KR20200090524A - Suitable joint structure of steel column and beam on seismic design - Google Patents

Abstract

The present invention provides a joint structure of a steel column and beam suitable for an aseismic design, which comprises: a steel column (10); a steel beam (20) traversely connected to the steel column (10); and a flexible bracket (30) arranged between the steel column (10) and the steel beam (20), having one side coupled to the steel column (10) and the other side coupled to the steel beam (20), and deformable in the longitudinal direction of the steel beam (20) and in the direction crossing the longitudinal direction. The flexible bracket (30) includes: a flat plate portion (31) coupled to any one between the steel column (10) and the steel beam (20); a flexible portion (35) bent in a C shape from both ends of the flat plate portion (31) and having an S-shaped cross section; and a flange portion (35) bent from an end portion of the flexible portion to the outer side and coupled to the other between the steel column (10) and the steel beam (20). The present invention absorbs vibration in the vertical direction of the steel beam as well as compressive load and tensile load in the longitudinal direction of the steel beam.

Description

SUITABLE JOINT STRUCTURE OF STEEL COLUMN AND BEAM ON SEISMIC DESIGN}

The present invention relates to a coupling structure of steel columns and beams, and more particularly, to a coupling structure of steel columns and beams suitable for seismic design suitable for seismic design.

In recent years, the importance of seismic design of buildings has been highlighted as the risk of large-scale earthquakes in Korea has increased. In addition to earthquakes, strong winds such as typhoons and ground phenomena such as sinkholes have a significant impact on the stability of the building.

In order to counter this external force, it is basically necessary to perform proper seismic design so that the steel column and beam coupling structure can effectively absorb the external force.

An example of such a seismic design technology is Korean Patent No. 10-0982296. According to this technology, the tensile load applied in the longitudinal direction of the steel beam can be absorbed by the coil spring by combining the steel column and the steel beam with a bolt and installing a coil spring on the same axis as the bolt. However, this technique cannot absorb the compressive and torsional loads applied between the steel column and the steel beam. Also, it is difficult to effectively absorb vibrations in the vertical direction.

An object of the present invention is to provide a coupling structure of a steel column and a beam suitable for a seismic design that can effectively absorb compressive loads, tensile loads, and vibrations in the vertical direction as well as compression loads generated between a steel column and a steel beam by a simple configuration. In addition, it is to provide a coupling structure of a steel column and beam suitable for seismic design capable of absorbing torsional loads generated between the steel column and the steel beam.

In order to achieve the above object, according to the present invention, the steel column (10) and; A steel frame beam (20) transversely connected to the steel column (10); It is disposed between the steel column 10 and the steel beam 20, coupled to the steel column 10 on one side and coupled with the steel beam 20 on the other side, the longitudinal direction and the longitudinal direction of the steel beam 20 Includes; the elastic bracket 30 is deformable in a direction intersecting to, The elastic bracket 30, the steel column 10 and the flat plate portion 31 coupled to any one of the steel beams (20), The flat part 31 is bent in a'c' shape from both ends, and an elastic part 35 having an'S' type cross section, and is bent outwardly from an end of the elastic part 35, and the steel column 10 and A steel column and beam coupling structure suitable for an earthquake-resistant design including a flange portion 35 coupled to another one of the steel beams 20 is provided.

An end plate 25 is provided at an end of the steel frame beam 20, and the elastic bracket 30 may be coupled to the end plate 25.

Any one of the coupling of the telescopic bracket 30 and the steel column 20 and the coupling of the telescopic bracket 30 and the end plate 25 may be a plurality of bolt combinations allowing relative movement.

The elastic bracket 30 may be made of an elastic steel material.

The plurality of bolt coupling is made on at least one concentric circle having a longitudinal center line (CL) of the steel frame beam 20 as a rotation axis, and the expansion and contraction bracket 30 is the bolted steel frame column 10 or the steel frame beam ( 20) is relatively rotatable about the center line (CL), and the flat plate portion 31 or the flange portion 33 of the telescopic bracket 30 has a plurality of agents corresponding to the plurality of bolt couplings. A first bolt hole is formed, and a plurality of second bolt holes corresponding to the plurality of first bolt holes are formed in the steel column 10 or the end plate 25 that are bolted to the elastic bracket 30. And at least one of the plurality of first bolt hole sets and the plurality of second bolt hole sets may be elongated holes extending on the concentric circle.

