KR101214139B1 - Steel reinforced concrete aseismatic structure and method using clamp - Google Patents

Abstract

PURPOSE: An aseismatic structure and method for enlarging the section of a concrete structure using a clamp are provided to easily fix a lower steel plate to the surface of a concrete structure. CONSTITUTION: An aseismatic structure for enlarging the section of a concrete structure using a clamp comprises a lower steel plate(100), multiple anchor bolts(200), bar-shaped fixing clamps(300), a plate-shaped load transfer plate(400), and an upper steel plate(500). The lower steel plate is installed along the surface of an existing concrete structure. The anchor bolts are installed in anchor holes formed along the surface of the existing concrete structure. The fixing clamps fix the lower steel plate to the surface of the concrete structure using fixing nuts(210) fastened to the anchor bolts. The load transfer plate is coupled to the top center of the lower steel plate and is protruded upward from the lower steel plate. The upper steel plate is coupled to the top end of the load transfer plate to be parallel to the lower steel plate.

Description

Steel Reinforced Concrete Aseismatic Structure and Method using Clamp}

According to the present invention, the reinforcing member of the existing reinforced concrete structure is fixed to the concrete surface using a clamp, and then the cross section is expanded to simplify the installation process of the reinforcing member and increase the work efficiency in the field. The present invention relates to a seismic reinforcement structure and method for sectional expansion to minimize the loss of valuable life and property by inducing behavior.

The recent damages caused by earthquakes in neighboring countries are beyond imagination, and Korea, which is classified as a middle and weak area, is not safe from such natural disasters.

     Moreover, domestic earthquake preparedness environment is more than 80% of existing building facilities are almost defenseless against earthquakes. In particular, multi-family houses, which are the majority of middle and low-rise structures, and school facilities that should be used as evacuation sites for residents in case of emergency Now, only the seismic reinforcement is starting.

     In general, seismic reinforcement works of existing building facilities are carried out outdoors except for special cases. This can be said to not limit the usability of the existing building as possible.

     In the case of a conventional joint structure in which the seismic reinforcing steel structure is integrally coupled to the outer surface of the concrete structure 10 as shown in FIG. 1, the reinforcing plate 20, the load transfer plate 30, and the steel frame 40 are existing. After installing on the surface of the concrete structure mortar (50) is poured to increase the cross section. In the case of the conventional cross-sectional reinforcement method, the hole 21 for anchor bolt mounting is drilled in the reinforcing plate 20 in advance, and then the perforated reinforcing plate 20 is attached to the surface of the concrete structure 10. After drilling the holes 11 for mounting the anchor bolts 60 on the surface of the concrete structure 10 according to the pattern of the holes 21, the anchor bolt 60 is mounted to reinforce the plate 20 of the concrete structure. The process of fixing to the surface must be carried out. Because when drilling the hole for mounting the anchor bolt 60 on the surface of the concrete structure 10 in advance inconsistent with the pattern of the hole 21 perforated in the reinforcing plate 20, the reinforcing plate 20 is the surface of the concrete structure This is because it often happens that it can't be installed in. In addition, after the installation work of the reinforcing plate 20 is completed, the work of welding the load transfer plate 30 in which the steel frame 40 is integrally coupled to the upper portion of the reinforcing plate 20, because the reinforcing plate 20 If the load transfer plate 30 and the steel frame 40 is welded to the upper part of the), it is not possible to drill holes for mounting the anchor bolt 60 on the surface of the concrete structure using the reinforcement plate 20 as a template. to be.

As such, it is not impossible to perform the welding work by placing the load transfer plate 30 on the surface of the concrete structure forming the vertical wall. However, the work space is troublesome and time-consuming due to the small space, and the risk of safety accident is high. have. Of course, using the reinforcement plate 20 as a template, the process of drilling holes for mounting the anchor bolt 60 on the surface of the concrete structure also anchor bolt (60) on the surface of the concrete structure without the reinforcement plate 20 is installed Compared to the process of drilling holes for mounting, work is cumbersome, takes a relatively long time, and has a high risk of safety accidents.

Therefore, it is urgent to introduce a new structure and construction method that can be quickly and safely reinforced with seismic capacity through cross-sectional expansion.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems.

First, it is an object of the present invention to provide a seismic reinforcement structure and construction method of concrete structure cross-section expansion of a new concept that can be easily installed steel structure.

Secondly, another object of the present invention is to provide a seismic reinforcement structure and construction method for concrete section cross-section expansion of a new concept that can exclude on-site welding work.

