KR102440309B1 - Seismic retrofit frame structure - Google Patents

Abstract

The present invention relates to a seismic reinforcement frame structure with reinforced flexibility and a construction method thereof, capable of excellently improving seismic performance. The seismic reinforcement frame structure of the prevent invention, comprises: an upper wall (200); a lower wall (202) installed below the upper wall (200); a left masonry wall (204) having a tensile reinforcing structure (105); and a right wall (206) having a tensile reinforcing main rebar structure (105).

Description

Seismic reinforcing frame structure with reinforced flexibility and its construction method {Seismic retrofit frame structure }

The present invention relates to a frame structure for earthquake-resistant reinforcement with reinforced flexibility and a construction method therefor, and more particularly, to a reinforcement frame installed on the inner surface of upper, lower, left, and right walls by mixing an epoxy or urethane-based bonding material with a reinforcing fiber material. By attaching and installing structural reinforcement materials with strong tensile strength and polygonal frame, round frame and square frame, the safety of the reinforcement frame in the form of a polygonal frame, a round frame and a square frame is secured and the flexibility is reinforced to improve the seismic performance. it's about

In recent years, as the frequency of earthquakes increases and the intensity of earthquakes also increases, the demand for seismic reinforcement for existing reinforced concrete structures is increasing.

All buildings should be built by seismic design in preparation for seismic resistance, and since seismic design regulations were not applied to existing buildings, there was a need to have a structure for seismic reinforcement of the building.

In the case of the Ramen group consisting of columns and beams among the conventional building structures, H-beam steel frames are installed inside the column-beam frames to secure seismic performance and maintain the maximum open area of the opening at the same time to increase the rigidity and ductility of the structure. technology was used.

These prior arts were installed by fixing the outer flange of the H-beam member to the inner surface of the existing member using an anchor bolt to fix the H-beam steel frame to the existing member.

However, this method has the disadvantage that the anchor bolt is missing or is not properly fixed due to interference with the flange during anchor hole drilling or anchor bolt installation work. .

In addition, the existing reinforced concrete frame may have different member sizes due to construction errors, etc. For frame reinforcement, the steel frame member manufactured at the factory and brought into the site is different in size from the existing member, so the steel frame member is cut and cut at the site. Therefore, the cumbersome use and complexity of the construction work were raised.

In order to solve these difficulties in construction, seismic reinforcement technology that can facilitate anchor bolt construction has been disclosed by using T-beams other than H-beams to secure the web with bolts.

However, in the case of fastening the web of such T-beams with bolts, there is a problem in that concentrated stress is generated at the bolt fastening portion and is damaged when an earthquake occurs.

In addition, most reinforcing bodies, reinforcing frames, or structures have a polygonal shape, such as a rectangle, a rectangular shape, a channel shape, and a circular bar shape, so that only the rigidity of the structure itself is maintained, but there is a problem that separate rigidity cannot be provided.

Korean Patent Registration No. 10-1185974 (Registered on September 19, 2012) Korean Patent Registration No. 10-1459082 (Registered on October 31, 2014)

The present invention has been devised to solve the above problems, and has excellent flexibility and excellent rigidity on the outer surface of circular frames, round bars, channel-shaped, square-shaped structures of existing building structures such as schools and buildings. Seismic reinforcement frame structure with reinforced flexibility to protect the reinforcement frame from external shocks, vibrations and earthquakes by attaching structural reinforcement materials Its purpose is to provide a construction method.

According to the present invention, by mixing a material having high tensile strength and an epoxy-based and urethane-based material with excellent flexibility to the vertical and horizontal structures constituting the building structure to cover the surface of the structure, the earthquake-resistance performance can be excellently improved. Its purpose is to provide a frame structure for earthquake-resistant reinforcement with reinforced flexibility.

The present invention combines a material having high tensile strength and excellent flexibility in vertical and horizontal structures constituting a building structure to cover the surface of the structure by mixing an epoxy-based and urethane-based material to excellently improve the seismic performance. An object of the present invention is to provide a construction method of a frame structure for earthquake-resistant reinforcement with reinforced flexibility.

And, the present invention is to install a structural reinforcement with continuity without segmentation in the curved or corner parts of structures such as giyeokja, digutja, and H. The purpose of the present invention is to provide a frame structure for earthquake-resistant reinforcement with reinforced flexibility that can enhance tensile strength, shorten the construction period, and reduce cost, and a construction method thereof.

The present invention is not limited to the above purpose and other objects not mentioned may be provided within a range that can be clearly understood by those of ordinary skill in the art to which the present invention belongs.

