KR20110123338A - Reinforcement of polygon truss type and seismic resistance methods using thereof - Google Patents

Abstract

PURPOSE: A polygonal truss type reinforcing member and a seismic retrofit method using the same are provided to improve the mechanical and physical properties of a concrete structure. CONSTITUTION: A polygonal truss type reinforcing member comprises first members(10), second members(20), and third members(30). The first members are arranged at uniform intervals. The second members are arranged at uniform intervals to have one or more crossings with the first members. The third members are arranged at uniform intervals at uniform intervals to have one or more crossings with the first members and/or the second members. Grooves are formed in one side and/or the other side of the first, second, and third members. Multiple triangles are formed by fitting the grooves to each other.

Description

Polygonal truss type reinforcement and seismic resistance method using same

The present invention relates to a polygonal truss type reinforcement and a seismic reinforcement method using the same, and more specifically, to improve the seismic performance while forming a composite through physical and chemical methods with anti-corrosion seismic mortar and finish coating material, By fitting the rectangular members with many grooves together and constructing them, the mechanical and physical properties of the structure (tensile strength) are increased while increasing the contact area between the sphere and the reinforcement, which is an existing structure made of concrete or brick. , Compressive strength, flexural strength, resistance to cracking, shear strength, impact resistance and ductility, etc.), while reducing the load increase problem of existing stiffeners and simplifying the construction of stiffeners. Economical and the seismic and repair reinforcement effect of the structure The present invention relates to a polygonal truss type reinforcement that maximizes and prevents local fracture at the corners of a filling wall and a seismic reinforcement method using the same.

In Korea, the history of seismic design of various structures underestimated the risks of earthquakes, but the history of seismic performance and seismic performance of facilities are increasing as recent earthquakes in the world have occurred. It is true.

Since 2005, seismic design has been applied to buildings with more than 3 stories and total floor area of 1,000㎡, but most of the facilities constructed before the introduction of seismic design are designed and constructed without considering the effects of earthquake. The facilities of the aging facility have been aging due to the long years of use.

In the event of an unexpected earthquake on such an existing facility, the damage is likely to be very widespread, and the economic and social losses of the country are expected to be enormous.

Therefore, for existing facilities that are not aging or earthquake-resistant, and existing facilities that are seismic-designed but do not meet the newly revised seismic design criteria, the seismic repair and reinforcement will be appropriately secured to ensure the safety of the facilities and collapse of the structure in the event of an earthquake. There is an increasing need to minimize human and property damage.

Conventionally, in order to maximize the repair and reinforcement effect of various structures, it has been used to bury or attach a band-shaped reinforcement, fibrous reinforcement or wire mesh.

However, these reinforcing materials such as wire mesh and reinforcing bars have a small contact area with the spheres, and thus the adhesive strength is reduced, and the structure itself is unstable, so that the reinforcing effect on the structure is insufficient, and the reinforcing materials such as fibrous reinforcing materials are expensive and uneconomical. There was a problem.

In addition, these conventional structures are required to be installed using materials requiring a certain thickness or more in order to maintain a constant tensile strength or compressive strength as concrete reinforcement materials, or to install a separate structure, so that a lot of time and difficulty of construction There was a problem that should be put.

The present invention has been made to solve the above problems, the object of the structure is to increase the adhesive force with the sphere in the structure to obtain the effect of the stress distribution on the structure.

In addition, the present invention is to improve the structural characteristics of the structure by the stable structure of the polygonal truss type reinforcement itself, and to improve the adhesion to the sphere by the mechanical and physical properties (tensile strength, compressive strength, bending strength) , Resistance to cracking, shear strength, impact resistance and ductility, etc., can be increased to provide seismic reinforcement for various structures (bridges, tunnels, earthquake-proof concrete structures, foundations, buildings, etc.) have.

In addition, the present invention is to improve the strength and ductility of the core seismic reinforcement, and to have energy dissipation capacity, to solve the increase in load, which is a problem of the conventional steel plate reinforcement method, and does not require precise construction by simple assembly construction It is an object to provide a reinforcement.

