Balloon flange girder

Last updated

Brunel's bridges over the entrance locks to the Cumberland Basin, Bristol Harbour. Side view, Brunel's lock bridge.jpg
Brunel's bridges over the entrance locks to the Cumberland Basin, Bristol Harbour.

A balloon flange girder or (colloquially) balloon topper is a form of vertical I-beam wrought iron plate girder, where the top flange, instead of being a simple flat plate, is extended into a hollow tube. When a girder is subjected to a positive bending moment the top flange acts in compression making a flat plate flange more susceptible to local buckling than the balloon flange is.

Contents

Surviving section of Chepstow Railway Bridge girder, now at Brunel University, Uxbridge Mounted girder at Brunel University, cropped.jpg
Surviving section of Chepstow Railway Bridge girder, now at Brunel University, Uxbridge

This type of girder was rarely used, its only common user being Isambard Kingdom Brunel in the 1840s and 1850s.

Design

Brunel was working at a period of increased theoretical and mathematical analysis of bridge and mechanical structures. Together with the work of William Fairbairn, particularly in relation to Stephenson's tubular bridges such as Conwy, there was an increased understanding of how beams in compression would fail by buckling.

Brunel was known for his distrust of cast iron as a material, at least for large beams. [1] [2] [lower-roman 1] This distrust of cast iron was vindicated when his friend Stephenson's adventurous cast-iron Dee Bridge (1846) collapsed in 1847. Brunel gave evidence in his support at the following inquiry, but this was on the basis of Stephenson being a competent engineer within the bounds of current knowledge, rather than in support of large cast-iron beams. [1] Stephenson's Dee Bridge had used a truss girder, where an inverted T-shaped cast iron girder was trussed by applied wrought iron tension bars. This faulty design was instrumental in the bridge failure, where tension in the truss rods increased compression in the upper part of the girder such that it underwent columnar failure. Despite this, although with the advantage of hindsight, Brunel would use similar applied tension chains for his truss design. [4]

Around the 1840s, developments in the puddling furnace reduced the cost of wrought iron and improvements to rolling mills allowed the production of large flat sections. This iron was now economic for the construction of girders, assembled by riveting of flat sections. [5]

Development

Brunel had already experimented with simple bulb-headed girders in cast iron, for the relatively short 35-foot span of Bishop's Bridge canal bridge at Paddington. These had a T-section lower flange in tension and a larger circular bulb at the upper edge, [lower-roman 2] in compression. [7] [8] As was his habit, Brunel hydraulically tested samples of these girders for strength in 1838 and recorded the results in one of his books of 'Facts'. [6]

Experimental girder

To develop a reliable truss girder for long-span bridges, Brunel carried out a remarkable experiment with a full size girder. [9] This used a single wrought iron plate girder, 70 ft in length, which was loaded up to the point of collapse, first with 165 tons load then, after repair, to 188 tons. [10] [lower-roman 3] Brunel was aware that the likely failure mechanism of this girder was by buckling collapse in the upper flange, which would be under compression forces. To resist this, the flange was supported by triangulated plates and the flange was also slight curved. [lower-roman 4] The experiment was a great success, the bridge eventually failing at a considerable load, representing an efficient use of construction materials for a bridge of this capacity, compared to previous designs. [12]

From the left: * Experimental girder (Chepstow Railway Bridge was similar) * South Wales Railway * Eastern Bengal Railway * Cumberland Basin bridges * Windsor Railway Bridge All girders are to the same scale, except for the Windsor truss that is half size. Brunel balloon flange girders.jpg
From the left:
• Experimental girder (Chepstow Railway Bridge was similar)
South Wales Railway
• Eastern Bengal Railway
Cumberland Basin bridges
Windsor Railway Bridge
All girders are to the same scale, except for the Windsor truss that is half size.

South Wales Railway

Brunel made early and widespread use of this girder across his South Wales Railway. It was used for spans up to 100 feet, iron truss bridges being used beyond that.

Improvements in plate rolling allowed a change in the shape of the girder. Rather than merely a slightly-curved top plate with triangular gussets, it was now possible to roll a semi-circular plate. This allowed the fully developed 'balloon' shape to be used, as in the second cross-section illustrated. [10] The top web of the girder was semi-circular and riveted to the centre plate by an L-strip. The side gussets, also curved, were riveted parallel to the edges of this top plate, rather than through another L-strip, as used originally. Brunel (probably correctly) considered the smooth balloon profile to be a more efficient design, influenced by his geometric approaches to design rather than Eaton's mathematical analysis. More practically, the parallel lap joint halved the amount of riveting needed, compared to the L-strip.

