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(Redirected from Variable gauge axles) System used by trains to cross a break of gauge
Track gauge
By transport mode
By size (list)
Graphic list of track gauges

  Minimum
  Fifteen inch 381 mm (15 in)

  Narrow
  600 mm 600 mm (1 ft 11+5⁄8 in)
Two foot 610 mm (2 ft)
Two foot three inch 686 mm (2 ft 3 in)
  750 mm 750 mm (2 ft 5+1⁄2 in)
Bosnian gauge 760 mm (2 ft 5+15⁄16 in)
Two foot six inch 762 mm (2 ft 6 in)
  Swedish three foot 891 mm (2 ft 11+3⁄32 in)
900 mm 900 mm (2 ft 11+7⁄16 in)
Three foot 914 mm (3 ft)
Italian metre 950 mm (3 ft1+13⁄32 in)
  Metre 1,000 mm (3 ft 3+3⁄8 in)
  Three foot six inch 1,067 mm (3 ft 6 in)
  Four foot 1,219 mm (4 ft)
  Four foot six inch 1,372 mm (4 ft 6 in)
  1432 mm 1,432 mm (4 ft 8+3⁄8 in)

  Standard 1,435 mm (4 ft 8+1⁄2 in)

  Broad
  Italian broad gauge 1,445 mm (4 ft 8+7⁄8 in)
Dresden gauge 1,450 mm (4 ft 9+3⁄32 in)
  Leipzig gauge 1,458 mm (4 ft 9+13⁄32 in)
  Toronto gauge 1,495 mm (4 ft 10+7⁄8 in)
  1520 mm 1,520 mm (4 ft 11+27⁄32 in)
Five foot 1,524 mm (5 ft)
  Pennsylvania gauge 1,581 mm (5 ft 2+1⁄4 in)
Pennsylvania gauge 1,588 mm (5 ft 2+1⁄2 in)
Five foot three inch 1,600 mm (5 ft 3 in)
  Baltimore gauge 1,638 mm (5 ft 4+1⁄2 in)
  Iberian gauge 1,668 mm (5 ft 5+21⁄32 in)
Five foot six inch 1,676 mm (5 ft 6 in)
  Six foot 1,829 mm (6 ft)
  Brunel 2,140 mm (7 ft 1⁄4 in)
  Breitspurbahn 3,000 mm (9 ft 101⁄8 in)
Change of gauge
By location
World map, rail gauge by region
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Variable gauge systems allow railway vehicles to travel between two railways with different track gauges. Vehicles are equipped with variable gauge axles (VGA). The gauge is altered by driving the train through a gauge changer installed at the break of gauge which moves the wheels to the gauge desired.

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 the need to stop is in widespread use for passenger traffic in Spain, for 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 in their infancy, as the higher axle weight increases the technological challenge. Although several alternatives exist, including transferring freight, replacing individual wheels and axles, bogie 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 Systems (ATGCS/AGCS), Rolling Stock Re-Gauging System (RSRS), Rail Gauge Adjustment System (RGAS), Shifting wheelset, Variable Gauge Rolling Truck, track gauge change and track change wheelset.

Overview

Variable gauge axles help solve the problem of a break-of-gauge without having to resort to dual gauge tracks or transshipment. Systems allow the adjustment between two gauges. No gauge changer designs supporting more than two gauges are used.

Systems

Variable gauge axle DR III for 1,435 mm (4 ft 8+1⁄2 in) and 1,524 mm (5 ft) gauge, developed in 1957

There are several variable gauge axle systems:

Compatibility

The variable gauge systems are not themselves all compatible. The SUW 2000 and Rafil Type V systems are interoperable, as are TALGO-RD and CAF-BRAVA.

In 2009, at Roda de Barà near Tarragona, a Unichanger capable of handling four different VGA systems was under development.

International traffic

VGA is particularly important with international railway traffic because gauge changes tend to occur more often at international borders.

Features

Different systems have different limitations, for example, some can be used on carriages and wagons only and are unsuitable for motive power, while others require that rolling stock is unloaded before going through the gauge changer. When one of the gauges is narrow there may not be enough space between the wheels for the Brakes, Gauge Changer and the Traction Motors.

