How do maglev trains go back and forth?

The way maglev trains go forward or backwards is that there are coils lined up on the track in an order north pole south pole and so on and across from that is the opposite side of a magnet south pole north pole and so on.



Maglev (magnetic levitation) trains do not use traditional engines or wheels; instead, they are propelled by a Linear Synchronous Motor (LSM) system built into the guideway and the train itself. To move forward, a system of electromagnets creates a traveling magnetic field along the track. The magnets on the train are "pulled" forward by the magnetic poles ahead of them and "pushed" from behind by the poles they just passed. To go "back and forth" or change direction, the system simply reverses the polarity of the electric current flowing through the coils in the guideway. This reverses the direction of the traveling magnetic wave, effectively pulling the train in the opposite direction. Unlike a traditional train that might need a turntable or a complex series of switches to turn around, a maglev can theoretically operate at full speed in either direction because its propulsion is entirely electronic. In 2026, advanced software manages these magnetic pulses with millisecond precision, allowing for smooth acceleration, deceleration, and "shuttling" between stations without the mechanical wear associated with friction-based brakes.

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The trains used to change tracks in a 'pinched loop' system. Today, the maglev uses two trains running on their own dedicated track all day, with the switches not used in regular operation, except in the morning and evening to put the trains away in the depot.

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The front corners have magnets with north poles facing out, and the back corners have magnets with south poles outward. Electrifying the propulsion loops generates magnetic fields that both pull the train forward from the front and push it forward from behind. This floating magnet design creates a smooth trip.

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This reaction between the magnets creates a magnetic field. The field lifts the train off of the track. This lets air flow between the train and the guideway. The trains never touch the track; they hover just above the track.

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Because maglev trains require entirely new guideways, cars, and power specifications, they must be built from scratch. Despite their decades-long allure, implementation costs can be prohibitive relative to HSR. Today there are only six operational maglev trains—three in China, two in South Korea, and one in Japan.

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There are guidance magnets and levitation magnets. The guidance magnets are designed to maintain the car alignment, never letting any physical contact. Ther is transverse inclination of the rails too, which helps reducing the curve of the turn.

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Maglev train systems use powerful electromagnets to float the trains over a guideway, instead of the old steel wheel and track system. A system called electromagnetic suspension suspends, guides, and propels the trains. A large number of magnets provide controlled tension for lift and propulsion along a track.

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The magnetic field generated by the Superconducting Maglev has no impact on health, as it is controlled with various measures to keep it below the standards established in international guidelines (ICNIRP Guidelines). The standards are set at approx. 1/5 to 1/10 the level that could affect the human body.

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How Maglev Trains Work. The magnetized coil running along thetrack, called a guideway, repels the large magnets on the train'sundercarriage, allowing the train tolevitate between 0.39 and 3.93 inches (1 to 10 centimeters) above the guideway. ... Maglev trains float on a cushion of air, eliminating friction.

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Present Maglev systems cost 30 million dollars or more per mile. Described is an advanced third generation Maglev system with technology improvements that will result in a cost of 10 million dollars per mile. Plotkin, D.; Kim, S. Lever, J.H.

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SNCF, widely regarded as one of the best high-speed rail operators in the world, has had 4 profitable years and 5 loss-generating years since 2012. The Shanghai Metro Maglev has never been profitable. Clearly, there is an issue with passenger transport. No mode of transportation can consistently generate profits.

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And also because it can travel up higher ascending grades (up to 10 percent), compared to conventional trains (up to 4 percent or less), maglev trains can also reduce the need to create new tunnels or to level the landscape to build its tracks.

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Maglev trains do not have wheels or rails. As shown in Figure 3, they have guideways, and they float down these guideways without ever touching them.

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Maglev trains do not create direct pollution emissions and are always quieter in comparison to traditional systems when operating at the same speeds.

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Cost concerns over innovative rail The primary challenge facing maglev trains has always been cost. While all large-scale transportation systems are expensive, maglev requires a dedicated infrastructure including substations and power supplies and cannot be integrated directly into an existing transportation system.

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Compared to highspeed passenger rail, maglev passenger rail consumes roughly twice the power per passenger kilometer. For commercial freight I found an efficiency figure of 520 ton-miles per gallon (660 kg-km/MJ). Assuming 70kg for the average commuter passenger this gives us an efficiency of (116 kg-km/MJ) for maglev.

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