KR101879072B1 - Damper apparatus and building sturcture - Google Patents

Abstract

The present invention relates to a damper device which is provided to connect a first structure and a second structure having different vibration periods to each other and to buffer a relative displacement caused by a difference in vibration period, the core fixing part being fixed to the first structure; And a damper fixing unit fixed at one side to the second structure and at the other side to the core fixing unit and being deformably installed in a direction of connection between the first structure and the second structure, A fixed fixing member fixed to the core fixing unit; A movable fusing member fixed to the second structure and movably installed with respect to the fixed fusing member; And a damper plate movably connecting the fixed fixing member and the moving fixing member while being plastic-deformed in a direction of connection between the first structure and the second structure, wherein the core fixing portion is embedded in the first structure, A supporting anchor body to be fixed; A pair of fixed frames extending from the supporting anchor body toward the moving fixing member and fixed to the fixed fixing member; And a guide frame connecting between the pair of fixed frames and guiding the movable fixing member to be slidable.

Description

[0001] DAMPER APPARATUS AND BUILDING STURCTURE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a damper device in which stress is concentrated on a joint portion of a structure, and a structure structure.

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

1, a conventional building structure is composed of a core portion 1 and a frame portion 2, and the core portion 1 and the frame portion 2 are directly connected to each other via the joint portion 3 Or the like.

The frame portion 2 is designed mainly by a gravity load and has a relatively low rigidity. The core portion 1 is designed mainly by a lateral force and has a relatively high rigidity.

In the case of using the core part 1 and the frame part 2 as described above, it is currently widely used in a low-rise building to a high-rise building, and an efficient structure design can be made as the building progresses.

For example, the joining portion 3 of the core portion 1 and the frame portion 2 may be formed by previously forming the core portion 1 before the frame portion 2 and by pre-embedding the buried iron plate on which the stud bolt is mounted, And a semi-rigid welding method in which a steel plate 1 and a steel plate provided in the core portion 1 are steel-welded and connected.

However, as shown in FIG. 1 and FIG. 2, in the conventional case, by adopting a method of directly joining the core portion 1 and the frame portion 2 via the joint portion 3, A stress transmission problem between heterogeneous materials may occur at the junction between the core section 1 and the frame section 2 composed of a steel frame structure and the stress is concentrated on the joint section 3 where the stress transmission is not smooth, There is a problem that can lead to.

The frame portion 2 to be joined to the core portion 1 is often designed to have a strong resistance against the viewing core portion 1 so that the joint portion of the frame portion 2 and the core portion 1 3) becomes complicated and the workability is deteriorated.

As shown in Fig. 2, since joint portions are formed at each point where the core portion 1 and the frame portion 2 meet each other, the joint portion 3 must be separately formed for each joint portion, , There is a problem that economical deterioration may occur.

The core portion 1 and the frame portion 2 which can effectively absorb the load transmission between the core portion 1 and the frame portion 2 while effectively transmitting the lateral load generated between the core portion 1 and the frame portion 2, It is necessary to develop the details of the joint portion 3 of the portion 2.

Korean Patent Publication No. 2008-0006342

As one aspect, the present invention is to provide a damper device and a building structure that prevent damage to a structure by concentrating stress on a joint portion of the structure.

According to an aspect of the present invention, there is provided a damper device for connecting a first structure and a second structure having different vibration periods to each other, A core fixing unit fixed to the structure; And a damper fixing unit fixed at one side to the second structure and at the other side to the core fixing unit and being deformably installed in a direction of connection between the first structure and the second structure, A fixed fixing member fixed to the core fixing unit; A movable fusing member fixed to the second structure and movably installed with respect to the fixed fusing member; And a damper plate movably connecting the fixed fixing member and the moving fixing member while being plastic-deformed in a direction of connection between the first structure and the second structure, wherein the core fixing portion is embedded in the first structure, A supporting anchor body to be fixed; A pair of fixed frames extending from the supporting anchor body toward the moving fixing member and fixed to the fixed fixing member; And a guide frame connecting between the pair of fixed frames and guiding the movable fixing member to be slidable.

delete

Preferably, the moving fusing member may be slidably inserted into the pair of fixed frames and the moving space formed between the guide frames.

Preferably, the moving fusing member comprises: a fixed damper anchor plate of the second structure; A pair of side frames extending from the damper anchor plate toward the fixed fixing member and slidably installed between the pair of fixed frames; And a slide frame connecting the pair of side frames and slidably installed on the guide frame.

