Claims
- 1. A dynamoelectric machine, comprising:
(a) at least one stator assembly, a plurality of stator windings, and at least one rotor assembly supported for rotation about a rotational axis, said rotor and stator assemblies being concentric with said rotational axis; (b) said at least one rotor assembly comprising at least two rotor layers having equal numbers of discrete rotor magnets, each of said magnets having a polarity defining north and south poles at opposite ends thereof, said layers being substantially planar, perpendicular to said rotational axis, and axially spaced apart, said magnets in each layer being disposed equiangularly about the circumference of said rotor assembly, such that:
(i) one of said ends of each of said magnets is situated on a cylindrical periphery of said rotor assembly; (ii) said ends on said periphery have circumferentially alternating north and south poles; and (iii) each of said magnets is magnetically linked to an adjacent one of said magnets by a magnetically permeable linking member situated proximate the other of said ends of said adjacent magnet; (c) said at least one stator assembly comprising a plurality of stator cores, each of said stator cores terminating in a first and a second stator poleface, said stator cores being disposed equiangularly about the circumference of said stator assembly, such that:
(i) said first and second stator polefaces of each of said stator cores are situated on a cylindrical periphery of said stator assembly in axial alignment; (ii) said first stator polefaces are in a first stator layer radially adjacent one of said rotor layers; and (iii) said second stator polefaces are in a second stator layer adjacent another of said rotor layers; and (d) said stator windings encircling said stator cores.
- 2. A dynamoelectric machine as recited by claim 1, wherein said magnets are composed of a rare earth-transition metal alloy.
- 3. A dynamoelectric machine as recited by claim 2, wherein said magnets are SmCo or FeNdB magnets.
- 4. A dynamoelectric machine as recited by claim 1, wherein said magnets in said layers are situated in axial alignment.
- 5. A dynamoelectric machine as recited by claim 1, wherein said magnets in said layers are skewed by an amount ranging up to about one half the distance between said circumferentially adjacent stator cores.
- 6. A dynamoelectric machine as recited by claim 1, wherein said linking members comprise a laminated stack of sheets of a magnetically permeable material.
- 7. A dynamoelectric machine as recited by claim 6, wherein said magnetically permeable material is selected from the group consisting of amorphous, nanocrystalline, and flux-enhancing Fe-based magnetic material
- 8. A dynamoelectric machine as recited by claim 1, wherein said linking members link circumferentially adjacent magnets.
- 9. A dynamoelectric machine as recited by claim 1, wherein said linking members link axially adjacent magnets.
- 10. A dynamoelectric machine as recited by claim 1, wherein said stator cores comprise laminated layers composed of a material selected from the group consisting of amorphous, nanocrystalline, and flux enhancing Fe-based metal.
- 11. A dynamoelectric machine as recited by claim 10, wherein said laminated layers are composed of amorphous metal.
- 12. A dynamoelectric machine as recited by claim 10, wherein said laminated layers are composed of nanocrystalline metal.
- 13. A dynamoelectric machine as recited by claim 10, wherein said laminated layers are composed of non-oriented Fe-based metal consisting essentially of an alloy of Fe and about 6.5 wt. % Si.
- 14. A dynamoelectric machine as recited by claim 1, having a slot per phase per pole ratio that ranges from about 0.25 to 4.0.
- 15. A dynamoelectric machine as recited by claim 14, having a slot per phase per pole ratio that ranges from about 0.25 to 1.
- 16. A dynamoelectric machine as recited by claim 15, having a slot per phase per pole ratio of 0.50.
- 17. A dynamoelectric machine as recited by claim 1, having at least 16 poles.
- 18. A dynamoelectric machine as recited by claim 1, adapted to run with a commutating frequency ranging from about 500 Hz to 2 kHz.
- 19. A dynamoelectric machine as recited by claim 18, having at least 32 poles.
- 20. A dynamoelectric machine as recited by claim 1, wherein said rotor assembly is radially inward of said stator assembly.
- 21. A dynamoelectric machine as recited by claim 1, wherein said stator assembly is radially inward of said rotor assembly.
- 22. A dynamoelectric machine system, comprising a dynamoelectric machine and power electronics means for interfacing and controlling said machine and being operably connected thereto, the dynamoelectric machine comprising:
(a) at least one stator assembly, a plurality of stator windings, and at least one rotor assembly supported for rotation about a rotational axis, said rotor and stator assemblies being concentric with said rotational axis; (b) said at least one rotor assembly comprising at least two rotor layers having equal numbers of discrete rotor magnets, each of said magnets having a polarity defining north and south poles at opposite ends thereof, said layers being substantially planar, perpendicular to said rotation axis, and axially spaced apart, said magnets in each layer being disposed equiangularly about the circumference of said rotor assembly, such that:
(i) one of said ends of each of said magnets is on a cylindrical periphery of said rotor assembly; (ii) said ends on said periphery have circumferentially alternating north and south poles; and (iii) each of said magnets is magnetically linked to an adjacent one of said magnets by a magnetically permeable linking member situated proximate the other of said ends of said adjacent magnet; (c) said at least one stator assembly comprising a plurality of stator cores, each of said stator cores terminating in a first and a second stator poleface, said stator cores being disposed equiangularly about the circumference of said stator assembly, such that:
(i) said first and second stator polefaces of each of said stator cores are situated on a cylindrical periphery of said stator assembly in axial alignment; (ii) said first stator polefaces are in a first stator layer radially adjacent one of said rotor layers; and (iii) said second stator polefaces are in a second stator layer adjacent another of said rotor layers; and (d) said stator windings encircling said stator cores.
- 23. For use in a dynamoelectric machine having a rotational axis:
a rotor assembly comprising at least two rotor layers having equal numbers of discrete rotor magnets, each of said magnets having a polarity defining north and south poles at opposite ends thereof, said layers being substantially planar, perpendicular to said rotational axis, and axially spaced apart, said magnets in each layer being disposed equiangularly about the circumference of said rotor assembly, such that:
(i) one of said ends of each of said magnets is on a cylindrical periphery of said rotor assembly; (ii) said ends on said periphery have circumferentially alternating north and south poles; and (iii) each of said magnets is magnetically linked to an adjacent one of said magnets by a magnetically permeable linking member situated proximate the other of said ends of said adjacent magnet.
- 24. For use in a dynamoelectric machine having a rotational axis and a rotor assembly comprising at least two rotor layers having equal numbers of discrete rotor magnets, each of said magnets having a polarity defining north and south poles at opposite ends thereof, said layers being substantially planar, perpendicular to said rotational axis, and axially spaced apart, said magnets in each layer being disposed equiangularly about the circumference of said rotor assembly:
a stator assembly comprising a plurality of stator cores, each of said stator cores terminating in a first and a second stator poleface, said stator cores being disposed equiangularly about the circumference of said stator assembly, such that:
(i) said first and second stator polefaces of each of said stator cores are situated on a cylindrical periphery of said stator assembly in axial alignment; and (ii) said first stator polefaces are in a first stator layer and said second stator polefaces are in a second stator layer.
RELATED U.S. APPLICATION DATA
[0001] This application claims the benefit of co-pending U.S. Provisional Application Ser. No. 60/478,074, filed Jun. 12, 2003, and entitled “Radial Airgap Transverse Flux Motor Using Amorphous, Nanocrystalline Grain-Oriented Fe-Based Materials Or Non-Grain-Oriented Fe-Based Materials,” which is incorporated herein in the entirety by reference thereto.
Provisional Applications (1)
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Number |
Date |
Country |
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60478074 |
Jun 2003 |
US |