KR20220118804A - Seismic Retrofit method for Concrete square Columns - Google Patents

Abstract

The present invention relates to a seismic reinforcement method for a concrete square column. According to the present invention, the seismic reinforcement method for a concrete square column comprises: a step of installing a surface-binding spacer on an outer circumferential surface of the square column to be constructed; a step of installing one or more wires on an outer circumferential surface of the spacer for adding binding force to the spacer; and a step of installing a settlement unit adding and maintaining prestress to the wire. According to the seismic reinforcement method for a concrete square column, a surface-binding spacer is installed on an outer circumference of a square cross-section in an RC square column, and a wire and a settlement unit for controlling the prestress on the wire are constructed on an outer circumference of the spacer. Moreover, the prestress of the wire is controlled to transfer binding force to the spacer. Therefore, the binding force can be increased to improve the seismic performance of the square column.

Description

Seismic Retrofit method for Concrete square Columns

The present invention relates to a seismic reinforcement method of a concrete prismatic column, more specifically, a spacer for surface restraint on the cross section of the RC column, and a wire by constructing a wire and applying prestressing to the wire. It relates to a seismic reinforcement method of a rectangular concrete column that can increase the rigidity and ductility of a structure by generating a restraining force in the cross section.

In general, concrete structures are composed of a mixture of materials with different properties, such as cement, aggregate, and admixture. The demand for seismic reinforcement of structures is increasing according to the reinforcement of

As the shape of concrete structures becomes more diversified and complicated in recent years, loads more than the design load are often applied. There is also a risk of escalation into a major accident, such as a decrease in seismic performance.

On the other hand, there are three main methods for seismic reinforcement of existing concrete structures. First, the method of increasing the toughness of the structure, the second method of increasing the horizontal strength of the structure, and the method of reducing the seismic input to the structure have.

Among these, as a method of increasing the toughness of a structure, it is known that when a concrete column is restrained, the strength of concrete is improved and toughness is improved at the same time. A construction method of improving the strength or toughness of a structure by constructing it as a plastic (FRP) is being made.

This seismic reinforcement method can obtain a reinforcement effect by maximizing the characteristics of FRP with excellent specific strength and specific stiffness by winding FRP around an independent column. There was a problem in that the FRP could not be wound over the entire circumference, so that the strength of the fiber could not be sufficiently exhibited when an external force was applied, and the FRP was peeled off and a sufficient reinforcing effect could not be obtained.

In order to prevent peeling of the FRP constructed in this way, there is a method of pressing the end of the FRP with an iron plate or an angle material and fixing it to the concrete with anchor bolts. However, this method may look good through curing of the concrete, but there is a problem in that the strength is lowered than that of the simple bonding method by causing a number of scratches on the concrete.

The present invention is to solve the problems of the prior art as described above, and an object of the present invention is to construct a spacer for surface restraint on the cross section of an RC column, and a wire, and apply prestressing to the wire so that the restraining force by the wire is the spacer It is to provide a seismic reinforcement method of a prismatic concrete column that can increase the rigidity and ductility of the structure by generating a restraining force to the cross section of the RC column.

In order to achieve the above object, the seismic reinforcement method of a prismatic concrete column according to the present invention is a vacuum-resistant method of a prismatic column, the step of installing a spacer for surface restraint on the outer circumferential surface of the prismatic column to be constructed, the spacer It characterized in that it comprises the steps of installing one or more wires on the outer circumferential surface of the spacer to apply a restraining force, and installing an anchorage for applying and retaining prestressing to the wire.

In addition, the step of installing the spacer, it characterized in that it comprises the step of installing a reinforcing material for preventing damage to the prismatic pillar at the edge of the prismatic pillar.

In addition, the wire is characterized in that it is formed of a stainless steel or FRP material.

In addition, the spacer is characterized in that the circular or elliptical column shape to increase the contact area with the wire.

In addition, the outer peripheral surface of the spacer is characterized in that the projection for preventing the separation of the wire is formed.

