JP6604037B2 - Brace structure - Google Patents

Description

  The present invention relates to a brace structure including a brace member disposed obliquely between an upper beam and a lower beam.

  When building an elevator shaft, a large load may be applied between the upper and lower floors due to an earthquake or wind. Therefore, when building a room or a vertical shaft built in a building, the installation of a beam for receiving seismic force or wind load is considered between the beams on the upper and lower floors (see, for example, Patent Document 1). .) In the building frame described in this document, a plurality of extension pillars are provided on two opposite pillar spans, braces are provided between the extension pillars and the main pillar, and floor level beams are attached between the extension pillars. Yes.

  On the other hand, the structure which suppressed the damage of the brace when an interlayer deformation | transformation arises in a building by an earthquake etc. is examined (for example, refer patent document 2). In the structure described in this document, four brace members each having one end pin-connected to the four gusset plates of the frame are provided. A node material is provided at the other end of each brace member. When the frame is sheared in one direction, the node material rotates. During the rotation of the node material, no compressive force or tensile force is generated in the four brace members. When the deformation further proceeds, the brace member and the brace member are arranged on the same straight line, a compressive force is generated in the brace member, a tensile force is generated in the brace member, and the horizontal load is resisted. Thereby, the deformation | transformation exceeding the predetermined displacement is restrained in a building.

JP-A-10-184072 JP 2010-70991 A

  In the structure provided with the braces described in Patent Document 2 described above, a case where a load due to an earthquake or wind is applied between the columns installed between the beams on the upper and lower floors is not considered. In addition, when the floor height of the upper and lower floors is high, a load receiving beam is installed between the columns installed between the beams on the upper and lower floors. In this case, it is necessary to increase the cross-sectional area of the column in order to suppress deformation and stress due to an intermediate load.

  This invention is made in view of the above-mentioned subject, and provides the brace structure which can restrain the deformation | transformation of the column by an intermediate load, suppressing the yield of a brace in the interlayer deformation | transformation of a building.

  A brace structure that solves the above problem is a brace structure including a brace member disposed obliquely between a lower beam and an upper beam, and is disposed obliquely upward from the intersection of the first beam and the column. A first brace member, a second brace member disposed obliquely downward from an intersection of the second beam and the column disposed above the first beam, and the first beam. A rotation center disposed between a beam and the second beam so as to be rotatable about the rotation center, and fixed to the first brace member below the rotation center. And a gusset fixed to the second brace member at the top. As a result, when interlayer deformation occurs in the building, the gusset rotates around the rotation center and releases the force applied to the first and second brace members, and thus acts on the first and second brace members. The stress can be reduced and the yield of the brace can be suppressed. On the other hand, when a load acts on the middle of the column, deformation of the column can be constrained.

  In the brace structure, it is preferable that the gusset is rotatably attached to an intermediate beam disposed between the first beam and the second beam. Thereby, it is possible to attach a gusset that is rotatably supported with a simple configuration.

  In the brace structure, it is preferable that the gusset is rotatably attached to a column arranged side by side with a column to which the first and second brace members are attached. Thereby, a gusset can be attached to positions other than an intermediate beam between a lower beam and an upper beam.

  ADVANTAGE OF THE INVENTION According to this invention, in the interlayer deformation | transformation of a building, deformation | transformation of the column by an intermediate load can be restrained, suppressing the yield of a brace.

It is explanatory drawing explaining the brace structure in 1st Embodiment, Comprising: (a) is a whole conceptual diagram, (b) is an enlarged front view of the principal part, (c) is an enlarged perspective view of the principal part, (d) FIG. 3 is a conceptual diagram for explaining a mounting position of a rotation center point of a brace structure gusset. It is explanatory drawing explaining a motion when force acts on the brace structure in 1st Embodiment, (a) shows the state where force does not act, (b) shows the state at the time of interlayer deformation occurrence, (C) is an enlarged front view of the main part of (b), and (d) shows a state when an intermediate load is applied. It is explanatory drawing explaining the principal part of the brace structure in 2nd Embodiment, Comprising: (a) is an enlarged front view of the principal part, (b) is an enlarged perspective view of the principal part. It is explanatory drawing explaining the brace structure in 3rd Embodiment, Comprising: (a) is a conceptual diagram in the state where force does not act, (b) is an enlarged front view of the principal part of (a), (c) is an interlayer The conceptual diagram in the state at the time of deformation | transformation generation, (d) is an enlarged front view of the principal part of (c). It is explanatory drawing of the brace structure in a modification, Comprising: (a) is each brace structure arrange | positioned in the space between pillars, (b) is the state which has arrange | positioned two brace structures so that a brace member may intersect, ( c) shows a state in which a plurality of brace structures are arranged vertically, and (d) and (e) show a state in which the gusset is pivotally attached to the column.