In addition, an object of the present invention is to provide a reinforcing material applied to the earthquake-resistant reinforcement method having an excellent environmental efficiency and economic efficiency compared to the existing reinforcement method, which is an eco-friendly and existing reinforcement method that does not generate construction waste.

In order to achieve the above object, an embodiment of the present invention includes a plurality of rectangular first members disposed at a predetermined interval, and a plurality of the first members having at least one intersection point at a predetermined angle with the first member. A rectangular second member and a plurality of rectangular third members disposed at regular intervals to have at least one intersection point at a predetermined angle with respect to the first member and / or the second member, wherein The member, the second member, and the third member have grooves of a predetermined depth on one side and / or the other side, and a plurality of triangles are formed by fitting the grooves together.

In addition, in the present invention, it is preferable that a plurality of grooves having a predetermined interval are formed in the first member, the second member, and the third member in pairs along the longitudinal direction of the body at regular intervals.

In the present invention, the pair of grooves formed in the first member is preferably formed in the upper portion of the body longitudinal direction.

In addition, in the present invention, one groove of the pair of grooves formed in the second member is preferably formed in the upper portion of the body longitudinal direction and the other groove is preferably formed in the lower portion of the body longitudinal direction.

In the present invention, the pair of grooves formed in the third member is preferably formed in the lower portion of the body longitudinal direction.

In the present invention, it is preferable that the pair of grooves formed in the first member, the second member, and the third member are arranged with a predetermined distance therebetween.

Further, in the present invention, the opening direction of each groove formed in the first member, the second member, and the third member is orthogonal to the longitudinal direction of the body of the corresponding first member, the second member, and the third member. It is preferable to open in the direction.

Further, in the present invention, each of the grooves formed in the first member, the second member and the third member is preferably formed with a depth of half the height of the height of the first member, the second member and the third member. Do.

In addition, in the present invention, the first member, the second member and the third member is preferably formed to a predetermined thickness or more.

Further, in the present invention, it is preferable that a fourth member fitted with the grooves formed in the first member or the second member is further formed.

Another embodiment of the present invention in order to achieve the above object in the seismic reinforcement method using the polygonal truss-shaped reinforcement, the square space is formed by a beam formed horizontally with a column standing vertically on one side of the building wall, the square It is preferable to form a gap of a predetermined space by removing the wall surfaces at the four corners of the space, and attach the polygonal truss reinforcement to the rectangular space.

In another embodiment of the present invention, the gap formed at the four corners of the rectangular space is preferably filled with an elastic body having a constant elasticity.

On the other hand, another embodiment of the present invention, in the seismic reinforcement method using the polygonal truss-type reinforcement, the pier is placed and the top plate is arranged spaced apart from each other on top of the pier, the polygonal truss-shaped reinforcement is attached to the top plate It is desirable to.

As described above, the polygonal truss reinforcement of the present invention, first, in the new structure and the existing structure to increase the contact area between the sphere and the reinforcement to obtain the effect of stress distribution on the concrete structure and at the same time stable There is an effect that can improve the structural mechanical properties of the concrete structure.

Second, the present invention is to provide a reinforcement made of a structure of a simple shape has the effect of reducing the weight increase and simplify the construction of the problem of the existing reinforcement method.

Third, the present invention has the effect of providing a reinforcing material to have a seismic effect through the integration behavior by maximizing the adhesion between the material of the rust-resistant seismic earth mortar and the finish coating material.

Fourth, there is an effect to provide a reinforcement method that can prevent local destruction of the wall edge through the seismic reinforcement method of the present invention.