Third, another object of the present invention is to provide a seismic reinforcement structure and construction method of cross-section expansion of a concrete structure that can prevent safety accidents and maximize work efficiency.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention relates to a seismic reinforcement structure that is constructed in a concrete structure, the lower plate 100 of the plate shape elongated in one direction to be installed along the surface of the existing concrete structure; A plurality of anchor bolts 200 installed in the anchor hole perforated on the outside of the lower steel plate 100 along the surface of the existing concrete structure; The fixing clamp 300 having a rod shape fixed to the surface of the concrete structure by pressing the lower steel plate 100 by a fixing nut 210 inserted into the anchor bolt 200 and fastened to the anchor bolt 200. ; An elongated plate-shaped load transfer plate 400 which is welded in the longitudinal direction along the center of the upper surface of the lower steel plate 100 so as to be perpendicular to the lower steel plate 100, protruding upward from the lower steel plate 100; And an upper steel plate 500 welded to the upper end of the load transfer plate 400 and arranged in parallel with the lower steel plate 100. The fixing clamp 300 includes the anchor bolt 200. A) through which the anchor mounting hole 310 is long cut in the longitudinal direction of the fixed clamp 300 is characterized in that the position of the fixed clamp 300 can be adjusted.

In addition, the present invention relates to a seismic reinforcement method through the cross-sectional expansion of the existing concrete structure, the first step of drilling the anchor hole to a certain depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10); A second step of inserting and installing the anchor bolt 200 at the same time as injecting the synthetic resin into the anchor hole; Inserting the fixing clamp 300 into the anchor bolt 200 and pre-fastening the fixing nut 210; The lower steel plate 100, the load transfer plate 400, and the upper steel plate 500, which are welded in advance, are installed on the surface of the concrete structure, and the fixing clamps 300 are completely fastened by fastening the fixing nuts 210 to the lower steel plates. A fourth step of pressing and fixing the upper surface of the 100; A fifth step of filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with a synthetic resin layer (not shown); A sixth step of reinforcing the reinforcement 800 surrounding the lower steel plate 100, the load transfer plate 400, and the upper steel plate 500; A seventh step of pouring mortar 900 after installing a formwork (not shown) to surround the reinforcement bar 800; And an eighth step of removing the formwork after curing the mortar (900).

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

First, the steel structure can be conveniently installed.

In other words, the tolerance generated during the drilling of the anchor hole is a concrete structure directly without the need to use the lower steel plate 100 that can be absorbed through the anchor hole 310 of the fixed clamp 300 as a template for anchor hole drilling Anchor holes can be drilled on the surface of Therefore, as well as to facilitate the drilling operation, the operation of attaching the lower steel plate 100 to the surface of the concrete structure can also select the appropriate position while moving the fixed clamp 300 in the front and rear direction, the lower steel plate 100 more easily Can be fixed to the surface of the concrete structure.

Second, field welding can be ruled out.

In other words, the load is transferred to the lower steel plate 100 by fixing the lower steel plate 100 by using the anchor bolt 200 and the fixing nut 210 installed in the anchor hole drilled in the outer region of the lower steel plate 100. Even if the plate 400 or the upper steel plate 500 is input to the site in a pre-welded state, the operation of fixing the lower steel plate 100 to the surface of the concrete structure may be performed without difficulty.

Third, it is possible to prevent safety accidents and maximize work efficiency.

In other words, it is not necessary to use the lower steel plate 100 as a template for drilling the anchor hole, it is possible to omit the field welding work can minimize the risk of safety accidents and maximize the work efficiency.

1 is a cross-sectional view of a conventional cross-sectional seismic reinforcement structure.
Figure 2 shows a perspective view of (a) the cross-sectional structure of a specific embodiment of the present invention, and (b) the upper steel plate 500, the lower steel plate 100 and the load transfer plate 400, respectively.
Figure 3 shows (a) a cross-sectional structure of another specific embodiment of the invention, and (b) a perspective view of the first transfer plate 410 and the second transfer plate 420, respectively.
4 shows a cross-sectional structure of another specific embodiment of the present invention.
FIG. 5 shows a perspective view of another specific embodiment of the first transfer plate 410 and the second transfer plate 420, respectively, applied in the case of FIG.
6 shows a cross-sectional structure of an embodiment in which mortar 900 is poured without reinforcing the reinforcement 800, (a) when the load transfer plate 400 is an integral type, and (b) the load transfer plate 400. The case where it consists of this 1st transmission board 410 and the 2nd transmission board 420 is respectively shown.

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 lower steel plate 100 is installed along the surface of the existing concrete structure as a plate shape elongated in one direction as shown in Figure 2, the lower steel plate 100 is anchor bolt 200 and the fixed clamp 300 It is fixed to the surface of the concrete structure.

The anchor bolt 200 is installed in the anchor hole perforated at predetermined intervals along the outer region of the lower steel plate 100 along the surface of the existing concrete structure, in consideration of the size and shape of the lower steel plate 100 100) can be drilled in advance on the surface of the concrete structure. This is because anchor fixing holes 310 cut in the longitudinal direction are formed in the fixed clamp 300 so that the tolerance can be absorbed to a large extent. In the process of installing the anchor bolt 200, the epoxy resin is injected into the anchor hole.

