KR101180240B1 - Outrigger connection apparatus - Google Patents

Abstract

The present invention relates to an outrigger bonding apparatus, and more particularly includes an energy dissipation device installed at the end of the outrigger, and a guide member attached to an outer column, the energy dissipation device is mounted to be movable up and down, the energy dissipation The apparatus is a slit damper, the slit damper having a pair of end plates extending in parallel and a plurality of abdominal members provided between the pair of end plates, wherein one end plate of the pair of end plates Is installed at the end of the outrigger, the other end plate is mounted to the guide member, the upper and lower sides of the guide member is formed with a spring receiving groove, the spring receiving groove is provided with a spring for elastically supporting the other end plate The abdomen member is attached to the pair of end plates Both ends may have a large cross section and a central portion may have a small cross section.

According to the present invention, it is possible to solve the problem of inequality reduction occurring between the core and the outer column during construction, and also to cope with the horizontal load such as wind load or earthquake load.

Energy dissipation device, slit damper, guide member, core, outer pillar

Description

OUTRIGGER CONNECTION APPARATUS}

The present invention relates to a joining device of an outer column and an outrigger.

Higher buildings require higher horizontal loads, such as wind and seismic loads, and therefore require horizontal load resistance systems such as outriggers. Outriggers connect the building's exterior columns with the central core to allow the exterior columns and core to behave integrally against the horizontal load, resulting in more efficient horizontal load resistance.

In high-rise buildings, the outer pillars are generally steel pillars or steel reinforced concrete columns, whereas the core is mostly designed with reinforced concrete structures. However, due to the different shrinkage of the steel frame and concrete during the construction of the building, the problem of inequality shrinkage occurs in the outer column and core. In spite of this inequality, connecting the outer pillars and cores with outriggers causes unexpected additional stresses on the structural members, thus degrading the load resistance performance.

Therefore, the outrigger junction must be provided with a structure that can accommodate this inequality. However, in the related art, the outer pillar and the outrigger joint are joined later after all the inequality shrinkage occurs, or they are left unbonded at very small intervals without any joining, and then, to resist any potential moments of horizontal load that may occur. Inefficient methods are being applied. This conventional method is accompanied by the difficulty of continuously adjusting the interval in response to inequality and the problem of instability in the unbonded state. Naturally, it is an uneconomical and labor intensive method.

Proposed to solve such a problem, Korean Patent Publication No. 2009-0055962 discloses a configuration in which a displacement receiving device that extends or contracts according to the displacement of an outrigger end is installed between an outer column and an outrigger end. Employs a fluid cylinder operated by fluid pressure.

However, the fluid cylinder moves well without resistance when moving slowly, such as inequality that occurs during building construction. However, when an external force is suddenly acted upon by an earthquake, the fluid causes resistance and does not operate smoothly. In addition, the outrigger joint should be used semi-permanently because it is mounted inside the building. The fluid cylinder has a short life due to leakage, etc., and is expensive due to complicated mechanisms.

The present invention is designed to solve the problems of the prior art, and an object of the present invention is to provide an outrigger bonding apparatus that can cope not only with the problem of inequality reduction occurring during the construction of a building, but also with a sudden horizontal load such as wind load or earthquake load. .

According to a feature of the present invention for achieving the above object, including an energy dissipation device installed at the end of the outrigger, and a guide member attached to the outer pillar, the energy dissipation device is mounted to be movable up and down, the energy The dissipation device is a slit damper, wherein the slit damper includes a pair of end plates extending in parallel and a plurality of abdominal members provided between the pair of end plates, and one end plate of the pair of end plates. Is installed at the end of the outrigger, the other end plate is mounted to the guide member, a spring receiving groove is formed on the upper and lower sides of the guide member, the spring receiving groove is a spring that can elastically support the other end plate The abdominal member is received, the amount attached to the pair of end plates An outrigger bonding apparatus is provided in which a stage has a large cross section and a central portion has a small cross section.

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A friction member is attached to the guide member so that the other end plate and the friction member contact each other and slide.

The abdominal member may have a circular cross section.

According to the present invention, it solves the problem of inequality reduction that occurs between the core and the outer column during construction, and for horizontal loads such as wind loads and earthquake loads, when the load is small depending on the magnitude of the load, it is disposed at the upper and lower ends of the energy dissipation device. Corresponding step is provided by providing a restoring force by the spring to be applied, and correspondingly stepping is possible by allowing energy dissipation by the toughness of the energy dissipation device to be applied to a load larger than this.

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

1 is a side view of the outrigger bonding apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view along the line A-A of Figure 1, Figure 3 is a perspective view of the energy dissipation device.

1 to 3, the outrigger bonding device 100 is attached to an energy dissipation device 120 installed at an end of the outrigger 10 and an outer column 20, and the energy dissipation device 120 is movable up and down. It comprises a guide member 140 that is mounted.