Preferably, the damper fixing unit may further include a damper block protruding from the lower surface of the moving fixing member and reducing frictional force while being in contact with a part of the guide frame.

The core fixing unit may further include a core block protruding from the upper surface of the guide frame and reducing frictional force while being in contact with a part of the moving fixing member.

Preferably, the core block and the damper block are spaced apart from each other at a predetermined interval in the moving direction of the moving fixing member in a state where the core fixing portion and the damper fixing portion are engaged with each other, It can serve as a limiting stopper member.

Preferably, the damper fixing unit is detachably attachable to the second structure and the fixed fixing member so as to be replaceable.

According to an aspect of the present invention, there is provided a building structure comprising: a first structure having a core portion of a building and having a reinforced concrete (RC) structure or a steel reinforced concrete (SRC) structure; A second structure forming an outer frame portion of the building and having a steel structure; The damper device according to any one of claims 2 to 8, which is provided to connect between the first structure and the second structure and to buffer the relative displacement between the first structure and the second structure ; ≪ / RTI >

According to an embodiment of the present invention as described above, damage to the structure can be prevented in advance by constructing the damper device to concentrate stress on the damper device connecting the structures so as to yield the preceding damages.

According to an embodiment of the present invention, stress is concentrated on the damper device due to relative movement between the first structure and the second structure, and when the damper device is damaged, the damper device can be replaced, There is an easy effect.

1 and 2 are views showing the behavior of a core part and a frame part of a conventional building structure.
FIG. 2 is a view showing a joint portion between a core portion and a frame portion of a conventional building structure.
3 is a view illustrating a joint portion of a building structure according to an embodiment of the present invention.
4 is an exploded perspective view of a damper device according to an embodiment of the present invention.
5 is an assembled perspective view of Fig.
6A and 6B are cross-sectional views showing the damper device before and after deformation of the damper device of the present invention.
7A is a perspective view showing the core fixing unit of the damper device of the present invention.
7B is a cross-sectional view taken along line AA 'in FIG. 7A.
8A is a perspective view showing a damper fixing unit of the damper device of the present invention.
8B is a sectional view in the direction of BB 'in Fig. 8A.
FIGS. 9A and 9B are views showing a test structure of a building structure according to an embodiment of the present invention.
10 (a) is a view showing a damage distribution test result of the test body in the case where the joint portion is formed by rigidly bonding the core portion and the frame portion as in the conventional method (CASE 1).
10 (b) is a diagram showing a damage distribution test result of an experiment body in which a first structure and a second structure are connected by a damper device, as in the case of the present invention (CASE 2).

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

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

Referring to FIGS. 4 and 5, the damper device 10 according to an embodiment of the present invention may include a core fixing unit 100 and a damper fixing unit 200.

As shown in FIG. 2, in the case of the conventional method, there is a problem that a joint portion of the structure is excessively increased.

3, the first structure 20 and the second structure 30, which have different vibration periods, are connected to each other by the damper device 10, so that the first structure 20 and the second structure 30 And the joints of the first structure 20 and the second structure 30 are greatly reduced, thereby improving the workability in the field.

The present invention relates to a damper device (10) provided to connect a first structure (20) and a second structure (30) having different vibration periods to each other and to buffer relative displacement caused by a difference in vibration period.

5, the damper device 10 of the present invention includes a core fixing part 100 fixed to the first structure 20 and a fixing part 100 fixed to the second structure 30 at one side, And a damper fusing unit 200 fixed to the core fixing unit 100 and installed to be deformable in a connection direction between the first structure 20 and the second structure 30, The damper fixing unit 200 includes a fixed fixing member 210 fixed to the core fixing unit 100 and a fixed fixing member 210 fixed to the second structure 30 and movably installed with respect to the fixed fixing member 210. [ The fixing fixture member 210 and the moving fixture member 230 can be moved while being plastically deformed in the direction of connection between the first structure 20 and the second structure 30, And a damper plate 250 connected to the damper plate 250.

The first structure 20 and the second structure 30 may be constructed of structures having different natural periods of vibration due to seismic loads or the like.

6A and 6B, the core fixing unit 100 may be installed in the first structure 20, and the damper fixing unit 200 may be installed in the second structure 30. As shown in FIGS.

Referring to FIG. 3, since the first structure 20 is designed to mainly resist a horizontal load, the shear rigidity with respect to the lateral load is relatively large and the mass is relatively small.

Since the second structure 30 mostly plays a role of supporting the vertical load, the shear rigidity is relatively smaller and the mass is larger than that of the core portion.

