KR102083066B1 - Frame-type Damping Device and Reinforcing Method Using The Same - Google Patents

Abstract

The present invention constitutes a composite damper composed of a viscoelastic damper and a steel rod using a high damping rubber to dissipate energy as a characteristic of a viscoelastic damper and a steel hysteresis damper. It relates to a frame-type vibration suppression apparatus and a structure seismic strengthening method using the same.
One preferred embodiment of the composite damper is composed of a high damping rubber and a strain-inducing steel rod of the present invention comprises a first, second fixing plate configured in parallel to be spaced apart a certain distance in the shape of a plate; A vertical load supporting steel rod having a predetermined length, the plurality of being configured to connect the central portion with a predetermined distance of the first and second fixing plates; A plurality of deformation-inducing steel rods having a predetermined length having a tapered inclined portion and a cross-sectional reduction portion so as to connect the first and second fixed plates at both sides of the vertical load supporting steel rods spaced apart from each other by a predetermined distance; It is formed with a predetermined length of the H-shaped cross-section and formed of a predetermined length of the H-shaped cross-section, the first connecting member to which the coupling plate is coupled to the other end, the high damping rubber configured on the outside of the coupling plate of the first connecting member A plurality of coupling holes are formed at the other end and the other end, respectively, and the coupling plate at one end of the coupling hole is coupled to a coupling plate made of a long hole, and is configured to bolt the coupling plate, the high damping rubber and the coupling plate to the outside of the high damping rubber. And a viscoelastic damper member formed of a second connecting member and configured to join one end of the first connecting member to the outside of the first and second fixing plates of the composite damper, respectively.

Description

Frame-type damping device including composite damper composed of high damping rubber and deformation-inducing steel rod and structure seismic reinforcement method using the same {Frame-type Damping Device and Reinforcing Method Using The Same}

The present invention relates to a frame damping device including a composite damper and a composite damper composed of a high damping rubber and a deformation induction steel rod, and a seismic reinforcing method using the same, comprising a composite damper consisting of a viscoelastic damper and a steel rod using the high damping rubber. The present invention relates to a frame damping device including a composite damper and a composite damper composed of a high damping rubber and a deformed guide steel rod to dissipate energy due to the characteristics of a viscoelastic damper and a steel hysteresis damper, and a method for seismic reinforcement using the same.

Vibration Control refers to the control of vibration generated by wind or earthquake in the case of buildings, and the structure in which a special device or mechanism is installed for vibration control is called a vibration suppression structure. The purpose of vibration suppression is to improve the safety and habitability of the structure by dissipating the vibration energy input to the structure due to wind or earthquake.

In the method of vibration suppression, the structure itself is equipped with a function to detect the vibration from the outside and the vibration of the structure according to the active control and the building to reduce the vibration of the structure by applying a control force corresponding to the vibration of the structure inside or outside the structure. There is a manual control to control the dynamic response of the building by installing additional energy dissipation devices to improve the damping performance of the structure.

Passive vibration dampers can be divided into mass tuning type and energy dissipation type. The former is mainly installed on the top of the building, mainly for the purpose of enhancing the wind habitability, the latter is mainly installed on each floor is used to increase the safety of the earthquake and the wind habitability.

Energy dissipation type vibration suppressors can be divided into displacement-dependent and speed-dependent types, which use energy dissipation characteristics due to frictional forces between materials or plastic deformation of metals, and speed-dependent types are used when viscous and viscoelastic materials deform. Heat is generated, and the energy dissipated by using the characteristic of dissipating vibration energy is large in proportion to the speed.

Hydraulic damper, which is a kind of speed-dependent vibration damping device, has superior seismic performance compared to the composite damper, and is mainly used in Japan, where heavy and heavy earthquakes occur frequently throughout the country. However, since such a hydraulic damper is expensive, it is an excessively unnecessary method in Korea, where the frequency of earthquakes is low and the strength of the earthquake is not high. On the other hand, the composite damper has a somewhat lower seismic performance than the hydraulic damper, but the construction cost is low, so it is used for reinforcing steel structures.

However, the above-described vibration damping structure using the composite damper is a type of brace shape, which causes spatial obstacles and is not suitable for the variable structure, and has a disadvantage in that replacement after an earthquake is cumbersome. Therefore, it is difficult to apply to the vibration suppression structure of RC structure that requires a variable structure, and it is inefficient to reinstall the vibration suppression device after the earthquake.

As a background technology of the present invention, there is a patent registration 10-1070043 'Pillar-type damper for improving the seismic performance of the building' (Patent Document 1). This patent devises a column-type damper so as not to cause spatial obstacles. In particular, it proposes a column-type damper in which micro and macro fibers are added to cement paste or cement mortar to improve the seismic performance of a building. The pillar-type damper proposed by this patent has superior ability to suppress or delay cracking under design load and additional load, compared to existing cement composites, which has excellent permeability and durability, and improved energy dissipation and damage control. However, when compared with other materials, there were problems such as the ductility of the cement composite and non-environmental waste generated when the damper in the form of a pillar after the earthquake was required to be replaced.