Country Spain Poland Germany Japan Switzerland
System(s) TALGO CAF SUW 2000 Rafil V RTRI Stadler
+ Prose
Railways for which suitable .es .eu .es .eu .eu .ua .de .ru .jp .ch
MOB
Passenger carriages Green tickY Green tickY Green tickY Red XN Green tickY Green tickY
Goods wagons Green tickY Red XN Green tickY Green tickY Red XN Red XN
Motive power
(driven axles)
Green tickY Green tickY Red XN Red XN Green tickY Red XN
Under load
(change with load on wheels)
Red XN Red XN Green tickY Green tickY Red XN Red XN
Standard Gauge/Broader Gauge
Green tickY Green tickY Green tickY Green tickY Red XN Red XN
Standard Gauge/Narrower Gauge
Red XN Red XN Red XN Red XN Green tickY Green tickY
Maximum speed

The maximum speed of the trains equipped with the different technologies varies. Only CAF and Talgo produce high-speed VGA, allowing speeds up to 330 km/h.

Speed changing

The Talgo RD GC changes gauge at a speed of 15 kilometres per hour (9.3 mph; 4.2 m/s) so a 100 m (328 ft) train takes only 24 seconds to convert.

Gauge changer

A Talgo gauge changing system in Lleida, Spain

A gauge changer is a device which forces the gauge adjustment in the wheels. Designs consist of a pair of running rails that gradually vary in width between the two gauges, combined with other rails and levers to perform the following steps, using Talgo RD as an example:

  1. Verify that all vehicles in train are suitable for Gauge Change.
  2. Support on – takes weight off lock and on the guide rails.
  3. Unlock.
  4. Move wheels to new position.
  5. Relock.
  6. Support off – put weight back on lock from the guide rails.
  7. Verify correct operation and generate statistics. Use ECPB power and supervisory cables.

In the Spanish Talgo-RD system, a constant spray of water is used to lubricate the metal surfaces, to reduce heat and wear. A Talgo RD gauge changer is 20 m (65 ft 7 in) long and 6 m (19 ft 8 in) wide.

Limitations

At present the choice of gauge is limited to two out of three of 1,435 mm (4 ft 8+1⁄2 in) and broad gauges 1,520 mm (4 ft 11+27⁄32 in) and 1,676 mm (5 ft 6 in). With narrow gauges such as 1,000 mm (3 ft 3+3⁄8 in) as found at Zweisimmen, Switzerland, there is less room between the wheels for the gauge change mechanism, the traction motors, and the brakes. The diameter of the wheels also limits the axleload to no more than 22.5 tonnes.

Operation

A variable gauge multiple unit, or a train including a variable gauge locomotive (e.g. Talgo 250) and rolling stock, may drive straight across a gauge changer. Normally the locomotive will not be able to change gauge, meaning that it must move out of the way whilst the remainder of the train itself passes through. On the opposite side, a new locomotive of the other gauge will couple to the train.

A Talgo train with a locomotive can drive across a gauge change at 1 axle per second at a speed of about 10–15 km/h (6.2–9.3 mph).

A train (or an individual car) can be pushed halfway across the gauge-changer, uncoupled, and then (once far enough across) coupled to the new locomotive and pulled the rest of the way. A long length of wire-rope with hooks on the end means that the process can be asynchronous, with the rope used to bridge across the length of the gauge changer (to temporarily couple the arriving cars and receiving locomotive, although without braking control from the locomotive to the train vehicles).

On long-distance trains in Spain and night trains crossing from Spain into France, the arriving locomotive stops just short of the gauge changer, uncouples and moves into a short siding out of the way. Gravity then moves the train through the gauge changer at a controlled low speed. The new locomotive is coupled onto the front only after the full train has finished passing through the changer.

From 2014 gauge changing systems for freight wagons were being developed.

Countries

Australia

In 1933, as many as 140 inventions were offered to Australia railways to overcome the breaks of gauge between the different states. None was accepted. About 20 of these devices were adjustable wheels/axles of some kind or another, which may be analogous to the modern VGA. VGA systems were mostly intended for Broad Gauge and Standard Gauge lines.