The steel column and beam coupling structure suitable for the seismic design, on the same axis as the bolt constituting the bolt coupling, between the head of the bolt and the end plate 25 and the flange portion 33 of the telescopic bracket 30 And the reinforcing spring provided on at least one of the steel column (10).

The steel column and beam coupling structure suitable for the seismic design include a support bracket 60 fixed to the steel column 10 at a position spaced apart from the lower portion of the steel beam 20; It is disposed on the support bracket 60, the elastic support member 70 for elastically supporting the lower portion of the steel beam 20; further comprising, the plurality of first bolt holes corresponding to the bolt coupling At least one of the set and the plurality of second bolt hole sets may be a long hole extending in the vertical direction.

According to the present invention, by arranging the expansion and contraction bracket 30 having a'S'-shaped cross-section 35 between the steel column 10 and the steel beam 20, the compression load in the longitudinal direction of the steel beam 20 It can absorb not only tensile load but also vibration in the vertical direction.

In addition, according to the present invention, a plurality of bolt couplings are arranged on at least one concentric circle, and at least one of the bolt-coupled members forms a long hole-shaped bolt hole extending in the circumferential direction of the concentric circles so that the members form a steel beam 20 By making it relatively slidable about the longitudinal center line (CL) in the longitudinal direction, it absorbs up to the torsional load applied to the steel beam (20) in addition to the compression load and tensile load in the longitudinal direction of the steel beam (20) and vibrations in the vertical direction. Can be.

In addition, according to the present invention, between the head of the bolt 41a and the end plate 25 of the steel beam 20 and between the flange portion 33 of the telescopic bracket 30 and the flange 13 of the steel column 10 The elastic bracket 30 can be protected by arranging the reinforcing springs 50a and 50b on at least one of them to absorb the compressive load or tensile load before the elastic part 35 of the elastic bracket 30.

In addition, according to the present invention, by placing the elastic support member 70 on the lower portion of the steel frame beam 20 to protect the expansion and contraction bracket 30 by absorbing the vibration in the vertical direction before the expansion and contraction portion 35 of the expansion and contraction bracket 30. can do.

1 is a front view of a steel column and beam coupling structure suitable for a seismic design according to the first embodiment of the present invention.
Figure 2 is a perspective view of a coupling structure of a steel column and beam suitable for seismic design according to the first embodiment of the present invention.
3 is a perspective view of a telescopic bracket used in a steel column and beam coupling structure suitable for a seismic design according to a second embodiment of the present invention.
Figure 4 is a front view showing a coupling structure of a steel column and beam suitable for seismic design according to the third embodiment of the present invention.
5 is a perspective view of a telescopic bracket used in a steel column and beam coupling structure suitable for a seismic design according to a third embodiment of the present invention.
6 is a front view showing a coupling structure of a steel column and a beam suitable for a seismic design according to a fourth embodiment of the present invention.
7 is a schematic front view showing a coupling structure of a steel column and a beam suitable for a seismic design according to a fifth embodiment of the present invention.
8 is a schematic diagram of an end plate used in a steel column and beam coupling structure suitable for a seismic design according to a fifth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view of a coupling structure of a steel column and a beam suitable for an earthquake-resistant design according to the first embodiment of the present invention, and FIG. 2 is a schematic perspective view thereof.

As shown in Figures 1 and 2, the steel column and beam coupling structure suitable for the seismic design according to this embodiment is a steel column (10) and a steel beam (20) transversely connected to the steel column (10). , It includes a telescopic bracket 30 disposed between the steel column (10) and the steel frame beam (20).

The steel column 10 is preferably composed of H-shaped steel, and is composed of a web 11 and a flange 13 on both sides of the web. However, the steel column 10 is not necessarily limited to the H-beam, and may be a section steel having a different cross section if necessary.