In the present invention, a reinforcing frame having a plurality of structures is reinforced on the inner side of an earthquake-resistant reinforcement frame consisting of an upper wall, a lower wall, a left wall, and a right wall, so as to alleviate shock and vibration when an earthquake occurs. In the frame structure,

an upper wall 200 having a tensile reinforcement main reinforcing bar structure 105 installed in the transverse direction and installed in the transverse direction on the lower surface;

a lower wall 202 installed in a lower portion of the upper wall 200 and spaced apart from each other by a predetermined distance and installed in parallel;

a left masonry wall 204 installed on the left side of the upper wall 200 and the lower wall 202 and having a tensile reinforcement structure 105 installed on one inner surface in the longitudinal direction;

It includes a right side wall 206 provided on the right side of the upper wall 200 and the lower wall 202 and having a tension-reinforced main reinforcing bar structure 105 installed on one inner surface in the longitudinal direction,

Including a tension-reinforced main reinforcing bar structure 104 installed in the longitudinal direction at the inner middle portion of the upper wall 200 and the lower wall 202,

A plurality of tension-reinforced structure reinforcements 106 are attached to each side of the tensile-reinforced main reinforcing bar structure body 104 by spaced apart from each other at regular intervals, and a plurality of tensile-reinforced structure reinforcing materials 106 are attached and constructed,

The left masonry wall 204 and the right side wall 206 are spaced apart from each other at regular intervals on each side of the tension-reinforced main reinforcing bar structure 105, and a plurality of tensile reinforcing structure reinforcements 106 are attached and constructed in the longitudinal direction,

A plurality of tension-reinforced structure reinforcements 106 are attached to each side of the tensile-reinforced main reinforcing bar structure 105 installed in the transverse direction on the lower surface of the upper wall 200 at regular intervals and installed in the transverse direction. It is characterized in that it is formed to reinforce the earthquake resistance by providing a reinforcing frame 102 and being in close contact with the structure body (104, 105) flexibly without being segmented in bent or curved or cornered parts.

The reinforcing frame is

Structures (104, 105) formed in a quadrangular or digut-shaped (c) channel shape and having corners;

It is preferable to provide a plurality of tensile-reinforced structure reinforcing materials 106 attached to one surface of the structures 104 and 105 in the longitudinal direction to strengthen the tensile strength.

The reinforcement frame.

Structures (104, 105) formed in a quadrangular or digut-shaped (c) channel shape and having corners;

Providing a plurality of shear reinforcement structure reinforcing materials 110 attached to and constructed along the periphery of one surface of the structures 104 and 105 to strengthen shear strength

The reinforcement frame.

Structures (104, 105) formed in a quadrangular or digut-shaped (c) channel shape and having corners;

A plurality of tensile-reinforced structure reinforcing materials 106 that are attached and constructed along the longitudinal direction on each one surface of the structures 104 and 105 to strengthen tensile strength are provided,

After the plurality of tensile reinforcing structure reinforcing materials 106 are spaced apart from each other and constructed, the tensile reinforcing structure reinforcing materials 107 of different materials are closely interposed therebetween,

It is located on the outer surface of the tensile reinforcement structure reinforcements 106 and 107 installed on one side of each of the structures 104 and 105 and is attached along the perimeter to form a grid shape. It is preferable to provide the structural reinforcement 112 to reinforce the tensile strength and the shear strength to the structural body 104 and 105 at the same time.

The present invention comprises the steps of constructing a plurality of tensile reinforcement structure reinforcements 106 to reinforce the tensile strength in the longitudinal direction on each surface of the structure body 104 and the structure body 105;

The tensile reinforcement structure reinforcing material 106 is constructed in the horizontal direction along the periphery along the outer part of the structure body 104 and the structure body 105 to reinforce the shear strength and flexibly wrap the corners without being segmented to protect from earthquake resistance. It is preferable to include the step of constructing a plurality of shear reinforcement structure reinforcement 110 in order to do so.

As described above, the present invention provides for earthquake resistance such as shock and vibration by reinforcing a reinforcing material with reinforced flexibility for reinforcing earthquake resistance in a square frame-shaped building structure such as a school or building without segmenting the angled corner or circular part. It has the effect of shortening the construction period excellently because it is easy to reinforce and the construction work is fast.

In addition, the present invention has the effect of flexibly constructing the reinforcement for the segmental part when constructing an angled reinforcing structure body, and by using a reinforcing material having excellent strength and flexibility, it is possible to significantly reduce the construction cost by reducing the cost. can have an effect.