The first structure 20 having a relatively short natural period due to the earthquake vibrates rapidly at a small amplitude and the natural period of the second structure slowly oscillates at a large amplitude.

Therefore, the relative displacement is generated between the first structure 20 and the second structure 30, and the damper device 10 installed between the two structures undergoes plastic deformation, leading to yielding the vibration energy generated by the relative displacement The structure structure in which the first structure 20 and the second structure 30 are combined with each other can maintain the elastic state and minimize damage to the structure.

The damper device 10 installed between the first structure 20 and the second structure 30 may be configured so that the damper device 10 is deformed (preceded to yield) earlier than the structures, so that the first structure 20 and the second structure 30, 2 structure 30 absorbs the vibration energy generated by the relative displacement of the first structure 20 and the second structure 30 to maintain the elastic state in a state where the first structure 20 and the second structure 30 are coupled to minimize damage to the structure.

The core fixing part 100 is a part installed in the first structure 20 and the first structure 20 may be formed of a reinforced concrete (RC) structure or a steel reinforced concrete (SRC) structure.

7A and 7B, the core fixation unit 100 may include a support anchor body 150, a pair of fixed frames 110, and a guide frame 130. As shown in FIGS.

The core fixing unit 100 includes a supporting anchor body 150 which is fixedly embedded in the first structure 20 and a fixing anchor body 150 extending from the supporting anchor body 150 toward the moving fixing member 230, A pair of fixing frames 110 fixed to the fixing member 210 and a guide frame 130 connecting between the pair of fixing frames 110 and guiding the moving fixing member 230 to slide, .

7A, the supporting anchor body 150 includes a core anchor plate 151 that forms a mounting surface of the stationary frame 110, a second anchor plate 151 that extends from the back surface of the core anchor plate 151, Shaped buried anchor 153 to be buried and a resistance plate 155 fixed to the rear end of the buried anchor 153 to improve the supporting force.

The fixing frame 110 may include a horizontal fixing plate 111 formed on the upper side and a pair of vertical fixing plates 113 bent downward from the horizontal fixing plate 111.

The horizontal fixing plate 111 is fixed to the upper fixing plate 211 of the fixing fixing member 210 and the pair of vertical fixing plates 113 are fixed to the fixing fixing member 210, The side fusing plate 213 can be fixed to the pair of side fusing plates 213. [

8A and 8B, the damper fixing unit 200 is fixed to the second structure 30 at one side and the other side is fixed to the core fixing unit 100 and the first structure 20 ) And the second structure (30).

3, the direction of connection between the first structure 20 and the second structure 30 is the transverse direction and the main direction of deformation is the direction of connection between the first structure 20 and the second structure 30 Quot; direction "

Here, the connection direction between the first structure 20 and the second structure 30 includes a case where a main deformation direction is induced in the lateral direction and a minute deformation occurs in the longitudinal direction.

The damper fixing unit 200 includes a fixed fixing member 210 fixed to the core fixing unit 100 and a fixing member 210 fixed to the second structure 30 and movably installed with respect to the fixed fixing member 210 The fixing fixing member 210 and the moving fixing member 230 are movably connected to each other while being plastically deformed in the connecting direction of the moving fixing member 230 and the first structure 20 and the second structure 30, The damper plate 250 may be provided.

8A, the fixed fixing member 210 is a member fixed to the core fixing unit 100, and the fixed fixing member 210 includes an upper fixing plate 211 and a pair of side fixing plates 213 ).

The fixed fixing member 210 includes an upper fixing plate 211 fixed to a horizontal fixing plate 111 formed on the upper side of the fixing frame 110 and a lower fixing plate 211 bent downward from the upper fixing plate 211, And a pair of side fixing plates 213 fixed to the vertical fixing plate 113 bent downward from the lower fixing plate 111.

The upper fusing plate 211 is detachably bolted to a horizontal fixing plate 111 formed on the upper side of the fixing frame 110 and a pair of side fusing plates 213 May be detachably bolted to a pair of vertical fixing plates 113 of the fixed frame 110. [

Accordingly, the deformation of the damper device 10 of the present invention is concentrated by the relative movement of the first structure 20 and the second structure 30, so that when the damper device 10 is broken, the bolts are disassembled, Can be replaced and reused.

6A and 6B, the movable fusing member 230 is a member fixed to the second structure 30 and movably installed with respect to the fixed fusing member 210. As shown in Figs.

