Simple suspension bridge
A simple suspension footbridge in the Zillertal Alps | |
Ancestor | None |
---|---|
Related | None |
Descendant | Underspanned suspension bridge, Suspended-deck suspension bridge, Stressed ribbon bridge |
Carries | Pedestrians, livestock |
Span range | short to medium |
Material | Rope (fiber), chain, steel wire rope; appropriate decking material |
Movable | No |
Design effort | low |
Falsework required | No |
A simple suspension bridge (also rope bridge, swing bridge (in New Zealand), suspended bridge, hanging bridge and catenary bridge) is a primitive type of bridge that is supported entirely from anchors at either end and has no towers or piers. However, it may have saddles. In such bridges, the deck of the bridge follows the downward and upward arc of the load-bearing cables, with additional light ropes at a higher level used to form a handrail. Alternatively, stout handrail cables supported on short piers at each end may be the primary load-bearing element, with the deck suspended below. Suspended well from two high locations over a river or canyon, simple suspension bridges follow a shallow downward catenary arc and are not suited for modern roads and railroads. Owing to practical limitation in the grade (i.e. the deck being an arc, not flat) and the response to dynamic loads of the bridge deck, this type is quite restricted in its load-carrying capacity relative to its span. This type of bridge is considered the most efficient and sustainable design in developing countries, however, especially for river crossings that lie in non-floodplain topography such as gorges.
Comparison to other types
In some contexts the term "simple suspension bridge" refers not to this type of bridge but rather to a suspended deck bridge that is "simple" in that its deck is not stiffened.[1][2] Although simple suspension bridges and "simple" suspended deck bridges are similar in many respects, they differ in their physics. On a simple suspension bridge, the main cables (or chains) follow a hyperbolic curve, the catenary. This is because the main cables are free hanging. In contrast, on a suspended deck bridge (whether "simple" or not) the main cables follow a parabolic curve. This is because the main cables are tied at uniform intervals to the bridge deck below (see suspension bridge curve). The differences between these two curves was a question of importance in the 17th century, worked on by Isaac Newton among others.[3]
A stressed ribbon bridge also has one or more catenary curves and a deck laid on the main cables. Unlike a simple suspension bridge however, a stressed ribbon bridge has a stiff deck, usually due to the addition of compression elements (concrete slabs) laid over the main cables. This stiffness allows the bridge to be much heavier, wider, and more stable.
History
The simple suspension bridge is the oldest known type of suspension bridge and, ignoring the possibility of pre-Columbian trans-oceanic contact, there were at least two independent inventions of the simple suspension bridge, in the wider Himalaya region and South America.[4]
The earliest reference to suspension bridges appear in Han dynasty records on the travels of Chinese diplomatic missions to the countries on the western and southern fringe of the Himalaya, namely the Hindukush range in Afghanistan, and the lands of Gandhara and Gilgit.[5] These were simple suspension bridges of three or more cables made from vines, where people walked directly on the ropes to cross. Later, they also used decking made from planks resting on two cables.[5]
In South America, Inca rope bridges predate the arrival of the Spanish in the Andes in the 16th century. The oldest known suspension bridge, reported from ruins, dates from the 7th century in Central America (see Maya Bridge at Yaxchilan).
Simple suspension bridges using iron chains are also documented in Tibet and China. One bridge on the upper Yangtze dates back to the 7th century. Several are attributed to Tibetan monk Thang Tong Gyalpo, who reportedly built several in Tibet and Bhutan in the 15th century, including Chakzam Bridge and one at Chuka.[4] Another example, the Luding Bridge, dates from 1703, spanning 100 m using 11 iron chains.[4]
Development of wire cable suspension bridges dates to the temporary simple suspension bridge at Annonay built by Marc Seguin and his brothers in 1822. It spanned only 18 m.[4] However, simple suspension bridge designs were made largely obsolete by the 19th century invention and patent of the suspended deck bridge by James Finley.[6] A late 18th century English painting of a bridge in Srinagar, then part of the Garhwal Kingdom, anticipates the invention of the suspended deck bridge. This unusual bridge, built on a floodplain, had suspended deck ramps used to access a simple suspension bridge supported from towers.
Materials
This type of bridge is known as a rope bridge due to its historical construction from rope. Inca rope bridges still are formed from native materials, chiefly rope, in some areas of South America. These rope bridges must be renewed periodically owing to the limited lifetime of the materials, and rope components are made by families as contributions to a community endeavor.
