IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0672691
(2008-08-28)
|
등록번호 |
US-8587154
(2013-11-19)
|
우선권정보 |
GB-0716679.6 (2007-08-28) |
국제출원번호 |
PCT/GB2008/002906
(2008-08-28)
|
§371/§102 date |
20100209
(20100209)
|
국제공개번호 |
WO2009/027674
(2009-03-05)
|
발명자
/ 주소 |
- Fells, Julian Andrew John
- Pooley, David Martin
|
출원인 / 주소 |
- Access Business Group International LLC
|
대리인 / 주소 |
Warner Norcross & Judd LLP
|
인용정보 |
피인용 횟수 :
39 인용 특허 :
37 |
초록
▼
There is disclosed an inductive power transfer system including a primary unit and a secondary device separable from the primary unit, the primary unit may include a power transfer surface and more than two field generators each operable to generate an electromagnetic field. The field generators may
There is disclosed an inductive power transfer system including a primary unit and a secondary device separable from the primary unit, the primary unit may include a power transfer surface and more than two field generators each operable to generate an electromagnetic field. The field generators may be located at different positions relative to the power transfer surface. The secondary device may include a power receiver having a secondary coil. In one embodiment, the system may determine at least one of the position and the orientation of the power receiver relative to the power transfer surface, and control the field generators such that at least one first field generator and at least one second field generators, selected in dependence upon such determination, are active in a substantially opposite sense to one another so as to direct magnetic flux through the secondary coil thereby supplying power to the secondary device, and further such that a third one of the field generators is inactive so that fewer than all of the field generators are active simultaneously.
대표청구항
▼
1. A primary unit for use in an inductive power transfer system, the system including said primary unit and a secondary device separable from said primary unit, the system of said primary unit and the secondary device having a resonant frequency and being operable to transfer power inductively to th
1. A primary unit for use in an inductive power transfer system, the system including said primary unit and a secondary device separable from said primary unit, the system of said primary unit and the secondary device having a resonant frequency and being operable to transfer power inductively to the secondary device, said primary unit comprising: a power transfer surface capable of enabling inductive coupling with said secondary device in a plurality of different working positions;a plurality of field generators arranged in an array, each of said field generators operable to generate an electromagnetic field for transferring power inductively to the secondary device, each of said field generators having an axis substantially perpendicular to said power transfer surface and being located at a different position relative to said power transfer surface such that said axes of said field generators are spaced apart with respect to each other; anddriver circuitry operable to provide power from a power source to said field generators, said driver circuitry including: switching circuitry to selectively activate at least one of said plurality of field generators by selectively powering said at least one field generator in order to generate said electromagnetic field, wherein said driver circuitry selectively activates said at least one field generator to transfer power inductively to the secondary device, wherein said driver circuitry is operable to drive one or more of said field generators to provide power to the secondary device in at least one of said plurality of different working positions;variable impedance circuitry operably coupled between said power source and said plurality of field generators such that said variable impedance circuitry is shared by said plurality of field generators, said variable impedance circuitry to be adjusted to affect the resonant frequency of the system based on which of said plurality of field generators are selectively activated by said switching circuitry to generate said electromagnetic field, wherein said variable impedance circuitry is adjusted in operation to a predetermined impedance based on which of said plurality of field generators are selectively activated; andwherein said variable impedance circuitry includes a plurality of capacitors arranged in a switched network shared by the plurality of field generators, wherein one or more switches of said switched network are selectively controlled to select an impedance of said variable impedance circuitry. 2. The primary unit of claim 1 further comprising control circuitry to control said switching circuitry to selectively activate said at least one field generator to transfer power inductively to the secondary device. 3. The primary unit of claim 2 wherein said control circuitry maintains inductive power transfer at or near the resonant frequency by adjusting said variable impedance circuitry. 4. The primary unit of claim 2 wherein said control circuitry adjusts said variable impedance circuitry based on a number of selectively activated field generators. 5. The primary unit of claim 4 wherein said control circuitry adjusts said variable impedance circuitry based on a load of the secondary device. 6. The primary unit of claim 4 further comprising determining circuitry to determine a position and an orientation of the secondary device relative to said power transfer surface, wherein said control circuitry adjusts said variable impedance circuitry based on said determined position of the secondary device and said determined orientation. 