JPH11172952A - Seisemic resistant and wind resistant structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To greatly absorb energy of earthquake and wind acting on a structure by setting a vertical member at a central position on a plan of the structure and providing a damper between the vertical member and beam end parts of each story collecting on the vertical member to connect them slidably. SOLUTION: This structure is constituted in such a way that two vertical members 1 are set in a substantially central part at a predetermined interval when viewed in plan. This vertical member 1 has higher rigidity than a column 2, a beam 3, etc., arranged on the outside of the member 1, and a damper D is provided between the member 1 and beam 3 end parts of each story collected on the member 1 and is separated from a floor system 5 completely. Moreover, the end parts of the beams 3 collected on the vertical member 1 are supported through slide mechanism by brackets 7 overhanging from the vertical member 1. When external force acts on this structure, the energy is absorbed greatly by the damper D so that the oscillation and deformation can be reduced.

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【０００１】[0001]

【発明の属する技術分野】本発明は、耐震耐風構造物に
関するもので、低層から超高層の建物や塔状構造物に適
用できる。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an earthquake-resistant and wind-resistant structure, and can be applied to low- to high-rise buildings and tower structures.

【０００２】[0002]

【従来の技術】従来の構造物は、一般に柱、梁、床及び
耐震壁或いはブレ−ス材で構成し、仮定荷重即ち、固定
荷重、積載荷重、地震や風等の荷重を予測推定して設計
し、設計した構造物のモデルに、同構造物が立地する条
件に合った地震波等を入力し、その応答にもとずき構造
物の剛性や強度を全体的に調整し、安全性を確認して構
築される。2. Description of the Related Art Conventional structures are generally composed of columns, beams, floors, and shear walls or bracing materials, and predict and estimate assumed loads, that is, fixed loads, loaded loads, and loads such as earthquakes and winds. Designed and input a seismic wave or the like that matches the conditions where the structure is located into the model of the designed structure, and adjust the rigidity and strength of the structure as a whole based on the response to improve safety. Confirmed and built.

【０００３】[0003]

【発明が解決しようとする課題】しかし、建設された構
造物に、予測を超えた大きな水平力、例えば巨大地震や
暴風が作用したとき、大きな揺れにより構造物に損傷が
生じる惧れがある。それを回避するために過剰設計とな
る場合があり、その結果、建設コストが増大することに
なる。However, when an unexpectedly large horizontal force, such as a large earthquake or a storm, acts on the constructed structure, the structure may be damaged by large shaking. In order to avoid this, over-designing can occur, which results in increased construction costs.

【０００４】[0004]

【本発明の目的】上記のような課題を解決するためにな
された本発明は、予測を超える大きな水平力が構造物に
作用したときでも、大きな揺れが生じることのない合理
的且つ経済的な設計及び構築が可能な、耐震耐風構造物
を提供することにある。SUMMARY OF THE INVENTION An object of the present invention, which has been made to solve the above-mentioned problems, is to provide a rational and economical method which does not cause large shaking even when a large horizontal force exceeding a prediction is applied to a structure. An object of the present invention is to provide a seismic and windproof structure that can be designed and constructed.

【０００５】[0005]

【課題を解決するための手段】前記の目的を達成するた
めに、本発明の耐震耐風構造物の構成は、（１）鉛直部
材は、同部材の外側に配設する柱、梁よりも剛性が高い
部材であり、同鉛直部材を構造物の平面の略中心位置に
設定し、鉛直部材と、同部材に集まる各階の梁端部との
間にダンパ−を介装して接続したことにあり、（２）上
記（１）の構造物において、鉛直部材に、同部材の外側
に配設する柱、梁よりも剛性が高い水平部材を剛接合し
たことにあり、（３）上記（２）の構造物において、鉛
直部材の頂部に、同部材の外側に配設する柱、梁よりも
剛性が高い水平部材を剛接合したことにあり、（４）前
記（２）の構造物において、鉛直部材に、同部材の外側
に配設する柱、梁よりも剛性が高い水平部材を、複数層
毎に剛接合したことにあり、（５）前記（１）〜（４）
のいずれかに記載の構造物において、鉛直部材に、同部
材に集まる梁を水平方向にスライド可能に接続したこと
にある。In order to achieve the above object, the structure of the earthquake-resistant and windproof structure of the present invention is as follows. (1) The vertical member is more rigid than the columns and beams provided outside the member. Is a high member, and the vertical member is set at substantially the center position of the plane of the structure, and a damper is interposed between the vertical member and the beam end of each floor gathered by the member to connect the vertical member. (2) In the structure of the above (1), the vertical member is rigidly joined to a horizontal member having higher rigidity than columns and beams provided outside the member, and (3) the above (2) (4) In the structure of (2), a horizontal member having higher rigidity than columns and beams disposed outside the member is rigidly joined to the top of the vertical member. (4) In the structure of (2), Vertical members rigidly connected to columns and beams, which are more rigid than columns and beams, Located, (5) the (1) to (4)
In the structure according to any one of the above, a beam gathered on the vertical member is connected to the vertical member so as to be slidable in the horizontal direction.

