KR20120124606A - Damping device for the control of horizontal displacement due to earthquake loadings - Google Patents

Abstract

PURPOSE: A damping device for reducing horizontal vibration displacement caused by an earthquake load is provided to efficiently reduce horizontal change of an actual building by enhancing a damping effect of a horizontal direction displacement by amplifying minute horizontal direction displacement. CONSTITUTION: A damping device for reducing horizontal vibration displacement caused by an earthquake load comprises a bar shaped displacement transfer link(110), a displacement amplification link(120), a rotation panel joint(130), and a first damper(140). One end of the displacement transfer link is joined to an edge where a first horizontal panel and a side wall(13) meet. The displacement amplification link comprises a first bean(122), a third beam(126), a second beam(124), a fourth beam(128), and a first panel joint(129a), a second panel joint(129b), a third panel joint(129c), and a fourth panel joint(129d). A first beam is formed in a position facing the first horizontal panel. The third beam is formed in a position facing the second horizontal panel. The second and fourth beams are formed in between the third and first beams. The first panel joint is formed in a position where the first and second beams are connected. The second panel joint is formed in a position where the second and third beams are connected. The third panel joint is formed in a position where the third and fourth beams are connected. The fourth panel joint is formed in a position where the fourth and first beams are connected. The rotation panel joint is fixed to the second horizontal panel and joined to the second panel joint of the displacement amplification link by a hinge. The first damper comprises a body(140a) and a transfer beam(140b).

Description

Damping device for lateral vibration displacement reduction due to earthquake load {DAMPING DEVICE FOR THE CONTROL OF HORIZONTAL DISPLACEMENT DUE TO EARTHQUAKE LOADINGS}

The present invention relates to a damping device for reducing the lateral vibration displacement caused by the earthquake load, and more particularly, in order to reduce the lateral deformation of the actual building, the lateral displacement of the building caused by the earthquake, etc. The present invention relates to a damping device for reducing the lateral vibration displacement caused by the earthquake load that can be installed on all walls in a building.

In general, the vibration damper absorbs vibration energy to reduce deformation of the medium through which vibration is transmitted. Conventionally, in order to prevent building, in particular, as shown in Figure 1a, by linking the link structure and the vibration damper between the first horizontal plate located in the upper and the second horizontal plate located in the lower, to prevent the deformation of the floor between buildings. . In the conventional vibration damping device, since the vibration damper is located on the second horizontal plate, a pair of connecting members connected to both ends of the first horizontal plate meet at one point and become triangular, and the transverse displacement of the building is connected to the connecting member. When a displacement difference is generated at one point through, the displacement difference is directly attenuated by the vibration suppressor without amplification.

However, when the vibration damping device is installed between the floors of the building, the link is installed across the entire area of the wall, so it cannot be applied to a wall that requires a structure for drilling the wall, such as a window. If the transverse displacement changes minutely in each layer, the vibration damper cannot effectively dampen the displacement. Therefore, even in the case of high-rise buildings, even when the lateral displacement occurring in each floor is minute, as shown in FIG. 1B, there is still a problem that the safety of the building is not guaranteed because the displacement difference between the lower floor and the higher floor increases when the displacement difference is combined. .

Therefore, in recent years, there is a need for a damping device for lateral vibration displacement reduction due to earthquake loads that can be applied to all walls and can effectively exhibit vibration damping performance even with relatively small displacements by amplifying the lateral displacement.

The problem to be solved by the present invention can be applied to all the floors and walls of the building because the front openness is secured, by amplifying the fine lateral displacement to improve the damping effect of the lateral displacement, the actual lateral deformation of the building It is to provide a damping device for reducing the lateral vibration displacement due to seismic load that can be effectively reduced.

In order to solve the above problems, the present invention provides a pair of horizontal plates located above and below each floor of a building and installed so that the lateral displacement applied to the floors constituted by sidewalls constructed between the pair of horizontal plates is attenuated. In that,

A bar-shaped displacement transfer link including one end coupled to a corner position where the first horizontal plate and the sidewall meet each other, and the other end positioned opposite the one end of the pair of horizontal plates;

A first beam formed at a position opposed to the first horizontal plate among the pair of horizontal plates, a third beam formed at a position opposite to the second horizontal plate, and a third formed between the third beam and the first beam A first node formed at a position where the first beam and a second beam are connected, a second node formed at a position where the second beam and a third beam are connected, and a third beam and a fourth beam A displacement amplification link having a third node formed at a position where four beams are connected and a fourth node formed at a position at which the fourth beam and the first beam are connected;

A rotation node fixed to the second horizontal plate and hinged to the second node of the displacement amplifier link; And

A body fixed to the second horizontal plate, and a transmission beam coupled to the body so that the lateral displacement is attenuated and having an end hinged to one of the third node and the fourth beam of the displacement amplifier link. 1 damper; including,

The displacement amplifier link provides a damping device for reducing the lateral vibration displacement caused by the earthquake load is formed in a quadrangular form by the first beam to the fourth beam is fixed to each other sequentially.

