Difference between revisions of "Maglev train" - New World Encyclopedia

Neither Inductrack nor the Superconducting EDS are able to levitate vehicles at a standstill, although Inductrack provides levitation down to a much lower speed. Wheels are required for both systems. EMS systems are wheel-less.

The German Transrapid, Japanese HSST (Linimo), and Korean Rotem EMS maglevs levitate at a standstill, with electricity extracted from guideway using power rails for the latter two, and wirelessly for Transrapid. If guideway power is lost on the move, the Transrapid is still able to generate levitation down to 10 km/h speed, using the power from onboard batteries. This is not the case with the HSST and Rotem systems.

Propulsion

An EMS system can provide both levitation and propulsion using an onboard linear motor. EDS systems can only levitate the train using the magnets onboard, not propel it forward. As such, vehicles need some other technology for propulsion. A linear motor (propulsion coils) mounted in the track is one solution. Over long distances where the cost of propulsion coils could be prohibitive, a propeller or jet engine could be used.

Stability

Static magnetic bearings using only electromagnets and permagnets are unstable, as explained by Earnshaw's theorem. EMS systems rely on active electronic stabilization. Such systems constantly measure the bearing distance and adjust the electromagnet current accordingly. As all EDS systems are moving systems (that is, no EDS system can levitate the train unless it is in motion), Earnshaw's theorem does not apply to them.

Pros and cons of maglev vs. conventional trains

Due to the lack of physical contact between the track and the vehicle, there is no rolling friction, leaving only air resistance (although maglev trains also experience electromagnetic drag, this is relatively small at high speeds). ^[1]

Maglevs can handle high volumes of passengers per hour (comparable to airports or eight-lane highways) and do it without introducing air pollution along the right of way. Of course, the electricity has to be generated somewhere, so the overall environmental impact of a maglev system is dependent on the nature of the grid power source.

The weight of the large electromagnets in EMS and EDS designs is a major design issue. A very strong magnetic field is required to levitate a massive train. For this reason one research path is using superconductors to improve the efficiency of the electromagnets.

The high speed of some maglev trains translates to more sound due to air displacement, which gets louder as the trains go faster. A study found that high speed maglev trains are 5dB noisier than traditional trains.^[2] At low speeds, however, maglev trains are nearly silent.

Economics

The Shanghai maglev cost 9.93 billion yuan (US$1.2 billion) to build.^[3] This total includes infrastructure capital costs such as manufacturing and construction facilities, and operational training. At 50 yuan per passenger^[4] and the current 7,000 passengers per day, income from the system is incapable of recouping the capital costs (including interest on financing) over the expected lifetime of the system, even ignoring operating costs.

China aims to limit the cost of future construction extending the maglev line to approximately 200 million yuan (US$24.6 million) per kilometer.^[3] These costs compare competitively with airport construction (for example, Hong Kong Airport cost US$20 billion to build in 1998) and eight-lane Interstate highway systems that cost around US$50 million per mile in the US.

While high-speed maglevs are expensive to build, they are less expensive to operate and maintain than traditional high-speed trains, planes or intercity buses. Data from the Shanghai maglev project indicates that operation and maintenance costs are covered by the current relatively low volume of 7,000 passengers per day. Passenger volumes on the Pudong International Airport line are expected to rise dramatically once the line is extended from Longyang Road metro station all the way to Shanghai's downtown train depot.

The proposed Chūō Shinkansen maglev in Japan is estimated to cost approximately US$82 billion to build.

The only low-speed maglev (100 km/h) currently operational, the Japanese Linimo HSST, cost approximately US$100 million/km to build^[5]. Besides offering improved O&M costs over other transit systems, these low-speed maglevs provide ultra-high levels of operational reliability and introduce little noise and zero air pollution into dense urban settings.

