The invention concerns a magnetic guiding device (1) having at least one element (2) to be guided magnetically in the axial direction, e.g. a shaft or an actuation member that is movable in the axial direction, the element (2) having a radial flange (14) made of magnetizable material that is enclose
The invention concerns a magnetic guiding device (1) having at least one element (2) to be guided magnetically in the axial direction, e.g. a shaft or an actuation member that is movable in the axial direction, the element (2) having a radial flange (14) made of magnetizable material that is enclosed by an axial yoke (47) made of ferromagnetic material and constituting a stator, forming magnet gaps (51, 52) in which is producible, by means of a combination of permanent magnets and electromagnets (53, 54, 55), an axial magnetic flux with which the axial position of the element (2) can be influenced, which is characterized in that in the axial yoke (47), at least one pair of axially oppositely polarized permanent magnets (53, 54) are arranged axially next to one another, and an electromagnetic coil (55) is moreover arranged radially adjacently as an electromagnet, the magnetic flux in the coil (55) being controllable in such a way that an asymmetrical magnetic flux having an axial resultant force is producible in the magnet gaps (51, 52).
대표청구항▼
The invention claimed is: 1. A magnetic guiding device (1) having at least one element (2) comprising a shaft or an actuation member to be guided magnetically in the axial direction, the element (2) having a radial flange (14) made of magnetizable material that is enclosed by an axial yoke (47) mad
The invention claimed is: 1. A magnetic guiding device (1) having at least one element (2) comprising a shaft or an actuation member to be guided magnetically in the axial direction, the element (2) having a radial flange (14) made of magnetizable material that is enclosed by an axial yoke (47) made of ferromagnetic material and constituting a stator, forming magnet gaps (51, 52) in which is producible, by means of a combination of permanent magnets and electromagnets (53, 54, 55), an axial magnetic flux with which the axial position of the element (2) can be influenced, wherein in the axial yoke (47), at least one pair of axially oppositely polarized permanent magnets (53, 54) are arranged axially next to one another and in contact against one another, and an electromagnetic coil (55) is moreover arranged radially adjacently as an electromagnet, the magnetic flux in the coil (55) being controllable in such a way that an asymmetrical magnetic flux having an axial resultant force is producible in the magnet gaps (51, 52). 2. The magnetic guiding device as defined in claim 1, wherein a controller is present that is embodied such that the radial flange (14) is permanently axially centered in the axial yoke (47) in a single defined position. 3. The magnetic guiding device as defined in claim 1, wherein a control device is provided with which the element (2) is movable axially back and forth out of a defined position. 4. The magnetic guiding device as defined in claim 1, wherein the radial flange is embodied as an annular flange (14). 5. The magnetic guiding device as defined in claim 4, wherein several axial yokes (47), distributed around the circumference, are provided. 6. The magnetic guiding device as defined in claim 4, wherein the axial yoke is embodied as an annular yoke (47) that surrounds the annular flange. 7. The magnetic guiding device as defined in claim 6, wherein the permanent magnets (52, 54) are embodied as annular magnets, and the coil (55) as an annular coil. 8. The magnetic guiding device as defined in claim 1, wherein the permanent magnets (53, 54) are in contact against the axial yoke (47). 9. The magnetic guiding device as defined in claim 1, wherein the coil (35) is in contact against the axial yoke (47). 10. The magnetic guiding device as defined in claim 1, wherein the coil (55) is in contact against the permanent magnets (53, 54). 11. The magnetic guiding device as defined in claim 1, wherein the permanent magnets (53, 54) are radially adjacent to the circumferential side of the bearing ring (14), and the coil (55) sits radially externally therefrom. 12. The magnetic guiding device as defined in claim 1, wherein the element comprises several radial flanges one behind another in the axial direction, and each radial flange is enclosed by an axial yoke. 13. The magnetic guiding device as defined in claim 1, wherein at least one radial bearing (5, 6) is additionally present for the element (2). 14. The magnetic guiding device as defined in claim 13, wherein the radial bearing (5, 6) comprises a bearing ring (12, 16) sitting on the shaft, and at least one radial bearing stator (19 through 22) axially opposite that ring on at least one side, permanent magnets (23 through 31) being provided both on the bearing rings and on the radial bearing stators (19 through 22). 15. The magnetic guiding device as defined in claim 14, wherein several permanent magnets (23 through 31) are arranged next to one another in the radial direction. 16. The magnetic guiding device as defined in claim 15, wherein the permanent magnets (23 through 31) are in contact with one another against the radial bearing stator (19 through 22) and the bearing ring in the radial direction. 17. The magnetic guiding device as defined in claim 15, wherein in the radial direction, each two adjacent permanent magnets (19 through 22) are oppositely polarized. 18. The magnetic guiding device as defined in claim 14, the radial bearing stator (19 through 22) comprises several sub-stators distributed over the circumference and having permanent magnets (23 through 31). 19. The magnetic guiding device as defined in claim 14, wherein the radial bearing stator (19 through 22) is embodied as an annular stator, and the permanent magnets (23 through 31) as annular magnets. 20. The magnetic guiding device as defined in claim 14, wherein the bearing ring (12, 16) is respectively enclosed on both sides by radial bearing stators (19 through 22). 21. The magnetic guiding device as defined in claim 20, wherein each two radial bearing stators (19 through 22) are combined into one radial yoke (17, 18) that is U-shaped in cross section. 22. The magnetic guiding device as defined in claim 14, wherein at least one radial bearing stator (19 through 22) is supported via spring and damper elements (35, 36; 40 through 44) on a housing-mounted part (37, 38, 39) of the magnetic guiding device (1). 23. The magnetic guiding device as defined in claim 22, wherein the spring elements (35, 36; 40, 41, 42) are embodied as axially extending flexural springs (42). 24. The magnetic guiding device as defined in claim 23, wherein each radial bearing stator (19 through 22) is connected to the housing-mounted part (37, 38, 39) via several flexural springs (42) distributed over the circumference. 25. The magnetic guiding device as defined in claim 24, wherein the flexural springs (42) are each part of a cage (35, 36) that connects the ends of the flexural springs (42) via cage rings (40, 41). 26. The magnetic guiding device as defined in claim 25, wherein the cage (35, 36) surrounds the respective radial bearing stators (19 through 22). 27. The magnetic guiding device as defined in claim 22, wherein the radial bearing stator or stators (19 through 22) are braced via at least one damping element (43, 44) against the housing-mounted part (37, 38, 39). 28. The magnetic guiding device as defined in claim 27, wherein the damping element (43, 44) is embodied annularly and coaxially with respect to the element (2). 29. The magnetic guiding device as defined in claim 27, wherein the damping elements (43, 44) are embodied as liquid films. 30. The magnetic guiding device as defined in claim 29, wherein the liquid films (43, 44) contain magnetic or magnetizable particles and are magnetically impinged upon on at least one side via a permanent magnet (45, 46). 31. The magnetic guiding device as defined in claim 30, wherein the permanent magnets (45, 46) are part of the radial bearing or bearings (5, 6).
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이 특허에 인용된 특허 (12)
Andres Michael (Rockford IL) Coons Terry L. (Dayton OH), Air cycle machine with magnetic bearings.
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