Patent Registration No. 10-0718294 'pillar-type damper for improving the seismic performance of buildings'

The present invention is to solve the above problems, comprising a composite damper consisting of a viscoelastic damper using a high damping rubber, a vertical load supporting steel rod and a strain-inducing steel rod, viscoelasticity using a high damping rubber when wind or micro deformation occurs The characteristic of damper dissipates energy and the vertical load supporting steel rods support the vertical loads, while the deformation-inducing steel rods elastically absorb and attenuate the horizontal loads for horizontal loads such as earthquakes. Usability can be secured, the structure is simple, easy to manufacture and install, and the cost is low, which not only contributes to the improvement of productivity, but also seismic energy is absorbed by the elastic deformation of the vibration damper even when a high earthquake occurs. Just replace the vibration damper before the earthquake In womb can simply revert to the frame provides the maintenance is easy and a damping rubber and variations induced gangjaebong configured combined damper and the frame for vibration damper apparatus, including composite structures, and earthquake-proof reinforcement method using the same have the purpose.

The present invention and the first and second fixed plate is configured in parallel to be spaced apart a certain distance in a plate shape; A vertical load supporting steel rod having a predetermined length, the plurality of being configured to connect the central portion with a predetermined distance of the first and second fixing plates; A plurality of deformation-inducing steel rods having a predetermined length having a tapered inclined portion and a cross-sectional reduction portion so as to connect the first and second fixed plates at both sides of the vertical load supporting steel rods spaced apart from each other by a predetermined distance; A first connection member having a predetermined length of the H-shaped cross section and having a coupling plate having a plurality of coupling holes formed at the other end thereof, a high damping rubber configured at an outer side of the coupling plate of the first connection member, and A plurality of coupling holes are formed at one end and the other end, respectively, and a plurality of coupling holes are formed at one end, and the coupling plate at one end of the coupling hole is coupled to a coupling plate made of a long hole. And a viscoelastic damper member configured to join one end of the first connecting member to an outer side of the first and second fixing plates of the composite damper, respectively. It is an object of the present invention to provide a composite damper composed of damped rubber and strain induced steel rods.

In addition, the strain-inducing steel rod and the vertical load supporting steel rods are each formed with threads at both ends, and the first and second fixing plates corresponding to both ends of the deformation-inducing steel rod are formed through the fixing holes, respectively, The thread is inserted and fixed by a nut, and the first and second fixing plates corresponding to both ends of the vertical load supporting steel rod are formed through the fixing holes through the long holes in the direction of the deformation-inducing steel rods of the circular or both sides, respectively. It is an object of the present invention to provide a composite damper comprising a high damping rubber and a deformed induction steel rod, characterized in that both ends of a load-bearing steel rod are inserted and fixed by a nut.

In addition, the upper horizontal member is coupled to the upper slab or beam lower surface of the structure; A lower horizontal member coupled to the lower slab or the beam upper surface of the structure; An upper vertical member coupled vertically at both ends of the upper horizontal member; A lower vertical member spaced in series with the upper vertical member and vertically coupled to both ends of the lower horizontal member; First and second fixing plates configured to be spaced apart at a predetermined distance in parallel to a plate shape; A vertical load supporting steel rod having a predetermined length, the plurality of being configured to connect the central portion with a predetermined distance of the first and second fixing plates; A plurality of deformation-inducing steel rods having a predetermined length having a tapered inclined portion and a cross-sectional reduction portion so as to connect the first and second fixed plates at both sides of the vertical load supporting steel rods spaced apart from each other by a predetermined distance; A first connection member having a predetermined length of the H-shaped cross section and having a coupling plate having a plurality of coupling holes formed at the other end thereof, a high damping rubber configured at an outer side of the coupling plate of the first connection member, and A plurality of coupling holes are formed at one end and the other end, respectively, and a plurality of coupling holes are formed at one end, and the coupling plate at one end of the coupling hole is coupled to a coupling plate made of a long hole. And a viscoelastic damper member configured to join one end of the first connecting member to the outside of the first and second fixing plates of the composite damper, respectively, the second connecting member being configured to be coupled with the bolt, perpendicular to the upper vertical member. It characterized in that it comprises a composite damper is composed of a high damping rubber and deformation induction steel rods provided between the members The present invention provides a frame damping device including a composite damper composed of a high damping rubber and a deformed induction steel bar.

In addition, the deformed induction steel rods and the vertical load supporting steel rods are formed with threads at both ends, and the first and second fixing plates corresponding to both ends of the deformed induction steel rods are formed through the fixing holes, respectively, The thread is inserted and fixed by a nut, and the first and second fixing plates corresponding to both ends of the vertical load supporting steel rod are formed through the fixing holes through the long holes in the direction of the deformation-inducing steel rods of the circular or both sides, respectively. An object of the present invention is to provide a frame damping device including a composite damper composed of a high damping rubber and a strain-inducing steel bar, characterized in that both ends of a load-bearing steel bar are inserted and fixed by a nut.

