JP2012127465A - High bearing support device for structure - Google Patents

High bearing support device for structure Download PDF

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JP2012127465A
JP2012127465A JP2010281362A JP2010281362A JP2012127465A JP 2012127465 A JP2012127465 A JP 2012127465A JP 2010281362 A JP2010281362 A JP 2010281362A JP 2010281362 A JP2010281362 A JP 2010281362A JP 2012127465 A JP2012127465 A JP 2012127465A
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rubber body
support device
bearing support
rubber
high bearing
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JP5408672B2 (en
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Yuichi Aida
裕一 合田
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MIWA TEC KK
Miwa Tech Co Ltd
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Miwa Tech Co Ltd
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Abstract

PROBLEM TO BE SOLVED: To provide a high bearing support device for a structure which can be inexpensively manufactured, exert a high bearing force by restraining deformation to the outside in a horizontal direction with respect to a larger compression load, and suppress oscillation of an upper structure by exerting an excellent attenuation effect of earthquake energy.SOLUTION: In the high bearing support device for the structure installed between the upper structure and the lower structure of the structure, a pillar-shaped rubber body is disposed between upper and lower steel plates, and fiber members are disposed in the rubber body in parallel to the compression load direction which acts on the rubber body in a shape with a plurality of concentric circles or spirals.

Description

本発明は、橋梁や建物などの構造物の上部構造と下部構造の間に介設され、地震時に作用した地震エネルギーを吸収し減衰させて上部構造の揺れを抑えるための構造物用高支圧支承装置に関する。   The present invention is provided between a superstructure and a substructure of a structure such as a bridge or a building, and absorbs and attenuates seismic energy that has acted during an earthquake to suppress shaking of the superstructure. It relates to a bearing device.

従来、例えば橋梁や高層建物などの構造物においては、主桁や主構と橋台や橋脚の間、建物と基礎の間など、上部構造と下部構造の間にゴム支承(反力分散支承,免震支承等)が配置される。   Conventionally, for structures such as bridges and high-rise buildings, rubber bearings (reactive force dispersion bearings, Seismic support etc.).

ゴム支承として、高減衰ゴムなどのゴム材(弾性体)と鋼板(補剛体)とを上下方向に交互に積層して構成したものがある。このような支承装置においては、ゴム材及び鋼板によって鉛直荷重に対し高ばね化されているため、上部構造を支持することができる。また、水平荷重に対しゴム材が水平方向に変形するように低ばね化されているため、地震時に水平方向に大きな外力(地震エネルギー)が作用するとともにゴム材が水平方向に変形し、このゴム材の変形によって地震エネルギーが吸収される。   As a rubber bearing, there is a structure in which a rubber material (elastic body) such as high damping rubber and a steel plate (stiffening body) are alternately laminated in the vertical direction. In such a support device, the upper structure can be supported because the spring is made high with respect to the vertical load by the rubber material and the steel plate. In addition, since the spring is reduced so that the rubber material deforms in the horizontal direction against the horizontal load, a large external force (earthquake energy) acts in the horizontal direction during an earthquake and the rubber material deforms in the horizontal direction. Seismic energy is absorbed by deformation of the material.

一方、ゴム材の中にゴム材と交互になるように織布や不織布(繊維材)を積層埋設して構成したものもある(例えば、特許文献1、特許文献2参照)。このような支承装置においては、一定値以上の鉛直荷重が作用した場合に繊維材が破断することでエネルギー吸収効果を発揮し、鉛直方向(上下方向、積層方向)の衝撃荷重の発生を抑制することができる。また、一定値以上の水平荷重が作用した場合には、繊維材とゴム材の界面が剥離することでエネルギー吸収効果を発揮する。   On the other hand, there is a rubber material in which a woven fabric or a non-woven fabric (fiber material) is laminated and embedded so as to alternate with a rubber material (see, for example, Patent Document 1 and Patent Document 2). In such a support device, when a vertical load of a certain value or more is applied, the fiber material breaks to exhibit an energy absorption effect and suppress the occurrence of impact load in the vertical direction (vertical direction, stacking direction). be able to. Further, when a horizontal load of a certain value or more acts, the energy absorption effect is exhibited by peeling the interface between the fiber material and the rubber material.