(First embodiment)
Hereinafter, a first embodiment in which the brace structure is embodied will be described with reference to FIGS. 1 and 2.
Fig.1 (a) is a schematic diagram of the brace structure 20 of this embodiment. FIG. 1B and FIG. 1C are an enlarged front view and an enlarged perspective view of the main part of the brace structure 20.

  As shown in FIG. 1 (a), the brace structure 20 of the present embodiment is constructed between adjacent columns 11 and 12. A lower beam 15 and an upper beam 16 are installed on the columns 11 and 12 with an interval therebetween. Each beam (15, 16) is a beam constituting an adjacent floor of the building. In the present embodiment, an intermediate beam 17 is disposed between the lower beam 15 and the upper beam 16. The intermediate beam 17 is laid and fixed to the columns 11 and 12 in an arrangement parallel to the beams (15 and 16).

  In the present embodiment, two brace structures 20 are provided between the pillars 11 and 12. These brace structures 20 are arranged in line symmetry with respect to the span center 13 of the columns 11 and 12.

Each brace structure 20 includes a first brace member 21 and a second brace member 22.
The first brace member 21 is disposed obliquely from the intersection of the pillars 11 and 12 and the lower beam 15 so as to go upward. A lower end portion of the first brace member 21 is fixed to an intersection of each of the columns 11 and 12 and the lower beam 15 by a not-shown metal fitting or the like. In the present embodiment, the first brace member 21 is inclined toward the intersection of the span center 13 and the intermediate beam 17.

  The second brace member 22 is disposed obliquely so as to go downward from the intersection of each column 11, 12 and the upper beam 16. The upper end portion of the second brace member 22 is fixed to the intersection of each column 11, 12 and the upper beam 16 by a not-shown metal fitting or the like. In the present embodiment, the second brace member 22 is inclined toward the intersection of the span center 13 and the intermediate beam 17, similarly to the first brace member 21.

In addition, each brace structure 20 includes a gusset 25. In FIG. 1A, the gusset 25 is schematically displayed in a right isosceles triangle shape.
FIG. 1B is an explanatory diagram of the gusset 25 on the right side. Note that the left brace structure 20 is a structure obtained by inverting the right and left of the right brace structure 20, and thus the description thereof is omitted. As described above, in this embodiment, the gusset 25 is constituted by a pentagonal steel piece lacking two base angles (top and bottom vertices) of a right isosceles triangle shape. The gusset 25 has a line-symmetric shape with respect to the bisector (symmetry axis) of the apex angle. It is also possible to use a steel piece having a right isosceles triangle shape without missing two base angles.

  The gusset 25 is supported by the intermediate beam 17 as a rotation center point Cg so as to be able to rotate (rotate) in both the upper and lower directions. The rotation center point Cg is located on the symmetry axis of the gusset 25 in the vicinity of the right angle. The lower end portion (near one bottom angle) of the gusset 25 is joined to the upper end portion of the first brace member 21. Further, the upper end portion (near the other bottom angle) of the gusset 25 is joined to the lower end portion of the second brace member 22.

Next, the configuration of the gusset 25 will be described in detail with reference to FIGS. 1B and 1C.
As shown in FIG.1 (c), the intermediate beam 17 which attaches the gusset 25 is comprised with H steel. The web 17w of the intermediate beam 17 is formed with a through hole 17h penetrating vertically at a position where the gusset 25 is disposed. This through-hole 17h has a rectangular shape with the extending direction of the intermediate beam 17 as the longitudinal direction.

  As shown in FIG. 1 (b), the gusset 25 is inserted into the through hole 17 h of the intermediate beam 17 and is disposed in a vertical plane including the columns 11 and 12. When the gusset 25 is installed, the axis of symmetry is arranged parallel to the extending direction of the intermediate beam 17.