1 is a perspective view showing a frame structure for earthquake-resistant reinforcement of the present invention;
2 is a partially enlarged cross-sectional view showing the structure of the frame structure for earthquake-resistant reinforcement of the present invention;
Figure 3 is an exploded perspective view showing the structure of the frame for earthquake-resistant reinforcement of the present invention
4 is a perspective view showing the reinforcement structure of the frame structure for earthquake-resistant reinforcement of another embodiment of the present invention;
5 is a partially enlarged cross-sectional view showing the reinforcement structure of the frame structure for earthquake-resistant reinforcement of another embodiment of the present invention;
Figure 6 is an exploded perspective view showing the structure of the earthquake-resistant reinforcement frame of the present invention;
7 is a perspective view showing a reinforcement structure of a frame structure for earthquake-resistant reinforcement of another embodiment of the present invention;
8 is a partially enlarged cross-sectional view showing the reinforcement structure of the frame structure for earthquake-resistant reinforcement of another embodiment of the present invention;
9 is an enlarged view showing the structure of the shear reinforcement structure reinforcement of the present invention;

The following objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and that the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular also includes the plural, unless specifically stated otherwise in the phrase. As used herein, an element referred to as 'comprise' and/or 'comprising' does not exclude the presence or addition of one or more other elements.

In addition, in describing the configurations described as embodiments below, descriptions of technical contents that are well known in the technical field to which the present invention pertains and are not directly related to the present invention will be omitted. This is for clarification without obscuring the gist of the present invention by omitting unnecessary description.

Hereinafter, a specific embodiment according to the earthquake-resistant reinforcement frame structure and its construction method with reinforced flexibility of the present invention will be described.

1 is a perspective view showing a frame structure for earthquake-resistant reinforcement of the present invention, Figure 2 is a partially enlarged cross-sectional view showing the structure of the earthquake-resistant reinforcement frame of the present invention, Figure 3 is an exploded view showing the structure of the earthquake-resistant reinforcement frame of the present invention is a perspective view.

And, Figure 4 is a perspective view showing the reinforcing structure of the frame structure for seismic reinforcement of another embodiment of the present invention, Figure 5 is a partial cross-sectional enlarged view showing the reinforcement structure of the frame structure for seismic reinforcement of another embodiment of the present invention. , Figure 6 is an exploded perspective view showing the structure of the seismic reinforcement frame of the present invention.

In addition, Figure 7 is a perspective view showing a reinforcing structure of the frame structure for seismic reinforcement of another embodiment of the present invention, Figure 8 is a partial cross-sectional enlarged view showing the reinforcement structure of the frame structure for seismic reinforcement of another embodiment of the present invention it is do

And, Figure 9 is an enlarged view showing the structure of the shear reinforcement structure reinforcement of the present invention.

Referring to Figs. 1 to 9, the structure of the frame structure for earthquake-resistant reinforcement with reinforced flexibility of the present invention and its construction method will be described. First, as shown in Figs. 1 to 3, the reinforcing frame 102 is a longitudinal It includes a structure 104 and a structure 105 made of tensile reinforcement main reinforcing bars, and a structure reinforcement 106 attached to and installed on three or four longitudinal surfaces of the structure 104 and the structure 105 . ) is included.

In the seismic reinforcement frame structure 100 with reinforced flexibility of the present invention, the upper wall 200 is installed long in the transverse direction in the transverse direction, and the lower wall 202 is parallel to the lower part of the upper wall 200. are installed horizontally and parallel to each other.

A left masonry wall 204 is firmly installed in the longitudinal direction between the left side of the upper wall 200 and the lower wall 202, and between the right side of the upper wall 200 and the lower wall 202, the right side The wall 206 is installed in the longitudinal direction.

In the seismic reinforcement frame structure 100 installed as described above, the reinforcement frame 102 is installed in parallel to the lower surface of the upper wall 200 in the horizontal direction, and the upper wall 200 and the lower wall 202 are formed. In the middle part, the reinforcement frame 102 is fixedly installed so as to firmly support the upper wall and the lower wall in the vertical direction.

At this time, the reinforcing frame 102 is firmly installed in the longitudinal direction on the inner side of the left masonry wall 204 installed on the left side of the upper wall 200 and the lower wall 202, and the upper wall 200 and the lower The reinforcing frame 102 is firmly installed in the longitudinal direction on the inner side of the right wall 206 installed on the right side of the wall 202 .