【０００６】[0006]

【発明の実施の形態１】以下、図面を用いて本発明の実
施の形態を説明する。 ＜イ＞耐震耐風構造物Ａ（図１，図２） 構造物Ａは、平面で見てその略中心部に、２本の鉛直部
材１（図示の例では芯柱）が所定間隔をおいて設定して
ある。この鉛直部材１は、同部材１の外側に配設した柱
２、梁３，４よりも剛性が高い部材であって、この鉛直
部材１と、同部材１に集まる各階の梁３端部との間にダ
ンパ−Ｄが介装してあり、床版５とは縁切りされてい
る。（図７）鉛直部材１に集まる梁３の端部は、鉛直部
材１から張出したブラケット７によりスライド機構を介
装して支承されている。この構造物Ａは低層及び中層建
物に好適であって、構造物Ａに外力が作用したとき、そ
のエネルギ−がダンパ−Ｄにより著しく吸収されるの
で、従来の構造物と比べて揺れが少なく、変形を小さく
することができる。DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. <A> Seismic and wind-resistant structure A (FIGS. 1 and 2) The structure A has two vertical members 1 (core poles in the illustrated example) spaced apart from each other at a substantially central portion in a plan view. It has been set. The vertical member 1 is a member having higher rigidity than the columns 2 and the beams 3 and 4 disposed outside the member 1, and includes the vertical member 1 and the ends of the beams 3 on each floor gathered in the member 1. A damper D is interposed therebetween, and is separated from the floor slab 5. (FIG. 7) The ends of the beams 3 gathering on the vertical member 1 are supported by a bracket 7 projecting from the vertical member 1 via a slide mechanism. This structure A is suitable for low-rise and middle-rise buildings. When an external force acts on the structure A, its energy is remarkably absorbed by the damper D. Deformation can be reduced.

【０００７】[0007]

【発明の実施の形態２】＜ロ＞耐震耐風構造物Ｂ（図３
及び図５，図６） 構造物Ｂは、前記[Embodiment 2] <b> Seismic and windproof structure B (FIG. 3)
And FIGS. 5 and 6) The structure B is

【実施の形態１】に示したの構造物Ａにおいて、鉛直部
材１の頂部に高剛性の水平部材を設置した場合である。
即ち、構造物Ｂの平面の中心に設定した鉛直部材１０
（芯柱）は、同部材の外側に配設した柱１２、梁１３，
１４よりも剛性が高くしてある。また、水平部材１１
は、鉛直部材１０（芯柱）の外側に配設した柱１２、梁
１３，１４よりも剛性が高い部材であって、鉛直部材１
０の頂部に剛接合してある。 鉛直部材１０と、同部材
１０に集まる各階の梁１３端部との間にダンパ−Ｄが介
装してある。尚、その他の符号は図１，図２と同一であ
る。この構造物Ｂは、中層乃至高層建物やアスペクト比
が大きい建物に好適であって、構造物Ｂに水平力が作用
したとき、このエネルギ−はダンパ−Ｄにより吸収され
ると共に、構造物Ｂの上層部に生じる曲げ変形に抵抗し
て曲げ戻し作用が働くので、従来の同規模のそれと比べ
て上層階の揺れが少なくなり、変形を小さくすることが
できる。This is a case where a high-rigidity horizontal member is installed on the top of the vertical member 1 in the structure A shown in the first embodiment.
That is, the vertical member 10 set at the center of the plane of the structure B
(Core column) are columns 12, beams 13, and
The rigidity is higher than 14. The horizontal member 11
Is a member having higher rigidity than the column 12 and the beams 13 and 14 disposed outside the vertical member 10 (core column).
0 is rigidly connected to the top. A damper D is interposed between the vertical member 10 and the end of the beam 13 of each floor gathered on the vertical member 10. The other reference numerals are the same as those in FIGS. This structure B is suitable for middle to high-rise buildings and buildings with a large aspect ratio. When a horizontal force acts on the structure B, this energy is absorbed by the damper D and the structure B Since the bending-back action acts against the bending deformation generated in the upper layer, the swing of the upper floor is reduced as compared with the conventional one of the same scale, and the deformation can be reduced.

