KR102193144B1 - Seismic retrofit structure using supporting device and construction method thereof - Google Patents

Abstract

The present invention relates to a seismic reinforcement structure using earthquake-proof support devices and a construction method thereof, wherein the seismic reinforcement structure includes a plurality of earthquake-proof support devices installed between an existing frame and a reinforcing frame arranged to be spaced away from each other, thereby enabling the reinforcing frame to be easily installed and having an excellent seismic reinforcement performance. The seismic reinforcement structure using earthquake-proof support devices according to the present invention is to reinforce the existing frame including vertical members and horizontal members, and comprises: the reinforcing frame including a pair of reinforcing vertical members and a pair of reinforcing horizontal members, wherein the reinforcing members are provided inside the existing frame to be spaced away from existing members, respectively; and the plurality of earthquake-proof support devices provided between the existing frame and the reinforcing frame to fix the reinforcing frame into the existing frame, wherein the earthquake-proof support devices are screw jacks for pressing the reinforcing frame through length-extension.

Description

Seismic retrofit structure using a seismic support and construction method thereof {Seismic retrofit structure using supporting device and construction method thereof}

The present invention relates to a seismic reinforcement structure and a construction method thereof using a seismic support having excellent seismic reinforcement performance while being easy to install a reinforcement frame by installing a plurality of seismic support between the existing frame and the reinforcing frame disposed spaced apart from each other. .

As the frequency of earthquakes such as the Pohang earthquake and Gyeongju earthquake increases, demand for seismic reinforcement for existing reinforced concrete structures is increasing.

In particular, as the structural safety of non-seismic structures such as buildings built before 1988 when the seismic design was introduced or existing low-rise buildings to which the seismic design regulations were not applied, the cost of school buildings, major government offices, private buildings, etc. The overall seismic reinforcement design and reinforcement work of the seismic structure are required.

In the conventional ramen structure composed of reinforced concrete columns and beams, a number of reinforcement details have been developed to increase the rigidity and ductility of the structure by installing a steel frame inside the frame.

For example, in order to reinforce the ramen structure composed of columns and beams with a steel frame, a rectangular frame composed of H-beam members was combined inside the existing reinforced concrete frame (Registration Patent No. 10-1951454, etc.).

However, H-beams are fixedly coupled to the inside of the member by anchor bolts, and there is a problem in that it is difficult to drill anchor holes and install anchor bolts due to interference of the upper flange. In addition, since the reinforcing frame must be installed in close contact with the existing frame, it is difficult to assemble the square reinforcing frame in advance and insert it into the existing frame.After measuring the dimensions of the existing frame on-site, each member of the reinforcing frame must be processed and individually constructed. Poor workability. In addition, since post-construction anchors are installed over the entire length of the existing members, and H-beam members are fixed and installed to integrate with the existing members, there is a problem that a lot of construction time is required due to the increased number of anchor hole drilling and anchor installation points. In many cases, it is difficult to drill an anchor hole due to the interference of the rebar. In addition, since the reinforcing frame is in close contact with the inside of the existing frame, there is a hassle of having to chip the joint surface of the existing member to treat the rough surface, then install the reinforcing frame and fill it with epoxy or non-shrink mortar.

In order to improve the problems such as anchor construction interference of the steel frame reinforcement method, a technology for fixing a separate anchor plate to the existing frame with anchor bolts and fixing the reinforcing frame to the anchor plate was developed (Registration Patent No. 10-1845717, etc.) ).

However, since such a conventional technique is also to integrally fix the reinforcing frame to the existing frame entirely, there are many anchor drilling holes and anchor construction points, so there is still a limit of poor workability.

In order to solve the above problems, the present invention is to provide a seismic reinforcement structure and a construction method thereof using a seismic support that is easy to install and has excellent seismic reinforcement performance.

