KR102011814B1 - Aseismatic Reinforcement Device with Friction Slip Flange, and Aseismatic Reinforcement Method using thereof - Google Patents

Abstract

The present invention relates to an earthquake-resistant reinforcement device having a friction flange mounted on a reinforced concrete structure (50) and an earthquake resistance method, the anchor plate (100) having a flat plate attached to the reinforced concrete structure (50); An anchor bolt 200 embedded in the reinforced concrete structure 50 by passing through the anchor bolt mounting hole 11 formed in the anchor plate 100; Steel frame member 300 is mounted to the reinforced concrete structure 50; And, one end is welded to the outer surface of the anchor plate 100 at the construction site, the other end is a plurality of connecting members 400 are pre-tightened by a bolt so as to flow at a predetermined distance along the steel member 300 It is configured to include, and the steel member 300 is a member of the elongated flat plate shape in close contact with the flange outer surface of the steel member 300 bolted or welded to the flange of the steel member 300 to be arranged in the longitudinal direction A friction pad 310 coupled to and provided with a plurality of slot holes 33 in a length direction; A binding pressure plate 320 that is bolted or welded to the flange of the steel frame member 300 so as to be in close contact with the outer surface of the friction pad 310 and arranged in the longitudinal direction; A spacer plate 330 installed between the lower surface of the upper end portion of the binding pressure plate 320 and the flange of the steel frame member 300, which is bolted or welded, and has a thickness corresponding to that of the friction pad 310; And a compression bolt 340 fastened to pass through the slot hole 33 of the friction pad 310, the flange of the steel frame member 300, and the binding pressure plate 320.

Description

Aseismatic Reinforcement Device with Friction Slip Flange, and Aseismatic Reinforcement Method using Technical

The present invention provides a seismic reinforcement device equipped with a friction flange of a new concept that can effectively respond to earthquakes by securing the integral behavior of the reinforced concrete structure and the seismic reinforcement device when seismic reinforcing the existing reinforced concrete structure using a steel frame; It relates to a vacuum method using the same.

Since the September 2016 Gyeongju earthquake, interest in seismic reinforcement in preparation for earthquakes has increased, and seismic reinforcement of building structures such as schools and public facilities has been increasing.In general, seismic reinforcement of existing reinforced concrete structures is equipped with toggles or braces. Vibration reinforcement methods such as friction dampers, viscous dampers, and slit steel dampers, and seismic reinforcement methods such as steel frame, steel frame, and CF column reinforcement are actively used.

However, it can be said that the performance of the various types of seismic reinforcing methods described above has been secured to some extent through various experiments and numerous performances. They can only be useless.

Therefore, with the development of seismic reinforcement device or the construction method itself, the importance of research and development on the joint structure that can ensure the integral behavior of the seismic reinforcement device and the existing reinforced concrete structure is increasing, looking at the related arts as follows.

As shown in Fig. 1 (a), when a web of H-shaped steel for seismic reinforcement is joined to a reinforced concrete structure to be reinforced, seismic reinforcement is provided, and a plurality of resin anchors 2 are installed in one or two rows of the concrete structure to be reinforced. In the web (4) of the seismic reinforcement reinforcement, a plurality of stud bolts (3) are welded in one row or two rows, and the concrete (5) is poured after the formwork is installed. The method inevitably causes cracks in concrete due to irregular seismic energy (lateral load) during the earthquake, and at the same time, it is difficult to transfer seismic loads to H-beams, which makes it difficult to expect an expected seismic reinforcing effect.

In addition, when the seismic reinforcement is reinforced in a manner in which the flange 7 of the H-shaped steel for seismic reinforcement is bonded to the concrete structure 1 to be reinforced using an anchor 8 and an epoxy resin 9 as shown in FIG. As shown in (c), the anchor hole drilling operation must be performed using the drilling drill 10. In this drilling operation, the drilling drill 10 interferes with the upper flange 11, so that vertical drilling of a prescribed depth is difficult. In the drilling process, when the reinforcing bar in the concrete structure (1) is in contact with the drill drill, there is a problem that it is difficult to install a seismic reinforcement device is not an appropriate way to avoid this. In addition, in order to improve such a problem, a hole of the upper flange 11 may be drilled during the anchor hole drilling by using a relatively long drilling drill 13, but this method also matches the reinforcing bar inside the reinforced concrete structure during the drilling. Not only does not have a proper way to avoid the case of contact, but also adds unnecessary drilling process, resulting in a decrease in strength due to the drilling of the upper flange (11).

Therefore, there is an urgent need to develop a more effective joint structure and a vacuum method that can secure the integral behavior of the seismic reinforcing device and the existing reinforced concrete structure.

[Preceding technical literature]

Patent Registration No. 10-1150392

Patent Registration No. 10-1670633

The object of the present invention created to solve the above problems is as follows.

