KR102018098B1 - Replaceable rigidity control type hysyeresis damper - Google Patents

Abstract

The present invention relates to a replaceable rigidity control type hysteresis damper. By simplifying a structure, a manufacturing process is easy, and the manufacturing cost and construction period are saved. Since each component is separately manufactured, transported, and installed on site, it is easy to carry and work on site by a worker. In addition, each component is installed separably after an earthquake, thereby facilitating maintenance. The present invention comprises: a pair of fixing members installed and embedded on one side and the other side of a concrete structure together with the construction of the concrete structure; and a damper member, when installing the pair of fixing members, installed by being coupled by a fastening bolt separably therebetween, or by being coupled by the fastening bolt separably between the pair of fixing members after the construction of the concrete structure to absorb vibration energy acting between the pair of fixing members.

Description

Replaceable rigidity control type hysyeresis damper

The present invention relates to a replaceable rigid adjustable hysteresis damper, and in particular, the construction is separated and fabricated after installation in the field is easy to work by installing, replaceable rigid adjustable hysteresis damper to facilitate maintenance after an earthquake. It is about.

In general, earthquake-resistant technologies include earthquake-resistant technologies that absorb seismic energy due to damage to the structure itself to prevent collapse, and concentrate seismic damage to vibration dampers to absorb earthquake energy to reduce building shake and prevent damage to buildings. There are seismic isolation technologies and seismic isolation techniques that prevent earthquake shakes from being transmitted directly to the building.

The types of seismic reinforcement techniques vary depending on the material and type of the structure, but most of them are compressed into three methods: strength, deformation, and input energy reduction. In terms of the cost and air of the seismic reinforcement technique, existing reinforcement techniques that enhance the strength or strength and ductility increase the strength to satisfy the seismic design, so many reinforcement is required. Since the reinforcement technique reduces the earthquake load and has fewer reinforcement points, it can be said that it is much more effective than other methods when evaluating economic feasibility considering air shortening. In addition, in the case of using the vibration suppression device with fewer reinforcement points in construction and bonding with other reinforcement methods, it is possible to secure space and light, so that it can be installed without major problems.

The energy dissipation type vibration damping device can be divided into displacement dependent and speed dependent type. The displacement dependent type device uses the energy dissipation characteristics due to plastic deformation of steel or frictional force of material. Energy generated by dissipating and dissipating vibration energy is large in proportion to speed. Viscous and viscoelastic dampers are mainly used for the characteristics of high wind loads, but steel dampers and friction dampers tend to be used for seismic reinforcement of low-rise buildings. Among them, the application of steel dampers, which are excellent in manufacturability and construction, and exhibits a large deformation capacity, has a large number.

Korean Patent Publication No. 10-1697753 'Stiffness Adjustable Hysteresis Damper with Protective Cover', which is registered and registered by the present applicant as a related prior art, is disclosed (see FIGS. 1A, 1B and 1C). This prior art is a rigid adjustable hysteresis damper, comprising: a steel pipe (60) having a hollow therein; Rigidity adjusting groove 70 formed on the outer surface of the steel pipe 60; And a connection plate 80 connecting the steel pipe 60 and the surrounding structure; to adjust the size, shape, number, or position of the stiffness adjusting groove 70 so that its rigidity can be adjusted. The rigid adjustable hysteresis damper may further include a protective cover 90 at an outer side thereof, and the protective cover 90 may include: a first protective cover 91 covering an entire surface of the rigid adjustable hysteresis damper; And a second protective cover 92 provided only at one or both ends of the rigidly adjustable hysteretic damper in the state where the first protective cover 91 is provided. ) Is divided into an upper protection unit 91a and a lower protection unit 91b, and the rigid adjustable hysteresis damper, the upper protection unit 91a and the lower protection unit 91b are bolted to each other. 2, the protective cover 92 is divided into an upper protection unit 92a and a lower protection unit 92b, and is provided with the rigid adjustable hysteresis damper, the first protection cover 91, the upper protection unit 92a and the lower portion. The protection unit (92b) is bolted to each other, characterized in that the rigidly adjustable hysteresis damper (see claim 1) provided with a protective cover, characterized in that the bolt is coupled to flow through the slit hole (h), the By adjusting the shape or size or the number or position of the stiffness adjusting groove, Regardless of the size, shape, use or usage environment of the structure, the rigidity can be freely adjusted, and the protective cover is installed in a structure that does not transmit force to the damper side, so that the damper does not interfere with the rigidity control efficiency. .