The present invention according to a preferred embodiment is for reinforcing an existing frame consisting of a vertical member and a horizontal member, and consists of a pair of reinforcing vertical members and a pair of reinforcing horizontal members, so that each existing reinforcing member is inside the existing frame. A reinforcing frame provided to be spaced apart from the member; And a plurality of seismic supports, which are screw jacks provided between the existing frame and the reinforcing frame to fix the reinforcing frame in the existing frame and press the reinforcing frame by length extension. It provides a seismic reinforcement structure using a seismic support, characterized in that consisting of.

The present invention according to another preferred embodiment provides a seismic reinforcement structure using a seismic support, characterized in that the seismic support is provided only at the end side of the reinforcing vertical member and the reinforcing horizontal member.

The present invention according to another preferred embodiment provides a seismic reinforcement structure using a seismic support, characterized in that a support bracket is provided inside the corner of the reinforcement frame.

The present invention according to another preferred embodiment is characterized in that a reinforcing plate surrounding the inside of an existing vertical member or an existing horizontal member is installed in the panel zone of the existing frame, and the seismic support is provided between the reinforcing plate and the reinforcing frame. It provides a seismic reinforcement structure using the seismic support.

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The present invention according to another preferred embodiment relates to a construction method of a seismic reinforcement structure using the seismic support, (a) by installing a plurality of the seismic support inside the existing frame, one end of the seismic support to the existing frame Fixing on the inside of the; (b) positioning a reinforcing frame inside the plurality of seismic supports; And (c) by installing a hydraulic jack between the existing frame and the reinforcing frame, pressing the existing frame and the reinforcing frame by extension of the hydraulic jack, and then extending the seismic support, which is a screw jack, so that both ends of the seismic support are reinforced with the existing frame. Fixing the other end of the seismic support to the reinforcing frame in a state in close contact with the frame, releasing the hydraulic pressure of the hydraulic jack to reduce the hydraulic jack, and then removing the hydraulic jack; It provides a construction method of a seismic reinforcement structure using a seismic support, characterized in that consisting of.

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According to the present invention, there are the following effects.

First, by installing a plurality of seismic supports between the existing frame and the reinforcing frame that are spaced apart from each other, it is possible to provide a seismic reinforcement structure and a construction method thereof using a seismic support that can easily fix the reinforcement frame to the existing frame. have.

Second, when an earthquake occurs, the stress of the existing frame can be smoothly transmitted to the reinforcing frame and resisted by the seismic support, so the seismic reinforcement performance is excellent.

Third, since the reinforcing frame is installed apart from the existing frame, it is not affected by the dimensional error of the existing frame. In addition, after the entire reinforcing frame is formed, it can be inserted and installed in the existing frame collectively, so construction is convenient. In addition, chipping of existing frames can be minimized.

1 is a perspective view showing a seismic reinforcement structure using the present invention seismic support.
2 is an elevational view showing a seismic reinforcement structure using the seismic support according to the present invention.
Figure 3 is a perspective view showing an embodiment in which the reinforcing plate is installed.
Figure 4 is a perspective view showing an embodiment of a screw jack.
Figure 5 is a side view showing another embodiment of the screw jack.
6 and 7 are views showing a step-by-step process for the construction method of the seismic reinforcement structure using the seismic support according to the present invention.
8 to 11 are views showing the installation sequence using a hydraulic jack.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

1 is a perspective view showing a seismic reinforcement structure using the seismic support of the present invention, Figure 2 is an elevation view showing a seismic reinforcement structure using the seismic support of the present invention.

1, 2, etc., the seismic reinforcing structure using the seismic support according to the present invention is to reinforce the existing frame 1 composed of a vertical member 11 and a horizontal member 12, a pair of A reinforcing frame composed of a reinforcing vertical member 21 and a pair of reinforcing horizontal members 22 so that the reinforcing members 21 and 22 are spaced apart from the existing members 11 and 12, respectively, inside the existing frame 1 (2); And a plurality of seismic support (3) provided between the existing frame (1) and the reinforcing frame (2) to fix the reinforcing frame (2) in the existing frame (1). It characterized in that it consists of.

