KR20200065414A - Joint damper structure and joint structure for beam to column connection - Google Patents

Abstract

The present invention provides a joint damper structure which includes: a first joint plate part coupled to a first structural member; a second joint plate part coupled to a second structural member that is connected to the first structural member to cross the same; a damper plate part connecting the first joint plate part and the second joint plate part and absorbing energy transmitted from the first structural member and the second structural member; and deformation inducing parts respectively formed in a space between the first joint plate part and the damper plate part and a space between the second joint plate part and the damper plate part to induce deformation of the damper plate part. Therefore, the joint damper structure can prevent damage to the main structural members.

Description

Joint damper structure and joint structure between pillar member and beam member {JOINT DAMPER STRUCTURE AND JOINT STRUCTURE FOR BEAM TO COLUMN CONNECTION}

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

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

There are a lot of earthquakes around the world as a ring region of the Pacific Rim, and after the recent Gyeongju and Pohang earthquakes, the Republic of Korea recognizes that it is not an earthquake safety zone.

When designing buildings, it is well known that steel structures are more advantageous to seismic performance than reinforced concrete structures.

However, according to the current structural design standards, even if a steel structure is simply seismic designed, it is possible to prevent the collapse of the building in the event of an earthquake, but it cannot prevent damage to major structural members such as beams and columns.

Accordingly, interest is increasing in seismic isolation technologies that control earthquakes or seismic isolation technologies that insulate energy generated by earthquakes in buildings.

Among them, vibration control technology is known to be the most economical and efficient.

Damping technology requires a damper that absorbs energy. Of the dozens of existing dampers, the most economical and efficient steel damper can be seen by looking at the case of Japan, an earthquake-heavy country.

In order to exhibit performance in a building with a steel damper or any damper, the damper must be connected to structural members constituting the building, and a brace and a damper are usually connected to the structure.

However, in this case, there is a drawback in that the window is covered and becomes quite frustrating when viewing the building from the perspective of the resident in the building or from the outside.

KR 20-1996-0022884 U

The present invention is to provide a joint damper structure and a joint structure of a pillar member and a beam member that can prevent damage to the main structural member by focusing deformation due to external load on the damper part.

As one aspect for achieving the above object, the present invention is a first bonding plate portion coupled to the first structural member; A second bonding plate portion coupled to a second structural member connected to cross the first structural member; A damper plate portion connecting between the first bonding plate portion and the second bonding plate portion and absorbing energy transmitted from the first structural member and the second structural member; And a deformation inducing portion formed in a space between the first bonding plate portion and the damper plate portion and between the second bonding plate portion and the damper plate portion to induce deformation of the damper plate portion. to provide.

Preferably, the first bonding plate portion may be detachably installed on the first structural member, and the second bonding plate portion may be detachably installed on the second structural member.

Preferably, the first structural member is composed of a beam member having an upper flange, a lower flange, and a web member, and the second structural member is provided as a pillar member intersecting the beam member, and the first bonding plate portion Is composed of a plate-shaped member that is bolted in a state parallel to the lower surface of the lower flange of the beam member, and the second bonding plate portion is a plate-shaped member that is bolted in a state parallel to the side of the pillar member. It can be composed of.

Preferably, the damper plate portion, the damper plate is formed to extend horizontally in the direction of the second bonding plate portion from the first bonding plate portion, a plurality of damper holes are spaced apart; And a pair of damper brackets extending from the second bonding plate portion to support both side surfaces of the damper plate.

Preferably, the damper plate includes a central plate extending in the longitudinal direction; A pair of end plates formed on both side surfaces of the central plate and having long elongated holes in the width direction spaced apart in the longitudinal direction; And a connection plate that connects between the first bonding plate portion and the central plate, and that the first deforming space of the deforming portion is formed on both sides.

Preferably, the damper bracket may be composed of a reinforcement bracket having a'T'-shaped cross section.

Preferably, the cross section of the damper bracket may increase as it goes from the first bonding plate portion toward the second bonding plate portion.

Preferably, the deformation inducing portion, a first deformation inducing space formed to be spaced apart between the first bonding plate portion and the damper plate, the damper plate to be deformed in the direction of the first structural member; And a second deformation inducing space formed between the second bonding plate portion and the damper plate to induce the damper plate to deform in the direction of the second structural member.

Preferably, it is installed over the lower side of the first bonding plate portion and the damper plate, and may further include a behavior plate that acts by linking the first bonding plate portion and the damper plate.