The fixing clamp 300 is inserted into the anchor bolt 200 as a general rod shape, and compresses the lower steel plate 100 by fixing nuts 210 fastened to the anchor bolt 200 to fix the surface of the concrete structure. Play a role. The anchor clamp hole 310 through which the anchor bolt 200 passes through the fixed clamp 300 is cut in the longitudinal direction of the fixed clamp 300 to adjust the position of the fixed clamp 300. Therefore, it is possible to stably fix the lower steel plate 100 by absorbing the deviation of the distance between the anchor bolt 200 and the lower steel plate 100 by placing the fixing clamp 300 at an appropriate position.

The load transfer plate 400 is a member of a long elongated plate shape and is welded in the longitudinal direction along the center of the upper surface of the lower steel plate 100 so as to be perpendicular to the lower steel plate 100 to protrude upward from the lower steel plate 100.

The load transfer plate 400 may additionally be provided with a plurality of mortar through holes 460 penetrated at predetermined intervals, as shown in FIG. The mortar through hole 460 serves as a path through which mortars 900 placed on the left and right sides of the load transfer plate 400 are connected to each other, thereby strengthening the binding force between the mortar 900 and the load transfer plate 400. do. The specific shape, size, spacing, etc. of the mortar through hole 460 may be appropriately selected in consideration of the specifications and the field situation of the load transfer plate 400.

In addition, the load transfer plate 400 and the lower steel plate 100 by connecting to each other may be further provided with a reinforcing plate 470 to reinforce the coupling force of the load transfer plate 400 and the lower steel plate 100, Figure 2 (b) As shown in), the vertical cross section of the reinforcing plate 470 is welded to the left or right surface of the load transfer plate 400, and the horizontal cross section is welded to the top surface of the lower steel plate 100, and the load transfer plate 400. Arranged at predetermined intervals along the left and right sides of the), the specific shape and size of the reinforcement plate 470, the spacing of the arrangement also appropriately in consideration of the specifications and field conditions of the load transfer plate 400 or the lower steel plate 100, etc. Although not shown separately in the accompanying drawings, the reinforcement plate 470 may connect the upper steel plate 500 and the load transfer plate 400 to each other.

The upper steel plate 500 is welded to the upper end of the load transfer plate 400 as a member of elongated plate shape is arranged side by side with the lower steel plate (100).

Synthetic resin layer (not shown) is formed in the space between the lower steel plate 100 and the surface of the existing concrete structure to fill the gap by injecting epoxy-based synthetic resin to strengthen the adhesion between the lower steel plate 100 and the concrete structure surface.

The reinforcement 800 is reinforced to surround the lower steel plate 100, the load transfer plate 400, and the upper steel plate 500. The transfer plate 400 and the upper steel plate 500 to surround the entire.

The reinforcement 800 is not necessarily to be reinforcement, and as shown in FIG. 6, the mortar may be formed on the lower region of the upper steel plate 500 so that the upper surface of the upper steel plate 500 is exposed without separately reinforcing the reinforcement 800. 900 may be poured.

When constructed in such a structure, there is an advantage in that an additional steel structure such as an earthquake brace or an earthquake damper can be easily installed on the upper surface of the exposed upper steel plate 500.

Mortar (900) is installed after the formwork (not shown) to surround the entire reinforcement reinforcement (800) is poured by curing. When the mortar 900 is cured in this manner, the mortar 900 can be integrated with the existing concrete structure to significantly improve the seismic performance when an earthquake occurs, and the seismic reinforcement structure can be prevented from being separated and collapsed from the existing concrete.

3 illustrates another specific embodiment of the present invention. The difference from FIG. 2 is that the load transfer plate 400 is composed of a first transfer plate 410 and a second transfer plate 420.

The first transfer plate 410 is welded in the longitudinal direction along the center of the upper surface of the lower steel plate 100, the second transfer plate 420 is welded in the longitudinal direction along the center of the lower surface of the upper steel plate 500 do.

The first transfer plate 410 and the second transfer plate 420, as shown in Figure 3 (a) overlap the first transfer plate 410 and the second transfer plate 420 in a state overlapping each other by a predetermined area. It is assembled by a plurality of coupling bolts 430 fastened through. As shown in FIG. 3 (b), the first carrier plate 410 is provided with horizontal holes 440 cut in the horizontal direction at regular intervals, and the second transfer plate 420 is long cut in the vertical direction. Vertical holes 450 are provided at regular intervals.

Therefore, while the first transfer plate 410 and the lower steel plate 100 is fixed to the surface of the concrete structure, the second transfer plate 420 in which the upper steel plate 500 is integrally coupled within a predetermined range up, down, left, and right. The position of the second transfer plate 420 and the upper steel plate 500 can be adjusted.

In some cases, the vertical long hole 450 may be provided in the first transfer plate 410, and the horizontal long hole 440 may be provided in the second transfer plate 420.

