KR101538074B1 - Pivot Joint Type Aseismatic Device and Method using thereof - Google Patents

Abstract

The present invention has an elongated shape formed toward one side to be installed along the surface of an existing concrete structure. The present invention relates to a seismic reinforcement body having a pivoting joint member and a seismic reinforcement method using the same comprises: a segment reinforcement body (100) composed of a plurality of joint members (110) divided to be rotated and closely attached along a curve of the surface of the concrete structure; and a reinforcement frame (200) installed in the longitudinal direction along an upper portion of the segment reinforcement body (100) and coupled with the segment reinforcement body (100).

Description

TECHNICAL FIELD [0001] The present invention relates to a pivot joint type seismic device and method using the same,

The present invention can easily be installed along the surface curvature of existing concrete structures and easily accommodates the deviations caused by the surface curvature, thereby simplifying the installation process of the anti-earthquake rigid body and improving the work efficiency in the field. In case of earthquake, And to improve the strength and seismic retrofitting method which can minimize the loss of valuable human life and property by inducing the behavior.

The recent earthquakes in neighboring countries are often beyond the imagination, and Korea, which is classified as a medium - and high - intensity region, is not safe from such a natural disaster.

     In addition, more than 80% of the existing construction facilities in the earthquake environment are almost defenseless to earthquakes. Especially, multi-family houses, which are the majority of middle- and low-rise buildings, and school facilities that should be used as evacuation sites for nearby residents, We are just starting to reinforce the earthquake.

     In general, seismic retrofitting of existing construction facilities is performed outdoors except in special cases. This means that the usability of existing buildings is not limited as much as possible.

     1, in the case of the conventional joining structure in which the steel structure for seismic strengthening is integrally joined to the outer surface of the concrete structure 10, the reinforcing plate 20, the load transfer plate 30, the steel frame 40, The mortar 50 is installed on the surface of the concrete structure to increase the cross section. In the case of such a conventional sectional extension reinforcing method, a hole 21 for mounting an anchor bolt is bored in advance on the reinforcing plate 20, and then the reinforced plate 20 is attached to the surface of the concrete structure 10, The hole 11 for mounting the anchor bolt 60 is drilled on the surface of the concrete structure 10 along the pattern of the hole 21 and then the anchor bolt 60 is mounted to fix the reinforcing plate 20 to the concrete structure 10 And fixing it to the surface. After the installation work of the reinforcing plate 20 is completed, it is necessary to perform a work of welding the load transmitting plate 30 integrally joined to the upper part of the reinforcing plate 20, because the reinforcing plate 20 If the load transfer plate 30 and the steel frame 40 are welded to the upper portion of the concrete structure 20, the reinforcing plate 20 can not be used as a template to drill a hole for mounting the anchor bolt 60 on the surface of the concrete structure to be.

It is not impossible to perform the welding work by disposing the load transmission plate 30 on the surface of the concrete structure constituting the vertical wall. However, since the space is narrow, the work is troublesome and time consuming and the risk of safety accidents is high. have.

In addition, when the surface of the concrete structure is severely curved, if the reinforcing plate 20 is forcibly mounted, the reinforcing plate 20 itself has a curvature so that the portion where the interface between the load transmitting plate 30 and the reinforcing plate 20 does not abut There is a problem that welding becomes almost impossible.

Therefore, it is urgent to introduce a new anti-seismic rigid body and seismic reinforcement method that can provide seismic reinforcement more quickly, safely and comfortably.

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

First, it is an object of the present invention to provide an anti-earthquake rigid body and an anti-seismic reinforcement method that can be installed while effectively absorbing surface curvature of a concrete structure.

Secondly, it is another object of the present invention to provide a variable in-progressive rigid body capable of adjusting the length and height to be applied to various fields and smooth vertical and horizontal construction.

Third, it is another object of the present invention to provide a new endurance steel body and an anti-seismic reinforcement method capable of ensuring unified construction and operation with concrete structures.

Fourthly, it is another object of the present invention to provide an anti-seize rigid body and an anti-seismic reinforcement method that can be installed safely, quickly, and conveniently.

Technical features of the present invention are as follows.