As one aspect for achieving the above object, the present invention is a pillar member; A beam member installed to cross the side of the pillar member; A joining member joined to a side of the pillar member and an upper side of the beam member to connect the pillar member and the beam member; And, to connect the pillar member and the beam member, a junction damper structure that is joined to the side of the pillar member and the lower side of the beam member; including, the junction damper structure, the first junction coupled to the beam member Plate part; A second bonding plate portion coupled to the pillar member; A damper plate portion connecting between the first bonding plate portion and the second bonding plate portion and absorbing energy transmitted from the beam member and the pillar member; And a deformation inducing portion formed in a space between the first bonding plate portion and the damper plate portion and between the second bonding plate portion and the damper plate portion to induce deformation of the damper plate portion. It provides a joining structure of the member.

According to an embodiment of the present invention, there is an effect of preventing the damage of the main structural member by concentrating the deformation due to the external load on the damper portion.

1 is a perspective view of a junction damper structure according to an embodiment of the present invention.
FIG. 2 is a view showing an I-I' direction of FIG. 1.
FIG. 3 is a view showing a direction II-II' of FIG. 1.
FIG. 4 is a view showing a direction III-III' of FIG. 1.
5 is a perspective view of an exploded state of the joint structure of the pillar member and the beam member of the present invention.
FIG. 6 is a perspective view of a bonding structure of the pillar member and the beam member of FIG. 5.
7 and 8 are views illustrating a modified state of the joint damper structure of the joint structure of the pillar member and the beam member of FIG. 6.
Referring to FIG. 9, a deformation is generated in the damper plate portion of the joint structure in a large-scale structure experiment of the joint structure of the present invention.
10 is a view showing the deformation angle (X-axis) and the moment (Y-axis) measured during the large-scale structure experiment of FIG. 9.
FIG. 11 is a view showing cumulative strain values (X-axis) and strain values (Y-axis) of each member measured during the large-scale structural experiment of FIG. 9.

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 to more fully describe the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for a more clear description.

Hereinafter, a bonded damper structure 10 according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 to 11, the junction damper structure 10 according to an embodiment of the present invention includes and may additionally include.

1 to 4, the joint damper structure 10 includes a first joint plate portion 100 coupled to the first structural member 1 and a second joint crossing the first structural member 1. The second bonding plate portion 200 coupled to the structural member 2, the first bonding plate portion 100 and the second bonding plate between the connection between the 200, the first structural member 1 and the A damper plate portion 300 that absorbs energy transmitted from the second structural member 2, a space between the first bonding plate portion 100 and the damper plate portion 300, and the second bonding plate portion 200 and the It may be formed in each of the inter-space of the damper plate portion 300, the deformation inducing portion 400 for inducing the deformation of the damper plate portion 300; may include.

5 and 6, the junction damper structure 10 may connect between two structural members connected to cross each other.

The first bonding plate portion 100 may be coupled to the first structural member 1, and the second bonding plate portion 200 may be coupled to the second structural member 2.

5 and 6, the first bonding plate portion 100 is detachably installed on the first structural member 1, and the second bonding plate portion 200 is the second structural member 2 It can be installed detachably.

In one example, the first structural member 1 is composed of a beam member 1, and the second structural member 2 may be composed of a pillar member 2 connected to cross the beam member 1.

The first bonding plate portion 100 may be detachably installed by a bolting method or the like to the beam member 1 which is the first structural member 1.

The second bonding plate portion 200 may be detachably installed by a method such as bolt fastening to the pillar member 2 which is the second structural member 2.

The joint damper structure 10 of the present invention is configured such that the first joint plate portion 100 and the second joint plate portion 200 are detachably attached to the structural member, thereby causing damage to the damper plate portion 300 of the joint damper structure 10. In the event of occurrence, it is possible to simply repair the joints of the two structural members by replacing only the joint damper structure 10.

5 and 6, the first structural member 1 is composed of a beam member 1 having an upper flange, a lower flange, and a web member, and the second structural member 2 is the beam member It may be provided with a pillar member (2) that is joined to cross (1).

The first bonding plate portion 100 is composed of a plate-shaped member that is bolted in a state parallel to the lower surface of the lower flange of the beam member 1, and the second bonding plate portion 200 is the pillar member 2 It may be composed of a plate-like member that is bolted in a state arranged parallel to the side of the.

The first bonding plate portion 100 is composed of a plate-shaped member, and a bolt may be fastened to the fastening hole H in a state where the upper surface of the first bonding plate portion 100 overlaps the lower surface of the lower flange of the beam member 1. .

