KR102323675B1 - Coupled composite steel girder with transition section at the end, and the structure that jointed it to the column - Google Patents

Abstract

The present invention relates to a moment bonding of a PC concrete beam to a CFT column, wherein the coupled steel composite beam is a coupled steel composite beam composed of a concrete PC part, a composite PC part, and a joint, and the concrete PC part has a reinforced concrete structure. It has a bay and is located in the central section of the beam where the positive moment acts, and the composite PC part has a structure in which a steel beam is synthesized in a reinforced concrete member and is located in both end sections of the beam where the positive moment and the negative moment intersect, the joint The part is characterized in that it is made of only steel beams and protrudes from the composite PC part, and the connecting beam installed on the CFT column to join it to the column is provided with an upper flange, a lower flange, and a web connecting the ends of these flanges. It is made of the first and second connecting beams, and the lower flange of the connecting beam is characterized in that a holding part is installed on which a coupled steel composite beam can be mounted during joint connection work.

Description

COUPLED COMPOSITE STEEL GIRDER WITH TRANSITION SECTION AT THE END, AND THE STRUCTURE THAT JOINTED IT TO THE COLUMN}

The present invention relates to a way to moment-bond a coupled steel composite beam to a CFT column, and more specifically, to have a transition section at both ends of a PC concrete beam, thereby reinforcing the end and moment joining the CFT column. It relates to the structure of a coupled steel composite beam (Coupled Steel Precast Girder) that can easily implement the structure, and a joint structure to a CFT column thereof.

CFT columns effectively combine the material properties of steel and concrete by filling concrete inside the thin steel pipe, and also prevent brittle fracture of concrete through the organic relationship between steel and concrete. Therefore, it can be said that the CFT column is a very efficient structural member that uses a small amount of steel and improves seismic resistance, fire resistance and durability as well as high buckling performance.

However, as described above, since the CFT column is made of a thin steel plate and has a closed cross-section inside, it is not easy to have various structural types when joined to a beam member.

For example, it is not easy to join reinforced concrete beams economically compared to steel beams. In particular, it is even more difficult to have a high-quality PC concrete beam with a moment-bonding structure on a CFT column because it is manufactured in a factory, which can reduce the amount of on-site construction and facilitate long-span introduction of pre-stress.

The reinforcing structure of the CFT steel pipe column and the beam joint of FIG. 1 is registered as Patent Registration No. 10-0660522, and an inner reinforcing plate 10 joined to the inner surface of the concrete filled steel pipe column SP; and a connection bracket 20 that is joined to the outer surface of the concrete filled steel pipe column SP to fix the beam to the concrete filled steel pipe column SP, and is disposed to face the inner reinforcing plate 10; However, the inner reinforcing plate 10, a vertical plate 11 to be joined to the concrete filled steel pipe column (SP) by standing in the longitudinal direction; and stud bolts 15 joined to both sides of the vertical plate 11 at predetermined intervals along the longitudinal direction, and the beam is a precast concrete beam (PC), and the connection bracket 20 is made of a rectangular steel pipe. The precast concrete beam (PC) is joined to the concrete filled steel pipe column (SP) at a position coincident with the lower surface of the precast concrete beam (PC), and the precast concrete beam (PC) is a connecting bracket (20) made of the square steel pipe on the bottom surface of the end ) is characterized in that it is manufactured so that the insertion groove (PC-20) is inserted.

In the above-mentioned prior art, the connection bracket 20 previously attached to the concrete filled steel pipe column (SP) in the field is inserted into the insertion groove (PC-20) of the precast concrete beam (PC) of the precast concrete beam (PC). Since the installation work is completed, field work is simplified. However, since the above-described column-beam joint structure of the prior art is merely a pin joint structure and not a moment joint structure, there are many limitations in its application. Furthermore, in order to install the connection bracket 20 for bonding with the precast concrete beam (PC) to the concrete filled steel pipe column (SP), the inner reinforcing plate 10 must be joined to the inner side thereof, and for this purpose, the concrete filled steel pipe column There is a limitation that the (SP) must be of a structure in which it is divided and assembled.

