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JP7661144B2 - Bearing and vibration control systems - Google Patents
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JP7661144B2 - Bearing and vibration control systems - Google Patents

Bearing and vibration control systems Download PDF

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JP7661144B2
JP7661144B2 JP2021100139A JP2021100139A JP7661144B2 JP 7661144 B2 JP7661144 B2 JP 7661144B2 JP 2021100139 A JP2021100139 A JP 2021100139A JP 2021100139 A JP2021100139 A JP 2021100139A JP 7661144 B2 JP7661144 B2 JP 7661144B2
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support portion
long hole
reinforcing member
support
movable plate
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JP2022191732A (en
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明徳 中川
進之介 北原
義文 杉村
幹夫 鈴木
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NTT Facilities Inc
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Description

本発明は、例えば鉛直支持力が大きく水平抵抗が小さい支承およびこれを備えた制振システムに関する。 The present invention relates to a bearing that has, for example, high vertical support force and low horizontal resistance, and a vibration control system equipped with the same.

従来、構造物を支持する支承および制振システムとして、制振材に粘弾性体を用いたものが知られている(例えば、特許文献1参照)。
特許文献1に記載された制振装置では、構造物の層の空間を形成して対向する一対の柱にそれぞれ制振構造を設置し、これら一対の制振構造の間に接合材が架け渡されている。
2. Description of the Related Art Conventionally, as a bearing and vibration control system for supporting a structure, there is known one that uses a viscoelastic body as a vibration control material (see, for example, Patent Document 1).
In the vibration control device described in Patent Document 1, a pair of opposing columns form a space between layers of a structure, and vibration control structures are respectively installed on the pair of columns, with a bonding material spanning between the pair of vibration control structures.

この制振構造は、柱の側面に取り付けられた柱側取付部材と、接合材側取付部材との間に制振材が挟み込まれ、2つの取付部材と制振材とが接着されている。
制振材は、接合材側取付部材と柱側取付部材とが水平軸線回りに相対回転可能となるよう粘弾性体で形成され、地震発生時等には相対回転に伴うねじれ変形によって建物の振動エネルギーが吸収される。
しかし、制振材は、柱側取付部材と接合材側取付部材とに接着されているので、制振構造の水平抵抗は大きい。
In this vibration-damping structure, a vibration-damping material is sandwiched between a column-side mounting member attached to the side surface of a column and a joining material-side mounting member, and the two mounting members and the vibration-damping material are bonded together.
The vibration-damping material is made of a viscoelastic material so that the joining material side mounting member and the column side mounting member can rotate relatively around a horizontal axis, and in the event of an earthquake, the vibration energy of the building is absorbed by the torsional deformation associated with the relative rotation.
However, since the vibration-damping material is bonded to the column-side mounting member and the joining material-side mounting member, the horizontal resistance of the vibration-damping structure is large.

水平方向に相対移動可能で、水平抵抗が小さくされた支承として、構造物の対向する2本の柱の各支持部に補強部材の両端部を支持するものが知られている(例えば、特許文献2参照)。
柱の支持部には長孔等のルーズホールが設けられ、ルーズホールと補強部材とに締結ボルト等のピンが通されている。構造物が振動して柱が梁と共に水平方向に往復運動すると、補強部材も水平方向に往復移動し、柱の両端を貫通するピンが支持部の長孔に対して相対移動する。
A known support that is relatively movable in the horizontal direction and has low horizontal resistance is one in which both ends of a reinforcing member are supported on the support parts of two opposing columns of a structure (see, for example, Patent Document 2).
A loose hole such as a long hole is provided in the support part of the column, and a pin such as a fastening bolt is passed through the loose hole and the reinforcing member. When the structure vibrates and the column reciprocates horizontally together with the beam, the reinforcing member also reciprocates horizontally, and the pin that passes through both ends of the column moves relative to the long hole in the support part.

特開2011-64024号公報JP 2011-64024 A 特開2021-21310号公報JP 2021-21310 A

しかし、特許文献2の構造では、ピンと長孔との接点における支圧応力度が大きくなり、大きな鉛直荷重が作用する支承に採用する際の課題が残る。
本発明は、第一の方向の支持力を大きく、且つ第一の方向と交差する第二の方向の抵抗をより小さくすることが可能な支承および制振システムを提供することを目的とする。
However, in the structure of Patent Document 2, the bearing stress at the contact point between the pin and the long hole becomes large, and problems remain when using it for a support where a large vertical load acts.
SUMMARY OF THE PRESENT EMBODIMENT An object of the present invention is to provide a bearing and vibration control system that can provide a large support force in a first direction and a smaller resistance in a second direction that intersects the first direction.

本発明による支承は、構造物および前記構造物に連結する部材の一方における第一支持部に設けられた長孔形成部と、前記構造物および前記部材の他方における第二支持部に設けられた軸受と、前記長孔形成部が形成する長孔に挿入され、前記長孔内を前記長孔の長手方向に移動可能な可動板と、前記第一支持部に対して前記可動板とともに前記長孔の長手方向に移動可能に支持されるとともに、前記第二支持部に対して前記軸受を介して回動可能に支持されて、前記第一支持部および前記第二支持部を連結する軸と、を備えることを特徴とする。 The support according to the present invention is characterized by comprising: a long hole forming portion provided in a first support portion of one of a structure and a member connected to the structure; a bearing provided in a second support portion of the other of the structure and the member; a movable plate that is inserted into a long hole formed by the long hole forming portion and is movable within the long hole in the longitudinal direction of the long hole; and a shaft that is supported by the first support portion so as to be movable together with the movable plate in the longitudinal direction of the long hole, and is supported by the second support portion via the bearing so as to be rotatable, connecting the first support portion and the second support portion.

この構成によれば、地震や強風等によって構造物が振動した際、第一支持部及び第二支持部が相対変位しても、両支持部同士を連結する軸は、第一支持部に対して可動板とともに長孔内を移動するので、長孔の長手方向における第一支持部及び第二支持部の相対変位が許容される。このとき、第一支持部及び第二支持部の相対変位によってこれらの相対回動が生じる場合にも、軸が軸受を介してスムーズに回動するので、回動を含む相対変位が良好に許容される。また、可動板が長孔の内面に面又は複数の点により接触する構成とすることで、可動板から長孔の内面に作用する荷重を分散させて接触圧を抑え、第一支持部及び第二支持部の相対変位をより良好に許容することができる。一方、長孔の長手方向と交差する方向においては、可動板および軸受を介して十分な支持荷重を受けることができる。 According to this configuration, even if the first support part and the second support part are displaced relative to each other when the structure vibrates due to an earthquake, strong wind, etc., the shaft connecting the two support parts moves inside the long hole together with the movable plate relative to the first support part, so the relative displacement of the first support part and the second support part in the longitudinal direction of the long hole is permitted. At this time, even if the relative displacement of the first support part and the second support part causes relative rotation, the shaft rotates smoothly via the bearing, so that the relative displacement including rotation is permitted well. In addition, by configuring the movable plate to contact the inner surface of the long hole at a surface or multiple points, the load acting from the movable plate on the inner surface of the long hole can be dispersed to suppress the contact pressure, and the relative displacement of the first support part and the second support part can be permitted well. On the other hand, in the direction intersecting the longitudinal direction of the long hole, a sufficient support load can be received via the movable plate and the bearing.

また、前記軸受は、前記軸を回動可能に支持するとともに、前記軸を揺動可能に支持することが好ましい。
この構成によれば、第一支持部及び第二支持部の相対変位によってこれらの相対揺動が生じる場合にも、軸が軸受を介して揺動可能であるので、揺動を含む相対変位が良好に許容される。長孔の長手方向への軸の移動と、軸受による軸の回動および揺動とが分離して行われるので、前者の移動と後者の回動および揺動とが互いに影響を受けにくい。よって第一支持部及び第二支持部の相対変位をより一層良好に許容することができる。
It is also preferable that the bearing rotatably supports the shaft and swingably supports the shaft.
According to this configuration, even when the relative swinging occurs due to the relative displacement of the first support part and the second support part, the shaft can swing via the bearing, so the relative displacement, including swinging, is well tolerated. Since the movement of the shaft in the longitudinal direction of the long hole and the rotation and swinging of the shaft by the bearing are performed separately, the former movement and the latter rotation and swing are less likely to affect each other. Therefore, the relative displacement of the first support part and the second support part can be tolerated even better.

また、前記長孔は、長手方向が水平方向を指向することが好ましい。
この構成によれば、地震や強風等によって構造物が水平方向に振動した際にも、第一支持部及び第二支持部の水平方向の相対変位を良好に許容することができる。なお、前記「水平方向を指向する」とは、水平方向に一致することに限らず、例えば水平方向に対して±30度程度の範囲を含む。
It is also preferable that the longitudinal direction of the slot is oriented horizontally.
According to this configuration, it is possible to satisfactorily tolerate the relative horizontal displacement of the first support part and the second support part even when the structure vibrates in the horizontal direction due to an earthquake, strong wind, etc. Note that the term "oriented in the horizontal direction" does not necessarily mean coinciding with the horizontal direction, but includes, for example, a range of about ±30 degrees with respect to the horizontal direction.

また、前記長孔は、互いに平行をなして対向する第一内面および第二内面を有し、前記可動板は、前記第一内面および前記第二内面にそれぞれ内接又は近接した状態で、前記長孔内を移動することが好ましい。
この構成によれば、長孔の各内面と交差する方向への可動板の移動を規制するとともに、可動板のスムーズな移動を実現することができる。長孔を矩形等の単純形状とすることで、長孔形成部の加工を容易にすることができる。
It is also preferable that the long hole has a first inner surface and a second inner surface which are parallel and opposed to each other, and the movable plate moves within the long hole while being inscribed in or in close proximity to the first inner surface and the second inner surface, respectively.
According to this configuration, it is possible to restrict the movement of the movable plate in a direction intersecting with each inner surface of the long hole, and to realize smooth movement of the movable plate. By forming the long hole in a simple shape such as a rectangle, it is possible to easily process the long hole forming portion.

また、前記可動板は、面又は複数の点により前記第一内面および前記第二内面の少なくとも一方に接した状態で、前記長孔内を移動することが好ましい。
この構成によれば、可動板から長孔の内面に伝わる荷重を分散させて接触圧を抑え、第一支持部及び第二支持部の相対変位をより良好に許容することができる。
It is also preferable that the movable plate moves within the long hole while being in contact with at least one of the first inner surface and the second inner surface at a surface or a plurality of points.
According to this configuration, the load transmitted from the movable plate to the inner surface of the long hole can be dispersed to suppress the contact pressure, and the relative displacement of the first support portion and the second support portion can be more satisfactorily tolerated.

また、前記長孔と前記可動板との接触部分に潤滑剤が塗布されることが好ましい。
この構成によれば、可動板が長孔内を移動する際の抵抗をより一層小さくし、第一支持部及び第二支持部の相対変位をより良好に許容することができる。
It is also preferable that a lubricant be applied to the contact portion between the slot and the movable plate.
According to this configuration, the resistance when the movable plate moves inside the long hole can be further reduced, and the relative displacement of the first support portion and the second support portion can be more satisfactorily tolerated.

また、前記第一支持部および前記第二支持部の少なくとも一方に設けられ、前記軸の軸方向で前記第一支持部および前記第二支持部の他方を滑り可能に押圧する拘束部材を備え、前記拘束部材は、前記第一支持部および前記第二支持部の前記軸方向の相対位置を拘束することが好ましい。
この構成によれば、長孔内の軸の移動への影響を抑えた上で、第一支持部および第二支持部の位置調整や施工誤差吸収を可能とすることができる。
It is also preferable that a restraining member is provided on at least one of the first support portion and the second support portion and slidably presses the other of the first support portion and the second support portion in the axial direction of the shaft, and the restraining member restrains the relative positions of the first support portion and the second support portion in the axial direction.
According to this configuration, it is possible to adjust the positions of the first support portion and the second support portion and absorb construction errors while suppressing the effect on the movement of the shaft within the long hole.

また、前記第一支持部および前記第二支持部の少なくとも一方における前記拘束部材に押圧される被押圧部と、前記拘束部材の押圧部との少なくとも一方に、低摩擦部を備えることが好ましい。
この構成によれば、拘束部材によって第一支持部および第二支持部の少なくとも一方に押圧力を付与しながら、第一支持部および第二支持部の相対変位への影響を抑えることができる。
It is also preferable that at least one of a pressed portion of at least one of the first support portion and the second support portion, which is pressed by the restraining member, and a pressing portion of the restraining member, is provided with a low friction portion.
According to this configuration, it is possible to suppress the effect on the relative displacement of the first support portion and the second support portion while applying a pressing force to at least one of the first support portion and the second support portion by the restraining member.

