KR102398605B1 - Construction method of seismic retrofit system using pc panel - Google Patents

Abstract

The present invention uses a PC reinforcing panel that is easy to construct and can secure excellent seismic reinforcing performance by closely installing a PC reinforcing panel in the vertical direction on the front side of a support member constructed on the front side of a beam of an existing frame and fixing it with a large-diameter dowel bar. It is about the construction method of the seismic reinforcement system.
The present invention is to reinforce the existing frame composed of a column and a beam, a support member constructed on the front surface of the beam; a PC reinforcement panel installed in a vertical direction on the front surface of the existing frame and in close contact with the front surface of the support member; and a large-diameter dowel bar installed through the PC reinforcement panel, the support member, and the beam; To construct an earthquake-resistant reinforcement system using a PC reinforcement panel consisting of, (a) forming a through hole in the beam of the existing frame, while chipping the front surface of the beam; (b) pouring a support member so that a through hole communicating with the through hole of the beam is formed on the front surface of the beam; (c) installing a PC reinforcement panel on the front surface of the existing frame so as to be in close contact with the front surface of the support member; and (d) installing and fixing the large-diameter dowel bar through the PC reinforcement panel, the support member, and the beam; It is characterized in that it is composed of

Description

Construction method of seismic retrofit system using pc panel}

The present invention uses a PC reinforcing panel that is easy to construct and can secure excellent seismic reinforcing performance by closely installing a PC reinforcing panel in the vertical direction on the front side of a support member constructed on the front side of a beam of an existing frame and fixing it with a large-diameter dowel bar. It is about the construction method of the seismic reinforcement system.

The need for earthquake-resistant reinforcement is growing as the frequency of earthquakes greater than or equal to medium-scale has recently increased.

In Korea, buildings before 1988, when the seismic design regulations were introduced, are still in use, and the 1988 earthquake-resistant design application regulations only target buildings with 6 stories or more. Therefore, earthquake-resistant design is not applied to small-scale buildings built before 2017, when the application target was expanded to two or more floors, so earthquake-resistance reinforcement is urgently needed.

Reinforced concrete ramen-like structures to which seismic design has not been applied have low resistance to lateral forces, so additional measures are required to reinforce strength and ductility.

For this purpose, a method of reinforcing the existing frame by attaching a reinforcing structure to the front of the existing frame in a staggered manner is widely used. However, since the reinforcing method is constructed using the conventional RC method at the site, work such as rebar reinforcement, formwork installation, concrete pouring, and formwork demolding is required, which reduces workability and takes a lot of time. In addition, the construction is cumbersome because the exterior finishing materials of the existing structures, such as stucco bricks, must be completely removed.

In addition, there is a method of reinforcing the existing frame by inserting and fixing a PC wall panel inside the Ramenzo frame (Patent No. 10-1903286, etc.). However, in the prior art, since the PC wall panel must be inserted into the frame, construction is inconvenient, and since each frame is individually reinforced, there is a limit to the reinforcement effect of the structure as a whole.

In addition, there is a steel plate reinforcement method in which a steel plate is joined to the front of the existing frame and then mortar is filled in the space between the front of the frame and the steel plate to increase the strength of the existing frame. However, the steel plate reinforcement method has the inconvenience of having to fire-resistance the entire steel plate.

In order to solve the above problems, the present invention solves the problems of the existing earthquake-resistant reinforcement method in reinforcing the existing frame composed of columns and beams to secure constructability as well as excellent earthquake-resistant reinforcement performance. Seismic reinforcement using a PC reinforcement panel We would like to provide a method of constructing the system.