7. The primary unit of claim 2 wherein the secondary device includes a secondary coil operable to inductively couple with said field generators; wherein said control circuitry selectively activates said at least one field generator such that at least one first field generator and at least one second field generator are active in a substantially opposite polarity to one another so as to direct magnetic flux through the secondary coil thereby supplying power to the secondary device, and further such that a third one of said field generators is inactive so that fewer than all of said field generators are active simultaneously. 8. The primary unit of claim 1 wherein the system includes a plurality of secondary devices, and said field generators are operable to be selectively activated to provide power inductively to the plurality of secondary devices. 9. The primary unit of claim 1 wherein said switched network includes parallel circuits comprising said plurality of capacitors in series with said one or more switches. 10. An inductive power transfer system for transferring power to at least one secondary device comprising: a primary unit including a power transfer surface and a plurality of field generators arranged in an array, each of said field generators operable to generate an electromagnetic field for inductive power transfer, said primary unit including switching circuitry to selectively activate at least one of said plurality of field generators by selectively providing power from a power source to said at least one field generator, each of said field generators having an axis substantially perpendicular to said power transfer surface and being located at a different position relative to said power transfer surface such that said axes of said field generators are spaced apart with respect to each other, wherein said field generators are positioned to provide power to said at least one secondary device at any location in proximity to said power transfer surface;said at least one secondary device separable from said primary unit, said at least one secondary device including a power receiver operable to inductively couple with said field generators for inductive power transfer; wherein said system of said primary unit and said at least one secondary device has a resonant frequency;variable impedance circuitry operably coupled between said power source and said plurality of field generators such that said variable impedance circuitry is shared by said plurality of field generators, said variable impedance circuitry to be adjusted to affect said resonant frequency of said inductive power transfer system based on which of said plurality of field generators are selectively activated by said switching circuitry to generate said electromagnetic field, wherein said variable impedance circuitry is adjusted in operation to a predetermined impedance based on which of said plurality of field generators are selectively; andwherein said variable impedance circuitry includes a plurality of capacitors arranged in a switched network shared by the plurality of field generators, wherein one or more switches of said switch network are selectively controlled to select an impedance of said variable impedance circuitry. 11. The inductive power transfer system of claim 10 further comprising control circuitry to control said switching circuitry to selectively activate said at least one field generator in order to transfer power inductively to said at least one secondary device. 12. The inductive power transfer system of claim 10 further comprising control circuitry to maintain inductive power transfer at or near said resonant frequency by adjusting said variable impedance circuitry. 13. The inductive power transfer system of claim 12 wherein said control circuitry adjusts said variable impedance circuitry based on a number of selectively activated field generators. 14. The inductive power transfer system of claim 12 wherein said control circuitry adjusts said variable impedance circuitry based on a load of said at least one secondary device. 15. The inductive power transfer system of claim 12 wherein said primary unit includes determining circuitry to determine a position of said at least one secondary device relative to said power transfer surface, wherein said control circuitry adjusts said variable impedance circuitry based on said determined position of said at least one secondary device. 16. The inductive power transfer system of claim 10 wherein said primary unit includes said variable impedance circuitry. 17. The inductive power transfer system of claim 10 wherein said switched network includes parallel circuits comprising said plurality of capacitors in series with said one or more switches. 18. A method for use in an inductive power transfer system, the system comprising a primary unit and a secondary device separable from the primary unit, the primary unit including a power transfer surface, drive circuitry, and a plurality of field generators arranged in an array and each being operable to generate an electromagnetic field to transfer power in proximity to the power transfer surface, said method comprising: selectively activating a number of the field generators to transfer power inductively to the secondary device to provide power to the secondary device at any location in proximity to the power transfer surface, wherein each of the field generators has an axis substantially perpendicular to the power transfer surface and is located at a different position relative to said power transfer surface such that the axes of the field generators are spaced apart with respect to each other;controlling the drive circuitry to supply power to the number of active field generators in order to form an