First, it is an object of the present invention to provide an earthquake-resistant reinforcement device and an earthquake resistance method that can ensure the integral behavior of the existing reinforced concrete structure and seismic reinforcement device in the event of an earthquake.

Secondly, it is another object of the present invention to provide a joint structure and a vacuum method capable of firmly joining an earthquake-resistant reinforcement device having a friction flange to an existing reinforced concrete structure.

Third, another object of the present invention is to provide an earthquake-resistant reinforcing device and a vacuum method, which are easy to construct and are equipped with a friction flange capable of absorbing the base surface bending deviation of the reinforced concrete structure.

Fourth, another object of the present invention is to provide a semi-permanent seismic reinforcing device and a vacuum method that does not require any maintenance.

The present invention relates to a seismic reinforcement device having a friction flange mounted on the reinforced concrete structure (50), the anchor plate 100 of the flat form attached along the base surface of the reinforced concrete structure (50) to be reinforced; An anchor bolt 200 that is embedded in the reinforced concrete structure 50 by passing through the anchor bolt mounting hole 11 formed in the anchor plate 100; Steel frame member 300 is mounted to the reinforced concrete structure 50; And, one end is welded to the outer surface of the anchor plate 100 at the construction site, the other end is a plurality of connection members pre-tightened with a bolt so as to flow at a predetermined distance along the steel member 300 ( 400); and the gap between the anchor plate 100 and the base surface of the reinforced concrete structure 50, even when the anchor bolt 200 is buried mounted there is a gap (gap) is formed The connection member 400 pre-tightened with bolts is fixed to the steel member 300 by fully tightening the bolt after welding to the anchor plate 100 at the construction site, and the steel member 300 is The steel member is made of "H" shaped steel and arranged in the form of "|", "ㅁ" or "日" along the column or beam of the reinforced concrete structure 50. Flange outside of 300 And is in close contact with the lower end of the bolt or weld joint on the flanges of the steel frame member 300 so as to be arranged in the longitudinal direction, a plurality of slow-teuhol 33 is a friction pad 310, having a longitudinal direction; A binding pressure plate 320 having an upper end bolted or welded to a flange of the steel frame member 300 so as to be in close contact with an outer surface of the friction pad 310; A spacer plate 330 installed between the lower surface of the upper end of the binding bearing plate 320 and the flange of the steel frame member 300 to be bolted or welded and having a thickness corresponding to that of the friction pad 310; And the slots 33 of the friction pad 310, the flange of the steel member 300, and the binding bearing plate 320 are fastened so that the friction pad 310 is a flange of the steel member 300. And a compression bolt 340 to be compressed between the binding pressure plate 320.

In addition, the present invention relates to an earthquake resistance method using an earthquake-resistant reinforcement device having a friction flange, and to clean up the base surface by removing paint and foreign substances on the base surface of the reinforced part of the reinforced concrete structure 50 after the demolition work of the existing finishing material. First step; A second step of drilling a hole for mounting the anchor bolt on the base surface of the reinforced concrete structure 50 in accordance with the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100; A third step of attaching the anchor bolt 200 to the hole drilled in the second step to attach the anchor plate 100 to the base surface of the reinforced concrete structure 50 by a predetermined distance; A fourth step of contacting and welding the outer side of the anchor plate 100 by pushing or pulling the connecting member 400 prefabricated with the high strength bolt to the steel frame member 300; A fifth step of finally coupling the connection member 400 and the steel member 300 by completely tightening the pretightened high tension bolt; A sixth step of forming a pouring cured layer 500 integrally coupling the reinforced concrete structure 50 and the steel member 300 by pouring mortar or concrete after installing the formwork; And a seventh step of removing the formwork after the curing is completed and performing a finishing process.

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

First, the seismic reinforcement device equipped with the friction flange can be firmly bonded to the existing reinforced concrete structure to ensure the integral behavior of the existing reinforced concrete structure and the seismic reinforcement device when an earthquake occurs.

In other words, after installing the seismic reinforcement device equipped with a friction flange consisting of anchor bolt 200, anchor plate 100, connecting member 400, steel member 300, etc. along the column or beam of the existing reinforced concrete structure Integrating high-strength non-shrink mortar or concrete to ensure integrated behavior with existing reinforced concrete structures even during earthquakes.

Second, the construction is easy, and can absorb the surface bending deviation of the reinforced concrete structure.

In other words, the base member bending deviation of the reinforced concrete structure 50 by performing the welding coupling of the connecting member 400 and the anchor plate 100 in the state that the connecting member 400 is bolted to the steel member 300 only. B, while absorbing the deviation of the shape of the anchor plate 100 or the steel frame member 300, it is possible to perform the welding operation more conveniently and quickly. Because, together with the gap between the anchor plate 100 and the reinforced concrete structure 50, when the connecting member 400 is also temporarily assembled to the steel member 300, the anchor plate 100, the connecting member 400 and the steel member This is because the fluidity of the 300 is sufficiently secured so that the web end of the connection member 400 is easily adhered to the outer surface of the anchor plate 100 so that welding can be performed quickly.

