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Understanding the basics of amorphous-iron motors

04-25-2022 at 11:11:48 PM

Understanding the basics of amorphous-iron motors

Understanding the basics of amorphous-iron motors



Most engineers think amorphous iron is an exotic material that is hard to come by. But the interest level in this metal is rising because its magnetic properties can promote energy efficiency in electrical machinery and power distribution equipment. So it is timely to review the properties of amorphous iron that make it useful as a component in electrical equipment.Get more news about Amorphous Stators,you can vist our website!

One commercially available amorphous-iron motor uses a two-stator PM brushless configuration. Each stator has 54 slots. The rotor has 36 poles. The amorphous iron is green in this diagram. The motor is designed to operate at 1,000 rpm.
Despite what many engineers think, amorphous iron is actually made in large quantities. Two firms now supply the entire world’s amorphous iron: Metglas in Conway, S.C., and Tokyo (a division of Hitachi Metals), and Advanced Technology & Materials Co. Ltd. (AT&M) in China. About 100,000 tons of amorphous iron is produced annually, with Hitachi Metals supplying the vast majority.

Typical amorphous iron is an alloy of iron with boron and silicon. Amorphous iron comes from these suppliers in the form of a thin (25-microns thick) ribbon or foil. This form factor arises directly from the process used to manufacture the iron: Molten iron drips onto a wheel comprised of pure molybdenum. The molybdenum wheel is kept at a controlled temperature so iron hitting the wheel quenches quickly. The molten iron temperature drops at a rate of about 1 million°C/sec. This extra-fast quench freezes the iron molecules before they have a chance to form crystals, resulting in an amorphous structure that is much less orderly than that of crystalline iron.

The amorphous iron harvested from the molybdenum wheel is necessarily thin. At thicknesses exceeding about 25 microns, the temperature doesn’t drop as quickly for the internal iron molecules. These internal molecules would have time to form crystals so the resulting metal would lose its uniform amorphous quality.

The disorderly structure of the amorphous iron lets it respond to changes in magnetic fields more readily than is the case for ordinary crystalline iron. The magnetic field change also causes eddy currents in the iron that are an additional source of loss, and the superthin nature of the amorphous iron limits these as well. Thus amorphous iron exhibits much less power loss, typically measured in units of Watts-per-pound or Watts-per-kilogram, for a given magnetic field strength than does crystalline iron.

Recently developed amorphous-iron motors use a segmented stator devised to avoid difficulties associated with efficiently assembling a stator with amorphous-iron teeth. A yoke made from either a soft magnetic material or amorphous-iron holds individual iron teeth. The yoke is made of individual pieces that are assembled to the teeth after copper windings are formed around each tooth. Each yoke piece has a tongue-and-groove to let multiple yoke pieces connect to the teeth. This lets the individual stator tooth pieces be wound with copper wire while sitting flat. Once windings are completed on the teeth, the yoke pieces can be connected together to form a complete stator.
The advantage amorphous iron provides also becomes evident in magnetization curves (also called BH curves or hysteresis curves). When these curves are plotted for ordinary iron under the influence of alternating (ac) fields, a hysteresis effect is apparent because the iron stores some amount of magnetic energy. Said another way, there is a measureable difference between the magnetizing field H and the magnetic field B of the iron as the H field alternates polarity. But amorphous iron has a hysteresis that is nearly nonexistent at frequencies normally used in ac power equipment.

That said, amorphous alloys saturate at a lower flux density than do ordinary irons. Because its flux density is lower, electrical applications must use more amorphous material than would be necessary with crystalline iron to handle a given level of magnetic flux. Also, it can be difficult to work with amorphous iron without changing its magnetic properties. So, for example, there may be problems stamping out laminations of the material as is normally done to form components for squirrel-cage rotors in induction motors.

Poetry is not the expression of personality but an escape from personality.

T. S. Eliot (1888-1965) American-English poet and playwright.