All vehicles on a rail network must have running gear that is compatible with the track gauge, and in the earliest days of railways the selection of a proposed railway's gauge was a key issue. As the dominant parameter determining interoperability, it is still frequently used as a descriptor of a route or network.
In some places there is a distinction between the nominal gauge and the actual gauge, due to divergence of track components from the nominal. Railway engineers use a device, like a caliper, to measure the actual gauge, and this device is also referred to as a track gauge.
The terms structure gauge and loading gauge, both widely used, have little connection with track gauge. Both refer to two-dimensional cross-section profiles, surrounding the track and vehicles running on it. The structure gauge specifies the outline into which new or altered structures (bridges, lineside equipment etc.) must not encroach. The loading gauge is the corresponding envelope within which rail vehicles and their loads must be contained. If an exceptional load or a new type of vehicle is being assessed to run, it is required to conform to the route's loading gauge. Conformance ensures that traffic will not collide with lineside structures.
The earliest form of railway was a wooden wagonway, along which single wagons were manhandled, almost always in or from a mine or quarry. Initially the wagons were guided by human muscle power; subsequently by various mechanical methods. Timber rails wore rapidly: later, flat cast-iron plates were provided to limit the wear. In some localities, the plates were made L-shaped, with the vertical part of the L guiding the wheels; this is generally referred to as a "plateway". Flanged wheels eventually became universal, and the spacing between the rails had to be compatible with that of the wagon wheels.
As the guidance of the wagons was improved, short strings of wagons could be connected and pulled by horses, and the track could be extended from the immediate vicinity of the mine or quarry, typically to a navigable waterway. The wagons were built to a consistent pattern and the track would be made to suit the wagons: the gauge was more critical. The Penydarren Tramroad of 1802 in South Wales, a plateway, spaced these at 4 ft 4 in (1,321 mm) over the outside of the upstands.
The Penydarren Tramroad probably carried the first journey by a locomotive, in 1804, and it was successful for the locomotive, but unsuccessful for the track: the plates were not strong enough to carry its weight. A considerable progressive step was made when cast iron edge rails were first employed; these had the major axis of the rail section configured vertically, giving a much stronger section to resist bending forces, and this was further improved when fish-belly rails were introduced.
Edge rails required a close match between rail spacing and the configuration of the wheelsets, and the importance of the gauge was reinforced. Railways were still seen as local concerns: there was no appreciation of a future connection to other lines, and selection of the track gauge was still a pragmatic decision based on local requirements and prejudices, and probably determined by existing local designs of (road) vehicles.
Thus, the Monkland and Kirkintilloch Railway (1826) in the West of Scotland used 4 ft 6 in (1,372 mm); the Dundee and Newtyle Railway (1831) in the north-east of Scotland adopted 4 ft 6 1⁄2 in (1,384 mm); the Redruth and Chasewater Railway (1825) in Cornwall chose 4 ft (1,219 mm).
Locomotives were being developed in the first decades of the 19th century; they took various forms, but George Stephenson developed a successful locomotive on the Killingworth Wagonway, where he worked. His designs were so successful that they became the standard, and when the Stockton and Darlington Railway was opened in 1825, it used his locomotives, with the same gauge as the Killingworth line, 4 ft 8 in (1,422 mm).
The Stockton and Darlington line was immensely successful, and when the Liverpool and Manchester Railway, the first intercity line, was built (it opened in 1830), it used the same gauge. It was also hugely successful, and the gauge (now eased to 4 ft 8 1⁄2 in or 1,435 mm), became the automatic choice: "standard gauge".
The Liverpool and Manchester was quickly followed by other trunk railways, with the Grand Junction Railway and the London and Birmingham Railway forming a huge critical mass of standard gauge. When Bristol promoters planned a line from London, they employed the innovative engineer Isambard Kingdom Brunel. He decided on a wider gauge, to give greater stability, and the Great Western Railway adopted a gauge of 7 ft (2,134 mm), later eased to 7 ft 1⁄4 in (2,140 mm). This became known as broad gauge. The Great Western Railway (GWR) was successful and was greatly expanded, directly and through friendly associated companies, widening the scope of broad gauge.
At the same time, other parts of Britain built railways to standard gauge, and British technology was exported to European countries and parts of North America, also using standard gauge. Britain polarised into two areas: those that used broad gauge and those that used standard gauge. In this context, standard gauge was referred to as "narrow gauge" to indicate the contrast. Some smaller concerns selected other non-standard gauges: the Eastern Counties Railway adopted 5 ft (1,524 mm). Most of them converted to standard gauge at an early date, but the GWR's broad gauge continued to grow.
