KR101294289B1 - Buckling restrained brace of dry type, and manufacturing method for the same - Google Patents

Abstract

PURPOSE: A dry process type buckling preventing brace and a construction method thereof are provided to easily handle a buckling preventing brace by reducing a weight and to be applied without the restriction of sizes or lengths of the buckling preventing brace by constructing the buckling preventing brace in a dry process method. CONSTITUTION: A dry process type buckling preventing brace (100) comprises a brace core (110), a first curve forming fixing member (130), a first plate outer cover (140), a second plate outer cover (150), and fastening members (160,170). The brace core is fastened to a building structure in order to prevent buckling. The first curve forming fixing member is welded on the first plate outer cover at regular intervals. The second curve forming fixing member is welded on the second plate outer cover at the regular intervals. The first plate outer cover is formed in a C shape and includes a first fastening hole. The second plate outer cover is formed in the C shape and includes a second fastening hole. The position of the second plate outer cover is arranged in order to correspond to the first plate outer cover. The fastening member fastens the first plate outer cover and the second plate outer cover through the first fastening hole and the second fastening hole. [Reference numerals] (AA,BB,CC,DD) Bolting

Description

Dry Buckling Brace and Construction Method {BUCKLING RESTRAINED BRACE OF DRY TYPE, AND MANUFACTURING METHOD FOR THE SAME}

The present invention relates to an anti-buckling brace, and more particularly, to a dry-type anti-buckling brace and construction method thereof by constructing in a dry (Dry) method by minimizing or omitting concrete or mortar casting during construction of the buckling-brace.

Generally, seismic design (seismic design) is essential to protect architectural structures from earthquakes in architectural structures such as houses, buildings, buildings, and apartments. Especially, it is necessary to reinforce columns and slabs in order to resist earthquake load, because damage to property and property damage are caused by collapse of building structure at the time of earthquake.

In addition, civil engineering and building structures are subjected to various kinds of loads such as earthquake, wind, and traffic load depending on the external environment, and a reliable and safe design is required to reflect them. Modern structures are becoming more and more developed due to the development of new materials and construction technology. However, due to the vibration of the structure, excessive displacement occurs in the structure, which can cause damage to the structure.

For example, in order to strengthen the earthquake-proof reinforcement, a vibration damping system is installed in a building structure, and a damper and a brace are provided. In addition, in a structural member having a general steel structure, a brace may be simply installed to secure the lateral stiffness of the column-beams against horizontal loads such as earthquakes and wind loads or to prevent buckling. Here, buckling refers to a phenomenon in which when the magnitude of the load exceeds a certain value, the deformed shape is changed to a shape different from the shape up to that time, and the ability to withstand the load decreases.

Specifically, the brace (brace) is an inclined member disposed diagonally with respect to the column and beam in the wooden structure or steel structure, receives a lateral force to act as an axial force to transfer to the pillar. Such brace prevents deformation of vertical and horizontal members, prevents buckling due to vertical pressure, resists horizontal forces, and ensures stability of the structure due to its rigidity compared to the amount of material used.

On the other hand, braces have been generally recognized as members that resist tension, but in 1980, the Tokyo Institute of Technology jointly developed a compression member that suppressed buckling failure in cooperation with Nippon Steel Co., Ltd. Successfully commercialized BRB). At that time, the compression member, which suppressed buckling, was designed as a hysteresis damper, which could reduce the total steel tonnage of 5 ~ 10% in the whole building structure. The structural concept of this anti-buckling bracing (BRB) is to support the compression element in the lateral direction at a dense and regular interval so that the buckling length is close to zero.

Figure 1a is a view for explaining the ideal control of compression buckling, Figure 1b is a view for explaining the comparison of the hysteretic behavior of the Special Concentric Brace (SCB) and Buckling Restrained Brace (BRB) .

As shown in FIG. 1A, BRB exhibits almost the same yielding behavior under repeated tension and compression, and absorbs a lot of seismic energy based on this to secure structural safety of the surrounding frame.

In addition, as shown in FIG. 1B, the cumulative plastic deformation of BRB is significantly higher than the required value compared to Special Concentric Brace (SCB), which is known to perform better than general brace.

In addition, while these SCBs must be symmetrically arranged in an X-type or V-type (inverted V-type), etc. in order to effectively resist the lateral force repeated by tension and compression, BRB can be installed alone. Ability to resist up to 70%.