US 10-0660522 B1

The present invention is to solve the problems of the prior art described above, it allows to have a moment joint structure between the CFT column and the coupled steel composite beam, minimizes the amount of work in the field, and provides a reinforcement structure for shear and bending It is intended to provide a coupled steel composite beam capable of achieving a low-profile and long-span PC bottom plate structure and a structure in which the coupled steel composite beam is momentarily joined to a CFT column.

According to the most preferred embodiment of the present invention for solving the above problems, as a coupled steel composite beam consisting of a concrete PC part, a composite PC part, and a joint, the concrete PC part has only a reinforced concrete structure and a positive moment acts. It is located in the central section of the beam, and the composite PC part has a structure in which a steel beam is synthesized in a reinforced concrete member and is located in both end sections of the beam where positive and negative moments intersect, and the composite PC part consists of only steel beams. There is provided a coupled steel composite beam having an end transition section, characterized in that it is formed protruding from.

In this case, the steel beams are opposite to each other and are spaced apart by at least the width of the CFT column, and may be made of first and second steel beams each having an upper flange and a lower flange and a web connecting each end of these flanges.

In addition, the lower main bar and stirrup bar are buried inside the reinforced concrete member of the composite PC part, but the upper end of the stirrup bar can be exposed to the upper part of the reinforced concrete member. is applied to In addition, by embedding the pre-stressed strands in the reinforced concrete member, it is possible to realize a low dance beam and achieve a long span.

According to another embodiment of the present invention, as a structure in which the coupled steel composite beam is joined to a CFT column, a connecting beam is attached to the CFT column, and the steel beam of the joint provided in the coupled steel composite beam is the connecting beam. Doedoe connection, the connecting beam is made of first and second connecting beams facing each other while having an upper flange, a lower flange, and a web connecting the ends of these flanges, and a joint is connected to the lower part of the lower flange of the connecting beam There is provided a CFT column joint structure of a coupled steel composite beam, characterized in that a mounting portion on which the coupled steel composite beam can be mounted is installed during operation.

At this time, the first and second cradles attached to the lower flanges of the first and second connecting beams, and the first and second holders installed in the lower flange of the first and second connecting beams; By forming a reinforcing concrete filling space composed of a lower plate installed under the bar, it is possible to safely proceed with the joint connection work of the coupled steel composite beam to the connecting beam and to function as a means to increase the bearing capacity of the end of the beam. .

In addition, joint reinforcing bars connected to the upper and lower main reinforcing bars of the coupled steel composite beam are installed on both sides of the CFT column. It is possible to omit the installation of the connector.

In addition, the flange of the steel beam and the flange of the connecting beam connected thereto are installed so that they protrude in the same direction, or the flange of the steel beam and the flange of the connecting beam connected to it protrude from either side of the end of the coupled steel composite beam. By making them opposite to each other, the width of the cross section of the CFT column on both sides of the beam can be configured differently.

The coupled steel composite beam of the present invention has a transition section at the end so that the PC beam of the reinforced concrete structure has continuity with the connecting beam installed on the CFT column. As a result, the steel beam in the transition section reinforces the portion where prestress is not introduced, so that the stress transfer to the entire beam is not distorted and made safely.

In addition, the coupled steel composite beam of the present invention has a structure that is joined to the CFT column and allows the introduction of prestress as described above, thereby facilitating the construction of a long-span PC floor plate structure. can be applied.

In addition, since the connecting beam installed to install the coupled steel composite beam of the present invention to the CFT column passes through both sides of the CFT column, the stress transfer is made directly between the beams on both sides of the CFT column, the outer shell of the CFT column It has a strong moment joint structure without putting too much load on it.