Like the steel column 10, the steel frame beam 20 is preferably made of H-shaped steel, and is composed of a web 21 and a flange 23 on both sides of the web. The steel beam 20 is not necessarily limited to the H-beam, but may be a beam having a different cross section if necessary. An end plate 25 is attached to the end of the steel beam 20 by welding or the like. However, as required by design, the end plate 25 may be omitted, and the elastic bracket 30 may be directly coupled to the end of the steel frame beam 20.

The elastic bracket 30 is coupled to the steel frame beam 20 on one side (right side of the drawing), and is coupled to the steel frame column 10 on the other side (left side of the drawing). The coupling of the telescopic bracket 30 and the steel frame beam 20 is preferably a bolt combination by a plurality of bolts 40 and nuts 42, as shown in FIG. 1, but may also be a joint by welding, or technology Other bonding methods known in the art may also be used. The coupling of the telescopic bracket 30 and the steel column 10 may be a bolt bonding or a joining by welding, or other bonding methods known in the art. When these couplings are bolt couplings, it goes without saying that bolt holes through which bolts are formed are formed on the coupling members.

The elastic bracket 30 is a flat portion 31 coupled to the steel frame beam 20, and a pair of stretched portions 35 bent in a'c' shape toward the steel column 10 from both ends of the flat plate portion 31 And, the flange portion 35 is bent outward from the end of the expansion and contraction portion 35 is coupled to the steel column (10).

The elastic part 35 has a'S'-shaped cross section as a whole. In FIG. 1, for convenience of description, although the cross section of the elastic part 35 is shown to have one'S' type waveform, it may be included, of course, 1.5 or two or more'S' type waveforms according to design needs. to be. In addition, although the'S' type waveform is composed of two subwaveforms that are approximately semicircular in shape, the partial waveforms may be a'U' type or a'V' type, or other shapes, depending on design needs. In other words, if the cross section of the expansion/contraction section 35 forms an overall'S' shape, the partial waveforms can be any shape.

According to this configuration, when the steel beam 20 is moved in the longitudinal direction due to lateral vibration due to an earthquake, etc. to apply a compressive load or a tensile load to the steel column 10, the'S of the expansion bracket 30 'A compression or tensile load can be absorbed by the contraction or elongation of the elastic part 35.

In particular, when a pair of steel columns 10 are arranged at both ends of the steel beam 20 to form a symmetrical structure, when a compressive load acts on one steel column 10, the tensile load may act on the other steel column 10. , In this case, by using the elastic bracket 30 of the same configuration, one side can absorb the compressive load by contraction of the elastic part 35 and the other side can absorb the tensile load by elongation of the elastic part 35.

In addition, even when the steel frame beam 20 vibrates up and down with respect to the steel column 10, the expansion and contraction brackets 30 can be deformed up and down relatively easily because the expansion and contraction part 35 has an'S' type cross section. Accordingly, it is possible to absorb vibration in the vertical direction.

The material of the elastic bracket 30 may be a steel material that is plastically deformed at a lower strength than the steel column 10 and the steel beam 20. In this case, since the elastic bracket 30 absorbs the load applied by the axial vibration or the vertical vibration of the steel beam 20 before the steel column 10 and the steel beam 20, it is plastically deformed, so that the steel column 10 And it has the advantage that can protect the cheolgolbo (20).

As another example, the material of the elastic bracket 30 may be an elastic steel material. In this case, after the elastic part 35 absorbs the axial vibration or the vertical vibration of the steel beam 20 by elastic deformation, it has an advantage that it is possible to recover the original shape again.

3 is a perspective view of a telescopic bracket 30 used in a steel column and beam coupling structure suitable for a seismic design according to a second embodiment of the present invention.

The difference between the second embodiment and the first embodiment is as follows. That is, when the telescopic bracket 30 and the steel beam 20 are bolted by a plurality of bolts 40 and nuts 42 as shown in FIG. 1, the steel beam 20 is steel beam 20 with respect to the elastic bracket 30. ) A plurality of long hole-shaped bolt holes 37 are formed on the circumference of the flat plate portion 31 of the telescopic bracket 30 so as to be able to rotate relative to the longitudinal center line CL.

According to this configuration, even when a torsional load is generated on the steel beam 20, the steel beam 20 can be absorbed torsional load by sliding and rotating relative to the telescopic bracket 30 by the length of the long hole bolt hole 37.