本発明による制振システムは、層を成す建造物の制振システムであって、前記建造物の層における層間に設けられ、前記第一支持部および前記第二支持部の一方が設けられた第一部材と、前記第一部材に連結され、前記第一支持部および前記第二支持部の他方が設けられた第二部材と、前記第二部材に設置されたブレース部材と、前記第二部材に対向する梁と前記ブレース部材との間に設けられて水平方向の振動を減衰させる制振ダンパーと、上記何れかに記載の前記支承と、を備えることを特徴とする。
また、前記第二部材は、水平方向に延びて前記構造物に連結する部材であり、前記第二部材の長さ方向両端部は、前記長孔の長手方向が水平方向を指向した前記支承を介して前記構造物に連結され、前記第二部材の長さ方向中間部は、前記長孔の長手方向が鉛直方向を指向した前記支承を介して前記構造物に連結されることを特徴とする。
この構成によれば、構造物に水平方向の振動が発生したとしても、この振動を制振ダンパーで減衰させるとともに、制振ダンパーの反力を第一支持部および第二支持部の相対変位の範囲内で吸収可能となり、構造物の層間の第一部材に前記反力が伝達されにくくすることができる。
The vibration control system according to the present invention is a vibration control system for a building having layers, comprising: a first member provided between layers of the building and having one of the first support part and the second support part; a second member connected to the first member and having the other of the first support part and the second support part; a brace member installed on the second member; a vibration control damper provided between a beam facing the second member and the brace member to damp horizontal vibrations; and any of the supports described above.
The second member is a member that extends horizontally and connects to the structure, and both longitudinal ends of the second member are connected to the structure via the support in which the longitudinal direction of the long hole is oriented horizontally, and the longitudinal middle portion of the second member is connected to the structure via the support in which the longitudinal direction of the long hole is oriented vertically.
With this configuration, even if horizontal vibrations occur in the structure, the vibrations can be damped by the vibration damper, and the reaction force of the vibration damper can be absorbed within the range of relative displacement between the first support part and the second support part, making it difficult for the reaction force to be transmitted to the first member between the layers of the structure.

本発明によれば、第一の方向の支持力(例えば鉛直支持力)を大きく、且つ第一の方向と交差する第二の方向の抵抗(例えば水平抵抗)をより小さくすることが可能な支承および制振システムを提供することができる。 The present invention provides a support and vibration control system that can increase the support force in a first direction (e.g., vertical support force) and reduce the resistance in a second direction that intersects the first direction (e.g., horizontal resistance).

本発明の実施形態による制振システムを構造物の層間の架構に取り付けた状態の要部説明図である。1 is an explanatory diagram of a main part of a vibration control system according to an embodiment of the present invention attached to a frame between layers of a structure. 上記制振システムの支承を示す説明図である。FIG. 2 is an explanatory diagram showing a support of the vibration control system. 図2のIII-III線断面図である。3 is a cross-sectional view taken along line III-III in FIG. 2. 図3のIV-IV線断面図である。FIG. 4 is a cross-sectional view taken along line IV-IV in FIG. 図4のK部拡大図である。FIG. 5 is an enlarged view of a portion K in FIG. 4 . 上記支承による一方向の回動を示す作用説明図である。13 is an explanatory diagram showing the rotation in one direction caused by the support. FIG. 上記支承による他方向の回動を示す作用説明図である。13 is an explanatory diagram showing the rotation in another direction caused by the support. FIG. 上記支承による水平方向一側の変位を示す作用説明図である。FIG. 11 is an explanatory diagram showing the displacement of one side in the horizontal direction by the support. 上記支承による水平方向他側の変位を示す作用説明図である。13 is an explanatory diagram showing the displacement of the other side in the horizontal direction by the support. FIG. 上記支承による回動及び水平方向の変位を示す作用説明図である。11 is an explanatory diagram showing the rotation and horizontal displacement caused by the support. FIG. 図3に相当する断面図であり、上記支承の拘束部材による水平方向一側への位置調整の作用を示す。FIG. 4 is a cross-sectional view corresponding to FIG. 3, showing the effect of adjusting the position of the support to one side in the horizontal direction by the restraining member. 図3に相当する断面図であり、上記支承の拘束部材による水平方向他側への位置調整の作用を示す。FIG. 4 is a cross-sectional view corresponding to FIG. 3, showing the effect of adjusting the position of the support to the other side in the horizontal direction by the restraining member. 図2に相当する説明図であり、上記支承に生じる付加曲げモーメントの作用を示す。FIG. 3 is an explanatory diagram corresponding to FIG. 2, showing the action of an additional bending moment generated in the support. 図5に相当する拡大図であり、上記支承の長孔の第一変形例を示す。FIG. 6 is an enlarged view corresponding to FIG. 5, showing a first variant of the elongated hole of the bearing. 図5に相当する拡大図であり、上記支承の長孔の第二変形例を示す。FIG. 6 is an enlarged view corresponding to FIG. 5, showing a second variant of the elongated hole of the bearing. 図3に相当する断面図であり、上記拘束部材の変形例を示す。FIG. 4 is a cross-sectional view corresponding to FIG. 3, showing a modified example of the restraining member. 図1に相当する説明図であり、上記制振システムの変形例を示す。FIG. 2 is an explanatory diagram corresponding to FIG. 1, showing a modified example of the vibration damping system.

<制振装置>
以下、本発明の実施形態の支承Sを備えた制振装置(制振システム)1について添付図面を参照して説明する。
図1に示す制振装置1は、例えば、鉄筋コンクリート造の構造物BLの下層部の層間の架構に取り付けられている。
なお、制振装置1の設置箇所は下層部に限らず上層部等、任意の層(階)に設置してもよい。制振装置1は、構造物BLの架構の相対変位可能な任意の二層間の開口部である空間2に配置されている。構造物BLは、例えば、1フロアの左右の柱(第一部材)P1,P2と、上下の梁Q1,Q2と、で仕切られた空間2を上下左右に多数有している。
<Vibration control device>
Hereinafter, a vibration control device (vibration control system) 1 including a bearing S according to an embodiment of the present invention will be described with reference to the accompanying drawings.
The vibration damping device 1 shown in FIG. 1 is attached to, for example, an inter-story frame in the lower part of a reinforced concrete structure BL.
The vibration control device 1 may be installed on any floor (story) including the upper floor and not limited to the lower floor. The vibration control device 1 is disposed in a space 2 which is an opening between any two floors where the framework of the structure BL can be displaced relative to one another. The structure BL has many spaces 2 on the top, bottom, left and right sides, partitioned by, for example, left and right columns (first members) P1, P2 and top and bottom beams Q1, Q2 on one floor.

例えば、空間2内において、対向する柱P1,P2の各上端部の内面3には、柱側支持部(第二支持部)5が締結ボルト(不図示)等で固定されている。柱側支持部5は、例えば、上下に延びる平行な一対の板材で形成されている。
また、空間2の上側の梁Q1における下側の梁Q2に対向する面(下面)は、第一構面6とされ、下側の梁Q2の上側の面(上面)は、第二構面4とされている。
For example, in the space 2, a column-side support part (second support part) 5 is fixed to the inner surface 3 of each upper end part of the opposing columns P1, P2 by a fastening bolt (not shown) or the like. The column-side support part 5 is formed of, for example, a pair of parallel plate members extending vertically.
In addition, the surface (lower surface) of the upper beam Q1 in the space 2 that faces the lower beam Q2 is the first structural surface 6, and the upper surface (upper surface) of the lower beam Q2 is the second structural surface 4.

上側の梁Q1の第一構面6側には、例えば、断面矩形の角筒状を成す鋼材からなる補強部材(第二部材)7が配置されている。第一構面6の長手方向中間部(中央部を含ぬ幅をもつ範囲、以下同様)には、断面視略U字状の上受け部8が固定されている。補強部材7は、その一部が第一構面6側に拡幅する拡幅部7aを備え、この拡幅部7aが上受け部8内に挿入されている。補強部材7は、拡幅部7aの位置で上受け部8に設けられた上部ピン10を中心に揺動可能に支持されている。 On the first structural surface 6 side of the upper beam Q1, for example, a reinforcing member (second member) 7 made of steel material having a rectangular cross-section is arranged. An upper support portion 8 having a generally U-shaped cross section is fixed to the longitudinal middle portion (a range having a width not including the center, the same applies below) of the first structural surface 6. The reinforcing member 7 has a widening portion 7a, a part of which widens toward the first structural surface 6 side, and this widening portion 7a is inserted into the upper support portion 8. The reinforcing member 7 is supported so that it can swing about an upper pin 10 provided on the upper support portion 8 at the position of the widening portion 7a.

補強部材7の両端部には、柱側支持部5の内側に配置された補強部材側支持部(第一支持部)11が固定されている。補強部材側支持部11は、例えば、上下方向に延びる板状に形成されている。
柱P1,P2のそれぞれの柱側支持部5には、補強部材側支持部11が支承Sを介して上下方向・左右方向に揺動可能および水平方向に移動可能に支持されている。
A reinforcing-member-side support portion (first support portion) 11 arranged inside the column-side support portion 5 is fixed to both ends of the reinforcing member 7. The reinforcing-member-side support portion 11 is formed, for example, in a plate shape extending in the vertical direction.
A reinforcing member side support portion 11 is supported on each of the pillar side support portions 5 of the pillars P1, P2 via supports S so as to be swingable in the vertical and horizontal directions and movable in the horizontal direction.

上記したように、層を成す構造物BLの制振装置1は、構造物BLの層における層間に設けられた柱P1,P2と、柱P1,P2に連結された補強部材7と、補強部材7に設置されたV字ブレース(ブレース部材)30と、を備えている。また、制振装置1は、補強部材7に対向する梁Q2とV字ブレース30との間に設けられて水平方向の振動を減衰させる制振ダンパー35と、支承Sと、を備えている。 As described above, the vibration control device 1 for the layered structure BL includes columns P1 and P2 provided between the layers of the structure BL, reinforcing members 7 connected to the columns P1 and P2, and a V-shaped brace (brace member) 30 installed on the reinforcing member 7. The vibration control device 1 also includes a vibration damper 35 provided between the beam Q2 facing the reinforcing member 7 and the V-shaped brace 30 to damp horizontal vibrations, and a support S.

図2および図3に示すように、柱側支持部5は、一対の軸支持部13で構成され、これら一対の軸支持部13の間に、補強部材側支持部11が配置されている。
一対の軸支持部13と補強部材側支持部11とは、連結軸(軸)14が貫通している。
軸支持部13は、上下に延びる柱側支持板16と、柱側支持板16に形成された長孔16a内に移動可能に配置された可動板17と、可動板17が柱側支持板16の長孔16aから抜けないようにする一対の可動板抜け防止部材18と、を備えている。
As shown in Figures 2 and 3, the column side support part 5 is composed of a pair of shaft support parts 13, and the reinforcing member side support part 11 is disposed between this pair of shaft support parts 13.
A connecting shaft (shaft) 14 passes through the pair of shaft support portions 13 and the reinforcing member side support portion 11 .
The shaft support portion 13 comprises a column side support plate 16 extending vertically, a movable plate 17 movably arranged within a long hole 16a formed in the column side support plate 16, and a pair of movable plate slip-out prevention members 18 that prevent the movable plate 17 from slipping out of the long hole 16a of the column side support plate 16.

柱側支持板16は、その略中央部に長孔形成部16bを備え、この長孔形成部16bに長孔16aが形成されている。長孔16aの周縁部は、長孔形成部16bを含んでいる。可動板17には、連結軸14が貫通する軸貫通孔17aが形成されている。軸貫通孔17aと連結軸14とのはめあいは、すきまばめ、しまりばめの何れであっても良い。また、連結軸14の両端部には、例えば一対の可動板17よりも外側において連結軸14の柱側支持部5からの抜け止めをなす止め輪、止めピンなどを設けても良い。
一対の可動板抜け防止部材18は、可動板17を両側から覆うように柱側支持板16の両側に配置されている。一対の可動板抜け防止部材18は、連結軸14が挿通される軸挿通孔18aを備えている。一対の可動板抜け防止部材18は、図示せぬ締結部材等で柱側支持板16に固定されている。
The column side support plate 16 has a long hole forming portion 16b in its approximate center, and a long hole 16a is formed in this long hole forming portion 16b. The peripheral portion of the long hole 16a includes the long hole forming portion 16b. The movable plate 17 has a shaft through hole 17a through which the connecting shaft 14 passes. The fit between the shaft through hole 17a and the connecting shaft 14 may be either a clearance fit or an interference fit. In addition, a retaining ring, a retaining pin, or the like may be provided on both ends of the connecting shaft 14, for example, on the outer side of the pair of movable plates 17, to prevent the connecting shaft 14 from slipping out of the column side support portion 5.
The pair of movable plate slip-out prevention members 18 are disposed on both sides of the column side support plate 16 so as to cover both sides of the movable plate 17. The pair of movable plate slip-out prevention members 18 have shaft insertion holes 18a through which the connecting shafts 14 are inserted. The pair of movable plate slip-out prevention members 18 are fixed to the column side support plate 16 by fastening members or the like (not shown).

補強部材側支持部11は、補強部材側支持板(被押圧部)21と、補強部材側支持板21の略中央部に設けられて軸受嵌合孔21aに嵌合した球面滑り軸受(軸受)22と、を備えている。
球面滑り軸受22は、補強部材側支持板21の軸受嵌合孔21aに嵌合された外輪23と、外輪23の内側に滑り自在に嵌合された内輪24と、を備えている。
The reinforcing member side support portion 11 comprises a reinforcing member side support plate (pressed portion) 21, and a spherical plain bearing (bearing) 22 provided approximately in the center of the reinforcing member side support plate 21 and fitted into a bearing fitting hole 21a.
The spherical plain bearing 22 comprises an outer ring 23 fitted in a bearing fitting hole 21 a of the reinforcing member side support plate 21 , and an inner ring 24 fitted slidably inside the outer ring 23 .

