Broad-gauge railway

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A broad-gauge railway is a railway with a track gauge (the distance between the rails) broader than the 1,435 mm (4 ft 8+12 in) used by standard-gauge railways.

Broad gauge of 1,520 mm (4 ft 11+2732 in), more known as Russian gauge, is the dominant track gauge in former Soviet Union countries (CIS states, Baltic states, Georgia, Ukraine) and Mongolia. Broad gauge of 1,524 mm (5 ft), commonly known as Five foot gauge, is mainly used in Finland. Broad gauge of 1,600 mm (5 ft 3 in), commonly known as Irish gauge, is the dominant track gauge in Ireland, the Australian state of Victoria and Adelaide in South Australia and passenger trains of Brazil.

Broad gauge of 1,668 mm (5 ft 5+2132 in), commonly known as Iberian gauge, is the dominant track gauge in Spain and Portugal.

Broad gauge of 1,676 mm (5 ft 6 in), commonly known as Indian gauge, is the dominant track gauge in India, Pakistan, Bangladesh, Sri Lanka, Argentina, Chile, and on BART (Bay Area Rapid Transit) in the San Francisco Bay Area. This is the widest gauge in common use anywhere in the world. It is possible for trains on both Iberian gauge and Indian gauge to travel on each other's tracks with no modifications in the vast majority of cases.[citation needed]

History

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Great Western Railway broad-gauge steam locomotives awaiting scrapping in 1892 after the conversion of the tracks to 4 ft 8+12 in (1,435 mm) standard gauge.
 
A replica GWR Firefly Class broad gauge steam locomotive, with a preserved, standard-gauge GWR railcar, Didcot Railway Centre, 2009

In Great Britain, broad gauge was first used in Scotland for the Dundee and Arbroath Railway (1836–1847) and the Arbroath and Forfar Railway (1838–1848). Both short and isolated lines, they were built in 5 ft 6 in (1,676 mm). The lines were subsequently converted to standard gauge and connected to the emerging Scottish rail network.

The Great Western Railway was designed by Isambard Kingdom Brunel in 1838 with a gauge of 7 ft 14 in (2,140 mm), and retained this gauge until 1892. Some harbours also used railways of this gauge for construction and maintenance. These included Portland Harbour and Holyhead Breakwater, which used a locomotive for working sidings. As it was not connected to the national network, this broad-gauge operation continued until the locomotive wore out in 1913.[1] The gauge initially proposed by Brunel was 7 ft (2,134 mm) exactly but this was soon increased by 14 in (6 mm) to 7 ft 14 in (2,140 mm) to accommodate clearance problems identified during early testing. George Stephenson was to add an extra half inch to his original 4 ft 8 in (1,422 mm) gauge for the same reason.[citation needed]

While the parliament of the United Kingdom of Great Britain and Ireland was initially prepared to authorise lines built to the broad gauge of 7 ft (2,134 mm), it was eventually rejected by the Gauge Commission in favour of all new railways in England, Wales and Scotland being built to standard gauge of 4 ft 8+12 in (1,435 mm), this being the gauge with the greatest mileage. Railways which had already received their enabling Act would continue at the 7 ft gauge. Ireland, using the same criteria, was allocated a different standard gauge, the Irish gauge, of 5 ft 3 in (1,600 mm) which is also used in the Australian states of South Australia and Victoria. Broad-gauge lines in Britain were gradually converted to dual gauge or standard gauge from 1864 and finally the last of Brunel's broad gauge was converted over a weekend in 1892.

