Magnetic river is an electrodynamic magnetic levitation (maglev) system designed by Fredrick Eastham and Eric Laithwaite in 1974. It consists of a thin conductive plate on an AC linear induction motor. Due to the transverse flux and the geometry, this gives it lift, stability and propulsion as well as being relatively[ vague ] efficient. The name refers to the action that provides stability along the longitudinal axis, which acts similar to the flow of water in a river.
A linear induction motor (LIM) is essentially a conventional induction motor with its primary "unwound" and laid out flat. The rotor, normally consisting of a series of conductors wound onto a form of some sort, is replaced by a sheet of magnetically susceptible metal. Due to its good conductance to weight ratio, aluminium is almost always used for this "stator plate". When the primaries are fed current, they induce a magnetic field in the stator plate, which generates forces away from the plate and along it. [1]
The simplest way to use these forces to produce linear motion is to arrange two such motors on either side of a single stator plate. That way the lift forces from one motor are opposite of the other, and clamping the two motors together results in there being no net sideways force (it is contained in the stress of the clamp). This is normally arranged in a C-shaped device which is hung above a vertical stator plate. Arrangements of this sort can be commonly seen on many pioneering transit systems from the 1960s, normally running through a slot in the middle of the vehicle floor. [1]
By the late 1960s, a fatal flaw in this "sandwich motor" arrangement had been discovered. The stator plate cannot be made of a single casting, as it is kilometres long. Instead, it is made of many smaller plates that are then welded together. The strength of these welds is much smaller than the plate itself, and are prone to breaking in cold weather. When the vehicle passes, any misalignment between the motor and the stator results in enormous forces being generated, pushing the plate back into the center of the motor. These forces may be great enough to break the welds between the plates, or simply deform them. In this case, a motor on a following vehicle can strike the plate, catastrophically. [2]
Looking to address the problems found in the sandwich motor, starting in 1967 Eric Laithwaite and his team at Imperial College London began experimenting with single-sided LIM arrangements. In this arrangement there is no corresponding set of magnetic fields on the "far side" of the stator, which requires some other system to be used to create a complete flux path. [3]
The team initially considered small plates of soft iron, like those in a transformer core. The size of the flux arrangement, and thus the size of the iron plates required, was a function of vehicle speed, power frequency and the size of the magnets. The size of the magnets is a function of the power dissipation within them, and are therefore a fixed size for any given type of vehicle; larger magnets are needed for higher power levels, which are used on higher-speed vehicles. Thus the only real variable is the frequency of the power supply. At the time, efficient high-power frequency conversion was expensive and heavy, so using standard 50 Hz mains power was the only practical system. Considering these inputs, a single-sided LIM demanded flux "core" about 30 cm deep, which would add enormously to the cost of the tracks. [4]
In February 1969, Laithwaite's team made a breakthrough that improved the practicality of the single-sided LIM for high-speed use. They noticed that by turning the vehicle-mounted rotor side of the motor through 90 degrees, so it was aligned "across" the tracks instead of along them, the flux was able to spread through the entire stator plate, thereby eliminating the problems with depth. Once again, a simple thin aluminum sheet would serve as an appropriate stator plate. As Laithwaite later noted, there was no reason not to consider this design from the start, it had simply not come up during the development of the LIM from rotary electric motors, which had their primaries aligned "along" the stator in the same fashion as earlier LIMs. [5] These new arrangements were known as Traverse Flux Machines, or TFMs. [4]
During the development of the TFM, maglev vehicles were a major area of research, especially in Germany. Laithwaite had always been interested in these designs, and invested some effort developing his own versions. Most maglev systems used a series of magnets to provide lift, and separate sets to provide guidance side-to-side along the rail. All of these designs had considerable problems with stability, and required electronic systems to maintain the ride. Laithwaite was highly critical of any design that used attractive forces for lift, and felt a repulsive system, which is naturally stable, would be a better design.
