SCMaglev
The SCMaglev (superconducting maglev) (formerly called the MLU) is a magnetic levitation (maglev) railway system based on the principle of magnetic repulsion between the track and the cars. The Central Japan Railway Company (JR Central) and the company's Railway Technical Research Institute developed the system.[1][2][3]
On 21 April 2015, a manned seven-car L0 series SCMaglev train reached a speed of 603 km/h (375 mph), less than a week after the same train clocked 590 km/h (370 mph), breaking the previous land speed record for rail vehicles of 581 km/h (361 mph) set by a JR Central MLX01 maglev train in December 2003.[4]
Technology
The SCMaglev system uses an electrodynamic suspension (EDS) system. Installed in the trains' bogies are superconducting magnets, and the guideways contain two sets of metal coils.
The current levitation system utilizes a series of coils wound into a "figure 8" along both walls of the guideway. These coils are also cross-connected underneath the track.[3]
Levitation system |
Guidance system |
Propulsion system |
As the train accelerates, the magnetic fields of its superconducting magnets induce a current into these coils due to the magnetic field induction effect. If the train were centered with the coils, the electrical potential would be balanced and no currents would be induced. However, as the train runs on rubber wheels at relatively low speeds, the magnetic fields are positioned below the center of the coils, causing the electrical potential to no longer be balanced. This creates a reactive magnetic field opposing the superconducting magnet's pole (in accordance with Lenz's law), and a pole above that attracts it. Once the train reaches 150 km/h (93 mph), there is sufficient current flowing to lift the train 100 mm (4 in) above the guideway.[3]
These coils also generate guiding and stabilizing forces. Because they are cross-connected underneath the guideway, if the train moves off-center, currents are induced into the connections that correct its positioning.[3]
SCMaglev also utilizes a linear synchronous motor (LSM) propulsion system, which powers a second set of coils in the guideway.
History
Japanese National Railways (JNR) began research on a linear propulsion railway system in 1962 with the goal of developing a train that could travel between Tokyo and Osaka in one hour. Shortly after Brookhaven National Laboratory patented superconducting magnetic levitation technology in the United States in 1969, JNR announced development of the its own superconducting maglev (SCMaglev) system. The railway made its first successful SCMaglev run on a short track at its Railway Technical Research Institute in 1972.[5]
Miyazaki test track
In 1977, SCMaglev testing moved to a new 7 km test track in Hyūga, Miyazaki. By 1980, the track was modified from a "reverse-T" shape to the "U" shape used today. In April 1987, JNR was privatized, and Central Japan Railway Company (JR Central) took over SCMaglev development.
In 1989, JR Central decided to build a better testing facility with tunnels, steeper gradients, and curves.[5] After the company moved maglev tests to the new facility, the company's Railway Technical Research Institute began to allow testing of ground effect trains, an alternate technology based on aerodynamic interaction between the train and the ground, at the Miyazaki Test Track in 1999.[citation needed]
Yamanashi maglev test line
Construction of the Yamanashi maglev test line began in 1990. The 18.4 km (11.4 mi) "priority section" of the line in Tsuru, Yamanashi, opened in 1997. MLX01 trains were tested there from 1997 to fall 2011, when the facility was closed to extend the line to 42.8 km (26.6 mi) and to upgrade it to commercial specifications.[6]
Commercial use
Japan
In 2009, Japan's Ministry of Land, Infrastructure, Transport and Tourism decided that the SCMaglev system was ready for commercial operation. In 2011, the ministry gave JR Central permission to operate the SCMaglev system on their planned Chūō Shinkansen linking Tokyo and Nagoya by 2027, and to Osaka by 2045. Environmental impact assessments are currently underway.[6]
USA
Since 2010, JR Central has promoted the SCMaglev system in international markets, particularly the Northeast Corridor of the United States.[1] In 2013, Prime Minister Shinzō Abe met with U.S. President Barack Obama and offered to provide the first portion of the SC Maglev track free, a distance of approximately 40 miles.[7]
Australia
In late 2015, JR Central partnered with Mitsui and General Electric in Australia to form a joint venture named CLARA ("Consolidated Land and Rail Australia") to provide a commercial funding model using private investors that could build the SC Maglev (linking Sydney, Canberra and Melbourne), create 8 new self-sustaining inland cities linked to the high speed connection, and contribute to the community.[8][9]
Vehicles
- 1972 – LSM200
- 1972 – ML100
- 1975 – ML100A
- 1977 – ML500
- 1979 – ML500R (remodeled ML500)
- 1980 – MLU001
- 1987 – MLU002
- 1993 – MLU002N
- 1995 – MLX01 (MLX01-1, 11, 2)
- 1997 – MLX01 (MLX01-3, 21, 12, 4)
- 2002 – MLX01 (MLX01-901, 22)
- 2009 – MLX01 (MLX01-901A, 22A: remodeled 901 and 22)
- 2013 – L0 Series Shinkansen