Although FIG. 3 shows an example in which the bolt hole 37 is disposed on one circumference for convenience of description, the bolt hole 37 may be disposed on a plurality of circumferences concentrically formed according to design needs. Of course.

Also, FIG. 3 shows an example in which a long hole bolt hole 37 is formed in the flat plate portion 31 of the telescopic bracket 30 for convenience of explanation, but the long hole bolt hole is an end plate 25 of the steel frame beam 20. It may be formed on, or may be formed on both the flat plate portion 31 and the end plate (25).

4 is a front view showing a steel column and beam coupling structure suitable for seismic design according to the third embodiment of the present invention, and FIG. 5 is a steel column and beam coupling suitable for seismic design according to the third embodiment of the present invention It is a perspective view of the elastic bracket 30 used in the structure.

The difference between the third embodiment and the second embodiment is as follows. That is, in contrast to the second embodiment, the telescopic bracket 30 and the steel frame beam 20 are fixedly coupled, and the flange portion 33 and the steel column 10 of the telescopic bracket 30 are coupled to be rotatable. To this end, as shown in FIG. 5, a long hole-shaped bolt hole 39 is formed in the flange portion 33 of the telescopic bracket 30, and a bolt corresponding to the flange 13 of the steel column 10 is also provided. A hole (not shown) is formed.

According to this configuration, when a torsional load occurs on the steel beam 20, the combination of the steel beam 20 and the expansion bracket 30 is a long hole bolt around the center line CL of the steel beam 20 with respect to the steel column 10 Torsional load can be absorbed by relative rotation by the length of the hole 39.

FIG. 4 shows an example in which the bolt hole 39 is disposed on one circumference for convenience of explanation, but the bolt hole 39 may be disposed on a plurality of circumferences concentrically formed according to design needs. Of course.

Also, FIG. 4 shows an example in which a long hole bolt hole 39 is formed in the flange portion 33 of the telescopic bracket 30 for convenience of explanation, but the long hole bolt hole is a flange 13 of the steel column 20 It may be formed on, or may be formed on both the flange portion 31 and the flange (13).

6 is a front view showing a coupling structure of a steel column and a beam suitable for a seismic design according to a fourth embodiment of the present invention.

The difference between the fourth embodiment and the first to third embodiments is as follows. That is, instead of the short bolt 40, a long bolt 40a is used, and the first reinforcing spring 50a is coaxial with the bolt 40a between the head of the bolt 40a and the end plate 25 of the steel beam 20. The second reinforcement spring 50b is installed on the coaxial with the bolt 40a between the flange portion 33 of the telescopic bracket 30 and the flange 13 of the steel column 10.

The first reinforcing spring 50a and the second reinforcing spring 50b are preferably compression coil springs as shown, but are not limited thereto, and may be other elastic members such as rubber.

According to this configuration, when a tensile load is applied to the steel column 10 by the longitudinal movement of the steel beam 20, the first reinforcement spring 50a is elastic as the steel beam 20 is spaced apart from the elastic bracket 30. Deformation first absorbs a portion of the tensile load, and then the stretchable portion 35 of the stretchable bracket 30 can be stretched to absorb the rest of the stretched load, thereby protecting the stretchable bracket 30.

Conversely, when a compressive load is applied to the steel column 10 by the longitudinal movement of the steel beam 20, the second reinforcement spring 50b elastically deforms while the elastic bracket 30 moves toward the steel column 10. First, a portion of the compression load is absorbed, and then the expansion and contraction portion 35 of the expansion and contraction bracket 30 contracts to absorb the rest of the compression load, thereby protecting the expansion and contraction bracket 30.

6 illustrates an example in which both the first reinforcing spring 50a and the second reinforcing spring 50b are installed for convenience of description, it can be understood that only one of the two may be installed according to design needs.

In particular, in the case of a symmetrical structure in which a pair of steel columns 10 are disposed at both ends of the steel frame beam 20, when a compressive load acts on one steel column 10, the tensile load may act on the other steel column 10, In this case, by installing one of the first reinforcement spring 50a and the second reinforcement spring 50b on one side and the other on the other side, the same effect can be achieved when both are installed on one side.