As maglev systems are deployed around the world, experts expect construction costs to drop as new construction methods are perfected.^{[citation needed]}

Historical maglev systems

First patents

<<Patent numbers, if used, need to be placed as footnotes (with the "ref" tags) and the Web sites should be checked and tagged with "Retrieved" dates. See how I've placed the first two patent numbers in footnotes.>>

High speed transportation patents would be granted to various inventors throughout the world. Early United States patents for a linear motor propelled train were awarded to the inventor, Alfred Zehden (German). The inventor gained a patent on June 21, 1902^[6] and another on August 21, 1907.^[7][8] In 1907, another early electromagnetic transportation system was developed by F. S. Smith^[9]. A series of German patents for magnetic levitation trains propelled by linear motors were awarded to Hermann Kemper between 1937 and 1941^[10]. An early modern type of maglev train was described in U.S. Patent 3158765 (PDF), Magnetic system of transportation, by G. R. Polgreen (Aug 25, 1959). The first use of "maglev" in a United States patent was in "Magnetic levitation guidance"^[11] by Canadian Patents and Development Limited.

Hamburg, Germany 1979

Transrapid 05 was the first maglev train with longstator propulsion licensed for passenger transportation. In 1979 a 908 m track was open in Hamburg for the first International Transportation Exhibition (IVA 79). There was so much interest that operation had to be extended three months after exhibition finished, after carrying more than 50,000 passengers. It was reassembled in Kassel in 1980.

Birmingham, England 1984–1995

The world's first commercial automated system was a low-speed maglev shuttle that ran from the airport terminal of Birmingham International Airport (UK) to the nearby Birmingham International railway station from 1984 to 1995. Based on experimental work commissioned by the British government at the British Rail Research Division laboratory at Derby, the length of the track was 600 m, and trains "flew" at an altitude of 15 mm. It was in operation for nearly eleven years, but obsolescence problems with the electronic systems made it unreliable in its later years and it has now been replaced with a cable-drawn system.

Several favourable conditions existed when the link was built.

1. The BR Research vehicle was 3 tons and extension to the 8 ton vehicle was easy.
2. Electrical power was easily available.
3. Airport and rail buildings were suitable for terminal platforms.
4. Only one crossing over a public road was required and no steep gradients were involved
5. Land was owned by Railway or Airport
6. Local industries and councils were supportive
7. Some Government finance was provided and because of sharing work, the cost per organization was not high.

Japan, 1980s

In Tsukuba, Japan (1985), the HSST-03 wins popularity in spite of being 30km/h and a run of low speed in Tsukuba World Exposition. In Okazaki, Japan (1987), the JR-Maglev took a test ride at holding Okazaki exhibition and runs. In Saitama, Japan (1988), the HSST-04-1 exhibited it at Saitama exhibition performed in Kumagaya, and runs. Best speed per hour 30km/h. In Yokohama, Japan (1989), the HSST-05 acquires a business driver's license at Yokohama exhibition and carries out general test ride driving. Maximum speed 42km/h.

Vancouver,Canada & Hamburg,Germany 1986-1988

In Vancouver, Canada (1986), the JR-Maglev took a test ride at holding Vancouver traffic exhibition and runs. In Hamburg, Germany (1988), the TR-07 in international traffic exhibition (IVA88) performed Hamburg.

Berlin, Germany 1989–1991

In West Berlin, the M-Bahn was built in the late 1980s. It was a driverless maglev system with a 1.6 km track connecting three stations. Testing in passenger traffic started in August 1989, and regular operation started in July 1991. Although the line largely followed a new elevated alignment, it terminated at the U-Bahn station Gleisdreieck, where it took over a platform that was then no longer in use; it was from a line that formerly ran to East Berlin. After the fall of the Berlin Wall, plans were set in motion to reconnect this line (today's U2). Deconstruction of the M-Bahn line began only two months after regular service began and was completed in February 1992.