The larger railway companies wished to expand geographically, and large areas were considered to be under their control. When a new independent line was proposed to open up an unconnected area, the gauge was crucial in determining the allegiance that the line would adopt: if it was broad gauge, it must be friendly to the Great Western railway; if narrow (standard) gauge, it must favour the other companies. The battle to persuade or coerce that choice became very intense, and became referred to as "the gauge wars".
As passenger and freight transport between the two areas became increasingly important, the difficulty of moving from one gauge to the other—the break of gauge—became more prominent and more objectionable. In 1845 a Royal Commission on Railway Gauges was created to look into the growing problem, and this led to the Regulating the Gauge of Railways Act 1846, which forbade the construction of broad gauge lines unconnected with the broad gauge network. The broad gauge network was eventually converted—a progressive process completed in 1892, called gauge conversion. The same Act mandated the gauge of 5 ft 3 in (1,600 mm) for use in Ireland.
As railways were built in other countries, the gauge selection was pragmatic: the track would have to fit the rolling stock. If locomotives were imported from elsewhere, especially in the early days, the track would be built to fit them. In some cases standard gauge was adopted, but many countries or companies chose a different gauge as their national gauge, either by governmental policy, or as a matter of individual choice. Government officials in Spain were concerned that the rail lines they were planning could be used by an invader, and purposely chose gauges that were different from their neighbors.
Narrow gauges were widely used in mountainous regions, as construction costs tended to be lower and they enabled the tighter turns that were often required.
To keep the rail traffic compatible within a network, not only the track gauge needs to be the same, but also the couplers, at least for locomotive-hauled vehicles. For this reason, most of the standard gauge railways in Europe use the standard buffers and chain coupler with some use of the buckeye coupler in the UK, for locomotive hauled vehicles, and some use Scharfenberg couplers on suburban multiple unit as well as variants of the SA3 couplers on some rolling stock, while narrow gauge railways use a variation of couplers, since they often are isolated from each other, so standardisation is not needed. Similarly, standard gauge railways in Canada, the US and Mexico use the janney coupler or the compatible tightlock coupling for locomotive-hauled equipment.
The terms standard gauge, broad gauge and narrow gauge do not have any fixed meaning. A "standard" gauge is only standard in a geographical region where it is dominant, but it is generally understood to be 1,435 mm (4 ft 8 1⁄2 in). An infrastructure owner would be ill-advised to order track materials simply as "standard gauge", but would normally specify the required critical dimensions of the components.
Broad gauge and narrow gauge are relative to the generally adopted standard.
In British practice, the space between the rails of a track is colloquially referred to as the "four-foot", and the space between two tracks the "six-foot", descriptions relating to the respective dimensions.
In common usage the term "standard gauge" refers to 1,435 mm (4 ft 8 1⁄2 in).
In modern usage, broad gauge generally refers to track spaced significantly wider than 1,435 mm (4 ft 8 1⁄2 in).
The term medium gauge had different meanings throughout history, depending on the local dominant gauge in use.
During the period known as "the Battle of the gauges", Stephenson's standard gauge was commonly known as "narrow gauge", while Brunel's railway's 7 ft 1⁄4 in (2,140 mm) gauge was termed "broad gauge".
As the gauge of a railway is reduced the costs of construction can be reduced since narrow gauges allow smaller-radius curves, allowing obstacles to be avoided rather than having to be built over or through (valleys and hills); the reduced cost is particularly noticeable in mountainous regions, and many narrow gauge railways were built in Wales, the Rocky Mountains of North America, Central Europe and South America.
Industrial railways are often narrow gauge. Sugar cane and banana plantations are often served by narrow gauges such as 2 ft (610 mm), as there is little through traffic to other systems. 500 mm (19 3⁄4 in) gauge was also used in French mines.
The most widely used narrow gauges on public railways are:
Very narrow gauges of 2 feet (610 mm) and under were used for some industrial railways in space-restricted environments such as mines or farms. The French company Decauville developed 500 mm (19 3⁄4 in) and 400 mm (15 3⁄4 in) tracks, mainly for mines; Heywood developed 15 in (381 mm) gauge for estate railways. The most common minimum-gauges were 15 in (381 mm), 400 mm (15 3⁄4 in), 16 in (406 mm), 18 in (457 mm), 500 mm (19 3⁄4 in) or 20 in (508 mm).
