Structural membrane - Revision history

Editor at 15:15, 9 December 2020

2020-12-09T15:15:06Z

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−	\| [[File:~~Millennium Dome fabric installation~~.jpg]]	+	\| [[File:Millennium_Dome_fabric_installation.jpg\|link=File:Millennium_Dome_fabric_installation.jpg]]
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	\| The Millennium Dome, London is a cable net structure that features a double-layer PTFE-coated glass fabric membrane.		\| The Millennium Dome, London is a cable net structure that features a double-layer PTFE-coated glass fabric membrane.
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	* Types of dome.		* Types of dome.

−	[[Category:Theory]]	+	[[Category:DCN_Definition]] [[Category:Theory]]

Designing Buildings at 11:29, 27 January 2020

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	\| The Millennium Dome, London is a cable net structure that features a double-layer PTFE-coated glass fabric membrane.		\| The Millennium Dome, London is a cable net structure that features a double-layer PTFE-coated glass fabric membrane.
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−	\| [[File:Soap-bubbles-~~4021995 640~~.jpg]]	+	\| [[File:Soap-bubbles-4021995_640.jpg\|link=File:Soap-bubbles-4021995_640.jpg]]
−	\| [[File:~~Soap film~~.png]]	+	\| [[File:Soap_film.png\|link=File:Soap_film.png]]
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Designing Buildings at 11:28, 27 January 2020

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	From a structural perspective, membranes are extremely thin relative to their span; this means that there are certain stresses – such as those resulting from bending – which they cannot appreciably develop. Membranes are therefore mainly affected by tensile stresses, and for this reason can be employed usefully as materials of construction in which they bear mainly tension forces. Analogously, just like the shortest line between two points is a straight line, so the smoothest possible surface connecting points on a boundary is a membrane - as is seen for example in the form of soap films, which adopt minimum surface shapes.		From a structural perspective, membranes are extremely thin relative to their span; this means that there are certain stresses – such as those resulting from bending – which they cannot appreciably develop. Membranes are therefore mainly affected by tensile stresses, and for this reason can be employed usefully as materials of construction in which they bear mainly tension forces. Analogously, just like the shortest line between two points is a straight line, so the smoothest possible surface connecting points on a boundary is a membrane - as is seen for example in the form of soap films, which adopt minimum surface shapes.
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		+	{\|
		+	\| [[File:Soap-bubbles-4021995 640.jpg]]
		+	\| [[File:Soap film.png]]
		+	\|}

	Membranes can support loads in a similar way that cables do: they adopt a curved catenary shape (generally doubly curved in the case of membranes), and in so doing, distribute uniformly the two-dimensional forces across their cross-sectional areas.		Membranes can support loads in a similar way that cables do: they adopt a curved catenary shape (generally doubly curved in the case of membranes), and in so doing, distribute uniformly the two-dimensional forces across their cross-sectional areas.

Designing Buildings at 11:24, 27 January 2020

2020-01-27T11:24:54Z

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−	\| [[File:~~Millennium Dome cable net~~.jpg]]	+	\| [[File:Millennium_Dome_cable_net.jpg\|link=File:Millennium_Dome_cable_net.jpg]]
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−	\| The Millennium Dome, London is a cable net structure that features a ~~pre-stressed,~~ double-layer PTFE-coated glass fabric membrane.	+	\| The Millennium Dome, London is a cable net structure that features a double-layer PTFE-coated glass fabric membrane.
	\|}		\|}

−	A (non-biological) membrane is a very thin, sheet-like material, such as cling film, soap film or a piece of cloth.	+	A (non-biological) membrane is a very thin, sheet-like material, such as cling film, soap film or a piece of cloth. Membranes may be used as structural components of tensile structures. A tensile structure is a structure that is stabilised by tension rather than compression. For example, a piece of fabric pulled in opposite directions in a tent or inflatable structure.