Laithwaite developed a repulsive-based maglev using two long conductors set on either side of a flux plate. The conductors ran down the top of the plate off the end, were bent through 180 degrees, and then ran back along the top of the plate, forming a long U-shape. Running current through the loops of wire caused magnetic fields that were repulsive over the loops, and attractive in the area between them. This meant that if the motor became uncentered compared to the stator plate, it would naturally feel a force pulling it back to the center. The only downside of this approach is that the vehicle in proper alignment feels both attractive and repulsive forces, meaning that greater energy is needed to provide the required amount of lift. The system did not provide thrust, only lift, so the team proposed to place a thin LIM between the two lift coils. [6]
Tom Fellows of the Tracked Hovercraft team approached Laithwaite to build a model of a maglev system for the upcoming Transpo '72 trade show. Using the repulsive design he found that the model required a very wide motor, about 25 cm for a track that was to be only 9 m long, so Laithwaite began examining ways to reduce the system size. One early change was to move the conductors from lying on the top of the motor to having one half of the loop under the flux plate. This was found to cause the system to become unstable, until someone accidentally hooked up the lift conductors the "wrong way" so the current flowed in the same direction in the two loops. This immediately caused the system to stabilize. [6]
When Laithwaite hired an engineering firm to build the model, they noted that a 9 m long stack of iron plates would be highly unlikely to survive the journey to the US intact. Considering the problem, Fredrick Eastham considered breaking the track down into multiple sections, each with its own lift loops. This led to a design using a series of U-shaped iron cores with looped wire creating a flux in them, similar to ½ of a transformer core. When this arrangement was tried out, it was found that it provided lift from both arms of the U, eliminating the need for two rows of lift coils. Finally, by connecting the U's to a 3-phase power supply, thrust was created. This was the magnetic river. [6]
In magnetic river the conductive plate is a critical width relative to the magnets underneath it.
The row of magnets for the linear motor each have two poles, with the poles arranged transverse to the 'river' with U-shaped cores, and excited with an AC current.
When energised the magnets produce an oscillating transverse field which cuts the plate. The plate then generates two eddy currents, one above each pole.
However, the edge reduces the size of the eddy current on each side, since it interferes with the circular current. Moving the plate sideways increases the current on one side, since the edge is interfering less, and this pushes that side higher. The plate is also pulled laterally back towards the centre by the currents, stabilising the lateral motion.
This stabilisation only works provided that the plate is not too wide or too narrow, and is also somewhat dependent on levitation height, the plate must be wider at higher lifts.
A linear motor is an electric motor that has had its stator and rotor "unrolled", thus, instead of producing a torque (rotation), it produces a linear force along its length. However, linear motors are not necessarily straight. Characteristically, a linear motor's active section has ends, whereas more conventional motors are arranged as a continuous loop.
Electromagnetic or magnetic induction is the production of an electromotive force across an electrical conductor in a changing magnetic field.
An electric motor is an electrical machine that converts electrical energy into mechanical energy. Most electric motors operate through the interaction between the motor's magnetic field and electric current in a wire winding to generate force in the form of torque applied on the motor's shaft. Electric motors can be powered by direct current (DC) sources, such as from batteries, or rectifiers, or by alternating current (AC) sources, such as a power grid, inverters or electrical generators. An electric generator is mechanically identical to an electric motor, but operates with a reversed flow of power, converting mechanical energy into electrical energy.
An electromagnet is a type of magnet in which the magnetic field is produced by an electric current. Electromagnets usually consist of wire wound into a coil. A current through the wire creates a magnetic field which is concentrated in the hole, denoting the center of the coil. The magnetic field disappears when the current is turned off. The wire turns are often wound around a magnetic core made from a ferromagnetic or ferrimagnetic material such as iron; the magnetic core concentrates the magnetic flux and makes a more powerful magnet.
Eric Roberts Laithwaite was a British electrical engineer, known as the "Father of Maglev" for his development of the linear induction motor and maglev rail system.
Eddy currents are loops of electrical current induced within conductors by a changing magnetic field in the conductor according to Faraday's law of induction. Eddy currents flow in closed loops within conductors, in planes perpendicular to the magnetic field. They can be induced within nearby stationary conductors by a time-varying magnetic field created by an AC electromagnet or transformer, for example, or by relative motion between a magnet and a nearby conductor. The magnitude of the current in a given loop is proportional to the strength of the magnetic field, the area of the loop, and the rate of change of flux, and inversely proportional to the resistivity of the material. When graphed, these circular currents within a piece of metal look vaguely like eddies or whirlpools in a liquid.
A linear induction motor (LIM) is an alternating current (AC), asynchronous linear motor that works by the same general principles as other induction motors but is typically designed to directly produce motion in a straight line. Characteristically, linear induction motors have a finite primary or secondary length, which generates end-effects, whereas a conventional induction motor is arranged in an endless loop.
A synchronous electric motor is an AC electric motor in which, at steady state, the rotation of the shaft is synchronized with the frequency of the supply current; the rotation period is exactly equal to an integral number of AC cycles. Synchronous motors contain multiphase AC electromagnets on the stator of the motor that create a magnetic field which rotates in time with the oscillations of the line current. The rotor with permanent magnets or electromagnets turns in step with the stator field at the same rate and as a result, provides the second synchronized rotating magnet field of any AC motor. A synchronous motor is termed doubly fed if it is supplied with independently excited multiphase AC electromagnets on both the rotor and stator.
