KR20210051263A - Connecting sturcture between column and beam - Google Patents

Abstract

The present invention provides a bonding structure of a column and a beam member, which comprises: a column; a reinforcement plate welded and bonded to the column and having an insert hole, where steps are formed on an opposing surface of the column, inserted and formed; a beam member connected to the reinforcement plate and having a bonding plate formed in an end part; and an insert fastening device fastened with the bonding plate to connect the reinforcement plate and the beam member while inserted and fixated to the insert hole.

Description

Connection structure between column and beam member{CONNECTING STURCTURE BETWEEN COLUMN AND BEAM}

The present invention relates to a joint structure of a column and a beam member.

It should be noted that the contents described in this section merely provide background information on the present invention and do not constitute prior art.

CFT column refers to a concrete-filled steel pipe filled with concrete in a circular or square-shaped steel pipe.

CFT columns are exhibiting excellent performance in various fields such as fire resistance and construction as well as structural aspects such as stiffness, strength, and deformation as steel pipes restrain concrete.

The outer diaphragm, the inner diaphragm and the through-type diaphragm are used in the connection between the steel pipe column and the steel frame beam, which is widely used in buildings, but it is made of welding, which requires a lot of manufacturing cost and work time, and skillful work skills are required. Do.

Accordingly, there is a need for a joining technology of a column and a beam member that allows a beginner to easily work while maintaining a high level of quality.

In addition, in the connection using bolts, there is a safety problem due to the phenomenon that the nut is loosened due to repeated tensile loads, a technology for joining a column and a beam member is required to solve this problem.

KR 10-1671894 B1

An aspect of the present invention is to provide a joint structure between a column and a beam member, which can minimize welding and improve the quality of a column and a beam member, and improve workability.

As an aspect for achieving the above object, the present invention is a pillar; A reinforcing plate which is welded to the pillar and in which an insert hole having a step is formed in the opposite surface of the pillar; A beam member connected to the reinforcing plate and having a joint plate formed at an end thereof; And an insert fastening hole for connecting the reinforcing plate and the beam member by being fastened to the bonding plate while being inserted and fixed in the insert hole.

Preferably, the reinforcing plate is composed of a plurality of segmented reinforcing modules, and welding lines of the adjacent reinforcing modules may be welded together with the pillars.

Preferably, the reinforcing plate is composed of a plurality of segmented reinforcing modules, and welding lines of adjacent reinforcing modules may be disposed on an installation portion of the beam member.

Preferably, in the reinforcing plate, four reinforcing modules having a'b'-shaped cross section are connected in a circumferential direction to form a closed cross-section in a rectangular shape, and the welding line of the adjacent two reinforcing modules is in the height direction of the column. It can be formed in a corresponding direction.

Preferably, the reinforcing plate comprises: a reinforcing plate body installed between the pillar and the beam member, welded to the pillar, and fixed via the beam member and the insert fastener; And an insert hole in which the reinforcing plate body is internally formed on an opposite surface in contact with the pillar, and in which a step difference is formed while varying the diameter of the hole.

Preferably, the insert hole includes: a first insert hole in which the insert nut of the insert fastening hole is fixed by a force fitting method; And a second insert hole having a relatively small diameter compared to the first insert hole and through which an insert bolt of the insert fastening hole is installed.

Preferably, the beam member, a section steel member extending in the transverse direction; And a joint plate installed at an end of the section steel member and fixed to the reinforcing plate through a plurality of insert fastening holes.

Preferably, the insert fastener may be disposed outside the pillar.

Preferably, the insert fastening hole includes an insert nut that is fixed while being inserted into the insert hole in a force-fitting manner; And an insert bolt connecting the reinforcing plate and the bonding plate while being fastened to the insert nut.

Preferably, the insert fastening hole may further include a washer member having a relatively high frictional force on the first surface in contact with the bonding plate compared to the second surface in the opposite direction.

