KR102250857B1 - An external reinforcement method using CFT and external reinforcement therefor - Google Patents

Abstract

The present invention relates to an external reinforcement method using CFT, which comprises: (a) a step of vertically placing a steel rod (190) to be apart from an existing building (1) to be reinforced, and binding a base (2) of the existing building (1) with a lower end of the steel rod (190); (b) a step of placing a first member (110) to cover the steel rod (190) by a coupler (130) placed on the first member (110), and fixing the first member (110) on an outer wall of the existing building (1) by using an anchor (115); (c) a step of placing a second member (120) on the outside of the first member (110), and making one end of the coupler (130) pass through a coupler insertion groove (123) of the second member (120), and engaging the first member (110) with the second member (120) by using an engagement member (125); and (d) a step of placing and curing high-strength mortar (180) in a space formed between the first member (110) and the second member (120). Also provided is an external reinforcement body therefor. The present invention aims to provide an external reinforcement method using CFT and an external reinforcement body therefor, which are able to display an excellent seismic performance.

Description

An external reinforcement method using CFT and external reinforcement therefor}

The present invention relates to the field of architecture, and specifically, to a method for reinforcing an existing building using CFT and a reinforcing body according thereto.

It has been confirmed that a number of cases where seismic reinforcement is necessary for buildings in use after completion. In particular, school buildings are often constructed before the seismic design standards are established and have been used for a long time. Considering the frequency of recent earthquakes, the demand and interest for such seismic reinforcement technology is increasing.

CFT (concrete filled tube) method is sometimes used for seismic reinforcement. This is a method of increasing various properties such as stiffness and strength by filling concrete such as high-strength mortar into a circular or rectangular steel pipe so that the steel pipe restrains the concrete. When CFT is used for seismic reinforcement, the CFT steel pipe is tightly bonded to the outside of the existing building to absorb the shock caused by the earthquake and transfer the load to the foundation.

This CFT method is still widely used, but several problems have been confirmed.

First, the impact or load absorbed by the CFT steel pipe must be transmitted to the foundation, but it is not easy to connect the CFT steel pipe to the foundation. If the CFT steel pipe and the foundation are not properly connected and move separately, the seismic performance will not be fully exhibited.

Second, the difficulty of attaching the CFT steel pipe to the exterior wall of the existing building is high. This causes an increase in the construction period. In particular, earthquake-resistant reinforcement work in school buildings is often performed during vacation. If construction continues during the semester due to an increase in construction period, noise and dust generated by the construction will interfere with school operation, and safety for students. Problems can also arise.

Third, there are many on-site welding work when using CFT steel pipes. Many field welding is performed for attachment of various anchors, bonding between vertical and horizontal reinforcements, and bonding between the reinforcement and existing buildings. This increases the risk of fire.

Fourth, the outer wall of the school building is often made of masonry, and most of the masonry must be removed in order to firmly bond the CFT steel pipe. This will increase the construction period as well as increase the amount of construction waste.

(Patent Document 1) KR 1791819 B1

(Patent Document 2) KR 1882386 B1

(Patent Document 3) KR 2004419 B1

The present invention was devised to solve the above problems.

Specifically, an external reinforcement method using CFT is provided for seismic reinforcement, but the external reinforcement method capable of exhibiting excellent seismic performance by ensuring that the CFT steel pipe and the existing building, as well as the CFT steel pipe and the foundation are tightly bonded, and the external reinforcement method used therein We want to provide a reinforcement.

In addition, by using pre-fabricated members, it is intended to provide a construction method that can reduce the amount of work on the site and reduce the difficulty of work while minimizing field welding, shortening the construction period, and lowering the risk of safety accidents such as fire.

In order to solve the above problems, an embodiment of the present invention is to (a) vertically arrange the steel bars 190 to be spaced apart from the existing building (1) to be reinforced, but on the foundation (2) of the existing building (1). Binding the lower end of the steel bar 190; (b) Arranging the first member 110 so that the coupler 130 provided on the first member 110 surrounds the steel bar 190, and the first member 110 using the anchor 115 Fixing to the outer wall of the existing building (1); (c) The second member 120 is disposed outside the first member 110, but one end of the coupler 130 passes through the coupler insertion groove 123 of the second member 120, and is coupled. Coupling the first member 110 and the second member 120 using a member 125; And (d) pouring and curing a high-strength mortar 180 in a space formed between the first member 110 and the second member 120 and curing.

