KR101531786B1 - Seismic retrofit method using seismic control device - Google Patents

Abstract

The present invention relates to a method to make a rahmen structure in which columns and beams are rigid-joined to each other more resistant to seismic activity and, more specifically, to a seismic retrofitting method to absorb and reduce the seismic load of a building by attaching a seismic load absorption device with cut parts to columns or beams of the building. According to an appropriate embodiment of the present invention, the seismic retrofitting method using a seismic load absorption device with cut parts comprises; (a) a step of manufacturing a seismic load absorption device with cut parts which is formed of a length material having an upper plate with anchor bolt holes longitudinally bored at a predetermined interval, a lower plate separated from the upper plate at a predetermined interval in parallel, a corrugated web formed by a corrugated steel sheet and vertically arranged on the upper and lower plates to connect to each other and which has cut parts formed by removing the corrugated web and the lower plate in predetermined sections; (b) a step of removing aged concrete from the exposed surface of a structure member of a reinforced concrete building where seismic retrofit is required to expose main reinforced bars of the structure member; (c) a step of fixing one end of anchor bolts on the structure member and protruding the other end of the anchor bolts from the structure member; (d) a step of fixing the seismic load absorption device with cut parts on the structure member by coupling nuts after inserting the protrusion part of the anchor bolts in the seismic load absorption device to penetrate the anchor bolt holes of the upper plate; and (e) a step of placing and curing the concrete in a space between the seismic load absorption device and the structure member.

Description

Technical Field [0001] The present invention relates to a seismic retrofit method using a seismic load absorbing device having an incision,

The present invention relates to a method for reinforcing a raymen frame structure in which a column and a beam are in contact with each other. More particularly, the present invention relates to a seismic load absorbing device having a cut- Reinforced construction method.

Existing buildings constructed before the seismic design criteria were established are expected to suffer considerable damage and collapse due to lack of seismic performance. To solve these problems, the government is continuously conducting seismic performance evaluation and seismic reinforcement projects for public buildings. The government 's existing buildings' seismic strengthening projects are being extensively carried out for schools, local governments' offices, hospitals, fire stations, and other critical buildings that serve as shelters for disaster relief and earthquake disaster relief.

Most of the structural members of existing buildings have very weak ductile capacity because they do not satisfy the interval standard of the seismic design criteria for the stirrup due to the reinforced concrete members. In order to reinforce the ductility of such a member, the steel sheet or the aramid fiber should be reinforced at its front end, but the cost is excessively increased, which is uneconomical.

Therefore, there is a need for an economical seismic retrofitting method capable of enhancing the seismic performance by increasing the strength of the structure by increasing the strength and stiffness of the structural members of existing buildings.

As a background of the present invention, there is a patent application No. 10-1190547 'Seismic retrofitting structure for a rainstorm building and seismic retrofitting method of a rainstorm building using the same' (Patent Document 1). This patent proposes a seismic retrofitting method that can integrate H-beams, T-beams and side plates into a building by constructing a reinforced beam with a multi-layer structure of H-beam and T-beam. The seismic retrofit method proposed by this patent reinforces the external beams and pillars from the external surface of the existing building, so there is no damage to the exterior adherents on the elevation of the building, which is an architectural limitation, However, since the installation is confined to the outside of the building, the use of the reinforcement method is limited and the appearance of the building is undermined.

Patent Registration No. 10-1190547 'Seismic Retrofit for Raymeno Buildings and Seismic Retrofit Method for Raymennos Buildings'

The present invention relates to a seismic load absorbing device for absorbing and damping a seismic load so that a seismic load is not transmitted to a structural member of a building when a seismic load occurs in a building, And to provide a technique for improving performance.

Another object of the present invention is to provide a technique for reinforcing the seismic performance of an existing reinforced concrete structure and repairing and reinforcing the aged concrete.