In addition, the upper and lower horizontal members and the upper and lower vertical members are composed of an H-shaped roll beam which is rolled and cast into an H-shaped cross section, and a joining plate is installed at the connection portion of the upper and lower vertical members, and the joining plate and the joining plate of the viscoelastic damper member are Another object of the present invention is to provide a frame damping device including a composite damper configured with a high damping rubber and a deformed guide steel rod, each of which is bolted to each other.

In addition, the upper and lower horizontal members and the upper and lower vertical members are composed of reinforced concrete, and the upper horizontal member and the upper vertical member are integrally manufactured in a U shape, and the lower horizontal member and the lower vertical member are integrally manufactured in a C shape. The upper and lower vertical members are configured such that one end of the anchor bolt is embedded in the upper and lower vertical members in advance, and the other end of the anchor bolt protrudes from the upper and lower vertical members, and the anchor bolts protruding from the coupling plate of the viscoelastic damper member are provided. An object of the present invention is to provide a frame damping device including a composite damper composed of a high damping rubber and a deformed guide steel rod, characterized in that the nut is coupled.

In addition, (a) the first and second fixing plates configured in parallel with a predetermined distance spaced apart in a plate shape; A vertical load supporting steel rod having a predetermined length, the plurality of being configured to connect the central portion with a predetermined distance of the first and second fixing plates; A plurality of deformation-inducing steel rods having a predetermined length having a tapered inclined portion and a cross-sectional reduction portion so as to connect the first and second fixed plates at both sides of the vertical load supporting steel rods spaced apart from each other by a predetermined distance; A first connection member having a predetermined length of the H-shaped cross section and having a coupling plate having a plurality of coupling holes formed at the other end thereof, a high damping rubber configured at an outer side of the coupling plate of the first connection member, and A plurality of coupling holes are formed at one end and the other end, respectively, and a plurality of coupling holes are formed at one end, and the coupling plate at one end of the coupling hole is coupled to a coupling plate made of a long hole. High damping rubber and deformation comprising a; viscoelastic damper member consisting of a second connecting member configured to be coupled by a bolt, the one end of the first connecting member is configured to join the outer side of the first and second fixing plates, respectively The composite damper and the upper horizontal member is composed of an induction steel rod, and the upper vertical member coupled vertically at both ends of the upper horizontal member The method comprising making a sub-horizontal member, the lower vertical member coupled perpendicularly to both ends of the lower horizontal member; (b) coupling the upper horizontal member to the upper slab or beam lower surface of the structure and the lower horizontal member to the lower slab or beam upper surface of the structure; And (c) to install a composite damper between the upper vertical member and the lower vertical member; to provide a structure seismic reinforcement method using a frame-type vibration damper characterized in that it comprises a.

In addition, in the step (a), the composite damper, the strain-inducing steel rod and the vertical load supporting steel rods are formed with threads at both ends, respectively, and the fixing holes are formed in the first and second fixing plates corresponding to both ends of the deformation-inducing steel rod, respectively. Both ends of the strain inducing steel rod are inserted into the fixing hole and fixed with nuts. The fixing holes are formed in the first and second fixing plates corresponding to both ends of the vertical load supporting steel rod, respectively, in the direction of a long or long hole in the direction of the circular induction strain bars. It is formed, and to provide a structure seismic reinforcement method using a frame-type vibration damper characterized in that both ends of the vertical load supporting steel rod is inserted into the fixing hole to be fixed by a nut.

In addition, in step (a), the upper and lower horizontal members and the upper and lower vertical members are composed of an H-shaped roll beam which is rolled and cast into an H-shaped cross section, and a joining plate is installed at the connection portion of the upper and lower vertical members. In the step, to provide a structure seismic reinforcement method using a frame-type vibration damper characterized in that the coupling plate and the bonding plate of the viscoelastic damper member are each bolted to each other.

In addition, in step (a), the upper and lower horizontal members and the upper and lower vertical members are made of reinforced concrete, and the upper horizontal member and the upper vertical member are integrally manufactured in a C shape, and the lower horizontal member and the lower vertical member are It is made integrally in the U-shape, in the step (c), the upper and lower vertical members, one end of the anchor bolt is embedded in the upper and lower vertical members in advance, and the other end of the anchor bolt is configured to protrude from the upper and lower vertical members, An anchor bolt protruding from a coupling plate of a viscoelastic damper member is to provide a structure seismic reinforcement method using a frame-type vibration damper characterized in that the nut is coupled.