【０００８】[0008]

【発明の実施の形態３】＜ハ＞耐震耐風構造物Ｃ（図４
及び図５，図６） 構造物Ｃは、前記<Embodiment 3><c> Seismic and windproof structure C (FIG. 4)
And FIGS. 5 and 6) The structure C is

【実施の形態１】又はEmbodiment 1 or

【実施の形態２】の各構造物Ａ，Ｂにおける鉛直部材
１，１０に、高剛性の水平部材を複数階毎に設置した場
合である。 即ち、構造物Ｃの平面の中心に設定した鉛
直部材２０（芯柱）は、同部材の外側に配設した柱２
２、梁２３，２４よりも剛性が高くしてある。また、水
平部材２１，３１は、鉛直部材２０（芯柱）の外側に配
設した柱２２、梁２３，２４よりも剛性が高い部材であ
って、鉛直部材２０の頂部に水平部材２１が、複数階お
きに水平部材３１が夫々剛接合してある。鉛直部材２０
と、同部材２０に集まる各階の梁２３端部との間にダン
パ−Ｄが介装してある。尚、その他の符号は図１〜図３
と同一である。この構造物Ｃは、高層乃至超高層建物や
アスペクト比が非常に大きい建物や塔状構造物に好適で
あって、構造物Ｃに水平力にが作用したとき、このエネ
ルギ−はダンパ−Ｄにより吸収されると共に、構造物Ｃ
の上層部及び中層部に生じる変形に抵抗して曲げ戻し作
用が働くので、従来の同規模のそれと比べて上層及び中
層階の揺れが少なくなり、各階の変形を小さくすること
ができる。In this embodiment, a high-rigidity horizontal member is provided for each of a plurality of floors on the vertical members 1 and 10 of each of the structures A and B of the second embodiment. That is, the vertical member 20 (core column) set at the center of the plane of the structure C is the column 2 disposed outside the member.
2. The rigidity is higher than the beams 23 and 24. The horizontal members 21 and 31 are members having higher rigidity than the columns 22 and the beams 23 and 24 disposed outside the vertical member 20 (core column). The horizontal member 21 is provided on the top of the vertical member 20. The horizontal members 31 are rigidly connected to each other on a plurality of floors. Vertical member 20
A damper D is interposed between the member 20 and the end of the beam 23 on each floor gathered on the member 20. Other symbols are shown in FIGS.
Is the same as This structure C is suitable for high-rise or high-rise buildings or buildings having a very large aspect ratio or tower-like structures. When a horizontal force is applied to the structure C, this energy is generated by the damper D. While being absorbed, the structure C
Since the bending-back action acts against the deformation occurring in the upper layer and the middle layer, the swing of the upper and middle floors is reduced as compared with the conventional one of the same scale, and the deformation of each floor can be reduced.

【０００９】各構造物Ａ，Ｂ，Ｃは、平面形状が不整形
（図２）や矩形（図５，図６）の例が示してあるが、円
形、楕円形、或いは多角形でも勿論適用できるものであ
る。Each of the structures A, B, and C has an example in which the planar shape is irregular (FIG. 2) or rectangular (FIGS. 5 and 6). However, a circular shape, an elliptical shape, or a polygonal shape is of course applicable. You can do it.

【００１０】＜ニ＞鉛直部材（図１〜図６） 各鉛直部材１，１０，２０は、同部材１，１０，２０の
外側に配設した柱２，１２，２２よりも高剛性、即ち断
面２次モ−メントや断面係数等の断面性能が著しく大き
い高強度の部材である。例えば、ＲＣ造、ＳＲＣ造、Ｓ
造、ＰＳ造の柱、及びそれらの複合柱、或いはトラス形
式の組立て柱などであって、各構造物Ａ，Ｂ，Ｃにおけ
る芯柱として位置付けされる。<D> Vertical members (FIGS. 1 to 6) Each of the vertical members 1, 10, and 20 has higher rigidity than the columns 2, 12, and 22 disposed outside the members 1, 10, and 20, that is, It is a high-strength member that has a remarkably large cross-sectional performance such as a cross-sectional secondary moment and a section modulus. For example, RC, SRC, S
Pillars, PS pillars, and composite columns thereof, or truss-type assembled pillars, etc., which are positioned as core pillars in each of the structures A, B, and C.