In 1839, the Netherlands started its railway system with two broad-gauge railways. The chosen gauge of 1,945 mm (6 ft 4+916 in) was applied between 1839 and 1866 by the Hollandsche IJzeren Spoorweg-Maatschappij (HSM) for its Amsterdam–The Hague–Rotterdam line and between 1842 and 1855, firstly by the Dutch state, but soon by the Nederlandsche Rhijnspoorweg-Maatschappij (NRS), for its Amsterdam–Utrecht–Arnhem line. But the neighbouring countries Prussia and Belgium already used standard gauge, so the two companies had to regauge their first lines. In 1855, NRS regauged its line and shortly afterwards connected to the Prussian railways. The HSM followed in 1866. There are replicas of one broad-gauge 2-2-2 locomotive (De Arend) and three carriages in the Nederlands Spoorwegmuseum (Dutch Railway Museum) in Utrecht. These replicas were built for the 100th anniversary of the Dutch Railways in 1938–39.

The erstwhile Great Indian Peninsula Railway introduced a broad gauge of 1,676 mm (5 ft 6 in) for the first passenger railway line in India, between Bori Bunder and Thane. This was later adopted as the standard throughout the country, as it was thought to be safer in areas prone to cyclones and flooding.[2][3] The 1,676 mm (5 ft 6 in) gauge is now commonly referred to as Indian gauge. While some initial freight railway lines in India were built using standard gauge, most of the standard and narrow gauge railways have since been dismantled and relaid in broad gauge.

Ireland and some states in Australia and Brazil have a gauge of 5 ft 3 in (1,600 mm) but Luas, the Dublin light rail system, is built to standard gauge. Russia and the other former Soviet Republics use a 1,520 mm (4 ft 11+2732 in) (originally 5 ft (1,524 mm)) gauge while Finland continues to use the 5 ft (1,524 mm) gauge inherited from the Russian Empire (the two standards are close enough to allow full interoperability between Finland and Russia). Portugal and the Spanish Renfe system use a gauge of 1,668 mm (5 ft 5+2132 in) called Ancho Ibérico in Spanish or Bitola Ibérica in Portuguese (see Iberian gauge); though there are plans to convert to standard gauge.[4][5]

In Toronto, Canada, the gauge for TTC subways and streetcars was chosen in 1861. Toronto adopted a unique Toronto gauge of 4 ft 10+78 in (1,495 mm), an "overgauge" originally stated to "allow horse-drawn wagons to use the rails" on the horse-drawn streetcar lines of the day but with the practical effect of precluding the use of standard-gauge equipment in the street. The Toronto Transit Commission still operates the Toronto streetcar system and three heavy-rail subway lines using this unique gauge. The light metro Scarborough RT and two light rail lines under construction (Eglinton Crosstown line and Finch West) use standard gauge.[6]

In 1851, the 5 ft 6 in (1,676 mm) broad gauge was officially adopted as the standard gauge for the Province of Canada, becoming known as the Provincial gauge and government subsidies were unavailable for railways that chose other gauges. This caused problems in interchanging freight cars with northern United States railroads, most of which were built to standard gauge or a gauge similar to it. In the 1870s (mainly between 1872 and 1874), Canadian broad-gauge lines were changed to standard gauge to facilitate interchange and the exchange of rolling stock with American railroads. Today, almost all Canadian railways are standard-gauge.

In the early days of rail transport in the US, railways tended to be built out from coastal cities into the hinterland, and systems did not initially connect. Each builder was free to choose its own gauge, although the availability of British-built locomotives encouraged some railways to be built to standard gauge. As a general rule, southern railways were built to one or another broad gauge, mostly 5 ft (1,524 mm), while northern railroads that were not standard gauge tended to be narrow gauge. Most of the original track in Ohio was built in 4 ft 10 in (1,473 mm) Ohio gauge, and special "compromise cars" were able to run on both this track and standard gauge track.[7] In 1848, Ohio passed a law stating "The width of the track or gauge of all roads under this act, shall be four feet ten inches between the rails."[8] When American railroads' track extended to the point that they began to interconnect, it became clear that a single nationwide gauge was desirable.