The frame damping device including the composite damper and the composite damper composed of the high damping rubber and the strain induced steel bar of the present invention, and the structure seismic reinforcing method using the same, is composed of a viscoelastic damper using the high damping rubber, a vertical load supporting steel rod, and a strain inducing steel rod By constructing a damper, if the wind or micro deformation occurs, the characteristics of the viscoelastic damper using high damping rubber dissipate energy, while the vertical load supporting steel rods support the vertical loads, but the deformation-inducing steel bars for horizontal loads such as earthquakes. This elastic deformation can absorb and attenuate the horizontal load to ensure structural stability and usability of the structure, and the structure is simple, easy to manufacture and install, and inexpensive, which not only contributes to productivity improvement but also progress. Seismic energy even when a high earthquake occurs Is absorbed by the deformation of elastoplastic damping devices by replacing only the damping device has a very useful effect, easy maintenance can easily revert back to the state before the earthquake wear Frames.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a perspective view of a composite damper composed of a high damping rubber and deformation induction steel rod according to the present invention.
2 is an exploded perspective view of the main portion of FIG.
3 is a partially exploded perspective view of FIG. 1.
Figure 4 is a schematic diagram illustrating the behavior of the composite damper is composed of a high damping rubber and deformation induction steel rod according to the present invention.
5 is a cross-sectional view of a steel frame vibration damper including a composite damper composed of a high damping rubber and a strain induced steel bar according to the present invention.
6 is a perspective view of an essential part of FIG. 5.
7 is a cross-sectional view of a reinforced concrete frame type vibration suppression apparatus including a composite damper configured with a high damping rubber and a strain induced steel bar according to the present invention.

In the following the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments presented are exemplary for a clear understanding of the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention according to a preferred embodiment in detail.

1 is a perspective view of a composite damper is composed of a high damping rubber and deformation induction steel rod according to the present invention, Figure 2 is an exploded perspective view of the main portion of Figure 1, Figure 3 is a partially exploded perspective view of FIG.

As shown in FIG. 1, the composite damper 100 including the high damping rubber and the deformation induction steel rod of the present invention is configured to connect the first and second fixing plates 20 and 30 and the first and second fixing plates 20 and 30. It includes a plurality of vertical load supporting steel rod 40 and the deformed induction steel rod 10, and a viscoelastic damper member 60 coupled to the outside of the first and second fixing plates 20 and 30, respectively.

The first and second fixing plates 20 and 30 are formed in a plate shape so as to be parallel to each other by a predetermined distance, and the plurality of vertical load supporting steel bars 40 and the first and second fixing plates 20 and 30 are connected to each other. Deformation induction steel rod 10 is configured.

The deformed induction steel rod 10 has a rod shape having a predetermined length, and has a tapered inclined portion 12 and a cross-sectional reduction portion 13 in the center portion thereof so that the cross section becomes smaller toward the center portion.

The cross-sectional reduction part 13 is formed as a weak part of the deformation-inducing steel rod 10, and when a large horizontal load such as an earthquake load occurs, the deformation-inducing steel rod 10 fixed to the first and second fixing plates 20 and 30 is formed. Both ends 11 and 11 have a relative displacement in the horizontal direction. At this time, the section reduction part 13, which is a weak part of the deformation-inducing steel rod 10, elastically and plastically deforms to attenuate the energy of the structure.

The shape of the deformation-inducing steel rod 10 may be formed in a circular cross section, but is not limited thereto and may be manufactured in various shapes.

The vertical load supporting steel bar 40 is a rod shape having a predetermined length so that the entire length is made of the same cross-sectional size, while the vertical load supporting steel bar 40 supports the vertical load of the structure, It is to be elastic and plastic deformation through the cross-sectional reduction portion 13, which is a weak part.

The vertical load supporting steel rod 40 may be formed in a circular cross section, and may be made in various shapes such as a polygonal cross section.

The vertical load supporting steel rod 40 is positioned at the center of the first and second fixing plates 20 and 30 so that both ends thereof are coupled to and fixed to the first and second fixing plates 20 and 30, respectively. 10 is fixed to a plurality of both ends coupled to the first and second fixing plates 20 and 30 so as to connect the first and second fixing plates 20 and 30 at both sides of the vertical load supporting steel rod 40 at a predetermined distance from each other. Be sure to

The combination of the deformed induction steel rod 10 and the first and second fixed plates 20 and 30 of the vertical load supporting steel rod 40 may be made by various known methods, and in particular, the deformed induction steel rod 10 and the vertical load supporting steel rod. 40 has threads 11 and 41 formed at both ends thereof, and fixing holes 22h and 32h and 21h and 31h are respectively provided at positions corresponding to the first and second fixing plates 20 and 30, respectively. And the threads 11 and 11 at both ends of the deformation-inducing steel rod 10 are inserted into the fixing holes 22h and 32h, and are fixed by the nuts 50, and the vertical load supporting steel rods are fixed to the fixing holes 21h and 31h. (40) Both ends 41 and 41 may be inserted and fixed to the nut 50.

In particular, the inner circumferential surfaces of the fixing holes 22h and 32h and 21h and 31h formed in the first and second fixing plates 20 and 30 are formed so that the threads corresponding to the threads 11 and 41 are formed. Deformation-inducing steel rod 10 and vertical load support by rotationally inserting the deformed induction steel rod 10 and the vertical load supporting steel rod 40 into the fixing holes 22h, 32h (21h, 31h) of the fixing plates 20, 30. The steel rod 40 and the first and second fixing plates 20 and 30 may be combined with each other, and in addition, the deformation-inducing steel rod 10 and the vertical load supporting steel rod 40 may include the first and second fixing plates 20 and 20. 30 may be coupled to penetrate through the nut 50 to the threads 11 and 41 at both ends protruding from the first and second fixing plates 20 and 30 so that the fixing may be strongly constrained.