外輪23は、軸受嵌合孔21aに嵌合する外周面23aと、凹状の球面とされた内周面23bと、を備えている。内輪24は、凸状の球面とされた外周面24aと、連結軸14に嵌合する内周面24bと、を備えている。
外輪23の内周面23b(凹状の球面)と内輪24の外周面24a(凸状の球面)とは、互いに滑り自在に嵌合している。従って、連結軸14と補強部材側支持板21とは、相対的に上下方向及び水平方向に揺動可能、且つ連結軸14の軸芯回りに相対回動可能である。
内輪24の内周面24bと連結軸14とのはめあいは、すきまばめ、しまりばめの何れでも良いが、好ましくは、しまりばめが良い。
The outer ring 23 has an outer peripheral surface 23a that fits into the bearing fitting hole 21a and an inner peripheral surface 23b that is a concave spherical surface. The inner ring 24 has an outer peripheral surface 24a that is a convex spherical surface and an inner peripheral surface 24b that fits around the connecting shaft 14.
An inner peripheral surface 23b (concave spherical surface) of the outer ring 23 and an outer peripheral surface 24a (convex spherical surface) of the inner ring 24 are slidably fitted into each other. Therefore, the connecting shaft 14 and the reinforcing-member-side support plate 21 can swing relatively in the vertical and horizontal directions and can rotate relatively around the axis of the connecting shaft 14.
The fit between the inner peripheral surface 24b of the inner ring 24 and the connecting shaft 14 may be either a clearance fit or an interference fit, but an interference fit is preferable.

柱側支持部5の一対の軸支持部13には、それぞれ補強部材側支持部11を拘束する複数の拘束部材26が設けられている。
拘束部材26は、柱側支持板16のねじ孔16gにねじ結合するボルト状の位置調整部材27と、位置調整部材27の先端部に設けられた拘束部(押圧部)28と、位置調整部材27を柱側支持板16に固定するロックナット29と、を備えている。
A pair of shaft support portions 13 of the column side support portion 5 are each provided with a plurality of restraining members 26 that restrain the reinforcing member side support portion 11.
The restraint member 26 comprises a bolt-shaped position adjustment member 27 that is screwed into the screw hole 16g of the column side support plate 16, a restraint portion (pressure portion) 28 provided at the tip of the position adjustment member 27, and a lock nut 29 that fixes the position adjustment member 27 to the column side support plate 16.

拘束部28は、位置調整部材27の先端部に支持された拘束部基部28aと、拘束部基部28aに取り付けられ、補強部材側支持部11の補強部材側支持板21を滑り可能に押圧して拘束する滑り板28bと、を備えている。滑り板28bの材質としては、例えば、フッ素樹脂等の低摩擦材が好適である。また、滑り板28bに押圧される補強部材側支持板21の表面に低摩擦材を備えてもよい。すなわち、滑り板28bおよび補強部材側支持板21の表面の少なくとの一方に低摩擦材を備える構成であればよい。低摩擦材はコーティングであってもよい。 The restraining portion 28 includes a restraining portion base 28a supported on the tip of the position adjustment member 27, and a sliding plate 28b attached to the restraining portion base 28a, which slidably presses and restrains the reinforcing member side support plate 21 of the reinforcing member side support portion 11. A low-friction material such as fluororesin is suitable as the material for the sliding plate 28b. A low-friction material may also be provided on the surface of the reinforcing member side support plate 21 that is pressed by the sliding plate 28b. In other words, it is sufficient that at least one of the surfaces of the sliding plate 28b and the reinforcing member side support plate 21 is provided with a low-friction material. The low-friction material may be a coating.

図3および図4に示すように、柱側支持板16の長孔16aは、矩形とされた内周面16cを備え、長孔16aの長手方向は水平方向に指向している。内周面16cは、上部内面16d、下部内面16eおよび一対の側部内面16fを備え、上部内面16dと下部内面16eとは互いに平行で、共に水平方向に延びている。 As shown in Figures 3 and 4, the long hole 16a of the column side support plate 16 has a rectangular inner peripheral surface 16c, and the longitudinal direction of the long hole 16a is oriented horizontally. The inner peripheral surface 16c has an upper inner surface 16d, a lower inner surface 16e, and a pair of side inner surfaces 16f, and the upper inner surface 16d and the lower inner surface 16e are parallel to each other and both extend horizontally.

可動板17は、側面視略正方形に形成され、上面17d、下面17eおよび一対の側面17fを備えるとともに、上面17dおよび下面17eの両端からそれぞれ側面17fに向けて湾曲して延びる複数の円弧面17gを備えている。
上面17dは、長孔16aの上部内面16dに当接又は近接している。下面17eは、長孔16aの下部内面16eに当接している。
長孔16aの上部内面16dと可動板17の上面17dとの間、および長孔16aの下部内面16eと可動板17の下面17eとの間には、グリース等の潤滑剤が塗布されている。
The movable plate 17 is formed in a roughly square shape when viewed from the side and has an upper surface 17d, a lower surface 17e and a pair of side surfaces 17f, as well as a number of arcuate surfaces 17g that extend and curve from both ends of the upper surface 17d and the lower surface 17e toward the side surfaces 17f.
The upper surface 17d abuts against or is close to the upper inner surface 16d of the long hole 16a, and the lower surface 17e abuts against the lower inner surface 16e of the long hole 16a.
A lubricant such as grease is applied between an upper inner surface 16d of the slot 16a and an upper surface 17d of the movable plate 17, and between a lower inner surface 16e of the slot 16a and a lower surface 17e of the movable plate 17.

支承Sは、補強部材側支持部11の球面滑り軸受22と、柱側支持部5の長孔形成部16bと、長孔16a内に移動可能に配置された可動板17と、球面滑り軸受22に挿入されるとともに可動板17に支持された連結軸14と、を備えている。支承Sは、柱側支持部(第一支持部)5および補強部材側支持部(第二支持部)11を含むと捉えてもよい。
可動板17は、長孔16a内において、長孔16aの上部内面16dおよび下部内面16eに沿って長孔16aの長手方向に移動可能とされている。
The support S includes a spherical plain bearing 22 of the reinforcing member side support part 11, an elongated hole forming part 16b of the column side support part 5, a movable plate 17 movably arranged in the elongated hole 16a, and a connecting shaft 14 inserted into the spherical plain bearing 22 and supported by the movable plate 17. The support S may be considered to include the column side support part (first support part) 5 and the reinforcing member side support part (second support part) 11.
The movable plate 17 is movable in the longitudinal direction of the elongated hole 16a along an upper inner surface 16d and a lower inner surface 16e of the elongated hole 16a.

図5に示すように、可動板17は、上面17dを長孔16aの上部内面16dに面接触可能であり、下面17eを長孔16aの下部内面16eに面接触可能である。可動板17は、上面17dおよび下面17eの少なくとも一方を長孔16aの内面に面接触させた状態で、長孔16a内を長手方向に移動可能である。
補強部材側支持部11(図4参照)から連結軸14を介して可動板17に伝えられた荷重は、矢印A,Bで示すように、可動板17の上面17dから長孔16aの上部内面16dへ分散されて伝えられる。また、前記荷重は、可動板17の下面17eから長孔16aの下部内面16eへ分散されて伝えられる。上記した可動板17は、可動板17に伝えられた荷重を分散させる支圧分散板として機能する。
5, the upper surface 17d of the movable plate 17 can be in surface contact with the upper inner surface 16d of the long hole 16a, and the lower surface 17e can be in surface contact with the lower inner surface 16e of the long hole 16a. The movable plate 17 can move in the longitudinal direction within the long hole 16a with at least one of the upper surface 17d and the lower surface 17e in surface contact with the inner surface of the long hole 16a.
The load transmitted from the reinforcing member side support part 11 (see FIG. 4) to the movable plate 17 via the connecting shaft 14 is distributed and transmitted from the upper surface 17d of the movable plate 17 to the upper inner surface 16d of the long hole 16a as shown by arrows A and B. The load is also distributed and transmitted from the lower surface 17e of the movable plate 17 to the lower inner surface 16e of the long hole 16a. The movable plate 17 described above functions as a support pressure distribution plate that distributes the load transmitted to the movable plate 17.

このように、可動板17の上面17dおよび下面17eと、長孔16aの上部内面16dおよび下部内面16eとがそれぞれ面接触することで、長孔16aの上部内面16dおよび下部内面16eに荷重が分散されて伝わるため、各接触面の面圧が低く抑えられる。これにより、支承Sでの鉛直支持力をより大きくするとともに、連結軸14の水平移動の抵抗を小さくすることができる。また、可動板17と長孔16aとの各接触面に塗布された潤滑剤の膜厚が確保され、長孔16aに対して可動板17が水平方向に円滑に移動可能となり、水平方向の抵抗をより小さくすることができる。 In this way, the upper surface 17d and lower surface 17e of the movable plate 17 come into surface contact with the upper inner surface 16d and lower inner surface 16e of the long hole 16a, respectively, and the load is distributed and transmitted to the upper inner surface 16d and lower inner surface 16e of the long hole 16a, so the surface pressure on each contact surface is kept low. This increases the vertical support force at the support S and reduces the resistance to the horizontal movement of the connecting shaft 14. In addition, the film thickness of the lubricant applied to each contact surface between the movable plate 17 and the long hole 16a is ensured, allowing the movable plate 17 to move smoothly horizontally relative to the long hole 16a, and further reducing horizontal resistance.

図1において、補強部材7の下面には、空間2内の梁Q2の第二構面4側に延びるフレームとしてのV字ブレース30が連結されている。V字ブレース30は、補強部材7からそれぞれ斜め下方に延びる第一縦枠31および第二縦枠32を備え、第一縦枠31および第二縦枠32によって略V字状に形成されている。第一縦枠31は、例えば、第二縦枠32より長い辺に形成されている。 In FIG. 1, a V-shaped brace 30 is connected to the underside of the reinforcing member 7 as a frame extending toward the second structural face 4 of the beam Q2 in the space 2. The V-shaped brace 30 includes a first vertical frame 31 and a second vertical frame 32 that each extend diagonally downward from the reinforcing member 7, and is formed into a substantially V-shape by the first vertical frame 31 and the second vertical frame 32. The first vertical frame 31 is formed, for example, on a side that is longer than the second vertical frame 32.

更に、V字ブレース30の下端部の頂部30aは、梁Q2の第二構面4の近傍に位置し、頂部30aの近傍には、梁Q2の第二構面4に固定された下受け部34が設けられている。下受け部34は、断面視略U字状に形成され、梁Q2の第二構面4における長手方向中間部に締結ボルト等で固定されている。下受け部34とV字ブレース30の頂部30aとには、制振ダンパー35が連結されている。制振ダンパー35は、第二構面4の長手方向中間部の上方に配置されている。 Furthermore, the apex 30a of the lower end of the V-shaped brace 30 is located near the second structural surface 4 of the beam Q2, and a lower support 34 fixed to the second structural surface 4 of the beam Q2 is provided near the apex 30a. The lower support 34 is formed in a roughly U-shape in cross section, and is fixed to the longitudinal middle part of the second structural surface 4 of the beam Q2 with a fastening bolt or the like. A vibration damper 35 is connected to the lower support 34 and the apex 30a of the V-shaped brace 30. The vibration damper 35 is located above the longitudinal middle part of the second structural surface 4.

制振ダンパー35は、例えば、オイルダンパー、摩擦ダンパーまたは粘弾性体(高減衰ゴム)等の任意のダンパーを採用可能である。制振ダンパー35は、例えば、オイルや粘性体等を内蔵したシリンダ35aの一端部が下受け部34に設けられた下部ピン36に固定され、シリンダ35a内に進退して振動を減衰させるピストンロッド35bの一端部がV字ブレース30の頂部30aに固定されている。
制振ダンパー35は、V字ブレース30の頂部30aと下受け部34の下部ピン36との間に水平方向に指向されて配置され、制振ダンパー35によって、柱P1,P2および梁Q1,Q2に生じる水平方向の振動を減衰させることができる。
The vibration damper 35 may be any damper, such as an oil damper, a friction damper, or a viscoelastic body (high damping rubber). The vibration damper 35 has, for example, one end of a cylinder 35a containing oil, a viscous body, or the like, fixed to a lower pin 36 provided on the lower support 34, and one end of a piston rod 35b that moves back and forth within the cylinder 35a to damp vibrations, fixed to the top 30a of the V-shaped brace 30.
The vibration damper 35 is arranged horizontally between the top 30a of the V-shaped brace 30 and the lower pin 36 of the lower support 34, and the vibration damper 35 can damp horizontal vibrations occurring in the columns P1, P2 and the beams Q1, Q2.

