KR20220085106A - Buttress assembly comprising fluid viscous damper - Google Patents

Abstract

The present invention relates to a sub-axis wall assembly for seismic reinforcement of a building, which is a sub-axis wall assembly installed on end walls located on both sides of a long side of an existing building, and a sub-axis wall located outside the longitudinal direction of the end wall: and the end wall and It includes; a viscous damping device for connecting the auxiliary wall, wherein the viscous damping device includes a fixing part fixed to the upper part of the existing building; a cylinder fixedly installed in the fixing part and filled with a viscous fluid in a chamber formed therein; a piston movably positioned within the viscous fluid within the chamber; a rod connecting the piston and the auxiliary wall; and an orifice formed through the piston in the longitudinal direction of the cylinder; provides a subaxial wall assembly comprising a.

Description

Buttress assembly comprising fluid viscous damper

The present invention relates to a sub-axis wall assembly, and more particularly, to a sub-axis wall assembly connecting an existing building and a sub-axis wall with a viscous damping device for seismic reinforcement of an existing building.

As a non-seismic designed building as a general wall or plate-type building, seismic reinforcement is performed because it cannot withstand high seismic loads.

In particular, buildings such as old (outdated) apartments do not have earthquake-resistant design, so earthquake-resistant reinforcement is urgently needed.

However, if seismic reinforcement is carried out in a general way in a multi-family house such as an apartment, it is necessary to relocate the occupants because seismic reinforcement must be carried out from the inside.

Although the migration of residents itself is a problem, there is a problem that the relocation period is long because the foundation construction for earthquake-resistant reinforcement is complicated.

Patent Document 1 relates to a method for external seismic reinforcement in consideration of disaster countermeasures, and relates to an external earthquake-resistant reinforcement method in which reinforcement structures are constructed on both sides of an existing building so that the occupants of the building can construct it while living there.

Although this method does not need to relocate the residents of the existing building, it has the disadvantages that the specific seismic reinforcement performance is not proven, the seismic reinforcement is not sufficient with only the proposed reinforcing structure, and a foundation work is required.

Patent Document 2, which is a registered patent of the present applicant, is intended to solve the problem of Patent Document 1 described above, in which a supporting wall is constructed outside the end wall of an existing building, and the end wall and the supporting wall are reinforced with webs, reinforcing bars, etc. and reinforcement members It provides a subaxial wall assembly to be connected using.

Patent Document 2 has advantages in that it is possible to secure the inter-dong spacing within the site of an existing building, simplifies the foundation construction, secures constructability, and does not require relocation of the occupants of the existing building.

However, in the case of Patent Document 2, as a significant number of reinforcement and reinforcement members are installed on the end wall of an existing building, a problem has been raised that the end wall may be damaged.

Therefore, it will be said that an earthquake-resistant reinforcement structure is needed to solve this problem.

JP 1999-081703 A KR 10-2093322 B1

Accordingly, the present invention has been devised to solve the problems of the prior art, and it is an object of the present invention to provide a sub-axis wall assembly capable of earthquake-resistant reinforcement while minimizing damage to an existing building during and after installation.

In order to achieve the above object, the present invention provides a sub-axis wall assembly installed on end walls located on both sides of a long side of an existing building, a sub-axis wall located outside the longitudinal direction of the end wall: and connecting the end wall and the sub-axis wall and a viscous damping device, wherein the viscous damping device includes: a fixing part fixed to the upper part of the existing building; a cylinder fixedly installed in the fixing part and filled with a viscous fluid in a chamber formed therein; a piston movably positioned within the viscous fluid within the chamber; a rod connecting the piston and the auxiliary wall; and an orifice formed through the piston along the longitudinal direction of the cylinder; provides a subaxial wall assembly comprising a.

As the cylinder moves by the lateral load generated in the existing building, compression or tension of the viscous fluid filled in the inner chamber is made by the piston, and the viscous fluid is compressed or stretched through the orifice in the cylinder. It is desirable to damp the transverse load as the cylinder and the piston move relative to each other in the transverse direction as they flow in the opposite direction to which they are tensioned.

It is preferable to further include an anchor for fixing the fixing part and the cylinder to the upper part of the existing building.

According to the auxiliary wall assembly according to the present invention, it is natural to have the effects of controlling the lateral displacement of the building, minimizing the change in the elevation of the existing building, and maintaining the plan of the existing building.