As described above, in the seismic reinforcement method of a prismatic concrete column according to the present invention, a spacer for surface restraint is installed on the periphery of the column cross-section in an RC prismatic column, and a wire and an anchorage for controlling the prestressing of the wire on the outer periphery of the spacer By controlling the pre-stressing of the wire during construction, the restraint force is transmitted to the spacer, which has the advantage of increasing the restraint effect for improving the seismic performance of the prismatic column.

1 is a view showing a concrete prismatic column constructed according to the seismic reinforcement method of the concrete prismatic column of the present invention;
Figure 2 is a cross-sectional view of the concrete prismatic column shown in Figure 1, and
FIG. 3 is a view of the concrete prismatic column shown in FIG. 1 as viewed from above.

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

1 is a view showing a concrete prismatic column constructed according to the seismic reinforcement method of the concrete prismatic column of the present invention, FIG. 2 is a cross-sectional view of the concrete prismatic column shown in FIG. 1, and FIG. This is a view of the column viewed from above.

The seismic reinforcement method of the prismatic concrete column according to the embodiment of the present invention is to improve the seismic performance of the non-seismic reinforced concrete column, and the concrete prismatic column 10, which is a construction target for improving the seismic performance, and the prismatic column 10 ) a spacer 20 surrounding the surface, a wire 30 in which one or more is installed on the outer peripheral surface of the spacer 20 in order to apply a restraining force to the spacer 20, and prestressing the wire 30 It may be configured to include an anchorage 40 that generates a restraining force by applying and maintaining it.

The prismatic column 10 may be a non-circular RC column constructed in a non-seismic manner, and is intended to impart or improve seismic performance by applying a binding force to the damaged and undamaged concrete prismatic column 10, in this embodiment As an example, the prismatic pillar 10 is configured as a rectangular pillar.

The spacer 20 is wrapped around the surface of the prismatic column 10 in the shape of a hollow column, and transmits the binding force generated by the wire 30 and the anchorage 40 to be described later to the prismatic column 10 . The spacer 20 is preferably formed in the same shape as the shape of the prismatic column 10 so as to apply the maximum restraining force to the prismatic column 10, and in this embodiment, the prismatic column ( 10), the inner surface was configured in the shape of a square column.

In addition, the outer circumferential surface of the spacer 20 is preferably formed in a circular or oval shape to maximize the contact area with the wire 30 to be described later, and in this embodiment, the outer circumferential surface of the spacer 20 is Constructed in a circular shape.

In addition, protrusions 21 may be formed on the outer circumferential surface of the spacer 20 in the outer circumferential direction in order to prevent the wire 30 from being twisted and separated during the pre-stressing process of the wire 30 to be described later. The protrusion 21 is preferably formed so that the wire 30 can maintain a path capable of exerting the maximum restraint force along the outer circumferential surface of the spacer 20 . In this embodiment, the lower surface of the wire 30 is configured to be seated on the upper surface of the protrusion 21 .

One or more wires 30 are installed on the outer circumferential surface of the spacer 20 and are pre-stressed to apply a restraining force to the spacer 20. It is installed according to the shape of the outer circumferential surface of the spacer 20 in order to apply the maximum restraining force.

When the wire 30 is formed of FRP (Fiber Reinforced Polymer), the FRP may include at least one of carbon fiber, aramid fiber, glass fiber, basalt fiber, metal fiber, and silica fiber. .

The anchorage 40 is installed on the wire 30 to apply prestressing to the wire 30 and fix it. The anchorage 40 may be installed such that one side is connected to one side of the wire 30 and the other side is connected to the other side of the copper wire 30 , and also the wire 30 in the middle of the wire 30 It can be installed to pass through and apply prestressing. In the present embodiment, one side and the other side of the wire 30 are connected to one side and the other side of the anchorage 40 .

On the other hand, as described above, the seismic reinforcement method consisting of the spacer 20, the wire 30, and the anchorage 40 uses the binding force generated by the prestressing and fixing of the wire 30 and the anchorage 40 to the spacer. Although there is an advantage that it can be transmitted to the prismatic column 10 through the isher 20 , the corner portion of the prismatic column 10 may be damaged by the binding force of the wire 30 .