The movable fixing member 230 can be slidably inserted into the pair of fixed frames 110 and the movable space 190 formed between the guide frames 130. [

8A and 8B, the movable fusing member 230 may include a damper anchor plate 231, a pair of side frames 233, and a slide frame 235.

The movable fixing member 230 includes a damper anchor plate 231 fixed to the second structure 30 and a fixing member 230 extending from the damper anchor plate 231 toward the fixed fixing member 210, A pair of side frames 233 slidably installed between the fixed frames 110 of the guide frame 130 and slidably mounted on the guide frames 130, A frame 235 may be provided.

The side frame 233 may be provided in a trapezoid shape having a downwardly inclined surface in the direction of the fixed fixing member 210.

The damper plate 250 is plastically deformed in the connecting direction of the first structure 20 and the second structure 30 so that the fixing fixture member 210 and the moving fixture member 230 are deformed, As shown in Fig.

The damper plate 250 can relatively movably connect the fixed fixing member 210 and the movable fixing member 230.

The relative displacement between the first structure 20 and the second structure 30 can be absorbed and buffered through the damper plate 250 which is plastically deformed.

The damper plate 250 can be deformed by the relative displacement between the first structure 20 and the second structure 30 and the damper plate 250 is plastically deformed so that the movable fixing member 230 is fixedly fixed Relative movement with respect to the member 210 is possible.

8B, the damper plate 250 includes a damper main body 251 connecting the upper fusing plate 211 of the fixed fusing member 210 and the slide frame 235 of the moving fusing member 230, A slit 253, which is a hollow portion formed in the damper main body 251, may be formed.

The damper plate 250 connects the upper fusing plate 211 of the fixed fusing member 210 and the slide frame 235 of the moving fusing member 230 with the damper plate 250 interposed between the first structure 20 and the second structure 30 A plurality of damper plates 250 may be installed in a direction crossing the connecting direction.

The damper fixing unit 200 including the damper plate 250 is replaced when stress is concentrated on the damper device 10 of the present invention due to the relative movement of the first structure 20 and the second structure 30, And can be reused.

Therefore, the structure can be easily restored to the state before the damage to the structure, and the maintenance can be easily performed.

8B, the damper fixing unit 200 includes a damper block 270 protruding from the lower surface of the moving fixing member 230 and contacting a part of the guide frame 130 to reduce frictional force, As shown in FIG.

The damper block 270 protrudes from the lower surface of the slide frame 235 of the movable fixing member 230 and can reduce the frictional force by contacting a part of the upper surface of the guide frame 130 of the core fixing unit 100 .

Two damper blocks 270 may be provided on the lower surface of the movable fixing member 230 at a predetermined interval.

7B, the core fixing unit 100 includes a core block 170 protruding from the upper surface of the guide frame 130 and contacting a part of the moving fixing member 230 to reduce frictional force, As shown in FIG.

The core block 170 is protruded from the upper surface of the guide frame 130 and is capable of reducing frictional force by contacting a part of the lower surface of the slide frame 235 of the movable fixing member 230.

The core block 170 may be provided on the upper surface of the guide frame 130 with two core blocks 170 spaced apart from each other by a predetermined distance.

6A, the core block 170 and the damper block 270 are fixed to the moving fixing member 230 (see FIG. 6A) while the core fixing portion 100 and the damper fixing portion 200 are engaged with each other, In the direction of movement of the movable member.

At this time, as shown in FIG. 6B, the core block 170 and the damper block 270 can serve as a stopper member for restricting movement of one side of each other.

6A and 6B, the damper fixing unit 200 is detachably attachable to the second structure 30 and the fixed fixing member 210 via the fastening member T .

The deformation of the damper device 10 of the present invention is concentrated due to the relative displacement between the first structure 20 and the second structure 30 so that the damper device 10 is reused can do.

For example, the damper fixing unit 200 may be detachably bolted to the second structure 30 and the fixed fixing member 210.

Next, the building structure will be described in detail with reference to FIGS. 3 to 10. FIG.

3 to 10, a building structure according to an embodiment of the present invention may include a first structure 20, a second structure 30, and a damper device 10.

Referring to FIGS. 3 and 6A and 6B, the building structure includes a first structure 20 forming a core portion of a building and having a reinforced concrete (RC) structure or a steel-reinforced concrete (SRC) structure, A second structure 30 formed of a steel frame structure and a second structure 30 connected between the first structure 20 and the second structure 30 to form an outer frame portion of the first structure 20, The damper device 10 may be provided to damp the relative displacement between the second structures 30.

