JP2011202493A - Buckling restraining brace, core unit used for the same, and method of manufacturing the core unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a buckling restraining brace which is easily joined to a structure frame and is formed considerably flat, and also to provide a core unit used for the buckling restraining brace, and a method of manufacturing the core unit.SOLUTION: This core unit for a buckling restraining brace is joined, at both projecting ends, to two joint plates which are installed inside a structure frame so as to face each other. A plurality of slits opened to the distal end and lateral both ends are formed at the both projecting ends so as to be laterally arranged parallel to each other. Each slit extends in the extending direction of a restraining pipe.

Description

  The present invention relates to a buckling-restrained brace, a core unit used therefor, and a method for manufacturing the same, and in particular, a buckling-restraining brace that can be easily connected to a structure frame and configured to be relatively flat, and a core unit used therefor. And a manufacturing method thereof.

  The buckling-restraining brace is used to absorb vibration energy generated by an earthquake or the like before being transmitted to the steel frame by being hung inside the structure steel frame or the like.

  FIG. 1 is a top view of a conventional buckling-restrained brace spanned between a pair of joint members 16 installed on both sides in a steel frame of a structure, and FIG. 2 is shown in FIG. FIG. 3 is a cross-sectional view of a conventional buckling restrained brace, and FIG. 3 is a perspective view of a protruding end portion of the conventional buckling restrained brace connected to a joint material 16.

  As shown in FIGS. 1 and 2, this conventional buckling-restrained brace is composed of a core material 11 spanned between a steel frame 13 of a structure, and a vibration energy enveloping the core material 11 from the circumferential direction. It consists of a restraining material 12 that protects against deformation and tearing due to absorption. Further, as shown in FIG. 3, the core 11 is formed to have a cross-shaped cross section, and a plurality of abutment plates 14 (only two are shown) and A plurality of bolts 15 are fixed to the joint member 16 of the steel frame 13. Such a connection process takes time to work.

  Further, the core material 11 formed so as to have a cross-shaped cross section has a considerable weight and requires a considerable space.

    In view of the above problems, the present invention provides a buckling-restraining brace that can be more easily connected to a structure frame and can be configured to be relatively flat, a core unit used therefor, and a method for manufacturing the same. With the goal.

  In order to achieve the above object, the present invention is a core unit for a buckling restrained brace that is joined to two joint plates that are installed to face each other inside the structure frame at both projecting ends. In addition, a plurality of slits having openings on both the front end and the left and right sides are formed in the left and right sides at both ends which are both projecting ends, and any of the slits extends in the extending direction of the core unit. A core material unit for a buckling-restrained brace, characterized in that the joint plate can be inserted along the plurality of slits.

  The first embodiment of the core material unit includes a long core material body and two pairs of slit forming members fixed to both ends of the core material body. Each of the slit forming members has a flat plate shape, and is arranged in parallel vertically. One end side sandwiches the core material body, and the other end side defines one of the plurality of slits together with an end portion of the core material body. Can be configured to.

  As a second embodiment of the core material unit, the core material main body is fixed to both the left and right side surfaces extending along the longitudinal direction of the core material main body, and both ends are the core material. It is composed of a long side core member protruding from both end portions of the main body, and one of the plurality of slits can be formed at each end portion of each side core member.

  As a third embodiment of the core unit, the core unit includes a pair of long side cores arranged in parallel, and one of the plurality of slits is formed at each end of each side core. Can be configured.

    The present invention also provides a buckling restrained brace using the core unit of each of the above embodiments.

  That is, corresponding to the first embodiment of the core unit, a straight tube-shaped constraining tube having both ends open, and both ends are exposed to the outside of the constraining tube and have openings on the tip and both the left and right sides. A plurality of slits are formed on both protruding ends formed in parallel in the left and right direction, a core material unit penetrating the constraint tube, and a space inside the constraint tube is filled and solidified, and the constraint tube and the core material The core unit is fixed to both of the long core body and both ends of the core body. Each pair of the slit forming members is formed in a flat plate shape, and is arranged in parallel vertically. One end side sandwiches the core body, and the other end is an end of the core body. Together with one of the plurality of slits. And, wherein each slit forming member, at least its top provides a buckling restraint braces, wherein a portion of either the lower end surface is in contact with the inner surface of the restraining tube.