inductive coupling between the active field generators and the secondary device, wherein the inductive coupling has a resonant frequency;adjusting an impedance of the drive circuitry to maintain inductive power transfer at or near the resonant frequency based on which of said field generators are selectively activated to transfer power, wherein the impedance circuitry is adjusted in operation to a predetermined impedance based on which of the plurality of field generators are selectively activated;wherein the variable impedance circuitry is operably coupled between a power source and the plurality of field generators such that the variable impedance circuitry is shared by the plurality of field generators, wherein the variable impedance circuitry includes a plurality of capacitors arranged in a switched network shared by the plurality of field generators; andselectively controlling one or more switches of the switch network to select an impedance of said variable impedance circuitry. 19. The method of claim 18 wherein the switched network includes parallel circuits comprising the plural of capacitors in series with the one or more switches. 20. The method of claim 18 wherein the impedance of the drive circuitry is adjusted based on the number of active field generators. 21. A primary unit for use in an inductive power transfer system, the system including said primary unit and a secondary device separable from said primary unit, the system of said primary unit and the secondary device having a resonant frequency and being operable to transfer power inductively to the secondary device, said primary unit comprising: a power transfer surface capable of enabling inductive coupling with said secondary device in a plurality of different working positions;a plurality of field generators arranged in an array and disposed adjacent said power transfer surface, each of said field generators operable to generate an electromagnetic field for transferring power inductively to the secondary device, each of said field generators having an axis substantially perpendicular to said power transfer surface and being located at a different position relative to said power transfer surface such that said axes of said field generators are spaced apart with respect to each other;determining circuitry to determine a position and orientation of the secondary device relative to said power transfer surface;driver circuitry operable to provide power from a power source to said field generators as a function of said determined position and said determined orientation, said driver circuitry including: switching circuitry to selectively activate at least one of said plurality of field generators by selectively powering said at least one field generator in order to generate said electromagnetic field to provide power to the secondary device in at least one of said plurality of different working positions;variable impedance circuitry operably coupled between said power source and said plurality of field generators such that said variable impedance circuitry is shared by said plurality of field generators, said variable impedance circuitry to be adjusted to affect the resonant frequency of the system, wherein said variable impedance circuitry is adjusted in operation to a predetermined impedance based on which of said plurality of field generators are selectively powered; andwherein said variable impedance circuitry includes a plurality of capacitors arranged in a switched network shared by the plurality of field generators, wherein one or more switches of said switched network are selectively controlled to select an impedance of said variable impedance circuitry. 22. The primary unit of claim 21 further comprising control circuitry to control said switching circuitry to selectively activate said at least one field generator to transfer power inductively to the secondary device. 23. The primary unit of claim 22 wherein said control circuitry maintains inductive power transfer at or near the resonant frequency by adjusting said variable impedance circuitry. 24. The primary unit of claim 22 wherein said control circuitry adjusts said variable impedance circuitry based on a number of selectively activated field generators. 25. The primary unit of claim 24 wherein said control circuitry adjusts said variable impedance circuitry based on a load of the secondary device. 26. The primary unit of claim 24 wherein each of said plurality of field generators are located in a plane substantially parallel to said power transfer surface and located at different positions within said plane substantially parallel to said power transfer surface. 27. The primary unit of claim 22 wherein the secondary device includes a secondary coil operable to inductively couple with said field generators; wherein said control circuitry selectively activates said at least one field generator such that at least one first field generator and at least one second field generator are active in a substantially opposite sense to one another so as to direct magnetic flux through the secondary coil thereby supplying power to the secondary device, and further such that a third one of said field generators is inactive so that fewer than all of said field generators are active simultaneously. 28. The primary unit of claim 21 wherein the system includes a plurality of secondary devices, and said field generators are operable to be selectively activated to provide power inductively to the plurality of secondary devices. 29. The primary unit of claim 21 wherein said switched network includes parallel circuits comprising said plurality of capacitors in series with said one or more switches.
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