KR20180137268A - Aseismatic Reinforcement Steel Frame with Friction Slip Brace and Aseismatic Reinforcement Method using thereof - Google Patents

Abstract

The present invention relates to a seismic reinforcement steel frame with a frictional reinforcement slip brace, capable of securing integrated behavior between an existing rebar concrete structure and a seismic reinforcement apparatus in occurrence of earthquake, and a seismic reinforcement method using the same. According to the present invention, the seismic reinforcement steel frame with a frictional reinforcement slip brace comprises: a planar anchor plate (100) attached along a base surface of a rebar concrete structure (50) to be reinforced; an anchor bolt (200) passing through an anchor bolt installation hole (11) formed on the anchor plate (100) to be buried and installed in the rebar concrete structure (50); a steel frame member (300) mounted along a column and a beam of the rebar concrete structure (50); and a plurality of connection members (40), wherein one end part is welded and coupled to the outer surface of the anchor plate (100) in a construction site and the other end part is temporarily coupled to the steel frame member (300) at each predetermined distance by a bolt to be able to move. A gap is generated between the anchor plate (100) and the base surface of the rebar conc structure (50) when the anchor bolt (200) is buried and installed therebetween, such that empty space is formed. The connection member (400) temporarily coupled by the bolt is welded and coupled to the anchor plate (100) in the construction site, and the bolt is completely fastened, such that the connection member (400) is fixed to the steel frame member (300). The steel frame member (300) is disposed along the column and the beam of the rebar concrete structure (50) to form a square or stacked-double square shape, and includes a frictional reinforcement brace (300) welded and coupled in a horizontal symmetrical structure to cross the internal space of the steel frame member (300).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an anti-seismic steel frame having a frictional reinforcement,

The present invention relates to a steel frame having a new concept of a frictional reinforcing member capable of effectively responding to an earthquake by securing the integrated behavior of a reinforced concrete structure and a steel frame for seismic reinforcement when an existing reinforced concrete structure is seismically reinforced using a steel frame Frame and an earthquake-proof method using the same.

Since the earthquake in Gyeongju in September 2016, interest in earthquake-resistant seismic retrofitting has increased, and earthquake-proof reinforcement of buildings, such as schools and public facilities, has been increasing. Generally, seismic retrofitting of existing reinforced concrete structures is carried out with a toggle or brace Seismic reinforcement methods such as friction dampers, viscous dampers, and slit steel dampers have been actively used, as well as seismic retrofitting methods such as steel braces, steel frame and CF column reinforcement.

However, the self-performance of various types of seismic retrofitting techniques described above can be said to be secured to some extent through various experiments and a large number of achievements. However, if the seismic reinforcement device and the reinforcing concrete structure to be reinforced can not secure the integrated behavior, They are inevitable.

Therefore, the importance of R & D on seismic strengthening apparatuses and joint structures that can secure the integral behavior of existing reinforced concrete structures with the development of the seismic reinforcement apparatuses and the construction method itself is increasing, and the prior art related thereto will be described as follows.

As shown in FIG. 1 (a), when the web of the H-shaped steel for the reinforcement steel is joined to the reinforced concrete structure to be reinforced, a plurality of resin anchors 2 are installed in one or two rows in the reinforced concrete structure 1 A method in which a plurality of stud bolts 3 are welded to one another in a row or two in a web 4 of an H-shaped steel for an advanced steel and the concrete 5 is installed after the formwork is installed. In this method, cracks are generated in concrete due to irregular seismic energy (lateral load) at the time of earthquake, and it is difficult to transmit the seismic load to the H-shaped steel at the same time as cracks are generated and it is difficult to expect a desired seismic strengthening effect.

1 (b), when the flange 7 of the H-shaped steel for an advanced steel is joined to the reinforced concrete structure 1 by using the anchor 8 and the epoxy resin 9, it is necessary to perform an anchor hole drilling operation using the drilling hole 10 as shown in FIG. 3 (c). In such a drilling operation, the drilling hole 10 is interfered with the upper flange 11, , There is a problem that when the reinforcing bars and the drilling drill in the concrete structure 1 to be reinforced are in contact with each other during the drilling operation, there is no proper way to avoid this, and it is difficult to securely install the reinforcement. Further, in order to solve such a problem, a hole is drilled in the upper flange 11 during an anchor hole drilling operation using a relatively long drill hole 13, but this method is also applied to the reinforcing concrete structure inside the reinforced concrete structure There is not an appropriate way to avoid this, and an unnecessary drilling process is added, resulting in a decrease in strength due to the perforation of the upper flange 11.