特開平10−140524号公報JP-A-10-140524 特開2001−49619号公報JP 2001-49619 A

しかしながら、上記従来のゴム材と鋼板を交互に積層して構成した支承装置においては、地震時に作用した地震エネルギー(水平荷重)をゴム材の水平方向の変形のみで吸収して減衰効果を発揮し、また、一定値以上の変形が発生して初めて減衰効果を発揮するため、免震装置(ゴム材)の水平変形量が大きく、上部構造の水平変位量が大きくなる。すなわち、この種の免震装置は、例えばレベル1地震動(構造物の供用期間内に1〜2度発生する確率をもつ地震動)の地震時にゴム材の厚さの150%程度、レベル2地震動(極めて稀であるが非常に強い地震動)の地震時にゴム材の厚さの250%程度の水平変位が発生する。このため、この支承装置を例えば橋梁の主桁(主構)と橋台の間に介設した場合には、地震時に支承装置の変位(ゴム材の変形)とともに主桁が大きく水平方向に変位することになり、主桁の端部と橋台との間の遊間を大きく設定する必要が生じていた。そして、これに伴い、大きなフィンガージョイントなどのジョイント構造が必要になって、ジョイント構造のコストが高くなるなどの問題があった。   However, the conventional bearing device constructed by alternately laminating the rubber material and steel plate absorbs the seismic energy (horizontal load) applied during the earthquake only by the horizontal deformation of the rubber material and exhibits a damping effect. In addition, since the damping effect is exhibited only after a deformation exceeding a certain value occurs, the amount of horizontal deformation of the seismic isolation device (rubber material) is large, and the amount of horizontal displacement of the superstructure is large. That is, this type of seismic isolation device is, for example, approximately 150% of the thickness of rubber material at the time of level 1 ground motion (earth motion with a probability of occurring once or twice during the service period of the structure), level 2 ground motion ( A horizontal displacement of about 250% of the thickness of the rubber material occurs during an earthquake of extremely rare but very strong earthquake motion. For this reason, when this support device is interposed between the main girder (main structure) of the bridge and the abutment, for example, the main girder is greatly displaced in the horizontal direction along with the displacement of the support device (deformation of the rubber material) during an earthquake. Therefore, it was necessary to set a large gap between the end of the main girder and the abutment. Along with this, there is a problem that a joint structure such as a large finger joint is required and the cost of the joint structure is increased.

一方、上記従来のゴム材の中に繊維材を水平に積層埋設して構成した支承装置においては、地震時に作用した一定値以上の地震エネルギー(水平荷重)を繊維材とゴム材の界面が剥離することで吸収し、減衰効果を発揮するため、ゴム材の水平変形量ひいては上部構造の水平変位量を制御できる。しかしながら、このような繊維材とゴム材の剥離によって地震エネルギーを減衰させる場合には、繊維材の破断による減衰効果ほど大きな効果を期待できず、例えばレベル1地震動やレベル2地震動に対しては、やはりゴム材の水平変形量ひいては上部構造の水平変位量を十分に制御できない。   On the other hand, in the bearing device that is constructed by horizontally laying and embedding fiber materials in the above-mentioned conventional rubber material, the interface between the fiber material and the rubber material exfoliates the seismic energy (horizontal load) that has acted at the time of the earthquake. In order to absorb and exhibit a damping effect, the horizontal deformation amount of the rubber material and thus the horizontal displacement amount of the superstructure can be controlled. However, when the seismic energy is attenuated by such a separation of the fiber material and the rubber material, the effect as great as the attenuation effect due to the breakage of the fiber material cannot be expected. For example, for level 1 earthquake motion or level 2 earthquake motion, Again, the amount of horizontal deformation of the rubber material and thus the amount of horizontal displacement of the superstructure cannot be controlled sufficiently.