As shown in FIG. 3, the viscoelastic damper member 60 is coupled to the outside of the first and second fixing plates 20 and 30, respectively, and the viscoelastic damper 60 using the high damping rubber 62 and the deformed induction steel rod ( 10) and the vertical load supporting steel rod 40 is configured to dissipate energy due to the characteristics of the viscoelastic damper and the steel hysteresis damper.

As shown, the viscoelastic damper member 60 is coupled to the outside of the first and second fixing plates 20 and 30, respectively, and includes a first connection member 61 and a second connection member formed in a predetermined length in an H-shaped cross section. The high damping rubber 62 is constituted between the 63.

The first connection member 61 is formed to have a predetermined length of the H-shaped cross section to facilitate the coupling with the first and second fixing plates 20 and 30, and the coupling plate 611 to be coupled to the other end thereof to provide high attenuation rubber ( 62) to be interviewed. One end of the first connection member 61 is connected to the outside of the first and second fixing plates 20 and 30 of the composite damper 100 by various known methods such as welding.

The second connection member 63 is formed to have a predetermined length of the H-shaped cross section so that the coupling plates 631 and 632 are coupled to one end and the other end, respectively, to provide an installation space of the high damping rubber 62, It is possible to facilitate the installation with the steel frame and the like.

The coupling plates 611, 631, 632 and the high damping rubber 62 may be formed through a plurality of coupling holes 611a, 621a, 631a, 632a for bolt coupling.

In particular, the first coupling member 61 and the second coupling member 63 are formed in the coupling plate 631 at one end of the second coupling member 63 of the viscoelastic damper member 60 such that the coupling hole 631a is formed as a long hole. The high damping rubber 62, which is press-fitted between, is slid in the press-fitted state along the coupling hole 631a of the long hole when receiving the wind load, etc., so that the high damping rubber 62 is the first connecting member 61. ) And viscoelastic resistance and deformation between the coupling plates 611 and 631 of the second connection member 63 to absorb energy.

The composite damper 100 composed of the high damping rubber and the strain inducing steel rod combined as described above is configured to dissipate energy due to the characteristics of the viscoelastic damper using the high damping rubber 62 when wind or micro deformation occurs. The steel rods 40 support the vertical loads, and resist the horizontal loads according to the relative displacements of both ends of the first and second fixed plates 20 and 30 and the deformed guide steel rods 10 fixed to the first and second fixed plates.

In this case, the fixing holes 21h and 31h to which the vertical load supporting steel rods 40 are coupled are formed to have long holes in the direction of the deformation induction steel rods 10 on both sides thereof, thereby fixing them to the first and second fixing plates 20 and 30. When both ends of the deformed induction steel rod 10 have a relative displacement in the horizontal direction, the vertical load supporting steel rod 40 does not resist in the horizontal direction and slides along the fixing holes 21h and 31h of the long hole so that the deformed induction steel rod ( It is possible to induce the cross-sectional reduction part 13 of 10) to elastic and plastic deformation.

Figure 4 is a schematic diagram illustrating the behavior of the composite damper is composed of a high damping rubber and deformation induction steel rod according to the present invention.

As shown in Figure 4, when the horizontal load acts on the moment frame (Moment Frame) the bottom of the moment connection (rigid connection) and the column-beam connection of the column is constrained rotation and the column is subjected to horizontal displacement .

If a damper is additionally installed at the horizontal displacement generating area (D) of the column, the damper is not subjected to axial force and is used as a member to absorb horizontal load.

The deformed induction steel rod 10 and the vertical load supporting steel rod 40 are made of unit units, and a plurality of fixing holes 22h, 32h, 21h, 23h of the first and second fixing plates 20, 30 are preferably formed in advance. Do. Where a large amount of energy dissipation is required to install a large number of deformation-inducing steel rods 10, where a small amount of deformation-inducing steel rod 10 is installed in the energy dissipation capacity of the damper can be easily adjusted. In detail, the damper functions as a damping structure that prevents the collapse of structural members of the building against lateral loads caused by earthquakes, and the total cross-sectional area of the deformed induction steel rod 10 is determined according to the design value of the tolerable lateral loads. Therefore, in consideration of the design value of the lateral load, it is possible to respond appropriately to the required performance by a simple method of adjusting the number of installation of the deformed induction steel rod 10 manufactured in a unit unit.

5 is a cross-sectional view of a steel frame vibration damper including a composite damper composed of a high damping rubber and a strain induced steel bar according to the present invention.

Steel frame type vibration damping apparatus including a high damping rubber and a composite damper composed of deformation-inducing steel rod according to the present invention is coupled to the upper horizontal member 110, the lower slab or beam upper surface of the structure is coupled to the upper slab or beam bottom of the structure Lower vertical member 120, the upper vertical member 130,130 coupled vertically at both ends of the upper horizontal member 110, the lower vertical member spaced in series with the upper vertical member vertically coupled to both ends of the lower horizontal member 120 (140,140), the composite damper 100 is composed of a high damping rubber and deformation induction steel rod is installed between the upper vertical member (130,130) and the lower vertical member (140,140).