[0001] The present invention relates to an endurance-enhanced rigid body which is constructed in a concrete structure and has a shape elongated in one direction so as to be installed along the surface of a conventional concrete structure and is composed of a plurality of segment members 110 rotatably segmented, A segment reinforcing body 100 which is brought into close contact with the surface curvature of the surface; And a reinforcing frame 200 installed longitudinally along the upper portion of the segment reinforcing member 100 and coupled to the segment reinforcing member 100.

In addition, the present invention relates to an anti-seismic reinforcement method applied to a concrete structure, wherein an epoxy resin (not shown) is applied to a surface of a reinforcement portion of a concrete structure or an outer surface of a cage member 110 to be installed, The nodal member 110 of the segment reinforcing member 100 in which the anchor hole 130 is drilled is attached to the surface of the reinforcement portion of the concrete structure and then the anchor bolt mounting hole (not shown) is formed on the surface of the concrete structure along the pattern of the anchor hole 130 (Not shown) is filled in an anchor bolt mounting hole (not shown), and an anchor bolt 310 is installed to fix the nodal member 110 to the surface of the concrete structure. Stage 1; The detachable hinge pin 125 is used to connect the nodal member 110 to be added to the nodal member 110 installed in the first step and attached to the surface of the concrete structure, An anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor bolt 130, an epoxy resin (not shown) is filled into the perforated anchor bolt mounting hole (not shown) A second step of sequentially fixing the nodal member 110 to the surface of the concrete structure; A third step of installing a reinforcing frame 200 in the longitudinal direction along the upper part of the segment reinforcing member 100 in which the nodal member 110 is fixedly fixed in the second step and welding the segment reinforcing member 100; And a fourth step of placing the mortar 330 in an internal space surrounded by the reinforcing frame 200 and the segment reinforcing member 100 and curing the same.

In addition, the present invention relates to an anti-seismic reinforcement method applied to a concrete structure, wherein an epoxy resin (not shown) is applied to a surface of a reinforcement portion of a concrete structure or an outer surface of a cage member 110 to be installed, The nodal member 110 of the segment reinforcing member 100 in which the anchor hole 130 is drilled is attached to the surface of the reinforcement portion of the concrete structure and then the anchor bolt mounting hole (not shown) is formed on the surface of the concrete structure along the pattern of the anchor hole 130 (Not shown) is filled in an anchor bolt mounting hole (not shown), and an anchor bolt 310 is installed to fix the nodal member 110 to the surface of the concrete structure. Stage 1; The detachable hinge pin 125 is used to connect the nodal member 110 to be added to the nodal member 110 installed in the first step and attached to the surface of the concrete structure, An anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor bolt 130, an epoxy resin (not shown) is filled into the perforated anchor bolt mounting hole (not shown) A second step of sequentially fixing the nodal member 110 to the surface of the concrete structure; A third step of installing a reinforcing frame 200 in the longitudinal direction along the upper part of the segment reinforcing member 100 in which the nodal member 110 is fixedly fixed in the second step and welding the segment reinforcing member 100; A fourth step of arranging the reinforcing frame (320) so as to surround the reinforcing frame (200); A fifth step of installing a mortar (330) after installing a mold (not shown) so as to surround reinforced reinforcing bars (320); And a sixth step of removing the mold after the cured mortar 330 is cured.

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

First, it can be installed while effectively absorbing the surface curvature of the concrete structure.

In other words, the segment reinforcing member 100 is not a fixed frame, but a plurality of divided segment members 110 are connected to form one segment reinforcing member 100, and each of the segment members 110 The gap between the surface of the concrete structure and the segment reinforcing member 100 can be minimized and the segment reinforcing member 100 can be attached to the concrete structure So that it can be more firmly fixed to the surface of the substrate.

Second, it provides a variable in-progressive rigid body capable of adjusting the length and height, so that it can be applied to various fields, and vertical and horizontal construction can be easily performed.

In other words, the hinge 120, which is rotatably connected to the inner side surface or the outer side surface of the web 11 of the segment member 110 constituting the segment reinforcing member 100 so as to be rotatable by the separable hinge pin 125, The separable hinge pin 125 may be removed as necessary to separate the nodal member 110 from the nodal member 110. In this case, Can be separated. That is, the total length of the segment reinforcing member 100 can be easily adjusted by a method of adding or separating the nodal members 110 as needed. Since the surface of the concrete structure is bent, The vertical and horizontal construction can be performed regardless of the surface curvature of the concrete structure by using the height adjusting rods 210 and the height adjusting nuts 215 mounted on the reinforcing frame 200 even if the state has a bend.