In addition, the external reinforcement method includes the steps of (A) installing two spaced vertical external reinforcement bodies 100 by performing the steps (a) to (d); And (B) installing a horizontal external reinforcing body 200 connecting one side of the two vertical external reinforcing bodies 100, and the (B) step includes: (e) two steel bar binding members ( Binding the upper portions of the steel bars 190 of each of the vertical external reinforcing bodies 100 to both ends of the steel bars 290 of the horizontal external reinforcing bodies 200 using 240); (f) The horizontal first member is disposed so that the coupler 230 provided in the horizontal first member surrounds the steel bar 290, and the horizontal first member is connected to the existing building (1) by using an anchor 215. ) Fixing to the outer wall of the; (c) a horizontal second member is disposed outside the horizontal first member, and one end of the coupler 230 passes through the coupler insertion groove of the horizontal second member, and the horizontal first member Coupling a member and the horizontal second member; And (d) pouring and curing a high-strength mortar 280 in the space formed between the horizontal first member and the horizontal second member.

In addition, the horizontal external reinforcing body 200 is at least one, and the step (B) is preferably performed for each horizontal external reinforcing body 200.

In addition, the step (a), (a1) creating a steel rod insertion hole (3) in the base (2), and digging below the steel rod insertion hole (3); (a2) passing the steel rod 190 through the steel rod insertion hole 3; (a3) binding the steel bar 190 and the base 2 at the upper and lower sides of the steel bar insertion hole 3; And (a4) placing and curing high-strength mortar in the space excavated in step (a1).

In addition, the (b) step, (b1) binding the first member 110 to the existing building (1) using an epoxy pressing method, and the anchor 115 of the first member 110 It is preferable to include the step of fastening to pass through the anchor fastening hole 113 and the anchor hole 4 of the existing building (1).

In addition, the steel bar 190 may be formed of a plurality of steel bars, and the step (b) includes the first member 110 so that the coupler 130 is positioned at a portion to which the plurality of steel bars are connected. It is preferable to further include the step of positioning.

In addition, the coupling member 125 includes a bolt and a nut, and the step (c) includes: (c1) a bolt head of the bolt inside the first coupling hole 114 formed in the first member 110 After arranging to be positioned, the bolt is operated to pass through the first coupling hole 114 and the second coupling hole 124 of the second member, and the bolt from the outside of the second coupling hole 124 It is preferable to include the step of fastening the nut to.

Another embodiment of the present invention to solve the above problems, as an external reinforcement body formed by the above-described external reinforcement method, two or more vertical external reinforcement body (100); And it provides an external reinforcement, including one or more horizontal external reinforcement 200.

In addition, the horizontal cross-section of the first member 110 is U, but the outer ends of the pair are each formed with inwardly curved flange portions, and the second member 120 is a pair of the first member 110. It is preferable that it is formed so as to be bound with the flange portion.

In addition, the steel bar binding member 240 may include a vertical steel bar insertion hole 242 through which the steel bar 190 of the vertical external reinforcing body 100 passes; And a horizontal steel rod insertion hole 244 orthogonal to the vertical steel rod insertion hole 242 and through which the steel rod 290 of the horizontal external reinforcing body 200 passes.

According to the present invention, construction in which excellent seismic performance is exhibited is possible.

In addition, most of the members are manufactured in advance at the factory and only need to be assembled at the site, so the construction period is greatly shortened and the construction difficulty is lowered.

Little on-site welding is required. Depending on the structural analysis, it only needs to be performed in a few parts in special cases. It shortens the construction period and lowers the risk of fire.

If the existing building is a masonry, the amount of masonry removed can be minimized. Accordingly, the amount of construction waste decreases and the construction period also decreases.

Various changes are possible depending on the situation of the existing building, the site situation, and the required seismic performance. The number of vertical and horizontal external reinforcements can be freely adjusted.

1 is a perspective view schematically showing an external reinforcing body according to the present invention.
FIG. 2 is a cross-sectional view as viewed from AA of FIG. 1.
3 is an exploded perspective view of the vertical external reinforcement body, and for explanation, the high strength mortar is omitted and only a part of the vertical external reinforcement body is shown.
4 is a cross-sectional view as viewed from BB of FIG. 1.
5 is an elevational view of a portion of a vertical external reinforcement.
6 is a cross-sectional view of a portion of a vertical external reinforcement body.
7 is a cross-sectional view of another part of the vertical external reinforcing body as viewed from CC of FIG.
8 is an elevation view of a steel bar binding member.
9 is a cross-sectional view showing another embodiment of an external reinforcing body according to the present invention.

