KR102459913B1 - Seismic retrofit structure of RC column and construction method thereof - Google Patents

Abstract

The present invention reinforces the existing reinforced concrete column by connecting the corner reinforcement provided so that both legs surround the corner of the column with a transverse support member, thereby minimizing damage to the existing column and increasing the rigidity and strength of the column, and the construction is easy It is easy and it is possible to minimize the amount of steel, so it is about an economical seismic reinforcement structure of a reinforced concrete column and its construction method.
The seismic reinforcing structure of the reinforced concrete column of the present invention is for reinforcing the existing reinforced concrete column, a plurality of corner reinforcements provided at each corner of the column so that both legs are provided to surround two sides of the corner; A transverse support member for connecting the adjacent corner reinforcement in the transverse direction, at least one point is divided; and a connector for interconnecting the divided transverse support members. It is characterized in that it is composed of

Description

Seismic retrofit structure of RC column and construction method thereof

The present invention reinforces the existing reinforced concrete column by connecting the corner reinforcement provided so that both legs surround the corner of the column with a transverse support member, thereby minimizing damage to the existing column and increasing the rigidity and strength of the column, and the construction is easy It is easy and it is possible to minimize the amount of steel, so it is about an economical seismic reinforcement structure of a reinforced concrete column and its construction method.

In recent years, as the frequency of earthquakes greater than or equal to medium-scale has increased in Korea, the need for measures to reinforce earthquake resistance is growing.

However, buildings before 1988, when seismic design was introduced, are still in use, and the 1988 earthquake-resistant design application regulations only target buildings with 6 stories or more. application has been expanded. For this reason, earthquake-resistant design is not often applied to small-scale buildings built before that, so it is urgent to reinforce the earthquake resistance.

Reinforced concrete ramen-like structures to which conventional seismic design is not applied have a limit to the constraint of concrete inside the column. In addition, the lack of support for the main bars causes buckling of the main bars and brittle fracture of the concrete after the cover concrete is removed, which may lead to the collapse of the building. Therefore, measures are required to reinforce the strength and ductility of the column.

For this purpose, the cross-sectional extension reinforcement method, the steel plate reinforcement method, and the carbon fiber reinforcement method were used to reinforce the existing reinforced concrete column.

The cross-section extension reinforcement method is a method of reinforcing the cross-section by placing concrete after reinforcing reinforcing bars outside the existing column. The method has the advantage of low reinforcing construction cost. However, since it is constructed by the wet method, the construction period is long, measures to unify old and new concrete are required, and there are problems in that the area used is reduced due to a large cross-section increase.

The steel plate reinforcement method is a method of increasing the bearing strength of the column by filling the space between the surface of the column and the steel plate with mortar after bonding the steel plate to the outside of the existing column. However, the above method has a disadvantage in that the entire steel sheet needs to be subjected to fireproof treatment, and thus a fireproof work area is wide.

The carbon fiber reinforcement method is a method of improving strength and durability by impregnating a carbon fiber sheet with excellent tensile strength in epoxy and then attaching it to the surface of the column. However, there is a disadvantage in that the epoxy adhesive for attaching the carbon fiber is weak to heat and thus weak in fire resistance.

In addition, these conventional pillar reinforcement methods require chipping or anchor construction of the entire surface of the pillar in order to secure adhesion between the existing pillar and the new reinforcement member. Accordingly, damage to the structure is unavoidable, and scattering dust is generated in the process of surface treatment of the column, resulting in a poor working environment.

US 10-1065469 B1

In order to solve the above problems, the present invention provides a seismic reinforcement structure of a reinforced concrete column that can effectively increase the rigidity and strength of the column while minimizing damage to the existing column in seismic reinforcement of the existing reinforced concrete column and its construction We want to provide a way

An object of the present invention is to provide an economical seismic reinforcing structure of a reinforced concrete column and a construction method thereof because construction is easy and the amount of steel required can be minimized.