Therefore, it is urgently required to develop a more effective joint structure and seismic proofing method capable of ensuring the integrated movement of the seismic retrofitting apparatus and the existing reinforced concrete structure.

[Prior Art Literature]

Patent No. 10-1150392

Registration No. 10-1670633

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide a steel frame frame and an earthquake-proof method which can secure the integral behavior of an existing reinforced concrete structure and an earthquake-resistant reinforcement device in the event of an earthquake.

Another object of the present invention is to provide a means for firmly bonding a web or flange of a steel frame frame provided with a frictional reinforcement to a conventional reinforced concrete structure.

Third, it is another object of the present invention to provide a steel frame frame and an earthquake-proof method which are simple in construction and capable of absorbing the ground surface flexural deviation of a reinforced concrete structure.

Fourth, another object of the present invention is to provide a semi-permanently advanced steel frame frame and an earthquake-proofing method that do not need any maintenance.

The present invention relates to a steel frame for an anti-corrosion steel which is mounted on a reinforced concrete structure (50), comprising: a plate-like anchor plate (100) attached along a base surface of a reinforced concrete structure (50) to be reinforced; Anchor bolts 200 passing through the anchor bolt mounting holes 11 formed in the anchor plate 100 and being embedded in the reinforced concrete structure 50; A steel member 300 mounted along columns and beams of the reinforced concrete structure 50; And a plurality of connecting members 400 welded to the outer surface of the anchor plate 100 at one end and bolted at predetermined distances along the steel member 300 at the other end A gap is formed between the anchor plate 100 and the base surface of the reinforced concrete structure 50 in a state where the anchor bolts 200 are embedded, Frictionally welded in a bilaterally symmetrical structure so as to cross the inner space of the steel frame member 300 and to be arranged in a " The friction reinforcement member 330 is welded to one side of the steel member 300 and welded to the other side of the steel member 300 while the other side is provided with a plurality of slot holes 33 cut in the longitudinal direction A first reinforcing member 331; A second reinforcing member 332 having one side welded to and welded to the steel frame member 300 and the other side having a plurality of slit holes 33 cut in the longitudinal direction; And a bolt passing through a slot hole 33 provided in each of the first reinforcing member 331 and the second reinforcing member 332 so as to be bolted to the first reinforcing member 331 and the second reinforcing member 332, And a binding steel plate 333 which is in close contact with the other side of each of the members 332.

In addition, the present invention relates to a seismic proofing method using a steel frame for an anti-friction steel having a frictional reinforcement bird, which removes paint and foreign matter from the reinforcement site of the reinforced concrete structure 50 after the existing finishing material is removed, A first step of arranging the first step; A second step of drilling a hole for mounting the anchor bolt on the base surface of the reinforced concrete structure 50 according to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100; A third step of attaching the anchor bolts 200 to the perforated holes in the second step so that the anchor plates 100 are spaced apart from the base surface of the reinforced concrete structure 50 by a predetermined distance; A fourth step of pressing and joining the connecting member 400 assembled with the high-tension bolt to the steel member 300 while closely contacting the outer surface of the anchor plate 100 and welding the same; A final step of finally joining the connecting member 400 and the steel frame member 300 by tightly tightening the high tension bolt fastened with the fastening bolt; A sixth step of placing mortar or concrete on concrete after the mold is installed and forming a cured concrete layer 500 for integrally joining the reinforced concrete structure 50 and the steel frame member 300; And a seventh step of removing the mold after completion of curing and performing a finishing process.

Technical effects of the configuration of the present invention are as follows.

First, the web or flange of the steel frame with anti-friction steel reinforcement is fitted firmly with the existing reinforced concrete structure, so that the integrated behavior of the existing reinforced concrete structure and the seismic strengthening device can be ensured when an earthquake occurs.

In other words, the steel frame for an advanced steel which is provided with an anchor bolt 200, an anchor plate 100, a connecting member 400 and a steel reinforcing member 300 is installed along a column or a beam of a conventional reinforced concrete structure And then integrated with high-strength non-shrinkage mortar or concrete to ensure integrated behavior with existing reinforced concrete structures even in the event of an earthquake.