2A and 2B are photographs illustrating anti-buckling braces (BRBs) and special centered braces (SCBs), respectively, and FIG. 2A shows a BRB deployment example and FIG. 2B shows an SCB deployment example.

For example, such an SCB is connected to the frame via a fairly large gusset plate, such as an X- or V-type (inverse V-type) using a square steel tube, as shown in FIG. 2B, but the BRB is shown in FIG. 2A. As shown in the figure, the core plate is inserted into the inside of the square steel pipe, and has a configuration for filling with concrete, it can be connected to the frame using a relatively small gusset plate.

In Korea, we have been researching braces filled with concrete inside square steel pipes. Concrete filled square steel brace has the effect of suppressing local buckling as the plate width ratio is larger, and the effect of energy dissipation is improved experimentally when the plate width thickness ratio is 20 or more. This has been proposed. In addition, by developing a BRB filled with the core material of the rectangular steel bar with mortar and a BRB supported by the rectangular bar, the AISC seismic regulation was satisfied, as shown in FIG.

Figure 3 is a view for explaining the experimental example of the rectangular steel core brace according to the prior art, Figure 3 a) shows the cross section of the test object, Figure 3 b) shows the elevation of the test object (uniaxial test body). , C) of FIG. 3 shows an elevation (frame skeleton) of the test body, respectively.

Overseas, BRBs are now commercialized to form markets, such as Unbonded Brace, CoreBrace and PowerCat.

4A and 4B are views illustrating Unbonded Brace of Nippon Steel Co., Ltd. among the anti-buckling braces BRB according to the prior art, and FIGS. 5A and 5B are views of the anti-buckling braces BRB according to the prior art. FIG. 6A and 6B are diagrams illustrating PowerCat of Star Seismic LLC among anti-buckling braces (BRBs) according to the prior art. FIG.

Specifically, as shown in FIGS. 4A and 4B, in Japan, Unbonded Brace Co., Ltd. provided the first BRB product. However, such BRB has a disadvantage in that the number of bolts is traditionally bolted to the gusset plate. In addition, as shown in Figs. 5A and 5B, CoreBrace of Core Brace LLC of the United States is an improvement of UnbondedBraceTM of Japan shown in Figs. 4A and 4B described above, and uses a small number of bonded bolts. 6A and 6B, PowerCat of Star Seismic LLC of the United States is capable of complete pin bonding, and also has a relatively long yield length, thus showing a small deformation.

On the other hand, Figure 7a and 7b is a view for explaining the problem of the anti-buckling brace (BRB) according to the prior art, Figure 7a is a perspective view of the anti-buckling brace, Figure 7b is a cut line AA of Figure 7a It is a cross section.

The anti-buckling bracing 10 according to the prior art, as shown in Figure 7a and 7b, the steel core (Steel) is a compression element inside the steel pipe (Steel Casing) 11 to avoid the compression buckling failure mode of the general brace core (13) penetrates in the longitudinal direction, and the concrete or mortar (12) is placed therein to suppress the buckling caused by the action of the compressive force, as shown by the reference numeral d, concrete or mortar A debonded gap is formed between the 12 and the steel core 13.

However, in the case of the anti-buckling bracing 10 according to the prior art, the work of placing concrete or mortar 12 increases the weight of the anti-buckling bracing 10, there was a problem that a rather long curing period is required.

1) Republic of Korea Patent No. 10-944363 (filed December 5, 2007), the name of the invention: "steel brace with a buckling prevention portion" 2) Japanese Patent Application Laid-Open No. 2005-207016 (published: August 4, 2005), title of invention: "buckling restraint brace member" 3) US Patent Publication No. 2005-257490 published on November 24, 205, entitled "Buckling restrained braced frame." 4) Republic of Korea Patent Publication No. 2012-123916 (published: November 12, 2012), the title of the invention: "Anti-buckling candidate steel structure of seismic reinforcing brace steel frame moment frame" 5) Republic of Korea Patent No. 10-1171448 (application date: December 29, 2009), the name of the invention: "brace structure and steel structure having the same" 6) Republic of Korea Patent No. 10-765719 (Application Date: March 5, 2007), the title of the invention: "Reinforcement structure of brace for steel structure" 7) Republic of Korea Patent No. 10-43543 (application date: September 15, 1999), the title of the invention: "steel structure with damper brace" 8) Japanese Patent Laid-Open No. 2000-186372 (published: July 4, 2000), title of the invention: "buckling restrained brace member and its construction method"

The technical problem to be solved by the present invention for solving the above problems, to minimize or omit concrete or mortar casting provides a dry type anti-buckling bracing and construction method that can be produced in a dry (dry) method. It is to.