Break of Gauge stations were installed at Port Pirie, Peterborough and Albury; these were fairly manual in operation. The newest installation was at Dry Creek and was of a more automatic design. The Talgo RD design is even more automatic and efficient.

Belarus/Poland

A Talgo gauge changing facility is installed at Brest near the Belarusian-Polish border. It is used by Russian Railways' fast trains connecting Moscow and Berlin.

Orders for 7 Talgo VGA trainsets placed were placed in 2011. The trains under the brand "Strizh" are in service since 2016.

Canada

Variable gauge axles were used for a while on the Grand Trunk Railway in the 1860s in Canada to connect 5 ft 6 in (1,676 mm) and 4 ft 8+1⁄2 in (1,435 mm) standard gauge without transshipment. Five hundred vehicles were fitted with "adjustable gauge trucks" but following heavy day-in, day-out use the system proved unsatisfactory, particularly in cold and snowy weather. The system used telescoping axles with wide hubs that allowed the wheels to be squeezed or stretched apart through a gauge-changer, after holding pins had been manually released.

Railway operations over the Niagara Bridge were also complicated.

Finland/Sweden

In 1999, a gauge-changer was installed at Tornio at the Finnish end of the dual-gauge section between Haparanda and Tornio, for use with variable gauge freight wagons. The Tornio gauge changer is a Rafil design from Germany; a similar Talgo-RD gauge changer at the Haparanda end used to exist, but was removed as it required de-icing in winter.

Train ferry traffic operated by SeaRail and arriving from Germany and Sweden by sea used bogie exchange facilities in the Port of Turku.

Georgia

A new gauge changer has been put in place in Akhalkalaki for Baku-Tbilisi-Kars railway. Northwestern end has rails 1,435 mm (4 ft 8+1⁄2 in) apart, southeastern end has rails 1,520 mm (4 ft 11+27⁄32 in) apart. Both bogie exchange and variable gauge adapters are provided.

Japan

The Japanese third-generation GCT "Gauge Change Train" EMU on a test run in November 2014
Main article: Gauge Change Train

The "Gauge Change Train" is a project started in Japan in the 1990s to investigate the feasibility of producing an electric multiple unit (EMU) train capable of operating both the 1,435 mm (4 ft 8+1⁄2 in) Shinkansen high-speed network at 270–300 km/h (168–186 mph) and the original 1,067 mm (3 ft 6 in) network at 130–140 km/h (81–87 mph). See U.S. patent 5,816,170.

The first-generation train was tested from 1998 to 2006, including on the US High-speed Test Track in 2002. The second-generation train, intended to run at a maximum speed of 270 km/h (168 mph), was test-run in various locations in Japan between 2006 and 2013. A third-generation train has been undergoing reliability trials since 2014 in preparation for potential introduction to service on the planned Kyushu Shinkansen extension to Nagasaki.

Gallery

  • The first-generation "Gauge Change Train" EMU in May 2003 The first-generation "Gauge Change Train" EMU in May 2003
  • The second-generation "Gauge Change Train" EMU in September 2012 The second-generation "Gauge Change Train" EMU in September 2012

Lithuania/Poland

A gauge changing facility of the Polish SUW 2000 system is installed at Mockava north of the Lithuanian-Polish border. VGA passenger trains between Lithuania and Poland were running between October 1999 and May 2005, and VGA goods trains between early 2000s and 2009.

Poland/Ukraine

There are two gauge changing facilities of the Polish SUW 2000 system installed on the Polish-Ukrainian border, one of them in Dorohusk (Poland) on the Warsaw-Kiyv line, another in Mostyska (Ukraine) on the Kraków-Lviv line. On 14 December 2003 VGA passenger trains were introduced between Kraków (Poland) and Lviv (Ukraine) instead of bogie exchange. VGA saves about 3 hours compared to bogie exchange. The trains last ran in 2016.