本発明は、低コストで製造ができ、大きな圧縮荷重に対して水平方向外側への変形を拘束して高支圧力を発揮することができ、且つ優れた地震エネルギーの減衰効果を発揮して上部構造の揺れを抑えることが可能な構造物用高支圧支承装置を提供することを目的とする。   The present invention can be manufactured at a low cost, can restrain deformation to the outside in the horizontal direction against a large compressive load and can exert a high support pressure, and exhibits an excellent seismic energy damping effect. An object of the present invention is to provide a high bearing support device for a structure capable of suppressing the shaking of the structure.

本発明の構造物用高支圧支承装置は、前記課題を解決するために、構造物の上部構造と下部構造の間に設置される構造物用高支圧支承装置において、上下鋼板間に柱状のゴム体を配置し、前記ゴム体内に繊維部材を前記ゴム体に作用する圧縮荷重方向に対して平行に複数の同心円状又は螺旋状に配置することを特徴とする。   In order to solve the above-mentioned problem, a high bearing support device for a structure according to the present invention is a column-like structure between upper and lower steel plates in a high bearing support device for a structure installed between an upper structure and a lower structure of the structure. The rubber member is disposed, and the fiber member is disposed in the rubber body in a plurality of concentric or spiral shapes in parallel to the compression load direction acting on the rubber body.

また、本発明の構造物用高支圧支承装置は、前記繊維部材は、糸状又は布状の繊維にゴム又は減衰性に優れた樹脂を含浸又は塗布しシート状にしたものを複数回巻き付けるか複数枚積層して形成することを特徴とする。   Further, in the high bearing support device for a structure of the present invention, the fiber member may be a plurality of times in which a fiber or fiber-like fiber impregnated or coated with rubber or a resin excellent in damping property is wound a plurality of times. It is characterized by being formed by laminating a plurality of sheets.

また、本発明の構造物用高支圧支承装置は、前記ゴム体内の外側に位置する繊維部材を内側に向かって凹ませた形状にして配置することを特徴とする。   Further, the high bearing support device for a structure according to the present invention is characterized in that the fiber member located outside the rubber body is arranged in a concave shape toward the inside.

また、本発明の構造物用高支圧支承装置は、前記ゴム体の中心部に硬質樹脂プレートとゴムを水平方向に複数枚積層した芯材を配置することを特徴とする。   Moreover, the high bearing support device for a structure of the present invention is characterized in that a core material in which a plurality of hard resin plates and rubber are laminated in the horizontal direction is arranged at the center of the rubber body.

また、本発明の構造物用高支圧支承装置は、前記ゴム体と前記繊維部材の配置領域を前記上下鋼板の外周外側位置まで延長することを特徴とする。   Moreover, the high bearing support apparatus for structures of this invention is characterized by extending the arrangement | positioning area | region of the said rubber body and the said fiber member to the outer periphery outer side position of the said upper and lower steel plates.

また、本発明の構造物用高支圧支承装置は、前記上下鋼板、前記ゴム体及び前記繊維部材を加硫一体成形により一体化することを特徴とする。   Moreover, the high bearing support device for structures of the present invention is characterized in that the upper and lower steel plates, the rubber body, and the fiber member are integrated by vulcanization integral molding.

