KR101858493B1 - Hinge Junction Coupling Beam Type Steel Finger Damper - Google Patents

Abstract

The present invention relates to a damper installed inside a center portion of a connecting beam connecting two neighboring reinforcing concrete shear walls, comprising: a pair of steel frame members 100 spaced apart from each other on both sides; A hinge hole 22 rotatably coupled to the upper end of each of the steel frame members 100 by a hinge bolt 33 is provided at both the left and right ends of the hinge hole 22 to connect the steel frame members 100 spaced apart from each other, (250); A hinge hole (22) rotatably coupled to a lower end of each of the steel members (100) by a hinge bolt (33) is provided at both left and right ends of the lower displacement displacement transmitting and contracting member (200); And upper ends of each of the vertical extending pieces 310 are coupled to a central portion of the upper displacement transducer 250 by a coupling bolt 44 And a lower end portion extending in the horizontal direction is coupled to a central portion of the lower displacement transitional member 200 with a coupling bolt 44. [

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hinge-

[0001] The present invention relates to a hinge-connected connecting-type flange steel damper at the center of a connecting beam of a reinforced concrete shear wall structure, in which a minute shear displacement under the slab by interlayer displacement is doubled through a hinge- , Minimizes the damage of the joint between the shear wall and the connecting beam and the plastic area under the shear wall when the earthquake occurs, and prevents the broken joint from breaking due to the hinge joint structure even when the finger is broken due to repeated seismic forces. And property loss can be prevented.

Recently, due to the rapid industrialization of our country, the concentration of population in the city has intensified so that many of the general buildings including the apartment buildings are being built up due to the environmental impact of narrow urban papers (residential papers and commercial papers).

These high-rise buildings are generally sized by the load acting in the horizontal direction of the building. The horizontal load acting on the structure is the earthquake load and the wind load, and the building can secure the usability and sufficient safety of the building by securing the appropriate rigidity and strength against these horizontal loads.

In addition, wind loads and seismic loads acting on the buildings cause dynamic behavior in buildings with unpredictable directionality, so it is necessary to secure structural safety. Therefore, a variety of vibration control technologies including a conventional method through securing rigidity and strength are required.

Most of the high-rise buildings including the domestic apartment houses use the reinforced concrete shear wall as the main lateral resistance structural element. This is because the transverse stiffness is superior to the frame system and the displacement due to the major horizontal load of the building such as wind load and seismic load can be reliably controlled.

However, since it is difficult to control the horizontal displacement efficiently by the cantilever shape of the reinforced concrete structure, it is difficult to control the horizontal displacement effectively. Therefore, it is difficult to control the displacement of the frame by connecting the two reinforced concrete shear walls with a link beam or a coupling beam ) Type shear wall structure is used.

Therefore, it is necessary to solve the problem of economic and construction inherent in the connection structure of ordinary shear wall structure and special shear wall structure which are indispensably required in the openings of domestic high-rise buildings, as well as to secure structural stability against earthquake load or wind load, It is urgent to develop technology for shear connection.

Recently, in Korea, various connection type dampers such as a shear yield type slit steel damper, a friction damper, and a shear yielding type steel damper have been developed and actively applied in response to shear wall connection beams.

However, these existing connection type dampers need to complement some important parts.

First, existing friction dampers or steel dampers can only be installed with limited specifications at the center of the connection beam at the bottom of the slab due to their application characteristics. In general slabs, the shear displacement due to interlayer displacement is insufficient, It is practically impossible to expect the damping of the displacement and the seismic force of the damper.

Second, in the case of a conventional slit steel damper, when the displacement occurs repeatedly four to five times or more due to an earthquake, the slit portion is inevitably ruptured. In this case, there is a serious problem that the connecting beam itself is broken have.

Third, when an earthquake occurs, the existing friction damper is displaced by a preset friction region, and the connection of the connecting beam is loosened, so that unstable structural deformation may occur in the building.

Therefore, it is possible to expect an effective seismic damping through stable displacement of the connecting bridge type damper by increasing the slight shear displacement at the center of the slab lower connection beam, and even if the slit portion is broken due to the earthquake, It is urgent to develop a connection type vibration damping device which does not cause a problem.

[Prior Art Literature]

Patent No. 10-1539577

Patent No. 10-1527600

In order to solve the above-mentioned problems, the object of the present invention is as follows.

A first aspect of the present invention is to provide a new slit steel damper capable of maximizing the damping efficiency of a horizontal load installed at a central portion of a connecting beam where a bending moment hardly occurs in a connecting beam, do.

Another object of the present invention is to provide a new slit steel damper capable of efficiently damping an input seismic load by maximally amplifying a relatively small amount of displacement under the slab by using a leverage property when the seismic load is inputted, .