  The upper end portion of the first brace member 21 is fixed to the lower end portion of the gusset 25 by a combination of a bolt and a nut. The lower end portion of the second brace member 22 is fixed to the upper end portion of the gusset 25 by a combination of a bolt and a nut. In the present embodiment, the first brace member 21 and the second brace member 22 are arranged in line symmetry with respect to the symmetry axis of the gusset 25.

  As shown in FIG. 1B and FIG. 1C, a rotating shaft 26 is fixed to the gusset 25 so as to penetrate therethrough. As the rotating shaft 26 rotates, the gusset 25 rotates about the rotation center point Cg. The rotating shaft 26 is supported by the intermediate beam 17 so as to be rotatable using the fixing members 27 at both ends.

Next, the position of the rotation center point Cg of the gusset 25 will be described with reference to FIG. FIG.1 (d) is a schematic diagram of the gusset 25 similarly to Fig.1 (a).
In the present embodiment, the first and second brace members 21 and 22 are arranged so as to be inclined toward the intersection of the intermediate beam 17 and the span center 13. Here, first, the allowable rotation amount of the gusset 25 is calculated according to the allowable amount of interlayer deformation generated between the lower beam 15 and the upper beam 16. The size of the gusset 25 is determined on the basis of this rotation allowance. FIG. 1D shows the distance (offset Of) from the intermediate beam 17 to the position where the gusset 25 supports the brace members (21, 22) based on the rotation allowance.

  Here, the case where the inclination of a brace member (21, 22) differs is assumed. The dotted brace members (21, 22) in FIG. 1 (d) show a case where they are arranged at an angle closer to the vertical than the solid brace members (21, 22). Even when the inclination of the brace members (21, 22) is different, the position of the rotation center point Cg is determined by moving the gusset 25 horizontally so as to contact the brace members (21, 22) at the same offset Of. be able to.

Next, the effect | action of the brace structure 20 mentioned above is demonstrated using FIG.
FIG. 2A shows the brace structure 20 in a state where no force is applied to the columns 11 and 12 and the beams (15 and 16) in the lateral direction. In the present embodiment, the gusset 25 of the brace structure 20 has a symmetry axis that is substantially parallel to the intermediate beam 17.

  FIG. 2B shows the brace structure 20 in a state where interlayer deformation has occurred due to the earthquake. Here, a state is shown in which an interlayer deformation occurs in which the upper beam 16 is moved in the horizontal direction (right direction in the figure) with respect to the lower beam 15. FIG. 2C is an enlarged view of the right gusset 25 in this state.

  As shown in FIG. 2B, force is applied to the first brace member 21 of the right brace structure 20 and the second brace member 22 of the left brace structure 20 in the compressing direction. Further, force is applied to the second brace member 22 of the right brace structure 20 and the left first brace member 21 in the pulling direction. Here, the first brace member 21 and the second brace member 22 connected via the gusset 25 receive forces in opposite directions (the direction of compression and the direction of pulling).

  Therefore, as shown in FIG. 2C, the gusset 25 rotates clockwise around the rotation center point Cg of the rotation shaft 26. Here, the two-dot chain line indicates the positions of the gusset 25 and the brace members (21, 22) before the rotation, and the solid line indicates the positions of the gusset 25 and the brace members (21, 22) after the rotation.

  FIG. 2D shows the brace structure 20 in the case where the pillars 11 and 12 are deformed by applying a load in the horizontal direction (right direction in the figure) to the intermediate beam 17. When an intermediate load that causes deformation that moves in the horizontal direction (rightward in the figure) is applied to the lower beam 15 and the upper beam 16, the intermediate beam 17 tends to be deformed into the shape shown in FIG. . In this case, a force is applied substantially evenly on the upper and lower sides of the gusset 25 of the brace structure 20 of the present embodiment, so that a force for rotating the gusset 25 is hardly applied and the gusset 25 does not rotate. Therefore, the brace members (21, 22) restrain the deformation of the columns 11, 12 as if the intermediate beam 17 was moved with respect to the lower beam 15 and the upper beam 16.

