KR102571669B1 - A steel box member with a web of thin steel plate using an anti-buckling plate - Google Patents

Abstract

The present invention relates to a steel box member having a box-shaped cross-sectional structure and minimizing the thickness of the steel plate members constituting the web to be used as a column member or beam member in a pure steel structure building by configuring a web with thin steel plates, wherein the steel box The member consists of a pair of flanges spaced apart from each other, and a pair of webs spaced apart from each other are attached to each end of the flange to form a closed section of a steel box structure, the web being a steel plate having a thickness thinner than that of the flange. It is characterized in that both side ends of the anti-buckling plate having a corrugated cross section are integrally welded to each inner surface of the pair of webs.

Description

Thin steel web-type steel box member using an anti-buckling plate {A STEEL BOX MEMBER WITH A WEB OF THIN STEEL PLATE USING AN ANTI-BUCKLING PLATE}

The present invention relates to a steel structural member used as a column member or a beam member in a pure steel structure building, and more specifically, to a web of thin steel plates by minimizing the thickness of the steel plate members constituting the same while having a box-shaped cross-sectional structure. It relates to the structure of a steel box member with

In buildings with pure steel structures, it is common to use H-beams as column members and beam members.

The pair of flanges of the H-beam are greatly spaced from the center, which greatly increases the moment of inertia of area and maximizes the efficiency of the section. For example, when the standard of a member is influenced by a bending load, a pair of flanges spaced far from the center minimize the thickness of the web by bearing the stress caused by the bending load, thereby minimizing the cross section of the steel material.

However, the H-beam has a high bending stiffness in the vertical direction of the strong axis in terms of cross-sectional structure, but has a low bending stiffness in the vertical direction of the weak axis. Due to this structural shape, it acts heavily against loads acting in the direction of the weak axis, and is very vulnerable to torsion due to the difference in stiffness between the strong axis and the weak axis.

On the other hand, since earthquakes and typhoons have frequently occurred in recent years due to abnormal weather, higher performance of structural members such as pillar members and beam members is required to cope with them.

However, it is common to satisfy the demand for improving the performance of structural members by increasing standards, such as increasing the thickness of a cross section. However, when the standard of the member is increased in this way, there is a problem in that the usable space of the building is narrowed as well as the amount of steel used is increased.

There is a CFT structure that uses steel as a structural member such as a column member and does not generate a weak axis unlike H-shaped steel.

In the CFT structure, a square pipe is made of a steel plate, concrete is poured therein, and the square pipe restrains the concrete therein, thereby preventing brittle fracture of the concrete and increasing yield strength.

However, the above performance of the CFT structure presupposes the high tightness of the concrete poured inside the square tube. However, since it is not easy to fill the concrete tightly, the structural performance cannot be fully trusted in practice, and the In that it is difficult to join and has a large weight due to concrete, it is not easy to apply to buildings that require rapid construction, such as warehouses.

In addition, in the case of using the CFT structure as a beam member, there is a problem in that the bending stiffness must be reinforced by significantly increasing the thickness of the square tube or placing reinforcing bars therein.

In addition, Patent Registration No. 10-2027704, as shown in Figure 1, discloses a steel column having a honeycomb-shaped opening, but it can be applied to an SRC column by embedding it in concrete, but the opening Due to the occurrence of cross-sectional defects, the resistance to axial force is weakened, so in order to use it alone as a column member or beam member in a pure steel structure, the cross-sectional size must be greatly increased, so it is not practical.

KR 10-2027704 B1

?薦? has a general-purpose structure that can be used both as a column member or a beam member in a building with a pure steel structure, and minimizes the thickness of the steel plate forming it. It is composed of a steel plate structure to reduce the amount of steel used and improve manufacturability to secure economic feasibility, and to provide a steel box member capable of securing structural stability by satisfying the plate width-to-thickness ratio for the thin plate portion of the web. .