  Corresponding to the second embodiment of the core unit, a plurality of straight tube-shaped constraining tubes having both ends open, and a plurality of end portions exposed to the outside of the constraining tube and having openings on the front end and both left and right sides A slit is formed on both projecting ends formed in parallel on the left and right sides, a core material unit penetrating the restraint tube, and filled into the restraint tube to be solidified, and the restraint tube and the core material unit are integrated. The core material unit is fixed to each of the long core body and the left and right side surfaces extending along the longitudinal direction of the core body, Each of the slits is formed at each end of each of the side cores, and both ends of the side cores are projected from both ends of the core body. The side cores are arranged in the vertical direction at both ends. The width is wider than the width in the vertical direction of the portion between the two tip portions, and at least a part of each of the upper and lower end surfaces of the wide tip portions is in contact with the inner surface of the restraint material. A buckling-restrained brace is provided.

  Corresponding to the third embodiment of the core unit, a straight tube-shaped restraint tube having both ends open, and both ends are exposed to the outside of the restraint tube and have openings on the tip and both the left and right sides. A plurality of slits are formed in parallel on both right and left ends, a core unit passing through the restraint tube, and filled inside the restraint tube and hardened, and the restraint tube and the core unit And the core unit is composed of a pair of long side cores arranged in parallel, and each of the plurality of side cores has a plurality of the side reinforcements. Each of the side core members has a width in the vertical direction of both tip portions that is wider than the width in the vertical direction of the portion between the two tip portions, and The upper and lower end surfaces of the wide end portions are at least Some provide a buckling restraint braces, characterized in that in contact with the inner surface of the restraining member.

  Furthermore, the present invention also provides a method for manufacturing each of the above buckling restrained braces.

  That is, according to the first embodiment of the core unit, the present invention provides two pairs of both a straight tube-shaped constraining tube having both ends open and both ends of the long core body. Cores formed by fixing the flat slit-forming members of the pair in parallel vertically so that one end of each pair sandwiches the core body and the other end defines a slit together with the end of the core body A material unit is prepared, and after inserting the prepared core material unit into the restraint tube so that both end portions are exposed to the outside of the restraint tube, the inside of the restraint tube is filled with a filling reinforcing material and solidified. The manufacturing method of the buckling restraint brace characterized by these is provided.

  Corresponding to the second embodiment of the core unit, the right and left both sides extending along the longitudinal direction of the straight core body having both ends open and the long core body Prepare a core unit prepared by fixing a long side core material with both ends protruding from both ends of the core material main body and slits formed on each of the surfaces. A buckling-restraining brace characterized in that a core material unit is inserted into the constraining tube so that both ends thereof are exposed to the outside of the constraining tube, and then the inside of the constraining tube is filled with a filling reinforcing material and solidified. A manufacturing method is provided.

  Corresponding to the third embodiment of the core unit, a straight tube-shaped constraining tube open at both ends is parallel to the left and right, and one slit is formed at each end. A core unit composed of a pair of long side core members, and after inserting the prepared core unit into the restraint tube so that both ends are exposed outside the restraint tube, the restraint Provided is a method for manufacturing a buckling-restrained brace characterized by filling a solid reinforcing material inside a tube and solidifying it.

  The buckling-restraining brace of the present invention according to the above method and configuration includes two joint plates installed to face each other inside the structure frame by providing slits at both projecting ends of the core unit. Since it can be easily joined, the core unit can be connected to the frame of the structure without forming a cross-shaped cross section, and the entire core unit and buckling restraint brace can be flattened. It can be configured. That is, the buckling restrained brace of the present invention can be easily connected to the structure of the buckling restrained brace and can be configured to be relatively flat.