Second, it is easy to construct and can absorb the deviation of the ground plane of the reinforced concrete structure.

In other words, the welded joint of the connecting member 400 and the anchor plate 100 is performed in a state in which the connecting member 400 is bolted to the steel member 300, It is possible to more conveniently and quickly perform the welding work while absorbing the shape variation of the anchor plate 100 or the steel member 300. When the anchor plate 100 and the reinforcing concrete structure 50 are spaced apart from each other and the connecting member 400 is also assembled to the steel frame member 300, the anchor plate 100, the connecting member 400, The fluidity of the anchor plate 300 is sufficiently secured and the web end of the connecting member 400 can be easily brought into close contact with the outer surface of the anchor plate 100,

Third, it is possible to provide a semi-permanent advanced steel frame frame and seismic proofing method that do not require separate maintenance.

In other words, the steel frame of the steel frame with the friction-strengthening reinforcement is integrally formed with the existing reinforced concrete structure 50, so that the maintenance is not necessary.

Fourth, the frictional reinforcements 330 reinforce the rigidity of the steel member 300, and at the same time, when an external force of a predetermined magnitude or more is transmitted, the first reinforcement member 331 and the second reinforcement member 331, The mutual movement of the reinforcing members 332 is caused, and the external force can be absorbed while the frictional force is generated by the mutual movement.

In other words, a flow accompanied by a frictional force is generated within the range allowed by the slot hole 33, so that the seismic energy can be effectively damped while minimizing damage or deformation of the steel frame member 300 or the frictional reinforcement bird 330 itself have.

Figure 1 shows a prior art.
2 shows a case in which the connecting member 400 of the " T " shaped steel is coupled to the flange of the steel member 300 as a specific embodiment of the present invention.
3 shows another embodiment of the present invention in which the connecting member 400 of the " D " shape steel is coupled to the flange of the steel member 300.
4 shows a further embodiment of the present invention in which (a) is a case in which a connecting member 400 made of a "T" shaped steel is bolted to one side of a web of the steel frame member 300, (b) Quot; C " shaped steel member is bolted to one side surface of the web of the steel frame member 300. As shown in Fig.
5 shows another embodiment of the present invention in which the connection member 400 is composed of the lower connection part 410 and the upper connection part 420. [
6A shows a state in which the anchor plate 100 is installed along the inner side surface of the opening of the existing reinforced concrete structure 50. FIG.
6B shows a state in which one end of the connecting member 400 is welded to the anchor plate 100, and then the bolt fastened to the anchor plate 100 is fully tightened.
6C shows a state in which curing is completed by installing mortar or concrete.
7A shows a state in which an anchor plate 100 is installed along an outer front surface of an opening of an existing reinforced concrete structure 50. FIG.
FIG. 7B shows a state in which the bolt fastened after welding the lower connection part 410 to the anchor plate 100 by welding to the anchor plate 100 is fully tightened.
FIG. 7C shows a state in which curing is completed by installing mortar or concrete.
8 exemplarily illustrates various forms of the steel member 300. As shown in Fig.
9 exemplarily illustrates another form of the steel member 300. As shown in Fig.
Fig. 10 shows the coupling structure of the friction enhancer 330, where (a) friction pad 334 is not used, and (b) friction pad 334 is used, respectively.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The present invention relates to a steel frame for an internal-strength steel with a friction reinforcement member mounted on a reinforced concrete structure (50).

As shown in FIG. 2, the anchor plate 100 is attached along the base surface (surface) of the reinforced concrete structure 50 to be reinforced as a plate-shaped steel plate member, and is installed mainly along the column or the beam.

In addition, the anchor plate 100 may be constructed as a plurality of pieces as shown in FIG. 6A and may be separately attached to the base surface of the reinforced concrete structure 50 by the anchor bolts 200, And may be formed of one steel plate member which is elongated to one side as shown in FIG.