As shown in FIG. 3, the first structure 20 forms the core portion of the building, and the second structure 30 forms the outer frame portion of the building.

As shown in FIG. 3, the first structure 20 forms a core portion of the building, and may be provided with a reinforced concrete (RC) structure or a steel reinforced concrete (SRC) structure.

The damper device 10 is constructed such that the supporting anchor body 150 of the core fixing part 100 is embedded in the concrete forming the reinforced concrete RC structure or the steel reinforced concrete concrete structure Can be fixed.

As shown in FIG. 3, the second structure 30 forms an outer frame portion of the building, and may be provided with a steel frame structure.

The damper device 10 is fixed to the second structure 30 while being bolted to the joint plate 31 provided on a steel member such as an H-shaped steel or the like forming a steel frame structure of the damper fixing part 200 .

The second structure 30 may have a vibration period different from that of the first structure 20 and the damper device 10 may have a vibration period between the first structure 20 and the second structure 30, The relative displacement occurring due to the difference between the first and second axes can be buffered.

Since the first structure 20 forming the core portion is designed mainly to resist the horizontal load, the shear rigidity with respect to the lateral load is relatively large and the mass is small.

The second structure 30 forming the outer frame portion has a relatively large shearing rigidity and a larger mass than the core portion because it largely supports the vertical load.

The core portion having a relatively short natural period due to the earthquake vibrates rapidly at a small amplitude, and the outer frame portion having a long natural period vibrates slowly at a large amplitude.

Accordingly, relative displacement occurs between the core part and the outer frame part, and the damper device 10 installed between the two structures is plastically deformed to yield the preceding vibration, thereby absorbing the vibration energy generated by the relative displacement, The building structure to which the second structure 30 is coupled maintains an elastic state, so that damage to the structure can be minimized.

Referring to FIGS. 9A to 10, a damage distribution test result using an experiment of the conventional method (CASE 1) and an experiment of the method of the present invention (CASE 2) will be described below.

FIGS. 9A and 9B are views showing a test structure of a building structure according to an embodiment of the present invention.

10A shows a result of the damage distribution test of the test specimen in the case where the joint portion 3 is formed by joining the core portion 1 and the frame portion 2 to each other like the conventional method (CASE 1) FIG.

10B is a view showing a damage distribution test result of an experiment body in which a first structure 20 and a second structure 30 are connected to each other by a damper device 10 like the method of the present invention (CASE 2) to be.

CASE 1 (Experimental body of the conventional method): The core part 1 and the frame part 2 are rigidly joined to form a joint part 3

CASE 2 (Test Subject of the Present Invention): The first structure 20 and the second structure 30 are connected by the damper device 10

Experiments of the conventional method (CASE 1) and the method of the present invention (CASE 2) were respectively installed, and experiments were performed by sequentially applying the steps carried out by the shaking table 40 to the test specimen.

Experiments of the conventional method (CASE 1) and the method of the present invention (CASE 2) are installed and the experiment is performed by applying the step with the shaking table 40. The maximum response acceleration (PGA) The experiment was carried out while changing to 5 steps.

Step 1: Maximum response acceleration (PGA: 238.7 cm / s ² )

Step 3: Maximum response acceleration (PGA: 341.0 cm / s ² )

Step 3: Maximum response acceleration (PGA: 443.3 cm / s ² )

Step 4: Maximum response acceleration (PGA: 545.6 cm / s ² )

Step 5: Maximum response acceleration (PGA: 647.9 cm / s ² )

In the excitation stage in which the specimen maintains elasticity, the natural cycles of the conventional system (CASE 1) and the inventive system (CASE 2) were all 0.35 seconds.

The natural period of the conventional method (CASE 1) was 0.57 seconds which was increased by about 1.6 times due to the damage of the main member of the test specimen in the final excitation step (step 5) after the plasticization progressed. However, in the case of the CASE 2 of the present invention It can be seen that damage is concentrated in the damper device 10 and the natural period is increased by 1.3 times to 0.46 seconds and the damage of the main members of the test specimen corresponding to the first structure 20 and the second structure 30 is reduced .

For reference, FIG. 10 shows a triangle with minor damage (0.0015 to 0.003) in the case of minor damage, and FIG. 10 shows a circle with minor damage (0.003 to 0.005) In considerable cases (over 0.005), it is shown as a square.

As shown in FIG. 10 (a), in the case of the conventional method (CASE 1), damage tends to be concentrated on the first floor column of the test body.