According to one embodiment of the invention, the displacement amplifier link is rectangular,

Preferably, the third beam is formed longer than the second beam.

In addition, the body is fixed to the first horizontal plate, and the transmission beam is coupled to the body so that the lateral displacement is attenuated and the end is hinged to any one of the fourth node and the fourth beam of the displacement amplifier link It is preferable to further include a second damper.

In addition, the inner side of the corner of the displacement amplification link is connected to any two or more of the first to fourth beams, it is preferable to further include a support beam inclinedly connected to reinforce the stiffness of the corner.

In addition, the present invention, in order to solve the above problems, is formed perpendicular to each floor of the building, a pair of horizontal plates located on the upper and lower portions of each floor of the building are respectively coupled to the upper and lower and formed between the upper and lower It is installed in the building wall where a pair of wall sides are formed,

A bar-shaped transverse displacement transfer link including one end coupled to a corner position where the first horizontal plate and the side wall meet, and the other end opposite to the one end of the pair of horizontal plates;

A first beam formed at a position opposed to the first horizontal plate among the pair of horizontal plates, a third beam formed at a position opposite to the second horizontal plate, and a third formed between the third beam and the first beam A first node formed at a position where the first beam and a second beam are connected, a second node formed at a position where the second beam and a third beam are connected, and a third beam and a fourth beam A displacement amplification link having a third node formed at a position where four beams are connected and a fourth node formed at a position at which the fourth beam and the first beam are connected;

A rotation node fixed to the second horizontal plate and hinged to the second node of the displacement amplifier link; And

A body fixed to the second horizontal plate, and a transmission beam coupled to the body so that the lateral displacement is attenuated and having an end hinged to one of the third node and the fourth beam of the displacement amplifier link. 1 damper; including,

The displacement amplifier link provides a damping device for reducing the lateral vibration displacement caused by the earthquake load is formed in a quadrangular form by the first beam to the fourth beam is fixed to each other sequentially.

According to one embodiment of the invention, the displacement amplifier link is rectangular,

Preferably, the third beam is formed longer than the second beam.

In addition, the body is fixed to the first horizontal plate, and the transmission beam is coupled to the body so that the lateral displacement is attenuated and the end is hinged to any one of the fourth node and the fourth beam of the displacement amplifier link It is preferable to further include a second damper.

In addition, the inner side of the corner of the displacement amplification link is connected to any two or more of the first to fourth beams, it is preferable to further include a support beam inclinedly connected to reinforce the stiffness of the corner.

According to the present invention, since it can be installed regardless of whether the wall is perforated or not, it can be applied to all walls according to the design characteristics of the building, and the seismic performance is optimal because it can be installed at an appropriate position according to the structural characteristics of the building. We can build building. In addition, since the transverse displacement generated in the building is amplified by the rotational displacement in the apparatus and then attenuated with respect to the amplified rotational displacement, the transverse displacement can be more effectively attenuated, which causes an earthquake damage. Can be prevented. In addition, since the front openness is secured compared to the conventional diagonal brace, it is possible to build a structure that penetrates the wall, which is very advantageous in terms of utilization of space.

1 is a front view showing a lateral displacement of a building equipped with a general vibration damper and a general vibration damper.
2 is a front view of a damping device for reducing the lateral vibration displacement caused by the earthquake load according to various embodiments of the present invention.
3 is a schematic diagram of a damping device for reducing the lateral vibration displacement caused by the earthquake load according to an embodiment of the present invention.
4 is a schematic diagram of a building to which a damping device for reducing lateral vibration displacement due to earthquake load according to the present invention is applied.

Hereinafter, the present invention will be described in more detail with reference to preferred embodiments. It will be apparent to those skilled in the art, however, that these examples are provided to further illustrate the present invention, and the scope of the present invention is not limited thereto.