V字ブレース30の頂部30aは、下部ピン36を中心にして揺動可能とされている。柱P1,P2が水平方向に揺動した際に、下部ピン36に対してV字ブレース30が揺動可能とされている。なお、上受け部8および上部ピン10と、下受け部34および下部ピン36との取り付け位置は、梁Q1,Q2の長手方向に直交する方向の反力が生じないように、例えば、梁Q1,Q2の長手方向中央部に設置することが好ましい。本実施形態では、下受け部34の両側部間に装着された締結ボルト等の下部ピン36は、上受け部8の上部ピン10に対してわずかに水平方向に位置がずれている。 The top 30a of the V-shaped brace 30 is capable of swinging around the lower pin 36. When the columns P1 and P2 swing horizontally, the V-shaped brace 30 is capable of swinging relative to the lower pin 36. The upper support 8 and upper pin 10, and the lower support 34 and lower pin 36 are preferably attached to the longitudinal center of the beams Q1 and Q2, for example, so that no reaction force is generated in a direction perpendicular to the longitudinal direction of the beams Q1 and Q2. In this embodiment, the lower pin 36, such as a fastening bolt, attached between both sides of the lower support 34 is slightly misaligned horizontally relative to the upper pin 10 of the upper support 8.

本実施形態による制振装置1では、構造物BLの層間の空間2を構成する柱P1,P2、梁Q1,Q2に対して、柱P1,P2間の上部に補強部材7を取り付けている。補強部材7は、V字ブレース30の底辺として第一縦枠31および第二縦枠32を連結して三角形枠状を構成している。更に、補強部材7の拡幅部7aを上受け部8の上部ピン10で支持し、V字ブレース30の頂部30aと下受け部34の下部ピン36との間を、制振ダンパー35を介して連結している。 In the vibration control device 1 according to this embodiment, a reinforcing member 7 is attached to the upper portion between the columns P1, P2 and the beams Q1, Q2 that form the space 2 between the layers of the structure BL. The reinforcing member 7 forms a triangular frame shape by connecting the first vertical frame 31 and the second vertical frame 32 as the base of the V-shaped brace 30. Furthermore, the widened portion 7a of the reinforcing member 7 is supported by the upper pin 10 of the upper support portion 8, and the top 30a of the V-shaped brace 30 and the lower pin 36 of the lower support portion 34 are connected via the vibration control damper 35.

このように、上部ピン10、下部ピン36で、補強部材7およびV字ブレース30を制振ダンパー35を介して支持するため、第一構面6および第二構面4に伝達される応力を、第一構面6および第二構面4に沿った応力(梁Q1,Q2の長手方向の軸力)のみにすることができる。そのため、上下階での梁Q1,Q2の補強工事が不要で構造物BLの補強工事を空間2内のみで施工することができる。 In this way, the upper pins 10 and lower pins 36 support the reinforcing members 7 and V-shaped braces 30 via the vibration dampers 35, so the stress transmitted to the first structural face 6 and the second structural face 4 can be limited to the stress along the first structural face 6 and the second structural face 4 (the longitudinal axial force of beams Q1, Q2). Therefore, reinforcement work for beams Q1, Q2 on the upper and lower floors is not required, and reinforcement work for structure BL can be carried out only within space 2.

また、柱P1,P2の柱側支持部5に対して、補強部材7の両端の補強部材側支持部11を連結軸14および可動板17を介して連結して支持しているため、補強部材7の鉛直方向の支持力を大きくすることができる。更に、柱P1,P2の水平方向の振動は、連結軸14および可動板17で受けるため、水平方向の抵抗は小さくなり、且つ構造的に、部品数が少なく、小型でコンパクトな支承Sを得ることができる。 In addition, the reinforcing member side support parts 11 at both ends of the reinforcing member 7 are connected and supported by the column side support parts 5 of the columns P1 and P2 via the connecting shafts 14 and movable plates 17, so the vertical support force of the reinforcing member 7 can be increased. Furthermore, the horizontal vibrations of the columns P1 and P2 are received by the connecting shafts 14 and movable plates 17, so the horizontal resistance is small, and structurally, the number of parts is small, making it possible to obtain a small and compact support S.

なお、上記した支承Sは、柱P1,P2の柱側支持部5が一対の軸支持部13(長孔16aおよび可動板17含む)で構成され、これら一対の軸支持部13の間に補強部材7の単一の補強部材側支持部11(軸受22含む)が配置されているが、これとは逆に、補強部材側支持部11が一対の軸支持部(長孔16aおよび可動板17含む)で構成され、これら一対の軸支持部の間に単一の柱側支持部5(軸受22含む)が配置される構成でもよい。
また、支承Sの他の形態として、柱(第一部材)P1,P2の柱側支持部(第一支持部)5が一対の支持部(軸受22含む)で構成され、これら一対の支持部の間に補強部材(第二部材)7の単一の補強部材側支持部(第二支持部)11(長孔16aおよび可動板17含む)が配置される構成でもよい。
さらに、補強部材側支持部11が一対の支持部(軸受22含む)で構成され、これら一対の支持部の間に単一の柱側支持部5(長孔16aおよび可動板17含む)が配置される構成でもよい。
In the above-mentioned support S, the column side support portion 5 of the columns P1, P2 is composed of a pair of shaft support portions 13 (including the long hole 16a and the movable plate 17), and a single reinforcing member side support portion 11 (including the bearing 22) of the reinforcing member 7 is arranged between this pair of shaft support portions 13. However, the reinforcing member side support portion 11 may be configured conversely as a pair of shaft support portions (including the long hole 16a and the movable plate 17), and a single column side support portion 5 (including the bearing 22) may be arranged between this pair of shaft support portions.
As another form of the support S, the column side support portion (first support portion) 5 of the columns (first members) P1, P2 may be composed of a pair of support portions (including bearings 22), and a single reinforcing member side support portion (second support portion) 11 (including the long hole 16a and the movable plate 17) of the reinforcing member (second member) 7 may be arranged between the pair of support portions.
Furthermore, the reinforcing member side support portion 11 may be configured to be composed of a pair of support portions (including bearings 22), and a single column side support portion 5 (including the long hole 16a and movable plate 17) may be arranged between the pair of support portions.

次に、地震や強風等で生じる振動に対して構造物BLの振動を減衰する方法について説明する。
図1において、地震発生時や強風発生時等に基礎等の支持構造物が水平方向に振動すると、支持構造物に支持された構造物BLが応答して水平方向に振動する。
構造物BLが地震等で振動して変形すると、架構の各空間2の上層と下層とに水平方向の層間変位が生じる。即ち、構造物BLの振動により、空間2を構成する柱P1,P2と梁Q1,Q2とがそれぞれ水平方向に往復運動する。
このとき、補強部材7は、上側の梁Q1の第一構面6の上受け部8の上部ピン10を中心に揺動する。
Next, a method for damping vibrations of the structure BL caused by earthquakes, strong winds, etc. will be described.
In FIG. 1, when a support structure such as a foundation vibrates horizontally due to an earthquake, strong wind, or the like, a structure BL supported by the support structure responds by vibrating horizontally.
When the structure BL vibrates and deforms due to an earthquake or the like, horizontal inter-story displacement occurs between the upper and lower stories of each space 2 of the frame. That is, due to the vibration of the structure BL, the columns P1, P2 and the beams Q1, Q2 that constitute the space 2 each move back and forth in the horizontal direction.
At this time, the reinforcing member 7 swings around the upper pin 10 of the upper receiving portion 8 of the first structural face 6 of the upper beam Q1.

構造物BLが水平方向に振動すると、補強部材7の一端部(図1において右側の補強部材側支持部11)は、図6中矢印Cのように、連結軸14を中心にして一方向(時計回り)に相対的に回動するとともに、図7中矢印Dのように、連結軸14を中心にして他方向(反時計回り)にも相対的に回動する。このとき、補強部材7の他端部(図1において左側の補強部材側支持部11)も同様に、連結軸14を中心にして一方向(時計回り)に相対的に回動するとともに、連結軸14を中心にして他方向(反時計回り)にも相対的に回動する。
このように、補強部材7の両側に配置された連結軸14によって、柱P1,P2に対する補強部材7の両端部の回動がスムーズに行われ、補強部材7の揺動時の摩擦抵抗は極めて小さくなる。
When the structure BL vibrates in the horizontal direction, one end of the reinforcing member 7 (the reinforcing member support part 11 on the right side in Fig. 1) rotates relatively in one direction (clockwise) around the connecting shaft 14 as indicated by arrow C in Fig. 6, and also rotates relatively in the other direction (counterclockwise) around the connecting shaft 14 as indicated by arrow D in Fig. 7. At this time, the other end of the reinforcing member 7 (the reinforcing member support part 11 on the left side in Fig. 1) also rotates relatively in one direction (clockwise) around the connecting shaft 14, and also rotates relatively in the other direction (counterclockwise) around the connecting shaft 14.
In this way, the connecting shafts 14 arranged on both sides of the reinforcing member 7 allow both ends of the reinforcing member 7 to rotate smoothly relative to the pillars P1, P2, and frictional resistance when the reinforcing member 7 swings is extremely small.

また、構造物BLが地震等で振動して変形し、補強部材7の一端部(図1において右側の補強部材側支持部11)が、図8中矢印Eのように水平方向右側へ変位すると、右側の補強部材側支持部11は柱P2に接近する。また、右側の補強部材側支持部11に連結軸14を介して連結された可動板17は、柱P2の柱側支持部5の長孔16a内を水平方向右側へ移動する。さらに、補強部材7の他端部(図1において左側の補強部材側支持部11)も同様に、水平方向右側へ変位し、左側の補強部材側支持部11は柱P1から離間する。また、左側の補強部材側支持部11に連結軸14を介して連結された可動板17は、柱P1の柱側支持部5の長孔16a内を水平方向右側へ移動する。 In addition, when the structure BL vibrates and deforms due to an earthquake or the like, and one end of the reinforcing member 7 (the reinforcing member support part 11 on the right side in FIG. 1) is displaced horizontally to the right as indicated by the arrow E in FIG. 8, the reinforcing member support part 11 on the right side approaches the column P2. The movable plate 17 connected to the reinforcing member support part 11 on the right side via the connecting shaft 14 moves horizontally to the right inside the long hole 16a of the column support part 5 of the column P2. Furthermore, the other end of the reinforcing member 7 (the reinforcing member support part 11 on the left side in FIG. 1) is also displaced horizontally to the right, and the reinforcing member support part 11 on the left side moves away from the column P1. The movable plate 17 connected to the reinforcing member support part 11 on the left side via the connecting shaft 14 moves horizontally to the right inside the long hole 16a of the column support part 5 of the column P1.

また、構造物BLの振動により、補強部材7の一端部(図1において右側の補強部材側支持部11)が、図9中矢印Fのように水平方向左側へ変位すると、右側の補強部材側支持部11は柱P2から離間する。また、右側の補強部材側支持部11に連結軸14を介して連結された可動板17は、柱P2の柱側支持部5の長孔16a内を水平方向左側へ移動する。さらに、補強部材7の他端部(図1において左側の補強部材側支持部11)も同様に、水平方向左側へ変位し、左側の補強部材側支持部11は柱P1に接近する。また、左側の補強部材側支持部11に連結軸14を介して連結された可動板17は、柱P1の柱側支持部5の長孔16a内を水平方向左側へ移動する。
このように、柱P1,P2の柱側支持部5の可動板17によって、柱P1,P2に対する補強部材7の両端部の水平方向の変位がスムーズに行われ、補強部材7の水平移動時の摩擦抵抗は極めて小さくなる。
In addition, when one end of the reinforcing member 7 (the reinforcing member support part 11 on the right side in FIG. 1) is displaced horizontally to the left as indicated by the arrow F in FIG. 9 due to vibration of the structure BL, the reinforcing member support part 11 on the right side moves away from the column P2. In addition, the movable plate 17 connected to the reinforcing member support part 11 on the right side via the connecting shaft 14 moves horizontally to the left in the long hole 16a of the column support part 5 of the column P2. Furthermore, the other end of the reinforcing member 7 (the reinforcing member support part 11 on the left side in FIG. 1) is also displaced horizontally to the left in the same manner, and the reinforcing member support part 11 on the left side approaches the column P1. In addition, the movable plate 17 connected to the reinforcing member support part 11 on the left side via the connecting shaft 14 moves horizontally to the left in the long hole 16a of the column support part 5 of the column P1.
In this way, the movable plates 17 of the column side support parts 5 of the columns P1 and P2 allow smooth horizontal displacement of both ends of the reinforcing member 7 relative to the columns P1 and P2, and frictional resistance during horizontal movement of the reinforcing member 7 is extremely small.

支承Sでは、上記した回動と水平方向の変位とを同時に許容可能である。
図10に示すように、補強部材7の一端部(図1において右側の補強部材側支持部11)は、図中矢印Gのように、連結軸14を中心にして他方向(反時計回り)に相対的に回動するとともに、矢印Hのように水平方向左側へ変位する。その結果、右側の補強部材側支持部11は柱P2から離間する。また、右側の補強部材側支持部11に連結軸14を介して連結された可動板17は、柱側支持部5の長孔16a内を水平方向左側へ移動する。
The support S can simultaneously allow the above-mentioned rotation and horizontal displacement.
As shown in Figure 10, one end of the reinforcing member 7 (the reinforcing member-side support part 11 on the right side in Figure 1) rotates relatively in the other direction (counterclockwise) around the connecting shaft 14 as indicated by arrow G in the figure, and displaces horizontally to the left as indicated by arrow H. As a result, the reinforcing member-side support part 11 on the right side moves away from the pillar P2. In addition, the movable plate 17 connected to the reinforcing member-side support part 11 on the right side via the connecting shaft 14 moves horizontally to the left within the long hole 16a of the pillar-side support part 5.