Through operation between railway networks with different gauges was originally impossible; goods had to be transshipped and passengers had to change trains. This was obviously a major obstacle to convenient transport, and in Great Britain, led to political intervention.
On narrow gauge lines, Rollbocks or transporter wagons are used: standard gauge wagons are carried on narrow gauge lines on these special vehicles, generally with rails of the wider gauge to enable those vehicles to roll on and off at transfer points.
On the Transmongolian Railway, Russia and Mongolia use 1,520 mm (4 ft 11 27⁄32 in) while China uses the Standard gauge of 1,435 mm. At the border, each carriage is lifted and its bogies are changed. The operation can take several hours for a whole train of many carriages.
Other examples include crossings into or out of the former Soviet Union: Ukraine/Slovakia border on the Bratislava–L'viv train, and the Romania/Moldova border on the Chişinău-Bucharest train.
A system developed by Talgo and Construcciones y Auxiliar de Ferrocarriles (CAF) of Spain uses variable gauge wheelsets; at the border between France and Spain, through passenger trains are drawn slowly through apparatus that alters the gauge of the wheels, which slide laterally on the axles. This is fully described in Automatic Gauge Changeover for Trains in Spain.
A similar system is used between China and Central Asia, and between Poland and Ukraine, using the SUW 2000 and INTERGAUGE variable axle systems. China and Poland use standard gauge, while Central Asia and Ukraine use 1,520 mm (4 ft 11 27⁄32 in).
Where a railway corridor is used by trains of two gauges, mixed gauge (or dual gauge) track can be provided, in which three rails are supported in the same track structure. This arose particularly when individual railway companies chose different gauges and were subsequently required to share a route; this is most commonly found at the approaches to city terminals, where land space is limited.
Trains of different gauges sharing the same track can save considerable expense compared to using separate tracks for each gauge, but introduces complexities in track maintenance and signalling, and may require speed restrictions for some trains. If the difference between the two gauges is large enough, for example between 1,435 mm (4 ft 8 1⁄2 in) standard gauge and 3 ft 6 in (1,067 mm), three-rail dual-gauge is possible, but if not, for example between 3 ft 6 in (1,067 mm) and 1,000 mm (3 ft 3 3⁄8 in) metre gauge, four-rail triple-gauge is used. Dual-gauge rail lines are used in Switzerland, Australia, Argentina, Brazil, Japan, North Korea, Spain, Tunisia and Vietnam.
On the GWR, there was an extended period between political intervention in 1846 that prevented major expansion of its 7 ft 1⁄4 in (2,140 mm) broad gauge[note 1] and the final gauge conversion to standard gauge in 1892.
During this period, there were many locations where practicality required mixed gauge operation, and in station areas, the track configuration was extremely complex. This was compounded by the fact that the common rail had to be at the platform side in stations, so in many cases, standard-gauge trains needed to be switched from one side of the track to the other at the approach. A special fixed point arrangement was devised for the purpose, where the track layout was simple enough. Jenkins and Langley give an illustration and description.
In some cases, mixed gauge trains operated, conveying wagons of both gauges. For example, MacDermot says:
In November 1871 a novelty in the shape of a mixed-gauge goods train was introduced between Truro and Penzance. It was worked by a narrow-gauge engine, and behind the narrow-gauge trucks came a broad-gauge match-truck with wide buffers and sliding shackles, followed by the broad-gauge trucks. Such trains continued to run in West Cornwall until the abolition of the Broad Gauge; they had to stop or come down to walking pace at all stations where fixed points existed and the narrow portion side-stepped to right or left.
The nominal track gauge is the distance between the inner faces of the rails. In current practice, it is specified at a certain distance below the rail head as the inner faces of the rail head (the gauge faces) are not necessarily vertical.
Rolling stock on the network must have running gear (wheelsets) that are compatible with the gauge, and therefore the gauge is a key parameter in determining interoperability, but there are many others – see below. In some cases in the earliest days of railways, the railway company saw itself as an infrastructure provider only, and independent hauliers provided wagons suited to the gauge. Colloquially the wagons might be referred to as "four-foot gauge wagons", say, if the track had a gauge of four feet. This nominal value does not equate to the flange spacing, as some freedom is allowed for.
An infrastructure manager might specify new or replacement track components at a slight variation from the nominal gauge for pragmatic reasons.
