KR102606346B1 - Self-restoring friction damper - Google Patents

Abstract

A self-restoring friction damper is initiated. A self-restoring friction damper according to an embodiment of the present invention includes a housing in the form of a hexahedral box; a first compressive force attenuation portion in contact with the inside of the front wall of the housing; a second compression force attenuation portion in contact with the inside of the rear wall of the housing; a first moving plate that is in contact with the first compressive force attenuation portion and can move forward; a second movable plate facing the first movable plate, in contact with the second compression force attenuation portion, and movable rearward; a left fixing portion coupled to the left wall inside the housing and in contact between the first and second moving plates; A right fixing part coupled to the right wall inside the housing and in contact between the first moving plate and the second moving plate; A moving block that is in contact with the first moving plate, the second moving plate, the left fixing part, and the right fixing part and can move in the forward and backward directions; and a friction part that is coupled to the housing and generates friction by making surface contact with the moving block, so that displacement caused by an external force can be automatically restored and damaged parts can be easily replaced, making it economical.

Description

Self-restoring friction damper}

The present invention relates to a self-restoring friction damper, and more specifically, to a damping device installed in a frame structure to reduce the vibration energy of an earthquake.

In general, building structures must be designed to be earthquake-resistant in order to safely protect them from earthquakes. In particular, the damage caused by the collapse of the structure during an earthquake is enormous, so it is essential to strengthen the strength and earthquake resistance of the structure by installing vibration isolating devices on frames such as columns and beams to resist seismic loads.

Therefore, a vibration control system including a vibration control device is installed in a building structure for earthquake resistance reinforcement, and the vibration control device provided in the vibration control system mainly consists of a damper and a brace.

Material deformation or friction force is used to dissipate energy transmitted to the structure. When using material deformation, plastic deformation of the material is used, so the problem of having to replace the material after plastic deformation occurs, so the damper is a friction surface. Friction dampers that absorb the external force applied to the brace due to relative movement are mainly used.

Friction dampers exhibit vibration control performance proportional to the area of the load-displacement history curve, and are usually installed in the area where the greatest displacement occurs in the vibration control device. In other words, the energy absorption capacity of a friction damper increases as the friction force and relative movement distance of the friction surface increase, so it is very important to determine the friction force and relative movement distance generated on the friction surface when manufacturing a friction damper.

Meanwhile, conventional friction dampers are manufactured so that the friction force generated on the friction surface and the relative moving distance have fixed values. However, the braces connected to the building structure may be applied with different sizes of compressive or tensile force depending on the part and type of connection to which they are connected, and the corresponding amount of displacement may also be required differently.

In the conventional friction damper, once the external force applied to the brace is absorbed, the relative movement on the friction surface is maintained, so there was a problem in that a huge amount of money was spent in the process of replacing or repairing the friction damper. .

Korean Patent No. 10-1724535 (Registration Date: April 3, 2017)

One problem that the present invention seeks to solve is to provide a self-restoring friction damper that automatically restores displacement caused by an external force.

Another problem to be solved by the present invention is to provide a self-restoring friction damper that can easily replace damaged parts.

Another problem to be solved by the present invention is to provide a self-restoring friction damper that can be easily installed in a structure and has a simple structure.

Another problem to be solved by the present invention is to provide a self-restoring friction damper that can adjust the degree of pre-compression.

Another problem to be solved by the present invention is to provide a self-restoring friction damper with high structural stability and excellent energy dissipation ability.

In order to achieve the above object, a self-restoring friction damper according to an embodiment of the present invention includes a housing in the form of a hexahedral box; a first compressive force attenuation portion in contact with the inside of the front wall of the housing; a second compression force attenuation portion in contact with the inside of the rear wall of the housing; a first moving plate that is in contact with the first compressive force attenuation portion and can move forward; a second movable plate facing the first movable plate, in contact with the second compression force attenuation portion, and movable rearward; a left fixing portion coupled to the left wall inside the housing and in contact between the first and second moving plates; A right fixing part coupled to the right wall inside the housing and in contact between the first moving plate and the second moving plate; A moving block that is in contact with the first moving plate, the second moving plate, the left fixing part, and the right fixing part and can move in the forward and backward directions; and a friction portion coupled to the housing and generating friction by making surface contact with the moving block. The moving block may have a protrusion that penetrates the first moving plate and the front wall and is exposed to the outside of the housing.

In addition, in order to achieve the above object, the first compressive force damping part of the self-restoring friction damper according to an embodiment of the present invention includes a first damping spring disposed spaced apart in the left and right directions between the front wall and the first moving plate, The first damping spring may be precompressed.