However, the above-described prior art has a problem in that its construction is rather complicated, making the manufacturing process difficult and increasing the construction cost. In addition, since the components are integrally manufactured and then transported and installed to the site, there is a problem in that transportation and installation are not easy. In addition, since the components are integrally manufactured and then installed, there is a problem in that replacement is not easy when the earthquake is damaged.

Republic of Korea Patent Publication No. 10-1697753

In order to solve the above problems, the present invention is to provide a replaceable rigid adjustable hysteresis damper that the manufacturing process is easy, manufacturing cost and construction period is reduced by simplifying the configuration.

In addition, by separately manufacturing each component to be transported and installed on-site, to provide a replaceable rigid adjustable hysteresis damper that is easy to transport and field work of the operator.

In addition, by installing each component separably after an earthquake or the like, to provide a replaceable rigid adjustable hysteresis damper that can facilitate maintenance.

Replaceable rigid adjustable hysteresis damper according to an embodiment of the present invention is a pair of fixing member is installed and embedded on one side and the other side of the concrete structure with the construction of the concrete structure; When the pair of fixing members are installed, the coupling bolts are installed to be detachable therebetween, or the coupling bolts are installed to be detachable between the pair of fixing members after construction of the concrete structure. And a damper member for absorbing vibration energy acting between the pair of fixing members.

In addition, each of the pair of fixing members, buried in the concrete structure H-shaped steel including a pair of flanges and webs connecting the pair of flanges are installed spaced apart from each other; An inner side coupled to the H-beam and an outer side fixing plate exposed to the outside of the concrete structure; And a buried nut coupled to the inside of the fixing plate, and the fastening bolt may be coupled to the buried nut.

In addition, the buried nut further includes a silicon member or PE (Polyethylene, polyethylene) member provided, the end of the fastening bolt may be characterized in that it is inserted into the silicon member or PE member.

In addition, the damper member is provided on both sides of the pair of coupling plates installed in contact with each of the fixing plate; And a plurality of damper plates installed side by side while being spaced apart from each other to be coupled between the pair of coupling plates, wherein the damper plates include a wider extension portion at both ends and a narrow absorption portion at the center portion. You can do

In addition, a plurality of shear members for mutually coupling the expansion portion, the shear member is installed between the plurality of shear bolts and fastening bolts that penetrate through the expansion portion, and the plurality of expansion portions at the same time installed in the shear bolt And it may be characterized in that it comprises a shear pipe to support the expansion at the same time to reinforce the shear bolt.

In addition, the upper plate and the lower plate and the inner plate covering the upper and lower portions and the inner portion of the plurality of expansion portion, the combined space and the upper portion, the lower plate and the inner plate to form a closed space, the concrete is It may be characterized by being filled.

The apparatus may further include an upper protective cover and a lower protective cover surrounding the outer side of the damper member, wherein the upper protective cover includes an upper cover plate covering an upper surface of the damper member, a front cover plate covering the front surface of the damper member, and the damper member. The rear cover plate covering the back of the, may be characterized by including a pair of side cover plate is installed on both sides.

In addition, the side cover plate may be inserted between the fixing member and the damper member may be fastened with the fastening bolt.

In the present invention, by simplifying the configuration, the manufacturing process is simple, manufacturing cost and construction period can be saved.

In addition, by separately manufacturing each component and then transported and installed in the field, it can be easy to transport and field work of the operator.

In addition, the components can be detachably installed after an earthquake or the like, thereby facilitating maintenance.

In addition, by installing a buried nut on the inside of the concrete structure, and by further installing a silicon member or a PE member inside the buried nut, it is possible to fasten the fastening bolts of various lengths.