The reinforcing frame 102 is formed in a polygonal or circular hollow bar shape such as a quadrangle, a pentagonal shape, or a channel shape, and the reinforcing frame 102 is formed to have a shape that requires connection while forming corners or enclosing it in a round shape.

The reinforcing frame 102, which is reinforced by fixing the upper wall 200 and the lower wall 202 in the longitudinal direction in the middle part, is made of a structure 104 having a rectangular frame shape, and the structure of the structure 104 is A number of structural reinforcements 106 are attached and installed in the longitudinal direction on the front and rear surfaces and on the left and right sides.

The plurality of structural reinforcing materials 106 are vertically spaced apart from each other at regular intervals, and 3 - 4 are attached in a long way to maintain uniform strength in the vertical direction.

A plurality of structural reinforcements 106 attached as described above are attached to the front, rear, left and right surfaces, and the number and attachment distance can be adjusted according to the length and width of the structure body 104 .

That is, when the width of the structure 104 is wide, the number of the structure reinforcement 106 increases to four or more, so that the attachment construction can be performed.

And the reinforcing frame 102 attached and installed on the inner side of the left masonry wall 204 and the right wall 206, respectively, includes a structure body 105 formed of a channel in the shape of a digwan (c), and the structure body 105 ), a plurality of structural reinforcements 106 are installed in the longitudinal direction, that is, in the direction of the main reinforcing bars, which is a direction from the top to the bottom for tensile reinforcement.

Next, the lower surface of the upper wall 200 is formed in the shape of a digut (c), and a channel structure 105 is provided, and the structure reinforcement 106 is attached to the lower surface of the structure body 105 to construct the tension. Constructed to increase strength.

In addition, the inner part of the structure 105 may be filled with concrete or a soft flexible filler for earthquake-resistance reinforcement to increase tensile strength and may be constructed to withstand vibrations and shocks generated during earthquake resistance.

As shown in FIG. 2, the structure reinforcement 106 installed as described above has the structure 105 installed on the lower surface of the lower wall 200 in the horizontal direction, and the structure reinforcement 106 is installed on the lower surface of the horizontal direction in the horizontal direction. ) are attached and constructed.

3 is an embodiment of the present invention, the structure reinforcement 106 is all attached to the front, rear, left and right four sides of the structure body 104, which extends long in the vertical direction and is made in the shape of a square bar and has a hollow inside.

The structural reinforcing material 106 is a two-component bonding material, epoxy, as a main ingredient, and a room temperature curing agent is mixed in a ratio of 2.5 to 3.5: 1, and carbon fiber, aramid fiber, glass fiber, bar, which is a reinforcing fiber material having high tensile strength. Any one of the fiber materials made of salt fiber or a mixture of one or more is used.

The structural reinforcing material 106 uses urethane as a main ingredient and mixes a room temperature curing agent in a ratio of 2.5 to 3.5:1, and resins with excellent bending rate, such as urethane, pulley urethane, silicone, elastic epoxy, rubber, and synthetic resin, in addition to urethane. A bonding material consisting of construct

The curing agent of the bonding material is used as a room temperature curing agent by mixing any one of polyoxypropylene diamine, polyetheramine, diethylenetriamine, and triethylenetetramine in a predetermined ratio.

As described above, the structure 104 may have various shapes, and mainly use a square, channel type, hollow cylinder, etc. as seismic reinforcing steel, and bend or bend the reinforcing steel of the structure 104 with corners. As it bends naturally, it can be constructed without segmentation.

In addition, the mixing ratio of the epoxy bonding material and the reinforcing fiber material is preferably used in the range of 1: 3.0 - 1: 4.5.

3 is a state perspective view showing a state in which the structural reinforcement 106 is constructed so that the main reinforcing bar direction, that is, the tensile reinforcement, is in the longitudinal direction in the structure 104 of the present invention.

4 to 6, another embodiment of the present invention will be described in more detail with reference to Figs. and a structural reinforcement 110 installed along the periphery of three or four sides of the structure 104 and the structure 105 .

In the seismic reinforcement frame structure 101 with reinforced flexibility of the present invention, the upper wall 200 is installed long in the transverse direction in the transverse direction, and the lower wall 202 is parallel to the lower portion of the upper wall 200. is installed horizontally.

A left masonry wall 204 is firmly installed in the longitudinal direction between the left side of the upper wall 200 and the lower wall 202 .

And between the right side of the upper wall 200 and the lower wall 202, the right wall 206 is installed in the vertical direction.