The first transfer plate 410 and the second transfer plate 420 may have a form in which the cutouts 480 are formed at a predetermined interval, as shown in FIG. 5, and the cutouts 480 are horizontal holes. 440 and the vertical hole 450 is provided in the region without the mortar (900) by acting as a passage through which the mortar (900) in the state in which the first transfer plate 410 and the second transfer plate 420 is assembled And serves to strengthen the binding force between the load transfer plate 400. Specific shape, size, spacing, etc. of the cutout 480 may be appropriately selected in consideration of the specifications and the field situation of the load transfer plate 400.

In addition, there is also a difference in that a pair of vertical reinforcing plates 600 are arranged in the longitudinal direction of the upper steel plate 500 while being welded to the left and right end surfaces of the upper steel plate 500 to form a 'H' cross section.

The upper steel plate 500 and the vertical reinforcing plate 600 may be replaced with a pre-fabricated H-shaped steel.

The remaining components are the same as those shown in FIG.

Figure 4 shows another embodiment of the present invention, the difference with Figure 2 is welded to the left and right cross-sections of the upper steel plate 500, respectively, as long as the 'H' cross-section is arranged in the longitudinal direction of the upper steel plate 500 The pair of vertical reinforcing plate 600 is further provided, the same as that already mentioned in Figure 3 in the case of the vertical reinforcing plate 600 will be omitted.

Since other components have already been described with reference to FIG. 2 or FIG. 3, redundant descriptions thereof will be omitted.

Hereinafter, look at the seismic reinforcement method through the section expansion of the existing concrete structure.

≪ Embodiment 1 >

The first embodiment is a construction method related to the seismic reinforcing structure shown in FIG.

(1) Step 1

Drilling the anchor hole to a certain depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10).

A process of drilling the anchor hole to a predetermined depth using a drill in the outer region of the lower steel plate 100 along the reinforcement portion of the concrete structure 10. In other words, considering the size of the lower steel plate 100 to be used is perforated along the outer area spaced a certain distance from the end of the lower steel plate 100 is sufficient, and the lower steel plate 100 is attached to the surface of the concrete structure 10 It is not necessary to carry out a drilling operation at.

The anchor hole is drilled to a depth sufficient to insert and anchor the anchor bolt 200, and the number and spacing of the anchor hole is appropriately determined in consideration of the site conditions of the reinforced concrete structure.

(2) Step 2

The epoxy bolt is injected into the anchor hole and the anchor bolt 200 is inserted and installed at the same time.

(3) Step 3

The fixing clamp 300 is inserted into the anchor bolt 200 fixed to the surface of the concrete structure 10, and the fixing nut 210 is temporarily fastened.

(4) Step 4

The lower steel plate 100, the load transfer plate 400, and the upper steel plate 500, which are welded in advance, are installed on the surface of the concrete structure, and the fixing clamps 300 are completely fastened by fastening the fixing nuts 210 to the lower steel plates. It is a process of pressing and fixing the upper surface of the (100).

Since the fixing clamp 300 is provided with the anchor hole 310, the fixed clamp 300 is moved along the anchor hole 310 in the forward and backward directions to adjust the position to absorb the tolerances generated during the drilling of the anchor hole. can do.

(5) Step 5

Filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin. Through such a process, the gap between the lower steel plate 100 and the concrete structure 10 is filled, and the bonding force between the lower steel plate 100 and the concrete structure 10 is enhanced.

(6) Step 6

The lower steel plate 100, the load transfer plate 400 and the upper steel plate 500 surrounding the reinforcement (800) surrounding the process.

The reinforcement 800 is to reinforce the hoop and cast iron in accordance with the design book to surround the entire lower plate 100, load transfer plate 400 and the upper steel plate 500.

(7) Step 7

After installing the formwork (not shown) to surround the reinforced reinforcement (800) is a process of pouring mortar (900).

This process is the same as the general concrete placing process, so a detailed description thereof will be omitted.

(8) Step 8

Mortar (900) After curing the process of removing the formwork.

As such, when the mortar 900 is cured, the seismic reinforcing structure can be prevented from being collapsed by being integrated with the existing concrete structure to significantly improve the seismic performance when an earthquake occurs.

≪ Embodiment 2 >

The second embodiment is a construction method related to the seismic reinforcing structure shown in FIG.

(1) Step 1

Drilling the anchor hole to a certain depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10).

This process is the same as the first step of the first embodiment, so duplicated description is omitted.

(2) Step 2

The epoxy bolt is injected into the anchor hole and the anchor bolt 200 is inserted and installed at the same time.

This process is the same as the second step of the first embodiment, so duplicated description is omitted.

(3) Step 3

The fixing clamp 300 is inserted into the anchor bolt 200 and the fixing nut 210 is temporarily fastened.

(4) Step 4

The lower welded steel plate 100 and the first transfer plate 410 pre-welded are installed on the surface of the concrete structure, and the fixing clamp 300 is completely fastened by fastening the fixing nut 210 to the upper surface of the lower steel plate 100. It is the process of crimping and fixing.