構造物の上部構造と下部構造の間に設置される構造物用高支圧支承装置において、上下鋼板間に柱状のゴム体を配置し、ゴム体内に繊維部材をゴム体に作用する圧縮荷重方向に対して平行に複数の同心円状又は螺旋状に配置することで、複数の同心円状又は螺旋状にゴム体中に配置された繊維部材により鉛直方向の圧縮荷重によるゴム体の水平方向外側への大きな変形を拘束し、高支圧力荷重支承作用を実現することが可能となる。
繊維部材は、糸状、布状又はネット状の繊維素材にゴム又は減衰性に優れた樹脂を含浸又は塗布しシート状にしたものをゴム体に複数回巻き付けるか複数枚積層して形成することで、ゴム体への繊維部材の一体配置を容易とすると共に、ゴム体と繊維部材の一体化を強固にし、圧縮荷重によるゴムの水平方向外側への変形を拘束する力を増加することが可能となる。
ゴム体内の外側に位置する繊維部材を内側に向かって凹ませた形状にして配置することで、大きな圧縮荷重によるゴム体の水平方向外側への大きな変形を抑制することが可能となる。
ゴム体の中心部に硬質樹脂プレートとゴムを水平方向に複数段積層した芯材を配置することで、芯材を高剛性にすることでゴム体を高バネ化しより高支圧力を発揮することが可能となる。
ゴム体と繊維部材の配置領域を上下鋼板の外周外側位置まで延長することで、上下鋼板、ゴム体及び繊維部材の一体化をより強固にすることが可能になる。
上下鋼板、ゴム体及び繊維部材を加硫一体成形により一体化することで、上下鋼板、ゴム体及び繊維部材の一体化を強固にすることが可能になる。
In a high bearing support device for a structure installed between the upper structure and the lower structure of a structure, a columnar rubber body is disposed between upper and lower steel plates, and a compressive load direction in which a fiber member acts on the rubber body in the rubber body Are arranged in parallel in a plurality of concentric circles or spirals, so that a plurality of concentric or spiral fiber members arranged in the rubber body causes the rubber body to move outward in the horizontal direction due to a vertical compressive load. It is possible to restrain a large deformation and realize a high support pressure load support operation.
The fiber member is formed by winding a rubber-like fiber material impregnated or coated with rubber or a resin excellent in damping property into a sheet shape, or by wrapping the rubber body a plurality of times or by laminating a plurality of sheets. The fiber body can be easily integrated with the rubber body, the rubber body and the fiber member can be firmly integrated, and the force that restrains the deformation of the rubber in the horizontal direction due to the compressive load can be increased. Become.
By disposing the fiber member located outside in the rubber body so as to be recessed toward the inside, it is possible to suppress a large deformation of the rubber body in the horizontal direction due to a large compressive load.
By placing a core material in which multiple layers of hard resin plates and rubber are stacked horizontally in the center of the rubber body, the core material is made highly rigid, making the rubber body more springy and exhibiting higher support pressure. Is possible.
By extending the arrangement region of the rubber body and the fiber member to the outer peripheral position of the upper and lower steel plates, it is possible to further strengthen the integration of the upper and lower steel plates, the rubber body, and the fiber member.
By integrating the upper and lower steel plates, the rubber body, and the fiber member by vulcanization integral molding, it becomes possible to strengthen the integration of the upper and lower steel plates, the rubber body, and the fiber member.

(a)(b)本発明の実施形態を示す図である。(A) (b) It is a figure which shows embodiment of this invention. (a)(b)本発明の実施形態を示す図である。(A) (b) It is a figure which shows embodiment of this invention. (a)(b)本発明の実施形態を示す図である。(A) (b) It is a figure which shows embodiment of this invention. (a)(b)本発明の実施形態を示す図である。(A) (b) It is a figure which shows embodiment of this invention. 本発明の実施形態を示す図である。It is a figure which shows embodiment of this invention. 本発明の実施形態を示す図である。It is a figure which shows embodiment of this invention. 本発明の実施形態を示す図である。It is a figure which shows embodiment of this invention.

本発明の実施の形態を図により説明する。図1(a)(b)は、本発明の構造物用高支圧支承装置1の一実施形態を示す図である。   Embodiments of the present invention will be described with reference to the drawings. Fig.1 (a) (b) is a figure which shows one Embodiment of the high bearing support apparatus 1 for structures of this invention.

橋梁、建築物等の構造物の上部構造と下部構造の間に設置される構造物支承装置1は、上下鋼板4、5の間に天然ゴム又は高減衰ゴムからなる柱状のゴム体2が配置される。柱状のゴム体2内には、中心ゴム2aの周囲に複数の環状の繊維部材3a、3b、3cが複数の環状のゴム2b、2cを挟んで同心円状に配置される。繊維部材3a、3b、3cは、構造物支承装置1が受ける鉛直方向の圧縮荷重方向と平行に配置される。繊維部材3は、ゴム体2の軸方向の長さとほぼ同じか若干短い長さとして配置する。   In a structure support device 1 installed between an upper structure and a lower structure of a structure such as a bridge or a building, a columnar rubber body 2 made of natural rubber or high damping rubber is disposed between upper and lower steel plates 4 and 5. Is done. In the columnar rubber body 2, a plurality of annular fiber members 3a, 3b, 3c are arranged concentrically around the center rubber 2a with the plurality of annular rubbers 2b, 2c interposed therebetween. The fiber members 3a, 3b, 3c are arranged in parallel to the vertical compressive load direction received by the structure bearing device 1. The fiber member 3 is arranged with a length substantially the same as or slightly shorter than the length of the rubber body 2 in the axial direction.