The history of maximum speed record by a trial run

• 1971 - West Germany - Prinzipfahrzeug - 90km/h
• 1971 - West Germany - TR-02 - 164km/h
• 1972 - Japan - ML100 - 60km/h - (manned)
• 1973 - West Germany - TR04 - 250(manned)
• 1974 - West Germany - EET-01 - 230km/h(Unmanned)
• 1975 - West Germany - Komet - 401.3km/h(by steam rocket propulsion).(Unmanned)
• 1978 - Japan - HSST01 - 307.8km/h(by Supporting Rockets propulsion, made in Nissan).(Unmanned)
• 1978 - Japan - HSST02 - 110km/h (manned)
• 1979 - Japan - ML500 - 517km/h (unmanned)It succeeds in operation over 500km/h for the first time in the world.
• 1987 - West Germany - TR06 - 406km/h(manned)
• 1987 - Japan - MLU001 - 400.8km/h(manned)
• 1988 - West Germany - TR-06 - 412.6km/h (manned)
• 1989 - West Germany - TR-07 - 436km/h (manned)
• 1993 - Germany - TR-07 - 450km/h(manned)
• 1994 - Japan - MLU002N-431km/h(unmanned)
• 1997 - Japan - MLX01 - 531km/h (manned)
• 1997 - Japan - MLX01 - 550km/h (unmanned)
• 1999 - Japan - MLX01 - 548km/h (unmanned)
• 1999 - Japan - MLX01 - 552km/h (manned/Five formation).

Guinness authorization.

• 2003 - Germany - TR-08 - 501km/h (manned)
• 2003 - Japan - MLX01 - 581km/h (manned/Three formation).

Guinness authorization.

Existing maglev systems

Emsland, Germany

Transrapid at the Emsland test facility

Transrapid, a German maglev company, has a test track in Emsland (Hermann Kemper's homeland) with a total length of 31.5 km. The single track line runs between Dörpen and Lathen with turning loops at each end. The trains regularly run at up to 420 km/h. The construction of the test facility began in 1980 and finished in 1984.

JR-Maglev, Japan

JR-Maglev at Yamanashi

Japan has a demonstration line in Yamanashi prefecture where test trains JR-Maglev MLX01 have reached 581 km/h (361 mph), slightly faster than any wheeled trains (the current TGV speed record is 574.8 km/h). These trains use superconducting magnets which allow for a larger gap, and repulsive-type Electro-Dynamic Suspension (EDS). In comparison Transrapid uses conventional electromagnets and attractive-type Electro-Magnetic Suspension (EMS). These "Superconducting Maglev Shinkansen," developed by the Central Japan Railway Company (JR Central) and Kawasaki Heavy Industries, are currently the fastest trains in the world, achieving a record speed of 581 km/h on December 2, 2003. Yamanashi Prefecture residents (and government officials) can sign up to ride this for free, and some 100,000 have done so already.

Linimo (Tobu Kyuryo Line, Japan)

Linimo train approaching Banpaku Kinen Koen, towards Fujigaoka Station

The world's first commercial automated "Urban Maglev" system commenced operation in March 2005 in Aichi, Japan. This is the nine-station 8.9 km long Tobu-kyuryo Line, otherwise known as the Linimo. The line has a minimum operating radius of 75 m and a maximum gradient of 6%. The linear-motor magnetic-levitated train has a top speed of 100 km/h. The line serves the local community as well as the Expo 2005 fair site. The trains were designed by the Chubu HSST Development Corporation (Japan Airlines developed it in the mid 1970s; it has since been withdrawn), which also operates a test track in Nagoya. Urban-type maglevs patterned after the HSST have been constructed and demonstrated in Korea, and a Korean commercial version Rotem is now under construction in Daejeon and projected to go into operation by April of 2007.

FTA's UMTD program

In the US, the Federal Transit Administration (FTA) Urban Maglev Technology Demonstration program has funded the design of several low-speed urban maglev demonstration projects. It has assessed HSST for the Maryland Department of Transportation and maglev technology for the Colorado Department of Transportation. The FTA has also funded work by General Atomics at California University of Pennsylvania to demonstrate new maglev designs, the MagneMotion M3 and of the Maglev2000 of Florida superconducting EDS system. Other US urban maglev demonstration projects of note are the LEVX in Washington State and the Massachusetts-based Magplane.

Southwest Jiaotong University, China

On December 31, 2000, the first crewed high-temperature superconducting maglev was tested successfully at Southwest Jiaotong University, Chengdu, China. This system is based on the principle that bulk high-temperature superconductors can be levitated or suspended stably above or below a permanent magnet. The load was over 530 kg and the levitation gap over 20 mm. The system uses liquid nitrogen, which is very cheap, to cool the superconductor.

