A fault tolerant synchronous permanent magnet machine is disclosed that reduces rotor losses by limiting eddy-current losses in the retaining sleeve. The machine limits eddy-current loss by any one or combination of axially segmenting the retaining sleeve, providing a highly electrically conductive
A fault tolerant synchronous permanent magnet machine is disclosed that reduces rotor losses by limiting eddy-current losses in the retaining sleeve. The machine limits eddy-current loss by any one or combination of axially segmenting the retaining sleeve, providing a highly electrically conductive non-magnetic shield to the retaining sleeve, and by configuring stator teeth width, stator teeth tip width, and slot distribution of the stator.
대표청구항▼
The invention claimed is: 1. A fault-tolerant synchronous permanent magnet machine, comprising: a stator having an axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth hav
The invention claimed is: 1. A fault-tolerant synchronous permanent magnet machine, comprising: a stator having an axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth having a head end that provides a plurality of head ends spaced around said interior cylindrical surface; a rotor having an axial length and comprising a rotor core fixed to a rotatable shaft for rotation therewith and a plurality of permanent magnets mounted on said rotor core at a plurality of locations circumferentially spaced around said rotor core facing the interior cylindrical surface of the stator; and a retaining sleeve having an axial length and disposed between the permanent magnets and the interior cylindrical surface of the stator, wherein a gap is defined between the retaining sleeve and the interior cylindrical surface of the stator, and wherein the permanent magnets and the retaining sleeve are axially segmented into at least four segments to reduce eddy-current losses within the permanent magnet machine. 2. A fault-tolerant synchronous permanent magnet machine, comprising: a stator having an axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth having two side faces terminating at a distal head, each of said distal heads having a head end that provides a plurality of head ends spaced around said interior cylindrical surface; a rotor having an axial length and comprising a rotor core fixed to a rotatable shaft for rotation therewith and a plurality of permanent magnets mounted on said rotor core at a plurality of locations circumferentially spaced around said rotor core facing the interior cylindrical surface of the stator; a retaining sleeve having an axial length and an outer radial surface and disposed between the permanent magnets and the interior cylindrical surface of the stator, wherein the permanent magnets and the retaining sleeve are axially segmented into at least four segments; and a shield disposed upon the outer radial surface of the retaining sleeve, wherein a gap is defined between the shield and the interior cylindrical surface of the stator. 3. The machine of claim 2, wherein the shield comprises an electrically conductive, nonmagnetic material. 4. The machine of claim 3, wherein the shield comprises copper. 5. A fault-tolerant synchronous permanent magnet machine, comprising: a stator having an axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth having two side faces terminating at a distal head, each of said distal heads have a head end that provides a plurality of head ends that circumferentially span said interior cylindrical surface and spaced to create slot openings to the slots; a rotor having an axial length and comprising a rotor core fixed to a rotatable shaft for rotation therewith and a plurality of permanent magnets mounted on said rotor core at a plurality of locations circumferentially spaced around said rotor core facing the interior cylindrical surface of the stator; a retaining sleeve having an axial length and an outer radial surface and disposed between the permanent magnets and the interior cylindrical surface of the stator, wherein the permanent magnets and the retaining sleeve are axially segmented into at least four segments to reduce eddy-current losses within the permanent magnet machine, wherein a gap is defined between the retaining sleeve and the interior cylindrical surface of the stator, and wherein the slots between the plurality of teeth of the stator are irregularly circumferentially spaced. 6. The machine of claim 5, wherein the slots of the stator are irregularly spaced because of a variable thickness of the stator teeth. 7. The machine of claim 5, wherein the slot openings are irregularly circumferentially spaced. 8. The machine of claim 6, wherein the slot openings are irregularly circumferentially spaced. 9. The machine of claim 5, wherein a shield is disposed on the outer radial surface of the retaining sleeve. 10. The machine of claim 6, wherein a shield is disposed on the outer radial surface of the retaining sleeve. 11. The machine of claim 9, wherein the shield comprises copper. 12. A method of reducing eddy-current losses in a permanent magnet machine, comprising: providing an permanent magnet machine comprising: a stator having and axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth having two side faces terminating at a distal head, each of said teeth having two side faces terminating at a distal head, each of said distal heads having a head end that provides a plurality of head ends spaced around said interior cylindrical surface, a rotor having an axial length and comprising a rotor core fixed to a rotatable shaft for rotation therewith and a plurality of permanent magnets mounted on said rotor core at a plurality of locations circumferentially spaced around said rotor core facing the interior cylindrical surface of the stator, and a retaining sleeve having an axial length and an outer radial surface and disposed between the permanent magnets and the interior cylindrical surface of the stator, wherein a gap is defined between the retaining sleeve and the interior cylindrical surface of the stator; and axially segmenting the permanent magnets and the retaining sleeve into at least four segments to reduce eddy-current losses within the permanent magnet machine. 13. The method of claim 12, further comprising: providing a copper shield upon the outer radial surface of the retaining sleeve. 14. A method of reducing eddy-current losses in a permanent magnet machine, comprising: providing a permanent magnet machine comprising: a stator having an axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth having two side faces terminating at a distal head, each of said teeth having two side faces terminating at a distal head, each of said distal heads having a head end that provides a plurality of head ends spaced around said interior cylindrical surface, a rotor having an axial length and comprising a rotor core fixed to a rotatable shaft for rotation therewith and a plurality of permanent magnets mounted on said rotor core at a plurality of locations circumferentially spaced around said rotor core facing the interior cylindrical surface of the stator, and a retaining sleeve having an axial length and an outer radial surface and disposed between the permanent magnets and the interior cylindrical surface of the stator, wherein the permanent magnets and the retaining sleeve are axially segmented into at least four segments, wherein a gap is defined between the retaining sleeve and the interior cylindrical surface of the stator; and providing a copper shield upon the outer radial surface of the retaining sleeve. 15. A method of reducing eddy-current losses in a permanent magnet machine, comprising: providing a permanent magnet machine comprising: a stator having an axial length and a plurality of teeth spaced to define slots therebetween and circumferentially aligned to define an interior cylindrical surface for the stator, each of said teeth having two side faces terminating at a distal head, each of said distal heads have a head end that provides a plurality of head ends that circumferentially span said interior cylindrical surface and spaced to create slot openings to the slots, a rotor having an axial length and comprising a rotor core fixed to a rotatable shaft for rotation therewith and a plurality of permanent magnets mounted on said rotor core at a plurality of locations circumferentially spaced around said rotor core facing the interior cylindrical surface of the stator, and a retaining sleeve having an axial length and an outer radial surface and disposed between the permanent magnets and the interior cylindrical surface of the stator; wherein the permanent magnets and the retaining sleeve are axially segmented into at least four segments to reduce eddy-current losses within the permanent magnet machine, and wherein a gap is defined between the retaining sleeve and the interior cylindrical surface of the stator; and forming the slots between the plurality of teeth of the stator such that the slots are irregularly circumferentially spaced. 16. The method of claim 15, further comprising: forming the head ends to irregularly circumferentially space the slot openings.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (10)
Shinoda Masaki,JPX, Color cathode-ray tube and method of manufacturing the same.
Johnson Roger Neal ; Kliman Gerald Burt ; Liao Yuefeng ; Soong Wen Liang, Method of fabricating rotors with retaining cylinders and reduced harmonic field effect losses.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.