Since the fixing clamp 300 is provided with the anchor hole 310, the fixed clamp 300 is moved along the anchor hole 310 in the forward and backward directions to adjust the position to absorb the tolerances generated during the drilling of the anchor hole. can do.

(5) Step 5

Pre-welded second transfer plate 420, the upper steel plate 500 and the vertical reinforcing plate 600 is disposed on the upper portion of the lower steel plate 100 and the first transfer plate 410 and the second transfer plate 420 In this overlapping state, the coupling bolt 430 passing through the horizontal long hole 440 and the vertical long hole 450 is fastened to combine the first transfer plate 410 and the second transfer plate 420 into one.

The first transfer plate 410 and the second transfer plate 420 have horizontal holes 440 and vertical holes 450, respectively, so that the first transfer plate 410 and the lower steel plate 100 are formed on the surface of the concrete structure. In the state fixed to the upper plate 500 is integrally coupled to the second transfer plate 420 is moved up and down, left and right within a predetermined range to the final coupling position of the second transfer plate 420 and the upper steel plate 500 I can regulate it.

(6) Step 6

Filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin.

This process is the same as the fifth step of the first embodiment, and thus duplicated description thereof will be omitted.

(7) Step 7

The lower steel plate 100, the first transfer plate 410, the second transfer plate 420, the upper steel plate 500, and the reinforcement 800 surrounding the vertical reinforcement plate 600 are placed in the process of reinforcement.

The reinforcement 800 is arranged in accordance with the design hoop and the main reinforcement to the lower steel plate 100, the first transfer plate 410, the second transfer plate 420, the upper steel plate 500 and the vertical reinforcement plate 600 Surround it all.

(8) Step 8

After installing the formwork (not shown) to surround the reinforced reinforcement (800) is a process of pouring mortar (900).

This process is the same as the general concrete placing process, so a detailed description thereof will be omitted.

(9) Step 9

Mortar (900) After curing the process of removing the formwork.

Third Embodiment

The third embodiment relates to the construction method of the seismic reinforcing structure shown in FIG.

(1) Step 1

Drilling the anchor hole to a certain depth using a drill along the left and right sides of the reinforcement portion of the concrete structure 10.

This process is the same as the first step of the first embodiment, so duplicated description is omitted.

(2) Step 2

The epoxy bolt is injected into the anchor hole and the anchor bolt 200 is inserted and installed at the same time.

This process is the same as the second step of the first embodiment, so duplicated description is omitted.

(3) Step 3

The fixing clamp 300 is inserted into the anchor bolt 200 and the fixing nut 210 is temporarily fastened.

(4) Step 4

The lower steel plate 100, the load transfer plate 400, the upper steel plate 500, and the vertical reinforcement plate 600, which are previously welded, are installed on the surface of the concrete structure, and the fixing nut 210 is completely fastened to fix the clamping clamp. 300 is a process of pressing and fixing the upper surface of the lower steel plate (100).

Since the fixing clamp 300 is provided with the anchor hole 310, the fixed clamp 300 is moved along the anchor hole 310 in the forward and backward directions to adjust the position to absorb the tolerances generated during the drilling of the anchor hole. can do.

(5) Step 5

Filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin.

This process is the same as the fifth step of the first embodiment, and thus duplicated description thereof will be omitted.

(6) Step 6

The lower steel plate 100, the load transfer plate 400, the upper steel plate 500 and the vertical reinforcing plate 600 is a process of reinforcing the reinforcement (800) surrounding.

The reinforcement 800 is to reinforce the hoop and cast iron in accordance with the design book to surround the lower steel plate 100, the load transfer plate 400, the upper steel plate 500 and the vertical reinforcement plate 600.

(7) Step 7

After installing the formwork (not shown) to surround the reinforced reinforcement (800) is a process of pouring mortar (900). This process is the same as the general concrete placing process, so a detailed description thereof will be omitted.

(8) Step 8

Mortar (900) After curing the process of removing the formwork.

<Fourth Embodiment>

The fourth embodiment relates to the construction method of the seismic reinforcing structure shown in Fig. 6A.

(1) Step 1

Drilling the anchor hole to a certain depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10).

A process of drilling an anchor hole to a predetermined depth by using a drill in the outer region of the lower steel plate 100 along the reinforcement portion of the concrete structure 10. In other words, considering the size of the lower steel plate 100 to be used is perforated along the outer area spaced a certain distance from the end of the lower steel plate 100 is sufficient, and the lower steel plate 100 is attached to the surface of the concrete structure 10 It is not necessary to carry out a drilling operation at.

The anchor hole is drilled to a depth sufficient to insert and anchor the anchor bolt 200, and the number and spacing of the anchor hole is appropriately determined in consideration of the site conditions of the reinforced concrete structure.

(2) Step 2

The epoxy bolt is injected into the anchor hole and the anchor bolt 200 is inserted and installed at the same time.