Preferably, the insert fastener may further include a reinforcing nut that is fastened to a rear end of the insert bolt to reinforce a head portion of the insert bolt.

Preferably, the insert bolt, a bolt body that is fastened to the insert nut through the insert hole; And a pintail that is installed at the rear end of the bolt body and is broken by the bolt body when a fastening force of more than a limit set value is applied.

Preferably, the pillar is provided as a CFT pillar having a rectangular cross section or a circular cross section, and the reinforcing plate is installed to surround the pillars of a plurality of reinforcing modules, and the welding lines of the adjacent reinforcing modules are together with the pillars. Can be welded together.

According to an embodiment of the present invention, there is an effect of minimizing the welding joint to improve the quality of the joint and the beam member, and improve the workability.

1 is a perspective view of an exploded state of a joint structure of a column and a beam member according to an embodiment of the present invention.
2 is a perspective view of a bonding state of a joint structure of a column and a beam member according to an embodiment of the present invention.
3 is a plan view of a joint structure of a column and a beam member according to an embodiment of the present invention.
4 is a view showing a problem that occurs when a tensile load is applied when a welding line is not disposed at an installation portion of a beam member.
5 is a cross-sectional view of a joint structure between a column and a beam member according to an embodiment of the present invention.
6 is a partially enlarged view of FIG. 5.
7 is a cross-sectional view of a joint structure between a column and a beam member according to another embodiment of the present invention.
8 is a plan view of a joint structure between a column and a beam member according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, embodiments of the present invention are provided in order to more completely explain the present invention to those with average knowledge in the art. In the drawings, the shapes and sizes of elements may be exaggerated for clearer explanation.

Hereinafter, a joint structure between the pillar 100 and the beam member 300 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 8.

The joint structure of the pillar 100 and the beam member 300 according to an embodiment of the present invention may include a pillar 100, a reinforcing plate 200, a beam member 300, and an insert fastening hole 400. have.

1 to 3, the joint structure of the pillar 100 and the beam member 300 is welded to the pillar 100 and the pillar 100, and there is a step difference on the opposite surface of the pillar 100. A reinforcing plate 200 in which the formed insert hole 230 is internally formed, a beam member 300 connected to the reinforcing plate 200 and having a bonding plate 330 formed at an end thereof, and the insert hole 230 It may include an insert fastening hole 400 connected to the reinforcing plate 200 and the beam member 300 by being fastened to the bonding plate 330 in the inserted and fixed state.

Referring to Figure 3, the column 100 is filled with concrete (C) inside a tube made of a metal material such as steel.

For example, the pillar 100 may be made of a steel pipe having a hollow, and the steel pipe and the poured concrete (C) may be integrated while the concrete (C) is filled therein.

As another example, the pillar 100 is made of a steel pipe having a hollow and can be configured so as not to be filled with concrete (C) therein, of course.

Referring to FIG. 3, the pillar 100 may be formed of a steel pipe having a rectangular cross section.

Referring to FIG. 8, the pillar 100 may be formed of a steel pipe having a circular cross section.

However, the cross-sectional shape of the pillar 100 is not limited only to a square, and may be various cross-sectional shapes.

The pillar 100 and the reinforcing plate 200 may be welded to each other while the reinforcing plate 200 is padded on the outside of the pillar 100.

The pillar 100 is transported to the site, and the reinforcing plate 200 may be installed on the outside of the pillar 100, and accordingly, there is no part protruding to the outside of the pillar 100, so that a large amount of the pillar 100 There is an effect that can be easily transported to the site.

1 to 3, the reinforcing plate 200 may be installed between the pillar 100 and the beam member 300.

The reinforcing plate 200 is welded to the pillar 100, and the beam member 300 and the reinforcing plate 200 may be detachably fixed through the insert fastening hole 400.

The reinforcing plate 200 may be welded to the pillar 100 to prevent the reinforcing plate 200 from slipping on the pillar 100.