【００１１】各鉛直部材１，１０，２０は前記＜ニ＞の
芯柱に代えて、壁柱、コアウォ−ルなどでもよく、各構
造物Ａ，Ｂ，Ｃにおける壁体として位置付けされる部材
である。（図示省略）Each of the vertical members 1, 10, and 20 may be a wall column, a core wall, or the like instead of the core column of <d>, and is a member positioned as a wall in each of the structures A, B, and C. is there. (Not shown)

【００１２】図示の例では、各芯柱１，１０，２０に集
まる各階の梁３，１３，２３は、４本の場合であるがそ
れに限定せず、例えば構造物の平面形状が円形や楕円形
で、各芯柱１，１０，２０に梁が多数本放射状に集まる
場合にも適用される。（図示省略）In the example shown in the figure, the number of beams 3, 13, and 23 on each floor gathering on each of the core columns 1, 10, and 20 is four, but is not limited thereto. For example, the planar shape of the structure is circular or elliptical. The present invention is also applicable to a case where a large number of beams are radially gathered on each of the core pillars 1, 10, and 20. (Not shown)

【００１３】＜ホ＞水平部材 各水平部材１１，２１，２２は、各芯柱１，１０，２０
の外側に配設した各柱２，１２，２２、梁３，４、１
３，１４、２３，２４よりも高剛性、即ち断面２次モ−
メントや断面係数等の断面性能が著しく大きい高強度の
部材で、例えば鉄筋コンクリ−ト造、鉄骨鉄筋コンクリ
−ト造、鉄骨造、プレストレストコンクリ−ト造の梁
や、トラス梁等のガ−ダ−である。<E> Horizontal Member Each of the horizontal members 11, 21, and 22 includes
Pillars 2, 12, 22 and beams 3, 4, 1
Higher rigidity than 3,14,23,24
High-strength members with remarkably large cross-sectional performance such as element and section modulus. For example, girder such as reinforced concrete, steel-framed reinforced concrete, steel frame, prestressed concrete beam, truss beam, etc. -.

【００１４】＜へ＞ダンパ−Ｄ，Ｅ（図８〜１２） ダンパ−Ｄは、各芯柱１，１０，２０と、同柱に集まる
各梁３，１３，２３の端面との間に介装してあり（図８
〜図１１）、またダンパ−Ｅは、各芯柱１，１０，２０
から張出したブラケット７と、梁３，１３，２３の端部
下端との間に介装してある（図１１，図１２）。これに
よって、各構造物Ａ，Ｂ，Ｃに水平力が作用したとき、
エネルギ−が吸収されるので揺れが少なくなる。図１１
に示すダンパ−Ｄ，Ｅは、夫々小型化して梁３，１３，
２３の端面及び端部下端に配設したので、大きな外力に
対応できる上、狭い空間でも据付けることができ経済的
である。尚、ダンパ−Ｄ，Ｅは同種又は異種の装置を用
いることができる。<F> Dampers D, E (FIGS. 8 to 12) The dampers D are provided between the core pillars 1, 10, 20 and the end faces of the beams 3, 13, 23 gathering on the pillars. (Fig. 8
To FIG. 11), and the damper E is provided for each of the core columns 1, 10, and 20.
It is interposed between the bracket 7 protruding from the lower end and the lower ends of the ends of the beams 3, 13, and 23 (FIGS. 11 and 12). Thus, when a horizontal force acts on each of the structures A, B, and C,
Since the energy is absorbed, the swing is reduced. FIG.
The dampers D and E shown in FIG.
Since it is arranged at the end face and the lower end of the end 23, it can cope with a large external force and can be installed in a narrow space, which is economical. The dampers D and E may be of the same or different types.