The present invention according to a preferred embodiment is for reinforcing the existing reinforced concrete column, a plurality of corner reinforcement provided so as to be provided at each corner of the column both sides of the legs to surround the two sides of the corner; A transverse support member for connecting the adjacent corner reinforcement in the transverse direction, at least one point is divided; and a connector for interconnecting the divided transverse support members. Doedoe, the connector is formed in a cylindrical shape with a first coupling bolt and a second coupling bolt respectively coupled to the ends of the transverse support member, and a female thread is formed on an inner circumferential surface of the first coupling bolt and the second coupling bolt. Consists of a coupling nut screwed to the outside of the first coupling bolt, a guide groove of a polygonal cross section is formed at an end of the first coupling bolt, and a cross section corresponding to the guide groove is formed at an end of the second coupling bolt. The guide protrusion inserted into the guide groove is formed to protrude, and the relative rotation of the first coupling bolt and the second coupling bolt is limited by preventing the guide protrusion from rotating inside the guide groove. It provides an earthquake-resistant reinforcement structure.

The present invention according to another preferred embodiment is seismic reinforcement of reinforced concrete columns, characterized in that the transverse support member is a steel bar that is divided left and right by being welded to the outer surface of the leg of the adjacent corner reinforcement at both ends and interconnected by the connector provide structure.

The present invention according to another preferred embodiment provides an earthquake-resistant reinforcement structure of a reinforced concrete column, characterized in that the transverse support member is a steel wire of a closed cross-section surrounding the outside of the column.

The present invention according to another preferred embodiment provides an earthquake-resistant reinforcement structure of a reinforced concrete column, characterized in that the L-shaped guide pipe through which the transverse support member passes is provided on the outside of the corner reinforcement.

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The present invention according to another preferred embodiment is for constructing an earthquake-resistant reinforcement structure of the reinforced concrete column, comprising the steps of: (a) surface-treating the outer surface of the four corners of the column; (b) attaching a corner reinforcement to the outer surface of the corner of the pillar with epoxy; and (c) coupling the transverse support members to the outside of the corner stiffeners to connect the adjacent corner stiffeners in the transverse direction; It provides a method of constructing an earthquake-resistant reinforcement structure of a reinforced concrete column, characterized in that it consists of.

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

First, since the existing reinforced concrete column is reinforced by connecting the corner reinforcement provided so that both legs surround the corner of the column with a lateral support member, construction is easy and damage to the existing column can be minimized.

Second, by reinforcing the corner of the column with the corner reinforcement, it is possible to prevent the cladding concrete from falling off, to prevent the main rod of the existing column from buckling, and to maximize the cross-sectional efficiency by maximizing the cross-sectional secondary moment of the column.

Third, since the outer peripheral surface of the column is wrapped and reinforced with a closed cross-section by the transverse support member connecting the corner reinforcement and the neighboring corner reinforcement in the transverse direction, ductility can be improved by restraining the concrete inside the column.

Fourth, when the transverse support member is connected to the connector on each side of the column, tension can be introduced by adjusting the length of the transverse support member by the connector. Accordingly, it is possible to increase the axial compressive strength and ductility of the column by restraining the concrete inside the column by introducing prestress.

1 is a perspective view showing the seismic reinforcement structure of the present invention reinforced concrete column according to an embodiment.
Figure 2 is a perspective view showing the seismic reinforcement structure of the present invention reinforced concrete column according to another embodiment.
Figure 3 is a cross-sectional view showing a part of the seismic reinforcement structure of the reinforced concrete column of the present invention.
4 is a perspective view showing an embodiment in which the transverse support member is a steel bar;
5 is a cross-sectional view showing an embodiment in which the corner reinforcement is accommodated in the receiving groove.
6 is a cross-sectional view showing an embodiment in which a corner reinforcement of a C-shaped steel is used.
7 is a perspective view showing an embodiment in which a lateral support member, which is a steel bar, is coupled by a connector.
8 is a perspective view showing an embodiment in which the transverse support member is a steel wire;
Fig. 9 is a perspective view showing an embodiment of a guide tube;
Fig. 10 is a perspective view showing a transverse support member connected by a connector;
Fig. 11 is a perspective view showing a coupling relationship of a coupler;
12 is a perspective view showing a coupling relationship between the first coupling bolt and the second coupling bolt;
13 is a side view showing a state in which the reinforcement plate is installed between the slabs in the upper and lower parts of the column.
Fig. 14 is a perspective view showing an embodiment in which the connector is a turnbuckle;