Spain

Spain is the largest user of variable gauge systems. This is because of the need to connect older mainlines built to Iberian gauge and extensive new high-speed railway lines and connections to France, using the standard gauge. Two gauge changes are installed on lines to France and at all entrances/exits leading between the high-speed network and older lines. There are also significant lengths of 1,000 mm (3 ft 3+3⁄8 in) secondary lines but these are not connected to the main network.

In February 2004, RENFE placed orders for:

  • Forty-five CAF/Alstom 25 kV AC/3 kV DC, variable gauge EMUs for 250 km/h regional services, between October 2006 and May 2009 (€580 million)
  • Twenty-six 25 kV AC variable gauge trains for 250 km/h (155 mph) long-distance services using two Bombardier power cars and Talgo Series VII trailer cars (€370 million) Gauges involved are 1,435 mm (4 ft 8+1⁄2 in) and 1,668 mm (5 ft 5+21⁄32 in).
  • Olmedo to Medina del Campo in Valladolid, Spanish test track.
  • November 2008 – High Speed trainset for Cadiz to Warsaw.
  • July 2009 – Talgo 250 supplied with Voith Turbo SZH-692 gauge change final drives.

There is also a 14.4 km (8.95 mi) circular test track in Spain.

Switzerland

See also: GoldenPass Express
MOB gauge changing system at Zweisimmen

Variable gauge bogies are implemented on the Montreux–Gstaad–Zweisimmen–Spiez–Interlaken line. Trains automatically switch from 1,000 mm (3 ft 3+3⁄8 in) to 1,435 mm (4 ft 8+1⁄2 in) at Zweisimmen. The bogie has no axles, which allow the bogie half frames holding the wheels on both sides to slide sideways relative to each other. The EV09-Prose gauge changer at Zweisimmen was satisfactorily tested on 19 June 2019. The system, designed to allow operation on both Montreux Oberland Bernois Railway's (MOB) 1000mm gauge line and BLS AG 1435mm gauge infrastructure, was first implemented on 11 December 2022. Moreover, while the gauge is being automatically changed at Zweisimmen, the air spring mounted on the bogie cross member is automatically adjusted by 200 mm to match the body height with the platform height on the MOB or BLS AG portion of the GoldenPass Express.

United Kingdom

John Fowler mentions in 1886 at attempt by the GWR to develop a "telescopical" axle.

Trams ran between Leeds (4 ft 8+1⁄2 in or 1,435 mm standard gauge) and Bradford (4 ft or 1,219 mm gauge) following a successful trial in 1906 using Bradford tram car number 124. The system was later patented by – GB190601695 (A) of 1906. This system was improved again in patent GB190919655 (A) of 1909 by introducing a locking system acting on the wheel and axle rather than just the wheel rim. This provided a more effective grip where the wheel was free to move along the splined axle.

Comparison with bogie exchange

Time taken

In VGA, the train is pulled through the "adjuster" at about 15 km/h (9.3 mph) without any need to uncouple the wagons or disconnect (and test) the brake equipment. Alternatively, as the train need not be uncoupled, the locomotive may pull the coupled carriages all together.

See Talgo Gauge Changer.

Locomotives

Steam locomotive are generally not gauge convertible on-the-fly. While diesel locomotives can be bogie exchanged, this is not normally done owing to the complexity in the reconnection of cables and hoses. In Australia, some locomotives are transferred between gauges. The transfer might happen every few months, but not for an individual trip.

By 2004, variable gauge electric passenger locomotives were available from Talgo. It is not clear if variable gauge freight locomotives are available.

Electric

  • L-9202 is an experimental high speed Bo-Bo dual voltage (3 kV DC/25 kV AC) VGA locomotive.
  • Talgo 250 locomotives were also planned to haul dual-voltage variable-gauge trainsets from Montpellier 200 km (124 mi) from the border to Barcelona and Madrid. Two Talgo 250 power cars haul 11 passenger trailer cars.
  • EMU

Weight

  • A gauge adjustable bogie complete with wheelsets weighs a total of about one ton/tonne more than a conventional bogie and normally must use disc brakes, which cool more slowly.