【００１５】ダンパ−Ｄ，Ｅは、各構造物Ａ，Ｂ，Ｃの
振動性状に応じて下記のタイプを選択することができ
る。 （ａ）板ばねダンパ− （ｂ）コイルばねダンパ− （ｃ）硬質ゴムダンパ− （ｄ）金属板積層ゴムダンパ− （ｅ）エアダンパ−（エアチュ−ブ） （ｆ）粘性体ダンパ−（オイル又は水をチュ−ブに封
入）The following types of dampers D and E can be selected according to the vibration characteristics of each of the structures A, B and C. (A) Leaf spring damper (b) Coil spring damper (c) Hard rubber damper (d) Laminated rubber damper for metal plate (e) Air damper (air tube) (f) Viscous material damper (oil or water (Enclosed in tube)

【００１６】＜ト＞鉛直部材周りの床版５の縁切り機構
（図７） 芯柱１，１０，２０の周囲の床５はクリアランス１５を
設けて縁切りしてある。クリアランス１５を設けたこと
によって、構造物Ａ，Ｂ，Ｃは、水平力を受けたとき、
ダンパ−Ｄ，Ｅの変形分だけ水平変形してその変形量を
吸収する。尚、クリアランス１５は弾性材料により充填
する。<G> Trimming mechanism of the floor slab 5 around the vertical member (FIG. 7) The floor 5 around the core pillars 1, 10, 20 is trimmed by providing a clearance 15. When the clearances 15 are provided, the structures A, B, and C receive a horizontal force.
The horizontal deformation is performed by the deformation of the dampers D and E, and the deformation is absorbed. The clearance 15 is filled with an elastic material.

【００１７】＜チ＞梁のスライド機構６（図８〜１２） スライド機構６は、各構造物Ａ，Ｂ，Ｃの鉛直部材１，
１０，２０から張出したブラケット７と、鉛直部材１，
１０，２０に集まる梁３，１３，２３との間に設置して
ある。これにより各構造物Ａ，Ｂ，Ｃは、ダンパ−Ｄ，
Ｅの変形量だけ移動する。尚、以上の説明による変形量
は、ダンパ−Ｄ，Ｅによってエネルギ−吸収されるので
極めて微小であり、建物の居住性を損なうことは全くな
い。<H> Beam slide mechanism 6 (FIGS. 8 to 12) The slide mechanism 6 includes a vertical member 1 for each of the structures A, B and C.
Bracket 7 extending from 10, 20 and vertical member 1,
It is installed between the beams 3, 13 and 23 gathering at 10 and 20. As a result, each of the structures A, B, and C becomes a damper D,
Move by the amount of deformation of E. The amount of deformation according to the above description is extremely small because the energy is absorbed by the dampers D and E, and does not impair the livability of the building at all.

【００１８】図８に示すスライド機構６は、摩擦係数の
小さい滑り板１６を２枚（１枚でも可）介装した場合で
ある。The slide mechanism 6 shown in FIG. 8 is a case in which two (even one) slide plates 16 having a small coefficient of friction are interposed.

【００１９】図９及び図１１，図１２に示すスライド機
構６は、滑り支承体２６をブラケット７と梁３，１３，
２３との間に設置した場合で、支承体２６は梁３と固着
してあり、ブラケット７上を滑動する。The slide mechanism 6 shown in FIGS. 9, 11 and 12 comprises a sliding support 26 which includes a bracket 7 and beams 3, 13,.
23, the bearing 26 is fixed to the beam 3 and slides on the bracket 7.

【００２０】図１０に示すスライド機構６は台車の例で
あるが、ベアリングやころ等により滑動するロ−ラ−支
承３６としてもよい。Although the slide mechanism 6 shown in FIG. 10 is an example of a bogie, it may be a roller bearing 36 which slides with a bearing or a roller.

【００２１】[0021]

