Deprecated: The each() function is deprecated. This message will be suppressed on further calls in /home/zhenxiangba/zhenxiangba.com/public_html/phproxy-improved-master/index.php on line 456
JPH0233826B2 - - Google Patents
[go: Go Back, main page]

JPH0233826B2 - - Google Patents

Info

Publication number
JPH0233826B2
JPH0233826B2 JP59041667A JP4166784A JPH0233826B2 JP H0233826 B2 JPH0233826 B2 JP H0233826B2 JP 59041667 A JP59041667 A JP 59041667A JP 4166784 A JP4166784 A JP 4166784A JP H0233826 B2 JPH0233826 B2 JP H0233826B2
Authority
JP
Japan
Prior art keywords
membrane
cables
roof
cable
panels
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
JP59041667A
Other languages
Japanese (ja)
Other versions
JPS60188579A (en
Inventor
Hiroyuki Kuroiwa
Ryozo Kawai
Nobuo Yamaguchi
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Takenaka Komuten Co Ltd
Original Assignee
Takenaka Komuten Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Takenaka Komuten Co Ltd filed Critical Takenaka Komuten Co Ltd
Priority to JP4166784A priority Critical patent/JPS60188579A/en
Publication of JPS60188579A publication Critical patent/JPS60188579A/en
Publication of JPH0233826B2 publication Critical patent/JPH0233826B2/ja
Granted legal-status Critical Current

Links

Landscapes

  • Tents Or Canopies (AREA)

Description

【発明の詳細な説明】 この発明は空気膜構造屋根に関する。[Detailed description of the invention] The present invention relates to a pneumatic membrane structure roof.

空気膜構造とは屋根面にケーブルを交叉させ
て、もち網状に張り渡し、その升目部分に膜材を
四周に固定させながら張りめぐらし、屋根面に膜
材を張り終わつた段階で、室内に空気を送入し、
室内空気圧を大気圧より0.0025気圧(25Kg/m2
ほど高めて屋根面を膨らませるエアサポート構造
であるが、そのケーブル配置の従来技術として
は、2方向配置が多い。
The air membrane structure is made by crossing cables on the roof surface and stretching them in the shape of a sticky net, and then fixing the membrane material around the squares of the grid on all four sides. send the
Indoor air pressure 0.0025 atmospheres (25Kg/m 2 ) below atmospheric pressure
This is an air support structure that inflates the roof surface by increasing the height of the air support structure, and the conventional technology for cable arrangement is often two-way arrangement.

この2方向配置は、米国において、当該建物の
平面形状が矩形または超楕円形式になる場合、境
界構造としてのコンプレツシヨンリングに曲げ応
力の発生を極力少なくする方法として、最も都合
の良いケーブル配置として採用されたものであ
る。
This two-way arrangement is the most convenient cable arrangement in the United States as a method to minimize bending stress on the compression ring as a boundary structure when the plan shape of the building is rectangular or super elliptical. It was adopted as

この2方向ケーブルは、米国で10数例を数え、
建物の都度、次第に改善されてきているが、これ
にはいくつかの問題点も残されている。
There are over 10 examples of this two-way cable in the United States.
Although improvements have been made gradually with each building, some problems remain.

第一は、内圧によつて釣合曲面を得るエアサポ
ート構造では、第1図に示す如く、形状決定した
後で風や雪で形状が変化しやすいため、膜1やケ
ーブル2が変化した状態で再び釣合いを保持する
条件で幾何学的非線形解析を行なわなければなら
ないが、この2方向ケーブルで作られた区画に取
付けられた膜パネルがほとんど製作形状を異に
し、同一製品を量産化する様に製造することが出
来ず、製作費が割高となることである。この理由
は、2方向ケーブル配置で作られた膜材区画は、
投影平面では同一寸法となるが、屋根は曲面を構
成しているため、実際に製作される膜パネルはそ
れぞれにわずかながら寸法が異なるのである。
Firstly, in an air support structure that obtains a balanced curved surface by internal pressure, the shape is easily changed by wind or snow after the shape is determined, as shown in Figure 1, so the membrane 1 and cable 2 may change. Geometric nonlinear analysis must be performed again under the condition of maintaining balance, but the membrane panels installed in the compartments made of these two-way cables are almost all manufactured in different shapes, making it difficult to mass-produce the same product. It cannot be manufactured in the same time frame, and the manufacturing cost is relatively high. The reason for this is that membrane sections made with a two-way cable arrangement
Although the dimensions are the same on the projected plane, because the roof is a curved surface, the dimensions of the membrane panels actually manufactured differ slightly.