The energy dissipation device 120 may be composed of a slit damper 122. As shown in the figure, the slit damper 122 includes a pair of end plates 124, 126 extending in parallel and a plurality of abdominal members 128 provided between the pair of end plates 124, 126. It is provided with. The abdominal member 128 has a circular cross section, and both ends attached to the end plates 124 and 126 have a large cross section and a central portion has a small cross section. Abdominal member 128 may be integrally formed with end plates 124 and 126 or may be fabricated separately and joined by welding or bolting. End plates 124 and 126 and abdominal member 128 may be made of steel.

One end plate 124 is attached to the hinge coupling portion 12 installed at the end of the outrigger 10. One end plate 124 may be attached to the hinge coupling portion 12 by welding or bolting. On the other hand, the other end plate 126 is mounted to the guide member 140 attached to the outer column 20 to be slidably movable in the vertical direction. Although not shown in the drawings, the friction member may be attached to the inside of the guide member 140 to allow the other end plate 126 to slide in contact with the friction member.

The guide member 140 has a spring receiving groove 142 formed on the upper and lower sides thereof, and the spring receiving groove 142 accommodates a spring 144 that can elastically support the other end plate 126. The spring receiving groove 142 may be provided with a plurality of springs 144, it is possible to change the restoring force characteristics by adjusting the rigidity of the spring 144 in the design. Meanwhile, a central hole 146 on which the other end plate 126 may be mounted is formed at the center of the guide member 140. Accordingly, the other end plate 126 of the slit damper 122 is inserted into the center hole 146 of the guide member 140, and the upper and lower ends of the other end plate 126 are supported by the spring 144.

Now, the operation of the outrigger bonding apparatus 100 configured as described above will be described.

If an uneven contraction occurs between the core and the outer column during building construction, the other end plate 126 of the slit damper 122 slides up and down along the guide member 140 to receive an uneven contraction amount to generate additional stress. To prevent it.

When a horizontal load such as a wind load or an earthquake load is applied, a restoring force is provided and supported by the spring 144 on the upper and lower ends of the other end plate 126 of the slit damper 122 for a small load. In the case where a large load is applied, the cross section of the abdominal member 128 of the slit damper 122 is bent from the smallest point in the state where the spring 144 of the other end plate 126 is fully tensioned and compressed. Energy dissipation.

When the direction of the wind load or the earthquake load is changed and the vertical movement of the outrigger joining device 100 is changed, the spring 144 connected to the upper and lower ends of the other end plate 126 acts as the compression is changed, the compression is changed to tension, and then the load is further increased. If it becomes large, the cross section of the abdomen member 128 is bent again from the point where the energy dissipation.

In addition, when the outrigger bonding apparatus 100 moves up and down, the other end plate 126 and the friction member come into contact with each other to cause friction, so that energy may be dissipated by the frictional heat generated at this time.

As described above, according to the outrigger joining apparatus of the present invention, the problem of inequality reduction occurring between the core and the outer column during construction, and for a horizontal load such as a wind load or an earthquake load, Corresponding step is provided by providing the restoring force by the springs disposed on the upper and lower ends of the energy dissipation device, and for the larger load, energy dissipation by the toughness of the energy dissipation device is achieved.

In high-rise building outrigger system, instead of inefficient way of solving the problem of inequality reduction between core and external pillar, it is solved by structural system to improve economy and constructability. One can provide step-by-step horizontal force control for load sizes that are difficult to implement.

In addition, by employing a simple configuration compared to the conventionally implemented fluid cylinder can be used in the building semi-permanently and lower the cost burden.

1 is a side view of the outrigger bonding apparatus according to the embodiment of the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a perspective view of an energy dissipation device.

Description of the Related Art [0002]

100 Outrigger Junction Device 120 Energy Dissipation Device

122 Slit Damper 124 One Side End Plate

126 other end plate 128 abdominal member

140 Guide member 142 Spring receiving groove

144 spring

Claims (6)

An energy dissipation device 120 installed at an end of the outrigger 10, Attached to the outer pillar 20, the energy dissipation device 120 includes a guide member 140 is mounted to be movable up and down, The energy dissipation device 120 is a slit damper 122, The slit damper 122 includes a pair of end plates 124 and 126 extending in parallel and a plurality of abdominal members 128 provided between the pair of end plates 124 and 126. One end plate 124 of the pair of end plates 124, 126 is installed at the end of the outrigger 10, the other end plate 126 is mounted to the guide member 140, Spring receiving groove 142 is formed on the upper and lower sides of the guide member 140, the spring receiving groove 142 is a spring 144 that can elastically support the other end plate 126 is accommodated, The abdominal member (128), the both ends attached to the pair of end plates (124, 126) is an outrigger bonding apparatus, characterized in that the cross section has a large cross section is formed small. delete delete delete The method according to claim 1, A friction member is attached to the guide member (140), and the other end plate (126) and the friction member are in contact with the outrigger bonding apparatus, characterized in that the sliding movement. The method according to claim 1, The abdominal member (128) is an outrigger bonding apparatus, characterized in that the cross section is circular.

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