Another object of the present invention is to provide a new slit steel damper which can prevent breakage of a connecting beam by a hinge joint structure even when a slit portion is broken due to repeated earthquake load input.

Fourthly, another object of the present invention is to provide a new slit steel damper excellent in economy and workability.

The present invention relates to a damper installed inside a center portion of a connecting beam connecting two neighboring reinforcing concrete shear walls, comprising: a pair of steel frame members 100 spaced apart from each other on both sides; A hinge hole 22 rotatably coupled to the upper end of each of the steel frame members 100 by a hinge bolt 33 is provided at both the left and right ends of the hinge hole 22 to connect the steel frame members 100 spaced apart from each other, (250); A hinge hole (22) rotatably coupled to a lower end of each of the steel members (100) by a hinge bolt (33) is provided at both left and right ends of the lower displacement displacement transmitting and contracting member (200); And upper ends of each of the vertical extending pieces 310 are coupled to a central portion of the upper displacement transducer 250 by a coupling bolt 44 And a lower end portion extending in the horizontal direction is coupled to a central portion of the lower displacement transitional member 200 with a coupling bolt 44. [

In addition, the present invention relates to a damper installed in a central portion of a connecting beam connecting adjacent two reinforced concrete shear walls, comprising: a pair of steel frame members 100 spaced apart from each other on both sides; A hinge hole (22) rotatably coupled to a lower end of each of the steel members (100) by a hinge bolt (33) is provided at both left and right ends of the lower displacement displacement transmitting and contracting member (200); A plurality of vertical extending pieces 310 are upwardly protruded from the lower end of the lower displacement displacement transmitting and contracting member 200 with a coupling bolt 44, ); And a finger upper support member 400 coupled to the upper portion of the vertical extension piece 310 of the finger steel member 300 by a coupling bolt 44 and installed in an upper space between the steel frame members 100 The upper support member 400 is buried in the concrete constituting the connection beam without being coupled with the steel frame member 100, thereby being restricted in its behavior.

Technical effects of the configuration of the present invention are as follows.

First, it is possible to maximize the attenuation efficiency of the horizontal load applied to the center of the connecting beam where the maximum shear deformation occurs without bending moment in the connecting beam.

Secondly, when inputting the seismic load, the input seismic load can be effectively damped by maximizing the relatively small amount of displacement under the slab and transmitting it to the slit site using the leverage property.

Another object of the present invention is to provide a new slit steel damper which can prevent breakage of a connecting beam by a hinge joint structure even when a slit portion is broken due to repeated earthquake load input.

Fourth, it is excellent in economy and construction.

1 shows the operation principle of a connection boom type damper.
Figure 2 shows a specific embodiment of the present invention.
Figure 3 shows another specific embodiment of the present invention.
Figure 4 shows another specific embodiment of the present invention.
Fig. 5 shows a completed state in which concrete is installed by placing a mounted reinforcing bar using the present invention and installing it on a slab lower connecting beam.

The present invention relates to a damper installed inside a central portion of a connecting beam connecting two neighboring reinforcing concrete shear walls,

The present invention comprises a pair of steel members 100, an upper displacement increasing and decreasing transmitting member 250, a lower displacement increasing and transmitting member 200, and a finger steel member 300 and a finger upper supporting member 400 , And Figs. 2 to 4 show the embodiments thereof.

The structure of the first embodiment shown in Fig. 2 is as follows.

The steel members 100 are spaced apart from each other on both sides of the left and right sides to form a line.

Each of the steel frame members 100 is a structure in which two pairs of the webs 110 of "[" Each of the webs 110 of the "[" section steel is provided with a concrete through hole 11 to allow the concrete to be poured to pass therethrough, and when the concrete is cured, the buried steel member 100 is fixed together with the concrete, .

The upper displacement transducer 250 is provided at its left and right ends with a hinge hole 22 rotatably coupled to the upper end of each of the steel frame members 100 by a hinge bolt 33. The upper displacement transducer 250 Serve to connect the separated steel members 100 together.

The lower displacement transducer 200 includes a hinge hole 22 rotatably coupled to a lower end of each of the steel frame members 100 by hinge bolts 33. The lower displacement transducer 200 Serve to connect the separated steel members 100 together.

The upper displacement increasing and decreasing transmitting member 250 and the lower displacement increasing and transmitting member 200 are engaged with the inner side surface between the webs 110 of the section steel constituting the steel member 100.

The finger steel member 300 is a steel material in which a plurality of vertical extending pieces 310 protrude upward while maintaining a gap therebetween.

The upper end of each of the vertical extension pieces 310 of the finger steel member 300 is coupled to the center of the upper displacement increase and decrease transmission member 250 by a plurality of coupling bolts 44.