In addition, in order to achieve the above object, the second compressive force damping part of the self-restoring friction damper according to an embodiment of the present invention includes a second damping spring disposed spaced apart in the left and right directions between the rear wall and the second moving plate, The second damping spring may be precompressed.

In addition, in order to achieve the above object, the first compressive force damping part of the self-restoring friction damper according to an embodiment of the present invention includes a first damping spring disposed spaced apart in the left and right directions between the front wall and the first moving plate; And it may include a first fitting plate that is in contact between the front wall and the first damping spring and linearly compresses the first damping spring.

In addition, in order to achieve the above object, the second compression force damping part of the self-restoring friction damper according to an embodiment of the present invention includes a second damping spring disposed spaced apart in the left and right directions between the rear wall and the second moving plate; And it may include a second fitting plate that contacts between the rear wall and the second damping spring and linearly compresses the second damping spring.

In addition, in order to achieve the above problem, the first damping spring of the self-restoring friction damper according to an embodiment of the present invention has a cylindrical shape disposed in the front and rear directions, and a first central hole penetrating along the central axis is formed, and the second damping spring is The spring has a cylindrical shape disposed in the front-to-back direction, and a second central hole penetrating along the central axis may be formed.

In addition, in order to achieve the above object, the first fitting plate of the self-restoring friction damper according to an embodiment of the present invention has a cylindrical shape disposed in the front-back direction and has a first mounting hole penetrating along the central axis, and a first mounting hole on the front wall is formed. The first protrusion formed inside may be coupled to the first mounting hole.

In addition, in order to achieve the above problem, the second fitting plate of the self-restoring friction damper according to an embodiment of the present invention has a cylindrical shape disposed in the front-back direction and has a second mounting hole penetrating along the central axis, and a second mounting hole on the rear wall is formed. The second protrusion formed inside may be coupled to the second mounting hole.

In addition, in order to achieve the above object, the left fixing part of the self-restoring friction damper according to an embodiment of the present invention includes a first left plate disposed parallel to the left wall; a second left plate extending from the front end of the first left plate toward the left wall; And it may include a third left plate extending from the rear end of the first left plate toward the left wall.

In addition, in order to achieve the above object, the right fixing part of the self-restoring friction damper according to an embodiment of the present invention includes a first right plate disposed parallel to the right wall; a second right plate extending from the front end of the first right plate toward the right wall; And it may include a third right plate extending from the rear end of the first right plate toward the right wall.

In addition, in order to achieve the above problem, the left fixing part of the self-restoring friction damper according to an embodiment of the present invention has a front end that penetrates the second left plate and is coupled to the first moving plate, and a rear end that penetrates the third left plate. Thus, it may further include a first tension reduction wire coupled to the second moving plate.

In addition, in order to achieve the above problem, the right fixing part of the self-restoring friction damper according to an embodiment of the present invention has a front end that penetrates the second right plate and is coupled to the first moving plate, and a rear end that penetrates the third right plate. Thus, it may further include a second tension reduction wire coupled to the second moving plate.

Additionally, in order to achieve the above object, a plurality of first tensile force attenuation wires and second tensile force attenuation wires of the self-restoring friction damper according to an embodiment of the present invention may be provided in parallel.

Additionally, in order to achieve the above object, the first tensile force attenuation wire and the second tensile force attenuation wire of the self-restoring friction damper according to an embodiment of the present invention may be formed of a shape memory alloy.

In addition, in order to achieve the above object, the friction portion of the self-restoring friction damper according to an embodiment of the present invention includes a plurality of first permanent magnets coupled to the lower plate of the housing; And it may include a plurality of second permanent magnets coupled to the upper plate of the housing.