It is a top view in which the installation position of the conventional buckling restraint brace is shown. It is sectional drawing of the conventional buckling restraint brace. It is a perspective view of the protrusion part connected to the joint material 16 of the conventional buckling restraint brace. It is a perspective view in which the structure of the buckling restraint brace of the 1st preferred embodiment of the present invention is shown. It is a top view by which the use condition of this buckling restraint brace of the 1st preferred embodiment of the present invention is shown. It is sectional drawing cut along the 92-92 line | wire in FIG. It is a flowchart in which the manufacturing method of the buckling restraint brace of the 1st preferable embodiment of this invention is shown. It is a perspective view of the restraint pipe of the both ends opening used for the buckling restraint brace of the 1st preferred embodiment of the present invention. It is an exploded view of the core unit of the buckling restraint brace of the first preferred embodiment of the present invention. It is a perspective view by which the structure of the buckling restraint brace of the 2nd preferable embodiment of this invention is shown. FIG. 11 is a top view showing the usage state of the buckling restrained brace of the second preferred embodiment of the present invention. It is sectional drawing cut along the 94-94 line | wire in FIG. It is a flowchart in which the manufacturing method of the buckling restraint brace of the 2nd preferable embodiment of this invention is shown. It is a perspective view of the restraint pipe | tube of both ends opening used for the buckling restraint brace of the 2nd preferable embodiment of this invention. It is an exploded view of the core unit of the buckling restraint brace of the second preferred embodiment of the present invention. It is a perspective view by which the structure of the buckling restraint brace of the 3rd preferable embodiment of this invention is shown. FIG. 11 is a top view showing the usage state of the buckling restrained brace of the third preferred embodiment of the present invention. It is sectional drawing cut along the 96-96 line | wire in FIG. It is a flowchart in which the manufacturing method of the buckling restraint brace of the 3rd preferable embodiment of this invention is shown. It is a perspective view of the restraint pipe | tube of both ends opening used for the buckling restraint brace of the 3rd preferable embodiment of this invention. It is an exploded view of the core material unit of the buckling restraint brace of the 3rd preferred embodiment of the present invention.

  The manufacturing method and configuration of each preferred embodiment of the present invention will be described below with reference to the drawings.

  FIG. 4 is a perspective view showing the configuration of the buckling restrained brace 201 of the first preferred embodiment of the present invention. 5 is a top view showing the usage state of the buckling restrained brace 201, and FIG. 6 is a cross-sectional view taken along the line 92-92 in FIG.

  As shown in the figure, the buckling restrained brace 201 of the first preferred embodiment of the present invention has two joint plates 9 installed so that both projecting ends thereof face each other inside the frame of the structure, respectively. It is what is joined.

  This buckling restraint brace 201 has a straight tube shape and is open through both ends of the restraint tube 31 so that both ends are exposed to the outside of the restraint tube 31 and become both projecting ends. The core material unit 4 and the space inside the restraint tube 31 are filled and solidified, the restraint tube 31 and the core material unit 4 are integrated, and the core material unit 4 is restrained together with the restraint tube 31. 4 and a filling reinforcing material 32 that functions as a restraining material that suppresses deformation and tearing of 4.

  For example, concrete or the like can be used as the filling reinforcing material 32.

  In the core unit 4, a plurality of slits 443 having openings on both the front end and the left and right sides are formed in the left and right sides at both ends serving as the projecting ends, respectively. The film is stretched along the longitudinal direction. With this configuration, the joint plate 9 can be inserted into the slits 443 that are arranged side by side.

  As shown in the figure, the core unit 4 includes a long core body 41 and a plurality of slit forming members fixed to both ends of the core body 41.

  The slit forming member includes a pair of first slit forming member 441 and second slit forming member 442, and each of the first slit forming member 441 and the second slit forming member 442 is a flat plate. The one end side of each pair of core material bodies 41 sandwiches the core material body 41, and the other end side protruding from the core material body 41 is the end of the core material body 41. It is arranged and configured to define one of the plurality of slits 443 together with the portion. The manufacturing method of this buckling restraint brace 201 can refer to the flowchart shown in FIG.

  As shown in FIG. 7, the buckling restrained brace 201 of the first preferred embodiment of the present invention can be manufactured by the steps 901 to 904.

  Step 901 is a constraining material preparation step of preparing a straight constraining tube 31 having both ends open as shown in FIG.

  As shown in FIG. 9, the step 902 includes a first slit forming member 441 and a second slit on the upper and lower surfaces 411 and 412 at both ends of the elongated core body 41 longer than the constraining tube 31. This is a core material preparation step of preparing the core material unit 4 in which the slit forming member 442 is fixed so as to correspond vertically.

  As shown in the drawing, the core body 41 is formed such that the width of both end portions is wider than the width of the central portion between the both end portions, and each of the first or second slit forming members 411 and 412 includes the core material. An end portion from the central portion of the main body 41 is formed to be inclined. The first slit forming member 441 and the second slit forming member 442 are fixed so as to protrude from both end portions of the core body main body 41 so as to correspond to each other in the vertical direction. A slit 443 having a height equal to

  Step 903 is an assembly process in which the core unit 4 prepared in Step 902 is inserted into the restraint pipe 31 prepared in Step 901, as shown in FIG. At this time, both ends of the core body 41 are exposed to the outside of the restraint tube 31, and at least a part of any one of the first and second slit forming members 441 and 442 on the lower end surface is restrained. It arrange | positions so that the inner surface of the pipe | tube 31 may be contact | abutted.

