Superconducting electric machine
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New article name is Superconducting electric machine
DC homopolar machines are among the oldest electric machines. Michael Faraday made one in 1831.[citation needed] Superconducting DC homopolar machines use superconductors in their stationary field windings and normal conductors in their rotating pickup winding. In 2005 the General Atomics company received a contract for the creation of a large low speed superconducting homopolar motor for ship propulsion. Superconducting homopolar generators have been considered as pulsed power sources for laser weapon systems. However, homopolar machines have not been practical for most applications.
Now there is more interest in superconducting AC synchronous electric machines (alternators and synchronous motors). The rotors (rotating members) of these use superconductors. The stators (stationary members) use conventional, normal conduction, copper conductors. Often the stator conductors are cooled to reduce, but not eliminate, their resistive losses.
Contents
- 1 History
- 2 Present interest
- 3 Advantages of a superconductor machine over a conventional conductor machine
- 4 Disadvantages of a superconductor machine compared to a conventional conductor machine
- 5 Advantage of an electric machine using ceramic superconductors rather than the older metal superconductors
- 6 Disadvantages of an electric machine using ceramic superconductors rather than the older metal superconductors
- 7 References
- 8 Links
History
In the past, experimental AC synchronous superconducting machines were made with rotors using low-temperature metal superconductors that exhibit superconductivity when cooled with liquid helium. These worked, however the high cost of liquid helium cooling made them too expensive for most applications.
More recently AC synchronous superconducting machines have been made with ceramic rotor conductors that exhibit high-temperature superconductivity. These have liquid nitrogen cooled ceramic superconductors in their rotors. The ceramic superconductors are also called high-temperature or liquid-nitrogen-temperature superconductors. Because liquid nitrogen is relatively inexpensive and easy to handle, there is a greater interest in the ceramic superconductor machines than the liquid helium cooled metal superconductor machines.
Present interest
Present interest in AC synchronous ceramic superconducting machines is in larger machines like the generators used in utility and ship power plants and the motors used in ship propulsion. The American Superconductor company and Northrup Grumman company together created and demonstrated a 36.5 MW ceramic superconductor ship propulsion motor.
Advantages of a superconductor machine over a conventional conductor machine
1) Reduced resistive losses. 2) Reduced size and weight per power capacity.
Disadvantages of a superconductor machine compared to a conventional conductor machine
1) The cost and complications of the cooling system. 2) A sudden decrease or elimination of motor or generator action if the superconductors leave their superconductive state. 3) A greater tendency for rotor speed instability. A superconducting rotor does not have the inherent damping of a conventional rotor. Its speed may hunt or oscillate around its synchronous speed. 4) Motor bearings need to be able to withstand cold or need to be insulated from the cold rotor.
Advantage of an electric machine using ceramic superconductors rather than the older metal superconductors
Ceramic superconductors become superconducting at more easily obtainable liquid nitrogen temperatures.
Disadvantages of an electric machine using ceramic superconductors rather than the older metal superconductors
1) Ceramic superconductors are fragile relative to metal conductors. 2) Ceramic superconductors cannot be bolted or welded together to form superconducting junctions. Ceramic superconductors must be cast in their final shape when created. This may increase production costs. 3) Ceramic superconductors can be more easily driven out of superconductivity by oscillating magnetic fields. This could be a problem during transient conditions, as during a sudden load or supply change.
References
- Bumby, J. R., Superconducting Rotating Electrical Machines, Oxford: Clarendon Press, 192 pages, 1983.
- Kuhlmann, J. H., Design of Electrical Apparatus, 3rd edition; New York: John Wiley & Sons, Inc., 512 pages, 1950. <Note, this book does not consider superconducting machines. However, it provides excellent detailed design information that could be used when designing a superconducting machine.>
- Tubbs, S. P., Design and Analysis of a Superconducting High Speed Synchronous/Induction Motor, ProQuest Direct Complete Database, Publication No. AAT LD03278, 227 pages, 1995. <Literature evaluation, analysis, experimental results, and a large bibliography.>
Links
- American Superconductor, AC synchronous superconducting ceramic motors and generators http://www.amsc.com/
- General Atomics, DC homopolar superconducting motor http://atg.ga.com/EM/defense/dc-motor/index.php