diagram showing a method of manufacturing a partial reflection composite girder according to an embodiment of the present invention;
Figure 3a is an exploded perspective view showing the connection structure of a beam and a column according to an embodiment of the present invention;
Figure 3b is a longitudinal cross-sectional view of the second-story column of Figure 3a;
Figures 4a to 4e are flowcharts showing a method of constructing a connection structure between a partial reflection composite girder and a column according to an embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to “include” a certain element, this means that it may further include other elements rather than excluding other elements, unless specifically stated to the contrary.

Hereinafter, a method of constructing a connection structure between a partial reflection composite girder and a column according to an embodiment of the present invention will be described in detail with reference to the drawings.

Figure 2 is a diagram showing a method of manufacturing a partial reflection composite girder according to an embodiment of the present invention, Figure 3a is an exploded perspective view showing the connection structure of a beam and a column according to an embodiment of the present invention, and Figure 3b is Figure 3a is a longitudinal cross-sectional view of the second-story pillar, and Figures 4a to 4e are flowcharts showing a method of constructing a connection structure between a partial reflection composite girder and a pillar according to an embodiment of the present invention.

Referring to FIG. 2, a first construction step is initiated in which a partial reflection composite girder is prepared by combining socket reinforcement members 120, 120a, and 120b at the center of the girder 110 where sagging occurs.

More specifically, in the first construction step, the girder 110 is mounted in (a) of FIG. 2 and a deflection (δ1) is generated by the own weight of the girder 110. Thereafter, as shown in (b) of FIG. 2, additional deflection (δ2) is caused to occur in the girder 110 due to the preflection load (p1).

The socket reinforcement members 120, 120a, and 120b are prepared in advance and manufactured with a curvature corresponding to the curvature generated in the central part of the girder 110 due to the deflection (δ1) due to its own weight and the additional deflection (δ2).

Although the socket reinforcement members (120, 120a, 120b) have a 'ㄷ'-shaped or 'ㅁ'-shaped cross section, support portions (123a, 123b) are provided at the center. The socket reinforcement members 120, 120a, and 120b may be provided to be welded to the upper flange 111, lower flange 115, and abdomen 113 of the girder 110, respectively.

As shown in (d) of Figure 2, socket reinforcement members (120, 120a, 120b) are synthesized on the girder 110 sagging due to self-weight and reflection load, and then as shown in (e) of Figure 2, socket reinforcement members (120, 120a) , 120b) is used when constructing a girder later by flipping the girder 110 synthesized in the central part by 180 degrees.

Accordingly, the rigidity of the girder 110 is reinforced by combining the socket reinforcement members 120, 120a, and 120b when the positive moment is maximum at the center of the girder 110, and the prestress is introduced into the girder 110, thereby improving the present invention. The following girders are designed to improve constructability while securing economical girders.

After the reflection composite girder is prepared, a second construction step is prepared to set and fix the foundation pillar 210 on the foundation parts S1 and S3 as shown in Figure 4a, and on the upper part of the foundation pillar 210 as shown in Figure 4b. A third construction step is provided to install the first cover-type connection part 220.

Thereafter, as shown in FIG. 4C, the partial reflection composite girders 110 are respectively connected to the first covered connection part 220, and the second covered connection part 230 is connected to the uppermost part of the foundation pillar 210 or the lower part of the upper pillar 240. ) is provided to connect the foundation pillar 210 and the girder 110 to the fourth construction step.

Thereafter, as shown in FIGS. 4D and 4E, a fifth construction step is prepared in which concrete is poured after placing deck plates and slab reinforcement on the floor where the partial reflection composite girder 110 is installed. In the case of multiple floors, the above construction steps are performed. may be repeated.

The pillar 210 or the upper pillar 240 is connected to the partial reflection composite girder 110. Here, the foundation pillar 210 and the upper pillar 240 may be made of reinforced concrete pillars, and may be made of I-beam steel or H-beam steel.

Referring to FIGS. 3A to 4E, in the connection structure between the beam and the column according to an embodiment of the present invention, the foundation column 210 and the upper column 240 are reinforced concrete columns and are provided as precast, and the foundation column 210 A first cover-type connection part 220 provided in an 'ㄱ' shape is provided at the lower part spaced apart from the upper end by a preset length to surround a part of the foundation pillar 210.

At the lower end of the foundation column 210, a support portion 211 is provided to maintain the foundation column body 215 erected on the foundation S1 and connect it to the concrete to be poured, and the inside of the foundation column 210 Vertical reinforcing bars 217 are provided to protrude from the top and bottom of the foundation pillar 210.

The upper part of the vertical reinforcing bar 217 may be inserted into the vertical reinforcing bar insertion portion 243 of the upper column 240 to connect the foundation column 210 and the upper column 240. The lower end 213 of the vertical reinforcing bar 217 extends to the support portion 211 to facilitate connection with the concrete to be poured.

The first cover-type coupling part 220 has a cross-section formed in an 'ㄱ' shape, and has a coupling hole 223 for coupling the coupling body 221 and the girder 110 provided on the upper part of the coupling body 221. Includes. In addition, although not shown, a rigid reinforcement part (not shown) is provided in the center of the coupling body to reinforce the rigidity of the first cover-type coupling part 220, and on both sides of the rigid reinforcement part for coupling with the foundation pillar 210. A coupling hole (not shown) is provided to securely couple the first cover-type coupling part 220 and the foundation pillar 210 by bolting.