Imperial units were established in the United Kingdom by The Weights and Measures Act of 1824. The United States customary units for length did not agree with the Imperial system until 1959, when one International yard was defined as 0.9144 meters, i.e. 1 foot as 0.3048 meter and 1 inch as 25.4 mm.
The list shows the Imperial and other units that have been used for track gauge definitions:
|Unit||SI equivalent||Track gauge example|
|Imperial feet||304.8 mm|
|Castilian feet||278.6 mm||6 Castilian feet =1,672 mm (5 ft 5 13⁄16 in)|
(2 Castilian feet = 558 mm, 1 ft 9 31⁄32 in)
|Portuguese feet||332.8 mm||5 Portuguese feet = 1,664 mm (5 ft 5 1⁄2 in)|
|Swedish feet||296.904 mm||3 Swedish feet =891 mm (2 ft 11 3⁄32 in)|
2.7 Swedish feet =802 mm (2 ft 7 9⁄16 in)
|Prussian feet (Rheinfuß)||313.85 mm||2 1⁄2 Prussian feet =785 mm (2 ft 6 29⁄32 in)|
|Austrian fathom||1520 mm||1⁄2 Austrian fathom =760 mm (2 ft 5 15⁄16 in)|
The temporary way is the temporary track often used for construction, replaced by the permanent way (the structure consisting of the rails, fasteners, sleepers/ties and ballast (or slab track), plus the underlying subgrade) when construction nears completion. In many cases narrow-gauge track is used for a temporary way because of the convenience in laying it and changing its location over unimproved ground.
In restricted spaces such as tunnels, the temporary way might be double track even though the tunnel will ultimately be single track. The Airport Rail Link in Sydney had construction trains of 900 mm (2 ft 11 7⁄16 in) gauge, which were replaced by permanent tracks of 1,435 mm (4 ft 8 1⁄2 in) gauge.
During World War I trench warfare led to a relatively static disposition of infantry, requiring considerable logistics to bring them support staff and supplies (food, ammunition, earthworks materials, etc.). Dense light railway networks using temporary narrow gauge track sections were established by both sides for this purpose.
In 1939 it was proposed to construct the western section of the Yunnan–Burma Railway using a gauge of 15 1⁄4 in (387 mm), since such tiny or "toy" gauge facilitates the tightest of curves in difficult terrain.
Infrastructure owners specify permitted variances from the nominal gauge, and the required interventions when non-compliant gauge is detected. For example, the Federal Railroad Administration in the USA specifies that the actual gauge of a 1,435 mm track that is rated for a maximum of 60 mph (96.6 km/h) must be between 4 ft 8 in (1,422 mm) and 4 ft 9.5 in (1,460 mm).
When selecting a gauge, there is a trade-off between different pros and cons:
One generally wants speed/stability/capacity, and one wants economy, but there is often an inverse relationship between these priorities. In addition, there are other constraints, such as the load-carrying capacity of axles, which may be problematic with an excessively wide gauge. There is a common misconception that a narrower gauge permits a tighter turning radius, but for practical purposes, there is no meaningful relationship between gauge and curvature.
Narrow gauge railways usually cost less to build because they are usually lighter in construction, using smaller cars and locomotives (smaller loading gauge), as well as smaller bridges, smaller tunnels (smaller structure gauge) and tighter curves. Narrow gauge is thus often used in mountainous terrain, where the savings in civil engineering work can be substantial. It is also used in sparsely populated areas, with low potential demand, and for temporary railways that will be removed after short-term use, such as for construction, the logging industry, the mining industry, or large-scale construction projects, especially in confined spaces (see Temporary way – permanent way).
Broader gauge railways are generally more expensive to build, but offer higher speed, stability, and capacity. For routes with high traffic, greater capacity may more than offset the higher initial cost of construction.
There is no single perfect gauge, because different environments and economic considerations come into play. A narrow gauge is better suited for difficult terrain and/or routes with low traffic. Conversely, wide gauge is preferable for direct, unimpeded routes with high traffic. The Standard Gauge is intended to strike a reasonable balance between these factors; this may also be true of the 1,372 mm (4 ft 6 in) and the Russian gauge.
In addition to the general trade-off, another important factor is standardization. Once a standard has been chosen, and equipment, infrastructure, and training calibrated to that standard, conversion becomes difficult and expensive. This also makes it easier to adopt an existing standard than to invent a new one. This is true of many technologies, including railroad gauges. For rail gauge in particular, break-of-gauge often causes inefficiency far in excess of the merits of any particular gauge. The reduced cost, greater efficiency, and greater economic opportunity offered by the use of a common standard explains why a small number of gauges predominate worldwide.