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

1 is a perspective view showing the seismic reinforcement structure of the present invention reinforced concrete column according to one embodiment, Figure 2 is a perspective view showing the seismic reinforcement structure of the present invention reinforced concrete column according to another embodiment, Figure 3 is this It is a cross-sectional view showing a part of the earthquake-resistant reinforcement structure of the reinforced concrete column of the invention. And Figure 4 is a perspective view showing an embodiment in which the lateral support member is a steel bar, Figure 5 is a cross-sectional view showing an embodiment in which the corner reinforcement is accommodated in the receiving groove, Figure 6 is an embodiment in which a corner reinforcement of a C-shaped steel is used. It is a cross-sectional view showing.

As shown in FIGS. 1 to 6, the seismic reinforcement structure of the reinforced concrete column of the present invention is for reinforcing the existing reinforced concrete column 1, and is provided at each corner of the column 1, and both legs 21, 22) a plurality of corner reinforcements (2) provided to surround the two sides of the corner; and a transverse support member (3) in which at least one point is divided by connecting the adjacent corner reinforcement (2) in the transverse direction; It is characterized in that it is composed of

The present invention can effectively increase the rigidity and strength of the column 1 while minimizing damage to the existing column 1 in seismic reinforcement of the existing reinforced concrete column 1, facilitate construction, and minimize the amount of steel To provide an economical seismic reinforcement structure for reinforced concrete columns and a construction method thereof.

The existing reinforced concrete column (1) is a reinforced concrete member of a rectangular cross section.

The corner reinforcement (2) is formed in a L-shaped cross-section is provided at each corner of the pillar (1).

The corner reinforcement 2 may be formed of L-shaped steel.

The corner reinforcement 2 can be attached to both sides of the side legs 21 and 22 by the epoxy 20 to both sides of the corner of the column 1 (FIG. 3).

To this end, the corner portion of the column 1 to which the corner reinforcement 2 is attached may be subjected to surface treatment such as chipping to secure adhesion.

As shown in Figure 1, the corner reinforcement (2) can be installed to be continuous over the entire height of the pillar (1) composed of a single member. Alternatively, as shown in FIG. 2 , the corner reinforcement 2 may be divided into a plurality and installed to be spaced apart from each other in the vertical direction.

Since the corner reinforcement 2 is installed at the corner of the pillar 1, the surface treatment area of the existing pillar 1 can be minimized.

The corner reinforcing material (2) reinforces the corner of the column (1) to prevent falling off of the covered concrete, and prevents the main bar (11) of the existing column (1) from buckling.

When the corner reinforcement 2 is continuously installed over the entire height of the pillar 1 , the corner reinforcement 2 can reinforce the strength and rigidity of the pillar 1 by supporting the axial force by itself. At this time, since the corner reinforcement 2 is disposed at the outermost portion of the cross section of the column 1, the cross-sectional efficiency with respect to the bending moment can be maximized by maximizing the cross-sectional secondary moment in all directions. Therefore, it is possible to minimize the amount of steel required, and economical construction is possible.

The transverse support member 3 is provided in the horizontal direction to connect the adjacent corner reinforcement 2 in the transverse direction.

A plurality of the transverse support members 3 may be provided to be spaced apart from each other in a vertical direction.

The transverse support member (3) interconnects the adjacent corner reinforcements (2) in the transverse direction, and the column reinforcement (2) restrains the column concrete by the tensile force of the transverse support member (3). improve the ductility of

That is, since the corner reinforcement 2 and the lateral support member 3 disposed at each corner of the column 1 form a closed cross-section, the inner column can be effectively restrained.

The transverse support member 3 may be a steel strip or a steel bar welded to the outer surfaces of the legs 21 and 22 of the corner reinforcement 2 .

1 and 2 show an embodiment in which the transverse support member 3 is a steel strip, and FIG. 4 shows an embodiment in which the transverse support member 3 is a steel bar.

As shown in FIG. 5 , a receiving groove 10 having a predetermined depth may be formed in a shape corresponding to the cross-section of the corner reinforcement 2 at the edge of the pillar 1 .

When accommodating the corner reinforcement 2 in the interior of the receiving groove 10, the portion in which the corner reinforcement 2 protrudes outside the surface of the column 1 can be minimized.