Another technical problem to be achieved by the present invention, by constructing the anti-buckling bracing in the dry (Dry) method, can be applied regardless of the length or size of the anti-buckling bracing, reducing the weight of the anti-buckling bracing It is to provide a dry type anti-buckling brace and its construction method which is easy to handle.

As a means for achieving the above-mentioned technical problem, the dry-type buckling-resistant bracing according to the present invention, in the dry-type buckling-resistant bracing is formed in a dry manner to minimize or omit the use of concrete or mortar, Brace Core fastened to the building structure to prevent; A first plate shell formed in a C-shape and having a first fastening hole formed therein; A second plate shell formed in a C-shape and having a second fastening hole, the positions of which are aligned in correspondence with the first plate shell; A first curved molding restraint material welded to the first plate shell at regular intervals; A second curved molding restraint material welded to the second plate shell at regular intervals; And a fastening member configured to fasten the first plate sheath and the second plate sheath through the first and second fastening holes while the first plate sheath, the brace core and the second plate sheath are aligned. The first and second curved molding restraints may be elastic steels, and the fastening members may be bolts and nuts fastened to the first and second fastening holes.

Here, the dry type anti-buckling brace according to the present invention may further include concrete or mortar filled in the space between the first and second plate shell and the first and second curved molding restraint.

Here, both end portions of the first and second curved molding restraints are welded to the first and second plate shells, respectively.

Here, the first and second curved molding restraints support the brace cores in both transverse directions as plate springs at regular intervals to suppress buckling when compressive force is applied, and to allow the brace core to elongate when a tension force is applied. It is characterized by resisting the lateral force.

As another means for achieving the above-described technical problem, the dry type buckling brace according to the present invention, in the dry type buckling prevention bracing is formed in a dry manner to minimize or omit the use of concrete or mortar, to prevent buckling Brace Core fastened to the building structure (Brace Core); A first plate shell formed in a C-shape; A second plate sheath formed in a C-shape and aligned in correspondence with the first plate sheath; A first curved molding restraint material welded to the first plate shell at regular intervals; And a second curved shaping restraint welded to the second plate sheath at a predetermined interval, wherein the first and second curved shaping restraints are elastic steels, and a joint surface of the first and second plate sheaths is formed. It is characterized by being welded to each other.

According to the present invention, by minimizing or omitting concrete or mortar casting, the buckling-resistant bracing is manufactured in a dry manner, thereby enabling the batch production of the buckling-resistant bracing and reducing the production schedule, thereby increasing productivity.

According to the present invention, it can be applied irrespective of the length or size of the anti-buckling brace, and as the weight is reduced, the handling of the anti-buckling brace is facilitated.

According to the present invention, it is easier to dismantle than conventional anti-buckling braces, and concrete waste is not generated, which is advantageous in recycling resources.

According to the present invention, according to the structural conditions can be adjusted to increase or decrease the force to support the pressing brace core.

According to the present invention, it can be utilized to reinforce the lateral force of the existing building through the performance of the anti-buckling brace showing a significantly higher strength than the general brace.

Figure 1a is a view for explaining the ideal control of compression buckling, Figure 1b is a view for explaining the comparison of the hysteretic behavior of the Special Concentric Brace (SCB) and Buckling Restrained Brace (BRB) .
2A and 2B are photographs illustrating anti-buckling braces (BRB) and special center braces (SCB), respectively.
3 is a view for explaining an experimental example of the square steel core brace according to the prior art.
4A and 4B are views illustrating Unbonded Brace of Nippon Steel Co., Ltd. in the anti-buckling bracing BRB according to the prior art.
5A and 5B are diagrams illustrating CoreBrace of Core Brace LLC among anti-buckling braces (BRBs) according to the prior art.
6A and 6B illustrate PowerCat of Star Seismic LLC among anti-buckling braces (BRBs) according to the prior art.
7A and 7B are views for explaining a problem of the anti-buckling bracing BRB according to the related art.
8 is a view showing a dry type anti-buckling brace according to the first embodiment of the present invention.
FIG. 9 is an exploded assembly view of the dry type anti-buckling brace shown in FIG. 8.
10 is a view showing a dry type anti-buckling brace according to a second embodiment of the present invention.
FIG. 11 is an exploded view of the dry-buckling prevention brace shown in FIG. 10.
12 is an operation flowchart of a dry type anti-buckling bracing construction method according to a first embodiment of the present invention.
Figure 13 is a flow chart of the dry-buckling prevention brace construction method according to a second embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