さらに、補強部材7の他端部(図1において、左側の補強部材側支持部11)も同様に、連結軸14を中心にして他方向(反時計回り)に相対的に回動するとともに、水平方向左側へ変位する。その結果、左側の補強部材側支持部11は柱P1に接近する。また、左側の補強部材側支持部11に連結軸14を介して連結された可動板17は、柱側支持部5の長孔16a内を水平方向左側へ移動する。 Furthermore, the other end of the reinforcing member 7 (the left reinforcing member support part 11 in FIG. 1) also rotates relatively in the other direction (counterclockwise) around the connecting shaft 14 and displaces horizontally to the left. As a result, the left reinforcing member support part 11 approaches the pillar P1. In addition, the movable plate 17 connected to the left reinforcing member support part 11 via the connecting shaft 14 moves horizontally to the left within the long hole 16a of the pillar support part 5.

このように、補強部材7の両側に配置された連結軸14によって、柱P1,P2に対する補強部材7の両端部の回動と、水平方向への変位とが同時にスムーズに行われ、補強部材7の揺動時の摩擦抵抗は極めて小さくなる。
なお、図10では、補強部材7の一端部の一方向の回動及び変位を例に説明したが、補強部材7の一端部の前記一方向とは逆の方向の回動及び変位でも同様の作用効果が得られる。
In this way, the connecting shafts 14 arranged on both sides of the reinforcing member 7 allow both ends of the reinforcing member 7 to rotate smoothly relative to the pillars P1, P2 and to displace horizontally at the same time, making the frictional resistance when the reinforcing member 7 sways extremely small.
In addition, in Figure 10, the rotation and displacement of one end of the reinforcing member 7 in one direction has been described as an example, but the same effect can be obtained by rotating and displacing one end of the reinforcing member 7 in the opposite direction to the one direction.

以上の図6~図10では、更に、補強部材側支持部11の補強部材側支持板21の両面上を、複数の拘束部材26の滑り板28b(図3参照)が小さい摩擦力で相対的に摺動しつつ、補強部材側支持板21を連結軸14の軸方向(補強部材側支持板21の厚さ方向)に押圧する。水平方向に揺動しつつ変位する補強部材7により、制振ダンパー35がストロークする。具体的に、図6および図9に示す状態では、制振ダンパー35のピストンロッド35bがシリンダ35a内に押し込まれる、また、図7および図8に示す状態では、ピストンロッド35bがシリンダ35a内から引き出される。このとき、制振ダンパー35の反力(減衰力)が働き、構造物BLの振動が抑制される。 In the above Figs. 6 to 10, the sliding plates 28b (see Fig. 3) of the multiple restraining members 26 slide relatively on both sides of the reinforcing member side support plate 21 of the reinforcing member side support section 11 with a small frictional force, while pressing the reinforcing member side support plate 21 in the axial direction of the connecting shaft 14 (thickness direction of the reinforcing member side support plate 21). The vibration damper 35 strokes due to the reinforcing member 7 that displaces while swinging horizontally. Specifically, in the state shown in Figs. 6 and 9, the piston rod 35b of the vibration damper 35 is pushed into the cylinder 35a, and in the state shown in Figs. 7 and 8, the piston rod 35b is pulled out from the cylinder 35a. At this time, the reaction force (damping force) of the vibration damper 35 acts, suppressing the vibration of the structure BL.

次に、補強部材側支持部11の補強部材側支持板21に垂直な方向における構造物BLや補強部材7の寸法誤差や施工誤差に対する位置調整の方法について、図3、図11及び図12を参照して説明する。
図3において、補強部材側支持部11の補強部材側支持板21は、複数の拘束部材26の位置調整部材27によって両面側から位置調整可能に押圧されている。このため、柱側支持部5および補強部材側支持部11の寸法誤差や施工誤差等があっても、位置調整部材27による柱側支持部5のねじ孔16gに対するねじ込み量を調整することで吸収することができる。
Next, a method of adjusting the position of the structure BL and the reinforcing member 7 in the direction perpendicular to the reinforcing member side support plate 21 of the reinforcing member side support portion 11 will be described with reference to Figures 3, 11 and 12.
3, the reinforcing-member-side support plate 21 of the reinforcing-member-side support part 11 is pressed from both sides by position adjustment members 27 of a plurality of restraining members 26 so as to be position-adjustable. Therefore, even if there are dimensional errors or construction errors of the column-side support part 5 and the reinforcing-member-side support part 11, these can be absorbed by adjusting the amount of screwing of the position adjustment members 27 into the screw holes 16g of the column-side support part 5.

例えば、図11、図12に示すように、柱P1,P2に対して補強部材7の補強部材側支持板21が規定の設置位置(二点鎖線の位置)から水平方向の相対誤差を有するときは、各拘束部材26の位置調整部材27により拘束部28の位置を図11中矢印H1または図12中矢印H2で示す方向へ調整し、実際の補強部材側支持板21の設置位置において補強部材側支持板21の表裏面を押圧する。位置調整部材27による調整後に、ロックナット29を閉め込み、位置調整部材27を固定する。
この調整により、補強部材側支持板21の固定位置に傾きや撓み等が生じることが抑えられる。
For example, as shown in Figures 11 and 12, when the reinforcing-member-side support plate 21 of the reinforcing member 7 has a horizontal relative error from the specified installation position (position indicated by the two-dot chain line) with respect to the columns P1, P2, the position of the restraining portion 28 is adjusted by the position adjustment member 27 of each restraining member 26 in the direction indicated by the arrow H1 in Figure 11 or the arrow H2 in Figure 12, and the front and back surfaces of the reinforcing-member-side support plate 21 are pressed at the actual installation position of the reinforcing-member-side support plate 21. After adjustment by the position adjustment member 27, the lock nut 29 is tightened to fix the position adjustment member 27.
This adjustment prevents tilting, bending, etc. from occurring at the fixed position of the reinforcing member side support plate 21.

図13に示すように、構造物BLの自重や地震等の外乱による荷重をNとすると、柱側支持部5から連結軸14に作用する荷重がN1、補強部材側支持部11から連結軸14に作用する逆方向の荷重がN2となり、N1=N2=Nである。
更に、柱側支持部5の荷重作用点(連結軸14)から柱P1,P2(柱P1は図1参照)までの距離をL1、補強部材側支持部11の荷重作用点(連結軸14)から補強部材7までの距離をL2とする。柱P1,P2における連結軸14の周辺に生じる付加曲げモーメントM1と、補強部材7における連結軸14の周辺に生じる付加曲げモーメントM2とは、次のようになる。
M1=N1×L1
M2=N2×L2
すなわち、所定の荷重N1,N2に対して距離L1,L2を短く設定することで、付加曲げモーメントM1,M2を小さくすることができる。
As shown in Figure 13, if the load due to the weight of the structure BL or an external disturbance such as an earthquake is N, the load acting on the connecting shaft 14 from the column side support part 5 is N1, and the load acting in the opposite direction from the reinforcing member side support part 11 to the connecting shaft 14 is N2, and N1 = N2 = N.
Furthermore, the distance from the load application point (connecting shaft 14) of the column-side support part 5 to columns P1, P2 (see Figure 1 for column P1) is defined as L1, and the distance from the load application point (connecting shaft 14) of the reinforcing member-side support part 11 to the reinforcing member 7 is defined as L2. The additional bending moment M1 generated around the connecting shaft 14 in columns P1, P2 and the additional bending moment M2 generated around the connecting shaft 14 in the reinforcing member 7 are as follows:
M1 = N1 x L1
M2 = N2 x L2
That is, by setting the distances L1, L2 short for the predetermined loads N1, N2, the additional bending moments M1, M2 can be reduced.

<長孔の変形例>
図14に示すように、柱側支持部(第一支持部)5Aの柱側支持板16Aは、その略中央部に長孔形成部16bを備え、この長孔形成部16bに長孔46aが形成されている。なお、柱側支持部5Aは、前述の柱側支持部5(図3参照)に対して、柱側支持板16Aの長孔46aの形状のみ異なる。
支承SAは、補強部材側支持部11(図3参照)の球面滑り軸受22(図3参照)と、柱側支持部5Aの長孔形成部16bと、長孔46a内に移動可能に配置された可動板17と、連結軸14と、を備えている。
<Modification of the long hole>
As shown in Fig. 14, the column side support plate 16A of the column side support part (first support part) 5A has a long hole forming part 16b at its approximate center, and a long hole 46a is formed in this long hole forming part 16b. The column side support part 5A differs from the above-mentioned column side support part 5 (see Fig. 3) only in the shape of the long hole 46a of the column side support plate 16A.
The support SA includes a spherical plain bearing 22 (see Figure 3) of the reinforcing member side support part 11 (see Figure 3), a long hole forming part 16b of the column side support part 5A, a movable plate 17 movably arranged within the long hole 46a, and a connecting shaft 14.

長孔46aは、正面視略矩形とされた内周面46cを備え、長孔46aの長手方向は、水平方向に指向している。内周面46cは、上部内面46d、下部内面46eおよび一対の側部内面46fを備えるとともに、上部内面46dおよび下部内面46eの両端からそれぞれ側部内面46fに向けて湾曲して延びる複数の円弧状内面46gを備えている。上部内面46dと下部内面46eとは互いに平行で、共に水平方向に延びている。
上記したように、長孔46aの四隅にそれぞれ円弧状内面46gを設けることで、内周面46cにおける応力集中を抑制することができる。
The long hole 46a has an inner peripheral surface 46c that is generally rectangular in front view, and the longitudinal direction of the long hole 46a is oriented in the horizontal direction. The inner peripheral surface 46c has an upper inner surface 46d, a lower inner surface 46e, and a pair of side inner surfaces 46f, as well as a plurality of arc-shaped inner surfaces 46g that extend in a curved manner from both ends of the upper inner surface 46d and the lower inner surface 46e toward the side inner surface 46f. The upper inner surface 46d and the lower inner surface 46e are parallel to each other and both extend in the horizontal direction.
As described above, by providing the arc-shaped inner surfaces 46g at the four corners of the long hole 46a, it is possible to suppress stress concentration on the inner circumferential surface 46c.

可動板17において、上面17dは、長孔46aの上部内面46dに当接又は近接し、下面17eは、長孔46aの下部内面46eに当接している。
可動板17は、長孔46a内を、長孔46aの上部内面46dおよび下部内面46eに沿って、長孔46aの長手方向すなわち水平方向に移動可能である。
In the movable plate 17, an upper surface 17d abuts or is close to an upper inner surface 46d of the elongated hole 46a, and a lower surface 17e abuts against a lower inner surface 46e of the elongated hole 46a.
The movable plate 17 is movable within the elongated hole 46a in the longitudinal direction of the elongated hole 46a, that is, in the horizontal direction, along an upper inner surface 46d and a lower inner surface 46e of the elongated hole 46a.

図15に示すように、柱側支持部(第一支持部)5Bの柱側支持板16Bは、その略中央部に長孔形成部16bを備え、この長孔形成部16bに長孔56aが形成されている。なお、柱側支持部5Bは、前述の柱側支持部5(図3参照)に対して、柱側支持板16Bの長孔56aの形状のみ異なる。
支承SAは、補強部材側支持部11(図3参照)の球面滑り軸受22(図3参照)と、柱側支持部5Bの長孔形成部16bと、長孔56a内に移動可能に配置された可動板17と、連結軸14と、を備えている。
As shown in Fig. 15, the column side support plate 16B of the column side support part (first support part) 5B has a long hole forming part 16b in its approximate center, and a long hole 56a is formed in this long hole forming part 16b. The column side support part 5B differs from the above-mentioned column side support part 5 (see Fig. 3) only in the shape of the long hole 56a of the column side support plate 16B.
The support SA includes a spherical plain bearing 22 (see Figure 3) of the reinforcing member side support part 11 (see Figure 3), a long hole forming part 16b of the column side support part 5B, a movable plate 17 movably arranged within the long hole 56a, and a connecting shaft 14.

長孔56aは、正面視長円形とされた内周面56cを備え、長孔56aの長手方向は、水平方向に指向している。内周面56cは、上部内面56d、下部内面56eおよび一対の円弧状側部内面56fを備えている。上部内面56dと下部内面56eとは互いに平行で、共に水平方向に延びている。
上記したように、長孔56aの内周面56cを長円形状に形成することで、内周面56cにおける応力集中を抑制することができるとともに、長孔56aを切削工具等で容易に形成することができる。
The long hole 56a has an inner peripheral surface 56c that is elliptical when viewed from the front, and the longitudinal direction of the long hole 56a is oriented in the horizontal direction. The inner peripheral surface 56c has an upper inner surface 56d, a lower inner surface 56e, and a pair of arcuate inner side surfaces 56f. The upper inner surface 56d and the lower inner surface 56e are parallel to each other and both extend in the horizontal direction.
As described above, by forming the inner peripheral surface 56c of the long hole 56a in an elliptical shape, it is possible to suppress stress concentration on the inner peripheral surface 56c, and the long hole 56a can be easily formed by a cutting tool or the like.