History

  • 1915. C. W. Prosser. – Argus
  • 1921. C. R. Prosser. – Argus Friday 8 July 1921
  • 1922. J. Grieve. – Argus 19 July 1922

See also

References

  1. "New generation of gauge changeover Facilities: The UNICHANGER Project" (PDF). Retrieved 30 March 2017.
  2. "Avant Serie 121". Retrieved 30 March 2017.
  3. "Frictions On The New Silk Road – Analysis". 26 January 2017. Retrieved 30 March 2017.
  4. Tieri, Roberto; Cavicchi, Paolo; Kinderis, Vytautas (2016). "Implementation of Automatic Gauge Changeover Systems: available technical solutions, cost effectiveness and standardisation. (AGCS)". railknowledgebank.com. UIC. Retrieved 19 September 2024. For this purpose a survey has been conducted of the various AGCS solutions available (chapters 2, 3 and 4), the potential market share (chapter 5) and the cost-effectiveness of the system (chapter 6).
  5. Chudzikiewicz, Andrzej (2007). "Shifting Wheelset". Machine Dynamics Problems. 31 (2): 46–56.
  6. "The Variable Gauge Rolling Truck". Archived from the original on March 10, 2007. Retrieved February 18, 2016.
  7. "Operational Requirements". Development of the Trans-Asian Railway: Trans-Asian Railway in the North-south Corridor, Northern Europe to the Persian Gulf. 2001. pp. 49–58. ISBN 978-92-1-120099-7. Archived from the original (PDF) on 2014-02-03. Retrieved 2014-02-01.
  8. ^ Kanclerz, Miroslaw (9 October 2007). "Study on European Automatic Track Gauge Changeover Systems (ATGCS)" (PDF). Gdańsk: UIC. Retrieved 7 December 2008. Variable gauge systems: SUW 2000, Poland; DBAG/Rafil Type V, Germany; CAF BRAVA, Spain; Talgo RD, Spain; Japan RTRI; Korea KRRI DB Rafil Type V and PKP SUW 2000 are technically compatible and thereby 'interoperable'
  9. "Talgo Variable Gauge". Archived from the original on 2 June 2013. Retrieved 27 July 2013.
  10. Álvarez 2010, pp. 31–34.
  11. "New Swift international train makes first journey with passengers from Moscow to Berlin". rzd.ru. Russian Railways. Retrieved 31 March 2017.
  12. GC Freight
  13. Talgo RD video
  14. BRAVA Archived February 4, 2012, at the Wayback Machine
  15. "HIGH-SPEED TRAIN ATPRD s-120". Archived from the original on May 22, 2006. Retrieved February 18, 2016.
  16. "ÉCARTEMENTS VARIABLES: 'L' "ESSIEU MIRACLE" EST-IL NÉ DANS LE CANTON DE VAUD?". La Vie du Rail, No. 1415, 4 November 1973 (in French).
  17. "webvdr.com". Archived from the original on 25 March 2006.
  18. Jane's World Railways 2002–2003 p165.
  19. Variable-Gauge Wagon Wheelsets | International Railway Journal
  20. Schwartze, Matthias. "Gauge change system could help ease movement between countries". Rail International/Live Engineer. Archived from the original on 10 October 2008. Retrieved 17 September 2008. The DB AG/Rafil Type V change gauge wheel set consists of a wheel set shaft and two axially displaceable solid wheels, which are joined to the shaft by a locking system. The solid wheel has been derived from the well-proved solid wheel of the 004 type of DB AG.
  21. Gasanov, Isolde; Hoffmann, Hans-Karsten (2007). "Automatische Spurwechseltechnik für Güterwagen: Derzeit wird der Warenaustausch auf der Schiene durch die in Europa vorhandenen unterschiedlichen Spurweiten stark beeinträchtigt" [Automated gauge-change system for freight wagons]. Eisenbahntechnische Rundschau (in German). 6: 318–26. INIST 18819553.
  22. Science Links Japan | Development of Variable Gauge Bogie Archived February 6, 2012, at the Wayback Machine
  23. "Science Links Japan | Development of Traction Motor for Adjustable Gauge Train". Sciencelinks.jp. 18 March 2009. Archived from the original on 17 February 2012. Retrieved 20 August 2013.
  24. "Archived copy". Archived from the original on 2011-07-10. Retrieved 2008-11-25.{{cite web}}: CS1 maint: archived copy as title (link) CS1 maint: bot: original URL status unknown (link)
  25. "INA ELGOGLIDE ® Plain Bushes in SUW 2000 Gauge Changeover Systems from ZNTK Poznán S.A." (PDF). Retrieved November 25, 2008.