According to the self-restoring friction damper according to an embodiment of the present invention, a housing in the form of a hexahedral box; a first compressive force attenuation portion in contact with the inside of the front wall of the housing; a second compression force attenuation portion in contact with the inside of the rear wall of the housing; a first moving plate that is in contact with the first compressive force attenuation portion and can move forward; a second movable plate facing the first movable plate, in contact with the second compression force attenuation portion, and movable rearward; a left fixing portion coupled to the left wall inside the housing and in contact between the first and second moving plates; A right fixing part coupled to the right wall inside the housing and in contact between the first moving plate and the second moving plate; A moving block that is in contact with the first moving plate, the second moving plate, the left fixing part, and the right fixing part and can move in the forward and backward directions; and a friction part that is coupled to the housing and generates friction by making surface contact with the moving block, so that displacement caused by an external force can be automatically restored, and damaged parts can be easily replaced, reducing maintenance costs. can do.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the moving block may form a protrusion that penetrates the first moving plate and the front wall and is exposed to the outside of the housing, so that the moving block is located outside the housing. It can be connected to structures such as braces.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the first compressive force damping portion includes a first damping spring disposed to be spaced apart in the left and right directions between the front wall and the first moving plate, and the first damping spring is Since it can be pre-compressed, the compression force generated in front of the damper by an external force can be dissipated, the displacement of the damper generated by the compression force can be recovered, and the residual displacement of the friction damper can be controlled.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the second compressive force damping portion includes a second damping spring disposed to be spaced apart in the left and right directions between the rear wall and the second moving plate, and the second damping spring is Since it can be pre-compressed, the compression force generated at the rear of the damper by an external force can be dissipated, the displacement of the damper generated by the compression force can be recovered, and the residual displacement of the friction damper can be controlled.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the first compressive force damping part includes a first damping spring disposed spaced apart in the left and right directions between the front wall and the first moving plate; and a first fitting plate that is in contact between the front wall and the first damping spring and pre-compresses the first damping spring, so that the compression force generated in the front of the damper by an external force can be dissipated, and the compression force The displacement of the damper caused by the damper can be recovered, and the residual displacement of the friction damper can be controlled by adjusting the degree of linear compression.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the second compressive force damping part includes a second damping spring disposed spaced apart in the left and right directions between the rear wall and the second moving plate; and a second fitting plate that is in contact between the rear wall and the second damping spring and pre-compresses the second damping spring, so that the compression force generated at the rear of the damper by an external force can be dissipated, and the compression force The displacement of the damper caused by the damper can be recovered, and the residual displacement of the friction damper can be controlled by adjusting the degree of linear compression.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the first damping spring has a cylindrical shape disposed in the front-back direction and a first central hole penetrating along the central axis is formed, and the second damping spring is in the front-back direction. Since it is arranged in a cylindrical shape and a second central hole penetrating along the central axis can be formed, the first damping spring and the second damping spring can be uniformly compressed.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the first fitting plate has a cylindrical shape arranged in the front-back direction, a first mounting hole penetrating along the central axis is formed, and the first fitting plate is formed inside the front wall. Since one protrusion can be coupled to the first mounting hole, the first fitting plate can be fixed to the front wall.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the second fitting plate has a cylindrical shape disposed in the front-back direction, a second mounting hole penetrating along the central axis is formed, and the second fitting plate is formed inside the rear wall. Since the two protrusions can be coupled to the second mounting hole, the second fitting plate can be fixed to the rear wall.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the left fixing part includes a first left plate disposed parallel to the left wall; a second left plate extending from the front end of the first left plate toward the left wall; And since it may include a third left plate extending from the rear end of the first left plate toward the left wall, the weight of the left fixing part can be reduced.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the right fixing part includes a first right plate disposed parallel to the right wall; a second right plate extending from the front end of the first right plate toward the right wall; And since it may include a third right plate extending from the rear end of the first right plate toward the right wall, the weight of the right fixing part can be reduced.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the left fixing part has a front end that penetrates the second left plate and is coupled to the first movable plate, and a rear end that penetrates the third left plate and is coupled to the second movable plate. Since it may further include a first tension reduction wire coupled to, the tension force generated on the left side of the damper by an external force can be dissipated, the displacement of the damper generated by the tension force can be recovered, and the friction damper Residual displacement can be controlled.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the front end of the right fixing part penetrates the second right plate and is coupled to the first movable plate, and the rear end penetrates the third right plate and is connected to the second movable plate. It may further include a second tension reduction wire coupled to the, so that the tension force generated on the right side of the damper by an external force can be dissipated, the displacement of the damper generated by the tension force can be recovered, and the friction damper Residual displacement can be controlled.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the first tensile force attenuation wire and the second tensile force attenuation wire may be provided in parallel in plurality, so that the residual displacement of the friction damper is adjusted by adjusting the degree of attenuation of the tensile force. You can control it.

In addition, according to the self-recovering friction damper according to an embodiment of the present invention, the first tensile force reducing wire and the second tensile force reducing wire may be formed of a shape memory alloy, so that the residual force of the friction damper is restored by using the property of self-recovering the displacement. Displacement can be controlled.

In addition, according to the self-restoring friction damper according to an embodiment of the present invention, the friction portion includes a plurality of first permanent magnets coupled to the lower plate of the housing; And since it may include a plurality of second permanent magnets coupled to the upper plate of the housing, the forces acting on the damper can be attenuated to friction force.