The anchor bolts 200 pass through the anchor bolt mounting holes 11 formed in the anchor plate 100 and are embedded in the reinforced concrete structure 50 to attach the anchor plate 100 to the surface of the reinforced concrete structure 50 An anchor plate 100 and an anchor plate 100 are formed on the anchor plate 100. The anchor plate 100 has a gap formed between the anchor plate 100 and the surface of the reinforced concrete structure 50, It is possible to secure a fluidized space even in the state of being attached to the surface of the reinforced concrete structure 50. In addition, since the cured layer 500 is formed in the hollow space through the gap, the integrated behavior of the steel frame member 300 and the reinforced concrete structure 50 is secured.

The steel frame member 300 is installed along the anchor plate 100 and serves as a main frame to receive and resist an external force such as an earthquake. do.

The steel frame member 300 may be installed along the inner side surface of the opening of the existing reinforced concrete structure 50 as shown in FIG. 6B or may be installed along the outside front surface of the opening of the existing reinforced concrete structure 50 as shown in FIG. 7B .

The steel member 300 may also be in the form of a "ch" or "sun" along the columns and beams of the reinforced concrete structure 50, as shown in FIG. 8 or 9, wherein the frictional reinforcements 330 And is welded in a horizontally symmetrical structure so as to cross the inner space of the steel member 300. [

10 (a), the frictional reinforcing barb 330 may include a first reinforcing member 331, a second reinforcing member 332, and a binding steel plate 333, or may be formed as shown in Fig. 10 (b) A friction pad 334 may be added.

One side of the first reinforcing member 331 is welded to the steel member 300 and welded to the other side of the first reinforcing member 331. The other side of the first reinforcing member 331 is provided with a plurality of slot holes 33 cut in the longitudinal direction.

One side of the second reinforcing member 332 is welded to and welded to the steel member 300 and the other side of the second reinforcing member 332 is provided with a plurality of slit holes 33 cut in the longitudinal direction.

The bundled steel plate 333 is bolted to the first reinforcing member 331 and the second reinforcing member 332 by bolts passing through the slot holes 33 formed in the first reinforcing member 331 and the second reinforcing member 332, And the first reinforcing member 331 and the second reinforcing member 332 are connected to each other while being in contact with the other side of each of the members 332.

The friction pad 334 is provided with a slot hole 33 having a pattern corresponding to the slot hole 33 formed in each of the first reinforcing member 331 and the second reinforcing member 332 and the binding steel plate 333 is bolted The first reinforcing member 333 and the second reinforcing member 332 and the second reinforcing member 332 to further increase the frictional force between the binding steel plate 333 and the first reinforcing member 331.

The frictional reinforcements 330 may be formed in the inner space of the steel member 300 as shown in FIG. 6B, FIG. 7B, FIG. 8 or FIG. 9, or may be reinforced with the inner lower edge of the steel member 300 Or the upper and lower ends may be in the form of an " H " 9, when the steel frame member 300 has a two-dimensional structure having a "sun" shape, a friction reinforcement bird 330 may be installed in each of the inner spaces.

The frictional reinforcements 330 reinforce the rigidity of the steel member 300 and at the same time provide a first reinforcing member 331 and a second reinforcing member 331 joined together through a binding steel plate 333, Thereby causing mutual movement of the members 332, and the external force is absorbed while the frictional force is generated by the mutual movement. That is, a flow accompanied by the frictional force is generated within the range allowed by the slot hole 33, so that the seismic energy can be effectively damped while minimizing the damage or deformation of the steel frame member 300 or the frictional reinforcement bird 330 itself.

When an external force (seismic energy) of a magnitude that can not be attenuated due to the mutual movement of the first reinforcing member 331 and the second reinforcing member 332 acts, finally the portion of the slot hole 33 is broken, Absorbed.

One end of the connecting member 400 is welded to the outer surface of the anchor plate 100 at the construction site, and the connecting member 400 is welded to the outer surface of the anchor plate 100, The other end of the steel member 400 is welded and finally fixed to the steel frame member 300 by fully tightening the bolt.

That is, the connecting member 400 is supplied to the construction site in a state where the bolt is fastened to the steel frame member 300. At the construction site, the connecting member 400 and the anchor plate 100 are first welded, The bolt connection is completed.

This connecting member 400 can be made of "T" shaped steel as shown in FIG. 2 or "C" shaped steel as shown in FIG. 3, where the plates are welded together to form a "T" Member having a cross-sectional shape or a " C " -shaped cross-sectional shape may be produced and used. In addition, the connection member 400 is provided with a plurality of through holes 22 through which high-strength non-shrinkage mortar or concrete is inserted.