According to the most preferred embodiment of the present invention for solving the above problems, a pair of flanges spaced apart from each other and a pair of webs spaced apart from each other are attached to each end of the flange to form a closed type of steel box structure. An anti-buckling plate, characterized in that the web is composed of a steel plate having a thickness thinner than the flange, and both side ends of the anti-buckling plate having a corrugated cross section are integrally welded to the inner surface of each of the pair of webs. A web-shaped steel box member of a thin steel plate is provided.

At this time, the corrugated cross section of the anti-buckling plate is formed in a direction perpendicular to the plane of the flange.

In addition, the corrugated cross-section may be of a wavy shape, or may be of a vertical or inclined concavo-convex shape.

The steel box member of the present invention can be used for both column members and beam members and can replace ready-made H-beams, and enables the construction of economical buildings by exerting the following effects.

First, the steel box member of the present invention locates the web at the end of the flange to increase the cross-sectional efficiency in the weak axis direction, thereby reducing the amount of steel used compared to the web located in the center of the H-beam because the web can be made of a thin steel plate. let it

Second, the steel box member of the present invention is provided with an anti-buckling plate having a corrugated section in the weak axis direction to prevent deformation such as local buckling of the web, thereby increasing rigidity, so that compared to H-beams, it is more resistant to torsional load and lateral load in the weak axis direction. The higher the strength, the better the seismic performance.

Third, the steel box member of the present invention enables the optimal structural design for the building to be built because the standard can be freely set, unlike the H-beam for which the standard is set.

1 is a perspective view of a steel column according to the prior art.
2 is a perspective view of a steel box member according to an embodiment of the present invention.
3 is a cutaway perspective view of the steel box member.
4 is a cross-sectional view of portion AA of FIG. 2 .
5 is a deformation view of a web for explaining the function of an anti-buckling plate according to the present invention.
6 is an explanatory view of each embodiment related to the cross section of the corrugation of the anti-buckling plate.
7 is a use state diagram of an example in which the steel box member of the present invention is used as a pillar member.
8 is a use state diagram of an example in which the steel box member of the present invention is used as a beam member.

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, when the technical idea of the present invention is blurred or unclear due to the detailed description of the known configuration, the description of the configuration of the above known will be omitted.

Figure 2 shows the overall appearance of the steel box member according to an embodiment of the present invention, Figure 3 shows a state in which a part is cut so that the inside can be checked, Figure 4 is a portion A-A of Figure 2 cross section is shown.

The present invention maximizes the efficiency of the cross section in each vertical direction to reduce the amount of steel used, while maintaining the bending stiffness in the strong axis direction as in the flange (1) of the H-beam, and reinforcing the weak axis to obtain torsional stiffness and shear It is a technical feature to improve rigidity so that it can be used as a beam member (B) as well as a column member (C) in a pure steel structure.

To this end, in the steel box member of the present invention, a pair of thick flanges 1 are disposed so as to be spaced apart from each other, between the pair of flanges 1, more specifically, at both ends of the flanges 1. Another pair of webs 2 are attached to it to have a closed cross-section structure of L-shaped cross section or ㅁ-shaped cross section.

However, here, for convenience of description, an end portion of the flange 1 protrudes slightly from the outer surface of the web 2.

In addition, the steel box member of the present invention seeks to reduce the amount of steel used as described above by configuring the web 2 with a steel plate having a thinner thickness than the flange 1.

As a result, the yield strength in the weak axis direction in which the web 2 bears the stress is lowered compared to the strong axis direction in which the flange 1 bears the stress, and thereby there is room for deformation such as local buckling of the web 2 to occur. .

Therefore, in the present invention, both side ends of the anti-buckling plate 3 are integrally welded to each inner surface of the pair of webs 2 to reinforce rigidity in the weak axis direction.

For example, when a horizontal load is applied in the axial direction of the web 2 when used as a pillar member (C), or when a vertical load is applied in the axial direction of the web 2 when used as a beam member (B), in FIG. As shown, local buckling deformation occurs in the web 2 of the thin steel plate. In addition, sinusoidal deformation, that is, transverse buckling deformation, also occurs due to the bending load.

