JP2015094079A - Structural body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structural form that reduces the bending deformation amount of a core portion at the time of an earthquake.SOLUTION: A structural body 10 includes: a core portion 20; a plurality of outer peripheral columns 30 surrounding the core portion 20; a plurality of upper beam materials 42A and a plurality of lower beam materials 42B which respectively protrude from the core portion 20, are installed on each of the plurality of outer peripheral columns 30 to structure a frame with the core portion 20 and the outer peripheral columns 30; and a diagonal member 44 provided in the frame. Among the adjacent outer peripheral columns 30, the upper beam materials 42A and lower beam materials 42B installed on one of the outer peripheral columns 30 have different protruding heights HHprotruding from the core portion 20 from the upper beam materials 42A and lower beam materials 42B installed on the other outer peripheral column 30.

Description

  The present invention relates to a structure.

  There is known an earthquake-resistant structure including a core provided at the center of the structure, and a top beam that projects from the top of the core to both sides and connects the top to the outer frame (for example, Patent Documents). 1). In this seismic structure, since the seismic force (horizontal force) acting on the core part is transmitted to the outer peripheral frame via the top beam, the amount of bending deformation near the top part of the core part is reduced.

JP 2009-114701 A JP 2005-284713 A

  Although the technique disclosed in Patent Document 1 reduces the amount of bending deformation near the top of the core during an earthquake, there is room for improvement in order to further reduce the amount of bending deformation of the core.

  In view of the above facts, the present invention aims to reduce the amount of bending deformation of the core during an earthquake.

  The structure according to claim 1, wherein the core portion, a plurality of outer peripheral columns surrounding the core portion, and each projecting from the core portion, are erected on each of the plurality of outer peripheral columns, and the core portion and the outer peripheral column A plurality of upper beam members and lower beam members constituting the frame, and a diagonal member provided on the frame, and the upper beam provided on one of the adjacent outer peripheral columns. The overhanging height protruding from the core portion differs between the material and the lower beam material, and the upper beam material and the lower beam material installed on the other outer peripheral column.

  According to the structure of the first aspect, a plurality of upper beam members and lower beam members protrude from the core portion. The upper beam material and the lower beam material are installed on each of the core portion and the plurality of outer peripheral columns, and the core portion and the outer peripheral column constitute a frame. This frame is provided with diagonal materials. Therefore, during an earthquake, the seismic force (horizontal force) acting on the core portion is distributed and transmitted to the outer peripheral column via a plurality of upper beam members, lower beam members, and diagonal members.

  Here, of the adjacent outer peripheral columns, the upper beam material and the lower beam material installed on one outer peripheral column and the upper beam material and the lower beam material installed on the other outer peripheral column project from the core portion. Overhang height is different. In this way, by changing the overhang height of the upper beam material and the lower beam material between the adjacent outer peripheral columns, for example, the seismic force acting on the core portion across multiple layers is distributed and transmitted to the plurality of outer peripheral columns. can do. Therefore, the amount of bending deformation of the core portion can be reduced over a plurality of layers.

  In the structure according to claim 2, in the structure according to claim 1, between the adjacent outer peripheral columns, an upper connecting material that connects the joint portions with the upper beam material is constructed, A lower connecting material for connecting the joint portions with the lower beam material is installed.

  According to the structure which concerns on Claim 2, the seismic force transmitted to the predetermined | prescribed outer periphery pillar from the overhang | projection part is transmitted to the other outer periphery pillar adjacent via an upper joint material and a lower joint material. Thereby, the concentration of the seismic force with respect to the predetermined outer peripheral column is suppressed. Therefore, the bending deformation amount of the core part can be further reduced.

  The structure according to claim 3 is the structure according to claim 2, wherein between the adjacent outer peripheral pillars, there is a joint portion between one upper connecting material and the other lower connecting material. An oblique connecting material that connects the joint is erected.

  According to the structure which concerns on Claim 3, the diagonal connection material is constructed between the adjacent outer periphery pillars. A truss structure is formed by connecting the joint portion of the one outer peripheral column with the upper joint member and the joint portion of the other outer peripheral column with the lower joint member by the oblique joint member. Thereby, the seismic force transmitted from the overhang portion to the predetermined outer peripheral column is efficiently transmitted to another adjacent outer peripheral column via the truss structure. Therefore, it is possible to further reduce the concentration of seismic force on the predetermined outer peripheral column.

  As described above, according to the structure according to the present invention, the amount of bending deformation of the core portion during an earthquake can be reduced.