Figure 1 shows a perspective view of a self-restoring friction damper according to an embodiment of the present invention.
Figure 2 shows an exploded perspective view of Figure 1.
Figure 3 shows the displacement of a self-restoring friction damper according to an embodiment of the present invention.
Figure 4 shows a state diagram of the use of a self-restoring friction damper according to an embodiment of the present invention.
Figure 5 shows a modified usage state diagram of a self-restoring friction damper according to an embodiment of the present invention.
Figure 6 shows a stress-strain diagram of a self-restoring friction damper according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

However, in describing the present invention, descriptions of already known functions or configurations will be omitted to make the gist of the present invention clear.

The X, Y, and Z axes shown in the drawing are arbitrarily determined for the convenience of explanation and not for the purpose of limiting rights. The and the Z-axis is defined as indicating the upward and downward directions.

Each direction described below is based on this, except where otherwise specifically limited.

In the description and claims of the invention, directions such as up (up), down (bottom), left and right (lateral or lateral), anterior (forward, front), posterior (belly, rear), etc. are not intended to limit rights. For convenience of explanation, the relative positions between drawings and structures are set as a standard, and each direction described below is based on this, except where otherwise specifically limited.

Referring to Figures 1 to 3, the self-restoring friction damper 10 according to a preferred embodiment of the present invention includes a housing 100 in the form of a hexahedral box; A first compressive force attenuation portion 200 in contact with the inside of the front wall 110 of the housing 100; a second compressive force attenuation portion 300 in contact with the inside of the rear wall 120 of the housing 100; A first moving plate 400 that is in contact with the first compressive force attenuating part 200 and can move forward; A second movable plate 500 facing the first movable plate 400 and in contact with the second compressive force attenuating part 300 and movable backwards; A left fixing part 600 coupled to the left wall 130 inside the housing 100 and in contact between the first movable plate 400 and the second movable plate 500; A right fixing part 700 coupled to the right wall 140 inside the housing 100 and in contact between the first movable plate 400 and the second movable plate 500; A moving block 800 that is in contact with the first moving plate 400, the second moving plate 500, the left fixing part 600, and the right fixing part 700 and can move in the forward and backward directions; And it may include a friction portion 900 that is coupled to the housing 100 and generates friction by making surface contact with the moving block 800.

The movable block 800 may be formed with a protrusion 820 that penetrates the first movable plate 400 and the front wall 110 and is exposed to the outside of the housing 100.

Referring to Figure 4, the self-restoring friction damper 10 according to a preferred embodiment of the present invention is coupled to the brace 4 installed in the frame structure in which the column 1 and the beam 2 are combined to reduce vibration and Prevent damage to structures due to impact.

Both ends of the brace (4) may be coupled to the connection portion (5) of the column (1) and the connection portion (3) of the beam (2).

The connection part 5 of the pillar 1 may mean a flange or plate formed at the lower part of the pillar 1.

The connection part 3 of the beam 2 may mean a flange or plate formed in the middle of the beam 2.

As shown in Figure 5, the friction damper 10 may be coupled to one end or both ends of the brace 4.

Hereinafter, the friction damper 10 will be described based on the form in which it is installed in the middle of the brace 4.

Referring to Figures 1 to 4, the housing 100 has a first compressive force attenuating part 200, a second compressive force attenuating part 300, a first moving plate 400, a second moving plate 500, and a left side inside. The configuration includes a fixing part 600, a right fixing part 700, and a moving block 800.

The housing 100 has a hexahedral box shape and can have one or more sides open.

If a part installed inside the housing 100 needs to be replaced, the housing 100 can be opened and the part replaced.

Housing 100 may include a front wall 110, a rear wall 120, a left wall 130, a right wall 140, a lower plate 150, and an upper plate 160.

The housing 100 may have a first through hole 111 formed in the front wall 110.

The protrusion 820 of the moving block 800 can move through the first through hole 111 of the front wall 110.

The front wall 110 may have a first protrusion 112 formed on its inner surface.

The first fitting plate 220 of the first compressive force reducing part 200 may be coupled to the first protrusion 112 of the front wall 110.

The rear wall 120 may have a second protrusion 121 formed on its inner surface.

The second fitting plate 320 of the second compressive force reducing unit 300 may be coupled to the second protrusion 121 of the rear wall 120.

The rear wall 120 of the housing 100 may be coupled to the brace 4.

The housing 100 may have a first coupling portion 151 formed on the lower plate 150.

In the housing 100, the first permanent magnet 910 of the friction portion 900 may be coupled to the first coupling portion 151 of the lower plate 150.

The housing 100 may have a second coupling portion 161 formed on the upper plate 160.

In the housing 100, the second permanent magnet 920 of the friction portion 900 may be coupled to the second coupling portion 161 of the upper plate 160.