Electrodynamic suspension (EDS) is a form of magnetic levitation in which there are conductors which are exposed to time-varying magnetic fields. This induces eddy currents in the conductors that creates a repulsive magnetic field which holds the two objects apart.
A Halbach array is a special arrangement of permanent magnets that augments the magnetic field on one side of the array while cancelling the field to near zero on the other side. This is achieved by having a spatially rotating pattern of magnetisation.
Electromagnetic propulsion (EMP) is the principle of accelerating an object by the utilization of a flowing electrical current and magnetic fields. The electrical current is used to either create an opposing magnetic field, or to charge a field, which can then be repelled. When a current flows through a conductor in a magnetic field, an electromagnetic force known as a Lorentz force, pushes the conductor in a direction perpendicular to the conductor and the magnetic field. This repulsing force is what causes propulsion in a system designed to take advantage of the phenomenon. The term electromagnetic propulsion (EMP) can be described by its individual components: electromagnetic – using electricity to create a magnetic field, and propulsion – the process of propelling something. When a fluid is employed as the moving conductor, the propulsion may be termed magnetohydrodynamic drive. One key difference between EMP and propulsion achieved by electric motors is that the electrical energy used for EMP is not used to produce rotational energy for motion; though both use magnetic fields and a flowing electrical current.
Maglev is a system of train transportation that uses two sets of magnets: one set to repel and push the train up off the track, and another set to move the elevated train ahead, taking advantage of the lack of friction. Along certain "medium-range" routes, maglev can compete favourably with high-speed rail and airplanes.
An eddy current brake, also known as an induction brake, electric brake or electric retarder, is a device used to slow or stop a moving object by dissipating its kinetic energy as heat. Unlike friction brakes, where the drag force that stops the moving object is provided by friction between two surfaces pressed together, the drag force in an eddy current brake is an electromagnetic force between a magnet and a nearby conductive object in relative motion, due to eddy currents induced in the conductor through electromagnetic induction.
Electromagnetic suspension (EMS) is the magnetic levitation of an object achieved by constantly altering the strength of a magnetic field produced by electromagnets using a feedback loop. In most cases the levitation effect is mostly due to permanent magnets as they don't have any power dissipation, with electromagnets only used to stabilize the effect.
Flux pumping is a method for magnetising superconductors to fields in excess of 15 teslas. The method can be applied to any type II superconductor and exploits a fundamental property of superconductors, namely their ability to support and maintain currents on the length scale of the superconductor. Conventional magnetic materials are magnetised on a molecular scale which means that superconductors can maintain a flux density orders of magnitude bigger than conventional materials. Flux pumping is especially significant when one bears in mind that all other methods of magnetising superconductors require application of a magnetic flux density at least as high as the final required field. This is not true of flux pumping.
Tracked Hovercraft was an experimental high speed train developed in the United Kingdom during the 1960s. It combined two British inventions, the hovercraft and linear induction motor, in an effort to produce a train system that would provide 250 mph (400 km/h) inter-city service with lowered capital costs compared to other high-speed solutions. Substantially similar to the French Aérotrain and other hovertrain systems of the 1960s, Tracked Hovercraft suffered a similar fate to these projects when it was cancelled as a part of wide budget cuts in 1973.
A hovertrain is a type of high-speed train that replaces conventional steel wheels with hovercraft lift pads, and the conventional railway bed with a paved road-like surface, known as the track or guideway. The concept aims to eliminate rolling resistance and allow very high performance, while also simplifying the infrastructure needed to lay new lines.
Krauss-Maffei's Transurban was a 12-passenger automated guideway transit (AGT) mass transit system based on a maglev guideway. Development started in 1970 as one of the many AGT and PRT projects that followed in the wake of the HUD reports of 1968. Its selection as the basis of the GO-Urban system in Toronto in 1973 made it well known in the industry; it would have been the basis of the first large-area AGT mass transit network in the world. Technical problems cropped up during the construction of the test track, and the sudden removal of funding by the West German government led to the project's cancellation in late 1974. The Ontario government completed development and installation of a non-maglev version, today known as the Bombardier Advanced Rapid Transit.
Road powered electric vehicles (RPEV) collect any form of potential energy from the road surface to supply electricity to locomotive motors and ancillary equipment within the vehicle.
Magnetic levitation (maglev) or magnetic suspension is a method by which an object is suspended with no support other than magnetic fields. Magnetic force is used to counteract the effects of the gravitational force and any other forces.