Simple suspension bridges, for use by pedestrians and livestock, are still constructed, based on the ancient Inca rope bridge but using wire rope and sometimes steel or aluminum grid decking, rather than wood.
In modern bridges, materials used instead of (fiber) rope include wire rope, chain, and special-purpose articulated steel beams.
Living bridges
Around Cherrapunji in northeast India there are living root bridges, a form of tree shaping, which are simple suspension bridges made of living tree roots of some suitable species such as Ficus elastica growing alongside the gap to be bridged, by gradually training some of its roots to grow across the gap until they take root on the other side.[7] There are examples with a span of over 100 feet (30 meters). They are naturally self-renewing and self-strengthening as the component roots grow thicker and some are thought to be more than 500 years old.[8][9][10]
In the Iya Valley of Japan, bridges have been constructed using wisteria vines. To build such a bridge, these vines were planted on opposite sides of a river and woven together when they grew long enough to span the gap. The addition of planks produced a serviceable bridge.[11] [12]
Design
The arc of the bridge deck varies between a catenary and a parabola, depending on the weight of the bridge itself versus the load it carries.
The very lightest bridges of this type consist of a single footrope and nothing more. These are tightropes and slacklines, and require skill to use. More commonly, the footrope is accompanied by one or two handrail ropes, connected at intervals by vertical side ropes. This style is used by mountaineers. A slightly heavier variation has two ropes supporting a deck, and two handrail ropes. Handrails are necessary because these bridges are prone to oscillate side to side and end to end. Rarely, the footrope (or footrope plus handrails) is combined with an overhead rope similar to a zip-line (see also Ropeway).
In some cases, such as the Capilano Suspension Bridge, the primary supports form the handrails with the deck suspended below them. This makes for more motion side-to-side in the deck than when the primary supports are at deck level, but less motion in the handrails.
Disadvantages connected with simple suspension bridges are very great. The location of the deck is limited, massive anchorages and piers generally are required, and loading produces transient deformation of the deck.[13] Solutions to these problems led to a wide variety of methods of stiffening the deck,[13][14] resulting in several other types of suspension bridge. These include a stressed ribbon bridge, which is closely related to a simple suspension bridge but has a stiffened deck suitable for vehicle traffic.
A very light bridge, constructed with cables under high tension, may approach a suspended deck bridge in the nearly horizontal grade of its deck.
The bridge may be stiffened by the addition of cables that do not bear the primary structural or live loads and so may be relatively light. These also add stability in wind. An example is the 220-meter long bridge across the river Drac at Lac de Monteynard-Avignonet: this bridge has stabilizing cables below and to the side of the deck.
To reduce twisting motion in response to users a bridge may employ vertical drop cables from each side at the center of the bridge, anchored to the ground below.
Use
The lightest of these bridges, without decking, are suitable for use only by pedestrians. Light bridges with decking, and sufficient tension that crossing the bridge does not approach climbing, may be used also by pack horses (and other animals), equestrians, and bicycle riders. To walk a lighter bridge of this type at a reasonable pace requires a particular gliding step, as the more normal walking step will induce traveling waves that can cause the traveler to pitch (uncomfortably) up and down or side-to-side. The exception is a stabilized bridge, which may be quite stable.
Simple suspension bridges have applications in outdoor recreation. They are a popular choice for tree-top trails[15] and, where the terrain is suitable, for stream crossings.[16] They may be designed without stabilizing so that the free movement of the bridge provides a more interesting experience for the user.[16]
In French, a rudimentary simple suspension bridge is known by one of three names, depending on its form: pont himalayen ("Himalayan bridge": a single footrope and handrails on both sides, usually without a deck); pont de singe ("monkey bridge: a footrope with overhead rope); and tyrolienne ("Tyrolean": a zip-line).[17] Zip-lines can be traversed by hanging below, or walked (by individuals with exceptional balance). A more developed version of the pont himalayen, provided with a deck between a pair of main cables, is known as a passerelle himalayenne (French, "Himalayan footbridge").[18] Examples of this type include two bridges at Lac de Monteynard-Avignonet in the French Alps; these bridges are exceptionally long, for bridges of this type.
Notable bridges
Notable simple suspension bridges include:
Name | Span length | Year built |
---|---|---|
Capilano Suspension Bridge | 136 metres (446 ft) | 1888 |
Arroyo Cangrejillo Bridge | 337 metres (1,106 ft) | 1998 |
Lac de Monteynard-Avignonet Drac bridge | 220 metres (720 ft) | 2007 |
Carrick-a-Rede Rope Bridge | 20 metres (66 ft) | rebuilt 2008 |
Gallery
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Simple suspension bridge
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Canopy Walk
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Simple suspension bridge
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thumb|Stressed ribbon bridge
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Astore Valley, Gilgit-Baltistan, Pakistan.