In addition, by adjusting the number of damper plates, coupling the extension parts of the damper plate to the shear member, adjusting the number of shear members, or placing concrete between the extension parts, the seismic performance of the damper plates is increased, and necessary. The seismic performance can be easily ensured.

1A-1C are prior art drawings.
2 is a view showing a position where a replaceable rigid adjustable hysteresis damper according to an example of the present invention is installed.
3A is an exploded perspective view of a replaceable rigid adjustable hysteresis damper in accordance with an example of the present invention.
3B is a perspective view of a replaceable rigid adjustable hysteresis damper assembled according to an example of the present invention.
3C is a perspective view showing a state in which a damper member is coupled between a pair of fixing members of the present invention.
Figure 3d is a perspective view showing a state of the fastening bolt fastened to the buried nut and the buried nut is installed inside the fixing plate of the present invention.
3E is a perspective view illustrating a state in which expansion parts of the damper plates of the present invention are mutually coupled to a shear member.
Figure 3f is a perspective view showing a state in which the upper plate and the lower plate and the inner plate further installed in the expansion portion of the damper plate of the present invention to form a closed space portion and then filled with concrete and integrated therein.

Hereinafter, some embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the reference numerals to the components of the drawings, the same components are to have the same reference numerals as much as possible even if displayed on different drawings. In addition, in describing the embodiments of the present invention, when it is determined that a detailed description of a related well-known configuration or function disturbs the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but there is another component between each component. May be “connected”, “coupled” or “connected”.

Hereinafter, a replaceable rigid adjustable hysteresis damper according to an example of the present invention will be described in detail with reference to FIGS. 2 to 3.

Replaceable rigid adjustable hysteresis damper according to an embodiment of the present invention is a pair of fixing member 10 is installed and embedded on one side and the other side of the concrete structure with the construction of the concrete structure; When the pair of fixing members 10 are installed, the coupling bolts are installed to be detachable therebetween, or after the construction of the concrete structure, the fixing bolts are detachable between the pair of fixing members 10. By being installed in combination, the damper member 20 for absorbing the vibration energy acting between the pair of fixing member 10; may include.

This embodiment can be installed in the concrete structure, for example, installed between the slab and the inner beam inside the concrete structure, it is possible to increase the seismic performance by absorbing the seismic energy acting on the concrete structure.

The pair of fixing members 10 may be buried in one side and the other side of the concrete structure, for example, the slab and the pullout of the concrete structure. The fixing member 10 may include an H-shaped steel 12, a fixing plate 14, a buried nut 16, and the like.

The H-shaped steel 12 may be embedded in the interior of the concrete structure, that is, a slab, a pullout, or the like, and may include a web connecting a pair of flanges and a pair of flanges spaced apart from each other.

The fixing plate 14 may be coupled to the inner side of the H-shaped steel 12 and exposed to the outside of the concrete structure. That is, the inner side of the fixing plate 14 is welded to the pair of flanges and the web of the H-shaped steel 12 at the same time, the outer side is exposed to the outside of the concrete structure may be coupled to the coupling plate 22 to be described later. The fixing plate 14 may be formed with a plurality of insertion holes into which the fastening bolt can be inserted.

The buried nut 16 may be embedded in the concrete structure by being welded to the inside of the fixing plate 14, that is, the inside of the position where the insertion hole is formed. A fastening bolt inserted through the insertion hole is fastened to the buried nut 16 to couple the coupling plate 22 of the damper member 20 to be described later.

The inner end of the buried nut 16 may be further provided with a silicon member 18 or a PE member (18). An end of the fastening bolt may be inserted into the silicon member 18 or the PE member 18. That is, by providing the silicon member 18 or the PE member 18 at the inner end of the buried nut 16, various fastening bolts, for example, long fastening bolts can be easily fastened.

The damper member 20 is installed by coupling with a fastening bolt so as to be detachable therebetween when the pair of fixing members 10 are installed, or separated between the pair of fixing members 10 after construction of the concrete structure. It can be installed in combination with fastening bolts to make it possible. The damper member 20 may increase vibration resistance against earthquakes acting on the concrete structure by absorbing vibration energy acting on the concrete structure.