The present invention according to a preferred embodiment, in order to reinforce the existing frame consisting of a column and a beam, a support member constructed on the front surface of the beam; a PC reinforcement panel installed in a vertical direction on the front surface of the existing frame and in close contact with the front surface of the support member; and a large-diameter dowel bar installed through the PC reinforcement panel, the support member, and the beam; To construct an earthquake-resistant reinforcement system using a PC reinforcement panel consisting of, (a) forming a through hole in the beam of the existing frame, while chipping the front surface of the beam; (b) pouring a support member so that a through hole communicating with the through hole of the beam is formed on the front surface of the beam; (c) installing a PC reinforcement panel on the front surface of the existing frame so as to be in close contact with the front surface of the support member; and (d) installing and fixing the large-diameter dowel bar through the PC reinforcement panel, the support member, and the beam; It provides a construction method of an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that consisting of.

The present invention according to another preferred embodiment provides a construction method of an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that a first reinforcement plate is provided on the front surface of the support member.

The present invention according to another preferred embodiment provides a construction method of a seismic reinforcement system using a PC reinforcement panel, characterized in that a second reinforcement plate is provided on the rear surface of the beam.

The present invention according to another preferred embodiment provides a construction method of an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that the lower ends of the first and second reinforcement plates are connected to the lower plate.

The present invention according to another preferred embodiment provides a method of constructing an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that a fixing bar having one or both ends fixed to the beam is provided inside the support member.

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

First, in reinforcing the existing frame composed of columns and beams, excellent seismic reinforcing performance can be secured by installing a PC reinforcement panel in close contact with the front surface of the support member installed on the front side of the beam of the existing frame in the vertical direction to resist lateral force.

Second, since the PC reinforcement panel is spaced apart from the existing frame by the support member, only the part where the support member is installed can remove the external finishing material, thereby minimizing the removal of the external finishing material.

Third, the large-diameter dowel bar can be installed and fixed through the PC reinforcement panel, support member, and beam, so that the construction is convenient, and the load of the existing structure due to the lateral force can be smoothly transferred to the PC reinforcement panel by the shear force of the large-diameter dowel bar.

1 is a perspective view showing a seismic reinforcement system using a PC reinforcement panel.
Figure 2 is a perspective view showing a PC reinforcement panel.
3 is a cross-sectional view showing a seismic reinforcement system using a PC reinforcement panel.
4 is a perspective view showing a reinforcing member;
Figure 5 is a cross-sectional view showing an embodiment provided with a reinforcing member in a large-diameter dowel bar position.
Figure 6 is a cross-sectional view showing an embodiment provided with a reinforcing member in the fixing bar position.
7 is a cross-sectional view showing an embodiment in which the support member extends to the lower part of the beam.
8 to 10 is a view showing a step-by-step process for the construction method of the earthquake-resistant reinforcement system using the PC reinforcement panel of the present invention.
11 to 13 are views illustrating a construction method for an embodiment in which a stucco brick is provided on the front surface of an existing frame.
14 to 15 are views showing a construction method for the embodiment provided with a reinforcing member.

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

Figure 1 is a perspective view showing a seismic reinforcement system using a PC reinforcement panel, Figure 2 is a perspective view showing a PC reinforcement panel, Figure 3 is a cross-sectional view showing the earthquake-resistant reinforcement system using a PC reinforcement panel.

1 to 3, the earthquake-resistant reinforcement system using a PC reinforcement panel is to reinforce the existing frame (1) composed of a column (11) and a beam (12), the front of the beam (12) a support member to be constructed (2); A PC reinforcement panel (3) that is installed in the vertical direction on the front surface of the existing frame (1) and is in close contact with the front surface of the support member (2); and a large-diameter dowel bar (4) installed through the PC reinforcement panel (3), the support member (2) and the beam (12); It is characterized in that it is composed of

An object of the present invention is to provide a construction method of an earthquake-resistant reinforcement system using a PC reinforcement panel having good constructability and excellent earthquake-resistant reinforcement performance in reinforcing an existing frame (1) composed of a column (11) and a beam (12).

The frame 1 of the existing structure is composed of a column 11 and a beam 12 which are reinforced concrete members, and may be a multi-layered Ramen structure.

A support member 2 is installed on the front side of the beam 12 of the existing structure.