  26. Railway Gazette International December 2008 p 944
  27. "Maintenance and service - PROSE". prose.ch. Archived from the original on 10 February 2009.
  28. Gyr, Christoph (13 February 2023). "Split-frame bogies overcome the break of gauge". International Railway Journal. Retrieved 4 March 2023. For the bogie, compatibility with the two track gauges is ensured by moving sideways the bogie halves with the wheels mounted on them, and by raising the air spring mounted on the bogie cross member from the low to high platform height. At the end of 2008 Prose began work to develop a prototype bogie based on MOB's concepts, while the two companies worked together on a protype gauge-changing facility.
  29. ^ Trippi, Peider; Arnet, Roland (11 December 2022). "From MOB to BLS: The GoldenPass Express variable gauge explained" (PDF). Retrieved 9 September 2024.
  30. Álvarez 2010, p. 14.
  31. Railway Gazette International July 2009, p 20
  32. Álvarez 2010, p. 13.
  33. Talgo RD Gauge Change video
  34. Gauge Change
  35. Talgo GC in action.
  36. Gauge Change freight
  37. "BREAK OF GAUGE". The Brisbane Courier. Qld.: National Library of Australia. 14 August 1933. p. 15. Retrieved 4 February 2011.
  38. "04 Sep 1918 – BREAK OF GAUGE PROBLEM REPORT OF BOARD OF EXPERT". Trove.nla.gov.au. Retrieved 20 August 2013.
  39. DVV Media Group GmbH. "Gauge-changing trains ordered for Moscow – Berlin". Railway Gazette. Retrieved 20 August 2013.
  40. "Introduction". Niagara Rails. Archived from the original on 26 August 2013. Retrieved 17 September 2008. two mechanical solutions were tried: the GWR used a dual gauge system requiring a third rail, and the GTR used adjustable gauge trucks. However neither method proved satisfactory, and full conversion to standard gauge became necessary
  41. "Break of Gauge at Prescott Junction". Bytown Railway Society, Branchline, June 2003. Colin Churcher's railway pages. June 2003. Archived from the original on 7 August 2008. Retrieved 3 September 2008. The scheme selected was patented by C.D. Tisdale of East Boston, Massachusetts, with the first patent having been issued in March 1863. Special wheels with extra-large hubs were fitted with key wedges. The axles were notched so that the wheels could be set at standard or 5 -foot 6-inch gauge. The keys were locked in place by a long safety pin and giant rubber bands. The position of the wheel was shifted by a gradually diverging or converging track. In the shift from broad to standard, the keys would be loosened and removed at one end of the tapering track, workmen in a 4-foot-deep pit removed the keys from below the train. A long shed was built over the pits to protect the workmen. With the keys out, the train was slowly pushed down the track, and the wheels-would be forced inward as the train moved along the converging rails. Once at the end, the workers would reinsert and lock the wedges and the train could go on its way. The change could be done in five to ten minutes. When shifting to broad gauge, a third rail set inside the tapering track pushed the wheel out to the wider gauge. Shifting stations were located at Pointe-Saint-Charles, Montreal, and Sarnia, Ontario. The plan was first tried in November 1863, yet no serious consideration was given to it until early 1868. The tests proved so promising that by late in the following year two hundred adjustable-gauge cars were running between Chicago and Boston via the Michigan Central, the Grand Trunk, the Vermont Central, and several connecting lines in New England. The problems of the northern east-west route seemed to have been resolved, and three hundred more cars were ordered by National Despatch. his disruptive and costly conversion might have been avoided had the variable-gauge trucks worked as well as advertised. Problems obviously had developed. The keyway grooves were said to weaken the axles. Misgivings over the safety of the telescoping axles were voiced as early as 1846, long before the Grand Trunk test. Considerable skepticism was expressed as to the reliability of the workmen charged with loosening and tightening so many wheels day in and day out.