Six-foot-gauge railroads (6 ft [1,829 mm]) had developed a large regional following in New York State in the first part of the 19th century, due to the influence of the New York and Erie, one of the early pioneering railroads in America, chartered in 1832, with its first section opening in 1841. The builders and promoters decided that a six-foot track gauge would be needed for locomotives to be larger and more powerful than were in general use at the time, for pulling very large trains. Also the six-foot gauge provided greater stability, and the New York and Erie would operate passenger cars up to 11 feet (3.4 m) wide. Building westward from the Hudson River, it eventually reached Lake Erie, establishing a mainline longer than 400 miles (640 km) providing a shortcut to the American Midwest region from the New York City vicinity, and helping spawn a regional network of six-foot-gauge railroads almost exclusively within New York State.

Many early New York railways were Erie railroad-built branch lines, while others were independent railroads that wanted to partner and interchange with the Erie. These included the Walkill Valley, the Albany and Susquehanna (later part of the Delaware and Hudson); the Elmira, Jefferson & Canandaigua (later the Northern Central, becoming part of the Pennsylvania Railroad); the Delaware, Lackawanna and Western mainline (which also had a significant amount of trackage in Pennsylvania); predecessor lines of the New York and Oswego Midland (later the New York, Ontario, and Western); and the Canandaigua and Niagara Falls (later becoming part of the New York Central railroad's Peanut Route along the shoreline of Lake Ontario). However, by the late 1870s, the trend was inevitable, and conversion to standard gauge began, some lines first becoming "dual gauged" with the addition of a third running rail. Between 1876 and 1880, most of the remaining six-foot gauge trackage was converted.[9]

In 1886, the railways in the Southern United States agreed to coordinate changing gauge on all their tracks. After considerable debate and planning, most of the southern rail network was converted from 5 ft (1,524 mm) gauge to 4 ft 9 in (1,448 mm) gauge, nearly the standard of the Pennsylvania Railroad, over two days beginning on 31 May 1886. Over a period of 36 hours, tens of thousands of workers pulled the spikes from the west rail of all the broad-gauge lines in the South, moved them 3 in (76 mm) east and spiked them back in place. The new gauge was close enough that standard-gauge equipment could run on it without difficulty. By June 1886, all major railroads in North America were using approximately the same gauge. The final conversion to true standard gauge took place gradually as track was maintained.[10]

Some North American tram (streetcar) lines intentionally deviated from standard gauge. This may have been to make the tram companies less tempting targets for takeovers by the steam railways (or competing tram companies), which would be unable to run their trains over the tram tracks.[11]

Pennsylvania trolley gauge of 5 ft 2+12 in (1,588 mm),[12] is still used on the streetcars in New Orleans, and the Pittsburgh Light Rail system. This gauge was also used for the now defunct Pittsburgh Railways, West Penn Railways, and trams in Cincinnati. Similar 5 ft 2+14 in (1,581 mm) gauge is used in Philadelphia on SEPTA routes, 15, the Media–Sharon Hill Line, the Subway–Surface Trolleys and the Market–Frankford Line.

Bay Area Rapid Transit (BART) system in the San Francisco Bay Area was opened in 1972 with 5 ft 6 in (1,676 mm) gauge. The system has been extended multiple times since then, using new railcars custom built with this non-standard gauge.

The use of a non-standard gauge precludes interoperability of rolling stock on railway networks. On the British Great Western Railway the 7 ft 14 in (2,140 mm) gauge was supposed to allow high speed, but the company had difficulty with locomotive design in the early years, losing much of the advantage, and rapid advances in railway track and suspension technology allowed standard-gauge speeds to approach broad-gauge speeds within a decade or two. On the 5 ft 3 in (1,600 mm) and 5 ft 6 in (1,676 mm) gauges, the extra width allowed bigger inside cylinders and greater power, a problem solvable by using outside cylinders and higher steam pressure on standard gauge. In the end, the most powerful engines on standard gauge in North America and Scandinavia far exceeded the power of any early broad-gauge locomotive, but then met limits set by other factors such as the capacity of manual stoking, the axle (and total) locomotive weight that would trigger upgrades to the rails and bridges, the maximum wheelbase and/or boiler length compatible with an individual route's curves.