None of these bridges are known to survive in their balloon form, although a girder from one was later re-used for bridge widening work (1861) across the Coity road near Bridgend and survived there. [13] The Coity Road bridge had been built before this date, but was widened to accommodate the new Llynvi Valley Railway. One side of the bridge was moved outwards to accommodate a new siding and a balloon girder installed on that side. This girder (especially as it was installed after Brunel's death) is thought to have previously been used elsewhere on the SWR, [13] although its original date and location is unknown.

Similar girders were used to cross the Severn at Over. [10] [14]

Eastern Bengal Railway

The next development retained the semicircular top flange, but the side gussets were now abandoned altogether as it was considered that the depth of the flange, even if not supported by another plate, would be stiff enough. This also allowed better access to the inside, for painting. Intermittent cross diaphragms were placed across the flange, to maintain its position relative to the main web and avoid distortion by rocking sideways. [10]

The form of girder was widely used in Brunel's work for the Eastern Bengal Railway. [10]

Cumberland Basin bridges

Cumberland Basin bridge girder, showing the upper and lower flanges Cross girders beneath decking, Brunel's lock bridge.jpg
Cumberland Basin bridge girder, showing the upper and lower flanges

When Brunel rebuilt the entrance locks of the Cumberland Basin in Bristol Harbour, between 1848 and 1849, he also constructed a 'swivel bridge' – Brunel's first moving bridge. [10] This was of centre-pivot construction, but were highly asymmetrical, the outboard side being nearly three times longer than the landward, balanced by a large cast-iron counterweight. [10]

As the bridge was for a light roadway and did not have to carry the weight of a railway or train, its girders were of a lightweight construction that simplified manufacture. A full balloon upper flange was used, similar in shape to the South Wales Railway bridges, but the flange sat above the main web of the girder and the web did not span the flange and reach to the top. This simplified construction as it avoided the T-joint, the necessary L-strips and thus several rows of riveting. [10]

The lower flange was of an entirely novel form, being triangular in section, although with concave sides. Again, the main web did not span the flange. All three joints were now simple lap joints with single-row riveting. [10]

Like a number of early Brunel bridges, Brunel's involvement with them was largely forgotten and only recorded in obscure works. [15] At one point they were under serious threat of demolition until their historical significance was re-recognised. A £1 million appeal was launched in 2014 to restore the bridge. [16] [17]

A very similar swivel bridge was built a few years later as the Dock Bridge  [ ru ] in Kronstadt, Russia. [18]

Windsor Railway Bridge

The girders of Windsor Railway Bridge Windsor bridge clipped.jpg
The girders of Windsor Railway Bridge

Windsor Railway Bridge (1849) is a tied-arch or bowstring girder bridge. [19] The span is composed of two girders that form a truss. The upper girder is an arch and carries the weight of the bridge. [20] The lower girder is suspended from this by vertical rods and is not required to support its own weight. The main function of the lower girder is to act as a tie; this counteracts the side-forces of the arch, avoiding the arch's usual side-forces on its foundations. As this is a railway bridge, where suspended deck bridges are a problem owing to swaying of their deck, this girder also has a stiffening function.

Brunel used a form of his balloon flange girder for both girders. The upper arch girder uses the triangulated form of the early experiment, with a flat top plate and without any vertical web below the flange box at all. The lower girder uses the 'open' form of the flange, slightly curved and with no gusset plates. As the lower girder is not carrying its weight, it is not subject to the usual buckling forces.

Chepstow Railway Bridge

Chepstow Railway Bridge (1852) was a complicated bridge that made the first use of Brunel's truss design to produce a suspension bridge with a wide uninterrupted span at high level above a shipping channel. The west bank of the gorge was shallow and muddy though, so half of the bridge's total span was provided by three 100-foot spans of a girder bridge, carried on cast iron cylindrical piers. These girders (illus) were of a form and size very similar to the original experimental girder. [21]

The landward girders were replaced in 1948 and the main truss, with its girders beneath, in 1962. [22] Portions of the girders survive today.