Approximately 55% of the world's railways use the 1,435 mm (4 ft 8 1⁄2 in) standard gauge.
|Gauge||Name||Installation (km)||Installation (miles)||Usage|
|1,000 mm (3 ft 3 3⁄8 in)||Metre gauge||95,000||59,000||Argentina (11,000 km or 6,800 mi), Brazil (23,489 km or 14,595 mi), Bolivia, northern Chile, Spain (Feve, FGC, Euskotren, FGV, SFM), Switzerland (RhB, MOB, BOB, MGB), Malaysia, Thailand, Indochina, Bangladesh, East Africa|
(approx. 7% of the world's railways)
|1,067 mm (3 ft 6 in)||Three foot six inch gauge||112,000||70,000||Southern and Central Africa, Nigeria (most), Indonesia, Japan, Taiwan, Philippines, New Zealand, Queensland Australia, Western Australia |
(approx. 9% of the world's railways)
|1,435 mm (4 ft 8 1⁄2 in)||Standard gauge||720,000||450,000||Albania, Argentina, Australia, Austria, Belgium, Bosnia and Herzegovina, Brazil (194 km or 121 mi), Bulgaria, Canada, China, Croatia, Cuba, Czech Republic, Denmark, Djibouti, DR Congo (Kamina-Lubumbashi section, planned), Ethiopia, France, Germany, Great Britain (United Kingdom), Greece, Hungary, India (only used in rapid transit), Indonesia (Aceh and Sulawesi), Italy, Israel, Liechtenstein, Lithuania (Rail Baltica), Luxembourg, Macedonia, Mexico, Montenegro, Netherlands, North Korea, Norway, Panama, Peru, Philippines, Poland, Romania, Serbia, Slovakia, Slovenia, South Korea, Spain (AVE, Alvia and FGC), Sweden, Switzerland, United States, Uruguay, Venezuela, Also private companies' lines and JR high-speed lines in Japan. High-speed lines in Taiwan. Gautrain commuter system in South Africa.|
(approx. 55% of the world's railways)
|1,520 mm (4 ft 11 27⁄32 in)||Five foot and 1520 mm gauge||220,000||140,000||Armenia, Azerbaijan, Belarus, Finland, Estonia, Georgia, Kazakhstan, Kyrgyzstan, Latvia, Lithuania, Moldova, Mongolia, Russia, Tajikistan, Turkmenistan, Ukraine, Uzbekistan. |
(approx. 17.2% of the world's railways; all contiguous – redefined from 1,524 mm (5 ft))
|1,524 mm (5 ft)||Finnish gauge||5,865||3,644||Finland (contiguous to and generally compatible with 1,520 mm (4 ft 11 27⁄32 in))|
|1,600 mm (5 ft 3 in)||Five foot three inch gauge||9,800||6,100||Ireland, Northern Ireland (United Kingdom) (1,800 km or 1,100 mi), and in the Australian states of Victoria and South Australia (4,017 km or 2,496 mi), Brazil (4,057 km or 2,521 mi)|
|1,668 mm (5 ft 5 21⁄32 in)||Iberian gauge||15,394||9,565||Portugal, Spain. Sometimes referred to as Iberian gauge. In Spain the Administrador de Infraestructuras Ferroviarias (ADIF) managed 11,683 km (7,259 mi) of this gauge and 22 km (14 mi) of mixed gauge at end of 2010. The Portuguese Rede Ferroviária Nacional (REFER) managed 2,650 km (1,650 mi) of this gauge of this track at the same date.|
|1,676 mm (5 ft 6 in)||Five foot six inch gauge||134,008||83,269||India, Pakistan, Bangladesh, Sri Lanka, Argentina, Chile, BART in the United States San Francisco Bay Area|
(approx. 11.37% of the world's railways)
Total for each type of gauge.
Further convergence of rail gauge use seems likely, as countries seek to build inter-operable networks, and international organisations seek to build macro-regional and continental networks. The European Union has set out to develop inter-operable freight and passenger rail networks across its area, and is seeking to standardise gauge, signalling and electrical power systems. As countries build High-speed rails, they also tend to converge these rails' gauge to standard gauge, with the exceptions of Uzbekistan and Russia.