In the 1930s German engineering studies focused on a Breitspurbahn system of railways of 3 meter gauge to serve Hitler's future German Empire.

High Speed Rail

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Spain uses standard gauge track for its high speed railways in order to provide cross-border services with France and the rest of Western Europe, but runs high speed trains on its legacy broad gauge network at 200 km/h (120 mph) and are developing trains to travel at speeds in excess of 250 km/h (160 mph). Russia uses a modified Siemens Velaro High Speed Train on its flagship St Petersburg to Moscow service at 250 km/h (160 mph) and can run at 350 km/h (220 mph) on dedicated track. The country is planning to build its portion of the Beijing to Moscow high speed railway in broad gauge. Finland uses a modified Alstom pendolino on the Allegro service to Helsinki at 220 km/h (140 mph). Uzbekistan uses a modified Talgo 250 on the Tashkent–Bukhara high-speed rail line at 250 km/h (160 mph).

South Asia primarily uses the broad gauge for its passenger rail services and the fastest broad gauge train presently in the region is the Indian Railways' Vande Bharat Express (a.k.a. Train 18). During one of the trial runs, the Vande Bharat Express achieved a peak speed of 180 km/h (110 mph).[13] The sustained speeds of this train is considerably lower, with a peak operational speed of 160 km/h[14] and an average speed of 95 km/h, due to track limitations. Indian Railways has plans to introduce a higher speed Vande Bharat sleeper train that is capable of 200 km/h, but the project has encountered delays stemming from bids for rolling-stocks with poor local sourcing.[15] A number of semi high speed railway projects using broad gauge tracks are being planned or built in the region, with sustained speeds of 200 km/h with future-proofing for 250 km/h. India's current high speed railway project is being built on the standard gauge due to limitations imposed by the Japanese consortium funding the project, however the feasibility reports by both the French and German consultants preferred a broad gauge high speed railway. These European reports stated that the additional costs of train procurement, due to the essential modifications of the rolling-stock for the broad gauge, from European rolling-stock manufacturers such as Alstom or Siemens would be softened through a large minimum order size of at least thirty train sets. A considerable debate has continued about the suitability of the high speed rail on standard gauge for the Indian travel demands and the possible exclusion of the existing rail network in India.[16] The recent discussions around the Kerala semi-high speed rail has highlighted the limitations of high speed rail on broad gauge. Since most of the global high speed rail infrastructure is built using the standard gauge, the cost benefits of using off-the-shelf rolling-stocks with minimal customizations and the availability of extensive, well proven technical know-how, are significant factors in favor of the high speed rail on the standard gauge over the broad gauge, for cost sensitive rail markets in South Asia, especially in India.[17]

Gauges

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4 ft 10+78 in gauge

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This gauge is used by the Toronto streetcar system and the Toronto subway

5 ft and 1520 mm gauge

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This gauge was first used in the United Kingdom and the United States before it became the standard gauge for most railways in the former Soviet Union.

Russian gauge or CIS gauge 1,520 mm (4 ft 11+2732 in) is the second most widely used gauge in the world, and spans the whole of the former Soviet Union/CIS bloc including the Baltic states and Mongolia. Finland uses 1,524 mm (5 ft). The difference is clearly lower than the tolerance margin, so through running is feasible. Care must be taken when servicing international trains because the wear profile of the wheels differs from that of trains that run on domestic tracks only.

When the Finnish rail network was founded in 1862, Finland was the Grand Duchy of Finland, an autonomic state ruled by the Imperial Russia. The first border crossing railway to Russia was opened in 1870, while the first to Sweden was not until 1919, so railways were built to the broad Russian track gauge of 1,524 mm (5 ft). In Russia, this gauge was re-standardized to 1,520 mm (4 ft 11+2732 in) during the 1960s. Finland retained the original gauge with no re-standardisation.