Crathie Bridge

X lattice and upper flange of Crathie Bridge Bridge Over River Dee - geograph.org.uk - 1275704.jpg
X lattice and upper flange of Crathie Bridge

Crathie Bridge (1854–1857) is a 125-foot single span across the River Dee to the royal Balmoral estate. [23] [24] [25] [26] The bridge had first been drawn with a form of the Brunel truss echoing his Royal Albert Bridge at Saltash. [27] The bridge as constructed though used the C-shaped open form of the upper flange, as used for the Eastern Bengal Railway. As the bridge was only for light road traffic, it was also possible to replace the solid web of the girder above the roadway level with an openwork lattice, making the view from the bridge visually more appealing for its illustrious resident. Despite this, Her Majesty was 'not amused' by the bridge. [23] [24]

Devizes 'Fish Bridge'

The line of 1857 through Devizes in Wiltshire down Caen Hill was carried over a road on an unusual development of the balloon flange, combining it with a lenticular plate girder. [28] [29] This lenticular fishbelly shape gave its popular name of 'Fish Bridge'. From his work on his truss design, Brunel was already familiar with the advantages of the lenticular form.

The original Fish Bridge was replaced in 1901 with a bowstring truss. [30] The name remained in common use, even after the railway was removed during the Beeching Axe.

Surviving examples

Dock Bridge, Kronstadt, Russia Kronshtadt, Saint Petersburg, Russia - panoramio (63).jpg
Dock Bridge, Kronstadt, Russia

See also

Related Research Articles

<span class="mw-page-title-main">Royal Albert Bridge</span> Railway bridge spanning the River Tamar in southwest England

The Royal Albert Bridge is a railway bridge which spans the River Tamar in England between Plymouth, Devon and Saltash, Cornwall. Its unique design consists of two 455-foot (138.7 m) lenticular iron trusses 100 feet (30.5 m) above the water, with conventional plate-girder approach spans. This gives it a total length of 2,187.5 feet (666.8 m). It carries the Cornish Main Line railway in and out of Cornwall. It is adjacent to the Tamar Bridge which opened in 1961 to carry the A38 road.

<span class="mw-page-title-main">William Henry Barlow</span> British civil engineer

William Henry Barlow was an English civil engineer of the 19th century, particularly associated with railway engineering projects. Barlow was involved in many engineering enterprises. He was engineer for the Midland Railway on its London extension and designed the company's London terminus at St Pancras.

<span class="mw-page-title-main">Britannia Bridge</span> Road-rail bridge over the Menai Strait

Britannia Bridge is a bridge in Wales that crosses the Menai Strait between the Isle of Anglesey and city of Bangor. It was originally designed and built by the noted railway engineer Robert Stephenson as a tubular bridge of wrought iron rectangular box-section spans for carrying rail traffic. Its importance was to form a critical link of the Chester and Holyhead Railway's route, enabling trains to directly travel between London and the port of Holyhead, thus facilitating a sea link to Dublin, Ireland.

<span class="mw-page-title-main">Bishop's Bridge</span> Bridge in Paddington, London

Bishop's Bridge, sometimes known as Paddington Bridge, is a road bridge in the Paddington district of London which carries Bishop's Bridge Road across the rail approaches to Paddington station and across the adjacent Paddington Arm of the Grand Union Canal. The original Isambard Kingdom Brunel built bridge was replaced in 2006. The name Bishop's Bridge Road comes from the manor of Paddington which was granted to the Bishop of London, Nicholas Ridley, by Edward VI in the mid 16th Century.

<span class="mw-page-title-main">Plate girder bridge</span> Type of bridge

A plate girder bridge is a bridge supported by two or more plate girders.

<span class="mw-page-title-main">Tubular bridge</span>

A tubular bridge is a bridge built as a rigid box girder section within which the traffic is carried. Famous examples include the original Britannia Bridge over the Menai Strait, the Conwy railway bridge over the River Conwy, designed and tested by William Fairbairn and built by Robert Stephenson between 1846 and 1850, and the original Victoria Bridge in Montreal.

<span class="mw-page-title-main">Chepstow Railway Bridge</span> Bridge spanning the River Wye between England and Wales

Chepstow Railway Bridge was built to the instructions of Isambard Kingdom Brunel in 1852. The "Great Tubular Bridge" over the River Wye at Chepstow, which at that point forms the boundary between Wales and England, is considered one of Brunel's major achievements, despite its appearance. It was economical in its use of materials, and would prove to be the design prototype for Brunel's Royal Albert Bridge at Saltash. Although the superstructure has since been replaced, Brunel's tubular iron supports are still in place. It is a Grade II listed structure.

<span class="mw-page-title-main">Bath Spa railway station</span> British railway station in Bath, England

Bath Spa railway station is the principal station serving the city of Bath in South West England. It is on the Great Western Main Line, 106 miles 71 chains down the line from the zero point at London Paddington between Chippenham to the east and Oldfield Park to the west. Its three-letter station code is BTH.

