KR102156870B1 - Damper block and earthquake-proof wall structure using the same - Google Patents

Abstract

The present invention relates to a damper block configured to dissipate, when seismic force exceeding an allowable range reaches a building structure, the seismic force applied to the building structure by means of internal elasticity, and an earthquake-proof wall structure having an earthquake-proof and vibration control function using the same. The damper block comprises: an outer frame surrounded by upper and lower walls and both side walls and opened in front and rear directions; a haunch part formed on each inner corner of the outer frame; a reference member formed as a cylindrical member laid to have lengths in front and rear directions and arranged at the central part of the outer frame; and a damper spring having one end fixed to the haunch part and the other end fixed to the reference member to locate the reference member at the central part by means of elasticity when external force does not exist. When external force exceeding an allowable value is applied in left and right directions, the damper spring expands and contracts according to an installation site such that restoring force is configured to act in the direction in which the reference member is located at the central part.

Description

Damper block and earthquake-proof wall structure using the same

The present invention relates to a damper block that dissipates a seismic force acting on a building structure with elasticity inside when a seismic force exceeds an allowable range, and a seismic-vibration wall structure using the same.

For seismic reinforcement of a building, a reinforcing wall may be newly installed or expanded in an area surrounded by beams and columns (Public Patent 2012-0094973, Registered Patent 1089322, etc.). Adding or expanding the reinforcing wall is a way to increase the permissible seismic load of the building, but since it integrates the existing bearing members (existing beams, columns, bearing walls, etc.) and the reinforcing wall, when seismic forces exceeding the allowable load are applied, the existing bearing members and The reinforcing walls behave in an integral way, which can lead to simultaneous failure rather than gradual collapse.

In addition, it is possible to apply a method of adding a frame made of a brace, a plate, a damper, or the like to the existing wall (Registration Register Patent 10-0983638, etc.). However, if the wall is reinforced by adding the top and the frame, the allowable weight of the reinforced wall is higher than that of other existing structures, so in case of an earthquake, only the reinforced frame remains intact, and the remaining bearing members (pillars, beams, etc.) may be destroyed first. .

In addition, the method of improving the rigidity of the non-bearing wall, which is particularly vulnerable to earthquakes, is effective in strengthening the non-bearing wall, but it is difficult to expect a positive effect on the bearing-bearing member of a building (registered patent 10-1787375, etc.). There is also a method of integrating the block wall with the existing structure to share the load, but since this is also integrating the existing bearing member and the block wall, the entire building is destroyed when the seismic force exceeding the allowable load is applied (Japanese Patent Laid-Open No. 2016-108911). , Japanese Patent No. 5702169, etc.)

Meanwhile, in recent years, a number of vibration isolation structures or seismic isolation structures have been developed to reduce seismic forces transmitted to buildings. Among these, Patent Publication No. 2019-0030562 provides a technology that can be applied to a wall block. However, Korean Patent Application Publication No. 2019-0030562 cannot contribute to securing light and visibility through a block structure, and when a block is damaged due to seismic force, the damaged block must be newly constructed.

1. Publication Patent 2012-0094973 "Seismic Reinforcement Structure Using High Toughness Cement Composite Panel" 2. Registered Patent 1089322 "Non-demolition type eco-friendly seismic reinforcement method for existing masonry walls" 3. Registered Patent 0983638 "Seismic Reinforcing Structure and Method of Existing Building" 4. Registered Patent 1787375 "Seismic Block and Masonry Wall for Seismic Improvement Construction of Non-reinforced Non-bearing Wall" 5. Japanese Patent Application Publication No. 2016-108911 "耐震壁構造" 6. Japanese Patent No. 5702169 "耐震壁" 7. Patent Publication 2019-0030562 "Seismic block for seismic isolation structure and seismic structure using the same"

The present invention shares the burden load of the structural member, is advantageous in securing light and visibility, can partially dissipate the seismic force when the seismic force exceeds the allowable load, and can be easily recovered after an earthquake, and a seismic-vibration wall using the same It's about the structure.

In order to solve the above problems, the present invention,

“Outer frame surrounded by upper and lower walls and both side walls and open in the front and rear directions; A haunch part formed in each inner corner of the outer frame; A reference member disposed in a central portion of the outer frame as a cylindrical member laid to have a length in a front-rear direction; And a damper spring having one end fixed to the heonchi portion, and the other end fixed to the reference member so as to position the reference member in the central portion by elasticity in a state in which there is no external force. It includes, and when an external force exceeding the allowable value is applied in the left and right directions, the reference member moves in the direction of the external force action inside the outer frame and the damper spring expands and contracts according to the installation site, and the damper spring has A damper block configured to generate a restoring force in a direction in which the reference member is positioned in the central portion is provided.

The damper block may further include an elastic cover covering the damper spring, and the outer surfaces of the upper and lower walls and the outer surfaces of both side walls of the outer frame may have uneven surfaces corresponding to each other.