It is an elevation which shows the structure concerning one embodiment of the present invention. It is sectional drawing of the structure cut | disconnected along 2-2 line | wire of FIG. It is a longitudinal cross-sectional view of the structure shown by FIG. It is an expanded sectional view which shows the truss-like overhang | projection part shown by FIG. It is a perspective view which shows the spiral belt part shown by FIG.

  Hereinafter, a structure according to an embodiment of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the structure 10 according to the present embodiment is a columnar tower structure having a plurality of layers. The structure 10 includes a core portion 20, a plurality of outer peripheral columns 30, a plurality of truss-like overhang portions 40 (see FIG. 3) that connect the core portion 20 and the outer peripheral columns 30, and an adjacent truss-like overhang portion 40. And a spiral belt-like portion 50 connecting the two.

  The core portion 20 is raised from the base portion of the structure 10 and is disposed over a plurality of layers. This core part 20 is arrange | positioned over the substantially whole length in the center part of the structure 10, for example, The inside is used as an elevator shaft, a staircase, and an installation shaft.

  As shown in FIG. 2, the core portion 20 includes a plurality of core columns 22 arranged along the outer periphery thereof, and a plurality of core beams 24 respectively installed between adjacent core columns 22. It is formed in a cylindrical shape as a whole. Reference symbol C is a central axis of the core portion 20. The core column 22 is formed in a cylindrical shape by CFT or the like. The core beam 24 is formed of a steel member such as a shape steel.

  In addition, the core pillar 20 may be formed with shape steel, such as H-section steel, and may be formed with reinforced concrete. The same applies to the core beam 24. That is, the core part 20 may be made of steel or RC. Further, the core portion 20 may be provided with a multi-layer seismic element (wall, brace, etc.) continuous in the vertical direction.

  A plurality of outer peripheral columns 30 are arranged outside the core portion 20. The outer peripheral column 30 is formed in a cylindrical shape by CFT, for example, and is raised from the foundation. These outer peripheral pillars 30 are arranged in a circular shape along the outer periphery of the structure 10 and surround the core portion 20. These outer peripheral columns 30 are connected by a spiral belt-like portion 50 described later. In addition, you may form the outer periphery pillar 30 with RC, a steel frame, etc.

  Here, as shown in FIGS. 3 and 4, a plurality of truss-like projecting portions 40 project from the core portion 20 in a spiral staircase shape. Each truss-like overhanging portion 40 includes a pair of upper beam members 42A and lower beam members 42B, and diagonal members 44, and connects the core portion 20 and each of the plurality of outer peripheral columns 30.

  As shown in FIG. 3, the pair of the upper beam member 42 </ b> A and the lower beam member 42 </ b> B is formed of a steel frame or the like, and is installed between the opposing core column 22 and the outer peripheral column 30. Thereby, the frame 46 is constituted by the pair of the upper beam member 42A, the lower beam member 42B, the core column 22, and the outer peripheral column 30. A diagonal member 44 is provided on the diagonal of the frame 46.

  The pair of upper beam members 42A and the lower beam members 42B are installed between the core column 22 and the outer column 30 with one or more gaps (four layers in this embodiment) in the vertical direction. A frame 46 extending over a plurality of layers is formed together with the core pillar 22 and the outer peripheral pillar 30. Thereby, the inclination angle of the diagonal member 44 with respect to the core portion 20 (vertical direction) is adjusted to be a predetermined angle (in the present embodiment, around 45 degrees).

  The diagonal member 44 is formed of a steel frame or the like, and connects the core column 22 and the outer peripheral column 30. Specifically, the diagonal member 44 includes a joint portion (joint portion) 22A with the upper beam member 42A in the core column 22 and a joint portion (joint portion) 30B with the lower beam member 42B in the outer peripheral pillar 30. It is connected. The truss structure is configured by connecting the core column 22 and the outer peripheral column 30 by the upper beam member 42A, the lower beam member 42B, and the diagonal member 44.

  The joining method of the upper beam member 42A, the lower beam member 42B, and the diagonal member 44 to the core column 22 and the outer peripheral column 30 may be rigid bonding or pin bonding. The inclination direction of the diagonal member 44 with respect to the core portion 20 may be opposite. That is, the diagonal member 44 is installed between the joint portion (joint portion) of the core column 22 with the lower beam member 42B and the joint portion (joint portion) 30A of the outer pillar 30 with the upper beam member 42A. May be. In the present embodiment, a ceiling material such as a glass panel is attached along the diagonal member 44.

