KR101186448B1 - Lintel beam type hysteretic damper using interstory drift of rahmen frame - Google Patents

Abstract

The present invention relates to a damper using the interlaminar deformation of a ramen frame. In particular, the damper is installed on a pulverized beam and operates by the interlaminar deformation that occurs when the horizontal load acts on the ramen frame structure in which the column and beam are in contact with each other. It is about damper which can attenuate.
The hygroscopic hysteresis damper using the interlayer deformation according to the preferred embodiment of the present invention is a simple plate positioned between a plurality of plate-shaped damping plate having a flat plate-like plane in which the long width portion is formed at both ends of the short width portion, and the long width portion of the damping plate. Vibration absorbers made of a tapered shape of the width connecting the short width portion and the long width portion is connected to the long width portion linearly wider, the short width portion plastic deformation relative to the horizontal load acting; A first fixed plate positioned above and below one end of the long width portion of the vibration absorber, and a second fixed plate respectively positioned above and below the other end of the long width portion of the vibration absorber; A first fixing bolt coupling the first and second fixing plates to the vibration absorber; And a safety plate which is hinged to the front and rear surfaces of the vibration absorber, respectively, to freely rotate when the short width portion is plastically deformed by the horizontal load, and to prevent the long width portions of both ends from being separated from each other after the short width portions of the plurality of plate damping plates are all broken. .

Description

Lintel beam type hysteretic damper using interstory drift of rahmen frame}

The present invention relates to a damper using the interlaminar deformation of a ramen frame. In particular, the damper is installed on a pulverized beam and operates by the interlaminar deformation that occurs when the horizontal load acts on the ramen frame structure in which the column and beam are in contact with each other, and absorbs the horizontal load by hysteresis. It is about damper which can attenuate.

Vibration Control refers to the control of vibrations caused by wind or earthquakes in buildings, and a 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, and the latter is mainly installed on each floor to be used for the safety of the earthquake and the wind habitability.

Energy dissipation type vibration suppressors can be divided into displacement-dependent and speed-dependent types. Displacement-dependent devices utilize energy dissipation characteristics due to frictional forces between materials or plastic deformation of metals. By generating heat and dissipating vibration energy, the dissipated energy is large in proportion to the speed.

Speed-dependent hydraulic dampers have superior seismic performance compared to displacement-dependent steel dampers, and are mainly used in Japan, where heavy and heavy earthquakes occur frequently throughout the country. However, since the 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 steel damper has a somewhat lower seismic performance than the hydraulic damper, but the steel damper is used for reinforcement of the steel structure because the construction cost is low.

However, the vibration damping structure using the above-mentioned steel 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.

Therefore, it is possible to solve the problems of the vibration damping structure using the above-mentioned hydraulic damper and the vibration damping structure using the steel damper, that is, economical and spatial obstacles, and to obtain the optimum seismic control effect at a reasonable cost as well as the earthquake load. There is an urgent need for a new vibration isolator that can achieve effects on horizontal loads including wind loads.

In particular, in Korea, there are many buildings that were constructed before the seismic design standards were applied and the remodeling of old buildings is active, and the development of passive vibration damping devices that can achieve sufficient seismic reinforcement effect at low cost is required.

The present invention has been made in view of the above circumstances and has the following object.

The present invention operates by the interlayer deformation that occurs when the horizontal load acts on the ramen frame structure in which the column and beam are rigidly installed without being limited by space because it is installed in the pulverized beam and efficiently absorbs and attenuates the horizontal load using hysteretic behavior. It is possible to provide a damper that can prevent structural collapse even if the damping plate that is hysterically acting can be prevented from collapsing.

The hygroscopic hysteresis damper using the interlayer deformation according to the preferred embodiment of the present invention is a simple plate positioned between a plurality of plate-shaped damping plate having a flat plate-like plane in which the long width portion is formed at both ends of the short width portion, and the long width portion of the damping plate. Vibration absorbers made of a tapered shape of the width connecting the short width portion and the long width portion is connected to the long width portion linearly wider, the short width portion plastic deformation relative to the horizontal load acting; A first fixed plate positioned above and below one end of the long width portion of the vibration absorber, and a second fixed plate respectively positioned above and below the other end of the long width portion of the vibration absorber; A first fixing bolt coupling the first and second fixing plates to the vibration absorber; And a safety plate which is hinged to the front and rear surfaces of the vibration absorber, respectively, to freely rotate when the short width portion is plastically deformed by the horizontal load, and to prevent the long width portions of both ends from being separated from each other after the short width portions of the plurality of plate damping plates are all broken. .