According to this embodiment, the following effects can be obtained.
(1) The brace structure 20 of the present embodiment includes a first brace member 21, a second brace member 22, and a gusset 25. The first brace member 21 is disposed obliquely upward from the intersection of the lower beam 15 and the columns 11 and 12, and the second brace member 22 is downward from the intersection of the upper beam 16 and the columns 11 and 12. Are arranged diagonally. The gusset 25 is supported so as to be rotatable around a rotation center point Cg disposed between the lower beam 15 and the upper beam 16, and is fixed to the first brace member 21 below the rotation center point Cg. The second brace member 22 is fixed above the rotation center point Cg. As a result, when an interlayer deformation occurs in the building, the gusset 25 rotates around the rotation center point Cg to release the force applied to each brace member (21, 22), so that each brace member (21, 22) It is possible to reduce the stress acting on the brace member and to suppress the yielding of the brace members (21, 22). On the other hand, when a load is applied between the columns 11 and 12, the gusset 25 does not rotate, so that the cross-sectional area of the columns 11 and 12 is not increased, and the same deformation restraining effect as that of the conventional X-type brace member is achieved. Can be expected.

  (2) The gusset 25 of the brace structure 20 of the present embodiment is rotatably supported by the intermediate beam 17 provided between the lower beam 15 and the upper beam 16. Thereby, the structure which fixes the 1st brace member 21 to the lower part of the gusset 25 supported so that rotation is possible, and fixes the 2nd brace member 22 to the upper part of the gusset 25 is realizable.

  (3) In this embodiment, the gusset 25 of the brace structure 20 is inserted into the through hole 17h formed in the web 17w of the intermediate beam 17 in a rectangular shape. On the axis of symmetry of the gusset 25, a rotary shaft 26 is fixed in the vicinity of the apex angle, and this rotary shaft 26 is rotatably supported by the intermediate beam 17. Thereby, the brace structure 20 can be arrange | positioned in the in-plane area | region where the intermediate beam 17 is arrange | positioned.

(Second Embodiment)
Next, a second embodiment in which the brace structure is embodied will be described with reference to FIG. In this embodiment, the specific configurations of the gusset of the brace structure 20 in the above embodiment and the intermediate beam to which the gusset is attached are different. In addition, the brace structure 20 of this embodiment is shown with the same schematic diagram as the brace structure 20 shown to Fig.1 (a) of 1st Embodiment. In the following embodiments, the same parts as those in the above embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

3A and 3B show a gusset 45 attached to the brace structure 20 on the right side of the present embodiment.
As shown to Fig.3 (a), the gusset 45 of the brace structure in this embodiment is comprised from the lower gusset part 45a and the upper gusset part 45b. The gusset 45 is rotatably attached to the intermediate beam 37. Similar to the intermediate beam 17, the intermediate beam 37 is installed on the adjacent columns 11 and 12 at a position between the lower beam 15 and the upper beam 16.

  Similar to the intermediate beam 17 of the first embodiment, the intermediate beam 37 is made of H steel. A rectangular protruding member 37a is formed in a part of the web 37w of the intermediate beam 37 of the present embodiment by cutting a predetermined shape (in this embodiment, a U-shape). The projecting member 37a has a thin plate shape, and on the column 11 side (right side in FIG. 3A) to which one end of each brace member (21, 22) of the brace structure 20 is fixed, It is connected to the web 37w. In this embodiment, the connecting portion (connection line) between the projecting member 37a and the web 37w functions as the rotation center point Cg of the gusset 45. And the front-end | tip part of the left side (opposite side to the pillar 11) of the protrusion member 37a can be rotated to the up-down direction around the rotation center point Cg.

  A plate-shaped lower gusset portion 45a is fixed to the lower surface of the protruding member 37a by welding. A plate-shaped upper gusset portion 45b is fixed to the upper surface of the protruding member 37a by welding. The lower gusset portion 45a and the upper gusset portion 45b are arranged so as to be flush with each other and constitute the same vertical plane. The lower gusset portion 45a and the upper gusset portion 45b are arranged in a vertical plane parallel to the extending direction of the intermediate beam 17 and perpendicular to the horizontal plane constituted by the web 17w.

  Further, the first brace member 21 is fixed to the lower gusset portion 45a by a combination of a bolt and a nut. The second brace member 22 is fixed to the upper gusset portion 45b by a combination of a bolt and a nut.