Since the enactment of the Enforcement Ordinance for Seismic Design in Korea, seismic design has become mandatory for buildings of a certain size since 1988. Seismic reinforcement methods of reinforced concrete buildings include strength resistance type to improve the strength of building and toughness resistance type and vibration damping method to improve deformation capacity of building. The seismic reinforcement method of strength resistance type reinforces such as increasing the bearing wall or increases the thickness of the existing wall. The toughness resistance type seismic reinforcement method reinforces around individual members such as columns and beams. .

The present invention is a device that can use the vibration damping method for controlling the shaking of the building, there is no restriction on the view right or usability of the existing building already constructed, can be additionally installed for seismic reinforcement without changing the shape, new building construction By installing in the interior space of the building during the process, it is possible to minimize the amount of concrete or reinforcing bars additionally applied to the building for seismic reinforcement, and does not damage the existing viewing area. Therefore, it is possible to effectively improve the vibration damping performance while reducing the cost of building construction. The present invention may be installed in the wall attenuating device for reducing the lateral vibration displacement caused by the earthquake load in the process of reinforcing the wall and the new construction of the building.

Figure 2 is a front view of the damping device for reducing the lateral vibration displacement caused by the earthquake load according to various embodiments of the present invention, Figure 2a is a horizontal vibration displacement reduction caused by the earthquake load according to an embodiment of the present invention Figure 2b is a front view of the damping device, Figure 2b is a front view of the damping device for reducing the lateral vibration displacement caused by the earthquake load according to another embodiment of the present invention, Figure 2c is another embodiment of the present invention The front view of the damping device for reducing the lateral vibration displacement by the earthquake load according to the example is shown.

First, in the case of installing a vibration damping transverse displacement attenuator in a space within a floor of a building, a vibration damping transverse displacement attenuator according to an embodiment of the present invention includes a pair of horizontal plates located above and below each floor of the building, and By installing so that the lateral displacement applied to the interlayer composed of the side wall 13 constructed between the pair of horizontal plates,

Among the pair of horizontal plates, a bar-shaped displacement transfer link including one end coupled to a corner position where the first horizontal plate and the sidewall 13 meet, and the other end positioned opposite the one end ( 110);

Among the pair of horizontal plates, a first beam 122 formed at a position facing the first horizontal plate, a third beam 126 formed at a position facing the second horizontal plate, and the third beam 126. A first node including a second beam 124 and a fourth beam 128 formed between the first beam 122 and the first beam 122 and the second beam 124. 129a, a second node 129b formed at a position where the second beam 124 and a third beam 126 are connected, and a second formed at a position where the third beam 126 and the fourth beam 128 are connected. A displacement amplification link (120) having three nodes (129c) and a fourth node (129d) formed at a position where the fourth beam (128) and the first beam (122) are connected;

A rotation node 130 fixed to the second horizontal plate and hinged to the second node 129b of the displacement amplification link 120; And

The body 140a fixed to the second horizontal plate, and the transmission coupled to the body 140a so that the lateral displacement is attenuated, the end is hinged to the fourth beam 128 of the displacement amplifier link 120 It includes; a first damper 140 is provided with a beam (140b),

The displacement amplification link 120 has the first beam 122 to the fourth beam 128 are sequentially fixed to each other is formed in a rectangular shape.

Here, the first horizontal plate and the second horizontal plate are any one of the beam 11 located on the upper surface of the floor and the bottom plate 12 located on the lower surface of the floor. For example, when the first horizontal plate is the beam 11, the second horizontal plate is the bottom plate 12, and when the first horizontal plate is the bottom plate 12, the second horizontal plate is the beam 11. ) That is, although the beam 11 is applied to the first horizontal plate and the bottom plate 12 is applied to the second horizontal plate in FIG. 2, the lateral vibration displacement reduction due to the earthquake load according to the present invention is shown. The damping device can be applied to the reverse.

In addition, when the damping device for reducing the lateral vibration displacement caused by the earthquake load in the wall of the building, the damping device for reducing the lateral vibration displacement caused by the earthquake load according to an embodiment of the present invention, each floor of the building It is formed perpendicular to, and a pair of horizontal plates located on the upper and lower portions of each floor of the building are respectively installed in the building wall formed with a pair of wall side 23 formed between the upper and lower and formed between the upper and lower, respectively. ,

Of the pair of horizontal plates, a bar-shaped transverse displacement including one end coupled to the corner position where the first horizontal plate and the wall side surface 23 meet, and the other end located opposite the one end Transmission link 110;