5 ft 3 in gauge

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Irish 5 ft 3 in (1,600 mm) broad gauge tracks

As part of the railway gauge standardisation considered by the United Kingdom Parliamentary Gauge Commission, Ireland was allocated its own gauge, Irish gauge. Ireland then had three gauges, and the new standard would be a fourth.

The Irish gauge of 1,600 mm (5 ft 3 in) is used in Ireland and parts of Australia and Brazil. A problem with the Irish Gauge in Australia is that it is only 165 mm (6+12 in) wider than the standard gauge used in other parts of Australia, principally New South Wales. Therefore, it is not considered advisable to use a third rail to allow dual-gauge operation on mainline sections of track, because of the danger of material lodging between the two rails.[18] There has been argument for well over a century about the practicability of third rail operation, and numerous devices have been promoted to overcome the problem, especially at turnouts, including the "Brennan Switch".[19]

5 ft 4+12 in

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This gauge was once used by the United Railways and Electric Company and the MTA Maryland and is now used only by the Baltimore Streetcar Museum.

Iberian gauge

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As finally established, the Iberian gauge of 1,668 mm (5 ft 5+2132 in) is a compromise between the similar, but slightly different, gauges first adopted as respective national standards in Spain and Portugal in the mid-19th century. The main railway networks of Spain were initially constructed to a 1,672 mm (5 ft 5+1316 in) gauge of six Castilian feet. Those of Portugal were initially built in standard gauge, but by 1864 were all converted to a 1,664 mm (5 ft 5+12 in) gauge of five Portuguese feet – close enough to allow interoperability in practice.[20] The new high-speed network in Spain and Portugal uses standard gauge. The dual-gauge high-speed train RENFE Class 130 can change gauge at low speed without stopping.

5 ft 6 in gauge

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The 5 ft 6 in (1,676 mm) gauge was first used in Great Britain in Scotland for two short, isolated lines, the Dundee and Arbroath Railway (1836-1847) and the Arbroath and Forfar Railway (1838- ). Both the lines were subsequently converted to standard gauge and connected to the Scottish rail network.

Later this gauge was adopted as a standard for many British colonies such as Province of Canada and British India.

In 1851, the 5 ft 6 in (1,676 mm) broad gauge was officially adopted as the standard gauge for the Province of Canada, becoming known as the Provincial gauge, and government subsidies were unavailable for railways that chose other gauges. In the 1870s, mainly between 1872 and 1874, Canadian broad-gauge lines were changed to standard gauge to facilitate interchange and the exchange of rolling stock with American railways. Today, all Canadian railways are standard-gauge.

In US, this gauge was adopted for many lines, but soon fell out in favour of standard gauge. Today, only California's Bay Area Rapid Transit (BART) uses this gauge.

In British India, some standard gauge freight railways were built in initial period, though they were dismantled later. Later, in the 1850s, the gauge of 5 ft 6 in (1,676 mm) was adopted as standard for the nationwide network. Attempts to economize on the cost of construction led to the adoption of 1,000 mm (3 ft 3+38 in) gauge and then 2 ft 6 in (762 mm) and 2 ft (610 mm) narrow gauges for many secondary and branch lines. In the later part of the 20th century, due to interchangeability and maintenance issue, the railways in each of the countries in the Indian Subcontinent began to convert all metre-gauge and narrow-gauge lines to this gauge. Today, the nationwide rail network in Pakistan, Sri Lanka and Nepal is entirely on this gauge, whereas India, under Project Unigauge, and Bangladesh are still undergoing gauge conversion.

This gauge is the widest gauge in regular passenger use in the world.

Broader gauges

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Gualala River Railroad with broad gauge track and locomotive number 2, S.H. Harmon

Some railways in the United States were laid with a gauge of 6 ft (1,829 mm). The Gualala River Railroad operated 5 feet 8+12 inches (1,740 mm) tracks for a logging railroad.