Third, it is possible to provide a semi-permanent seismic reinforcement device and a vacuum method without the need for separate maintenance.

In other words, the seismic reinforcement device having a friction flange is integrated with the existing reinforced concrete structure 50 and has a lifespan, thus requiring no additional maintenance.

Fourth, the lower end is in close contact with the outer surface of the friction pad 310, the friction pad 310 is bolted or welded to the flange of the steel member 300 so as to be in close contact with the flange outer surface of the steel member (300) To be arranged in the longitudinal direction between the upper end portion of the binding pressure plate 320 is bolted or welded to the flange of the steel member 300, the lower end of the upper portion of the binding pressure plate 320 and the flange of the steel member 300 is installed bolt Welded to pass through the spacer plate 330 having a thickness corresponding to the friction pad 310, the slot hole 33 of the friction pad 310, the flange of the steel member 300, and the binding pressure plate 320. When the friction pad 310 is fastened to be pressed between the flange of the steel frame member 300 and the binding pressure plate 320, a compression bolt 340 is provided, such that an external force such as an earthquake acts so that the displacement of the steel frame member 300 is reduced. If so, the friction pad 310 Pilot holes 33 is the frictional force accompanying the extent that the flow is granted may be generated repeatedly effectively attenuated by an external force.

Figure 1 shows the prior art.
Figure 2 shows a case in which the connection member 400 of the "T" section steel is coupled to the flange of the steel frame member 300 as a specific embodiment of the present invention.
Figure 3 shows a case in which the connection member 400 of the "C" section steel is coupled to the flange of the steel frame member 300 as another specific embodiment of the present invention.
4 is another specific embodiment of the present invention (a) is a case where the connecting member 400 made of "T" section steel is bolted to one side of the web of the steel member 300, (b) is " It shows the case where the connecting member 400 is made of "" steel bolted to one side of the web of the steel frame member 300.
FIG. 5 illustrates a case in which the connection member 400 includes a lower connection part 410 and an upper connection part 420 as another specific embodiment of the present invention.
Figure 6a shows a state in which the anchor plate 100 is installed along the inner surface of the opening of the existing reinforced concrete structure (50).
6B illustrates a state in which the pretightening bolt is completely tightened after welding one end of the connecting member 400 to the anchor plate 100.
6c shows a state in which curing is completed by pouring mortar or concrete.
FIG. 7A illustrates a state in which the anchor plate 100 is installed along the outer side of the opening of the existing reinforced concrete structure 50.
FIG. 7B illustrates a state in which the pre-tightened bolt is completely tightened after welding the lower connection part 410 to the anchor plate 100 to the anchor plate 100.
7c shows a state in which curing is completed by pouring mortar or concrete.
8 exemplarily shows the shape of the steel frame member 300 ("|" letter shape)
9 exemplarily shows another form of the steel frame member 300, in which the friction pad 310 and the binding pressure plate 320 are installed on both sides of the flange.
10 exemplarily shows yet another form of the steel frame member 300 (“day” shape).
11 illustrates a coupling structure of the friction pad 310, the binding pressure plate 320, the spacer plate 330, and the compression bolt 340 coupled to the steel member.
12 is a conceptual diagram of seismic force attenuation of an earthquake-resistant reinforcement device having a friction flange.

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

The present invention relates to a seismic reinforcement device having a friction flange mounted on the reinforced concrete structure (50).

The anchor plate 100 is attached along the base surface (surface) of the reinforced concrete structure 50 to be reinforced as a steel plate member in the form of a flat plate, as shown in Figure 2, mainly installed along the column or beam.

In addition, the anchor plate 100 is made of a plurality of pieces as shown in Figure 6a may be a structure that is attached to the base surface of the reinforced concrete structure 50 by the anchor bolt 200 individually, shown in Figure 7a It may be made of one steel sheet member elongated to one side as shown.

The anchor bolt 200 is attached to the anchor plate 100 to the surface of the reinforced concrete structure 50 while being embedded in the reinforced concrete structure 50 through the anchor bolt mounting hole 11 formed in the anchor plate 100 A gap is formed between the anchor plate 100 and the surface of the reinforced concrete structure 50 even when the anchor bolt 200 is buried and an empty space is formed, and the anchor plate 100 is formed through the gap. Is to ensure a flow space even in the state attached to the surface of the reinforced concrete structure (50). In addition, the pour curing layer 500 is formed in the empty space through the gap to ensure the integral behavior of the steel member 300 and the reinforced concrete structure (50).