(3) Step 3

The fixing clamp 300 is inserted into the anchor bolt 200 fixed to the surface of the concrete structure 10, and the fixing nut 210 is temporarily fastened.

(4) Step 4

The lower steel plate 100, the load transfer plate 400, the upper steel plate 500, and the vertical reinforcing plate 600, which are previously welded, are installed on the surface of the concrete structure 10, and the fixing nut 210 is completely fastened. The fixing clamp 300 is a process of pressing and fixing the upper surface of the lower steel plate (100).

Since the fixing clamp 300 is provided with the anchor hole 310, the fixed clamp 300 is moved along the anchor hole 310 in the forward and backward directions to adjust the position to absorb the tolerances generated during the drilling of the anchor hole. can do.

(5) Step 5

Filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin. Through such a process, the gap between the lower steel plate 100 and the concrete structure 10 is filled, and the bonding force between the lower steel plate 100 and the concrete structure 10 is enhanced.

(6) Step 6

After installing the formwork (not shown) to surround the vertical reinforcing plate 600 is a process of pouring mortar (900).

This process is the same as the general concrete placing process, so a detailed description thereof will be omitted.

(7) Step 7

Mortar (900) After curing the process of removing the formwork.

As such, when the mortar 900 is cured, the seismic reinforcing structure can be prevented from being collapsed by being integrated with the existing concrete structure to significantly improve the seismic performance when an earthquake occurs.

In addition, by using the exposed upper surface of the vertical reinforcing plate 600 and the upper surface of the upper steel plate 500, it is possible to easily install a steel structure, such as earthquake-resistant brace or seismic damper.

<Fifth Embodiment>

The fifth embodiment is a construction method related to the seismic reinforcing structure shown in Fig. 6B.

(1) Step 1

Drilling the anchor hole to a certain depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10).

This process is the same as the first step of the fourth embodiment, and thus duplicated description thereof will be omitted.

(2) Step 2

The epoxy bolt is injected into the anchor hole and the anchor bolt 200 is inserted and installed at the same time.

This process is the same as the second step of the fourth embodiment, and overlapping description thereof will be omitted.

(3) Step 3

The fixing clamp 300 is inserted into the anchor bolt 200 and the fixing nut 210 is temporarily fastened.

(4) Step 4

The lower welded steel plate 100 and the first transfer plate 410 pre-welded are installed on the surface of the concrete structure, and the fixing clamp 300 is completely fastened by fastening the fixing nut 210 to the upper surface of the lower steel plate 100. It is the process of crimping and fixing.

Since the fixing clamp 300 is provided with the anchor hole 310, the fixed clamp 300 is moved along the anchor hole 310 in the forward and backward directions to adjust the position to absorb the tolerances generated during the drilling of the anchor hole. can do.

(5) Step 5

Pre-welded second transfer plate 420, the upper steel plate 500 and the vertical reinforcing plate 600 is disposed on the upper portion of the lower steel plate 100 and the first transfer plate 410 and the second transfer plate 420 In this overlapping state, the coupling bolt 430 passing through the horizontal long hole 440 and the vertical long hole 450 is fastened to combine the first transfer plate 410 and the second transfer plate 420 into one.

The first transfer plate 410 and the second transfer plate 420 have horizontal holes 440 and vertical holes 450, respectively, so that the first transfer plate 410 and the lower steel plate 100 are formed on the surface of the concrete structure. In the state fixed to the upper plate 500 is integrally coupled to the second transfer plate 420 is moved up and down, left and right within a predetermined range to the final coupling position of the second transfer plate 420 and the upper steel plate 500 I can regulate it.

(6) Step 6

Filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin.

This process is the same as the fifth step of the fourth embodiment, and thus duplicated description is omitted.

(7) Step 7

After installing the formwork (not shown) to surround the vertical reinforcing plate 600 is a process of pouring mortar (900).

This process is the same as the general concrete placing process, so a detailed description thereof will be omitted.

(8) Step 8

Mortar (900) After curing the process of removing the formwork.

As such, when the mortar 900 is cured, the seismic reinforcing structure can be prevented from being collapsed by being integrated with the existing concrete structure to significantly improve the seismic performance when an earthquake occurs.

In addition, by using the exposed upper surface of the vertical reinforcing plate 600 and the upper surface of the upper steel plate 500, it is possible to easily install a steel structure, such as earthquake-resistant brace or seismic damper.

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 notifications are made within the scope of not changing the technical gist 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.