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A simple suspension footbridge in Finland
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A simple suspension bridge in Bohol, Philippines.
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Capilano Suspension Bridge, supported by its handrail cables
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A simple suspension bridge at Lingenau in the Bregenzerwald, with a nearly horizontal deck
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This bridge across a gorge in Austria has a footrope, two handrail ropes, and an overhead rope to which the user can attach a sliding carabiner or safety loop that is tied securely to the user's climbing harness
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Drac bridge at Lac de Monteynard-Avignonet
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Closeup of the Drac bridge, showing stabilizing cables
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A simple suspension footbridge in Shizuoka Prefecture, Japan, with stabilizing cables
See also
- Category:Simple suspension bridges
- Inca Bridge
- Stressed ribbon bridge (compression forces on the deck stabilize against swaying)
- Suspension bridge types
References
Wikimedia Commons has media related to Simple suspension bridges. |
- ↑ Hugh Chisholm (1910). The Encyclopædia Britannica: A Dictionary of Arts, Sciences, Literature and General Information 4 (11 ed.). The Encyclopædia Britannica Co. pp. 536–538.
- ↑ Arthur Morley (1912). Theory of structures. Longmans, Green, and Co. pp. 482–484, 574.
- ↑ Isaac Newton (2008). D. T. Whiteside, ed. The Mathematical Papers of Isaac Newton: Volume 5: 1683–1684. Cambridge University Press. p. 664. ISBN 0-521-04584-3. Appendix 2, footnote 373 on pages 285-287, footnote 1 on pages 520-521, footnote 5 on pages 521-522
- ↑ 4.0 4.1 4.2 4.3 Peters, Tom F. (1987). Transitions in Engineering: Guillaume Henri Dufour and the Early 19th Century Cable Suspension Bridges. Birkhauser. ISBN 3-7643-1929-1.
- ↑ 5.0 5.1 Needham, Joseph. (1986d). Science and Civilization in China: Volume 4, Physics and Physical Technology, Part 3, Civil Engineering and Nautics. Taipei: Caves Books Ltd. ISBN 0-521-07060-0, 187–189.
- ↑ Eda Kranakis (1996). Constructing a bridge: an exploration of engineering culture, design, and research in nineteenth-century France and America. MIT Press. p. 453. ISBN 0-262-11217-5.
- ↑ "Living Root Bridge in Laitkynsew India". www.india9.com. Retrieved 2010-02-22.
- ↑ "Cherrapunjee". www.cherrapunjee.com. Retrieved 2010-02-22.
- ↑ "Living Bridges in India Have Grown for 500 Years (Pics)". TreeHugger, New York. Retrieved 2010-10-24.
- ↑ The living root bridges of Cherrapunji, India
- ↑ Otto, M. Rebekah et al., "The Vine Bridges of Iya Valley", Atlas Obscura
- ↑ Ruchira Paul (April 22, 2010). "Living architecture: The root bridges of India and Japan". Accidentalblogger.typepad.com. Retrieved April 3, 2015.
- ↑ 13.0 13.1 Henry Taylor Bovey (1882). Applied Mechanics 2. Montreal: Printed by John Lovell & Son for the Office of the Minister of Agriculture, Canada. p. 150. pages 85-90
- ↑ Fleeming Jenkin (1776 [sic 1876]). Bridges: an elementary treatise on their construction and history. Edinburgh: Adam and Charles Black. p. 345. Check date values in:
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(help) pages 304-305 - ↑ Simon Bell (2008). Design for Outdoor Recreation (2nd ed.). Taylor & Francis. p. 232. ISBN 0-415-44172-2. page 145
- ↑ 16.0 16.1 Simon Bell (2008). Design for Outdoor Recreation (2nd ed.). Taylor & Francis. p. 232. ISBN 0-415-44172-2. page 108, 133-135
- ↑ Nicola Williams, Catherine Le Nevez (2007). Provence & the Côte d'Azur (5th ed.). Lonely Planet. p. 456. ISBN 1-74104-236-4. page 253
- ↑ "Des passerelles himalayennes" (in French). www.enviscope.com. Retrieved 2009-03-04.
- Troyano, Leonardo Fernández (2003). "8.3.2 Catenary Bridges". Bridge Engineering: A Global Perspective. Thomas Telford. p. 514. ISBN 0-7277-3215-3.
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