Another object of the present invention is to secure a solid integrity of a building with a seismic load absorbing device when a seismic load absorbing device is installed in a building to reinforce the seismic performance of the building.

Another object of the present invention is to provide a seismic load absorbing device that provides a joining surface for easy installation when a finished wall or a window frame is installed on a building.

(A) an upper plate having anchor bolt holes formed at regular intervals along the longitudinal direction, a lower plate parallel to and spaced from the upper plate, And a cut portion formed with a corrugated web which is vertically disposed on the upper and lower plates and connected to the upper and lower plates and includes a corrugated web including corrugated webs and corrugated webs, (B) removing the aged concrete exposed on the structural member exposed to the seismic reinforcement of the reinforced concrete building so as to expose the cast iron root of the structural member; (c) removing one end of the anchor bolt from the structural member; (D) the projecting portion of the anchor bolt is fixed to the top plate of the top plate, Inserting a seismic load absorbing device through the bolt hole and fastening the nut to the seismic load absorbing device having the cut-out portion to the structural member; and (e) placing the concrete in the space between the seismic load absorbing device and the structural member The method comprising the steps of:

In step (b), the upper surface of the bottom slab of the reinforcement layer and the lower concrete of the ceiling are removed to expose the main steel bars of the slab and the beam, respectively. In step (c), the anchor bolts are fixedly connected to the slab and the beam And the other end is provided so as to protrude from the slab and the beam. In the step (d), the seismic load absorbing device is inserted so that the protrusion of the anchor bolt penetrates the anchor bolt hole of the top plate, And in step (e) concrete can be placed in the space between the seismic load absorber and the slab, the seismic load absorber and the space between the beams.

Meanwhile, the step (b) may further include a step of removing the partition wall provided between the beam and the slab.

Here, the step (e) may further include the step of installing a finishing wall between the seismic load absorbing devices.

According to the present invention, when a seismic load occurs in a building, a corrugated web of a seismic load absorber installed on a slab or column is plastically deformed to absorb and damp the subsurface load, so that the seismic load is not transmitted to the structural member of the building The seismic performance of the building is improved.

According to the present invention, there is an effect of repairing and reinforcing a reinforced concrete structure that can reinforce seismic performance of a building, remove aged concrete, and cure and cure new concrete to prolong the life of the building.

Compared with the conventional techniques of installing an anchor bolt in an existing building to install a vibration damping member, a solid integration effect of the existing vibration damping device and the existing building can be expected.

The seismic load absorbing device according to the present invention provides an installation surface on which a finished wall or the like can be installed, thereby improving the workability.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is a perspective view of a seismic load absorbing device having an incision according to an embodiment of the present invention.
2 is a perspective view of a corrugated web according to various embodiments of the present invention.
3 is a schematic diagram for explaining the mechanism of the present invention.
4A to 4F are sectional views sequentially showing an earthquake-proof reinforcement method using a seismic load absorber having an incision according to the present invention.
5 is a cross-sectional view of a structure equipped with a seismic load absorber having an incision according to the present invention.

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 seismic load absorbing device having an incision according to an embodiment of the present invention.

As shown in FIG. 1, the seismic load absorbing device having an incision according to the present embodiment includes an upper plate 11, an upper plate 11, and an upper plate 11 having anchor bolt holes 11h formed at regular intervals along the longitudinal direction. And a corrugated web 13 made of a corrugated steel plate and vertically disposed on the upper and lower plates 11 and 12 and connecting the corrugated webs 13. The corrugated web 13 and the corrugated web 13 are separated from each other by a predetermined distance, The cut-out portion 14 is omitted.

The upper plate 11 and the lower plate 12 have a plate shape having a constant thickness and width and may be made of various materials. However, it is advantageous that the upper plate 11 and the lower plate 12 are made of various steel members having various joining methods with other members.

2 is a perspective view of a corrugated web according to various embodiments of the present invention.