In the seismic reinforcement frame structure 100 installed as described above, the reinforcement frame 108 is installed in parallel to the lower surface of the upper wall 200 in the horizontal direction, and the upper wall 200 and the lower wall 202 are formed. In the middle part, a reinforcing frame 108 is fixedly installed to firmly support the upper wall and the lower wall in the vertical direction.

At this time, a reinforcing frame 108 is firmly installed in the longitudinal direction on the inner side of the left masonry wall 204 installed on the left side of the upper wall 200 and the lower wall 202, and the upper wall 200 and the lower A reinforcing frame 108 is firmly installed in the longitudinal direction on the inner side of the right wall 206 installed on the right side of the wall 202 .

The reinforcing frame 108 is formed in a polygonal or circular hollow bar shape such as a quadrangle, a pentagonal shape, or a channel shape, and the reinforcing frame 108 is formed to have a shape that requires connection while forming corners or enclosing it in a round shape.

The reinforcing frame 108, which is reinforced by fixing the upper wall 200 and the lower wall 202 in the longitudinal direction in the middle part, is made of a structure 104 having a rectangular frame shape, and the structure of the structure 104 is A plurality of structural reinforcements 110 are attached to the front and rear and left and right sides in the horizontal direction.

That is, it intersects with the shear reinforcement main reinforcing bar and is inclined at a predetermined angle to be constructed within the range of 10 degrees to 170 degrees. When it is constructed at an angle smaller than 10 degrees, the reinforcing effect is reduced as it approaches the direction of the tensile reinforcement main reinforcing bar, and even when it is constructed at an angle greater than 170 degrees, the reinforcing effect is not exerted because it is constructed close to the direction of the tensile reinforcement main rebar.

The plurality of structural reinforcements 110 are vertically spaced apart from the structural body 104 by a predetermined interval in the horizontal direction, and are installed in plurality to vertically intersect for shear reinforcement and are attached briefly in one direction to maintain uniform strength.

A plurality of structural reinforcements 110 attached as described above are attached to surround the perimeter of the front, rear, left, and right sides, and the number and the attachment distance can be adjusted according to the length and width of the structure 104 .

That is, when the width of the structure 104 is wide, the length of the structure reinforcement 110 increases and at the same time increases to a plurality or more, so that the length and amount can be adjusted according to the user and the construction environment to be attached.

And the reinforcing frame 108 attached and installed on the inner surface of the left masonry wall 204 and the right wall 206, respectively, is provided with a structure body 105 formed of a channel in the shape of a digwan (c), and the structure body 105 ) is installed along the perimeter in the horizontal direction to cover three sides of the bar, that is, a plurality of structural reinforcements 108 in the direction of the shear reinforcement main reinforcing bars installed while wrapping from left to right or right to left for shear reinforcement. install the construction

Subsequently, the lower surface of the upper wall 200 is formed in a digut-shape (c) and provided with a channel structure 105 , and the structure reinforcement 106 is wrapped around the lower surface of the structure body 105 along the circumference. It is constructed so as to increase the shear strength of the structure body 105 by attaching it to the structure.

In addition, the inner part of the structure body 105 may be filled with concrete or a soft flexible filler for earthquake-resistance reinforcement to increase shear strength and may be constructed to withstand vibrations and shocks generated during earthquake resistance.

As shown in FIG. 5 , the structure reinforcement 110 installed as described above has a structure 105 having a digut character (c) channel shape installed on the lower surface of the lower wall 200 in the transverse direction, and on the lower surface of the transverse direction A plurality of structural reinforcements 110 are attached and constructed while surrounding the perimeter in the vertical direction.

When the structure reinforcement 110 is attached and installed, the structure 105 installed on the lower surface of the upper wall 200 forms a vertical stripe shape, and is installed in the middle of the upper wall 200 and the lower wall 202 . The structure body 104 has a diagonal stripe shape, and the structure body 105 of the left masonry wall 204 and the right wall 206 has a horizontal stripe shape.

Continuing, Figure 6 is another embodiment of the present invention, the structure reinforcement 110 on the front, rear, left and right four sides of the structure body 104, which extends long in the vertical direction and is made in the shape of a square bar and has a hollow inside. It shows that it can be formed integrally by wrapping around the perimeter.

The structure reinforcing material 110 uses any one of fiber materials made of carbon fiber, aramid fiber, glass fiber, and basalt fiber having high tensile strength, or a mixture of at least one or more.