7 is a schematic front view showing a steel column and beam coupling structure suitable for an earthquake-resistant design according to a fifth embodiment of the present invention, and FIG. 8 is a steel column and beam suitable for an earthquake-resistant design according to a fifth embodiment of the present invention It is a schematic view of the end plate 25 used in the coupling structure. In FIG. 7, for the convenience of description, only the steel column 10, the steel frame beam 20, and the expansion bracket 30 are schematically illustrated except for the characteristic configuration of the fifth embodiment.

The fifth embodiment is different from the above-described embodiments, the support bracket 60 fixed to the steel column 10 is installed in a position spaced apart from the lower portion of the steel beam 20, the support bracket 60 and the steel beam It is that the elastic support member 70 for elastically supporting the steel beam 20 is provided between the lower portions of the (20).

The support bracket 60 includes a vertical support portion 63 fixed to the steel column 10 at one side (left side in FIG. 7) and a horizontal support portion 61 disposed above the vertical support portion 63. 7 illustrates an example in which the vertical support 63 is indirectly fixed to the steel column 10 through the expansion and contraction bracket 35 for convenience of explanation, but the vertical support 63 directly directs the steel column 10 by appropriate design changes. It is also possible to have a fixed configuration.

The elastic support member 70 may be a spring member such as a compression coil spring, or other elastic member such as rubber.

When the support bracket 60 and the elastic support member 70 are installed in this way, the end plate 25 of the steel beam 20 extends in the vertical direction as shown in FIG. 8 in the long hole bolt hole 27a. This is formed, to allow the relative vertical sliding movement of the steel beam 20 and the telescopic bracket 30.

According to such a configuration, when the steel beam 20 vibrates up and down, the elastic support member 70 first absorbs a part of the vibration by elastic deformation, and then the elastic part 35 of the elastic bracket 30 rests the vibration. Since it can absorb the expansion and contraction bracket 30 can be protected.

FIG. 8 shows an example in which a vertically long bolt hole in the vertical direction is formed on the end plate 25 for convenience of description, but the vertically long bolt hole may be formed in the flat plate portion 31 of the expansion and contraction bracket 30. Alternatively, it may be formed on both the end plate 25 and the flat plate portion 31.

In addition, when the telescopic bracket 30 and the steel beam 20 are fixedly coupled and the flange portion 33 and the steel column 10 of the telescopic bracket 30 are bolted (see FIG. 4), the telescopic bracket 30 A long hole bolt hole in the vertical direction may be formed in at least one of the flange portion 33 and the flange 13 of the steel column 10.

In the above-described embodiments, an example in which the flat plate portion 31 of the telescopic bracket 30 is coupled to the steel beam 20 and the flange portion 33 is coupled to the steel column 10 is described, on the contrary, the flange portion 33 It is of course also included in the scope of the present invention is a configuration that is coupled to the steel beam (20) and the flat plate portion (31) coupled to the steel column (10).

In addition, in the above-described embodiments, both the flanges 33 of the telescopic bracket 30 have been described in an example arranged along the longitudinal direction of the steel column 10, but both flanges 33 are steel column ( 10) can be arranged in the horizontal direction, and such a configuration is also included in the scope of the present invention. In this case, "vertical direction" in the present specification means "horizontal direction".

As described above, according to the present invention, by arranging the telescopic bracket 30 having an'S'-shaped cross-section 35 between the steel column 10 and the steel beam 20, the steel beam 20 It can absorb not only the compression load and tensile load in the longitudinal direction but also vibration in the vertical direction.

In addition, according to the present invention, a plurality of bolt couplings are arranged on at least one concentric circle, and at least one of the bolt-coupled members forms a long hole-shaped bolt hole extending in the circumferential direction of the concentric circles so that the members form a steel beam 20 By relatively sliding rotation about the longitudinal center line (CL) of the center, in addition to the compressive load and tensile load in the longitudinal direction of the steel beam 20 and vibration in the vertical direction, it can absorb up to the torsional load applied to the steel beam 20. Can be.