According to another suitable embodiment of the present invention, the abdominal plate is coupled along the longitudinal direction of the fixing plate to connect the upper and lower first fixing plate and the upper and lower second fixing plate, respectively; And a fitting plate coupled along the width direction of the fixing plate to connect the upper and lower first fixing plates and the upper and lower second fixing plates, respectively, wherein both ends of the vibration absorber are in contact with each other.

According to another suitable embodiment of the present invention, the space between the vibration absorber and the safety plate is filled with an insulating material so as to prevent the penetration of concrete during concrete placement, so that the vibration absorber can move freely when a horizontal load is applied.

According to another suitable embodiment of the present invention, the U-shaped main root consisting of two or more spaced at regular intervals in the width direction of the first and the second fixing plate, and wrapped around the interruption of the main root and formed along the longitudinal direction of the main root Wall fixing reinforcing bars including a plurality of stirrup reinforcement is fixed to the outer end of the first and second fixing plate, respectively.

The plenum-proof eccentric damper according to the present invention is designed to operate by the interlaminar deformation of the ramen frame due to the horizontal load, and is constructed in the specimen shape so that the deformation is concentrated on the short width portion of the damping plate. The deformation can be absorbed by plastic deformation of the short width portion. In addition, by installing a safety plate suddenly a large horizontal load is applied to prevent the collapse of the pullover even if the damping plate is broken.

The following drawings, which are attached in the present specification, illustrate exemplary embodiments of the present invention, and together with the detailed description of the present invention, 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 hysteresis-type hysteresis damper according to an embodiment of the present invention, Figure 2 is an enlarged view of an important part of FIG. In addition, Figure 3 is an exploded perspective view of the hysteresis-type hysteresis damper according to an embodiment of the present invention.
4A and 4B are diagrams illustrating a state of use of the hysteresis-type hysteresis damper according to an exemplary embodiment of the present invention, where 4a is a front view and 4b is a plan view.
5 is a conceptual view showing a deformation form according to the shear behavior of the pulverulent beam.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

1 is a perspective view of a hysteresis-type hysteresis damper according to an embodiment of the present invention, Figure 2 is an enlarged view of an important part of FIG. In addition, Figure 3 is an exploded perspective view of the hysteresis-type hysteresis damper according to an embodiment of the present invention.

As shown in FIGS. 1 to 3, the hygroscopic hysteresis damper 10 according to an embodiment of the present invention includes a pair of first and second bodies 11a and 11b spaced apart in a horizontal direction, and The vibration absorber 12 installed between the first and second bodies 11a and 11b, a pair of safety plates 13 hinged to the front and rear surfaces of the vibration absorber 12, and the first and second bodies ( First and second wall fixing reinforcing bars 14a and 14b respectively provided on the outside of 11a and 11b.

The hygroscopic hysteresis damper 10 having such a configuration has a symmetrical shape with respect to the vibration absorber 12. That is, a pair of the first body 11a and the first wall fixing rebar 14a at one end of the vibration absorber 12 and a pair of the second body 11b and the second wall fixing bar 14b at the other end thereof. Are installed respectively.

Each component described above will be described in more detail.

First, the vibration absorber 12 has a structure in which a plurality of damping plates 122 and simple plates 124 are alternately stacked.

The damping plate 122 of the vibration absorber 12 is a thin steel plate. The plane is in the form of a specimen in which long width portions are formed at both ends of the short width portion. The connecting portion connecting the short width portion and the long width portion of the damping plate 122 has a tapered shape in which the width is linearly widened toward the long width portion side.

The damping plate 122 of this shape is stacked up and down, spaced apart at equal intervals so that the simple rate (124) can be located between a pair of adjacent damping plate (122).

The simple rate 124 is composed of first and second simple rates 124a and 124b positioned at the long width portions of both ends of the damping plate 122. The simple plate 124 is a thin plate and is formed in the same shape and width as the long width portion of the damping plate 122.

At this time, the simple rate 124 is formed with a different thickness according to the position. That is, as shown in Figure 2, the top and bottom of the simple rate is formed thinner than the simple rate of the middle.

On the other hand, the damping plate 122 and the simple plate 124 are integrally connected by the first fixing bolt 126, wherein the fixing bolt 126 is the first and the plate in addition to the damping plate 122 and the simple plate (124) The second fixing plates 110a and 110b are connected together.

The vibration absorber 12 described above is a means for absorbing and dissipating the horizontal load. That is, when a horizontal load is applied through the first and second bodies 11a and 11b, the short width portion of the damping plate 122 made of steel is plastically deformed and absorbed and dissipated.

The damping plate 122 is a structure that is stacked up and down as described above, and is coupled by the fixing bolt 126. The vibration absorber 12 of this structure may adjust the number of damping plates 122 as necessary. For example, in the region where the horizontal load including the wind load is expected, the number of damping plates 122 may be increased, and in other regions, the number of damping plates 122 may be reduced.