<span class="mw-page-title-main">Dee Bridge disaster</span> Railway accident

The Dee Bridge disaster was a rail accident that occurred on 24 May 1847 in Chester, England, that resulted in five fatalities. It revealed the weakness of cast iron beam bridges reinforced by wrought iron tie bars, and brought criticism of its designer, Robert Stephenson, the son of George Stephenson.

<span class="mw-page-title-main">Isambard Kingdom Brunel</span> British mechanical and civil engineer (1806–1859)

Isambard Kingdom Brunel was a British civil engineer and mechanical engineer who is considered "one of the most ingenious and prolific figures in engineering history", "one of the 19th-century engineering giants", and "one of the greatest figures of the Industrial Revolution, [who] changed the face of the English landscape with his groundbreaking designs and ingenious constructions". Brunel built dockyards, the Great Western Railway (GWR), a series of steamships including the first purpose-built transatlantic steamship, and numerous important bridges and tunnels. His designs revolutionised public transport and modern engineering.

<span class="mw-page-title-main">Girder bridge</span> Bridge built of girders placed on bridge abutments and foundation piers

A girder bridge is a bridge that uses girders as the means of supporting its deck. The two most common types of modern steel girder bridges are plate and box.

<span class="mw-page-title-main">Box girder</span> Type of girder

A box girder or tubular girder is a girder that forms an enclosed tube with multiple walls, as opposed to an I- or H-beam. Originally constructed of wrought iron joined by riveting, they are now made of rolled or welded steel, aluminium extrusions or prestressed concrete.

<span class="mw-page-title-main">Loughor Viaduct</span> Bridge over River Loughor, south Wales

The Loughor railway viaduct carries the West Wales Line across the River Loughor. It is adjacent, and runs parallel to, the Loughor road bridge. The 1880 viaduct was granted Grade II listed building status. Before it was demolished in early 2013, the viaduct was the last remaining timber viaduct designed by Isambard Kingdom Brunel.

<span class="mw-page-title-main">Usk Railway Bridge</span> Bridge in Newport

The Usk Railway Bridge is a railway viaduct in Newport city centre, Wales. It crosses the River Usk in an east—west direction, carrying the Great Western Main Line.

<span class="mw-page-title-main">Windsor Railway Bridge</span> Bridge in Windsor

Windsor Railway Bridge is a wrought iron 'bow and string' bridge in Windsor, Berkshire, crossing the River Thames on the reach between Romney Lock and Boveney Lock. It carries the branch line between Slough and Windsor.

<span class="mw-page-title-main">Cumberland Basin (Bristol)</span> Place in Bristol, England

The Cumberland Basin is the main entrance to the docks of the city of Bristol, England. It separates the areas of Hotwells from the tip of Spike Island.

<span class="mw-page-title-main">Baulk road</span> Railway track on undergirding timber bearings

Baulk road is the name given to a type of railway track or 'rail road' that is formed using rails carried on continuous timber bearings, as opposed to the more familiar 'cross-sleeper' track that uses closely spaced sleepers or ties to give intermittent support to stronger rails.

<span class="mw-page-title-main">Hadley Parabolic Bridge</span> Bridge in NY, USA

The Hadley Parabolic Bridge, often referred to locally as the Hadley Bow Bridge, carries Corinth Road across the Sacandaga River in Hadley, New York, United States. It is an iron bridge dating from the late 19th century.

<span class="mw-page-title-main">Gaunless Bridge</span> Bridge in County Durham, England

Gaunless Bridge was a railway bridge on the Stockton and Darlington Railway. It was completed in 1823 and is one of the first railway bridges to be constructed of iron and the first to use an iron truss. It is also of an unusual lenticular truss design.

<span class="mw-page-title-main">Meldon Viaduct</span> Bridge in United Kingdom

Meldon Viaduct is a disused railway viaduct crossing the West Okement River at Meldon, 2.5 miles (4.0 km) south-west of Okehampton, on the edge of Dartmoor in Devon, South West England. This truss bridge was constructed from wrought iron, instead of stone or brick arches. It opened in 1874 for a single track; in 1879 its width was doubled for a second track. Although regular services were withdrawn in 1968, the bridge was used for shunting by a local quarry. In the 1990s the remaining single track was removed.