Steel frame member 300 is used, such as steel "H" steel, if the cross section is provided with a web and flange may be used "C" shaped steel or "C" shaped steel, not "H" shaped steel.

The steel frame member 300 is mounted along the anchor plate 100 and serves as a main skeleton that receives and receives the external force when an external force such as an earthquake acts.

Steel frame member 300 may be installed along the inner surface of the opening of the existing reinforced concrete structure 50, as shown in Figure 6b, and installed along the outer surface of the opening of the existing reinforced concrete structure 50, as shown in Figure 7b May be

In addition, the steel frame member 300 may be in the form of "|", "", "" or "日" characters along the column or beam of the reinforced concrete structure 50, as shown in Figures 8 to 10.

In the case of Figure 8 along the pillar is used to form a steel frame member (300), which is manufactured for the reinforcement of the pillar mounted on the outside of the building. Such steel frame member 300 is a friction pad as shown in Figure 8 A friction flange configured to include a 310, a binding pressure plate 320, a spacer plate 330, and a compression bolt 340 may be provided at both flanges of the steel member 300.

In the case of Figure 9 shows the steel member 300 of the "ㅁ" shape is installed along the pillars and beams of the building, which is mounted along the outer front of the opening of the building, the steel member 300 arranged in the vertical direction A friction flange structure may be provided on each side flange.

10 shows a case in which the steel frame member 300 has a two-stage structure having a "day" shape, and may be a three-stage structure as necessary.

The friction pad 310, the binding pressure plate 320, the spacer plate 330, and the compression bolt 340 is coupled to the flange of the steel member 300 to act as a friction flange to attenuate external forces such as earthquakes.

As shown in FIG. 11, the friction flange includes a friction pad 310, a binding pressure plate 320, a spacer plate 330, and a compression bolt 340.

The friction pad 310 is a member of elongated flat plate shape, the lower end of the friction pad 310 is bolted or welded to the flange of the steel member 300 so as to be in close contact with the flange outer surface of the steel member 300. When the bolt is coupled, the reinforcement plate 350 may be provided inside the flange of the steel frame member 300 to which the lower end of the friction pad 310 is bolted.

The friction pad 310 may be made of a metal (steel plate), and in general, various kinds of pads that generate frictional force may be used. When the steel sheet is not used, welding pads cannot be welded and bolted. The friction pad 310 is provided with a plurality of slot holes 33 in the length direction as shown in FIG. 10.

The binding pressure plate 320 is bolted or welded to the flange of the steel member 300 so that the upper end of the binding pressure plate 320 overlaps the outer surface of the friction pad 310 and is arranged in the longitudinal direction. The reinforcement plate 350 may be provided inside the flange of the steel frame member 300 to which the upper end of the binding pressure plate 320 is bolted.

The spacer plate 330 is installed between the lower surface of the upper end of the binding pressure plate 320 and the flange of the steel frame member 300 and has a thickness corresponding to that of the friction pad 310.

The pressing bolt 340 is fastened to pass through the slot hole 33 of the friction pad 310, the flange of the steel member 300, and the binding pressure plate 320 so that the friction pad 310 may be connected to the flange of the steel member 300. It is to be compressed between the binding pressure plate (320).

As such, the friction pad 310 is pressed between the flange of the steel member 300 and the binding pressure plate 320 so that an external force acts and the displacement of the steel member 300 occurs, so that the friction pad 310 is the steel member 300. It is to effectively damp the external force (earthquake energy) by the friction while repeating the relative movement between the flange and the binding pressure plate 320 of the.

In other words, when the earthquake load (lateral force) acts as shown in FIG. 12 and the horizontal displacement D of the steel member 300 occurs, the slot hole provided in the friction pad 310 according to the horizontal displacement D is generated. The friction pad 310 repeats the relative movement between the flange of the steel member 300 and the binding pressure plate 320 within the allowable range (L) of (33), and the seismic load is generated by the friction force generated in this process. Absorbed and attenuated.

When an earthquake load (lateral force) of a size that cannot be attenuated by the frictional force due to the relative movement of the friction pad 310 is applied, the slot hole 33 is finally broken to absorb the seismic load.

The connection member 400 is pretightened with bolts at predetermined distances along the steel member 300, one end of the connection member 400 is welded to the outer surface of the anchor plate 100 at the construction site, the connection member The other end of the 400 is finally fixed to the steel frame member 300 by fully tightening the bolt after welding.

That is, the connection member 400 is supplied to the construction site in a pre-tightened state to the steel frame member 300 with a bolt, the welding member and the anchor plate 100 is first welded in the construction site and then fully tighten the bolts. Bolting is completed.

The connecting member 400 may be made of "T" shaped steel as shown in Figure 2 or "C" shaped steel as shown in Figure 3, in some cases by welding the flat plates "T" type It is also possible to produce and use a cross-section or "c" shaped cross-section member. In addition, the connection member 400 is provided with a plurality of through-holes 22 through which the high-strength non-contraction mortar or concrete to be poured is provided.