Third, integrated behavior with concrete structures can be guaranteed.

In other words, even if there is a curvature on the surface of the concrete structure, the segment reinforcing member 100 is closely contacted along the curvature to minimize the gap between the surface of the concrete structure and the segment reinforcing member 100, (100) can be more firmly fixed to the surface of the concrete structure. When the segment reinforcing member 100 is vertically installed along the column surface of the concrete structure, the microfailure hole 345 is provided at a lower end surface of the reinforcing frame 200, and a plurality of J anchors 350 are provided. And a micro pile 360 penetrates through the foundation of the concrete structure to be connected to the pillar of the concrete structure so as to reach the ground and the micro pile 360 is mounted on the lower steel plate 340, The reinforcing frame 200 is installed so as to pass through the microfilm passage hole 345 of the microfilm passage 340 and the microfiber coupling nut 365 is fastened to the upper end of the microfilm 360 passing through the microfilm passage hole 345 Thereby ensuring the integral behavior of the foundations of the concrete structure and the ground and the progressive rigid body.

Fourth, my progressive body can be installed safely, quickly and conveniently.

Fig. 1 shows a concrete embodiment of a conventional anti-seismic steel structure.
2 is a perspective view showing a specific embodiment of the reinforcement frame 100 and the reinforcement frame 200. As shown in Fig.
3 is a perspective view showing another specific embodiment of the reinforcement frame 100 and the reinforcing frame 200. As shown in Fig.
4 shows a structure in which the reinforcing frame 200 is mounted on the segment reinforcing member 100 by the fixing bar 220. FIG.
Fig. 5 shows a side structure of a specific embodiment of the reinforcement frame 100 and the reinforcement frame 200. Fig.
6 shows a sectional structure according to an anti-seismic reinforcement method using an anti-earthquake rigid body.
FIG. 7 shows a coupling structure with a foundation of a concrete structure and a micro pile 360 mounted on the ground, when an advanced steel body is installed in a vertical direction along a column surface of the concrete structure.
8 shows a cross section of a concrete embodiment in which the mortar 330 is laid only in the inner space surrounded by the reinforcement frame 100 and the reinforcing frame 200. Fig.

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.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an endurance strengthened body to be applied to a concrete structure.

As shown in FIG. 2 or 3, the segment reinforcing member 100 is elongated in one direction so as to be installed along the surface of the existing concrete structure. The segment reinforcing member 100 is composed of a plurality of pivotal segment members 110 And adheres along the surface curvature of the concrete structure.

That is, not a single fixed frame but a plurality of divided segment members 110 are connected to form one segment reinforcing member 100, and each of the segment members 110 is rotatable so that the surface of the concrete structure The gap between the surface of the concrete structure and the segment reinforcing member 100 can be minimized and the segment reinforcing member 100 can be more firmly fixed to the surface of the concrete structure have.

Although only the case where each of the nodal members 110 constituting the segment reinforcing member 100 is made of a "c" shaped steel member is shown in the attached drawings, the present invention is not limited to the "c" shaped steel member, This is possible.

Each of the nodal members 110 constituting the segment reinforcing member 100 can be pivoted. When the nodal member 110 is manufactured by using the "c" shaped steel member, And a hinge 120 rotatably connected to each of the side ends of the side surface by detachable hinge pins 125, respectively. That is, a plurality of segment members 110 may be connected as needed to form the segmented reinforcing member 100. In the case of the segmented reinforcing member 100, So that the nodal member 110 can be separated.

In other words, the total length of the segment reinforcing member 100 can be easily adjusted by a method of adding or separating the cage members 110 as needed.

When the nodal member 110 is made of a "c" shaped steel member, the flanges 22 on both sides of the nodal member 110 can have various shapes such as a rectangle, a trapezoid, or a triangle, Thereby securing a certain range of rotation angle.