The structural reinforcing material 106 uses a material made of a resin having an excellent curvature, such as urethane-based, pulley-urethane-based, silicone-based, elastic epoxy-based, rubber, synthetic resin, etc. It is formed in a band shape or a band shape, and attached to each side while wrapping the edge and the peripheral surface to give the structure body seismic rigidity.

As described above, the structure 104 may have various shapes, and mainly use a square, channel type, hollow cylinder, etc. as seismic reinforcing steel, and bend or bend the reinforcing steel of the structure 104 with corners. As it bends naturally, it can be constructed without segmentation.

On the other hand, the structure reinforcement 110 is attached to the outer surface of the channel structure 105 in the shape of a digwan (c) to be constructed on the right wall 206 while surrounding the periphery, and the corner portion in contact with the right wall 206 The silver is bent in a nieunja (b) shape to form a flexible bent portion 109 without being segmented.

Then, the bracket 302 in the shape of a nieunja (b) is added to the outside and fixed using fixing means 300 such as anchor bolts, pieces, and bolts.

6 is a perspective view showing the construction state while surrounding the structure reinforcement 106 so that the shear reinforcement main reinforcing bar direction, that is, shear reinforcement is constructed in the circumferential direction with respect to the structure body 104 of the present invention.

7 and 8 are views of another embodiment of the frame structure for seismic reinforcement of the present invention. First, the reinforcing frame 112 is installed on the upper surface in the transverse direction and the structure 105 made of the shear reinforcement main reinforcing bar. Including, the reinforcing frame 112 is installed in the longitudinal direction on the left and right sides and the middle portion and includes a structure 104 made of tensile reinforcing main reinforcing bars, and a tensile reinforcing structure reinforcing material 106 is attached to the structure 105 and constructing by adding the tensile reinforcement structure reinforcement 110 of different materials between the tension reinforcement structure reinforcement materials 106 .

In the seismic reinforcement frame structure 100 with reinforced flexibility of the present invention, the upper wall 200 is installed long in the transverse direction in the transverse direction, and the lower wall 202 is parallel to the lower part of the upper wall 200. is installed in the horizontal direction, and between the left side of the upper wall 200 and the lower wall 202, a left masonry wall 204 is firmly installed in the longitudinal direction, and the upper wall 200 and the lower wall ( A right wall 206 is provided in the vertical direction between the right side portions of the 202 .

In the seismic reinforcement frame structure 100 installed as described above, the reinforcement frame 112 is installed in a horizontal direction parallel to the lower surface of the upper wall 200, and the upper wall 200 and the lower wall 202 are formed. In the middle part, the reinforcing frame 112 in the vertical direction is fixedly installed to firmly support the upper wall and the lower wall, and the left masonry wall 204 installed on the left side of the upper wall 200 and the lower wall 202. A reinforcing frame 112 is firmly installed in the vertical direction on the inner side of It is installed securely in the vertical direction.

The reinforcing frame 112 is formed in a polygonal or circular hollow bar shape such as a quadrangle, a pentagonal shape, or a channel shape, and the reinforcing frame 112 is formed to have a shape that requires connection while forming corners or enclosing it in a round shape.

The reinforcing frame 112 for reinforcing the upper wall 200 and the lower wall 202 by fixing them in the longitudinal direction in the middle is made of a hollow structure 104 having a rectangular frame shape, and the structure 104 is ), a plurality of structural reinforcements 106 and structural reinforcements 110 are attached to the front and rear surfaces, and left and right sides for tensile reinforcement in the longitudinal direction.

The plurality of structural reinforcing materials 106 are spaced apart from each other at regular intervals in the longitudinal direction, and 3 to 4 are attached to each other so as to maintain uniform tensile strength in the longitudinal direction.

After constructing a plurality of structural reinforcements 106 for tensile reinforcement spaced apart by a predetermined distance, a structural reinforcement 107 having different tensile strength as a heterogeneous material is inserted between the structural reinforcements 106 to attach and construct. .

And the structural reinforcement 106 and the structural reinforcement 107, the shear reinforcement structure reinforcement 114 for shear reinforcement over the outer surface portion of the construction along the peripheral surface of the structure body 104 and the structure body 105 along the outer surface portion It is closely adhered to the inside and wrapped so that it overlaps, and the corners of the structures 104 and 105 are flexibly refracted without segmentation, and the rigidity is reinforced against earthquake resistance such as vibration and shock.

At this time, the tensile reinforcement structure reinforcing material 107 is made to be in close contact between the gaps between the tensile reinforcing structure reinforcing materials 106 and is in close contact with the surface of the structure body 104 to strengthen the tensile reinforcement.