100: lower steel sheet
200: anchor bolt
210: fixing nut
300: fixed clamp
310: anchor anchor
400: load carrier
410: first delivery board
420: second delivery board
430: coupling bolt
440: horizontal worker
450: Vertical Worker
460: mortar passing
470: reinforcement plate
480: incision
500: upper steel sheet
600: vertical reinforcement plate
800: Rebar
900: mortar

Claims (12)

Regarding the seismic reinforcement structure to be constructed in the concrete structure,
A lower steel plate 100 having a long plate shape extending in one direction to be installed along a surface of an existing concrete structure;
A plurality of anchor bolts 200 installed in the anchor hole perforated in the outer region of the lower steel plate 100 along the surface of the existing concrete structure;
The fixing clamp 300 having a rod shape fixed to the surface of the concrete structure by pressing the lower steel plate 100 by a fixing nut 210 inserted into the anchor bolt 200 and fastened to the anchor bolt 200. ;
An elongated plate-shaped load transfer plate 400 which is welded in the longitudinal direction along the center of the upper surface of the lower steel plate 100 so as to be perpendicular to the lower steel plate 100, protruding upward from the lower steel plate 100; And
An upper steel plate 500 welded to an upper end of the load transfer plate 400 and arranged in parallel with the lower steel plate 100;
The anchor clamp 310 through which the anchor bolt 200 passes through the fixed clamp 300 is cut in the longitudinal direction of the fixed clamp 300, the position of the fixed clamp 300 Sectional expansion seismic reinforcement structure using a clamp, characterized in that to adjust the. In claim 1,
The load transfer plate 400,
A first transfer plate 410 welded along the center of the upper surface of the lower steel plate 100 in the longitudinal direction;
A second transfer plate 420 welded along the center of the lower surface of the upper steel plate 500 in the longitudinal direction; And
A plurality of coupling bolts 430 fastened through the first transfer plate 410 and the second transfer plate 420 in a state where the first transfer plate 410 and the second transfer plate 420 overlap. ;
Consist of
One of the first transfer plate 410 and the second transfer plate 420 is provided with a horizontal long hole 440 long cut in the horizontal direction to pass through the coupling bolt 430 at regular intervals, the other one The expansion bolt seismic reinforcement structure using a clamp, characterized in that the coupling bolt 430 is provided with a vertical long hole 450 long cut in the vertical direction to pass through at regular intervals. 3. The method according to claim 1 or 2,
A pair of vertical reinforcing plates 600 welded to the left and right end surfaces of the upper steel plate 500 to form a 'H' cross-section, and arranged in the longitudinal direction of the upper steel plate 500;
Sectional expansion seismic reinforcement structure using a clamp characterized in that it further comprises. 4. The method of claim 3,
Synthetic resin layer (not shown) to fill the space between the lower steel plate 100 and the surface of the existing concrete structure;
Reinforcement (800) which is reinforced to surround the lower steel plate 100, the load transfer plate 400, the upper steel plate 500 and the vertical reinforcing plate 600; And
A mortar 900 that is cured to surround the reinforcement 800 and is integrally coupled to the surface of the existing concrete structure;
Sectional expansion seismic reinforcement structure using a clamp characterized in that it further comprises. In claim 1,
The load transfer plate 400 includes a plurality of mortar through holes 460 penetrated at predetermined intervals;
Sectional expansion seismic reinforcement structure using a clamp, characterized in that formed. In claim 1,
The vertical cross section is welded to the load transfer plate 400 and the horizontal cross section is welded to the lower steel plate 100 and the reinforcement plate 470 arranged at predetermined intervals along the left and right sides of the load transfer plate 400. ;
Sectional expansion seismic reinforcement structure using a clamp characterized in that it further comprises. In claim 2,
Sectional expansion seismic reinforcement structure using a clamp, characterized in that the incision 480 is formed in each of the first transfer plate 410 and the second transfer plate 420 at a predetermined interval. As the seismic reinforcement method through the section expansion of the existing concrete structure,
A first step of drilling the anchor hole to a predetermined depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10);
A second step of installing the anchor bolt 200 by inserting the synthetic resin into the anchor hole and at the same time;
Inserting the fixing clamp 300 into the anchor bolt 200 and pre-fastening the fixing nut 210;
The lower steel plate 100, the load transfer plate 400, and the upper steel plate 500, which are welded in advance, are installed on the surface of the concrete structure, and the fixing clamps 300 are completely fastened by fastening the fixing nuts 210 to the lower steel plates. A fourth step of pressing and fixing the upper surface of the 100;
A fifth step of forming a synthetic resin layer (not shown) by filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with synthetic resin;
A sixth step of reinforcing the reinforcement 800 surrounding the lower steel plate 100, the load transfer plate 400, and the upper steel plate 500;
A seventh step of pouring mortar 900 after installing a formwork (not shown) to surround the reinforcement bar 800; And
An eighth step of removing the mold after curing the mortar (900);
Sectional expansion seismic reinforcement method using a clamp, characterized in that consisting of. As the seismic reinforcement method through the section expansion of the existing concrete structure,
A first step of drilling the anchor hole to a predetermined depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10);