  In step 904, the space inside the restraint tube 31 of the buckling restraint brace 201 assembled in step 903 is filled and solidified with a filling reinforcing material 32 such as concrete, so that the restraint tube 31 and the core material unit 4 are connected. It is a finishing process to be integrated.

  As described above, the buckling-restraining brace 201 of the first preferred embodiment of the present invention according to the above method and configuration is provided with a plurality of slits 443 at both projecting end portions of the core material unit 4, thereby Since it can be easily joined to each of the two joint plates 9 installed so as to face each other inside the frame, the frame of the structure can be formed without forming the core unit 4 to have a cross-shaped cross section. Depending on the adjustment of the dimensions of the first and second slit forming members 441 and 442 and the constraining material 31, it is possible to configure the core unit 4 and the buckling constraining brace 201 as a whole flat. It becomes. That is, the buckling restrained brace of the present invention can provide a buckling restrained brace that can be easily connected to a structure and can be configured to be relatively flat.

  Next, FIG. 10 is a perspective view showing the configuration of the buckling restrained brace 202 of the second preferred embodiment of the present invention. 11 is a top view showing the usage state of the buckling restrained brace 202, and FIG. 12 is a cross-sectional view taken along the line 94-94 in FIG.

  As shown in the drawing, the buckling restrained brace 202 of the second preferred embodiment of the present invention is installed so that both projecting ends face each other inside the frame of the structure, as in the first embodiment. The two joint plates 9 are joined to each other.

  This buckling restraint brace 202 has a straight tube shape and is open through both ends of the restraint tube 51 so that both ends are exposed to the outside of the restraint tube 51 and become both projecting ends. A core material unit 6 and a filling reinforcing material 52 that fills and hardens the space inside the restraint tube 51 and integrates the restraint tube 51 and the core material unit 6.

  For example, concrete may be used as the filling reinforcing material 52.

  The core unit 6 is formed with a plurality of slits 642 having openings at both ends and left and right sides at both ends, which are both projecting ends, and both the slits 642 are constrained pipes 51. The film is stretched along the stretching direction. With this configuration, the joint plate 9 can be inserted into each slit 642.

  As shown in the figure, the core material unit 6 is elongated along the longitudinal direction of the core material body 611 and a long core material body 611 in which grooves 641 are formed along the longitudinal direction thereof. Each of the side core members 62 and 63 has a plurality of long side core members 62 and 63 that are fixed to the left and right side surfaces, and whose both end portions protrude from both end portions of the core member main body 611. One slit 443 is formed.

  In addition, each side core member 62, 63 has a width in the vertical direction of both tip portions that is wider than a width in the vertical direction of the portion between the two tip portions. At least a part of each end surface is in contact with the inner surface of the restraint material 51.

  The manufacturing method of this buckling restraint brace 202 can refer to the flowchart shown in FIG.

  As shown in FIG. 13, the buckling restrained brace 202 of the second preferred embodiment of the present invention can be manufactured by the processes of Step 905 to Step 908.

  Step 905 is a constraining material preparation step for preparing a straight constraining tube 51 having both ends open as shown in FIG.

  As shown in FIG. 15, the step 906 has both ends projecting from both ends of the core body 611 on both the left and right sides extending along the longitudinal direction of the long core body 611. And a core material preparation step of preparing the core material unit 6 manufactured by fixing the long side core materials 62 and 63 in which the slits 642 are formed. Here, each of the side core members 62 and 63 is formed such that the width in the vertical direction of both tip portions is wider than the width in the vertical direction of the portion between the two tip portions.

  Step 907 is an assembly process in which the core unit 6 prepared in Step 906 is inserted into the restraint pipe 51 prepared in Step 905, as shown in FIG. At this time, both ends of the core body 611 are exposed to the outside of the restraint tube 51, and at least a part of the upper and lower end faces of the wide end portions of the side core members 62, 63 is the inner surface of the restraint material 51. It arrange | positions so that it may contact | abut.

  In step 908, the space inside the restraint tube 51 of the buckling restraint brace 202 assembled in step 907 is filled and solidified with a filling reinforcing material 52 such as concrete, so that the restraint tube 51 and the core unit 6 are connected. It is a finishing process to be integrated.

  As described above, the buckling restrained brace 202 manufactured by the above steps can perform substantially the same function as that of the first embodiment.

  Next, FIG. 16 is a perspective view showing the configuration of the buckling restrained brace 203 of the third preferred embodiment of the present invention. FIG. 17 is a top view showing the usage state of the buckling restrained brace 203, and FIG. 18 is a cross-sectional view taken along the line 96-96 in FIG.