これを解決するため、米国であえて膜製作寸法
を統一した事例があるが、これは屋根が期待した
曲面とならず平坦になつてしまつたため、降雪時
に雪が中央部にたまり屋根が降下してしまつたと
いう事故があり、再びそれ以降に造られたものは
再び従来の方法をとり、屋根パネルの寸法を統一
することをやめ、一つづつ所定の寸法形状に基づ
いて製作している。
In order to solve this problem, there is a case in the United States where the dimensions of membrane production were purposely standardized, but this resulted in the roof not being curved as expected but becoming flat, and when it snowed, snow accumulated in the center and the roof fell down. There was an accident called Shimatsuta, and the ones built after that time have again used the conventional method, and instead of standardizing the dimensions of the roof panels, they are manufactured one by one based on a predetermined size and shape.

第二は、2方向ケーブル配置を屋根面全面に配
置した事例もあつたが、周辺部はケーブル長も短
かくなり、ケーブル張力も大きくならないため、
周辺ケーブルを省略してケーブル本数を少なくす
る事例が多くなつている。これは屋根の建設費を
低減させ、屋根重量を軽減させるメリツトはある
が、一方膜材の材料強度から判断すると中央部分
の菱形部分は2方向で膜応力を負担することが出
来るのに対し、周辺部の長方形部分は短辺方向で
膜応力を負担することになる。
Second, there were cases where two-way cables were placed on the entire roof surface, but the cable length was short in the peripheral area, and the cable tension did not increase.
There are many cases where peripheral cables are omitted to reduce the number of cables. This has the advantage of reducing roof construction costs and roof weight, but on the other hand, judging from the material strength of the membrane material, the diamond-shaped part in the center can bear the membrane stress in two directions. The rectangular portion at the periphery bears membrane stress in the short side direction.

従つて当該長方形部分においては、膜材の1軸
許容応力により、膜材設計がなされ、同一膜材を
使用する場合、菱形部分の膜パネルは過剰設計に
なる。
Therefore, in the rectangular portion, the membrane material is designed based on the uniaxial allowable stress of the membrane material, and if the same membrane material is used, the membrane panel in the diamond-shaped portion will be over-designed.

第三に、この2方向ケーブル配置はほぼ同間隔
に配置されるが、極めて大規模な屋根面積におい
ては、屋根面にかかる最大風荷重も屋根部位によ
つて異なり、膜パネルも同一応力ではありえな
い。これは2方向等間隔ケーブル配置から起因す
るものである。
Third, although this two-way cable arrangement is placed at approximately the same spacing, in extremely large roof areas, the maximum wind load on the roof surface also varies depending on the roof area, and the membrane panels cannot be under the same stress. . This results from the two-way equally spaced cable arrangement.

