Cable-stayed bridge explained

Image Title:The Russky Bridge in Vladivostok has a central span of 1104m (3,622feet), the world's longest cable-stayed bridge span as of 2024.
Sibling Names:Extradosed bridge
Descendent Names:Side-spar cable-stayed bridge, Self-anchored suspension bridge, cantilever spar cable-stayed bridge
Ancestor Names:Suspension bridge
Carries:Pedestrians, bicycles, automobiles, trucks, light rail
Span Range:Medium to Long
Material:Steel rope, post-tensioned concrete box girders, steel or concrete pylons
Movable:No
Design:medium
Falsework:Normally none

A cable-stayed bridge has one or more towers (or pylons), from which cables support the bridge deck. A distinctive feature are the cables or stays, which run directly from the tower to the deck, normally forming a fan-like pattern or a series of parallel lines. This is in contrast to the modern suspension bridge, where the cables supporting the deck are suspended vertically from the main cable, anchored at both ends of the bridge and running between the towers. The cable-stayed bridge is optimal for spans longer than cantilever bridges and shorter than suspension bridges. This is the range within which cantilever bridges would rapidly grow heavier, and suspension bridge cabling would be more costly.

Cable-stayed bridges were being designed and constructed by the late 16th century,[1] and the form found wide use in the late 19th century. Early examples, including the Brooklyn Bridge, often combined features from both the cable-stayed and suspension designs. Cable-stayed designs fell from favor in the early 20th century as larger gaps were bridged using pure suspension designs, and shorter ones using various systems built of reinforced concrete. It returned to prominence in the later 20th century when the combination of new materials, larger construction machinery, and the need to replace older bridges all lowered the relative price of these designs.[2]

History

Cable-stayed bridges date back to 1595, where designs were found in Machinae Novae, a book by Croatian-Venetian inventor Fausto Veranzio. Many early suspension bridges were cable-stayed construction, including the 1817 footbridge Dryburgh Abbey Bridge, James Dredge's patented Victoria Bridge, Bath (1836), and the later Albert Bridge (1872) and Brooklyn Bridge (1883). Their designers found that the combination of technologies created a stiffer bridge. John A. Roebling took particular advantage of this to limit deformations due to railway loads in the Niagara Falls Suspension Bridge.

The earliest known surviving example of a true cable-stayed bridge in the United States is E.E. Runyon's largely intact steel or iron Bluff Dale Suspension bridge with wooden stringers and decking in Bluff Dale, Texas (1890), or his weeks earlier but ruined Barton Creek Bridge between Huckabay, Texas and Gordon, Texas (1889 or 1890).[3] [4] In the twentieth century, early examples of cable-stayed bridges included A. Gisclard's unusual Cassagnes bridge (1899),[5] in which the horizontal part of the cable forces is balanced by a separate horizontal tie cable, preventing significant compression in the deck, and G. Leinekugel le Coq's bridge[6] at Lézardrieux in Brittany (1924). Eduardo Torroja designed a cable-stayed aqueduct[7] at Tempul in 1926.[8] Albert Caquot's 1952 concrete-decked cable-stayed bridge[9] over the Donzère-Mondragon canal at Pierrelatte is one of the first of the modern type, but had little influence on later development.[8] The steel-decked Strömsund Bridge designed by Franz Dischinger (1955) is, therefore, more often cited as the first modern cable-stayed bridge.

Other key pioneers included Fabrizio de Miranda, Riccardo Morandi, and Fritz Leonhardt. Early bridges from this period used very few stay cables, as in the Theodor Heuss Bridge (1958). However, this involves substantial erection costs, and more modern structures tend to use many more cables to ensure greater economy.

Comparison with suspension bridge

Cable-stayed bridges may appear to be similar to suspension bridges, but they are quite different in principle and construction. In suspension bridges, large main cables (normally two) hang between the towers and are anchored at each end to the ground. This can be difficult to implement when ground conditions are poor. The main cables, which are free to move on bearings in the towers, bear the load of the bridge deck. Before the deck is installed, the cables are under tension from their own weight. Along the main cables smaller cables or rods connect to the bridge deck, which is lifted in sections. As this is done, the tension in the cables increases, as it does with the live load of traffic crossing the bridge. The tension on the main cables is transferred to the ground at the anchorages and by downwards compression on the towers.