1 is a perspective view of a polygonal truss reinforcement of the present invention,
2 is a conceptual view as seen from the front of the polygonal truss reinforcement of the present invention,
3 is a front view of a first member of the polygonal truss reinforcement of the present invention,
4 is a front view of a second member of the polygonal truss reinforcement of the present invention,
5 is a front view of a third member of the polygonal truss reinforcement of the present invention,
6 is a front view of a fourth member of the polygonal truss reinforcement of the present invention;
7 is a schematic diagram of performance evaluation of a polygonal truss type reinforcement of the present invention;
8 is a state evaluation test setting state of the polygonal truss reinforcement of the present invention,
Figure 9 is a crack shape of each truss-shaped reinforcement of the present invention and the control cycle
10 is an explanatory diagram of the emphasis and stiffness model of the masonry filling wall;
11 is an embodiment of the seismic reinforcement method using the multi-layered truss type reinforcement of the present invention in the wall of the building,
12 shows another embodiment of the seismic reinforcement method using the polygonal truss type reinforcement of the present invention in a bridge.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a perspective view of a polygonal truss type reinforcement of the present invention, Figure 2 is a conceptual view as seen from the front of the polygonal truss type reinforcement of the present invention, Figure 3 is a front view of the first member of the polygonal truss type reinforcement of the present invention, Figure 4 is a front view of a second member of the polygonal truss reinforcement of the present invention, FIG. 5 is a front view of a third member of the polygonal truss reinforcement of the present invention, and FIG. 6 is a view of a fourth member of the polygonal truss reinforcement of the present invention. Front view is shown.

As shown in Figures 1 and 2, the present invention uses the first member 10, the second member 20 and the third member 30 by fitting the grooves formed in each member to each other in the shape of a triangle It is a reinforcing material.

In addition, it is preferable to further add a fourth member 40 having another shape to the combination of the first member 10, the second member 20, and the third member 30 to the polygonal truss reinforcement of the present invention. .

The first member 10 is formed in a rectangular shape in which a plurality of first members are arranged at regular intervals.

The first member 10 includes a first long member 10a that is relatively long and a first end member 10b that is relatively shorter than that of the first long member 10a.

The second member 20 has a rectangular shape in which a plurality of second members 20 are arranged at predetermined intervals with one or more intersection points at a predetermined angle.

The second member 20 includes a second long member 20a that is relatively long and a second end member 20b that is relatively shorter than the second long member 20a.

The third member 30 is formed in a rectangular shape in which a plurality of third members 30 are arranged at regular intervals so as to have one or more intersection points at a predetermined angle with respect to the first member 10 and / or the second member 20.

The third member 30 includes a third long member 30a that is relatively long and a third end member 30b that is relatively shorter than the third long member 30a.

Here, a groove having a predetermined depth is formed at a portion corresponding to the intersection point where the first member 10, the second member 20, and the third member 30 meet each other, and the angle formed between the members in the groove is about 60 °. They form a triangle with each other.

In addition, the fourth member 40 is provided with a groove having a predetermined depth so that the fourth member 40 and the first member 10 and / or the third member 30 may be joined to each other while forming about 60 ° at an intersection point.

As described above, each member of the present invention is formed with a groove of a certain depth along one side and / or the other side along the longitudinal direction, this groove is a pair of two grooves are formed at a constant interval and the pair A plurality of grooves are formed along the longitudinal direction of the body of each member.

And, in the present invention, the material of each of the first to fourth members is preferably formed of steel.

Hereinafter, the shape of each member will be described with reference to FIGS. 3 to 6.

In the first member 10, the second member 20 and the third member 30, each of the long members 10a, 20a, 30a is formed of 200 mm x 15 (or 10) mm, and each end member 10b, 20b and 30b are preferably formed to be 150 mm x 15 (or 10) mm.

In addition, the fourth member 40 is preferably formed of 30 mm x 15 (or 10) mm.

Figure 3 shows a front view of the first member of the polygonal truss reinforcement of the present invention.

The first member 10 includes a first long member 10a and a first end member 10b, and each member has a groove formed at an upper portion thereof in the longitudinal direction of the body.