The end of the girder 110 may be mounted on the top of the first cover-type coupling portion 220 and coupled to the first cover-type coupling portion 220 by bolting. The upper part of the girder 110 may be fixedly coupled to the lower part of the upper pillar 240 by being connected to the second cover-type connection part 230.

The second cover-type connection part 230, which is provided in an 'ㄴ' shape at the upper part spaced apart by a preset length from the lower end of the upper pillar 240, is provided to surround a part of the upper pillar 240, and is connected to the first and second pillars 240. 2 The side portions of the cover-type connections (220, 230) are provided to face the reinforcing plates that reinforce the pillars (210, 240).

Looking at Figure 3b, the second cover-type connection part 230 is shown in more detail, and the second cover-type connection part 230 is a coupling body 231 provided in an 'ㄴ' shape, and is provided to reinforce the coupling body 231. It includes a rigid reinforcement part 233, fastening parts 235 and 237 provided to fasten the lower part of the upper pillar 240 and the coupling body 231, and a cover part 239 surrounding the lower part of the upper pillar 240. .

The coupling body 231 may be directly coupled to the lower part of the upper pillar 240, but is preferably face-to-face bonded to the reinforcing plate 239 surrounding the lower part of the upper pillar 240, and the fastening portion 235, The bolt portion 235 of 235) can be coupled by simultaneously penetrating the coupling body 231 and the reinforcement plate 239.

Vertical reinforcing bars 245 may also be provided inside the upper column 240, and a vertical reinforcing bar insertion portion 243 that can be coupled to the upper part of the vertical reinforcing bar 217 of the foundation column 210 may be provided at the lower part. there is.

A second cover-type connection part 230 may be provided at the bottom of the upper pillar 240 as shown in Figure 3a, but as shown in Figure 3b, the second cover-type connection part (230) is spaced apart from the bottom of the upper pillar 240 by a preset height. 230) is also possible.

The foundation pillar 210 and the first covered connection part 220, the upper pillar 240 and the first covered connection part 220, the first covered connection part 220 and the girder 110 and the second covered connection part ( 230) can be connected by bolting coupling.

According to the present invention, when connecting pillars to pillars or pillars to beams, constructability can be improved by connecting by bolting using a cover-type connection, economic efficiency can be improved by excluding components that do not contribute structurally, the number of pillars is reduced, and the neatness of the beam can be improved. By reducing the cross-section of the ment section, the visual openness of the connection structure between columns and beams can be increased.

The connecting structure of columns and beams may be, for example, a multi-story parking lot building, but is not limited to this.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

110: Reflection composite girder (girder)
210: foundation pillar
220: first covered connection part
230: Second covered connection part
230: Upper pillar

Claims (7)

A first construction step of providing a partial reflection composite girder by combining a socket reinforcement member at the center of the girder where sagging occurs;
A second construction step of setting and fixing foundation pillars in the foundation;
A third construction step of installing a first cover-type connection on the upper part of the foundation pillar;
A fourth connection that connects the partial reflection composite girders to the first cover-type connection parts, and provides a second cover-type connection part at the top of the foundation pillar or the lower part of the upper pillar to connect the foundation pillar and the partial reflection composite girder. Construction stage; and
A fifth construction step of placing concrete after reinforcing the deck plate and slab reinforcement on the floor where the partial reflection composite girder is installed. A method of constructing a connection structure between a partial reflection composite girder and a column, including a fifth construction step. According to paragraph 1,
The first construction step includes mounting the girder and allowing sagging to occur in the girder due to the girder's own weight and reflection load; And a step of synthesizing a socket reinforcement member at the center of the girder where the maximum deflection occurs,
A method of constructing a connection structure between a partial reflection composite girder and a column, characterized in that the girder on which the socket reinforcement member is composite is flipped 180 degrees and erected in the fourth construction step. According to paragraph 2,
The socket reinforcement member has a 'ㄷ'-shaped or 'ㅁ'-shaped cross-section, is manufactured to correspond to the shape of the girder in which sagging occurs, and is a partial prism characterized in that it is coupled between the upper flange and the lower flange of the girder. Connection structure construction method of reflection composite girder and column. According to paragraph 1,
The foundation pillar and the upper pillar are precast reinforced concrete pillars, and a first cover-type connection part provided in an 'ㄱ' shape at the lower part spaced apart by a preset length from the upper end of the foundation pillar connects a part of the foundation pillar. A method of constructing a connection structure between a partial reflection composite girder and a column, characterized in that it is provided to surround it. According to clause 4,
A second cover-type connection part provided in an 'ㄴ' shape at the upper part spaced apart from the lower end of the upper pillar by a preset length is provided to surround a part of the upper pillar, and the side of the first and second cover-type connection parts A method of constructing a connection structure between a partial reflection composite girder and a column, characterized in that it is provided for interviewing a reinforcing plate reinforcing the column. According to clause 4,
A plurality of vertical reinforcing bars protrude from the upper part of the foundation column and are coupled to the vertical reinforcing bar insertion portion previously provided in the upper column,
The part characterized in that the foundation column and the first covered connection part, the upper pillar and the first covered connection part, the first covered connection part and the girder and the second covered connection part are connected by a bolting connection. Connection structure construction method of reflection composite girder and column. A connection structure between a girder and a column constructed by the connection structure construction method of a partial reflection composite girder and a column according to any one of claims 1 to 6.