  42. "Break of Gauge at Prescott Junction". Railways.incanada.net. Archived from the original on 7 August 2008. Retrieved 20 August 2013.
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  44. "VR Annual Report 1998" (PDF). VR Group. 1998. p. 12. Retrieved 17 September 2008. Traffic between Tornio and Haaparanta continued to decline slightly. Measures were taken to boost the volume on this line by speeding up border crossing formalities. Development of a new track gauge changing machine made further progress and testing will be started in Tornio in the early spring of 1999. This machine will raise traffic volumes between Finland and Scandinavia.
  45. Thorsten Büker (December 2004). "border lines Sweden – Finland". Retrieved 17 September 2008. In 2002 through workings by suitable wagons had been involved in cooperation of Finnish VR, Green Cargo and Nordwaggon. A Gauge-changer of German design "Rafil" was installed at Tornia ; a Talgo-type gauge changer at Haparanda. This one was already taken out of use.
  46. Lars-Åke Josefsson (15 March 2007). "A bridge between differences in infrastructure" (PDF). Automatic track gauge technique. Banverket (Swedish National Rail Administration). pp. 14, 18. Archived from the original (PDF) on 21 July 2011. Retrieved 17 September 2008. Trials with systems with automatic track gauge change technique have been going on at the border between Sweden and Finland since 1997 during severe winter conditions. Two different systems, the Spanish Talgo system and the German Rafil system, have been tested. We have decided to go on with the Rafil system. 14 bogies has been bought. Commercial traffic has been going on since October 2005.
  47. Kasai, Kenichi; Tsujino, Shodo; Uruga, Kenichi (2000). "Gauge Change Train. Development of Monitor System of Gauge Change Train". RTRI Report. 14 (10): 47–52. Archived from the original on 11 October 2008.
  48. Oda, Kazuhiro; Ohtsuyama, Sumiaki; Kobayashi, Hideyuki; Kawano, Ichiro; Mimura, Yuichi (2003). "Developing a Gauge-Changing EMU". Quarterly Report of RTRI. 44 (3): 99–102. doi:10.2219/rtriqr.44.99. Retrieved November 30, 2008.
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  53. "新形フリーゲージトレイン" [New Gauge-changing Train]. Japan Railfan Magazine. Vol. 47, no. 556. Japan: Koyusha Co., Ltd. August 2007. pp. 86–87.
  54. "East - intercity.pl". Archived from the original on 13 May 2014. Retrieved 13 June 2014.
  55. Kasper Fiszer (31 December 2018). "Polska – Ukraina: Kolejny rok bez SUW 2000" [Poland – Ukraine: Another year without SUW 2000]. Rynek Kolejowy (in Polish).
  56. "GIF develops dual-gauge track". International Railway Journal. March 2002. Archived from the original on 11 October 2008. Retrieved 7 December 2008. A new test track, which opened in December 2001, is being used to help develop and test the dual-gauge concept. The 14.4 km track between Olmedo and Medina del Campo in Valladolid province, includes 10 km of tangent track (part of the old Segovia-Medina line, which has been out of service since 1993), a gauge-changing facility, workshops, and a technical building for the interlocking. ... The test track is not yet electrified, so initial tests, which started in January, were conducted using a Talgo XXI diesel train. Tests include running through turnouts and crossings at a maximum of 242 km/h on plain track and 110 km/h on deviations.
  57. ^ Railway Gazette International November 2008, p. 881
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  59. "Factsheets - PROSE". prose.ch. Archived from the original on 2012-02-04. Retrieved 2012-02-17.
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Further reading

External links

Track gauge (list)
Minimum-gauge
Minimum-gauge railways
Narrow gauge
Standard gauge
Broad gauge
List of track gauge articles
Gauge differences
Transport mode
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