The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 may be formed of various shapes and materials as members for forming a frame. For example, the upper and lower horizontal members 110 and 120 may be rolled and cast into an H-shaped cross section. The steel frame is formed by the H-shaped roll beam. Forming a steel frame using a ready-made H-beam has the advantage of ensuring ease of manufacture and economics.

Figure 6 is a perspective view of the main part of the steel frame type vibration damping apparatus including a composite damper composed of a high damping rubber and deformation induction steel rod according to the present invention.

As shown in FIG. 6, the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are formed of H-shaped roll beams which are roll-cast into an H-shaped cross section, and connected to the upper and lower vertical members 130 and 140. Bonding plates 131 and 141 may be installed, and coupling plates 632 and bonding plates 131 and 141 of the viscoelastic damper member 60 may be bolted to each other, and may be welded further.

Frame-type vibration damping apparatus including a composite damper composed of a high damping rubber and a strain-inducing steel rod according to the present invention as described above can be used for the seismic reinforcement of the structure is installed in existing or stretch moment frame structure.

As shown in FIG. 4, when the damping device having a moment frame shape is manufactured to constitute a composite damper having high damping rubber and a deformed guide steel bar in the deformation section D of the vertical member, the frame type damping device is horizontally loaded from the structure. Receives the composite damper composed of a high damping rubber and deformation-inducing steel rod installed in the deformation section (D) to shear deformation. Even after the earthquake load, deformation does not occur in the structure, and even in the frame vibration suppression system, shear deformation is concentrated only in the composite damper composed of high damping rubber and deformed steel rod. Seismic energy is absorbed by the elastic and plastic deformation of the composite damper composed of the high damping rubber and the strain-inducing steel bar of the frame type vibration damper, and only the steel rod of the composite damper with the high damping rubber and the strain-inducing steel bar. If it is replaced or additionally installed, it can be easily returned to the frame that was in the condition before the earthquake damage, so it is easy to repair.

7 is a cross-sectional view of a reinforced concrete frame type vibration suppression apparatus including a composite damper configured with a high damping rubber and a strain induced steel bar according to the present invention.

This embodiment is the same as the previous embodiment except for the constituent material of the frame, so repeated description thereof will be omitted. Unlike the previous embodiment, in the present embodiment, the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 constituting the frame are made of reinforced concrete. The reinforcement amount and reinforcement position of reinforcing bars (not shown) reinforcement to the reinforced concrete frame are based on the structural calculation.

The upper horizontal member 110 and the upper vertical members 130 and 130 may be integrally manufactured in a U shape, and the lower horizontal member 120 and the lower vertical members 140 and 140 may be integrally manufactured as well. One end of the anchor bolts 132 and 142 is pre-filled in the upper and lower vertical members 130 and 140 so that the other ends of the anchor bolts 132 and 142 protrude from the upper and lower vertical members 130 and 140 in the upper and lower vertical members 130 and 140. do. The composite damper 100 having high damping rubber and strain-inducing steel rods is reinforced in such a way that the protruding anchor bolts 132 and 142 are nut-coupled to the anchor bolts 132 and 142 protruding from the coupling plate 632 of the viscoelastic damper member 60. It can be installed in a concrete frame.

Hereinafter, a method of seismic reinforcing the existing or elastic moment frame structure of the frame-type vibration suppression apparatus including the composite damper configured with the high damping rubber and the strain-inducing steel rod according to the present invention configured as described above.

First, both ends of the composite damper 100 and the upper horizontal member 110, the upper vertical member 130,130 and the lower horizontal member 120, the lower horizontal member 120 are vertically coupled at both ends of the upper horizontal member 110 Produce a lower vertical member (140,140) coupled vertically to (a).

Then, the upper horizontal member 110 is coupled to the upper slab or beam lower surface of the structure and the lower horizontal member 120 is coupled to the lower slab or beam upper surface of the structure (b).

In this case, a space is formed between the upper vertical members 130 and 130 and the lower vertical members 140 and 140, and the upper vertical members 130 and 130 and the lower vertical members 140 and 140 are spaced apart from the pillar of the structure to secure a working space. It is desirable to.

As described above, as the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140, which are members for forming a frame, an H type roll beam rolled and cast into an H type cross section may be used.

Next, in the space between the upper vertical member (130,130) and the lower vertical member (140,140) is installed a composite damper (100) consisting of a high damping rubber and deformation induction steel rod (c).

In the installation method, the junction plates 131 and 141 may be installed at the connection portions of the upper and lower vertical members 130 and 140, and the coupling plates 632 and the junction plates 131 and 141 of the viscoelastic damper member 60 may be bolted to each other.

Alternatively, the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140, which are members for forming a frame, may be made of reinforced concrete. In this case, the upper horizontal member 110 and the upper vertical members 130 and 130 may be integrally formed in a U shape, and the lower horizontal member 120 and the lower vertical members 140 and 140 may be integrally formed in a C shape. One end of the anchor bolts 132 and 142 is pre-filled in the upper and lower vertical members 130 and 140 so that the other ends of the anchor bolts 132 and 142 protrude from the upper and lower vertical members 130 and 140 in the upper and lower vertical members 130 and 140. do. Reinforce the composite damper 100 including the high damping rubber and the strain-inducing steel rod in such a manner that the anchor bolts 132 and 142 protrude from the protruding anchor bolts 132 and 142 to the coupling plate 632 of the viscoelastic damper member 60. Can be installed on a concrete frame.