When the connecting member 400 is made of a T-shaped steel, the end surface of the web of the connecting member 400 is welded to the outer surface of the anchor plate 100, and the flange outer surface of the connecting member 400 is welded to the steel member 300 And is bolted to abut one side flange outer surface of the flange.

When the connecting member 400 is made of a " C " shape steel, both side end portions of the connecting member 400 are welded to the surface of the anchor plate 100, 300). ≪ / RTI >

4, the connecting member 400 may be bolted to one side of the web of the steel frame member 300. FIG. 4 (a) shows a connecting member 400 made of "T" 4 (b) shows a case where the connecting member 400 made of the "c" shaped steel is bolted to one side of the web of the steel frame member 300.

The bolts for connecting the connecting member 400 and the steel frame member 300 are welded to the web or flange surface of the steel frame member 300 in advance as shown in Figs. 2 to 4, The head portion of a conventional bolt having a head may be welded to the web or flange surface of the steel member 300 or welded to the flange surface of the steel member 300 Or a general bolt having a head portion to penetrate the flange may be selected.

5, the connecting member 400 is composed of a lower connecting portion 410 and an upper connecting portion 420, and the web end face of the upper connecting portion 420 of the connecting member 400 is welded to the web of the steel frame member 300, do.

The lower connecting portion 410 of the connecting member 400 is formed of a "C" shaped steel as shown in FIG. 5 and the upper connecting portion 420 is also formed of a "C" shaped steel.

The lower connection part 410 and the upper connection part 420 are provided with a plurality of through holes 22 through which the high strength non-shrinkage mortar or concrete passes.

The web end faces of the lower connection part 410 are respectively welded to the outer side of the anchor plate 100 and the flange outer side faces of the lower connection part 410 and the flange outer side faces of the upper connection part 420 are bolted together, The web cross-section of the upper connection portion 420 is welded to one side of the web of the steel member 300, respectively.

In this case, the upper connection part 420 and the steel frame member 300 are provided at the construction site in a welded state beforehand, and the lower connection part 410 and the upper connection part 420 are connected to the lower connection part 410 After welding the anchor plate 100 first, the bolts are completely tightened to complete the bolt connection.

In this case, as shown in FIG. 5, a method may be selected in which the bolts are welded to the flange surface of the upper connection part 420 in advance, then the lower connection part 410 is welded to the welded bolts and the nut is tightened, A method of welding a head portion of a conventional bolt having a head portion to the flange surface of the upper connection portion 420 or inserting a conventional bolt having a head portion to penetrate the flange of the upper connection portion 420 may be selected.

In addition, the upper connection part 420 and the lower connection part 410 may be arranged such that the arrangement of the webs is orthogonal to each other, as shown in FIG. The upper connection part 420 and the lower connection part 410 may be made of " T " -shaped steel, though not shown separately in the accompanying drawings.

The casting layer 500 is made of high-strength non-shrinkage mortar or concrete which is cured so as to fill the space of the lower region of the steel member 300 occupied by the anchor plate 100 and the connecting member 400. The layer 500 serves to integrally join the reinforced concrete structure 50 and the steel frame member 300 together with the anchor bolts 200.

The installed curing layer 500 is also formed in an empty space formed between the anchor plate 100 and the surface of the reinforced concrete structure 50 as shown in FIG. 2 or FIG.

The curing layer 500 is cured by being poured through a plurality of through holes 22 formed in the connecting member 400, the upper connecting portion 420 and the lower connecting portion 410 to increase the bonding force with the connecting member 400 do.

As shown in Figs. 6 (a) to 6 (c) or 7 (a) to (c), the reinforced concrete steel frame having such a frictional reinforcing reinforcement is installed along a column or a beam of a conventional steel- A seismic resistant method using a steel frame with an anti-friction steel frame with a friction reinforcement bird is described.

<Earthquake Resistance Method of Coupling Structure shown in FIG. 6>

(1) Step 1

And removing the paint and foreign matter on the reinforced portion of the reinforced concrete structure 50 after the removal of the existing finishing material. This process can be carried out through a surface grinding process or the like.