In the present invention, "outside" and "inside" are set around the existing building (1) to be reinforced, and one side of the existing building (1) facing the outside is the outside, and facing the inside of the existing building (1). One side of the direction is the inner side.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

Description of external reinforcement

The external reinforcement according to the present invention will be described.

As shown in FIG. 1, the external reinforcement body 10 is a structure installed outside the existing building 1 to reinforce the seismic performance of the existing building 1 to be reinforced.

The external reinforcement body 10 may be divided into a vertical external reinforcement body 100 and a horizontal external reinforcement body 200.

Although only the vertical external reinforcement body 100 may be used alone, there will often be a case where the vertical external reinforcement body 100 and the horizontal external reinforcement body 200 are used together according to the structural analysis of the existing building 1.

As shown in Figure 2, preferably two vertical external reinforcement body 100 and a horizontal external reinforcement body 200 connecting them may be used, as shown in Figure 9 two vertical external reinforcement body ( 100) and two horizontal external reinforcing bodies 200 connecting them may be used. In this way, it is noted that there is no limit to the number of the vertical external reinforcement body 100 and the horizontal external reinforcement body 200.

The vertical external reinforcement body 100 will be described with reference to FIGS. 3 to 6.

The vertical external reinforcing body 100 includes a steel bar 190 and a first member 110 and a second member 120 surrounding the steel bar 190. The first member 110 and the second member 120 overlap each other and are fastened by the coupling member 125, and a high-strength mortar 180 is poured and cured in the space between them.

The steel bar 190 is fastened to the foundation 2 of the existing building 1 and is bonded to the first member 110 by a coupler 130. The portion fastened to the base 2 will be described later.

The steel bar 190 may be threaded. When there is a thread, the steel rods 190 and 290 may be more tightly bound when using the steel rod binding member 240 to be described later.

The first member 110 is a member that surrounds the steel bar 190 and is fixed to the outer wall of the existing building 1. The first member 110 may be fixed to the outer wall of the existing building 1 by an epoxy pressing method and anchoring.

An anchor fastening hole 113 is located inside the first member 110. When fixing the first member 110 and the outer wall of the existing building 1 by anchoring, the anchor 115 passes through the anchor fastening hole 113 to the anchor hole 4 provided in the existing building 1. Is inserted.

A coupler 130 is located inside the first member 110. The coupler 130 is manufactured by being integrated with the first member 110. A hole is located inside the coupler 130, and the steel bar 190 passes through this hole.

The coupler 130 is inserted into the coupler insertion groove 123 of the second member 120 when the second member 120 is fastened, and a part of the end may protrude outside the second member 120.

A first coupling hole 114 is positioned outside the first member 110. Subsequently, when the first member 110 and the second member 120 are fixed by the coupling member 125, the coupling member 125 passes through the first coupling hole 114.

The second member 120 is a member covering the open surface of the first member 110.

A coupler insertion groove 123 is positioned in the second member 120. The coupler 130 is inserted therein, and a part of the end protrudes out of the second member 120 through it.

A second coupling hole 124 is positioned in the second member 120. It is a part through which the coupling member 125 passes.

The heights of the first member 110 and the second member 120 are substantially the same.

When the horizontal external reinforcement body 200 is used, a hole (not shown) through which the steel rod 290 passes through the second member 120 of the portion through which the steel rod 290 of the horizontal external reinforcement body 200 passes is formed. It may be further located (see Fig. 2).

When the first member 110 and the second member 120 are bound, a space is formed therebetween, and a high-strength mortar 180 is poured and cured therein according to the CFT method.

In addition to the first member 110, the second member 120, and the steel bar 190 described above, a vertical external reinforcement cover (not shown) may be further provided to cover the open top after the high-strength mortar 180 is poured and cured. have.

On the other hand, as well as shown in Figure 4, the horizontal cross section of the first member 110 is U, but the outer ends of the pair are each formed with a flange portion bent inward, and the second member 120 is the first member ( 110) is formed to be bound with a pair of flange portions.