  Also in the present embodiment, as in the above embodiment, when interlayer deformation occurs, the force applied to the brace members (21, 22) moves the ends of the brace members (21, 22) and rotates. The gusset 45 is rotated in the same direction around the center point Cg. Further, when a load is applied to the intermediate beam 37 in the horizontal direction, the gusset 45 does not rotate. Therefore, the brace members (21, 22) restrain the deformation of the columns 11, 12 as if the intermediate beam 17 was moved with respect to the lower beam 15 and the upper beam 16.

According to the present embodiment, the following effects can be obtained in addition to the effects similar to the effects described in (1) and (2) above.
(4) In the present embodiment, the intermediate beam 37 is formed with a protruding member 37a protruding toward the column 12 by cutting. A lower gusset portion 45a to which the first brace member 21 is fixed is fixed to the lower surface, and an upper gusset portion 45b to which the second brace member 22 is fixed is fixed to the upper surface of the protruding member 37a. Thereby, the rotatable gusset 45 can be formed using a part of the intermediate beam 37.

(Third embodiment)
Next, a third embodiment in which the brace structure is embodied will be described with reference to FIG. In this embodiment, the structure of the gusset of the brace structure 20 in the first embodiment is different.

  FIG. 4A and FIG. 4C are schematic views of the brace structure 20 of the present embodiment. 4A shows a state in which no force is applied in the lateral direction, and FIG. 4C shows a state in which interlayer deformation has occurred. 4 (b) and 4 (d) show the gusset 65 of the brace structure 20 on the right side in the case of FIGS. 4 (a) and 4 (c), respectively.

As shown in FIG. 4A, the brace structure 20 of the present embodiment includes a first brace member 21, a second brace member 22, and a gusset 65, as in the above embodiment.
In this embodiment, the gusset 65 of the brace structure 20 includes a rotating member 66 that is rotatably supported and a winding member 68 that is wound around a part of the rotating member 66. As the rotating member 66, for example, a substantially disk-shaped pulley having a groove formed on the outer periphery is used. A part of the winding member 68 is disposed in the groove, and the length and tension of the winding member 68 are adjusted, whereby the winding member 68 is held so as not to be detached from the outer periphery of the rotating member 66.

  Further, as shown in FIG. 4B, the winding member 68 is made of a flexible member such as a wire. Both ends of the winding member 68 are fixed to the end of the first brace member 21 and the end of the second brace member 22, respectively. Accordingly, the winding member 68 connects the upper end portion of the first brace member 21 and the lower end portion of the second brace member 22. In FIG. 4A and FIG. 4C, the winding member 68 is shown separately from the rotating member 66 in order to clearly show it.

  As shown in FIG. 4B, the rotating member 66 is inserted into the through hole 17h formed in the intermediate beam 17 so that the rotation axis thereof is orthogonal to the extending direction of the intermediate beam 17 in the horizontal plane of the web 17w. It is inserted. Both ends of the rotating shaft of the rotating member 66 are rotatably supported by the intermediate beam 17 by a fixing member (not shown), as in the first embodiment. In the present embodiment, the rotation center point Cg of the gusset 65 corresponds to the center of the rotation shaft of the rotation member 66.

Next, the operation of the brace structure 20 of the present embodiment will be described.
FIG. 4C shows a state in which interlayer deformation is generated by moving the upper beam 16 in the horizontal direction (right direction in the drawing) with respect to the lower beam 15. In this case, similarly to the brace structure 20 shown in FIG. 2B, the first brace member 21 of the right brace structure 20 and the second brace member 22 of the left brace structure 20 are compressed. Force is applied in the direction. Further, force is applied to the second brace member 22 of the right brace structure 20 and the left first brace member 21 in the pulling direction.

  Here, the first brace member 21 and the second brace member 22 connected via the winding member 68 receive forces in opposite directions (the direction of compression and the direction of pulling), and each brace The ends of the members (21, 22) move, and the winding member 68 rotates together with the rotating member 66. And as shown in FIG.4 (d), the winding member 68 rotates along the rotation member 66, and the position of the edge part by the side of the rotation member 66 of each brace member (21, 22) moves.