Referring to Figures 1 to 4, the first compressive force attenuator 200 is configured to receive compressive force generated in the friction damper 10 by an external load in front of the moving block 800.

The first compressive force attenuation unit 200 may be responsible for most of the energy dissipated by the friction damper 10 in front of the moving block 800.

The first compressive force reducing unit 200 may be formed of a polyurethane spring.

The first compression force attenuator 200 may apply linear compression force to eliminate displacement caused by compression force.

The linear compression force applied to the first compression force attenuator 200 can automatically restore the displacement generated by the compression force.

As the linear compression amount of the first compression force attenuation unit 200 increases, the automatic restoration force becomes stronger.

The first compressive force attenuation unit 200 may be installed between the front wall 110 and the first moving plate 400.

The first compressive force damping unit 200 may include a first damping spring 210 disposed to be spaced apart in the left and right directions between the front wall 110 and the first moving plate 400.

The first compression force attenuation unit 200 may install the first damping spring 210 in a pre-compressed state between the front wall 110 and the first moving plate 400.

The first damping spring 210 may be formed in a cylindrical shape disposed in the front-back direction.

The first damping spring 210 may be formed with a first central hole 211 penetrating along the central axis.

When the first central hole 211 is formed in the cylindrical first damping spring 210, the inside and outside of the first damping spring 210 can be uniformly compressed by compression force.

The first compression force attenuation unit 200 may further include a first fitting plate 220 that is in contact between the front wall 110 and the first damping spring 210 and linearly compresses the first damping spring 210. .

The first fitting plate 220 is configured to provide linear compression force to the first damping spring 210.

By adjusting the thickness of the first fitting plate 220, the linear compression force applied to the first damping spring 210 can be adjusted.

The first fitting plate 220 may be formed in a cylindrical shape disposed in the front-back direction.

The first fitting plate 220 may be formed with a first mounting hole 221 penetrating along the central axis.

The first protrusion 112 formed inside the front wall 110 may be coupled to the first mounting hole 221 formed in the first fitting plate 220.

Referring to Figures 1 to 4, the second compressive force attenuator 300 is configured to receive compressive force generated in the friction damper 10 by an external load at the rear of the moving block 800.

The second compressive force attenuation unit 300 may be responsible for most of the energy dissipated by the friction damper 10 at the rear of the moving block 800.

The second compressive force reducing unit 300 may be formed of a polyurethane spring.

The second compression force attenuator 300 may apply linear compression force to eliminate displacement caused by compression force.

The linear compression force applied to the second compression force attenuator 300 can automatically restore the displacement generated by the compression force.

As the linear compression amount of the second compression force attenuator 300 increases, the automatic restoration force becomes stronger.

The second compressive force reducing unit 300 may be installed between the rear wall 120 and the second moving plate 500.

The second compressive force reducing unit 300 may include a second reducing spring 310 disposed to be spaced apart in the left and right directions between the rear wall 120 and the second moving plate 500.

The second compression force attenuation unit 300 may install the second damping spring 310 in a pre-compressed state between the rear wall 120 and the second moving plate 500.

The second damping spring 310 may be formed in a cylindrical shape disposed in the front-back direction.

The second damping spring 310 may have a second central hole 311 formed therethrough along the central axis.

When the second central hole 311 is formed in the cylindrical second damping spring 310, the inside and outside of the second damping spring 310 can be uniformly compressed by compression force.

The second compression force attenuation unit 300 may further include a second fitting plate 320 that is in contact between the rear wall 120 and the second damping spring 310 and linearly compresses the second damping spring 310. .

The second fitting plate 320 is configured to provide linear compression force to the second damping spring 310.

By adjusting the thickness of the second fitting plate 320, the linear compression force applied to the second damping spring 310 can be adjusted.

The second fitting plate 320 may be formed in a cylindrical shape disposed in the front-back direction.

The second fitting plate 320 may be formed with a second mounting hole 321 penetrating along the central axis.

The second protrusion 121 formed inside the rear wall 120 may be coupled to the second mounting hole 321 formed in the second fitting plate 320.

Referring to Figures 1 to 4, the first movable plate 400 is configured to compress the first compression force attenuator 200 by the movable block 800 that moves forward.

The first moving plate 400 may have a second through hole 410 formed therein.

The protrusion 820 of the movable block 800 can move through the second through hole 410 of the first movable plate 400.

The first moving plate 400 may be installed in contact with the moving block 800, the left fixing part 600, and the right fixing part 700.

The first movable plate 400 can be maintained in contact with the left fixing part 600 and the right fixing part 700 by the pre-compressed first compression force attenuating part 200.