The lower portion of the finger steel member 300 extending in the horizontal direction is coupled with a plurality of coupling bolts 44 at a central portion of the lower displacement transducer 200.

The two finger steel members 300 form a pair and are engaged with the front and rear surfaces of the upper displacement transducer 250 and the lower displacement transducer 200, respectively.

As shown in FIG. 5, the hinge-joint connecting-type bridge-type steel damper is assembled as shown in FIG. 2, and two walls (shear walls) facing each other installed inside the slab- .

The hinge-joint connecting-type flange steel damper includes an upper displacement transducer 250 rotatably coupled to an upper end portion and a lower end portion of each of the steel frame members 100 by a hinge bolt 33 when a horizontal seismic load or a wind load acts, And the lower displacement transducer 200 are rotated about the respective hinge bolts 33 to amplify the displacement of the portion of the vertical extension piece 310 of the finger steel member 300, And breakage, the seismic load and the wind load are effectively attenuated.

In addition, when the vertical extension piece 310 is completely broken, the steel frame member 100 is maintained in a connected state by the upper displacement transducer 250 and the lower displacement transducer 200, Thereby preventing the problem of collapsing.

3 shows another embodiment of the present invention in which a finger upper support member 400 is used in place of the upper displacement increasing /

The steel members 100 are spaced apart from each other on both sides of the left and right sides to form a line.

Each of the steel frame members 100 is a structure in which two pairs of the webs 110 of "[" Each of the webs 110 of the "[" section steel is provided with a concrete through hole 11 to allow the concrete to be poured to pass therethrough, and when the concrete is cured, the buried steel member 100 is fixed together with the concrete, .

The lower displacement transducer 200 includes a hinge hole 22 rotatably coupled to a lower end of each of the steel frame members 100 by hinge bolts 33. The lower displacement transducer 200 Serve to connect the separated steel members 100 together.

The lower displacement-increasing / transmitting member 200 is engaged with the inner surface between the webs 110 of the "[" section steel constituting the steel member 100.

The finger steel member 300 is a steel material in which a plurality of vertical extending pieces 310 protrude upward while maintaining a gap therebetween.

The upper end of each of the vertical extension pieces 310 of the finger steel member 300 is coupled to the steel coupling plate 410 of the upper finger support member 400 with a plurality of coupling bolts 44.

The lower portion of the finger steel member 300 extending in the horizontal direction is coupled with a plurality of coupling bolts 44 at a central portion of the lower displacement transducer 200.

The two finger steel members 300 are coupled to the front and rear surfaces of the steel joint plate 410 and the lower displacement-increasing and transmitting member 200 of the upper finger support member 400 in a pair.

The upper finger support member 400 is coupled to the finger steel member 300 by a coupling bolt 44 and installed in an upper space between the steel frame members 100.

The upper finger support member 400 is not combined with the steel frame member 100 but is buried in the concrete constituting the connection beam and is restricted in its behavior by the cured concrete.

The upper finger support member 400 is composed of a steel plate 410 and an upper plate 420. The steel plate 410 includes a pair of vertically extending pieces of two finger steel members 300 The upper support plate 420 is welded in a horizontal direction along the upper end surface of the steel plate 410 to fill the upper space between the steel plate members 100. When the concrete is cured by being placed on the upper support plate 420, the movement of the upper support plate 420 is prevented and the behavior of the upper finger support member 400 is restricted.

When the horizontal earthquake load or the wind load is applied, the lower displacement displacement transmitting and contracting member 200 rotatably coupled to the lower end of each of the steel frame members 100 by the hinge bolt 33 is installed in each of the hinge- The displacement of the vertical extension piece 310 of the finger steel member 300 whose motion is restricted by the upper finger support member 400 while rotating around the hinge bolt 33 of the vertical extension piece 310 is amplified, The deformation and fracture effectively damp earthquake load and wind load.

Also, when the vertical extension piece 310 is completely broken, the steel frame member 100 is kept connected to the lower displacement transducer 200 unlike the prior art, thereby preventing the collapse of the connection beam itself.

3, a concrete block plate 500 may be further provided. The concrete block plate 500 is not limited to FIG. 3, and is not specifically shown in the accompanying drawings. However, in the case of FIGS. 2 and 4, A plate 500 may be provided.

The concrete block plate 500 has a rectangular plate shape to be mounted on each of the front and rear surfaces of the steel frame member 100 and can be made of various materials such as wood, synthetic resin, and styrofoam.

3, the concrete shielding plate 500 includes a portion of each of the front and rear surfaces of the steel frame member 100, the lower displacement-increasing / transmitting member 200, the finger steel member 300, and the upper finger support member 400, The hinge bolt 33, the coupling bolt 44, and the slit 310 are blocked so as not to be filled with concrete, so that the hinge action can be smoothly performed.