  As shown in the figure, the buckling restrained brace 203 of the third preferred embodiment of the present invention has both projecting ends facing each other inside the frame of the structure, as in the first and second embodiments. The two joint plates 9 installed in this way are joined respectively.

  The buckling restraint brace 203 includes a straight tube-shaped restraint tube 71 having both ends open and a core passing through the restraint tube 71 so that both ends are exposed to the outside of the restraint tube 71 and become both projecting ends. A material unit 8 and a filling reinforcing material 72 that is filled and hardened in a space inside the restraint tube 71 and integrates the restraint tube 71 and the core material unit 8 are provided.

  As the filling reinforcing material 72, for example, concrete or the like can be used.

  The core unit 8 is formed with a plurality of slits 841 having openings at both ends and left and right sides at both ends, which are both projecting ends, and both slits 841 are constrained pipes 71. The film is stretched along the stretching direction. With this configuration, the joint plate 9 can be inserted into each slit 841.

  As shown in the figure, the core material unit 8 is composed of a pair of long side core materials 82 and 83 arranged in parallel, and the slits 841 are formed at both ends of the side core materials 82 and 83, respectively. One is formed.

  Further, each side core member 82, 83 has a width in the vertical direction of both tip portions that is wider than the width in the vertical direction of the portion between the two tip portions, and the top and bottom of the wide tip portions. At least a part of each end surface is in contact with the inner surface of the restraining material 71.

  The manufacturing method of this buckling restraint brace 203 can refer to the flowchart shown in FIG.

  As shown in FIG. 19, the buckling restrained brace 203 of the second preferred embodiment of the present invention can be manufactured by steps 909 to 912.

  Step 909 is a constraining material preparation step for preparing a straight constraining tube 71 having both ends open as shown in FIG.

  In step 910, as shown in FIG. 21, long side core members 82 and 83 each having slits 841 formed at both ends thereof are prepared, and a core unit 8 is prepared by arranging these in parallel. This is a material preparation process.

  Here, each of the side core members 82 and 83 is formed such that the width in the vertical direction of both tip portions is wider than the width in the vertical direction of the portion between the tip portions.

  Step 911 is an assembly process in which the core unit 8 prepared in Step 910 is inserted into the constraining tube 71 prepared in Step 909, as shown in FIG. At this time, both end portions of the side core members 82 and 83 are exposed to the outside of the restraint tube 71, and at least a part of the upper and lower end surfaces of both wide end portions of the side core members 82 and 83 is restraint member 71. It arrange | positions so that it may contact | abut on the inner surface.

  In step 912, the space inside the restraint tube 71 of the buckling restraint brace 203 assembled in step 911 is filled and solidified with a filling reinforcing material 72 such as concrete, so that the restraint tube 71 and the core material unit 8 are connected. It is a finishing process to be integrated.

  Thus, the buckling restrained brace 203 produced by the above steps can perform substantially the same function as the first and second embodiments.

  The buckling-restraining brace of the present invention according to the above method and configuration includes two joint plates installed to face each other inside the structure frame by providing slits at both projecting ends of the core unit. Each can be easily joined, so the core unit can be connected to the frame of the structure without having a cross-shaped cross section, and the entire core unit and buckling restraint brace can be flattened. Can be configured. That is, the buckling restrained brace of the present invention can be easily connected to the structure of the buckling restrained brace and can be configured to be relatively flat.

201 Buckling Restraint Brace 202 Buckling Restraint Brace 203 Buckling Restraint Brace 31 Restraint Tube 32 Filling Reinforcement Material 4 Core Material Unit 41 Core Material Body 441 First Slit Forming Member 442 Second Slit Forming Member 443 Slit 51 Restraint Tube 52 Filling reinforcing material 6 Core material unit 611 Core material body 62 Side core material 63 Side core material 641 Groove 642 Slit 71 Restraint tube 72 Filling reinforcing material 8 Core material unit 82 Side core material 83 Side core material 841 Slit 9 Joint plate

Claims (10)