The frame damping device including the composite damper and the composite damper composed of the high damping rubber and the strain induced steel bar of the present invention as described above, and the seismic reinforcing method using the same are the viscoelastic damper and the vertical load supporting steel bar and the strain inducing steel bar using the high damping rubber. This composite damper is constructed to dissipate energy due to the characteristics of viscoelastic dampers using high damping rubber when wind or micro deformation occurs, and to support vertical loads while supporting horizontal loads such as earthquakes. Strain-induced steel rods can be elastically deformed to absorb and attenuate horizontal loads to ensure structural stability and usability of the structure, and contribute to productivity improvement due to their simple structure, easy fabrication and installation, and low cost. Even if an earthquake with high magnitude When Jean energy is absorbed by the deformation of elastoplastic damping devices replace only the damping device has a very useful effect, easy maintenance can easily revert back to the state before the earthquake wear Frames.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art may make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The invention is not limited by the invention as such variations and modifications but only by the claims appended below.

10: steel rod
11: thread
12: steel bar slope
13: Steel rod section reduction part
20: first fixing plate
30: second fixing plate
21h, 31h, 22h, 32h: fixing hole
40: vertical load bearing steel rods
60: viscoelastic damper member
61: first connecting member
62: high damping rubber
63: second connecting member
100: Composite damper with high damping rubber and induction steel bar
110: upper horizontal member
120: lower horizontal member
130: upper vertical member
140: lower vertical member
131,141: upper and lower vertical member bonding plate
132,142: upper and lower vertical member anchor bolt

Claims (10)

