Apparatus and method for forming a magnet assembly
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H01F-007/06
H02K-015/03
H02K-001/27
H01F-007/02
H02K-041/02
출원번호
US-0208452
(2016-07-12)
등록번호
US-9673688
(2017-06-06)
발명자
/ 주소
Shaw, Steven Robert
출원인 / 주소
E-Circuit Motors, Inc.
대리인 / 주소
Pierce Atwood LLP
인용정보
피인용 횟수 :
0인용 특허 :
40
초록▼
An apparatus for forming a magnet assembly may comprise a base, a bearing assembly, and a support structure positioning mechanism. The bearing assembly may be configured to support a magnet and to allow the magnet to rotate about an axis normal to a surface of the base. The support structure positio
An apparatus for forming a magnet assembly may comprise a base, a bearing assembly, and a support structure positioning mechanism. The bearing assembly may be configured to support a magnet and to allow the magnet to rotate about an axis normal to a surface of the base. The support structure positioning mechanism may be configured to position a support structure on the magnet when the magnet is on the base. The base may comprise at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet moves closer to the base. The bearing assembly may be movable along the axis to allow the magnet to be moved closer to the base and cause the magnet to achieve the preferred angular orientation.
대표청구항▼
1. A method for forming a magnet assembly, comprising: disposing a magnet on a bearing assembly so that the magnet is free to rotate about an axis normal to a surface of a base, the base comprising at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred a
1. A method for forming a magnet assembly, comprising: disposing a magnet on a bearing assembly so that the magnet is free to rotate about an axis normal to a surface of a base, the base comprising at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet is moved closer to the base;moving the bearing assembly relative to the base to bring the magnet closer to the base and allow the magnet to achieve the preferred angular orientation;further moving the bearing assembly relative the base until a surface of the magnet contacts the surface of the base;positioning a support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base; andseparating the magnet and support structure from the base as a unit,wherein the magnet comprises a ring magnet having an alternating sequence of north and south poles and the support structure is configured to be attached to a rotor shaft of an axial flux motor or generator so that the angular position of the unit is fixed with respect to the rotor shaft. 2. The method of claim 1, wherein the at least one magnet alignment feature comprises at least one magnetic field generating component that creates a variable magnetic field that varies as a function of angle about the axis. 3. The method of claim 2, wherein the at least one magnetic field generating component comprises a coil through which a current can flow to generate the magnetic field. 4. The method of claim 1, wherein the support structure comprises a back iron. 5. A method for forming a magnet assembly, comprising: disposing a magnet on a bearing assembly so that the magnet is free to rotate about an axis normal to a surface of a base, the base comprising at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet is moved closer to the base;moving the bearing assembly relative to the base to bring the magnet closer to the base and allow the magnet to achieve the preferred angular orientation;further moving the bearing assembly relative the base until a surface of the magnet contacts the surface of the base;positioning a support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base; andseparating the magnet and support structure from the base as a unit, wherein:one or more ejector members are movably attached to the base; andthe act of separating the magnet and support structure from the base comprises moving the ejector members relative to the base so that the one or more ejector members contact the surface of the magnet and cause the magnet to separate from the base. 6. A method for forming a magnet assembly, comprising: disposing a magnet on a bearing assembly so that the magnet is free to rotate about an axis normal to a surface of a base, the base comprising at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet is moved closer to the base;moving the bearing assembly relative to the base to bring the magnet closer to the base and allow the magnet to achieve the preferred angular orientation;further moving the bearing assembly relative the base until a surface of the magnet contacts the surface of the base; andpositioning a support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base;wherein the at least one magnet alignment feature comprises a characteristic of the base that creates a variable reluctance profile that varies as a function of angle about the axis. 7. The method of claim 6, further comprising: separating the magnet and support structure from the base as a unit. 8. The method of claim 6, wherein the characteristic comprises at least one discontinuity in the surface of the base. 9. A method for forming a magnet assembly, comprising: disposing a magnet on a bearing assembly so that the magnet is free to rotate about an axis normal to a surface of a base, the base comprising at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet is moved closer to the base;moving the bearing assembly relative to the base to bring the magnet closer to the base and allow the magnet to achieve the preferred angular orientation;further moving the bearing assembly relative the base until a surface of the magnet contacts the surface of the base; andpositioning a support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base;wherein:an aligning shaft is attached to the base and comprises an angular positioning feature that corresponds to the angular positioning feature of the support structure;the act of disposing the magnet on the bearing assembly comprises disposing the aligning shaft through a hole in the magnet; andthe act of positioning the support structure on the magnet comprises positioning the support structure on the magnet while keeping the angular positioning feature of the support structure aligned with the angular positioning feature of the aligning shaft. 10. The method of claim 9, wherein the act of positioning the support structure on the magnet comprises engaging the angular positioning feature of the support structure with the angular positioning feature of the aligning shaft so as to prevent the support structure from rotating relative to the aligning shaft about the axis. 11. The method of claim 10, further comprising: separating the magnet and support structure from the base as a unit; andattaching the unit to a rotor shaft of an axial flux motor or generator so that the angular positioning feature of the support structure engages an angular positioning feature of the rotor shaft so as to prevent the unit from rotating relative to the rotor shaft. 12. The method of claim 9, wherein: the angular positioning features of the support structure and the aligning shaft comprise shapes that can be aligned to form a first passage for an aligning key that prevents the support structure from rotating relative to the aligning shaft about the axis; andthe method further comprises inserting an aligning key into the first passage prior to positioning the support structure on the magnet. 