Among the pair of horizontal plates, a first beam 122 formed at a position facing the first horizontal plate, a third beam 126 formed at a position facing the second horizontal plate, and the third beam 126. A first node including a second beam 124 and a fourth beam 128 formed between the first beam 122 and the first beam 122 and the second beam 124. 129a, a second node 129b formed at a position where the second beam 124 and a third beam 126 are connected, and a second formed at a position where the third beam 126 and the fourth beam 128 are connected. A displacement amplification link (120) having three nodes (129c) and a fourth node (129d) formed at a position where the fourth beam (128) and the first beam (122) are connected;

A rotation node 130 fixed to the second horizontal plate and hinged to the second node 129b of the displacement amplification link 120; And

The body 140a fixed to the second horizontal plate, and the transmission coupled to the body 140a so that the lateral displacement is attenuated, the end is hinged to the fourth beam 128 of the displacement amplifier link 120 It includes; a first damper 140 is provided with a beam (140b),

The displacement amplification link 120 has the first beam 122 to the fourth beam 128 are sequentially fixed to each other is formed in a rectangular shape. That is, the vibration damping lateral displacement damper according to the present invention is formed in the same structure both when applied to the wall, or applied to the space within the floor of the building.

The vibration damping lateral displacement attenuator according to an embodiment of the present invention uses a rectangular displacement amplifier link 120 to amplify the lateral displacement applied to each floor of the building. The displacement transfer link 110 and the rotation node 130 are coupled to the positions of the first horizontal plate and the second horizontal plate, respectively. The rotating node 130 is fixedly mounted on the second horizontal plate and the displacement transfer link 110 is installed on the first horizontal plate to transmit the maximum value of the lateral displacement in one layer to the displacement amplifier link 120. That is, since the difference in the transverse position of the first horizontal plate relative to the second horizontal plate is the maximum value of the transverse displacement occurring between the layers, the displacement transfer link 110 and the rotation node 130 are respectively connected to the first horizontal plate. And the second horizontal plate. The first node 129a of the displacement amplification link 120 is hinged to the displacement transmission link 110, and the second node 129b of the displacement amplification link 120 is hinged to the rotation node 130. Therefore, when the lateral displacement occurs, the displacement transfer link 110 is moved according to the lateral displacement of the first horizontal plate, the displacement amplifier link 120 is hinged to the rotation node 130, the second node The third node 129c of the displacement amplification link 120 has a lateral displacement of the displacement transmission link 110 by the length ratio of the second beam 124 and the third beam 126 while rotating with reference to 129b. It is amplified by the vertical displacement at the position. Accordingly, the lateral displacement value amplified by the first damper 140 installed on the second horizontal plate and hinged on the third node 129c or the fourth beam 128 is attenuated. When the displacement value is attenuated by the first damper 140 as described above, the transverse displacement transmitted from the first node 129a is also attenuated while the transverse displacement acting on each floor of the building is attenuated.

The displacement amplification link 120 is manufactured in a quadrangular shape so as to prevent deformation from occurring in the link during the amplification of the displacement while maximizing the amplification in the process of the transverse displacement being amplified by the rotational displacement. In particular, when the displacement amplification link 120 is manufactured in a rectangular shape, the load applied to each of the first beam 122 to the fourth beam 128 constituting the displacement amplification link 120 can be smoothly dispersed. In addition, it is possible to secure a space in which structures are installed between floors. For example, in the case of a window formed through a wall, since the frame is generally formed in a rectangular shape, the damping for lateral vibration displacement reduction due to the earthquake load on the wall is irrespective of the size of the window to be installed. You can install the device. Rather, the larger the size of the displacement amplification link 120, the greater the lateral displacement is amplified to a larger value, so that the damping for the lateral vibration displacement reduction due to the earthquake load, even in the case of the wall wall is installed as a glass window The device is applicable. In this case, the frame itself of the window may be used as the displacement amplifier link 120.

Since the third beam 126 rotates by the transverse displacement, the maximum value of the rotational displacement is transmitted to the fourth beam 128 coupled to the end of the third beam 126. Therefore, the first damper 140 is hinged to any point on the third node 129c or the fourth beam 128 to which the third beam 126 and the fourth beam 128 are connected. At this time, to more effectively control the rotational displacement transmitted to the fourth beam 128, as shown in Figure 2b, the body 150a fixed to the first horizontal plate, and the transverse displacement is attenuated The second damper 150 is coupled to the body 150a and has a transmission beam 150b having an end hinged to the fourth node 129d or the fourth beam 128 of the displacement amplifier link 120. It may further include. The second damper 150 may also be hinged to one position of the fourth beam 128 as well as the fourth node 129d. Here, the first damper 140 is installed at a position near the third beam 126 side of the fourth beam 128, and the second damper 150 is the first beam 122 of the fourth beam 128. By providing at a position close to the side), the transverse displacement can be effectively attenuated.