When the connecting member 400 is made of “T” shaped steel, the cross section of the connecting member 400 web is welded to the outer surface of the anchor plate 100, and the flange outer surface of the connecting member 400 is steel frame member 300. Bolted to abut the outer surface of the flange of one side.

When the connecting member 400 is made of "c" section steel, both web end surfaces of the connecting member 400 are welded to the surface of the anchor plate 100, respectively, and the flange outer surface of the connecting member 400 is a steel member ( Bolted to abut the outer surface of the flange of one side 300).

In addition, as shown in Figure 4, the connecting member 400 may be bolted to one side of the web of the steel member 300, Figure 4 (a) is a connecting member 400 made of "T" shaped steel steel When the bolt is coupled to one side of the web of the member 300 and Figure 4 (b) is a case where the connecting member 400 made of "c" section steel is bolted to one side of the web of the steel member (300).

The bolt coupling the connection member 400 and the steel member 300 is selected to insert a general bolt having a head to penetrate the web or flange of the steel member 300, as shown in Figures 2 to 4, Although not shown separately in the accompanying drawings, a method of joining the connecting bolt 400 to the welded bolt after joining the computer bolt to the web or the flange surface of the steel member 300 in advance may be selected. A method of welding the head of the additional general bolt to the web or flange surface of the steel member 300 may be selected.

In the case of Figure 5, the connecting member 400 is composed of a lower connecting portion 410 and the upper connecting portion 420, the web cross-section of the upper connecting portion 420 of the connecting member 400 welded to the web of the steel member 300 do.

The lower connecting portion 410 of the connecting member 400 is made of "c" section steel as shown in Figure 5 and the upper connecting portion 420 is also made of "c" section steel.

Each of the lower connection part 410 and the upper connection part 420 is provided with a plurality of passing holes 22 through which high strength non-contraction mortar or concrete is poured.

The web cross-sections of the lower connecting portion 410 are respectively welded to the outer surface of the anchor plate 100, the outer bolt of the flange of the lower connector 410 and the outer surface of the flange of the upper connector 420 are bolted to abut each other, Web cross-sections 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 portion 420 and the steel member 300 is provided to the construction site in the pre-welded state, the lower connection portion 410 and the upper connection portion 420 and the lower connection portion 410 and the pre-tightening bolt The anchor plate 100 is first welded to complete the bolting by fully tightening the bolts.

In this case, as shown in FIG. 5, a method of inserting a general bolt having a head to penetrate through the flange of the upper connection part 420 may be applied, and the computer bolt or the general bolt is welded to the flange of the upper connection part 420 and lowered. Inserting the connection part 410 into the welded bolt and fastening the nut may be selected.

In addition, the upper connector 420 and the lower connector 410 may be arranged such that the arrangement of the web is perpendicular to each other as shown in FIG. The upper connection part 420 and the lower connection part 410 are not shown separately in the accompanying drawings, but may be made of "T" section steel.

The pour curing layer 500 is made of high strength non-contraction mortar or concrete that is poured to fill the space of the lower region of the steel member 300 occupied by the anchor plate 100 and the connecting member 400, such pour curing The layer 500 serves to integrally combine the reinforced concrete structure 50 and the steel frame member 300 together with the anchor bolt 200.

In addition, the pouring curing layer 500 is also formed in the empty space formed at the interval between the surface of the anchor plate 100 and the reinforced concrete structure 50, as shown in FIG.

The pouring curing layer 500 is poured through the plurality of through holes 22 formed in the connecting member 400, the upper connecting part 420, and the lower connecting part 410 to cure to increase the bonding force with the connecting member 400. do.

The seismic reinforcement device equipped with such a friction flange is installed along the columns or beams of the existing steel concrete structure as shown in Figure 6 (a ~ c) or Figure 7 (a ~ c) to reinforce the opening, below the friction flange It looks at the earthquake resistance method using the seismic reinforcement device equipped with.

<The vacuum method of the coupling structure shown in FIG. 6>

(1) First step

After the demolition work of the existing finishing material is a process of cleaning the base surface by removing the paint and foreign substances on the surface of the reinforcement part of the reinforced concrete structure (50). This process may be performed through a surface grinding process.

(2) second stage

According to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100 is a process of drilling a hole for mounting the anchor bolt on the surface of the reinforced concrete structure 50.

Anchor plate 100 may be used that is divided into a plurality of pieces, as shown in Figure 6a, may be used as an integral steel sheet, although not shown separately in the accompanying drawings.

(3) Third Step (FIG. 6A)

In the second step, the anchor bolt 200 is mounted to the hole drilled in the second step to attach the anchor plate 100 to the surface of the reinforced concrete structure 50 so as to have a predetermined distance therebetween.