1 is an explanatory view of a joint structure of a CFT steel pipe column and a precast concrete beam according to the prior art.
2 is a cross-sectional view of a state in which the beam is moment-bonded to the CFT column using the coupled steel composite beam of the present invention.
3 is a cross-sectional view of each part of FIG. 2 .
4 is a perspective view of the coupled steel composite beam.
5 is a partial cross-sectional view of FIG. 4 .
6 is a perspective view of a coupled steel composite beam of another embodiment.
7 is a partial cross-sectional view of FIG. 6 .
8 is a perspective view of a connecting beam installed on a CFT column of the present invention.
9 is an explanatory view of the process of connecting the coupled steel composite beam to the connecting beam.
10 and 11 are perspective and plan views each illustrating a joint connection structure of a steel beam and a connecting beam of a coupled steel composite beam for changing the cross-sectional size of the CFT column on both sides of the beam.

Hereinafter, the most preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, in the description of the present invention, in the case of obscuring or obscuring the technical idea of the present invention due to the detailed description of the known configuration, the description of the above known configuration will be omitted.

2 is a view showing a state constructed by moment bonding to a CFT column 200 using a coupled steel composite beam 100 according to an embodiment of the present invention, and FIG. 3 is a cross-section at each part of FIG. is shown, and FIGS. 4 and 6 show each embodiment regarding the coupled steel composite beam 100, and FIGS. 5 and 7 are cross-sections in each part of FIGS. 4 and 6, and FIG. 8 is installed on the CFT column 200 and shows a connecting beam 300 that is connected to the coupled steel composite beam 100 and jointly connected, and FIG. It shows the process.

Here, the CFT column 200 refers to having a closed square cross-section, and includes not only a square steel pipe produced by roll forming, but also a plate material attached to each flange of the H-beam to form four outer surfaces. .

The coupled steel composite beam 100 of the present invention is manufactured in a factory and then transported and installed to the site, and as shown in FIGS. 4 and 6, the concrete PC part 100A and the composite PC part 100B and the joint part ( 100C), and as shown in each cross section in FIGS. 5 and 7, the joint 100C is configured in the form of a steel structure of only the steel beam 120 so that it can be jointly connected with the connecting beam 300, The composite PC unit 100B is configured in the form of a steel frame reinforced concrete structure in which the steel beam 120 and the reinforced concrete member 110 are synthesized, and the concrete PC unit 100A has only a reinforced concrete structure. These will be described in more detail as follows.

The concrete PC unit 100A is located in the positive moment section, which is the central section of the beam (B), and promotes economic feasibility by having a reinforced concrete structure and enables the introduction of prestress using the stranded wire 115 to realize a low dance. make it possible

The stirrup reinforcing bar 113 is embedded together with the lower main bar 111 in the inside of the reinforced concrete member 110, and the stirrup reinforcing bar 113 has a structure in which the upper end is exposed to the upper part of the reinforced concrete member 110. . In addition, as described above, the strand 115 to which the prestress is introduced may be further embedded.

The composite PC unit 100B has a structure in which the steel beam 120 is synthesized in the reinforced concrete member 110, and is located at both end sections of the coupled steel composite beam 100 where the positive moment and the negative moment intersect. do.

The reinforced concrete member 110 part synthesized in the steel beam 120 is made in such a way that the end of the concrete PC part 100A is extended, and a shear connector is more on the inner surface of the steel beam 120 so that they have a high bonding force. can be installed.

This composite PC part 100B improves structural stability by forming a transition section at the end of the beam (B) for stress change, and also has continuity with the joint part 100C and is connected to the coupled steel composite beam 100 It allows the joint connection of the beam 300 to be easily made.

That is, the steel beam 120 is composed of a first steel beam 120A and a second steel beam 120B that face each other and are spaced apart by at least the width of the CFT column 200, and these first and second steel beams 120A , 120B) forms first and second joint portions 120a and 120b formed by protruding from the end of the composite PC unit 100B, and these first and second joint portions 120a and 120b are described later. 1 and 2 connecting beams 310A and 310B are jointly connected. At this time, each dance of the first steel beam 120A and the second steel beam 120B is not necessarily configured to be identical, and may be configured differently depending on the shape conditions of the adjacent slab.