可動板17において、上面17dは、長孔56aの上部内面56dに当接又は近接し、下面17eは、長孔56aの下部内面56eに当接している。
可動板17の上面17dおよび長孔56aの上部内面56dは、例えば互いに平滑な平面状に形成されているが、これに限らない。例えば、上面17dおよび上部内面56dの少なくとも一方に、潤滑剤保持用の溝や窪み等の凹部を設けてもよい。これにより、長期に亘って潤滑剤を保持することができ、可動板17の良好な潤滑性を保つことができる。
また、可動板17の上面17dも同様に、滑剤保持用の溝や窪み等の凹部を設けたり、あるいは複数の点接触を実現する複数の凸部を設けてもよい。
In the movable plate 17, an upper surface 17d abuts or is close to an upper inner surface 56d of the elongated hole 56a, and a lower surface 17e abuts against a lower inner surface 56e of the elongated hole 56a.
The upper surface 17d of the movable plate 17 and the upper inner surface 56d of the long hole 56a are formed, for example, as smooth flat surfaces, but are not limited thereto. For example, at least one of the upper surface 17d and the upper inner surface 56d may be provided with a recess such as a groove or a depression for retaining a lubricant. This allows the lubricant to be retained for a long period of time, and the movable plate 17 can maintain good lubrication.
Similarly, the upper surface 17d of the movable plate 17 may be provided with recesses such as grooves or depressions for retaining a lubricant, or may be provided with a plurality of protrusions for achieving a plurality of point contacts.

可動板17は、長孔56a内を、長孔56aの上部内面56dおよび下部内面56eに沿って、長孔56aの長手方向すなわち水平方向に移動可能とされている。
可動板17の下面17eおよび長孔56aの下部内面56eは、例えば互いに平滑な平面状に形成されているが、これに限らない。例えば、下面17eおよび下部内面56eの少なくとも一方に、潤滑剤保持用の溝や窪み等の凹部を設けてもよい。これにより、長期に亘って潤滑剤を保持することができ、可動板17の良好な潤滑性を保つことができる。
また、可動板17の下面17eも同様に、滑剤保持用の溝や窪み等の凹部を設けたり、あるいは複数の点接触を実現する複数の凸部を設けてもよい。
The movable plate 17 is movable within the elongated hole 56a in the longitudinal direction of the elongated hole 56a, that is, in the horizontal direction, along an upper inner surface 56d and a lower inner surface 56e of the elongated hole 56a.
The lower surface 17e of the movable plate 17 and the lower inner surface 56e of the long hole 56a are formed, for example, as smooth flat surfaces, but are not limited thereto. For example, at least one of the lower surface 17e and the lower inner surface 56e may be provided with a recess such as a groove or a depression for retaining a lubricant. This allows the lubricant to be retained for a long period of time, and the movable plate 17 can maintain good lubrication.
Similarly, the lower surface 17e of the movable plate 17 may be provided with recesses such as grooves or depressions for retaining a lubricant, or may be provided with a plurality of protrusions for achieving a plurality of point contacts.

<拘束部材の変形例>
図16に示すように、補強部材側支持部(第二支持部)11Cは、補強部材側支持板21Cと、補強部材側支持板21Cの略中央部に設けられて軸受嵌合孔21aに嵌合する球面滑り軸受22と、柱側支持部(第一支持部)5Cの一対の軸支持部13Cを拘束する拘束部材61と、を備えている。なお、補強部材側支持部11Cは、前記補強部材側支持部11に対して拘束部材61が追加された点で特に異なる。また、補強部材側支持板21Cには、例えば拘束部材61の貫通ボルト62が貫通して固定される一対のボルト固定孔21eが追加されている。
拘束部材61は、詳しくは、軸支持部13Cに備える柱側支持板(被押圧部)16Cを押圧して拘束する。なお、軸支持部13Cは、前記軸支持部13に対して一対のねじ孔16gを無くしている。
<Modifications of Restraint Member>
As shown in Fig. 16, the reinforcing member side support part (second support part) 11C includes a reinforcing member side support plate 21C, a spherical plain bearing 22 provided in the approximate center of the reinforcing member side support plate 21C and fitted into the bearing fitting hole 21a, and a restraining member 61 that restrains a pair of shaft support parts 13C of the column side support part (first support part) 5C. The reinforcing member side support part 11C is particularly different from the reinforcing member side support part 11 in that the restraining member 61 is added. In addition, the reinforcing member side support plate 21C is additionally provided with a pair of bolt fixing holes 21e through which the through bolts 62 of the restraining member 61 pass and are fixed.
Specifically, the restraining member 61 presses and restrains a column side support plate (pressed portion) 16C provided in the shaft support portion 13C. Note that the shaft support portion 13C does not have a pair of screw holes 16g with respect to the shaft support portion 13C.

拘束部材61は、補強部材側支持板21Cを貫通するとともにこの補強部材側支持板21Cに固定された貫通ボルト62と、貫通ボルト62の両端部側にねじ結合された一対の位置調整部材63と、各位置調整部材63に設けられた拘束部(押圧部)64と、位置調整部材63を貫通ボルト62に固定するロックナット65と、を備えている。 The restraining member 61 includes a through bolt 62 that passes through the reinforcing member side support plate 21C and is fixed to the reinforcing member side support plate 21C, a pair of position adjustment members 63 that are screwed to both ends of the through bolt 62, a restraining portion (pressing portion) 64 provided on each position adjustment member 63, and a lock nut 65 that fixes the position adjustment member 63 to the through bolt 62.

貫通ボルト62は、補強部材側支持板21Cの両側に突出する一対のねじ部62aを備えている。位置調整部材63は、ナット状に形成され、貫通ボルト62の一対のねじ部62aにそれぞれねじ結合されている。拘束部64は、位置調整部材63の外周部に支持された拘束部基部64aと、拘束部基部64aに取り付けられて柱側支持部5Cの柱側支持板16Cを滑り可能に押圧する滑り板64bと、を備えている。 The through bolt 62 has a pair of threaded portions 62a that protrude from both sides of the reinforcing member side support plate 21C. The position adjustment member 63 is formed in a nut shape and is screwed to each of the pair of threaded portions 62a of the through bolt 62. The restraining portion 64 has a restraining portion base 64a supported on the outer periphery of the position adjustment member 63, and a sliding plate 64b attached to the restraining portion base 64a and slidably pressing against the column side support plate 16C of the column side support portion 5C.

滑り板64bの材質としては、例えば、フッ素樹脂等の低摩擦材が好適である。また、滑り板64bに押圧される柱側支持板16Cの表面に低摩擦材を備えてもよい。すなわち、滑り板64bおよび柱側支持板16Cの表面の少なくとの一方に低摩擦材を備える構成であればよい。低摩擦材はコーティングであってもよい。 The material of the sliding plate 64b is preferably a low-friction material such as fluororesin. In addition, a low-friction material may be provided on the surface of the column side support plate 16C that is pressed against the sliding plate 64b. In other words, it is sufficient that at least one of the surfaces of the sliding plate 64b and the column side support plate 16C is provided with a low-friction material. The low-friction material may be a coating.

以上説明したように、上記実施形態における支承Sは、構造物BLおよび補強部材7の一方(例えば構造物BL)における第一支持部(例えば柱側支持部5)に設けられた長孔形成部16bと、構造物BLおよび補強部材7の他方(例えば補強部材7)における第二支持部(例えば補強部材側支持部11)に設けられた球面滑り軸受22と、長孔形成部16bが形成する長孔16aに挿入され、長孔16a内を長孔16aの長手方向に移動可能な可動板17と、柱側支持部5に対して可動板17とともに長孔16aの長手方向に移動可能に支持されるとともに、補強部材側支持部11に対して球面滑り軸受22を介して回動可能に支持されて、柱側支持部5および補強部材側支持部11を連結する連結軸14と、を備えている。 As described above, the support S in the above embodiment includes a long hole forming portion 16b provided in the first support portion (e.g., column side support portion 5) of one of the structure BL and the reinforcing member 7 (e.g., the structure BL), a spherical plain bearing 22 provided in the second support portion (e.g., the reinforcing member side support portion 11) of the other of the structure BL and the reinforcing member 7 (e.g., the reinforcing member 7), a movable plate 17 inserted into the long hole 16a formed by the long hole forming portion 16b and movable within the long hole 16a in the longitudinal direction of the long hole 16a, and a connecting shaft 14 supported to be movable in the longitudinal direction of the long hole 16a together with the movable plate 17 relative to the column side support portion 5 and rotatably supported via the spherical plain bearing 22 relative to the reinforcing member side support portion 11, connecting the column side support portion 5 and the reinforcing member side support portion 11.

この構成によれば、地震や強風等によって構造物BLが振動した際、補強部材側支持部11及び柱側支持部5が相対変位しても、両支持部同士を連結する連結軸14は、柱側支持部5に対して可動板17とともに長孔16a内を移動するので、長孔16aの長手方向における補強部材側支持部11及び柱側支持部5の相対変位が許容される。このとき、補強部材側支持部11及び柱側支持部5の相対変位によってこれらの相対回動が生じる場合にも、連結軸14が球面滑り軸受22を介してスムーズに回動するので、回動を含む相対変位が良好に許容される。また、可動板17が長孔16aの内面に面又は複数の点により接触する構成とすることで、可動板17から長孔16aの内面に作用する荷重を分散させて接触圧を抑え、補強部材側支持部11及び柱側支持部5の相対変位をより良好に許容することができる。一方、長孔16aの長手方向と交差する方向においては、可動板17および球面滑り軸受22を介して十分な支持荷重を受けることができる。 According to this configuration, even if the reinforcing member side support part 11 and the column side support part 5 are displaced relative to each other when the structure BL vibrates due to an earthquake, strong wind, etc., the connecting shaft 14 connecting the two support parts moves in the long hole 16a together with the movable plate 17 relative to the column side support part 5, so that the relative displacement of the reinforcing member side support part 11 and the column side support part 5 in the longitudinal direction of the long hole 16a is permitted. At this time, even if the relative rotation of the reinforcing member side support part 11 and the column side support part 5 occurs due to the relative displacement of the reinforcing member side support part 11 and the column side support part 5, the connecting shaft 14 rotates smoothly via the spherical plain bearing 22, so that the relative displacement including the rotation is well tolerated. In addition, by configuring the movable plate 17 to contact the inner surface of the long hole 16a at a surface or multiple points, the load acting on the inner surface of the long hole 16a from the movable plate 17 is dispersed to suppress the contact pressure, and the relative displacement of the reinforcing member side support part 11 and the column side support part 5 can be better tolerated. On the other hand, in the direction intersecting the longitudinal direction of the long hole 16a, sufficient support load can be received via the movable plate 17 and the spherical plain bearing 22.

また、上記支承Sにおいて、球面滑り軸受22は、連結軸14を回動可能に支持するとともに、連結軸14を揺動可能に支持するので、柱側支持部5および補強部材側支持部11の相対変位によってこれらの相対揺動が生じる場合にも、連結軸14が球面滑り軸受22を介して揺動可能であるので、揺動を含む相対変位が良好に許容される。長孔16aの長手方向への連結軸14の移動と、球面滑り軸受22による連結軸14の回動および揺動とが分離して行われるので、前者の移動と後者の回動および揺動とが互いに影響を受けにくい。よって柱側支持部5および補強部材側支持部11の相対変位をより一層良好に許容することができる。 In addition, in the above-mentioned support S, the spherical plain bearing 22 supports the connecting shaft 14 so that it can rotate and also supports the connecting shaft 14 so that it can swing. Therefore, even when relative swing occurs due to the relative displacement of the column side support part 5 and the reinforcing member side support part 11, the connecting shaft 14 can swing via the spherical plain bearing 22, so that relative displacement including swing is well tolerated. Since the movement of the connecting shaft 14 in the longitudinal direction of the long hole 16a and the rotation and swing of the connecting shaft 14 by the spherical plain bearing 22 are performed separately, the former movement and the latter rotation and swing are less likely to affect each other. Therefore, the relative displacement of the column side support part 5 and the reinforcing member side support part 11 can be tolerated even better.

また、上記支承Sにおいて、長孔16aは、長手方向が水平方向を指向するので、地震や強風等によって構造物BLが水平方向に振動した際にも、柱側支持部5および補強部材側支持部11の水平方向の相対変位を良好に許容することができる。 In addition, in the above-mentioned support S, the long hole 16a has a longitudinal direction oriented horizontally, so that it can well tolerate the relative horizontal displacement of the column side support part 5 and the reinforcing member side support part 11 even when the structure BL vibrates horizontally due to an earthquake, strong winds, etc.

また、上記支承Sにおいて、長孔16aは、互いに平行をなして対向する上部内面16dおよび下部内面16eを有し、可動板17は、上部内面16dおよび下部内面16eにそれぞれ内接又は近接した状態で、長孔16a内を移動するので、長孔16aの各内面と交差する方向への可動板17の移動を規制するとともに、可動板17のスムーズな移動を実現することができる。長孔16aを矩形等の単純形状とすることで、長孔形成部16bの加工を容易にすることができる。 In addition, in the support S, the long hole 16a has upper and lower inner surfaces 16d and 16e that face each other in parallel, and the movable plate 17 moves within the long hole 16a while inscribed in or adjacent to the upper and lower inner surfaces 16d and 16e, respectively, so that the movement of the movable plate 17 in a direction intersecting with each inner surface of the long hole 16a is restricted, and smooth movement of the movable plate 17 can be achieved. By making the long hole 16a a simple shape such as a rectangle, the machining of the long hole forming portion 16b can be facilitated.