On the other hand, according to the cross-sectional size of the existing pillar (1), the adjacent legs (21, 22) of a pair of corner reinforcement (2) located on both sides of the pillar (1) are interconnected to form the corner reinforcement (2) in a U-shape. It is also possible to form integrally with the shape.

That is, as shown in FIG. 6, the corner reinforcement 2, which is a C-shaped steel, may be installed on both sides of the column 1 to reinforce it.

7 is a perspective view illustrating an embodiment in which a lateral support member, which is a steel bar, is coupled by a connector.

As shown in Figure 7, the transverse support member (3) is to be welded to the outer surface of the legs (21, 22) of the adjacent corner reinforcement (2) at both ends, it is divided into left and right and mutually connected to the connector (4) It can be composed of connecting steel rods.

When the transverse support member 3 is a steel bar, the transverse support member 3 is divided into left and right, but the middle portion of the transverse support member 3 may be interconnected by a connector 4 .

The connector 4 may be configured to be able to adjust the length of both sides of the divided transverse support member (3).

Therefore, after installing the transverse support member (3), the length of the transverse support member (3) can be shortened to introduce a tension force to the transverse support member (3). Accordingly, by applying a prestress to the concrete inside the column 1 by the corner reinforcement 2 in the transverse direction, it is possible to constrain the column concrete to increase the axial compressive strength and ductility of the column 1 .

8 is a perspective view showing an embodiment in which the transverse support member is a steel wire.

As shown in FIG. 8 , the transverse support member 3 may be formed of a steel wire having a closed cross-section that surrounds the outside of the column 1 .

The transverse support member 3 may be composed of a steel wire of a closed cross-section that surrounds the entire outer periphery of the pillar (1).

The steel wire can freely maintain its shape so that it is possible to wrap the entire outer circumference of the column 1 .

When an appropriate tension force is introduced into the steel wire, the transverse support member 3 can be easily installed without a separate welding process.

In addition, since the steel wire has excellent ductility, it is advantageous for securing the ductility of the column 1 .

9 is a perspective view showing an embodiment of a guide tube.

As shown in FIGS. 8 and 9 , a L-shaped guide tube 5 through which the transverse support member 3 penetrates may be provided on the outside of the corner reinforcement 2 .

When the transverse support member 3 is a steel wire, a guide pipe 5 through which the transverse support member 3 is inserted may be provided on the outer surface of the corner reinforcement 2 to fix the vertical position of the steel wire. .

The guide tube 5 may be formed in a L-shape on a plane and fixed to the outer surfaces of the legs 21 and 22 on both sides of the corner reinforcement 2 .

When a tension force is introduced into the transverse support member 3, the center of the guide pipe 5 is preferably formed to be rounded so that the transverse support member 3 can slide smoothly at the edge of the column 1 .

As shown in FIG. 8 , the divided lateral support members 3 may be interconnected by a connector 4 .

When the transverse support member 3 is a steel wire, a certain amount of tension must be introduced into the steel wire to support the corner reinforcement 2 . Accordingly, after the transverse support member 3 is installed, a connector 4 may be installed to introduce tension to the steel wire.

That is, both ends of the transverse support member 3 may be connected by a connector 4 to form a closed cross-section.

The connector 4 may be configured with an adjustable length such as a turnbuckle, a coupler, and the like.

In Figure 8, a pair of U-shaped transverse support members (3) are arranged to surround the pillar (1), and the ends of the neighboring transverse supporting members (3) are interconnected by a connector (4) at the center of one side of the pillar (1) One embodiment is shown.

After installing the transverse support member (3), by introducing a tension force to the transverse support member (3) using the connector (4), it is possible to constrain the concrete inside the column.

10 is a perspective view showing a transverse support member connected by a coupler, and FIG. 11 is a perspective view showing a coupling relationship between the coupler.

10 and 11, the connector 4 is a first coupling bolt 41 and a second coupling bolt 42 coupled to the ends of the transverse support member 3, respectively, and a female screw on the inner circumferential surface. It is formed in a cylindrical shape with an acid formed therein and may be composed of a coupling nut 43 screwed to the outside of the first coupling bolt 41 and the second coupling bolt 42 .