In addition to the above-described reasons, the number of damping plates 122 is adjusted according to the height (dance) of the pulverized beam, and in the case of the damping plates 122 that are severely deformed due to deformation, replacement is also possible.

On the other hand, the first fixing bolt 126 to integrate the damping plate 122 and the simple plate 124 is composed of a pair spaced apart in the width direction of the first and second fixing plates (110a, 110b). This is to prevent the fixing plate (110a, 110b) is rotated about the fixing bolt 126.

Body (11a, 11b) is a pair of fixing plates (110a, 110b) and the abdominal plate coupled to each other along the longitudinal direction of the fixing plates (110a, 11b) to connect a pair of fixing plates (110a, 110b) to each other ( 111a and 111b and fitting plates 112a and 112b which are coupled along the width direction of the fixing plates 110a and 11b to connect a pair of fixing plates 110a and 110b to each other and to which both ends of the vibration absorber 12 come into contact with each other. )

The fixed plates 110a and 110b are configured in pairs positioned at the long end portions of both ends of the vibration absorber 12. In addition, the first fixed plate (110a) is a pair attached to the upper and lower ends of the long width portion of the vibration absorber 12, respectively, and the second fixed plate (110b) and the upper and the other end of the long width portion of the vibration absorber 120 It consists of a pair each attached to the lower surface.

The abdominal plates 111a and 111b connect the pair of first fixing plates 110a to form the H-shaped cross-section and the first abdominal plate 111a to connect the pair of second fixing plates 110b to form the H-shaped cross-section. The second abdominal plate 111b is formed, and each of the abdominal plates 111a and 111b is embedded in the plinth beam, and the holes 111c are formed to increase the combined force with the concrete constituting the plinth beam.

The fitting plates 112a and 112b connect the pair of first fixing plates 110a to partition a space for accommodating one end of the long width portion of the vibration absorber 12 while allowing the long width portion to be in surface contact with the first fitting plate 112a. ) And a second fitting plate 112b for connecting the pair of second fixing plates 110b to allow the other end of the long width part to be in surface contact while partitioning a space accommodating the other end of the long width part of the vibration absorber 12. Thus, both ends of the vibration absorber 12 contact the fitting plates 112a and 112b, respectively, to prevent the vibration absorber 12 from rotating around the first fixing bolt 126 together with the pair of fixing bolts 126. Done.

Before and after the vibration absorber 12, a pair of safety plates 13 are hinged. The safety plate 13 is a rectangular plate shape and has a height smaller than a gap between the pair of first fixing plates 110a and the pair of second fixing plates 110b and all corners are rounded. The length may have a length equal to or slightly larger than the length of the damping plate 122. Therefore, each of the pair of first fixed plate (110a) and a pair of the second fixed plate (110b) spaced apart in the height direction at regular intervals and when the hysteresis damper according to the invention is operated by the interlayer deformation fixed plate ( By being able to rotate until the edge abuts 110a and 110b, the damping plate 122 is deformed to sufficiently absorb the horizontal load. The size, that is, the height and the length of the safety plate 13 may be determined by the magnitude of the horizontal load that the damping plate 122 can absorb by the displacement angle generated by the interlayer deformation. By installing the safety plate 13 as described above, even if the damping plate 122 is broken, it is possible to prevent the collapse of the pullout.

The safety plate 13 may be hinged to each of the front and rear surfaces of the vibration absorber 12 using the second fixing bolt 136. That is, before the vibration absorber 12 is moved by the pair of second fixing bolts 136 penetrating the first and second simple plates 124a and 124b positioned at the long width portions of both ends of the damping plate 122, respectively. The safety plates 13 are respectively coupled to the rear surface and are rotatably coupled to the second fixing bolt 136.

Wall fixing reinforcing bars (14a, 14b) is a portion that is embedded in the wall (30 of Figure 4) and fixed when installing the hysteresis-type hysteresis damper (10). The wall fixing reinforcing bars 14a and 14b are constituted by a pair fixed to the outer ends of the first and second fixing plates 110a and 110b, respectively.

Looking at the configuration, the U-shaped main roots (142a, 142b) and the stop of the main roots (142a, 142b) of which both ends are fixed to the outer ends of the pair of first and second fixing plates (110a, 110b), respectively It includes a plurality of stub steel reinforcing (144a, 144b).

At this time, the main roots (142a, 142b) is composed of two or more (three in the present embodiment) spaced at equal intervals in the width direction of the first and second fixing plates (110a, 110b). In addition, the stirrup reinforcing bars (144a, 144b) is composed of a plurality formed along the longitudinal direction of the main bars (142a, 142b).