The first sheet member 10a is formed with a plurality of grooves 11 and 12 formed thereon at regular intervals.

here. The distance between the grooves 11 and 12 is preferably 10 mm, and the distance between the pair of grooves is preferably 40 mm.

A plurality of first end members 10b are formed with a pair of grooves 13 and 14 formed thereon at regular intervals.

here. The distance between the grooves 13 and 14 is preferably 10 mm, and the distance between the pair of grooves is preferably 40 mm.

Figure 4 shows a front view of the second member of the polygonal truss reinforcement of the present invention.

The second member 20 includes a second long member 20a and a second end member 20b. Each member has one groove formed at an upper portion and the other groove formed at a lower portion thereof in the body length direction. do.

The second sheet member 20a is formed with a plurality of grooves 21 and 22 formed at upper and lower portions at regular intervals.

here. The distance between the grooves 21 and 22 is preferably 10 mm, and the distance between the pair of grooves is preferably 40 mm.

The second end member 20b is formed with a plurality of grooves 23 and 24 formed at upper and lower portions at regular intervals.

here. The distance between the grooves 23 and 24 is preferably 10 mm, and the distance between the pair of grooves is preferably 40 mm.

Figure 5 shows a front view of the third member of the polygonal truss-shaped reinforcement of the present invention.

The third member 30 includes the third member 30a and the third end member 30b, and each member has a groove formed at a lower portion thereof in the longitudinal direction of the body.

The third chapter member 30a has a plurality of grooves 31 and 32 formed at a lower portion thereof at regular intervals.

Here, the distance between the grooves 31 and 32 is preferably 10 mm, and the distance between the pair of grooves is preferably 40 mm.

The third end member 30b has a plurality of grooves 33 and 34 formed at a lower portion thereof at regular intervals.

here. The distance between the grooves 33 and 34 is preferably 10 mm, and the distance between the pair of grooves is preferably 40 mm.

Figure 6 shows a front view of the fourth member of the polygonal truss reinforcement of the present invention.

The fourth member 40 has one groove formed in the upper portion and the other groove formed in the lower portion in the body length direction.

The distance between the grooves 41 and 42 formed in the fourth member is preferably 10 mm.

In the present invention, the first long member 10a, the first end member 10b, the second end member 20b, the third long member 30a and the third end member 30b are each formed in two, It is preferable that two pieces of member 20a are formed.

In addition, it is preferable that two fourth members 40 are formed.

On the other hand, the first member 10, the second member 20, the third member 30 and the fourth member 40 of the present invention to be formed to the same predetermined thickness or more, to the maximum stress of the concrete structure to be installed It is desirable to set the thickness accordingly.

Here, the widths of the grooves 11, 12, 13, 14; 21, 22, 23, 24; 31, 32, 33, 34; 41, 42 according to the thickness of each member 10, 20, 30, 30 It is also desirable to increase.

In addition, each of the grooves 11, 12, 13, 14; 21, 22, 23, 24 formed in the first member 10, the second member 20, the third member 30, and the fourth member 40. 31, 32, 33, 34; 41, 42 are preferably formed to a depth of half the height of the body.

In the present invention, each of the grooves 11, 12, 13, 14; 21, formed in the first member 10, the second member 20, the third member 30 and the fourth member 40, The opening direction of the 22, 23, 24; 31, 32, 33, 34; 41, 42 is preferably formed to be orthogonal to the longitudinal direction of the body of each member (10, 20, 30, 40).

On the other hand, look at the performance evaluation of the present invention made of such a configuration as follows.

7 is a schematic view of the performance evaluation of the polygonal truss-shaped reinforcement of the present invention, Figure 8 is a performance evaluation test setting state diagram of the polygonal truss-shaped reinforcement of the present invention, Figure 9 is a crack per cycle of the polygonal truss-shaped reinforcement and the control of the present invention. This is an aspect.

Performance Evaluation Overview

In order to evaluate the reinforcing performance of the present invention, an experiment was performed to cyclically reinforce the RC beam sheared with a polygonal truss type reinforcement. In the previous experiment, the shear reinforcement performance evaluation for unidirectional cyclic loading showed an ultimate load increase rate of 36%.