【発明の効果】本発明の耐震耐風構造物は、以上説明し
たようになるから次のような効果を得ることができる。 （１）鉛直部材は、同部材の外側に配設する柱、梁より
も剛性が高い部材であり、構造物の平面の略中心位置に
前記鉛直部材を設定し、鉛直部材と、同部材に集まる各
階の梁端部との間にダンパ−を介装し、水平方向にスラ
イド可能に接続したことによって、 ＜イ＞構造物に作用する地震や風のエネルギ−が著しく
吸収されるので、従来の構造物と比べて揺れが少なくな
り、従って変形を小さくすることができる。 ＜ロ＞その結果、本発明の構造物の各階の柱梁材は、従
来のそれと比べて重量低減が可能となるので、合理的且
つ経済的な構造物の設計・構築ができる。 ＜ハ＞大きな外力に対しても構造物の安全性が飛躍的に
向上する。 ＜ニ＞構造物の外周や空間内に壁やブレ−ス材などの耐
震要素が激減するので、従来の構造物と比べて居住性に
優れる。 ＜ホ＞制御装置などによる特別な操作を必要としないの
で、ランニングコストがかからない。 （２）前記（１）の構造物において、鉛直部材の頂部
に、同部材の外側に配設する柱、梁よりも剛性が高い水
平部材を剛接合したことによって、前記（１）と同様の
効果が得られるほか、＜イ＞構造物に外力が作用したと
き、このエネルギ−はダンパ−により吸収されると共
に、構造物の上層部に生じる曲げ変形に抵抗して曲げ戻
し作用が働くので、従来の同規模のそれと比べて上層階
の揺れが少なくなり、変形を小さくすることができる。 （３）前記（１）又は（２）の構造物において、鉛直部
材に、同部材の外側に配設する柱、梁よりも剛性が高い
水平部材を、複数層毎に剛接合したことによって、上記
（１）及び（２）と同様の効果がえられるほか、＜イ＞
構造物に水平力にが作用したとき、このエネルギ−はダ
ンパ−により吸収されると共に、構造物の上層部及び中
層部に生じる変形に抵抗して曲げ戻し作用が働くので、
従来の同規模のそれと比べて上層及び中層階の揺れが少
なくなり、各階の変形を小さくすることができる。The seismic and windproof structure according to the present invention has the following effects. (1) The vertical member is a member having higher rigidity than columns and beams provided outside the member, and the vertical member is set at substantially the center of the plane of the structure, and the vertical member and the member By installing a damper between the beam end of each floor and the slidable connection in the horizontal direction, <a> seismic and wind energy acting on the structure is remarkably absorbed. As compared with the structure of the above, the shaking is reduced, so that the deformation can be reduced. <B> As a result, the weight of the column and beam material on each floor of the structure of the present invention can be reduced as compared with that of the related art, so that a rational and economical structure can be designed and constructed. <C> The safety of the structure is dramatically improved even with a large external force. <D> Seismic elements such as walls and bracing material are drastically reduced on the outer periphery and in the space of the structure, so that the structure is more comfortable than conventional structures. <E> Since no special operation is required by the control device or the like, no running cost is required. (2) In the structure of the above (1), a horizontal member having higher rigidity than a column or a beam disposed outside the vertical member is rigidly joined to the top of the vertical member, thereby providing the same structure as the above (1). In addition to the effect obtained, <i> When an external force acts on the structure, this energy is absorbed by the damper, and a bending-back action acts against the bending deformation generated in the upper layer of the structure. Compared with the conventional one of the same scale, the swing of the upper floor is reduced, and the deformation can be reduced. (3) In the structure according to the above (1) or (2), a horizontal member having higher rigidity than columns and beams arranged outside the member is rigidly joined to the vertical member for each of a plurality of layers. The same effects as in the above (1) and (2) are obtained.
When a horizontal force acts on the structure, this energy is absorbed by the damper, and a bending-back action acts against the deformation generated in the upper and middle layers of the structure.
The swing of the upper and middle floors is reduced as compared with the conventional one of the same scale, and the deformation of each floor can be reduced.

【図面の簡単な説明】[Brief description of the drawings]

【図１】 本発明に係る、耐震耐風構造物の実施形態１
を示す側面図（図２のａ−ａ視）FIG. 1 shows a first embodiment of an earthquake-resistant and wind-resistant structure according to the present invention.
Side view showing (a-a view of FIG. 2)

【図２】 図１の平面図FIG. 2 is a plan view of FIG. 1;

【図３】 本発明に係る、耐震耐風構造物の実施形態２
を示す側断面図（図５及び図６のｂ−ｂ視）FIG. 3 is a second embodiment of the earthquake-resistant and wind-resistant structure according to the present invention.
FIG. 5 is a side cross-sectional view (a bb view in FIGS. 5 and 6).

【図４】 本発明に係る、耐震耐風構造物の実施形態３
を示す側断面図（図５及び図６のｂ−ｂ視）FIG. 4 is an embodiment 3 of an earthquake-resistant windproof structure according to the present invention.
FIG. 5 is a side cross-sectional view (a bb view in FIGS. 5 and 6).

【図５】 図３又は図４における基準階平面図FIG. 5 is a plan view of a reference floor in FIG. 3 or FIG.