また、上記支承Sにおいて、可動板17は、面又は複数の点により上部内面16dおよび下部内面16eの少なくとも一方に接した状態で、長孔16a内を移動するので、可動板17から長孔16aの内面に伝わる荷重を分散させて接触圧を抑え、柱側支持部5および補強部材側支持部11の相対変位をより良好に許容することができる。 In addition, in the above-mentioned support S, the movable plate 17 moves within the long hole 16a while in contact with at least one of the upper inner surface 16d and the lower inner surface 16e by a surface or multiple points, so that the load transmitted from the movable plate 17 to the inner surface of the long hole 16a is dispersed, suppressing the contact pressure and allowing better tolerance for relative displacement of the column side support part 5 and the reinforcing member side support part 11.

また、上記支承Sにおいて、長孔16aと可動板17との接触部分に潤滑剤が塗布されるので、可動板17が長孔16a内を移動する際の抵抗をより一層小さくし、柱側支持部5および補強部材側支持部11の相対変位をより良好に許容することができる。 In addition, in the above-mentioned support S, a lubricant is applied to the contact area between the long hole 16a and the movable plate 17, which further reduces the resistance when the movable plate 17 moves within the long hole 16a, and better tolerates relative displacement between the column side support part 5 and the reinforcing member side support part 11.

また、上記支承Sにおいて、補強部材側支持部11および柱側支持部5の少なくとも一方に設けられ、連結軸14の軸方向で補強部材側支持部11および柱側支持部5の他方を滑り可能に押圧する拘束部材26を備え、拘束部材26は、補強部材側支持部11および柱側支持部5の軸方向の相対位置を拘束するので、拘束部材26を設けることで、長孔16a内の連結軸14の移動への影響を抑えた上で、補強部材側支持部11および柱側支持部5の位置調整や施工誤差吸収を可能とすることができる。 The support S also includes a restraining member 26 that is provided on at least one of the reinforcing member side support part 11 and the column side support part 5 and slidably presses the other of the reinforcing member side support part 11 and the column side support part 5 in the axial direction of the connecting shaft 14. The restraining member 26 restrains the relative axial positions of the reinforcing member side support part 11 and the column side support part 5. By providing the restraining member 26, it is possible to adjust the positions of the reinforcing member side support part 11 and the column side support part 5 and absorb construction errors while suppressing the effect on the movement of the connecting shaft 14 within the long hole 16a.

また、上記支承Sにおいて、補強部材側支持部11および柱側支持部5の少なくとも一方における拘束部材26に押圧される補強部材側支持板21と、拘束部材26の拘束部28との少なくとも一方に、低摩擦部を備えるので、拘束部材26によって補強部材側支持部11および柱側支持部5の少なくとも一方に押圧力を付与しながら、補強部材側支持部11および柱側支持部5の相対変位への影響を抑えることができる。 In addition, in the above-mentioned support S, at least one of the reinforcing member side support plate 21, which is pressed against the restraining member 26 in at least one of the reinforcing member side support part 11 and the column side support part 5, and the restraining part 28 of the restraining member 26, is provided with a low friction part, so that the restraining member 26 can apply a pressing force to at least one of the reinforcing member side support part 11 and the column side support part 5 while suppressing the effect on the relative displacement of the reinforcing member side support part 11 and the column side support part 5.

上記実施形態における制振システム1は、層を成す構造物BLの制振システムであって、構造物BLの層における層間に設けられ、前記第一支持部および前記第二支持部の一方である柱側支持部5が設けられた柱P1,P2と、柱P1,P2に連結され、前記第一支持部および前記第二支持部の他方である補強部材側支持部11が設けられた補強部材7と、補強部材7に設置されたV字ブレース30と、補強部材7に対向する梁Q2とV字ブレース30との間に設けられて水平方向の振動を減衰させる制振ダンパー35と、上記何れかに記載の支承Sと、を備えている。 The vibration control system 1 in the above embodiment is a vibration control system for a layered structure BL, and includes columns P1, P2 provided between layers of the structure BL and provided with a column side support part 5 which is one of the first support part and the second support part, a reinforcing member 7 connected to the columns P1, P2 and provided with a reinforcing member side support part 11 which is the other of the first support part and the second support part, a V-shaped brace 30 installed on the reinforcing member 7, a vibration control damper 35 provided between the beam Q2 facing the reinforcing member 7 and the V-shaped brace 30 to damp horizontal vibrations, and a support S as described above.

この構成によれば、構造物BLに水平方向の振動が発生したとしても、この振動を制振ダンパー35で減衰させるとともに、制振ダンパー35の反力を補強部材側支持部11及び柱側支持部5の相対変位の範囲内で吸収可能となり、構造物BLの層間の柱P1,P2に反力が伝達されにくくすることができる。 With this configuration, even if horizontal vibrations occur in the structure BL, the vibrations can be damped by the vibration damper 35, and the reaction force of the vibration damper 35 can be absorbed within the range of relative displacement between the reinforcing member side support part 11 and the column side support part 5, making it difficult for the reaction force to be transmitted to the columns P1 and P2 between the layers of the structure BL.

ここで、上記実施形態の制振システム1の変形例について図17を参照して説明する。上記実施形態と同一構成には同一符号を付して詳細説明は省略する。
変形例の制振システム101は、前記制振システム1と同様、構造物BLの二層間の空間2に配置されている。
上側の梁(第一部材)Q1の第一構面6側には、補強部材(第二部材)7が配置されている。第一構面6の長手方向中間部には、梁側支持部(第一支持部)105が固定されている。梁側支持部105は、例えば、互いに平行な一対の板材で形成されている。
Here, a modified example of the vibration control system 1 of the above embodiment will be described with reference to Fig. 17. The same components as those of the above embodiment will be given the same reference numerals and detailed description will be omitted.
The vibration control system 101 of the modified example is disposed in the space 2 between two floors of a structure BL, similar to the vibration control system 1 described above.
A reinforcing member (second member) 7 is disposed on the first structural face 6 side of the upper beam (first member) Q1. A beam-side support portion (first support portion) 105 is fixed to the longitudinal middle portion of the first structural face 6. The beam-side support portion 105 is formed, for example, of a pair of plate members parallel to each other.

補強部材7には、梁側支持部105の内側に配置された補強部材上側支持部(第二支持部)111が固定されている。補強部材上側支持部111は、例えば、梁側支持部105の各板材と平行な板状に形成されている。
補強部材上側支持部111ひいては補強部材7は、梁側支持部105ひいては上側の梁Q1に、支承S’を介して支持されている。支承S’は、図2に示す支承Sを、連結軸14中心に90度回転させた態様をなしている。支承S’は、梁側支持部105に対して補強部材上側支持部111を、上下方向・左右方向に揺動可能に支持し、かつ鉛直方向に移動可能に支持している。
A reinforcing member upper support portion (second support portion) 111 arranged inside the beam side support portion 105 is fixed to the reinforcing member 7. The reinforcing member upper support portion 111 is formed, for example, in a plate shape parallel to each plate material of the beam side support portion 105.
The reinforcing member upper support portion 111, and therefore the reinforcing member 7, are supported by the beam side support portion 105, and therefore the upper beam Q1, via a bearing S'. The bearing S' is formed by rotating the bearing S shown in Fig. 2 by 90 degrees around the connecting shaft 14. The bearing S' supports the reinforcing member upper support portion 111 relative to the beam side support portion 105 so that it can swing up and down and left and right, and also supports it so that it can move vertically.

図2、図3を援用し、梁側支持部105は、柱側支持部5と同様、一対の軸支持部13で構成され、これら一対の軸支持部13の間に補強部材上側支持部111が配置されている。一対の軸支持部13と補強部材上側支持部111とは、連結軸14と同様の連結軸114が貫通し、この連結軸114を介して一対の軸支持部13と補強部材上側支持部111とが互いに連結されている。梁側支持部105の軸支持部13は、柱側支持板16と同様の支持板に、長手方向が鉛直方向を指向する長孔16aを形成し、この長孔16a内に可動板17を移動可能に配置している。梁側支持部105の長孔16aは、互いに平行をなして鉛直方向に延びる側部内面を備え、これら一対の側部内面に沿って、可動板17が鉛直方向に移動可能である。なお、前記「鉛直方向を指向する」とは、鉛直方向に一致することに限らず、例えば鉛直方向に対して±30度程度の範囲を含む。 2 and 3, the beam side support part 105 is composed of a pair of shaft support parts 13, similar to the column side support part 5, and the reinforcing member upper support part 111 is arranged between the pair of shaft support parts 13. A connecting shaft 114 similar to the connecting shaft 14 penetrates the pair of shaft support parts 13 and the reinforcing member upper support part 111, and the pair of shaft support parts 13 and the reinforcing member upper support part 111 are connected to each other via the connecting shaft 114. The shaft support part 13 of the beam side support part 105 has a long hole 16a whose longitudinal direction is oriented vertically in a support plate similar to the column side support plate 16, and the movable plate 17 is movably arranged in the long hole 16a. The long hole 16a of the beam side support part 105 has side inner surfaces that extend vertically in parallel to each other, and the movable plate 17 can move vertically along the pair of side inner surfaces. Note that "pointing vertically" does not necessarily mean coinciding with the vertical direction, but includes a range of, for example, about ±30 degrees from the vertical direction.

補強部材上側支持部111は、補強部材側支持板21と同様の支持板に、球面滑り軸受(軸受)22を嵌合させている。球面滑り軸受22の内輪には、連結軸114が嵌合されている。連結軸114と補強部材上側支持部111の支持板とは、相対的に上下方向及び水平方向に揺動可能、且つ連結軸114の軸芯回りに相対回動可能である。
梁側支持部105の一対の軸支持部13には、それぞれ補強部材上側支持部111の支持板を拘束する複数の拘束部材26が設けられている。
The reinforcing member upper support part 111 has a spherical plain bearing (bearing) 22 fitted to a support plate similar to the reinforcing member side support plate 21. A connecting shaft 114 is fitted to the inner ring of the spherical plain bearing 22. The connecting shaft 114 and the support plate of the reinforcing member upper support part 111 can swing relatively in the vertical and horizontal directions, and can rotate relatively around the axis of the connecting shaft 114.
A pair of shaft support portions 13 of the beam side support portion 105 are provided with a plurality of restraining members 26 that restrain the support plates of the reinforcing member upper support portions 111 .

本実施形態による制振装置101では、構造物BLが地震等で振動して変形すると、空間2を構成する柱P1,P2と梁Q1,Q2とがそれぞれ水平方向に往復運動する。
このとき、補強部材7は、上側の梁Q1の第一構面6の支承S’の連結軸114を中心に揺動する。補強部材7の両端部においては、支承Sの連結軸114を中心に回動するとともに、連結軸114を介して連結された可動板17が長孔16a内を水平方向に移動する。これにより、補強部材7の両端部の支承Sにおいて、補強部材7の鉛直方向の支持力を確保しつつ、上記した回動と水平方向の変位とを同時に許容可能である。
In the vibration control device 101 according to this embodiment, when the structure BL vibrates and deforms due to an earthquake or the like, the columns P1, P2 and the beams Q1, Q2 that constitute the space 2 each perform a reciprocating motion in the horizontal direction.
At this time, the reinforcing member 7 swings around the connecting shaft 114 of the support S' of the first structural face 6 of the upper beam Q1. At both ends of the reinforcing member 7, it rotates around the connecting shaft 114 of the support S, and the movable plate 17 connected via the connecting shaft 114 moves horizontally within the long hole 16a. As a result, at the supports S at both ends of the reinforcing member 7, it is possible to simultaneously allow the above-mentioned rotation and horizontal displacement while ensuring the vertical supporting force of the reinforcing member 7.

さらに、変形例では、補強部材7の長手方向中間部を上方から支持する支承S’において、長手方向を鉛直方向に向けた長孔16a内を可動板17が鉛直方向に移動する。これにより、構造物BLが水平方向に振動して補強部材7と梁Q1との間の間隔が変化する場合にも、梁Q1に対する補強部材7の鉛直方向の移動を許容可能である。また、構造物BLの水平方向の振動に限らず、梁Q1に作用する積載荷重の変化等に起因して補強部材7と梁Q1との間の間隔が変化する場合にも、補強部材7に対する梁Q1の鉛直方向の移動を許容可能である。これにより、補強部材7の上部の支承S’において、補強部材7の水平方向の支持力を確保しつつ、上記した揺動と鉛直方向の変位とを同時に許容可能である。 In addition, in the modified example, in the support S' that supports the longitudinal middle part of the reinforcing member 7 from above, the movable plate 17 moves vertically in the long hole 16a whose longitudinal direction is oriented vertically. This allows the vertical movement of the reinforcing member 7 relative to the beam Q1 even when the structure BL vibrates horizontally and the distance between the reinforcing member 7 and the beam Q1 changes. In addition, not only when the structure BL vibrates horizontally, but also when the distance between the reinforcing member 7 and the beam Q1 changes due to a change in the load acting on the beam Q1, the vertical movement of the beam Q1 relative to the reinforcing member 7 can be allowed. This allows the support S' at the top of the reinforcing member 7 to simultaneously allow the above-mentioned rocking and vertical displacement while ensuring the horizontal support force of the reinforcing member 7.