The present invention is to provide a seismic reinforcing structure and a construction method thereof using a seismic support that is easy to install and has excellent seismic reinforcement performance.

The existing frame 1 is composed of a vertical member 11 and a horizontal member 12.

The vertical member 11 and the horizontal member 12 constituting the existing frame 1 are collectively referred to as the existing members 11 and 12.

The reinforcing frame 2 is for reinforcing the existing frame 1, and is composed of a pair of reinforcing vertical members 21 and a pair of reinforcing horizontal members 22, and is generally formed in a square shape.

The reinforcing vertical member 21 and the reinforcing horizontal member 22 may be formed of H-beam.

The reinforcing vertical member 21 and the reinforcing horizontal member 22 constituting the reinforcing frame 2 are referred to as reinforcing members 21 and 22.

The reinforcing frame 2 is provided inside the existing frame 1, and the reinforcing members 21 and 22 are provided to be spaced apart from the existing members 11 and 12, respectively.

The inside of the existing frame 1 means an interior partitioned by a rectangular frame. That is, it means a side surface of the vertical member 11, a lower surface of the upper horizontal member 12, and an upper surface side of the lower horizontal member 12.

The reinforcing frame 2 is installed so as to be spaced apart from the existing frame 1, unlike the conventional frame 1 that is closely installed inside the existing frame 1.

That is, the reinforcing vertical member 21 of the reinforcing frame 2 is spaced apart from the inner surface of the vertical member 11 of the existing frame 1. The upper and lower reinforcing horizontal members 22 of the reinforcing frame 2 are also spaced apart from the lower surface of the upper horizontal member 12 and the upper surface of the lower horizontal member 12 of the existing frame 1.

The seismic support (3) is provided between the existing frame (1) and the reinforcing frame (2) a plurality of, to fix the reinforcing frame (2) in the existing frame (1).

That is, the space between each member of the existing frame 1 and the reinforcing frame 2 is supported by a plurality of seismic supports 3.

One end of the seismic support 3 is fixed inside the member of the existing frame 1, and the other end is fixed outside the member of the reinforcing frame 2.

The seismic support (3) is to fix the reinforcing frame (2) inside the existing frame (1), and when an earthquake occurs, the stress of the existing frame (1) is transmitted to the reinforcement frame (2) to resist.

In this way, since the reinforcing frame 2 is spaced apart from the existing frame 1, it is not affected by the dimensional error of the existing frame 1. In addition, the reinforcing vertical member 21 and the reinforcing horizontal member 22 may be pre-assembled to form the entire reinforcing frame 2, and then collectively inserted into the existing frame 1 and installed.

In addition, since the reinforcing frame 2 is not in close contact with the existing frame 1, chipping of the existing frame 1 can be minimized.

The spaced space between the existing frame 1 and the reinforcing frame 2 can remain as an empty space, and there is no need to separately charge a filler or the like.

Accordingly, workability is greatly improved compared to the existing steel frame seismic reinforcement method.

As shown in FIGS. 1 and 2, the seismic support 3 may be provided only at the ends of the reinforcing vertical member 21 and the reinforcing horizontal member 22.

In the case of seismic reinforcement by a conventional steel frame, the stress transmission path between the existing frame 1 and the reinforcing frame 2 is not clear during structural analysis. Therefore, in general, the reinforcement frame 2 is not interpreted as being integrated with the existing frame 1 to behave as a rigid body, but is designed by analyzing it as being fixed only at the corners. In this case, the analysis for design is not consistent with the actual behavior, so there is a limit to accurate design.

Therefore, in the present invention, by installing the seismic support 3 only at the corners of the existing frame 1 and the reinforcing frame 2, the seismic force flow can be simplified and the structural analysis can be clearly performed.

The seismic force acting on the existing frame 1 is transmitted to the reinforcing frame 2 only through the corners.

When the stress is transmitted from the existing frame (1) by the seismic support (3), the seismic support (3) so that the load by the seismic support (3) does not act as a bending moment on the reinforcing members (21, 22) It is preferable to be installed on the end side of each reinforcing member (21, 22).