The coupling structure of the detachable hinge pin 125 and the hinge 120 is not only used as a component for connecting the neighboring cage member 110 but may be used as a connecting member between the web 11 of the cage member 110 and the flange 22 The hinge 120 may be provided on the inner side or the outer side of the web 11 so that the flange 22 can be formed so as to be perpendicular to the web 11 or to be horizontal.

When the web 11 and the flange 22 are configured to be rotatable, the reinforcing frame 200 can be inserted into the segmented reinforcing member 100 from the side with the flange 22 extended. .

A hooking groove 115 is formed on an outer end surface of each of the first flange member 22 and the second flange member 22 of each of the first and second member members 110 and 110 of the segment reinforcing member 100, 200). That is, the reinforcing frame 200 may be temporarily installed by inserting the segment reinforcing member 100 on the surface of the concrete structure and then inserting the stationary bar 220 of the reinforcing frame 200 into the hooking slot 115. It is preferable that a plurality of the hooking grooves 115 are provided at regular intervals so as to be able to adjust the joining position of the fixing bar 220.

The reinforcing frame 200 is installed longitudinally along the upper portion of the segment reinforcing member 100 as shown in FIG. 2 or 3, and is integrated with the segment reinforcing member 100. The cross-sectional structure of the reinforcing frame 200 is not limited to a special shape, but in the concrete embodiment of the present invention, an "H" shaped steel member is used as shown in Fig.

The joining of the reinforcing frame 200 and the segment reinforcing member 100 is generally performed by welding in the field, but is not limited to welding, and pin or bolt joining may be performed according to the site conditions.

The stiffening frame 200 may be provided at one side of the reinforcing frame 200 so as to cross the end of the reinforcing frame 200. The reinforcing frame 200 may be formed to have an & A part of the web 33 is cut and both ends of the fixing bar 220 are coupled to penetrate the center of the flange 44 so as to cross the area where the web 33 is cut.

The mounting bar 220 may be completely fixed to the reinforcing frame 200, but may be a pin structure that can be inserted or removed from the reinforcing frame 200 as required.

4, the reinforcing frame 200 may be mounted on or suspended from the segment reinforcing member 100. For example, the reinforcing frame 200 may be mounted on the segment reinforcing member 100, The reinforcing frame 200 is vertically installed by inserting the stationary bar 220 into the hooking groove 115 provided at the upper end of the segment reinforcing body 100 after being vertically installed along the surface of the concrete structure . When the reinforcing frame 200 and the segment reinforcing member 100 are welded in a state where the reinforcing frame 200 is temporarily mounted, the reinforcing frame 200 can be installed more conveniently and safely.

When the segment reinforcing member 100 is installed horizontally along the surface of the concrete structure, the height adjusting rod 210 and the height adjusting nut 215 provided on the reinforcing frame 200 overlapping the segment reinforcing member 100 It is possible to stably install the reinforcing frame 200 by aligning the reinforcing frame 200 in a horizontal direction. When the reinforcing frame 200 and the reinforcing frame 100 are welded in this state, the reinforcing frame 200 can be more conveniently and safely installed.

5, a plurality of height adjusting rods 210 are fastened to the reinforcing frame 200 so as to penetrate the surface of the reinforcing frame 200. The lower end of the height adjusting rods 210 is brought into contact with the surface of the segment reinforcing member 100 .

That is, when the reinforcing frame 200 is an "H" shaped steel member, the height adjusting rods 210 pass through the web 33 or the flange 44 of the reinforcing frame 200 and the web 33 or the flange 44 The height adjustment rods 215 are coupled to the height adjustment rods 210 in the upper and lower portions of the body 210. The height adjustment rods 210 are adjusted in height by using the height adjustment rods 215, The distance between the reinforcing frame 200 and the segment reinforcing member 100 can be varied and the reinforcing frame 200 can be adjusted to be vertically or horizontally placed.

In other words, even if the nodal member 110 constituting the segment reinforcing member 100 is bent according to the surface curvature of the concrete structure, if the height of the height adjusting nut 215 is appropriately adjusted, You can set it to be exactly vertical or horizontal.

Hereinafter, an earthquake-proof reinforcement method for constructing a concrete structure using the above-described reinforcement steel body will be described with reference to FIGS. 6 and 7. FIG.