Anchor bolt 200 may be used in a variety of products and specifications, and perform the operation according to the installation manual of each product, anchor plate 100 and reinforced concrete structure in the state of mounting the anchor bolt 200 is completed An interval of about 10 to 20 millimeters is maintained between the base surfaces of the 50 so as to properly secure the flow space (distance) of the anchor plate 100.

(4) Fourth Step (Fig. 6B)

While pushing or pulling the connecting member 400 pre-assembled with bolts to the steel member 300 is a process of welding the end surface portion of the web of the connecting member 400 in close contact with the outer surface of the anchor plate 100.

That is, by performing the welding coupling of the connecting member 400 and the anchor plate 100 in the state that the connecting member 400 is bolted to the steel member 300 only, the base surface deviation of the reinforced concrete structure 50 or In addition, while absorbing the deviation of the shape of the anchor plate 100 or the steel frame member 300, the welding operation can be performed more conveniently and quickly.

In other words, when the connecting member 400 is also temporarily assembled to the steel member 300 together with the gap between the anchor plate 100 and the reinforced concrete structure 50, the anchor plate 100, the connecting member 400 and the steel frame The fluidity of the members 300 is sufficiently secured so that the web end of the connection member 400 is easily adhered to the outer surface of the anchor plate 100 so that welding can be performed quickly.

(5) 5th step (FIG. 6B)

After the anchor plate 100 and the connection member 400 are joined by welding, the process of finally connecting the connection member 400 and the steel member 300 by fully tightening the pretightened bolts is performed. 100), the connection member 400 and the steel frame member 300 is coupled so as to be perfectly integrated, anchor plate 100 is mounted to the reinforced concrete structure 50 by the anchor bolt 200 do.

(6) Sixth Step (Fig. 6C)

After the formwork is installed, the high strength non-contraction mortar or concrete is poured to form the pouring cured layer 500 that integrally couples the reinforced concrete structure 50 and the steel member 300.

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

The process of installing formwork or pouring high strength non-shrinkable mortar or concrete is carried out in consideration of site conditions according to general construction methods in the field, and the high strength non-shrinkage mortar or concrete to be poured is anchor plate 100 and The empty space between the reinforced concrete structure 50 is to be filled enough.

(7) 7th step

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

<The vacuum method of the coupling structure shown in FIG. 7>

(1) First step

After the demolition work of the existing finishing material is a process of cleaning the base surface by removing the paint and foreign substances on the surface of the reinforcement part of the reinforced concrete structure (50). This process may be performed through a surface grinding process.

(2) second stage

According to the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100 is a process of drilling a hole for mounting the anchor bolt on the surface of the reinforced concrete structure 50.

The anchor plate 100 may be an integral steel plate, as shown in Figure 7, or may be used to separate a plurality of pieces, although not shown separately in the accompanying drawings.

(3) Third Step (Fig. 7A)

In the second step, the anchor bolt 200 is mounted to the hole drilled in the second step to attach the anchor plate 100 to the surface of the reinforced concrete structure 50 so as to have a predetermined distance therebetween.

Anchor bolt 200 may be used in a variety of products and specifications, and perform the operation according to the installation manual of each product, anchor plate 100 and reinforced concrete structure in the state of mounting the anchor bolt 200 is completed An interval of about 10 to 20 millimeters is maintained between the base surfaces of the 50 so as to properly secure the flow space (distance) of the anchor plate 100.

(4) Fourth Step (Fig. 7B)

It is a process of welding and then closely contacting the outer surface of the anchor plate 100 while pushing or pulling the lower connection portion 410 prefabricated with bolts to the upper connection portion 420 welded to the steel member 300.

That is, by performing the welding coupling of the lower connecting portion 410 and the anchor plate 100 in the state in which the lower connecting portion 410 is temporarily assembled with the upper connecting portion 420 with a bolt, the base surface deviation of the reinforced concrete structure 50 or In addition, while absorbing the deviation of the shape of the anchor plate 100 or the steel frame member 300, the welding operation can be performed more conveniently and quickly.

In other words, when the lower connection portion 410 is also temporarily assembled to the upper connection portion 420 welded to the steel member 300 together with the gap between the anchor plate 100 and the reinforced concrete structure 50, the anchor plate 100 ), The lower connecting portion 410, the upper connecting portion 420 and the steel member 300 is secured enough fluid so that the web end of the lower connecting portion 410 is in close contact with the outer surface of the anchor plate 100 quickly welding Can be done.

(5) 5th step (FIG. 7B)

After the anchor plate 100 and the lower connection part 410 are joined together by welding, the lower connection part 410 and the upper connection part 420 are finally joined by completely tightening the pretightened bolts. 100, the lower connection portion 410, the upper connection portion 420 and the steel member 300 is coupled so as to be perfectly integrated, anchor plate 100 is reinforced concrete structure 50 by the anchor bolt 200 ) Is attached to.