The connector 4 is a first coupling bolt 41 and a second coupling bolt so that a tension force can be introduced into the transverse support member 3 by adjusting the length of the transverse support member 3 by the connector 4 . (42) and a coupling nut 43 connecting them can be configured.

The first coupling bolt 41 and the second coupling bolt 42 are each coupled to and fixed to the end of the connector 4 of the transverse support member 3 .

The first coupling bolt 41 and the second coupling bolt 42 can be fixed to the end of the transverse support member 3 by screwing, welding, wedge, or the like.

A thread may be formed on the outer peripheral surfaces of the first coupling bolt 41 and the second coupling bolt 42 , and a female thread may be formed on the inner peripheral surface of the coupling nut 43 . Accordingly, the first coupling bolt 41 and the second coupling bolt 42 may be respectively inserted into both sides of the coupling nut 43 to be screw-coupled.

By adjusting the interval between the first coupling bolt 41 and the second coupling bolt 42 according to the rotation of the coupling nut 43 , a tension force can be introduced or removed from the transverse support member 3 .

It is preferable that the outer surface of the coupling nut 43 is formed in a polygonal shape so that it can be rotated using a tool such as a wrench.

In the case of configuring the connector 4 as described above, the tension force can be easily introduced to the transverse support member 3 by the connector 4 and simply rotate the coupling nut 43 even when the reinforcing structure is dismantled. It is convenient to be able to remove the lateral support member (3).

12 is a perspective view showing a coupling relationship between the first coupling bolt and the second coupling bolt.

11 and 12 , a guide groove 411 having a polygonal cross section is formed at an end of the first coupling bolt 41 , and the guide groove is formed at an end of the second coupling bolt 42 . The guide protrusion 421 formed in a cross section corresponding to the 411 and inserted into the guide groove 411 is formed to protrude, so that the guide protrusion 421 is not rotated inside the guide groove 411 to prevent the first couple from rotating. The relative rotation of the ring bolt 41 and the second coupling bolt 42 is limited.

When the transverse support member 3 is a steel bar or a steel wire, the transverse support member 3 has very weak resistance to torsion. Accordingly, when the coupling nut 43 is rotated, the first coupling bolt 41 and the second coupling bolt 42 rotate together, so that it may be difficult to adjust the length of the connector 4 .

In addition, even if the coupling nut 43 is rotated in a state in which any one of the first coupling bolt 41 and the second coupling bolt 42 is fixed, the remaining coupling bolts that are not fixed are also the coupling nut ( 43), the length may not be adjusted properly.

Therefore, when the first coupling bolt 41 and the second coupling bolt 42 are interconnected to limit the rotation of any one coupling bolt, it is necessary to configure the other coupling bolts to limit the rotation. . To this end, a guide groove 411 may be formed in the first coupling bolt 41 , and a guide protrusion 421 inserted into the guide groove 411 may be formed in the second coupling bolt 42 .

At this time, by forming the guide groove 411 and the guide protrusion 421 in a polygonal cross section, it is possible to prevent the guide protrusion 421 from rotating inside the guide groove 411 .

Accordingly, when the operator rotates the coupling nut 43 in a state in which the first coupling bolt 41 is fixed, the second coupling bolt 42 is connected to the first coupling bolt 41 and rotation is limited. . Similarly, when the coupling nut 43 is rotated while the second coupling bolt 42 is fixed, the first coupling bolt 41 is connected to the second coupling bolt 42 to limit rotation.

Therefore, the coupling nut 43 is rotated without twisting the transverse support member 3 to adjust the length of the connector 4 .

Tool insertion grooves or polygonal tool coupling portions 412 and 422 may be formed in the first coupling bolt 41 or the second coupling bolt 42 so that an operator can limit rotation using a tool. .

13 is a side view showing a state in which the reinforcement plate is installed between the slabs in the upper and lower parts of the column.

13, when reinforcing the existing reinforced concrete column (1), the lower surface of the upper slab (7a) and the upper surface of the lower slab (7b) around the column (1) using an anchor to install the reinforcing plate (6) can

The method for constructing an earthquake-resistant reinforcement structure of a reinforced concrete column of the present invention relates to a method of constructing the earthquake-resistant reinforcement structure of the reinforced concrete column of the present invention described above with reference to FIGS. 1 to 13 .