The general RC beam is different from the upper and lower back muscles as shown in the cross section of Fig. 7 (a). The beams and columns are resistant to the bidirectional load during the earthquake, so the shear reinforcement performance was evaluated by the bidirectional cyclic loading test.

Performance Evaluation Experiment Design and Methods

Section and side information of the test object for the performance evaluation of the present invention is shown in FIG. The composite triangle reinforcement for reinforcement was carried out in front and rear both sides of the shaded portion in Figure 7 (b), the number of test specimens were a total of two, one control specimen (control) and one reinforcement specimen (the present invention) not reinforced.

The overall experimental setup is shown in FIG. 8. As the force equipment, an actuator of 1,000kN capacity capable of bi-directional periodic loads was used.In order to prevent the subject from lifting upward when negative force is applied, a hinge and a 600kN capacity oil jack ( An oiljack was installed to prevent the movement of the rigid body.

The load load method was the same as the load load method shown in Table 1 and the graph below, and repeated load was applied twice for each cycle in the positive (+) and negative (-) directions by the displacement control method.

[Load force history] Cycle Displacement increment (mm) Displacement (mm) Deflection level One 2 2 0.17 2 2 3 0.33 3 2 6 0.5 4 2 8 0.67 5 2 10 0.83

[Load force method]

Performance evaluation result

The crack shape at each displacement is shown in FIG. 9. The initial crack of the unreinforced specimen (Control specimen; Fig. 9 (a)) began to occur from the initial level of 2mm.

In contrast, in the present invention (reinforced specimen; FIG. 9 (b)), relatively fine cracks occurred up to the displacement level of 4 mm, but no obvious deformation shape was observed. However, in the present invention, deformation began to occur at the displacement level of 6 mm, and deformation was more clearly developed at the 8 to 10 mm level. At the final level of 10mm, the interface dropout occurred at the corner reinforcement. In fact, the ultimate load occurred below 6mm, so the higher level is the behavior after the specimen breakage.

The results of this experiment are summarized in Table 2 below and the graph load-displacement hysteresis curves below.

In the case of the shear-reinforced specimens of the present invention, the maximum load was increased by 13% in the positive and negative directions by 36% than in the non-reinforced specimens. The effect of reinforcement on the positive and negative forces in the positive and negative directions is due to the effects of the main root. In the case of general RC beams, the maximum moments in each direction are taken into consideration, which causes a difference in the upper and lower dominant abs. As can be seen in Figure 7 (a) the test body used in this experiment is also the lower muscles are different from the upper and lower muscles as two times the upper muscles. In RC beams, the main rod is mainly reinforced to bear the tensile force due to the bending moment, but also the shear force due to the dowel work. Therefore, when the amount of the main root increases, the amount of bending reinforcement and the amount of shear reinforcement burdened by the main root increase accordingly, so that the shear reinforcing effect of the polygonal truss type reinforcement of the present invention is relatively reduced.

Therefore, as can be seen from the experimental results, it can be seen that the shear reinforcement effect by the polygonal truss type reinforcement is more exerted in the direction where the main root is relatively small.

Ultimate load comparison Experiment Static load capacity Additional load Control Experiment 286 kN 202 kN Reinforcement 323 kN 275 kN Load ratio 113% 136% Increase 13% 36%

[Load-displacement hysteresis curve]

Looking at the assembly process of the present invention composed of the above components are as follows.

First, two first long members 10a of the first member 10 are disposed at regular intervals, and the first end member 10b is disposed at both sides.

In addition, the second longest member 20a and the second end member 20b of the second member 20 are formed at a predetermined angle with the first longest member 10a while forming a predetermined angle with the first member 10. Fit into the groove corresponding to the first end member (10b).