When the moving block 800 moves forward, the first moving plate 400 moves forward and compresses the first compression force attenuation unit 200.

When the movable block 800 moves backward, the first movable plate 400 cannot move backward due to the left fixing part 600 and the right fixing part 700.

The first moving plate 400 may be formed with a first mounting portion (not shown) that secures the first compressive force attenuating portion 200.

The first moving plate 400 may be coupled to the front end of the first tensile force reducing wire 640.

The first moving plate 400 may be formed with a first through hole 420 through which the front end of the first tensile force reducing wire 640 penetrates and is coupled.

Referring to Figures 1 to 4, the second movable plate 500 is configured to compress the second compression force attenuator 300 by the movable block 800 moving backward.

The second moving plate 500 may be installed in contact with the moving block 800, the left fixing part 600, and the right fixing part 700.

The second movable plate 500 can be maintained in contact with the left fixing part 600 and the right fixing part 700 by the pre-compressed second compression force attenuating part 300.

When the movable block 800 moves rearward, the second movable plate 500 moves rearward and compresses the second compression force attenuator 300.

When the movable block 800 moves forward, the second movable plate 500 cannot move forward due to the left fixing part 600 and the right fixing part 700.

The second moving plate 500 may be formed with a second mounting portion (not shown) that secures the second compressive force reducing portion 300.

The second moving plate 500 may be coupled to the rear end of the second tension reduction wire 740.

The second moving plate 500 may be formed with a second through hole 510 through which the rear end of the second tension reduction wire 740 is coupled.

Referring to Figures 1 to 4, the left fixing part 600 is coupled to the left wall 130 inside the housing 100 to limit the movement range of the first movable plate 400 and the second movable plate 500. It is a composition that does.

The left fixing part 600 is fixed to the left wall 130 and does not move.

The left fixing part 600 may provide a space where the first tension reduction wire 640 is installed.

The left fixing part 600 may be installed to be in contact with the first moving plate 400 and the second moving plate 500.

The left fixing part 600 includes a first left plate 610 disposed parallel to the left wall 130; a second left plate 620 extending from the front end of the first left plate 610 toward the left wall 130; And it may include a third left plate 630 extending from the rear end of the first left plate 610 toward the left wall 130.

The first left plate 610, the second left plate 620, and the third left plate 630 may be formed in an approximately ‘ㄷ’ shape.

The first left plate 610 may be installed to contact the left side of the moving block 800.

The second left plate 620 may be installed to contact the first moving plate 400.

The third left plate 630 may be installed to contact the second moving plate 500.

The left fixing part 600 may have a first tension reduction wire 640 disposed in a space surrounded by the first left plate 610, the second left plate 620, and the third left plate 630.

The second left plate 620 and the third left plate 630 may have a through hole 650 through which the first tensile force reducing wire 640 passes.

1 to 4, the right fixing part 700 is coupled to the right wall 140 inside the housing 100 to limit the movement range of the first movable plate 400 and the second movable plate 500. It is a composition that does.

The right fixing part 700 is fixed to the right wall 140 and does not move.

The right fixing part 700 may provide a space where the second tension reduction wire 740 is installed.

The right fixing part 700 may be installed to be in contact with the first moving plate 400 and the second moving plate 500.

The right fixing part 700 includes a first right plate 710 disposed parallel to the right wall 140; a second right plate 720 extending from the front end of the first right plate 710 toward the right wall 140; And it may include a third right plate 730 extending from the rear end of the first right plate 710 toward the right wall 140.

The first right plate 710, second right plate 720, and third right plate 730 may be formed approximately in a ‘ㄷ’ shape.

The first right plate 710 may be installed to contact the right side of the moving block 800.

The second right plate 720 may be installed to contact the first moving plate 400.

The third right plate 730 may be installed to contact the second moving plate 500.

The right fixing part 700 may have a second tension reduction wire 740 disposed in a space surrounded by the first right plate 710, the second right plate 720, and the third right plate 730.

The second right plate 720 and the third right plate 730 may have a through hole 750 through which the second tension reduction wire 740 passes.

Referring to Figures 1 to 4, the left fixing part 600 may further include a first tensile force attenuation wire 640.

The first tension reduction wire 640 is configured to receive the tension force generated in the friction damper 10 by an external load on the left side of the moving block 800.

The first tensile force reducing wire 640 may be formed of a superelastic shape memory alloy.

Superelastic shape memory alloy has the property of restoring its original shape even at room temperature when permanent deformation occurs in the material.

The first tension reduction wire 640 can automatically restore the displacement occurring in the friction damper 10 due to an external load.

