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Rotor and stator segments for a generator and motor apparatus are provided. The apparatus includes: a pair of parallel, spaced apart stator segments, each stator segment comprising a stator winding set; and a rotor segment slidably coupled to the pair of stator segments, the rotor segment comprising

Rotor and stator segments for a generator and motor apparatus are provided. The apparatus includes: a pair of parallel, spaced apart stator segments, each stator segment comprising a stator winding set; and a rotor segment slidably coupled to the pair of stator segments, the rotor segment comprising a magnet and being dimensioned to fit between the parallel, spaced apart stator segments. The apparatus may include a support structure, the rotor segment being slidably coupled to the support structure and the stator segment being attached to the support structure. The apparatus may be a rim generator, wind turbine generator or other electrical machine. The stator winding set includes a stator winding, and may include other electrical or electronic components, including possibly a power factor capacitor, direct current filtering capacitor, supercapacitor, and one or more diodes. The stator winding set may be encapsulated within the stator segment.

대표청구항 ▼

1. An electromechanical apparatus, the apparatus comprising: (a) a first pair and a second pair of substantially parallel and spaced apart stator segments, each of said first and second pairs of stator segments comprising first and second stator segments, each stator segment of said first and second

1. An electromechanical apparatus, the apparatus comprising: (a) a first pair and a second pair of substantially parallel and spaced apart stator segments, each of said first and second pairs of stator segments comprising first and second stator segments, each stator segment of said first and second pairs comprising a stator winding; and(b) a plurality of rotor segments slidably coupled between said first and second pairs of stator segments, said rotor segments comprising a plurality of magnets, wherein each said magnet of said plurality is arranged such that a polar orientation of each said magnet alternates with respect to a polar orientation of an adjacent said magnet;wherein said pairs of stator segments form a channel, and said rotor segments form a train operable to move within said channel; andwherein said first and second pairs of stator segments are substantially magnetically decoupled from each other; and wherein each said stator segment is physically separate from each other of said stator segments. 2. The apparatus according to claim 1, wherein each said stator winding in each said stator segment is substantially magnetically decoupled from each other of said stator windings. 3. The apparatus according to claim 1, wherein each said stator segment is substantially thermally decoupled from each other of said stator segments. 4. The apparatus according to claim 1, wherein each said rotor segment comprises a plurality of magnets. 5. The apparatus according to claim 1, said rotor segments comprising a first rotor segment, and additionally comprising a second rotor segment comprising at least one magnet, wherein said first and second rotor segments are substantially parallel and axially disposed to each other, and slidably coupled between said first and second pairs of stator segments. 6. The apparatus according to claim 1, wherein said pairs of stator segments form a circumferential channel, and said rotor segments form an annular train operable to move within said channel. 7. The apparatus according to claim 6, said plurality of said rotor segments comprising a first annular train, and further comprising a second plurality of said rotor segments forming a second annular train operable to move within said channel, wherein said first and second annular trains of said rotor segments are substantially parallel and axially disposed to each other. 8. The apparatus according to claim 1, wherein a first distance between said rotor segments and said first stator segments of said first and second pairs is greater than a second distance between said rotor segments and said second stator segments of said first and second pairs. 9. The apparatus according to claim 1, wherein said first pair of said stator segments comprises a first phase of said apparatus, and wherein said second pair of said stator segments comprises a second phase of said apparatus. 10. A method of producing an electromechanical apparatus, the method comprising: (a) manufacturing a plurality of pairs of substantially parallel and spaced apart stator segments, each said pair of stator segments comprising first and second stator segments, each stator segment of said each pair comprising a stator winding;(b) manufacturing a plurality of a rotor segments, wherein each said rotor segment is dimensioned to fit between said each pair of stator segments, said each rotor segment comprising at least one magnet;(c) assembling said plurality of pairs of stator segments to form a circumferential channel, wherein each said pair of stator segments are substantially magnetically decoupled from each other said pair, and each said stator segment is physically separate from each other of said stator segments; and(d) assembling said plurality of rotor segments to form an annular train of said rotor segments slidably coupled to said plurality of pairs of stator segments and operable to move through said channel. 11. The method according to claim 10, wherein said step of manufacturing a plurality of rotor segments comprises encapsulating each said rotor segment in encapsulating material. 12. The method according to claim 10, wherein said step of manufacturing a plurality of pairs of stator segments comprises encapsulating each said stator segment in encapsulating material. 13. The method according to claim 12, wherein said step of encapsulating each said stator segment comprises at least one of: an output electrical component; a capacitor; and a diode; with each said first stator segment of each said pair. 14. The method according to claim 10, wherein said step of assembling said plurality of pairs of stator segments comprises attaching said plurality of pairs of stator segments to a support structure of said apparatus. 15. The method according to claim 10, wherein said step of assembling said plurality of rotor segments further comprises assembling said plurality of rotor segments to form first and second annular trains of said rotor segments, wherein said first and second annular trains are substantially parallel and axially disposed to each other, and are slidably coupled to said plurality of pairs of stator segments and are operable to move through said channel. 16. The method according to claim 10, additionally comprising selecting a first distance between said magnets of said rotor segments and said first stator segments of said plurality of pairs of stator segments, and selecting a second distance between said magnets of said rotor segments and said second stator segments of said plurality of pairs of stator segments. 17. The method according to claim 16, wherein said first distance is greater than said second distance.