Narrow-gauge railway explained

A narrow-gauge railway (narrow-gauge railroad in the US) is a railway with a track gauge narrower than . Most narrow-gauge railways are between and .

Since narrow-gauge railways are usually built with tighter curves, smaller structure gauges, and lighter rails, they can be less costly to build, equip, and operate than standard- or broad-gauge railways (particularly in mountainous or difficult terrain).[1] Lower-cost narrow-gauge railways are often used in mountainous terrain, where engineering savings can be substantial. Lower-cost narrow-gauge railways are often built to serve industries as well as sparsely populated communities where the traffic potential would not justify the cost of a standard- or broad-gauge line. Narrow-gauge railways have specialised use in mines and other environments where a small structure gauge necessitates a small loading gauge.

In some countries, narrow gauge is the standard; Japan, Indonesia, Taiwan, New Zealand, South Africa, and the Australian states of Queensland, Western Australia and Tasmania have a gauge, whereas Vietnam, Malaysia and Thailand have metre-gauge railways. Narrow-gauge trams, particularly metre-gauge, are common in Europe. Non-industrial, narrow-gauge mountain railways are (or were) common in the Rocky Mountains of the United States and the Pacific Cordillera of Canada, Mexico, Switzerland, Bulgaria, the former Yugoslavia, Greece, and Costa Rica.

Nomenclature

See main article: Track gauge. A narrow-gauge railway is one where the distance between the inside edges of the rails is less than .[2] Historically, the term was sometimes used to refer to what are now standard-gauge railways, to distinguish them from broad-gauge railways, but this use no longer applies.

History

Early hand-worked lines

The earliest recorded railway appears in Georgius Agricola's 1556 De re metallica, which shows a mine in Bohemia with a railway of about gauge. During the 16th century, railways were primarily restricted to hand-pushed, narrow-gauge lines in mines throughout Europe. In the 17th century, mine railways were extended to provide transportation above ground. These lines were industrial, connecting mines with nearby transportation points (usually canals or other waterways). These railways were usually built to the same narrow gauge as the mine railways from which they developed.[3]

Introduction of steam

The world's first steam locomotive, built in 1802 by Richard Trevithick for the Coalbrookdale Company, ran on a plateway. The first commercially successful steam locomotive was Matthew Murray's Salamanca built in 1812 for the Middleton Railway in Leeds.[4] Salamanca was also the first rack-and-pinion locomotive. During the 1820s and 1830s, a number of industrial narrow-gauge railways in the United Kingdom used steam locomotives. In 1842, the first narrow-gauge steam locomotive outside the UK was built for the -gauge Antwerp-Ghent Railway in Belgium.[5] The first use of steam locomotives on a public, passenger-carrying narrow-gauge railway was in 1865, when the Ffestiniog Railway introduced passenger service after receiving its first locomotives two years earlier.

Industrial use

Many narrow-gauge railways were part of industrial enterprises and served primarily as industrial railways, rather than general carriers. Common uses for these industrial narrow-gauge railways included mining, logging, construction, tunnelling, quarrying, and conveying agricultural products. Extensive narrow-gauge networks were constructed in many parts of the world; 19th-century mountain logging operations often used narrow-gauge railways to transport logs from mill to market. Significant sugarcane railways still operate in Cuba, Fiji, Java, the Philippines, and Queensland, and narrow-gauge railway equipment remains in common use for building tunnels.

Introduction of internal combustion

In 1897, a manganese mine in the Lahn valley in Germany was using two benzine-fueled locomotives with single cylinder internal combustion engines on the 500mm gauge tracks of their mine railway; these locomotives were made by the Deutz Gas Engine Company (Gasmotorenfabrik Deutz), now Deutz AG.[6] [7] Another early use of internal combustion was to power a narrow-gauge locomotive was in 1902. F. C. Blake built a 7 hp petrol locomotive for the Richmond Main Sewerage Board sewage plant at Mortlake. This gauge locomotive was probably the third petrol-engined locomotive built.[8]

First World War and later

Extensive narrow-gauge rail systems served the front-line trenches of both sides in World War I.[9] [10] They were a short-lived military application, and after the war the surplus equipment created a small boom in European narrow-gauge railway building.