In addition, by connecting the upper part of the building and the supporting wall using a viscous damping device without any direct connection between the wall and the supporting wall, it is possible to obtain the effect of minimizing damage to the existing building, which is an earthquake-resistant reinforcement of an old building It can be said to be particularly effective in construction.

1 is a perspective view of an existing building and a sub-axis wall assembly constructed on the outside thereof.
Figure 2 is a perspective view showing a state in which the auxiliary wall assembly according to an embodiment of the present invention is installed.
Figure 3 is a longitudinal cross-sectional view showing a state in which the auxiliary wall assembly according to an embodiment of the present invention is installed.

The above objects, features and other advantages of the present invention will become more apparent by describing preferred embodiments of the present invention in detail with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be described based on the content throughout this specification.

In addition, the described embodiments are provided by way of example for the description of the invention, and do not limit the technical scope of the present invention.

Hereinafter, the 'existing building 10' is not limited as long as it is a building requiring seismic reinforcement, but in one embodiment, it may be a wall-type building or a plate-shaped building. However, it is assumed that a non-rectangular building having a different aspect ratio is used to determine the 'long side direction', which will be described later.

Hereinafter, the 'long side direction' refers to a direction extending toward both sidewalls with respect to the existing building 10 as a reference, and the 'short side direction' refers to the front side of the existing building 10 with respect to the existing building 10 and It means a direction formed toward the rear (see FIG. 1).

Hereinafter, the 'vertical direction' refers to the height of the existing building 10, that is, a longitudinal direction extending vertically.

Hereinafter, with reference to FIGS. 1 to 3, a subaxial wall assembly according to an embodiment of the present invention according to the present invention will be described in detail.

As shown in FIG. 1 , in the case where the existing building 10 has a wall structure, the auxiliary wall assembly is installed outside the long side of the short wall 11 located on both sides of the long side of the existing building 10 .

The auxiliary wall assembly is installed on the end wall 11 of the existing building 10, thereby reinforcing the seismic performance in the long side direction.

It can be installed on the barriers 12 located on both sides of the short side of the existing building 10, but in this case, a relatively large-scale construction is required, and in the case of a building that has been moved in, the windows of the building can be covered. There is a need to relocate the occupants, and there is a risk of impairing the aesthetics of the building, so it is preferable to be installed on the end wall 11

Therefore, construction is possible even if the residents do not move, and the building does not grow in the short side direction, so it does not reduce the interpersonal space at all in the site of the existing building 10 and does not impair the aesthetics of the building.

1 and 2 , the auxiliary wall assembly according to an embodiment of the present invention includes the auxiliary wall 100 and the viscous damping device 200 .

The auxiliary wall 100 is positioned at a predetermined distance apart from the outside in the long side direction of the existing building 10 . That is, they are spaced apart from the end wall 11 of the existing building 10 by a predetermined distance and positioned to face each other.

The supporting wall 100 may be constructed of reinforced concrete, and the specific design (size and reinforcement, etc.) of the supporting wall 100 is made based on the state of the existing building 10 and the expected earthquake-based shear force or moment.

The viscous damping device 200 is located between the end wall 11 and the auxiliary wall 100 of the existing building 10 .

Specifically, by connecting between the existing building 10 and the supporting wall 100, the vibration applied to the existing building 10 due to an earthquake or the like is dissipated so as to be attenuated.

2 and 3 , the viscous damping device 200 includes a fixing part 210 , a cylinder 220 , a piston 230 , a rod 240 , and an orifice 250 .

The fixing part 210 is located above the existing building 10 . Specifically, the fixing part 210 is integrally constructed on the upper part of the existing building 10 or fixed to the upper part of the building by driving the anchor 300 between the upper part of the building and the fixing part 210 .

The cylinder 220 is fixed inside the fixing part 210 . The cylinder 220 may be constructed together to be located inside the fixing part 210 when the fixing part 210 is constructed, and also the anchor 300 for fixing between the fixing part 210 and the existing building 10 . It can be fixed by extending to the lower part of the cylinder 220.

A chamber 221 , which is a predetermined space, is provided inside the cylinder 220 , and the viscous fluid F is filled in the chamber 221 .

The viscous fluid F filled in the chamber 221 is a fluid having a predetermined viscosity, and the type of the viscous fluid F may include, for example, silicone oil, but is not limited thereto. Likewise, it may be selected based on the condition of the existing building 10 and the expected earthquake-based shear force or moment.

