KR20220093523A - Method for reinforcing seismic capability of moment frames of reinforced concrete - Google Patents

Abstract

The present invention relates to a method for the seismic reinforcement of a rebar concrete moment frame including pillars installed a predetermined distance apart from each other, and beams installed in upper and lower parts of the pillars. The method includes: a reinforcement bar installation step of forming a grid-shaped space part between a plurality of reinforcement bars having a square pipe shape by installing the plurality of reinforcement bars across each other between the pillars and the beams, and a composite panel installation step of installing a composite panel having a housing space housing an insulation material therein, in the space part. In accordance with the present invention, since there is no considerable increase in the entire weight of an existing rebar concrete moment frame, the method can prevent the stability of a structure from deteriorating due to heavy weight. Also, the method can facilitate the seismic reinforcement and maintenance of the existing rebar concrete moment frame by enabling simple installation through premanufacturing work as well as can considerably reduce construction costs by shortening a construction period. Moreover, the insulation performance of the existing rebar concrete moment frame can be reinforced to considerably improve the insulation performance after construction.

Description

Method for reinforcing seismic capability of moment frames of reinforced concrete

The present invention relates to a seismic reinforcement method of a reinforced concrete moment frame, and more particularly, it does not significantly increase the overall weight of the existing reinforced concrete moment frame, and is simple to install through pre-fabrication, and the insulation performance of the existing reinforced concrete moment frame It relates to the seismic reinforcement of reinforced concrete moment frames that can reinforce the

Existing buildings built before the seismic design standards were established lack seismic performance, so considerable damage and collapse are expected in the event of an earthquake.

For this reason, the government is continuously conducting seismic performance evaluation and seismic reinforcement projects for public buildings, and the earthquake-resistance reinforcement project targets schools, local government offices, hospitals, fire stations, etc. It is being carried out extensively for important buildings to be used.

On the other hand, as the main construction methods applied as earthquake-resistant reinforcement construction methods for existing buildings, the shear wall construction method, the strength and ductility reinforcement construction method of existing members, and the vibration damping device application method are applied.

The existing shear wall new construction method requires reinforcement of the foundation, and since it is a wet construction method, it takes a considerable period of time, damage to the interior, etc. have.

When the strength and ductility reinforcement method of existing members is applied to an existing building with weak seismic performance, most members must be reinforced, so the weight of the existing building increases significantly, and the interior space interior is damaged for steel plate reinforcement or aramid fiber reinforcement. Therefore, there is a problem that costs other than seismic reinforcement are enormous.

In the vibration damper application method, the dismantling of the existing structure is relatively limited to a part, and its application has been continuously expanded recently due to the simple construction. When applied to Korean-style buildings, there is a limit to equally reinforcing the seismic performance of the entire structure.

Therefore, there is an urgent need for a new earthquake-resistant reinforcement method that can improve the problems of the existing earthquake-resistant reinforcement method.

Korean Patent Registration No. 10-1377327

The present invention has been devised to solve the above problems, and an object of the present invention is not to significantly increase the overall weight of the existing reinforced concrete moment frame, and simple installation through prefabrication, and insulation of the existing reinforced concrete moment frame It relates to a seismic reinforcement method of reinforced concrete moment frame that can reinforce the performance.

According to the present invention for achieving the above object, in the earthquake-resistant reinforcement method of a reinforced concrete moment frame comprising a column installed spaced apart from the column and a beam installed in the upper and lower parts of the column, a rectangular tube shape between the column and the beam A reinforcing bar installation step of intersecting a plurality of reinforcing bars to form a lattice-shaped space between the plurality of reinforcing bars, and a composite panel installation step of installing a composite panel having an accommodating space for accommodating the heat insulating material therein in the space portion There is provided a seismic reinforcement method of reinforced concrete moment frame, characterized in that it comprises.

Here, the composite panel is characterized in that it includes a housing-shaped body having an open front surface and an accommodation space formed therein, and a pair of flanges extending outwardly from both ends of the front end of the body.

And, the composite panel is characterized in that it further comprises a reinforcing bar coupled to one side of the opposite inner surface of the main body having both ends formed with an accommodation space.

In addition, the plurality of reinforcing bars further include a cross-connection bracket installed in the intersecting area to cross-connect them, the cross-connection bracket includes the first tube body into which the reinforcing bar is inserted and the 1 on one side of the first tube body. It characterized in that it comprises a fastening means for fastening the second tube and the second tube and the first tube and the second tube is vertically coupled to the reinforcing bar is inserted, and the reinforcing bar.

In addition, it further comprises an end connection bracket for connecting the ends of the plurality of reinforcing bars to a column or a beam, wherein the end connection bracket is a base plate coupled to one side of the outer surface of the column or beam, and from one of the upper and lower ends opposite to the base plate It characterized in that it comprises a fastening plate extending outwardly to form an insertion region in which the reinforcing bar is inserted therebetween, and coupling means for coupling the fastening plate and the reinforcing bar.