If the first tensile force attenuation wire 640 does not completely restore the displacement occurring in the friction damper 10 due to an external load, the pre-compressed first compressive force attenuator 200 or the second compressive force attenuator 300 is The displacement of the friction damper 10 can be completely restored.

The front end of the first tension reduction wire 640 may pass through the second left plate 620 and be coupled to the first moving plate 400.

The rear end of the first tension reduction wire 640 may pass through the third left plate 630 and be coupled to the second moving plate 500.

The first tensile force reducing wire 640 may be provided in parallel in a vertical or left-right direction.

By adjusting the diameter or number of the first tension reduction wire 640, the tension applied to the first tension reduction wire 640 can be adjusted.

Referring to Figures 1 to 4, the right fixing part 700 may further include a second tension attenuation wire 740.

The second tension reduction wire 740 is configured to receive the tension force generated in the friction damper 10 by an external load on the right side of the moving block 800.

The second tensile force reducing wire 740 may be formed of a superelastic shape memory alloy.

The second tension reduction wire 740 can automatically restore the displacement occurring in the friction damper 10 due to an external load.

If the second tension attenuation wire 740 does not completely restore the displacement occurring in the friction damper 10 due to an external load, the pre-compressed first compressive force attenuator 200 or the second compressive force attenuator 300 is The displacement of the friction damper 10 can be completely restored.

The front end of the second tension reduction wire 740 may pass through the second right plate 720 and be coupled to the first moving plate 400.

The rear end of the second tension reduction wire 740 may pass through the third right plate 730 and be coupled to the second moving plate 500.

The second tension reducing wire 740 may be provided in parallel in a vertical or left-right direction.

By adjusting the diameter or number of the second tension reduction wire 740, the tension applied to the second tension reduction wire 740 can be adjusted.

Referring to Figures 1 to 4, the moving block 800 is configured to move in the front-back direction inside the housing 100 by an external load.

The moving block 800 includes a body portion 810 having a substantially hexahedral shape; And it may include a protrusion 820 extending forward from a portion of the front of the main body 810.

The protrusion 820 may penetrate the first moving plate 400 and the front wall 110 and be exposed to the outside of the housing 100.

The protrusion 820 may be coupled to the brace 4 outside the housing 100.

When an external load is transmitted to the moving block 800 through the protrusion 820, the moving block 800 can move forward or backward.

When the moving block 800 moves forward, the first moving plate 400 moves forward, so the first moving plate 400 applies compressive force to the first compressive force attenuator 200.

When the moving block 800 moves forward, the first moving plate 400 moves forward and moves away from the second moving plate 500, so the first tensile force reducing wire 640 and the second tensile force reducing wire 740 ) is applied to the tension.

When the moving block 800 moves backward, the second moving plate 500 moves backward, so the second moving plate 500 applies compressive force to the second compressive force attenuator 300.

When the movable block 800 moves rearward, the second movable plate 500 moves rearward and away from the first movable plate 400, so the first tensile force attenuation wire 640 and the second tensile force attenuation wire 740 ) is applied to the tension.

Referring to Figures 1 to 4, the friction portion 900 is configured to generate friction by making surface contact with the moving block 800.

The friction portion 900 includes a plurality of first permanent magnets 910 coupled to the lower plate 150 of the housing 100; And it may include a plurality of second permanent magnets 920 coupled to the upper plate 160 of the housing 100.

The first permanent magnet 910 may be coupled to the first coupling portion 151 of the lower plate 150.

The second permanent magnet 920 may be coupled to the second coupling portion 161 of the upper plate 160.

The friction portion 900 may be formed of a neodymium permanent magnet.

The friction portion 900 may be magnetically coupled to the moving block 800.

Since the friction portion 900 is fixed to the housing 100, frictional force can be generated when the moving block 800 moves due to an external load.

The friction portion 900 may be additionally installed on the first left plate 610 and the first right plate 710.

The self-restoring friction damper 10 according to the present invention is an energy dissipation damper. The unit of energy dissipation is the product of length and force. In the graph of FIG. 6, the closed area means the value, and the larger the area, the more vibration energy can be reduced.

Therefore, by adjusting the number of superelastic shape memory alloys and the number of neodymium permanent magnets according to the characteristics of the area where the friction damper 10 is installed, this area can be expanded to dissipate more energy.

Although specific embodiments of the present invention have been described and shown above, it is known in the art that the present invention is not limited to the described embodiments, and that various modifications and changes can be made without departing from the spirit and scope of the present invention. This is self-evident to those who have it.

Accordingly, such modifications or variations should not be understood individually from the technical idea or viewpoint of the present invention, and the modified embodiments should be regarded as falling within the scope of the claims of the present invention.