The structural reinforcement 106 and the structural reinforcement 107 are constructed in a lattice shape while enclosing the periphery so that the structural reinforcement 114 is covered on the outer surface of which the structural reinforcement 106 and the structural reinforcement 107 are constructed. Reinforcement for earthquake resistance is excellently demonstrated.

That is, the reinforcing frame 112 attached and installed on the inner surface of the left masonry wall 204 and the right wall 206, respectively, has a structure 105 formed of a channel in the shape of a digwan (c), and the structure ( 105), a plurality of structural reinforcements 106 are installed in the longitudinal direction, that is, in the direction of the main reinforcing bars that come down from the top for tensile reinforcement.

Next, the lower surface of the upper wall 200 is formed in the shape of a digut (c), and a channel structure 105 is provided, and the structure reinforcement 106 is attached to the lower surface of the structure body 105 to construct the tension. Constructed to increase strength.

Thereafter, the structure reinforcement 114 is tightly constructed along the periphery to cover the outer surface of the structure body 105 so as to respond to the external shear force.

As described above, the structure 104 may have various shapes, and mainly use a square, channel type, hollow cylinder, etc. as seismic reinforcing steel, and bend or bend the reinforcing steel of the structure 104 with corners. It is naturally bent and not segmented, and by sequentially stacking the tensile reinforcement structure reinforcement 106, the tension reinforcement structure reinforcement material 110, and the shear reinforcement structure reinforcement material 114, excellent tensile and shear strength to exhibit excellent tensile and shear strength. It can be constructed to implement an earthquake-resistant reinforcement frame that responds to earthquakes that can generate earthquakes such as vibration or shock.

9 is a view showing the structure of the reinforcing material of the shear reinforcement structure of the present invention, which is installed on the outer surface of the digutja (c)-shaped structure 105 installed on the right wall 206, the front side of the one side, and the lower surface in the drawing It is installed so as to surround the part and the left side and right side.

The shear reinforcement structure reinforcement 114 is spaced apart by a predetermined distance along the circumference of the structure body 105, and a plurality of them are constructed while moving from the upper side to the lower side. is formed, and on the left and right portions of the front portion 10, the inclined portions 11 are respectively formed so as to increase in the upper left and right directions, and the right portion 12 is perpendicular to the right portion of the structure body 105. is formed, and the upper and lower portions of the right side portion 12 are respectively formed with a right inclined portion 13 inclined in an upper left and a lower left direction, respectively.

At the same time, a round portion 16 is formed to prevent cracking due to shock and vibration transmitted to the right edge portion of the structure 105, and the round portion 16 is formed with the upper right inclined portion 11 and Finishing construction is made by reinforcing the corners by connecting the lower left and lower inclined portions 13 to form a semi-circular round.

Subsequently, a left side portion 14 is vertically formed on the left side of the structure body 105 , and a left side slope portion 15 inclined to the right and bottom sides is respectively formed on the upper and lower portions of the left side portion 14 , respectively. is formed

At the same time, a round portion 18 is formed to prevent cracking due to shock and vibration transmitted to the left corner portion of the structure 105, and the round portion 18 is formed with the lower right inclined portion 15 and Finish construction is carried out by connecting the upper left inclined part 11 and reinforcing the corner part so that it becomes a semi-circular round.

10 is a process diagram showing the construction method of the earthquake-resistant reinforcement frame of the present invention, first, setting the construction position for determining the position for constructing the structural reinforcement (106, 110) on the structural body (104, 105) (S1) and, After setting the construction location, the structural reinforcement is constructed as the structural reinforcements 106 and 110. In this case, as the structural reinforcement, either the tensile reinforcement structure reinforcement 107 or the shear reinforcement structure reinforcement material 114 is selected and constructed It includes a step (S2 or S3), and a finishing treatment step (S4) of closely adhering the corners of the structures (104, 105) in a round shape after construction of the structural reinforcements (106, 110).

As the structural reinforcing material, any one of the tensile reinforcing structure reinforcing material or the shear reinforcing structure reinforcing material can be selected and constructed as a single reinforcing material on a structure such as a giyeok-shaped (a) shape, a digut-shaped (c) shape, and an H shape. In addition, the tensile-reinforced structure reinforcement and the shear-reinforced structure reinforcement may be alternately constructed, and selective implementation changes according to the construction of the structural reinforcement may be variously made, and this will be said to be within the scope of the present invention.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be variously implemented by those of ordinary skill in the art to which the present invention belongs, and within this range Technical changes will be said to be within the scope of the present invention.