(1) Step 1

An epoxy resin (not shown) is applied to the surface of the reinforcement portion of the concrete structure or the outer surface of the nodal member 110 to be installed and a plurality of anchor holes 130 are formed at predetermined intervals, After the member 110 is attached to the surface of the reinforcement portion of the concrete structure, an anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor hole 130, and an anchor bolt mounting hole (Not shown) and an anchor bolt 310 is installed to fix the nodal member 110 to the surface of the concrete structure.

(2) Step 2

The detachable hinge pin 125 is used to connect the nodal member 110 to be added to the nodal member 110 installed in the first step and attached to the surface of the concrete structure, An anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor bolt 130, an epoxy resin (not shown) is filled into the perforated anchor bolt mounting hole (not shown) And the nodal member 110 is closely contacted and fixed to the surface of the concrete structure. This process is repeated until the segment reinforcing member 100 reaches a pre-designed length, and before the additional member 110 is attached to the surface of the concrete structure, the surface of the concrete structure to which the member 110 is attached Or an epoxy resin (not shown) should be applied to the outer surface of the cage member 110 to be added.

(3) Step 3

In the second step, a reinforcement frame 200 is installed in the longitudinal direction along the upper part of the segment reinforcing member 100 closely fixed to the segment reinforcing member 100.

In this third step, the height of the height adjusting rods 210 fastened to the reinforcing frame 200 is adjusted so that the distance between each of the barrel members 110 constituting the segment reinforcing member 100 and the reinforcing frame 200 A process of absorbing the deviation may be included.

In addition, when the segment reinforcing member 100 is installed along the column surface of the concrete structure in the vertical direction, the hook reinforcement member 100 may be provided at the upper end of the reinforcing frame 200, And temporarily hanging the mounting bar 220 to mount it.

When the segment reinforcing member 100 is vertically installed along the column surface of the concrete structure, the microfailure hole 345 is provided at a lower end surface of the reinforcing frame 200, and a plurality of J anchors 350 are provided. A step of welding the lower steel plate 340 protruding downward to the bottom of the concrete structure connected to the column of the concrete structure, and a step of mounting the micro pile 360 on the foundation of the concrete structure connected to the pillar of the concrete structure, A process of installing the reinforcing frame 200 so as to pass through the microfilm passage hole 345 of the steel plate 340 and a process of installing the reinforcing frame 200 at the upper end of the microfilm 360 passing through the microfilm passing hole 345, ) May be further included.

In the case where a plurality of hooking grooves 115 are provided, the hooking grooves 115 at appropriate positions may be selected and used in consideration of the site conditions.

(4) Step 4

And reinforcing bars 320 are arranged to surround the reinforcing frame 200 and the segment reinforcing member 100. The reinforcement process is performed by arranging the hoop roots and the cast iron rods in accordance with the design book so as to surround the whole reinforcement frame 100 and the reinforcement frame 200.

In addition, when the segment reinforcing member 100 is installed in a vertical direction along the column surface of the concrete structure, the micro piles 360 positioned between the lower steel plate 340 and the foundation of the concrete structure and the periphery of the J- The reinforcing bars 320 may be disposed so as to surround the reinforcing bars 320.

(5) Step 5

(Not shown) is installed so as to surround the reinforced bar 320 and then the mortar 330 is laid.

(6) Step 6

Putty mortar (330) This is the process of removing the mold after curing. When mortar (330) is cured through such a process, it can be integrated with existing concrete structure to improve seismic performance in case of earthquake, and it is possible to prevent collapse of seismic reinforced structure separated from existing concrete.

In another embodiment of the construction method according to the present invention, as shown in FIG. 8, the construction may be performed. In this case, after the first, second, and third steps, 100 and the reinforcing frame 200, the curing is performed by placing the mortar 330 in the inner space. In this case, the clearance between the segment reinforcing member 100 and the reinforcing frame 200 is sealed before the mortar 330 is installed to prevent the mortar 330 from being leaked to the outside. In the case of installing the mortar 330 only in the internal space surrounded by the reinforcing frame 200 and the segment reinforcing member 100, the microfiles 360 may be installed on the foundation and the ground of the concrete structure The microfibers 360 and J anchors 350 positioned between the lower steel plate 340 and the foundation of the concrete structure are welded to each other at the lower end of the reinforcing frame 200. In this case, A process of disposing the reinforcing bars 320 so as to surround the reinforcing bars 320, and a process of installing a mold to surround the reinforced reinforcing bars and pouring the mortar.

