KR20200145183A - Steel Column Structure for Structural Reinforcement and Seismic Improvement - Google Patents

Abstract

The present invention relates to a column member, which has earthquake-proof properties in case of an earthquake to prevent damage occurring by the earthquake and, more specifically, to a steel column structure for reinforcing a structure and improving earthquake-proof properties, which comprises: a stiffener provided in shape steel forming a column member; and a cover plate for covering the outside, thereby dispersing distortion stress or buckling stress formed on the column member in case of an earthquake to have the earthquake-proof properties. Thus, the steel column structure for reinforcing a structure and improving earthquake-proof properties can minimize damage caused by the earthquake.

Description

Steel Column Structure for Structural Reinforcement and Seismic Improvement}

The present invention relates to a column member for preventing damage that may be caused by an earthquake by providing seismic resistance when an earthquake occurs, and in detail, a cover plate for configuring a stiffener inside a section steel forming the column member and covering the outer wall The present invention relates to a steel column structure for reinforcing a structure for minimizing damage due to earthquakes and improving earthquake resistance by distributing torsional stress or buckling stress formed in the column member when an earthquake occurs to have earthquake resistance.

As the demand for high-rise buildings increases, a construction method based on seismic design of buildings is used as one of the methods to prevent collapse and minimize damage due to high-intensity earthquakes. Interest in this is growing significantly.

In particular, various technologies are being developed to secure the seismic resistance of pillars, which can be referred to as skeletons in architectural structures.

In the process of revising the KBC (Korea Building Code), which is the recent domestic building structure design standard, through a new proposal for the detail of the joint, the response correction factor was set at 8, respectively, in the intermediate and normal moment frames with the previous response correction factor of 6. An amendment proposal has been proposed in which a special moment frame, which differentiates into 4.5 and 3.5, is revised into a special moment frame, an intermediate moment frame, and a normal moment frame, and adds a kind of penalty to the intermediate and normal moment frames.

The above-mentioned normal moment frame expresses 2% of interlaminar deformability, and special moment frame expresses 4% of interlaminar deformability, and at this point, the performance corresponding to 80% of the preservation plastic moment is specified. .

In the case of using the column-beam connection structure composed of the special moment frame, the design strength is reduced in proportion to the connection part performance, so there is an advantage that economic design is possible compared to the normal moment frame.

On the other hand, there is a problem that brittle fracture occurs when an external force of more than a certain strength is applied to the joint part of a column and a beam made of high-strength steel, which is higher in strength compared to general steel with a yield strength of about 490 MPa, resulting in poor seismic performance.

Due to such problems, there is a need for a structure capable of improving seismic performance by preventing brittle fracture while using columns and beams made of high-strength steel in the column-beam connection structure.

In addition, in the case of a column member that is usually applied in a steel structure, it can be said that most cases are made of a section steel having a steel frame shape.

In addition, in general structural steel structures, there are many examples in which a square tube having a closed section is used as a column. There is a configuration that is connected to a column made of such a square tube using a beam such as H-beam.

In the case of adopting such a square tube as a column, a diaphragm is installed at the junction of the column and the beam to smoothly transfer the stress acting on the beam to the column, and the diaphragm serves to firmly connect the column and the beam. Is done.

However, in the case of such a steel structure, since the column must be cut to install the diaphragm at each position of the column to which the beam is joined, and the diaphragm and the beam must be welded, great inconvenience and economic inefficiency have been pointed out.

In addition, in the case of forming a pillar with a square tube, there is a problem in that it requires an installation space of the square tube column member more than necessary, thereby reducing the use efficiency of the limited area.

Domestic patent registration No. 10-0516332 (announced on September 23, 2005)

Accordingly, the present invention has been devised to solve the above problems, by providing a column with a structure having earthquake resistance to efficiently disperse torsional stress or buckling stress formed on the column of a building when an earthquake occurs, and to have earthquake resistance, The effect of minimizing the damage caused by can be expected.

The present invention as a means for solving the above problems,

Column member;

A stiffener that crosses the inner side of the column member and is fixed in plurality;

A beam member connected in a horizontal direction from the column member;

A set of reinforcing plates each fixed up and down within a connection area range of the column member to which the beam member is connected;

A beam-connection plate fitted between the set of reinforcing plates in a vertical direction and fixed to be connected to the beam member;

A cover plate covering a region of a stiffener fixed to a plurality of the pillar members;

It provides a steel column structure for improving the structural reinforcement and earthquake resistance comprising a.