Then, the third member 30 forms a predetermined angle (here 60 °) with the first member 10 and / or the second member 20, and the third member 30a and the third end member 30b. To fit the grooves corresponding to the first chapter member 10a / second chapter member 20a and the first end member 10b / second end member 20b.

On the other hand, in the case of forming the fourth member 40 in the present invention, after the second member 20 is disposed, the fourth member 40 is fitted with the first member 10a, and then the third member It is preferable that the member 30a fits into the groove of the fourth member 40.

In addition, it is preferable that the technical application of the present invention is applied to a method in which a steel multi-truss reinforcement member, an rust-proof seismic mortar, and a finish coating material exhibit a seismic performance by forming a composite through an interface attachment through physical and chemical methods. Do.

On the other hand, look at the seismic reinforcement method using a polygonal truss-type reinforcement of the present invention made of the above configuration as follows.

First, we will look into the masonry-filled walls that are used not only in Korea but also in the world as the partition wall in a framed building.

10 shows an explanatory diagram of the emphasis and stiffness model of the masonry filling wall.

The masonry fill wall is considered to be a non-structural element with no lateral resistance in structural design because it has a very low strength and ductility compared to the frame.

However, according to the recent research results, the filling walls are known to directly or indirectly affect the seismic performance of the entire structure because they have a significant influence on the strength, stiffness and natural frequency of the structure.

Thus, the masonry fill wall can be idealized with equivalent struts as shown in FIG.

In other words, assuming that only the compressive resistance performance of the filling wall is effective, the lateral force acting on the structure can be divided by the diagonal strut of the filling wall, so that the filling wall can actually share the lateral force of the structure.

The seismic reinforcement method using the present invention is a seismic reinforcement method using the multiple truss type reinforcement to reinforce the filling wall of the frame-type building with a multi-truss type reinforcement as a seismic performance reinforcement method of the existing building. .

Figure 11 shows an embodiment of the seismic reinforcement method using the polygonal truss-shaped reinforcement of the present invention in the wall of the building.

Looking at the embodiment using the seismic reinforcement method of the present invention in the wall of the building in detail as follows.

In an existing building wall or a new building, the wall surface of the building is filled with concrete or brick (masonry filling wall).

One side of the building wall is formed with a rectangular space consisting of two pillars 50 vertically and a beam 60 horizontally orthogonal to the pillars 50.

The polygonal truss type reinforcement 100 described above is attached to this rectangular space to increase the seismic resistance of the wall surface.

Here, before attaching the polygonal truss-shaped reinforcement 100, a part of the wall surface is removed at four corners of the rectangular space to form a gap 70 which is a predetermined empty space.

Forming the clearance 70 of the four corner predetermined spaces of the rectangular space is to space the corner portion of the filling wall and the pillar to prevent local destruction occurring at the corner portion of the wall (filling wall).

Therefore, the energy transmitted to the column is relaxed, such as impact, and the energy transmitted to the building wall can be minimized to improve the earthquake resistance of the building.

On the other hand, the gap 70 is preferably filled with an elastic body that has a constant elasticity to block and relax the energy transmitted to the building wall.

The strength of the entire structure should be calculated in consideration of the individual behavior of the reinforced filling wall, and if the strength of the beam 60 is relatively weak, it is desirable to reinforce the additional beam 60.

In addition, the present invention can be applied not only to the wall surface of the building described above but also to a bridge through which a vehicle or a train passes.

12 shows another embodiment of the seismic reinforcement method using the polygonal truss type reinforcement of the present invention in a bridge.

The bridge is a plurality of bridges 50a with a predetermined interval at the bottom, and the upper plate (60a) is arranged on the upper portion of the bridge (50a).

The plurality of top plates 60a are spaced apart from each other at regular intervals.

As each top plate 60a is spaced apart from each other, the movement between the top plates 60a may be separated and the influence due to the stretching may be dispersed.

Here, the polygonal truss reinforcement 100 is disposed on the upper plate 60a before applying the base layer 70a for waterproofing and / or the surface layer 80a such as concrete or asphalt.