In cable-stayed bridges, the towers are the primary load-bearing structures that transmit the bridge loads to the ground. A cantilever approach is often used to support the bridge deck near the towers, but lengths further from them are supported by cables running directly to the towers. That has the disadvantage, unlike for the suspension bridge, that the cables pull to the sides as opposed to directly up, which requires the bridge deck to be stronger to resist the resulting horizontal compression loads, but it has the advantage of not requiring firm anchorages to resist the horizontal pull of the main cables of the suspension bridge. By design, all static horizontal forces of the cable-stayed bridge are balanced so that the supporting towers do not tend to tilt or slide and so must only resist horizontal forces from the live loads.

The following are key advantages of the cable-stayed form:

Designs

There are four major classes of rigging on cable-stayed bridges: mono, harp, fan, and star.[10]

There are also seven main arrangements for support columns: single, double, portal, A-shaped, H-shaped, inverted Y and M-shaped. The last three are hybrid arrangements that combine two arrangements into one.[10]

Depending on the design, the columns may be vertical or angled or curved relative to the bridge deck.

Variations

Side-spar cable-stayed bridge

A side-spar cable-stayed bridge uses a central tower supported only on one side. This design allows the construction of a curved bridge.

Cantilever spar cable-stayed bridge

Far more radical in its structure, the Puente del Alamillo (1992) uses a single cantilever spar on one side of the span, with cables on one side only to support the bridge deck. Unlike other cable-stayed types, this bridge exerts considerable overturning force upon its foundation and the spar must resist the bending caused by the cables, as the cable forces are not balanced by opposing cables. The spar of this particular bridge forms the gnomon of a large garden sundial. Related bridges by the architect Santiago Calatrava include the Puente de la Mujer (2001), Sundial Bridge (2004), Chords Bridge (2008), and Assut de l'Or Bridge (2008).

Multiple-span cable-stayed bridge

Cable-stayed bridges with more than three spans involve significantly more challenging designs than do 2-span or 3-span structures.

In a 2-span or 3-span cable-stayed bridge, the loads from the main spans are normally anchored back near the end abutments by stays in the end spans. For more spans, this is not the case and the bridge structure is less stiff overall. This can create difficulties in both the design of the deck and the pylons.Examples of multiple-span structures in which this is the case include Ting Kau Bridge, where additional 'cross-bracing' stays are used to stabilise the pylons; Millau Viaduct and Mezcala Bridge, where twin-legged towers are used; and General Rafael Urdaneta Bridge, where very stiff multi-legged frame towers were adopted. A similar situation with a suspension bridge is found at both the Great Seto Bridge and San Francisco–Oakland Bay Bridge where additional anchorage piers are required after every set of three suspension spans – this solution can also be adapted for cable-stayed bridges.[13]

Extradosed bridge

An extradosed bridge is a cable-stayed bridge with a more substantial bridge deck that, being stiffer and stronger, allows the cables to be omitted close to the tower and for the towers to be lower in proportion to the span. The first extradosed bridges were the Ganter Bridge and Sunniberg Bridge in Switzerland. The first extradosed bridge in the United States, the Pearl Harbor Memorial Bridge was built to carry I-95 across the Quinnipiac River in New Haven, Connecticut, opening in June 2012.

Cable-stayed cradle-system bridge

A cradle system carries the strands within the stays from the bridge deck to bridge deck, as a continuous element, eliminating anchorages in the pylons. Each epoxy-coated steel strand is carried inside the cradle in a one-inch (2.54 cm) steel tube. Each strand acts independently, allowing for removal, inspection, and replacement of individual strands. The first two such bridges are the Penobscot Narrows Bridge, completed in 2006, and the Veterans' Glass City Skyway, completed in 2007.[14]

Related bridge types

Self-anchored suspension bridge

A self-anchored suspension bridge has some similarity in principle to the cable-stayed type in that tension forces that prevent the deck from dropping are converted into compression forces vertically in the tower and horizontally along the deck structure. It is also related to the suspension bridge in having arcuate main cables with suspender cables, although the self-anchored type lacks the heavy cable anchorages of the ordinary suspension bridge. Unlike either a cable-stayed bridge or a suspension bridge, the self-anchored suspension bridge must be supported by falsework during construction and so it is more expensive to construct.