According to the present invention, when an earthquake occurs, the torsional stress or buckling stress formed on the pillar of the building is efficiently dispersed and has seismic resistance, so that the effect of minimizing the damage caused by the earthquake can be expected.

1 is a perspective view showing a column member of a building structure adopted in the present invention
2 to 3 are perspective views showing the cover plate separated from the drawing of FIG. 1
FIG. 4 is a view showing that the beam members are connected in a horizontal line in the area (A) of the connection range for connecting the beam members of the column members shown in the drawing of FIG. 1
5 is a schematic view showing an example of an inclined stiffener that faces each of the horizontal stiffeners vertically in the present invention

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in the present specification are exemplified only for the purpose of describing the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention are Since various changes can be added and may have various forms, all changes, equivalents, or substitutes included in the spirit and scope of the present invention are included, and terms or words used in the specification and claims are conventional or dictionary. The meaning and concept consistent with the technical idea of the present invention are not limited to the meaning, and based on the fact that the inventor can appropriately define the concept of terms in order to describe his own invention in the best way. Should be interpreted as. Accordingly, the embodiments described in the specification of the present invention and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, but are substituted at the time of filing of the present invention. It will be understood that various equivalents and variations that may be made are possible or exist.

In addition, unless otherwise defined in the specification of the present invention, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Have. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this specification. Does not.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in the accompanying drawings, the present invention consists of a column member 100 adopted and installed in a building structure and a beam 200 connected in the lateral direction of the column member 100 to be constructed.

The column member 100 and the beam 200 are each made of H-beam.

As shown in the previous drawings of Figs. 1 to 5, the column member 100 made of H-beam is named both sides for convenience of explanation of the present invention, and is named both side irregularities 102. For convenience, an uneven material formed on the left side is divided into a left uneven material (102a), and an uneven material formed on the right side is divided into a right uneven material (102b) based on the drawing, and the centralized material 101 is to divide both sides 102 at the center. It will be called as.

Meanwhile, a plurality of horizontal stiffeners 110 are fixed while horizontally crossing the inner side of the column member 100.

Since the column member 100 is made of H-beam, a space is formed between the two side members 102, and the horizontal stiffener 110 reaches and is fixed to the central member 101 while crossing the space.

The horizontal stiffener 110 is fixed at appropriate intervals along the column member 100.

Meanwhile, the inclined stiffeners 120 may be fixed up and down the horizontal stiffeners 110, respectively.

That is, the inclined stiffener 120 is installed to face each other vertically and horizontally with respect to the horizontal stiffener 110, and as shown in FIG. 5, the inclined stiffeners 120 are inclined in a form that extends around the center of the horizontal stiffener 110, respectively. The inclined stiffeners 120 that are fixed and open respectively may be formed to face up and down with respect to the horizontal stiffener 110.

The horizontal stiffener 110 and the inclined stiffener 120 and the horizontal stiffener 110 and both side irregularities (102; 102a, 102b), the inclined stitcher 120 end side and the both side irregularities (102; 102a, 102b) The means for fixing the liver is fixed by using known means or methods such as welding or other rivet joints, bolts and nuts.

Meanwhile, the beam member 200 is connected in the horizontal direction from the column member 100.

The connection range of the column member 100 to which the beam member 200 is connected is limited to a region in which the beam-connection plate 140 is fixed.

As shown in the drawing, the area of the connection range in which the beam member 200 and the column member 100 are connected is indicated by reference numeral A.

The beam-connection plate 140 is fixedly connected in the vertical direction from the inside of the column member 100, and as shown in FIG. 3, the reinforcing plate 130 is respectively disposed on the upper and lower sides of the beam-connection plate 140 It is sandwiched between the two side pieces (102a, 102b) of (100) and fixed.

The reinforcing plate 130 also plays the same role as the horizontal stiffener 110 described above, but for convenience, the horizontal stiffener 110 and the horizontal stiffener 110 are a member fixed to the beam-connection plate 140 to be connected to the beam member 200. It is necessary to understand that it is named to be distinguished.

The beam-connecting plate 140 is fixed to the rear end to the central uneven material 101 of both sides (102; 102a, 102b) and the central uneven material 101 of the column member 100, and the upper and lower portions are respectively The reinforcing plate 130 has a body portion 141 that is fixed and partitioned with the bottom and top portions, and further extends toward the front end of the body portion 141, and is fixedly coupled with the beam central part 210 of the beam member 200 It consists of a coupling stepped portion 142.

Here, the total length of the coupling stepped portion 142 is formed to be relatively short compared to the total length of the body portion 141 but is configured to protrude from the side ends of both sides of the column member 100.