13. The method of claim 12, further comprising: separating the magnet and support structure from the base as a unit;attaching the unit to a rotor shaft of an axial flux motor, the rotor shaft comprising a shape that can be aligned with the shape of the support structure to form a second passage for an aligning key that prevents the unit from rotating with respect to the rotor shaft; andinserting an aligning key into the second passage so as to prevent the support structure from rotating relative to the rotor shaft. 14. A method for forming a magnet assembly, comprising: disposing a magnet on a bearing assembly so that the magnet is free to rotate about an axis normal to a surface of a base, the base comprising at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet is moved closer to the base;moving the bearing assembly relative to the base to bring the magnet closer to the base and allow the magnet to achieve the preferred angular orientation;further moving the bearing assembly relative the base until a surface of the magnet contacts the surface of the base; andpositioning a support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base;wherein:the bearing assembly is supported by one or more alignment members movably connected to the base; andthe acts of moving and further moving the bearing assembly relative to the base comprise moving the one or more alignment members relative to the base so as to cause the bearing assembly to move relative to the base. 15. An apparatus for forming a magnet assembly, comprising: a base:a bearing assembly configured to support a magnet and to allow the magnet to rotate about an axis normal to a surface of the base;a support structure positioning mechanism configured to position a support structure on the magnet when the magnet is on the base; andone or more ejector members movably attached to the base and configured to contact a surface of the magnet and cause the magnet and support structure to separate from the base as a unit,wherein the base comprises at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet moves closer to the base,wherein the bearing assembly is movable along the axis to allow the magnet to be moved closer to the base and cause the magnet to achieve the preferred angular orientation, and to be further moved until the surface of the magnet contacts the surface of the base, andwherein the support structure positioning mechanism is configured to position the support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base. 16. The apparatus of claim 15, wherein the magnet comprises a ring magnet having an alternating sequence of north and south poles and the support structure is configured to be attached to a rotor shaft of an axial flux motor or generator so that the angular position of the unit is fixed with respect to the rotor shaft. 17. The apparatus of claim 15, wherein the at least one magnet alignment feature comprises at least one magnetic field generating component configured to create a variable magnetic field that varies as a function of angle about the axis. 18. The apparatus of claim 17, wherein the at least one magnetic field generating component comprises a coil through which a current can flow to generate the magnetic field. 19. The apparatus of claim 15, wherein the support structure comprises a back iron. 20. An apparatus for forming a magnet assembly, comprising: a base;a bearing assembly configured to support a magnet and to allow the magnet to rotate about an axis normal to a surface of the base; anda support structure positioning mechanism configured to position a support structure on the magnet when the magnet is on the base,wherein the base comprises at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet moves closer to the base,wherein the bearing assembly is movable along the axis to allow the magnet to be moved closer to the base and cause the magnet to achieve the preferred angular orientation, and to be further moved until a surface of the magnet contacts the surface of the base,wherein the support structure positioning mechanism is configured to position the support structure on the magnet while keeping an angular positioning feature of the support structure aligned with a particular angular position of the base, andwherein the at least one magnet alignment feature comprises a characteristic of the base that creates a variable reluctance profile that varies as a function of angle about the axis. 21. The apparatus of claim 20, wherein the characteristic comprises at least one discontinuity in the surface of the base. 22. An apparatus for forming a magnet assembly, comprising: a base;a bearing assembly configured to support a magnet and to allow the magnet to rotate about an axis normal to a surface of the base;a support structure positioning mechanism configured to position a support structure on the magnet when the magnet is on the base; andan aligning shaft attached to the base, the aligning shaft comprising an angular positioning feature that corresponds to an angular positioning feature of the support structure,wherein the base comprises at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet moves closer to the base,wherein the bearing assembly is movable along the axis to allow the magnet to be moved closer to the base and cause the magnet to achieve the preferred angular orientation, and to be further moved until the surface of the magnet contacts the surface of the base, andwherein the support structure positioning mechanism is configured to position the support structure on the magnet while keeping the angular positioning feature of the support structure aligned with a particular angular position of the base and the angular positioning feature of the aligning shaft. 23. The apparatus of claim 22, wherein the angular positioning feature of the support structure is configured and arranged to engage the angular positioning feature of the aligning shaft so as to prevent the support structure from rotating relative to the aligning shaft about the axis. 24. The apparatus of claim 22, wherein: the angular positioning features of the support structure and the magnet comprise shapes that can be aligned to form a passage for an aligning key that prevents the support structure from rotating relative to the aligning shaft about the axis. 25. The apparatus of claim 24, further comprising the aligning key. 26. An apparatus for forming a magnet assembly, comprising: a base;a bearing assembly configured to support a magnet and to allow the magnet to rotate about an axis normal to a surface of the base;a support structure positioning mechanism configured to position a support structure on the magnet when the magnet is on the base; andone or more alignment members movably connected to the base and configured to support the bearing assembly and cause the bearing assembly to move relative to the base,wherein the base comprises at least one magnet alignment feature that causes the magnet to rotate about the axis to a preferred angular orientation corresponding to a lower energy configuration as a function of angle about the axis as the magnet moves closer to the base,wherein the bearing assembly is movable along the axis to allow the magnet to be moved closer to the base and cause the magnet to achieve the preferred angular orientation, and to be further moved until the surface of the magnet contacts the surface of the base, andwherein the support structure positioning mechanism is configured to position the support structure on the magnet while keeping the angular positioning feature of the support structure aligned with a particular angular position of the base. 27. The apparatus of claim 26, wherein the bearing assembly comprises a thrust bearing.
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