A plurality of beam members 300 are joined to the column 100, the reinforcing plate 200 is segmented into a number corresponding to the number of the plurality of beam members 300, and the welding line of the adjacent reinforcing module 200M is a beam member It may be disposed at a portion corresponding to the bonding plate 330 of 300.

An insert hole 230 is formed in the reinforcing plate 200, and an insert fastening hole 400 may be inserted and fixed in the insert hole 230.

In the reinforcing plate 200, an insert hole 230 with a step formed on the opposite surface of the column 100 may be internally formed, and an insert nut 410 and an insert bolt 430 may be disposed in the insert hole 230. I can.

The insert hole 230 of the reinforcing plate 200 may have a step difference while varying the diameter of the hole.

The insert nut 410 may be installed in an area having a large diameter of the insert hole 230, and the insert bolt 430 may pass through the area having a small diameter.

The insert hole 230 may be slightly smaller than the insert nut 410 so that the insert nut 410 is pressed and inserted into the hole so that the insert nut 410 does not loosen.

1 to 3, the beam member 300 may be fixed to the reinforcing plate 200 welded to the pillar 100 through an insert fastening hole 400.

The lengthwise end of the beam member 300 may be bonded to the reinforcing plate 200, and the bonding plate 330 of the beam member 300 may be fixed to the reinforcing plate 200 via the insert fastening hole 400. .

The beam member 300 may be composed of a steel beam such as H-beam. A bonding plate 330 connected to the reinforcing plate 200 may be formed at an end of the beam member 300.

The bonding plate 330 may be formed of a plate-shaped member that is bonded to the end of the beam member 300.

Referring to FIGS. 2 and 5, the bonding plate 330 is formed of a rectangular plate, and may be installed in a longitudinal direction in contact with the reinforcing plate 200.

Since the bonding plate 330 secures a wide contact area with the pillar 100, it is possible to stably resist tensile and compressive forces transmitted from the beam member 300.

Referring to FIG. 7, the beam members 300 installed on the reinforcing plate 200 may have different dances (heights) from each other.

In this case, the height of the reinforcing plate 200 welded to the pillar 100 may vary in response to the dance of the beam member 300.

When installing the two beam members 300 having different dances, it may be installed so that the heights of the upper ends of the two beam members 300 are matched.

1 to 3, the insert fastening hole 400 may connect the reinforcing plate 200 and the beam member 300, and specifically, the bonding plate 330 between the reinforcing plate 200 and the beam member 300. ) Can be connected.

The insert fastening hole 400 may be coupled to the bonding plate 330 while being inserted and fixed in the insert hole 230 to connect the reinforcing plate 200 and the beam member 300.

The insert fastening hole 400 may be formed to protrude toward the beam member 300 through the reinforcing plate 200 while one side is fixed to the insert hole 230 of the reinforcing plate 200.

The insert fastening hole 400 is a joint plate 330 and a reinforcing plate 200 in a state in which the joint plate 330 of the beam member 300 is placed in contact with the reinforcing plate 200 welded to the column 100. Can be concluded.

Referring to FIG. 3, the insert fastening hole 400 may be disposed outside the pillar 100 in a state in which the reinforcing plate 200 bonded to the pillar 100 and the beam member 300 are connected.

The pillar 100 and the reinforcing plate 200 applied to the joint structure of the pillar 100 and the beam member 300 may be made of a metal material such as steel, and the pillar 100 and the reinforcing plate 200 are Welding can be done.

Of course, all of the pillar 100, the reinforcing plate 200, the beam member 300, and the insert fastener 400 may be made of a metal material such as steel.

2 and 3, the reinforcing plate 200 is composed of a plurality of segmented reinforcing modules 200M, and the welding lines of the adjacent reinforcing modules 200M are welded together with the pillar 100. I can.

The reinforcing plate 200 is composed of a plurality of reinforcing modules 200M welded to the pillar 100, and welding lines of the adjacent reinforcing modules 200M may be welded together with the pillar 100.

That is, two adjacent reinforcing modules 200M and the pillar 100 may be welded together.