繊維部材3は、繊維素材6として炭素繊維、ガラス繊維、ポリアミド系繊維、ビニロン繊維、ビニール繊維、鋼繊維等が用いられる。図5は、糸状の繊維素材6を縦方向に複数配列したものであり、図6は、糸状の繊維素材6を横方向に複数配列したものであり、図7は、縦方向の繊維素材6と横方向の繊維素材6を織ったり編んだりして布状又はネット状としたものである。図5〜図7に示されるように配列された繊維素材6に天然ゴム又は減衰性に優れた樹脂等からなる母材7を含浸又は塗布しシート状にする。シート状にした繊維素材6を中心ゴム2a、環状のゴム2b、2cの周囲に複数巻き巻き付け、径方向に所定厚みの繊維部材3として同心円状に複数配置する。   The fiber member 3 is made of carbon fiber, glass fiber, polyamide fiber, vinylon fiber, vinyl fiber, steel fiber or the like as the fiber material 6. 5 shows a plurality of thread-like fiber materials 6 arranged in the longitudinal direction, FIG. 6 shows a plurality of thread-like fiber materials 6 arranged in the transverse direction, and FIG. 7 shows a fiber material 6 in the longitudinal direction. The fabric material 6 is woven or knitted in the transverse direction to form a cloth shape or a net shape. The fiber material 6 arranged as shown in FIGS. 5 to 7 is impregnated or coated with a base material 7 made of natural rubber or a resin having excellent damping properties to form a sheet. A plurality of sheet-like fiber materials 6 are wound around the center rubber 2a and the annular rubbers 2b and 2c, and a plurality of fiber members 3 having a predetermined thickness in the radial direction are arranged concentrically.

図5及び図6に示されるように繊維素材6が縦横一方向に配列されたシート状のものは、中心ゴム2a、環状のゴム2b、2cの周囲に複数巻き巻き付ける場合、繊維素材7が縦方向に配列されたものと横方向に配列されたものを交互に巻き付けて繊維部材3を形成することで、ゴムの圧縮荷重による水平方向外側への変形を拘束するための拘束力を増加することが可能となる。   As shown in FIG. 5 and FIG. 6, in the case of a sheet in which the fiber material 6 is arranged in one vertical and horizontal direction, when a plurality of windings are wound around the center rubber 2 a and the annular rubbers 2 b and 2 c, the fiber material 7 is vertically Increasing the restraining force for restraining the deformation to the outside in the horizontal direction due to the compression load of rubber by forming the fiber member 3 by alternately winding the one arranged in the direction and the one arranged in the lateral direction Is possible.

繊維部材3が複数同心円状に配置した柱状のゴム体2の上下に上鋼板4と下鋼板5を配置する。上鋼板4と下鋼板5の外周外側の位置まで繊維部材3cと環状のゴム体2dを配置する。その結果、上鋼板4と下鋼板5は、外周面部と裏面又は上面がゴム体2又は繊維部材3と接するように配置される。このように配置された上下鋼板4,5、ゴム体2及び繊維部材3を加硫一体成形することで、上下鋼板4,5、ゴム体2及び繊維部材3が強固に一体化することが可能となる。   An upper steel plate 4 and a lower steel plate 5 are arranged above and below a columnar rubber body 2 in which a plurality of fiber members 3 are arranged concentrically. The fiber member 3c and the annular rubber body 2d are disposed up to the outer peripheral positions of the upper steel plate 4 and the lower steel plate 5. As a result, the upper steel plate 4 and the lower steel plate 5 are disposed so that the outer peripheral surface portion and the back surface or the upper surface are in contact with the rubber body 2 or the fiber member 3. The upper and lower steel plates 4 and 5, the rubber body 2, and the fiber member 3 can be firmly integrated by vulcanizing and integrally forming the upper and lower steel plates 4 and 5, the rubber body 2, and the fiber member 3 arranged in this way. It becomes.