EU funds have been dedicated to assist Lithuania, Latvia, and Estonia in the building of some key railway lines (Rail Baltica) of standard gauge, and to assist Spain and Portugal in the construction of high-speed lines to connect Iberian cities to one another and to the French high-speed lines. The EU has developed plans for improved freight rail links between Spain, Portugal, and the rest of Europe.
The United Nations Economic and Social Commission for Asia and the Pacific (UNESCAP) is planning a Trans-Asian Railway that will link Europe and the Pacific, with a Northern Corridor from Europe to the Korean Peninsula, a Southern Corridor from Europe to Southeast Asia, and a North–South corridor from Northern Europe to the Persian Gulf. All these would encounter breaks of gauge as they cross Asia. Current plans have mechanized facilities at the breaks of gauge to move containers from train to train rather than widespread gauge conversion.
The East African Railway Master Plan is a proposal for rebuilding and expanding railway lines connecting Ethiopia, Djibouti, Kenya, Uganda, Rwanda, Burundi, Tanzania, South Sudan and beyond. The plan is managed by infrastructure ministers from participating East African Community countries in association with transport consultation firm CPCS Transcom. Older railways are of 1,000 mm (3 ft 3 3⁄8 in) metre gauge or 3 ft 6 in (1,067 mm) gauge. Newly rebuilt lines will use Standard gauge. The standard gauge Addis Ababa–Djibouti and Mombasa–Nairobi railways were scheduled to begin regular freight and passenger services in 2017.
Lines for iron ore to Kribi in Cameroon are likely to be 1,435 mm (4 ft 8 1⁄2 in) standard gauge with a likely connection to the same port from the 1,000 mm (3 ft 3 3⁄8 in) metre gauge Cameroon system. This line owned by Sundance Resources may be shared with Legend Mining.
Nigeria's railways are mostly 3 ft 6 in (1,067 mm) Cape gauge. The Lagos–Kano Standard Gauge Railway is a gauge conversion project by the Nigerian Government to create a north-south standard gauge rail link. The first converted segment, between Abuja and Kaduna, was completed in July 2016.
2 ft 6 in (762 mm) gauge railways are narrow gauge railways with track gauge of 2 ft 6 in (762 mm). This type of rail was promoted especially in the colonies of the British Empire during the second half of the nineteenth century by Thomas Hall and Everard Calthrop.3 ft gauge railways
Three foot gauge railways have a track gauge of 3 ft (914 mm) or 1 yard. This gauge is a narrow gauge and is generally found throughout North, Central, and South America. In Ireland, many secondary and industrial lines were built to 3 ft gauge, and it is the dominant gauge on the Isle of Man, where it is known as the Manx Standard Gauge. Modern 3 ft gauge railways are most commonly found in isolated mountainous areas, on small islands, or in large-scale amusement parks and theme parks (see table below). This gauge is also popular in model railroading (particularly in G scale), and model prototypes of these railways have been made by several model train brands around the world, such as Accucraft Trains (US), Aristo-Craft Trains (US), Bachmann Industries (Hong Kong), Delton Locomotive Works (US), LGB (Germany), and PIKO (Germany).5 ft 6 in gauge railway
5 ft 6 in / 1,676 mm, a broad gauge, is the track gauge used in India, Pakistan, western Bangladesh, Sri Lanka, Argentina, Chile, and on the BART (Bay Area Rapid Transit) in the San Francisco Bay Area.
In North America, it is called Provincial, Portland, or Texas gauge. In Argentina, it is known as "trocha ancha" (Spanish for broad gauge). In the Indian Subcontinent it is simply known as "broad gauge". Elsewhere it is known as Indian gauge. It is the widest gauge in regular passenger use anywhere in the world.5 ft and 1520 mm gauge railways
Railways with a railway track gauge of 5 ft (1,524 mm) were first constructed in the United Kingdom and the United States. This gauge is also commonly called Russian gauge because this gauge was later chosen as the common track gauge for the Russian Empire and its neighbouring countries. The gauge was redefined by Soviet Railways to be 1,520 mm (4 ft 11 27⁄32 in).The primary region where Russian gauge is used is the former Soviet Union (CIS states, Baltic states, Georgia and Ukraine), Mongolia and Finland, with about 225,000 km (140,000 mi) of track. Russian gauge is the second most common gauge in the world, after 1,435 mm (4 ft 8 1⁄2 in) standard gauge.Bermuda Railway
The Bermuda Railway was a 21.7-mile (34.9 km) common carrier line that operated in Bermuda for a brief period (October 31, 1931 – May 1, 1948). In its 17 years of existence, the railway provided frequent passenger and freight service over its length spanning most of the archipelago from St. George's in the east to Somerset, Sandys Parish, in the west.