No. | Type | Note | Built |
---|---|---|---|
MLX01-1 | Kōfu-end car with double-cusp head | Displayed at the SCMaglev and Railway Park | 1995 |
MLX01-11 | Standard intermediate car | ||
MLX01-2 | Tokyo-end car with aero-wedge head | ||
MLX01-3 | Kōfu-end car with aero-wedge head | Displayed at the Railway Technical Research Institute | 1997 |
MLX01-21 | Long intermediate car | ||
MLX01-12 | Standard intermediate car | ||
MLX01-4 | Tokyo-end car with double-cusp head | ||
MLX01-901A | Kōfu-end car with long head | Remodeled and renamed from MLX01-901 in 2009 | 2002 |
MLX01-22A | long intermediate car | Remodeled and renamed from MLX01-22 in 2009 |
Records
Manned records
Speed [km/h (mph)] | Train | Type | Location | Date | Comments |
---|---|---|---|---|---|
60 (37) | ML100 | Maglev | RTRI of JNR | 1972 | |
400.8 (249.0) | MLU001 | Maglev | Miyazaki Maglev Test Track | February 1987 | Two-car train set. Former world speed record for maglev trains. |
394.3 (245.0) | MLU002 | Maglev | Miyazaki Maglev Test Track | November 1989 | Single-car |
411 (255) | MLU002N | Maglev | Miyazaki Maglev Test Track | February 1995 | Single-car |
531 (330) | MLX01 | Maglev | Yamanashi Maglev Test Line, Japan | 12 December 1997 | Three-car train set. Former world speed record for maglev trains. |
552 (343) | MLX01 | Maglev | Yamanashi Maglev Test Line | 14 April 1999 | Five-car train set. Former world speed record for maglev trains. |
581 (361) | MLX01 | Maglev | Yamanashi Maglev Test Line | 2 December 2003 | Three-car train set. Former world speed record for all trains. |
590 (367) | L0 series | Maglev | Yamanashi Maglev Test Line | 16 April 2015 | Seven-car train set.[10] Former world speed record for all trains. |
603 (375) | L0 series | Maglev | Yamanashi Maglev Test Line | 21 April 2015 | Seven-car train set. Current world speed record for all trains.[4] |
Unmanned records
Speed [km/h (mph)] | Train | Type | Location | Date | Comments |
---|---|---|---|---|---|
504 (313.2) | ML-500 | Maglev | Miyazaki Maglev Test Track | 12 December 1979 | |
517 (321.2) | ML-500 | Maglev | Miyazaki Maglev Test Track | 21 December 1979 | |
352.4 (219.0) | MLU001 | Maglev | Miyazaki Maglev Test Track | January 1986 | Three-car train set |
405.3 (251.8) | MLU001 | Maglev | Miyazaki Maglev Test Track | January 1987 | Two-car train set |
431 (267.8) | MLU002N | Maglev | Miyazaki Maglev Test Track | February 1994 | Single-car |
550 (341.8) | MLX01 | Maglev | Yamanashi Maglev Test Line | 24 December 1997 | Three-car train set |
548 (340.5) | MLX01 | Maglev | Yamanashi Maglev Test Line | 18 March 1999 | Five-car train set |
Relative passing speed records
Speed [km/h (mph)] | Train | Type | Location | Date | Comments |
---|---|---|---|---|---|
966 (600) | MLX01 | Maglev | Yamanashi Maglev Test Line | December 1998 | Former world relative passing speed record |
1,003 (623) | MLX01 | Maglev | Yamanashi Maglev Test Line | November 1999 | Former world relative passing speed record |
1,026 (638) | MLX01 | Maglev | Yamanashi Maglev Test Line | 16 November 2004 | Current world relative passing speed record |
See also
- MAGLEV 2000
- Transrapid
- Krauss-Maffei Transurban - Electromagnetic suspension technology had been transferred from Krauss-Maffei.
- ROMAG
- Inductrack
References
- Hood, Christopher P. (2006). Shinkansen – From Bullet Train to Symbol of Modern Japan. Routledge. ISBN 0-415-32052-6.
- ^ a b Central Japan Railway Company (11 May 2010). Test Ride of Superconducting Maglev by the US Secretary of Transportation, Mr. Ray LaHood. Retrieved 24 May 2012.
- ^ Central Japan Railway Company (2012). "Central Japan Railway Company Annual Report 2012" (PDF). pp. 23–25. Retrieved 23 July 2013.
- ^ a b c d He, J.L.; Rote, D.M.; Coffey, H.T. (1994). "Study of Japanese Electrodynamic-Suspension Maglev Systems". Argonne National Laboratory. doi:10.2172/10150166. OSTI 10150166. Retrieved 26 December 2014.
- ^ a b McCurry, Justin (21 April 2015). "Japan's Maglev Train Breaks World Speed Record with 600km/h Test Run". The Guardian (U.S. ed.). New York. Retrieved 21 April 2015.
- ^ a b U.S.-Japan Maglev (2012). "History". USJMAGLEV. Retrieved 26 December 2014.
- ^ a b Central Japan Railway Company (2012). "The Chuo Shinkansen Using the Superconducting Maglev System". Data Book 2012 (PDF). pp. 24–25.
- ^ Pfanner, Eric (19 November 2013). "Japan Pitches Its High-Speed Train With an Offer to Finance". The New York Times (New York ed.). p. B8. Retrieved 28 April 2015.
- ^ "General Electric, Japan Rail and Mitsui all aboard high-speed rail proposal". Financial Review. 12 May 2016. Retrieved 22 June 2016.
- ^ "Consolidated Land and Rail Australia Pty Ltd". www.clara.com.au. Retrieved 22 June 2016.
- ^ リニアが世界最速590キロ 長距離走行記録も更新. Sankei News (in Japanese). Japan: The Sankei Shimbun & Sankei Digital. 16 April 2015. Retrieved 16 April 2015.
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Further reading
- Heller, Arnie (June 1998). "A New Approach for Magnetically Levitating Trains—and Rockets". Science & Technology Review.
- Henry H. Kolm; Richard D. Thornton (October 1973). "Electromagnetic Flight". Scientific American. 229 (4). Springer Nature: 17–25.
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