本発明は叙上の問題点に鑑みなされたもので、
その要旨とするところは、ケーブルを放射状並び
に同心円状に配置し、周辺部において配置した放
射状ケーブルを中央部になるにつれて、その本数
を間引きする様に取付け、それらのケーブルによ
つて構成された升目区画に膜材を取付けるとし
て、膜パネルの形状・寸法を出来る限り統一し、
屋根面積に対して、膜パネル数を少なくし、生産
の合理化・経済化を図ると共に、膜及びケーブル
の許容応力度を最大限に活用できる様に、膜につ
いては相当の2軸応力負担としケーブルについて
は等寸法のものを用いて、張力分担の均等化を図
れる様にしたことを特徴とするもので、以下、こ
れを図にもとづいて詳細に説明する。
The present invention was made in view of the above problems.
The gist of this is that cables are arranged radially and concentrically, and the radial cables arranged at the periphery are thinned out in number as they move towards the center. When installing membrane materials in compartments, the shape and dimensions of the membrane panels should be unified as much as possible.
In order to reduce the number of membrane panels relative to the roof area and to rationalize and make production more economical, as well as to make maximum use of the allowable stress of the membrane and cables, the membranes bear considerable biaxial stress and the cables This feature is characterized in that the tension is distributed evenly by using the same dimensions, and this will be explained in detail below based on the drawings.

すなわち、米国ではフツトボール競技等のため
に建設された屋根付きスタジアムが多く、平面形
状は長方形あるいは超楕円形状となることが多い
が、日本では野球を主要対象競技とするため、円
形に近い平面を持つことが多い。
In other words, in the United States, there are many stadiums with roofs built for football games, etc., and the planar shape is often rectangular or super elliptical, but in Japan, since baseball is the main sport, stadiums with a roof are often built with a planar shape that is close to circular. often have.

よつて、この平面形状を前提とした場合、第2
図に示す如く放射状ケーブルa配置と同心円状ケ
ーブルb配置の併用が可能である。
Therefore, assuming this planar shape, the second
As shown in the figure, it is possible to use both the radial cable arrangement a and the concentric cable arrangement b.

しかしながら、この様な同心円状と放射状ケー
ブルb,a配置は、円周部にあつては使用膜材の
許容応力度が最大限に活用できる様、膜パネル寸
法を設定できるが、中央部にくるにつれて放射状
ケーブルaの間隔は狭くなり、膜面積が小さく膜
の存在応力は小さくなり、膜材の強度を経済的に
活用できないことになるうえ、膜パネル数が増大
し、ケーブルと膜材の取付金物等も不必要に多く
なり、不経済となる。
However, with such a concentric and radial cable arrangement b and a, the membrane panel dimensions can be set so that the allowable stress of the membrane material used can be set to the maximum in the circumferential area, but in the central area As the distance between the radial cables a becomes narrower, the membrane area becomes smaller and the existing stress of the membrane becomes smaller, which means that the strength of the membrane material cannot be utilized economically, and the number of membrane panels increases, making it difficult to attach the cables and the membrane material. The amount of hardware, etc. increases unnecessarily, making it uneconomical.

このため、同心円状ケーブルbと放射状ケーブ
ルaによつて構成される空気膜構造ケーブル配置
に関して、中央部においては放射状ケーブルaを
間引き、中央部のケーブル区画を適切な区画とし
たものである。
For this reason, regarding the air membrane structure cable arrangement constituted by concentric cables b and radial cables a, the radial cables a are thinned out in the center, and the cable sections in the center are made into appropriate sections.

尚、図中Oは境界構造としてのコンプレツシヨ
ンリングを示す。
Note that O in the figure indicates a compression ring as a boundary structure.

この多段リング状の均等升目区画帯を構成する
方式を採用することにより、膜材cの許容応力度
を最大限に発揮でき、かつ異種パネルを少なくし
て膜パネルの製作枚数を減じ、膜パネル製作寸法
の統一を図り、経済的に生産することが出来るよ
うになる。
By adopting this method of configuring a multi-stage ring-shaped equally spaced zone, it is possible to maximize the allowable stress of the membrane material c, reduce the number of membrane panels manufactured by reducing the number of different types of panels, and reduce the number of membrane panels manufactured. By standardizing the manufacturing dimensions, it becomes possible to produce economically.