The support beam 160 may be formed inside the corner of the displacement amplifier link 120 in which at least two of the first beam 122 to the fourth beam 128 are connected. That is, as shown in FIG. 2C, the support beam 160 is formed to be inclinedly connected to the first beam 122 and the second beam 124, and is inclinedly connected to the second beam 124 and the third beam 126. The support beam 160 is formed obliquely connected to the support beam 160, the third beam 126 and the fourth beam 128, and the support beam is formed obliquely connected to the fourth beam 128 and the first beam 122 ( By providing a 160, it is possible to prevent the deformation in the displacement amplifier link 120 during the process of the displacement is attenuated.

Figure 3 is a schematic diagram of the damping device for reducing the lateral vibration displacement by the earthquake load according to an embodiment of the present invention, in order to show the displacement amplified in the third node transverse vibration displacement by the earthquake load A diagram schematically illustrating a displacement transfer link, a rotation node, and a displacement amplifier link of a damping device for reduction. Here, the first damper and the second damper are omitted in order to indicate the magnitude of the amplified displacement. 4 is a schematic view of a building to which a damping device for reducing lateral vibration displacement due to seismic loads according to the present invention is shown.

The displacement transmission link 110, the rotation node 130, and the displacement amplifier link 120 of the damping device for reducing the lateral vibration displacement due to the earthquake load are coupled as shown in FIG. 3A. In this case, the lengths of the second beam 124 and the fourth beam 128 of the displacement amplifier link 120 are x, and the lengths of the first beam 122 and the third beam 126 are nx. In this case, n is a value greater than 1, and the first beam 122 and the third beam 126 are longer than the second beam 124 and the fourth beam 128.

The displacement amplification link 120 formed as described above, when the displacement transmission link 110 coupled to the first horizontal plate transmits the lateral displacement δ ₁ , as shown in FIG. 3B, the position of the first node 129a. The displacement β ₁ value of the first node 129a is generated while moving. When the third beam 126 is rotated by the rotation angle α of the second beam 124, the position of the third node 129c is moved, and the displacement β ₂ value of the third node 129c is also generated. do. Here, the displacement damped by the first damper 140 is the displacement β ₂ of the third node 129c.

The reason why the lateral displacement δ ₁ is amplified by the displacement β ₂ of the third node 129c by the displacement amplifier link 120 is, as shown in FIG. 3C, the length of the third beam 126. This is because is longer than the second beam 124. With the triangle is an isosceles triangle shown in Figure 3c, the displacement (β ₂₎ values of the first node deflection of (129a) (β ₁₎ value, and a third node (129c) can be calculated by mathematical formula below.

First, the displacement β ₁ value of the first node 129a may be obtained as shown in Equation 1.

In addition, the displacement β ₂ value of the third node 129c may be calculated as in Equation 2.

Therefore, in the third node 129c, the displacement value increases by the value β ₂ -β ₁ obtained from Equation 3 compared to the first node 129a.

At this time, since the difference between the displacement β ₁ value of the first node 129a and the transverse displacement value generated between each floor of the building is a small amount, the displacement β ₁ of the first node 129a and the horizontal displacement ( δ ₁ ) can be regarded as the same. That is, β ₁ acts because you can see that the same is δ _1, from a third node (129c) relative to the lateral displacement (δ ₁₎ is amplified by the values as set forth in equation (3) to the first damper 140 Done. Accordingly, the first damper 140 is adjusted in the lateral direction displacement amplification (δ _1), thereby attenuating a lateral displacement occurring in the actual first horizontal plate (δ _1).

Therefore, the building to which the damping device for reducing the lateral vibration displacement due to the earthquake load according to the present invention is applied to each floor as compared to the building to which the vibration damping lateral displacement damper is not applied as shown in FIG. 4. The magnitude of the displacement δ 'is small. Therefore, the magnitude of the transverse displacement nδ 'acting on the entire building is reduced by n (δ-δ') compared to the magnitude of the conventional transverse displacement nδ. Therefore, when the damping device for reducing the lateral vibration displacement due to the earthquake load according to the present invention is applied to the building, it is possible to easily attenuate the lateral displacement of the building, thereby improving the seismic performance of the building. .