Construction and maintenance proved to be exceedingly costly, as the Bermuda Railway was built along a coastal route to minimize the amount of land acquisition needed for the right-of-way. In so doing, however, extensive trestles and bridgework were necessary. More than 10 percent of the line was elevated on 33 separate structures of timber or steel construction spanning the ocean. In addition, the proximity to the ocean made rot and corrosion a significant problem. This, along with the introduction of private automobiles to the island after World War II, would ultimately doom the line.Break of gauge
With railways, a break of gauge occurs where a line of one gauge meets a line of a different gauge: specifically a different track gauge. Trains and rolling stock cannot run through without some form of conversion between gauges, and freight and passengers must otherwise be transshipped. A break of gauge adds delays, cost, and inconvenience.Brighton and Rottingdean Seashore Electric Railway
The Brighton and Rottingdean Seashore Electric Railway was a unique coastline railway in Brighton, England that ran through the shallow coastal waters of the English Channel between 1896 and 1901.Broad-gauge railway
A broad-gauge railway is a railway with a track gauge broader than the 1,435 mm (4 ft 8 1⁄2 in) standard-gauge railways.
Initially introduced in Europe, broad gauge has given way to standard gauge in Europe, United States and Canada. Broad gauge of 1,676 mm (5 ft 6 in), commonly known as Indian Gauge, is the dominant track gauge used in India, Pakistan, Bangladesh, Sri Lanka, Argentina, Chile, and on the BART (Bay Area Rapid Transit) in the San Francisco Bay Area.Minimum-gauge railway
Minimum-gauge railways have a gauge of most commonly 15 in (381 mm), 400 mm (15 3⁄4 in), 16 in (406 mm), 18 in (457 mm), 500 mm (19 3⁄4 in) or 20 in (508 mm). The notion of minimum-gauge railways was originally developed by estate railways and the French company of Decauville for industrial railways, mining, and farming applications.OO gauge
OO gauge or OO scale (also spelled 00 gauge and 00 scale) model railways are the most popular standard-gauge model railway tracks in the United Kingdom. This track gauge is one of several 4 mm-scale standards (4 mm to 1 foot or 1:76.2) used, but it is the only one to be served by the major manufacturers. Despite this, the OO track gauge of 16.5 mm (0.65 in) is inaccurate for 4 mm scale, and other gauges of the same scale have arisen to better serve the desires of some modellers for greater scale accuracy.Standard-gauge railway
A standard-gauge railway is a railway with a track gauge of 1,435 mm (4 ft 8 1⁄2 in). The standard gauge is also called Stephenson gauge after George Stephenson, International gauge, UIC gauge, uniform gauge, normal gauge and European gauge in the European Union and Russia. It is the most widely used railway track gauge across the world, with approximately 55% of the lines in the world using it. All high-speed rail lines use standard gauge except those in Russia, Finland, Portugal and Uzbekistan. The distance between the inside edges of the rails is defined to be 1435 mm except in the United States and on some heritage British lines, where it is still defined in U.S. customary units as exactly "four feet eight and one half inches" (0.1 mm larger than the metric standard).Track gauge conversion
Gauge conversion is the change of one railway track gauge to another. This may be required if loads are too heavy for the existing track gauge or if rail cars are of a broader gauge than the existing track gauge. Gauge conversion may become less important as time passes due to the development of variable gauge systems, also called Automatic Track Gauge Changeover Systems.Track gauge in Europe
Most railways in Europe use the standard gauge of 1,435 mm (4 ft 8 1⁄2 in). Some countries use broad gauge, of which there are three types. Narrow gauges are also in use.Track gauge in Ireland
The track gauge adopted by the mainline railways in Ireland is 5 ft 3 in (1,600 mm). This unusual track gauge is otherwise found only in Australia (where it was introduced by the Irish railway engineer F. W. Sheilds), in the states of Victoria, southern New South Wales (via some extensions of the Victorian rail network) and South Australia, as well as in Brazil.