10: friction damper 100: housing
110: Front wall 111: First through hole
112: first protrusion 120: rear wall
121: Second projection 130: Left wall
140: Right wall 150: Lower plate
151: first coupling portion 160: upper plate
161: second coupling portion 200: first compressive force attenuation portion
210: first damping spring 211: first center hole
220: First fitting plate 221: First mounting hole
300: second compression force reduction unit 310: second reduction spring
311: second center hole 320: second fitting plate
321: second mounting hole 400: first moving plate
410: second through hole 420: first through hole
500: second moving plate 510: second through hole
600: Left fixing part 610: First left plate
620: Second left plate 630: Third left plate
640: First tensile force reduction wire 650: Through hole
700: Right fixing part 710: First right plate
720: 2nd right plate 730: 3rd right plate
740: Second tensile force reduction wire 750: Through hole
800: moving block 810: main body
820: protrusion 900: friction part
910: first permanent magnet 920: second permanent magnet

Claims (10)

Housing in the form of a hexahedral box; a first compressive force attenuation portion in contact with the inside of the front wall of the housing; a second compression force attenuation portion in contact with the inside of the rear wall of the housing; a first moving plate that is in contact with the first compressive force attenuation portion and can move forward; a second movable plate facing the first movable plate, in contact with the second compression force attenuation portion, and movable rearward; a left fixing part coupled to the left wall inside the housing and in contact between the first and second moving plates; a right fixing part coupled to the right wall inside the housing and in contact between the first moving plate and the second moving plate; A moving block that is in contact with the first moving plate, the second moving plate, the left fixing part, and the right fixing part and can move in a forward and backward direction; And a friction part coupled to the housing and generating friction by making surface contact with the moving block,
The moving block has a protrusion formed through the first moving plate and the front wall and exposed to the outside of the housing,
The first compressive force damping part includes a first damping spring disposed to be spaced apart in the left and right directions between the front wall and the first moving plate; And a first fitting plate that contacts between the front wall and the first damping spring and linearly compresses the first damping spring,
The second compressive force damping unit includes a second damping spring disposed to be spaced apart in the left and right directions between the rear wall and the second moving plate; and a second fitting plate that contacts between the rear wall and the second damping spring and linearly compresses the second damping spring. According to paragraph 1,
The first compressive force damping portion includes a first damping spring disposed to be spaced apart in the left and right directions between the front wall and the first moving plate,
The second compressive force reducing unit includes a second reducing spring disposed to be spaced apart in the left and right directions between the rear wall and the second moving plate,
A self-restoring friction damper, wherein the first damping spring and the second damping spring are pre-compressed. delete According to paragraph 1,
The first damping spring has a cylindrical shape disposed in the front-back direction and has a first central hole penetrating along the central axis,
The second damping spring is in the form of a cylinder arranged in the front-back direction and has a second central hole penetrating along the central axis. According to clause 4,
The first fitting plate has a cylindrical shape disposed in the front-back direction and has a first mounting hole penetrating along the central axis,
A first protrusion formed inside the front wall is coupled to the first mounting hole,
The second fitting plate has a cylindrical shape disposed in the front-back direction and has a second mounting hole penetrating along the central axis,
A self-restoring friction damper, wherein the second protrusion formed inside the rear wall is coupled to the second mounting hole. According to paragraph 1,
The left fixing part is,
a first left plate disposed parallel to the left wall;
a second left plate extending from the front end of the first left plate toward the left wall; and
It includes a third left plate extending from the rear end of the first left plate toward the left wall,
The right fixing part is,
a first right plate disposed parallel to the right wall;
a second right plate extending from the front end of the first right plate toward the right wall; and
A self-restoring friction damper comprising a third right plate extending from the rear end of the first right plate toward the right wall. According to clause 6,
The left fixing part is,
It further includes a first tension reduction wire whose front end penetrates the second left plate and is coupled to the first movable plate, and whose rear end penetrates the third left plate and is coupled to the second movable plate,
The right fixing part is,
The front end passes through the second right plate and is coupled to the first movable plate, and the rear end passes through the third right plate and is coupled to the second movable plate. Self-recovering friction damper. In clause 7,
A self-restoring friction damper, characterized in that the first tensile force reducing wire and the second tensile force reducing wire are provided in parallel. According to clause 8,
A self-restoring friction damper, wherein the first tensile force reducing wire and the second tensile force reducing wire are formed of a shape memory alloy. According to paragraph 1,
The friction part,
a plurality of first permanent magnets coupled to the lower plate of the housing; and
A self-restoring friction damper comprising a plurality of second permanent magnets coupled to the upper plate of the housing.

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