As an embodiment of the present invention, there is provided a dry-type anti-buckling brace that can avoid the compression buckling failure mode by maintaining a dense and constant lateral support interval, regardless of the length or size of the brace, according to the implementation of the present invention The dry buckling prevention brace according to the example supports the brace cores in both transverse directions with leaf springs at regular intervals while densifying the curved steel plate to suppress buckling when compressive force is applied, and when the tensile force is applied, the brace brace Allowing it can effectively resist the lateral force.

Hereinafter, the dry-type buckling-resistant bracing according to the first embodiment of the present invention is a case in which the buckling-resistant bracing is configured through bolt assembly, which will be described with reference to FIGS. 8 and 9 and the dry type according to the second embodiment of the present invention. The anti-buckling brace is a case in which a buckling prevention brace is formed by welding a plate shell, and will be described with reference to FIGS. 10 and 11.

8 is a view showing a dry type anti-buckling brace according to the first embodiment of the present invention, Figure 9 is an exploded assembly view of the dry type anti-buckling brace shown in FIG.

8 and 9, the dry type anti-buckling brace 100 according to the first embodiment of the present invention is a dry type anti-buckling brace is formed in a dry manner to minimize or omit the use of concrete or mortar, The structure, for example, to prevent the buckling of the column or beam, at this time, the dry-type buckling-resistant bracing 100 may serve to resist earthquakes by hysteretic behavior according to the increase of the rigidity of the frame.

Specifically, the anti-buckling bracing 100 is, as shown in Figure 8 and 9, the brace core material 110, the first curved molding constraint 120, the second curved molding constraint 130, the first It may include the first plate shell 140, the second plate shell 150 and the fastening members (160, 170).

Braced core 110 is fastened to the building structure, for example, pillars or beams to prevent buckling.

A plurality of first curved molding restraints 120 are welded to the first plate shell 140 at regular intervals. At this time, both end portions of the first curved molding restrainer 120 are welded to the first plate shell 140.

In addition, a plurality of second curved molding restraints 130 are welded to the second plate shell 150 at regular intervals. At this time, both end portions of the second curved molding restrainer 130 are welded to the second plate shell 150.

The first plate shell 140 is formed in a C-shape, a first fastening hole is formed, the second plate shell 150 is formed in a C-shape, and a second fastening hole is formed, and the fastening member 160, 170) The position is aligned with respect to the first plate shell 140 during assembly.

Here, the first and second curved molding restraining members 120 and 130 may be steel having elasticity, but are not limited thereto. Accordingly, the first and second curved molding restraining members 120 and 130 support the brace core 110 in both transverse directions as plate springs at regular intervals to suppress buckling when compressive force is applied, and a tensile force may be applied. When allowing the elongation of the brace core material 110, it resists the lateral force.

The fastening members 160 and 170 are bolts 160 and nuts 170 fastened to the first and second fastening holes, and include the first plate shell 140, the brace core 110, and the second plate. The first plate outer shell 140 and the second plate outer shell 150 are fastened through the first and second fastening holes while the outer shell 150 is aligned.

That is, in the case of the bolt fastening type that is the dry type anti-buckling bracing 100 according to the first embodiment of the present invention, by tightening the bolt 160, the portion shown by the reference numeral A serves as the end of the end plate, When the sections are engaged, a predetermined tightening force can be introduced.

In addition, concrete or mortar may be filled in the space between the first and second plate shells 140 and 150 and the first and second curved molding restraints 120 and 130. That is, when the supporting force of the first and second curved molding restraints 120 and 130, that is, the leaf spring force is insufficient, the first and second plate shells 140 and 150 and the first and second curved lines The space between the molding restraints 120 and 130 may be partially filled with concrete or mortar to increase the bearing capacity.