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

110: displacement transfer link 120: displacement amplifier link
122: first beam 124: second beam
126: third beam 128: fourth beam
129a; Node 1 Node 129b: Node 2
129c: third node 129d: fourth node
130: rotation node 140: first damper
140a, 150a: Body 140b, 150b: Delivery beam
150: second damper 160: support beam

Claims (8)

In order to attenuate the transverse displacement applied between the floor consisting of a pair of horizontal plates located in the upper and lower portions of each floor of the building and the side walls constructed between the pair of horizontal plates,
A bar-shaped displacement transfer link including one end coupled to a corner position where the first horizontal plate and the sidewall meet each other, and the other end positioned opposite the one end of the pair of horizontal plates;
A first beam formed at a position opposed to the first horizontal plate among the pair of horizontal plates, a third beam formed at a position opposite to the second horizontal plate, and a third formed between the third beam and the first beam A first node formed at a position where the first beam and a second beam are connected, a second node formed at a position where the second beam and a third beam are connected, and a third beam and a fourth beam A displacement amplification link having a third node formed at a position where four beams are connected and a fourth node formed at a position at which the fourth beam and the first beam are connected;
A rotation node fixed to the second horizontal plate and hinged to the second node of the displacement amplifier link; And
A body fixed to the second horizontal plate, and a transmission beam coupled to the body so that the lateral displacement is attenuated and having an end hinged to one of the third node and the fourth beam of the displacement amplifier link. 1 damper; including,
The displacement amplification link is a damping device for reducing the lateral vibration displacement caused by the earthquake load is formed in a quadrangular form by the first beam to the fourth beam is fixed to each other sequentially. The method of claim 1,
The displacement amplifier link is rectangular,
And the third beam is formed longer than the second beam, and the damping device for reducing the lateral vibration displacement caused by the earthquake load. The method of claim 1,
A body fixed to the first horizontal plate, and a transmission beam coupled to the body so that the lateral displacement is attenuated and having an end hinged to one of the fourth node and the fourth beam of the displacement amplifier link. Damping device for reducing the lateral vibration displacement caused by the earthquake, characterized in that it further comprises a damper. The method of claim 1,
Transverse direction due to the earthquake load further comprises a support beam inclinedly connected to reinforce the stiffness of the corner inside the corner of the displacement amplification link that any two or more of the first to fourth beams are connected; Damping device for reducing vibration displacement. It is formed perpendicular to each floor of the building, a pair of horizontal plates located on the upper and lower parts of each floor of the building is installed in the building wall is coupled to the upper and lower, respectively, and a pair of wall side formed between the upper and lower In that,
A bar-shaped transverse displacement transfer link including one end coupled to a corner position where the first horizontal plate and the side wall meet, and the other end opposite to the one end of the pair of horizontal plates;
A first beam formed at a position opposed to the first horizontal plate among the pair of horizontal plates, a third beam formed at a position opposite to the second horizontal plate, and a third formed between the third beam and the first beam A first node formed at a position where the first beam and a second beam are connected, a second node formed at a position where the second beam and a third beam are connected, and a third beam and a fourth beam A displacement amplification link having a third node formed at a position where four beams are connected and a fourth node formed at a position at which the fourth beam and the first beam are connected;
A rotation node fixed to the second horizontal plate and hinged to the second node of the displacement amplifier link; And
A body fixed to the second horizontal plate, and a transmission beam coupled to the body so that the lateral displacement is attenuated and having an end hinged to one of the third node and the fourth beam of the displacement amplifier link. 1 damper; including,
The displacement amplification link is a damping device for reducing the lateral vibration displacement caused by the earthquake load is formed in a quadrangular form by the first beam to the fourth beam is fixed to each other sequentially. The method of claim 5,
The displacement amplifier link is rectangular,
And the third beam is formed longer than the second beam, and the damping device for reducing the lateral vibration displacement caused by the earthquake load. The method of claim 5,
A body fixed to the first horizontal plate, and a transmission beam coupled to the body so that the lateral displacement is attenuated and having an end hinged to one of the fourth node and the fourth beam of the displacement amplifier link. Damping device for reducing the lateral vibration displacement caused by the earthquake, characterized in that it further comprises a damper. The method of claim 5,
Transverse direction due to the earthquake load further comprises a support beam inclinedly connected to reinforce the stiffness of the corner inside the corner of the displacement amplification link that any two or more of the first to fourth beams are connected; Damping device for reducing vibration displacement.

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