However, this shape can be deformed any number of times. For example, both the first member 110 and the second member 120 may have a U shape. In this case, the curved end of either the first member 110 or the second member 120 must be formed to overlap the other bent end, and the coupling member 125 is fastened to the overlapping portion to be the first member. 110 and the second member 120 may be fastened.

In addition, as long as it may be manufactured in advance in a factory and the coupling member 125 may be positioned partially overlapping each other, the first member 110 and the second member 120 may have any shape.

With reference to FIG. 7, a part in which the vertical external reinforcement body 100 is bound with the base 2 will be described.

The vertical external reinforcement body 100 is connected to the ground as well as the ground to reach the foundation (2). In particular, the steel bar 190 of the vertical external reinforcing body 100 penetrates the base 2.

For this purpose, a steel rod insertion hole 3 is formed in the foundation 2. The steel rod insertion hole 3 may have a larger size than the steel rod 190, and a high-strength mortar 180 may be filled in the space generated accordingly.

Above and below the steel rod insertion hole 3, the upper and lower foundation steel rod binding portions 141 and the lower foundation steel rod binding portions 142 are positioned. A locking nut or the like may be used as the upper steel bar binding portion 141 and the lower steel bar binding portion 142 of the foundation. These serve to bind the steel rod 190 and the base (2).

High-strength mortar 180 is also poured and cured in the space under the steel rod insertion hole 3. By this part, the bonding force between the foundation 2 and the steel bar 190 is enhanced, structurally hardened, and more impacts or loads can be transmitted to the ground.

The horizontal external reinforcement body 200 will be described with further reference to FIGS. 2 and 8.

Unlike the vertical external reinforcement body 100, the steel bar 290 of the horizontal external reinforcement body 200 is bound with the steel bar 190 of the vertical external reinforcement body 100. For this, a steel bar binding member 240 is used.

As shown in FIG. 8, the steel bar binding member 240 includes a vertical member 241 and a horizontal member 243 to bind the steel bars 190 and 290 in the vertical and horizontal directions. A vertical steel rod insertion hole 242 penetrating vertically is positioned in the vertical member 241 portion, and a horizontal steel rod insertion hole 244 formed on one side is positioned in the horizontal member 243 portion. In other words, the vertical steel rod insertion hole 242 and the horizontal steel rod insertion hole 244 are orthogonal to each other.

Since the steel bars 190 and 290 may have threads, a female thread fastened with the threads of the steel bars 190 and 290 may be positioned in either of the vertical steel bar insertion holes 242 and the horizontal steel bar insertion holes 244.

The structure except for the steel bar binding member 240 in the horizontal external reinforcement body 200 is similar to the vertical steel bar reinforcement body 100. That is, the horizontal external reinforcing body 200 is also composed of a horizontal first member and a horizontal second member, and the coupler 230 is located on the horizontal first member, and the outer wall of the existing building 2 is formed by epoxy and anchor 215. Is bound to A portion of the end of the coupler 230 may protrude outward through the coupler insertion groove of the horizontal second member. A high-strength mortar 280 may be poured and cured in a space between the horizontal first member and the horizontal second member.

Explanation of external reinforcement method

The external reinforcement method according to the present invention will be described.

First, a method of installing the vertical external reinforcing body 100 will be described.

The steel bar 190 is vertically arranged to be spaced apart from the existing building 1 to be reinforced, but the lower end of the steel bar 190 must be bound to the foundation 2 of the existing building 1.

To this end, specifically, first, the outer wall of the existing building 1 to which the external reinforcing body 100 is to be installed is arranged. In the case of a masonry building, part of the masonry is exposed. Unlike existing external reinforcement methods, there is no need to expose all the masonry. It suffices to expose only the portion in which the external reinforcement body 100 is installed, or the portion in which anchoring to be described later is performed. This shortens the air time and simplifies the installation.

When arranging the outer wall of the existing building (1), a plurality of anchor holes (3) are first constructed on the outer wall of the existing building (1).

Organize the foundation (2).

Drill a steel rod insertion hole (3) in the base (2). It is sufficient to use the filing method or any other method. The steel rod insertion hole 3 may have a larger size than the inserted steel rod 190. The outer portion of the steel bar 190 is then filled with a high-strength mortar 180.