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

第1図は幾何学的非線形解析による屋根曲面
図、第2図は本発明の空気膜構造屋根を示す平面
図である。 1……膜、2……ケーブルネツト、a……放射
状ケーブル、b……同心円ケーブル、c……膜
材。
FIG. 1 is a roof curved surface diagram obtained by geometric nonlinear analysis, and FIG. 2 is a plan view showing the air membrane structure roof of the present invention. 1...Membrane, 2...Cable net, a...Radial cable, b...Concentric cable, c...Membrane material.

Claims (1)

【特許請求の範囲】[Claims] 1 ケーブルを放射状並びに同心円状に配置し、
周辺部において配置した放射状ケーブルを中央部
になるにつれて、その本数を間引きする様に取付
け、それらのケーブルによつて構成された升目区
画に膜材を取付けるとしてなることを特徴とする
空気膜構造屋根。
1 Arrange the cables radially and concentrically,
An air membrane structure roof characterized in that radial cables arranged at the periphery are thinned out in number toward the center, and a membrane material is attached to square sections formed by these cables. .
JP4166784A 1984-03-05 1984-03-05 Cable arrangement in air film structure roof Granted JPS60188579A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP4166784A JPS60188579A (en) 1984-03-05 1984-03-05 Cable arrangement in air film structure roof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP4166784A JPS60188579A (en) 1984-03-05 1984-03-05 Cable arrangement in air film structure roof

Related Child Applications (2)

Application Number Title Priority Date Filing Date
JP29032989A Division JPH02232483A (en) 1989-11-08 1989-11-08 Air film structure roof
JP29033089A Division JPH02232484A (en) 1989-11-08 1989-11-08 Air film structure roof

Publications (2)

Publication Number Publication Date
JPS60188579A JPS60188579A (en) 1985-09-26
JPH0233826B2 true JPH0233826B2 (en) 1990-07-31

Family

ID=12614739

Family Applications (1)

Application Number Title Priority Date Filing Date
JP4166784A Granted JPS60188579A (en) 1984-03-05 1984-03-05 Cable arrangement in air film structure roof

Country Status (1)

Country Link
JP (1) JPS60188579A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH044924U (en) * 1990-04-25 1992-01-17

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS62182372A (en) * 1986-02-07 1987-08-10 清水建設株式会社 Roof membrane in non-cable membrane structure
JPH0723655B2 (en) * 1988-03-28 1995-03-15 株式会社大林組 Air film structure
JP2525905B2 (en) * 1989-10-12 1996-08-21 アルパイン株式会社 Security remote control device

Family Cites Families (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS4941604U (en) * 1972-07-17 1974-04-12
JPS58322A (en) * 1981-06-22 1983-01-05 Shinwa Kogyo Kk Manufacturing method and device for tapered roof member

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH044924U (en) * 1990-04-25 1992-01-17

Also Published As

Publication number Publication date
JPS60188579A (en) 1985-09-26

Similar Documents

Publication Publication Date Title
US3959937A (en) Modular dome structure
JP3231071B2 (en) Dome roof structure
US3744191A (en) Large air supported structures
US5378078A (en) Manhole cover
CA1036890A (en) Inflatable shelter
EP0722525A1 (en) Space truss dome
EP0555396B1 (en) Triangulated roof structure
US5440840A (en) Triangulated roof structure
US4665664A (en) Dome building structure
JPH0233826B2 (en)
US2929473A (en) Structural framework
US4271641A (en) Tension structure
US4559746A (en) Air-supported fabric roof structure
CA1215207A (en) Cabling system for an inflatable building
US4578908A (en) Fabric roof structure
JPH0327709B2 (en)
Levy Floating fabric over Georgia dome
JPH0327708B2 (en)
CN118958498A (en) A strap-supported air rib membrane structure
WO1996025572A2 (en) Inflatable roof support systems
JP3313469B2 (en) Dome roof structure
US4711063A (en) Large span dome
JPH0229172Y2 (en)
CN201176652Y (en) Double-layer cable-lever roof system
JP2755264B2 (en) Roof structure