(2) Step 2

A hole for mounting an anchor bolt is formed on the surface of the reinforced concrete structure 50 according to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100. [

The anchor plate 100 may be divided into a plurality of pieces as shown in FIG. 6A, or an integral steel plate may be used although not separately shown in the accompanying drawings.

(3) The third step (Fig. 6A)

The anchor bolts 200 are attached to the perforated holes in the second step so that the anchor plate 100 is adhered to the surface of the reinforced concrete structure 50 with a predetermined distance therebetween.

The anchor bolts 200 can be manufactured in various types and sizes and work according to the mounting manual of each product. When the anchor bolts 200 are completely mounted, the anchor plate 100 and the reinforced concrete structure A distance of about 10 to 20 millimeters is maintained between the bottom surface of the anchor plate 50 and the flow space (distance) of the anchor plate 100 is appropriately secured.

(4) In the fourth step (FIG. 6B)

The end face of the web of the connecting member 400 is brought into close contact with the outer surface of the anchor plate 100 while pushing or pulling the connecting member 400 assembled with the bolts to the steel member 300.

That is to say, by performing the welding connection between the connecting member 400 and the anchor plate 100 in a state where the connecting member 400 is bolted to the steel member 300, The anchor plate 100, or the steel frame member 300 can be absorbed and the welding operation can be performed more conveniently and quickly.

The anchor plate 100 and the reinforcing concrete structure 50 together with the connecting member 400 are also attached to the steel frame member 300. The anchor plate 100, The fluidity of the members 300 is sufficiently ensured so that the web end of the connecting member 400 can be easily brought into close contact with the outer surface of the anchor plate 100 and welding can be performed quickly.

(5) In the fifth step (FIG. 6B)

After the anchor plate 100 and the connecting member 400 are welded together, the bolts fastened to the anchor plate 100 are completely tightened to finally join the connecting member 400 and the steel frame member 300. Through this process, The anchor plate 100 is coupled to the reinforced concrete structure 50 by the anchor bolts 200 so that the anchor plate 100 and the connecting members 400 and 300 are completely integrated do.

(6) In the sixth step (Fig. 6C)

And a high strength non-shrinkage mortar or concrete is placed and cured to form a cured cured layer 500 which integrally joins the reinforced concrete structure 50 and the steel frame member 300.

Through this process, the integrated behavior of the existing reinforced concrete structure 50 and the steel frame member 300 is secured.

The mortar or concrete with high strength and non-shrinkage mortar or concrete can be cured by taking into account the site conditions according to the general construction method of the relevant field. So that an empty space between the reinforced concrete structures 50 is sufficiently filled.

(7) Step 7

After curing is completed, the mold is removed and necessary finishing process is performed.

<Seismic Retention Method of Coupling Structure shown in FIG. 7>

(1) Step 1

And removing the paint and foreign matter on the reinforced portion of the reinforced concrete structure 50 after the removal of the existing finishing material. This process can be carried out through a surface grinding process or the like.

(2) Step 2

A hole for mounting an anchor bolt is formed on the surface of the reinforced concrete structure 50 according to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100. [

The anchor plate 100 may be an integral steel plate as shown in FIG. 7A, or may be a plate having a plurality of pieces, not separately shown in the accompanying drawings.

(3) The third step (Fig. 7A)

The anchor bolts 200 are attached to the perforated holes in the second step so that the anchor plate 100 is adhered to the surface of the reinforced concrete structure 50 with a predetermined distance therebetween.

The anchor bolts 200 can be manufactured in various types and sizes and work according to the mounting manual of each product. When the anchor bolts 200 are completely mounted, the anchor plate 100 and the reinforced concrete structure A distance of about 10 to 20 millimeters is maintained between the bottom surface of the anchor plate 50 and the flow space (distance) of the anchor plate 100 is appropriately secured.

(4) In the fourth step (FIG. 7B)

A lower connecting portion 410 bolted to the upper connecting portion 420 welded to the steel member 300 is pressed or pulled on the outer surface of the anchor plate 100 and welded.

That is, by welding the lower connection part 410 and the anchor plate 100 in a state where the lower connection part 410 is bolted to the upper connection part 420, it is possible to prevent the deviation of the ground surface of the reinforced concrete structure 50 The anchor plate 100, or the steel frame member 300 can be absorbed and the welding operation can be performed more conveniently and quickly.