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

11, 33: web
22, 44: flange
100:
110: member absence
115: hook groove
120: HINGE
125: Detachable hinge pin
130: anchor hole
200: reinforced frame
210: height adjustment rod
215: height adjustment nut
220: Mounting rod
310: anchor bolt
320: Rebar
330: Mortar
340: Lower steel plate
345: Micro file through hole
350: J (J) anchor
360: Micro file
365: Micro-file fastening nut

Claims (13)

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an advanced steel body applied to a concrete structure,
A segment reinforcing member 100 formed of a plurality of segment members 110 rotatably segmented and extending in one direction so as to be installed along the surface of the existing concrete structure and closely contacting with the surface curvature of the concrete structure; And
A reinforcing frame 200 installed longitudinally along the upper part of the segment reinforcing body 100 and coupled with the segment reinforcing body 100;
And,
Each of the nodal members 110 constituting the segment reinforcing member 100 is made of a "c" shaped steel member and the first nodal member 110 or the last nodal member 110 constituting the segmental reinforcing member 100, Hooking groove portions 115 are formed on the outer end surfaces of the respective side flanges 22,
Wherein a fixing bar 220 accommodated in the hooking groove 115 is provided at one end or both ends of the reinforcing frame 200 so as to cross an end of the reinforcing frame 200. [ And an inner elastic member. BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an advanced steel body applied to a concrete structure,
A segment reinforcing member 100 formed of a plurality of segment members 110 rotatably segmented and extending in one direction so as to be installed along the surface of the existing concrete structure and closely contacting with the surface curvature of the concrete structure; And
A reinforcing frame 200 installed longitudinally along the upper part of the segment reinforcing body 100 and coupled with the segment reinforcing body 100;
And,
The segment reinforcing member (100)
And a hinge (120) rotatably connected by a detachable hinge pin (125) is provided at both side ends of an inner side surface or an outer side surface of the web (11). BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an advanced steel body applied to a concrete structure,
A segment reinforcing member 100 formed of a plurality of segment members 110 rotatably segmented and extending in one direction so as to be installed along the surface of the existing concrete structure and closely contacting with the surface curvature of the concrete structure; And
A reinforcing frame 200 installed longitudinally along the upper part of the segment reinforcing body 100 and coupled with the segment reinforcing body 100;
And,
The reinforcing frame (200)
Wherein a plurality of height adjusting rods (210) are coupled through the surface of the height adjusting rods (210), and a lower end portion of the height adjusting rods (210) abuts against the surface of the segment reinforcing member (100) . BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an advanced steel body applied to a concrete structure,
A segment reinforcing member 100 formed of a plurality of segment members 110 rotatably segmented and extending in one direction so as to be installed along the surface of the existing concrete structure and closely contacting with the surface curvature of the concrete structure; And
A reinforcing frame 200 installed longitudinally along the upper part of the segment reinforcing body 100 and coupled with the segment reinforcing body 100;
And,
Each of the node members (110) constituting the segment reinforcing member (100)
A hinge 120 pivotally connected by a detachable hinge pin 125 is provided along the interface between the web 11 and the flange 22 so that the flange 22 is erected to be perpendicular to the web 11, Wherein the inner member is provided with a pivoting member. The method of claim 1,
Wherein the fixing rod (220) is detachably attached to the reinforcing frame (200). 4. The method of claim 3,
The reinforcing frame 200 is an "H"
The height adjusting rods 210 penetrate the web 33 or the flange 44 of the reinforcing frame 200 and are fastened to the height adjusting rods 210 on the upper surface and the lower surface of the web 33 or the flange 44, Wherein a height of the height adjusting rod (210) is adjusted by a height adjusting nut (215). 5. The method of claim 4,
The nodal element (110) of the segment reinforcing member (100)
Wherein the flanges (22) are rectangular, trapezoidal, or triangular in shape, and interference is prevented to a certain angle range during the inner rotation. The present invention relates to a seismic retrofitting method applied to a concrete structure,