The second bonding plate portion 200 is composed of a plate-shaped member, and a bolt may be fastened to the fastening hole H in a state where the second bonding plate portion 200 is superposed on the side surface of the pillar member 2.

1 and 2, the damper plate portion 300 connects between the first bonding plate portion 100 and the second bonding plate portion 200, and the first structural member 1 and the second structure It serves to absorb energy due to the load transmitted from the member (2).

The joint damper structure 10 of the present invention focuses the deformation due to external loads acting between the first structural member 1 and the second structural member 2 on the damper plate portion 300 so that the first structural member 1 ) And the second structural member 2 is prevented, and if necessary, only the damaged damper plate part 300 is replaced to easily repair the joint between the structural members.

1 and 2, the deformation inducing part 400 is formed around the damper plate part 300, and is a part that induces deformation of the damper plate part 300.

In one example, the deformation inducing portion 400 may be formed in the longitudinal direction front and rear of the damper plate portion 300, respectively.

1 and 2, the damper plate portion 300 is formed to extend horizontally in the direction of the second bonding plate portion 200 from the first bonding plate portion 100, and a plurality of damper holes are spaced apart from each other. 310 and a pair of damper brackets 330 extending from the second bonding plate portion 200 to support both side surfaces of the damper plate 310.

The damper plate 310 may be connected to the first bonding plate portion 100 in one direction in the longitudinal direction, and a second deformation induction space 430 in the deformation induction unit 400 may be formed in the other direction in the longitudinal direction.

The damper bracket 330 is joined to the second joining plate portion 200, and a pair of damper brackets 330 are spaced apart in the width direction so that the damper plate 310 is disposed between the pair of damper brackets 330. Can be.

The pair of damper brackets 330 may support both sides of the damper plate 310 while being joined to the second joint plate portion.

The damper plate 310 is formed of a plate-like member that is formed to extend horizontally, and a plurality of damper holes are formed on the plate-shaped member, so that the damper plate 310 is formed from a lower portion of the first structural member 1 composed of a beam member 1 or the like. It is possible to reduce the height of the occupied space to reduce the floor height of the building (F).

1 and 2, the damper plate 310 is formed on both side surfaces of the central plate 311 extending in the longitudinal direction and the central plate 311, and a long hole having a long length in the width direction ( 316) a pair of end plates 313 that are spaced apart in the longitudinal direction, and connected between the first bonding plate portion 100 and the central plate 311, the second side of the deformation inducing portion 400 1 may be provided with a connecting plate 317, each of which is a deformation-inducing space 410 is formed.

The central plate 311 may be formed to extend in the longitudinal direction of the damper plate 310.

The central plate 311 may be disposed between the connection plate 317 and the second deformation inducing space 430.

The central plate 311 may be formed with a connecting plate 317 extending at one end in the longitudinal direction, and a second deformation inducing space 430 of the deformation inducing unit 400 may be disposed at the other end in the longitudinal direction.

Referring to FIG. 1, a behavior plate 500 may be vertically coupled to a lower surface of the central plate 311.

In this case, referring to FIG. 2, the behavior plate 500 may be formed over the lower surface of the central plate 311 and the lower surface of the first bonding plate portion 100.

End plates 313 may be respectively formed on both sides in the width direction of the central plate 311, and the central plate 311 and a pair of end plates 313 may be integrally formed.

The damper plate 310 may include a connection plate 317 that connects between the first bonding plate portion 100 and the central plate 311.

First deformation-inducing spaces 410 may be formed on both sides of the connection plate 317 in the width direction.

1 and 4, the damper bracket 330 may be composed of a reinforcement bracket having a'T'-shaped cross section.

The damper bracket 330 may form a cross-section in cross shape with one side of the damper plate 310.

The damper bracket 330 improves the stiffness of the damper bracket 330 compared to the damper plate 310 so as to form a cross-section with one side of the damper plate 310, so that the first structural member 1 and the second Deformation occurring in the damper plate portion 300 by energy transmitted from the structural member 2 may be induced to be concentrated in the damper plate 310 portion.

Referring to FIG. 3, the cross section of the damper bracket 330 may increase from the first bonding plate portion 100 toward the second bonding plate portion 200.

The stress may be increased toward the joint portion of the first structural member 1 and the second structural member 2.