−	Materials that are commonly used as structural ~~components of tensile membrane structures~~ include canvas and PTFE. ~~These are typically used as part of a system which makes use of cables~~, ~~pylons~~ and ~~other construction members which force the membrane to adopt its final geometric form~~.	+	Materials that are commonly used as structural membranes include cotton canvas, PVC coated polyester and PTFE coated glass. They may also be formed by foils, films, reinforced films, inflated cushions and so on. For more information see: Architectural fabrics.

−	~~From a structural perspective,~~ membranes are ~~extremely thin relative to their span; this means that there are certain stresses – such as those resulting from bending –~~ which ~~they cannot appreciably develop. Membranes are therefore mainly affected by tensile stresses, and for this reason can be employed usefully as materials~~ of ~~construction in which they bear mainly tension forces. Analogously~~, ~~just like the shortest line between two points is a straight line~~, so the ~~smoothest possible surface connecting points on~~ a ~~boundary is a membrane~~.	+	These membranes are typically part of a system which makes use of cables, pylons, anchors and so on which force the membrane to adopt a tensioned anticlastic or synclastic form.

−	~~Membranes can support loads in~~ a ~~similar way~~ that ~~cables do:~~ they ~~sag~~, and in ~~so doing~~, ~~distribute uniformly~~ the two-~~dimensional forces across their cross-sectional areas~~.	+	From a structural perspective, membranes are extremely thin relative to their span; this means that there are certain stresses – such as those resulting from bending – which they cannot appreciably develop. Membranes are therefore mainly affected by tensile stresses, and for this reason can be employed usefully as materials of construction in which they bear mainly tension forces. Analogously, just like the shortest line between two points is a straight line, so the smoothest possible surface connecting points on a boundary is a membrane - as is seen for example in the form of soap films, which adopt minimum surface shapes.

−	~~Essentially, membrane action involves~~:	+	Membranes can support loads in a similar way that cables do: they adopt a curved catenary shape (generally doubly curved in the case of membranes), and in so doing, distribute uniformly the two-dimensional forces across their cross-sectional areas.

−	* Tensile and shear stresses: these are planar i.e they act along the membrane, never perpendicular to it.	+	Essentially, membrane action involves tensile and shear stresses: these are planar i.e they act along the membrane, never perpendicular to it.
−	* The geometry adopted by the membrane: the membrane’s curvature and twist will essentially determine the membrane action.	+

−	Membranes ~~can accept higher loads~~ when they are pre-tensioned. An example is an umbrella, in which the material is placed under a curving pre-tension by the outward force of the struts emanating from the central pole.	+	Membranes remain more stable under load when they are pre-tensioned. An example is an umbrella, in which the material is placed under a curving pre-tension by the outward force of the struts emanating from the central pole. This means they distort less when subsequently blown by the wind.

−	At 320m in diameter, the Millennium Dome is ~~one of~~ the largest ~~domes~~ in the world. The pre-stressing applied to its double-layer PTFE-coated glass fabric material is applied by cables (from ground anchors and those supported by pylons) which force the membrane into a dome shape. However, although cable net structures such as the Millennium Dome can adopt an overall domed shape, it should be noted that individual sections are generally flat or anticlastic in form (rather than the synclastic form of compression domes).	+	At 320m in diameter, the Millennium Dome is the largest dome in the world. The pre-stressing applied to its double-layer PTFE-coated glass fabric material is applied by cables (from ground anchors and those supported by pylons) which force the membrane into a dome shape. However, although cable net structures such as the Millennium Dome can adopt an overall domed shape, it should be noted that individual sections are generally flat or anticlastic in form (rather than the synclastic form of compression domes).