The corrugated web 13 is formed of a corrugated steel sheet rather than a flat plate. The corrugated steel sheet can be manufactured through a cold-forming process, and its shape is not limited to a predetermined shape such as a wave shape and a square shape as shown in FIG. The corrugated web 13 whose both ends are fixed to the upper plate 11 and the lower plate 12 is a means for absorbing and attenuating the seismic load by plastic deformation such as an accordion when the seismic load acts on the building. It acts as a kind of steel material history damper and improves seismic performance of building by absorbing seismic load by using characteristics possessed by corrugated steel sheet material itself in case of earthquake load.

3 is a schematic diagram for explaining the mechanism of the present invention.

When a horizontal load such as an earthquake load occurs in the building, a horizontal displacement occurs as shown in Fig. 3A. In the present invention, the corrugated web (13) of the seismic load absorbing device is devised to shear deformation to absorb horizontal displacement. The cut-out portion 14 is a means for causing a strain to be concentrated on the corrugated web 13 by forming a weak portion in the seismic load absorbing device. And to minimize the damage to the building by efficiently dissipating the energy due to the earthquake using the vibration isolation device.

4A to 4F are sectional views sequentially showing an anti-seismic reinforcement method using a seismic load absorber having an incision according to the present invention, and Fig. 5 is a sectional view of a structure having a seismic load absorber having an incision according to the present invention.

Hereinafter, an earthquake-proofing method using the earthquake load absorbing device having the cut-out portion according to the present invention constructed as described above will be sequentially described.

Since the seismic load absorbing device according to the present invention has the same installation method of the seismic load absorbing device even if the installation position is different, the seismic load absorbing device according to the present invention is installed on the lower part of the reinforced- I will explain. Hereinafter, the beam and the slab are collectively referred to as the structural member 20 for convenience of explanation.

4A is a cross-sectional view of a conventional reinforced concrete building frame.

Although the reinforced concrete structure is generally considered to have a semi-permanent lifetime, the functions of the structure such as the strength, durability and waterproofing of the structure are deteriorated due to the cracking and aging occurring during the failure of the concrete structure or over time, . Neutralization of concrete means that concrete in a strong alkali state is changed into a weak alkaline state by penetration of cracks or carbon dioxide gas in the atmosphere. Reinforcements are not rusted even in the presence of oxygen in a strong alkaline state, but when they become neutralized, they rust and volumetric expansion occurs A pop out phenomenon may occur that pushes out the concrete on the surface of the reinforcing bar.

In order to solve such a problem, as shown in FIG. 4B, the upper surface of the reinforcement layer ceiling and the upper surface of the bottom slab, that is, the aged concrete 22 exposed on the structural member 20 are removed. In the case where a coarse-walled wall is formed from the upper surface of the bottom slab to the lower surface of the ceiling beam between adjacent pillars so as to separate the thread from the structure such as the school building, the wall is firstly removed, The concrete 22 is removed. This is to improve various problems caused by the aging of concrete, and it has the effect of repairing and reinforcing the reinforced concrete structure which can extend the life of the building by removing aged concrete and casting new concrete.

Next, anchor bolts 30 are installed on the beams as shown in Fig. 4C. The anchor bolts may be installed by various methods known in the art, and preferred examples thereof may be performed by piercing the anchor holes and inserting the anchor bolts to fill the anchor holes with the shrinkage mortar. That is, one end of the anchor bolt 30 is inserted and fixed to the structural member 20, and the other end of the anchor bolt 30 is installed to protrude from the structural member 20 by a predetermined length. This allows the seismic load absorbing device 10 to be more integrated with the existing building, and a solid integration effect can be expected as compared with existing technologies in which the anchor bolt is installed in the existing member to install the vibration eliminating member.

Then, as shown in Fig. 4D, a seismic load absorbing device 10 having an incision according to the present invention is installed on the structural member 20. Fig. The seismic load absorbing device 10 is inserted and fixed with a nut so that the projecting portion of the anchor bolt provided on the structural member 20 passes through the anchor bolt hole 11h of the top plate.