Digging is made in the space above and below the steel rod insertion hole (3) of the foundation (2). The space above the steel rod insertion hole 3 may be excavated prior to the creation of the steel rod insertion hole 3 or together with the creation of the steel rod insertion hole 3. The space under the steel rod insertion hole 3 is dug up by the piling method, and vomit can be discharged to the outside. Since the vertical external reinforcing body 100 is located in the space above the steel rod insertion hole 3, it is excavated to a size taking this into account.

Now, the steel rod 190 is positioned to pass through the steel rod insertion hole (3). At this time, in the space above and below the excavated steel rod insertion hole 3, that is, in the upper and lower sides of the steel rod insertion hole 3, the foundation upper steel bar binding portion 141 and the foundation lower steel rod binding portion 142 are used. Thus, the steel bar 190 is bound to the base (2). Through this, a load applied to the vertical external reinforcing body 100 and the steel bar 190 is transmitted to the foundation 2.

Next, a high-strength mortar 180 is poured and cured inside the excavated steel rod insertion hole 3 and in the space below it. High-strength mortar pouring and curing, the high-strength mortar 180 of the vertical external reinforcing body 100 to be described later and curing work, or the high-strength mortar 180, 280 of the vertical external reinforcing body 100 and the horizontal external reinforcing body 200 ) Can also be done in conjunction with the work.

When the lower end of the steel bar 190 is bound to the foundation 2 of the existing building 1, a vertical external reinforcement 100 is installed.

To this end, the first member 110 and the second member 120 are prepared. The first member 110 and the second member 120 are manufactured in advance in a factory, etc., and only assembling is required at the site.

The first member 110 is disposed so that the coupler 130 provided in the first member 110 surrounds the steel bar 190. Since the steel bar 190 bound to the foundation 2 by the previous step is in a state that is vertically erected, the first member 110 is disposed while lowering from the top of the steel bar 190 in a downward direction, but the steel bar 190 It is arranged so as to pass through this coupler (130).

In another embodiment of the present invention, the steel bar 190 may be a combination of several short steel bars instead of one long steel bar in the longitudinal direction. In this case, the coupler 130 should be positioned at each portion where the steel rods are in contact with each other. This is manufactured by adjusting the position of the coupler 130 in consideration of the length of the steel bar 190 used when manufacturing the first member 110 in advance in a factory, etc. The junction of the coupler 130 will be located inside.

After the first member 110 is disposed, it is fixed to the outer wall of the existing building 1 that has been arranged first. Epoxy pressing and anchoring can be used.

To this end, the first member 110 is bonded to the outer wall of the existing building 2 by compressing the first member 110 while applying epoxy between the outer surface of the first member 110 and the outer surface of the existing building 1 in which the masonry is arranged. At the same time, the anchor 115 is fastened to pass through the anchor fastening hole 113 of the first member 110 and the anchor hole 4 previously constructed in the existing building 1.

Next, the second member 120 is disposed outside the first member 110 and fixed.

To this end, one end of the coupler 130 is disposed to pass through the coupler insertion groove 123 of the second member 120, and a coupling member 125 such as a bolt and a nut is a first coupling of the first member 110. It is constructed so as to penetrate the hole 114 and the second coupling hole 124 of the second member 120.

At this time, after placing all the bolts in advance so that the bolt head is positioned inside the first coupling hole 114 formed in the first member 110 and the end of the bolt passes through the first coupling hole 114 and protrudes outward. , The second member 120 is disposed so that the end of the bolt passes through the second coupling hole 124 and partially protrudes outward. The operator is located outside the second member 120 and rotates some of the protruding bolts and at the same time performs the work of additionally fastening the nut, so that the coupling member 125 is easily combined while using the long second member 120. Construction is possible. There is no need to put equipment or the like into a narrow space formed between the first member 110 and the second member 120.

When the first member 110 and the second member 120 are fastened in this way, a portion of the protruding end of the coupler 130 and a part of the protruding coupling member 125 are exposed outside of the second member 120. Will (see Fig. 5).

In another embodiment of the present invention, according to the structural analysis, a process of welding the protruding end portion of the coupler 130 and the second member 120 may be further performed.

Now, since the first member 110 and the second member 120 are fastened to form a space therebetween, a high-strength mortar 180 is poured and cured in this space. As a space between the first member 110 and the second member 120, a high-strength mortar 180 may be poured through an open upper portion.

The process of placing and curing the high-strength mortar 180 in the space under the steel rod insertion hole 3 may be performed simultaneously with the pouring and curing steps of the vertical external reinforcement body 100. In this case, the high-strength mortar 180 poured into the space between the first member 110 and the second member 120 reaches the base 2 and passes through the steel rod insertion hole 3 to reach the space below it. .