The damper member 20 may include a plurality of damper plates 24 coupled by welding or the like between the pair of coupling plates 22 and the pair of coupling plates 22. The pair of coupling plates 22 may be installed in contact with the fixing plate 14 of the fixing member 10 and then fastened with the above-described fastening bolts. That is, a plurality of insertion holes corresponding to the insertion holes of the fixing plate 14 are formed in the coupling plate 22, and the above-mentioned fastening bolts may be inserted into the coupling plate 16 to be fastened to the buried nut 16. have. That is, the damper member 20 is installed on the fixing plate 14 exposed to the outside of the concrete structure so as to contact the fastening plate 22 and fastened to penetrate the insertion hole formed in the fixing plate 14 and the coupling plate 22. The bolt may be inserted into the buried nut 16.

The plurality of damper plates 24 may be coupled by welding or the like between the pair of coupling plates 22. The damper plate 24 may be installed side by side while being spaced apart from each other. That is, the plurality of damper plates 24 are installed side by side while being spaced apart from each other between the pair of coupling plates 22, thereby absorbing seismic energy acting between the pair of concrete structures to increase the seismic performance.

The damper plate 24 of the present embodiment absorbs energy due to the seismic load acting on the concrete structure, and can be adjusted to suit the seismic design value of the concrete structure by controlling the number, stiffness, and thickness of the damper plate 24. .

The damper plate 24 may include a wider extension portion 242 that is both ends, and a narrow absorption portion 246 that is a central portion. That is, the damper plate 24 may include a wider extension portion 242, which is a portion that is coupled to the coupling plate 22 by welding, and an absorbing portion 246, which is a central portion connecting both expansion portions 242. Can be.

The plurality of expansion parts 242 spaced apart from each other may be coupled to each other by a shear member 25. The shear member 25 may be composed of only a shear bolt 252, or may include a shear bolt 252 and a shear pipe 254. When only the front bolt 252 is configured, the front bolt 252 may be fastened with a nut after passing through the plurality of expansion parts 242. In this case, the nut may be fastened to the end of the shear bolt 252, or may be fastened both before and after each expansion 242. When the shear bolt 252 and the shear pipe 254 are included, the shear bolt 252 is fastened through the plurality of expansion portions 242, and the shear bolt 252 between the expansion portions 242 is sheared. Pipe 254 may be fitted to be installed. The shear pipe 254 may reinforce the rigidity of the shear bolt 252 and maintain the spacing between the extension portions 242. Therefore, it may not be necessary to tighten the nut before and after the extension 242.

The shear member 25 can cope well with the load acting in the left and right directions by coupling the plurality of expansion portions 242 at the same time, and at the same time bending at the coupling point of the expansion portion 242 and the coupling plate 22 Can be prevented. Therefore, by allowing the earthquake load to be absorbed by the absorber 246, the designed earthquake strength can be secured and excellent seismic performance can be exhibited.

The damper member 20 may include an upper plate 272 and a lower plate and an inner plate 276 that cover upper and lower portions and inner portions of the plurality of expansion portions 242 of the damper plates 24. The upper plate 272, the lower plate and the inner plate 276 may be formed of a waste space together with the coupling plate 22 and the expansion portion 242, and the waste space may be filled with concrete. That is, the space formed by the coupling plate 22 of the damper member 20 and the expansion part 242 of the damper plate 24 is covered with the upper plate 272 and the lower plate inner plate 276 to form a closed space portion. By filling concrete in the closed space, it prevents the bending at the coupling point of the expansion part 242 and the coupling plate 22, and secures the designed earthquake strength by allowing the absorbing part 246 to receive the earthquake load. Excellent seismic performance can be achieved. Filling holes may be formed in the upper plate 272 to fill concrete.

