Combination radial/axial electromagnetic actuator with an improved axial frequency response
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H02K-007/09
F16C-032/04
출원번호
US-0045379
(2011-03-10)
등록번호
US-8847451
(2014-09-30)
발명자
/ 주소
Filatov, Alexei V.
Hawkins, Lawrence A.
출원인 / 주소
Calnetix Technologies, L.L.C.
대리인 / 주소
Fish & Richardson P.C.
인용정보
피인용 횟수 :
0인용 특허 :
66
초록▼
A first bias magnetic flux may be communicated between a first axial pole and a first axial facing surface of the body. A second bias magnetic flux may be communicated between a second axial pole and a second axial facing surface of the body. A time-varying axial control magnetic flux may be communi
A first bias magnetic flux may be communicated between a first axial pole and a first axial facing surface of the body. A second bias magnetic flux may be communicated between a second axial pole and a second axial facing surface of the body. A time-varying axial control magnetic flux may be communicated through the first and second axial facing surfaces of the body, and may be generated in a magnetic circuit including the body, the first and second axial poles, and an axial magnetic backiron. The first and second axial poles may include axial pole laminated inserts composed of electrically isolated steel laminations stacked along the body axis. The axial magnetic backiron may include laminated inserts composed of electrically isolated steel laminations stacked in the direction tangential to the body axis. The axial pole laminated inserts may be magnetically coupled to the axial magnetic backiron laminated inserts.
대표청구항▼
1. An electromagnetic actuator comprising: a body having a rotational axis;a first axial pole residing apart from the body, the first axial pole adjacent a first end facing surface of the body and adapted to communicate magnetic flux across a gap with the first end facing surface of the body;a secon
1. An electromagnetic actuator comprising: a body having a rotational axis;a first axial pole residing apart from the body, the first axial pole adjacent a first end facing surface of the body and adapted to communicate magnetic flux across a gap with the first end facing surface of the body;a second axial pole residing apart from the body, the second axial pole adjacent a second end facing surface of the body and adapted to communicate magnetic flux with the second end facing surface of the body;a first lamination stack comprising electrically isolated steel laminations stacked in a circumferential direction of the body;an axial backiron; the body, the first axial pole, the second axial pole, the axial backiron, and the first lamination stack magnetically linked and defining an axial magnetic control circuit; anda first radial pole residing apart from the body, the first radial pole adjacent a lateral facing surface of the body and adapted to communicate magnetic flux with the lateral facing surface of the body and at least one of the first axial pole or the second axial pole, the body, the first radial pole and the first axial pole or the second axial pole defining a magnetic bias circuit. 2. The electromagnetic actuator of claim 1 further comprising a second radial pole adjacent the lateral facing surface of the body and adapted to communicate the magnetic flux with the lateral facing surface of the body, the first radial pole and at least one of the first axial pole or the second axial pole; the body, the second radial pole and the first axial pole or the second axial pole defining the magnetic bias circuit; the body, the first radial pole and the second radial pole defining a radial magnetic control circuit. 3. The electromagnetic actuator of claim 2 further comprising a radial coil adapted to produce the magnetic flux in the radial magnetic control circuit. 4. The electromagnetic actuator of claim 3 wherein the magnetic fluxes entering the lateral facing surfaces of the body exert radial forces on the body. 5. The electromagnetic actuator of claim 4 wherein the radial forces are proportional to the magnetic fluxes in the radial magnetic control circuits. 6. The electromagnetic actuator of claim 4, wherein an isolated steel lamination includes a first edge that is substantially parallel to the rotational axis and a second edge that is orthogonal to the first edge and that is substantially parallel to a radius of the body. 7. The electromagnetic actuator of claim 1 wherein the end facing surface of the body is substantially orthogonal to the rotational axis. 8. The electromagnetic actuator of claim 1 wherein the body incorporates a magnetically permeable actuator target, the actuator target adapted to communicate the magnetic flux. 9. The electromagnetic actuator of claim 1 further comprising a magnetic element configured to produce magnetic bias flux in the magnetic bias circuit. 10. The electromagnetic actuator of claim 1 further comprising an axial coil adapted to produce the magnetic flux in the axial magnetic control circuit. 11. The electromagnetic actuator of claim 10 wherein the magnetic flux entering the first and second end facing surfaces of the body exerts an axial force on the body. 12. The electromagnetic actuator of claim 11 wherein the axial force is proportional to the magnetic flux in the axial magnetic control circuit. 13. The electromagnetic actuator of claim 1 wherein the first axial pole includes a first segment and a second segment. 14. The electromagnetic actuator of claim 13 wherein the first segment and the second segment are electrically isolated from each other. 15. The electromagnetic actuator of claim 13 wherein the first segment includes a first lamination segment and a second lamination segment, the first and second lamination segments defining the lamination stack. 16. The electromagnetic actuator of claim 15 wherein the first and the second lamination segments are electrically isolated from each other. 