Improvements

Heavy-duty tracks

The heavy-duty narrow-gauge railways in Australia (Queensland), New Zealand, South Africa, Japan, Taiwan, Indonesia and the Philippines demonstrate that if track is built to a heavy-duty standard, performance almost as good as a standard-gauge line is possible.

Two-hundred-car trains operate on the Sishen–Saldanha railway line in South Africa, and high-speed Tilt Trains run in Queensland. In South Africa and New Zealand, the loading gauge is similar to the restricted British loading gauge; in New Zealand, some British Rail Mark 2 carriages have been rebuilt with new bogies for use by Tranz Scenic (Wellington-Palmerston North service), Tranz Metro (Wellington-Masterton service), and Auckland One Rail (Auckland suburban services).

Another example of a heavy-duty narrow-gauge line is Brazil's EFVM. gauge, it has over-100-pound rail (100lb/yd) and a loading gauge almost as large as US non-excess-height lines. The line has a number of 4000hp locomotives and 200-plus-car trains.

Fastest trains

Narrow gauge's reduced stability means that its trains cannot run at speeds as high as on broader gauges. For example, if a curve with standard-gauge rail (1435 mm) can allow speed up to 145km/h, the same curve with narrow-gauge rail (1067mm) can only allow speed up to 130km/h.[11]

In Japan and Queensland, recent permanent-way improvements have allowed trains on gauge tracks to exceed 160km/h. Queensland Rail's Electric Tilt Train, the fastest train in Australia and the fastest gauge train in the world, set a record of 210km/h.[12] The speed record for narrow-gauge rail is 245km/h, set in South Africa in 1978.[13] [14] [15]

A special gauge railcar was built for the Otavi Mining and Railway Company with a design speed of 137km/h.[16] Curve radius is also important for high speeds: narrow-gauge railways allow sharper curves, but these limit a vehicle's safe speed.

Gauges

See also: List of track gauges.

Many narrow gauges, from gauge and gauge, are in present or former use. They fall into several broad categories:

Just under standard gauge

See main article: List of 4 ft 8 in gauge railways and 4 ft 8 in gauge railways.

4 ft 6 in gauge

See main article: 4 ft 6 in gauge railway.

track gauge (also known as Scotch gauge) was adopted by early 19th-century railways, primarily in the Lanarkshire area of Scotland. lines were also constructed, and both were eventually converted to standard gauge.

Around 4 ft gauge

1093 mm gauge

3 ft 6 in gauge

See main article: 3 ft 6 in gauge railways. between the inside of the rail heads, its name and classification vary worldwide and it has about 112000km (70,000miles) of track.

Similar gauges

Metre gauge and Italian metre gauge

See main article: Metre gauge. As its name implies, metre gauge is a track gauge of . It has about 95000km (59,000miles) of track.

According to Italian law, track gauges in Italy were defined from the centre of each rail rather than the inside edges of the rails. This gauge, measured between the edges of the rails, is known as Italian metre gauge.

3 ft, 900 mm, and Swedish three-foot gauge

See main article: 3 ft gauge railways, 900 mm gauge railways and Swedish three foot gauge railways.

There were a number of large railroad systems in North America; notable examples include the Denver & Rio Grande and Rio Grande Southern in Colorado; the Texas and St. Louis Railway in Texas, Arkansas and Missouri; and, the South Pacific Coast, White Pass and Yukon Route and West Side Lumber Co of California. was also a common track gauge in South America, Ireland and on the Isle of Man. was a common gauge in Europe. Swedish three-foot-gauge railways are unique to that country and were once common all over the country. Today the only 891 mm line that remains apart from heritage railways is Roslagsbanan, a commuter line that connects Stockholm to its northeastern suburbs.

2 ft 9 in gauge

A few railways and tramways were built to gauge, including Nankai Main Line (later converted to), Ocean Pier Railway at Atlantic City, Seaton Tramway (converted from) and Waiorongomai Tramway.