On the other hand, Figure 10 is a view showing a dry type anti-buckling bracing according to the second embodiment of the present invention, Figure 11 is an exploded assembly view of the dry type anti-buckling bracing shown in FIG.

10 and 11, the dry type anti-buckling bracing 200 according to the second embodiment of the present invention is a dry type anti-buckling bracing is formed in a dry manner to minimize or omit the use of concrete or mortar, This will prevent buckling of structures, for example columns or beams. While the dry type anti-buckling bracing 100 according to the first embodiment of the present invention described above is formed by bolting, the dry type anti-buckling bracing 200 according to the second embodiment of the present invention is formed of a plate shell. It is formed by welding the joint surface.

Specifically, the anti-buckling bracing 200, as shown in Figure 10 and 11, the brace core 210, the first curved molding constraint 220, the second curved molding constraint 230, the first It may include a first plate shell 240 and a second plate shell 250.

The brace core 210 is fastened to the building structure to prevent buckling.

A plurality of first curved molding restraints 220 are welded to the first plate shell 240 at regular intervals. That is, both ends of the first curved molding restrainer 220 are welded to the first plate shell 240, whereby the elastic force and the number of installation of the first curved molding restraint 220 may be adjusted. .

The second curved molding restraint 230 is welded to the second plate shell 250 at regular intervals. That is, both end portions of the second curved molding restraint 230 are welded to the second plate sheath 250, wherein the elastic force and the number of installation of the second curved molding restraint 230 may be adjusted. .

The first plate shell 240 is formed as a C-shape, the second plate shell 250 is formed as a C-shape, and the joining surface is welded to the first plate shell 240.

Here, the first and second curved molding restraining materials 220 and 230 may be steel (Steel) having elasticity, but is not limited thereto. Accordingly, the first and second curved molding restraining members 220 and 230 support the brace core 210 in both transverse directions as a leaf spring at regular intervals to suppress buckling when a compressive force is applied and a tensile force may be applied. When allowing the extension of the brace core member 210, it resists the lateral force.

Therefore, the dry-type buckling-resistant bracing according to the first and second embodiments of the present invention is minimized or omitted, so that the buckling-resistant bracing is produced in a dry manner so that the buckling-resistant bracing can be made in a batch and the production schedule is reduced. Productivity can be increased.

In addition, the dry buckling-resistant bracing according to the first and second embodiments of the present invention can be applied regardless of the length or size of the buckling-resistant bracing, and as the weight is reduced, the handling of the anti-buckling bracing is reduced. It becomes easy.

In addition, the dry-type buckling-resistant bracing according to the first and second embodiments of the present invention is easier to dismantle compared to the existing buckling-resistant bracing, and does not generate concrete waste, which is advantageous in recycling resources.

In addition, the dry type anti-buckling brace according to the first and second embodiments of the present invention can be adjusted so as to increase or decrease the force to press the brace core material according to the structural conditions.

In addition, the dry-type buckling-resistant bracing according to the first and second embodiments of the present invention can be utilized for reinforcement of the lateral force of the existing building through the performance of the anti-buckling brace showing a significantly higher strength than the general brace.

On the other hand, Figure 12 is a flow chart of the dry-buckling-resistant brace construction method according to the first embodiment of the present invention.

Referring to FIG. 12, the dry-buckling-resistant brace construction method according to the first embodiment of the present invention is a construction method of a dry-buckling-resistant brace that is formed in a dry manner by minimizing or omitting the use of concrete or mortar. , The steel sheet is curved to form first and second curved molding restraints 120 and 130 ( S110 ). Here, the first and second curved molding restraining members 120 and 130 may be steel having elasticity.

Next, first and second fastening holes are formed in the first and second plate shells 140 and 150, respectively ( S120 ).

Next, both ends of the first and second curved molding restraints 120 and 130 are welded to the first and second plate shells 140 and 150 at predetermined intervals, respectively ( S130 ).

Next, the position of the brace core material 110, the first plate shell 140 and the second plate shell 150 is aligned ( S140 ).

Next, the fastening members 160 and 170 are fastened through the first and second fastening holes so that the second plate sheath 150 is fastened to the first plate sheath 140 ( S150 ). Here, the fastening member may be a bolt 160 and a nut 170 fastened to the first and second fastening holes, but is not limited thereto.