The plurality of truss-like projecting portions 40 configured in this manner project from the core portion 20 in a spiral staircase shape with the core portion 20 as the center. Accordingly, for example, as shown in FIG. 4, the upper beam member 42A (and the lower beam member 42B) installed on one outer peripheral column 30S and the other outer peripheral column 30T among the adjacent outer peripheral columns 30S and 30T. The overhanging heights H _S and H _T projecting from the core portion 20 are different from those of the upper beam member 42A (and the lower beam member 42B) laid on (H _T > H _S ). In the present embodiment, the overhang heights H _S and H _T are the height from the ground surface (ground level), but may be the height from the foundation, for example.

  More specifically, as shown in FIG. 2, the plurality of truss-like projecting portions 40 project radially from the core portion 20 (core pillar 22 thereof) in plan view. Also, as shown in FIG. 4, the protruding height (extension position) of the truss-like protruding portion 40 with respect to the core portion 20 is the structure 10 as it goes to the circumferential direction one side (arrow R direction) of the core portion 20. It is getting higher by one minute. In other words, the protruding height (extension position) of the truss-shaped protruding portion 40 with respect to the core portion 20 is decreased by one layer of the structure 10 as it goes to the other circumferential side of the core portion 20 (opposite to the arrow R). It has become. In the event of an earthquake, the seismic force (horizontal force) acting on the core portion 20 is transmitted as an axial force to the outer peripheral column 30 via each truss-like overhang portion 40.

  In addition, the protruding height of the truss-shaped protruding portion 40 with respect to the core portion 20 may be higher than that of the structure 10 toward the one side in the circumferential direction of the core portion 20, or may be higher than that of the structure 10. You may make it high within the range which is not satisfied. Further, the truss-like overhanging portion 40 having the same overhanging height may be partially continued to one side in the circumferential direction of the core portion 20.

  As shown in FIG. 5, a steel-structured spiral belt-like portion 50 is provided on the outer peripheral portion of the structure 10. The spiral belt-like portion 50 extends spirally along the outer peripheral portion of the structure 10 around the core portion 20 (see FIG. 1), and connects the plurality of outer peripheral pillars 30 in the circumferential direction of the core portion 20. Yes. The spiral belt-shaped portion 50 has a plurality of upper connecting members 52A, lower connecting members 52B, and oblique connecting members 54.

  The upper connecting member 52A connects the joint portions (joint portions) 30A with the upper beam member 42A in the adjacent outer peripheral pillars 30. On the other hand, the lower connecting member 52B connects the joint portions (joint portions) 30B with the lower beam member 42B in the adjacent outer peripheral pillars 30. A frame 56 is configured by the upper connecting member 52A, the lower connecting member 52B, and the outer peripheral pillar 30. An oblique connecting material 54 is provided on the diagonal of the frame 56. In FIG. 5, the upper beam member 42A and the lower beam member 42B are not shown. Further, FIG. 5 shows two wooden beams 60 joined to the outer peripheral column 30 via a bracket 58.

  The diagonal connecting material 54 connects the joint portion 30A with the upper joint material 52A in one adjacent outer peripheral column 30 and the joint portion 30B with the lower joint material 52B in the other outer peripheral column 30. The truss structure is configured by connecting the adjacent outer peripheral pillars 30 by the upper connecting member 52A, the lower connecting member 52B, and the oblique connecting member 54.

  In the present embodiment, the core portion 20, the outer peripheral column 30, the truss-like projecting portion 40, and the spiral belt-like portion 50 constitute a main frame of the structure 10. Then, as shown in FIG. 3, a floor of each layer of the structure 10 and the like is configured by incorporating a wooden subframe having a high specific strength into the main frame.

  Specifically, wooden beams 60 are respectively installed between the opposing core pillars 22 and the outer peripheral pillars 30, and floors of respective layers (not shown) are constructed on the wooden beams 60. A wooden inter-column 62 is erected between the upper and lower wooden beams 60 constituting each layer. The wooden inter-column 62 reduces the vibration of the floor of each layer and reduces the amount of interlayer deformation during an earthquake. Furthermore, a fire spread suppressing layer 64 (shaded portion) that suppresses the spread of the fire to the upper layer is provided at a key point of the structure 10. The fire spread suppressing layer 64 is formed of a steel beam 66 or the like that is covered with a fireproof coating, thereby ensuring a sufficient fireproof performance.

  The subframe may be a fireproof wooden structure to which a fireproof structure or a semi-fireproof structure is applied. Further, the structure of the subframe is not limited to a wooden structure, and may be, for example, an RC structure or a steel structure. Similarly, the main frame is not limited to the steel structure but may be an RC structure or the like. Moreover, you may use fireproof materials, such as ACL, for a floor.

  Next, the operation of this embodiment will be described.