The connecting beam 300 is composed of the above-described first and second connecting beams 310A and 310B attached to opposite sides of the CFT column 200 made of a square steel pipe as shown in FIG. 8, and here While facilitating the connection work with the coupled steel composite beam 100 in the future, a mounting portion 320 to increase the bearing capacity of the end of the beam (B) may be further included.

The steel beam 120 and the connecting beam 300 are upper flanges 121 and 311 and lower flanges 122 and 312 and webs 123 and 313 connecting each end of these flanges 121, 122, 311 and 312 while having a U-shaped cross section, which will be described later. As such, it is possible to have a change in the cross section of the CFT column 200 installed on both sides of the beam (B).

As such, the steel beam 120 and the connecting beam 300 having a U-shaped cross section can have different installation directions as needed, for example, the flange of the steel beam 120 as shown in FIGS. The coupled steel composite beam 100 may be configured so that the 121, 122) direction is directed outward, and the flanges 121 and 122 of the steel beam 120 are directed inward as shown in FIGS. 4 and 5, as shown in FIGS. (100) can also be configured. This point also applies to the connecting beam 300 as it is.

In addition, the first and second steel beams 120A and 120B may be maintained in a straight line for the entire section including the first and second joint portions 120a and 120b, but as shown in FIGS. 6 and 7, the first, It is possible to overcome the large difference in the cross-section of the CFT column on both sides of the coupled steel composite beam by forming a step difference between the portion and the remaining portion of the first and second joint portions 120a and 120b of the two steel beams 120A and 120B.

Mounting part 320 is installed in the lower part of the lower planar 312 paper of the connecting beam 300, both ends protrude from the end of the connecting beam 300, so that the installation work of the coupled steel composite beam 100 is safely and efficiently to be able to proceed to

The joint connection operation of the coupled steel composite beam 100 to the connecting beam 300 is, as shown in FIG. Thus, since the coupled steel composite beam 100 can proceed in a state supported by the mounting unit 320, lifting means such as a crane to be suspended and supported until the coupled steel composite beam 100 is installed is unnecessary. In addition, since the safety of the operator is secured, the operator can safely proceed with more precise construction.

The holder 320 includes the first and second cradles 321A and 321B that are attached to the lower flanges 312 of the first and second connecting beams 310A and 310B, and the first and second holders 321A and 321B. ) consists of a pole 322 installed in the transverse direction at both ends, and a lower plate 323 installed under the first and second holders 321A and 321B and the pole 322 .

Therefore, an interspace is formed by the first and second cradles 321A and 321B, the bar 322 closes the front and rear of the interspace, and the lower plate 323 closes the lower portion of the interspace so that the upper part is An open reinforced concrete filling space (s) is formed. At this time, by filling the reinforced concrete filling space (s) with concrete, the dance of the end of the beam (B) is increased, whereby the mounting part 320 functions as a means for improving the bearing capacity of the end of the beam (B). do.

On the other hand, the coupled steel composite beam 100 is manufactured so that the lower main bar 111 embedded in the concrete PC part 100A protrudes from the reinforced concrete member 110, and this coupled steel composite beam 100 is a connecting beam 300. After connecting with the bar, the upper main bar 112 is placed on the upper side of the stirrup bar 113 whose lower end is embedded in the reinforced concrete member 110, and the CFT column produced separately from the coupled steel composite beam 100 ( 200), the upper and lower joint reinforcing bars 116 for joint connection with the upper and lower main muscles 112 and 111 and the end stirrup muscles 114 surrounding them are respectively installed on both sides, in this case, the end stirrup muscles 114 By extending to the inside of the reinforcing concrete filling space (s), it is preferable to sufficiently secure the integrity of the end of the beam (B) without installing studs or the like in the mounting portion 320 to efficiently reinforce the bearing capacity.

The steel beam 120 and the connecting beam 300 are configured to have a U-shaped cross section as described above, and the flanges 121 and 122 of each steel beam 120 located on both sides of the concrete PC part 100A. By changing the direction of the flanges 311 and 312 of each connecting beam 300 located on both sides of the coupled steel composite beam 100, a separate connecting flange 124 is added to the web 123 of the steel beam 120 without adding the beam. It is possible to have a change in the cross section of the CFT column 200 installed on both sides of (B).