Referring to FIG. 3, both ends of the reinforcing module 200M are processed at an angle, and two reinforcing modules 200M can secure a welding space for forming a welding line.

An equilateral trapezoidal-shaped welding space may be secured between two adjacent reinforcing modules 200M, and a welding line having an equilateral trapezoidal shape may be formed while welding is performed along the welding space.

When forming an equilateral trapezoidal welding line, the upper surface of the isosceles trapezoid with a narrow width is welded to the column 100, and the two inclined sides of the equilateral trapezoid can be welded to the two reinforcing modules (200M). have

When forming an equilateral trapezoidal welding line, the lower surface of the equilateral trapezoid having a wide width may be disposed in contact with the bonding plate 330 of the beam member 300.

Of course, between the welding line and the bonding plate 330 is not joined by welding, only the bonding plate 330 and the welding line are arranged in contact, and the reinforcing plate 200 and the bonding plate 330 are insert fastening holes ( 400).

The reinforcing plate 200 is composed of a plurality of segmented reinforcing modules 200M, and a plurality of reinforcing modules 200M may be installed to surround the pillar 100.

As the welding line of the reinforcing module 200M is welded together with the pillar 100, there is an effect that the resistance against the shear load transmitted from the beam member 300 to the pillar 100 can be improved.

2 and 3, the reinforcing plate 200 is composed of a plurality of segmented reinforcing modules 200M, and the welding line of the adjacent reinforcing module 200M is an installation part of the beam member 300 Can be placed on

The reinforcing plate 200 is composed of a plurality of reinforcing modules 200M welded to the pillar 100, and the welding line of the adjacent reinforcing module 200M is at the portion where the joint plate 330 of the beam member 300 is formed. Can be placed.

In a state disposed in contact with the beam member 300 and the reinforcing plate 200, a welding line for joining the adjacent two reinforcing modules 200M may be disposed in contact with the bonding plate 330 of the beam member 300.

The welding line of the reinforcing module (200M) is welded together with the pillar (100), and by being disposed at the installation portion of the beam member (300), the reinforcing plate (200) and the pillar (100) are transmitted from the beam member (300). There is an effect that resistance against tensile load can be improved while resisting together against tensile load.

Referring to FIG. 4, when the welding line is not disposed at the installation portion of the beam member 300, when a tensile load acts on the beam member 300, the gap between the pillar 100 and the reinforcing plate 200 is widened. There is a problem that the resistance to tensile load is insufficient.

1 to 3, in the reinforcing plate 200, four reinforcing modules 200M having a'b'-shaped cross-section are connected in the circumferential direction to form a closed cross-section in a rectangular shape, and two adjacent The welding line of the reinforcement module 200M may be formed in a direction corresponding to the height direction of the pillar 100.

The reinforcing module 200M may be bent with a press to form a'b'-shaped cross-section, and the plate-shaped bonding plate 330 may be easily bonded to one side of the'b'-shaped cross-section.

3, the reinforcing plate 200 is installed between the pillar 100 and the beam member 300, welded to the pillar 100, and fastened with the beam member 300 and the insert The reinforcing plate body 210 fixed through the sphere 400 as a medium, and the insert hole 230 in which the reinforcing plate body 210 is internally formed on an opposite surface in contact with the pillar 100 and has a step difference while varying the diameter of the hole. ) Can be provided.

5 and 6, the insert hole 230 includes a first insert hole 231 in which the insert nut 410 of the insert fastening hole 400 is fixed by a force fitting method, and the first A second insert hole 232 having a relatively smaller diameter than the insert hole 231 and through which the insert bolt 430 is installed may be provided.

The insert hole 230 of the reinforcing plate 200 may be configured in a form in which the first insert hole 231 and the second insert hole 232 are connected to each other while having different diameters and forming a step difference.

The first insert hole 231 may have a relatively larger diameter than the second insert hole 232.