【図６】 図３又は図４における高剛性水平部材を設置
した階の平面図FIG. 6 is a plan view of a floor on which the high-rigidity horizontal member shown in FIG. 3 or 4 is installed.

【図７】 ダンパ−を設置した状況を示す平面図FIG. 7 is a plan view showing a situation where a damper is installed.

【図８】 ダンパ−及びスライド機構の設置例１示す側
面図FIG. 8 is a side view showing an installation example 1 of a damper and a slide mechanism.

【図９】 ダンパ−及びスライド機構の設置例２示す側
面図FIG. 9 is a side view showing an installation example 2 of a damper and a slide mechanism.

【図１０】ダンパ−及びスライド機構の設置例３示す側
面図FIG. 10 is a side view showing an installation example 3 of a damper and a slide mechanism.

【図１１】ダンパ−及びスライド機構の設置例４示す側
面図FIG. 11 is a side view showing an installation example 4 of a damper and a slide mechanism.

【図１２】ダンパ−及びスライド機構の設置例５示す側
面図FIG. 12 is a side view showing an installation example 5 of a damper and a slide mechanism.

───────────────────────────────────────────────────── フロントページの続き (72)発明者 鈴木 悦郎 神奈川県川崎市中原区今井南町441 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Etsuo Suzuki 441 Imai Minamicho, Nakahara-ku, Kawasaki-shi, Kanagawa

Claims (7)

【特許請求の範囲】[Claims] 【請求項１】鉛直部材は、同部材の外側に配設する柱、
梁よりも剛性が高い部材であり、 同鉛直部材を構造物の平面の略中心位置に設定し、 鉛直部材と、同部材に集まる各階の梁端部との間にダン
パ−を介装して接続したことを特徴とする、 耐震耐風構造物。The vertical member includes a column disposed outside the member.
It is a member that is higher in rigidity than the beam, and the vertical member is set at approximately the center of the plane of the structure, and a damper is interposed between the vertical member and the beam end of each floor gathered in the member. A seismic and windproof structure characterized by being connected. 【請求項２】請求項１に記載の耐震耐風構造物におい
て、 鉛直部材に、同部材の外側に配設する柱、梁よりも剛性
が高い水平部材を剛接合したことを特徴とする、 耐震耐風構造物。2. The earthquake-resistant wind-resistant structure according to claim 1, wherein a horizontal member having rigidity higher than columns and beams disposed outside the vertical member is rigidly connected to the vertical member. Wind resistant structure. 【請求項３】請求項２に記載の耐震耐風構造物におい
て、 鉛直部材の頂部に、同部材の外側に配設する柱、梁より
も剛性が高い水平部材を剛接合したことを特徴とする、 耐震耐風構造物。3. A seismic and windproof structure according to claim 2, wherein a horizontal member having a higher rigidity than columns and beams disposed outside the vertical member is rigidly connected to a top of the vertical member. , Seismic and windproof structures. 【請求項４】請求項２に記載の耐震耐風構造物におい
て、 鉛直部材に、同部材の外側に配設する柱、梁よりも剛性
が高い水平部材を、複数層毎に剛接合したことを特徴と
する、 耐震耐風構造物。4. The earthquake-resistant and wind-resistant structure according to claim 2, wherein the vertical member is rigidly connected to a horizontal member having a higher rigidity than columns and beams disposed outside the member, for each of a plurality of layers. Characterized as an earthquake-resistant and wind-resistant structure. 【請求項５】請求項１乃至４のいずれかに記載の耐震耐
風構造物において、 鉛直部材に、同部材に集まる梁を水平方向にスライド可
能に接続したことを特徴とする、 耐震耐風構造物。5. An anti-seismic wind-resistant structure according to claim 1, wherein a beam converging on the vertical member is connected to the vertical member so as to be slidable in a horizontal direction. . 【請求項６】請求項１乃至５のいずれかに記載の耐震耐
風構造物において、 鉛直部材は芯柱又は壁体であることを特徴とする、 耐震耐風構造物。6. An anti-seismic wind-resistant structure according to claim 1, wherein the vertical member is a pillar or a wall. 【請求項７】請求項１乃至６のいずれかに記載の耐震耐
風構造物において、 床板は、鉛直部材に対して水平方向にスライド可能に構
成したことを特徴とする、 耐震耐風構造物。7. The aseismic wind-resistant structure according to claim 1, wherein the floor plate is configured to be slidable in a horizontal direction with respect to a vertical member.