In order to prevent this, a reinforcing material 50 for preventing damage may be interposed in each corner portion of the prismatic column 10 between the prismatic column 10 and the spacer 20 . The reinforcing material 50 may be formed of rubber or FRP material, and although not shown in the drawings, the hollow inner surface of the spacer 20 is the prismatic pillar 10 generated by the interposition of the reinforcing material 50 and It is preferably formed in consideration of the reinforcing material 50 in order to compensate for the gap between the spacers 20 .

Hereinafter, a method of reinforcing the seismic resistance of a prismatic concrete column using the member as described above will be described in detail.

The seismic reinforcement method of the prismatic concrete column according to this embodiment includes the steps of installing a spacer 20 for surface restraint on the outer circumferential surface of the prismatic column 10 as a construction target, and the spacer 20 to apply a restraining force to the spacer. It may include the steps of installing one or more wires 30 on the outer peripheral surface of the isher 20 , and installing an anchorage 40 for applying and maintaining prestressing to the wires 30 .

First, a spacer 20 having an inner surface corresponding to the shape of the prismatic column 10 is installed on the outer circumferential surface of the prismatic column 10 to be constructed.

In this case, the step of installing the spacer 20 may further include the step of installing a reinforcing material 50 for preventing damage to the corner portion of the prismatic pillar 10 due to the restraining force. In this case, before installing the spacer 20, the reinforcing material 50 is installed in advance at each corner of the prismatic column 10, but the hollow inner surface of the spacer 20 is the prismatic column It is preferable to form in consideration of the shape in which the reinforcing material 50 is installed in (10).

Next, one or more wires 30 are installed on the outer peripheral surface of the spacer 20 installed on the prismatic column 10 . At this time, it is preferable that the outer surface of the spacer 20 is formed in a cylindrical or elliptical column shape so that the contact area with the wire 30 is maximized.

In addition, the wire 30 is twisted in the prestressing step to be described later so as not to deviate from the outer circumferential surface of the spacer 20, the wire 30 is on the path formed by the protrusions 21 on the outer circumferential surface of the spacer 20 It is preferable to be seated and installed.

Next, a fixing port 40 is installed at the end or the middle of the wire 30 to pre-stress and fix the wire 30 . At this time, the anchorage 40 may be installed in such a way that one side is connected to one side of the wire 30 and the other side is connected to the other side of the copper wire 30 , and in the middle of the wire 30 , the wire 30 It can be installed so as to penetrate through the pre-stressing. The anchorage 40 may be configured as, for example, a turnbuckle, but is not limited thereto.

In this way, the spacer 20, the wire 30, and the anchorage 40 are installed on the outer surface for the damaged and undamaged non-seismic concrete prismatic column 10, and the wire 30 and the anchorage 40 are pre-stressed. And the restraining force generated by the fixation is transmitted to the prismatic column 10 through the spacer 20 to increase the restraint effect on the prismatic column 10 in a simple way, so the seismic performance of the prismatic column 10 This is improved, and the constraint effect can be expressed from the beginning during seismic behavior, and the advantage that the behavior of the prismatic column 10 is induced into a ductile behavior is obtained.

10: prismatic column 20: spacer
30: wire 40: anchorage
50: stiffener

Claims (5)

As a vacuum-resistant method for a prismatic column,
Installing a spacer for surface restraint on the outer circumferential surface of the prismatic column to be constructed;
installing one or more wires on an outer circumferential surface of the spacer to apply a restraining force to the spacer; and
Seismic reinforcement method of a prismatic concrete pillar comprising the step of installing a fixture for applying and maintaining prestressing to the wire. The method of claim 1,
The step of installing the spacer, the seismic reinforcement method of the prismatic concrete pillar, characterized in that it comprises the step of installing a reinforcing material for preventing damage to the prismatic pillar at the edge of the prismatic pillar. The method of claim 1,
The wire is a seismic reinforcement method of a prismatic concrete column, characterized in that formed of stainless steel or FRP material. The method of claim 1,
The spacer is a seismic reinforcement method of a prismatic concrete column, characterized in that the circular or elliptical column shape to increase the contact area with the wire. 5. The method of claim 4,
Seismic reinforcement method of a prismatic concrete pillar, characterized in that the protrusion is formed on the outer peripheral surface of the spacer to prevent the separation of the wire.

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