The support member 2 separates the PC reinforcement panel 3 to be described later from the existing frame 1 .

The support member 2 may be formed by pouring non-shrinkable mortar or concrete on-site.

In order to reinforce the existing frame (1), it is necessary to remove the deteriorated surface of the front side of the beam (12). The support member (2) is poured on the front surface of the treated beam (12) to reinforce the beam (12).

The PC reinforcement panel (3) is constructed in close contact with the front surface of the support member (2).

The PC reinforcement panel 3 may be formed in a long rectangle in the vertical direction. The PC reinforcement panel 3 may be installed in a vertical direction over a plurality of layers, and may be installed in close contact with the front surface of the support member 2 installed on the front surface of the beam 12 of the plurality of layers.

The lower end of the PC reinforcing panel 3 may be fixed to the reinforcing foundation 5 installed at the lower portion (FIG. 1). To this end, a fixing root 31 embedded in the inside of the reinforcing base 5 and fixed therein may be formed protruding from the lower end of the PC reinforcing panel 3 ( FIG. 2 ).

The PC reinforcement panel 3 is fixed to the beam 12 of a plurality of layers so that the existing frame 1 resists lateral force.

The PC reinforcement panel (3) is arranged to be spaced apart from the front surface of the existing frame (1) by the support member (2).

Therefore, only the portion where the support member 2 to which the PC reinforcing panel 3 is bonded is installed only needs to remove the exterior finishing material of the existing structure, and the removal of the exterior finishing material such as stucco bricks can be minimized.

The PC reinforcing panel 3 may be installed in the central position of the beam 12 or may be installed in the column 11, which is an end of the beam 12.

When the PC reinforcement panel 3 is installed on the pillar 11, the support members 2 are respectively installed on the left and right beams 12 of the pillar 11, and the PC reinforcement on the front side of the support member 2 A panel (3) can be installed.

The large-diameter dowel bar 4 is installed through the PC reinforcement panel 3, the support member 2, and the beam 12 (FIG. 3).

A plurality of the large-diameter dowel bars 4 may be provided to be spaced apart from each other in the transverse direction according to the width of the PC reinforcing panel 3 .

The large-diameter dowel bar (4) is fixed by coupling the PC reinforcement panel (3) to the existing beam (12). In addition, the large-diameter dowel bar (4) transmits the load of the existing structure due to the lateral force by the shear force to the PC reinforcement panel (3).

The large-diameter dowel bar 4 may use a large-diameter bolt, a CFT member filled with mortar inside the steel pipe, and the like.

A fixing nut 40 may be fastened to each of the front and rear ends of the large-diameter dowel bar 4 to be fixed.

The PC reinforcing panel 3 and the beam 12 may have through-holes H for penetrating the large-diameter dowel bars 4 such as large-diameter bolts, respectively.

A pocket portion 32 in which the fixing nut 40 is accommodated may be formed at the front side of the through hole H ( FIGS. 2 and 3 ).

After fastening the fixing nut 40 to the large-diameter dowel bar 4 , the non-shrinkable mortar M can be poured into the pocket portion 32 .

4 is a perspective view showing a reinforcing member, FIG. 5 is a cross-sectional view showing an embodiment provided with a reinforcing member at a large-diameter dowel bar position, and FIG. 6 is a cross-sectional view showing an embodiment having a reinforcing member at a fixing bar position am.

5 and 6 , a first reinforcing plate 6a may be provided on the front surface of the support member 2 .

When the support member 2 is formed by casting on site, a separate formwork is required.

At this time, if the support member 2 is constructed using a conventional formwork, it is necessary to separately demold the formwork.

In addition, the PC reinforcement panel (3) must be in close contact with the support member (2) installed on the beams (12) of multiple layers at the same time. difficult to install

In order to solve this problem, the first reinforcing plate 6a may be installed at the front position of the support member 2 and the PC reinforcing panel 3 may be installed in close contact with the front surface of the first reinforcing plate 6a.