The insert nut 410 may be fixed to the first insert hole 231 by a force fitting method, and the insert bolt 430 may pass through and be installed through the second insert hole 232.

The first insert hole 231 may be slightly smaller than the insert nut 410 so that the insert nut 410 is pressed and inserted into the hole so that the insert nut 410 is not loosened.

The second insert hole 232 may have a fine tolerance between the insert bolt 430 and the second insert hole 232 so that one side of the insert bolt 430 can be inserted.

For example, the diameter of the insertion portion of the insert bolt 430 may be formed to be 2 to 3 mm smaller than the diameter of the second insert hole 232.

1 and 2, the beam member 300 is installed at the end of the section steel member 310 extending in the transverse direction and the section steel member 310, and a plurality of the insert fastening holes 400 ) May be provided with a bonding plate 330 fixed to the reinforcing plate 200 as a medium.

The section steel member 310 may include an H section steel having an upper flange 311, a lower flange 315, and a web member 313. In this case, the bonding plate 330 may be bonded to ends of the lower flange 315, the web member 313, and the upper flange 311.

The bonding plate 330 may be welded to the end of the section steel member 310.

A plurality of bolt holes 331 are formed in the bonding plate 330, and a plurality of insert fastening holes 400 may be installed through the bolt holes 331 of the bonding plate 330.

Insert fastening holes 400 may be installed at the top and bottom of the upper flange 311, respectively, and insert fastening holes 400 may be installed at the top and bottom of the lower flange 315, respectively.

Insert fastening holes 400 may be installed on the left and right sides of the web member 313, respectively.

1 to 3, the insert fastening hole 400 may be disposed outside the pillar 100.

Since the insert fastener 400 is disposed outside the pillar 100, there is no need for the insert fastener 400 to penetrate the pillar 100, so there is no need to form a hole in the pillar 100, and work in the field. The performance is improved, and there is an effect of preventing a decrease in structural rigidity of the pillar 100 due to the penetration of the hole.

5 and 6, the insert fastening hole 400 is an insert nut 410 fixed while being inserted into the insert hole 230 in a force-fitting manner, and fastened with the insert nut 410 While the reinforcing plate 200 may be provided with an insert bolt 430 connecting the bonding plate 330.

The insert nut 410 may be disposed outside the pillar 100 while being installed on the reinforcing plate 200.

The insert nut 410 may be fixed to the first insert hole 231 by a force fitting method, and the insert bolt 430 may penetrate through the second insert hole 232 and be fastened to the insert nut 410.

The first insert hole 231 is slightly smaller than the insert nut 410 so that the insert nut 410 is pressed and inserted into the hole. You can prevent loosening from occurring.

The insert nut 410 and the first insert hole 231 may be formed in a circular shape. At this time, the insert nut 410 has a vertical line formed at the circumferential edge portion to limit rotation of the insert nut 410 in the first insert hole 231, thereby enhancing the fixing force of the insert nut 410. .

The diameter of the first insert hole 231 is larger than the diameter of the second insert hole 232, and the diameter of the insert nut 410 is larger than the diameter of the second insert hole 232, so that the beam member 300 Even when a tensile force is applied, the insert nut 410 may stably resist the tensile force without being pulled out through the second insert hole 232.

5 and 6, the insert fastener 400 includes a washer member 450 having a relatively large frictional force on a first surface in contact with the bonding plate 330 as compared to a second surface in the opposite direction. It may be further provided.

The washer member 450 smoothes the surface of the second surface in contact with the bolt head 431 of the insert bolt 430 to minimize the frictional force, and has a relatively frictional force compared to the second surface in contact with the bonding plate 330. The surface can be roughened to be large.

The washer member 450 may reduce friction between the bolt head 431 of the insert bolt 430 and the bonding plate 330 when the insert bolt 430 rotates.

5 and 6, the insert fastening hole 400 further includes a reinforcing nut 470 that is fastened to the rear end of the insert bolt 430 to reinforce the head portion of the insert bolt 430. I can.