図1(a)(b)に示す実施形態では、同心円状に配置される環状の繊維部材3a,3b,3cの数を3列としているが、環状の繊維部材3の径方向の厚みを小さくしてより多くの列の環状の繊維部材3を配置しても良い。 In the embodiment shown in FIGS. 1A and 1B, the number of annular fiber members 3a, 3b, 3c arranged concentrically is three rows, but the radial thickness of the annular fiber member 3 is reduced. Then, more rows of annular fiber members 3 may be arranged.

この実施形態の構造物用高支圧支承装置1は、柱状のゴム体2内に同心円状に複数の環状の繊維部材3a,3b、3cが環状のゴム2b、2c、2dと一体化されて配置されているため、鉛直方向の圧縮荷重によるゴム体2の水平方向外側への変形が環状の繊維部材3a,3b、3cにより拘束され、高支圧力を発揮することが可能となる。   In the structure high bearing support device 1 of this embodiment, a plurality of annular fiber members 3a, 3b, 3c are integrated with annular rubbers 2b, 2c, 2d concentrically in a columnar rubber body 2. Therefore, deformation of the rubber body 2 toward the outside in the horizontal direction due to the compressive load in the vertical direction is restrained by the annular fiber members 3a, 3b, and 3c, and a high supporting pressure can be exerted.

図2(a)(b)は、本発明の構造物用高支圧支承装置1の他の実施形態を示す図である。   2 (a) and 2 (b) are diagrams showing another embodiment of the high bearing support device 1 for a structure according to the present invention.

この実施形態の構造物用高支圧支承装置1は、ゴム体2の中心にエボナイト等の硬質樹脂プレート8と積層ゴム2fを水平に複数積層して芯材9とする。柱状のゴム体2内には、複数の環状の繊維部材3a、3b、3cが複数の環状のゴム2b、2cを挟んで同心円状に配置される。繊維部材3a、3b、3cは、構造物支承装置1が受ける鉛直方向の圧縮荷重方向と平行に配置される。繊維部材3は、ゴム体2の軸方向の長さとほぼ同じか若干短い長さとして配置する。   The structural high bearing support device 1 of this embodiment forms a core material 9 by horizontally laminating a plurality of hard resin plates 8 such as ebonite and laminated rubber 2 f at the center of a rubber body 2. In the columnar rubber body 2, a plurality of annular fiber members 3a, 3b, 3c are arranged concentrically with the plurality of annular rubbers 2b, 2c interposed therebetween. The fiber members 3a, 3b, 3c are arranged in parallel to the vertical compressive load direction received by the structure bearing device 1. The fiber member 3 is arranged with a length substantially the same as or slightly shorter than the length of the rubber body 2 in the axial direction.

他の構成は、図1(a)(b)に示す実施形態と同様であるので説明を省略する。この実施形態では、芯材9が硬質樹脂プレート8と積層ゴム2fとを水平に複数積層して形成されているため、芯材9の剛性が大きく、鉛直方向の圧縮荷重に対して高バネ化し、柱状のゴム体2内に配置された複数の環状の繊維部材3a、3b、3cによりゴム体2の水平方向外側への変形に対する拘束力と協働して大きな高支圧力を発揮することが可能となる。   Other configurations are the same as those of the embodiment shown in FIGS. In this embodiment, since the core material 9 is formed by horizontally laminating a plurality of hard resin plates 8 and laminated rubber 2f, the rigidity of the core material 9 is large, and the spring is made high against a vertical compressive load. In addition, a plurality of annular fiber members 3a, 3b, 3c arranged in the columnar rubber body 2 can exert a large high supporting pressure in cooperation with the restraining force against the deformation of the rubber body 2 toward the outside in the horizontal direction. It becomes possible.

図3(a)(b)は、本発明の構造物用高支圧支承装置1の他の実施形態を示す図である。   3 (a) and 3 (b) are diagrams showing another embodiment of the high bearing support device 1 for a structure according to the present invention.