10 shows the desired purpose by changing the installation method of the steel beam 120 and the connecting beam 300 when the cross-sectional size of the CFT columns 200 on both sides of the beam B should be configured differently as described above for space division. is an example of achieving

In the embodiment of Figure 10, the installation direction of the steel beam 120 on both sides of the coupled steel composite beam 100 is mutually opposite. That is, on one side of the end of the coupled steel composite beam 100, the protruding direction of the flanges 121 and 122 faces outward, and on the other side, the protruding direction of the flanges 121 and 122 faces inward.

Correspondingly, the connecting beam 300 installed on the CFT column 200 also allows the projection direction of the flanges 311 and 312 to coincide with the projection direction of the flanges 121 and 122 of the steel beam 120 described above. That is, in the CFT column 200 where the flanges 121 and 122 of the steel beam 120 protrude in the outward direction, the protrusion of the flanges 311 and 312 of the connecting beam 300 is also directed in the outward direction so that the web is CFT column 200. It has a shape in contact with the outer surface, and in the CFT column 200 where the flanges 121 and 122 of the steel beam 120 protrude in the inward direction, the flanges 311 and 312 of the connecting beam 300 also protrude in the inward direction. The ends of the beam 300 flanges 311 and 312 have a shape in contact with the outer surface of the CFT column 200 . Therefore, the latter CFT column 200 can have a cross-section with a width that is reduced as much as the width of the flanges 311 and 312 of the connecting beam 300, and by adjusting the width of the flanges 311 and 312 of the connecting beam 300, the CFT column ( 200) can also be adjusted.

In the embodiment of Fig. 10, the flanges 121 and 122 of the steel beam 120 and the flanges 311 and 312 of the connecting beam 300 have a projecting structure in the same direction, so the use of the connection flange 124 was omitted, The width of the cross section of the CFT column 200 on both sides may be different by using the connecting flange 124 while the installation direction of the steel beam 120 on both ends of the coupled steel composite beam 100 is the same. Figure 9 shows one such embodiment.

In the embodiment of Figure 11, in a state in which the protrusions of the flanges 121 and 122 of the steel beam 120 on both sides of the coupled steel composite beam 100 are all directed toward the inside, the connecting beam 300 flange of one side CFT column 200 (311,312) were to protrude in the outside direction, and the flanges 311 and 312 of the connecting beam 300 of the other CFT column 200 in the inward direction, at this time, each flange 121,122,311,312 of the steel beam 120 and the connecting beam 300. ) by providing a connecting flange 124 to the web 123 so as to protrude in the outward direction on one side of the steel beam 120 opposite to each other, so that the joint connection between the connecting beam 300 and the steel beam 120 is easy is done

As such, the present invention provides the flanges 121, 122, 311, 312 of each steel beam 120 on both sides of the coupled steel composite beam 100 and each connecting beam 300 connected to these steel beams 120 in the same direction, or The projecting direction of each of these flanges (121,122,311,312), such as to reverse the projecting direction of the flanges (121,122,311,312) of the steel beam 120 and the connecting beam 300 connected thereto with respect to either side of the PC concrete beam 100 end can be set independently and individually, and by adjusting the size of the cross-section of the CFT column 200, it is possible to create spaces of various shapes.

However, the difference between the cross sections of the CFT columns 200 adjacent to each other in the spatial plan is too large, so that only the width of the flanges 121 , 122 , 311 , 312 of the steel beam 120 and the connecting beam 300 may not be able to overcome this. At this time, the coupled steel composite beam 100 of the embodiment shown in FIGS. 6 and 7 may be used very appropriately.

In the above, the present invention has been described in detail with reference to specific embodiments, but the embodiments are merely examples for easy understanding of the present invention. It is obvious that it can be implemented with various modifications within. Accordingly, such modifications will be said to be within the scope of the present invention as described in the claims.