In addition, the present invention relates to "a block wall structure built between vertical and horizontal structural members of a building, comprising: a siding member installed on the vertical and horizontal structural members along a predetermined section of wall formation; And the damper block built in close contact with the inside of the siding member. It includes, and provides a seismic-vibration-isolating wall structure in which the strain rate of the outer frame of the damper block is the same as that of the vertical structure member and the siding member.

According to the present invention, the following effects can be expected.

1. The wall formed by the damper block construction can share the horizontal and vertical loads of the structural members of the building.

2. When a horizontal load exceeding the allowable range is reached by an earthquake, the seismic force acting on the structural members of the building can be dissipated by the elasticity of the spring inside the damper block.

3. Due to the morphological characteristics of the damper block that is open in the front and rear direction, it is advantageous to secure light and view when building a wall.

4. Through the structural analysis of seismic force transmission, the wall opening can be variously deformed.

[Figure 1] is a perspective view of an embodiment of a damper block provided by the present invention.
[Fig. 2] is a cross-sectional view taken along AA' in [Fig. 1].
[Fig. 3] shows embodiments of the front of the damper block according to the present invention.
[Fig. 4] is a front view of an embodiment of a seismic-vibration-isolating wall structure in which the damper block of the present invention is constructed.
[Figure 5] shows the assembly process of the present invention seismic-vibration-proof wall structure.

Hereinafter, the present invention will be described in detail together with the accompanying drawings.

The present invention, as shown in [Fig. 1] and [Fig. 2], "the outer frame 11 is surrounded by upper and lower walls and both side walls and opened in the front-rear direction; Heonchi portions 12 formed in each inner corner of the outer frame 11; A reference member 13 disposed at the center of the outer frame 11 as a cylindrical member laid to have a length in the front and rear direction; And a damper spring 14 having one end fixed to the heonchi part 12 and the other end fixed to the reference member 13 so as to position the reference member 13 in the central part by elasticity in a state in which there is no external force. Including, when an external force exceeding the allowable value is applied in the left and right direction, the reference member 13 moves in the direction of the external force action inside the outer frame 11 and the damper spring 14 is installed According to the expansion and contraction, the damper spring 14 is provided with a damper block 10 ″ configured to generate a restoring force in a direction in which the reference member 13 is positioned in the central portion.

In addition, the damper block 10 of the present invention may further include an elastic cover 15 covering the damper spring 14.

The damper block 10 is a block for building a wall, and is configured to secure an internal elastic deformation capacity together with a vertical and horizontal proof force, and when a horizontal load exceeding the allowable value is applied, the internal reference member 13 is attached to the outer frame ( The damper spring 14, which is located in the center of 11) and has been in an equilibrium state, is configured to be expanded and contracted according to the installation portion, and then a restoring force is applied in a direction in which the reference member 13 is located in the center.

Accordingly, the outer frame 11 of the damper block 10 functions as a reinforcing wall that shares the load acting on the building while the reference member 13 is located in the center and maintains an equilibrium state in the wall formation state. At the same time, the stiffness capable of performing the operation should be secured, and ductility capable of dissipating the applied load by inducing the expansion and contraction of the damper spring 14 should be secured when a load exceeding the allowable load in the equilibrium state acts. .

Therefore, the damper block 10 may be manufactured by extrusion molding of aluminum as a whole or by filling the cast aluminum frame with high toughness concrete, and the strain rate in consideration of the strain rate (0.003) of concrete, which is the main structural material of the building, Can be determined.

The outer frame 11 is a rectangular frame surrounded by upper and lower walls and both side walls and opened in the front and rear directions. The front of the square surrounded by the upper and lower walls and both side walls may be formed in a square or rectangular shape according to design.

The heonchi portion 12 is formed in each inner corner of the outer frame 11 to reinforce each corner and fix one end of the damper spring 14. As shown in [Fig. 2], a method of embedding one end of the damper spring 14 in the heonchi part 12 can be applied, and a separate ring is fixed to the haunch part 12, and the damper One end of the spring 14 may be inserted into the ring to be fixed.

The reference member 13 is a cylindrical member that is laid to have a length in the front and rear direction, and is disposed at the center of the outer frame 11 by the damper spring 14.

As described above, the damper spring 14 has one end fixed to the heonchi portion 12 and the other end fixed to the reference member 13. The other end of the damper spring 14 may be embedded in the reference member 13 as shown in [Fig. 2], and a separate ring is fixed to the reference member 13, and the damper The other end of the spring 14 may be inserted into the ring to be fixed.

As shown in [Fig. 1] to [Fig. 3], one or more of the damper springs 14 are installed at intervals at each corner of the damper block 10 of the present invention. The reference member 13 is positioned in the central part. The damper springs 14 installed at both upper corners receive a force in the direction of tension by the weight of the reference member 13, and a restoring force acts in the contracting direction, and the damper springs 14 installed at the lower both corners are the reference The restoring force acts in the direction of expansion by receiving force in the direction of compression by the weight of the member 13, and as a whole, balance of the force without changing the length of all the damper springs 14 in the state where the reference member 13 is located in the center You can make sure the state is maintained.