A second step of installing the anchor bolt 200 by inserting the synthetic resin into the anchor hole and at the same time;
Inserting the fixing clamp 300 into the anchor bolt 200 and pre-fastening the fixing nut 210;
The lower steel plate 100, the load transfer plate 400, the upper steel plate 500, and the vertical reinforcement plate 600, which are previously welded, are installed on the surface of the concrete structure, and the fixing nut 210 is completely fastened to fix the clamping clamp. A fourth step in which the 300 press-fixes the upper surface of the lower steel plate 100;
A fifth step of forming a synthetic resin layer (not shown) by filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with synthetic resin;
A sixth step of reinforcing the reinforcing bars 800 surrounding the lower steel plate 100, the load transfer plate 400, the upper steel plate 500, and the vertical reinforcement plate 600;
A seventh step of pouring mortar 900 after installing a formwork (not shown) to surround the reinforcement bar 800; And
An eighth step of removing the mold after curing the mortar (900);
Sectional expansion seismic reinforcement method using a clamp, characterized in that consisting of. As the seismic reinforcement method through the section expansion of the existing concrete structure,
A first step of drilling the anchor hole to a predetermined depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10);
A second step of installing the anchor bolt 200 by inserting the synthetic resin into the anchor hole and at the same time;
Inserting the fixing clamp 300 into the anchor bolt 200 and pre-fastening the fixing nut 210;
The lower welded steel plate 100 and the first transfer plate 410 pre-welded are installed on the surface of the concrete structure, and the fixing clamp 300 is completely fastened by fastening the fixing nut 210 to the upper surface of the lower steel plate 100. Pressing and fixing the fourth step;
Pre-welded second transfer plate 420, the upper steel plate 500 and the vertical reinforcing plate 600 is disposed on the upper portion of the lower steel plate 100 and the first transfer plate 410 and the second transfer plate 420 A fifth step of coupling the first transfer plate 410 and the second transfer plate 420 by fastening the coupling bolt 430 passing through the horizontal long hole 440 and the vertical long hole 450 in the overlapped state;
A sixth step of forming a synthetic resin layer (not shown) by filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with synthetic resin;
A seventh step of reinforcing the reinforcing bars 800 surrounding the lower steel plate 100, the first transfer plate 410, the second transfer plate 420, the upper steel plate 500, and the vertical reinforcement plate 600;
An eighth step of placing mortar 900 after installing a formwork (not shown) to surround the reinforcement bar 800; And
A ninth step of removing the formwork after curing the mortar (900);
Sectional expansion seismic reinforcement method using a clamp, characterized in that consisting of. As the seismic reinforcement method through the section expansion of the existing concrete structure,
A first step of drilling the anchor hole to a predetermined depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10);
A second step of inserting and installing the anchor bolt 200 at the same time as injecting epoxy-based synthetic resin into the anchor hole;
Inserting the fixing clamp 300 into the anchor bolt 200 fixed to the surface of the concrete structure 10 and pre-fastening the fixing nut 210;
The lower steel plate 100, the load transfer plate 400, the upper steel plate 500, and the vertical reinforcing plate 600, which are previously welded, are installed on the surface of the concrete structure 10, and the fixing nut 210 is completely fastened. A fourth step in which the fixing clamp 300 press-fixes the upper surface of the lower steel plate 100;
A fifth step of filling the space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin to form a synthetic resin layer (not shown);
A sixth step of pouring mortar 900 after installing a formwork (not shown) to surround the vertical reinforcing plate 600; And
A seventh step of removing the mold after curing the mortar (900);
Sectional expansion seismic reinforcement method using a clamp, characterized in that consisting of. As the seismic reinforcement method through the section expansion of the existing concrete structure,
A first step of drilling the anchor hole to a predetermined depth using a drill along the left and right sides of the reinforcement portion of the concrete structure (10);
A second step of inserting and installing the anchor bolt 200 at the same time as injecting epoxy-based synthetic resin into the anchor hole;
Inserting the fixing clamp 300 into the anchor bolt 200 and pre-fastening the fixing nut 210;
The lower welded steel plate 100 and the first transfer plate 410 pre-welded are installed on the surface of the concrete structure, and the fixing clamp 300 is completely fastened by fastening the fixing nut 210 to the upper surface of the lower steel plate 100. Pressing and fixing the fourth step;
Pre-welded second transfer plate 420, the upper steel plate 500 and the vertical reinforcing plate 600 is disposed on the upper portion of the lower steel plate 100 and the first transfer plate 410 and the second transfer plate 420 A fifth step of coupling the first transfer plate 410 and the second transfer plate 420 by fastening the coupling bolt 430 passing through the horizontal long hole 440 and the vertical long hole 450 in the overlapped state;
A sixth step of filling a space between the lower steel plate 100 and the surface of the concrete structure 10 with an epoxy-based synthetic resin to form a synthetic resin layer (not shown);
A seventh step of pouring the mortar 900 after installing the formwork (not shown) to surround the vertical reinforcing plate 600; And
An eighth step of removing the mold after curing the mortar (900);
Sectional expansion seismic reinforcement method using a clamp, characterized in that consisting of.

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