10: front part 11: inclined part
12: right side part 13: right inclined part
14: left side part 15: left inclined part
16,18: Round part
100: earthquake-resistant reinforcement frame structure
102,108,112: reinforcement frame 104,105: structure body
106,110: structural reinforcement 107: tensile reinforcement structural reinforcement
114: shear reinforcement structure reinforcement
200: upper wall 202: lower wall
204: left masonry wall 206: right wall

Claims (5)

an upper wall 200 having a tensile reinforcement main reinforcing bar structure 105 installed in the transverse direction and installed in the transverse direction on the lower surface;
a lower wall 202 installed in a lower portion of the upper wall 200 and spaced apart from each other by a predetermined distance and installed in parallel;
a left masonry wall 204 installed on the left side of the upper wall 200 and the lower wall 202 and having a tensile reinforcement structure 105 installed on one inner surface in the longitudinal direction;
A right side wall 206 provided on the right side of the upper wall 200 and the lower wall 202 and provided with a tension-reinforced main reinforcing bar structure 105 installed on one inner surface in the longitudinal direction;
Tension reinforcement main reinforcing bar structures 104 installed in the longitudinal direction are installed in the inner middle portions of the upper wall 200 and the lower wall 202,
In the seismic reinforcing frame structure in which a reinforcing frame in which reinforcing materials are installed in a plurality of structures is reinforced to relieve shock and vibration when an earthquake occurs,
Structures (104, 105) formed in a quadrangular or digut-shaped (c) channel shape and having corners;
A plurality of tension-reinforced structure reinforcements 106 are attached to each side of the tensile-reinforced main reinforcing bar structure body 104 by spaced apart from each other at regular intervals, and a plurality of tensile-reinforced structure reinforcing materials 106 are attached and constructed,
The left masonry wall 204 and the right side wall 206 are spaced apart from each other at regular intervals on each side of the tension-reinforced main reinforcing bar structure 105, and a plurality of tensile reinforcing structure reinforcements 106 are attached and constructed in the longitudinal direction,
A plurality of tension-reinforced structure reinforcements 106 are attached to each side of the tensile-reinforced main reinforcing bar structure 105 installed in the transverse direction on the lower surface of the upper wall 200 at regular intervals and installed in the transverse direction. Provided with a reinforcing frame 102, the structure body (104, 105) is made to reinforce the earthquake resistance by being in close contact while forming a bend flexibly without being segmented at a bent or curved or cornered portion of the structure body (104, 105),
A plurality of shear reinforcement structure reinforcing materials 110 that are attached and constructed along the circumference on one surface of the structures 104 and 105 to strengthen shear strength are provided,
The inner part of the structure body 105 is filled with a soft flexible filler for seismic reinforcement so as to increase the tensile strength and withstand vibrations and shocks generated during earthquake resistance.
The structural reinforcing material 106 is a two-component bonding material, epoxy, as a main ingredient, and a room temperature curing agent is mixed in a ratio of 2.5 to 3.5: 1, and carbon fiber, aramid fiber, glass fiber, bar, which is a reinforcing fiber material having high tensile strength. Any one of the fiber materials made of salt fiber or a mixture of one or more is used,
A structure composed of a channel in the shape of a diverter (c) so that it can be firmly supported on the middle part of the upper wall 200 and the lower wall 202, the left masonry wall 204 of the left part, and the right wall 206 of the right part. A shear reinforcement structure reinforcement 110 is installed along the perimeter in the horizontal direction so as to have a 105 and surround three sides of the structure body 105,
The shear reinforcement structure reinforcing material 110 is inclined at a predetermined angle to be constructed within a range of 10 degrees to 170 degrees.
delete delete The method of claim 1,
A plurality of tensile reinforcement structure reinforcing materials 106 are attached to each side along the longitudinal direction to strengthen the tensile strength to the structures 104 and 105 formed in a rectangular or diverter (c) channel shape and having corners. The plurality of tensile reinforcement structure reinforcement materials 106 are spaced apart from each other at regular intervals, and the tension reinforcement structure reinforcement materials 107 of different materials are closely interposed therebetween,
It is located on the outer surface of the tensile reinforcement structure reinforcements 106 and 107 installed on one side of each of the structures 104 and 105 and is attached along the perimeter to form a grid shape. A frame structure for earthquake-resistant reinforcement with reinforced flexibility, characterized in that it is provided with a structural reinforcing material (114) to simultaneously reinforce the tensile strength and shear strength of the structural body (104) (105).


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