On the other hand, the high-strength mortar 180 is not poured at this stage, but after the assembly of the horizontal external reinforcement 200 to be described later is completed, it can be performed together with the pouring and curing of the high altitude mortar 280 to be poured. .

In this process, after the pouring of the high-strength mortar 180 is completed, or pouring and curing are completed, a vertical external reinforcing body cover (not shown), which is a separate steel plate, is added to the uppermost surface of the vertical external reinforcing body 100 Can be fixed. This process may also be performed after assembly of the horizontal external reinforcing body 200.

Next, a method of installing the horizontal external reinforcing body 200 will be described.

When the horizontal external reinforcement body 200 is installed, the outer surface of the vertical external reinforcement body 100 to which the horizontal external reinforcement body 200 is connected (that is, the second member 120) of the horizontal external reinforcement body 200 A hole is provided in advance by the size of the steel bar 290 in the portion through which the steel bar 290 is to pass.

First, a steel rod 290 is installed.

For the sake of explanation, the installation method of the horizontal external reinforcement body 200 is described after the installation method of the vertical external reinforcement body 100, but after installing the steel bar 190 in the vertical external reinforcement body 100, horizontal external reinforcement Note that the steel bar 290 of the sieve 200 may be installed, and then the first member 110 and the second member 120 of the vertical external reinforcement 100 may be installed.

The steel bar 290 should be bound with the steel bar 190 of the vertical external reinforcement body 100. For this, a steel bar binding member 240 is used. As shown in FIG. 2, since the ends of the steel bars 290 must be bound to the steel bars 190, respectively, when installing one horizontal external reinforcing body 200, two steel bar binding members 240 will be used.

The steel rod 190 of the vertical external reinforcement body 100 is inserted into the vertical steel rod insertion hole 242 of the steel rod binding member 240, and the steel rod 290 of the horizontal external reinforcement 200 in the horizontal steel rod insertion hole 244 ) Is inserted to establish a bond.

When a thread is located in the steel bars 190 and 290, a female thread is located in any one of the vertical steel bar insertion hole 242 and the horizontal steel bar insertion hole 244, through which the steel bars 190 and 290 can be tightly bound. .

Next, the horizontal first member of the horizontal external reinforcing body 200 is disposed and fixed to the outer wall of the existing building 2. The method is the same as the method described for the vertical external reinforcement body 100. Arrange the horizontal first member so that the coupler 230 provided in the horizontal first member surrounds the steel bar 290, and fix the horizontal first member to the outer wall of the existing building 1 using epoxy and anchor 215 It is to let you do.

Next, a horizontal second member of the horizontal external reinforcing body 200 is disposed and fastened to the horizontal first member. The method is also the same as the method described in the vertical external reinforcement body 100. The horizontal second member is disposed outside the horizontal first member, and one end of the coupler 230 passes through the coupler insertion groove of the horizontal second member, and the horizontal first member and the horizontal second member are connected using a horizontal coupling member. Is to combine.

Thereafter, similarly, a high-strength mortar 280 is poured and cured in the space formed between the horizontal first member and the horizontal second member.

In addition, parts not specifically described herein are the same as or similar to the installation method of the vertical external reinforcement body 100.

As shown in FIG. 9, when two or more horizontal external reinforcement bodies 200 are used, the above-described steps may be repeated.

In the above, the present specification has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but these are only exemplary, and those skilled in the art can use various modifications and equivalents from the embodiments of the present invention. It will be appreciated that examples are possible. Therefore, the scope of protection of the present invention should be determined by the claims.

1: existing building
2: foundation
3: steel rod insertion hole
4: anchor hole
10: external reinforcement
100: vertical external reinforcement
110: first member
113: anchor fastening hole
114: first coupling hole
115, 215: anchor
120: second member
123: coupler insertion groove
124: second coupling hole
125: coupling member
130, 230: coupler
141: upper base steel bar binding portion
142: steel bar binding portion under the foundation
180, 280: high strength mortar
190, 290: steel rod
200: horizontal external reinforcement
240: steel bar binding member
241: vertical member
242: vertical steel bar insertion hole
243: horizontal member
244: horizontal steel bar insertion hole

Claims (10)