17. The electromagnetic actuator of claim 1, wherein the steel laminations are stacked in a direction tangential to a rotational direction of the body. 18. The electromagnetic actuator of claim 1, wherein a steel lamination in the first lamination stack is in a radial plane from the rotational axis. 19. The electromagnetic actuator of claim 18, wherein the steel lamination in the first lamination stack is rectangular with a long axis parallel to the rotational axis. 20. The electromagnetic actuator of claim 1 further comprising a second lamination stack comprising electrically isolated steel laminations stacked in a direction substantially parallel to the rotational axis, wherein the second lamination stack is rigidly affixed to one of the first axial pole or the second axial pole. 21. The electromagnetic actuator of claim 20 wherein the second lamination stack includes a first annular lamination and a second annular lamination, the first and second annular laminations defining an annular lamination stack substantially coaxial to the rotational axis. 22. The electromagnetic actuator of claim 21 wherein the first annular lamination is a first disjointed annular element defining a first air gap between disjoined segments of the first annular element and the second annular lamination is a second disjointed annular element defining a second air gap between disjoined segments of the second annular element. 23. The electromagnetic actuator of claim 22 wherein the first air gap resides misaligned from the second air gap in the annular lamination stack. 24. The electromagnetic actuator of claim 1, wherein the first lamination stack is rigidly affixed to the axial backiron. 25. The electromagnetic actuator of claim 1, wherein the first lamination stack is stacked in the circumferential direction to decrease eddy current in the axial magnetic control circuit. 26. A method for exerting a time-varying force on a body along a body axis, the method comprising: communicating a first bias magnetic flux through a first axial facing surface of the body;communicating a second bias magnetic flux through a second axial facing surface of the body;generating a time-varying axial control magnetic flux;directing the time-varying axial control magnetic flux towards the first and the second axial facing surfaces of the body in a stationary magnetic control circuit, the stationary magnetic control circuit including at least one electrically isolated steel lamination stack stacked in a circumferential direction around the body axis, wherein the stationary magnetic circuit further includes magnetically-permeable electrically-isolated laminations stacked in a direction substantially parallel to the body axis; andcommunicating the time-varying axial control magnetic flux through the first and the second axial facing surfaces of the body. 27. The method of claim 26, wherein the time-varying axial control magnetic flux is generated by a time-varying current in a conductive coil wound around the body. 28. An electric machine system comprising: a stator;a rotor having a rotational axis configured to move relative to the stator;an electromagnetic actuator subassembly comprising: a cylindrical actuator target rigidly mounted on the rotor,a first axial pole residing apart from the actuator target, the first axial pole adjacent a first end facing surface of the actuator target and adapted to communicate magnetic flux across a gap with the first end facing surface of the actuator target,a second axial pole residing apart from the body, the second axial pole adjacent a second end facing surface of the body and adapted to communicate magnetic flux with the second end facing surface of the body,an axial backiron magnetically linking the first axial pole and the second axial pole,a first lamination stack comprising electrically isolated steel laminations stacked in a circumferential direction about the rotational axis, the body, the first axial pole, the second axial pole, the first lamination stack, and the axial backiron magnetically linked and defining an axial magnetic control circuit,a second lamination stack comprising electrically isolated steel laminations stacked in a direction substantially parallel to the rotational axis, wherein the second lamination stack is rigidly affixed to one of the first axial pole or the second axial pole, and wherein the first lamination stack is rigidly affixed to the axial backiron,an axial control conductive coil adapted to produce a magnetic flux in the axial magnetic control circuit,a plurality of radial poles residing apart from the body, the plurality of radial poles adjacent a lateral facing surface of the body and adapted to communicate magnetic fluxes with the lateral facing surface of the body, the body and the plurality of radial poles defining a plurality of radial magnetic control circuits, the plurality of radial poles adapted to communicate magnetic fluxes with the lateral facing surface of the body and at least one of the first axial pole or the second axial pole, the body, the plurality of radial poles and at least one of the first axial pole or the second axial pole defining a magnetic bias circuit, andradial control conductive coils wound around the radial poles and adapted to produce the magnetic flux in the radial magnetic control circuits;one or more position sensors configured to sense a position of the body; andat least one control electronics package configured to control the magnetic fluxes in the axial magnetic control circuit and the radial magnetic control circuits. 29. The electric machine system of claim 28 wherein the body is coupled to a driven load, the driven load comprising at least one of a flywheel, a compressor, a generator, or an expander. 30. The electric machine system of claim 29 wherein the body is coupled to a driver, the driver comprising at least one of a motor, an engine, or a turbine. 31. The electric machine system of claim 28 wherein the at least one electronic control package is configured to control the magnetic fluxes in the axial and radial magnetic control circuits by energizing axial and radial control conductive coil with control currents. 32. The electric machine system of claim 31 wherein the magnetic fluxes exert electromagnetic forces on the actuator target. 33. The electric machine system of claim 32 wherein the electronic control package is further configured to energize the axial and radial control conductive coil with control currents in response to changes of signals from the position sensors so that the rotor is supported by electromagnetic forces without a mechanical contact with the stator.
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