上記変形例では、補強部材7の長手方向中間部を上方から支承S’で支持し、補強部材7の下方にV字ブレース30を設置し、補強部材7に対向する下側の梁Q2とV字ブレース30との間に制振ダンパー35を設ける構成としたが、この構成に限らず、図17を上下反転した構成でもよい。すなわち、補強部材7の長手方向中間部を下方から支承S’で支持し、補強部材7の上方にV字ブレース30を設置し、補強部材7に対向する上側の梁Q1とV字ブレース30との間に制振ダンパー35を設ける構成でもよい。 In the above modified example, the longitudinal middle part of the reinforcing member 7 is supported from above by the support S', the V-shaped brace 30 is installed below the reinforcing member 7, and the vibration damper 35 is provided between the lower beam Q2 facing the reinforcing member 7 and the V-shaped brace 30, but this configuration is not limited to this, and a configuration in which FIG. 17 is inverted upside down may also be used. In other words, a configuration in which the longitudinal middle part of the reinforcing member 7 is supported from below by the support S', the V-shaped brace 30 is installed above the reinforcing member 7, and the vibration damper 35 is provided between the upper beam Q1 facing the reinforcing member 7 and the V-shaped brace 30 may also be used.

上記した支承S’においても、梁(第一部材)Q1の梁側支持部(第一支持部)105が一対の軸支持部13(長孔16aおよび可動板17含む)で構成され、これら一対の軸支持部13の間に補強部材(第二部材)7の単一の補強部材上側支持部(第二支持部)111(軸受22含む)が配置されているが、これとは逆に、補強部材上側支持部111が一対の軸支持部(長孔16aおよび可動板17含む)で構成され、これら一対の軸支持部の間に単一の梁側支持部105(軸受22含む)が配置される構成でもよい。
また、支承S’の他の形態として、梁(第一部材)Q1の梁側支持部(第一支持部)105が一対の支持部(軸受22含む)で構成され、これら一対の支持部の間に補強部材(第二部材)7の単一の補強部材上側支持部(第二支持部)111(長孔16aおよび可動板17含む)が配置される構成でもよい。
さらに、補強部材上側支持部111が一対の支持部(軸受22含む)で構成され、これら一対の支持部の間に単一の梁側支持部105(長孔16aおよび可動板17含む)が配置される構成でもよい。
In the above-mentioned support S', the beam side support portion (first support portion) 105 of the beam (first member) Q1 is composed of a pair of shaft support portions 13 (including the long hole 16a and the movable plate 17), and a single reinforcing member upper support portion (second support portion) 111 (including the bearing 22) of the reinforcing member (second member) 7 is arranged between this pair of shaft support portions 13. However, conversely, the reinforcing member upper support portion 111 may be composed of a pair of shaft support portions (including the long hole 16a and the movable plate 17), and a single beam side support portion 105 (including the bearing 22) may be arranged between this pair of shaft support portions.
In addition, as another form of the support S', the beam side support portion (first support portion) 105 of the beam (first member) Q1 may be composed of a pair of support portions (including bearings 22), and a single reinforcing member upper support portion (second support portion) 111 (including the long hole 16a and the movable plate 17) of the reinforcing member (second member) 7 may be arranged between this pair of support portions.
Furthermore, the reinforcing member upper support portion 111 may be configured to be composed of a pair of support portions (including bearings 22), and a single beam side support portion 105 (including the long hole 16a and movable plate 17) may be arranged between the pair of support portions.

なお、本発明は上記実施形態に限られるものではなく、例えば、軸受については、球面滑り軸受に限らず、軸の軸芯回りに回動可能および上下左右揺動可能な他の形式の軸受でも良い。
本発明は上述した実施形態による支承Sおよび制振装置1に限定されることはなく、本発明の要旨を逸脱しない範囲で適宜の変更や置換等が可能であり、これらはいずれも本発明に含まれる。
The present invention is not limited to the above embodiment. For example, the bearing is not limited to a spherical plain bearing, but may be another type of bearing that is rotatable around the axis of the shaft and capable of swinging up and down and left and right.
The present invention is not limited to the support S and vibration control device 1 according to the above-described embodiment, and appropriate modifications and substitutions are possible without departing from the gist of the present invention, and all of these are included in the present invention.

補強部材7と制振ダンパー35との間に接続するV字ブレース30に代えて略四角形枠状のブレース等を接続してもよい。
また、制振装置1および支承Sは構造物BLの任意の場所に設置することができ、かつ設置数も適宜選択できる。また、上述した実施形態では構造物BLに装着した支承Sおよび制振装置1について説明したが、本発明は構造物BLに限定されるものではなく、構造物BL以外に各種の施設や設備等を含む構造物にも適用できる。
Instead of the V-shaped brace 30 connected between the reinforcing member 7 and the vibration damper 35, a brace having a substantially rectangular frame shape or the like may be connected.
The vibration damping device 1 and the bearings S can be installed at any location in the structure BL, and the number of installations can be selected appropriately. In the above-mentioned embodiment, the bearings S and the vibration damping device 1 mounted on the structure BL are described, but the present invention is not limited to the structure BL, and can be applied to structures including various facilities and equipment other than the structure BL.

1,101 制振装置(制振システム)
5,5A,5B,5C 柱側支持部(第二又は第一支持部)
7 補強部材(第二部材)
11,11C 補強部材側支持部(第一又は第二支持部)
14,114 連結軸(軸)
16C 柱側支持板(被押圧部)
16a,46a,56a 長孔
16b 長孔形成部
16d,46d,56d 上部内面
16e,46e,56e 下部内面
17 可動板
17d 上面
17e 下面
21 補強部材側支持板(被押圧部)
22 球面滑り軸受(軸受)
26,61 拘束部材
28,64 拘束部(押圧部)
30 V字ブレース(ブレース部材)
35 制振ダンパー
105 梁側支持部(第二又は第一支持部)
111 補強部材上側支持部(第一又は第二支持部)
BL 構造物
P1,P2 柱(第一部材)
Q1,Q2 梁(第一部材)
S,SA,S’ 支承
1,101 Vibration control device (vibration control system)
5, 5A, 5B, 5C Pillar side support part (second or first support part)
7 Reinforcing member (second member)
11, 11C Reinforcing member side support portion (first or second support portion)
14,114 Connection shaft (shaft)
16C Pillar side support plate (pressed part)
16a, 46a, 56a Long hole 16b Long hole forming part 16d, 46d, 56d Upper inner surface 16e, 46e, 56e Lower inner surface 17 Movable plate 17d Upper surface 17e Lower surface 21 Reinforcement member side support plate (pressed part)
22 Spherical plain bearing (bearing)
26, 61 Restraint member 28, 64 Restraint portion (pressure portion)
30 V-shaped brace (brace member)
35 Vibration damper 105 Beam side support part (second or first support part)
111 Reinforcement member upper support portion (first or second support portion)
BL Structure P1, P2 Column (first member)
Q1, Q2 Beam (first member)
S, SA, S' Support

Claims (4)

構造物および前記構造物に連結する部材の一方における第一支持部に設けられた長孔形成部と、
前記構造物および前記部材の他方における第二支持部に設けられた軸受と、
前記長孔形成部が形成する長孔に挿入され、前記長孔内を前記長孔の長手方向に移動可能な可動板と、
前記第一支持部に対して前記可動板とともに前記長孔の長手方向に移動可能に支持されるとともに、前記第二支持部に対して前記軸受を介して回動可能に支持されて、前記第一支持部および前記第二支持部を連結する軸と、
を備え、
前記長孔と前記可動板との接触部分に潤滑剤が塗布されることを特徴とする支承。
a slot forming portion provided in a first support portion of one of the structure and a member connected to the structure;
a bearing provided in a second support portion on the other of the structure and the member;
a movable plate that is inserted into a long hole formed by the long hole forming portion and is movable within the long hole in a longitudinal direction of the long hole;
a shaft supported by the first support portion so as to be movable together with the movable plate in the longitudinal direction of the long hole and supported by the second support portion so as to be rotatable via the bearing, the shaft connecting the first support portion and the second support portion;
Equipped with
A bearing characterized in that a lubricant is applied to a contact portion between the long hole and the movable plate.
構造物および前記構造物に連結する部材の一方における第一支持部に設けられた長孔形成部と、
前記構造物および前記部材の他方における第二支持部に設けられた軸受と、
前記長孔形成部が形成する長孔に挿入され、前記長孔内を前記長孔の長手方向に移動可能な可動板と、
前記第一支持部に対して前記可動板とともに前記長孔の長手方向に移動可能に支持されるとともに、前記第二支持部に対して前記軸受を介して回動可能に支持されて、前記第一支持部および前記第二支持部を連結する軸と、
前記第一支持部および前記第二支持部の少なくとも一方に設けられ、前記軸の軸方向で前記第一支持部および前記第二支持部の他方を滑り可能に押圧する拘束部材を備え、
前記拘束部材は、前記第一支持部および前記第二支持部の前記軸方向の相対位置を拘束することを特徴とする支承。
a slot forming portion provided in a first support portion of one of the structure and a member connected to the structure;
a bearing provided in a second support portion on the other of the structure and the member;
a movable plate that is inserted into a long hole formed by the long hole forming portion and is movable within the long hole in a longitudinal direction of the long hole;
a shaft supported by the first support portion so as to be movable together with the movable plate in the longitudinal direction of the elongated hole and supported by the second support portion so as to be rotatable via the bearing, the shaft connecting the first support portion and the second support portion;
a restraining member provided on at least one of the first support portion and the second support portion and configured to slidably press the other of the first support portion and the second support portion in an axial direction of the shaft;
A support characterized in that the restraining member restrains the relative positions of the first support portion and the second support portion in the axial direction.
前記第一支持部および前記第二支持部の少なくとも一方における前記拘束部材に押圧される被押圧部と、前記拘束部材の押圧部との少なくとも一方に、低摩擦部を備えることを特徴とする請求項に記載の支承。 The support according to claim 2, characterized in that at least one of the pressed portion pressed by the restraining member in at least one of the first support portion and the second support portion and the pressing portion of the restraining member is provided with a low friction portion. 層を成す建造物の制振システムであって、
構造物および前記構造物に連結する部材の一方における第一支持部に設けられた長孔形成部と、
前記構造物および前記部材の他方における第二支持部に設けられた軸受と、
前記長孔形成部が形成する長孔に挿入され、前記長孔内を前記長孔の長手方向に移動可能な可動板と、
前記第一支持部に対して前記可動板とともに前記長孔の長手方向に移動可能に支持されるとともに、前記第二支持部に対して前記軸受を介して回動可能に支持されて、前記第一支持部および前記第二支持部を連結する軸と、
を備えを備える支承と、
前記建造物の層における層間に設けられ、前記第一支持部および前記第二支持部の一方が設けられた第一部材と、
前記第一部材に連結され、前記第一支持部および前記第二支持部の他方が設けられた第二部材と、
前記第二部材に設置されたブレース部材と、
前記第二部材に対向する梁と前記ブレース部材との間に設けられて水平方向の振動を減衰させる制振ダンパーと、
を備え
前記第二部材は、水平方向に延びて前記構造物に連結する補強部材であり、
前記補強部材の長さ方向両端部は、前記長孔の長手方向が水平方向を指向した前記支承を介して前記構造物に連結され、
前記補強部材の長さ方向中間部は、前記長孔の長手方向が鉛直方向を指向した前記支承を介して前記構造物に連結されることを特徴とする制振システム。
A vibration control system for a multi-storey building, comprising:
a slot forming portion provided in a first support portion of one of the structure and a member connected to the structure;
a bearing provided in a second support portion on the other of the structure and the member;
a movable plate that is inserted into a long hole formed by the long hole forming portion and is movable within the long hole in a longitudinal direction of the long hole;
a shaft supported by the first support portion so as to be movable together with the movable plate in the longitudinal direction of the elongated hole and supported by the second support portion so as to be rotatable via the bearing, the shaft connecting the first support portion and the second support portion;
A bearing comprising:
A first member provided between layers of the building and provided with one of the first support portion and the second support portion;
a second member connected to the first member and provided with the other of the first support portion and the second support portion;
A brace member installed on the second member;
A vibration damper provided between a beam facing the second member and the brace member to attenuate horizontal vibrations;
Equipped with
The second member is a reinforcing member extending horizontally and connected to the structure,
Both ends of the reinforcing member in the longitudinal direction are connected to the structure via the support in which the longitudinal direction of the long hole is oriented horizontally,
A vibration control system, characterized in that the longitudinal intermediate portion of the reinforcing member is connected to the structure via the support, the longitudinal direction of the long hole of which is oriented vertically.
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006274622A (en) 2005-03-29 2006-10-12 Misawa Homes Co Ltd Vibration control device
JP2014058790A (en) 2012-09-14 2014-04-03 Nippon Chuzo Co Ltd Vibration control damper
JP2021021310A (en) 2019-07-25 2021-02-18 株式会社Nttファシリティーズ Vibration damping reinforcement system

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006274622A (en) 2005-03-29 2006-10-12 Misawa Homes Co Ltd Vibration control device
JP2014058790A (en) 2012-09-14 2014-04-03 Nippon Chuzo Co Ltd Vibration control damper
JP2021021310A (en) 2019-07-25 2021-02-18 株式会社Nttファシリティーズ Vibration damping reinforcement system

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