4 shows another embodiment of the present invention in which the lower displacement transducer 200 and the finger steel member 300 are integrally made of one steel material and each of the steel frame members 100 is made of a steel material And the lower displacement-increasing / transmitting member 200 is formed by joining the web 110 of the steel section of the steel member 100 to the web 110 of the section steel constituting the steel member 100 And the vertical extension piece 310 of the finger steel member 300 is coupled to the steel coupling plate 410 of the upper finger support member 400 with a plurality of engagement bolts 44. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Addition or deletion of a technique, and limitation of a numerical value are included in the protection scope of the present invention.

100: Steel member
110: web
200: Lower displacement change transmission member
250: Upper displacement increase / decrease transmission member
300: finger steel member
310: Vertical extension piece
400: finger upper support member
410: steel plate
420: upper support plate
500: concrete block plate
11: Concrete penetration hole
22: Hinge hole
33: Hinge Bolt
44: coupling bolt

Claims (9)

The present invention relates to a damper installed inside a central portion of a connecting beam connecting two neighboring reinforcing concrete shear walls,
A pair of steel frame members 100 spaced apart from each other on the left and right sides;
A hinge hole (22) rotatably coupled to a lower end of each of the steel members (100) by a hinge bolt (33) is provided at both left and right ends of the lower displacement displacement transmitting and contracting member (200);
A plurality of vertical extending pieces 310 are upwardly protruded from the lower end of the lower displacement displacement transmitting and contracting member 200 with a coupling bolt 44, ); And
A finger upper support member 400 coupled to the upper portion of the vertical extension piece 310 of the finger steel member 300 by a coupling bolt 44 and installed in an upper space between the steel frame members 100;
, ≪ / RTI >
The upper finger support member (400)
A steel coupling plate 410 coupled between the two finger steel members 300 forming a pair so as to abut the front and rear surfaces; And
An upper support plate 420 coupled horizontally along an upper end surface of the steel material coupling plate 410 to fill an upper space between the steel material members 100;
Lt; / RTI >
The upper finger support member 400 is buried in the concrete constituting the connection beam without being coupled with the steel frame member 100,
Each of the steel frame members 100 is coupled such that two pairs of webs 110 of a section steel are opposed to each other and each of the webs 110 of the section steel constituting the steel frame member 100 A concrete passage hole 11 is provided,
The lower displacement transducer 200 is coupled between the webs 110 of the "[" section steel constituting the steel frame member 100,
Wherein the finger steel member (300) is coupled to the front and rear surfaces of the lower displacement transducer (200) while forming a pair of the two finger steel members (300). The present invention relates to a damper installed inside a central portion of a connecting beam connecting two neighboring reinforcing concrete shear walls,
A pair of steel frame members 100 spaced apart from each other on the left and right sides;
A hinge hole (22) rotatably coupled to a lower end of each of the steel members (100) by a hinge bolt (33) is provided at both left and right ends of the lower displacement displacement transmitting and contracting member (200);
A plurality of vertical extending pieces 310 are upwardly protruded from the lower end of the lower displacement displacement transmitting and contracting member 200 with a coupling bolt 44, ); And
A finger upper support member 400 coupled to the upper portion of the vertical extension piece 310 of the finger steel member 300 by a coupling bolt 44 and installed in an upper space between the steel frame members 100;
, ≪ / RTI >
The upper finger support member (400)
A steel coupling plate 410 coupled to abut the vertical extension piece 310 of the finger steel member 300; And
An upper support plate 420 coupled horizontally along an upper end surface of the steel material coupling plate 410 to fill an upper space between the steel material members 100;
Lt; / RTI >
The upper finger support member 400 is buried in the concrete constituting the connection beam without being coupled with the steel frame member 100,
Each of the steel frame members 100 is coupled such that two pairs of webs 110 of a section steel are opposed to each other and each of the webs 110 of the section steel constituting the steel frame member 100 A concrete passage hole 11 is provided,
The lower displacement transducer 200 is coupled between the webs 110 of the "[" section steel constituting the steel frame member 100,
Wherein the finger steel member (300) is integrally formed with the lower displacement change transmission member (200) by using one steel material. 3. The method according to claim 1 or 2,
The hinge bolt 33 and the lower displacement supporting member 400 are formed by wrapping a partial area of each of the front and rear surfaces of the steel frame member 100, the lower displacement transducer 200, the finger steel member 300, A pair of concrete blocking plates 500 blocking the concrete poured in the coupling bolt 44 and the vertical extending piece 310 from being filled to smoothly perform a hinge action;
Wherein the damper is further provided with a plurality of fingers.
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