That is, by installing the seismic support 3 to coincide with the member shafts of the reinforcing members 21 and 22, the load of the seismic support 3 acts only as an axial force of the reinforcing members 21 and 22. Accordingly, the cross section of the reinforcing members 21 and 22 can be minimized.

When the seismic support 3 is installed only at the corners of the reinforcing members 21 and 22, the anchoring points can be greatly reduced and damage to the existing frame 1 can be minimized.

In some cases, in consideration of the size of the design seismic force, the size and rigidity of the reinforcing frame 2, a plurality of seismic supports 3 may be installed at the corners of the reinforcing frame 2.

A stiffener 23 may be installed between the upper and lower flanges to prevent local buckling of the flange at the reinforcing members 21 and 22 at the portion where the seismic support 3 is installed.

As shown in FIGS. 1 and 2, a support bracket 24 may be provided inside the corner of the reinforcing frame 2.

The support bracket 24 increases the rigidity of the joint portion between the reinforcing vertical member 21 and the reinforcing horizontal member 22, thus contributing to the weight reduction of the reinforcing frame 2.

In addition, when a plurality of the seismic support 3 is installed at the edge of the reinforcing frame 2, some seismic support 3 must be installed at a distance spaced apart from the end of the member. At this time, the support bracket 24 smoothly transfers the load of the seismic support 3 installed eccentrically with the member shaft to the reinforcing members 21 and 22.

3 is a perspective view showing an embodiment in which a reinforcing plate is installed.

3, a reinforcing plate 4 surrounding the inside of the existing vertical member 11 or the existing horizontal member 12 is installed in the panel zone of the existing frame 1, and the seismic support 3 ) May be provided between the reinforcing plate 4 and the reinforcing frame 2.

When the seismic force is applied, the panel zone where the vertical member 11 of the existing frame 1 and the horizontal member 12 meet may be a weakened area due to stress concentration.

Accordingly, it is possible to reinforce by installing a reinforcing plate 4 in the panel zone of the existing frame 1.

The reinforcing plate 4 may be configured to have a U-shaped cross section with one side open to surround the inside of the existing members 11 and 12.

In this case, the reinforcing plate 4 may be fixed by through bolts penetrating both front and rear sides of the existing members 11 and 12.

One end of the seismic support 3 is fixed to the reinforcing plate 4.

Figure 4 is a perspective view showing an embodiment of the screw jack, Figure 5 is a side view showing another embodiment of the screw jack.

4 and 5, the seismic support 3 may be configured as a screw jack that presses the reinforcing frame 2 by length extension.

Due to the dimensional error of the existing frame 1 or the manufacturing error of the reinforcing frame 2, an error inevitably occurs in the spaced space between the existing frame 1 and the reinforcing frame 2 to some extent.

The seismic support (3) can be configured as a screw jack that can be adjusted in length to facilitate coping with such a space error.

As shown in FIG. 4, the screw jack may be provided with fixing plates 31 fixed to the existing frame 1 and the reinforcing frame 2 on both sides, respectively.

A screw rod 32 is fixedly coupled to each of the pair of fixing plates 31, and a coupler 33 is coupled to the inner end of the pair of screw rods 32, so that the screw jack is fixed according to the rotation of the coupler 33. It can be configured to be stretchable.

Alternatively, as shown in FIG. 5, the screw jack is fixedly coupled to a pair of fixing plates 31 fixed to the existing frame 1 and the reinforcing frame 2, respectively, with female threads formed on the inner circumferential surface thereof. Can be.

Both ends of the screw rod 32 are screwed to the pair of coupling pipes 34, so that the screw jack may be configured to expand and contract according to the rotation of the screw rod 32. A handle 321 for rotating the screw rod 32 may be provided outside the screw rod 32.

The fixing plate 31 at one end of the seismic support 3 may be fixed to the existing frame 1 by an anchor member 311 (FIG. 8).