The Grand Duchy of Baden State Railway used this gauge between 1840 and 1855, as did the Canterbury Provincial Railways in New Zealand, until conversion to the 3 ft 6 in (1,067 mm) gauge in the 1860s. The Launceston and Western Railway in Tasmania also used this gauge from 1871, until conversion to 3 ft 6 in (1,067 mm) gauge in 1888.Track gauge in Italy
Historically, Italy had two unusual dominant track gauges which were legally defined depending on the terrain encountered. The gauge of 1,445 mm (4 ft 8 7⁄8 in) was used for the national Italian rail network and was very similar to the popular 1,435 mm (4 ft 8 1⁄2 in) standard gauge.
Since the 1930s, the 1,435 mm gauge was adopted and gradually replaced the 1,445 mm track gauge.
A few isolated 1,445 mm gauge networks survive to this day.
The other popular gauge, a narrow gauge, was defined at 950 mm (3 ft 1 3⁄8 in) and is very similar to 1,000 mm (3 ft 3 3⁄8 in) commonly used in scenes in Europe or metre gauge and was thus called "Italian metre gauge".Track gauge in North America
The vast majority of North American railroads are standard gauge (4 ft 8 1⁄2 in / 1,435 mm). Exceptions include some streetcar, subway and rapid transit systems, mining and tunneling operations, and some narrow-gauge lines particularly in the west, e.g. the isolated White Pass and Yukon Route system, and the former Newfoundland Railway.
As well as the usual reasons for having one gauge i.e. being able to operate through trains without transfer arrangements, the North American continent-wide system of freight car interchange with rolling stock having the same standard gauge, couplings, and air brakes meant that individual companies could minimise their rolling stock requirements by borrowing from other companies. Peak demand periods varied over the continent, with seasonal requirements e.g. for grain shipments occurring at different times in different areas so that freight cars could be redistributed to cover peaks as required.Track gauge in Slovakia
Rail gauge in Slovakia. The track gauge for most lines in Slovakia is the international standard gauge of 1,435 mm (4 ft 8 1⁄2 in).Track gauge in South America
In South America, Argentina and Chile use 1,676 mm (5 ft 6 in) track gauge, as well as 1,000 mm (3 ft 3 3⁄8 in) or metre gauge.
Brazil uses 1,600 mm (5 ft 3 in) (known as "Irish gauge", most common for passenger services and a few corridors in the Southeast) and 1,000 mm (3 ft 3 3⁄8 in) (known as "narrow gauge" or "metre gauge", most common for cargo services). Exceptions are the Estrada de Ferro do Amapá north of the Amazon River, which has 1,435 mm (4 ft 8 1⁄2 in) gauge, and the new Line 5 of São Paulo Metro, which also uses standard gauge.
Argentina (partly), Venezuela, Paraguay, Uruguay, and Peru use standard gauge. In the past a few lines in Northern Chile also had standard gauge, as the only international railway between Arica (Chile) and Tacna (Peru), slightly more than 60 km, uses standard gauge. The El Cerrejón Coal Railway in Colombia is also 1,435 mm (4 ft 8 1⁄2 in).
There are and were also some lines using different narrow gauges; see the "narrow gauge" section in this list.Variable gauge
A variable gauge system allows railway vehicles in a train to travel across a break of gauge caused by two railway networks with differing track gauges.
For through-operation, a train must be equipped with special bogies holding variable gauge wheelsets containing a variable gauge axle (VGA). The gauge is altered by driving the train through a gauge changer or gauge changing facility. In effect, the track widens or narrows.
As the train passes through the gauge changer, the wheels are unlocked, moved closer together, or further apart, and are then re-locked. Installed variable gauge systems exist within the internal network of Spain, and are installed on international links between Spain/France (Spanish train), Sweden/Finland (Swedish train), Poland/Lithuania (Polish train) and Poland/Ukraine (Polish train).
A system for changing gauge, without need for stopping is widespread for passenger traffic in Spain, used in services run on a mix of dedicated high-speed lines (using Standard gauge) and older lines (using Iberian gauge). Similar systems for freight traffic are still rather incipient, as the higher axle weight increases the technological challenge. Although several alternatives exist, including transferring freight, replacing individual wheels and axles, truck exchange, transporter flatcars or the simple transshipment of freight or passengers, they are impractical, thus a cheap and fast system for changing gauge would be beneficial for cross-border freight traffic.Alternative names include Gauge Adjustable Wheelsets (GAW), Automatic Track Gauge Changeover System (ATGCS/TGCS), Rolling Stock Re-Gauging System (RSRS), Rail Gauge Adjustment System (RGAS), Shifting wheelset, Variable Gauge Rolling Truck, track gauge change and track change wheelset.
Track gauge (list)
Railway track layouts