The joint damper structure 10 of the present invention is a damper bracket 330 from the first joint plate portion 100 to the second joint plate portion 200 in order to respond to the stress distribution around the joint portion of the two structural members. It can be configured to increase in cross-section.

1 and 2, the deformation inducing portion 400 is formed spaced between the first bonding plate portion 100 and the damper plate 310, so that the damper plate 310 is the first structure A first deformation inducing space 410 leading to be deformed in the direction of the member 1, and formed between the second bonding plate portion 200 and the damper plate 310, the damper plate 310 A second deformation inducing space 430 may be provided to induce deformation in the direction of the second structural member 2.

The first deformation inducing space 410 is a buffer region where deformation is induced when the damper plate 310 is deformed in the direction of the first structural member 1.

The second deformation inducing space 430 is a buffer area where deformation is induced when the damper plate 310 is deformed in the direction of the second structural member 2.

Referring to FIG. 7, while the damper plate 310 moves in the direction of the first structural member 1, deformation may be absorbed in the first deformation inducing space 410.

For example, when the damper plate 310 receives a force in the direction of the beam member 1, which is the first structural member 1, the damper plate 310 may be deformed in the first deformation induction space 410 direction.

The first deformation inducing space 410 is formed around the connecting portion of the first bonding plate portion 100 and the damper plate 310, and the two plates are formed on both sides in the width direction with the connection plates of the damper plate 310 interposed therebetween. 1, the deformation-inducing space 410 may be formed.

The corner portion of the first deformation inducing space 410 may be rounded.

Referring to FIG. 8, while the damper plate 310 moves in the direction of the second structural member 2, deformation may be absorbed in the second deformation inducing space 430.

For example, when the damper plate 310 receives a force in the direction of the pillar member 2, which is the second structural member 2, the damper plate 310 may be deformed in the second deformation induction space 430 direction.

In the second deformation induction space 430, one second deformation induction space 430 may be formed between the second bonding plate portion 200 and the damper plate 310.

The second deformation-inducing space 430 may be configured as a rectangular shape having a short length and a wide width in the direction of the second bonding plate portion 200 from the damper plate 310.

Of course, the corner portion of the rectangular second deformation-inducing space 430 may be rounded.

Bonded damper structure 10 of the present invention, by forming the first strain inducing space 410 and the second strain inducing space 430 around both ends in the longitudinal direction of the damper plate 310, the first structural member ( 1) has the effect of stably absorbing the energy acting between the second structural member (2).

1 to 3, the bonding damper structure 10 is installed over the lower side of the first bonding plate portion 100 and the damper plate 310, and the first bonding plate portion 100 and the damper plate It may further include a behavior plate 500 to behave by linking (310).

Referring to FIG. 1, the behavior plate 500 may be vertically joined to the first bonding plate portion 100 and the damper plate 310, respectively.

In one example, the first bonding plate portion 100 and the damper plate 310 may be composed of plate-like members, respectively.

The behavior plate is installed over the first bonding plate portion 100 and the damper plate 310 and may be vertically extended downward.

The first bonding plate portion 100, the damper plate 310, and the behavior plate 500 may be made of a steel plate having the same thickness.

At this time, in order to prevent the height of the joint damper structure 10 from being excessive, the length of the behavior plate 500 extending vertically downward from the lower flange of the beam member 1 is 1.5 to 2.5 times the thickness of the steel plate. It can be configured in the following range.

Referring to FIG. 3, the damper bracket 330 of the damper plate portion 300 may be disposed so as not to protrude downward from the behavior plate 500.

Next, with reference to the drawings will be described in detail.

1 to 11, the bonding structure of the pillar member 2 and the beam member 1 according to an embodiment of the present invention includes a beam member 1, a pillar member 2, a bonding member 20 and , It may include a structure.

5 and 6, the joining structure of the pillar member 2 and the beam member 1 includes a pillar member 2 and a beam member 1 installed to cross the side surfaces of the pillar member 2 , To connect the pillar member (2) and the beam member (1), the side of the pillar member (2) and the bonding member (20) joined to the upper side of the beam member (1), and the pillar member (2) ) And to connect the beam member (1), it may include a joint damper structure (10) that is joined to the side of the pillar member (2) and the lower side of the beam member (1).

1 to 4, the bonding damper structure 10 includes a first bonding plate portion 100 coupled to the beam member 1 and a second bonding plate portion 200 coupled to the pillar member 2 ), a damper plate portion 300 that connects between the first bonding plate portion 100 and the second bonding plate portion 200 and absorbs energy transmitted from the beam member 1 and the pillar member 2. ), and the space between the first bonding plate portion 100 and the damper plate portion 300 and the second bonding plate portion 200 and the damper plate portion 300 are respectively formed in the damper plate portion 300 ) May be provided with a deformation inducing portion 400 for inducing deformation.