When a seismic force that induces deformation of the outer frame 11 is applied, the damper spring 14 is expanded and contracted to dissipate the seismic force, while the restoring force of the expanded damper spring 14 strengthens the resistance against the seismic force.

The elastic cover 15 covers the damper spring 14 and prevents the damper spring 14 from being exposed to sight, contamination, or the like. Although it is not necessary to fix both ends of the elastic cover 15, it may be fixed by embedding both ends in the heonchi part 12 and the reference member 13 as shown in FIG. 2.

Meanwhile, the outer surfaces of the upper and lower walls and the outer surfaces of both side walls of the outer frame 11 may be formed with uneven surfaces 16 corresponding to each other. The concave-convex surface 16 is for easily grasping the construction position when the damper block 10 is constructed, increasing frictional force between adjacent damper blocks, and strengthening the strength against loads applied in the vertical and horizontal directions.

In addition, pinholes p may be formed in each corner portion of the outer frame 11. By inserting the pin bolt (b) into the pin hole (h) and tightening the nut (n) to the protruding pin bolt (b), the connection plate (p1, p2) attached to the front or rear surface of the damper block (10) Can be combined, and thus the built damper block 10 can be integrated as a whole, and the strength against the front and rear acting load can be strengthened (see [Fig. 5]).

The present invention relates to "a block wall structure constructed between vertical and horizontal structural members of a building, comprising: a siding member 20 installed on the vertical and horizontal structural members along a predetermined section of wall formation; And a damper block (10) according to any one of claims 1 to 3 constructed in close contact with the inside of the siding member (20). It includes, and provides a seismic-vibration-proofing wall structure” in which the strain rate of the damper block outer frame 11 is the same as that of the vertical structure member and the siding member 20.

The seismic-vibration-isolating wall structure is the construction structure of the above-described damper block, and serves as a seismic reinforcing wall in terms of sharing the load acting on the vertical and horizontal structural members of the building, and an external force exceeding the allowable value due to earthquakes, etc. When this is applied, the internal elastic deformation occurs in a block unit to dissipate the external force, and the restoring force according to the elastic deformation acts as a resistance to the external force, thereby performing the role of the vibration suppression structure.

The siding member 20 is an intermediary member for securing the integrity of the wall by the construction of the existing structural member and the damper block 10, and the vertical/horizontal along the section in which the wall is to be formed by the construction of the damper block 10 It is installed on a structural member, and can be integrated with an existing structural member by a known dry method, a wet method, or a dry and wet method.

When the uneven surface 16 is formed on the upper and lower walls and both side walls of the damper block 10, the uneven surface corresponding to the uneven surface 16 of the damper block 10 is formed in the siding member 20 as well. Thus, it can be made to be engaged between members.

By configuring the strain rate of the damper block outer frame 11 and the siding member 20 to be the same as that of the vertical structural member, the siding member maintains the deformation of the vertical structural member when an external force (seismic force) in the horizontal direction is applied. 20) and the outer frame 11 of the damper block may be received, and as a result, the damper spring 14 may be expanded and contracted so that the reference member 13 may move. Since the horizontal external force transmitted through the vertical structural member is dissipated in the damper block 10 around the vertical structural member, the middle portion of the wall can form openings of various sizes and shapes.

In the above, the present invention was examined in detail together with specific examples. However, the present invention is not limited by the above embodiments, and may be modified and modified within the scope without departing from the gist of the present invention. Accordingly, the claims of the present invention include such modifications and variations.

10: damper block 11: outer frame
12: heonchi part 13: reference member
14: damper spring 15: elastic cover
16: uneven surface 20: siding member

Claims (3)

An outer frame 11 surrounded by upper and lower walls and both side walls and open in the front and rear direction, and filled with high toughness concrete in a cast aluminum frame;
Heonchi portions 12 formed in each inner corner of the outer frame 11;
A reference member 13 disposed at the center of the outer frame 11 as a cylindrical member laid to have a length in the front and rear direction; And
A damper spring 14 having one end fixed to the heonchi part 12 and the other end fixed to the reference member 13 so as to position the reference member 13 in the central part by elasticity in a state in which there is no external force; Including,
When an external force exceeding the allowable value is applied in the left and right directions, the reference member 13 moves in the direction of the external force action inside the outer frame 11 and the damper spring 14 expands and contracts according to the installation site. , A damper block 10 configured to generate a restoring force in the damper spring 14 in a direction in which the reference member 13 is located in the central portion.
In claim 1,
An elastic cover 15 covering the damper spring 14; A damper block 10, characterized in that it is configured to further include.
As a block wall structure built between vertical and horizontal structural members of a building,
A siding member 20 installed on the vertical/horizontal structural member along the section in which the wall is to be formed; And
The damper block 10 of claim 1 or 2 constructed in close contact with the inside of the siding member 20; Including,
A seismic-vibration-isolating wall structure in which the strain rate of the damper block outer frame 11 is the same as that of the vertical structure member and the siding member 20.

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