  According to the structure 10 according to the present embodiment, a plurality of truss-like projecting portions 40 project from the core portion 20 in a spiral staircase shape. These truss-shaped overhang portions 40 connect the core portion 20 and each of the plurality of outer peripheral pillars 30 surrounding the core portion 20. That is, in the present embodiment, the core portion 20 and the plurality of outer peripheral columns 30 are continuously connected across a plurality of layers by the plurality of truss-like protruding portions 40 protruding from the core portion 20 in a spiral staircase shape.

  Therefore, during an earthquake, seismic force (horizontal force) acting on the core portion 20 is continuously distributed and transmitted across the plurality of layers to the outer peripheral column 30 via the plurality of truss-like overhang portions 40. Thereby, the bending deformation amount of the core part 20 can be reduced over several layers. Further, by reducing the amount of bending deformation of the core portion 20, the pull-out load F1 (see FIG. 1) acting on the leg portion (lower end portion) of the core portion 20 can be reduced.

  Further, the adjacent outer peripheral pillars 30 are connected by a spiral belt-like portion 50. Therefore, the seismic force transmitted from the truss-shaped overhanging portion 40 to the predetermined outer peripheral column 30 is transmitted to the adjacent outer peripheral column 30 via the spiral belt-shaped portion 50. Thereby, the concentration of the seismic force with respect to the predetermined outer peripheral column 30 is suppressed. In other words, the seismic force acting on the core portion 20 is further dispersed and transmitted to the plurality of outer peripheral columns 30. Therefore, the amount of bending deformation of the core portion 20 can be further reduced. Further, it is possible to reduce the pull-out load F2 (push-in load F2 ') that acts on the leg portions (lower end portions) of the respective outer peripheral columns 30.

  Moreover, by using the truss-shaped overhanging portion 40 as a truss structure, it is possible to reduce the weight while increasing the rigidity and proof strength of the structure 10. Further, a spiral belt-like portion 50 is provided on the outer periphery of the structure 10. Since the connecting member 54 of each frame 56 constituting the spiral belt-like portion 50 functions as a brace, the rigidity and proof stress of the structure 10 can be further increased.

  In the present embodiment, a wooden subframe is incorporated into the steel main frame formed by the core portion 20, the outer peripheral column 30, the truss-like overhanging portion 40, and the spiral belt-like portion 50, so that the wood The structure 10 can be reduced in weight while ensuring a beautiful internal space.

  Next, a modification of the above embodiment will be described.

  In the said embodiment, although the example which provided the several truss-like overhang | projection part 40 over substantially the full length of the core part 20 was shown, it does not restrict to this. For example, a plurality of truss-like overhang portions 40 may be partially provided on the upper portion or intermediate portion of the core portion 20. The core portion 20 can be provided with at least two truss-like overhang portions 40.

  Moreover, in the said embodiment, although the example which provided the spiral belt-shaped part 50 over the substantially full length of the structure 10 was shown, it does not restrict to this. The spiral belt-like part 50 may be provided intermittently, or may be provided partially on the upper part or intermediate part of the structure 10. Further, the winding direction of the spiral belt-shaped portion 50 may be the reverse direction. Furthermore, the structure 10 may be provided with two spiral trusses whose winding directions are opposite to each other and a plurality of overhangs corresponding to these spiral trusses.

  Furthermore, the shapes of the core part 20 and the structure 10 are not limited to those described above, and may be, for example, elliptical in cross section or rectangular in cross section.

  As mentioned above, although one embodiment of the present invention was described, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate, and the gist of the present invention will be described. Of course, various embodiments can be implemented without departing from the scope.

DESCRIPTION OF SYMBOLS 10 Structure 20 Core part 30 Peripheral pillar 42A Upper beam material 42B Lower beam material 44 Diagonal material 46 Frame 52A Upper connection material 52B Lower connection material 54 Diagonal connection material

Claims (3)

The core,
A plurality of outer peripheral columns surrounding the core portion;
A plurality of upper beam members and lower beam members that respectively extend from the core portion and are constructed on each of the plurality of outer peripheral columns to form a frame with the core portion and the outer peripheral columns;
Diagonal members provided on the frame;
With
Among the adjacent outer peripheral columns, the upper beam material and the lower beam material laid on one of the outer peripheral columns, and the upper beam material and the lower beam material laid on the other outer peripheral column, The overhang height protruding from the core part is different.
Structure. Between the adjacent outer peripheral columns, an upper connecting material that connects the joint portions with the upper beam material is laid, and a lower connecting material that connects the joint portions with the lower beam material is installed.
The structure according to claim 1. Between the adjacent outer peripheral pillars, an oblique connecting material that connects a joint portion with one of the upper connecting materials and a joint portion with the other lower connecting material is installed.
The structure according to claim 2.

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