この実施形態の構造物用高支圧支承装置1は、図1(a)(b)に示す実施形態と同様に、柱状のゴム体2内には、中心ゴム2aの周囲に複数の環状の繊維部材3a、3b、3c、3dが複数の環状のゴム2b、2c、2dを挟んで同心円状に配置される。柱状のゴム体2内の外側に位置する環状の繊維部材3c、3dの軸方向の中間部をゴム体2の中心に向かって凹ませた状態で配置する。他の構成は、図1(a)(b)に示す実施形態と同様であるので説明を省略する。   As in the embodiment shown in FIGS. 1 (a) and 1 (b), the structure high bearing support device 1 of this embodiment has a plurality of annular members around the center rubber 2a in the columnar rubber body 2. The fiber members 3a, 3b, 3c, and 3d are arranged concentrically with a plurality of annular rubbers 2b, 2c, and 2d interposed therebetween. The intermediate portions in the axial direction of the annular fiber members 3 c and 3 d located outside the columnar rubber body 2 are arranged in a state of being recessed toward the center of the rubber body 2. Other configurations are the same as those of the embodiment shown in FIGS.

柱状のゴム体2内の外側に位置する環状の繊維部材3c、3dを圧縮荷重によりゴム体2が変形する反対方向に予め凹まして配置することで、圧縮荷重によるゴム体2の水平方向外側への変形を拘束する拘束力が増加し、高支圧化を図ることが可能となる。   The annular fiber members 3c and 3d located outside the columnar rubber body 2 are recessed in advance in the opposite direction in which the rubber body 2 is deformed by the compressive load, so that the rubber body 2 due to the compressive load is moved outward in the horizontal direction. The restraining force that restrains the deformation of the material increases, and a high bearing pressure can be achieved.

図4(a)(b)は、本発明の構造物用高支圧支承装置1の他の実施形態を示す図である。   4 (a) and 4 (b) are views showing another embodiment of the high bearing support device 1 for a structure of the present invention.

この実施形態の構造物用高支圧支承装置1は、柱状のゴム体2内に、中心ゴム2aを中心として繊維部材3aがゴム体2の外側に向かって螺旋状に配置される。螺旋状に配置された線に部材3aの外側に環状の繊維部材3bを配置する。他の構成は、図1(a)(b)に示す実施形態と同様であるので説明を省略する。   In the high bearing support device for a structure 1 of this embodiment, a fiber member 3a is spirally arranged in a columnar rubber body 2 with a center rubber 2a as a center toward the outside of the rubber body 2. An annular fiber member 3b is arranged outside the member 3a on a spirally arranged line. Other configurations are the same as those of the embodiment shown in FIGS.

柱状のゴム体2内に、中心ゴム2aを中心として繊維部材3aがゴム体2の外側に向かって螺旋状に配置することで、鉛直方向の圧縮荷重によるゴム体2の水平方向外側への変形が拘束され、高支圧力を発揮することが可能となる。   In the columnar rubber body 2, the fiber member 3 a is arranged spirally around the center rubber 2 a toward the outside of the rubber body 2, so that the rubber body 2 is deformed outward in the horizontal direction by a compressive load in the vertical direction. Is restrained and a high supporting pressure can be exerted.

以上のように本発明の構造物用高支圧支承装置によれば、大きな圧縮荷重に対して水平方向外側への変形を拘束して高支圧力を発揮することができ、且つ優れた地震エネルギーの減衰効果を発揮して上部構造の揺れを抑えることが可能な構造物用高支圧支承装置を提供することが可能となる。   As described above, according to the high bearing support device for a structure of the present invention, it is possible to constrain deformation to the outside in the horizontal direction against a large compressive load and exhibit high bearing pressure, and excellent seismic energy. It is possible to provide a high bearing support device for a structure that can exhibit the damping effect of the above and can suppress the shaking of the superstructure.