According to the present invention as described above, since the overall weight of the existing reinforced concrete moment frame is not significantly increased, there is no problem in that the stability of the structure is deteriorated due to the large weight.

In addition, since simple installation is possible through pre-production, seismic reinforcement work and maintenance of the existing reinforced concrete moment frame are easy, and the construction period can be shortened, thereby greatly reducing the construction cost.

In addition, the insulation performance of the existing reinforced concrete moment frame is reinforced, and the insulation performance after construction is greatly improved.

1 is a view showing the sequence of the seismic reinforcement method of the reinforced concrete moment frame according to an embodiment of the present invention.
Figure 2 shows a state in which a reinforcement bar for seismic reinforcement is installed in a reinforced concrete moment frame according to an embodiment of the present invention.
3 shows an example of an aluminum composite panel inserted into a lattice-shaped space formed between reinforcing bars for seismic reinforcement of a reinforced concrete moment frame according to an embodiment of the present invention.
Figure 4 shows another example of an aluminum composite panel inserted into a lattice-shaped space formed between the reinforcing bars for seismic reinforcement of the reinforced concrete moment frame according to an embodiment of the present invention.
Figure 5 shows a cross-connection bracket for cross-connecting the reinforcing bar for seismic reinforcement of the reinforced concrete moment frame according to an embodiment of the present invention.
Figure 6 shows an end connection bracket for connecting the ends of the reinforcement bar for seismic reinforcement of the reinforced concrete moment frame according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. It should be noted that the same components in the drawings are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted.

1 is a view showing the sequence of the seismic reinforcement method of the reinforced concrete moment frame according to an embodiment of the present invention, Figure 2 is a state in which a reinforcement bar for seismic reinforcement is installed in a reinforced concrete moment frame according to an embodiment of the present invention 3 shows an example of an aluminum composite panel inserted into a lattice-shaped space formed between reinforcing bars for seismic reinforcement of a reinforced concrete moment frame according to an embodiment of the present invention, 4 shows another example of an aluminum composite panel inserted into a lattice-shaped space formed between reinforcing bars for seismic reinforcement of a reinforced concrete moment frame according to an embodiment of the present invention, and FIG. It shows a cross-connection bracket for cross-connecting a reinforcing bar for seismic reinforcement of a reinforced concrete moment frame according to an embodiment of the present invention, and FIG. 6 is reinforcement for seismic reinforcement of a reinforced concrete moment frame according to an embodiment of the present invention It shows an end connection bracket connecting the ends of the bar.

1, the seismic reinforcement method of the reinforced concrete moment frame according to an embodiment of the present invention includes a column (C) installed at regular intervals and a beam (B) installed in the upper and lower parts of the column (C) A method for installing an earthquake-resistant reinforcing structure inside a reinforced concrete moment frame, comprising a reinforcing bar installation step and a composite panel installation step.

In the reinforcing bar installation step, a plurality of reinforcing bars 10 are installed to be spaced apart from each other at regular intervals between the pillars (C) and the beams (B) to form a lattice-shaped space (S) between the plurality of reinforcing bars (10). do.

A plurality of these reinforcing bars 10 provide an installation area of the composite panel 20 to be described later through the lattice-shaped space portion (S ₁ ) as well as seismic reinforcement of the reinforced concrete moment frame.

On the other hand, a plurality of reinforcing bars 10 are manufactured through prefabrication and are installed in their crossing areas and cross-coupled to each other by cross-connection brackets 11 that cross-connect them.

This cross-connection bracket 11 is, as shown in FIG. 5, the first tube body 11a into which the reinforcement bar 10 is inserted, and the first tube body 11a on one side of the first tube body 11a. A second tube body 11b vertically coupled and into which the reinforcing bar 10 is inserted, a fastening bolt 11ca for fastening the first tube body 11a and the second tube body 11b to the reinforcing bar 10, and a fastening nut It includes a fastening means (11c) including (11cb).

In addition, the ends of the plurality of reinforcing bars 10 are manufactured through pre-production and coupled to the column C or the beam B by the end connection bracket 12 connecting them to the column C or the beam B. do.

The end connection bracket 12 is, as shown in FIG. 6, a base plate 12a having a plurality of fastening holes 12aa for coupling with one side of the outer surface of the column C or the beam B at both ends. , is coupled to one surface of the base plate (12a) and both ends are formed to extend outwardly from the opposite upper and lower ends of the base plate (12a) to form an insertion area in which the reinforcement bar (10) is inserted therebetween is a 'C' shape It includes a fastening plate (12b) in the shape of a coupling means (12c) including a coupling bolt (12ca) and a coupling nut (12cb) coupling the coupling plate (12b) and the reinforcing bar (10). (S1)

The composite panel installation step is a step of installing the composite panel 20 formed in the accommodating space (S ₂ ) in which the heat insulating material (not shown) is accommodated in the lattice-shaped space portion ( S ₁ ).

