Swarastra Bhusana Mishra MAGLEV TRAINS SUBMITTED BY Swarastra Bhusana Mishra Reg. no-0701220318 UNDER THE GUIDANCE OF Er. Geetanjali Behera. A TECHNICAL SEMINAR ON 9/15/2018
MAGLEV TRAINS 9/15/2018
summary Introduction How does it work? - propulsion - suspension - advantages and disadvantages Development of the concept Present using Future plans Conclusion References 9/15/2018
introduction Out of science fiction books, a train running on magnetic and electrical force only, no wheels, no engine and the steel track replaced by a guideway, the maglev (Magnetic Levitation) trains are becoming a reality more then ever. With a record of 581km/h, these trains open new visions about future transportation. Just like airplanes revolutionize 20th century’s transportation, maglev trains are expected to do the same thing with 21th century’s transportation. 9/15/2018
How does it work? propulsion Electromagnetic Propulsion: In real life the opposite poles of magnets attract each other and like ends repel, this is the simple principle behind electromagnetic propulsion. However electromagnets attract metal objects while charged with electricity, the pull is temporary and dependent on the charge. For a train to operate three major components must be present in the system: a powerful electrical power source, large guidance magnets attached to the underside of the train, a track lined with metal coils. 9/15/2018
The magnetized coil running along the track, is called the guideway The magnetized coil running along the track, is called the guideway. This will repel the large magnets on the underside of the carriage, causing the train to hover above the track. The key advantage of the Maglev train is that it floats on a cushion of air, with virtually no friction. This allows the train to reach such high speeds! 9/15/2018
Suspension There is 2 forms of suspension technology: 1-Electromagnetic suspension 2-Electrodynamic suspension 1-Electromagnetic suspension: In current EMS systems, the train levitates above a steel rail while electomagnets attached to the train, are oriented toward the rail from below. The electromagnets use feedback control to maintain a train at a constant distance from a track. 9/15/2018
2-Electrodynamic suspension: In Electrodynamic suspension (EDS), both the rail and the train exert a magnetic field, and the train is levitated by the repulsive force between these magnetic fields. The magnetic field in the train is produced by either electromagnets or by an array of permanent magnets . At slow speeds, the force is not large enough to support the weight of the train. For this reason the train must have wheels or some other form of landing gear to support the train until it reaches a speed that can sustain levitation. 9/15/2018
+ and - Due to the lack of physical contact between the track and the vehicle, there is no rolling friction, leaving only air resistance. Maglevs can handle high volumes of passengers per hour and do it without introducing air pollution along the right way. Safest way of transportation, since its all automatically controlled, no chance of collision or brake down. No burning of fossil fuel, so no pollution, and the electricity needed will be nuclear or solar. The powerful magnets demand a large amount of electricity to function so the train levitates. What makes the maglev trains much more expensive to build and to operate. 9/15/2018
The weight of the large electromagnets in EMS and EDS designs are a major design issue. A very strong magnetic field is required to levitate a massive train. Due to its high speed and shape, the noise generated by a maglev train is similar to a jet aircraft, and is considerably more disturbing than standard train noise. A study found the difference between disturbance levels of maglev and traditional trains to be 5dB (about 78% noisier) Very costly to operate since it needs large magnets and a very advanced technology and huge amount of electrical power. 9/15/2018
Development of the concept A U.S. patent, dated 1 October 1907, is for a linear motor propelled train in which the motor, below the steel track, carried some but not all of the weight of the train. The inventor was Alfred Zehden. 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. 9/15/2018
Present using Shanghai Maglev Train: Contracted from 2000-2004 with a cost of 1.2 billion $, it links the Pudong Airport and Shanghai Metro, it is based on the maglev technologies of Siemens. It caries about 7000 passengers per day 9/15/2018
Linimo: 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 train has a top speed of 100 km/h. 9/15/2018
conclusion It’s no longer science fiction, maglev trains are the new way of transportation in the near future, just some obstacles are in the way, but with some researches nothing is impossible. With no engine, no wheels, no pollution, new source of energy, floating on air, the concept has token tens of years to develop, just recently it’s true capacities has been realized. Competing planes with speed, boats with efficiency, traditional trains with safety, and cars with comfort, it seems like it isn't a fair fight... ANY qURIES/??? 9/15/2018
Thank You. 9/15/2018
References http://www.21stcenturysciencetech.com/arti cles/Summer03/maglev2.html http://en.wikipedia.org/wiki/Magnetic_levitat ion_train http://science.howstuffworks.com/maglev- train.htm http://future.wikia.com/wiki/Maglev_train http://www.geocities.com/nastywik/trains.ht ml THANKS YOU 9/15/2018