In other words, when the anchor plate 100 and the reinforcing concrete structure 50 are spaced apart from each other and the lower connecting portion 410 is also joined to the upper connecting portion 420 welded to the steel frame member 300, The upper end connecting portion 420 and the steel member 300 are sufficiently secured so that the web end portion of the lower connecting portion 410 is easily brought into close contact with the outer surface of the anchor plate 100, Lt; / RTI &gt;

(5) In the fifth step (FIG. 7B)

The anchor plate 100 and the lower connecting portion 410 are welded together and then the bolts fastened together are completely tightened to finally join the lower connecting portion 410 and the upper connecting portion 420. Through this process, The anchor plate 100 is connected to the reinforced concrete structure 50 by the anchor bolts 200. The anchor plate 100 is connected to the lower connecting portion 410, the upper connecting portion 420, As shown in Fig.

(6) In the sixth step (FIG. 7C)

And a high strength non-shrinkage mortar or concrete is placed and cured to form a cured cured layer 500 which integrally joins the reinforced concrete structure 50 and the steel frame member 300.

Through this process, the integrated behavior of the existing reinforced concrete structure 50 and the steel frame member 300 is secured.

The mortar or concrete with high strength and non-shrinkage mortar or concrete can be cured by taking into account the site conditions according to the general construction method of the relevant field. So that an empty space between the reinforced concrete structures 50 is sufficiently filled.

(7) Step 7

After curing is completed, the mold is removed and necessary finishing process is performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Addition or deletion of a technique, and limitation of a numerical value are included in the protection scope of the present invention.

50: Reinforced Concrete Structures
100: anchor plate
200: Anchor bolt
300: steel member
330: Friction reinforcement new
331: first reinforcing member
332: second reinforcing member
333: Bonded steel plate
334: Friction pad
400: connecting member
410: Lower connection part
420: upper connection part
500: Placed curing layer
11: Anchor bolt mounting ball
22: Through ball
33: Slot hole

Claims (8)