The fixing plate 31 at the other end of the seismic support 3 may be fixed to the reinforcing frame 2 by bolts or welding.

As described above, if the seismic support 3 is configured with an expandable screw jack, the length of the seismic support 3 can be adjusted in consideration of the deformation of the existing structure while using the seismic reinforced structure, so maintenance is easy. .

6 and 7 are diagrams showing a step-by-step process for a method of constructing a seismic reinforcement structure using the seismic support according to the present invention.

The construction method of the seismic reinforcing structure using the seismic support according to the present invention relates to a method of constructing the seismic reinforcement structure using the seismic reinforcement according to the present invention described above with reference to FIGS. 1 to 5.

In the construction method of the seismic reinforcement structure using the seismic support according to the present invention, first, (a) one end of the seismic support (3) is existing by installing a plurality of the seismic support (3) inside the existing frame (1). It is fixed to the inside of the frame 1 (Fig. 6).

That is, a plurality of seismic support (3) is pre-attached to the inside of the existing frame (1).

The surface of the existing frame 1 of the part where the seismic support 3 is to be installed is chipped to treat a rough surface, and an anchor hole is drilled to fix the seismic support 3 with an anchor member 311.

Epoxy may be injected into the bonding surface between the seismic support 3 and the existing frame 1.

Next, (b) the reinforcing frame 2 is positioned inside the plurality of seismic support 3 (FIG. 7).

In the step (b), the reinforcing frame 2 is inserted inside the seismic support 3.

The reinforcing frame 2 may be assembled inside the existing frame 1 by individually installing each of the reinforcing members 21 and 22, or may be installed collectively after pre-assembling the entire reinforcing frame 2.

Finally (c) the other end of the seismic support (3) is fixed to the reinforcing frame (2).

1 shows a state in which the seismic support 3 and the reinforcing frame 2 are fixed.

The seismic support (3) is fixed to the outside of the reinforcing frame (2) by bolts or welding the other end.

8 to 11 are views showing the installation sequence using a hydraulic jack.

The seismic support (3) is a screw jack for pressing the reinforcing frame (2) by length extension, and in the step (c), a hydraulic jack (5) between the existing frame (1) and the reinforcing frame (2) By installing the hydraulic jack (5) to pressurize the existing frame (1) and the reinforcing frame (2), and then extend the seismic support (3), which is a screw jack, so that both ends of the seismic support (3) are (1) and the reinforcing frame (2), fix the other end of the seismic support (3) to the reinforcement frame (2), release the hydraulic pressure from the hydraulic jack (5), reduce the hydraulic jack (5), and then reduce the hydraulic jack (5). (5) can be configured to eliminate.

Referring to Figures 8 to 11, the installation sequence of the reinforcing frame 2 using a hydraulic jack will be described as follows.

First, the seismic support 3 is installed as shown in FIG. 8, and the reinforcing frame 2 is positioned as shown in FIG. 9. At this time, the screw jack maintains a shortened state.

Next, as shown in FIG. 10, after installing the hydraulic jack 5 between the existing frame 1 and the reinforcing frame 2, the existing frame 1 and the reinforcing frame 2 are formed by elongation of the hydraulic jack 5. Pressurize.

That is, in order to firmly fix the reinforcement frame 2 to the existing frame 1, the reinforcement frame 2 is placed inside the existing frame 1, and then the existing frame 1 and the reinforcement frame 2 are separated from each other. Install the hydraulic jack (5) in the space.

The hydraulic jack 5 is extended to pressurize the reinforcing frame 2 by the reaction force of the existing frame 1.

Here, since the seismic support 3 is installed at each corner of the reinforcing frame 2, at least one hydraulic jack 5 is also installed on each side of the reinforcing frame 2.

The plurality of hydraulic jacks 5 are controlled to be uniformly extended at the same time so that the reinforcing frame 2 is not pushed to any one side by the pressure of the hydraulic jack 5.