5 and 6, the joining member 20 is installed over the upper portion of the pillar member 2 and the beam member 1, and the joint damper structure 10 includes a pillar member 2 and a beam member ( It can be installed over the lower part of 1).

The joining member 20 and the joining damper structure 10 may be detachably installed on the pillar member 2 and the beam member 1 by a bolt fastening method or the like.

The bonding member 20 is a component that is joined to the side of the pillar member 2 and the upper side of the beam member 1 to connect the pillar member 2 and the beam member 1.

Referring to FIG. 2, the joining member 20 includes a vertical plate joined to the side surface of the pillar member 2, a horizontal plate extending horizontally from the vertical plate, and bolted to the upper flange of the beam member 1, It may include a horizontal plate and a reinforcement rib installed over the vertical plate.

The joint damper structure 10 is a component that is joined to the side of the pillar member 2 and the lower side of the beam member 1 so as to connect the pillar member 2 and the beam member 1.

The damper plate 310 is formed of a plate-like member that is formed to extend horizontally, and a plurality of damper holes are formed on the plate-like member, thereby reducing the height of the space occupied by the lower portion of the beam member 1 to build the building (F). There is an effect that can reduce the height of the back.

In addition, when the junction damper structure 10 includes the behavior plate 500, in order to prevent the height of the junction damper structure 10 from being excessive, the behavior plate 500 is in the lower flange of the beam member 1 The length extending vertically downward may be configured within a range of 1.5 to 2.5 times the thickness of the steel sheet.

Referring to FIG. 3, the damper bracket 330 of the damper plate portion 300 may be disposed so as not to protrude downward from the behavior plate 500.

Referring to FIGS. 7 and 8, when an earthquake (G), such as a building (F) occurs, lateral deformation occurs, and energy is concentrated at the upper and lower portions of the joint between the beam member (1) and the pillar member (2). Can be.

In particular, the largest force acts on the lower portion of the joining portion of the beam member 1 and the pillar member 2.

Therefore, the bonding structure of the pillar member 2 and the beam member 1 of the present invention is a pillar member (10) by arranging the junction damper structure 10 in the lower region of the connecting portion of the pillar member 2 and the beam member 1. 2) It is possible to stably buffer the energy acting at the junction of the beam member (1).

Referring to FIG. 9, in order to verify the performance of the joint structure of the pillar member 2 and the beam member 1 of the present invention, a large-scale structural experiment was conducted, and as a result, the damper plate portion of the joint damper structure 10 ( 300) is shown a deformation occurs.

10 is a view showing the deformation angle (X-axis) and the moment (Y-axis) measured during the large-scale structure experiment of FIG. 9.

FIG. 11 shows cumulative strain values (X-axis) and strain values (Y-axis) of each member of the beam member 1, column member 2, and joint damper structure 10 measured during the large-scale structure experiment of FIG. 9. It is a drawing shown.

FIG. 10 shows a relationship curve between the deformation angle (X-axis) and the moment (Y-axis) measured during the large-scale structure experiment constructed in FIG. 9.

Referring to FIG. 10, in the bonding structure of the pillar member 2 and the beam member 1 of the present invention, the interlayer deformation angle exceeds 2% and reaches 4%, so that the performance of the special moment joint as well as the intermediate moment joint is reached. It was confirmed possible.

11 shows the cumulative strain value (X) of each member measured after attaching strain gauges to major members such as the beam member (1), pillar member (2), and joint damper structure (10) while performing the large-scale structural experiment of FIG. Axis) and strain values for each member (Y axis).

Referring to FIG. 11, the beam member 1 measured strain values and cumulative strain values (upper flange_TF_MAX, lower flange_BF_MAX, web member_W_MAX) in the upper flange, the lower flange, and the web member, respectively.

In the case of the joint damper structure 10, the strain value and the cumulative strain value (D_MAX) were measured in the damper plate portion 300.

Referring to FIG. 11, the main structural members such as the upper flange, the lower flange, the web member, and the pillar member 2 of the beam member 1 are in the elastic section, but the strain value and the cumulative strain value in the damper plate part 300 It was confirmed that (D_MAX) was fired.