(6) Sixth Step (Fig. 7C)

After the formwork is installed, the high strength non-contraction mortar or concrete is poured to form the pouring cured layer 500 that integrally couples the reinforced concrete structure 50 and the steel member 300.

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

The process of installing formwork or pouring high strength non-contraction mortar or concrete is carried out in consideration of site conditions according to general construction methods in the field. The empty space between the reinforced concrete structure 50 is to be filled enough.

(7) 7th step

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

As described above, specific embodiments of the present invention have been described with reference to the accompanying drawings, but the scope of protection of the present invention is not necessarily limited to these embodiments, and various design changes and disclosures are made without departing from the technical spirit of the present invention. In the case of addition or deletion of technology, and simple numerical limitations, it is obvious that the scope of the present invention is included.

50: reinforced concrete structure
100: anchor plate
200: anchor bolt
300: steel member
310: friction pad
320: binding pressure plate
330: spacer
340: Crimping bolt
350: reinforcement plate
400: connecting member
410: lower connection
420: upper connection
500: pouring curable
11: Anchor bolt mounting work
22: passer
33: slot hole

Claims (7)

As to a seismic reinforcement device having a friction flange mounted on the reinforced concrete structure 50,
Anchor plate 100 of the flat form attached along the base surface of the reinforced concrete structure 50 to be reinforced;
An anchor bolt 200 that is embedded in the reinforced concrete structure 50 by passing through the anchor bolt mounting hole 11 formed in the anchor plate 100;
Steel frame member 300 is mounted to the reinforced concrete structure 50; And,
One end portion is welded to the outer surface of the anchor plate 100 at the construction site, the other end is a plurality of connecting members 400 are pre-tightened with a bolt to flow at a predetermined distance along the steel member 300 ;
It is configured to include,
Between the anchor plate 100 and the base surface of the reinforced concrete structure 50, there is a gap (gap) even in the state in which the anchor bolt 200 is embedded, an empty space is formed,
The connection member 400 pre-tightened with bolts are fixed to the steel frame member 300 by fully tightening the bolts after being welded to the anchor plate 100 at the construction site,
The steel frame member 300,
It is made of "H" section steel is a structure arranged in the form of "|", "ㅁ" or "日" along the column or beam of the reinforced concrete structure 50,
The lower end is bolted or welded to the flange of the steel member 300 to be arranged in the longitudinal direction in close contact with the flange outer surface of the steel member 300 as the elongated flat plate member, a plurality of slot holes 33 Friction pad 310 provided in the longitudinal direction;
A binding pressure plate 320 having an upper end bolted or welded to a flange of the steel frame member 300 so as to be in close contact with an outer surface of the friction pad 310;
A spacer plate 330 installed between the lower surface of the upper end of the binding bearing plate 320 and the flange of the steel frame member 300 to be bolted or welded and having a thickness corresponding to that of the friction pad 310; And,
The friction pad 310 is fastened so as to pass through the slot hole 33 of the friction pad 310, the flange of the steel member 300, and the binding pressure plate 320, and the flange of the steel member 300. Compression bolt 340 to be compressed between the binding pressure plate 320;
Is further provided,
The connection member 400,
Made of "T" or "ㄷ" section steel,
When the connecting member 400 is made of “T” shaped 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 of the connecting member 400. The bolt is coupled to abut one side of the flange outer surface of the steel member 300 or one side of the web of the steel member 300,
When the connecting member 400 is made of “c” shaped steel, both end surfaces of the web of the connecting member 400 are welded to the outer surface of the anchor plate 100, respectively, and outside the flange of the connecting member 400. Side is bolted to abut one side flange outer surface of the steel member 300 or one side of the web of the steel member 300,
The anchor plate 100,
Seismic reinforcement device having a friction flange, characterized in that made of a plurality of pieces individually attached to the surface of the reinforced concrete structure 50 by the anchor bolt (200) or stretched to one side. As to a seismic reinforcement device having a friction flange mounted on the reinforced concrete structure 50,
Anchor plate 100 of the flat form attached along the base surface of the reinforced concrete structure 50 to be reinforced;
An anchor bolt 200 that is embedded in the reinforced concrete structure 50 by passing through the anchor bolt mounting hole 11 formed in the anchor plate 100;
Steel frame member 300 is mounted to the reinforced concrete structure 50; And,
One end portion is welded to the outer surface of the anchor plate 100 at the construction site, the other end is a plurality of connecting members 400 are pre-tightened with a bolt to flow at a predetermined distance along the steel member 300 ;
It is configured to include,
Between the anchor plate 100 and the base surface of the reinforced concrete structure 50, there is a gap (gap) even in the state in which the anchor bolt 200 is embedded, an empty space is formed,