delete delete An upper horizontal member 110 coupled to the upper slab or the lower surface of the structure;
Lower horizontal member 120 is coupled to the lower slab or beam upper surface of the structure;
Upper vertical members 130 and 130 coupled vertically at both ends of the upper horizontal member 110;
Lower vertical members 140 and 140 spaced in series with the upper vertical member and vertically coupled to both ends of the lower horizontal member 120;
First and second fixing plates 20 and 30 spaced apart at a predetermined distance in a plate shape and configured in parallel; A vertical load supporting steel rod 40 having a plurality of lengths configured to connect the center portion at a predetermined distance from the first and second fixing plates 20 and 30; A plurality of vertical load supporting steel rods 40 are configured to connect the first and second fixing plates 20 and 30 at both sides spaced apart by a predetermined distance, and the tapered inclined portion 12 and the cross section in the center portion thereof to have a smaller cross section toward the center portion. A deformation-inducing steel rod 10 having a predetermined length having a reduction portion 13; The first connection member 61 and the coupling plate of the first connection member 61 are formed with a predetermined length of the H-shaped cross-section and the coupling plate 611 to which a plurality of coupling holes 611a are formed at the other end is coupled. 611 is formed of a high damping rubber 62 and a predetermined length of the H-shaped cross-section, and a plurality of coupling holes 631a and 632a are formed at one end and the other end, respectively. The coupling hole 631a is coupled to a coupling plate 631 and 632 formed of a long hole to connect the coupling plate 611, the high damping rubber 62, and the coupling plate 631 to the outside of the high damping rubber 62. It consists of a second connecting member 63 configured to be coupled by a bolt 70, one end of the first connecting member 61 is joined to the outside of the first and second fixing plates 20, 30 of the composite damper 100, respectively And a viscoelastic damper member 60 configured to be installed between the upper vertical members 130 and 130 and the vertical members 140 and 140. A frame-type vibration damping device including the damping and the rubber and deformation induced gangjaebong the configured composite damper 100 and damping rubber and variations induced gangjaebong complex damper configured characterized in that comprises a. The method according to claim 3,
The deformed induction steel rod 10 and the vertical load supporting steel rod 40 have threads 11 and 41 respectively formed at both ends thereof.
The fixing holes 22h and 32h are formed through the first and second fixing plates 20 and 30 corresponding to both ends of the deformation induction steel rod 10, respectively, and the deformation induction steel bars 10 are formed in the fixing holes 22h and 32h. Both ends are inserted and fixed with a nut 50,
The fixing holes 21h and 31h are formed in the first and second fixing plates 20 and 30 corresponding to both ends of the vertical load supporting steel rod 40 by long holes in the direction of circular or both sides of the deformed induction steel rod 10, respectively. It is formed, the frame-type vibration suppression including a composite damper consisting of a high damping rubber and a deformed induction steel rod, characterized in that both ends of the vertical load supporting steel rod 40 is inserted into the fixing holes (21h, 31h) to be fixed by a nut (50) Device. The method according to claim 4,
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are formed of an H-shaped roll beam that is roll-cast into an H-shaped cross section.
Bonding plates 131 and 141 are installed at the connection portions of the upper and lower vertical members 130 and 140,
Frame damping device comprising a composite damper consisting of a high damping rubber and a deformed induction steel rod, characterized in that the coupling plate 632 and the bonding plate (131, 141) of the viscoelastic damper member 60 are bolted to each other. The method according to claim 4,
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are made of reinforced concrete, and the upper horizontal member 110 and the upper vertical members 130 and 130 are integrally manufactured in a C shape, and the lower horizontal member ( 120) and the lower vertical members (140,140) are integrally manufactured in a U shape,
One end of the anchor bolts (132, 142) in the upper, lower vertical members (130, 140) is embedded in the upper, lower vertical members (130, 140) in advance, and the other ends of the anchor bolts (132, 142) are configured to protrude from the upper, lower vertical members (130, 140) ,
Frame-type vibration damper comprising a composite damper consisting of a high damping rubber and a deformed induction steel bar, characterized in that the anchor bolts (132, 142) protruding from the coupling plate 632 of the viscoelastic damper member 60 is nut-coupled. (a) first and second fixing plates 20 and 30 spaced apart by a predetermined distance in a plate shape and configured in parallel; A vertical load supporting steel rod 40 having a plurality of lengths configured to connect the center portion at a predetermined distance from the first and second fixing plates 20 and 30; A plurality of vertical load supporting steel rods 40 are configured to connect the first and second fixing plates 20 and 30 at both sides spaced apart by a predetermined distance, and the tapered inclined portion 12 and the cross section in the center portion thereof to have a smaller cross section toward the center portion. A deformation-inducing steel rod 10 having a predetermined length having a reduction portion 13; The first connection member 61 and the coupling plate of the first connection member 61 are formed with a predetermined length of the H-shaped cross-section and the coupling plate 611 to which a plurality of coupling holes 611a are formed at the other end is coupled. 611 is formed of a high damping rubber 62 and a predetermined length of the H-shaped cross-section, and a plurality of coupling holes 631a and 632a are formed at one end and the other end, respectively. The coupling hole 631a is coupled to a coupling plate 631 and 632 formed of a long hole to connect the coupling plate 611, the high damping rubber 62, and the coupling plate 631 to the outside of the high damping rubber 62. It consists of a second connecting member 63 configured to be coupled by a bolt 70, one end of the first connecting member 61 is joined to the outside of the first and second fixing plates 20, 30 of the composite damper 100, respectively Viscoelastic damper member 60 is configured to include; high damping rubber configured to include and a composite damper composed of deformation-inducing steel rod (1) 00) and the upper horizontal member 110, the upper vertical member 130, 130 coupled vertically at both ends of the horizontal member 110 and vertically coupled to both ends of the lower horizontal member 120, the lower horizontal member 120 Manufacturing lower vertical members 140 and 140;
(b) coupling the upper horizontal member 110 to the upper slab or the lower surface of the structure and the lower horizontal member 120 to the lower slab or the upper surface of the structure; And
(c) installing the composite damper (100) between the upper vertical member (130,130) and the lower vertical member (140,140); structure seismic reinforcement method using a frame-type vibration damper characterized in that it comprises a. The method according to claim 7,
in step (a),
Composite damper 100,
The deformed induction steel rod 10 and the vertical load supporting steel rod 40 have threads 11 and 41 respectively formed at both ends thereof.
The fixing holes 22h and 32h are formed through the first and second fixing plates 20 and 30 corresponding to both ends of the deformation induction steel rod 10, respectively, and the deformation induction steel bars 10 are formed in the fixing holes 22h and 32h. Both ends are inserted and fixed with a nut 50,
The fixing holes 21h and 31h are formed in the first and second fixing plates 20 and 30 corresponding to both ends of the vertical load supporting steel rod 40 by long holes in the direction of circular or both sides of the deformed induction steel rod 10, respectively. It is formed, both ends of the vertical load supporting steel rod 40 is inserted into the fixing holes (21h, 31h) to be fixed with a nut (50) structure seismic reinforcement method using a frame-type vibration damper. The method according to claim 7,
in step (a),
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are formed of H-shaped roll beams which are roll-cast into H-shaped cross sections, and bonding plates 131 and 141 are installed at the connection portions of the upper and lower vertical members 130 and 140. ,
in step (c),
The seismic reinforcement method of the structure using the frame-type vibration damper, characterized in that the coupling plate 632 and the bonding plates 131, 141 of the viscoelastic damper member 60 are bolted to each other. The method according to claim 7,
in step (a),
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are made of reinforced concrete, and the upper horizontal member 110 and the upper vertical members 130 and 130 are integrally manufactured in a C shape, and the lower horizontal member ( 120) and the lower vertical members (140,140) are integrally manufactured in a U shape,
in step (c),
One end of the anchor bolts (132, 142) in the upper, lower vertical members (130, 140) is embedded in the upper, lower vertical members (130, 140) in advance, and the other ends of the anchor bolts (132, 142) are configured to protrude from the upper, lower vertical members (130, 140) ,
Anchor-bolt strengthening method using a frame-type vibration damper, characterized in that the anchor bolts (132, 142) protruding from the coupling plate 632 of the viscoelastic damper member (60) is nut-coupled.

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