This composite panel 20 is formed of an aluminum material, manufactured through pre-production, and as shown in FIG. 3, the front side is opened and the housing-shaped body 21 in which the receiving space S2 is formed therein; It includes a pair of flanges 22 extending outwardly from both ends of the front end of the body 21 .

In this embodiment, the flange 22 is formed by vertically bending the plate member in a 'Z' shape and attaching it to the inner surface of the body 21 as an example, but the present invention is not limited thereto No, any structure is possible as long as a pair of flanges 22 extending outwardly are formed on both ends of the front end of the body 21 .

The composite panel 20 as above is fastened to the reinforcing bar in a state of being inserted into the grid-shaped space portion (S ₁ ) to reinforce the reinforced concrete moment frame together with the reinforcing bar for earthquake-resistance, and the accommodating space formed inside (S ₂ ) It provides an installation area for the insulation material through the

As the composite panel 20 is formed in a housing-shaped structure with an accommodating space (S ₂ ) formed therein, the overall weight of the existing reinforced concrete moment frame does not significantly increase, so the stability of the structure is lowered due to the large weight. does not occur

In addition, as the space in which the insulation is installed is provided through the receiving space (S ₂ ) inside, the insulation can be simply reinforced in the existing reinforced concrete moment frame that lacks insulation, so that the insulation performance after construction is remarkably improved.

On the other hand, as shown in FIG. 4, the composite panel 20 further includes a pair of reinforcing bars 23, both ends of which are coupled to one side of the opposite inner surface of the main body 21 in which the receiving space S ₂ is formed. can do.

This reinforcing bar 23 serves to further improve the earthquake resistance of the composite panel 20, so that the reinforced concrete moment frame can more reliably respond to the earthquake resistance. (S2)

As described above, in the present invention, since the reinforcing bar is installed through the pre-fabricated cross-connection bracket and the end connection bracket, and the composite panel installed between the reinforcing bars is also manufactured through pre-production, simpler installation is possible during construction.

Accordingly, not only the seismic reinforcement work and maintenance of the existing reinforced concrete moment frame is easy, but also the construction period can be shortened, so that the construction cost can be greatly reduced.

Although the present invention has been described with reference to the above preferred embodiments, various modifications and variations can be made without departing from the spirit and scope of the invention. Accordingly, the appended claims are intended to cover such modifications and variations as fall within the subject matter of the present invention.

1: Seismic reinforcement method of reinforced concrete moment frame
10: reinforcement bar 11: cross-connection bracket
11a: 1st tubular body 11b: 2nd tubular body
11c: fastening means 11ca: fastening bolt
11cb: Fastening nut 12: End connection bracket
12a: base plate 12aa: fastening hole
12b: fastening plate 12c: coupling means
12ca: coupling bolt 12cb: coupling nut
20: composite panel 21: body
22: flange 23: reinforcing bar
S ₁ : space part S ₂ : accommodation space
C: Column B: Beam

Claims (5)

In the earthquake-resistant reinforcement method of a reinforced concrete moment frame comprising a column installed at a predetermined interval and a beam installed in the upper and lower parts of the column,
a reinforcing bar installation step of intersecting a plurality of reinforcing bars in a rectangular tube shape between the pillars and the beams to form a lattice-shaped space between the plurality of reinforcing bars;
Seismic reinforcement construction method of reinforced concrete moment frame, characterized in that it comprises a composite panel installation step of installing a composite panel having a receiving space in which the insulating material is accommodated in the space portion. The method of claim 1,
The composite panel is
a body-shaped body having an open front and an accommodation space formed therein;
Seismic reinforcement method of reinforced concrete moment frame, characterized in that it comprises a pair of flanges extending outwardly from both ends of the front end of the main body. 3. The method of claim 2,
The composite panel is
Seismic reinforcement construction method of reinforced concrete moment frame, characterized in that both ends further include a reinforcing bar coupled to one side of the opposite inner surface of the main body in which the receiving space is formed. The method of claim 1,
It is installed in the cross region of the plurality of reinforcing bars further comprising a cross-connection bracket for cross-connecting them,
The cross-connection bracket is
a first tube body into which the reinforcing bar is inserted;
a second tubular body vertically coupled to one side of the first tubular body with respect to the first tubular body and into which the reinforcing bar is inserted;
Seismic reinforcement construction method of reinforced concrete moment frame, characterized in that it comprises a fastening means for fastening the first tube body and the second tube body and the reinforcing bar. Further comprising an end connection bracket for connecting the ends of the plurality of reinforcing bars to columns or beams,
The end connection bracket is
a base plate coupled to one side of the outer surface of the column or beam;
a fastening plate extending outwardly from one opposite upper and lower ends of the base plate to form an insertion region in which the reinforcing bar is inserted;
Seismic reinforcement method of reinforced concrete moment frame, characterized in that it comprises a coupling means for coupling the fastening plate and the reinforcing bar.

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