On the other hand, in the column member, the cover plate 150 is fixed to cover a range of other areas except for the area A of the connection range in which the beam-connection plate is fixed.

The cover plate 150 is fixed to the inner side between the two side members 102 (102a, 102b) of the column member 100 and may be fixed by welding.

When the joint construction between the column member 100 and the beam member 200 made of H-shaped steel is made using the present invention having the above configuration, the front and rear surfaces of both side members 102 constituting the column member 100 are A plurality of horizontal stiffeners 110 spaced apart from each other are fixed to each other, and the remaining areas except for the area A of the connection range for connecting the beam members 200 extending from the column member 100 to the horizontal line are flat plate The shape of the cover plate 150 is fixed.

Such an area between the cover plate 150 and the cover plate 150, that is, an area not covered by the cover plate 150 corresponds to an area to which the beam member 200 is connected.

The reinforcing plate 103 fixed to the upper and lower side portions 102 of the column member 100 as described above (102; 102a, 102b) as the region (A) of the connection range to which the beam member 200 is connected as described above. The beam-centered portion of the beam member 200 protruding toward the end side of the beam-connection plate 140 that is inserted and fixed in the vertical direction through the space, and the beam member 200 connected to the horizontal line from the column member 100 ( 210) can be fixedly connected to complete the installation of the beam member 200.

In this way, after the installation between the column member 100 and the beam member 200, by adopting a conventional construction method and construction structure, the installation of slabs (not shown in the drawing) between the beam members 200 can be made.

When the building structure having the pillar member 100 installed and constructed as described above is included in the earthquake occurrence area, bending stress and buckling stress, etc., are provided to the pillar member 100 from seismic waves transmitted to the structure due to the earthquake occurrence. In this case, it is possible to secure seismic resistance to withstand each stress applied to the column member 100 by support by structures such as the horizontal stiffener 100 and the inclined stiffener 120 and the cover plate 150 in the present invention. Therefore, it is possible to secure the safety of buildings and effectively prevent and block property and personal damage caused by earthquakes.

As described above, although the present invention has been described by a limited embodiment and drawings, the present invention is not limited to the above embodiment, as well as from the above description by a person having ordinary technical knowledge in the field to which the present invention belongs. It goes without saying that various modifications and variations may be possible.

Therefore, the technical idea in the present invention should be grasped by the claims described below, but it will be apparent that all of the equivalent or equivalent modifications thereof belong to the scope of the technical idea of the present invention.

100; Pillar member 101; Central ubiquity
102; Bilateral localization 102a; Left-handed
102b; Right ubiquity 110; Horizontal stiffener
120; Oblique stiffener 130; Reinforcement plate
140; Beam-connecting plate 141; Body
142; Coupling stepped portion 150; Cover plate
200; Beam member 210; Bojungang Localization

Claims (6)

Column member;
A horizontal stiffener horizontally crossing the inner side of the column member and fixed in plurality;
A beam member connected in a horizontal direction from the column member;
A set of reinforcing plates each fixed up and down within a connection area range of the column member to which the beam member is connected;
A beam-connection plate fitted between the set of reinforcing plates in a vertical direction and fixed to be connected to the beam member;
A cover plate that covers and is fixed to other area ranges except for the area range to which the beam-connection plate is fixed in the column member;
Steel column structure for improving the structural reinforcement and earthquake resistance comprising a.
The method of claim 1,
Steel column structure for structural reinforcement and seismic resistance improvement comprising that of the column member and the beam H-beam.
The method of claim 1,
The beam-connecting plate includes a body portion having a rear end side fixed to the central portion among both side portions and a central portion of the column member, and the upper and lower portions respectively fixed to and partitioned from the bottom and upper portions of the reinforcing plate;
A coupling stepped portion further extended toward the front end of the body portion and fixedly coupled to the beam central portion of the beam member;
Steel column structure for improving the structural reinforcement and earthquake resistance comprising a.
The method of claim 3,
The entire length of the coupling stepped portion is formed relatively short compared to the total length of the body portion, but the steel column structure for structural reinforcement and earthquake resistance improvement comprising protruding from both sides of the column member.
The method of claim 1,
Steel column structure for structural reinforcement and seismic resistance improvement, including fixing the inclined stiffeners up and down the horizontal stiffener.
The method of claim 5,
The inclined stiffener is a steel column structure for structural reinforcement and seismic resistance improvement, comprising mounting and fixing each of the horizontal stiffeners in a vertical direction and left and right.

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