This prevents damage to structural members such as the beam member 1 and the pillar member 2 while showing the performance of the joint close to the special moment joint, and concentrates the damage only to the damper plate portion 300 of the joint damper structure 10, When damage is caused by an earthquake (G) or the like, only the bonded damper structure 10 is replaced, and main structural members such as the beam member 1 and the pillar member 2 can be continuously used.

Of course, various embodiments of the bonding damper structure 10 having various embodiments described above may be applied to the bonding structure of the pillar member 2 and the beam member 1 of the present invention.

Therefore, the first joint plate portion 100, the second joint plate portion 200, the damper plate portion 300, and the deformation of the joint damper structure 10 utilized in the joint structure of the pillar member 2 and the beam member 1 The structure of the induction part 400 is the same as the structure of the junction damper structure 10 as described above, and a detailed description thereof will be omitted to avoid duplication.

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

1: first structural member, beam member 2: second structural member, pillar member
10: joint damper structure 20: joint member
100: first bonding plate portion 200: second bonding plate portion
300: damper plate portion 310: damper plate
311: center plate 313: end plate
316: long hole 317: connecting plate
330: damper bracket 400: deformation inducing part
410: first deformation induction space 430: second deformation induction space
500: behavior plate F: building
G: Earthquake H: Fastening hole

Claims (10)

A first bonding plate portion coupled to the first structural member;
A second bonding plate portion coupled to a second structural member connected to cross the first structural member;
A damper plate portion connecting between the first bonding plate portion and the second bonding plate portion and absorbing energy transmitted from the first structural member and the second structural member; And,
And a deformation inducing portion formed in a space between the first bonding plate portion and the damper plate portion and between the second bonding plate portion and the damper plate portion to induce deformation of the damper plate portion.
According to claim 1,
The first joining plate portion is detachably installed on the first structural member, the second joining plate portion is a joint damper structure, characterized in that detachably installed on the second structural member.
According to claim 1,
The first structural member is composed of a beam member having an upper flange, a lower flange, and a web member, and the second structural member is provided as a pillar member cross-joined to the beam member,
The first bonding plate portion is composed of a plate-like member that is bolted in a state parallel to the lower surface of the lower flange of the beam member,
The second bonding plate portion is a joint damper structure consisting of a plate-shaped member that is bolted in a state arranged parallel to the side of the pillar member.
According to claim 1, The damper plate portion,
A damper plate extending horizontally from the first bonding plate portion to the second bonding plate portion and having a plurality of damper holes spaced apart; And,
And a pair of damper brackets extending from the second bonding plate portion to support both side surfaces of the damper plate.
According to claim 4, The damper plate,
A central plate extending in the longitudinal direction;
A pair of end plates formed on both side surfaces of the central plate and having long elongated holes in the width direction spaced apart in the longitudinal direction; And,
A connection damper structure comprising a connection plate formed between the first bonding plate portion and the central plate, and connecting plates in which first deformation inducing spaces of the deformation induction portions are formed on both sides.
The method of claim 4,
The damper bracket is a junction damper structure, characterized in that it consists of a reinforcement bracket having a'T'-shaped cross section.
According to claim 6, The damper bracket,
A junction damper structure, characterized in that a cross section increases from the first bonding plate portion toward the second bonding plate portion.
The method of claim 4, wherein the deformation inducing unit,
A first deformation-inducing space formed between the first bonding plate portion and the damper plate to induce the damper plate to deform in the direction of the first structural member; And,
And a second deformation inducing space formed between the second bonding plate portion and the damper plate to induce the damper plate to deform in the direction of the second structural member.
The method of claim 4,
A junction damper structure further comprising: a behavior plate installed over the lower side of the first bonding plate portion and the damper plate, and actuating the first bonding plate portion and the damper plate.
Pillar member;
A beam member installed to cross the side of the pillar member;
A joining member joined to a side of the pillar member and an upper side of the beam member to connect the pillar member and the beam member; And,
Includes; to connect the pillar member and the beam member, a joint damper structure that is joined to the side of the pillar member and the lower side of the beam member,
The junction damper structure,
A first bonding plate portion coupled to the beam member;
A second bonding plate portion coupled to the pillar member;
A damper plate portion connecting between the first bonding plate portion and the second bonding plate portion and absorbing energy transmitted from the beam member and the pillar member; And,
Deformation inducing portion which is formed in the space between the first bonding plate portion and the damper plate portion and the space between the second bonding plate portion and the damper plate portion to induce deformation of the damper plate portion; Joint structure.

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