The anti-buckling plate 3 prevents deformation of the web 2 by holding the cross section of the web 2 in the deformation direction.

However, in order for the anti-buckling plate 3 to have the above function of preventing deformation of the web 2, the anti-buckling plate 3 must have a sufficient thickness or be installed at very close intervals, but this is another steel material It acts as a factor that causes an increase in usage.

Therefore, in the present invention, the thickness of the anti-buckling plate 3 is minimized by having a corrugated cross section, so that the amount of steel used by the anti-buckling plate 3 is not increased. The corrugated cross section increases the shear strength of the anti-buckling plate 3 itself so that its thickness can be reduced.

As shown in FIG. 3, the corrugated section is formed in a direction perpendicular to the surface of the flange 1, so that the gap between the webs 2 on both sides is firmly maintained. Therefore, the gap between the anti-buckling plates 3 can be widened relatively large compared to those made of flat plates, thereby reducing the number of welding operations and improving the manufacturability of the steel box member.

The corrugated cross section of the anti-buckling plate 3 may have various shapes.

For example, it may have a wavy cross-sectional shape, or may have a concave-convex cross-sectional shape as shown in Figs. It could be. 3 and 4 show an example in which the anti-buckling plate 3 having a corrugated cross section of an inclined concavo-convex shape is used, and in FIG. it is foreshadowed

The anti-buckling plate 3 having such a corrugated cross-section can be easily attached to the web 2 of the thin steel plate through spot welding or high-frequency welding.

7 and 8 show an example of using the steel box member of the present invention described so far as a pillar member (C) and a beam member (B).

In the case of using the steel box member of the present invention as a pillar member (C), as shown in Figure 7, the cross section of the steel box member so that the junction with the beam member (B) is made in the thick flange (1) placed

In this way, since the end of the beam member (B) is joined to the thick flange (1) of the steel box member used as the pillar member (C), unlike the CFT structure, even if a separate diaphragm is not installed, the beam by welding It is possible to have a strong joint structure of columns. Of course, although FIG. 7 illustrates the steel frame member of the H-beam as the beam member (B), a steel box member may be used as well as the column member (C).

When using the steel box member of the present invention as a beam member (B), as shown in Figure 8, the cross section of the steel box member so that a pair of flanges (1) are located up and down to bear the bending stress placed

In this way, the steel box member used as the beam member (B) can have a beam-column steel joint structure by welding the thick flange (1) to the column member (C), and at this time, the joined column member (C) Although a steel frame member of H-beam is exemplified, it is also possible to use a steel box member as described above.

In the above, the present invention has been described in detail with reference to specific embodiments, but since the above embodiments are merely examples to make the present invention easier to understand, those skilled in the art are within the scope of the technical idea of the present invention. It is obvious that it will be possible to carry out various modifications within. Therefore, it will be said that such modifications fall within the scope of the present invention as described in the claims.

One; flange 2; web
3; anti-buckling plate B; Beam member
C; column member

Claims (4)

As a structural member of steel that can be used in parallel as a column member (C) and a beam member (B) of a pure steel structure,
A pair of flanges 1 spaced apart from each other and a pair of webs 2 spaced apart from each other are attached to both side ends of the flanges 1 to form a closed cross section of a steel box structure, the web ( 2) is composed of a steel plate that is thinner than the flange 1,
Both side ends of the anti-buckling plate 3 having a corrugated cross section are integrally welded to each inner surface of the pair of webs 2,
The thin steel plate web-type steel box member using the anti-buckling plate, characterized in that the corrugated cross section of the anti-buckling plate (3) is formed in a direction perpendicular to the surface of the flange (1).
delete According to claim 1,
The corrugated section is a thin steel plate web-type steel box member using an anti-buckling plate, characterized in that the waveform.
According to claim 1,
The corrugated section is a thin steel plate web-type steel box member using an anti-buckling plate, characterized in that the vertical or inclined concavo-convex shape.

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