800 mm, 2 ft 6 in, Bosnian and 750 mm gauge

See main article: 800 mm gauge railways, 2 ft 6 in gauge railways and 750 mm gauge railways.

gauge railways are commonly used for rack railways. Imperial gauge railways were generally constructed in the former British colonies. Bosnian gauge and railways are predominantly found in Russia and Eastern Europe.

Between and gauge

See main article: List of 2 ft 3 in gauge railways. Gauges such as, and were used in parts of the UK, particularly for railways in Wales and the borders, with some industrial use in the coal industry. Some sugar cane lines in Cuba were .[18]

2 ft and 600 mm gauges

See main article: 2 ft and 600 mm gauge railways.

gauge railways were generally constructed in the former British colonies. The U.S. had a number of railways of that gauge, including several in the state of Maine such as the Wiscasset, Waterville and Farmington Railway., and were used in Europe.

Minimum gauge

See main article: Minimum-gauge railway.

Gauges below were rare. Arthur Percival Heywood developed gauge estate railways in Britain and Decauville produced a range of industrial railways running on and tracks, most commonly in restricted environments such as underground mine railways, parks and farms, in France. Several gauge railways were built in Britain to serve ammunition depots and other military facilities, particularly during World War I.

See also

Notes

Notes and References

  1. Book: Spooner, Charles Easton . Narrow Gauge Railways . 1879 . 71.
  2. Book: Coulls, Anthony . Narrow Gauge Locomotives . Amberley Publishing . 15 April 2018 . Narrow gauge is defined as anything less than the standard gauge of UK main lines.
  3. Book: Narrow Gauge Railways of the British Isles . Whitehouse, Patrick . Snell, John B. . amp . 1984 . David & Charles . 0-7153-0196-9.
  4. Book: Dawson, Anthony . Before Rocket: The Steam Locomotive up to 1829 . Gresley . 17 June 2020.
  5. Book: Ransom, P.J.G. . P. J. G. Ransom

    . P. J. G. Ransom . Narrow Gauge Steam – Its origins and worldwide development . Oxford Publishing Co. . 1996 . 0-86093-533-7.

  6. A Benzine Lgocomotive for use in Mines, The Petroleum Industrial and Technical Review, vol. 2, no. 68 (23 June 1900); page 388.
  7. Benzine Locomotive, English Mechanic and World of Science, No. 1713 (21 January 1898); pages 532–533.
  8. Industrial Railway Record . 236 . March 2019 . Dan . Quine . Dan Quine . F.C. Blake and the Mortlake Tramways . the Industrial Railway Society.
  9. Book: Dunn, Richard . Narrow gauge to no man's land: U.S. Army 60 cm gauge railways of the First World War in France . Benchmark Publications . 1 January 1990.
  10. Book: Westwood , J. N. . Railways at War . Howell-North Books . 1980.
  11. Web site: 日刊 動労千葉. doro-chiba.org. ja.
  12. Web site: Annual Report 1998-1999 . https://web.archive.org/web/20090930024735/http://www.corporate.qr.com.au/Images/QR_Annual_Report_tcm15-2468.pdf . 30 September 2009 . Queensland Rail . 1999 . 16, 19.
  13. Web site: Rail Speed Records . https://web.archive.org/web/20120211074300/http://www.speedrecordclub.com/outrail.php . 11 February 2012 . Speed Record Club . 10 February 2012.
  14. Web site: Class 5E/6E Electric . https://web.archive.org/web/20080615020009/http://home.intekom.com/bluegrass/sites/steamsa/historical11.html . 15 June 2008 . home.intekom.com.
  15. Web site: Pantograph testing in South Africa . https://web.archive.org/web/20220228105903/http://www.traintesting.com/SAR.htm . 28 February 2022 . live . Traintesting.com . 10 February 2012.
  16. Book: Shaw, Frederic J.. Little Railways of the World . Howell-North . 1958.
  17. Book: Eisenbahnatlas Schweiz . 2012 . Verlag Schweers + Wall GmbH . 978-3-89494-130-7 . 14–15.
  18. https://www.zelmeroz.com/album_rail/ctn/ctn_08.pdf