The first reinforcing plate 6a may be pre-constructed before installing the support member 2 to serve as a formwork when pouring concrete for forming the support member 2 .

A through hole (H) may be formed in the first reinforcing plate (6a) at an installation position of the large-diameter dowel bar (4) so that the large-diameter dowel bar (4) can pass therethrough.

A stud bolt 61 embedded in the inside of the on-site support member 2 is attached to the rear surface of the first reinforcing plate 6a so that the first reinforcing plate 6a and the supporting member 2 are integrated with each other. It can be (Fig. 6, Fig. 7).

A sleeve 7 communicating with the through hole H of the beam 12 may be provided at the position of the through hole H on the rear surface of the first reinforcing plate 6a (FIG. 5).

The sleeve 7 forms a through hole (H) through which the large-diameter dowel bar (4) penetrates in the inside of the support member (2) to be cast on site.

The first reinforcing plate 6a may be installed in a state in which the sleeve 7 is pre-attached. However, in this case, it may be difficult to install the first reinforcing plate 6a due to the interference of the sleeve 7 . Therefore, the first reinforcing plate 6a is installed first, and then the sleeve 7 is inserted through the through hole H of the first reinforcing plate 6a, and the front end of the sleeve 7 is connected to the first reinforcing plate. It is preferable to fix it by welding with (6a).

Since the through hole (H) can be formed in advance in the first reinforcing plate (6a), the position of the through hole (H) of the support member (2) can be accurately maintained.

In addition, the first reinforcing plate 6a reinforces the front surface of the support member 2 and connects a plurality of large-diameter dowel bars 4 to each other. Therefore, when a shear force is applied to the large-diameter dowel bar 4, it is possible to prevent pry-out failure due to stress concentration in the support member 2 around the large-diameter dowel bar 4 .

As shown in FIGS. 4 and 5 , a second reinforcing plate 6b may be provided on the rear surface of the beam 12 .

Like the front surface of the beam 12, the rear surface of the beam 12 also needs to remove the deteriorated surface. In this case, it may be difficult to firmly fasten the fixing nut 40 when the large-diameter dowel bar 4 is fixed because the smoothness of the surface of the beam 12 is not good.

In addition, when the fixing nut 40 is fastened to the large-diameter dowel bar 4 or when a shear force is applied, stress concentration occurs in the concrete of the beam 12 around the large-diameter dowel bar 4, and destruction may occur.

Therefore, the rear surface of the beam 12 can be reinforced by installing the second reinforcing plate 6b on the rear surface of the beam 12 .

The second reinforcing plate 6b may be fixed to the rear surface of the beam 12 by anchor bolts 62 ( FIGS. 6 and 7 ).

A through hole (H) may be formed in the second reinforcing plate (6b) at a position through which the large-diameter dowel bar (4) passes.

The inner end of the large-diameter dowel bar (4) may be fixed by fastening the fixing nut (40). Alternatively, the inner end of the large-diameter dowel bar 4 may be fixed by welding to the second reinforcing plate 6b without the fixing nut 40 .

4 and 5, lower ends of the first reinforcing plate 6a and the second reinforcing plate 6b may be connected to each other by a lower plate 6c.

When the support member 2 is formed by casting on site, a lower plate 6c may be provided to serve as a lower formwork.

Accordingly, the first reinforcing plate 6a, the lower plate 6c, and the second reinforcing plate 6b may be connected to each other to form the reinforcing member 6 having an open U-shaped cross-section.

The first reinforcing plate 6a, the lower plate 6c, and the second reinforcing plate 6b may be formed by bending a single steel plate into a U-shaped cross section. Alternatively, the first reinforcing plate 6a, the lower plate 6c, and the second reinforcing plate 6b each made of a steel plate may be welded to each other in the field.

The lower plate (6c) and the first reinforcing plate (6a) serve as a formwork when pouring concrete for forming the support member (2). Until the support member (2) is hardened, the second reinforcing plate (6b) It is fixed to the beam (12).