Shanghai Maglev Train

A maglev train coming out of the Pudong International Airport.

Transrapid, in Germany, constructed the first operational high-speed conventional maglev railway in the world, the Shanghai Maglev Train from downtown Shanghai (Shanghai Metro) to the Pudong International Airport. It was inaugurated in 2002. The highest speed achieved on the Shanghai track has been 501 km/h (311 mph), over a track length of 30 km. The plan for the Shanghai-Hangzhou Maglev Train was approved by the central government in February 2006, with construction set to start by the end of 2006 for completion by 2010.

Under construction

Old Dominion University

A track of less than a mile in length has been constructed at Old Dominion University in Norfolk, Virginia. Although the system was initially built by AMT, problems caused the company to abandon the project and turn it over to the University.^[12][13] The system is currently not operational, but research is ongoing to resolve stability issues with the system. This system uses a "smart train, dumb track" that involves most of the sensors, magnets, and computation occurring on the train rather than the track. This system will cost less to build per mile than existing systems. Unfortunately, the $14 Million originally planned did not allow for completion.

AMT Test Track - Powder Springs, GA

The same principle is involved in the construction of a second prototype system in Powder Springs, Georgia, by American Maglev Technology, Inc., already under testing and set for completion in January 2007.^[14]

Proposals

Many maglev systems have been proposed in various nations of North America, Asia, and Europe. Many of the systems are still in the early planning stages, or, in the case of the transatlantic tunnel, mere speculation. However, a few of the following examples have progressed beyond that point.

United Kingdom

London – Glasgow: A maglev line has recently been proposed in the United Kingdom from London to Glasgow with several route options through the Midlands, Northwest and Northeast of England and is reported to be under favourable consideration by the government. A further high speed link is also being planned between Glasgow to Edinburgh though there is no settled technology for this concept yet, ie (Maglev/Hi Speed Electric etc) ^[15][16][17]

Japan

TokyoーNagoyaーOsaka

In April of 2007, JR Central President Masayuki Matsumoto said that JR Central would aim to begin commercial maglev service between Tokyo and Nagoya in the year 2025.

• Linear Chuo Shinkansen Project

Venezuela

Caracas – La Guaira: A maglev train is scheduled to be built this year connecting the capital city Caracas to the main port town of La Guaira and Simón Bolívar International Airport. Due to the extremely mountainous conditions which exist over this path, with traditional rail extensive use of tunnelling and bridging is required. Maglev systems can negotiate altitudes of up to 10%, much steeper than those negotiable by standard rail systems, and as it may simply be able to climb over obstacles rather than be required to tunnel through or bridge over, this may make the maglev proposal more economically sound. The system is slated to be a stand-alone system of about 15 km. [6]

China

Shanghai – Hangzhou: China has decided to extend the world’s first commercial Transrapid line between Pudong airport and the city of Shanghai initially by some 35 kilometers to Hong Qiao airport before the World Expo 2010 and then, in an additional phase, by 200 kilometers to the city of Hangzhou (Shanghai-Hangzhou Maglev Train), becoming the first inter-city Maglev rail line in commercial service in the world. The line will be an extension of the Shanghai airport Maglev line.

Talks with Germany and Transrapid Konsortium about the details of the construction contracts have started. On March 7 2006, the Chinese Minister of Transportation was quoted by several Chinese and Western newspapers as saying the line was approved.

United States

California-Nevada Interstate Maglev: High-speed maglev lines between major cities of southern California and Las Vegas are also being studied via the California-Nevada Interstate Maglev Project. This plan was originally supposed to be part of an I-5 or I-15 expansion plan, but the federal government has ruled it must be separated from interstate public work projects.

Since the federal government decision, private groups from Nevada have proposed a line running from Las Vegas to Los Angeles with stops in Primm, Nevada; Baker, California; and points throughout Riverside County into Los Angeles. Southern California politicians have not been receptive to these proposals; many are concerned that a high speed rail line out of state would drive out dollars that would be spent in state "on a rail" to Nevada.