Some industrial uses require still broader gauges, such as:

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These applications might use double track of the country's usual gauge to provide the necessary stability and axle load. [citation needed] These applications may also use much heavier than normal rails, the heaviest rails for trains being about 70 kg/m (141 lb/yd). Vehicles on these gauges generally operate at very low speeds.

See also

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References

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  1. ^ Connection
  2. ^ "Railroads Asia – Up And Down India".
  3. ^ Indian Railways: Some Fascinating Facts, "Train Atlas", Train Atlas, Indian Railways, 2003
  4. ^ "Verkehrsrundschau, April 30, 2007". Archived from the original on 29 January 2019. Retrieved 21 August 2010.
  5. ^ Spanien: Bahn bis 2020 auf Normalspur
  6. ^ Kalinowski, Tess (6 January 2010). "Transit City measures up to international standard". Toronto Star. Archived from the original on 30 September 2013. Retrieved 6 August 2013.
  7. ^ Stover, John F. (1995). History of the Baltimore and Ohio Railroad. Purdue University Press.
  8. ^ Wright, Geo. B. (1868). Annual Report of the Commissioner of Railroads and Telegraphs to the Governor of the State of Ohio for the Year Ending June 30, 1868. Google Books: State of Ohio. p. 329.
  9. ^ The Day They Changed the Gauge on the D.L.& W. by Richard Palmer
  10. ^ "The Days They Changed the Gauge". southern.railfan.net. Retrieved 3 September 2012.
  11. ^ "Columbus' Streetcar Track Gauge: 5'2" vs 4'8 1/2"". Columbus Railroads. Retrieved 22 March 2011.
  12. ^ Hilton, George W.; Due, John Fitzgerald (1 January 2000). The Electric Interurban Railways in America. Stanford University Press. ISBN 978-0-8047-4014-2. Retrieved 10 June 2014. Worst of all, not all city systems were built to the standard American and European gauge of 4'-812". Pittsburgh and most other Pennsylvania cities used 5'-212", which became known as the Pennsylvania trolley gauge. Cincinnati used 5'-212", Philadelphia 5'-214", Columbus 5'-2", Altoona 5'-3", Louisville and Camden 5'-0", Canton and Pueblo 4'-0", Denver, Tacoma, and Los Angeles 3'-6", Toronto an odd 4'-1078", and Baltimore a vast 5'-412".
  13. ^ "Vande Bharat Express: India's fastest train Vande Bharat achieves 130 kmph speed during inaugural run". The Times of India. 15 February 2019. Retrieved 28 March 2022.
  14. ^ "India's 11th Vande Bharat Express from Bhopal-Delhi dashes at speed of 161 kmph! Know connecting routes, frequency and significance". Financialexpress. Retrieved 12 April 2023.
  15. ^ "Train 20: World-class semi-high speed train sets to replace Indian Railways Rajdhani Express; know about them". Financialexpress. Retrieved 28 March 2022.
  16. ^ Das, Mamuni. "India must adopt broad gauge for high-speed rail: Siemens Mobility". @businessline. Retrieved 14 July 2020.
  17. ^ സിൽവർ ലൈൻ പദ്ധതിയിൽ ഒന്നും മറച്ചു വയ്ക്കാനില്ല | K-Rail MD Ajith Kumar | Straight Line EP 440, retrieved 28 March 2022
  18. ^ "Third Rail System: Increased Danger Alleged". The Argus. Melbourne. 12 March 1926. Retrieved 3 September 2012.
  19. ^ "Break of Gauge". The Sydney Morning Herald. National Library of Australia. 13 April 1915. p. 10. Retrieved 26 August 2011.
  20. ^ Pequena História dos Caminhos de Ferro em Portugal. Archived 27 March 2008 at the Wayback Machine
  21. ^ The New York Times Magazine, 11 May 2008, p. 65
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