The first reinforcing plate 6a, the lower plate 6c and the second reinforcing plate 6b surround the beam 12 and the support member 2 to exert a confinement effect to increase strength and ductility. .

When the dance of the beam 12 is small, the support member 2 may be formed in an L-shape in cross-section to cover the front and lower surfaces of the beam 12 (FIG. 7). In this case, the lower plate 6c is installed to be spaced apart from the lower surface of the beam 12 by a predetermined interval.

7 is a cross-sectional view showing an embodiment in which the support member extends to the lower part of the beam.

As shown in FIGS. 6 and 7 , a fixing bar 21 having one or both ends fixed to the beam 12 may be provided inside the support member 2 .

A fixing bar 21 may be provided inside the support member 2 to structurally integrate the support member 2 with the existing beam 12 .

One or both ends of the fixing bar 21 are fixed to the beam 12 .

6 and 7, the fixing bar 21 can be formed in a L-shape or a C-shape.

A horizontal reinforcing bar 22 can be reinforced in the horizontal direction to the support member 2 .

The support member 2 may be formed in an L-shape or an L-shape in cross-section.

When the support member 2 is formed in an L-shape in cross section and is provided to extend to the lower portion of the beam 12 , one end of the fixing bar 21 is fixed to the front of the beam 12 , and the The other end may be fixed to the lower surface of the beam 12 (FIG. 7).

8 to 10 are views showing a step-by-step process for the construction method of the earthquake-resistant reinforcement system using the PC reinforcement panel of the present invention.

The construction method of the earthquake-resistant reinforcement system using the PC reinforcement panel of the present invention relates to a method of constructing the earthquake-resistant reinforcement system using the PC reinforcement panel described above with reference to FIGS. 1 to 7 .

In the construction method of the earthquake-resistant reinforcement system using the PC reinforcement panel of the present invention, first (a) forming a through hole (H) in the beam 12 of the existing frame 1, while chipping the front surface of the beam 12 process (FIG. 8).

That is, a through hole (H) is formed at the position of the beam (12) where the support member (2) is to be installed, and the front surface of the beam (12) is subjected to surface treatment by chipping.

When an external finishing material such as a stucco brick 13 is provided on the front surface of the beam 12, only the finishing material corresponding to the installation area of the support member 2 can be removed.

Next, (b) the support member 2 is poured so that a through hole (H) communicating with the through hole (H) of the beam 12 is formed on the front surface of the beam 12 (FIG. 9).

A formwork (not shown) may be installed in front of the beam 12 for installation of the support member 2 , and the support member 2 may be constructed by pouring non-shrinkage mortar or the like.

A fixing bar 21 and a horizontal reinforcing bar 22 may be installed inside the support member 2 .

A through hole (H) is formed in the support member (2) to communicate with the through hole (H) of the beam (12).

When the first reinforcing plate 6a, the second reinforcing plate 6b, or the lower plate 6c is provided, the reinforcing member 6 is installed before pouring concrete for forming the supporting member 2, etc. .

The through hole (H) of the support member (2) can be formed by attaching the sleeve (7) to the rear surface of the first reinforcing plate (6a).

And (c) the PC reinforcement panel 3 is installed on the front surface of the existing frame 1 so as to be in close contact with the front surface of the support member 2 (FIG. 10).

In step (c), the PC reinforcement panel 3 is installed on the front side of the existing frame 1 .

The PC reinforcement panel 3 is formed to have a long length in the vertical direction so that it can be in close contact with the front surface of the support member 2 of a plurality of layers at the same time.

When the first reinforcing plate 6a is installed, the PC reinforcing panel 3 may be installed in close contact with the front surface of the first reinforcing plate 6a.

A through hole (H) may be formed in the PC reinforcing panel (3), and the PC reinforcing panel is such that the through hole (H) of the PC reinforcing panel (3) coincides with the through hole (H) of the supporting member (2). (3) is installed.