Baltimore-Washington D.C. Maglev: A 64 km project has been proposed linking Camden Yards in Baltimore and Baltimore-Washington International (BWI) Airport to Union Station in Washington, D.C. It is in demand for the area due to its current traffic/congestion problems. The Baltimore proposal is competing with the above-referenced Pittsburgh proposal for a $90 million federal grant.

Most significant accidents and incidents

August 11, 2006 fire

On August 11, 2006 a fire broke out on the Shanghai commercial Transrapid, shortly after leaving the terminal in Longyang.

For more details, see Transrapid

September 22, 2006 crash

On September 22, 2006 an elevated Transrapid train collided with a maintenance vehicle on a test run in Lathen (Lower Saxony / north-western Germany). Twenty-three people were killed and ten were injured. These were the first fatalities resulting from a Maglev train accident.

Notes

References

ISBN links support NWE through referral fees

<<These references are in "cite news" and "cite book" templates. Please extract the info from these templates and format each reference according to our guidelines.>>

• Heller, Arnie, "A New Approach for Magnetically Levitating Trains—and Rockets", Science & Technology Review, June 1998.
• Hood, Christopher P. (2006). Shinkansen – From Bullet Train to Symbol of Modern Japan. Routledge. ISBN 0-415-32052-6. 
• Moon, Francis C. (1994). Superconducting Levitation Applications to Bearings and Magnetic Transportation. Wiley-VCH. ISBN 0-471-55925-3. 

See also

• Train
• Transport
• High-speed rail
• Magnetic levitation

External links

<<This list of links needs to be cleaned up and condensed. We don't need manufacturers' sites, advertising, or spam. Keep only sites that provide valuable info for readers of the encyclopedia.>>

Research and Government

• SupraTrans
• IFW-Dresden Flyer & Videos
• Federal Railroad Administration - MAGLEV
• Report to Congess: Costs and Benefits of Magnetic Levitation

Transrapid

• Transrapid
• The UK Ultraspeed Project
• The Shanghai Maglev
• Shanghai Pudong Airport Maglev in depth
• News story of accident on 22 September 2006
• Consortium Transrapid Nederland
• Baltimore-Washington Maglev Project
• California Maglev Project
• Magnetbahn-bayern
• Swissmetro
• Pennsylvania Project
• Transrapid USA

Japanese maglev

Linear motor car

RTRI

• RTRI MLX01
• RTRI Maglev R&D
• RTRI Technologies of Maglev

Research and Government

• Railway Technical Research Institute (RTRI)
• RTRI Maglev Systems Development Department
• Central Japan Railway Company
• Central Japan Railway Company - Chuo Shinkansen
• Central Japan Railway Company - Superconducting Maglev
• Central Japan Railway Company - Linear Express
• Linear Chuo Express (in Japanese)
• Linear Chuo Express for kids website (in Japanese)
• Linear Chuo Shinkansen Project
• Other Japanese Maglev Links
• Yamanashi Linear Express Fan Club (in Japanese)

Unofficial and media

• A site with MLX01 video and photo (in Japanese)
• MLX01 Video
• Another MLX01 video

Linimo

• Linimo

Maglev train companies

These websites contain further information provided by companies building maglev trains (alphabetical order).

• American Maglev Technology, Inc. (USA)
• Changchun Passenger Railway Car Plant (China)
• Cheng Du Aircraft Industrial (Group) Co. LTD (China)
• evico (Germany) - Producing also Superconductor Maglev Models
• General Atomics (USA)
• HSST (Japan)
• Maglev2000 (USA)
• MagneMotion M3 (USA)
• Magplane (USA/China)
• Magtube (USA)
• Rotem (Korea)
• Tangshan Locomotive & Rolling Stock Works (China)
• Transrapid International (Germany)

Info, Media and other

• Basic information, photos and links
• Urban Maglev Interest Group
• Maglev Quicklinks
• High Speed Surface Transport (HSST) : A Japanese Maglev Technology
• Magnetic Levitation for Transportation
• How stuff works maglev article
• Maglev video gallery
• LeviCar