The piston 230 is movably located inside the cylinder 220 . That is, it is positioned so as to be movable in the viscous fluid F filled in the chamber 221 , and the outer peripheral surface of the piston 230 is arranged to be close to the inner surface of the cylinder 220 .

The rod 240 has an elongated bar shape, and one side is connected to the piston 230 and the other side is connected to the subaxial wall 100 so that the viscous damping device 200 is connected to the subaxial wall 100 .

A plurality of orifices 250 are formed in the form of an elongated tube passing through the piston 230 in the longitudinal direction of the cylinder 220 .

A plurality of orifices 250 are formed along the circumferential direction of the piston 230 .

The diameter of the orifice 250 is also determined based on the condition of the existing building 10 and the expected seismic based shear force or moment.

When vibration, that is, a load in the lateral direction, occurs on the side of the existing building 10 in which the viscous damping device 200 is installed, the viscous fluid F filled in the inner chamber 221 of the cylinder 220 by the piston 230 (F) compression (or tension) of

The viscous fluid F compressed (or tensioned) by the load caused by the vibration of the existing building 10 flows to the opposite side where it is compressed (or tensioned) through the orifice 250 little by little, and the cylinder 220 and the piston ( 230) slowly moves in the lateral direction to damp the load.

The viscous fluid F cannot flow through the orifice 250 due to its own viscosity when a compressive force or tensile force is suddenly generated at a high speed, resulting in a strong resistance force.

On the other hand, when compressed or tensioned slowly at a slow rate, the internal fluid can sufficiently pass through the orifice 250, thereby generating a weak resistance force.

That is, the size of the load for each speed is determined according to the diameter of the orifice 250 and the degree of viscosity of the viscous fluid F.

As described above, since the viscous damping device 200 is connected between the end wall 11 and the auxiliary wall 100 of the existing building 10 , the auxiliary wall assembly resists the relative speed generated by the vibration of the existing building 10 . While doing so, the load is transmitted in the opposite direction to the movement direction of the existing building 10 to attenuate it.

In other words, when lateral deformation occurs in the existing building 10 due to wind or earthquake, the rigidity of the existing building 10 and the rigidity of the supporting wall 100 appropriately resist deformation, and a viscous damping device connecting them By dissipating kinetic energy by 200 , it is possible to control the lateral deformation of the existing building 10 .

*

According to the auxiliary wall assembly according to the present invention, as well as the effects of controlling the lateral displacement of the building, minimizing the change in elevation of the existing building, and maintaining the plan plan of the existing building, in addition, direct bonding of the wall and the supporting wall By connecting the upper part of the building and the supporting wall without any viscous damping device, the effect of minimizing damage to the existing building can be obtained, which is particularly effective in seismic reinforcement of old buildings.

In the above, the present specification has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but these are merely exemplary, and those skilled in the art can make various modifications and equivalent other modifications from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the protection scope of the present invention should be defined by the claims.

10: Existing building
11: barrier
12: barrier
100: support wall
200: viscous damping device
210: fixed part
220: cylinder
221: chamber
230: piston
240: load
250: orifice
300: anchor

Claims (3)

As a subaxial wall assembly installed on the end wall 11 located on both sides of the long side of the existing building 10,
A subaxial wall 100 positioned outside the long side of the end walls 11 and 12: And
It includes; a viscous damping device 200 connecting the end wall 11 and 12 and the auxiliary wall 100.
The viscous damping device 200,
a fixing part 210 fixed to the upper part of the existing building 10;
a cylinder 220 fixedly installed in the fixing part 210 and filled with a viscous fluid F in a chamber 221 formed therein;
a piston 230 movably located in the viscous fluid F within the chamber 221;
a rod 240 connecting the piston 230 and the subaxial wall 100; and
Including;;
buttress wall assembly.
The method of claim 1,
Compression or tension of the viscous fluid F filled in the inner chamber 221 is made by the piston 230 while the cylinder 220 is moved by the lateral load generated in the existing building 10,
As the viscous fluid F flows in the cylinder 220 through the orifice 250 to the opposite side where it is compressed or tensioned, the cylinder 220 and the tone 2130 slowly move relative to each other in the transverse direction. Damping the lateral load while doing,
buttress wall assembly.
The method of claim 1,
Further comprising an anchor 300 for fixing the fixing part 210 and the cylinder 220 to the top of the existing building 10,
buttress wall assembly.

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