References

  1. This view has recently been challenged, in light of the large number of cast-iron bridges which Brunel designed. [3]
  2. Brindle [6] describes these as 40% larger in cross-section, although this is slightly narrower in linear dimension
  3. Note that pagination varies between the 1870 edition of The Life of Isambard Kingdom Brunel, as reproduced at Google Books and the Cambridge facsimile edition, [11] and the 2006 STEAM bicentenary edition. [10] P. 193 in the original is now p. 146 in the 2006 STEAM edition. Page numbers are given here for the more affordable 2006 edition.
  4. The section of this first girder resembles the section from Chepstow, now preserved at Brunel University. illus.
  1. 1 2 Brindle, Steven (2005). Brunel: The Man Who Built the World. Weidenfeld & Nicolson. pp. 164–165. ISBN   0-297-84408-3.
  2. Life of IKB, pp. 144–1452.
  3. Brindle, Stephen; Tucker, Malcolm (6 September 2019). I.K. Brunel's bridges in cast iron. I.K. Brunel's Bristol swivel bridge: its place in his office and his world. Bristol: Institution of Structural Engineers.
  4. Beckett (1984). Stephenson's Britain. David & Charles. pp. 120–130. ISBN   0715382691.
  5. Brindle (2005), pp. 166–167.
  6. 1 2 Brindle, Steven. "Brunel's Paddington Bridge". Paddington Waterways and Maida Vale Society.
  7. Brindle (2005) , p. 166
  8. "In Pictures: Brunel's hidden bridge". BBC News Channel. 3 March 2004.
  9. Clark, Edwin (1850). "Experiments on the Transverse Strength of a Wrought Iron Girder". Britannia and Conway Tubular Bridges. Vol. I. London: Day & son. pp. 437–441.
  10. 1 2 3 4 5 6 7 8 9 10 Isambard Brunel (2006) [1870]. The Life of Isambard Kingdom Brunel, Civil Engineer. STEAM / Nonsuch Publishing. pp. 146–149. ISBN   1-84588-031-5.
  11. Isambard Brunel (2011) [1870]. The Life of Isambard Kingdom Brunel, Civil Engineer. Cambridge University Press. pp. 193–194. ISBN   978-1-108-02630-7.
  12. Clark (1850) , p. 441, The resistance of the triangular cell with the curved top to buckling was most satisfactory when compared with cells of other form.
  13. 1 2 3 Jones, II (2009) , pp. 133–134
  14. 1 2 Jones, Stephen K. (2009). Brunel in South Wales. Vol. II: Communications and Coal. Stroud: The History Press. p. 56. ISBN   9780752449128.
  15. Buchanan, Angus; Williams, Michael (1982). Brunel's Bristol. Redcliffe Press. p. 31. ISBN   0905459393.
  16. "Brunel's other bridge in Bristol may be repaired as £1m appeal launched". BBC News Online. 10 October 2014.
  17. "Brunel's Other Bridge".
  18. Greenfield, David; et al. (Eugene Kobchikov) (6 September 2019). Brunel's swivel bridge: its legacy, part 2 – the Kronstadt bridge. I.K. Brunel's Bristol swivel bridge: its place in his office and his world. Bristol: Institution of Structural Engineers.
  19. Humber, William (1870). A Complete Treatise on Cast and Wrought Iron Bridge Construction. Vol. I. London: Lockwood & Co. pp. 245–246.
  20. Life of IKB , p. 150
  21. Life of IKB , p. 151–155
  22. 1 2 Jones, II (2009) , pp. 93, figure 12, 128–129, 246–247
  23. 1 2 Brindle (2005) , p. 171
  24. 1 2 3 "Royal Deeside : Brunel's Bridge at Crathie". Royal Deeside. Archived from the original on 5 May 2017.
  25. "Crathie, Girder Bridge". Scotland's Places.
  26. "Balmoral Bridge". Engineering Timelines. Archived from the original on 4 March 2016.
  27. "Brunel's Balmoral bridge sketches go on display". 30 March 2006.
  28. "CH66: Fish Bridge - Devizes Branch Railway". Geocaching.
  29. Hyde, David; Priddle, Rod (1996). GWR to Devizes. Millstream Books. pp. 74–75. ISBN   0948975431.
  30. "Devizes and the railway". Devizes Heritage. Archived from the original on 3 May 2014.
  31. Malpass, Peter; King, Andy (2009). Bristol's Floating Harbour. Bristol: Redcliffe Press. pp. 52, 54–55. ISBN   978-1-906593-28-5.
  32. "Brunel Swing Bridge". Engineering Timelines.
  33. Jones, II (2009) , p. figure 12, 128–129
  34. "Stoodleigh Bridge". Grace's Guide .
  35. "Peel Street Bridge". Grace's Guide .
  36. Brindle, Steven. "Brunel's Lost Bridge: The Rediscovery and Salvage of the Bishops Road Canal Bridge, Paddington" (PDF). University of Cambridge Department of Architecture. Retrieved 16 July 2021.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.