Notable cable-stayed bridges

See also: List of longest cable-stayed bridge spans.

See also

Further reading

External links

Notes and References

  1. Web site: Types of Bridges . History of Bridges . 12 October 2020.
  2. News: Popular Cable-Stay Bridges Rise Across U.S. to Replace Crumbling Spans. Nordrum. Amy. Scientific American. 30 April 2017. en.
  3. Web site: Bluff Dale Suspension Bridge . . .
  4. Web site: Barton Creek Bridge . . .
  5. 42.504°N 2.1436°W
  6. 48.7807°N -3.1065°W
  7. 36.6488°N -5.9304°W
  8. Book: Troyano , Leonardo . Bridge Engineering: A Global Perspective . Thomas Telford . 2003 . 650–652 . 0-7277-3215-3.
  9. 44.3824°N 4.7284°W
  10. Web site: Cable Stayed Bridge . Middle East Economic Engineering Forum . 13 May 2016 . https://web.archive.org/web/20190525145904/http://www.eng-forum.com/articles/articles/cable_stayed.htm . 25 May 2019 . dead .
  11. Web site: Comparison Between Three Types of Cable Stayed Bridges Using Structural Optimization. Sarhang Zadeh. Olfat. October 2012. Western University Canada. PDF.
  12. Book: T.K. Bandyopadhyay. Alok Baishya. P. Dayaratnam. G.P. Garg. G.V. Ratnam. R.N. Raghavan. International Conference on Suspension, Cable Supported, and Cable Stayed Bridges: November 19–21, 1999, Hyderabad. 2000. Universities Press (India). 978-81-7371-271-5. 282, 373.
  13. 10.2749/101686601780324250 . Virlogeux . Michel . Bridges with multiple cable-stayed spans . Structural Engineering International . 1 February 2001 . 11 . 1 . 61–82 . 109604691 .
  14. American Society of Civil Engineers . Bridging To The Future Of Engineering . 12 March 2007 . 8 March 2008 . 10 October 2008 . https://web.archive.org/web/20081010044956/http://news.thomasnet.com/companystory/515472 . dead .
  15. Web site: First Amazon bridge to open world's greatest rainforest to development. The Guardian. 5 August 2010. 19 January 2020.
  16. Web site: Rio Negro Bridge, $400-Million Economic Link, Opens in Amazon Basin. 2021-12-07. www.enr.com. en.
  17. Web site: United States: The longest cable-stayed bridge in the West. 14 August 2015.
  18. News: The City's Most Hated Bridge Gets a Nearly $1 Billion Makeover. Paybarah. Azi. 2019-08-29. The New York Times. 2019-08-29. Schweber. Nate. en-US. 0362-4331.
  19. Web site: https://web.archive.org/web/20170105183708/http://www.texasce.org/?page=MHHBridge. 5 January 2017. Margaret Hunt Hill Bridge, 2012 OCEA. Texas Section-American Society of Civil Engineers. 5 January 2017.
  20. Web site: https://web.archive.org/web/20160218093336/http://www.texasce.org/?page=OCEA. 18 February 2016. Outstanding Civil Engineering Achievement Awards. Texas Section-American Society of Civil Engineers. 5 January 2017.
  21. Web site: Margaret Hunt Bridge, Dallas, USA. 2012 ECCS Award For Steel Bridges. European Convention for Constructional Steelwork. Brussels, Belgium. 4–7. 5 January 2017. https://web.archive.org/web/20170105205822/https://www.steelconstruct.com/site/index.php?process=download&id=5947&code=787574cca62869258a38a50941853324296b3e77. 5 January 2017. dead.
  22. Web site: Queensferry Crossing | the Forth Bridges.
  23. Web site: Cable Stays: Second Severn Crossing . Freyssinet .