On the other hand, as shown in FIG. 10 (b), in the case of the CASE 2 of the present invention, the main structural members of the test body hardly suffered damage, and damage was concentrated on the damper device 10 Damage was uniformly dispersed in the damper device 10 of each layer in the excitation stage.

Therefore, it can be seen that, in the case of the CASE 2 of the present invention, the damages of the main structural members can be minimized by intentionally concentrating the input energy due to the earthquake vibration to the damper device 10 through the experiment of the shaking table 40.

Accordingly, the building structure of the present invention is constructed so that the stress is concentrated on the damper device 10 connecting the first structure 20 and the second structure 30, leading to a preceding yield, thereby preventing damage to the structure in advance , The damper device 10 can be replaced when the damper device 10 is damaged due to the concentration of stress, so that the damper device 10 can be easily restored to its original state before the damage to the damper device 10, thereby facilitating maintenance.

It goes without saying that various embodiments of the damper device 10 having various embodiments described above may be applied to the building structure of the present invention.

The structure of the core fixing unit 100 and the damper fixing unit 200 of the damper device 10 utilized in the building structure is the same as that of the damper device 10 as described above, Omit to avoid.

Although the embodiments of the present invention have been described in detail, it is to be understood that the scope of the present invention is not limited to the above embodiments and various changes and modifications may be made without departing from the scope of the present invention. It will be obvious to those of ordinary skill in the art.

1: core part 2: frame part
3:
10: damper device 20: first structure
30: second structure 31: bonding plate
40: Shake table 100: Core fixing unit
110: fixed frame 111: horizontal fixing plate
113: vertical fixing plate 130: guide frame
150: Supporting anchor body 151: Core anchor plate
153: buried anchor 155: resistive plate
170: core block 190: moving space part
200: damper fixing unit 210: fixed fixing member
211: upper fixing plate 213: side fixing plate
230: moving fixing member 231: damper anchor plate
233: side frame 235: slide frame
250: damper plate 251: damper main body
253: Slit 270: Damper block
T: fastening member

Claims (9)

delete A damper device for connecting a first structure and a second structure having different vibration periods to each other and for buffering a relative displacement caused by a difference in vibration period,
A core fixing unit fixed to the first structure;
And a damper fixing unit fixed at one side to the second structure and at the other side to the core fixing unit and being deformably installed in a connection direction of the first structure and the second structure,
The damper fixing unit includes:
A fixing fixation member fixed to the core fixing unit;
A movable fusing member fixed to the second structure and movably installed with respect to the fixed fusing member; And
And a damper plate movably connecting the fixed fixing member and the moving fixing member while being plastic-deformed in a connection direction of the first structure and the second structure,
The core fixing unit includes:
A supporting anchor body embedded in the first structure;
A pair of fixed frames extending from the supporting anchor body toward the moving fixing member and fixed to the fixed fixing member; And
And a guide frame connecting between the pair of fixed frames and guiding the movable fixing member to slide.
The image forming apparatus according to claim 2,
Wherein the damper device is slidably inserted into the pair of fixed frames and the moving space formed between the pair of guide frames.
The image forming apparatus according to claim 2,
A fixed damper anchor plate of the second structure;
A pair of side frames extending from the damper anchor plate toward the fixed fixing member and slidably installed between the pair of fixed frames; And
And a slide frame connected to the pair of side frames and slidably mounted on the guide frame.
The image forming apparatus according to claim 2, wherein the damper fixing unit comprises:
And a damper block protruding from a lower surface of the moving fixing member and contacting a part of the guide frame to reduce frictional force.
6. The image forming apparatus according to claim 5,
And a core block protruding from an upper surface of the guide frame and contacting a part of the moving fixation member to reduce a frictional force.
7. The compressor according to claim 6, wherein the core block and the damper block
Wherein the core fixing unit and the damper fixing unit are disposed apart from each other at a predetermined interval in a moving direction of the moving fixing member,
The core block and the damper block,
And the damper device acts as a stopper member for restricting movement of one side of the damper device.
3. The method of claim 2,
Wherein the damper fixing unit is detachably attached to the second structure and the fixing fixing member so as to be replaceable.
A first structure that forms a core portion of a building and is provided with a reinforced concrete (RC) structure or a steel reinforced concrete (SRC) structure;
A second structure forming an outer frame portion of the building and having a steel structure; And
The damper device according to any one of claims 2 to 8, which is provided to connect between the first structure and the second structure and to buffer the relative displacement between the first structure and the second structure Included building structure.

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