  Also in this embodiment, as in the above embodiment, when interlayer deformation occurs, the force applied to the brace members (21, 22) moves the end of the brace members (21, 22). The rotation center point Cg rotates the winding member 68 of the gusset 65 in the same direction. Further, when a load is applied to the intermediate beam 17 in the horizontal direction, the winding member 68 does not rotate. Therefore, the brace members (21, 22) restrain the deformation of the columns 11, 12 as if the intermediate beam 17 was moved with respect to the lower beam 15 and the upper beam 16.

According to the present embodiment, the following effects can be obtained in addition to the effects similar to the effects described in (1) and (2) above.
(5) In the present embodiment, the gusset 65 of the brace structure 20 includes a rotating member 66 that is rotatably supported and a winding member 68 that is wound around the rotating member 66. The winding member 68 connects the end of the first brace member 21 and the end of the second brace member 22. The rotating member 66 is supported by the intermediate beam 17 so as to be rotatable around the rotation center point Cg. Thereby, the rotatable gusset 65 can be formed using the rotating member 66 and the winding member 68.

Further, the above embodiments may be modified as follows.
In each of the above embodiments, the two brace structures 20 that are line symmetric at the center 13 of the span are disposed between the pillars 11 and 12. The number of brace structures 20 arranged between adjacent pillars 11 and 12 is not limited to this.

  For example, as shown in FIG. 5A, when a plurality of pillars 11, 12, and 14 are erected, between the pillars 11 and 12, between the pillar 12 and the pillar 14 adjacent thereto. Each of the brace structures 20 may be provided. In this case, the adjacent brace structures 20 may be arranged line-symmetrically with respect to the column 12. When the floor height is high (the gap between the lower beam 15 and the upper column 16 is large), the brace members (21, 22) can be arranged at an inclination closer to 45 degrees than the arrangement shown in FIG. Therefore, the deformation of the columns 11 and 12 can be efficiently restrained.

  In the above embodiments, the two brace structures 20 between the pillars 11 and 12 are arranged apart from each other. The arrangement of the two brace structures 20 arranged between the pillars 11 and 12 is not limited to this. For example, the two brace structures 20 may be arranged so as to contact or partially overlap each other.

  As shown in FIG. 5 (b), the first brace members 21 and the second brace members 22 of the brace structure 20 may be arranged so as to intersect each other. Also in this case, since the brace members (21, 22) can be arranged at an inclination closer to 45 degrees, the deformation of the columns 11, 12 can be efficiently restrained.

  In the brace structure 20 of each of the above embodiments, the end portion of the first brace member 21 is fixed to the intersection of the lower beam 15 and the columns 11 and 12, and the end portion of the second brace member 22 is the upper beam 16 and pillars 11 and 12 were fixed at the intersection. The positions where the brace members (21, 22) are fixed are not limited to the lower beam 15 and the upper beam 16.

As shown in FIG. 5C, when the floor height is high (the distance between the lower beam 15 and the upper column 16 is large), a plurality of intermediate beams 17 are arranged between the lower beam 15 and the upper beam 16. There are things to do. In this case, the brace structure 20 may be arranged side by side in the vertical direction. Here, two intermediate beams 17 are arranged between the lower beam 15 and the upper beam 16. The brace structure 20 disposed on the lower side is fixed to the first brace member 21 whose end is fixed at the intersection of the lower beam 15 and the column 11, and the end is fixed to the intersection of the intermediate beam 17 and the column 11. And a second brace member 22 and a gusset 25 rotatably supported by the intermediate beam 17. The brace structure 20 arranged on the upper side has the first brace member 21 whose end is fixed at the intersection of the intermediate beam 17 and the column 11, and the end is fixed at the intersection of the upper beam 16 and the column 11. A second brace member 22 and a gusset 25 supported rotatably on the intermediate beam 17 are provided. As a result, when the floor height is high, an intermediate beam 17 is provided between the lower beam 15 and the upper beam 16, and the brace members (21, 22) are fixed at the intersections of the intermediate beam 17 and the column 11. By doing so, the brace members (21, 22) can be arranged with an inclination closer to 45 degrees.
Further, the intermediate beam 17 arranged between the lower beam 15 and the upper beam 16 may not be arranged evenly. In this case, the brace structure 20 having the non-axisymmetric gusset 25 may be used.

  In the above embodiments, the gussets 25, 45, 65 of the brace structure 20 are attached to the intermediate beams 17, 37. Instead of this, a gusset of the brace structure 20 may be provided in addition to the intermediate beam.