The present invention relates to a steel frame for an internal-progressive steel which is mounted on a reinforced concrete structure (50)
An anchor plate 100 in the form of a flat plate attached along the base surface of the reinforced concrete structure 50 to be reinforced;
Anchor bolts 200 passing through the anchor bolt mounting holes 11 formed in the anchor plate 100 and being embedded in the reinforced concrete structure 50;
A steel member 300 mounted along columns and beams of the reinforced concrete structure 50; And
And the other end of the connecting member 400 is welded to the outer surface of the anchor plate 100 at a construction site and the other end of the connection member 400 is fastened to the bolt so as to be movable at predetermined distances along the steel frame member 300. [ ;
And,
A gap is formed between the anchor plate 100 and the base surface of the reinforced concrete structure 50 even when the anchor bolts 200 are embedded,
The connecting member 400 fastened to the bolt is welded to the anchor plate 100 at the construction site and then fixed to the steel frame member 300 by completely tightening the bolt,
The steel frame member (300)
Are arranged in the form of &quot;?&Quot; or " date " along the columns and beams of the reinforced concrete structure (50)
A frictional reinforcing bar (330) welded in a symmetrical structure so as to cross the inner space of the steel member (300);
Respectively,
The frictional reinforcements (330)
A first reinforcing member 331 having one side welded to and welded to the steel frame member 300 and the other side having a plurality of slit holes 33 cut in the longitudinal direction;
A second reinforcing member 332 having one side welded to and welded to the steel frame member 300 and the other side having a plurality of slit holes 33 cut in the longitudinal direction; And
The first reinforcing member 331 and the second reinforcing member 332 are bolted to each other by bolts passing through the slot holes 33 provided in the first reinforcing member 331 and the second reinforcing member 332, A binding steel plate 333 which is in close contact with the other side;
Wherein the friction reinforcing brace is formed on the inner surface of the frame. The method of claim 1,
The connecting member (400)
It is made of "T" or "C"
The steel frame member (300)
It is made of "H" steel,
The cross section of the web of the connecting member 400 is welded to the outer surface of the anchor plate 100 and the flange outer surface 400 of the connecting member 400 is welded to the outer surface of the connecting plate 400. [ Is bolted to abut one side flange outer surface of the steel member (300) or one side surface of the web of the steel frame member (300)
When the connecting member 400 is made of a "C" shaped steel, both side end portions of the connecting member 400 are welded to the outer surface of the anchor plate 100, and the flange of the connecting member 400 And a side surface of the steel frame member is bolted so as to abut on one side flange outer side of the steel frame member (300) or one side surface of the web of the steel frame member (300). The method of claim 1,
The connecting member (400)
A lower connection part 410 made of a " T " And
An upper connection part 420 made of a " T "
Lt; / RTI &gt;
The web end portion of the lower connection portion 410 is welded to the outer surface of the anchor plate 100 and the flange outer side surface of the lower connection portion 410 and the flange outer side surface of the upper connection portion 420 are in contact with each other. And a web end of the upper connection part (420) is respectively welded to one side of the web of the steel frame member (300). 4. The method according to any one of claims 1 to 3,
The anchor plate (100)
Wherein the steel plate member is a single steel plate member composed of a plurality of pieces and attached to the surface of the reinforced concrete structure (50) individually by the anchor bolts (200) or elongated to one side. . 4. The method according to any one of claims 1 to 3,
The anchor plate 100 and the connecting member 400 are cured so as to fill the space of the lower region of the steel member 300 and the reinforcing concrete structure 50 and the steel member 300 are integrally joined together Curing layer 500;
Wherein the reinforcing steel reinforcement frame further comprises a friction reinforcing brace. 4. The method according to any one of claims 1 to 3,
The frictional reinforcements (330)
A slit hole 33 having a pattern corresponding to a slot hole 33 formed in each of the first reinforcing member 331 and the second reinforcing member 332 is provided and when the binding steel plate 333 is bolted, A friction pad 334 which increases the frictional force between the bundled steel plate 333 and the first reinforcing member 331 and between the bundled steel plate 333 and the second reinforcing member 332 while being compressed;
Wherein the frictional reinforcement member is provided with a frictional reinforcement member. The present invention relates to a seismic proofing method using a steel frame for an internal-progressive steel with a frictional reinforcement bird according to the first or second aspect,
A first step of removing the paint and foreign matter on the surface of the reinforcement portion of the reinforced concrete structure 50 after the existing finishing material is removed;
A second step of drilling a hole for mounting the anchor bolt on the base surface of the reinforced concrete structure 50 according to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100;
A third step of attaching the anchor bolts 200 to the perforated holes in the second step so that the anchor plates 100 are spaced apart from the base surface of the reinforced concrete structure 50 by a predetermined distance;
A fourth step of pressing and joining the connecting member 400 assembled with the high-tension bolt to the steel member 300 while closely contacting the outer surface of the anchor plate 100 and welding the same;
A final step of finally joining the connecting member 400 and the steel frame member 300 by tightly tightening the high tension bolt fastened with the fastening bolt;
A sixth step of placing mortar or concrete on concrete after the mold is installed and forming a cured concrete layer 500 for integrally joining the reinforced concrete structure 50 and the steel frame member 300; And
A seventh step of removing the formwork and performing a finishing process after curing is completed;
Wherein the steel reinforced concrete frame has a frictional reinforcement member. The present invention relates to a seismic proofing method using a steel frame for an anti-seizing steel plate provided with a frictional reinforcement member according to claim 3,
A first step of removing the paint and foreign matter on the surface of the reinforcement portion of the reinforced concrete structure 50 after the existing finishing material is removed;
A second step of drilling a hole for mounting the anchor bolt on the base surface of the reinforced concrete structure 50 according to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100;
A third step of attaching the anchor bolts 200 to the perforated holes in the second step so that the anchor plates 100 are spaced apart from the base surface of the reinforced concrete structure 50 by a predetermined distance;
A fourth step of pressing and pulling the lower connection part 410 bolted to the upper connection part 420 welded to the steel member 300 and welding the upper connection part 410 closely to the outer surface of the anchor plate 100;
A final step of finally joining the upper connection part 420 and the lower connection part 410 by completely tightening the bolts fastened together;
A sixth step of forming mortar or concrete after the mold is laid and curing the concrete to construct a curing layer 500 integrally joining the reinforcing concrete structure 50 and the steel member 300; And
A seventh step of removing the formwork and performing a finishing process after curing is completed;
Wherein the steel reinforced concrete frame structure has a frictional reinforcement member.

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