By attaching the polygonal truss type reinforcement 100 between the base layer 70a and / or the surface layer 80a and the top plate 60a, the shock and vibration caused by the vehicle or train passing through the surface layer 80a are dispersed and absorbed. .

On the other hand, the base layer 70a and the surface layer 80a are preferably packaged with tensile fibers that support the tension of the bridge.

And it is preferable to arrange | position the elastic resin 95a which has elasticity which can interrupt | block and absorb a predetermined shock between the upper boards 60a.

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

10: first member
10a: Chapter 1 member 10b: First end member
11,12: groove of the first end member 13,14: groove of the first end member
20: second member
20a: Chapter 2 member 20b: Second end member
21,22: groove of the second end member 23,24: groove of the first end member
30: third member
30a: Chapter 3 member 30b: Third end member
31,32: groove of the third end member 33,34: groove of the third end member
40: fourth member
41,42: groove of the fourth member
50: column
60 beam
70: void
50a: pier
60a: top plate
70a: substrate
80a: Surface layer
90a: Tensile tension fiber
95a: elastic resin
100: polygonal truss type reinforcement

Claims (13)

A rectangular first member having a plurality arranged at regular intervals;
A rectangular second member having a plurality of intersections with the first member at a predetermined angle and arranged in a plurality at regular intervals; And
And a rectangular third member disposed at a plurality of intervals at regular intervals such that the first member and / or the second member have one or more intersection points at a predetermined angle.
The first member, the second member and the third member is a polygonal truss reinforcement having a groove having a predetermined depth is formed on one side and / or the other side and the plurality of triangles are formed by fitting the grooves. The method of claim 1,
The first member, the second member, the third member is a polygonal truss reinforcement, characterized in that a plurality of grooves having a predetermined interval is formed in pairs at a predetermined interval along the longitudinal direction of the body. The method of claim 2,
A pair of grooves formed in the first member is a multiple truss reinforcement, characterized in that formed in the upper portion of the body longitudinal direction. The method of claim 2,
One groove of a pair of grooves formed in the second member is formed in the upper portion of the longitudinal direction of the body and the other groove is formed in the lower portion of the longitudinal direction of the body. The method of claim 2,
A pair of grooves formed in the third member is a polygonal truss reinforcement, characterized in that formed in the lower portion of the body longitudinal direction. The method of claim 2,
A pair of grooves formed in the first member, the second member and the third member is a multiple truss-shaped reinforcement, characterized in that the interval is arranged at a constant distance. The method of claim 2,
The opening direction of each groove formed in the first member, the second member, and the third member is opened in a direction perpendicular to the longitudinal direction of the body of the first member, the second member, and the third member. Polygonal truss type stiffener. The method according to any one of claims 2 to 7,
Each groove formed in the first member, the second member and the third member, the depth is formed in a depth of half the height of the height of the first member, the second member and the third member. The method of claim 1,
The first member, the second member and the third member is a polygonal truss-shaped reinforcement, characterized in that formed in a predetermined thickness or more. The method of claim 1,
And a fourth member fitted with the grooves formed in the first member or the second member. In the seismic reinforcement method using a polygonal truss-type reinforcement made of claim 1,
Square space is formed by columns vertically arranged on one side of the building walls and beams formed horizontally,
Remove the wall at the four corners of the rectangular space to form a gap of a certain space,
A seismic reinforcement method using a polygonal truss type reinforcement, characterized in that to attach the polygonal truss type reinforcement to the rectangular space. 12. The method of claim 11,
Seismic reinforcement method using a polygonal truss type reinforcement, characterized in that the gap formed in the four corners of the rectangular space filled with an elastic body having a certain elasticity. In the seismic reinforcement method using a polygonal truss-type reinforcement made of claim 1,
The piers are placed and the top plates are spaced apart from each other on top of the piers,
A seismic reinforcement method using a polygonal truss type reinforcement, characterized in that to attach the polygonal truss type reinforcement to the top plate.

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