  For example, as shown in FIG. 5 (d), the gusset 25 of the brace structure 20 is rotated to a column 12 different from (adjacent to) the column 11 to which the first and second brace members (21, 22) are fixed. Install as possible. In this case, there may be no intermediate beam between the lower beam 15 and the upper beam 16. Even in this case, the same effects as those of the above embodiments can be obtained.

  Furthermore, as shown in FIG. 5 (e), a mounting portion 12 a that protrudes toward the column 11 may be formed at the center of the column 12. By disposing the rotation center point Cg of the gusset 25 on the column 11 side of the mounting portion 12a, it is possible to avoid the gusset 25 from projecting greatly outside the column 12.

In the first and second embodiments, the gussets 25 and 45 are pentagonal. The shape of the gussets 25 and 45 is not limited to this, and may be, for example, an arc shape or a “<” shape.
In the brace structure 20 of each of the above-described embodiments, the gussets 25, 45, 65 are joined to the first brace member 21 obliquely below the rotation center point Cg, and the second is located obliquely above the rotation center point Cg. The brace member 22 was joined. As long as the brace structure 20 satisfies the relationship between the position of the rotation center point Cg and the joining position of each brace member (21, 22) and can resist the applied load, the shape of the gusset, the arrangement of the brace structure, etc. may be anything. .

  In the second embodiment, the U-shaped cut is made in the intermediate beam 17 to form the rectangular protruding member 37a. The shape of the protruding member 37a formed on the intermediate beam 17 is not limited as long as the protruding member 37a protrudes on the side opposite to the column 11 to which the brace members (21, 22) of the brace structure 20 to be arranged are fixed. For example, a triangular shape in which the base is connected to the intermediate beam 17 or a fan shape in which strings are connected may be used.

Next, technical ideas that can be grasped from the above-described embodiment and other examples will be described below together with their effects.
(A) The gusset is inserted through a hole formed in the intermediate beam and extending vertically.
The brace structure according to claim 2, wherein a rotation center shaft fixed to the gusset is rotatably supported by the intermediate beam.
Therefore, according to the invention described in (a), the brace structure in which the first and second brace members are fixed to the gusset rotatably supported is disposed in the in-plane region where the intermediate beam is disposed. be able to.

(B) A protruding member protruding to the opposite side of the column side is formed on a part of the intermediate beam,
The gusset is
A lower gusset portion fixed to the lower surface of the protruding member and fixing the first brace member;
An upper gusset portion fixed to the upper surface of the protruding member and fixing the second brace member;
3. The brace according to claim 2, wherein a connecting portion of the projecting member is a center of rotation of the gusset, and a tip of the projecting member opposite to the column side is rotatable around the center of rotation. Construction.
Therefore, according to the invention described in (b), the rotatable projecting member formed by a part of the intermediate beam is used to be rotatably supported in the in-plane region where the intermediate beam is disposed. A brace structure in which the first and second brace members are fixed to the gusset can be arranged.

  Cg: rotation center point, Of: offset, 11, 12, 14 ... column, 12a ... mounting portion, 13 ... span center, 15 ... lower beam, 16 ... upper beam, 17, 37 ... intermediate beam, 17h ... through hole, 17w, 37w ... web, 20 ... brace structure, 21 ... first brace member, 22 ... second brace member, 25, 45, 65 ... gusset, 26 ... rotating shaft, 27 ... fixing member, 37a ... projecting member, 45a ... lower gusset portion, 45b ... upper gusset portion, 66 ... rotating member, 68 ... winding member.

Claims (1)

A brace structure including a brace member disposed obliquely between a lower beam and an upper beam,
A first brace member disposed obliquely upward from the intersection of the first beam and the column;
A second brace member disposed obliquely downward from an intersection of the second beam and the column disposed above the first beam;
A gusset rotatably attached to an intermediate beam disposed between the first beam and the second beam;
The intermediate beam is composed of H steel material arranged so that the web is horizontal,
The gusset through the web hole formed, the H steel pierces supported rotatably around the arranged center of rotation between the front Symbol first beam and said second beam And
Brace characterized by a fixed lower child and the second brace member above with respect to the gusset, fixed to the first brace member downwardly with respect to the rotation center, and the center of rotation.

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