4E, the concrete 40 is poured and cured in the space between the seismic load absorbing device 10 and the structural member 20 (refer to FIG. 5). The concrete 40 And removal of the mold after curing of the concrete may be accomplished by any method known in the art.

Finally, as shown in Fig. 4f, a finishing wall 50 is installed between the seismic load absorbing devices. When the seismic load absorbing device 10 is installed in a planar interior, a light wall such as an ALC panel may be installed as the finishing wall 50 to form a partition wall. 50), a steel window frame can be formed as a window. There is no need to provide an additional joint surface for installing the finish wall by providing the installation surface of the bottom plate 12 of the seismic load absorbing device according to the present invention when the finish wall 50 is installed.

In the above description, the seismic load absorber is mounted on the lower surface of the beam and the upper surface of the slab. However, the present invention is not limited to this and the seismic load absorber may be installed on the opposite side of the adjacent columns, A partition wall may be provided on the upper surface of the lower surface and the opposite side of the adjacent pillars, that is, on all four surfaces of the frame.

As described above, according to the present invention, when a seismic load occurs in a building, a corrugated web of a seismic load absorbing device installed on a slab, a column or a column is plastically deformed by plastic deformation to absorb and damp the grounding load, So that the seismic performance of the building is improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: Seismic load absorbing device having an incision part 11h: Anchor bolt hole
11: top plate 12: bottom plate
13: corrugated web 14: incision
20: structural member 30: anchor bolt
40: Concrete 50: Finishing wall

Claims (4)

(a) an upper plate 11 having anchor bolt holes 11h formed at regular intervals along the longitudinal direction thereof, a lower plate 12 parallel to and spaced from the upper plate 11, and upper and lower plates 11 12 and a wave web 13 connecting the wave web 13 and the lower web 12 to each other, and the wave web 13 and the lower plate 12 are omitted in a predetermined interval spaced apart from each other at both ends. 14. A method of manufacturing a seismic load absorber comprising the steps of:
(b) removing the aged concrete (22) exposed on the structural member (20) requiring reinforcement of the reinforced concrete building to expose the cast iron (21) of the structural member (20)
(c) fixing one end of the anchor bolt (30) to the structural member (20) and installing the other end of the anchor bolt (30) so as to protrude from the structural member (20)
(d) A seismic load absorbing device (10) having a cut-out portion by inserting a seismic load absorbing device (10) and fastening a nut such that the protruding portion of the anchor bolt (30) penetrates the anchor bolt hole (11h) To the structural member (20) and
(e) placing the concrete (40) in a space between the seismic load absorber (10) and the structural member (20) and curing the seismic load; and curing the seismic load absorber using the seismic load absorber. The method according to claim 1,
In the step (b)
The upper surface of the bottom slab of the reinforcing object layer and the lower concrete 22 of the ceiling beam are removed so as to expose the slab and the beam 21 of the beam,
In the step (c)
One end of the anchor bolt 30 is fixed to the slab and the other end of the bolt 30 and the other end of the anchor bolt 30 is protruded from the slab and the beam.
In step (d)
The seismic load absorbing device 10 is inserted so that the protruding portion of the anchor bolt 30 penetrates through the anchor bolt hole 11h of the top plate 11 and the nut is fastened so that the seismic load absorbing device 10 having the cut- Fixed to the beam,
In the step (e)
Wherein a concrete (40) is laid in a space between the seismic load absorbing device (10), the slab space, the seismic load absorbing device (10) and the beam. 3. The method of claim 2,
further comprising the step of removing the partition wall provided between the beam and the slab before the step (b). < RTI ID = 0.0 > 8. < / RTI > The method of claim 3,
further comprising the step of installing a finishing wall (50) between the seismic load absorbing devices (10) after the step (e).

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