Thereafter, as shown in Fig. 11, the other end of the seismic support 3 is attached to the reinforcing frame 2 while both ends of the seismic support 3 are in close contact with the existing frame 1 and the reinforcing frame 2 ).

That is, in a state where the distance between the existing frame (1) and the reinforcing frame (2) is widened by the load of the hydraulic jack (5), the screw jack is extended to the maximum and the fixing plate (31) at the other end of the screw jack (2) is reinforced. To fix it.

Then, by releasing the hydraulic pressure of the hydraulic jack 5, the hydraulic jack 5 is reduced and removed.

When the load of the hydraulic jack 5 is removed, the distance between the existing frame 1 and the reinforcing frame 2 is brought back to its original position, so that the seismic support 3 can firmly fix the reinforcing frame 2.

As described above, when the reinforcing frame 2 is installed using the hydraulic jack 5, the compression force is maintained in a state in which the compressive force acts on the screw jack by the initial load of the hydraulic jack 5. Therefore, the screw jack is prevented from loosening during use.

In some cases, when the reinforcing frame 2 needs to be disassembled, the fixing plate 31 fixed to one or both ends of the screw jack is released, while the space between the existing frame 1 and the reinforcing frame 2 Install hydraulic jack (5) on. In addition, after the separation space is opened by pressing the hydraulic jack 5, the screw jack can be reduced to remove the screw jack.

Accordingly, it is easy not only to install the reinforcing frame 2 but also to disassemble it.

1: existing frame 11: vertical member
12: horizontal member 2: reinforcing frame
21: reinforcing vertical member 22: reinforcing horizontal member
23: stiffener 24: support bracket
3: seismic support 31: fixed plate
311: anchor member 32: screw rod
321: handle 33: coupler
34: coupling pipe 4: reinforcement plate
5: hydraulic jack

Claims (7)

It is to reinforce the existing frame (1) consisting of the vertical member (11) and the horizontal member (12),
Consisting of a pair of reinforcing vertical members 21 and a pair of reinforcing horizontal members 22, the reinforcing members 21 and 22 inside the existing frame 1 are provided to be spaced apart from the existing members 11 and 12, respectively. A reinforcing frame 2; And
It is provided between the existing frame (1) and the reinforcing frame (2) to fix the reinforcing frame (2) in the existing frame (1), a plurality of screw jacks that pressurize the reinforcing frame (2) by length extension. Jinji district (3); Seismic reinforcement structure using a seismic support, characterized in that consisting of.
In claim 1,
The seismic support (3) is a seismic reinforcing structure using a seismic support, characterized in that provided only at the end side of the reinforcing vertical member (21) and the reinforcing horizontal member (22).
In paragraph 2,
A seismic reinforcing structure using a seismic support, characterized in that a support bracket (24) is provided inside the corner of the reinforcing frame (2).
In paragraph 2,
In the panel zone of the existing frame (1), a reinforcing plate (4) surrounding the inside of the existing vertical member (11) or the existing horizontal member (12) is installed, and the seismic support (3) includes a reinforcing plate (4) and Seismic reinforcement structure using a seismic support, characterized in that provided between the reinforcing frames (2).
delete It relates to the construction method of the seismic reinforcement structure using the seismic support according to claim 1,
(a) installing a plurality of the seismic support (3) inside the existing frame (1) to fix one end of the seismic support (3) to the inside of the existing frame (1);
(b) positioning a reinforcing frame (2) inside the plurality of seismic support (3); And
(c) A hydraulic jack (5) is installed between the existing frame (1) and the reinforcing frame (2) to pressurize the existing frame (1) and the reinforcing frame (2) by elongation of the hydraulic jack (5). The other end of the seismic support (3) is reinforced by extending the seismic support (3) so that both ends of the seismic support (3) are in close contact with the existing frame (1) and the reinforcement frame (2). Fixing to and releasing the hydraulic pressure of the hydraulic jack 5 to reduce the hydraulic jack 5 and then removing the hydraulic jack 5; Construction method of a seismic reinforcement structure using a seismic support, characterized in that consisting of. delete

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