In the earthquake-resistant reinforcement structure construction method of the reinforced concrete column of the present invention, first, (a) the outer surface of the four corners of the column (1) is surface-treated.

In step (a), the corner portion of the column 1 to which the corner reinforcement 2 is to be attached is arranged.

Next, (b) attach the corner reinforcement (2) to the outer surface of the corner of the pillar (1) with an epoxy (20).

At this time, after locating the corner reinforcement 2 at the corner of the pillar 1 , the epoxy 20 may be injected and attached between the corner reinforcement 2 and the pillar 1 .

Alternatively, the corner reinforcement 2 may be attached after applying the epoxy 20 to the corner portion of the pillar 1 .

And (c) the lateral support member (3) is coupled to the outside of the corner reinforcement (2) to connect the adjacent corner reinforcement (2) in the transverse direction.

When the transverse support member 3 is a steel plate or a steel bar, the end of the transverse support member 3 can be fixed to the outer surfaces of the legs 21 and 22 of the corner reinforcement 2 by welding.

When the transverse support member 3 is a steel wire, it can be fixed by wrapping the entire circumference of the column 1 with a steel wire.

14 is a perspective view showing an embodiment in which the connector is a turnbuckle.

As shown in Figure 14, when the transverse support member 3 is a steel wire, it can be configured to introduce a tension force to the transverse support member 3 by the rotation of the turnbuckle by configuring the connector 4 as a turnbuckle.

1: pillar
10: accommodation home
11: Column Main
2: Corner reinforcement
20: epoxy
21, 22: leg
3: lateral support member
4: connector
41: first coupling bolt
411: guide home
412: tool coupling part
42: second coupling bolt
421: guide stone
422: tool coupling part
43: coupling nut
5: Guide Hall
6: Reinforcement plate
7a: upper slab
7b: lower slab

Claims (8)

To reinforce the existing reinforced concrete column (1),
A plurality of corner reinforcements (2) provided so as to be provided at each corner of the pillar (1), both sides of the legs (21, 22) to surround the two sides of the corner (2);
By connecting the adjacent corner reinforcement (2) in the transverse direction, at least one point is divided lateral support member (3); and
a connector (4) for interconnecting the divided transverse support members (3); is composed of
The connector 4 is formed in a cylindrical shape with a first coupling bolt 41 and a second coupling bolt 42 coupled to the ends of the transverse support member 3, respectively, and a female thread on the inner circumferential surface, so that the first couple It consists of a coupling nut 43 screwed to the outside of the ring bolt 41 and the second coupling bolt 42,
A guide groove 411 having a polygonal cross-section is formed at an end of the first coupling bolt 41, and a cross section corresponding to the guide groove 411 is formed at an end of the second coupling bolt 42. The guide protrusion 421 inserted into the guide groove 411 is formed to protrude, so that the guide protrusion 421 does not rotate inside the guide groove 411, so that the first coupling bolt 41 and the second coupling bolt are formed. (42) The seismic reinforcement structure of the reinforced concrete column, characterized in that the relative rotation is limited.
In claim 1,
The transverse support member (3) is a reinforcing bar, characterized in that both ends are welded to the outer surfaces of the legs (21, 22) of the adjacent corner reinforcement (2) and are divided left and right and interconnected by the connector (4). Seismic reinforcement structure of concrete column.
In claim 1,
The transverse support member (3) is a seismic reinforcement structure of a reinforced concrete column, characterized in that the steel wire of a closed cross-section surrounding the outside of the column (1).
In claim 3,
Seismic reinforcement structure of reinforced concrete columns, characterized in that the L-shaped guide pipe (5) through which the transverse support member (3) passes is provided on the outside of the corner reinforcement (2).
delete delete delete In order to construct the earthquake-resistant reinforcement structure of the reinforced concrete column according to claim 1,
(a) surface treatment of the outer surface of the four corners of the pillar (1);
(b) attaching a corner reinforcement (2) to the outer surface of the corner of the pillar (1) with an epoxy (20); and
(c) coupling the transverse support member 3 to the outside of the corner stiffener 2 so as to connect the adjacent corner stiffeners 2 in the transverse direction; Seismic reinforcement structure construction method of reinforced concrete columns, characterized in that consisting of.

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