Next, concrete or mortar (not shown) may be filled in the space between the first and second plate shells 140 and 150 and the first and second curved molding restraints 120 and 130 ( S160 ). That is, when the plate spring force of the first and second curved molding restraints 120 and 130 is insufficient, the first and second plate shells 140 and 150 and the first and second curved molding restraints ( 120, 130) can be partially filled with concrete or mortar to increase the bearing capacity.

Accordingly, the first and second curved molding restraints 120 and 130 support the brace core 110 in both transverse directions as plate springs at regular intervals to suppress buckling when compressive force is applied, and when a tension force is applied. By allowing elongation of the brace core material 110, it can resist lateral forces.

On the other hand, Figure 13 is a flow chart of the dry-buckling-resistant brace construction method according to a second embodiment of the present invention.

Referring to FIG. 13, the dry type anti-buckling brace construction method according to the second embodiment of the present invention is a construction method of a dry type buckling prevention brace that is formed in a dry manner by minimizing or omitting the use of concrete or mortar. , The steel sheet is curved to form first and second curved molding restraining materials 220 and 230 ( S210 ). Here, the first and second curved molding restraining materials 220 and 230 may be steel having elasticity.

Next, both ends of the first and second curved molding restraints 220 and 230 are welded to the first and second plate shells 240 and 250 at a predetermined interval ( S220 ).

Next, the position of the first plate shell 240, the brace core member 210 and the second plate shell 250 is aligned ( S230 ).

Next, the joint surface of the first plate shell 240 and the second plate shell 250 is welded to form a buckling preventing brace ( S240 ).

Accordingly, the first and second curved molding restraining members 220 and 230 support the brace core 210 in both transverse directions as a leaf spring at regular intervals to suppress buckling when compressive force is applied, and when a tension force is applied. The extension of the brace core member 210 is allowed to resist lateral forces.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

100: first anti-buckling bracing
110: Brace Heartwood
120: first curved molding restraint
130: second curved molding restraint
140: first plate shell
150: second plate shell
160: bolts
170: nut
200: second anti-buckling bracing
210: Brace Heartwood
220: first curved molding restraint
230: second curved molding restraint
240: first plate shell
250: second plate shell

Claims (7)

In the dry type anti-buckling brace is formed in a dry manner to minimize or omit the use of concrete or mortar,
Brace Core fastened to the building structure to prevent buckling (Brace Core);
A first plate shell formed in a C-shape and having a first fastening hole formed therein;
A second plate shell formed in a C-shape and having a second fastening hole, the positions of which are aligned in correspondence with the first plate shell;
A first curved molding restraint material welded to the first plate shell at regular intervals;
A second curved molding restraint material welded to the second plate shell at regular intervals; And
Fastening member for fastening the first plate shell and the second plate shell through the first and second fastening holes in a state that the first plate shell, the brace core and the second plate shell is aligned.
Including but not limited to:
And the first and second curved molding restraints are elastic steels, and the fastening members are bolts and nuts fastened to the first and second fastening holes. The method of claim 1,
Dry anti-buckling brace further comprising a concrete or mortar filled in the space between the first and second plate shell and the first and second curved molding restraint. The method of claim 1,
And both side ends of the first and second curved molding restraints are welded to the first and second plate shells, respectively. The method of claim 1,
The first and second curved molding restraints support the brace cores in both transverse directions as plate springs at regular intervals to suppress buckling when compressive force is applied and to allow the brace core to elongate when a tension force is applied, Dry-buckling bracing, characterized in that resistant to. In the dry type anti-buckling brace is formed in a dry manner to minimize or omit the use of concrete or mortar,
Brace Core fastened to the building structure to prevent buckling (Brace Core);
A first plate shell formed in a C-shape;
A second plate sheath formed in a C-shape and aligned in correspondence with the first plate sheath;
A first curved molding restraint material welded to the first plate shell at regular intervals; And
A second curved molding restraint material welded to the second plate shell at regular intervals;
Including,
And the first and second curved molding restraints are elastic steels, and the joint surfaces of the first and second plate shells are welded to each other. The method of claim 5,
And both side ends of the first and second curved molding restraints are welded to the first and second plate shells, respectively. The method according to claim 6,
The first and second curved molding restraints support the brace cores in both transverse directions as plate springs at regular intervals to suppress buckling when compressive force is applied and to allow the brace core to elongate when a tension force is applied, Dry-buckling bracing, characterized in that resistant to.

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