100; Coupled steel composite beam 100A; Concrete PC part
100B; Synthetic PC part 100C; seam
110; reinforced concrete member 111; lower main
112; upper main muscle 113; stirrup muscle
114; end stirrup muscle 115; strand
116; joint rebar 120; Jaebo Kang
120A; 1st steel beam 120B; 2nd steel beam
120a; first joint 120b; 2nd joint
121,311; upper flange 122,312; half flange
123,313; web 200; CFT column
300; Connection beam 310A; 1st connecting beam
310B; 2nd connection beam 320: holding part
321A; first cradle 321B; 2nd cradle
322; rod 323; lower plate
B; beam s; Reinforced concrete filling space

Claims (9)

As a coupled steel composite beam 100 consisting of a concrete PC part (100A), a composite PC part (100B), and a joint part (100C),
The concrete PC part (100A) is located in the central section of the beam (B), which consists of only the reinforced concrete member 110 so as to have only the reinforced concrete structure, and the positive moment acts,
The composite PC unit 100B has a structure in which the steel beam 120 is synthesized on both outer surfaces of the reinforced concrete member 110 and is located in both end sections of the beam B where the positive moment and the negative moment intersect, ,
The joint portion 100C is made of only the steel beam 120 and is formed to protrude from the composite PC portion 100B,
The steel beams 120 are opposed to each other and are spaced apart by at least the width of the CFT column 200 , and the upper flange 121 and the lower flange 122 and the web 123 connecting each end of the flanges 121 and 122 . ) is made of the first and second steel beams 120A and 120B each having a U-shaped cross section,
A lower main bar 111 and a stirrup reinforcing bar 113 are embedded in the reinforced concrete member 110 of the composite PC unit 100B, and the upper end of the stirrup reinforcing bar 113 is the upper portion of the reinforced concrete member 110 . Coupled steel composite beam with an end transition section, characterized in that it is exposed to
delete delete According to claim 1,
Coupled steel composite beam having an end transition section, characterized in that the prestressed strand 115 is embedded in the reinforced concrete member 110 .
As a structure in which the coupled steel composite beam 100 of claim 1 or 4 is joined to the CFT column 200,
A connecting beam 300 is attached to the CFT column 200 and installed, and the steel beam 120 of the joint 100C provided in the coupled steel composite beam 100 is jointly connected to the connecting beam 300 . ,
The connecting beam 300 is provided with an upper flange 311 and a lower flange 312 and a web 313 connecting the ends of these flanges 311 and 312, respectively, and the first and second connections of the U-shaped cross-section facing each other. Consists of beams 310A and 310B,
CFT of a coupled steel composite beam, characterized in that a mounting portion 320 on which the coupled steel composite beam 100 can be mounted is installed at a lower portion of the lower flange 312 of the connecting beam 300 column joint structure.
6. The method of claim 5,
The holder 320 includes first and second cradles 321A and 321B that are attached to the lower flanges 312 of the first and second connecting beams 310A and 310B, and the first and second cradles 321A, It consists of a pole 322 installed in the transverse direction at both ends of the 321B, and a lower plate 323 installed under the first and second holders 321A and 321B and the pole 322, the upper part of which is open. CFT column joint structure of coupled steel composite beam, characterized in that the filled reinforced concrete filling space (s) is formed.
7. The method of claim 6,
Joint reinforcement 116 is installed on both sides of the CFT column 200, and end stirrup reinforcement 114 extending to the inside of the reinforced concrete filling space s is installed in the joint reinforcement 116. CFT column joint structure of coupled steel composite beam with
6. The method of claim 5,
The flanges 121 and 122 of the steel beam 120 and the flanges 311 and 312 of the connecting beam 300 connected thereto are installed to protrude in the same direction.
6. The method of claim 5,
The direction in which the flanges 121 and 122 of the steel beam 120 and the flanges 311 and 312 of the connecting beam 300 connected thereto with respect to any one of both sides of the end of the coupled steel composite beam 100 are opposite to each other CFT column joint structure of coupled steel composite beam with

Images