Finally (d) the large-diameter dowel bar (4) is installed and fixed to pass through the PC reinforcement panel (3), the support member (2), and the beam (12) (FIG. 10).

After installing the large-diameter dowel bar (4), the fixing nut (40) is fastened to the front and rear ends of the large-diameter dowel bar (4), respectively.

11 to 13 are diagrams illustrating a construction method for an embodiment in which a stucco brick is provided on the front of an existing frame.

When the stucco brick 13 is provided on the front side of the existing frame 1, the stucco brick 13 provided on the front side of the beam 12 of the part where the support member 2 is to be installed in step (a) is removed, , to form a through hole (H) in the beam 12 (FIG. 11). And the front surface of the beam 12 from which the stucco brick 13 has been removed is subjected to surface treatment.

Next, (b) the support member 2 is constructed so that a through hole (H) communicating with the through hole (H) of the beam 12 is formed on the front surface of the beam 12 (FIG. 12).

Thereafter, (c) the PC reinforcement panel 3 is installed on the front side of the existing frame 1 so as to be in close contact with the front surface of the support member 2, (d) the large-diameter dowel bar 4 is attached to the PC reinforcement panel 3 ) and the support member 2 and the beam 12 to be installed and fixed (FIG. 13).

14 to 15 are views illustrating a construction method for an embodiment in which a reinforcing member is provided.

When the reinforcing member 6 is provided, the reinforcing member 6 is first installed in step (a) before construction of the supporting member 2 (FIG. 14).

And in the step (b), the support member 2 is constructed so that a through hole (H) communicating with the through hole (H) of the beam (12) is formed on the front side of the beam (12) inside the reinforcement member (6) Then (FIG. 15), steps (c) and (d) are sequentially performed.

1: Existing frame 11: Post
12: beam 13: stucco
2: support member 21: fixing bar
22: horizontal reinforcing bar 3: PC reinforcement panel
31: anchor 32: pocket portion
4: Large diameter dowel bar 40: Fixed nut
5: Reinforcement foundation 6: Reinforcement member
6a: first reinforcing plate 6b: second reinforcing plate
6c: lower plate 61: stud bolts
62: anchor bolt 7: sleeve
H: through hole M: non-shrink mortar

Claims (6)

To reinforce the existing frame (1) consisting of columns (11) and beams (12),
a support member (2) constructed on the front surface of the beam (12);
A PC reinforcement panel (3) that is installed in the vertical direction on the front surface of the existing frame (1) and is in close contact with the front surface of the support member (2); and
A large-diameter dowel bar (4) installed through the PC reinforcement panel (3), the support member (2) and the beam (12); It is to construct an earthquake-resistant reinforcement system using a PC reinforcement panel composed of
(a) forming a through hole (H) in the beam (12) of the existing frame (1), while chipping the front surface of the beam (12);
(b) pouring a support member (2) on the front surface of the beam (12) so that a through hole (H) communicating with the through hole (H) of the beam (12) is formed;
(c) installing a PC reinforcement panel (3) on the front surface of the existing frame (1) so as to be in close contact with the front surface of the support member (2); and
(d) installing and fixing the large-diameter dowel bar (4) through the PC reinforcement panel (3), the support member (2) and the beam (12); A construction method of an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that it consists of.
In claim 1,
A method of constructing an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that a first reinforcement plate (6a) is provided on the front surface of the support member (2).
In claim 2,
A method of constructing an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that a second reinforcement plate (6b) is provided on the rear surface of the beam (12).
In claim 3,
The lower end of the first reinforcing plate (6a) and the second reinforcing plate (6b) is a construction method of an earthquake-resistant reinforcement system using a PC reinforcing panel, characterized in that connected to the lower plate (6c).
In claim 1,
A method of constructing an earthquake-resistant reinforcement system using a PC reinforcement panel, characterized in that a fixing bar 21 having one or both ends fixed to the beam 12 is provided inside the support member (2). delete

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