The outside of the damper member 20 may be wrapped with the upper protective cover 30 and the lower protective cover 32. The upper protective cover 30 is the upper cover plate 302 covering the upper surface of the damper member 20, the front cover plate 304 covering the front surface of the damper member 20, the rear surface of the damper member 20 Covering the back cover plate, it may include a pair of side cover plate 308 is installed on both sides.

The side cover plate 308 may be inserted between the fixing member 10 and the damper member 20 to be fastened with the fastening bolts. That is, the side cover plate 308 may be inserted between the fixing plate 14 of the fixing member 10 and the coupling plate 22 of the damper member 20 to be fastened together. Therefore, the coupling process of the upper protective cover 30 is simple, the coupling portion may not be exposed to the outside. The lower protective cover 32 may be welded or bolted from the lower side of the upper protective cover 30.

In the above description, all elements constituting the embodiments of the present invention are described as being combined or operating in combination, but the present invention is not necessarily limited to the embodiments. That is, within the scope of the present invention, all of the components may be configured or operated by selectively combining one or more of them. In addition, the terms "comprise", "comprise" or "having" described above mean that the corresponding component may be inherent unless specifically stated otherwise, and thus excludes other components. It should be construed that it may further include other components instead. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms commonly used, such as terms defined in a dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be construed in an ideal or overly formal sense unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

10: fixing member
12: H section steel
14: fixing plate
16: Landfill Nut
18: silicone member or PE member
20: damper member
22: binding plate
24: damper plate
242: extension
246: absorber
25: shear member
252: shear bolt
254: shear pipe
272: top plate
276: inner plate
30: upper protective cover
302: top cover plate
304: faceplate
308: side cover plate
32: lower protective cover

Claims (8)

A pair of fixing members installed on one side and the other side of the concrete structure together with the construction of the concrete structure;
When the pair of fixing members are installed, the coupling bolts are installed to be detachable therebetween, or the coupling bolts are installed to be detachable between the pair of fixing members after construction of the concrete structure. And a damper member absorbing vibration energy acting between the pair of fixing members.
Each of the pair of fixing members,
An H-shaped steel embedded in the concrete structure and including a pair of flanges spaced apart from each other and a web connecting the pair of flanges;
The inner side is coupled to the H-beam and the outer side includes a fixing plate exposed to the outside of the concrete structure,
The damper member is
A pair of coupling plates provided on both sides and installed in contact with the fixing plate, respectively;
It includes; a plurality of damper plates are installed side by side while being spaced apart from each other to be coupled between the pair of coupling plates,
The damper plate includes a wide expansion portion at both ends and a narrow absorption portion at the center portion,
Further comprising a shear member for coupling a plurality of said expansion portion,
The shear member includes a shear bolt fastened through the plurality of expansion portions and a shear pipe installed between the expansion portions and inserted into the shear bolt to reinforce the shear bolt and simultaneously support the expansion portion. Including,
And an upper plate, a lower plate, and an inner plate covering the upper and lower and inner portions of the plurality of expansion parts. The method according to claim 1,
Includes a buried nut coupled to the inside of the fixing plate,
The fastening bolt is replaceable rigid adjustable hysteresis damper, characterized in that coupled to the buried nut. The method according to claim 2,
Further comprising a silicon member or a PE (Polyethylene, polyethylene) member provided inside the buried nut,
End of the fastening bolt is replaceable rigid adjustable hysteresis damper, characterized in that inserted into the silicon member or PE member. delete delete The method according to claim 1,
A closed space is formed by the coupling plate, the expansion unit, the upper plate, the lower plate, and the inner plate;
Replaceable rigidity adjustable hysteresis damper, characterized in that the concrete is filled in the closed space. The method according to claim 1,
Further comprising an upper protective cover and a lower protective cover surrounding the outside of the damper member,
The upper protective cover includes an upper cover plate covering the upper surface of the damper member, a front cover plate covering the front surface of the damper member, a rear cover plate covering the rear surface of the damper member, and a pair of side cover plates installed at both sides thereof. Replaceable rigid adjustable hysteresis damper comprising a. The method according to claim 7,
And the side cover plate is inserted between the fixing member and the damper member and fastened with the fastening bolts.

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