1:構造物用高支圧支承装置、2:ゴム体、2a:中心ゴム体、2b、2c、2d,2e:環状ゴム体、2f:積層ゴム体、3:繊維部材、3a,3b、3c、3e:環状の繊維部材、4:上鋼板、5:下鋼板、6:繊維素材、7:母材、8:硬質樹脂プレート、9:芯材   1: High bearing support device for structure, 2: rubber body, 2a: center rubber body, 2b, 2c, 2d, 2e: annular rubber body, 2f: laminated rubber body, 3: fiber member, 3a, 3b, 3c 3e: annular fiber member, 4: upper steel plate, 5: lower steel plate, 6: fiber material, 7: base material, 8: hard resin plate, 9: core material

Claims (6)

構造物の上部構造と下部構造の間に設置される構造物用高支圧支承装置において、
上下鋼板間に柱状のゴム体を配置し、前記ゴム体内に繊維部材を前記ゴム体に作用する圧縮荷重方向に対して平行に複数の同心円状又は螺旋状に配置することを特徴とする構造物用高支圧支承装置。
In the high bearing support device for a structure installed between the upper structure and the lower structure of the structure,
A structure in which a columnar rubber body is disposed between upper and lower steel plates, and a fibrous member is disposed in the rubber body in a plurality of concentric or spiral shapes in parallel to the direction of compressive load acting on the rubber body. High bearing support device.
前記繊維部材は、糸状又は布状の繊維にゴム又は減衰性に優れた樹脂を含浸又は塗布しシート状にしたものを複数回巻き付けるか複数枚積層して形成することを特徴とする請求項1に記載の構造物用高支圧支承装置。   2. The fiber member is formed by winding or laminating a plurality of yarn-like or cloth-like fibers impregnated or coated with rubber or a resin excellent in damping property into a sheet shape. High bearing support device for structures as described in 1. 前記ゴム体内の外側に位置する繊維部材を内側に向かって凹ませた形状にして配置することを特徴とする請求項1又は2に記載の構造物用高支圧支承装置。   The high bearing support device for a structure according to claim 1, wherein the fiber member located outside the rubber body is arranged in a concave shape toward the inside. 前記ゴム体の中心部に硬質樹脂プレートとゴムを水平方向に複数積層した芯材を配置することを特徴とする請求項1ないし3のいずれか1項に記載の構造物用高支圧支承装置。   The high bearing support device for a structure according to any one of claims 1 to 3, wherein a core material in which a plurality of hard resin plates and rubber are laminated in a horizontal direction is disposed at a central portion of the rubber body. . 前記ゴム体と前記繊維部材の配置領域を前記上下鋼板の外周外側位置まで延長することを特徴とする請求項1ないし4のいずれか1項に記載の構造物用高支圧支承装置。   5. The high bearing support device for a structure according to claim 1, wherein an arrangement region of the rubber body and the fiber member is extended to an outer peripheral outside position of the upper and lower steel plates. 前記上下鋼板、前記ゴム体及び前記繊維部材を加硫一体成形により一体化することを特徴とする請求項1ないし5のいずれか1項に記載の構造物用高支圧支承装置。   6. The high bearing support device for a structure according to claim 1, wherein the upper and lower steel plates, the rubber body, and the fiber member are integrated by vulcanization integrated molding.
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CN102995557A (en) * 2012-12-25 2013-03-27 南京工程学院 Fiber rubber supporting seat
CN103195854A (en) * 2013-04-09 2013-07-10 中国电力工程顾问集团中南电力设计院 Earthquake-isolation energy dissipator for ultra-high-voltage converter transformer
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CN114810939A (en) * 2022-05-09 2022-07-29 云南电网有限责任公司电力科学研究院 Electrical equipment damping device

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102995557A (en) * 2012-12-25 2013-03-27 南京工程学院 Fiber rubber supporting seat
CN103195854A (en) * 2013-04-09 2013-07-10 中国电力工程顾问集团中南电力设计院 Earthquake-isolation energy dissipator for ultra-high-voltage converter transformer
CN103195853A (en) * 2013-04-09 2013-07-10 中国电力工程顾问集团中南电力设计院 Earthquake-isolation limiting device for ultra-high-voltage converter transformer
JP2016003534A (en) * 2014-06-19 2016-01-12 旭化成ホームズ株式会社 Attenuation structure of building
CN114810939A (en) * 2022-05-09 2022-07-29 云南电网有限责任公司电力科学研究院 Electrical equipment damping device

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