In addition, according to the present invention, between the head of the bolt 41a and the end plate 25 of the steel beam 20 and between the flange portion 33 of the telescopic bracket 30 and the flange 13 of the steel column 10 The elastic bracket 30 can be protected by arranging the reinforcing springs 50a and 50b on at least one of them to absorb the compressive load or tensile load before the elastic part 35 of the elastic bracket 30.

In addition, according to the present invention, by placing the elastic support member 70 on the lower portion of the steel frame beam 20 to protect the expansion and contraction bracket 30 by absorbing the vibration in the vertical direction before the expansion and contraction portion 35 of the expansion and contraction bracket 30. can do.

10: Steel column 11: Web
13: flange 20: steel beam
21: web 23: flange
25: end plate 30: telescopic bracket
31: flat plate portion 33: flange portion
35: telescopic portion 40, 40a: bolt
42: Nut 50a: First reinforcement spring
50b: Second reinforcement spring 60: Support bracket
61: horizontal support 63: vertical support
70: elastic support member

Claims (8)

Steel column (10) and;
A steel frame beam (20) transversely connected to the steel column (10);
It is disposed between the steel column 10 and the steel beam 20, coupled to the steel column 10 on one side and coupled with the steel beam 20 on the other side, the longitudinal direction and the longitudinal direction of the steel beam 20 Includes; telescopic bracket 30 that can be deformed in a direction crossing;
The telescopic bracket 30 is bent in a'c' shape from both ends of the flat part 31 coupled to any one of the steel column 10 and the steel frame beam 20, and both ends of the flat part 31.' An elastic part 35 having an S'-shaped cross section, and a flange part 35 bent outward from an end of the elastic part 35 and coupled to the other one of the steel column 10 and the steel frame beam 20 Steel column and beam coupling structure suitable for seismic design, characterized in that it comprises. According to claim 1,
An end plate 25 is provided at an end of the steel frame beam 20,
The expansion bracket 30 is a steel column and beam coupling structure suitable for seismic design, characterized in that coupled to the end plate (25). According to claim 2,
Seismic, characterized in that any one of the combination of the expansion bracket 30 and the steel column 20 and the expansion bracket 30 and the end plate 25 is a plurality of bolt coupling to allow relative movement Steel column and beam joint structure suitable for design. According to claim 3,
The elastic bracket 30 is made of an elastic steel material, which is suitable for an earthquake-resistant design. The method of claim 3 or 4,
The plurality of bolt coupling is made on at least one concentric circle having a longitudinal center line (CL) of the steel beam 20 as a rotation axis,
The elastic bracket 30 is relatively rotatable about the center line CL with respect to the steel column 10 or the steel frame beam 20 that is bolted,
A plurality of first bolt holes corresponding to the plurality of bolt couplings are formed on the flat plate portion 31 or the flange portion 33 of the telescopic bracket 30,
A plurality of second bolt holes corresponding to the plurality of first bolt holes are formed in the steel column 10 or the end plate 25 that are bolted to the elastic bracket 30,
At least one of the plurality of first bolt hole sets and the plurality of second bolt hole sets is a long hole extending on the concentric circle. The method of claim 5,
Coaxially with the bolt constituting the bolt coupling, reinforcement provided at least one of between the head of the bolt and the end plate 25 and between the flange portion 33 and the steel column 10 of the telescopic bracket 30 Spring; a steel column and beam coupling structure suitable for seismic design, further comprising a. The method of claim 5,
A support bracket 60 fixed to the steel column 10 at a position spaced apart from the lower portion of the steel beam 20;
Further comprising; an elastic support member 70 disposed on the support bracket 60 and elastically supporting the lower part of the steel beam 20.
At least one of the plurality of first bolt hole sets and the plurality of second bolt hole sets corresponding to the bolt coupling is a long hole extending in the vertical direction. The method of claim 6,
A support bracket 60 fixed to the steel column 10 at a position spaced apart from the lower portion of the steel beam 20;
Further comprising; an elastic support member 70 disposed on the support bracket 60 and elastically supporting the lower part of the steel beam 20.
At least one of the plurality of first bolt hole sets and the plurality of second bolt hole sets corresponding to the bolt coupling is a long hole extending in the vertical direction.

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