(A) installing a vertical external reinforcing body 100; as an external reinforcing method comprising,
The step (A),
(a) vertically arranging the steel bar 190 to be spaced apart from the existing building 1 to be reinforced, but binding the lower end of the steel bar 190 to the foundation 2 of the existing building 1;
(b) Arranging the first member 110 so that the coupler 130 provided on the first member 110 surrounds the steel bar 190, and the first member 110 using the anchor 115 Fixing to the outer wall of the existing building (1);
(c) The second member 120 is disposed outside the first member 110, but one end of the coupler 130 passes through the coupler insertion groove 123 of the second member 120, and is coupled. Coupling the first member 110 and the second member 120 using a member 125; And
(d) placing and curing a high-strength mortar 180 in the space formed between the first member 110 and the second member 120,
The vertical external reinforcement body 100 includes the steel bar 190, the first member 110, the coupler 130, the anchor 115, the second member 120, and the coupling member 125 Containing,
External reinforcement method.
The method of claim 1,
The external reinforcement method,
Performing step (A) twice to install two spaced apart vertical external reinforcing bodies 100; And
(B) comprising the step of installing a horizontal external reinforcing body 200 connecting one side of the two vertical external reinforcing bodies 100,
The step (B),
(e) using two steel bar binding members 240 to bind the upper portion of each of the steel bars 190 of the vertical external reinforcing body 100 with both ends of the steel bars 290 of the horizontal external reinforcing body 200 step;
(f) The horizontal first member is disposed so that the coupler 230 provided in the horizontal first member surrounds the steel bar 290, and the horizontal first member is connected to the existing building (1) by using an anchor 215. ) Fixing to the outer wall of the;
(g) A horizontal second member is disposed outside the horizontal first member, and one end of the coupler 230 passes through the coupler insertion groove of the horizontal second member, and the horizontal first member is used by using a horizontal coupling member. Coupling a member and the horizontal second member; And
(h) including the step of pouring and curing a high-strength mortar 280 in the space formed between the horizontal first member and the horizontal second member,
External reinforcement method.
The method of claim 2,
The horizontal external reinforcement body 200 is at least one,
The (B) step is performed for each horizontal external reinforcement 200,
External reinforcement method.
The method of claim 1,
The step (a),
(a1) creating a steel rod insertion hole (3) in the foundation (2), and digging below the steel rod insertion hole (3);
(a2) passing the steel rod 190 through the steel rod insertion hole 3;
(a3) binding the steel bar 190 and the base 2 at the upper and lower sides of the steel bar insertion hole 3; And
(a4) including the step of pouring and curing high-strength mortar in the space excavated in step (a1),
External reinforcement method.
The method of claim 1,
The step (b),
(b1) The first member 110 is bound to the existing building 1 using an epoxy pressing method, and the anchor 115 is connected to the anchor fastening hole 113 of the first member 110 and the existing Including the step of fastening to pass through the anchor hole (4) of the building (1),
External reinforcement method.
The method of claim 1,
The steel bar 190 may be made of a plurality of steel bars,
The step (b),
(b2) further comprising the step of positioning the first member 110 such that the coupler 130 is positioned at a portion to which the plurality of steel bars are connected,
External reinforcement method.
The method of claim 1,
The coupling member 125 includes a bolt and a nut,
The step (c),
(c1) After the bolt head of the bolt is positioned inside the first coupling hole 114 formed in the first member 110, the bolt is connected to the first coupling hole 114 and the second member. Including the step of working to pass through the second coupling hole 124 of, and fastening the nut to the bolt from the outside of the second coupling hole 124,
External reinforcement method.
An external reinforcement body formed by the external reinforcement method according to claim 2,
Two or more vertical external reinforcement bodies 100; And
Including one or more horizontal external reinforcement 200,
External reinforcement.
The method of claim 8,
The horizontal cross-section of the first member 110 is formed in a U shape, but an inwardly curved flange portion is formed at the outer ends of the pair, and the second member 120 is a pair of flange portions of the first member 110 Formed to bind with,
External reinforcement.
The method of claim 8,
The steel bar binding member 240,
A vertical steel rod insertion hole 242 through which the steel rod 190 of the vertical external reinforcement body 110 passes; And
It is orthogonal to the vertical steel rod insertion hole 242, including a horizontal steel rod insertion hole 244 through which the steel rod 290 of the horizontal external reinforcement 200 passes,
External reinforcement.

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