The reinforcing nut 470 can be installed when reinforcement is required because the bolt head 431 of the insert bolt 430 is weak, and the insert bolt 430 is fastened to a threaded portion extending from the rear end of the bolt head 431 Can be.

Of course, the pintail 433 may protrude from the rear end of the reinforcing nut 470.

5 and 6, the insert bolt 430 passes through the insert hole 230 and is fastened to the insert nut 410, and is installed at the rear end of the bolt body, and a limit is set. A pintail 433 that is broken by the bolt body may be provided when a fastening force greater than or equal to a value is applied.

The bolt body may have a bolt head 431 formed at the rear end, and an insert nut 410 fixed in a force-fitting manner to the insert bolt 430 by rotating the bolt head 431 Tighten.

Accordingly, even when a tensile force is repeatedly applied to the bolt head 431 of the insert bolt 430, the insert bolt 430 is not loosened from the insert nut 410.

A pintail 433 is formed at the rear end of the bolt head 431, and the pintail 433 may be broken at the bolt head 431 when a fastening force equal to or greater than the limit set value is applied.

Here, the limit setting value may be set to a value such that the fastening force of the insert bolt 430 is secured.

The pintail 433 does not break until the clamping force of the limit set value for fixing the insert bolt 430 to the insert nut 410 acts, and the pintail 433 is a bolt It can be broken in the body.

The insert bolt 430 may be prevented from being fastened to the insert nut 410 with excessive fastening force as the pintail 433 is broken at the bolt body when an excessive fastening force equal to or greater than the limit set value is applied.

The pillar 100 is provided as a CFT pillar 100 having a rectangular cross section or a circular cross section, and the reinforcing plate 200 is installed to surround the pillar 100 of a plurality of reinforcing modules 200M, The welding line of the adjacent reinforcing module 200M may be welded together with the pillar 100.

Referring to FIGS. 2 and 3, a CFT column 100 having a rectangular cross section may be configured, and four reinforcement modules 200M may be connected in a circumferential direction.

In this case, as the adjacent two reinforcing modules 200M and the pillar 100 are welded together, a welding line may be formed in the height direction of the pillar 100.

The reinforcing plate 200 includes four reinforcing modules 200M having a'b'-shaped cross section connected in the circumferential direction to form a closed cross section in a square shape, and forming a welding line on each side of the square cross section. It can be bonded to the outer surface of (100).

That is, in the reinforcing plate 200, the four reinforcing modules 200M can form the pillar 100 and the four welding lines in the longitudinal direction, and the pillar 100 and the reinforcing plate 200 are in close contact with each other. Can be joined by welding in.

Referring to FIG. 8, it may be composed of a CFT column 100 having a circular cross section, and four reinforcement modules 200M may be connected in the circumferential direction.

A brief description of the construction process of the joint structure of the pillar 100 and the beam member 300 according to an embodiment of the present invention is as follows.

First, the insert hole 230 is processed in the reinforcing plate 200, and the insert fastening hole 400 is inserted into the processed insert hole 230 to be fixed.

Specifically, the insert nut 410 is inserted into the first insert hole 231 by pressing with a press or the like.

Next, the reinforcing plate 200 into which the insert nut 410 is inserted is bent.

Next, the bent reinforcing plate 200 is welded to the pillar 100.

Next, the bonding plate 330 of the beam member 300 is placed in contact with the reinforcing plate 200, and the bonding plate 330 and the reinforcing plate 200 are fastened with an insert fastening hole 400.

Specifically, the insert nut 410 is inserted and fixed in the first insert hole 231 of the reinforcing plate 200, and the insert bolt 430 is the bolt hole 331 and the second insert of the bonding plate 330. It may pass through the hole 232 and be fixed to the insert nut 410 fixed to the first insert hole 231.