	One architect who played a leading research and developmental role in pre-stressed fabric structures was the German architect, Frei Otto. His projects included the bandstand for the 1955 Federal Garden Exhibition in Kassel; the twin saddle structures at the entrance to the 1957 Cologne garden exhibition; the 8,000m² German pavilion for the 1967 Montreal Expo in Canada, and the plexi glass-clad cable net of the 1972 Munich Olympic Stadium.		One architect who played a leading research and developmental role in pre-stressed fabric structures was the German architect, Frei Otto. His projects included the bandstand for the 1955 Federal Garden Exhibition in Kassel; the twin saddle structures at the entrance to the 1957 Cologne garden exhibition; the 8,000m² German pavilion for the 1967 Montreal Expo in Canada, and the plexi glass-clad cable net of the 1972 Munich Olympic Stadium.

Editor: Created page with "{| | File:Millennium Dome cable net.jpg |- | The Millennium Dome, London is a cable net structure that features a pre-stressed, double-layer PTFE-coated glass fabric membrane..."

2020-01-08T17:25:31Z

Created page with "{| | File:Millennium Dome cable net.jpg |- | The Millennium Dome, London is a cable net structure that features a pre-stressed, double-layer PTFE-coated glass fabric membrane..."

New page

{|
| [[File:Millennium Dome cable net.jpg]]
|-
| The Millennium Dome, London is a cable net structure that features a pre-stressed, double-layer PTFE-coated glass fabric membrane.
|}

A (non-biological) membrane is a very thin, sheet-like material, such as cling film, soap film or a piece of cloth.

Materials that are commonly used as structural components of tensile membrane structures include canvas and PTFE. These are typically used as part of a system which makes use of cables, pylons and other construction members which force the membrane to adopt its final geometric form.

From a structural perspective, membranes are extremely thin relative to their span; this means that there are certain stresses – such as those resulting from bending – which they cannot appreciably develop. Membranes are therefore mainly affected by tensile stresses, and for this reason can be employed usefully as materials of construction in which they bear mainly tension forces. Analogously, just like the shortest line between two points is a straight line, so the smoothest possible surface connecting points on a boundary is a membrane.

Membranes can support loads in a similar way that cables do: they sag, and in so doing, distribute uniformly the two-dimensional forces across their cross-sectional areas.

Essentially, membrane action involves:

* Tensile and shear stresses: these are planar i.e they act along the membrane, never perpendicular to it.
* The geometry adopted by the membrane: the membrane’s curvature and twist will essentially determine the membrane action.

Membranes can accept higher loads when they are pre-tensioned. An example is an umbrella, in which the material is placed under a curving pre-tension by the outward force of the struts emanating from the central pole.

At 320m in diameter, the Millennium Dome is one of the largest domes in the world. The pre-stressing applied to its double-layer PTFE-coated glass fabric material is applied by cables (from ground anchors and those supported by pylons) which force the membrane into a dome shape. However, although cable net structures such as the Millennium Dome can adopt an overall domed shape, it should be noted that individual sections are generally flat or anticlastic in form (rather than the synclastic form of compression domes).

One architect who played a leading research and developmental role in pre-stressed fabric structures was the German architect, Frei Otto. His projects included the bandstand for the 1955 Federal Garden Exhibition in Kassel; the twin saddle structures at the entrance to the 1957 Cologne garden exhibition; the 8,000m² German pavilion for the 1967 Montreal Expo in Canada, and the plexi glass-clad cable net of the 1972 Munich Olympic Stadium.

= Related articles on Designing Buildings Wiki =

* Anticlastic.
* Architectural fabrics.
* Buckminster Fuller.
* Deflection.
* ETFE.
* Fabric structures.
* Frei Otto.
* Geodesic dome.
* Hyperbolic paraboloid.
* Kinetic facade.
* Khan Shatyr Entertainment Centre.
* London 2012 Olympic Stadium.
* Long span roof.
* Megastructure.
* Millennium Dome.
* Principles of enclosure.
* Structural steelwork.
* Structures at the end of their design life.
* Tensile structures.
* The history of fabric structures.
* The structural behaviour of architectural fabric structures.
* The thermal behaviour of spaces enclosed by fabric membranes.
* Types of dome.

[[Category:Theory]]