A core unit for a buckling restrained brace that joins with two joint plates installed so as to face each other inside the structure frame at both projecting ends,
A plurality of slits having openings at the front end and the left and right sides are formed in parallel on the left and right sides at both ends, which are both projecting ends, and both slits extend along the extending direction of the core unit. A core material unit for buckling-restrained braces, wherein the joint plate can be inserted into the plurality of slits. It consists of a long core body and two pairs of slit forming members fixed to both ends of the core body,
Each pair of slit forming members has a flat plate shape and is arranged in parallel vertically, and one end side sandwiches the core body, and the other end side is one of the plurality of slits together with the end of the core body. The core material unit of a buckling-restrained brace according to claim 1, wherein the core material unit is defined. A long core body,
It is fixed to the left and right side surfaces extending along the longitudinal direction of the core material body, respectively, and consists of a long side core material projecting from both ends of the core material body,
The core unit for a buckling-restrained brace according to claim 1, wherein one of the plurality of slits is formed at each end of each side core. It consists of a pair of long side cores in parallel,
The core unit for a buckling-restrained brace according to claim 1, wherein one of the plurality of slits is formed at each end of each side core. A straight tube-shaped restraint tube with both ends open;
A plurality of slits having both ends exposed to the outside of the constraining tube and having openings on the front end and the left and right sides take both projecting end portions formed in parallel on the left and right sides, and a core unit passing through the constraining tube,
The space inside the restraint tube is filled and solidified, and includes a filling reinforcing material that integrates the restraint tube and the core unit,
The core material unit comprises a long core material body and two pairs of slit forming members fixed to both ends of the core material body,
Each of the pair of slit forming members has a flat plate shape and is arranged in parallel vertically, and one end side sandwiches the core material body, and the other end side is one of a plurality of slits together with the end of the core material body. To define
Each of the slit forming members is a buckling restrained brace characterized in that at least a part of the lower end surface thereof is in contact with the inner surface of the restraint tube. A straight tube-shaped restraint tube with both ends open;
A plurality of slits having both ends exposed to the outside of the constraining tube and having openings on the front end and the left and right sides take both projecting end portions formed in parallel on the left and right sides, and a core unit passing through the constraining tube,
The inside of the restraint tube is filled and solidified, and includes a filling reinforcing material that integrates the restraint tube and the core unit.
The core unit is fixed to an elongated core body and left and right side surfaces extending along the longitudinal direction of the core body, and both ends protrude from both ends of the core body. Consisting of a long side core material
One of the plurality of slits is formed at both ends of each side core member,
And each side core material has the width in the up-and-down direction of the part between the both ends in the up-and-down direction of the both ends, and both the upper and lower end surfaces of the wide both-ends Is a buckling constraining brace characterized in that at least a part of each abuts against the inner surface of the constraining material. A straight tube-shaped restraint tube with both ends open;
A plurality of slits having both ends exposed to the outside of the constraining tube and having openings on the front end and the left and right sides take both projecting end portions formed in parallel on the left and right sides, and a core unit passing through the constraining tube,
The inside of the restraint tube is filled and hardened, and includes a filling reinforcing material that integrates the restraint tube and the core unit.
The core unit is composed of a pair of long side cores arranged in parallel,
One of the plurality of slits is formed at both ends of each side core member,
And each side core material has the width in the up-and-down direction of the part between the both ends in the up-and-down direction of the both ends, and both the upper and lower end surfaces of the wide both-ends Is a buckling constraining brace characterized in that at least a part of each abuts against the inner surface of the constraining material. Two pairs of flat slit-forming members are provided at both ends of the straight tube-shaped restraint tube having both ends open and the long core material body, and one end side of each pair sandwiches the core material body. A core unit prepared by fixing the other end side in parallel so that the other end defines a slit,
A buckling restraint characterized in that after the prepared core material unit is inserted into the restraint pipe so that both ends are exposed to the outside of the restraint pipe, the inside of the restraint pipe is filled with a filling reinforcing material and solidified. Brace manufacturing method. Both ends protrude from the both ends of the core material body on each of the straight tube-shaped constraining tube having both ends open and the left and right side surfaces extending along the longitudinal direction of the long core material body. And preparing a core unit produced by fixing a long side core material in which slits are formed,
A buckling restraint characterized in that after the prepared core material unit is inserted into the restraint pipe so that both ends are exposed to the outside of the restraint pipe, the inside of the restraint pipe is filled with a filling reinforcing material and solidified. Brace manufacturing method. A core material composed of a pair of elongated side core materials that are parallel to the right and left straight pipes that are open at both ends and in which one slit is formed at each of both ends. Prepare the unit and
A buckling restraint characterized in that after the prepared core material unit is inserted into the restraint pipe so that both ends are exposed to the outside of the restraint pipe, the inside of the restraint pipe is filled with a filling reinforcing material and solidified. Brace manufacturing method.

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