The construction process of the joint structure of the pillar 100 and the beam member 300 of the pillar 100 and the beam member 300 is to allow those of ordinary skill in the art to easily implement the present invention. In order to illustrate as a preferred construction method, in addition to the above-described sequence, modifications may be performed according to a different sequence according to specific site conditions, or other ancillary processes may be added.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and variations are possible without departing from the technical spirit of the present invention described in the claims. It will be obvious to those of ordinary skill in the field.

100: pillar 200: reinforcement plate
200M: reinforcement module 210: reinforcement plate body
230: insert hole 231: first insert hole
232: second insert hole 300: beam member
310: section steel member 311: upper flange
313: web member 315: lower flange
330: joint plate 331: bolt hole
400: insert fastener 410: insert nut
430: insert bolt 431: bolt head
433: pintail 450: washer member
470: reinforcement nut C: concrete

Claims (13)

Pillar;
A reinforcing plate which is welded to the pillar and in which an insert hole having a step formed on the opposite surface of the pillar is internally formed;
A beam member connected to the reinforcing plate and having a joint plate formed at an end thereof; And,
The joint structure of the column and the beam member comprising; an insert fastening hole for connecting the reinforcing plate and the beam member by being fastened to the joint plate while being inserted and fixed in the insert hole.
The method of claim 1, wherein the reinforcing plate,
Consisting of a plurality of segmented reinforcing modules, the welding line of the adjacent reinforcing module is welded together with the pillar, the joint structure of the pillar and the beam member.
The method of claim 1, wherein the reinforcing plate,
Consisting of a plurality of segmented reinforcing modules, the welding line of the adjacent reinforcing module is disposed at the installation portion of the beam member, the joint structure of the column and the beam member.
The method of claim 1, wherein the reinforcing plate,
Four reinforcement modules with a'b'-shaped cross section are connected in the circumferential direction to form a closed cross section in a square shape,
The welding line of the two adjacent reinforcing modules is formed in a direction corresponding to the height direction of the column.
The method of claim 1, wherein the reinforcing plate,
A reinforcing plate body installed between the pillar and the beam member, welded to the pillar, and fixed via the beam member and the insert fastening hole; And,
An insert hole in which the reinforcing plate body is internally formed on an opposite surface in contact with the pillar, and in which a step is formed while varying the diameter of the hole.
The method of claim 5, wherein the insert hole,
A first insert hole in which the insert nut of the insert fastening hole is fixed by a force fitting method; And,
A joint structure between a column and a beam member having a relatively small diameter compared to the first insert hole, and a second insert hole through which the insert bolt of the insert fastening hole is installed.
The method of claim 1, wherein the beam member,
A section steel member extending in the transverse direction; And,
A joint structure of a column and a beam member having; a joint plate installed at an end of the section steel member and fixed to the reinforcing plate through a plurality of insert fasteners.
The method of claim 1,
The insert fastening hole is a joint structure of a column and a beam member, characterized in that disposed outside the column.
The method of claim 1, wherein the insert fastener,
An insert nut fixed while being inserted into the insert hole in a force-fitting manner; And,
An insert bolt connecting the reinforcing plate and the joining plate while being fastened to the insert nut.
The method of claim 9, wherein the insert fastener,
The bonding structure of the column and the beam member further comprising a washer member having a relatively large frictional force on the first surface contacting the bonding plate compared to the second surface in the opposite direction.
The method of claim 9, wherein the insert fastener,
A reinforcing nut fastened to a rear end of the insert bolt to reinforce the head portion of the insert bolt.
The method of claim 9, wherein the insert bolt,
A bolt body through the insert hole and fastened to the insert nut; And,
A joint structure of a column and a beam member having; a pintail installed at the rear end of the bolt body and broken in the bolt body when a fastening force greater than or equal to a limit set value is applied.
The method of claim 1,
The pillar is provided as a CFT pillar having a square cross section or a circular cross section,
The reinforcing plate,
A joint structure of a pillar and a beam member, which is installed to surround the pillar of a plurality of reinforcement modules, and wherein welding lines of the adjacent reinforcement modules are welded together with the pillar.

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