The connection member 400 pre-tightened with bolts are fixed to the steel frame member 300 by fully tightening the bolts after being welded to the anchor plate 100 at the construction site,
The steel frame member 300,
It is made of "H" section steel is a structure arranged in the form of "|", "ㅁ" or "日" along the column or beam of the reinforced concrete structure 50,
The lower end is bolted or welded to the flange of the steel member 300 to be arranged in the longitudinal direction in close contact with the flange outer surface of the steel member 300 as the elongated flat plate member, a plurality of slot holes 33 Friction pad 310 provided in the longitudinal direction;
A binding pressure plate 320 having an upper end bolted or welded to a flange of the steel frame member 300 so as to be in close contact with an outer surface of the friction pad 310;
A spacer plate 330 installed between the lower surface of the upper end of the binding bearing plate 320 and the flange of the steel frame member 300 to be bolted or welded and having a thickness corresponding to that of the friction pad 310; And,
The friction pad 310 is fastened so as to pass through the slot hole 33 of the friction pad 310, the flange of the steel member 300, and the binding pressure plate 320, and the flange of the steel member 300. Compression bolt 340 to be compressed between the binding pressure plate 320;
Is further provided,
The connection member 400,
Lower connection portion 410 made of "T" or "c" section steel; And,
An upper connection part 420 made of “T” steel or “c” steel;
Consists of,
The web end of the lower connecting portion 410 is welded to the outer surface of the anchor plate 100, the bolt so that the flange outer surface of the lower connector 410 and the flange outer surface of the upper connector 420 abut each other Is coupled, the seismic reinforcement device with a friction flange, characterized in that the web end of the upper connection portion 420 is welded to each side of the steel frame member 300, respectively. In claim 2,
The anchor plate 100,
Seismic reinforcement device having a friction flange, characterized in that made of a plurality of pieces individually attached to the surface of the reinforced concrete structure 50 by the anchor bolt (200) or stretched to one side. The method of claim 1 or 2,
Placing is cured to fill the space of the lower portion of the steel member 300 occupied by the anchor plate 100 and the connecting member 400 is poured to integrally combine the reinforced concrete structure 50 and the steel member 300 integrally Curing layer 500;
A seismic reinforcement device having a friction flange, characterized in that it further comprises. The present invention relates to an earthquake resistance method using the seismic reinforcement device provided with the friction flange according to claim 1,
A first step of cleaning the base surface by removing paint and foreign substances from the base surface of the reinforcement part of the reinforced concrete structure 50 after the demolition work of the existing finishing material;
A second step of drilling a hole for mounting the anchor bolt on the base surface of the reinforced concrete structure 50 in accordance with the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100;
A third step of attaching the anchor bolt 200 to the hole drilled in the second step to attach the anchor plate 100 to the base surface of the reinforced concrete structure 50 by a predetermined distance;
A fourth step of contacting and welding the outer side of the anchor plate 100 by pushing or pulling the connecting member 400 prefabricated with the high strength bolt to the steel frame member 300;
A fifth step of finally coupling the connection member 400 and the steel member 300 by completely tightening the pretightened high tension bolt;
A sixth step of forming a pouring cured layer 500 integrally coupling the reinforced concrete structure 50 and the steel member 300 by pouring mortar or concrete after installing the formwork; And,
A seventh step of removing the formwork after the curing is completed and performing a finishing process;
A seismic resistance method using a seismic reinforcement device having a friction flange, characterized in that comprising a. The present invention relates to an earthquake resistance method using the seismic reinforcing apparatus provided with the friction flange according to claim 2,
A first step of cleaning the base surface by removing paint and foreign substances from the base surface of the reinforcement part of the reinforced concrete structure 50 after the demolition work of the existing finishing material;
A second step of drilling a hole for mounting the anchor bolt on the base surface of the reinforced concrete structure 50 in accordance with the pattern of the anchor bolt mounting hole 11 formed in the anchor plate 100;
A third step of attaching the anchor bolt 200 to the hole drilled in the second step to attach the anchor plate 100 to the base surface of the reinforced concrete structure 50 by a predetermined distance;
A fourth step of contacting and welding the outer surface of the anchor plate 100 by pushing or pulling the lower connection portion 410 pre-assembled with bolts to the upper connection portion 420 welded to the steel frame member 300;
A fifth step of finally coupling the upper connection part 420 and the lower connection part 410 by completely tightening the pretightened bolt;
A sixth step of forming a pouring cured layer 500 integrally coupling the reinforced concrete structure 50 and the steel member 300 by pouring mortar or concrete after installing the formwork; And,
A seventh step of removing the formwork after the curing is completed and performing a finishing process;
A seismic resistance method using a seismic reinforcement device having a friction flange, characterized in that comprising a. delete

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