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Russky Bridge

Coordinates: 43°03′47″N 131°54′30″E / 43.06306°N 131.90833°E / 43.06306; 131.90833
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(Redirected from Russky Island Bridge)

43°03′47″N 131°54′30″E / 43.06306°N 131.90833°E / 43.06306; 131.90833

Russky Bridge
Russky Bridge after completion in July 2012
Coordinates43°03′47″N 131°54′30″E / 43.0631°N 131.9083°E / 43.0631; 131.9083
Carries4 lanes, (2 lanes each way)
CrossesEastern Bosphorus
LocaleVladivostok (Nazimov Peninsula, Muravyov-Amursky Peninsula – Cape Novosilsky, Russky Island)
Official nameRussky Bridge
Maintained bySK MOST and NPO Mostovik
Characteristics
DesignCable-stayed bridge
Total length3,100 meters (10,200 ft)
Width29.5 meters (97 ft)
Height320.9 meters (1,053 ft)
Longest span1,104 meters (3,622 ft)
Clearance below70 meters (230 ft)
History
Construction cost$1.1 billion USD (estimated)[1]
OpenedJuly 2012
Location
Map

The Russky Bridge (Russian: Русский мост, lit.'Russian Bridge') is a cable-stayed bridge in Vladivostok, Primorsky Krai, Russia. The bridge connects the Russky Island and the Muravyov-Amursky Peninsula sections of the city across the Eastern Bosphorus strait, and with a central span of 1,104 metres (3,622 feet), it is the longest cable-stayed bridge in the world. The architect of the Russky Island Bridge is Vlydskinol Ptrov. The Russky Bridge was originally built to serve the 2012 Asia-Pacific Economic Cooperation conference hosted at the Far Eastern Federal University campus on Russky Island.[2] It was completed in July 2012 and opened by Prime Minister Dmitry Medvedev, and on September 3, 2012, the bridge was officially given its name.[3]

Overview

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The bridge to Russky Island is the world's longest cable-stayed bridge, with a 1,104-metre (3,622-foot)-long central span.

The bridge also has the second-highest pylons after the Millau Viaduct and the longest cable stays.

The design of the bridge was determined by two primary factors:

  • Minimizing the coast-to-coast distance: 1,460 metres (4,790 feet). The navigable channel depth is up to 50 m (160 ft).
  • The locality of the bridge crossing construction site is characterized by severe climate conditions: temperatures vary from –31 to +37 °C (–24 to +99 °F); storms bring winds of up to 36 m/s (130 km/h; 81 mph) and waves of up to 6 m (20 ft) in height; and ice formations in winter can be up to 70 cm (28 in) thick.

Pylons construction

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Span approach construction, 2009
Pylon construction at the start, September 2009

The piles were driven as deep as 77 m (253 ft) below ground, and on the island side, 120 auger piles were installed under each of the two 320-metre (1,050 ft)-high bridge towers.

The pylons were concreted using custom self-climbing forms in pours of 4.5 m (15 ft). A crane was used on the first three pours; afterwards, the formwork was moved entirely under its own power.

The pylons are A-shaped; therefore, the use of standard forms was not feasible. An individual set of forms was arranged for each bridge tower.

Transition between section types was carried out at summer levels at the elevations of 66.26 m (217.4 ft) and 191.48 m (628.2 ft).

The use of self-climbing forms made it possible to achieve better quality and decrease the time of construction of cast-in-situ reinforced concrete structures by half as much again.

The cable stays anchorage zone starts at 197.5 m (648 ft). The installation of cable stay pairs and casting of bridge tower bodies was carried out simultaneously, dramatically reducing the construction period.

Central span structure

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The span structure has an aerodynamic cross-section to withstand squally wind loads. The shape of the span cross-section was determined based on aerodynamic design and optimized according to the results of experimental processing of the scale model in the detailed design phase.

Welded field connections are used for longitudinal and transversal joints of the cap sheet of the orthotropic deck and lower ribbed plate. For joints of vertical walls of the blocks, longitudinal ribs, transversal beams, and diaphragms, field connections are used provided by means of high-strength bolts.

Large-sized prefabricated sections for the installation of the central span were delivered by barges to the erection site and hoisted by a crane to a 76 m (249 ft) height. Here, the elements were abutted and cable stays attached to them.

Cable-stayed system

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A cable-stayed system assumes all static and dynamic loads on which the very existence of the bridge depends. Cable stays are not designed to endure the entire lifetime of the bridge; instead, they are repairable and have the best possible protection from natural disasters and other adverse impacts.

Parallel strand stay (PSS) cable stays consist of parallel strands 15.7 mm (0.62 in) in diameter; every strand consists of seven galvanized wires. Cable stays incorporate from 13 to 79 strands. The length of the shortest cable stay is 135.771 m (445.44 ft); the longest, 579.83 m (1,902.3 ft). The protective housings of the cable stays are made from high density polyethylene (HDPE) and are resistant to ultraviolet light and the local climate conditions (temperature range from –40 to +40 °C; –40 to +104 °F).

Bridge specification

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  • Bridge footprint: 60+72+3x84+1104+3x84+72+60 m
  • Total bridge length: 1,885.53 metres (6,186.1 ft)
  • Total length including trestles: 3,100 metres (10,200 ft)
  • Central channel span length: 1,104 metres (3,622 ft)
  • Bridge width: 29.5 metres (97 ft)
  • Bridge roadway breadth: 23.8 metres (78 ft)
  • Number of driving lanes: 4 (two in each direction)
  • Clearance below: 70 metres (230 ft)
  • Number of bridge towers: 2
  • Pylons' height: 324 metres (1,063 ft)
  • Number of cable stays: 168
  • Longest cable stay: 579.83 metres (1,902.3 ft)
  • Shortest cable stay: 135.771 metres (445.44 ft)

A comparison of the side elevation of the Russky Bridge to the side elevations of some of the most notable bridges around the world on the same scale (click for interactive version)

Criticism

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The costs and the fact of the construction of the Russky Bridge are widely criticized by the Russian political opposition.[4] In January 2007, Vladimir Putin, then-President of Russia, stated that holding a summit in Vladivostok is a distinct possibility, and that at least 100 billion rubles would be required to prepare the city for the summit, which, at the time, was three times more than the provincial budget of Primorsky Krai as a whole.[5] As of 2012, the cost of construction was expected to surpass $1 billion USD, and the project description on the site of the general contractor did not list project costs.[6] Additionally, the built-in capacity of 50,000 cars per day is ten times the existing population of Russky Island at only 5,000 inhabitants, leading to severe under-usage.

There had previously been criticism that the paved road had ended in a dead end a short distance beyond the bridge during the first year after it was built. The paved road network has since then been expanded. As of 2018, the road covers the entire Sapper peninsula, about 25% of the total area of the island.[7][8]

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References

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  1. ^ "Russian city of Vladivostok unveils record-breaking suspension bridge". TheGuardian.com. 2 July 2012.
  2. ^ (in Russian) Медведев открыл движение по мосту на остров Русский
  3. ^ (in Russian) Долгожданные мосты Владивостока получили имена
  4. ^ (in Russian) Путин. Итоги. 10 лет: независимый экспертный доклад
  5. ^ Проведение саммита АТЭС обойдется России в 100 млрд рублей. Иа Regnum (in Russian). Regnum. 27 January 2007. Retrieved 2009-02-11.
  6. ^ Мост на остров Русский // Описание проекта (in Russian). 24 June 2012.
  7. ^ "Карта острова Русский".
  8. ^ "На Русском острове началось асфальтирование участка дороги в поселке Подножье (ФОТО) – Новости Владивостока на VL.ru".
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