4A and 4B are diagrams illustrating a state of use of the hysteresis-type hysteresis damper according to an exemplary embodiment of the present invention, where 4a is a front view and 4b is a plan view.

The pulverization-type hysteresis damper 10 according to an embodiment of the present invention is installed on the pulpal beam or is installed in place of the pulpal beam.

In this case, the space between the vibration absorber 12 and the safety plate 13 may be filled with the insulating material 33. This insulating material 33 is for preventing the concrete from flowing into the vibration absorber (12). That is, by separating the periphery of the vibration absorber 12 from the concrete so that the portion (vibration absorber) can move freely when a horizontal load is applied. The insulating material 33 may be made of a rubber material, and preferably high damping rubber may be used.

Therefore, when a horizontal load is applied through the first and second fixed plates 110a and 110b, the short width portion of the damping plate 122 is deformed and absorbed and extinguished.

As described above, the pulverized beam-type hysteresis damper 10 according to an embodiment of the present invention is installed at a predetermined position of the pulverized formwork (frame formed by molding, plywood, wood, etc.) before placing concrete, and thus has excellent workability. great. This structure can compensate for the drawbacks of the BRACE type damping device assembled and installed on site.

Hereinafter, the composite vibration damper according to an embodiment of the present invention will be described in detail with the example of the horizontal load action with an example installed in the pulley beam.

5 is a conceptual view showing a deformation form according to the shear behavior of the pulverulent beam.

As shown in FIG. 5, when a wind or earthquake acts on the structure, shear force is generated in the pulley beam, and minute micro deformation (displacement angle) occurs in the ramen frame. As shown in FIG. 4, the hysteresis damper according to the present invention installed in the center of the pulley is basically behaved by the shear force generated by wind or earthquake, and plastic deformation occurs in response to the micro deformation.

That is, the short width portion of the damping plate 122 is plastically deformed to absorb the horizontal load. At this time, the plane of the damping plate 122 is a specimen shape having a long width portion at both ends of the short width portion, and the connection portion connecting the short width portion and the long width portion of the damping plate 122 has a tapered shape in which the width is linearly widened toward the long width portion side. It is structured to induce deformation to concentrate on the short width part when the horizontal load is applied, and absorbs the horizontal load by plastic deformation in the short width part. At this time, the safety plate 13 is free to rotate without receiving a horizontal load.

And even if the horizontal load exceeding the plastic deformation region of the short width portion is applied, even if the short width portion is broken, the safety plate 13 can prevent the collapse of the tear beam by connecting the pulley beams on both sides.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

110a: first fixing plate
110b: second fixing plate
12: vibration absorber
122: damping plate
124: simple rate
13: safety valve

Claims (4)

It consists of a plurality of plate-shaped damping plates having a specimen-like plane in which the long width portion is formed at both ends of the short width portion, and a simple rate located between the long width portions of the damping plate, and the portion connecting the short width portion and the long width portion toward the long width portion. A vibration-absorbing body having a linearly tapered shape and having a short width portion plastically deformed with respect to an acting horizontal load and absorbing the horizontal load;
A first fixed plate positioned above and below one end of the long width portion of the vibration absorber, and a second fixed plate respectively positioned above and below the other end of the long width portion of the vibration absorber;
A first fixing bolt coupling the first and second fixing plates to the vibration absorber;
A safety plate that is hinged to the front and rear surfaces of the vibration absorber and freely rotates when the short width portion is plastically deformed by the horizontal load, and prevents the long width portions of both ends from being separated from each other after the short width portions of the plurality of plate damping plates are all broken;
An abdominal plate coupled along the longitudinal direction of the fixing plate to connect the upper and lower first fixing plates and the upper and lower second fixing plates, respectively; And
Coupled along the width direction of the fixed plate is connected to each of the upper and lower first fixed plate and the upper and lower second fixed plate, the interlaminar hysteresis-type hysteresis damper using an interlayer deformation, characterized in that it comprises a fitting plate that both ends of the vibration absorber contact. delete The method according to claim 1,
An interlaminar hysteresis damper using interlayer deformation, characterized in that the space between the vibration absorber and the safety plate is filled with an insulating material so as to prevent the penetration of concrete during concrete placing so that the vibration absorber can move freely when a horizontal load is applied. The method according to claim 1,
Wall fixing including two or more U-shaped main roots which are equally spaced apart in the width direction of the first and second fixing plates, and a plurality of stub steel reinforcing the interruption of the main roots and formed along the longitudinal direction of the main roots Reinforcement-proof hysteresis damper using an interlayer deformation, characterized in that the reinforcing bar is fixed to the outer ends of the first and second fixing plates, respectively.

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