An epoxy resin (not shown) is applied to the surface of the reinforcement portion of the concrete structure or the outer surface of the nodal member 110 to be installed and a plurality of anchor holes 130 are formed at predetermined intervals, After the member 110 is attached to the surface of the reinforcement portion of the concrete structure, an anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor hole 130, and an anchor bolt mounting hole A first step of filling an epoxy resin (not shown) inside an anchor bolt 310 and fixing an anchor bolt 310 to the surface of a concrete structure;
The detachable hinge pin 125 is used to connect the nodal member 110 to be added to the nodal member 110 installed in the first step and attached to the surface of the concrete structure, An anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor bolt 130, an epoxy resin (not shown) is filled into the perforated anchor bolt mounting hole (not shown) A second step of sequentially fixing the nodal member 110 to the surface of the concrete structure;
A third step of installing a reinforcing frame 200 in the longitudinal direction along the upper part of the segment reinforcing member 100 in which the nodal member 110 is fixedly fixed in the second step and welding the segment reinforcing member 100;
A fourth step of arranging the reinforcing frame (320) so as to surround the reinforcing frame (200);
A fifth step of installing a mortar (330) after installing a mold (not shown) so as to surround reinforced reinforcing bars (320); And
A sixth step of removing the mold after the cured mortar 330 is cured;
And an anti-seismic reinforcement method using an anti-shear rigid body having a pivoting nod member. 9. The method according to claim 8, wherein, in the third step,
When the segment reinforcing member 100 is installed along the column surface of the concrete structure in a vertical direction, the hook reinforcement member 100 may be provided in the hook groove portion 115 provided at the upper end of the segment reinforcing member 100, The method of claim 1, further comprising the step of temporarily suspending the suspension rod (220) to suspend the suspension rod (220). 9. The method according to claim 8, wherein, in the third step,
It is possible to adjust the clamping height of the height adjusting rods 210 fastened to the reinforcing frame 200 to absorb the difference in distance between the reinforcing frame 200 and each of the barrel members 110 constituting the segment reinforcing member 100 Wherein the method comprises the steps of: (a) The method of claim 9,
In the third step,
A lower steel plate 340 having a microfill passage hole 345 and a plurality of J anchors 350 protruding downward is welded to an end surface of a lower end of the reinforcing frame 200 and welded to a column of a concrete structure The reinforcing frame 200 is installed so that the micro pile 360 passes through the base of the concrete structure to reach the ground and the micro pile 360 passes through the micro pile hole 345 of the lower steel plate 340 And fastening the micropile lock nut 365 to the upper end of the micropile 360 passing through the micropile passing hole 345,
In the fourth step,
Further comprising a step of disposing a reinforcing bar (320) so as to surround the micro pile (360) positioned between the lower steel plate (340) and the foundation of the concrete structure and the J anchor (350) Seismic Retrofit Method Using Inner Progressive Rigid Body with Nodal Members. The present invention relates to a seismic retrofitting method applied to a concrete structure,
An epoxy resin (not shown) is applied to the surface of the reinforcement portion of the concrete structure or the outer surface of the nodal member 110 to be installed and a plurality of anchor holes 130 are formed at predetermined intervals, After the member 110 is attached to the surface of the reinforcement portion of the concrete structure, an anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor hole 130, and an anchor bolt mounting hole A first step of filling an epoxy resin (not shown) inside an anchor bolt 310 and fixing an anchor bolt 310 to the surface of a concrete structure;
The detachable hinge pin 125 is used to connect the nodal member 110 to be added to the nodal member 110 installed in the first step and attached to the surface of the concrete structure, An anchor bolt mounting hole (not shown) is drilled on the surface of the concrete structure along the pattern of the anchor bolt 130, an epoxy resin (not shown) is filled into the perforated anchor bolt mounting hole (not shown) A second step of sequentially fixing the nodal member 110 to the surface of the concrete structure;
A third step of installing a reinforcing frame 200 in the longitudinal direction along the upper part of the segment reinforcing member 100 in which the nodal member 110 is fixedly fixed in the second step and welding the segment reinforcing member 100;
A fourth step of placing mortar (330) in an internal space surrounded by the reinforcing frame (200) and cushioning reinforcement (100) to cure;
And an anti-seismic reinforcement method using an anti-shear rigid body having a pivoting nod member. delete

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